SERVICE
MANUAL
Model 330
Model 340 SC
Model 370 SC
Hughes-JVC Technology Corporation
2310 Camino Vida Roble, Carlsbad, CA 92009-1504
-¤
DECLARATION OF CONFORMITY
PER ISO/IEC GUIDE 22 AND EN 45014
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Safety
Safety Information
Introduction
Before operating or working on a Model 330, 340SC and 370SC Projector, especially
with the cover off, please read this safety information section thoroughly. Procedures
requiring the opening of the projector covers and/or contact with electrical components
should be performed by qualified service personnel. Strictly adhere to all notes and
warnings.
Safety Equipment
Safety equipment specified in the Hughes-JVC Series 300 Projector Service and
Operator’s Training Course and certification program or equivalent should be used for
maintenance of the equipment.
Warnings and Cautions
Warnings and Cautions
Warnings and Cautions in this manual should be read thoroughly and strictly adhered to.
Warning and Caution symbols and definitions are as follows:
WARNING!!! Warns user of a potential electric shock hazard
and/or specific procedure or situation that could result in personal injury if
improperly performed.
CAUTION! Warns user of a potential safety hazard or potential light
hazards that could cause severe eye injury or a specific procedure or situation
that could result in damage to the equipment if improperly used.
The following important safety instructions are designed to insure your safety and the
long life of your projector. Be sure to read these safety instructions thoroughly and adhere
to all warnings given below.
This device complies with Part 15 of the FCC Rules. Operation is subject to the following
two conditions: (1) this device may not cause harmful interference and (2) this device
Model 330, 340SC, and 370SC Service Manual
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Safety
must accept any interference received including interference that may cause undesired
operation.
Operation of this equipment in a residential area is likely to cause harmful interference, in
which case the user will be required to correct the interference at their own expense.
Shielded interconnect cables must be used with this equipment to insure compliance with
the pertinent RF emission limits governing this device.
Installation Safeguards
WARNING!!! If there is any visible damage to any of the cables do
not power on the projector until the damaged cable is replaced.
CAUTION!Place the projector on a smooth, stable and level surface
in an area free from dust and moisture. Do not place the equipment in direct
sunlight or near heat-radiating appliances. Smoke, steam and exposure to direct
sunlight could adversely affect the internal components. Avoid rough handling
when moving your equipment, as a strong shock could damage its internal
components.
CAUTION!If installing a ceiling mount, use only parts supplied or
recommended by the manufacturer. Observe all instructions and warnings as
listed in this manual.
Projector Weight
The HJT projector and shipping container have a combined weight of either 512 (Model
330 and 340SC) or 550 (Model 370SC) pounds. The HJT shipping container weighs 170
pounds and the projector itself weighs either 342 (Model 330 and 340SC) or 380 (Model
370SC) pounds.
Do Not Tilt the Projector More Than 85 Degrees
Do not mount the projector on an excessively tilted base. The projector can be tilted a
maximum of 85 degrees. Mount it only on a stable, vibration-resistant base capable of
supporting at least three times its weight. If in doubt, contact the factory.
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Safety
Avoid Projector Angles of 15° to 23°
Due to voids in the prism fluid there is a dead zone of 19° ± 4°. For this reason, avoid
projector angles of 15° to 23°.
Maximum Projector to Screen Angle is 15°
The maximum vertical tilt angle from projector to screen is 15°. This is the maximum
amount of keystone correction that is possible.
Heat Safeguards
Fans
The projector has multiple fans (exact number varies with projector model number) to
cool the projector system. Do not block the intake or outflow of any of the fans.
Intense heat is emitted within the system and must be properly dissipated in order to keep
the system running properly.
CAUTION!Do Not Block Ventilation. Blocking air intake or exhaust
ports can lead to projector overheating. Do not enclose the unit in a restricted
space. Refer to the appropriate Operator’s Manual for physical access and
thermal clearance and for specific clearances needed for heat dissipation. Allow
at least ten (10) minutes for projector cool down before removing power.
CAUTION!Do not unplug the power cord until after the arc lamp fan
has stopped running. This fan protects the arc lamp from overheating.
Light Safeguards
Ultra Violet and Infrared Light
Eye/face protection is required from ultra violet light and infrared light in accordance
with the following conditions:
1. X3 (up to 375 nanometers) shade goggles must be worn by anyone near the
projector when the lamp is lit and the cover is off.
2. X5 (375 to 700 nanometers) shade goggles when actually working on the
projector near the arc lamp source.
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Model 330, 340SC, and 370SC Service Manual
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Safety
WARNING!!!High temperature, ultraviolet and infrared light. Refer
all service to factory authorized personnel.
Ultraviolet radiation, dangerous glare, and high internal gas pressure
is present at the Xenon Arc Lamp. It is contained in a protective reflector housing
module.
DO NOT operate the Xenon Arc Lamp outside its intended standard housing or outside
of the projector.
When replacement is required, the arc lamp must be replaced as an entire module as
outlined in the Hughes-JVC Model 330, 340SC and 370SC Projector Service Manual.
No attempt should ever be made to replace the arc lamp inside its module!
The arc lamp produces dangerous intense light with hazardous levels of ultraviolet and
infrared radiation. It operates at high temperatures (180ºC, maximum 300º C or over 500º
F).
Do not touch the xenon arc lamp or any connections when the lamp is ignited or is arcing.
WARNING!!! BRIGHT LIGHT! Never look directly at the Arc
Lamp, the lighted Projection Lens, or into the lamp housing, from any distance,
when the projector is ON and light is projected. Direct exposure to light of this
brightness can cause severe eye injury.
WARNING!!!High voltage access and safety interlock. Defeat
restricted to factory authorized service personnel!
WARNING!!!High voltage points up to 40,000 volts are exposed inside the covers.
Allow at least one minute to bleed off high voltage even after the unit has been turned off.
Due to high voltage danger, DO NOT TOUCH:
!
White cables to CRTs—these cables can cause severe shock from a tiny, invisible
crack or hole and should never be touched while projector power is on.
!
!
!
CRT anodes—underneath the CRTs.
Main power +/- supply posts—if shorted with metal objects,
80 amps can flow across the terminals.
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Safety
!
CRT yoke assemblies and other proximity electrical assemblies, components and
wiring—if performing the yoke rotation or width adjustment (outlined in Section
3.2), always use an
!
!
!
ANSI/ASTM 10,000 volt rated safety glove.
Periodically check the condition of safety gloves for cracks.
Arc Lamp main power ± posts.
Power Supply
The projectors operate from power sources indicated in the table below. Verify that local
power source matches these requirements before operation!
Projector Power Supplies
Power
AC
Current
Hz
330
200-240V
20
340SC
200-240V
20
370SC
200-240V
30
50-60
2,700
50-60
3,325
50-60
4,550
Watts
Handle the power cord carefully and avoid excessive bending.
A damaged cord may cause electric shock or fire. For continued safe and reliable
operation, only use cables supplied by the manufacturer for power and signal connections.
Installation should be performed by an electrician with current knowledge of electrical
codes in the country of use.
Fluid Safeguards
Certain components of the projector contain fluid. If any fluid from the projector contacts
the skin, wash off with soap and water. If any fluid from the projector splashes into the
eyes, rinse with cool running water.
Ventilation and Foreign Object Retrieval
Ensure the projector’s multiple fans are free from obstructions and operating properly.
Air filters are located at vent ports on the cover. Air filters require periodic cleaning to
ensure adequate cooling of the projector (see Section 4.3). Verify that vent ports are clear
of all obstructions.
Keep the projector free from foreign objects, such as hairpins, nails, paper, etc. Do not
attempt to retrieve such objects yourself or insert metal objects such as wire and
screwdrivers inside the unit. If an object falls inside the projector, unplug the projector
immediately and call a Hughes-JVC certified technician for removal.
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Safety
WARNING!!!Various procedures in this manual involve the removal
and replacement of system subassemblies. Ensure that the projector AC power
plug is removed from the AC outlet prior to attempting any of these procedures.
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Safety
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Chapter 1---Introduction
1.0 Introduction
This Model 330, 340SC and 370SC Service Manual combines three (3) similar
projector models into one (1) reference book, and should be used in conjunction
with the appropriate projector Operator’s Manual. This manual provides more
detailed information on troubleshooting and maintaining the projectors and a more
in-depth functional description of the system subassemblies than the specific
Operator’s Manual, which cover the specific projector system description,
installation, adjustments, operation, maintenance, specifications, troubleshooting
guide, and parts list.
The areas covered in this Service Manual include any similarities and differences
of functional descriptions of Model 330, 340SC and 370SC projector electronics,
service adjustments, maintenance (removal and replacement of subassemblies),
and troubleshooting.
1.1 Acronyms Used In Manual
ALPS
CH
Arc Lamp Power Supply
Channel
CPU
CRT
Central Processing Unit
Cathode Ray Tube
DSP
Digital Signal Processor
Erasable Programmable Read-Only Memory
Frequency to Voltage
CRT Grid 2
EPROM
F to V
G2
HDB
HDTV
HSYNC
HVPS
ILA®
I/O
Horizontal Deflection Board
High Definition Television
Horizontal Sync
High Voltage Power Supply
Image Light Amplifier
Input/Output
I/R
Infrared
kHz
Kilohertz
LED
Light Emitting Diode
Low Voltage Power Supply
National Television Standards Committee
Printed Circuit Board
Phase Lock Loop
LVPS
NTSC
PCB
PLL
PLUGE
RAM
RGB
ROM
Picture Line-Up Generating Equipment
Random Access Memory
Red, Green and Blue
Read Only Memory
Model 330, 340SC and 370SC Service Manual
1-1
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Chapter 1---Introduction
RTG
SCB
SPS
Raster Timing Generator
System Control Board
System Power Supply
Transistor-Transistor Logic
Video Amplifier Board
Voltage Controlled Oscillator
Vertical Deflection Board
Video Input
TTL
VAB
VCO
VDB
VIN
VPB
VSYNC
VTR
Video Processor PCB
Vertical Sync
Video Tape Recorder
1.2 Safety
High voltages and high intensity light sources exist in the Model 330, 340SC and
370SC Projector Systems and power supplies. Prior to performing any procedures,
adjustments or maintenance review the chapter on Safety Information at the front
of this manual.
1.3 Updates
This manual will be updated with information provided by Service Bulletins and
manual supplements whenever necessary.
1.4 Hardware Compatibility
The table below lists part numbers currently compatible between the Model 330,
340SC and 370SC projectors, and those parts that are different in each.
Table 1-1 Hardware Compatibility
Printed Circuit Boards
330
340SC
370SC
DIFFERENT
PART NUMBERS
Lamp Assembly
900611S
102083
104070
100562
104651
102207
104071
100562
104120
104475
104038
103769
Ignitor
System Power Supply
High Voltage Power Supply
SAME
Raster Timing Generator
Horizontal Deflection Board
Vertical Deflection Board
Video Processing Board
100568
102523
102521
104672
100568
102523
102521
104672
100568
102523
102521
104672
1-2
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Chapter 1---Introduction
Printed Circuit Boards
Video Amplifier Board
System Controller Board
330
340SC
370SC
103774
104668
103774
104668
103774
104668
Table 1-2 Projector Model Comparisons
330 Model
340SC Model
370SC Model
Different
3,000 lumens
4,200 lumens
6,800 lumens
2,500 ANSI lumens
220V AC, 20A, 60Hz
2,700 Watts power
3,700 ANSI lumens
220V AC, 20A, 60Hz
3,325 Watts power
6,000 ANSI lumens
220V AC, 30A, 60Hz
4,550 Watts power
1,500 W Xenon arc lamp 2,000 W Xenon arc lamp 3,000 W Xenon arc lamp
Same
5.2.1 software
5.2.1 software
5.2.1 software
graphics enhancement
graphics enhancement
graphics enhancement
30 memories
30 memories
30 memories
decoder board option
decoder board option
decoder board option
Model 330, 340SC and 370SC Service Manual
1-3
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Chapter 2—Functional Descriptions
2.0 Functional Descriptions
Contents
2.1 Cover and Base............................................................................................2–2
2.2 External Power Requirements.....................................................................2–3
2.3 Electronics Systems Overview....................................................................2–3
2.4 System Power..............................................................................................2–5
System Power Supply................................................................................2–5
Arc Lamp Ignitor.......................................................................................2–9
High Voltage Power Supply......................................................................2-11
2.5 Card Cage....................................................................................................2-14
2.6 Circuit Boards .............................................................................................2-15
Raster Timing Generator Board (RTG) p/n 100568 ................................2-18
Horizontal Deflection Board P/N 102523 (HDB).....................................2-25
Vertical Deflection Board P/N 102521(VDB) ..........................................2-32
Video Processor Board P/N 104672 (VPB) ..............................................2-43
Video Amplifier Board P/N 103567 or 103774 (VAB)............................2-54
System Controller Board P/N 104668 (SCB)............................................2-59
Backplane Board p/n 100571 ...................................................................2-71
2.7 Optical Section............................................................................................2-72
CRT Assembly..........................................................................................2-72
Arc Lamp Assembly..................................................................................2-75
Optical Subassemblies...............................................................................2-76
2.8 Image Light Amplifier.................................................................................2-76
This chapter provides functional descriptions of the major assemblies in the
Model 330, 340SC and 370SC projectors.
Emphasis is placed on a description of system components to the functional block
level. A number of block diagrams are provided for user reference.
Figure 2-1 provides a block diagram overview of the HJT Model 330, 340SC and
370SC projectors. For simplicity, each major electronics assembly is shown with
signal paths between appropriate functional units. Major physical and electronics
assemblies will be described in more detail in the following sections of this
chapter.
Model 330, 340SC and 370SC Service Manual
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Chapter 2—Functional Descriptions
Low Voltage
Power Supply
Arc Lamp
System
Power
Supply
Line Voltage
Lamp Ignitor
RS 232
Infrared Remote
System
Controller
Horizontal
Deflection
Channel 1
Video
Processor
Video Output
Amplifier
CRTs
(3 each)
Channel 2
(R,G,B, H/V Sync)
Vertical
Deflection
and
Raster
Timing
Generator
Convergence
High Voltage
Power Supply
Fans
Image Light
Amplifiers
(3 each
Figure 2-1 Model 330, 340SC and 370SC System Block Diagrams
2.1 Cover and Base
The covers for the HJT Model 330, 340SC
CAUTION!
and 370SC projectors must be installed for proper operation.
Operation of the projector, other than for maintenance, with the
covers removed is not recommended and will void the projector
warranty.
In addition to aesthetics, the covers on the Model 330, 340SC and 370SC
projectors serve several functions. The covers are an integral part of the cooling
system of the projector. Air intake filters are contained in the covers as are cooling
fans. The covers provide the operator and audience with protection from the
extremely bright light produced in the projector. The covers also serve to reduce
the noise generated by operation of the projector. The UL approval is only valid
with the covers installed since they provide the primary protection to prevent
personnel from coming into contact with the high voltages and currents contained
within the projector.
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Chapter 2—Functional Descriptions
The HJT Model 330, 340SC and 370SC
WARNING!!!
projectors use high voltages and high currents. Operation with
covers removed exposes personnel to these dangerous conditions
and may result in serious injury or death. No user-serviceable parts
are contained within the projector. Refer all maintenance to only
factory authorized and trained technicians.
The projector cover is a two-piece molded assembly. It is fastened to the projector
frame by six (6) screws: two (2) on the rear cover; and four (4) on the front cover.
The fan intake side of the cover (right side) has filters on the intake vents.
Periodic cleaning of the filters is required and should be performed in accordance
with the procedure in this manual (Section 4.3). To avoid overheating the
projector, ensure that the cover vent ports are free of obstructions at all times and
that an adequate supply of fresh air is provided to the projector during operation.
2.2 External Power Requirements
The projectors require 208V to 240V, 50 Hz to 60 Hz, single-phase AC power.
The units are equipped with an attached AC power cord and 3-prong twist lock
plug (Model 330 and 340SC use Hubble Model 2323; Model 370SC uses Hubble
Model 2623 or equivalent).
Operation at voltages and frequencies outside of these
listed parameters may cause damage to the projector and will void the warranty.
CAUTION!
2.3 Electronics Systems Overview
The objective of this portion is to provide a good general understanding of the
projector electronics. The understanding gained will enable service personnel to
more effectively maintain the projector to produce the desired result—a great
picture on the screen —and quality you can see.
The Electronics Systems portion of this manual is based on block diagrams. The
diagrams used have been drawn with two purposes in mind. First, they are general
enough to be able to gain an understanding of the overall function of the various
components of the system. Second, the block diagrams contain enough detail to
make them valuable as a troubleshooting tool should the need arise. Schematics
are not used but, where necessary, simplified circuitry is shown to aid in
understanding the capabilities and/or limitations of the system. Discussion of
troubleshooting is included but is largely confined to symptoms and identification
of failed assemblies.
The Hughes-JVC Model 330, 340SC and 370SC projectors are multi-sync
projectors capable of data, graphics, and display from 15KHz to 90KHz
Model 330, 340SC and 370SC Service Manual
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Chapter 2—Functional Descriptions
horizontal and 45Hz to 120Hz vertical. The projected image is continuously
variable from 6 ft to 60 ft over throw distances (varies by projector model) from
10 ft to over 360 ft. All HJT Series 300 projectors are capable of keystone,
pincushion, and linearity correction. The projectors feature digital control of
functions, including convergence, picture adjustments, switching and diagnostics.
In addition, the projector provides the ability to control the relative brightness
anywhere on the screen.
The capabilities of the Model 330, 340SC and 370SC projectors are provided by a
sophisticated electronics system, which consists of power supplies, input/output
devices, and various circuit boards, and using both analog and digital components
to provide functionality with a simple user interface. The electronics systems are
assembled in modular fashion for ease of removal or maintenance.
The Model 330, 340SC and 370SC Electronics System consists of:
System Controller Board;
Video Processor Board;
Video Amplifier Boards (3);
Raster Timing Generator Board;
Horizontal Deflection Board;
Vertical Deflection Board;
Lamp Ignitor;
System Power Supply;
High Voltage Power Supply.
There are also image and sync signal inputs, an LED display, two (2) RS-232
communication ports, and two (2) IR receivers for projector control.
The digital and analog circuits of the System Controller Board direct the operation
of image and raster generation circuits as well as controlling the input/output and
power supply operation of the HJT Model 330, 340SC and 370SC projector
electronics systems.
The System Controller sets operating parameters of the system such as brightness
and contrast, produces internal test patterns and generates on-screen overlays, and
sets the timing for the raster generation to adjust phase, geometric corrections,
uniformity corrections and convergence. The System Controller houses the
program memory as well as the memory for all convergence and uniformity maps,
and has the responsibility of controlling communication with the user, power to
the other areas of the projector, and other necessary functions.
The Video Processor and Video Amplifiers select the desired input signal and
process it to produce the CRT beam modulation necessary to produce an image on
the raster.
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Chapter 2—Functional Descriptions
The Raster Timing Generator provides timing signals to the System Controller
Board, selects the appropriate incoming sync signal and produces the timing
signals for controlling the geometry of the raster.
The Vertical and Horizontal Deflection Boards produce their respective sweep
currents to drive the deflection yokes. The Vertical Deflection Board also houses
the convergence amplifiers that drive correction coils.
The System Power Supply provides all DC power below 200V to the projector.
This includes the supply to the arc lamp/ignitor and the supply to the High
Voltage Power Supply.
The High Voltage Power Supply provides all voltages of 200V and higher. This
includes all CRT bias voltages except the cathode.
Image and sync inputs arrive in the projector at the Video Processor Board.
Inclusion of the Decoder Board is optional. User communication is accomplished
by on-screen displays, LED display output, IR remote input, or RS232
Input/Output. All of these devices are separate from, but communicate directly
with the System Controller Board.
The detailed functional description of the subassemblies are covered below in the
following order:
1. System Power.
2. Card Cage and Circuit Boards.
3. CRT Assembly.
4. Arc Lamp.
2.4 System Power
System Power Supply
The System Power Supply provides the connection between the external power
source and the projector. The System Power Supply provides all internal DC
power to the projector with the exception of that provided by the High Voltage
Power Supply (Section 2.4.3). This includes the low voltage power to the
electronics, the supply power to the HVPS, and the Arc Lamp power.
The System Power Supply is a AC-DC power supply with an input rectifier and
protection circuit and several separate switchers; one (1) for Arc Lamp power, one
(1) for +5V Standby power, one (1) for +24V Standby power, and others for the
other low voltages.
All of the power supply outputs are protected against overvoltage and overcurrent.
Overcurrent protection is a foldback circuit that limits the output current by
reducing the output voltage when an overcurrent condition is detected. An
overvoltage condition at the output of the supply will cause the affected voltage to
be shut down until input power is removed and reapplied.
Model 330, 340SC and 370SC Service Manual
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Chapter 2—Functional Descriptions
All of the SPS output voltages except Arc Lamp power are indicated by a LED
display (see ). The LEDs are located on a bar-type display on the backplane at the
left side of the card cage. The individual LEDs will be lit when the corresponding
voltage is energized. The LEDs are wired to the SPS output power using only a
current limiting resistor so when the LED is lit, it is an indication that there is a
voltage present, not necessarily the correct voltage. To verify whether or not the
voltage at the output is correct, a voltmeter must be used to probe the output
connectors J500, J501, or J502.
+5V +5V +24V +6.3V +15V -15V +24V +48V +107V -200V
STB STB
Figure 2-2 Backplane Status Indicators.
A safety interlock switch is located on top of the power supply. The interlock
switch shuts off the System Power Supply whenever the cover is removed. During
normal operation with the cover installed, the switch is in the 'armed' position.
When the rear cover is removed, the switch will be released and cause power to
the projector to be interrupted. To run the unit without the cover installed,
override the interlock switch by pulling it up into the 'service' position. When the
cover is replaced, the switch will automatically be reset into the 'armed' position.
A circuit breaker is located on the right side of the System Power Supply. The
circuit breaker serves to remove all power from the projector (except for the
power at the input terminals) by switching it to the OFF position.
The circuit breaker must be switched off, and the
CAUTION!
projector must be disconnected from AC power prior to performance of any
maintenance, to ensure that all power is removed from the internal components of
the projector.
Normal operation of the System Power Supply is as follows:
When external power is applied, +5V Standby will always be energized as will the
internal SPS fans. +24V Standby power for operating the fans will be energized
whenever the lamp or electronics are turned-on and five (5) minutes after the
projector is shut down.
All other voltages are controlled by the power-up or power-down commands
issued by the operator.
2–6
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Chapter 2—Functional Descriptions
The Arc Lamp power supply is a current-controlled supply with an open circuit
voltage of about 170V. When the Arc Lamp is operating at steady state, the power
supply provides the current set by the technician. The output of the supply has a
large capacitor that will, on initial ignition of the Arc Lamp, provide the very high
initial current necessary to ionize the xenon gas in the lamp and sustain the arc.
The current setpoint is initially set at the factory and must be reset by the
technician whenever an Arc Lamp is replaced.
AC INPUT POWER
STANDBY/
I/O CONTROL
+5v, +24v
FACTOR
220-240vac
50Hz
CORRECTION
J502
J500
To
Backplane
/FANENBL
/LVPSNBL
/ALENBL
From
System
Controller
LOW VOLTAGE
Power Supply
+5v,+6.3v,+-15v,
+24v,+48v,+107v
J502
ARC LAMP
Power Supply
and Boost
To
Arc Lamp
Via
J503 (-)
J504 (+)
∇
+22v/68a
+170v/1.0a
Ignitor
∇ Model 330. Model 340SC = +25V/80a; Model 370SC = +30V/100a.
Figure 2-3 System Power Supply Block Diagram.
Normal system power-up (Electronics and Lamp):
1. Upon receipt of Power-On command, SCB pulls /FANENBL and
/ALENBL lines low.
2. +24V Standby and Arc Lamp power supplies turn on.
3. When Arc Lamp lights (run voltage sensed by a window comparator in the
SPS), SPS pulls /LAMPLIT line low.
4. When SCB senses /LAMPLIT low, SCB pulls /LVPSNBL line low.
5. Low voltage supplies turn on.
6. SCB senses +5V supply at correct level and enters normal program
sequence.
Lamp only power-up:
1. Upon receipt of Lamp-On command, SCB pulls /FANENBL and
/ALENBL lines low.
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Chapter 2—Functional Descriptions
2. +24V Standby and Arc Lamp power supplies turn on.
3. When Arc Lamp lights (run voltage sensed by a window comparator in the
SPS), SPS pulls /LAMPLIT line low.
4. SCB senses /LAMPLIT low and awaits further instructions.
Electronics only power-up:
1. Upon receipt of Electronics-On command, SCB pulls /FANENBL and
/LVPSNBL lines low.
2. +24V Standby and Low voltage supplies turn on.
3. SCB senses +5V supply at correct level and enters normal program
sequence, lamp can be turned on at any time.
Table 2-1 System Power Supply Voltage Distribution
F
a
n
Arc
CRT SCB HDB VDB VPB RTG VAB Lamp/
Ignitor
HV
PS
Voltage
+5v
+5v Stb
+6.3v
+15v
-15v
+24v
+24v Stb
+48v
+107v
+170v
2–8
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Chapter 2—Functional Descriptions
*Current depends on projector model (see Table 0-1 in Safety Chapter).
** Model 340SC = 2000 Watts; Model 370SC = 3000 Watts.
Figure 2-4 System Power Supply Input/Output Diagram
Arc Lamp Ignitor
The ignitor consists of a step-up power supply, a spark gap, and a transformer.
The Arc Lamp Ignitor is mounted under or next to the Arc Lamp. It provides the
high voltage pulse necessary to ignite the Xenon Arc Lamp that is the illumination
supply for the HJT Model 330, 340SC and 370SC projectors.
The System Power Supply’s Arc Lamp Supply section provides the necessary
voltage to activate the ignitor and to sustain the arc in the Arc Lamp once it has
been ignited. The SPS provides the power necessary to operate the ignitor.
The Ignitor is only active during the time between the Arc Lamp Power Supply
energizing and the Arc Lamp igniting. During steady state operation and when the
projector power is off, the ignitor is inactive.
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Chapter 2—Functional Descriptions
When the Arc Lamp supply first turns on, it supplies 170V to the ignitor. The
ignitor then senses this voltage, activates it’s on-board supply, and produces a
1µS, 38KV pulse to the Arc Lamp. This pulse strikes an arc in the lamp. The Arc
Lamp supply then provides the high current necessary to sustain the arc in the
lamp. Refer to Figure 2-5 and the summary below for a description on the Arc
Lamp and Ignitor timing.
/FANENBL
/ALENBL
/LAMPLIT
38 KV
170V
22-30V
0V
*
2
3
4
5
6
1
CPU TIME-OUT
5-10 MINUTES
ARC LAMP ON
LAMP-OFF
COMMAND
FAN DISABLE
IGNITOR FIRES
LAMP-ON COMMAND
*22-30V depending on projector model.
Figure 2-5 Arc Lamp Ignitor Timing Diagram
Arc Lamp/Ignitor Timing Diagram Summary:
1. The operator powers Arc Lamp on. /ALENBL and /FANENBL from
System Controller Board are pulled low. SPS receives /ALENBL from
SCB and turns on the Arc Lamp PS.
2. Ignitor receives +170V boost voltage from the Arc Lamp PS.
3. Ignitor steps up the +170V boost voltage to a 1 µsec pulse, approximately
38KV.
4. Arc Lamp ignites from the 38kV pulse.
5. High current (about 68-100A depending on projector model) begins
through Arc Lamp and voltage drops to +22-30V (depending on projector
model).
6. /LAMPLIT signal goes to SCB to inform board that Arc Lamp is lit.
2-10
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High Voltage Power Supply
The High Voltage Power Supply is a DC-DC converter (see Figures 2-6 and 2-7)
and is located on the left side of the CRT housing. It provides all necessary
voltages for the CRTs except the cathode drive, which comes from +107V from
the SPS.
Figure 2-6 High Voltage Power Supply
Input power is +24V at 5A from the SPS. The input power is converted into the
high voltage necessary to bias the CRTs.
The HVPS is controlled by an enable line (/HVEN) originating at the Video
Processor Board. This enable line is controlled by logic that turns the HVPS off
when there is a fault that could damage the CRTs. There are two (2) different
conditions that could damage the HVPS:
1. If the +5V supply to the VPB is interrupted, the control and protection is
compromised and the HVPS must be turned off.
2. If the cathode drive power is lost on one of the Video Amplifiers, the
cathode current cannot be controlled and the HVPS is turned off.
3. Further details regarding this logic can be found in the functional
description on the Video Processor Board in Section 2.6.4.
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Chapter 2—Functional Descriptions
The HVPS provides several voltages to the CRTs:
Anode
Grid 1
Grid 2
Focus
+24v
2
3
RED ANODE
GREEN ANODE
BLUE ANODE
GROUND
HDFOCUS
High
11
8
RED FOCUS
Voltage
Power
Supply
HDFOCUS RTN
GREEN FOCUS
BLUE FOCUS
VDFOCUS
12
9
RED G2
VDFOCUS RTN
GREEN G2
BLUE G2
/HVEN
7
6
-200v
(Pins 1,4,5,10 not used)
Power and Control Connector
Figure 2-7 High Voltage Power Supply Input/Output Diagram
3
2
1
6
5
4
9
8
7
12
11
10
Figure 2-8 HVPS Power and Control Connector Jack, J603
2-12
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Chapter 2—Functional Descriptions
CRT anode voltages are not user controllable. They are fixed at 32KV with a
maximum output of 2.1mA total or 0.7mA per CRT. The anode voltage is the
primary acceleration voltage for the CRT. Other bias voltages (screen grid, G2,
and control grid, G1) are used to control the level of beam current. The anode
voltage is routed out of the top of the HVPS, into the CRT housing to three (3)
bulkhead connectors. From there, the anode wires on the CRTs route the anode
voltage directly to the CRT. The anode voltages are overvoltage and overcurrent
protected in the event of short circuits or CRT arcing.
Focus voltage (called Electronic Focus) is a modulated DC voltage. The DC level
is set by the user during initial setup to focus the CRT electron beam. The
Electronic Focus controls are located on the left side of the HVPS (see appropriate
model Operator’s Manual). There are three (one for each color) ¾ turn pots for
adjusting the Electronic Focus. Of the six (6) pots found on the HVPS, the bottom
three (3) are for focus while the top three (3) are for G2 adjustment (Section 3.10).
The DC voltage is modulated within the HVPS using the HDFOCUS and
VDFOCUS input signals. VDFOCUS is the vertical dynamic focus signal, which
is a waveform with parabolic shape at the vertical sweep frequency. HDFOCUS is
the horizontal dynamic focus signal. It is a combination of the vertical dynamic
focus signal and a parabolic waveform at the horizontal sweep rate. These two (2)
signals are combined in the HVPS to form a composite dynamic focus signal.
Dynamic focus is necessary to ensure that the CRT electron beam is converged to
a point as the beam sweeps across the CRT face. Since the CRT faceplate is flat,
the raster sweep causes a varying path length for the electron beam. This means
the focus voltage must be varied as the raster is traced. Focus voltage cannot be
conveniently measured during normal operation.
G2 screen grid voltage is a DC voltage that is set by the user. The three (3)
adjustment controls, one for each color, consist of ¾ turn pots and are located on
the left side of the HVPS immediately above the focus controls. This voltage is set
during initial projector setup to adjust the black level on the screen (see
appropriate model Operator’s Manual). The G2 voltage sets the bias on the screen
grid of the CRT and is normally used to set the cutoff level. However, since the
HJT light valve requires a non-zero input to produce a just-cut-off image on the
screen, G2 is set to produce a slightly greater-than-black raster on the CRT. The
G2 is adjustable from 100V to 1400V individually by color. The actual operating
level will be near 1200V. G2 voltage cannot be conveniently measured during
normal operation.
-200V is the supply to the control grid (G1) of the CRTs through the Video
Amplifier Board. This voltage is not user controllable. The -200V is the only
output voltage from the HVPS that goes to the backplane of the projector to be
routed to the Video Amplifier, and uses the rear-most LED of the backplane LED
bar for indication.
-200V is the only convenient means of directly observing whether or not the
HVPS is turned on, either by observing the indicator LED on the backplane, or by
probing the control connector with a voltmeter.
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Chapter 2—Functional Descriptions
As with the other indicators on that LED bar, the LED is in series with current
limiting resistor, so a lit LED indicates only the presence of a voltage, not
necessarily the correct voltage.
The control grid, G1, voltage is regulated to -81V during normal operation.
During blanking, G1 is pulled to -111V. When the CRTs are disabled for
protection, G1 is pulled to its maximum negative level of -200V, which can be
measured, at the control connector, pin 6.
2.5 Card Cage
The Card Cage provides support and protection for five (5) circuit boards, the
Phase Locked Loop and the optional Decoder Board in the HJT Model 330,
340SC and 370SC projectors. The five-(5) circuit boards are, from rear to front,
the VPB, RTG, SCB, VDB, and HDB. Each circuit board has it's own keyed slot.
A circuit board cannot easily be plugged into the wrong slot since the connectors
will not match up.
Horizontal Deflection Board
Vertical Deflection Board
System Controller Board
(HDB)
(VDB)
(SCB)
P/N 102523
P/N 102521
P/N 104668
P/N 100568
Raster Timing Generator
and Phase Locked Loop
(RTG)
(PLL)
Video Processor Board
(VPB)
P/N 104672
and optional Decoder Board
Figure 2-9 Electronics Card Cage
Four (4) fans on the right side of the card cage cool the circuit cards in the card
cage. These fans are energized by the +24V standby power from the SPS. They
start when either the Arc Lamp or the electronics are powered up and run for
approximately five (5) minutes after the projector is shut down.
The five-(5) cards in the card cage are held into position by both the friction of the
connectors and by a circuit board retaining bar. The circuit board retaining bar
should always be installed during projector operation.
A lightweight top cover is included with the card cage. Eight (8) screws secure the
cover. The cover provides for direction of air flow and for physical protection of
the circuit cards contained in the card cage. The cover should always be installed
when the projector is in operation to ensure adequate cooling of the circuit cards
and to prevent foreign materials from falling into the electronics.
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The card cage is hinged in the rear to allow it to be folded backward for access to
the CRT housing (when folding the card cage backward be sure that nothing is
plugged into the rear electronic jacks or the plugs could be severely damaged).
During normal operation, the card cage should be in its upright position to ensure
proper cooling of the CRT enclosure.
A holddown screw is provided to secure the card cage and prevent it from rotating
backward during shipping or when the projector is mounted in an upward-
pointing position. The holddown screw is located on the lower, front, right corner
of the card cage.
The rear panel of the card cage provides mounting for the projector controls. The
VPB, which receives all image and sync inputs, is secured to the rear panel by
four screws. The RS-232 control connectors and the IR receiver and repeater
inputs as well as the LED dot matrix status display are located on the lower left of
the rear panel. The projector model and serial numbers are also found on the rear
panel.
2.6 Circuit Boards
The Model 330, 340SC and 370SC projectors have a total of twelve (12)
accessible circuit boards. Seven (7) boards are located within the card cage
(Figure 2-9) and five (5) are located outside the card cage (Table 2-2).
Table 2-2 Circuit Boards Outside Card Cage
No.
1
3
Description
330
340SC
370SC
Ignitor
102083
103567
100571
102207
103567
100571
104475
103567
100571
Video Amp Boards (VABS)
Backplane
1
Each circuit board can be replaced individually except the Backplane board and
the PLL. The PLL is replaced with the RTG as a unit. The Ignitor was previously
described in Section 2.4.2. The circuit boards covered in this Section are listed in
Table 2-3.
Table 2-3 Circuit Boards
Page
Circuit Board
P/N
2-18 Raster Timing Generator
2-26 Horizontal Deflection Board (HDB)
(RTG)
100568 and PLL
102523
2-34 Vertical Deflection Board
2-44 Video Processor Board
and optional Decoder Board
2-55 Video Amplifier Board
2-58 System Controller Board
2-70 Backplane Board
(VDB)
(VPB)
102521
104672
(VAB)
(SCB)
103567
104668
100571
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Chapter 2—Functional Descriptions
Figure 2-10 on the following page provides an overall view of how the raster is
produced. Details on the individual PCBs are provided in separate sections in this
chapter.
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Figure 2-10 Raster Generation Block Diagram
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Chapter 2—Functional Descriptions
Raster Timing Generator Board (RTG) p/n 100568
The Raster Timing Generator board is located in the electronics card cage and plugs into
the backplane. It is the second board from the rear of the card cage and consists of a main
board and the PLL daughter board (see Figure 2-11). The PLL board must be installed for
the projector to operate.
Figure 2-11 Raster Timing Generator Block Diagram
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Chapter 2—Functional Description
The following functions are provided by the RTG:
Internal sync generation.
Sync detection and selection.
Serration and equalization pulse removal.
Timing clock pulse generation.
VSYNC separation and field detection.
Timing for several geometry and correction functions.
Serial communication with the SCB.
The block diagram ( see Figure 2-11) description, along with the I/O description in the
Section following, provide information for module-level troubleshooting.
Sync Generator
The sync generator takes its input from the System Controller Board. The SCB provides a
4MHz clock signal, SYSCLK, which is used to generate a HDTV-like sync signal. The
internal sync signal generated is a 33.33KHz horizontal, 59.3Hz vertical, interlaced
signal. Because simply counting down from the 4MHz clock generates it, the actual
signal that is produced is a square wave signal. The square wave does not affect normal
operation of the projector but will cause a vertical bar to be generated on the screen when
the projector is operating on the internal sync with the DC restore timing set to BP or TL.
Sync Detector and Selector
The Sync Detector and Selector take inputs from the Video Processor Board. The VPB
sends the three (3) sync signals, SGSYNC (sync on green), HCSYNC (horizontal or
composite sync), and VSYNC (vertical sync only) of any polarity to the RTG. These are
the sync signals that come from the external source and are what the projector will gen-
lock to when they are available. The sync selector uses a pre-determined priority to
determine which of these sync signals will be used, based on which signals are present at
the input.
The pre-determined priority to determine which sync signals used is:
1. Separate H and V sync will be used if both are available on their respective sync
inputs,
2. Composite sync on the HSYNC input will be used if available and no sync signal
is present on the VSYNC input,
3. Composite sync on the green image input will be used if no coherent sync signal
is available on the HSYNC input.
If no external sync signal is detected on the three (3) sync input lines, the RTG will send
out a signal to the SCB via the IIC interface indicating that there is no sync present
(/External Sync Detect). The SCB will then make a determination whether or not to
command the RTG, via the IIC interface, to select internal sync (Internal Sync Forced).
The selected sync signal(s) is inverted, if necessary, to provide the negative-going sync
signal needed by the downstream circuits.
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Chapter 2—Functional Descriptions
Serration and Equalization Lockout
The Serration and Equalization Lockout takes a composite sync signal and removes any
equalization and serration pulses from it. The Model 330, 340SC and 370SC projectors
do not require these pulses to operate. Removal of the serration and equalization pulses
provides a faster, more reliable response to the vertical sync and subsequent relock to
horizontal sync. This circuit uses the 4xHsync clock that is generated in the PLL to delete
any sync information present in the center portion of the incoming horizontal waveform.
Phase Locked Loop
The PLL receives horizontal sync stripped of the serration and equalization pulses from
the Serration and Equalization Lockout circuit.
The Horizontal Sync signal is fed to horizontal frequency decoder which uses a
frequency/voltage circuit to pre-tune the VCO of the PLL to ensure proper locking. The
Horizontal Frequency Decoder also provides a count of the number of horizontal lines per
frame. The H count is then sent via the IIC interface, to the SCB (HCOUNT). The SCB
uses this information to set up the correction and overlay maps and to calculate the H
frequency.
The PLL takes in the horizontal sync signal and generates a clock signal that is a square
wave of 224 times the horizontal frequency. The PLL will perform this function over the
entire range of horizontal frequencies, 15KHz to 90Khz. It will maintain that signal over
the full period of the raster including the vertical sync pulse. Counters in the PLL circuit
also provide clock signals with frequencies of Hx112, Hx4, Hx2, and Hx1. These clock
signals are square wave signals and are phase-coherent with respect to the H sync signal.
The Hx224, Hx112, and Hx1 signals are used on both the RTG and the SCB for timing of
corrections and raster adjustment. The signals that go to the SCB are Hx224, Hx112
(clock signals), and /HSYNCR (regenerated HSync, a negative-going pulse signal that is
timed to be on the leading edge of the Hx1 clock). The Hx4 and Hx2 clocks are used
exclusively on board the RTG for sync detection and timing.
Control of phase noise is critical—jitter will translate into a "smearing" of the projected
image. Therefore, if the PLL loses lock, the /Phase Lock signal is sent to the SCB via the
IIC interface. The SCB then makes a decision based on that information.
VSYNC Detector, Field Separator, and Mux
The VSync detector uses the Hx2 clock signal to detect the vertical sync signal from the
composite external sync signal that arrives on either the HSYNC input or the sync-on-
green input.
The field separator determines whether or not the signal is interlaced and, if so, which
field is currently being displayed. This information is sent to the SCB as the signals INTI
(interlace indication, high if interlaced), /FIELD1 (low when the field number 1 is
current), and /FRAMEST (indicates the beginning of a new frame).
The mux takes the external Vsync and field signals and multiplexes them with the
internal sync signal to select which will be used. The multiplexed Vsync signal is pulse-
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Chapter 2—Functional Description
shaped to be three (3) horizontal periods in length. This signal, /VSYNCSC (pulse-
shaped vertical sync) is then sent to the SCB and the VPB.
Adjustment Counters
The adjustment counters implement the following timing functions:
Left side, right side, top side, and bottom side blanking.
Vertical and horizontal timing for convergence correction and overlay.
Pincushion and linearity correction timing.
Vertical phase.
DC restore timing.
The four-(4) sides' blanking adjustments are accomplished by counting from the
regenerated H and VSYNC signals respectively. Each adjustment is independent of the
others. Vertical blanking is accomplished by counting a specified number of horizontal
lines after the vertical sync signal out of the VSYNC Mux. The top blanking counts the
commanded number of lines then unblanks the picture. The bottom blanking counts the
commanded number of lines then blanks the image.
Horizontal blanking is accomplished by counting a specified number of Hx224 clock
pulses after the regenerated HSYNC pulse, /HSYNCR). The left side blanking counts the
commanded number of clock pulses then unblanks the image. The right blanking counts
the commanded number of clock pulses then blanks the image. The outputs from these
counters are combined with a signal indicating PLL lock, into a composite blanking
signal VIDBLANK (high when the image is to be blanked) that is sent to the VPB. The
user selects the actual position of the four sides' blanking by adjusting from the remote
control.
The SCB calculates the number of clock pulses to count for each of the four sides based
on the input from the user, and sends those numbers to the appropriate counters via the
IIC serial communication bus signals LBlank, RBlank, TBlank, and BBlank.
Adjustment counters also generate the convergence correction and overlay address
generators’ timing signals. The correction bit-map address counter's MAPST (timing
pulse to tell the correction and overlay address generators to start a new frame) timing
pulse is generated by counting the commanded number of /HSYNCR pulses since the
vertical deflection flyback start pulse. The /CORSTRT (signal that indicates to the SCB
when to start the correction and overlay address generators counting) timing signal is a
pulse signal sent to the SCB. Its timing is determined by counting the commanded
number of Hx224 pulses after the /HSYNCR signal.
The position of the overlays (including menus and test patterns) and correction maps is
controlled automatically in the vertical direction. In the horizontal direction, the user
controls the position via the MENU POSITION selection under the TIMING SETUP
MENU. This circuit also determines the phase between the regenerated HSYNC and the
HV Flyback from Deflection. This value is read by the SCB over the IIC bus.
The pincushion and linearity correction timing signal is a pulse signal called /PCST that
is sent to the Vertical Deflection Board. The signal is generated using the same timing
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method as the /CORSTRT signal but has a separate command from the SCB. It controls
the timing of the top and bottom pincushion correction, top and bottom keystone
correction, and horizontal linearity correction. The signal timing is selected by the user
and controlled by the SCB. Adjusting PINCUSHION POSN under the TIMING SETUP MENU
controls it.
Vertical phase adjustment is accomplished by timing the /VFBST (vertical start) signal
with respect to the regenerated vertical sync signal. This signal is generated by counting a
commanded number of horizontal lines after the vertical sync signal /VSYNCSC. The
signal timing is selected by the user and controlled by the SCB. It is controlled by
adjusting PHASE using the up/down arrows.
DC restore timing determines the point in time that the signal is clamped and the DC
restore (Section 2.6.4, Video Processor Board) function is accomplished. The user has
three (3) choices from which the DC restore timing can be selected. These are Backporch
(BP), Tri-level (TL), and Sync-tip (ST). The choices are selected in the SL column of the
CHANNEL LIST under the CHANNEL MENU (Figure 5-1, Menu Structure).
The DC restore timing counts a preset number of Hx224 clock pulses after the HSYNC
signal leading edge. ST will clamp and DC restore during the time that the HSYNC pulse
is active. ST clamping is timed with respect to the leading edge of the HSYNC pulse. It is
seldom used but is necessary when there is no back porch to clamp on (image starts
immediately after the sync pulse). BP will clamp and DC restore shortly after the HSYNC
pulse. BP clamping is timed with respect to the trailing edge of the HSYNC pulse. The
timing is calculated to be on the back porch of the signal (after the sync pulse but before
the image begins). This is the most frequently used clamp timing.
The default setting for the DC restore timing is BP when a new channel is set up. TL
clamping occurs significantly after the HSYNC pulse. The purpose of TL timing is to
provide DC restore timing that is compatible with the Tri-level type sync used with
HDTV signals. Like BP, TL clamping is timed with respect to the trailing edge of the
HSYNC pulse. The output of the Synctip/Backporch circuit is a pulse signal (DCRSTR)
going to the VPB.
Serial Communication
The RTG uses only the IIC bus for serial communication with the SCB (Section 2.6.6).
The information transferred over the IIC bus is indicated below (I = input to RTG, O =
output from RTG). A change in output data generates an interrupt pulse.
Table 2-4 IIC BUS Information
I/O
Information
Priority Select
Description
Commanded sync selection priority
(always fixed as described above).
I
Vertical Flyback Start Delay Commanded V phase.
I
I
Map Start Delay
Commanded timing for vertical positioning
of correction map.
Commanded position of left blanking.
L Blank
I
R Blank
Commanded position of right blanking.
I
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T Blank
B Blank
/STBP
Commanded position of top blanking.
I
I
I
Commanded position of bottom blanking.
Command for DC restore timing on either
leading or trailing edge of sync pulse.
DC Restore Delay
Commanded timing of DC restore after
reference edge of sync pulse.
I
Internal Sync Forced
Correction Start Delay
Pincushion Start Delay
Command to force internal sync select.
Commanded H phase of correction map.
I
I
I
Commanded H phase of pincushion, keystone,
and linearity correction.
2H Sync Enable
Command determines path of H sync signal.
Command determines path of H sync signal.
I
I
Shifted Sync Enable
/External Sync Detect
HCount
Is an external sync available.
Count of H lines per frame.
Indication of PLL lock.
Indication of phase difference between
HSYNC and HFlyback.
O
O
O
O
/Phase Lock
Phase Count
Raster Timing Generator I/O
This section provides a description of the inputs to and outputs from the RTG. The I/O
description are arranged by the source/destination of the signal and so the assemblies
communicated with are used as the primary heading of each group of signals and then are
further subdivided into inputs and outputs. In each case, the signal's direction is noted,
with input referring to an input to the RTG, and output to an output from the RTG. (e.g.:
under System Controller Board “Input”; SYSCLK refers to the signal SYSCLK that is an
input to the RTG from the System Controller Board). When test points are provided for
the I/O they are noted.
Table 2-5 Raster Timing Generator I/O Signals
System Controller Board
Inputs
Description
SYSCLK
4 MHz clock signal for derivation of internal HDTV sync signal.
(TP 13)
IICCLK
IIC clock line. Unidirectional clock line for control of
synchronous data transfer over IIC data bus.
Outputs
Description
/IICINT
IIC interrupt line. Signal line for slave boards to inform the SCB
(master) that there is data to be transferred. Master then polls
slaves to determine the source of the interrupt.
Square wave signal 224 X the horizontal frequency for overlay
address generator clocking. (TP 23)
/Hx224
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/Hx112
112 times the horizontal frequency for convergence and Z axis
correction address generator clocking. (TP 20)
/CORSTRT Signal used to start the convergence and overlay address
generators during each horizontal sweep. (TP 4)
/FRAMEST Indicates the beginning of a frame. Used in the SCB for
counting vertical frequency. (TP 5)
INTI
Indicates when input source signal is interlaced. (TP 2)
/VSYNCSC Regenerated vertical sync signal, pulse shaped to 3 horizontal
lines in width. (TP 7)
/FIELD1
/MAPST
Low during field #1 of an interlaced input source. (TP 8)
Pulse signal to signal the overlay and correction address
generators to reset for a new frame. (TP 12)
I/O
Description
IICDATA
IIC data line. Bi-directional serial line for synchronous data
transfer between SCB and other circuit boards. See detailed
description for list of signals transferred and data direction.
Video Processor Board
Description
Inputs
SGSYNC
Stripped Green Sync is Sync-on-Green composite sync signal.
(TP 10)
HCSYNC
VSYNC
Horizontal/Composite Sync. (TP 9)
Vertical Sync used only for separate H and V sync. (TP 21)
Outputs
Description
DCRSTR
Pulse for DC restore timed to correspond to ST, BP, or TL.
(TP 1)
VIDBLNK
Signal for image blanking from adjustment counters. (TP 6)
/VSYNCSC Vertical sync signal pulse for ILA bias sync. (TP 7)
Horizontal Deflection Board
Inputs
Description
/HVFLBCK Signal representing horizontal flyback from the HDB. Used for
determining H phase. (TP 17)
Outputs
Description
/VFBST
Signal to start the vertical retrace. (TP 11)
/HSYNCRE Selected HSYNC signal. (TP 14)
Vertical Deflection Board
Outputs
Description
/PCST
Signal to time the start of T/B pincushion and linearity
correction. (TP 31)
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Chapter 2—Functional Description
System Power Supply
Inputs
Description
+15V
Power for the analog section of the RTG including the PLL.
(TP 30)
-15V
Power for the analog section of the RTG including the PLL.
(TP 29)
+5V
AGND
DGND
Power for the digital portions of the RTG. (TP 3)
Return for +/-15V, separated from DGND by an inductor.
Return for +5V, separated from AGND by an inductor.
Interlocks and Protection
This section describes the interactions between boards where one (1) board may cause
others to perform protection functions.
Input
None
Output
If the PLL falls out of sync, a signal indicating an out-of-lock condition (/PLOCK) will be
sent to the SCB.
Internal
When no external sync signal is present, the RTG will select it's internal sync signal, thus
preventing the need to provide another source for overlay generation.
Horizontal Deflection Board P/N 102523 (HDB)
The horizontal deflection board plugs into the electronics card cage and is the forward-
most card in the card cage.
The following functions are provided by the HDB:
Drive main horizontal deflection coils to provide horizontal raster
scan.
Horizontal raster centering.
Horizontal width adjustment.
Side pincushion correction.
L/R keystone correction.
Horizontal sweep reversal.
Horizontal phase adjustment.
Oscillator for vertical deflection.
The block diagram (see Figure 2-12) description and the I/O description, in the section
following, provide information to perform module level troubleshooting.
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Chapter 2—Functional Descriptions
Figure 2-12 Horizontal Deflection Board Block Diagram
Vertical Oscillator
The function of the vertical oscillator is to lock to the vertical signal, /VFBST, sent by the
RTG, and produce a pulsed output, VERTDR, of the same frequency. The /VFBST signal
initially is sent to a Frequency to Voltage converter to provide a program voltage to the
oscillator. This presets the oscillator frequency so the oscillator then is able to lock to the
incoming vertical sync signal.
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Chapter 2—Functional Description
The purpose for having an oscillator for the vertical sweep circuit is to maintain a sweep
even in the event of loss of vertical sync signal to prevent damage to the CRT. The
vertical oscillator has a free-run frequency of approximately 35Hz when there is no input.
Horizontal Phase Locked Loop
The incoming signal, /HSYNCR initially is sent through a Frequency to Voltage
converter. The output from the F to V is used to provide a program voltage to the PLL, set
the horizontal phase adjustment range, and to set the frequency of the horizontal power
supply. The Horizontal PLL, like the vertical oscillator, takes the input pulsed signal,
/HSYNCR, from the RTG, locks to it, and produces a pulsed output of the same
frequency. The Horizontal PLL has the additional function of controlling the phase of the
output signal relative to the input signal. To do this, the horizontal PLL receives an input
from the SCB via the serial bus that indicates the desired phase relationship. The
incoming signal /HSYNCR is then compared with the flyback pulse (derived separately
from the /HVFLBCK signal listed in the I/O section) to measure the phase relationship.
To control horizontal phase, the operator presses the PHASE button on the remote
control, then adjusts phase with the left and right arrow keys. As with the vertical
oscillator, the Horizontal PLL provides for a minimum free-run frequency in the event of
loss of horizontal sync signal. That frequency is approximately 12.5kHz.
Horizontal Centering
Horizontal centering of each raster (R, G, and B) is accomplished by applying a direct
current bias to each horizontal deflection coil. The DC comes from a programmable
current source that is in series with the main deflection coil. The current source is capable
of providing either positive or negative polarity. Control input to the current sources
comes from the SCB via the serial interface. Pressing the POS (Position) button on the
remote control, then selecting the desired color can independently control the centering of
each individual color. The left and right arrow keys are then pressed to adjust horizontal
position. When controlling the position, Green is a master, i.e.: when Green is selected,
all three-(3) colors move. Red and Blue are independent.
Horizontal Power Supply
The horizontal power supply is a switching power supply that provides an output voltage
proportional to the horizontal frequency and width. The variable output of the power
supply is a negative voltage providing a sink for the horizontal deflection current. The
trace speed of the CRT spot will be determined by the voltage applied across the
deflection coil. The voltage at the power supply output directly determines this in turn. So
when the output from the power supply increases, a given width of raster can be obtained
in a shorter period of time, thus supporting a higher horizontal frequency. In addition to
providing for the maintenance of a constant raster size for varying frequency, a variable
power supply is also necessary for control of the raster width. The output voltage of the
horizontal power supply is controlled primarily by two (2) inputs.
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Chapter 2—Functional Descriptions
The first is an input derived from the F to V in the horizontal PLL circuit. This presets the
output of the supply to a voltage that will provide a nominal raster size for the horizontal
frequency applied.
The second input is provided by the SCB via the serial interface. This input allows
control of the raster width by the operator. To control the raster width, the operator
presses the SIZE button on the remote control. Pressing the left and right arrow keys then
controls the width. The three (3) rasters are not remotely controllable on an individual
basis. They can however, be set individually with respect to each other by adjusting the
cores of the variable inductors mounted on the yoke terminal boards (see appropriate
model Operator’s Manual).
Flyback Switching
Flyback switching, necessary to avoid overscan and excessive power consumption over
the wide range of horizontal frequencies covered, is accomplished using relays. When the
input source is changed, the relays are switched to change the response of the resonant
flyback circuit. Since horizontal flyback necessarily causes very high voltages, the relays
must not be switched while under load. When the SCB commands flyback switching to
occur, the switching circuit sends a signal to the GRN Horizontal sweep failure circuit to
turn off the CRT beams. It also sends a signal to the Horizontal Power Supply to turn it
off and shut down the horizontal sweep. The relays are then switched and the sweep and
CRT beams are allowed to return to normal. This sequence of events will occur each time
the input source to the projector changes, regardless of any line rate changes. There are
four frequency bands and flyback times that can be set. The frequency ranges and flyback
times are: 6.6uS @ 15-25.1kHz, 4.1uS @ 25-33.1kHz, 2.9uS @ 33-60.1kHz, and 2.4uS
@ 60-90kHz. Flyback switching is not manually controllable by the operator.
Geometric Correction
The HJT Model 330, 340SC and 370SC projectors provide the ability to obtain a
rectangular raster when shooting off-axis in the vertical direction from the screen. This
ability is provided by left/right keystone correction. A geometric correction signal,
GEOCORR, for controlling both the L/R keystone correction and the L/R pincushion
correction is obtained from the Vertical Deflection Board. The GEOCORR signal is a
periodic signal composed of a parabolic summed with a ramp signal, both at the vertical
frequency. This signal is used to vary the width of the horizontal sweep as the vertical
sweep progresses. It does this by modulating the negative voltage applied to the power
transistor, thereby modulating the horizontal width of the raster. The components of
GEOCORR, pincushion correction and keystone correction, are individually controllable
by the operator (see appropriate model Operator’s Manuals).
Output Section
The horizontal sync pulse signal produced by the Horizontal PLL is applied to the output
section to control the timing of the horizontal sweep. The output section includes the
power output transistor, base drive circuit, reversing connectors, and interlock circuit.
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Chapter 2—Functional Description
The three (3) horizontal deflection coils (B, G, and R) are driven in parallel by a single
drive circuit and transistor. This is the reason for the inability to remotely control the
three (3) raster widths independently. Since the deflection coils are in parallel, it is
imperative that they all be connected prior to applying sweep voltage—the interlock
circuit ensures this. An output from the Horizontal Power Supply is sent, in series,
through all three (3) yoke connectors. This is part of the bias voltage used to operate the
base drive circuit for the output section. Thus, if any of the yoke connectors is not
connected, the output transistor will not turn on, and no horizontal sweep will be present.
There are two (2) output jumpers on the board, J500 and J501. Their function is to
reverse the direction of the current through the horizontal deflection coils for front and
rear projection. The output cable shall be connected to J501 for rear projection and J500
for front projection (Jumper Settings, Section 3.9).
Horizontal Sweep Failure Detection
Protection of the CRT from spot burns is accomplished by never allowing the CRT to
continue to have beam current when there is no deflection. To this end, the HDB has a
sensing circuit that detects when there is a loss of sweep that may cause CRT damage.
This circuit senses the horizontal flyback voltage and frequency. By sensing both
amplitude and frequency, the projector is able to maintain sweep over the widely varying
input conditions allowed and still protect the CRTs from damage. The flyback signal is
AC coupled and peak detected, then compared with a reference. As long as the flyback
amplitude and frequency are above the minimum allowed, the sweep detection outputs
(HSENSBLU, HSENSGRN, and HSENSRED) are pulled high. These signals are sent to
the VDB for processing.
Serial Communication
The HDB uses two (2) separate, interrelated serial data communication systems to
communicate with the SCB; the IIC bus, and a differential, synchronous data bus. The
information transferred over the serial busses is indicated below (I = input to HDB, O =
output from HDB). Also noted is whether the information is transferred over the IIC or
the serial bus. A change in output data generates an interrupt pulse.
Table 2-6 HDB Serial BUS Information
Bus
IIC
I/O
I
Information
Flyback switch select
Description
Two bits that select one of four flyback switching
times (see detailed description)
Pulse signal that commands the flyback relays to
switch.
TTL level that indicates whether the projector is
in front screen mode (high) or rear screen
(pulled low).
IIC
IIC
Flyback switch pulse
Front/Rear indication
I
O
O
IIC
Floor/Ceiling
indication
TTL level that indicates whether the projector is
in the upright mode (high) or inverted mode
(pulled low).
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Chapter 2—Functional Descriptions
Bus
IIC
I/O
I
Information
Serial data load
Description
Command to the serial data receiver that the
incoming data is to be read.
Serial
Serial
HPHASE
HLINR
Commanded horizontal phase of picture.
Commanded amount of overall H linearity
correction.
I
I
Serial
TBKEY
Commanded amount of top and bottom Keystone
Correction.
I
Serial
Serial
Serial
Serial
HCENTBLU
HCENTGRN
HCENTRED
WIDTH
Commanded horizontal position of blue raster.
Commanded horizontal position of green raster.
Commanded horizontal position of red raster
Commanded width of raster
I
I
I
I
Horizontal Deflection Board I/O
This section provides a description of the inputs to and outputs from the HDB. The I/O
description are arranged by the source/destination of the signal and so the assemblies
communicated with are used as the primary heading of each group of signals and then are
further subdivided into inputs and outputs. In each case, the signal's direction is noted,
with input referring to an input to the RTG, and output to an output from the HDB. (e.g.:
under Raster Timing Generator 'Input'; /VFBST refers to the signal /VFBST that is an
input to the HDB from the Raster Timing Generator). When test points are provided for
the I/O they are noted.
Table 2-7 Horizontal Deflection Board I/O Signals
System Controller Board
Inputs
Description
IICCLK
IIC clock line. Unidirectional clock line for control of synchronous data
transfer over IIC data bus.
+SERCLK
Serial data transfer clock (+). Unidirectional, differential clock line from
SCB to other circuit boards. Used for synchronous control of serial
communication over SERDATA data lines.
Serial data transfer clock (-).
-SERCLK
System Controller Board
Inputs
Description
+SERDATA Serial data transfer. Unidirectional, differential, synchronous serial data
communication line. Used for transferring data from SCB to other
circuit boards. Uses SERCLK and IIC for control of receiver.
-SERDATA
Serial data transfer
Outputs
Description
/IICINT
IIC interrupt line. Signal line for slave boards to inform the SCB (master)
that there is data to be transferred. Master then polls slaves to
determine the source of the interrupt.
I/O
Description
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Chapter 2—Functional Description
IICDATA
IIC data line. Bi-directional serial line for synchronous data transfer
between SCB and other circuit boards. See detailed description for
list of signals transferred and data direction.
Raster Timing Generator
Inputs
Description
/VFBST
/HSYNCR
Signal to control the vertical oscillator frequency and retrace timing
Regenerated horizontal sync signal
Outputs
Description
/HVFLBCK
Pulse signal representing horizontal flyback used to determine phase of
image
Vertical Deflection Board
Description
Inputs
GEOCORR
FLRCLING
Periodic signal for L/R keystone and L/R pincushion correction
TTL level indicating whether or not raster is inverted
Outputs
VERTDR
HLINR
HFDBK
WIDTH
Description
Pulse output from vertical oscillator.
DC voltage controlling horizontal edge linearity correction
DC voltage proportional to the H power supply output voltage
DC voltage indicating commanded width.
TBKEYCOR DC voltage representing commanded top and bottom keystone correction
HSENSRED DC voltage, high when flyback pulse for red yoke is present at normal
frequencies.
HSENSBLU Similar to HSENSRED.
HSENSGRN Similar to HSENSRED.
Main Horizontal Deflection Coils
Inputs
Description
/INLCK
Return from series daisy-chain for sensing yoke connectors installed.
Outputs
Description
+INLCK
Negative voltage supply from the horizontal power supply to the daisy-
chained yoke connector interlock.
Positive supply from the centering current source to the blue horizontal
main deflection coil.
Return from the blue horizontal main deflection coil to the horizontal
deflection power transistor.
+BHORYK
-BHORYK
+GHORYK
-GHORYK
+RHORYK
-RHORYK
Similar to +BHORYK.
Similar to -BHORYK.
Similar to +BHORYK.
Similar to -BHORYK.
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Chapter 2—Functional Descriptions
System Power Supply
Inputs
+48V
+15V
-15V
+5V
GND
Description
Power for horizontal deflection
Power for the analog section of the HDB
Power for the analog section of the HDB
Power for the digital devices on the HDB
Return for HDB
Interlocks and Protection
Input
None
Output
HSENSRED - Used to shut down the CRT beams in the event of horizontal sweep
failure.
HSENSGRN - Identical to HSENSERED.
HSENSBLU - Identical to HSENSERED.
Internal
+INLCK
Prevents the horizontal output section from being turned on when 1 or more
deflection coils not connected.
-INLCK
!
!
!
Part of +INLCK circuit.
Minimum Frequency on Oscillators and PLLs
Ensures that there will be a sweep in both the horizontal and vertical
directions when the sync pulse disappears. This is for protection of the CRT
phosphor.
Vertical Deflection Board P/N 102521(VDB)
The Vertical Deflection Board plugs into the electronics card cage and is the second
board from the front in the card cage.
The following functions are provided by the VDB:
Drive main vertical deflection coils to provide vertical raster scan for
all three (3) CRTs.
Drive all correction coils to provide convergence and geometry
correction.
Scan failure detection for all six main deflection circuits.
Vertical size adjustment.
Vertical linearity adjustment.
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Chapter 2—Functional Description
Vertical raster centering.
Top and bottom pincushion correction.
Top and bottom keystone adjustment.
Horizontal overall and edge linearity adjustment.
Left and right pincushion and keystone correction
waveform generation.
Sweep reversal for normal and inverted operation.
Generation of wave forms used for dynamic focus.
The block diagram (see Figure 2-13) description, along with the I/O description in the
following section, provide information for module level troubleshooting.
Component numbering on the VDB, in general, follows the pattern that 2XX refers to
components for Green deflection, 3XX refers to Blue, 4XX refers to Red (e.g.: R428 is a
resistor in the red deflection amplifier). Likewise, the correction amplifiers are numbered
5XX for Green, 6XX for Blue, and 7XX for Red.
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Chapter 2—Functional Descriptions
Figure 2-13 Vertical Deflection Board
Vertical Preamps
The vertical preamps (B, G, and R) each generate a ramp signal with the frequency
determined by the incoming signal VERTDR from the Horizontal Deflection Board. The
ramps generated in the preamp section have their common amplitude set by the
commanded height and are corrected for vertical linearity (linearity is individually
adjustable by R211, R311, and R411 and raster height is individually adjusted by R228,
R328, and R428). The common raster height is adjusted by a signal sent from the SCB to
the VDB via the serial bus. To control height, the operator presses the SIZE button on the
remote control, then adjusts height with the up and down arrow keys. The ramp generated
by the red preamp is used elsewhere in the VDB for the generation of correction signals.
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Chapter 2—Functional Description
Vertical Amplifiers
The Vertical Amplifiers take the ramp signals generated by the Vertical Preamps and
provide further modification prior to driving the vertical deflection coils. Individual
centering signals, set by the operator and controlled by the SCB are inserted in the
Vertical Output Amps to provide offset for each vertical sweep. The centering of each
individual color can be independently controlled by pressing the POS (Position) button on
the remote control then selecting the desired color. The up and down arrow keys are then
pressed to adjust vertical position. When controlling the position, Green is a master, i.e.
when Green is selected, all three (3) colors move. Red and Blue are independent. After
the centering signal is summed with the ramp signal, the result is amplified to produce the
required amplitude signal to drive the main vertical deflection coils.
The Vertical Amplifiers output is sent to jumpers for reversing the direction of the
vertical sweep for inverted operation. Jumpers J200, 300, and 400 are used for normal
operation while J201, 301, and 401 are used for inverted operation. A signal is sent to the
SCB indicating which mode of operation the jumpers are specifying.
Sweep Failure Detection
Current through the vertical deflection coil is sensed and that signal used to drive a sweep
indication circuit. There is one (1) circuit for each of Green, Blue, and Red. The sweep
indication circuit combines the vertical current signal with the horizontal flyback signal.
The signals from Green, Blue, and Red are then combined to produce a signal,
/SWEEPOK, that is sent to the VPB and indicates the health of all of the six (6) sweeps.
In addition to the /SWEEPOK signal, there are six (6) LEDs on the VDB which indicate
the presence of the individual sweeps. The LEDs indicating vertical sweep health
(LED200, 300, and 400) are driven by the vertical sweep signal alone. The horizontal
sweep signals affect both of the appropriate color LEDs (e.g.: if the Blue vertical sweep
fails, LED300 would turn off, but if the Blue horizontal sweep fails, LED300 and
LED301 would both turn off).
Side Pincushion and Keystone Correction
This circuit uses the ramp from the Red preamp to generate a variable amplitude
parabolic waveform for use in L/R pincushion correction. The Red ramp is also used to
generate a variable amplitude and polarity ramp for L/R keystone correction. Both the
L/R pincushion and keystone are controlled by the SCB sending a signal over the serial
bus. The operator can control the L/R pincushion by pressing the PIN button on the
remote control. The left and right arrow keys are then used to vary the amount of
pincushion applied. Pressing the KEY button on the remote control can control the L/R
keystone correction. The left and right arrow keys are then used to vary the amount of
keystone correction applied. The two (2) waveforms are then summed.
This signal is then multiplied by HFDBK from the HDB. The resultant signal,
GEOCORR, is sent to the HDB to modulate the horizontal width for side pincushion and
keystone correction.
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Chapter 2—Functional Descriptions
A form of the vertical frequency parabolic waveform that is derived from the red ramp is
also sent out to the VPB as VPARAB for use in the dynamic focus circuit.
Horizontal Linearity Correction
The Horizontal Linearity Correction section provides correction for both horizontal
overall linearity, and horizontal edge linearity. The WIDTH signal from the HDB and the
/PCST signal from the RTG are combined to form a periodic ramp signal with horizontal
frequency. The ramp signal is used to form a parabolic signal, again with horizontal
frequency. This signal and a signal commanded by the operator, HLINCORR, combine to
form a variable polarity and amplitude parabolic signal with horizontal sweep frequency.
This signal is used for overall horizontal linearity correction. The parabola and ramp
signals are also combined with the HLINLR signal, imported from the HDB, to produce
an S-curve signal of variable polarity and amplitude, also with horizontal sweep
frequency, to be used for edge linearity correction.
The operator can control each of these correction functions from the remote control by
pressing the LIN key for overall linearity adjustment, or the EDGE key for edge linearity
adjustment. The left and right arrow keys are then used to make the adjustments. The S-
curve and parabola are then summed and sent to the Green, Blue, and Red X-correction
amplifiers where the corrections are applied to the correction coils. The parabolic signal
noted above, is also sent out to the VPB as HPARAB to be used in dynamic focus.
Top and Bottom Pincushion and Keystone Correction
A parabolic signal is borrowed from the horizontal linearity correction section for T/B
pincushion correction. It is combined with an operator command signal, TBPNCORR, to
produce a variable amplitude and polarity parabolic signal with horizontal sweep
frequency.
A ramp signal, also from the horizontal linearity section, is used for T/B keystone
correction. It is combined with an operator command signal, TBKEYCOR, to produce a
variable amplitude and polarity parabolic signal with horizontal sweep frequency.
Both the T/B pincushion and keystone are controlled by the SCB sending signals over the
serial bus. The operator can control the T/B pincushion by pressing the PIN button on the
remote control. The up and down arrow keys are then used to vary the amount of
pincushion correction applied. Pressing the KEY button on the remote control can control
the T/B keystone correction. The up and down arrow keys are then used to vary the
amount of keystone correction applied.
These two (2) signals are combined with the red ramp, having the frequency of the
vertical sweep, from the vertical pre-amp, to produce the top and bottom pincushion and
keystone correction waveform. This signal is then sent to the Green, Blue, and Red Y-
correction amplifiers. The operator can control the phase relationship of the T/B
pincushion, T/B keystone, and horizontal linearity, with respect to the picture.
To control these parameters, the operator selects PINCUSHION POSN from the TIMING
SETUP MENU under the MAIN MENU. The left and right arrow keys are then used to
vary the position of the corrections.
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Chapter 2—Functional Description
Correction Amplifiers
There are six (6) correction amplifiers. Each one receives a real-time convergence
correction signal:
RXCORR.
RYCORR.
GXCORR.
GYCORR.
BXCORR.
BYCORR, from the SCB convergence section.
The X-correction amplifiers, R, G, and B, also receive the horizontal linearity signal. The
horizontal linearity signal is then combined with the appropriate color's X-correction
signal to produce a composite horizontal correction signal. The Y-correction amplifiers,
R, G, and B, receive the top and bottom pincushion and keystone correction signal. The
pin and key correction signal is then combined with the appropriate color's Y-correction
signal to produce a composite vertical correction signal. All six (6) correction signals are
then amplified by the correction amplifiers and are sent to their respective yoke coils.
Serial Communication
The VDB uses two (2) separate, interrelated serial data communication systems to
communicate with the SCB; the IIC bus, and a differential, synchronous data bus. The
information transferred over the serial busses is indicated below (I = input to VDB, 0 =
output from VDB). Also noted is whether the information is transferred over the IIC or
the serial bus. A change in output data generates an interrupt pulse.
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Chapter 2—Functional Descriptions
Table 2-8 VDB Serial Bus Information
Bus
IIC
I/O
O
Information
Front/Rear convergence
indication
Description
TTL level that indicates whether the X-
convergence is in front screen mode (high)
or rear screen (pulled low).
IIC
Serial data load
Command to the serial data receiver that the
incoming data is to be read.
I
Serial
Serial
Serial
Serial
Serial
Serial
Serial
Serial
VH
Commanded vertical height of picture.
Commanded vertical position of blue raster.
Commanded vertical position of green raster.
Commanded vertical position of red raster.
Commanded L/R keystone correction.
Commanded L/R pincushion correction.
Commanded T/B pincushion correction.
Commanded overall horizontal linearity
correction.
I
I
I
I
I
I
I
I
VCENTBLU
VCENTGRN
VCENTRED
TRAPCORR
LRPNCORR
TBPNCORR
HLINCORR
General I/O
This section provides a comprehensive description of the inputs to and outputs from the
VDB. The I/O description are arranged by the source/destination of the signal and so the
assemblies communicated with are used as the primary heading of each group of signals
and then are further subdivided into inputs and outputs. In each case, the signal's direction
is noted, with input referring to an input to the RTG, and output to an output from the
VDB. (e.g. under 'Raster Timing Generator', 'Input'; /PCST refers to the signal /PCST that
is an input to the VDB from the Raster Timing Generator). When test points are provided
for the I/O they are noted.
Table 2-9 Vertical Deflection Board I/O Signals
System Controller Board
Input
IICCLK
Description
IIC clock line. Unidirectional clock line for control of synchronous data
transfer over IIC data bus.
RXCORR
A 0-1 V signal from the bit-mapped memory on the SCB. 0.5V represents
no correction. This is a real time signal representing the X correction on
red.
RYCORR
GXCORR
GYCORR
BXCORR
BYCORR
+SERCLK
Similar to RXCORR.
Similar to RXCORR.
Similar to RXCORR.
Similar to RXCORR.
Similar to RXCORR.
Serial data transfer clock (+). Unidirectional, differential clock line from
SCB to other circuit boards. Used for synchronous control of serial
communication over SERDATA data lines.
Serial data transfer clock (-).
-SERCLK
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+SERDATA
-SERDATA
Serial data transfer. Unidirectional, differential, synchronous serial data
communication line. Used for transferring data from SCB to other
circuit boards. Uses SERCLK and IIC for control of receiver.
Serial data transfer.
System Controller Board
Description
Output
/IICINT
IIC interrupt line. Signal line for slave boards to inform the SCB (master)
that there is data to be transferred. Master then polls slaves to
determine the source of the interrupt.
I/o
Description
IICDATA
IIC data line. Bi-directional serial line for synchronous data transfer
between SCB and other circuit boards. See detailed description for list
of signals transferred and data direction.
Raster Timing Generator
Description
Inputs
/PCST
Clock signal to start T/B pincushion, T/B Keystone, and horizontal
linearity correction.
Video Processor Board
Outputs
Description
HPARAB
VPARAB
/SWEEPOK
Parabolic signal at horizontal frequency for dynamic focus.
Parabolic signal at vertical frequency for dynamic focus.
Low indicates that all six sweeps are occurring at normal frequencies.
Horizontal Deflection Board
Description
Inputs
HSENSRED
HSENSBLU
+15V indicates red horizontal flyback occurring at normal frequencies.
Similar to HSENSRED.
HSENSGRN Similar to HSENSRED.
HFDBCK
Voltage representing amount of horizontal scan drive. Used for modifying
amount of side pincushion and keystone when changing horizontal
frequency.
WIDTH
Positive DC voltage representing commanded width of the raster. Used for
generation of horizontal linearity ramp and T/B pincushion correction
waveform.
VERTDR
HLINR
Pulse signal at vertical frequency from the vertical oscillator on the HDB.
Voltage representing commanded horizontal linearity correction.
TBKEYCOR Voltage representing commanded top and bottom keystone correction.
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Chapter 2—Functional Descriptions
Outputs
Description
FLRCLING
Low signal generated from jumper on connector J400 indicates non-
inverted operation.
GEOCORR
Output from L/R pincushion and keystone correction circuits.
Main Vertical Deflection Coils
Description
Outputs
+RVERTYK Supply line to the main vertical deflection coil (red) after going through
FLRCLING jumper plug.
-RVERTYK
Return from main vertical deflection coil (red) after going through
FLRCLING jumper plug.
+GVERTYK Similar to +RVERTYK.
-GVERTYK Similar to -RVERTYK.
+BVERTYK Similar to +RVERTYK.
-BVERTYK
Similar to -RVERTYK.
Correction Coils
Outputs
Description
+RXCORR
-RXCORR
+RYCORR
-RYCORR
+GXCORR
-GXCORR
+GYCORR
-GYCORR
+BXCORR
-BXCORR
+BYCORR
-BYCORR
Supply to the red X correction coil.
Return from the red X correction coil.
Similar to +RXCORR.
Similar to -RXCORR.
Similar to +RXCORR.
Similar to -RXCORR.
Similar to +RXCORR.
Similar to -RXCORR.
Similar to +RXCORR.
Similar to -RXCORR.
Similar to +RXCORR.
Similar to -RXCORR.
System Power Supplies
Description
Inputs
+24V
+15V
-15V
+5V
GND
Power to vertical deflection.
Power for analog portions of VDB.
Power for analog portions of VDB.
Power for digital devices on VDB.
Return for power on VDB.
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Interlocks and Shutdowns
Input
HSENSRED - Used to shut down the CRT beams in the event of horizontal sweep
failure.
HSENSGRN - Identical to HSENSERED.
HSENSBLU - Identical to HSENSERED.
Output
/SWEEPOK
Indicates whether or not all sweeps are occurring at or above a minimum frequency.
Used on the VPB to turn off the signal in the event of loss of sweep.
Internal
None
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Chapter 2—Functional Descriptions
Figure 2-14 Video Generation Block Diagram. This diagram provides an overall view of how the image is produced. Separate
sections of this chapter detail the individual PCBs.
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Chapter 2—Functional Description
Video Processor Board P/N 104672 (VPB)
The Video Processor Board (VPB) plugs into the electronics card cage.
It is the rear-most card in the card cage. The VPB is the only card in the card cage
that is held in by fasteners. There are four screws that tie the input tray to the rear
panel of the card cage. The input tray is an aluminum panel that attaches to the
VPB input BNC connectors. The input tray is a separate assembly and is not
included with the VPB when a new or repaired board is shipped.
The following functions are provided by the VPB:
Image and sync signal input.
Image and sync signal multiplexing.
Sync signal stripping.
Brightness and contrast control.
CRT protection logic.
Internal and external display multiplexing.
Image signal gamma correction.
LCLV uniformity correction.
LCLV bias.
Dynamic focus signal modification.
The block diagram (Figure 2-15) description, along with the I/O description in the
following section, provide information to perform module-level troubleshooting.
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Chapter 2—Functional Descriptions
Figure 2-15 Video Processor Board, Block Diagram
Decoder
The optional decoder is a daughter board installed on the VPB. Since the VPB can
only operate on an RGB/sync signal, use of the decoder is necessary in order for
the projector to use a composite signal. The decoder takes a composite (NTSC,
PAL, or SECAM) or S-Vid input and converts it into an RGB Sync signal for
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Chapter 2—Functional Description
further use in the Video Processor Board. The IIC bus is used by the decoder to
select either Channel 3 (NTSC) or Channel 4 (S-Vid). The two (2) signals are
multiplexed together on the decoder board for export to the Video/Sync Mux.
Video/Sync Mux
The Video/Sync Mux selects one (1) of three (3) external inputs (RGB1, RGB2,
or Decoder) for use as the source for Image display and sync signals. The two (2)
external RGB Sync signals are selected by choosing RGB1 or RGB2 in the
CHANNEL LIST under the CHANNEL MENU. Selecting either CVID (for the
composite input) or SVHS (for the S-Vid input) from the same CHANNEL LIST
uses the input from the decoder. The input to be used is selected by the System
Controller Board via the IIC bus. A green LED on the input panel is lit to indicate
which input is selected. The RGB image inputs are AC coupled while the sync
and decoder inputs are DC coupled. All inputs have a 75 ohm input impedance.
V & H Sync Strip
The vertical and horizontal sync signals are taken from the Video/Sync Mux and
individually peak and trough detected then pulse shaped to provide a TTL-level
signal representing the HSYNC and the VSYNC. Those signals are then sent out
to the RTG as the signals HSYNC and VSYNC and can be monitored on TP 14
and 15 respectively.
SG Sync Strip
The SG Sync Strip circuit looks at the green image signal between the video
MUX and the Brightness and Contrast Amp and sends the signal through a buffer
then peak detects the signal. The peak-detected signal then is compared with a
reference voltage to discriminate the sync signal from the video. The stripped sync
signal is then pulse shaped to provide a TTL representation of the composite sync
signal. The signal is sent out to the RTG as SGSYNC and can be probed at TP 13.
B, G, and R Brightness and Contrast Amplifiers
Each color of video (R, G, and B) uses an identical circuit. The Brightness and
Contrast amplifier serves to adjust the black and white levels of the external video
and also protects the CRT from excessive beam current by taking the beam
current signal from the Video Output Amp and comparing it with a reference. If
the beam current exceeds 1mA, the contrast command voltage is reduced to a
level that brings the CRT beam current back within bounds.
The Brightness and Contrast amplifier takes the contrast command signal after the
beam current limit circuit, and uses it to set the gain of the amplifier for contrast
control. Contrast is controlled by the SCB via the IIC interface. The operator
controls contrast level by pressing the CONT button and using the up and down
arrows on the remote control. Green is a master and will control all three (3)
colors together. R and B are independent.
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Chapter 2—Functional Descriptions
Adding a DC offset to the output of the amplifier controls brightness. The
brightness is controlled by the SCB via the IIC interface. The operator controls
contrast level by pressing the BRIGHT button and using the up and down arrows on
the remote control. All three (3) colors are controlled together. During the DC
Restore interval when the BPCP pulse (measured at TP 10) is high, the output of
this amp is set to the nominal DC level.
On-Screen Switch
In the on-screen switch, the external video signal is multiplexed, in real time, with
internal video signals. The internal video signals used are full brightness, black, or
gray-scale/pyramid for a total of four (4) different signals that are multiplexed at
each point on the screen. The real-time multiplexing is used for the generation of
overlays and test patterns and is controlled by the switch logic. The output of the
on-screen switch can be monitored by test points TP5 (Red), TP6 (Green), and
TP7 (Blue).
Gamma Correction
After the On-Screen Switch the signal goes to the Gamma Correction section.
Gamma Correction is a non-linear gain stage that accounts for the non-linearities
of the ILA® Assemblies as well as for the CRT to produce a linear gray-scale on
the screen for a linear gray-scale input.
Switch Logic and Video Enable
This section controls the overlays and test patterns on the screen as well as
providing protective functions.
Protection of the CRTs is accomplished by sensing dangerous conditions and
initiating protective functions. There are three (3) conditions that the projector
considers dangerous to the CRTs that are addressed in this circuit. Those three (3)
conditions are loss of sweep (any of the six), defective video amp, and loss of
power to the VPB.
When a loss of sweep occurs, the /SWEEPOK signal is released by the VDB and
is pulled high by the VPB. This initiates two (2) protective functions. First (1st)
is that the video signal is immediately cut off. This is the fastest way to reduce the
CRT beam current to prevent CRT damage. It is also the least effective since even
when there is no video signal to the video amp, there can still be beam current due
to a high G2 or other causes. Therefore, a second (2nd) function is initiated when
/SWEEPOK goes high. The enable signal to the video amps, /RENABLE,
/GENABLE, and /BENABLE is released by the VPB (all three [3] regardless of
which sweep is lost) and pulled high by the VAB. When this happens, it signals
the VAB to remove some of the bias voltage from its CRT. This further reduces
the possibility that there will be any beam current present during loss of sweep
and although more effective than removing video signal, it takes more time.
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A defective video amp is detected by the state of the /RVIDOK, /GVIDOK, and
/BVIDOK signals arriving from the VABs. A loss of +5V power to the VPB is
detected by observing it internally to this circuit. When any one of the VIDOK
signals goes high or a loss of +5V is detected, action will be taken to shut down
all three (3) CRTs.
Loss of +5V or defective VAB can potentially be more serious than loss of sweep.
Therefore, when one (1) of these conditions occurs, the same action will be taken
as for loss of sweep with the additional action of shutting down the HVPS. This is
done by releasing the /HVEN line allowing the HVPS to pull it high. Turning off
the HVPS is the most effective way of protecting the CRT but is also slowest—
explaining why other actions are taken in conjunction.
Switch logic is the portion of the circuit that controls what is seen on the screen at
any point at a given time. The SCB sends out signals as the raster is scanned.
These signals are outputs from the on-screen display bit-map. The signals
controlling on-screen video are BONSCRN, RONSCRN, GONSCRN,
VONSCRN, and VIDTEST. The signals are decoded in PALs on the VPB and
result in signals that control the on-screen switch multiplexers to display the test
patterns, text, and video.
Switch logic also takes in the signals from the RTG that control DC restore
(DCRSTR) and blanking (VIDBLANK) and distributes them throughout the VPB
and out to the VAB as the signals CLAMP and BLANKING.
RGB Sensitivity and Threshold Amplifier
Each color of video (R, G, and B) uses an identical circuit.
The video signal is taken from the output of the gamma correction section,
amplified, and sent off the VPB to the VAB via signals RVOUT (TP1), GVOUT
(TP2), and BVOUT (TP3).
The Threshold correction adds an offset to the signal in similar fashion to that of
the brightness control in the Brightness and Contrast Amp. The difference is that
the Threshold correction is, in general, not a pure DC signal, nor does the beam
current limit circuit affect it. Rather, it is a varying signal generated by the System
Controller Board in real time representing the correction necessary to account for
turn-on-point variations across the ILA® Assemblies. The signals from the SCB
are RTHRESH, GTHRESH, and BTHRESH. Also, when the clamp pulse signals
that it is time to do DC restore, the /BPCP signal removes the threshold correction
so that it will be reapplied after DC restore.
Sensitivity correction is applied by varying the gain of the amplifier. Like
threshold correction, the sensitivity correction signal that controls the gain is not,
in general, pure DC nor affected by beam current limit. It is a varying signal
generated by the System Controller Board in real time representing the correction
necessary to account for sensitivity variations across the ILA® Assemblies. The
signals for sensitivity correction from the SCB are RSENS, GSENS, and BSENS.
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Video signal cutoff is accomplished by pulling blanking to zero.
ILA® Bias
ILA® Assembly biasing is accomplished by generating a pseudo-square-wave
with frequency set by the operator. The SCB sends the information on bias
frequency via the IIC interface to the VPB. The operator can control the frequency
over a range of from 1.5KHz to 3.0KHz. Selecting ILA BIAS FREQ from the ILA
SETUP menu under the MAIN MENU controls the frequency. The bias square
wave is phase locked to the vertical sync to prevent any moving artifacts from
occurring on the screen due to bias.
The bias square wave is passed through an amplifier whose gain is set by the
operator via the SCB to vary the bias. This square wave is then turned into a
differential output in order to eliminate DC going to the ILA® Assemblies. The
outputs can be monitored at TP11 and 12 (RED), 1 and 14 (GRN), and 15 and 16
(BLU). Selecting BIAS W/O VIDEO from the ILA SETUP MENU under the
Main Menu controls the bias level for each individual color. The up and down
arrows are then used to vary the bias level.
Dynamic Focus Amplifier
The vertical focus amplifier takes the VPARAB signal from the VDB, amplifies it
and sends it out to the HVPS as the signal VDFOCUS for vertical dynamic focus.
The HPARAB signal, from the VDB, is multiplied by the VPARAB signal,
amplified, and also sent out to the HVPS as the signal HDFOCUS for horizontal
dynamic focus.
Serial Communication
The VPB uses two (2) separate, interrelated serial data communication systems to
communicate with the SCB; the IIC bus, and a differential, synchronous data bus.
The information transferred over the serial busses is indicated below (I = input to
VPB, O = output from VPB). Also noted is whether the information is transferred
over the IIC or the serial bus. A change in output data generates an interrupt pulse.
Table 2-10 VPB Serial BUS Information
BUS
IIC
I/O
Information
RENABLE
GENABLE
BENABLE
CH1SEL
Description
Signal to cut off red.
Signal to cut off green.
Signal to cut off blue.
Selects RGB1 as input.
I
I
I
I
I
I
IIC
IIC
IIC
IIC
IIC
CH2SEL
Selects RGB2 as input.
ILA® bias freq
Information for setting bias frequency to ILA®
Assembly.
IIC
I
SLOAD
Command to the serial data receiver that the
incoming data is to be read.
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IIC
IIC
IIC
O
O
O
VIDOK
SWEEPOK
BEAMDET
Tells SCB that no VABs are reporting problems.
Tells SCB that all sweeps are operating.
Tells SCB that beam current limiting is occurring.
BUS
I/O
Information
Description
Serial I
Serial I
Serial I
Serial I
Serial I
Serial I
Serial I
REDBIAS
GRNBIAS
BLUBIAS
RCONT
GCONT
BCONT
Commanded amplitude of red LCLV bias.
Commanded amplitude of green LCLV bias.
Commanded amplitude of blue LCLV bias.
Commanded red contrast.
Commanded green contrast.
Commanded blue contrast.
BRIGHT
Commanded brightness level.
General I/O
This section provides a comprehensive description of the inputs to and outputs
from the VPB. The I/O description are arranged by the source/destination of the
signal and so the assemblies communicated with are used as the primary heading
of each group of signals and then are further subdivided into inputs and outputs. In
each case, the signal's direction is noted, with input referring to an input to the
RTG, and output to an output from the VPB. (e.g.: under Raster Timing Generator
'Input'; VSYNC refers to the signal VSYNC that is an input to the VPB from the
Raster Timing Generator). When test points are provided for the I/O they are
noted.
Table 2-11. Video Processor Board I/O Signals
System Controller Board
Input
Description
IICCLK
IIC clock line. Unidirectional clock line for control of
synchronous data transfer over IIC data bus.
Along with RONSCRN, GONSCRN, VONSCRN,
VIDBLANK, and DCRSTR (the later two on from the
RTG board) determines whether there is full brightness,
black, gray-scale, or external video presented in blue at a
given point on the screen.
BONSCRN
RONSCRN
GONSCRN
VONSCRN
VIDTEST
Similar to BONSCRN.
Similar to BONSCRN.
Determines if internal test patterns will be shown.
Internal gray-scale video input information. Real time data 0V
to 1V.
RSENS
Sensitivity (Z-axis gain) correction information for red. Real
time data at 0V to 1V.
GSENS
BSENS
Similar to RSENS.
Similar to RSENS.
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RTHRESH
Threshold (Z-axis offset) correction information for red. Real
time data at 0V to 1V.
GTHRESH
BTHRESH
+SERCLK
Similar to RTHRESH.
Similar to RTHRESH.
Serial data transfer clock (+). Unidirectional, differential clock
line from SCB to other circuit boards. Used for
synchronous control of serial communication over
SERDATA data lines.
-SERCLK
Serial data transfer clock (-).
+SERDATA
Serial data transfer. Unidirectional, differential, synchronous
serial data communication line. Used for transferring data
from SCB to other circuit boards. Uses SERCLK and IIC
for control of receiver.
-SERDATA
Serial data transfer.
System Controller Board
Outputs
Description
/IICINT
Interrupt used to tell the SCB that the VPB has data to report.
I/O
Description
IICDATA
IIC data line. Bi-directional serial line for synchronous data
transfer between SCB and other circuit boards. See
detailed description for list of signals transferred and data
direction.
Raster Timing Generator
Inputs
Description
VIDBLANK
Along with RONSCRN, GONSCRN, BONSCRN, and
VONSCRN from the SCB, and DCRSTR, determines
whether there is full brightness, black, gray-scale, or
external video presented at a given point on the screen.
Along with RONSCRN, GONSCRN, BONSCRN,
VONSCRN, from the SCB, and VIDBLANK, determines
whether there is full brightness, black, gray-scale, or
external video presented at a given point on the screen.
DCRSTR
Outputs
Description
SGSYNC
Stripped Green Sync. The composite sync signal stripped from
the green channel
(if it exists) (TP13).
HSYNC
VSYNC
Horizontal Sync. This can be either just the horizontal sync, in
which case there will be a separate vertical sync, or
HSYNC can be a composite sync. (TP14)
Vertical Sync. This cannot be a composite sync signal. (TP15)
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Vertical Deflection Board
Description
Inputs
VPARAB
A periodic, positive-going, parabolic waveform with the
vertical scan frequency, used for dynamic focus.
HPARAB
A periodic, positive-going, waveform with the horizontal scan
frequency, used for dynamic focus.
/SWEEPOK
A TTL DC level signal indicating that, when low, indicates all
flybacks are occurring at or above a minimum frequency.
Video Amplifier Board
Description
Inputs
RBEAM
Voltage signal proportional to cathode current averaged over
several horizontal lines, in the red CRT. Voltage level is
+1mV/uA.
GBEAM
BBEAM
/RVIDOK
Similar to RBEAM.
Similar to RBEAM.
Open collector signal indicating the health of the red +100V
cathode supply.
/GVIDOK
/BVIDOK
Similar to /RVIDOK.
Similar to /RVIDOK.
Video Amplifier Board
Outputs
Description
BLANKING Pulse signal output that is a buffered replica of the VIDBLANK input
from the SCB. Indicates the commanded blanking interval during
the scan.
/BENABLE
Logical connection of video amp, sweep, and power health
indications. TTL level output.
/RENABLE
/GENABLE
RVOUT
Identical to /BENABLE.
Identical to /BENABLE.
Red video output. 0V to 1V (TP1).
GVOUT
BVOUT
CLAMP
Green video output. 0V to 1V (TP2).
Blue video output. 0V to 1V (TP3).
Pulse signal output that is a buffered replica of the SCRSTR input
from the SCB. Indicates the commanded timing and duration of
the DC restore.
External Video
Inputs
Description
RVIDCH1
RVIDCH2
GVIDCH1
GVIDCH2
Red video input to channel 1.
Red video input to channel 2.
Green video with optional composite sync signal input to channel 1.
Green video with optional composite sync signal input to channel 2.
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BVIDCH1
BVIDCH2
Blue video input to channel 1.
Blue video input signal to channel 2.
HSYNCCH1 Horizontal or composite sync signal to channel 1.
HSYNCCH2 Horizontal or composite sync signal to channel 2.
VSYNCCH1 Vertical sync signal to channel 1.
VSYNCCH2 Vertical sync signal to channel 2.
COMPVID
LUM
CHROM
RTN
Composite video signal, pass through to decoder.
Luminance signal for SVHS, pass through to decoder.
Chrominance signal for SVHS, pass through to decoder.
Return for SVHS; pass through to decoder.
Image Light Amplifiers
Description
Outputs
+RLCLV
One half (½) of the differential pair providing a distorted square
wave to the red ILA. (TP 21)
-RLCLV
One half (½) of the differential pair providing a distorted square
wave to the red ILA. (TP 20)
+GLCLV
-GLCLV
+BLCLV
-BLCLV
Similar to +RLCLV. (TP 19)
Similar to -RLCLV. (TP 18)
Similar to +RLCLV. (TP 17)
Similar to -RLCLV. (TP 16)
Decoder
Inputs
RED
Description
Red video signal from decoder.
GREEN
BLUE
Green video signal from decoder.
Blue video signal from decoder.
SYNC
Horizontal sync signal from decoder.
Interrupt signal from decoder, pass through to SCB.
Indicates to VPB that video input is composite.
Indicates to VPB that video input is SVHS.
Vertical sync signal from decoder.
IICINT
CH3SEL
CH4SEL
VERT
Outputs
SCLK
Description
Single ended serial clock from serial communication bus to decoder.
Single ended serial data from serial communication bus to decoder.
IIC clock pass through to decoder.
SDATA
IICCLK
IICDATA
COMPVID
LUM
IIC data pass through to decoder.
Composite video signal, pass through to decoder.
Luminance signal for SVHS, pass through to decoder.
Chrominance signal for SVHS, pass through to decoder.
Return for SVHS; pass through to decoder.
CHROM
RTN
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High Voltage Power Supply
Description
Outputs
VDFOCUS
HDFOCUS
Parabolic waveform of vertical frequency.
Parabolic waveform of horizontal frequency modulated by the
VDFOCUS waveform.
/HVEN
Enable signal for HVPS, used to shut down HVPS for CRT
protection.
System Power Supply
Description
Inputs
+5V
GND
+15V
-15V
Power supply to digital components.
Return from digital components.
Power supply to analog components.
Power supply to analog components.
Return from analog components.
GND (TP 0)
Interlocks and Protection
Input
/SWEEPOK
TTL high indicates that one or more of the sweeps, either horizontal or
vertical is not at or above the minimum amplitude and frequency. This will
cause a cutoff so that RVOUT, GVOUT, and BVOUT will be pulled low.
Additionally, /RENABLE, /GENABLE, and /BENABLE will be pulled high
resulting in shutdown of grid bias at the Video Output Boards. Also, the
SWEEPOK status bit will be transmitted to the SCB.
RBEAM
Signal representing average red CRT beam current at 1mV/1uA. At greater
than 0.7V, causes contrast and overlay intensity on all three colors to be
reduced.
GBEAM
Similar to RBEAM.
BBEAM
Similar to RBEAM.
/RVIDOK
High indicates low voltage at the +100V supply on the red Video Output
Board. This causes a low at the VIDOK status bit sent to the SCB over the IIC.
The /HVEN signal is allowed to go high shutting down the HVPS.
Additionally, a high cutoff signal is sent so RVOUT, GVOUT, and BVOUT
will be pulled low. /RENABLE, /GENABLE, and /BENABLE are also pulled
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Chapter 2—Functional Descriptions
high resulting in shutdown of grid bias at the Video Amplifier Boards. Also,
the SWEEPOK status bit will be transmitted as a low to the SCB.
/GVIDOK
Similar to /RVIDOK.
/BVIDOK
Similar to /RVIDOK.
Output
/HVEN
When either /RVIDOK, /GVIDOK, or /BVIDOK from the Video Amplifier
Boards is pulled high, or the +5V power on the Video Processor Board goes
low, /HVEN is pulled high. This results in the HVPS being disabled, thus
shutting down high voltage to the CRTs.
/RENABLE
High will cause grid voltages at the VAB to be pulled low shutting off the red
CRT beam. High will result from high on /RVIDOK, /GVIDOK, or /BVIDOK
from the VAB, +5V power going down on the VPB, or /SWEEPOK being
pulled high from the VDB.
/GENABLE
Similar to /RENABLE.
/BENABLE
Similar to /RENABLE.
Internal
None
Video Amplifier Board P/N 103567 or 103774 (VAB)
The Video Amplifier Board (VAB) is mounted on and plugs into the back of the
CRT. There are three (3) VABs—one (1) on each CRT and each is entirely
dedicated to servicing its respective CRT. The video amplifier boards are the last
stage of the video chain and provide all electrical connection to the CRTs except
for anode voltage and chassis bond.
The following functions are provided by the VPB:
Connection of all voltages to CRT.
Amplification of video signal.
Blanking.
DC restore.
Bias voltage control.
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Circuit failure detection.
Beam current sense.
Arc protection.
This section uses Figure 2-16 for reference. The description provides information
to perform module-level troubleshooting.
Figure 2-16 Video Amplifier Board, Block Diagram
Video Signal
The video signal comes directly from the VPB backplane connector via a coaxial
cable to the Video Amplifier Board and enters as VIN. The input signal will be a
maximum of 1Vpp. The video amplifier takes the input signal, amplifies and level
shifts it so that it will be a negative-going 75Vpp signal modulating the +84Vdc
black level, and applies this to the cathode of the CRT. In general, the 84Vdc
black level will be seen only during the DC Restore interval. Power for the video
amplifier is a locally derived 100V that is regulated down from the 107V input
from the SPS.
Failure Detection
The Failure Detection circuit senses the health of the video amp's 100V power
supply. When the 100V supply falls below about +64V, the normally low
/VIDOK signal is pulled high. The /VIDOK signal is then sent to the VPB.
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Beam Current Sense
The cathode current is sensed at the output of the video amplifier, then filtered
and amplified so that the output is a 1mV/1uA signal averaged over several
horizontal lines (the number of lines depending on the horizontal frequency). This
current sense signal is then sent to the VPB as the signal BEAM.
DC Restore
The DC Restore function is accomplished on the Video Amplifier Board when
commanded by the CLAMP signal from the VPB. When the CLAMP signal
arrives, the video signal has the offset values (Brightness and Threshold) removed
so that they will not be changed by the DC Restore circuit. The CLAMP signal
causes the output voltage to be sampled and compared to a reference. The
difference is sent to the input of the video amplifier to set the new black level for
the duration of the next horizontal line.
Arc Protection
The Arc Protection Circuit functions to drain off any energy that arrives at the
Video Output Amplifier board due to arcs on the cathode or grids. The arc energy
is suppressed by sending it directly to the HVPS chassis via the Arc Ground
terminal on the board.
Blanking
The Blanking circuit operates by using the BLANKING signal from the VPB. The
BLANKING signal causes an amplifier to drive an AC coupled pulldown of
GRID1. G1 voltage is normally -81V but will be pulled down to -111V during the
blanking interval. The cathode voltage is unaffected by blanking.
Enable Circuit
The Enable circuit is controlled by the /ENABLE signal from the VPB. The
/ENABLE signal, when pulled high, causes both GRID1 and GRID2 to be pulled
low: G1 is pulled from nominal -81V to the disabled value of -200V, G2 is pulled
from its usual value of between +800V to +1200V to its disabled value of +15V.
Focus
The FOCUS voltage is a pass through from the HVPS to the CRT. It is not in any
way modified by the VOB.
Filament Supply
For the CRT Filament supply, 6.3Vdc from the System PS is simply filtered and
sent to the CRT.
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General I/O
This section provides a comprehensive description of the inputs to and outputs
from the VAB. The I/O description are arranged by the source/destination of the
signal and so the assemblies communicated with are used as the primary heading
of each group of signals and then are further subdivided into inputs and outputs. In
each case, the signal's direction is noted, with input referring to an input to the
VAB, and output to an output from the VAB (e.g.: under Video Processor Board;
'Input'; CLAMP refers to the signal CLAMP that is an input to the VAB from the
Video Processor Board). When test points are provided for the I/O they are noted.
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Table 2-11 Video Amplifier Board I/O Signals
Video Processor Board
Input
Description
VIN
COAX input from VPB via the backplane. Video signal of 1V peak-
to-peak maximum.
/ENABLE
CLAMP
TTL level DC signal which controls grid voltages. High causes G2
to be pulled to +15V and G1 to be pulled to -200V shutting off
the CRT beam.
TTL level pulse controlling DC restore. Restores black level of
cathode voltage to +84V.
BLANKING TTL level signal controlling video blanking. Pulls G1 to 30V below
normal voltage to turn off beam.
Outputs
Description
BEAM
Positive voltage indicating beam current averaged over several lines.
1mV = 1uA of beam current.
/VIDOK
Indicates health of the +100V cathode supply. Open collector output
opens when supply goes below 64V.
CRTs
Output
FOCUS
GRID1
Description
Focus voltage directly from HVPS to CRT.
Regulated DC voltage to Grid1. Nominally -81V during normal
operation. During blanking, G1 is -111V, and during /ENABLE
high, G1 is -200V.
GRID2
Variable DC voltage to Grid2. G2 voltage is normally 800 to
1200V. When /ENABLE high, G2 is 15V.
DC black level modulated by video signal. DC black level is +84V.
Modulation is negative-going 75V peak-to-peak max.
6.3V filtered goes to filament.
CATHODE
FILAMENT
FILAMENT
RTN
Return from filament supply.
High Voltage Power Supply
Description
Power supply to Grid1 regulator.
Pass-through from HVPS to CRT.
+100V to +1400V supply to Grid2. Passes through G2 pulldown
circuit for protection.
Inputs
-200V
FOCUS
G2
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System Power Supply
Description
Power supply to cathode drive amplifier.
Power supply to filament.
Inputs
+107V
+6.3V
+15V
Power for analog components.
-15V
Power for analog components.
GND
Return for power supplies.
ARC GND
Low impedance return path to HVPS for arc currents.
System Controller Board P/N 104668 (SCB)
The system controller board plugs into the electronics card cage. It is the middle
board in the card cage (third from the front).
The following functions are provided by the SCB:
Operator Interface:
IR Interface.
RS232 Interface.
On-Screen Menus.
Dot Matrix Display.
Inter Board Communications and Control:
IIC Bus (Overall system control).
Serial Bus.
Power Supply Interface.
Projector operation:
Direct operation of the projector by issuing commands based on
external directives and internal information.
Contains program and working memories.
Generate Overlays:
Digital Test Patterns.
Gray-Scale.
Provide Convergence Correction Outputs:
X and Y Axis Correction.
Sensitivity and Threshold Correction.
The block diagram (see Figure 2-17) description, along with the I/O description in
the section following, provide information to perform module-level
troubleshooting.
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Chapter 2—Functional Descriptions
General Functional Description
The system controller board receives external commands, interprets those
commands, and issues internal commands to control the operation of the arc lamp,
light valves, raster generation, video signal amplifiers, and other components
necessary for projector operation.
The SCB receives commands from the outside world via the IR or RS232
interface. Output communication is accomplished via the RS232, the dot matrix
display, and the CRT display.
Control of raster generation by the SCB is limited to primarily controlling
geometric and convergence correction while most other raster functions are under
local hardware control.
Video signal control involves choosing which video input to use, whether or not
to insert overlays, and setting gain and offset values.
The SCB also takes in information on raster and video status from other circuit
boards and generates control signals and displays based on that information.
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Figure 2-17 System Controller Board, Block Diagram
CPU
The central processor (CPU) is a Motorola MC68302 embedded controller and is
the main controlling component of the projector.
Operation of the CPU is controlled by the program instructions written in the
Program Memory. The program memory consists of two (2) UV erasable
EPROMs (U24 and U63) loaded with the appropriate software for the projector,
mounted in sockets for ease of updating the software. The EPROMs, being non-
volatile, will maintain their integrity under all operational conditions. Upgrading
the program memory is simply a matter of replacing the EPROMs with the newer
version.
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As the CPU processes information, it is stored in the Working and Compressed
Memory. This includes all temporary storage as well as the channel data that the
operator sets while ‘tweeking up’ the projector.
All communication, both input and output, for internal signals and operator
interface, is directly controlled by the processor. On-screen messages are
generated and written to the Overlay Memory which serves as a video memory for
controlling the on-screen display. RS-232 commands are received and sent via the
RS-232 interface. IR communications are only received by the projector. No
capability for transmitting IR is provided in the projector. The CPU communicates
directly with the IR interface to receive commands. The CPU sends status and
error codes to the LED interface for display on the dot-matrix display on the rear
of the projector. Internal communication is accomplished by the processor sending
data via the IIC interface and the serial data interface.
The CPU also directs the operation of the DSP.
Working and Compressed Memory
The Working and Compressed Memory (WCM) consists of four (4) SRAMs,
mounted in sockets that provide battery backup which in turn provides the ability
to maintain all projector settings even when the projector loses power for
extended periods. Although not covered separately by warranty, the battery should
be able to maintain the stored data for over one (1) year with no power applied to
the projector. With power applied, the battery should remain viable for up to ten
(10) years.
WCM is used as working memory for the CPU. All temporary storage of working
data during routine CPU operations is done in the WCM. Additionally, the
channel data is stored in WCM. There are 29 channels of data that can be stored in
the projector. Channel data is all of the information that is stored that is specific to
a particular projector channel. For example, the Position settings for R, G, and B,
the ILA frequency, X convergence correction, Sensitivity correction, etc. As well
as the channel data, global data is also stored in the WCM. This includes anything
that is not channel specific such as auto-select groups, timers, and status logs. As
long as the battery backup remains viable or power is applied to the projector, the
WCM will remain intact. However, if data is corrupted for any reason, such as
removing one (1) of the four (4) memory chips or a battery losing power while the
projector is not plugged in, all of the data in the WCM will be lost. For this
reason, it is always a good idea to back up the channel data to an external data
storage medium.
Expanded Memory
The Expanded Memory (EXM) is composed of twelve (12) memories. Each of
these memories stores information that will be used to correct the raster for both
shading and convergence.
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The digital information that is to be used for raster correction is stored in bit-map
form. The bit-map is 96 fields (out of 112) wide by the number of horizontal lines
in a frame wide. Each address in the EXM corresponds to a small section of one
(1) line on the screen.
As the raster is scanned, the EXM is being read out so that during the time that
each line of the raster is being scanned, 96 memory locations are being read. In
this way, each area of the raster can be accurately corrected.
Since there are twelve (12) functions to be corrected (R, G, and B for each of X
registration, Y registration, Threshold, and Sensitivity), each memory corresponds
to one correction function. All twelve (12) memories are read out simultaneously,
one (1) address at a time, to provide the correction required for the raster.
Correction Address Generator
The Correction Address Generator is used to address the EXM during both load
and readout. During the loading time, when the DSP is writing to the EXM, the
DSP controls the address generator, both setup and timing. During the time when
writing is not occurring, the memory is being read. At that time, the address
generator is set up by the DSP, but it’s timing signals come from the RTG to
synchronize it with raster generation.
During the read times, the address generator uses the /CORRSTRT and /MAPST
signals from the RTG as timing signals. The timing clock used is the /HX112
signal. Thus, the address generator generates addresses at the rate of 112 times the
horizontal frequency. It does this for 96 clock pulses, then stops. After the next
/CORRSTRT signal, it generates another 96 addresses. This repeats for each line
in the raster. The starting address is timed by the /MAPST signal. When that
comes along, it indicates the top of the raster is beginning so the address generator
should begin counting at the beginning.
During writing times, as the DSP generates data, it causes the address generator to
increment to the proper address to be loaded.
DACs
The Digital to Analog Converters are used to convert the digital data stored in the
EXMs to analog form for use by the correction amplifiers. There are twelve (12)
DACs, one (1) for each memory. Six (6) of the DACs are for X-Y registration and
send their outputs to the VDB. The other six (6) DACs are for shading (Threshold
and Sensitivity) and send their outputs to the VPB. The data from the DACs is
real time data that corrects the raster as it is scanned.
DSP
The Digital Signal Processor is a slave processor that operates under the control of
the CPU. The DSP does the processing that converts the raw convergence and
shading numbers that the operator inputs, into the smooth correction data that
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Chapter 2—Functional Descriptions
drives the correction amplifiers. The raw (compressed) data is stored in the WCM
while the smooth (expanded) data is stored in the EXM.
When a channel change occurs in the projector, the compressed correction data
that is stored in the WCM is interpolated by the DSP into the expanded form that
is stored in the Expanded Memory.
The compressed data is stored in the WCM in a 33X33 matrix of values
representing the desired correction over the whole screen. For each channel, there
are twelve (12) of these matrices stored in the WCM; one (1) for each color of
each function (R, G, and B for each of X registration, Y registration, Threshold,
and Sensitivity).
Overlay Memory
All display that does not originate from the external source is called Overlay and
includes on-screen text and test patterns. In order to produce overlays, a bit-map
must be generated that can be read out as the raster is being produced by the
projector’s deflection circuits. This bit-map tells what to show on the screen at
any point at any time. The CPU generates the bit-map and stores it in the overlay
memory for readout during raster scanning. When there is no overlay to be
presented, there is nothing but external video to show. That information is also
stored in the overlay memory.
The Overlay Memory is composed of two SRAMs. They are not battery backed
since they store no data that must be held while the projector is not in operation.
The Overlay Memory is used to store the bit-mapped information that describes
the overlay pattern that is seen on the faces of the CRTs, hence on the screen. The
overlay bit-map is 192 fields wide (out of 224) by the total number of raster lines.
Each of these memory locations stores information that determines what will be
displayed at that particular point on the screen. These choices are full bright or
black for each color individually, gray scale for all three (3) colors together, or
external video for all three (3) colors.
Overlay Address Generator
The Overlay Address Generator is used to address the overlay memory in a
manner similar to how the correction address generator addresses the EXM during
both load and readout.
The CPU controls the operation of the Overlay Address Generator while writing
to the overlay memory. During the read times, as with the correction generator,
the overlay address generator uses the /CORRSTRT and /MAPST signals from
the RTG as timing signals. However, the timing clock used is the /HX224 signal.
This is because the generator must run at 224 times the H frequency in order to be
able to generate the 192 addresses required for each line of overlay.
The addresses are generated for 192 clock pulses then the generator pauses. After
the next /CORRSTRT signal, it generates another 192 addresses. This repeats for
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Chapter 2—Functional Description
each line in the raster. The starting address is timed by the /MAPST signal. When
that comes along, it indicates the top of the raster is beginning so the address
generator should begin counting at the beginning.
Overlay Interface
The Overlay Interface takes the raw data out of the Overlay Memory and sends
formatted information to the VPB for generating the desired displays. Some of the
data is simply buffered and sent along. That data is the information regarding the
full brightness and external video that produces everything but greyscale and dots.
The greyscale, dot, and pyramid patterns must first be decoded by a D to A. After
conversion to analog and appropriate filtering, the information is sent out to the
VPB as the VIDTEST signal.
LED Display Buffers and Logic
The LED dot matrix display is located on the rear of the projector just under the
video and sync input connectors. In that location, it is not physically located on
the SCB but it is directly controlled by the CPU with connection via the
backplane.
The Dot Matrix Display is used for displaying operational and error codes. These
codes will assist in troubleshooting and verifying proper operation. The Dot
Matrix Display receives its data from the CPU via the display buffer.
RS232 Interface
The RS232 Interface is a bi-directional communications port. The interface
protocol is RS232 with two (2) ports; one (1) port being fully functional with the
other having more limited use.
The Terminal In port is the fully functional port. It is used for communicating
with the projector using a VT100 or similar terminal emulator. The terminal
allows accessing all functions available on the projector. In addition, using the
terminal provides the user with continuously updated status data. The bi-
directional port allows third-party controllers to be used to control the projector
using ASCII character control codes.
The Terminal Out port is also RS232 but has limited functionality. It is used
primarily for attaching a switcher to the projector to allow for smoother switching
of sources.
IR Interface
The IR Interface is a receive-only interface. There is no capability to transmit
information out of the projector over the IR interface. The user must depend on
the on-screen information and LED Dot Matrix displays to verify operation of the
projector.
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There are three (3) ports for receiving IR radiation. One (1) is located on the front
of the projector just above the Green projection lens and the other two (2) are
located on the rear panel. One of the receivers on the rear panel is located next to
the LED display and, like the front receiver, is used for directly receiving IR
radiation. The other rear-mounted receiver is used for connecting an IR repeater,
which is an optional device that allows the user to control the projector from up to
150 feet away.
The IR receivers are not located on the SCB but are directly controlled by the
CPU and are connected via the backplane.
IIC Interface
The IIC Interface is used to transfer operating data to the circuit boards. IIC is a
protocol for a chipset made by Phillips. It is a bi-directional serial
communications interface. The IIC uses three (3) lines for communications: a
clock line (IICCLK), a data line (IICDATA), and an interrupt line (/IICINT). The
SCB is the master when communicating over the IIC with the other circuit boards
being slaves. The SCB sends information to another board by sending an address
then data. When the circuit boards have information to communicate to the SCB,
an interrupt is generated.
The SCB polls the boards to see who sent the interrupt. The SCB then reads the
information from the IIC bus.
One primary use of the IIC in the projector, in addition to its use as a data transfer
device, is control of the differential serial communications bus.
Serial Interface
The Serial Interface is a differential communication bus used for transferring data
quickly from the SCB to the other boards. It is unidirectional. In order for any
board to receive a packet of data via the Serial Interface, it must first be
commanded to receive that data by the IIC interface. Then the data is sent over the
differential bus to the receiving board. Once a packet of data has been sent, the IIC
must again be used to allow another packet to be received.
General I/O
This section describes the inputs to and outputs from the SCB. The I/O
descriptions are arranged by the source/destination of the signal. The assemblies
communicated with are the primary heading of each group of signals and are
further subdivided into inputs and outputs. In each case, the signal's direction is
noted, with input referring to an input to the SCB, and output to an output from
the SCB. (e.g. under Raster Timing Generator; 'Input'; /MAPST refers to the
signal /MAPST that is an input to the SCB from the Raster Timing Generator
Board). Any test points provided are noted.
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Table 2-12 System Controller Board I/O Signals
Video Processor Board
Description
I/O
IICDATA
Data line for transferring the following information
(I = input, O = output). The input data are associated with an
interrupt pulse.
I VIDOK
I SWEEPOK
I BEAMDET
O BENABLE
O GENABLE
O RENABLE
O CH1SEL
O CH2SEL
O SLOAD
O VERTICAL FREQUENCY
Input
Description
/IICINT
Interrupt used to tell the SCB that the VPB has data to report.
Video Processor Board
Description
Output
IICCLK
+SERCLK
-SERCLK
Clock signal for IIC data bus.
Serial data transfer clock.
Serial data transfer clock.
+SERDATA Serial data transfer. Used to transfer the following command data:
REDBIAS, GRNBIAS, and BLUBIAS to control the bias on
the three (3) ILA®s respectively, RCONT, GCONT, and
BCONT to control the contrast for the three CRTs, and
BRIGHT to control the brightness for all three CRTs.
-SERDATA
BONSCRN
Serial data transfer.
Output from the overlay interface used to turn blue overlay on and
off.
RONSCRN
GONSCRN
VONSCRN
Similar to BONSCRN.
Similar to BONSCRN.
Output from overlay interface used to turn external video on and
off.
VIDTEST
RSENS
GSENS
Video signal output for gray-scale. Real time data at 0V to 1V.
Sensitivity output from the DAC at 0V to 1V with 140 ohm Zout.
Similar to RSENS.
BSENS
Similar to RSENS.
RTHRESH
GTHRESH
BTHRESH
Threshold output from the DAC at 0V to 1V with 140 ohm .
Similar to RTHRESH.
Similar to RTHRESH.
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Raster Timing Generator
Description
I/O
IICDATA
Data line for transferring the following data (I = input, 0 =
output). The input data are associated with an interrupt pulse.
O Priority Select
I /Sync Select
I Internal Sync
I Horizontal Count
I /Phase Lock
I INTI
O Vertical Flyback Start Delay
O Map Start Delay
O L Blank
O R Blank
O U Blank
O D Blank
O /STBP
O DC Restore Delay
I Phase Count
I Correction Delay
I Pincushion Start Delay
Input
Description
/IICINT
/FRAMEST
Interrupt used to tell the SCB that the RTG has data to report.
Timing pulse Indicating the beginning of a frame. Used in the
SCB for counting vertical frequency. (TP5)
Signal used to start the correction and overlay address counters
during each vertical sweep. (TP12)
Clock pulse at 112 times the horizontal frequency. Used for
convergence and Z-axis correction map generation. (TP20)
Square wave signal 224 times the horizontal frequency for
overlay map generation, horizontal map correction start, left
and right blanking, DC restore, and other timing functions.
(TP23)
/MAPST
/Hx112
/Hx224
/FIELD1
TTL level indicating which field of an interlaced frame (Low if
non-interlaced. (TP8)
/CORRSTRT Signal used to start the convergence and overlay address
generators during each horizontal sweep. (TP4)
INTI
/VSYNC
Indicates when input source signal is interlaced. (TP2)
Regenerated vertical sync signal, pulse-shaped to 3 horizontal
lines in width. (TP21)
Output
Description
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SYSCLK
IICCLK
+SERCLK
-SERCLK
4.05MHz clock signal
Clock signal for the IIC data bus.
Serial data transfer clock.
Serial data transfer clock.
+SERDATA Serial data transfer.
-SERDATA
Serial data transfer.
Vertical Deflection Board
Description
I/O
IICDATA
Data line for transferring the following data (I = input, O =
output), the input data are associated with an interrupt
pulse.
I
SLOAD
Input
Description
/IICINT
Interrupt used to tell the SCB that the VDB has data to
report.
Output
Description
IICCLK
Clock signal for the IIC data bus.
Serial data transfer clock.
Serial data transfer clock.
Serial data transfer. Used to transfer the following command
data:
+SERCLK
-SERCLK
+SERDATA
VH+, VH- to control the vertical amplitude (height)
VCENTRED, VCENTGRN, VCENTBLU to control
vertical
centering of the red, green and blue rasters respectively;
TRAPCORR to control keystone correction;
LRPNCORR for left and right pincushion correction;
TBPNCORR for top and bottom pincushion correction;
HLINCORR for horizontal linearity correction.
Serial data transfer.
Horizontal correction output from DAC with 140 ohm Zout.
Vertical correction output from DAC with 140 ohm Zout.
Similar to RXCORR.
-SERDATA
RXCORR
RYCORR
GXCORR
GYCORR
BXCORR
BYCORR
Similar to RYCORR.
Similar to RXCORR
Similar to RYCORR.
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Horizontal Deflection Board
Description
I/O
IICDATA
Data line for transferring the following data (I = input, O = output).
O Flyback Switch Select
O Flyback Switch Pulse
I Front/Rear indication
I Floor/Ceiling Indication
O Serial Data Load
Input
Description
/IICINT
Interrupt that tells the SCB that the HDB has data to report.
Horizontal Deflection Board
Description
Output
IICCLK
Clock signal for the IIC data bus.
+SERCLK
-SERCLK
+SERDATA
Serial data transfer clock.
Serial data transfer clock.
Serial data transfer. Used to transfer the following command data:
HPHASE to control the horizontal phase, HLINR to control the
horizontal linearity, HCENTBLU, HCENTGRN, HCENTRED
to control the horizontal centering of the blue, green and red
rasters respectively, and WIDTH to control the horizontal width
of all three rasters and for control of geometric correction.
Serial data transfer
-SERDATA
System Power Supply
Description
Power for digital components
Inputs
+5.0V
+5V STB
+15V
Power to CPU and peripherals
Power for analog components
-15V
Power for analog components
/LAMPLIT
Indicates normal operating voltage being supplied to Arc Lamp
Output
Description
/LVPSNBL
/FANENBL
/ALENBL
Low Voltage Power Supply Enable
Signal to enable 24V Standby Power
Enables Arc Lamp Power
Dot Matrix Status Display
Outputs
LEDDO-6
/LEDLT
Description
Data
Lamp test
Write
/LEDWR
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/LEDBL1
/LEDBLO
Brightness
Brightness
RS-232 Interface Signals
RS232 #1
RXD1
TXD1
/CTS1
/RTS1
RS232 #2
RXD2
TXD2
/CTS2
/RTS2
Description
Receive data
Transmit data
/Clear to send
/Ready to send
Carrier detect
Return
DCD1
COMRTN
IR Interface
Input
Description
/RIRIN
Input from rear IR Receiver
/EXTIRIN
EXTIRIN
/FIRIN
Differential input from IR Receiver
Differential input from IR Receiver
Input from front IR Receiver
Backplane Board p/n 100571
The Backplane is a PCB that serves as an interconnecting point for the tethered
and IR remotes, power supplies, CRTs, Yokes, ILA® assemblies, PCBs and
external video. The Backplane does not modify signals in any way—it merely
provides an interfacing point for most of the wiring in the projector in lieu of
cabling. Refer to Figure 2-18 for a general idea of how the wiring is
interconnected in the projector.
Tethered
External Video
Remote
Signals
or PC
Power
System
Video and
Power
Supply
Deflection
Signals
CRTs,
Yokes,
Video Amps
Control
Power
Backplane
High
Voltage
Power
Supply
Control
ILA Biases
ILAs
PCBs
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Chapter 2—Functional Descriptions
Figure 2-18 Backplane Interface Block Diagram
2.7 Optical Section
The Optical section consists of the CRT Assembly, the Arc Lamp Assembly, and
the Optical subassemblies, which provides the image to be viewed on the screen.
The Optical Section filters, splits and directs the high intensity light to the three
(3) separate (RGB) light channels. Figure 2-19 shows the video path from the
CRT to the screen and the optical path from the Arc Lamp to the screen.
CRT Assembly
The image in the projector begins at the three (3) CRTs. The CRT Assembly is
located beneath the main electronics card cage and contains three (3) sets of the
following:
CRT tubes.
CRT cooling assemblies.
CRT Yokes.
Yoke clamps.
Video Amplifier Boards.
Each CRT has a high resolution infrared beam and a high resolution phosphor
screen. Fans mounted at the rear of the assembly cool the CRT Assembly.
Procedures for adjusting the yokes and the width coils can be found in
Section.3.2. A functional description of the Video Amplifier Boards is provided in
Section 2.6.5.
Relay Lens
The relay lens picks up the CRT image from the face of the CRT and focuses the
image to the ILA® assembly.
Image Light Amplifier (ILA®) Assembly
At the same time as the image is received at the input side of the ILA® assembly,
the output side of the ILA® assembly is receiving high intensity light from the arc
lamp through the prism. This high intensity light is then phase modulated (altered)
by the video signal from the input side of the ILA® assembly and then reflected
back out of the output side and then travels through the prism to be picked up by
the projection lens.
The prism reflects horizontally polarized light and passes vertically
NOTE:
polarized light. Light from the arc lamp is polarized horizontally and reflects from
the prism into the ILA® assembly then back out again, after being phase
modulated 90° to vertical by the Liquid Crystal layers into vertically polarized
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Chapter 2—Functional Description
light. The vertically polarized light then passes through the prism to the projector
lens. The ILA® assembly combines the input signal from the CRT with the high
intensity light from the arc lamp. Thus, the brightness of the screen image does
not depend on the brightness of the CRT but on the light from the xenon arc lamp.
(A more detailed explanation of the ILA® assembly is in Section 2.8 at the end of
this chapter.)
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Chapter 2—Functional Descriptions
CRT Image
Combined Image and High
Intensity Light=Bright Image
Relay
CRT
Projection
Prism
ILA
Screen
Lens
Lens
Image and
Focuses
Image onto
the ILA
CRT Image
Prism horizontally polarizes
High intensity
Arc lamp light
are combined
at the ILA and
reflected back
toward prism
the light and directs it to the
ILA. Also passes reflected
vertically polarized light
coming from the ILA to the
projection lens
High Intensity Blue Light
High Intensity Light
Blue dichroic reflects blue, passes
green & red. Green dichroic reflects
green, passes red.
Down-steering mirrors steer
light to correct prism.
Blue Dichroic
Cold
Arc
UV Filter and
Condensing
Lens
Filters out U.V.
light. Condenses
the light beam
Blue Down-
Steering Mirror
Mirror
Mirror
Lamp
Filters
Green light to
green prism
Green Down-
Steering Mirror
Generates
Green Dichroic
Mirror
infrared
high intensity
light beam
light
Red light to
red prism
Red Down-
Steering Mirror
Red Dichroic
Mirror
Figure 2-19 Optical Block Diagram
!
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Prism
The prism receives the high intensity light from the xenon arc lamp and polarizes
the light horizontally. The prism reflects virtually all of this light toward the ILA®
assembly. This light is then phase modulated into a vertical plane by the input side
of the ILA® assembly and then reflected back toward the same prism. Since the
prism reflects only horizontal light and passes vertical light, this high intensity,
vertically polarized image goes straight through the prism and into the projection
lens.
Projection Lens
The projection lens picks up the high intensity image from the prism and transmits
it to the projector screen. The projection lenses are individually mounted so they
can be focused and aligned separately. The green lens is fixed horizontally and the
red and blue lenses allow horizontal movement to align them with the green lens.
Various focal lengths, (focal length = throw distance/screen width), are available
for different sized rooms and screens.
Arc Lamp Assembly
The high intensity light from the Xenon Arc Lamp produces a “full screen” output
of between 3,000 and 6,800 lumens, depending on the model of projector. The
output from the arc lamp, along with the output from the ILA® Assemblies,
produces the images on the screen.
NOTE: To protect equipment and personnel against explosion hazard, the arc
lamp is covered with a safety glass plate and is mounted in a protective metal
housing. This housing provides protection and ensures accurate alignment of the
arc lamp optical axis with the projector housing by means of machined surfaces
and precision alignment pins.
The Arc Lamp itself, a gas-filled device, maintains a relatively constant voltage.
It, therefore becomes the voltage controlled device and the SPS Arc Lamp supply
controls the current to the lamp. The constant voltage maintained by the lamp and
the constant current provided by the SPS result in a constant power supplied to the
Arc Lamp.
The arc lamp and reflector housing is never disassembled in the field. The arc
lamp is replaced by exchanging the complete assembly.
The Arc Lamp Assembly also includes the Ignitor and its circuitry. The Ignitor
circuit provides a momentary high voltage that excites the xenon gas inside the
Arc Lamp. After the arc lamp is struck and turns on, it is maintained by a high-
current, low-voltage power supply.
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Chapter 2—Functional Descriptions
Optical Subassemblies
Cold Mirror
The Cold Mirror lets most of the infrared light pass through and reflects the rest of
the light toward the prism through an ultraviolet filter/condensing lens, dichroic
mirrors and down-steering mirrors.
The infrared light is absorbed in a series of fan-cooled screens.
Cold mirrors absorb IR light and can get very
CAUTION!
hot!
Ultraviolet Filter and Condensing Lens
The arc lamp light beam reflected off the cold mirror passes through the
Ultraviolet Filter/Condensing Lens that removes most of the Ultraviolet light and
condenses the light beam. Therefore, most of the infrared and ultraviolet light is
filtered out before the beam enters the more sensitive portions of the optics,
leaving only the visible portion. Without these filters, the infrared light would
overheat the prisms and the ILA® assemblies, and the ultraviolet light would
damage the ILA® assemblies and be hazardous to personnel.
Dichroic Mirrors and Down-Steering Mirrors
The condensed light beam strikes the first dichroic mirror that is designed to pass
red and green light but reflect blue light. The blue light is reflected to a down-
steering mirror which reflects it again directly to the prism in the blue system. The
red and green light travel on to the next dichroic mirror that passes the red light
and reflects the green light to the down-steering mirror and prism in the green
system. The red light travels on to the last Dichroic mirror which reflects the
remaining red light to the last down-steering mirror and prism in the red system.
Each of these three (3) light beams independently combines with the video image
in their own (red, green or blue) color systems at the ILA® assemblies as described
above.
Do not attempt to realign any mirrors. They require
the use of a complex laser beam alignment fixture.
CAUTION!
2.8 Image Light Amplifier
A closer examination of the output side of the ILA® assembly as illustrated in
Figure 2-20 helps in understanding its operation.
Visible light from the arc lamp passes through dichroic mirror assemblies and is
then reflected into a prism assembly that polarizes the light horizontally. The
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Chapter 2—Functional Description
horizontally polarized light is sent through the liquid crystal layer of the ILA®
assembly, reflected by a dielectric mirror surface, and then sent back through the
liquid crystal layer on the way out of the ILA® assembly.
Figure 2-20 The Hughes-JVC Image Light Amplifier
The polarized light is phase modulated, or rotated, up to 90º by the liquid crystal
layer; 45º of rotation for the first pass through, and another 45º after being
reflected by the internal mirror.
The axis of the polarized light is proportional to the brightness on the input side of
the ILA® assembly. For example, when the photoconductor on the input side is
not illuminated, the liquid crystal does not rotate the polarized light from the arc
lamp. Conversely, when the input side is fully illuminated, the liquid crystal
rotates the polarized light a full 90º from a horizontal direction to a vertical
direction. Ninety-nine percent (99%) of the light energy entering the ILA®
assembly is reflected.
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Figure 2-21 Simplified illustration of the Series 300 Projector optical path
The phase modulated light exiting the ILA® assembly re-enters the prism
assembly that, in this direction, passes vertically polarized light to the projection
lens and onto the screen. Horizontally polarized light re-entering the prism
assembly is rejected. Light that is not fully horizontally or vertically polarized will
pass through the prism assembly in varying degrees of brightness.
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Chapter 3---Service Adjustments
3.0 Service Adjustments
Contents
3.1 Service (Cover-Off) Power-On Sequence..................................................3-1
3.2 CRT Yoke Rotation....................................................................................3-3
3.3 Vertical Size Tracking................................................................................3-5
3.4 Vertical Linearity Tracking ........................................................................3-6
3.5 Horizontal Size Tracking ...........................................................................3-7
3.6 ILA® Bias Settings .....................................................................................3-8
3.7 CRT Mechanical Focus..............................................................................3-9
3.8 Electronic Focus.........................................................................................3-9
3.9 Jumper Settings ..........................................................................................3-13
Front/Rear Jumpers ...................................................................................3-13
Inverted Vertical Jumpers .........................................................................3-15
3.10 G2 Adjustment ...........................................................................................3-16
Sensitivity/Threshold Offset......................................................................3-16
G2 Setting..................................................................................................3-16
3.11 Arc Lamp Alignment and Focus ................................................................3-18
Model 330 Arc Lamp Alignment and Focus.............................................3-18
Model 340SC and 370SC Arc Lamp Alignment and Focus .....................3-20
3.12 Arc Lamp Current Adjustment...................................................................3-21
3.1 Service (Cover-Off) Power-On Sequence
Before applying power to the HJT Model 330, 340SC and 370SC Projector, verify
that the projector is connected to the correct power source (refer to Table 0-1 in
the Safety chapter). If there is any visible damage to any of the cables do not
power on the projector until the damaged cable is replaced.
To turn on projector power:
1. If using a terminal or tethered remote control, connect one or the other to
the input jack marked "Terminal In" on the rear panel of the projector card
cage.
2. Remove the rear cover from the projector.
CAUTION! If the projector has been operating,
and the rear cover must be removed, be sure to set the
power interlock switch (top right as shown in Photo 3-1) to
the UP position immediately and turn the projector back on
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Chapter 3---Service Adjustments
with the remote. Then turn the projector power back off with
the remote. This allows power to be reapplied to the fans to
cool the arc lamp that remains very hot even after power is
removed. During a normal power shutdown the fans
continue to run for several minutes to cool the arc lamp.
3. Turn on the main circuit breaker (located on the bottom, right side of the
main power supply inside the projector in (see Figure 3-1). This switch
turns on the +5V standby power supply for the main processor.
4. Replace the rear cover on the projector or set the power interlock switch,
on top of the system power supply, to the full UP position (see Figure
3-1).
WARNING!!! With the cover off the projector,
be careful not to touch any open parts of the projector. Be
particularly careful of any high voltage wires (large, red
wires) which although heavily insulated could still cause
severe electrical shock if the insulation is pinched or
damaged. NEVER look into the Xenon Arc Lamp light path
or directly at any of the projection lens light paths-the light
intensity is strong enough to cause injury to eyes.
NOTE: If using a tethered remote or a terminal for projector control, an
active display should now appear on the LCD or screen. This is the
Standby Power mode. The projector is now ready for a power "ON"
command.
Set power
interlock switch
to full UP
position to power
the projector with
the rear cover
removed.
Main AC
Circuit
Breaker
Figure 3-1 Power Interlock Switch and Main Circuit Breaker.
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1. Press the Power ON key to turn on the projector (press both power keys
simultaneously if using the tethered remote). The Ignitor circuit will ignite
the arc lamp and power will be applied to the electronics system.
NOTE: If using a terminal or PC, turn full power on by typing CTRL-P.
To power up the electronics only, type CTRL-E. To power up the lamp
only, type CTRL-L. These are toggle commands; repeated issuance of the
commands toggles these power sources on and off. The lamp and
electronics cannot be powered up separately with the remote controls.
3.2 CRT Yoke Rotation
The CRT deflection yokes are factory set. If the CRT image is not level, adjust the
individual CRT deflection yoke as required (see Figure 3-1).
WARNING!!! To prevent possible electrical shock
when performing the yoke rotation, always wear ANSI/ASTM
10,000 volt rated safety gloves for protection from high yoke
voltages present. Ensure the gloves are not cracked!
To adjust the deflection yokes:
2. Press TEST 2 to display the White X-hatch pattern.
3. Cutoff R and B and view G.
4. Remove the rear projector cover (see Section 4.2).
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Figure 3-2 View of the CRT Assembly showing deflection yokes, width coils, CRTs
and Video Amplifiers.
5. Remove the 2.5mm Allen screw holding the electronics module in place
and tilt the electronics module (see CAUTION following) back to expose
the CRT necks and yoke.
CAUTION! Remove anything plugged into the
rear electronics jacks or the plugs could be badly damaged
when the electronics module is tilted back.
6. While observing the center horizontal line on the grid pattern, rotate the
green CRT deflection yoke, (the green CRT is in the middle), to achieve a
level image at the center of the screen (if necessary, loosen the yoke clamp
slightly to adjust it).
NOTE: Whenever adjusting the CRT yoke, push forward on the yoke
while rotating it to ensure the yoke remains properly positioned on the
CRT.
7. View R.
8. Rotate the red CRT deflection yoke (on the right of the projector–from the
rear) to achieve a level image at the center of the screen (it should be
parallel to the green central horizontal line).
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9. View B.
10. Rotate the blue CRT deflection yoke to achieve a level image at the center
of the screen (it should be parallel to the green and red grid center lines).
11. Retighten the yoke clamp so it is secure. Be careful not to over-tighten it.
12. Tilt the electronics module back into place.
13. Replace the allen screw from Step 4 above.
14. Replace the rear cover.
15. After Yoke rotation, re-adjust Geometry, Convergence and CRT
Mechanical focus.
3.3 Vertical Size Tracking
If the R or B vertical size does not match G, adjust the R and B vertical size pots
on the Vertical Deflection Board (see Figure 3-2).
NOTE: The tracking pots are factory adjusted and should not normally need
adjustment. The Green Vertical Size control (R-228) in particular, should not
need to be adjusted unless the Green Yoke or Green CRT has been replaced. If
the Green Vertical Linearity is off, however, it should be adjusted. In this case,
Green should then be matched to Red and Blue.
➨ The Red Vertical Size control is R-428.
➨ The Blue Vertical Size control is R-328.
To adjust the vertical size controls:
1. Press Test 2 to display the White X-hatch pattern.
2. Remove the rear projector cover.
3. Remove the eight screws holding the electronics module cover
and remove the cover.
4. From the Convergence menu select #3, CLEAR CONVG AXES.
5. Position R and B over G (using the POS and arrow keys on the
remote–refer to Section 4.9) so that the R and B lines at the
outer edges have the same amount of error.
6. Adjust R328 and R428 so that the Red and Blue vertical sizes
match the Green vertical size.
7. If unable to match Red or Blue to Green, adjust Green to match the
smallest color.
8. Replace the electronics module cover.
9. Replace the rear projector cover.
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Blue
Vertical
Linearity
Blue
Vertical
Size
Red
Vertical
Linearity
Green
Vertical
Linearity
Red
Vertical
Size
Green
Vertical
Size
R
R
R
R
R
R
R
96
R
R
R
328
411 311 211
228 428
139 171
36
CAUTION!!!
Do not adjust the pots that are shaded! They are
factory adjusted. Do not adjust the Green Vertical
Size or Green Vertical Linearity unless the Green
Yoke or Green CRT has been replaced.
Figure 3-3 Vertical Size and Linearity Controls on the Vertical Deflection Board.
3.4 Vertical Linearity Tracking
If the vertical linearity is not completely linear, use a small slot screwdriver and
adjust the vertical linearity controls on the Vertical Deflection Board (refer to
Figure 3-2).
NOTE: The Vertical Linearity pots are factory adjusted and will not normally
need adjustment. The Green Vertical Linearity pot (R-211) in particular, should
not need to be adjusted unless the Green Yoke or Green CRT has been replaced.
If the Green Vertical Linearity is off, however, it should be adjusted.
To adjust vertical linearity:
1. Select Test Pattern 2.
2. Remove the projector cover.
3. Remove the electronics module cover.
4. View Red over Green and position Red (use the POS control and the
arrow keys on the remote) so that the Red lines at the edge match the
Green lines.
5. Adjust the Red Vertical Linearity pot R-411 so that Red linearity matches
Green.
6. Repeat the same procedure for Blue (R-311).
7. Replace the electronics module cover and the projector cover.
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3.5 Horizontal Size Tracking
The horizontal width coils are factory adjusted and will not normally need
adjustment. In general, if the R and B vertical lines are within two (2) crosshatch
lines of each other, they can be brought in line with the Convergence procedure. If
the R or B horizontal size does not match G within two crosshatch lines, adjust
the Horizontal Width coils on the R and B Deflection Yokes (refer to Figure 3-1).
The width coils are mounted on a small circuit board on top of the Yoke assembly
inside a white ceramic holder and the adjustment is accessed from the opening at
the end of the ceramic holder.
WARNING!!! To prevent possible electrical shock
when performing the width coil adjustment always wear
ANSI/ASTM 10,000 volt rated safety gloves for protection from the
high yoke voltages that are present. Make sure the gloves are not
cracked.
To adjust the horizontal size tracking:
1. Remove the rear cover and electronic module cover by removing the
2.5mm Allen screw holding the electronics module in place and tilting the
electronics module (see CAUTION! below) back to gain access to the
yoke.
CAUTION! Remove anything plugged into the
rear electronics jacks or the plugs could be badly damaged
when the electronics module is tilted back.
2. View G and R.
3. Using the POS and arrow keys, position Red over Green so that each edge
of the pattern has the same amount of error. Adjust the Red coil until the
edges align.
4. Use a small plastic hex screwdriver to turn the red coil core (the red CRT
is on the right side looking from the rear) clockwise or counterclockwise
until the Red horizontal size matches Green.
5. Cutoff R and view G and B.
5. Use a small plastic hex screwdriver to turn the blue coil core (the blue
CRT is
on the left side looking from the rear) clockwise or counterclockwise until
the Blue horizontal size matches Green.
6. Tilt the electronics module back into place.
7. Replace the allen screw from Step 1 above.
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8. After Yoke rotation, readjust Geometry, Convergence and CRT
Mechanical focus.
3.6 ILA® Bias Settings
The ILA® Bias settings are factory set and should not normally need adjustment
unless specific maintenance has been performed that requires an ILA® Bias
readjustment. Avoid readjusting the ILA® Bias settings unless absolutely
necessary.
The ILA® Bias settings adjust the electrical bias levels to each ILA® assembly to a
"just off" threshold point so that even the smallest incoming light from the CRT
makes the ILA® assembly react. When properly set, this adjustment will put each
ILA® assembly at the threshold of operation. If not properly set, image black level
will be adversely affected and the ILA® assembly won't react properly to incoming
light. ILA® Bias adjustments should be done in a darkened room.
NOTE: If the room cannot be darkened enough to set the ILA® Biases using the
screen, try holding a piece of paper a few inches from the lens of the color you are
adjusting. Adjust the bias in the usual manner while viewing the entire ILA®
assembly area on the paper.
Note On Super Contrast Ila® Assemblies
If using optional Super Contrast ILA® assemblies, the High Contrast Compensator
may have to be adjusted for each color prior to performing the ILA® bias
adjustment. This procedure is required whenever an ILA® assembly is replaced or
if the compensator adjustment lever is inadvertently moved.
To set the High Contrast Compensator:
1. Press the HIDE key to mute CRT images.
2. Block the light from the green and blue lenses with the lens caps.
3. Move the front cover forward to provide access to the ILA® assemblies.
4. Disconnect the connector from the top of the red ILA® assembly.
5. Move the Compensator lever (this lever is just in front of the ILA®
connector) to the right and left until the darkest level appears on the
screen. If a screen is not available use a piece of white paper in front of the
lens.
6. Reconnect the connector to the red ILA®.
7. Repeat the above steps for the green ILA® and the blue ILA®. Block the
light from the other two lenses each time.
8. Replace the cover.
9. Remove all lens caps
The CRTs will automatically cut off when you enter the ILA® Bias mode. Any
light on the screen is being reflected by the ILA® assembly.
To set the ILA® Frequency and Bias levels:
3-8
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Chapter 3---Service Adjustments
1. Select ILA® Menu, from the Main Menu.
2. Select Frequency Adjust from the ILA® Bias Menu.
3. A frequency of 1.8 kHz is acceptable for general video viewing. A lower
frequency (as low as 1.5 kHz) will provide a brighter image but with lower
image burn-in. A higher frequency provides higher resolution. For HDTV
a frequency of 2.0-2.5 kHz provides higher resolution. Use the up/down
keys to adjust the ILA® frequency for the appropriate input source. As a
general rule 1.8 kHz works well with most sources.
4. Display the ILA® BIAS MENU again.
5. Select ADJUST, NO VIDEO. Don't attempt ILA® Bias adjustments on
Bias W/ Video. This feature is used for factory quality control only.
6. Press GREEN on the remote to select Green. Place lens caps over the Red
and Blue lenses.
7. Use the up/down arrows to adjust the Green ILA® Bias until the brightest
area of the ILA® image dissappears. Then raise the bias level until the
ILA® image just starts to appear on the screen at any point. Finally, slowly
lower the bias level again to the threshold point where the ILA® image just
disappears.
NOTE: It’s crucial for the optimum operation of the projector to set the
bias level to the point where the selected color just begins to appear on the
screen. Find the spot on the screen where the active color first begins to
get brighter and use that as the reference point. Go below and above this
point to find the setting where one (1) click on the UP key causes an
increase in brightness and stop at that point. This will insure that the
weakest video signal will cause the ILA® assembly to respond.
8. Cover the Green lens and uncover the Red lens. Press RED to select Red.
9. Repeat Step 7 for the Red ILA® Bias.
10. Cover the Red lens and uncover the Blue lens. Press BLUE to select Blue.
11. Repeat Step 7 for the Blue ILA® Bias.
12. Press Enter on the remote to save the settings and exit this adjustment.
NOTE: The ILA® Bias settings affect other projector settings. When ILA®
Bias has been adjusted, verify and readjust, if necessary, all projector
adjustments from the appropriate section of the specific model Operator’s
Manual.
3.7 CRT Mechanical Focus
The CRT mechanical focus is factory set and will normally not need to be
adjusted. Whenever a major component (like a CRT or a HVPS) has been
replaced or repaired the CRT mechanical focus must be reset. Use Test Pattern 8,
H-Grid and observe the corners of the screen. If the corners are all in sharp focus,
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the mechanical CRT focus should not be adjusted. If the image is not sharp
enough, proceed with the CRT mechanical focus adjustment below.
There are three (3) adjustment rods for each CRT making a total of nine (9). The
rods are accessed through holes, covered by hole caps, in the base and fan casing
at the rear of the projector (see Figure3-3).
The focus rods will be adjusted so that each CRT face is completely parallel to its
respective ILA® assembly, (i.e. positioning the CRT screen face planar with the
ILA® along the x, y and z axes).
Each CRT has three (3) focus rods; lower-left, lower-right and upper-left. The
focus rods for each CRT work as follows (see Figures 3-3 and 3-4).
The lower-left rod adjusts the CRT to ILA® distance (z-
axis)
for upper-right corner and overall focus.
The lower-right rod adjusts the bottom position of the CRT
The upper-left rod adjusts left-side position of the CRT.
Figure 3-4 CRT Focus Adjustment Apertures. Use a 5mm nutdriver to adjust the focus
rods inside the apertures.
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Figure 3-5 On-Screen Focus Points. Adjust the focus rods for best focus at these
points.
Using Test Pattern 8, H-Grid, adjust the focus rods for the best mechanical focus
as follows:
1. Connect a low-resolution source (approx 31.5 kHz x 60Hz) to the
projector inputs so that the projector can sync on that source.
2. Increase Size to 100% horizontal and vertical.
3. Cutoff R and B and view G. Verify G highlighted on the screen.
4. Remove the hole caps to gain access to the focus rods. For the Green CRT,
use a 5mm nut driver to adjust the lower-left rod of the Green focus rods
(see Figure 3-3). Have another person watch the upper-right corner of the
screen for the sharpest focus as you adjust the rod. This focus rod is the
CRT z-axis position and affects the overall focus. Observe the upper right
corner because it is the pivot point for the other two focus rods.
5. Adjust the lower right focus rod of the Green focus rods and look for the
sharpest focus at the bottom right of the screen in the same manner as in
Step 2 above.
6. Adjust the upper left focus rod of the G CRT focus rods for the sharpest
focus at the upper left of the screen in the same manner as in Step 2.
7. Cut off G and view Red.
8. Repeat Steps 2-4 for Red.
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9. Cutoff R and view B.
10. Repeat Steps 2-4 for Blue.
3.8 Electronic Focus
The Electronic Focus adjustment is factory-set and should not need to be adjusted.
Whenever a major component has been replaced, like a CRT, or if the high
voltage power supply has been repaired the electronic focus will have to be
readjusted. To do this, select Test Pattern 8, H-GRID, and observe the screen for a
sharp focus at the center of the screen.
If the center appears sharply focused, there is no need to perform the electronic
focus. Follow the procedure below if readjustment is necessary.
NOTE: The electronic focus adjustment focuses the electron beam in the CRT.
View one color at a time for these adjustments. Recheck the focus of each color
because some interaction between R, G and B may occur. The electronic focus
adjustment panel is located on the High Voltage Power Supply on the left-rear
side of the projector (refer to Figure 3-5).
To adjust the electronic focus:
1. Press TEST 1, Test Pattern 8, H-GRID.
2. Cutoff R and B.
3. Continue with a low resolution source (31.5kHz/60Hz) connected to the
projector inputs and Size is at 100% from the previous CRT Mechanical
Focus procedure.
4. Using a small plastic screwdriver, adjust the electronic focus for Green
and observe the center of the screen. Have another person watch the center
of the screen up close while adjusting.
NOTE: Be careful to adjust the ELECTRONIC FOCUS and not G2. These
adjustments are close to each other and one could be mistaken for the
other. (Figure 3-5).
5. Cutoff G and view R.
6. Repeat Step 3 for R electronic focus.
7. Cutoff R and view B.
8. Repeat Step 3 for B electronic focus.
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Figure 3-6 Electronic Focus and G2 Adjustments
NOTE: The Electronic focus and G2 adjustments are located on the high voltage
power supply on the rear-left side of the projector under the cover.
3.9 Jumper Settings
Table 3-1 illustrates which jumpers are used on the Horizontal Deflection Board
and the Vertical Deflection Board for different projector orientations.
Table 3-1 Projection orientation jumper settings.
Convergence
jumpers
Vertical jumpers
Vert. Def. Board
Horizontal
jumpers
Orientation
Vert. Def. Board
Horiz. Def. Board
Front/Floor Upright
Image
J500, J600,J700
J501, J601, J701
J501, J601, J701
J500, J600, J700
J200, J300, J400
J201, J301, J401
J200, J300, J400
J201, J301, J401
J500
J501
J501
J500
Front/Ceiling
Inverted Image
Rear/Floor
Upright Image
Rear/Ceiling
Inverted Image
Front/Rear Jumpers
The Horizontal Scan Reversal Jumper reverses the image projection for front or
rear projection. Figure 3-7 illustrates the location of the jumpers on the Horizontal
Deflection Board (the board that is furthest from the rear of the projector) and
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indicates the proper location for front and rear projection. The HJT Series 300
Projector is shipped with the jumper plug inserted in J500 for front projection. For
a rear projection setup, insert this jumper plug into J501.
J501
J500
REAR
FRONT
projection
projection
Figure 3-7 Horizontal Scan Jumper and Jacks on Horizontal Deflection Board.
The jumper is installed at the factory in J500 for front projection.
NOTE: When replacing the horizontal deflection board, the Horizontal Deflection
Board (P/N 102523) could be damaged if the board is not seated properly on the
backplane. This problem usually occurs when the HDB is removed and reinserted
after a board failure or when changing the sweep reversal connector. A failure can
occur if connector J11 on the HDB (located at the far right when viewing from the
component side) does not connect completely with P11 on the backplane.
To ensure a proper connection between J11 and P11 follow the procedure below:
NOTE: Before installing the Horizontal Deflection Board, remove the Vertical
Deflection Board. This allows for a full inspection of the proper connection of J11
and P11. The P11 connector on the backplane is slightly loose to allow movement
for minor dimensional differences in the position of the J11 connector on the
HDB—Do not tighten connector P11 on the backplane.
To set the Horizontal Scan Jumper:
1. Turn power off at the projector and wait about five (5) minutes for the arc
lamp to cool.
2. Remove the rear cover from the projector.
3. Remove the cover from the card cage.
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4. Pull out the Horizontal Deflection board and verify that the horizontal scan
jumper is properly inserted for front (J500) or rear (J501) projection,
depending on your application (refer to Figure 3-6 and Table 3-1). Change
jumper if necessary.
5. Replace the card cage cover.
6. Replace the rear projector cover.
Inverted Vertical Jumpers
The Vertical Invert jumpers invert the image vertically for use in some situations
that use mirrors or ceiling projections. Figure 3-7 illustrates the location of the
jumpers on the Vertical Deflection Board (the fourth board from the rear of the
projector). The Model 330, 340SC and 370SC Projectors are shipped in the
normal vertical projection position with vertical jumpers in J200, J300 and J400
and convergence jumpers in J500, J600, and J700. For other orientations, change
the jumpers in accordance with Table 3-1.
NOTE: Do not turn projector upside down or at 90º!
J200
J300
J201
J301
J400
J401
J600
J601
J700 J701
J500
J501
Figure 3-8 Vertical Scan Jumpers on the Vertical Deflection Board.
To change jumpers on the Vertical Deflection Board:
1. Turn power off at the projector and wait about five (5) minutes for the arc
lamp to cool.
2. Remove the rear cover from the projector.
3. Remove the cover from the card cage.
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4. Pull out the Vertical Deflection Board and verify the vertical jumpers are
inserted in the correct jacks, depending on your application (refer to Table
3-1 and Figure 3-7). Change jumpers if necessary.
5. Replace the card cage cover and rear projector cover.
3.10 G2 Adjustment
NOTE: For convenience, HJT provides factory-preset channels. These channels
are covered in Chapter 4 of the Operator's Manual. Adjusting G2 affects the image
quality of these preset channels. Before adjusting G2, verify that the preset
channels can't be used as is. G2 adjustments are located on the High Voltage
Power Supply on the left-rear side of the projector. A protective label is placed
over the G2 and Electronic Focus adjustments after they are preset at the factory.
This label can be punched through with an adjustment screwdriver or removed by
a qualified technician.
G2 needs to be reset only when:
➨ A major component like a CRT; or ILA® has been replaced;
➨ The high voltage power supply has been repaired; or
➨ If the picture size or aspect ratio changes.
When the projector is set up for new sources, the Threshold Offset must be set to
the default level of 80 prior to setting G2.
Sensitivity/Threshold Offset
To set the Sensitivity/Threshold Offset for a new source:
1. Select a channel from the channel list.
2. Press CONV to access Convergence mode.
3. Press MODE and toggle to Sensitivity or Threshold.
4. Press MENU to display the SHADE AXIS MENU on the screen.
5. Select CLEAR SHADE AXES (clears Sensitivity to the default level of
128 and Threshold to the default level of 80).
6. From the SHADE AXIS MENU select INIT ALL PROPTN. This
initializes all Proportions to 230.
G2 Setting
G2 sets the threshold of the CRT image and is adjusted along with Sensitivity
Offset using the Pluge test pattern. These two settings determine the level of the
darkest and brightest areas of the screen image. G2 is preset at the factory and may
need little or no adjustment. Do these adjustments in sequence, one color at a
time.
7. Adjust for full size image on the screen. (Refer to the sections on
Position/Phase and Size).
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8. Adjust Menu Position using the Grey Scale and the Timing Setup Menu.
(Refer to the Menu Position section).
To set G2:
1. Cut off R and B and view G.
2. Select the Pluge test pattern.
3. Adjust green G2 so that the small, black rectangle in the center of the
larger, black rectangle is just barely visible (Figure 3-8).
4. Select the Dot Pattern test pattern and toggle the HIDE key. While
toggling, verify there is no change in the background raster brightness.
(The Dot Pattern will turn on and off as the HIDE key is toggled but the
background brightness should not change while toggling.) If the
background brightness changes as the HIDE key is toggled, G2 is set too
high and the procedure should be repeated. When readjusting G2, look for
a slightly less visible small, black rectangle in the larger, black rectangle.
5. Select the Pluge test pattern again.
6. Cut off G and view R.
NOTE: When setting the G2 levels for green, red, and blue, they should
be set as closely as possible so that all 3 colors are at approximately the
same level.
7. 7. Repeat steps 3 and 4 for the red G2 level.
8. 8. Cut off R and view B.
9. 9. Repeat Steps 3 and 4 for the blue G2 level.
NOTE: G-2 adjustments affect Color Balance, Shading, and Proportional
Offset. After completing the G-2 setting, verify and readjust these
adjustments.
Figure 3-9 The Pluge test pattern. Use the two small rectangles in the center to
set G2 and Sensitivity Offset.
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3.11 Arc Lamp Alignment and Focus
The Arc Lamp must be realigned and refocused whenever the lamp is replaced or
becomes defocused or misaligned from physical shock to the projector.
Refocusing only may be required if the Arc Lamp has been in use for a long time.
Adjustment procedures for Model 330 projectors differ from those for the Model
340SC and Model 370SC projectors and are each detailed in the following
sections.
Model 330 Arc Lamp Alignment and Focus
To check Model 330 Arc Lamp alignment, confirm the "hot spot" (brightest area)
of the screen is centered on a flat field test pattern.
If the hot spot is not centered, the Arc Lamp needs alignment.
To check if focusing is needed, use a flat field test pattern to measure the
brightness at the center of the screen and at the corners with a light meter, using
all four (4) corners to determine the roll-off. The roll-off (gradual decrease in
brightness from center to corners) should be between 2:1 and 4:1. Do not try to
compensate for a dim corner by adjusting the Arc Lamp—dimness in one or two
corners is usually caused by variations in the ILA® assemblies and will be
corrected by Shading adjustments. Perform the Arc Lamp focusing procedure
only if the roll-off in all four (4) corners is too high.
CAUTION! In the interest of safety, please read
these entire procedures, prior to performing any adjustments, in
order to become familiar with the special NOTES and CAUTIONS
indicated.
To align the Model 330 Arc Lamp (refer to Photo 3-2):
1. Use a long-handled Hexhead tool (a long handle helps keep fingers away
from Ignitor terminals) to loosen the four (4) Arc Lamp holding screws
very slightly, just so that the washers under the screwheads become loose
enough to move on the shaft.
CAUTION!Be careful to not touch the Arc Lamp—it
is very hot! Be especially careful when loosening the bottom screw
so that the shaft of the Hex tool does not touch the Ignitor terminals
to the right of the tool.
2. Insert 2 Allen wrenches in the X and Y adjustment screws.
3. Turn the Allen wrenches in or out to center the hot spot on the screen.
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4. When the hot spot is at the center of the screen, retighten the four (4) Arc
Lamp holding screws.
X and Y
Adjustments
Z axis set screw
3 of 4 Arc Lamp
Holding Screws
(bottom screw
not shown)
Z-Axis Adjustment
Figure 3-10 Model 330 Arc Lamp Adjustments (the Heat Sink has been
removed for photograph).
To refocus the Model 330 Arc Lamp:
1. Loosen the Set Screw on the Arc Lamp shaft.
2. Adjust the Z-axis hexhead screw so that the screen is fairly even in
brightness from center to the corners with the center being the brightest.
3. Use a light meter and adjust the Z-axis adjustment screw for a roll-off
(drop in brightness from center to corners) of a maximum of 4:1
(preferably closer to 2:1).
Example: If the center of the screen measures 20 foot-candles, the
corners should measure 10 foot-candles ideally,
but no less than 5 foot-candles.
CAUTION!Do not leave the roll-off at a value higher
than 4:1, or the center may be too bright and could result in
damage to the cold mirror.
4. Retighten the set screw.
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Model 340SC and 370SC Arc Lamp Alignment and Focus
To check Model 340SC and 370SC Arc Lamp alignment, observe the anode
shadow on the blue dichroic mirror (the blue dichroic mirror is the first mirror
after the condensing lens). Verify that the anode shadow (small, dark oval inside
the light circle) is a uniform oval that is no more than ½ inch or no less than ¼
inch in diameter.
If the oval looks non-uniform or has a flare coming from one (1) side,
adjust the X-Y plates in the following manner:
1. Use a standard Phillips screwdriver and loosen the two (2) top screws on
the pivot holes (refer to Figure 3-9). Slide the plates on their pivots until
the shadow looks uniform.
2. While viewing Test Pattern 6 (Static Flat Field) the uniformity on the
screen should become more centered also.
To refocus the Model 340S and 370SC Arc Lamp:
1. Adjust the Z-axis of the Xenon Arc Lamp using a 9/64 inch hexhead
balldriver and rotate the screwhead (see Figure 3-9) for overall brightness
from the center to the edges with a minimum of roll-off (roll-off is the
gradual difference in brightness from the center of the screen to the edges).
Only a turn or two should be required.
2. Verify the proper brightness after the adjustments are complete with a light
meter by measuring the foot-candles of light output at the screen center
and multiplying this measurement by the area of the screen in square feet.
Example: If the screen area is 15x20 = 300 sq. ft.
and the light output on the light meter measures 20 foot-candles, the
brightness level in lumens is 300x20 = 6000 lumens.
Y-Axis Plate
X-Axis Plate
Z-Axis Screwplate
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Figure 3-9. Model 340SC and 370SC Arc Lamp Adjustments
3. Verify that the condensing (collimating) lens assembly has not moved (see
Figure 4-1 or 4-2 and Photo 4-4). Check to see if the assembly is loose. It
should be unmovable in any direction.
4. The barrel of the lens assembly should be no more than 1½ inches (usually
much closer) from the blue dichroic mirror. If it needs to be moved closer,
first loosen the 3mm set screw located at the top of the mounting ring
(Photo 4-4) that the barrel sets in, then move the lens closer to the blue
dichroic mirror. This will increase the center brightness. Roll-off may not
be acceptable if the barrel is moved too far forward.
NOTE: Be careful to maintain proper roll-off in these illumination optics
(arc lamp and condensing lens) adjustments. It is possible to get very high
brightness values at the screen center at the expense of proper roll-off. Try
to keep the ratio between center brightness and edge brightness. Roll-off is
2:1 to the edge and 4:1 to the corners (e.g.: if the center brightness is 20
foot-candles, the edge brightness should be at least 10 foot-candles and
preferably 10 foot-candles).
CAUTION!Do not leave the roll-off at a value higher
than 4:1, or the center may be too bright and could result in
damage to the cold mirror.
5. Retighten the set screw.
3.12 Arc Lamp Current Adjustment
The Arc Lamp current must be reset whenever an Arc Lamp is replaced and
should be rechecked every 500 hours of Arc Lamp operation.
CAUTION! If the Arc Lamp current is being adjusted due to
the installation of a new Arc Lamp or Arc Lamp/Ignitor assembly, the
current adjust pot (Photo 4-3) must be turned to minimum (fully CCW).
Failure to do this may result in damage to the equipment including failure
of the Arc Lamp, Ignitor, or power supply.
To check and adjust the Arc Lamp current:
1. Measure the output voltage at the System Power Supply (SPS) Ignitor
terminals J503 and J504. Note this figure.
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2. Measure the number of millivolts between pins 3 and 4 on SPS J505.
NOTE: This circuit is designed so that the number of millivolts between
these pins (for Models 340 and 370, it is millivolts divided by 10)
represents the lamp current in amps.
3. Multiply the two (2) figures from Item 1 and from Item 2 together.
4. Divide the product from Step 3 by 1 for Model 330 wattage. Divide the
product from Step 3 by 10 to get wattage for Model 340SC or 370SC.
5. Adjust the Lamp Current Adjust pot (see CAUTION below Table 3-1) on
the top of the SPS (refer to Figure 4-3) until this result is within the
appropriate HJT model spec indicated in Table 3-1).
Example (for Model 370SC): Voltage measured between J503 and
J504 = 28V and voltage measured between pins 3 and 4 of J505 =
1070mv.
The product of this is 29960÷10 = 2996W. This result is within the Model
370SC spec of 3000W ± 25W and would not require adjustment.
Table 3-2 Arc Lamp Current and Amp Specs
Model 330
Model 340SC
2000 Watts ± 25W
80 Amps Normal
85 Amps Maximum
Model 370SC
3000 Watts ± 25W
100 Amps Normal
110 Amps Maximum
1500 Watts ± 25W
68 Amps Normal
70 Amps Maximum
CAUTION! Make adjustments in small increments to ensure lamp
integrity (lamp overheating may occur if current is abruptly increased). Do not
increase the current beyond the maximum levels listed in Table 3-2.
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Chapter 4—Maintenance
4.0 Maintenance Remove/Replace)
Contents
4.1 Maintenance Remove/Replace) ....................................................................4-1
4.2 Projector Covers.........................................................................................4-5
4.3 Ventilation Filters.......................................................................................4-5
4.4 Arc Lamp Assembly...................................................................................4-6
Model 330 Ignitor and Arc Lamp Assembly (P/N 900611S) Removal ....4-6
Model 340SC and 370SC Ignitor Assy/Arc Lamp Assy (P/N 104651 or
104120) Removal......................................................................................4-8
Collimating (Condensing) Lens Adjustment.............................................4-10
4.5 System Power Supply.................................................................................4-11
4.6 Electronics Module ....................................................................................4-13
4.7 Cathode Ray Tube (CRT)...........................................................................4-15
Model 330 CRT Removal .........................................................................4-15
Model 340SC and 370SC CRT Removal..................................................4-18
4.8 Video Amplifier Board (VAB)...................................................................4-18
4.9 CRT Yoke ..................................................................................................4-19
4.10 High Voltage Power Supply (HVPS).........................................................4-20
4.11 Card Cage (Printed Circuit Boards) ...........................................................4-21
4.12 Image Light Amplifier Assembly...............................................................4-22
4.13 Projection Lens...........................................................................................4-23
4.14 (SCB) Socket Battery Replacement ...........................................................4-25
4.15 Recommended Spares ................................................................................4-27
4.1 Introduction
This chapter covers procedures on removal, replacement, and adjustment of a
specific assembly or subassembly.
NOTE: Before performing the front or rear cover or replacing any components or
subassemblies, please review the Safety Section at the front of this manual. These
procedures must be performed by HJT certified maintenance engineers and
technicians only.
When performing removal and replacement procedures, protect yourself and
equipment by following these precautions:
➨ Turn projector power off with the remote.
➨ After the cooling fans have stopped running, turn the projector
off at the circuit breaker and disconnect the power cord.
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Chapter 4—Maintenance
➨ Wait at least a minute after turning off power and removing the
power plug for the high voltage to bleed off.
➨ Observe all cautions and warnings printed on labels.
➨ Observe proper electrostatic discharge procedures.
The major removal and replacement sections are as follows:
Projector Covers.
Ventilation Filters.
Ignitor Assembly.
Arc Lamp Assembly.
System Power Supply.
Electronics Module.
Cathode Ray Tube.
Video Amplifier Board.
CRT Yoke.
High Voltage Power Supply.
Card Cage PCBs.
Image Light Amplifier (ILA®) Assembly.
Projection Lens.
Procedures in this manual make reference to the left or right side of the projector.
Left and right are determined while standing at the rear of the projector, facing the
screen.
WARNING!!! Disconnect AC power from the projector
before performing any removal and replacement procedures.
The following tools are needed to perform maintenance and service:
Standard computer service tool box.
Metric socket set.
Hex driver set.
Offset hex ratchet screwdriver.
Conductive electrostatic wrist strap with ground clamp.
Proper safety equipment and clothing.
4-2
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Figure 4-1 Major components of the Model 330 Projector.
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Chapter 4—Maintenance
Figure 4-2 Major components of the Model 340SC and 370SC Projectors.
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Chapter 4—Maintenance
4.2 Projector Covers
To remove the two-piece projector cover:
CAUTION! When removing the projector covers do not bump
any internal components of the projector. If any undue resistance is felt,
pause to locate the source of resistance before proceeding with cover
removal. If the projector has been operating, and the rear cover must be
removed, be sure to set the power interlock switch to the UP position
immediately and turn the projector back on with the remote, then turn the
power back off with the remote. This allows power to be reapplied to the
fans to cool the arc lamp which remains very hot even after power is
removed. During a normal power shutdown the fans will continue to run
for several minutes to cool the arc lamp.
1. Unplug the projector.
2. Remove the four (4) front cover and two (2) rear cover screws.
NOTE: When both covers are to be removed, the front cover
should be removed first. However, the rear cover may be removed
by itself if necessary.
3. To remove the front cover, first pull cover forward about 10cm.
Disconnect the fan connector on the left inside of the front cover.
4. Carefully slide the front cover forward and off the projector.
5. To remove the rear cover, from the rear of the projector, grasp the side ribs
and lift the whole cover upward and toward the back.
6. To replace the covers, reverse the removal procedure.
4.3 Ventilation Filters
Filters should be cleaned every two (2) months or 500 hours of operation,
whichever comes first. If excessively dusty or dirty conditions prevail, filters
should be cleaned more frequently.
There are two (2) filters which need periodic cleaning and inspection.
Both are located on the right side of the front and rear covers.
To remove and clean ventilation filters:
1. Unplug the projector.
2. Remove the filter in the right, front cover by unsnapping the filter cover.
3. Wash with soap and water or blow clean with an compressed air.
4. For the filter in the right, rear cover, remove the rear cover. Pull the filter
away from the velcro. Wash with soap and water or blow clean with
compressed air.
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NOTE: This filter can also be removed, while leaving the rear cover in
place, by removing the two screws at the top of the side panel where the
filter is located. Slide the panel up and out.
4.4 Arc Lamp Assembly
The Arc Lamp Assembly, which includes the Ignitor, is located in the middle
section of the projector. Separate instructions for both the Model 330 and the
Model 340SC and 370SC arc lamp assembly removal follow.
WARNING!!! High Voltage points of up to 40,000 volts are
exposed inside the projector covers. It takes at least a minute to bleed off
high voltage even after the unit has been turned off.
Model 330 Ignitor and Arc Lamp Assembly (P/N 900611S)
Removal
To remove the Ignitor Assembly or Xenon Arc Lamp from
a Model 330 Projector:
Refer to Photo 4-1 for right and left orientation and to perform the following
procedure. Label any connectors prior to removing to ensure they are reconnected
correctly.
1. Unplug the projector.
2. Remove the front and rear projector covers (see Section 4.2).
3. Disconnect and label the four (4) high voltage cables that are connected to
the Ignitor.
NOTE: If the small, black wire on J503 (where the black negative cable
connects from the Ignitor to the System Power Supply) is disconnected in
order to remove the Ignitor negative cable, be sure to reconnect it when
reinstalling the Ignitor. This wire carries the boost voltage that keys the
Ignitor on.
CAUTION! Do not disconnect the cable from the arc
lamp end! If returning the arc lamp, leave both cables attached to
avoid misaligning the Arc Lamp interior components.
4. Remove the three (3) ground straps from the Ignitor and Arc Lamp. Leave
them connected to the projector.
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J503 and
J504.
Ignitor
Assembly.
Figure 4-3 Model 330 Arc Lamp and Ignitor Assembly (P/N 900611S),
shown without Heat Sink attached)
5. Remove the three (3) Hex-head screws that attach the Ignitor Assembly to
the Arc Lamp rails.
6. Put on protective clothing, including safety goggles and face shield.
7. Slide the Arc Lamp and Ignitor Assembly out, being careful to clear the
plastic cover on the top of the System Power Supply (where two (2) of the
Arc Lamp cables are attached).
8. Place the Arc Lamp and Ignitor Assembly on a safe, level surface and turn
it over on its’ side.
9. Remove the two (2) bottom screws that attach the Ignitor Assembly to the
Arc Lamp rails.
10. The units are now separated for returning.
11. Perform the above steps in the reverse order to replace the Arc Lamp or
Ignitor Assembly. When reattaching the cables, be careful to reconnect
them to their correct terminals in accordance with the way they were
labeled in Step 3 above. Be sure that the connections are tightened
securely. Use Table 4-1 below as a guide when reconnecting the cables.
12. Perform the Arc Lamp Focus and Alignment procedure (Section 3.11) and
the Arc Lamp Current Adjustment procedure (Section 3.12).
NOTE: Whenever an Arc Lamp is replaced the Collimating Lens (Figure 4-3)
may need to be readjusted to obtain maximum brightness. Follow the procedure in
Section 4.4.3 to readjust the Collimating Lens.
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Table 4-1 Ignitor Connections for Model 330 Projector
Ignitor
Terminal
Location on
Ignitor
Wire Color
Wire goes to:
POS
INPUT
NEG
Right Side of
Ignition Coil
Negative Terminal
Lug mounted on
circuit board
Red
J504 (+) terminal on
System Power Supply.
J503 (-) terminal
Black
(on J503
side)
INPUT
on System Power Supply.
NEG
INPUT
Negative Terminal
Lug mounted on
circuit board
Black
Terminal
on rear of Arc Lamp.
POS
Left Side of
White
Enters middle
OUTPUT Ignition Coil
of Arc Lamp Housing.
Model 340SC and 370SC Ignitor Assy/Arc Lamp Assy (P/N
104651 or 104120) Removal
To remove the Ignitor Assembly or Xenon Arc Lamp from a Model 340SC and a
Model 370SC Projector:
Refer to Figure 4-4 and Figure 4-5 throughout the procedure below and to
establish right and left orientation. Label any connectors prior to removing to
ensure they are reconnected correctly.
1. Turn power off at the remote and circuit breaker and unplug the projector.
Do not attempt to remove or replace the Arc Lamp assembly without first
ensuring that power is off and the projector is unplugged from the AC wall
outlet.
2. Remove the front and rear projector covers (Section 4.2).
3. Put on protective clothing, including safety goggles and face shield.
4. Disconnect the black and red Arc Lamp high voltage cables from System
Power Supply J503 and J504 and untie the J505 cable that is wrapped
around J503. Do not unplug this cable from J505—it is wrapped around
J503 to keep it in place in case it must be removed in order to replace the
System Power Supply.
5. Disconnect the fan connector at the left front of the Arc Lamp housing.
6. Disconnect the cable from the Squirrel Cage blower on the right side of
the Arc Lamp housing.
7. Remove the Start Capacitor from the bracket adjacent to the Arc Lamp
assembly (one nut underneath the capacitor).
8. Cut the cable tie wrap (not shown in Figure 4-4 or Figure 4-5) at the
bottom rear of the Arc Lamp assembly (beneath the fan on the bottom rear
of the Arc Lamp assembly).
9.
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Chapter 4—Maintenance
10. Remove the two (2) ground straps (not shown in Photo 4-2 or Photo 4-3)
from the top, right side of the Arc Lamp assembly housing. Leave these
straps attached to the Collimating Lens housing.
11. Remove the two (2) hex bolts on the left and right side of the Arc Lamp
assembly that attach the Arc Lamp assembly to the mounting rails (lower
front of the Arc Lamp assembly). When removing the hex bolts, also
remove the ground straps and leave them attached to the Relay Lens
bracket.
Start
Capacitor
Interlock
Switch
Squirrel Cage
Fan Cable
Fan
Connector
Circuit
Breaker
Figure 4-4 Model 340SC and 370SC Arc Lamp Assembly
J503
J504
J505
Interlock
Switch
Lamp
Current
Adjust
Figure 4-5 System Power Supply-Arc Lamp Connection.
12. Carefully slide the Arc Lamp assembly out from the right side of the
projector.
13. Perform the previous steps in the reverse order to replace the Arc Lamp
Assembly. When reattaching the cables, be careful to reconnect them to
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Chapter 4—Maintenance
their correct terminals in accordance with the way they were labeled
above. Be sure that the connections are tightened securely.
NOTE: Whenever an Arc Lamp is replaced the Collimating Lens may
need to
be readjusted to obtain maximum brightness. Follow the Collimating Lens
Adjustment procedure in Section 4.4.3 to accomplish this.
NOTE: The Arc Lamp current must also be reset when an Arc Lamp is
replaced. The procedure for adjusting the Arc Lamp current and verifying
power output is in Section 3.12 (Model 340SC is 2000W ±25W and
Model 370SC is 3000W ±25W).
CAUTION! Make adjustments in very small increments
to insure lamp integrity (lamp overheating may occur if current is
abruptly increased). Do not increase the current beyond the
amount specified in Table 3-1, Section 3.12 or damage to the
equipment could occur.
Collimating (Condensing) Lens Adjustment
To adjust the Collimating Lens (refer to Photo 4-4):
1. Loosen the 3mm set screw located at the top of the Colliminating Lens
housing (that the Collimating Lens barrel fits into).
3-mm Set
Screw
Mounting
Screws
Figure 4-6 Collimating Lens Adjustment (shown on Model 370SC)
2. Move the Collimating Lens closer to the Blue Dichroic mirror. This
increases center brightness. Roll-off may not be acceptable if the barrel is
moved too far forward. Roll-off is the gradual difference in brightness on
the screen from the center to the edges. Try to keep the roll-off between
center and edge brightness to 2:1.
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Chapter 4—Maintenance
Example: If the center brightness is 20 foot-candles, the ideal edge
brightness should be 10 foot-candles.
CAUTION! Do not allow roll-off to be greater than 4:1
or damage to the Cold Mirror could result. Refer to Section 3.11
information on how to check roll-off.
3. In some cases it may also be necessary to adjust the vertical and horizontal
orientation of the collimating lens to achieve maximum brightness.
CAUTION! This adjustment can be sensitive
and should not be attempted unless all other measures have
been tried first. To do this, loosen the three (3) mounting
screws on the rear of the condenser lens mount (see Figure
4-6) and move the collimating lens to orient the hot-spot
(brightest area) to the center of the screen.
4.5 System Power Supply
The System Power Supply is located immediately forward of the electronics card
cage.
To remove the system power supply (see Figure 4-4 and Figure 4-5 and Figure
4-7):
1. Unplug the projector. Allow at least one (1) minute for high voltage to
bleed off before proceeding.
2. Remove the rear projector cover (Section 4.2).
3. Remove the two (2) screws from the Plexiglas cover over the terminal
block (top of SPS, forward-Figure 4-1) and remove cover.
4. Label and remove the arc lamp ignitor cables, J503 and J504, and the
shield ground wire from the DC terminal block.
5. Remove the Plexiglas cover from the AC input terminal block located on
the right side of the power supply (see Figure 4-7).
6. Ensure power is disconnected then remove the three (3) AC input wires
from the AC terminal block:
Green (or Yellow/Green) left terminal (Ground).
White (or Blue) middle terminal (Neutral).
Black (or Brown) right terminal (Hot).
NOTE: Colors may be different, depending on country of use.
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AC Power
Terminal Block
Ground
Main AC Circuit
Breaker
Mounting
screws
(under lip)
Figure 4-7 System Power Supply (right side of projector)
7. Remove the grounding cable from the right side of the power supply (see
Figure 4-7).
8. Loosen and release the two (2) captive screws at the base of the power
supply, located on the right side below the AC terminal block (under the
mounting bracket–Figure 4-7).
9. Move to the left side of the power supply and cut the tie wrap securing the
HVPS anode leads to the power supply (see Figure 4-8).
10. Remove the screw securing the wire bundle clamp to the power supply
(Figure 4-3).
11. Unplug the three (3) system power supply connectors (Figure 4-3).
Do not pull on the connector wires-unplug from power supply by
squeezing the latching tabs and pulling on the connector shell or housing.
12. Loosen and release the two (2) captive screws at the base of the power
supply (Figure 4-3). Ensure the nylon spacers on the captive screws do not
get lost.
Be sure to replace them between the power supply and the support lip
when reinstalling the power supply.
13. Lift the power supply off from the projector.
14. Perform the above steps in the reverse order to replace the System Power
Supply. Be sure that all connectors are firmly seated and locked and all
pins are mating. When reinstalling the Arc Lamp cables to the DC
terminal block (Step 4 above), a torque wrench should be used. The Arc
Lamp connections to the top of the SPS should be torqued to 25-30 in. lbs.
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Chapter 4—Maintenance
SYSTEM POWER
SUPPLY
CONNECTORS
J501
J500
J502
Wire Bundle
Clamp
ARC
LAMP
ASSEMBLY
SYSTEM
POWER
SUPPLY
CARD
CAGE
BACKPLANE
TIE WRAP
ANODE LEADS
HIGH VOLTAGE
POWER SUPPLY
CAPTIVE SCREWS
Figure 4-8 System and HV Power Supply (left side of projector)
4.6 Electronics Module
The Electronics Module is the entire assembly to the rear of the Arc Lamp and
optics assemblies. The Electronics Module consists of the system power supply,
card cage, and CRT housing assembly.
To remove the Electronics Module:
1. Unplug the projector. Allow at least one (1) minute for high voltage to
bleed off before proceeding.
2. Disconnect the system power supply.
2.a If the system power supply is to be removed from the Electronics
Module, remove the system power supply following instructions
in Section 4.5.
2.b If the system power supply is not to be removed from the
Electronics Module, disconnect the system power supply
following instructions in Section 4.5, Steps 1 through 7.
3. Free the power cord from the electronics module by removing the cable
clamp(s) on the right side base of the electronics module.
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Chapter 4—Maintenance
4. At the rear of the projector, remove the three (3) filter housing screws
(located under the rear lip of the projector base-plate) and remove the filter
housing.
5. On the left side of the projector, unplug connectors P82 and P83 from the
backplane and move the wiring harness out of the way.
6. Back all CRTs into the CRT assembly (focus rod screws, at the rear of the
CRT assembly, to the stops—refer to Photo 4-6.
7. At the base of the electronics module remove the hex screw at each corner
(four [4] screws).
8. Ensure that all control and input cables are disconnected from the back of
the card cage then tilt the card cage back.
9. Remove the two (2) hex screws in the base of the electronics module
under the card cage. Tilt the card cage back forward.
CAUTION! Remove anything plugged into the rear
electronics jacks or the plugs could be severely damaged when the
module is tilted back.
10. Remove the electronics module (two people) by grasping the handles at
the rear and the lip under the system power supply in the front.
CAUTION! Do not bump the CRT cooling bellows
while removing the electronics module! The CRT cooling
bellows (refer to Figure 4-4) are fragile and easily damaged. If
damaged, the CRT must be replaced and will not be covered by
warranty. Use extreme care removing and replacing the electronics
module and CRTs.
11. Replace the module in the reverse order.
12. After the module is replaced, perform a CRT mechanical focus adjustment
(refer to Section 3.7).
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Chapter 4—Maintenance
4.7 Cathode Ray Tube (CRT)
Three (3) cathode ray tubes are located in the CRT assembly below the card cage
and system power supply. The following procedure is used to remove any CRT:
WARNING!!! Handle a CRT with extreme caution. If
dropped they can implode and flying glass can cause severe injury to
personnel. Never bump or drop the tube. Use extreme care when
removing and replacing CRTs. Dispose of the tube immediately.
Model 330 CRT Removal
Figure 4-9 Model 330 CRT Assembly
To remove a Model 330 CRT Assembly (refer to Figure 4-4):
1. Unplug the projector. Wait at least a minute before proceeding for the high
voltage to bleed off.
2. Remove the electronics module (Section 4.6).
NOTE: Removal and replacement of a CRT may be more easily
accomplished with the System Power Supply removed from the electronics
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Chapter 4—Maintenance
module. This is not absolutely necessary and it is up to the technician’s
discretion whether or not to remove it (Section 4.5).
3. After removing the System Power Supply, remove the system power
supply mounting plate that covers the top front area of the CRT Assembly.
4. Run the CRT all the way forward using the Z axis focus rod at the rear of
the CRT assembly (Photo 4-6).
5. Remove the video amplifier board from the CRT Assembly (Section 4.8).
6. Inside the CRT housing, remove the cable clamp(s) from the CRT anode
cable.
7. Inside the CRT housing on the left side, disconnect the CRT anode cable
from the bulkhead connector. Ensure the entire anode cable is free.
8. Loosen the yoke clamp and ensure the yoke is loose on the CRT neck.
9. Remove six (6) mounting screws at the face of the CRT.
10. Gently remove the CRT by sliding it forward out of the yoke and CRT
housing.
11. Replace the CRT in the reverse order.
12. Perform a CRT mechanical focus adjustment, yoke alignment, horizontal
width adjustment, vertical size adjustment, and linearity adjustment after
replacing the CRT (refer to the appropriate model Operator’s Manual).
Notes on replacing a Model 330 CRT:
Orient the bellows on the front of the CRT to the top side.
Remove the plastic coating from the tube screen only after the
CRT has been installed.
Tighten all CRT mounting screws in a diagonal pattern.
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Figure 4-10 Model 340SC and 370SC CRT Assembly
Figure 4-11 CRT Z-Axis Focus Adjustment Rods (circled).
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Chapter 4—Maintenance
Model 340SC and 370SC CRT Removal
To remove a Model 340SC and 370SC CRT (see Figure 4-10):
1. Unplug the projector. Wait at least one (1) minute before proceeding for
the high voltage to bleed off.
2. Remove the electronics module (Section 4.6).
NOTE: Removal and replacement of a CRT may be more easily
accomplished with the System Power Supply removed from the electronics
module. This is not absolutely necessary. It is at the technician’s discretion
to remove it or not (refer to Section 4.5).
3. After removing the System Power Supply, remove the System Power
Supply mounting plate that covers the top front area of the CRT Assembly.
4. Run the CRT all the way forward using the Z axis focus rods at the rear of
the CRT assembly. This allows more room to remove the CRT socket.
5. Remove the video amplifier board from the CRT Assembly (refer to
Section 4.8).
6. Inside the CRT housing, remove the cable clamp(s) from the CRT anode
cable.
7. Inside the CRT housing on the left side, disconnect the CRT anode cable
from the bulkhead connector. Ensure the entire anode cable is free. Loosen
the yoke clamp and ensure the yoke is loose on the CRT neck.
8. Remove three (3) mounting screws at the face of the CRT. Gently remove
the CRT by sliding it forward out of the yoke and CRT housing.
9. Replace the CRT in the reverse order.
10. Perform a CRT Mechanical Focus adjustment and yoke alignment after
replacing the CRT (refer to Section 3.7 and 3.2).
Notes on replacing a Model 340SC and 370SC CRT:
Orient the CRT high voltage cable connector downward.
Remove the plastic coating from the tube screen only after the
CRT has been installed.
4.8 Video Amplifier Board (VAB)
The video amplifier boards are located inside the CRT housing. They are mounted
on and fully supported by the CRT neck. There is one (1) video amplifier board on
each CRT.
To remove a VAB (see Figure 4-9 or Figure 4-10):
1. Unplug the projector. Wait at least a minute before proceeding for the high
voltage to bleed off.
2. Remove the rear projector cover (Section 4.2).
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Chapter 4—Maintenance
3. Ensure that all control cables are disconnected from the back of the
cardcage then tilt the card cage back to expose the inside of the CRT
housing.
4. Unplug and label the five cables connected to the VAB.
5. Unplug and remove the VAB from the back of the CRT.
CAUTION! The connector pins on the CRTs are easily
damaged. If damaged, the CRT must be replaced and will not be
covered by warranty. Use extreme care when taking the VAB out of
the CRT housing to avoid damage to the CRT connector pins. In
some cases, it may be necessary to move the CRT all the way
forward (Z axis focus rod, rear of CRT assembly—see to Figure
4-11).
6. Perform the above steps in the reverse order to replace the VAB.
7. Perform a CRT Mechanical Focus adjustment (Section 3.7) after replacing
the VAB.
4.9 CRT Yoke
The CRT yoke is located on the CRT neck and is supported by the CRT.
There is one (1) yoke for each CRT.
To remove the CRT yoke (see Figure 4-9 or Figure 4-10):
1. Unplug the projector. Wait at least one (1) minute before proceeding for
the high voltage to bleed off.
2. Run the CRT all the way forward (Z axis focus rod, rear of CRT
assembly).
3. Remove the video amplifier board (see Section 4.8).
4. Loosen the yoke clamp and ensure the yoke is loose on the CRT neck.
5. Disconnect the yoke cable connector. Slide the yoke assembly off the rear
of the CRT.
CAUTION! The connector pins on the CRTs are easily
damaged. If damaged, the CRT must be replaced and will not be
covered by warranty. Use extreme care when taking the yoke out of
the CRT housing to avoid damage to the CRT connector pins. In
some cases it may be necessary to use the two other mechanical
focus adjustment rods to tilt the CRT to allow the yoke to be
removed from the CRT neck.
6. Perform the above steps in the reverse order to replace the yoke assembly.
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Chapter 4—Maintenance
7. Perform a CRT mechanical focus adjustment (Section 3.7) and yoke
alignment (Section 3.2) after yoke replacement.
4.10 High Voltage Power Supply (HVPS)
The HVPS is located on the left side of the projector next to the CRT housing
assembly.
To remove the HVPS:
1. Unplug the projector. Wait at least a minute before proceeding for the high
voltage to bleed off.
2. Run all three (3) CRTs all the way forward using the Z axis focus rods at
the rear of the CRT assembly (Photo 4-6).
3. Remove all three (3) video amplifier boards (refer to Section 4.8 and either
Figure 4-4 or Figure 4-5).
4. Remove the System Power Supply (see Section 4.5).
5. Remove the System Power Supply mounting plate (covers High Voltage
Power Supply).
6. Inside the CRT housing on the left side, disconnect all three (3) CRT
anode cables from the bulkhead connectors. As an added precaution, short
the anode leads to the High Voltage Chassis ground to bleed off any
residual charges. Slide the anode wire connectors off their mounting
brackets.
7. In the bottom rear of the CRT housing, cut the tie wraps holding the HV,
G2, and focus cables.
8. Carefully slide all G2, and focus cables out of the CRT housing.
9. Remove the top connector (power control) at the rear of the HVPS.
10. Loosen and release the five (5) captive screws at the base of the HVPS:
Two (2) screws are located forward.
One (1) screw on top.
Two (2) screws at the rear.
11. Remove the HVPS.
12. Replace the HVPS in the reverse order.
13. Perform a CRT mechanical focus adjustment, yoke alignment, G2
adjustment, and electronic focus adjustment after HVPS replacement
(Sections 3.7, 3.2, 3.10, and 3.8).
NOTE: When replacing the HVPS, ensure that the wires are routed to the
proper color and that the wires are neatly placed in the bottom of the CRT
housing.
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Chapter 4—Maintenance
4.11 Card Cage (Printed Circuit Boards)
The card cage is located at the rear of the projector above the CRT housing.
CAUTION! Printed circuit boards in the electronics module
are susceptible to electrostatic damage. While servicing the projector be
sure to observe electrostatic discharge precautions. Always wear a
conductive wrist strap and ground lead when handling PCBs.
To remove a PCB:
1. Turn the projector power off at the remote. Wait at least one (1) minute for
the high voltage to bleed off.
2. Remove the rear projector cover (see Section 4.2) and toggle the Main
Circuit Breaker to off (see Figure 4-7).
3. Remove the eight (8) screws securing the electronics module cover and
remove the cover.
4. Slide the card lock latches toward the center of the card lock and remove
the card lock.
5. Lift the tabs of the card extractors on the edges of the PCB to unseat a card
from its connector(s).
6. Lift the PCB from the electronics module.
7. Replace the PCB in the reverse order.
NOTE: Each PCB has a dedicated card slot with keyed connector
positions. Observe the connector positions prior to inserting to ensure
proper placement.
CAUTION! Before inserting a PCB into the card cage,
ensure there are no bent pins on any connectors. The PCBs may
need to be slightly flexed or jostled in order to properly seat them
into the backplane. Be sure that all connectors on a PCB are
properly aligned with and started into their mating connectors on
the backplane before applying pressure on the PCB or its card
extractor tabs to seat it.
NOTE: When replacing the horizontal deflection board, the Horizontal
Deflection Board (P/Ns 100566 & 102523) could be damaged if the board
is not seated properly on the Backplane. This problem usually occurs when
the HDB is removed and reinserted after a board failure or when changing
the sweep reversal connector. A failure can occur if connector J11 on the
HDB (located at the far right when viewing from the component side) does
not connect completely with P11 on the backplane.
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Chapter 4—Maintenance
To ensure a proper connection between J11 and P11 follow the procedure below:
Before installing the Horizontal Deflection Board, remove the Vertical Deflection
Board. This allows for a full inspection of the proper connection of J11 and P11.
The P11 connector on the backplane is slightly loose to allow movement for
minor dimensional differences in the position of the J11 connector on the HDB.
Do not tighten connector P11 on the backplane.
4.12 Image Light Amplifier Assembly
The ILA® Assemblies are located in the optics module near the front of the
projector, directly ahead of the relay lenses.
To remove an ILA® Assembly:
1. Remove the front projector cover (Section 4.2).
NOTE: It may be necessary to remove the left side air baffle cover in
order to gain access to the Blue and Green ILA® Assemblies. To remove
the cover, remove the three (3) securing screws and pull the cover loose
from the velcro tabs.
2. Remove the bias connector from atop the ILA® assembly to be removed.
Mark all bias connectors, or remove one (1) ILA® assembly at a time to
avoid misconnections.
3. Loosen the hold down clamps on either side of the ILA® assembly (loosen
about 1 turn).
4. Lift the ILA® assembly out of its mount. Use care to avoid getting finger
prints or other contamination on any optical surfaces.
5. Perform the above steps in the reverse order to replace the ILA®
assembly.
The ILA® assemblies should be clamped only
enough to eliminate play in the mount. Overtightening can cause
unpredictable performance while undertightening may result in improper
focus and color reproduction.
CAUTION!
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Chapter 4—Maintenance
4.13 Projection Lens
Projection lenses are located at the front of the projector and are held in place by
friction clamps called Lens Locking Rods.
Lens Locking
Rods
Figure 4-12 Projection Lens Locking Rods
To remove a projection lens (see Figure 4-12):
1. Turn off the projector.
2. Using a slot screwdriver, loosen the lens locking rod and turn the clamp at
the top of the lens (first, see WARNING below) until the flat part of the
clamp is facing down.
WARNING!!! Be very careful when performing this
procedure, especially if the projector is tilted downward, because
the lens can fall out and seriously injure personnel.
3. Carefully pull the lens out of the clamp housing.
4. Perform the above steps in reverse order to replace the projection lens.
NOTE: Projection lenses are color sensitive. When replacing lenses ensure
they are placed in the correct positions. Use
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Chapter 4—Maintenance
Table 4-2 for reference to part numbers, if necessary.
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Chapter 4—Maintenance
Table 4-2 Lens Replacement
Lens Throw
Ratio
1.5:1
Lens Part Number or Designation
Red
Green
101241
Blue
101715
900609-1
101239
101240
101241
900609-3
101239
101240
3:1
5:1
7:1
900609-2
101239
101240
NOTE: More details on lens options, converters and other lens information
can be found in the appropriate model Operator's Manual.
4.14 (SCB) Socket Battery Replacement
As indicated in the troubleshooting table (under “Picture-Various Problems”,
weak backup RAM socket batteries in the SCB can cause lost data when the
projector is turned off and back on again. All four (4) of these batteries should be
replaced at the same time if this condition occurs.
CAUTION! Never place the socket battery on a metal
surface! The positive and negative terminals could short out and destroy
the battery!
WARNING!!! Danger of explosion if this battery is
incorrectly replaced! When replacing the Lithium batteries, be sure they
are ilnstalled with the correct polarity. If installed backwards they could
explode! Replace only with the same or equivalent type recommended by
the manufacturer. Dispose of the old Lithium batteries in accordance with
local safety codes. Contact your local authorities for proper disposal
procedure.
To replace the SCB socket batteries:
CAUTION! When replacing SRAM all channel data
will be lost. All channel data must be downloaded.
1. Download all channel data on the System Controller.
2. Remove the System Controller Board PCB (refer to Section 4.11).
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Chapter 4—Maintenance
Figure 4-13 System Controller Board SRAM Chips Location.
CAUTION! Never place the socket battery on
a metal surface! The positive and negative terminals of the
battery will short out and destroy the battery!
3. The four (4) socket batteries are located in the chip inserts beneath the
SRAM chips, U25, U26, U64, and U65 (refer to Figure 4-6 for location).
Remove the four (4) SRAM chips and batteries from the SCB (note the
position of pin 1 by the key in the chip-pin 1 is at the upper left looking
down at the chip with the cutout key at the top).
4. Carefully separate the socket batteries from the socket extensions (see
Figure 4-14). DO NOT remove the SRAM chip from the extension.
5. Reinsert the SRAM chip and extension into the new socket batteries.
Figure 4-14 SRAM Chip, Extension and Battery Side View
6. Carefully reinsert the socket batteries and SRAM chips back into the SCB.
7. Reinstall the SCB.
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Chapter 4—Maintenance
4.15 Recommended Spares
It may be advisable to maintain a supply of spares to maximize performance. This
is particularly important if projectors are being operated on a continuous basis or
when multiple projectors are used. Table 4-3 provides a list of recommended
spares for one (1) to four (4) Series 300 model projectors.
Table 4-3 Recommended Minimum Spares
Description
Quantity
330
340SC
PART NUMBERS
104071
370SC
System Power Supply
Arc Lamp Assembly
Ignitor
High Voltage Power Supply
Raster Timing Generator
Horizontal Deflection Board
Vertical Deflection Board
Video Processing Board
Video Amplifier Board
System Controller
1
1-4
1
1
1
1
1
1
1
104070
104038
104120
104475
103769
100568
102523
102521
104672
103567
104668
900611S
102083
100562
100568
102523
102521
104672
103567
104668
104651
102207
100562
100568
102523
102521
104672
103567
104668
1
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Chapter 5---Troubleshooting
5.0 Troubleshooting
Contents
5.1 General Information ....................................................................................5-1
5.2 Troubleshooting ..........................................................................................5-3
5.3 Break Points ................................................................................................5-5
5.4 Main Menu Structure ..................................................................................5-7
5.1 General Information
This chapter provides information and solutions on probable projector problems,
including Error Codes, Power-On Codes, and Break Points for HJT Model 330,
Model 340SC and Model 370SC Projectors with software version 5.1.0.
The Error Codes listed in Table 5-1 describe possible problems associated with
software and hardware while the projector is operating. The first (1st) column of
the table lists the LED letters shown on the rear of the projector, and the second
(2nd) column for the first seven (7) letters shows the on-screen text that shows
along with the operator messages (up to 19 characters). The remaining codes
appear without on-screen text—the second (2nd) column is the error description.
Status or error codes are flashed for no more than one (1) minute before being
replaced with the neutral beating “0” (zero) at a low light level.
The Power Codes in Table 5-2 show the sequence of codes that occur when the
projector power is first turned on. The first (1st) column indicates the LED code
letter or number and the second (2nd) column provides a description of the
problem.
Break Point (Trap Processing) Error Codes and Break (Trap) Data Code Displays
are detailed in Table 5-3 and Table 5-4.
The Menu Structure Diagram provides information about the Projector Menu Log
that will help to determine if certain assemblies are due for replacement.
Table 5-5 provides a Troubleshooting Guide to possible problems encountered in
the Model 330, 340SC and 370SC Projector. The first (1st) column calls out the
nature of the problem and a possible symptom to check. The second (2nd) column
suggests possible solutions. The third (3rd) column provides the reference section
in this manual. The fourth (4th column supplies the reference section in the
appropriate model Operator's Manual.
5-1
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Chapter 5---Troubleshooting
Table 5-1 Error Codes for the Model 330, 340SC and 370SC Projectors
LED On-Screen Text Description
Codes shown along with operator messages.
A RAM BATTERY Memory problem—data may be lost if
b
IS LOW
power-off.
COLOR IS
CUTOFF
Adjustment being attempted on cut-off gun.
c
DSP INIT FAILURE Convergence logic is dead at power-on.
d
l
LAMP TO-ON,
BUT OFF
Arc lamp did not light.
LAMP TO -OFF,
BUT ON
POWER TO-ON,
BUT OFF
Problem detecting arc lamp state.
Power supply problem.
m
p
POWER TO-OFF,
BUT ON
Power supply problem.
w
LED
Description
Codes indicating temporary error state or hardware problem.
An internal table controlling timing is momentarily full.
A CPU trap error has occurred. This is potentially serious.
The internal system command queue is momentarily full.
Problem with the terminal-in port timing.
a
e
f
g
h
i
Problem with the terminal-in port operation.
Problem with the DSP output circuits—convergence may be lost.
DSP time-out—should recover automatically. May affect
convergence.
j
Problem with the IIC hardware—Type 1.
Problem with the IIC hardware—Type 2.
Hardware detected source change but nothing found by software.
Problem with DAC hardware.
k
o
q
r
Vertical sync not detected.
s
t
Loss of video-OK detected.
Problem with Extron communication.
Extron communication time-out.
u
v
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Chapter 5---Troubleshooting
LED
x
On-Screen Text
Description
Problem with decoder module data.
Problem with decode input.
y
#
Loss of horizontal sweep detected.
Codes indicating a software bug—system should keep running.
Internal error code not recognized.
Incoming command not recognized.
Internal password control code bad.
DAC reference not recognized.
G
H
J
K
L
Timer table reference not valid.
IIC reference not recognized.
M
N
P
Q
R
RTG reference not recognized.
Internal convergence axis reference invalid.
Internal channel parameter reference not recognized.
Internal convergence data index invalid.
5.2 Power-On Codes
The projector performs a series of operations when power is turned on. Codes for
these operations are shown on a LED display at the rear of the projector.
Operations are divided into two (2) sets:
1. The first (1st) set occurs when standby power is applied. For example, the
projector is plugged into a proper outlet and the circuit breaker on the side
of the projector is ON.
2. The second (2nd) set takes place when the user issues a “power-on”
command. For example, presses “Control-P” on a VT-100 terminal or
“POWER ON” on the I/R or tethered remote.
First Set
The first (1st) set of operations occurs when the +5volts is activated to the SCB
prior to applying power to the projector (standby mode). After the +5volts is
applied, the LED should display a zero or #—if not displayed, there is a problem
with the SCB.
Verify the following conditions:
1. Verify that +5volts and +24volts standby LEDs are lit. If STB +5volts and
+24volts are not present, verify that the projector is plugged into a proper
outlet and that the circuit breaker on the right side of the projector is on. If
5-3
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Chapter 5---Troubleshooting
STB +5volts or +24volts are still not present after verifying that the circuit
breaker is on and the projector is plugged in, the System Power Supply
may be defective.
NOTE: Only the +5 volts LED is lit on the Backplane Status Indicator
panel (see Figure 2-2) when A/C power is applied. When the projector is
directed to Power-On the +24volts standby LED should light and fans
should be running.
2. If STB +5volts and +24volts are present, the SCB is the most likely
cause of the problem.
Second Set
The second (2nd) set of operations only complete if no errors occur. If an error is
detected, the code corresponding to the failed operation is displayed, and remains
on the LED until the circuit breaker is cycled or another user “Power-On”
command is issued. These errors are far more likely to occur than those of the first
set.
Table 5-2 Codes for Second Set of Operations (User "Power-On")
Code
F
Description
“Lamp On” not detected.
SCB defective.
E
B
9
8
7
6
5
4
3
2
1
0
Low Voltage Power Supply output not detected.
SCB defective.
SCB defective.
SCB or RTG defective.
SCB defective.
SCB defective.
Any PCB in the Card Cage could be defective.
SCB defective.
SCB defective.
SCB defective.
All systems okay; start-up is finished. LED stays at 0 unless
the SCB receives an error signal that is listed in Table 5.1.
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Chapter 5---Troubleshooting
5.3 Break Points
Break Points (or Trap Processing) handle internal interrupts generated by the
processor, such as: bus errors, illegal instruction, and divide by zero commands.
Perform the following steps to setup for break codes (trap processing):
1. Access MAIN MENU and select #4 (DIAGNOSTICS MENU).
2. Select #7—this is an invisible menu item.
3. Press ENTER to clear the displayed break (trap) data.
When a break (trap) occurs, the CPU stops normal operation and outputs a code to
the LED located at the rear of the projector. The code consists of the character “e”
followed by a “2” through “C.” The error code displays in a continuous loop.
Error codes and explanations are provided in Table 5-3.
Table 5-3 Break Point (Trap Processing) Error Codes
Code
Meaning
Description
Bus error.
Probably electrical noise.
2
Address error.
Illegal instruction.
Zero divide.
Noise or program bug.
Noise or program bug.
Program bug.
3
4
5
CHK instruction.
Unlikely—may be a bug.
6
TRAPV instruction. Unlikely—may be a bug.
7
Privilege violation.
Trace.
Bug.
8
Noise.
9
Line 1010 emulator. Noise.
Line 1111 emulator. Noise.
A
B
C
Spurious interrupt.
Hardware.
5-5
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Chapter 5---Troubleshooting
Resetting the Projector
The projector’s processor must be reset if a break (trap) condition occurs. The
processor can be reset by either of the following methods:
1. Cycle main power off, then back on (allow ten minutes
for Arc Lamp to cool).
2. Press the reset button (labeled S1) located at the top center
of the SCB.
Break (Trap) Data from the Diagnostics Menu
After resetting the projector, retrieve the break (trap) data from the diagnostics
menu by performing these steps:
1. Access MAIN MENU and select #4 (DIAGNOSTICS MENU).
2. Select #7—this is an invisible menu item.
3. Press ENTER to clear the displayed break (trap) data.
Break (trap) data is displayed in the format as indicated in Table 5-4.
Table 5-4 Break (Trap) Data Code Displays
Code
EXCPT
N
Description
Description per list in the LED display errors above.
Program counter value-program location when trap occurred.
Status register value.
PC
SR
Instruction register value.
IR
Access address.
AA
R/W, I/N and FC flags and values.
FLAGS
Use a Service Report to write down all the break (trap) data. The service report
will be analyzed by a Hughes-JVC technician to determine the problem.
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Chapter 5---Troubleshooting
5.4 Main Menu Structure
MAIN MENU
1. CHANNEL MENU
2. STATUS MENU
>
3. ILA MENU
>
4. DIAGNOSTIC MENU
>
5. TIMING MENU
>
6. VIDEO QUICKSET
>
7. GRAPHIC ENHANCE
>
.
.
.
. .
CHANNEL MENU
STATUS MENU
ILA BIAS MENU
TIMING SETUP MENU
1. CHANNEL LIST
2. AUTOSELECT LIST
3. COPY CHANNEL
4. UPDATE DEFAULTS
5. IMPORT CHANNEL
6. EXPORT CHANNEL
7. COPY PARAMETERS>
8. DECODER SETUP(option>)
1. CH 1....
LNDBL
16.0 KH
30.5H
YES/NO
INT/EXT
0
ON/OFF
ON/OFF
5.1.0
1. PINCUSHION POSN
2. MENU POSITION
3. 2H SYNC ENABLE
4. SHIFT SYNC
1. ADJUST WITH VIDEO
2. ADJUST, NO VIDEO
3. MAX-ON, NO VIDEO
4. FREQUENCY ADJUST
5. MAX-ON WITH VIDEO
2. HORZ RATE
3. FRAME RATE
4. INTERLACE
5. SYNC....
6. PROJ ADD
7
SHOW ADD
8. SHOW ERR
9. CPU SW...
10. DSP SW...
2.0.4.
GRAPHIC ENHANCE
1. WHITE ENHANCE
2. BLACK ENHANCE
DIAGNOSTICS MENU
This menu should be used
only by Hughes certified
.
.
engineer/technicians.
AUTOSELECT LIST
CHANNEL LIST
AUTOSELECT IS ON/OFF
GROUP 1-10
CHANNELS 1-10
N/A
CH
IN
SL NAME
VIDEO QUICKSET
1. 80% SENSITIVITY
2. 20% THRESHOLD
3. VIDEO SENSITIVITY
4. VIDEO THRESHOLD
1
2
RGB1 ST INIT
RGB1 ST
3
4 V
PC1
VTR BP
BP
.
.
29. NA ST
30. NA ST
CONVERGENCE MENU: Press POS/CONV to enter the
Convergence Mode, then use Mode key to select XY or
Sensitivity or Threshold, then press Menu to get either the XY
REGISTRN or SHADE AXIS MENU below.
TEST PATTERN MENU
(To access a test
pattern, select TEST
on the remote)
.
COPY PARAMETERS
1. EXTERNAL VIDEO
2. WHITE X-HATCH
3. RGB X-HATCH
4. DOT PATTERN
5. PLUGE
6. STATIC FLAT FIELD
7. ADJUST FLAT FIELD
8. H-GRID
1. X, Y CONVERGENCE
2. SHADE & PROPORTNS
3. PROPORTION VALUES
4. SHADE, NO PROPTNS
5. ILA BIAS & FREQ
SHADE AXIS MENU
1. OFFSET THIS AXIS
2. CLEAR THIS AXIS
3. CLEAR SHADE AXES
4. PROPTN THIS AXIS
5. INIT THIS PROPTN
6. INIT ALL PROPTN
7. SEE AXIS VALUES
XY- REG AXIS MENU
1. OFFSET THIS AXIS
2. CLEAR THIS AXIS
3. CLEAR CONVG AXES
4. CLEAR ALL AXES
6. GEOMETRY SETTINGS
5. SEE X AXIS VALUES
6. SEE Y AXIS VALUES
9. GREY SCALE
10 CONTRAST/BRIGHT
DECODER SETUP (OPTIONAL)
1. SELECT STANDARD------NTSC-M
PAL-BDGI, PAL-N, SECAM, PAL-M,
PAL-4.43, NTSC-M, NTSC-4.43,
BLK/WHT
KEY:
HELP
The remainder of items in this menu are
for use by HJT certified engineers and
technicians only.
= Press left or right arrow.
= Submenu available
>
Version 5.1.0 Software Menu Diagram
Software versions are indicated on the Status Menu,
and may be supplemented in Field Service Bulletins.
Figure 5-1 Menu Structure Diagram.
5-7
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Chapter 5---Troubleshooting
Table 5-5 Troubleshooting Guide
Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
No Power
Main input power.
System Power
Supply main
circuit breaker.
System Power
Supply circuit
breaker fails
when reset?
Reset circuit breaker.
3-1
3.1,
Figure 3-1
Reset System Power Supply circuit
breaker. Reset interlock switch
to the UP position.
Verify input power is correct.
Replace defective System Power
Supply
4.5
Power Interlock
Switch.
Projector cover not Reposition rear cover.
Test switch operation.
Figure 3-1
4.2
If defective, replace switch.
enabling
interlock switch.
System Power
Supply shuts
down during
power up
Re-seat circuit boards.
4.11
sequence.
No Picture
Correct channel
selected.
Arc Lamp turned
off.
Select correct channel input.
Restart projector.
4.2
4.1
3.1
3.1
System power
turned off.
Restart projector.
Video source.
Verify video source is turned on,
properly connected.
"HIDE" command
invoked.
Table 5-1
Un-hide video using HIDE/MODE.
Color Cutoff.
Turn on R,G, B. Press R, G, B and
CUTOFF.
No video or raster
on only one
CRT.
Raster present but
no video image.
Replace defective CRT or Video
Amplifier Board.
4.8, 4.9
4.11
Replace Video Amplifier Board or
Video Processor Board.
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
LEDs 200, 300, or
400 on the
Replace Vertical Deflection Board.
4.11
vertical
deflection are
unlit.
LEDs 200 and 201, Replace Horizontal Deflection
4.11
4.10
or 300 and 301,
or 400 and 401
on the vertical
deflection are
unlit.
Board
if any two (2) are unlit.
Increasing G2
voltages
Faulty High Voltage Power Supply
under full load. Replace High
Voltage power Supply.
decreases
brightness level
for all CRTs.
Arc Lamp
Arc lamp will not
light-'clicking'
sound audible
when projector is
commanded ON.
Replace worn out Arc Lamp.
4.4
4.5
'Clicking' sound not System Power Supply or Ignitor
audible when
projector is
commanded ON.
Arc Lamp ignites
but will not stay
lit.
Assembly
faulty. Replace SPS or Ignitor
Assembly.
Replace defective Ignitor
Assembly.
4.4
4.4
Brightness flicker or Arc Lamp may have too many
Picture very
dim.
hours.
Replace Arc Lamp.
5-9
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
Image out of focus
Spacer balls not
Set projection lens focus so ILA®
spacer balls are visible.
Adjust CRT Mechanical Focus.
4.5
visible.
ILA® Spacer balls
visible but
3.7
4.7.2
image fuzzy.
CRT focus range is Adjust electronic focus.
limited and
3.8
4.7.3
image is fuzzy.
CRT focus not
effective.
CRT focus not
effective.
CRT focus limited
due to focus rod
range.
Image blurry with
shadow on right
edge.
Set Relay Lens against back stop.
Ensure ILA® assembly is installed
correctly and clamps are snug.
Readjust fixed rod at upper left of
CRT mounting bracket.
4.12
3.7
Replace ILA® Assembly.
4.12
Replace ILA® Assembly.
Characters do not
appear legible.
4.12
4.7
CRT focus problem Replace CRT.
limited to single
color.
G2 mis-adjusted.
Reset G2.
3.10
Sensitivity offset set Reset sensitivity offset.
too high.
Picture geometry
Picture not
centered.
Picture size
incorrect.
Picture wrap around
left or right
edge.
4.8
Adjust using PHASE and POSITION.
Adjust using SIZE and BLANKING.
Reset left or right BLANKING.
Retrace lines on
raster.
Reset TOP BLANKING.
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
Video has shadow
on left or right
edge.
Correct using MENU POSITION and
PINCUSHION POSITION.
Video image not
squared.
Correct using PINCUSHION
POSITION and KEYSTONE.
Correct using PINCUSHION left/right
arrow.
Video image bowed
at left/right edge
or top/bottom.
Picture horizontal
linearity.
Correct using LINEARITY and EDGE
LINEARITY.
XY Convergence
Linearity different
between colors,
cannot converge.
Horizontal size
different
Yoke not properly set on CRT.
3.2
Adjust horizontal sizing coil on
yoke.
3.5
between colors.
Vertical size
Set vertical size and linearity
adjustment on Vertical
Deflection Board.
Adjust Red or Blue POSITION to
compensate.
3.3, 3.4
different
between colors.
Not enough range in
Red/Blue XY
convergence.
4.8.9
Picture color
balance
Missing either Red, ILA® assembly bias voltage bad or
4.11
Green, or Blue
video.
no video-replace Video
Processor Board.
Red, Green, or Blue Replace ILA® assembly or Video
4.12, 4.8
lacks color.
Internal gray scale
correct but
Amplifier Board.
Readjust CONTRAST adjustments.
incorrect video
color.
Dim area on screen Adjust collimating lens.
4.4
when viewing
flat field.
Black video image
overdriven.
3.10
4.6, 4.10
Adjust THRESHOLD, G2 and
BRIGHTNESS.
5-11
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
Bright Red, Green
or Blue area on
screen limited to
corners or edge.
Gray scale green in
bright levels.
Adjust ILA® Assembly Bias
3.6
4.10
and SHADING.
4.10, 4.11
Subtract Green SENSITIVITY offset,
add Red and Blue.
Gray scale red in
bright levels.
Subtract Red SENSITIVITY offset,
add Green and Blue.
Gray scale blue in
bright levels.
Subtract Blue SENSITIVITY offset,
add Green and Red.
Picture—various
problems
Out of focus blurry Clean oily spot off CRT, Prism, or
area on image
limited to R, G,
or B.
Projection lens.
Small dark line or
dot in R, G, or B
image.
Scratch in optics or CRT burn.
Bubbles in R, G, or Replace affected ILA® assembly.
B image.
4.12
Image Ghost on
video.
Replace Burn-In CRT or ILA®
assembly.
4.7, 4.12
Reversed ghost
image on screen.
If projecting through glass, prevent
light
from reflecting back into the
lens
Picture lacks depth
of field.
4.12.1,
4.12.2
Adjust Contrast and Brightness.
Video jitter and
noise.
Video jitter present Replace Raster Timing Generator.
Replace Video Processor Board.
4.11
4.11
at only one
source.
Video image is not
level.
Level projector or rotate CRT
Yoke.
3.2
Black band at top of Remove air bubbles from Prism.
video.
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual
Manual
Data lost when
projector is
SCB socket batteries weak. “RAM
BATTERY LOW” may appear
on screen.
4.14
turned off and
back on.
“Flagwaving” at top VCR mode (if using CVID or SVID
5.3 Table 5-4
of picture or top
of image is
skewed.
input).
Select 2H Sync Enable or
Shift Sync Enable from the
Menu.
Convergence and/or Menu Position adjustment for the
shading is
incorrect after
doing copy
“Copied to” channel.
channel.
Red bands across
image after
Channel data not loading properly.
Upgrade software.
channel change.
Communication
error.
Unplug tethered remote at the
projector
and reconnect.
Check hardwired
cable for broken
wires and/or if
wired for RS-
232 null modem.
Bad RS-232
interface port on
the System
Bad RS-232 null modem cable.
Replace System Controller Board.
4.11
Controller.
Board.
LCD displays
erroneous
Unplug tethered remote at projector
and reconnect.
characters.
Infrared I/R
Remote
No response.
Set I/R remote dip switch settings.
5.8
5-13
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Problem and
Symptom to
Check
Possible Solution
Service Operator
Manual Manual
Intermittent
operation.
Replace I/R remote battery or move
closer to projector. If not
possible to move closer to
projector, use an I/R repeater for
distances of 50’ or more. Stay in
“line of sight”.
Sticking keys on the Return remote control for
remote control. replacement.
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Glossary
Glossary of Terms
Flat field test pattern used for shading purposes,
Adjust Flat Fld
(adjusts in 7º increments).
Without definite form; not crystallized.
Amorphous
Arc Lamp
The xenon arc lamp in the Series 300 series projectors.
Produces dangerously intensive light with hazardous levels of
ultraviolet and infrared radiation. It operates at high
temperatures (180ºC, maximum 300º C, or over 500º F).
The ratio of the picture width to picture height. The standard
U.S. television aspect ratio is four units wide to three units
high (1:1.33). High Definition Television (HDTV) is 16:9.
Aspect Ratio
Bandwidth
The transmission or reception capacity of a computer or
communications channel measured in bits per second in
digital and in Hertz in communications. Bandwidth is the
difference between the lowest and highest frequencies
transmitted or received. Wider bandwidth provides more
information or picture detail capability.
Image adjustment used to mask out unwanted anomalies on
the picture edges. Blanking can be adjusted inward from 0%
on the left edge and top, and from 100% on the right edge and
bottom.
Blanking
Overall or average intensity of illumination of a video display,
setting black at 0%. Used with Contrast adjustment for best
picture display.
Brightness
Test pattern used as reference for brightness and contrast
settings.
Contrast/Bright
Displays status of all active channels.
Channel List
Projector function used to copy geometric and image
adjustment data from one channel to any or all of the other 29
input channels
Copy Channel
Abbreviated as "C." Color information signal or signals.
Chrominance
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Glossary
Mirror that absorbs infrared light so that its reflection contains
only "cold' light that does not transmit appreciable heat. As a
result of this absorption of infrared heat radiation, "cold"
mirrors get quite hot.
Cold Mirror
Means of transmission sending the complete video signal
consisting of chrominance, luminance and the sync signals. It
is the NTSC standard.
Composite Video
Contrast
The ratio between the dark and light areas of a television
picture, setting white at 100%. Used with Brightness
adjustment for best picture display.
The process of controlling CRT beam deflection to keep the
R, G and B beams properly aligned when scanning the raster.
Misconvergence shows up as color fringing on picture edges.
Convergence adjustment compensates for the physical
separation of the R, G and B tubes by aligning their output at
a fixed distance from the projector. Convergence adjustments
include X,Y-Axis Convergence and Black and White
Uniformity.
Convergence
The vacuum tube used as a display screen in video terminals
or television sets. Commonly called the picture tube.
CRT
(Cathode Ray Tube)
Exports setup data from projector to computer. Useful when
servicing. See Import Channel Data and refer to Appendix 1
for more details.
Export Channel
One half of a complete video frame. Odd lines in one field
and even lines in another make up one frame.
Field
One complete TV picture or screen of information. It is
composed of two fields and has a total of 525 scanning lines
in NTSC transmission.
Frame
When R and B are ganged to Green, green is set first, then R
and B are set to match G. Thereafter, if R or B are visible on
screen, any adjustments to G will affect all three colors.
Ganged
A circuit card in a computer that has the function of
converting signals used in a computer into signals that a
monitor can use to display a video picture.
Graphics Adapter
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Glossary
Test pattern of black-to-white gradation bars. The more levels
of gray scale that can be handled, the more realistic an image
can be displayed, especially a photograph that has been
scanned into the computer.
Gray Scale
HDTV
(High Definition Television) Has approximately twice the
horizontal and vertical emitted resolution of standard NTSC.
HDTV systems are wide aspect ratio systems.
The standard unit of frequency. One Hz is equal to one cycle
per second. A Kilohertz (KHz) is 1,000 cycles per second and
a Megahertz (MHz) is equal to 1,000,000 cycles per second.
Hertz (Hz)
H-Grid
Test Pattern 8 with rows of white H's on screen, used as a
focusing aid.
The rate at which horizontal lines are made to
scan on a CRT. This is controlled by horizontal sync from the
signal source.
Horizontal Scan
Frequency (H-Freq)
Reverses the image projection for front or rear
projection. Located on the Horizontal Deflection Board.
Horizontal Scan
Reversal Jumper
Also referred to as tint. A specific color such a blue, pink or
aqua. Hue or tint control on a display device adjusts red/green
balance.
Hue
(Improved Definition Television) Improvements that modify
NTSC standards. Improvements may be at the source or the
receiver.
IDTV
A device that uses low-intensity images to phase-modulate a
high-intensity light through a liquid crystal layer. It is the key
component in producing very bright, high resolution images
from Hughes-JVC large-screen projectors.
Image Light Amplifier
ILA®
Imports setup data from computer to projector. Store setup
data in computer and import during setup. Useful when
servicing the projector. See Export Channel Data and refer to
Appendix 1 for more details.
Import Channel
Used with rear projection setups. Conveys infrared signals to
HJT Series 300 Projector, since I/R remote control signals
cannot reach I/R windows on the projector.
Infrared Repeater
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Glossary
Concentration of information or what would be seen if a black
and white version of the image is displayed.
Intensity
The technique that refreshes a display screen by alternately
displaying all the odd lines (field one) and then all the even
lines (field two) of one frame.
Interlacing
Used to control the Series 300 Projector during presentations.
Limited use compared to the technician remotes; cannot
permanently change any projector setup values.
I/R Executive Remote
Remote control used during Series 300 setup and adjustment.
Alternative to optional terminal and tethered technician
remote.
I/R Technician Remote
I/R Windows
The Series 300 Projector has two I/R windows, one in front,
one in back. These windows receive projector control signals
from the I/R remotes.
Standard of Quality. Hughes-JVC received ISO
certification May 15, 1997.
ISO 9001
Corrects lines nearest to the screen edge to make them straight
and parallel to the center line of the test pattern or square to
the screen edge. The keystone adjustment is performed on
green only and affects all RGB.
Keystone Adjustment
Distortion resulting from having the projector improperly
placed vertically with respect to the screen.
Keystone Image
Lamp Assembly
Line Crawl
Behind the optics assembly, the arc lamp and one "cold"
mirror are mounted in an extension chamber.
Tendency of the eyes to follow the sequentially flashing
scanned lines of interlaced scanning up or down the screen in
the same way that the eyes follow the sequentially flashing
light bulbs on a movie theatre marquee. Line crawl tends to
reduce vertical resolution.
Corrects for improper horizontal grid spacing on an image.
With distorted linearity, lines in the grid are spaced closer
together on one side of the image and farther apart on the
other. The linearity adjustment is performed on green only
and affects all RGB..
Linearity Adjustment
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Glossary
A unit of measure of the flow, or rate of emission, of light.
An ordinary wax candle generates 13 lumens while a 100
watt bulb generates 1,200 lumens.
Lumen
Abbreviated as "Y." The portion of the signal that contains
the black and white information, which affects brightness.
Luminance
Single color and refers to monitors that display only one color
along with back, such as white on black, black on white,
green on black and amber on black.
Monochrome
(Multi-Channel Television Sound) A stereo TV signal is
transmitted together with the regular TV signal. Allows
stereo audio for TV.
MTS
A display monitor that adjusts automatically to the
synchronization frequency of the video display board that's
sending signals to it. Multisync monitors can adjust to a
range of frequencies, but not all of them.
Multisync Monitor
An undesirable electrical interference of a signal.
Noise
(National Television Standards Committee) The NTSC
governs the standard for television and video playback and
recording in the United States. The NTSC standard is 525
lines of resolution and is transmitted at 60 half frames
(interlaced) per second.
NTSC
Contains the optics used to transmit light from the arc lamp to
the projection channels (blue, green and red).
Optics Module
Overscanning
Displaying less than the complete area of an image to a
viewer (i.e., scanning beyond the visible area). All TV sets
are overscanned at least slightly, so that viewers do not see
blanking.
(Phase Alternate Line) The 625-line, 50-field system used in
the UK, Western Europe, Scandinavia, Australia, South
Africa and other countries.
PAL
Test pattern used to set B/W scale. Grid of four squares
within four squares.
Pluge
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Glossary
Positions the input image (test pattern, video, graphics, etc.)
on the CRT raster. If the phase is misadjusted, the image may
"wrap around" the edges or be positioned off the screen.
Phase adjustment
Corrects for warped distortion at the sides or top and bottom
of the image. The pincushion adjustment is performed on
green only and affects all RGB.
Pincushion Adjustment
The area illuminated by the scan lines on a CRT.
Raster
The degree of sharpness of a displayed or printed character or
image; the amount of detail in a picture. On a display screen,
resolution is expressed as the number of horizontal dots
(columns) by the number of vertical lines (rows). For
example, a 680 x 400 resolution means 680 dots across each
of 400 lines.
Resolution
The blanked-out line traced by the scanning beam of a picture
tube as it travels from the end of any horizontal line to the
beginning of either the next horizontal line or field. The
beam is turned "off" during retrace.
Retrace
Refers to the method of recording and generating colors in a
video system. On a television or color monitor, colors are
displayed as varying intensities of red, green and blue dots.
When red, green and blue are all turned on high, white is
produced. When all dots are turned off, the base color of the
screen appears.
RGB (Red, Green, Blue)
Test pattern of aligned, alternating dots of RGB, used for
convergence adjustment.
RGB X-Hatch
S-VHS
A high band video recording process for VHS that increases
picture quality and resolution capability. S-VHS tape
machines use a special output terminal which allows separate
output of luminance (Y) and chrominance (C) picture
information to monitors equipped with S-Video inputs.
A video signal that has the luminance (Y) information
separated from chrominance (C) information.
S-Video
SAP
(Second Audio Program) The MTS system for television also
provides the ability to send an additional audio signal, called
Second Audio Program (SAP).
1) A color as far from white, black or gray as it can be
(i.e., vermilion rather than pink).
Saturated Color
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Glossary
2) A display misadjustment that results in unnaturally bright
colors.
To scan is to move across a picture frame a line at a time,
either to detect the image, as in an analog or digital camera,
or to refresh a CRT-based video screen.
Scan
One of many horizontal lines in a graphics frame.
Scan Line
Scan Rate
SECAM
The frequency of line scanning for a monitor or projector.
"Sequential couleur a memoire" (sequential color with
memory). The French color TV system also used within the
Soviet Union. It is not compatible with NTSC or PAL.
Apparent image resolution. High sharpness may be the result
of high resolution, or it might be an optical illusion caused by
image enhancement or by visible edges in a display, such as
the vertical stripes of an aperture grille CRT.
Sharpness
Test pattern, 100% white flat field.
Static Flat Fld
Also called "sync" for short. Working together. At the same
time, horizontal and vertical sync signals from the signal
source control the monitor's scan circuits to properly time the
lines and frames of a picture.
Synchronization
Identical to the I/R technician remote, with the
addition of a 20-character, 4 line display. Use the tethered
remote exactly as you would the I/R technician remote to
control the Series 300 during setup.
Technician Remote
(Tethered)
Distance to the screen from the projector.
Throw
Decrease raster size H and V so that all four edges of the
picture are visible on the display.
Underscan
Adjustment for increasing brightness on the dark
areas of the screen. Used with White Balance adjustment to
obtain optimal projected image.
Adjustment for decreasing brightness on the
bright areas of the screen. Used with Black Balance
adjustment to obtain optimal projected image.
Updates picture setting default data. Technician-defined
picture values as default values. User can change values
Uniformity (Black)
Uniformity (White)
Update Defaults
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Glossary
temporarily with the Executive I/R remote.
The amount of detail that can be perceived in the vertical
direction; the maximum number of alternating white and
black horizontal lines that can be counted from the top of the
picture to the bottom.
Vertical Resolution
The vertical scan frequency of the input signal.
Vertical Scan Frequency
(V-Freq)
The number of times per second a frame is
transmitted to a video display screen.
Vertical
Synchronization
Frequency
See Arc Lamp.
Xenon Arc Lamp
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Glossary
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