User's Guide
SLAU286–June 2009
TLV320AIC3007EVM-K
This user's guide describes the characteristics, operation, and use of the TLV320AIC3007EVM-K. This
evaluation module (EVM) allows the user to evaluate the TLV320AIC3007 audio codec. The
TLV320AIC3007 is a complete 2-channel audio codec with an integrated Class-D speaker amplifier. It also
has many inputs and outputs, extensive audio routing, mixing, and effects capabilities. A complete circuit
description, schematic diagram, and bill of materials are included. Note that the TLV320AIC3007 only
uses the I2C™ bus for register control. Any references to the SPI control bus in this document is due to
the presence of this interface on the USB-MODEVM motherboard.
EVM-Compatible Device Data Sheets
Device
Literature Number
SLOS545
TLV320AIC3007
TAS1020B
SLES025
REG1117-3.3
TPS767D318
SN74LVC125A
SN74LVC1G125
SN74LVC1G07
SBVS001
SLVS209
SCAS290
SCES223
SCES296
Contents
1
2
3
4
EVM Overview ............................................................................................................... 3
EVM Description and Basics ............................................................................................... 3
TLV320AIC3007EVM-K Setup and Installation.......................................................................... 7
TLV320AIC3007EVM Software ............................................................................................ 8
Appendix A EVM Connector Descriptions ................................................................................... 32
Appendix B TLV320AIC3007EVM Schematic ............................................................................... 35
Appendix C TLV320AIC3007EVM Layout Views ........................................................................... 37
Appendix D TLV320AIC3007EVM Bill of Materials ......................................................................... 40
Appendix E USB-MODEVM Schematic ...................................................................................... 42
Appendix F USB-MODEVM Bill of Materials ................................................................................ 43
Appendix G USB-MODEVM Protocol ......................................................................................... 45
List of Figures
1
2
3
4
5
6
TLV320AIC3007EVM-K Block Diagram .................................................................................. 4
Quick Start - USB-MODEM Configurations .............................................................................. 8
Quick Start - Preset Configurations Tab.................................................................................. 9
Main Software Screen .................................................................................................... 10
................................................................................................................................ 11
Audio Input/ADC Tab ..................................................................................................... 12
I2C, I2S are trademarks of Koninklijke Philips Electronics N.V..
Windows is a trademark of Microsoft Corporation.
LabView is a trademark of National Instruments.
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EVM Overview
1
EVM Overview
1.1 Features
•
Full-featured evaluation board for the TLV320AIC3007 2-channel audio codec with integrated Class-D
amplifier.
•
Modular design for use with a variety of digital signal processor (DSP) and microcontroller interface
boards.
•
•
•
USB connection to PC provides power, control, and streaming audio data for easy evaluation.
Onboard microphone for ADC evaluation
Connection points for external control and digital audio signals for quick connection to other
circuits/input devices.
The TLV320AIC3007EVM-K is a complete evaluation kit, which includes a universal serial bus
(USB)-based motherboard and evaluation software for use with a personal computer (PC) running the
Microsoft Windows™ operating system (Win2000 or XP).
1.2 Introduction
The TLV320AIC3007EVM is in the Texas Instruments modular EVM form factor, which allows direct
evaluation of the device performance and operating characteristics, and eases software development and
system prototyping. This EVM is compatible with the 5-6K Interface Evaluation Module (SLAU104) and the
HPA-MCUINTERFACE (SLAU106) from Texas Instruments and additional third-party boards which
supports the TI Modular EVM format.
The TLV320AIC3007EVM-K is a complete evaluation/demonstration kit, which includes a USB-based
motherboard called the USB-MODEVM Interface board and evaluation software for use with a PC running
the Microsoft Windows operating systems.
The USB connection from the PC provides power, control, and streaming audio data to the EVM for
reduced setup and configuration. The EVM also allows external control signals, audio data, and power for
advanced operation, which allows prototyping and connection to the rest of the evaluation/development
system.
2
EVM Description and Basics
This section provides information on the analog input and output, digital control, power, and general
connection of the TLV320AIC3007EVM.
2.1 TLV320AIC3007EVM-K Block Diagram
The TLV320AIC3007EVM-K consists of two separate circuit boards, the USB-MODEVM and the
TLV320AIC3007EVM. The USB-MODEVM is built around a TAS1020B streaming audio USB controller
with an 8051-based core.
The USB-MODEVM Interface board is intended to be used in USB mode, whereas control of the installed
EVM is accomplished using the onboard USB controller device. Provision is made, however, for driving all
the data buses (I2C, I2S, etc.) externally. The source of these signals is controlled by SW2 on the
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EVM Description and Basics
2.1.1
USB-MODEVM Interface Board
When connecting the TLV320AIC3007EVM to the USB-MODEVM, use care to avoid bending the
connecting pins. The two boards can only be connected in one way. It is suggested to first align with the
10-pin connectors (J3 on the TLV320AIC3007EVM and J18A on the USB-MODEVM) and then gently
push all the connectors together until the boards are seated.
In the factory configuration, the board is ready to use with the TLV320AIC3007EVM. To view all the
functions and configuration options available on the USB-MODEVM board, see the USB-MODEVM
Interface Board schematic in Appendix E.
TLV320AIC3007EVM
TLV320AIC3007
USB-MODEVM
EVM Position 1
Control Interface
2
I C
TAS1020B
USB 8051
USB
EVM Position 2
Microcontroller
2
I S
Audio Interface
Figure 1. TLV320AIC3007EVM-K Block Diagram
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EVM Description and Basics
2.2 Default Configuration and Connections
2.2.1
USB-MODEVM
SW-2 positions 1 through 7 must be set to ON (LO), whereas SW-2.8 must be set to OFF (HI).
Table 1. USB-MODEVM SW2 Settings
SW-2 Switch Number
Label
Switch Description
1
A0
USB-MODEVM EEPROM I2C Address A0
ON: A0 = 0
OFF: A0 = 1
2
3
4
5
6
7
8
A1
USB-MODEVM EEPROM I2C Address A1
ON: A1 = 0
OFF: A1 = 1
USB-MODEVM EEPROM I2C Address A2
ON: A2 = 0
OFF: A2 = 1
A2
USB I2S™
USB MCK
USB SPI
USB RST
EXT MCK
I2S Bus Source Selection
ON: I2S Bus connects to TAS1020
OFF: I2S Bus connects to USB-MODEVM J14
I2S Bus MCLK Source Selection
ON: MCLK connects to TAS1020
OFF: MCLK connects to USB-MODEVM J14
SPI Bus Source Selection
ON: SPI Bus connects to TAS1020
OFF: SPI Bus connects to USB-MODEVM J15
RST Source Selection
ON: EVM Reset Signal comes from TAS1020
OFF: EVM Reset Signal comes from USB-MODEVM J15
External MCLK Selection
ON: MCLK Signal is provided from USB-MODEVM J10
OFF: MCLK Signal comes from either selection of SW2-5
2.2.2
TLV320AIC3007EVM Jumpers and Switches
Table 2. List of Stand-alone Jumpers
Jumper Jumper
Number Type
Default
Position
Jumper Description
W1
2-pin
2-pin
2-pin
2-pin
2-pin
2-pin
2-pin
3-pin
2-pin
2-pin
2-pin
2-pin
3-pin
2-pin
2-pin
soldered
soldered
soldered
soldered
soldered
soldered
soldered
2-3
AVDD_ADC power
W2
DRVDD power (DRVDD1 on EVM).
DRVDD power (DRVDD2 on EVM).
AVDD_DAC power.
W3
W3
W5
SPVDD power.
W7
DVDD power.
W8
IOVDD power.
W9
Mic bias select. Connect 1-2 to use AIC3007 Mic Bias. Connect 2-3 to use EVM 3.3V Mic Bias.
Connect EVM Onboard Mic to AIC3007 MIC3R input.
Connect EVM Onboard Mic to AIC3007 MIC3L input.
Enable 16-ohm load for HPL output test.
Enable 16-ohm load for HPR output test.
IOVDD select. Connect 1-2 for IOVDD=+1.8V. Connect 2-3 for IOVDD=+3.3V.
GPIO1 access point.
W10
W11
W12
W13
W14
W15
W16
Open
Open
Open
Open
1-2
Open
Installed
Software reset enable.
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EVM Description and Basics
Table 2. List of Stand-alone Jumpers (continued)
Jumper Jumper
Number Type
Default
Position
Jumper Description
W17
2-pin
Open
Selects onboard EEPROM as TAS1020B Firmware Source.(Not Used). Note that for this EVM the Firmware Source
EEPROM is on the USB-MODEVM.
W18
W19
2-pin
2-pin
Open
Open
Selects SWOUTP to J-18. Caution: Make sure that the Class-D Output is Disabled before Installing W18.
Selects SWOUTM to J-18. Caution: Make sure that the Class-D Output is Disabled before Installing W19.
Table 3. Switch SW1 Configurations
EVM
Connector
Connector Terminal Number
(Terminal 2 is always Ground.)
SW1 Switch Position = DIFF (Differential Inputs)
SW1 Switch Position = SE = Single-Ended
Inputs
J6
J7
J8
Terminal 1
Terminal 3
Terminal 1
Terminal 3
Terminal 1
Terminal 3
Input to AIC3007-pin 4 = LINE1LP
Input to AIC3007-pin 4 = LINE1LP
Input to AIC3007-pin 3 = MICDET/LINE1LM
Input to AIC3007-pin 5 = LINE1RP
Input to AIC3007-pin 5 = LINE1RP
Input to AIC3007-pin 9 = MIC3R/LINE2RM
Input to AIC3007-pin 6 = MIC3L/LINE1RM
Input to AIC3007-pin 7 = LINE2LP
Input to AIC3007-pin 6 = MIC3L/LINE1RM
Input to AIC3007-pin 7 = LINE2LP
Input to AIC3007-pin 8 = LINE2RP/LINE2LM
Input to AIC3007-pin 8 = LINE2RP/LINE2LM
Table 4. Switch SW2 Configurations
SW2 Switch Position = CAP
SW2 Switch Position = Capacitor-less
47-µF capacitors in-line with HPLOUT and HPROUT to J10 (Referenced to
Ground)
HPLOUT and HPROUT Direct Coupled to J10 (Referenced to HPCOM)
Table 5. Switch SW3 Configurations
SW3 Switch Position = EXT.
SW3 Switch Position = +5VA
User Provides an External Power Supply for SVDD (Class-D Power Amplifier EVM 5-VDC Supply used for SVDD (Class-D Power Amplifier Supply)
Supply), Max Value = 5 VDC
2.3 Power Connections
The TLV320AIC3007 can be powered independently when being used in stand-alone operation or by the
USB-MODEVM when it is plugged onto the motherboard.
2.3.1
Stand-Alone Operation
When used as a stand-alone, power is applied to J15 directly; be sure to reference the supplies to the
appropriate grounds on that connector.
CAUTION
Before applying power to the EVM, you must verify that all power supplies are
J15 provides connection to the common power bus for the TLV320AIC3007EVM. Power is supplied on the
The TLV320AIC3007EVM-K motherboard (the USB-MODEVM Interface board) supplies power to J15 of
the TLV320AIC3007EVM. Power for the motherboard is supplied either through its USB connection or via
terminal blocks on that board.
2.3.2
USB-MODEVM Operation
The USB-MODEVM Interface board can be powered from several different sources:
•
•
USB
6-Vdc to 10-Vdc ac/dc external wall supply (not included)
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TLV320AIC3007EVM-K Setup and Installation
•
Laboratory power supply
When powered from the USB connection, JMP6 must have a shunt from pins 1–2 (this is the default
factory configuration). When powered from 6 Vdc-10 Vdc, either through the J8 terminal block or J9 barrel
jack, JMP6 must have a shunt installed on pins 2–3. If power is applied in any of these ways, onboard
regulators generate the required supply voltages, and no further power supplies are necessary.
If laboratory supplies are used to provide the individual voltages required by the USB-MODEVM Interface,
JMP6 must have no shunt installed. Voltages are then applied to J2 (+5VA), J3 (+5VD), J4 (+1.8VD), and
J5 (+3.3VD). The +1.8VD and +3.3VD can also be generated on the board by the onboard regulators from
the +5VD supply; to enable this configuration, the switches on SW1 need to be set to enable the
regulators by placing them in the ON position (lower position, looking at the board with text reading
right-side up). If +1.8VD and +3.3VD are supplied externally, disable the onboard regulators by placing
SW1 switches in the OFF position.
Each power supply voltage has an LED (D1-D7) that lights when the power supplies are active.
3
TLV320AIC3007EVM-K Setup and Installation
The following section provides information on using the TLV320AIC3007EVM-K, including set up, program
installation, and program usage.
Note: If using the EVM in stand-alone mode, the software must be installed per the following
instructions, but the hardware configuration may be different.
3.1 Software Installation
1. Locate the installation file on the CD-ROM included with the EVM or download the latest version of the
2. Unzip the installation file by clicking on the self-extracting zip file.
3. Install the EVM software by double-clicking the Setup executable and follow the directions. Users may
be prompted to restart their computers.
This installs all the TLV320AIC3007 software and required drivers onto the PC.
3.2 EVM Connections
1. Ensure that the TLV320AIC3007EVM is installed on the USB-MODEVM Interface board, aligning J1,
J2, J3, J4, and J5 with the corresponding connectors on the USB-MODEVM.
2. Verify that the jumpers and switches are in their default conditions.
3. Attach a USB cable from the PC to the USB-MODEVM Interface board. The default configuration
provides power, control signals, and streaming audio via the USB interface from the PC. On the
USB-MODEVM, LEDs D3-6 light to indicate the power is being supplied from the USB.
4. For the first connection, the PC recognizes new hardware and begins an initialization process. The
user may be prompted to identify the location of the drivers or allow the PC to automatically search for
them. Allow the automatic detection option.
5. Once the PC confirms that the hardware is operational, D2 on the USB-MODEVM lights to indicate that
the firmware has been loaded and the EVM is ready for use. If the LED is not lighted, verify that the
drivers were installed, try to unplug, and restart at Step 3.
After the TLV320AIC3007EVM-K software installation (described in Section 3.2) is complete, evaluation
and development using the target TLV320AIC3007 can begin.
The TLV320AIC3007EVM software now can be launched. The user sees an initial screen that looks
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4
TLV320AIC3007EVM Software
The following section discusses the details and operation of the EVM software.
Note: For configuration of the codec, the TLV320AIC3007 block diagram located in the
TLV320AIC3007 data sheet is a good reference to help determine the signal routing. A
pop-up detailed block diagram also is provided in the TLV320AIC3007 GUI software.
4.1 Quick Start Tabs
helps the user to begin using the GUI.
4.1.1
Quick Start - USB-MODEM Configurations
Figure 2. Quick Start - USB-MODEM Configurations
The default tab is the Quick Start - USB-MODEVM tab. This tab shows two common USB-MODEVM
configurations used with the AIC3007EVM. The default configuration is the USB-MODEVM Audio Interface
Configuration. In this configuration, the USB-MODEVM acts as a USB sound card. Audio files can be
played on the PC and targeted to the USB-MODEVM via the USB connection. On the USB-MODEVM, the
TAS1020B converts the USB audio to I2S data and the I2C script data to I2C commands.
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4.1.2
Quick Start - Preset Configurations
Figure 3. Quick Start - Preset Configurations Tab
The Quick Start Preset Configurations tab provides several different preset configurations of the codec
(Figure 3). The Preset Configurations buttons allow the user to choose from the provided defaults. When
the selection is made, the Preset Configuration Description shows a summary of the codec setup
associated with the choice made. If the choice is acceptable, the Load button can be pressed, and the
preset configuration is loaded into the codec. The user can change to the Command Line Interface tab
(see Figure 29) to view the actual settings that were programmed into the codec. Note that the controls of
the GUI are updated per any downloaded script whether it be a Preset Configuration script or a User
Script run form the Command Line Interface tab.
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4.2 Main Software Screen With Indicators and Functions
Figure 4. Main Software Screen
Figure 4 illustrates the main screen of the EVM software. The indicators and buttons located above the
tabbed section of the front page are visible regardless of which tab is currently being selected.
The firmware box indicates from where the firmware being used is operating. In this release, the firmware
is on the USB-MODEVM, so the user sees USB-MODEVM in the box labeled Located on:. The version of
the firmware appears in the Version box below this.
To the right, the next group box contains controls for resetting the TLV320AIC3007EVM. A software reset
can be done by writing to a register in the TLV320AIC3007EVM; this is accomplished by clicking the
button labeled Reset.
Near the Firmware box, the Device Connected LED is green when the EVM is connected. If the indicator
is red, the EVM is not properly connected to the PC. Disconnect the EVM, and verify that the drivers were
correctly installed. Then reconnect, and try restarting the software.
On the upper right portion of the screen are located several indicators which provide the status of various
portions of the TLV320AIC3007. Pressing the Indicator Updates button activates these indicators. These
indicators, as well as the other indicators on this panel, are updated only when the software's front panel
is inactive, once every 20 ms.
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The ADC Overflow and DAC Overflow indicators illuminate when the overflow flags are set in the
TLV320AIC3007. Below these indicators are the AGC Noise Threshold Exceeded indicators that
illuminate when the AGC noise threshold is exceeded. To the far right of the screen, the Short Circuit
Detect indicators illuminate when a short-circuit condition is detected, if this feature has been enabled.
Below the short-circuit indicators, the AGC Gain Applied indicators use a bar graph to show the amount
of gain which has been applied by the AGC and indicators that illuminate when the AGC is saturated.
4.2.1
Detailed TLV320AIC3007 Block Diagram
Figure 5.
To view the detailed block diagram, click on the "Show" button at the top left of the Main Software Screen
(Figure 4). This block diagram shows the details of the processing blocks of the TLV320AIC3007 including
the I2C registers associated with each block.
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4.3 Audio Input/ADC Tab
Figure 6. Audio Input/ADC Tab
The Audio Input/ADC tab allows control of the analog input mixer and the ADC. The controls are
displayed to look similar to an audio mixing console (see Figure 6). Each analog input channel has a
vertical strip that corresponds to that channel. By default, all inputs are muted when the TLV320AIC3007
is powered up.
To route an analog input to the ADC:
1. Select the Input Mode button to correctly show if the input signal is single-ended (SE) or
fully-differential (Diff). Inputs that are single-ended must be made to the positive signal terminal.
2. Click on the button of the analog input channel that corresponds to the correct ADC. The caption of the
button changes to Active. Note that the user can connect some channels to both ADCs, whereas
others only connect to one ADC.
3. Adjust the Level control to the desired attenuation for the connected channel. This level adjustment
can be done independently for each connection.
The TLV320AIC3007 offers a programmable microphone bias that can either be powered down, set to 2
V, 2.5 V, or the power supply voltage of the ADC (AVDD_ADC). Control of the microphone bias (mic bias)
voltage is accomplished by using the Mic Bias pulldown menu button above the last two channel strips.
To use the onboard microphone, hardware jumpers W10 and W11 must be installed. Nothing must be
plugged into J9, in order for the mic bias settings in the software to take effect. Also, jumper W9 (Mic Bias
Sel) must be set to connect positions 2 and 3, so that MICBIAS is controlled by the TLV320AIC3007.
Also shown are controls for Weak Common Mode Bias. Enabling these controls results in unselected
inputs to the ADC channels to be weakly biased to the ADC common mode voltage.
Nearby are the controls for the ADC PGA, including the master volume controls for the ADC inputs. Each
channel of the ADC can be powered up or down as needed using the Power Up buttons. PGA
soft-stepping for each channel is selected using the pulldown menu control. The two large knobs set the
actual ADC PGA Gain and allow adjustment of the PGA gains from 0 dB to 59.5 dB in 0.5-dB steps
(excluding Mute). At the extreme counterclockwise rotation, the channel is muted. Rotating the knob
clockwise increases the PGA gain, which is displayed in the box directly above the volume control.
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4.4 Bypass Paths Tab
Figure 7. Bypass Paths Tab
LINE2RP, LINE1LP, and LINE2LP inputs can be passively bypassed to either RIGHT_LOP or LEFT_LOP
by using the Passive Analog Bypass Paths controls. LINE2L (left) and LINE2R (right) buffered inputs
can directed to the output mixer sections by using the Active Bypass Paths to Output Amplifiers
controls.
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4.5 Audio Interface Tab
Figure 8. Audio Interface Tab
TLV320AIC3007.
The interface mode can be selected using the Audio Serial Data Mode control—selecting either I2S
mode, DSP mode, or Right- or Left-Justified modes. Word length can be selected using the Audio Serial
Word Length control, and the bit clock rate can also be selected using the Bit Clock Mode rate control.
this tab.
Along the bottom of this tab are controls for choosing the BLCK and WCLK as being either inputs or
outputs. With the codec configured in Slave mode, both the BCLK and WCLK are set to inputs. If the
codec is in Master mode, then BCLK and WCLK are configured as outputs. Additionally, two buttons
provide the options for 3-stating the DOUT line when no valid data is available and for transmitting BLCK
and WCLK when the codec is powered down.
Re-synchronization of the audio bus is enabled using the controls in the lower right corner of this screen.
Re-synchronization is done if the group delay changes by more than ±FS/4 for the ADC or DAC sample
rates (see the TLV320AIC3007 data sheet). The channels can be soft-muted when doing the
Re-synchronization if the Soft Mute button is enabled.
The default mode for the EVM is configured as 44.1-kHz, 16-bit, I2C words, and the codec is a slave
(BCLK and WCLK are supplied to the codec externally). For use with the PC software and the
USB-MODEVM, the default settings must be used; no changes to the software are required.
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4.6 Clocks Tab
Figure 9. Clocks Tab
The TLV320AIC3007 provides a phase-locked loop (PLL) that allows flexibility in the clock generation for
the ADC and DAC sample rates. The Clocks tab contains the controls that can be used to configure the
TLV320AIC3007 for operation with a wide range of master clocks. See the Audio Clock Generation
Processing figure in the TLV320AIC3007 data sheet for further details of selecting the correct clock
settings.
For use with the PC software and the USB-MODEVM, the clock settings must be set a certain way. If the
settings are changed from the default settings which allow operation from the USB-MODEVM clock
reference, the EVM settings can be restored automatically by clicking the Load EVM USB Settings
button. Note that changing any of the clock settings from the values loaded when this button is pushed
can result in the EVM not working properly with the PC software or USB interface. If an external audio bus
is used (audio not driven over the USB bus), then settings can be changed to any valid combination. See
4.6.1
Configuring the Codec Clocks and Fsref Calculation
The codec clock source is chosen by the CODEC_CLK Source control. When this control is set to
CLKDIV_OUT, the PLL is not used; when set to PLLDIV_OUT, the PLL is used to generate the clocks.
Note: Per the TLV320AIC3007 data sheet, the codec must be configured to allow the value of
Fsref to fall between the values of 39 kHz to 53 kHz.
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4.6.1.1
Use Without PLL
Setting up the TLV320AIC3007 for clocking without using the PLL permits the lowest power consumption
by the codec. The CLKDIV_IN source can be selected as either MCLK (default) or BCLK. The CLKDIV_IN
frequency then is entered into the CLKDIV_IN box, in megahertz (MHz). The default value shown,
11.2896 MHz, is the frequency used on the USB-MODEVM board. This value then is divided by the value
of Q, which can be set from 2 to 17; the resulting CLKDIV_OUT frequency is shown in the indicator next
to the Q control. The result frequency is shown as the Actual Fsref.
4.6.1.2
Use With PLL
When PLLDIV_OUT is selected as the codec clock source, the PLL is used. The PLL clock source is
chosen using the PLLCLK_IN control, and can be set to either MCLK or BCLK. The PLLCLK_IN
frequency then is entered into the PLLCLK_IN Source box.
The PLL_OUT and PLLDIV_OUT indicators show the resulting PLL output frequencies with the values set
for the P, K, and R parameters of the PLL. See the TLV320AIC3007 data sheet for an explanation of
these parameters. The parameters can be set by clicking on the up/down arrows of the P, K, and R
combination boxes, or they can be typed into these boxes.
Use the Search for PLL Settings Based on Desired Fsref and PLLCLK_IN section to find the ideal
values of P, K, and R for a given PLL input frequency and desired Fsref:
1. Set the desired Fsref using the Fsref switch.
2. Verify that the correct reference frequency is entered into the PLLCLK_IN Source box in megahertz
(MHz)
3. Push the Search for Ideal PLL Settings button. The software starts searching for ideal combinations
of P, K, and R, which achieve the desired Fsref. The possible settings for these parameters are
displayed in the spreadsheet-like table labeled Possible Settings.
4. Click on a row in this table to select the P, K, and R values located in that row. Notice that when this is
done, the software updates the P, K, R, PLL_OUT and PLLDIV_OUT readings, as well as the Actual
Fsref and Error displays. The values show the calculations based on the values that were selected.
This process does not actually load the values into the TLV320AIC3007, however; it only updates the
displays in the software. If more than one row exists, the user can choose the other rows to see which
of the possible settings comes closest to the ideal settings.
When a suitable combination of P, K, and R has been chosen, pressing the Load Settings into Device?
button downloads these values into the appropriate registers on the TLV320AIC3007.
4.6.1.3
Setting ADC and DAC Sampling Rates
NDAC factors, the sampling rates are derived from the Fsref. If the dual-rate mode is desired, this option
can be enabled for either the ADC or DAC by pressing the corresponding Dual Rate Mode button. The
ADC and DAC sampling rates are shown in the box to the right of each control.
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4.7 GPIO1 Tab
Figure 10. GPIO1 Tab
The GPIO1 tab (see Figure 10) selects options for the general-purpose inputs and outputs (GPIO) of the
TLV320AIC3007.
The GPIO1 groupbox contains controls for setting options for the GPIO1 pin. The Function control selects
the function of GPIO1 from the following:
•
•
•
ADC Word Clock
An output clock derived from the reference clock (see TLV320AIC3007 data sheet)
Interrupt output pin to signal:
–
–
–
Short Circuit
AGC Noise Threshold detection
Jack/Headset detection
•
For use as an interrupt output, the behavior of the interrupt can be selected using the Interrupt
Duration control. A Single, 2ms pulse can be delivered when the selected interrupt occurs, or
Continuous Pulses can be generated signaling the interrupt.
•
•
Alternate I2S Word Clock
A general-purpose I/O pin
–
If selected as a General Purpose Input, the state of the GPIO1 pin is reflected by the Input Level
indicator. If selected as a General Purpose Output, the state of the GPIO1 pin can be set by using
the Output Level button.
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4.8 AGC Tab
Figure 11. AGC Tab
The AGC tab (see Figure 11) consists of two identical sets of controls, one for the left channel and the
other for the right channel. The AGC function is described in the TLV320AIC3007 data sheet.
The AGC can be enabled for each channel using the Enable AGC button. Target gain, Attack time in
milliseconds, Decay time in milliseconds, and the Maximum PGA Gain Allowed can all be set,
respectively, using the four corresponding knobs in each channel.
The TLV320AIC3007 allows for the Attack and Decay times of the AGC to be setup in two different
modes, standard and advanced. The Left/Right AGC Settings button determines the mode selection.
The Standard mode provides several preset times that can be selected by adjustments made to the
Attackand Decay knobs. If finer control over the times is required, then the Advanced mode is selected to
change to the settings. When the Advanced mode is enabled, two tabs appear that allow separate,
advanced control of the Attack and Delay times of the AGC (see Figure 12 and Figure 13). These options
allow selection of the base time as well as a multiplier to achieve the actual times shown in the
corresponding text box. The Use advanced settings? button must be enabled to program the registers
with the correct values selected via the pulldown options for base time and multiplier.
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Figure 12. Left AGC Settings
Figure 13. Advanced
Noise gate functions, such as Hysteresis, Enable Clip stepping, Threshold (dB), Signal Detect
Debounce (ms), and Noise Detect Debounce (ms) are set using the corresponding controls in the
Noise Gate groupbox for each channel.
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4.9 Filters Tab
Figure 14. Filters Tab
The TLV320AIC3007 has an advanced feature set for applying digital filtering to audio signals. This tab
controls all of the filter features of the TLV320AIC3007. In order to use this tab and have plotting of filter
responses correct, the DAC sample rate must be set correctly. Therefore, the clocks must be set up
The AIC3007 digital filtering is available to both the ADC and DAC. The ADC has optional high-pass (HP)
filtering and allows the digital output from the ADC through digital effects filtering before exiting the codec
through the PCM interface. Likewise, the digital audio data can be routed through the digital effects
filtering before passing through the optional de-emphasis filter before the DAC. The digital effects filtering
can only be connected to either the ADC or DAC, not both at the same time.
The Figure 14 is divided into several areas. The left side of the tab, is used to select between the DAC or
ADC filters and to assist in the selection and calculating of the desired filter coefficients. The right side of
the tab shows a frequency response plot of the digital effects filter selected and the coefficients that are
programmed into the device. The plots show the magnitude and phase response of each biquad section,
plus the combined responses of the two biquad filters. Note that the plot shows only the responses of the
effect filters, not the combined response of those filter along with the de-emphasis and ADC high-pass
filters.
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4.9.1
ADC Filters
High-Pass Filter
4.9.1.1
Figure 15. ADC High-Pass Filters
The TLV320AIC3007 ADC provides the option of enabling a high-pass filter, which helps to reduce the
effects of DC offsets in the system. The Figure 15 tab shows the options for programming various filter
associated with the ADC. The high-pass filter has two modes: standard and programmable.
The standard high-pass filter option (Figure 16) allows for the selection of the high-pass filter frequency
from several preset options that can be chosen with the Left ADC HP Filter and Right ADC HP Filter
controls. The four options for this setting are disabled or three different corner frequencies which are
based on the ADC sample rate.
Figure 16. ADC High-Pass Filter Settings
For custom filter requirements, the programmable function allows custom coefficients to achieve a
different filter than provided by the preset filters. The controls for the programmable high-pass filter are
located under the Programmable Filters heading. The following steps describe the process:
1. Enter the filter coefficients in the HP Filter controls near the bottom of the tab.
2. Press the Download Coefficients button to download the coefficients to the codec registers.
3. Enable the Programmable High-Pass Filters by selecting the Left ADC and Right ADC buttons.
The programmable high-pass filter is now correctly programmed and enabled. The ADC can be enabled
with the high-pass filter.
4.9.1.2
Digital Effects Filter - ADC
The ADC digital outputs stream can be routed through the digital effects filter in the codec to allow custom
audio performance. The digital effects filter cannot operate on both the ADC or DAC at the same time.
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4.9.2
DAC Filters
Figure 17. DAC Filters
4.9.2.1
De-emphasis Filters
The de-emphasis filters used in the TLV320AIC3007 can be programmed as described in the
TLV320AIC3007 data sheet, using this tab (Figure 18). Enter the coefficients for the de-emphasis filter
response desired. While on this tab, the de-emphasis response is shown on the Effect Filter Response
graph; however, note that this response is not included in graphs of other effect responses when on other
filter design tabs.
Figure 18. De-emphasis Filters
4.9.2.2
DAC Digital Effects Filter
The digital audio input stream can be routed through the digital effects filter in the codec before routing to
the DAC to allow custom audio performance. The digital effects filter cannot operate on both the ADC or
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4.9.3
Digital Effects Filters
The digital effect filters (the biquad filters) of the TLV320AIC3007 are selected using the check boxes
shown in Figure 19. The de-emphasis filters are described in the TLV320AIC3007 data sheet, and their
Figure 19. Enabling Filters
When designing filters for use with TLV320AIC3007, the software allows for several different filter types to
be used. These options are shown on a tab control in the lower left corner of the screen. When a filter
type is selected, and suitable input parameters defined, the response are shown in the Effect Filter
Response graph. Regardless of the setting for enabling the Effect Filter, the filter coefficients are not
loaded into the TLV320AIC3007 until the Download Coefficients button is pressed. To avoid noise during
the update of coefficients, it is recommended that the user uncheck the Effect Filter enable check boxes
before downloading coefficients. Once the desired coefficients are in the TLV320AIC3007, enable the
Effect Filters by checking the boxes again.
4.9.3.1
Shelf Filters
A shelf filter is a simple filter that applies a gain (positive or negative) to frequencies above or below a
certain corner frequency. As shown in Figure 20, in Bass mode, a shelf filter applies a gain to frequencies
below the corner frequency; in Treble mode, the gain is applied to frequencies above the corner
frequency.
Figure 20. Shelf Filters
To use these filters, enter the gain desired and the corner frequency. Choose the mode to use (Bass or
Treble); the response is plotted on the Effect Filter Response graph.
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4.9.3.2
EQ Filters
EQ, or parametric, filters can be designed on this tab (see Figure 21). Enter a gain, bandwidth, and a
center frequency (Fc). Either bandpass (positive gain) or band-reject (negative gain) filters can be created
Figure 21. EQ Filters
4.9.3.3
Analog Simulation Filters
Biquads are good at simulating analog filter designs. For each biquad section on this tab, enter the
desired analog filter type to simulate (Butterworth, Chebyshev, Inverse Chebyshev, Elliptic, or Bessel).
Parameter entry boxes appropriate to the filter type are shown (ripple, for example, with Chebyshev filters,
Figure 22. Analog Simulation Filters
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4.9.3.4
Preset Filters
Many applications are designed to provide preset filters common for certain types of program material.
This tab (see Figure 23) allows selection of one of four preset filter responses - Rock, Jazz, Classical, or
Pop.
Figure 23. Preset Filters
4.9.3.5
User Filters
If filter coefficients are known, they can be entered directly on this tab (see Figure 24) for both biquads for
both left and right channels. The filter response is not shown on the Effect Filter Response graph for user
filters.
Figure 24. User Filters
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4.9.3.6
3D Effect
The 3D effect is described in the TLV320AIC3007 data sheet. It uses the two biquad sections differently
than most other effect filter settings. To use this effect properly, ensure that the appropriate coefficients
are already loaded into the two biquad sections. The User Filters tab can be used to load the coefficients.
Figure 25. 3D Effect Settings
To enable the 3D effect, check the 3D Effect On box. The Depth knob controls the value of the 3D
Attenuation Coefficient.
4.10 DAC/Line Outputs Tab
Figure 26. DAC/Line Outputs Tab
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The DAC/Line Outputs tab controls the DAC power and volume, as well as routing of digital data to the
4.10.1 DAC Controls
On the left side of this tab are controls for the left and right DACs.
In similar fashion as the ADC, the DAC controls are set up to allow powering of each DAC individually and
setting the output level. Each channel's level can be set independently using the corresponding Volume
knob. Alternately, by checking the Slave to Right box, the left-channel Volume can be made to track the
right-channel Volume knob setting; checking the Slave to Left box causes the right-channel Volume knob
to track the left-channel Volume knob setting.
Data going to the DACs is selected using the drop-down boxes under the Left and Right DAC Datapath.
Each DAC channel can be selected to be off, use left-channel data, use right-channel data, or use a mono
mix of the left and right data.
Analog audio coming from the DACs is routed to outputs using the Output Path controls in each DAC
control panel. The DAC output can be mixed with the analog inputs (LINE2L, LINE2R, PGA_L, PGA_R)
and routed to the Line or High Power outputs using the mixer controls for these outputs on this tab (for the
line outputs) or on the High Power Outputs tab (for the high power outputs). If the DAC is to be routed
directly to either the Line or HP outputs, these can be selected as choices in the Output Path control.
Note that if the Line or HP outputs are selected as the Output Path, the mixer controls on this tab and the
High Power Output tabs have no effect.
4.10.2 Line Output Mixers
On the right side of this tab are horizontal panels where the analog output mixing functions for the line
outputs are located.
Each line output master volume is controlled by the knob at the far right of these panels, below the line
output labels. The output amplifier gain can be muted or set at a value between 0 and 9 dB in 1-dB steps.
Power/Enabled status for the line output can also be controlled using the button below this master output
knob (Powered Up).
If the DAC Output Path control is set to Mix with Analog Inputs, the six knobs in each panel can be used
to set the individual level of signals routed and mixed to the line output. LINE2L, LINE2R, PGA_L, PGA_R,
and DAC_L and DAC_R levels can each be set to create a custom mix of signals presented to that
particular line output. Note: if the DAC Output Path control is set to anything other than Mix with Analog
Inputs, these controls have no effect.
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4.11 HP Output Stage Configuration Tab
Figure 27. Output Stage Configuration Tab
drivers.
The Headset Configuration control can be set as either Fully-Differential or Pseudo-Differential. This
control is used to determine if the output stage is being used to drive a fully differential output load or a
output load where one of the outputs is referenced to a common-mode voltage (pseudo-differential).
The output Coupling control can be chosen as either Capless, that is capacitor less, (EVM
SW2-CAPLESS) or AC-coupled (EVM SW2-CAP). This setting corresponds to the setting of the hardware
switch (SW2) on the TLV320AIC3007EVM.
The common-mode voltage of the outputs can be set to 1.35V, 1.5V, 1.65V, or 1.8V using the Common
Mode Voltage control.
The TLV320AIC3007 offers several options to help reduce the turn-on/off pop of the output amplifiers. The
Power-On Delay of the output drivers can be set using the corresponding control from 0 µs up to 4 µs.
Ramp-Up Step Timing also can be adjusted from 0 ms to 4 ms. The outputs can be set to soft-step their
volume changes, using the Output Volume Soft Stepping control, and set to step once per Fs period,
once per two Fs periods, or soft-stepping can be disabled altogether.
The high power outputs of the TLV320AIC3007 can be configured to go to a weak common-mode voltage
when powered down. The source of this weak common-mode voltage can be set on this tab with the
Weak Output CM Voltage Source drop-down menu. Choices for the source are either a resistor divider
off the AVDD_DAC supply, or a bandgap reference. See the data sheet for more details on this option.
Headset detection features are enabled using the Enable button in the HP Headset Detection groupbox.
When enabled, the indicators in the HS/Button Detect groupbox illuminate when either a button press or
headset is detected. When a headset is detected, the type of headset is displayed in the Detection Type
indicator. Debounce times for detection are set using the Jack Detect Debounce and Button Press
Debounce controls, which offer debounce times in varying numbers of milliseconds. See the
TLV320AIC3007 data sheet for a discussion of headset detection.
Output short-circuit protection can be enabled in the HP Short Circuit Protection groupbox. Short Circuit
Protection can use a current-limit mode, where the drivers limit current output if a short-circuit condition is
detected, or in a mode where the drivers power down when such a condition exists.
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4.12 HP Outputs Tab
Figure 28. High Power Outputs Tab
This tab contains four horizontal groupings of controls, one for each of the high power outputs. Each
output has a mixer to mix the LINE2L, LINE2R, PGA_L, PGA_R, DAC_L and DAC_R signals, assuming
At the left of each output strip is a Powered Up button that controls whether the corresponding output is
powered up or not. The When powered down button allows 3-state outputs or driven weakly to a the
output common-mode voltage.
The HPxCOM outputs (HPLCOM and HPRCOM) can be used as independent output channels or can be
used as complementary signals to the HPLOUT and HPROUT outputs. In these complementary
configurations, the HPxCOM outputs can be selected as Differential of HPxOUT signals to the
corresponding outputs or can be set to be a common-mode voltage (Constant VCM Out. When used in
these configurations, the Powered Up button for the HPxCOM output is disabled, as the power mode for
that output tracks the power status of the HPL or HPR output that the COM output is tracking.
The HPRCOM Config selector allows a couple additional options compared to the HPLCOM Config
selector. Differential of HPLCOM allows the HPRCOM to be the complementary signal of HPLCOM for
driving a differential load between the HPxCOM outputs. The selector also allows Ext.
Feedback/HPLCOM constant VCM as an option. This option is used when the high power outputs are
configured for Capless output drive, where HPLCOM is configured as Constant VCM Out. The feedback
option provides feedback to the output and lowers the output impedance of HPLCOM.
At the right side of the output strip is a master volume knob for that output, which allows the output
amplifier gain to be muted or set from 0 to 9 dB in 1-dB steps.
4.13 Class-D Output Tab
The integrated Class-D speaker amplifier can drive one watt into an 8-Ω load. The input to the Class-D
amplifier is the same signal available at the left lineout LEFT_LOP pin. The Class-D amplifier must be
enabled first and then the gain control (0 dB to +18 dB) can be used. Note that many other gains are
available in the signal path leading up to the Class-D amplifier.
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4.14 Command Line Interface Tab
A simple scripting language controls the TAS1020 on the USB-MODEVM from the LabView™-based PC
software. The main program controls, described previously, do nothing more than write a script which is
then handed off to an interpreter that sends the appropriate data to the correct USB endpoint. Because
this system is script based, provision is made in this tab for the user to view the scripting commands
created as the controls are manipulated, as well as load and execute other scripts that have been written
and saved (see Figure 29). This design allows the software to be used as a quick test tool or to help
provide troubleshooting information in the rare event that the user encounters problem with this EVM.
Figure 29. Command Line Interface Tab
A script is loaded into the command buffer, either by operating the controls on the other tabs or by loading
a script file. When executed, the return packets of data which result from each command are displayed in
the Read Data array control. When executing several commands, the Read Data control shows only the
results of the last command. To see the results after every executed command, use the logging function
described in the following text.
Command File..., loads a command file script into the command buffer. This script then can be executed
by pressing the Execute Command Buffer button.
The second option is Log Script and Results..., which opens a file save dialog box. Choose a location for a
log file to be written using this file save dialog. When the Execute Command Buffer button is pressed, the
script runs, and the script along with resulting data read back during the script, is saved to the file
specified. The log file is a standard text file that can be opened with any text editor and looks much like
the source script file, but with the additional information of the result of each script command executed.
The third menu item is a submenu of Recently Opened Files. This is simply a list of script files that have
previously been opened, allowing fast access to commonly used script files. The final menu item is Exit,
which terminates the TLV320AIC3007EVM software.
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Figure 30. File Menu
Under the Help menu is an About... menu item which displays information about the TLV320AIC3007EVM
software.
The I2C Bus Error Detection button allows the user to enable circuitry which sets a register bit (Register
107, D0) if an I2C bus error is detected. It is unnecessary to use this with the GUI software but can be
used as part of error detection in the end-equipment software design.
The actual USB protocol used as well as instructions on writing scripts are detailed in the following
subsections. Although it is unnecessary to understand or use either the protocol or the scripts directly,
understanding them may be helpful to some users.
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Appendix A
Appendix A EVM Connector Descriptions
This appendix contains the connection details for each of the main header connectors on the EVM.
A.1 Analog Interface Connectors
A.1.1
Analog Input/Output Connectors
In addition to the analog headers, the analog inputs and outputs also can be accessed through alternate
connectors, either screw terminals or audio jacks. The stereo microphone input is also tied to J6 and the
stereo headphone output (the HP set of outputs) is available at J7.
Table A-1. Analog Input/Output Connectors
Designator
Description
Function
PIN 1
PIN 2
PIN3
J6
3-Conductor Screw
Terminal Input
See SW1 Configuration for
SE/Diff Usage
LINE1LP
AGND
LINE1LM
J7
3-Conductor Screw
Terminal Input
See SW1 Configuration for
SE/Diff Usage
LINE1RP
LINE2LP
AGND
LINE1RM
LINE2LM
MIC3R
J8
3-Conductor Screw
Terminal Input
See SW1 Configuration for
SE/Diff Usage
AGND
J9
Audio 3.5mm Stereo Input External Mic Input (See SW1 AGND
Jack
MIC3L
HPLOUT
Configuration)
J10
J11
J12
J15
J17
J18
Audio 3.5mm Stereo
Output Jack
Headset Output (See SW2
Configuration)
AGND
HPROUT
Audio 3.5mm Stereo
Output Jack
Headset Test Output (See
SW2 Configuration)
AGND
HPL-TEST
(filtered)
HPR-TEST
(filtered)
3-Conductor Screw
Terminal Output
Lineout
LEFT_LOP
AGND
RIGHT_LOP
2-Conductor Screw
Terminal Input
External SVDD (Class-D
Power)
Class-D Voltage
(SVDD)
SPGND (ground) NA
2-Conductor Screw
Terminal Output
Class-D Speaker Test
OUT-M (filtered)
OUT-P (filtered)
SPOP
NA
NA
2-Conductor Screw
Terminal Output
Class-D Speaker Output
SPOM
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Block A and Block B Digital Interface Connectors (J16 and J17)
A.2 Block A and Block B Digital Interface Connectors (J16 and J17)
The TLV320AIC3007EVM is designed to easily interface with multiple control platforms. Samtec part
numbers SSW-110-22-F-D-VS-K and TSM-110-01-T-DV-P provide a convenient 10-pin dual row
header/socket combination at J16 and J17. These headers/sockets provide access to the digital control
TLV320AIC3007EVM.
Table A-2. Block A and Block B Digital Interface Pinout
Pin Number
P4.1
Signal
NC
Description
Not Connected
P4.2
NC
Not Connected
P4.3
NC
Not Connected
P4.4
DGND
NC
Digital Ground
P4.5
Not Connected
P4.6
GPIO1
NC
General Purpose Input/Output
Not Connected
P4.7
P4.8
RESET INPUT
NC
Reset signal input to AIC3007EVM
Not Connected
P4.9
P4.10
P4.11
P4.12
P4.13
P4.14
P4.15
P4.16
P4.17
P4.18
P4.19
P4.20
P5.1
DGND
NC
Digital Ground
Not Connected
NC
Not Connected
NC
Not Connected
RESET
NC
Reset
Not Connected
NC
Not Connected
NC
Not Connected
DGND
NC
Digital Ground
Not Connected
NC
Not Connected
NC
Not Connected
P5.2
NC
Not Connected
P5.3
BCLK
DGND
NC
Audio Serial Data Bus Bit Clock (Input/Output)
Digital Ground
P5.4
P5.5
Not Connected
P5.6
NC
Not Connected
P5.7
WCLK
NC
Audio Serial Data Bus Word Clock (Input/Output)
Not Connected
P5.8
P5.9
NC
Not Connected
P5.10
P5.11
P5.12
P5.13
P5.14
P5.15
P5.16
P5.17
P5.18
P5.19
P5.20
DGND
DIN
Digital Ground
Audio Serial Data Bus Data Input (Input)
Not Connected
NC
DOUT
NC
Audio Serial Data Bus Data Output (Output)
Not Connected
NC
Not Connected
I2C Serial Clock
SCL
MCLK
DGND
NC
Block A Master Clock Input
Digital Ground
Not Connected
I2C Serial Data Input/Output
SDA
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Power Supply Connector Pin Header, J15
Note that P5 comprises the signals needed for an I2S serial digital audio interface; the control interface
(I2C and RESET) signals are routed to P4. I2C is actually routed to both connectors; however, the device
is connected only to P4.
A.3 Power Supply Connector Pin Header, J15
J15 provides connection to the common power bus for the TLV320AIC3007EVM. Power is supplied on the
Table A-3. Power Supply Pinout
Signal
Pin Number
Signal
NC J15.1
J15.2 NC
+5VA J15.3
DGND J15.5
J15.4 NC
J15.6 AGND
J15.8 NC
DVDD (1.8V) J15.7
IOVDD (3.3V) J15.9
J15.10 NC
The TLV320AIC3007EVM-K motherboard (the USB-MODEVM Interface board) supplies power to J15 of
the TLV320AIC3007EVM. Power for the motherboard is supplied either through its USB connection or via
terminal blocks on that board.
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Appendix B
Appendix B TLV320AIC3007EVM Schematic
The schematic diagram for the modular TLV320AIC3007EVM is provided as a reference.
D A P P
0
L C S
A D S
P
I N W
P T U O W
M T U O W
M I N W
S
L C S
A D S
1
2
3 0
2 9 P T U O W
2 8 M T U O W
2 7 M I N W
P
I N W
S
S
S
M L 1 E N I L / T E D C I
M
S
M
L 1 E N I L / T E D C I
M
1 L E N L I
1 R E N L I
3
S
P
1 L E L I N
1 R E N L I
S
P
4
S
P
P O P S
D D V P S
P
5
2 6
2 5
2 4
2 3
2 2
2 1
P O P S
5
W
1
M R 1 E I N / L L 3 I C M
M R 1 E I N / L L 3 I C M
2 L E N L I
2 L E I N / L P 2 R E N L I
M R 2 E N I L / R 3 C I
S A I I C M
6
D D V P S
M O P S
2
P
2 L E L I N
S S V P S
P
7
M
2 L E I N / L P 2 R E L I N
M O P S
M
8
M R 2 E N I L / R 3 C I
I A B C I
M
C A D _ S S V A
C A D _ D D V A
M
9
S
M
B
1 0
C A D _ D D V A
2
1
W
4
1
2
W
3 1
1
2
W
2 1
1 1
0 1
W
W
2
2
1
1
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35
Appendix B
L C S
A D S
P W
6
5
7
2 A
1 A
0 A
3
2
1
D N G
1
36
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Appendix C
Appendix C TLV320AIC3007EVM Layout Views
Figure C-1. Assembly layer
Figure C-2. Top Layer
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Appendix C
Figure C-3. Layer 3
Figure C-4. Layer 4
38
TLV320AIC3007EVM Layout Views
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Appendix C
Figure C-5. Bottom Layer
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Appendix D
Appendix D TLV320AIC3007EVM Bill of Materials
The complete bill of materials for the modular TLV320AIC3007EVM is provided as a reference.
Table D-1. TLV320AIC3007EVM Bill of Materials
Item
No.
Qty
Value
Ref Des
Description
Vendor
Part Number
ATTENTION:
Alternate Resistor and Capacitor vendors may be used. In this case substitutions must have like descriptions.
All components should be RoHS compliant. Some part numbers may be either leaded or RoHS. Verify purchased components
PCB
1
1
N/A
TLV320AIC3007_RSB_EVM_RevA_PWB
Texas Instruments
RESISTORS
2
3
4
5
6
7
8
9
4
2
4
1
2
2
1
1
0
R5, R6, R17, R18
R9, R10
R7, R8, R11, R12
R2
RES 0 Ω 1/10W 5% 0603 SMD
RES 16 Ω 1W 5% 2512 SMD
Panasonic
Panasonic
Panasonic
Yageo
ERJ-3GEY0R00V
16
ERJ-1TYJ160U
100
220
402
2.2K
2.7K
100K
RES 100 Ω 1/10W 1% 0603 SMD
RES 220 Ω 1/10W 1% 0603 SMD
RES 402 Ω 1/10W 1% 0603 SMD
RES 2.2 kΩ 1/10W 5% 0603 SMD
RES 2.7 kΩ 1/10W 5% 0603 SMD
RES 100 kΩ 1/10W 1% 0603 SMD
ERJ-3EKF1000V
RC0603FR-07220RL
CRCW0603402RFKEA
ERJ-3GEYJ222V
ERJ-3GEYJ272V
ERJ-3EKF1003V
R13, R14
R3, R4
Vishay/Dale
Panasonic
Panasonic
Panasonic
R19
R1
CAPACITORS
10
11
12
13
2
4
0.022 µF
0.047 µF
0.1 µF
C37, C38
CAP CER 0.022 µF 50V X8R 10% 0603
CAP 47000PF 25 V CERM X7R 0603
CAP CER 0.10 µF 6.3V X5R 10% 0402
CAP CER 0.1 µF 25V X7R 0603
TDK Corporation
Panasonic
C1608X8R1H223K
ECJ-1VB1E473K
C1005X5R0J104K
C1608X7R1E104K
C31–C34
7
C1–C5, C7, C8
TDK Corporation
TDK Corporation
11
0.1 µF
C17–C22, C24,
C25, C46, C48, C52
14
15
16
17
18
3
5
3
1
5
1.0uF
10 µF
10 µF
22 µF
47 µF
C15, C35, C36
C9–C12, C16
C45, C47, C51
C13
CAP CERAMIC 1 µF 10V X5R 0603
CAP CERAMIC 10 µF 6.3V X5R 0603
CAP CER 10UF 16V X5R 20% 1206
CAP CER 22UF 6.3V X5R 20% 0805
CAP CER 47 µF 10V X5R 1210
Panasonic
ECJ-BVB1A105K
Panasonic
ECJ-1VB0J106M
TDK Corporation
TDK Corporation
Murata
C3216X5R0J106M
C2012X5R0J226M
GRM32ER61A476KE20L
C23, C29, C30,
C49, C50
19
5
Not Installed C26–C41, C42
CAP 0603
N/A
N/A
PASSIVES
20
21
1
2
600
L5
FERRITE CHIP 600 OHM 500MA 0805
RES ZERO OHM 1/4W 5% 1206 SMD
TDK Corporation
Panasonic
MMZ2012R601A
ERJ-8GEY0R00V
0 (0 Ω used L1, L2
in place of
Ferrite)
INTEGRATED CIRCUITS
22
23
24
1
1
1
U1
U2
U3
Audio CODEC
Texas Instruments
Texas Instruments
MicroChip
TLV320AIC3007IRSB
REG1117-3.3
IC LDO REG 3.3V 800MA SOT-223
64K I2C EEPROM
24LC64-I/SN
MISCELLANEOUS ITEMS
25
26
27
28
29
30
31
32
33
4
4
3
J15– J18
J6–J8, J12
J9–J11
Screw Terminal Block, 2 Position
Screw Terminal Block, 3 Position
3.5mm Audio Jack, T-R-S, SMD
or alternate
On Shore Technology
On Shore Technology
CUI Inc.
ED555/2DS
ED555/3DS
SJ1-3515-SMT
KobiConn
161-3335-E
2
4
1
1
9
P4, P5
20 Pin SMT Plug
Samtec
TSM-110-01-L-DV-P
SSW-110-22-F-D-VS-K
TSM-105-01-L-DV-P
SSW-105-22-F-D-VS-K
TSW-102-07-L-S
J1, J2, J4, J5
20 pin SMT Socket
Samtec
P3
J3
10 Pin SMT Plug
Samtec
10 pin SMT Socket
Samtec
W10–W13,
W15–W19
2 Position Jumper , 0 .1" spacing
Samtec
40
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Appendix D
Table D-1. TLV320AIC3007EVM Bill of Materials (continued)
Item
No.
Qty
Value
Ref Des
Description
Vendor
Part Number
34
35
36
7
2
1
W1–W5, W7, W8
W9, W14
Bus Wire (18–22 Gauge)
3 Position Jumper , 0 .1" spacing
Omnidirectional Microphone Cartridge
or alternate
Samtec
TSW-103-07-L-S
MD9745APZ-F
MD9745APA-1
EG4208
MK1
Knowles Acoustics
Knowles Acoustics
E-Switch
37
38
39
2
1
SW1, SW2
SW3
SWITCH SLIDE 4PDT 30V RT ANGLE
SWITCH SLIDE SPDT 30V.2A PC MNT
TEST POINT PC MINI 0.040"D RED
E-Switch
EG1218
13
Not
Installed
TP1–TP5, TP7,
TP8, TP41–TP45,
TP49
Keystone Electronics
5000
40
41
3
TP46–TP48
TEST POINT PC MULTI PURPOSE BLK
TEST POINT PC MINI 0.040"D WHITE
Keystone Electronics
Keystone Electronics
5011
5002
30
Not
Installed
TP9–TP25,
TP28–TP40
42
Installed
per test
N/A
Header Shorting Block
Samtec
SNT-100-BK-T
procedure.
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41
Appendix E
Appendix E USB-MODEVM Schematic
The schematic diagram for USB-MODEVM Interface Board (included in the TLV320AIC3007EVM-K) is
provided as a reference. It appears on the following page.
42
USB-MODEVM Schematic
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Appendix F
Appendix F USB-MODEVM Bill of Materials
The complete bill of materials for USB-MODEVM Interface Board (included only in the
TLV320AIC3007EVM-K)is provided as a reference.
Table F-1. USB-MODEVM Bill of Materials
Designators
R4
Description
Manufacturer
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
Panasonic
CTS Corporation
TDK
Mfg. Part Number
10Ω 1/10W 5% Chip Resistor
27.4Ω 1/16W 1% Chip Resistor
75Ω 1/4W 1% Chip Resistor
ERJ-3GEYJ1300V
ERJ-3EKF27R4V
ERJ-14NF75R0U
ERJ-3GEYJ221V
ERJ-3GEYJ391V
ERJ-3EKF6490V
ERJ-3GEYJ1352V
ERJ-3GEYJ272V
ERJ-3EKF3091V
ERJ-3GEYJ1303V
ERJ-3GEYJ1304V
742C163103JTR
C1608C0G1H330J
C1608C0G1H470J
C1608C0G1H101J
C1608C0G1H102J
C1608X7R1C104K
C1608X5R1C334K
C1608X5R0J1305K
C3216X5R0J1306K
DL4001
R10, R11
R20
R19
220Ω 1/10W 5% Chip Resistor
390Ω 1/10W 5% Chip Resistor
649Ω 1/16W 1% Chip Resistor
1.5KΩ 1/10W 5% Chip Resistor
2.7KΩ 1/10W 5% Chip Resistor
3.09KΩ 1/16W 1% Chip Resistor
10KΩ 1/10W 5% Chip Resistor
100kΩ 1/10W 5%Chip Resistor
10KΩ 1/8W Octal Isolated Resistor Array
33pF 50V Ceramic Chip Capacitor, ±5%, NPO
47pF 50V Ceramic Chip Capacitor, ±5%, NPO
100pF 50V Ceramic Chip Capacitor, ±5%, NPO
1000pF 50V Ceramic Chip Capacitor, ±5%, NPO
0.1µF 16V Ceramic Chip Capacitor, ±10%, X7R
0.33µF 16V Ceramic Chip Capacitor, ±20%, Y5V
1µF 6.3V Ceramic Chip Capacitor, ±10%, X5R
10µF 6.3V Ceramic Chip Capacitor, ±10%, X5R
50V, 1A, Diode MELF SMD
R14, R21, R22
R13
R9
R1–R3, R5–R8
R12
R15, R16
R17, R18
RA1
C18, C19
C13, C14
C20
TDK
TDK
C21
TDK
C15
TDK
C16, C17
C9–C12, C22–C28
C1–C8
D1
TDK
TDK
TDK
Micro Commercial Components
Lumex
D2
Yellow Light Emitting Diode
SML-LX0603YW-TR
SML-LX0603GW-TR
SML-LX0603IW-TR
ZXMN6A07F
D3– D7
D5
Green Light Emitting Diode
Lumex
Red Light Emitting Diode
Lumex
Q1, Q2
X1
N-Channel MOSFET
Zetex
6MHz Crystal SMD
Epson
MA-505 6.000M-C0
TAS1020BPFB
U8
USB Streaming Controller
Texas Instruments
Texas Instruments
Texas Instruments
Texas Instruments
Texas Instruments
Texas Instruments
Microchip
U2
5V LDO Regulator
REG1117-5
U9
3.3V/1.8V Dual Output LDO Regulator
Quad, 3-State Buffers
TPS767D318PWP
SN74LVC125APW
SN74LVC1G07DBVR
SN74LVC1G125DBVR
24LC64I/SN
U3, U4
U5–U7
U10
Single IC Buffer Driver with Open Drain o/p
Single 3-State Buffer
64K 2-Wire Serial EEPROM I2C
USB-MODEVM PCB
U1
Texas Instruments
Keystone Electronics
Keystone Electronics
Mill-Max
6463995
TP1–TP6, TP9–TP11
Miniature test point terminal
5000
TP7, TP8
Multipurpose test point terminal
USB Type B Slave Connector Thru-Hole
2-position terminal block
5011
J7
897-30-004-90-000000
ED555/2DS
J13, J2–J5, J8
On Shore Technology
CUI Stack
AMP/Tyco
Samtec
J9
2.5mm power connector
PJ-102B
J130
BNC connector, female, PC mount
20-pin SMT plug
414305-1
J131A, J132A, J21A, J22A
J131B, J132B, J21B, J22B
J133A, J23A
J133B, J23B
J6
TSM-110-01-L-DV-P
SSW-110-22-F-D-VS-K
TSM-105-01-L-DV-P
SSW-105-22-F-D-VS-K
TSW-102-07-L-D
TSW-106-07-L-D
20-pin SMT socket
Samtec
10-pin SMT plug
Samtec
10-pin SMT socket
Samtec
4-pin double row header (2x2) 0.1"
12-pin double row header (2x6) 0.1"
Samtec
J134, J135
Samtec
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43
Appendix F
Table F-1. USB-MODEVM Bill of Materials (continued)
Designators
JMP1–JMP4
JMP8–JMP14
JMP5, JMP6
JMP7
Description
Manufacturer
Samtec
Mfg. Part Number
2-position jumper, 0.1" spacing
2-position jumper, 0.1" spacing
3-position jumper, 0.1" spacing
3-position dual row jumper, 0.1" spacing
SMT, half-pitch 2-position switch
SMT, half-pitch 8-position switch
Jumper plug
TSW-102-07-L-S
TSW-102-07-L-S
TSW-103-07-L-S
TSW-103-07-L-D
TDA02H0SK1
Samtec
Samtec
Samtec
SW1
C&K Division, ITT
C&K Division, ITT
Samtec
SW2
TDA08H0SK1
SNT-100-BK-T
44
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Appendix G
Appendix G USB-MODEVM Protocol
G.1 USB-MODEVM Protocol
The USB-MODEVM is defined to be a Vendor-Specific class, and is identified on the PC system as an
NI-VISA device. Because the TAS1020 has several routines in its ROM which are designed for use with
HID-class devices, HID-like structures are used, even though the USB-MODEVM is not an HID-class
device. Data is passed from the PC to the TAS1020 using the control endpoint.
Table G-1. USB Control Endpoint
HIDSETREPORT Request
Part
Value
Description
bmRequestType
bRequest
wValue
0x21
00100001
0x09
SET_REPORT
don't care
0x00
wIndex
0x03
HID interface is index 3
wLength
Data
calculated by host
Data packet as described below
Table G-2. Data Packet Configuration
Byte Number
Type
Description
0
Interface
Specifies serial interface and operation. The two values are logically ORed.
Operation:
READ
WRITE
0x00
0x10
Interface:
GPIO
0x08
0x04
0x02
0x01
0x00
SPI_16
I2C_FAST
I2C_STD
SPI_8
1
2
I2C Slave Address
Length
Slave address of I2C device or MSB of 16-bit reg addr for SPI
Length of data to write/read (number of bytes)
3
Register address
Data
Address of register for I2C or 8-bit SPI; LSB of 16-bit address for SPI
4..64
Up to 60 data bytes could be written at a time. EP0 maximum length is 64. The return
packet is limited to 42 bytes, so advise only sending 32 bytes at any one time.
Example usage:
Write two bytes (AA, 55) to device starting at register 5 of an I2C device with address A0:
[0]
[1]
[2]
[3]
[4]
[5]
0x11
0xA0
0x02
0x05
0xAA
0x55
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USB-MODEVM Protocol
Do the same with a fast mode I2C device:
[0] 0x12
[1] 0xA0
[2]
[3]
[4]
[5]
0x02
0x05
0xAA
0x55
Now with an SPI device which uses an 8-bit register address:
[0]
[1]
[2]
[3]
[4]
[5]
0x10
0xA0
0x02
0x05
0xAA
0x55
Now consider a 16-bit register address, as found on parts like the TSC2101. Assume that the register
address (command word) is 0x10E0:
[0]
[1]
[2]
[3]
[4]
[5]
0x14
0x10 --> Note: the I2C address now serves as MSB of reg addr.
0x02
0xE0
0xAA
0x55
In each case, the TAS1020 returns, in an HID interrupt packet, the following:
[0]
interface byte | status
status:
REQ_ERROR 0x80
INTF_ERROR 0x40
REQ_DONE 0x20
[1]
for I2C interfaces, the I2C address as sent
for SPI interfaces, the read back data from SPI line for transmission of the corresponding byte
length as sent
for I2C interfaces, the reg address as sent
[2]
[3]
for SPI interfaces, the read back data from SPI line for transmission of the corresponding byte
[4..60] echo of data packet sent
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USB-MODEVM Protocol
If the command is sent with no problem, the returning byte [0] is the same as the sent one logically ORed
with 0x20 - in the preceding first example, the returning packet is:
[0]
[1]
[2]
[3]
[4]
[5]
0x31
0xA0
0x02
0x05
0xAA
0x55
If for some reason the interface fails (for example, the I2C device does not acknowledge), it comes back
as:
[0]
[1]
[2]
[3]
[4]
[5]
0x51 --> interface | INTF_ERROR
0xA0
0x02
0x05
0xAA
0x55
If the request is malformed, that is, the interface byte (byte [0]) takes on a value which is not as preciously
described, the return packet is:
[0]
[1]
[2]
[3]
[4]
[5]
0x93 --> the user sent 0x13, which is not valid, so 0x93 returned
0xA0
0x02
0x05
0xAA
0x55
The preceding examples used writes. Reading is similar:
Read two bytes from device starting at register 5 of an I2C device with address A0:
[0]
[1]
[2]
[3]
0x01
0xA0
0x02
0x05
The return packet is:
[0]
[1]
[2]
[3]
[4]
[5]
0x21
0xA0
0x02
0x05
0xAA
0x55
assuming that the preceding values starting at Register 5 were actually written to the device.
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GPIO Capability
G.2 GPIO Capability
The USB-MODEVM has seven GPIO lines. Access them by specifying the interface to be 0x08, and then
using the standard format for packets—but addresses are unnecessary. The GPIO lines are mapped into
Table G-3. GPIO Pin Assignments
Bit 7
x
6
5
4
3
2
1
0
P3.5
P3.4
P3.3
P1.3
P1.2
P1.1
P1.0
Example: write P3.5 to a 1, set all others to 0:
[0]
[1]
[2]
[3]
[4]
0x18 --> write, GPIO
0x00 --> this value is ignored
0x01 --> length - ALWAYS a 1
0x00 --> this value is ignored
0x40 --> 01000000
The user may also read back from the GPIO to see the state of the pins. Let's say we just wrote the
previous example to the port pins.
Example: read the GPIO
[0]
[1]
[2]
[3]
0x08 --> read, GPIO
0x00 --> this value is ignored
0x01 --> length - ALWAYS a 1
0x00 --> this value is ignored
The return packet should be:
[0]
[1]
[2]
[3]
[4]
0x28
0x00
0x01
0x00
0x40
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Writing Scripts
G.3 Writing Scripts
A script is simply a text file that contains data to send to the serial control buses. The scripting language is
simple, as is the parser for the language. Therefore, although the program is not forgiving about mistakes
made in the source script file, the formatting of the file is simple. Consequently, mistakes are rare.
Each line in a script file is one command. Lines cannot be extended beyond one line. A line is terminated
by a carriage return.
The first character of a line is the command. Commands are:
I
r
w
#
b
d
Set interface bus to use
Read from the serial control bus
Write to the serial control bus
Comment
Break
Delay
The first command, I, sets the interface to use for the commands to follow. This command must be
followed by one of the following parameters:
i2cstd
i2cfast
spi8
Standard mode I2C bus
Fast mode I2C bus
SPI bus with 8-bit register addressing
SPI bus with 16-bit register addressing
Use the USB-MODEVM GPIO capability
spi16
gpio
For example, if a fast mode I2C bus is to be used, the script begins with:
I i2cfast
No data follows the break command. Anything following a comment command is ignored by the parser,
provided that it is on the same line. The delay command allows the user to specify a time, in milliseconds,
that the script pauses before proceeding.
Note: Unlike all other numbers used in the script commands, the delay time is entered in a decimal
format. Also, note that because of latency in the USB bus as well as the time it takes the
processor on the USB-MODEVM to handle requests, the delay time may not be precise.
A series of byte values follows either a read or write command. Each byte value is expressed in
hexadecimal, and each byte must be separated by a space. Commands are interpreted and sent to the
The first byte following a read or write command is the I2C slave address of the device (if I2C is used) or
the first data byte to write (if SPI is used—note that SPI interfaces are not standardized on protocols, so
the meaning of this byte varies with the device being addressed on the SPI bus). The second byte is the
starting register address that data is written to (again, with I2C; SPI varies—see Section G.1 for additional
information about what variations may be necessary for a particular SPI mode). Following these two bytes
are data, if writing; if reading, the third byte value is the number of bytes to read, (expressed in
hexadecimal).
For example, to write the values 0xAA 0x55 to an I2C device with a slave address of 0x90, starting at a
register address of 0x03, one would write:
#example script
I i2cfast
w 90 03 AA 55
r 90 03 2
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Writing Scripts
This script begins with a comment, specifies that a fast I2C bus is used, then writes 0xAA 0x55 to the I2C
slave device at address 0x90, writing the values into registers 0x03 and 0x04. The script then reads back
two bytes from the same device starting at register address 0x03. Note that the slave device value does
not change. It is unnecessary to set the R/W bit for I2C devices in the script; the read or write commands
does that.
Here is an example of using an SPI device that requires 16-bit register addresses:
# setup TSC2101 for input and output
# uses SPI16 interface
# this script sets up DAC and ADC at full volume, input from onboard mic
#
# Page 2: Audio control registers
w 10 00 00 00 80 00 00 00 45 31 44 FD 40 00 31 C4
w 13 60 11 20 00 00 00 80 7F 00 C5 FE 31 40 7C 00 02 00 C4 00 00 00 23 10 FE
00 FE 00
Note that blank lines are allowed. However, be sure that the script does not end with a blank line.
Although ending with a blank line does not cause the script to fail, the program does execute that line, and
therefore, may prevent the user from seeing data that was written or read back on the previous command.
In this example, the first two bytes of each command are the command word to send to the TSC2101
(0x1000, 0x1360); these are followed by data to write to the device starting at the address specified in the
command word. The second line may wrap in the viewer being used to look like more than one line;
careful examination shows, however, that only one carriage return is on that line, following the last 00.
Any text editor can be used to write these scripts; Jedit is an editor that is highly recommended for general
Once the script is written, it can be used in the command window by running the program, and then
selecting Open Command File... from the File menu. Locate the script and open it. The script then is
displayed in the command buffer. The user can also edit the script once it is in the buffer, but saving of the
command buffer is not possible at this time (this feature may be added at a later date).
Once the script is in the command buffer, it may be executed by pressing the Execute Command Buffer
button. If breakpoints are in the script, the script executes to that point, and the user is presented with a
dialog box with a button to press to continue executing the script. When ready to proceed, push that
button and the script continues.
Here an example of a (partial) script with breakpoints using the AIC33EVM as an example:
# setup AIC33 for input and output
# uses I2C
interface
I i2cfast
# reg 07 - codec datapath
w 30 07 8A
r 30 07 1
d 1000
# regs 15/16 - ADC volume, unmute and set to 0dB
w 30 0F 00 00
r 30 0F 2
b
This script writes the value 8A at register 7, then reads it back to verify that the write was good. A delay of
1000 ms (one second) is placed after the read to pause the script operation. When the script continues,
the values 00 00 is written starting at register 0F. This output is verified by reading two bytes, and pausing
the script again, this time with a break. The script does not continue until the user allows it to by pressing
OK in the dialog box that is displayed due to the break.
50
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