DATASHEET
TWO-CHANNEL, 20-BIT, AC’97 2.3 CODECS WITH HEADPHONE
DRIVE, SPDIF OUTPUT MICROPHONE & JACK SENSING STAC9752/9753
TSI™ CONFIDENTIAL
1 V 3.4 10/14
©2014 TEMPO SEMICONDCUTOR, INC. STAC9752/9753
Description
TSI's STAC9752/9753 are general purpose 20-bit, full
duplex, audio CODECs conforming to the analog
component specification of AC'97 (Audio CODEC 97
Component Specification Rev. 2.3). The STAC9752/9753
incorporate TSI's proprietary SD technology to achieve a
DAC SNR in excess of 90dB. The DACs, ADCs and mixer
are integrated with analog I/Os, which include four analog
line-level stereo inputs, two analog line-level mono inputs,
two stereo outputs, and one mono output channel. The
STAC9752/9753 include digital output capability for support
of modern PC systems with an output that supports the
SPDIF format. The STAC9752/9753 are standard
2-channel stereo CODECs. With TSI’s headphone
capability, headphones can be driven without an external
amplifier. The STAC9752/9753 may be used as a
secondary or tertiary CODECs, with
STAC9700/21/44/56/08/84/50/66 as the primary, in a
multiple CODEC configuration conforming to the AC'97
Rev. 2.3 specification. This configuration can provide the
true six-channel, AC-3 playback required for DVD
applications. The STAC9752/9753 communicate via the
five AC-Link lines to any digital component of AC'97,
providing flexibility in the audio system design. Packaged in
an AC'97 compliant 48-pin TQFP, the STAC9752/9753 can
be placed on the motherboard, daughter boards, PCI,
AMR, CNR, MDC or ACR cards.
Features
High performance SD technology
AC’97 Rev 2.3 compliant
20-bit full duplex stereo ADCs, DACs
Independent sample rates for ADCs & DACs
5-wire AC-Link protocol compliance
20-bit SPDIF Output
Internal Jack Sensing on Headphone and Line_Out
Internal Microphone Input Sensing
Digital PC Beep Option
Extended AC’97 2.3 Paging Registers
Adjustable VREF amplifier
Digital-ready status
General purpose I/Os
Crystal Elimination Circuit
Headphone drive capability (50 mW)
0dB, 10dB, 20dB, and 30dB microphone boost capability
+3.3 V (STAC9753) and +5 V (STAC9752) analog power
supply options
Pin compatible with the STAC9700, STAC9721,
STAC9756
100% pin compatible with STAC9750 and STAC9766
TSI Surround (SS3D) Stereo Enhancement
Energy saving dynamic power modes
Multi-CODEC option (Intel AC'97 rev 2.3)
Six analog line-level inputs
90dB SNR Line to Line
SNR > 89dB through Mixer and DAC
TSI™ CONFIDENTIAL
2 V 3.4 10/14
©2014 TEMPO SEMICONDCUTOR, INC. STAC9752/9753
STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
TABLE OF CONTENTS
1. TABLE OF CONTENTS ............................................................................................................ 2
1.1. List of Figures ....................................................................................................................................5
1.2. List of Tables .....................................................................................................................................6
2. PRODUCT BRIEF ..................................................................................................................... 7
2.1. Features .............................................................................................................................................7
2.2. Description .........................................................................................................................................7
2.3. STAC9752/53 Block Diagram ...........................................................................................................9
2.4. Key Specifications .............................................................................................................................9
2.5. Related Materials .............................................................................................................................10
2.6. Additional Support ...........................................................................................................................10
3. CHARACTERISTICS AND SPECIFICATIONS ....................................................................... 11
3.1. Electrical Specifications ...................................................................................................................11
3.1.1. Absolute Maximum Ratings: ..............................................................................................11
3.1.2. Recommended Operating Conditions ..............................................................................11
3.1.3. Power Consumption .........................................................................................................12
3.1.4. AC-Link Static Digital Specifications .................................................................................13
3.1.5. STAC9752 5V Analog Performance Characteristics .........................................................13
3.1.6. STAC9753 3.3V Analog Performance Characteristics ......................................................15
3.2. AC Timing Characteristics ...............................................................................................................17
3.2.1. Cold Reset .........................................................................................................................17
3.2.2. Warm Reset .....................................................................................................................17
3.2.3. Clocks ..............................................................................................................................18
3.2.4. STAC9752/53 Crystal Elimination Circuit and Clock Frequencies .....................................18
3.2.5. Data Setup and Hold ........................................................................................................19
3.2.6. Signal Rise and Fall Times ...............................................................................................19
3.2.7. AC-Link Low Power Mode Timing .....................................................................................20
3.2.8. ATE Test Mode .................................................................................................................20
4. TYPICAL CONNECTION DIAGRAM ...................................................................................... 21
4.1. Slit Independent Power Supply Operation .......................................................................................22
5. CONTROLLER, CODEC, AND AC-LINK ................................................................................ 23
5.1. AC-link Physical interface ................................................................................................................23
5.2. Controller to Single Codec ...............................................................................................................23
5.3. Controller to Multiple Codecs ...........................................................................................................25
5.3.1. Primary Codec Addressing ................................................................................................25
5.3.2. Secondary Codec Addressing ...........................................................................................26
5.3.3. Codec ID Strapping ............................................................................................................26
5.4. Clocking for Multiple Codec Implementations ..................................................................................26
5.5. STAC9752/53 as a Primary Codec ..................................................................................................27
5.5.1. STAC9752/53 as a Secondary Codec ...............................................................................27
5.6. AC-link Power Management ............................................................................................................27
5.6.1. Powering down the AC-link ................................................................................................27
5.6.2. Waking up the AC-link .......................................................................................................28
5.6.2.1. Controller Initiates Wake-up .............................................................................28
5.6.2.2. Codec Initiates Wake-up ..................................................................................28
5.6.3. Codec Reset ......................................................................................................................28
5.6.4. Cold AC ‘97 Reset .............................................................................................................29
5.6.5. Warm AC ‘97 Reset ...........................................................................................................29
5.6.6. Register AC ‘97 Reset .......................................................................................................29
6. AC-LINK DIGITAL INTERFACE ............................................................................................. 30
6.1. Overview ..........................................................................................................................................30
6.2. AC-link Serial Interface Protocol ......................................................................................................31
6.2.1. AC-link Variable Sample Rate Operation ...........................................................................31
6.2.2. Variable Sample Rate Signaling Protocol ..........................................................................32
6.2.2.1. SLOTREQ Behavior and Power Management .................................................33
6.2.3. Primary and Secondary Codec Register Addressing .........................................................33
6.3. AC-link Output Frame (SDATA_OUT) ...........................................................................................34
6.3.1. Slot 0: TAG / Codec ID .....................................................................................................35
TSI™ CONFIDENTIAL
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
6.3.2. Slot 1: Command Address Port ........................................................................................36
6.3.3. Slot 2: Command Data Port ..............................................................................................36
6.3.4. Slot 3: PCM Playback Left Channel ..................................................................................36
6.3.5. Slot 4: PCM Playback Right Channel ...............................................................................37
6.3.6. Slot 5: Modem Line 1 Output Channel ..............................................................................37
6.3.7. Slot 6 -11: DAC ................................................................................................................37
6.3.8. Slot 12: Audio GPIO Control Channel ...............................................................................37
6.4. AC-link Input Frame (SDATA_IN) .................................................................................................37
6.4.1. Slot 0: TAG ........................................................................................................................38
6.4.2. Slot 1: Status Address Port / SLOTREQ signaling bits .....................................................38
6.4.2.1. Status Address Port ..........................................................................................38
6.4.2.2. SLOTREQ signaling bits ...................................................................................39
6.4.3. Slot 2: Status Data Port ....................................................................................................39
6.4.4. Slot 3: PCM Record Left Channel .....................................................................................40
6.4.5. Slot 4: PCM Record Right Channel ..................................................................................40
6.4.6. Slot 5: Modem Line 1 ADC ................................................................................................40
6.4.7. Slot 6-9: ADC .....................................................................................................................40
6.4.8. Slots 7-8: Vendor Reserved ..............................................................................................40
6.4.9. Slot 10 & 11: ADC ..............................................................................................................40
6.4.10. Slot 12: Reserved ............................................................................................................40
6.5. AC-link Interoperability Requirements and Recommendations .......................................................41
6.5.1. “Atomic slot” Treatment of Slot 1 Address and Slot 2 Data ................................................41
6.6. Slot Assignments for Audio .............................................................................................................42
7. STAC9752/53 MIXER ............................................................................................................. 43
8. MIXER FUNCTIONAL DIAGRAMS ........................................................................................ 44
8.1. Analog Mixer Input .........................................................................................................................45
8.2. Mixer Analog Output .......................................................................................................................45
8.3. SPDIF Digital Mux ...........................................................................................................................45
8.4. PC Beep Implementation .................................................................................................................46
8.4.1. Analog PC Beep ................................................................................................................46
8.4.2. Digital PC Beep ..................................................................................................................46
9. PROGRAMMING REGISTERS ............................................................................................. 47
9.1. Register Descriptions .......................................................................................................................48
9.1.1. Reset (00h) ......................................................................................................................48
9.1.2. Master Volume Registers (02h) ..............................................................................49
9.1.3. Headphone Volume Registers (04h) ..................................................................................50
9.1.4. Master Volume MONO (06h) ...........................................................................................50
9.1.5. PC BEEP Volume (0Ah) ...................................................................................................51
9.1.6. Phone Volume (Index 0Ch) ...............................................................................................51
9.1.7. Mic Volume (Index 0Eh) .....................................................................................................52
9.1.8. LineIn Volume (Index 10h) ................................................................................................52
9.1.9. CD Volume (Index 12h) ....................................................................................................53
9.1.10. Video Volume (Index 14h) .............................................................................................53
9.1.11. Aux Volume (Index 16h) .................................................................................................54
9.1.12. PCMOut Volume (Index 18h) ..........................................................................................54
9.1.13. Record Select (1Ah) ........................................................................................................55
9.1.14. Record Gain (1Ch) ..........................................................................................................55
9.1.15. General Purpose (20h) ...................................................................................................56
9.1.16. 3D Control (22h) .............................................................................................................56
9.1.17. Audio Interrupt and Paging (24h) .....................................................................................57
9.1.18. Powerdown Ctrl/Stat (26h) ...............................................................................................58
9.1.18.1. Ready Status .................................................................................................59
9.1.18.2. External Amplifier Power Down Control Output ..............................................59
9.1.19. Extended Audio ID (28h) .................................................................................................59
9.1.20. Extended Audio Control/Status (2Ah) .............................................................................61
9.1.20.1. Variable Rate Sampling Enable .....................................................................62
9.1.20.2. SPDIF ............................................................................................................62
9.1.20.3. SPCV (SPDIF Configuration Valid) ...............................................................62
9.1.20.4. SPSA1, SPSA0 (SPDIF Slot Assignment) ...................................................62
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
9.1.21. PCM DAC Rate Registers (2Ch and 32h) .......................................................................63
9.1.22. PCM DAC Rate (2Ch) .....................................................................................................63
9.1.23. PCM LR ADC Rate (32h) ...............................................................................................63
9.1.24. SPDIF Control (3Ah) ........................................................................................................63
9.2. General Purpose Input & Outputs ....................................................................................................64
9.2.1. EAPD .................................................................................................................................64
9.2.2. GPIO Pin Definitions ..........................................................................................................64
9.2.3. GPIO Pin Implementation ..................................................................................................65
9.2.4. Extended Modem Status and Control Register (3Eh) ........................................................65
9.2.5. GPIO Pin Configuration Register (4Ch) .............................................................................65
9.2.6. GPIO Pin Polarity/Type Register (4Eh) ..............................................................................66
9.2.7. GPIO Pin Sticky Register (50h) .........................................................................................66
9.2.8. GPIO Pin Mask Register (52h) ..........................................................................................66
9.2.9. GPIO Pin Status Register (54h) .........................................................................................67
9.3. Extended Codec Registers Page Structure Definition .....................................................................68
9.3.1. Extended Registers Page 00 .............................................................................................68
9.3.2. Extended Registers Page 01 .............................................................................................68
9.3.3. Extended Registers Page 02, 03 .......................................................................................68
9.4. STAC9752/53 Paging Registers ......................................................................................................69
9.4.1. Codec Class/Rev (60h Page 01h) ..................................................................................69
9.4.2. PCI SVID (62h Page 01h) ................................................................................................70
9.4.3. PCI SSID (64h Page 01h) ................................................................................................70
9.4.4. Function Select (66h Page 01h) ......................................................................................71
9.4.5. Function Information (68h Page 01h) ..............................................................................72
9.4.6. Digital Audio Control (6Ah, Page 00h) ...............................................................................74
9.4.7. Sense Details (6Ah Page 01h) .........................................................................................74
9.4.8. Revision Code (6Ch) .........................................................................................................76
9.4.9. Analog Special (6Eh) .........................................................................................................76
9.4.10. Analog Current Adjust (72h) ............................................................................................77
9.4.11. EAPD Access Register (74h) ..........................................................................................77
9.4.12. High Pass Filter Bypass (78h) ........................................................................................78
9.5. Vendor ID1 and ID2 (Index 7Ch and 7Eh) .......................................................................................79
9.5.1. Vendor ID1 (7Ch) ..............................................................................................................79
9.5.2. Vendor ID2 (7Eh) ...............................................................................................................79
10. LOW POWER MODES ........................................................................................................ 80
11. MULTIPLE CODEC SUPPORT ............................................................................................ 82
11.1. Primary/Secondary Codec Selection .............................................................................................82
11.1.1. Primary Codec Operation ...............................................................................................82
11.1.2. Secondary Codec Operation ...........................................................................................82
11.2. Secondary Codec Register Access Definitions .............................................................................83
12. TESTABILITY ........................................................................................................................ 84
12.0.1. ATE Test Mode ................................................................................................................84
13. PIN DESCRIPTION .............................................................................................................. 85
13.1. Digital I/O .....................................................................................................................................86
13.2. Analog I/O .....................................................................................................................................87
13.3. Filter/References .........................................................................................................................87
13.4. Power and Ground Signals ..........................................................................................................88
14. PACKAGE DRAWING ......................................................................................................... 89
15. APPENDIX A: PROGRAMMING REGISTERS ..................................................................... 90
16. DOCUMENT HISTORY ......................................................................................................... 98
TSI™ CONFIDENTIAL
5 V 3.4 10/14
©2014 TEMPO SEMICONDCUTOR, INC. STAC9752/9753
STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
LIST OF FIGURES
Figure 1. Block Diagram ..................................................................................................................................8
Figure 2. Cold Reset Timing .........................................................................................................................16
Figure 3. Warm Reset Timing .......................................................................................................................16
Figure 4. Clocks Timing ...............................................................................................................................17
Figure 5. Data Setup and Hold Timing ..........................................................................................................18
Figure 6. Signal Rise and Fall Times Timing ................................................................................................18
Figure 7. AC-Link Low Power Mode Timing ...............................................................................................19
Figure 8. ATE Test Mode Timing ...............................................................................................................19
Figure 9. Typical Connection Diagram ...........................................................................................................20
Figure 10. Split Independent Power Supply Operation .................................................................................22
Figure 11. AC-Link to its Companion Controller ............................................................................................23
Figure 12. CODEC Clock Source Detection ..................................................................................................24
Figure 13. STAC9752/9753 Powerdown Timing ...........................................................................................27
Figure 14. Bi-directional AC-Link Frame with Slot assignments ...................................................................29
Figure 15. AC-Link Audio Output Frame .......................................................................................................33
Figure 16. Start of an Audio Output Frame ...................................................................................................33
Figure 17. STAC9752/9753 Audio Input Frame ............................................................................................36
Figure 18. Start of an Audio Input Frame .......................................................................................................36
Figure 19. Bi-directional AC-Link Frame with Slot assignments ...................................................................41
Figure 20. STAC9752 2-Channel Mixer Functional Diagram .........................................................................44
Figure 21. STAC9753 2-Channel Mixer Functional Diagram ........................................................................44
Figure 22. Example of STAC9752/9753 Powerdown/Powerup flow ...........................................................80
Figure 23. Powerdown/Powerup flow with analog still alive ..........................................................................81
Figure 24. Pin Description Drawing ................................................................................................................85
Figure 25. Reflow Profile ...............................................................................................................................90
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
LIST OF TABLES
Table 1. Clock Mode Configuration ................................................................................................................17
Table 2. Common Clocks and Sources ..........................................................................................................18
Table 3. Recommended CODEC ID strapping .............................................................................................26
Table 4. AC-Link output slots (transmitted from the Controller) .....................................................................29
Table 5. The AC-Link input slots (transmitted from the CODEC) ...................................................................30
Table 6. VRA Behavior ..................................................................................................................................31
Table 7. Output Slot 0 Bit Definitions ............................................................................................................34
Table 8. Command Address Port Bit Assignments ........................................................................................35
Table 9. Status Address Port Bit Assignments ..............................................................................................37
Table 10. Status Data Port Bit Assignments ..................................................................................................38
Table 11. Primary CODEC Addressing: Slot 0 Tag Bits ................................................................................40
Table 12. Secondary CODEC Addressing: Slot 0 Tag Bits ............................................................................40
Table 13. AC-Link Slot Definitions .................................................................................................................41
Table 14. AC-Link Input Slots Dedicated To Audio ........................................................................................41
Table 15. Audio Interrupt Slot Definitions .......................................................................................................42
Table 16. Digital PC Beep Examples .............................................................................................................46
Table 17. Programming Registers .................................................................................................................47
Table 18. Extended Audio ID Register Functions ..........................................................................................60
Table 19. AMAP compliant ............................................................................................................................63
Table 20. Hardware Supported Sample Rates ..............................................................................................63
Table 21. Supported Jack and Microphone Sense Functions ........................................................................71
Table 22. Reg 68h Default Values .................................................................................................................73
Table 23. Gain or Attenuation Examples .......................................................................................................73
Table 24. Register 68h/Page 01h Bit Overview .............................................................................................73
Table 25. Sensed Bits (Outputs) ....................................................................................................................75
Table 26. Sensed Bits (Inputs) .......................................................................................................................75
Table 27. Low Power Modes .........................................................................................................................80
Table 28. CODEC ID Selection ......................................................................................................................82
Table 29. Secondary CODEC Register Access Slot 0 Bit Definitions ............................................................83
Table 30. Test Mode Activation .....................................................................................................................84
Table 31. ATE Test Mode Operation .............................................................................................................84
Table 32. Digital Connection Signals .............................................................................................................86
Table 33. Analog Connection Signals ............................................................................................................87
Table 34. Filtering and Voltage References ...................................................................................................88
Table 35. Power and Ground Signals ............................................................................................................88
TSI™ CONFIDENTIAL
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
1. PRODUCT BRIEF
1.1. Description
TSI's STAC9752/9753 are general purpose 20-bit, full duplex, audio CODECs conforming to the
analog component specification of AC'97 (Audio CODEC 97 Component Specification Rev. 2.3). The
STAC9752/9753 incorporate TSI's proprietary SD technology to achieve a DAC SNR in excess of
90dB. The DACs, ADCs and mixer are integrated with analog I/Os, which include four analog
line-level stereo inputs, two analog line-level mono inputs, two stereo outputs, and one mono output
channel. The STAC9752/9753 include digital output capability for support of modern PC systems
with an output that supports the SPDIF format. The STAC9752/9753 are standard 2-channel stereo
CODECs. With TSI’s headphone capability, headphones can be driven without an external amplifier.
The STAC9752/9753 may be used as a secondary or tertiary CODECs, with
STAC9700/21/44/56/08/84/50/66 as the primary, in a multiple CODEC configuration conforming to
the AC'97 Rev. 2.3 specification. This configuration can provide the true six-channel, AC-3 playback
required for DVD applications. The STAC9752/9753 communicate via the five AC-Link lines to any
digital component of AC'97, providing flexibility in the audio system design. Packaged in an AC'97
compliant 48-pin TQFP, the STAC9752/9753 can be placed on the motherboard, daughter boards,
PCI, AMR, CNR, MDC or ACR cards.
The STAC9752/9753 block diagram is illustrated in Figure 1. The STAC9752/9753 provides variable
sample rate Digital-to-Analog (DA) and Analog-to-Digital (AD) conversion, mixing, and analog pro-
cessing. Supported audio sample rates include 48 KHz, 44.1 KHz, 32 KHz, 22.05 KHz, 16 KHz,
11.025 KHz, and 8 KHz; additional rates are supported in the STAC9752/9753 soft audio drivers. All
ADCs and DACs operate at 20-bit resolution.
Two 20-bit DACs convert the digital stereo PCM_OUT content to audio. The MIXER block combines
the PCM_OUT with any analog sources, to drive the LINE_OUT and HP_OUT outputs. The
MONO_OUT delivers either microphone only, or a mono mix of sources from the MIXER. The stereo
variable-sample-rate 20-bit ADCs provide record capability for any mix of mono or stereo sources,
and deliver a digital stereo PCM-in signal back to the AC-Link. The microphone input and mono mix
input can be recorded simultaneously, thus allowing for an all digital output in support of the digital
ready initiative. For a digital ready record path, the microphone is connected to the left channel ADC
while the mono output of the stereo mixer is connected to right channel ADC.
The STAC9752/9753 include jack sensing on the Headphone and Line_Out. The STAC9752/9753
jack sense can detect the presence of devices on the Headphone and Line Outputs and on both
Microphone inputs. With proprietary TSI current and impedance-sensing techniques, the impedance
load on the Headphone and Line Outputs can also be detected. The GPIOs on the STAC9752/9753
remain available for advanced configurations.
The STAC9752/9753 implementation of jack sense uses the Extended Paging Registers defined by
the AC'97 2.3 Specification. This allows for additional registry space to hold the identification infor-
mation about the CODEC, the jack sensing details and results, and the external surroundings of the
CODEC. The information within the Extended Paging Registers will allow for the automatic configu-
ration of the audio subsystem without end-user intervention. For example, the BIOS can populate
the Extended Paging Registers with valuable information for both the audio driver and the operating
system such as gain and attenuation stages, input population and input phase. With this input infor-
mation, the TSI driver will automatically provide to the Volume Control Panel only the volume sliders
that are implemented in the system, thus improving the end-user's experience with the PC.
The information in the Extended Paging Registers will also allow for automatic configuration of
microphone inputs, the ability to switch between SPDIF and analog outputs, the routing of the mas-
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
ter volume slider to the proper physical output, and SoftEQ configurations. The fully parametric TSI
SoftEQ can be initiated upon jack insertion and sensed impedance levels.
The STAC9752/9753 also offers 2 styles of PC BEEP; Analog and Digital. The digital PC Beep is a
new feature added to the AC’97 Specification Rev 2.3.
The STAC9752/9753 is designed primarily to support stereo (2-speaker) audio. True AC-3 playback
can be achieved for 6-speaker applications by taking advantage of the multi-CODEC option avail-
able in the STAC9752/9753 to support multiple CODECs in an AC'97 architecture. Additionally, the
STAC9752/9753 provides for a stereo enhancement feature, TSI Surround 3D (SS3D). SS3D pro-
vides the listener with several options for improved speaker separation beyond the normal two- or
four-speaker arrangements.
The STAC9752/9753 can be SoundBlaster® and Windows Sound System® compatible when used
with TSI’s WDM driver for Windows 98/2K/ME/XP or with Intel/Microsoft driver included with Win-
dows 2K/ME/XP. SoundBlaster is a registered trademark of Creative Labs. Windows is a registered
trademark of Microsoft Corporation.
1.2. STAC9752/9753 Block Diagram
Figure 1. Block Diagram
1.3. Key Specifications
Analog LINE_OUT SNR: 90 dB
STAC9752 DAC SNR: 89 dB
STAC9753 DAC SNR: 84dB
STAC9752 ADC SNR: 90 dB
STAC9753 ADC SNR: 88 dB
Crosstalk between Input Channels: -70 dB
Spurious Tone Rejection: 100 dB
HP_OUT
AC-link
Digital
Interface
Registers
64x16 bits
SYNC
BIT_CLK
SDATA_OUT
SDATA_IN
RESET#
Power
Management
DAC
DAC
ADC
ADC
PCM out DACs
PCM in ADCs
4 stereo
sources
2 mono
sources
MONO_OUT
Mic Boost
0,10,20
or 30 dB
MIC1
Stereo
Mono
MIXER
Analog mixing
and Gain Control
M
U
X
MIC2
LINE_OUT
Multi-Codec
CID0
CID1
SPDIF
Variable Sample Rate
20-Bit DACs and
20-Bit ADCs
EAPD
GPIO0
GPIO1
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
1.4. Related Materials
Product Brief
Reference Designs for MB, AMR, CNR, and ACR applications
Audio Precision Performance Plots
1.5. Additional Support
Additional product and company information can be obtained by going to the
TSI web site.
TSI™ CONFIDENTIAL
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STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
2. CHARACTERISTICS AND SPECIFICATIONS
2.1. Electrical Specifications
2.1.1. Absolute Maximum Ratings
Stresses above the ratings listed below can cause permanent damage to the STAC9752/9753. These ratings,
which are standard values for TSI commercially rated parts, are stress ratings only. Functional operation of the
device at these or any other conditions above those indicated in the operational sections of the specifications is not
implied. Exposure to absolute maximum rating conditions for extended periods can affect product reliability.
Electrical parameters are guaranteed only over the recommended operating temperature range.
2.1.2. Recommended Operation Conditions
Item Pin Maximum Rating
Analog maximum supply voltage AV d d 6 Volts
Digital maximum supply voltage DVdd 5.5 Volts
VREFOUT output current 5 mA
Voltage on any pin relative to ground Vss - 0.3 V to Vdd + 0.3 V
Operating temperature 0oC to +70oC
Storage temperature -55 oC to +125 oC
Soldering temperature
260 oC for 10 seconds *
Soldering temperature information for all available packages
begins on page 95.
Parameter Min. Typ. Max. Units
Power Supply Voltage Digital - 3.3 V 3.135 3.3 3.465 V
Analog - 5 V 4.75 5 5.25 V
Analog - 3.3 V 3.135 3.3 3.465 V
Ambient Operating Temperature 0 +70 C
Case Temperature Tcase (48-LQFP) +90 C
ESD: The STAC9752/9753 is an ESD (electrostatic discharge) sensitive device. The human body and test
equipment can accumulate and discharge electrostatic charges up to 4000 Volts without detection. Even though the
STAC9752/9753 implements internal ESD protection circuitry, proper ESD precautions should be followed to
avoid damaging the functionality or performance.
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2.1.3. Power Consumption
Parameter Min Typ Max Unit
Digital Supply Current
+ 3.3V Digital - 30 - mA
Analog Supply Current (at Reset state)
+ 5V Analog - 35 - mA
+ 3.3V Analog - 35 - mA
Power Down Status (individually asserted) - All PR measurements taken while unmuted.
All paths unmuted
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
50
44
33
-mA
PR0
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
42
39
22
-mA
PR1
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
41
38
28
-mA
PR2
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
32
29
12
-mA
PR3
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
23
19
12
-mA
PR4
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
50
44
0.2
-mA
PR5
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
50
44
12
-mA
PR6
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
38
36
33
-mA
PR0 & PR1
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
35
35
12
-mA
PR0, PR1, PR2, PR6
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
5
5
12
-mA
PR0, PR1, PR2, PR3, PR6
+5V Analog Supply Current
+3.3V Analog Supply Current
+3.3V Digital Supply Current
-
0.6
0.6
12
-mA
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2.1.4. AC-Link Static Digital Specifications
(Tambient = 25 ºC, DVdd = 3.3V ± 5%, AVss=DVss=0V)
Note: Due to an internal pulldown resistor, the BIT_CLK pin will exhibit less than 100 mA of
leakage current when the CODEC is configured as primary. This pin meets the +/- 10 mA leakage
specification when configured as secondary.
2.1.5. STAC9752 5 V Analog Performance Characteristics
(Tambient = 25 ºC, AVdd = 5.0 V ± 5%, DVdd = 3.3 V ± 5%, AVss=DVss=0 V; 1 KHz input sine wave;
Sample Frequency = 48 KHz; 0 dB = 1 Vrms, with a 10 KW, 50 pF load, Testbench Characterization
BW: 20 Hz to 20 KHz, 0 dB settings on all gain stages)
Parameter Symbol Min Typ Max Unit
Input voltage range Vin -0.30 - DVdd + 0.30 V
Low level input range Vil - - 0.35 x DVdd V
High level input voltage Vih 0.65 x DVdd - - V
High level output voltage Voh 0.90 x DVdd - - V
Low level output voltage Vol - - 0.1 x DVdd V
Input leakage current (AC-Link inputs) - -10 - 10 A
Output leakage current (Hi-Z AC-Link outputs) - -10 - 10 A
BIT_CLK (primary mode) Output leakage current - -10 - 100 A
BIT_CLK (secondary mode) Output leakage current - -10 - 10 A
Output buffer drive current - - 4 - mA
BIT_CLK/SPDIF Output drive current - - 18 - mA
Parameter Min Typ Max Unit
Full Scale Input Voltage:
All Analog Inputs except Microphone - 1.00 - Vrms
Microphone Inputs (Note 1) - 0.03 - Vrms
Full Scale Output:
Line Output - 1.00 - Vrms
PCM (DAC) to LINE_OUT - 1.00 - Vrms
MONO_OUT - 1.00 - Vrms
HEADPHONE_OUT (32 load) per channel (peak) -50 -mW
Dynamic Range: -60dB signal level (Note 2)
CD to LINE_OUT - 90 - dB
LINE / AUX / VIDEO to LINE_OUT - 90 - dB
PCM (DAC) to LINE_OUT 80 87 - dB
PCM (DAC) in BYPASS Mode to LINE_OUT - 88 - dB
LINE_IN to A/D (1 VRMS Input Referenced) 80 90 - dB
LINE_IN to HEADPHONE_OUT - 90 - dB
Analog Frequency Response (Note 3) 10 - 30,000 Hz
Total Harmonic Distortion + Noise (-3dB): (Note 4)
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CD to LINE_OUT - -85 - dB
Other to LINE_OUT - -87 - dB
PCM (DAC) to LINE_OUT (full scale) - -83 - dB
PCM (DAC) in BYPASS Mode to LINE_OUT - -86 - dB
LINE_IN to A/D (-3dBV input Level) - -85 - dB
HEADPHONE_OUT (32 load) --68 -dB
HEADPHONE_OUT (10 Kload) --81 -dB
SNR (idle channel) (Note 5)
DAC to LINE_OUT 80 90 - dB
DAC in BYPASS Mode - 92 - dB
LINE / AUX / VIDEO to LINE_OUT - 90 - dB
LINE_IN to A/D with High Pass Filter enabled - 92 - dB
A/D & D/A Digital Filter Pass Band (Note 6) 20 - 19,200 Hz
A/D & D/A Digital Filter Transition Band 19,200 - 28,800 Hz
A/D & D/A Digital Filter Stop Band 28,800 - - Hz
A/D & D/A Digital Filter Stop Band Rejection (Note 7) -100 - - dB
DAC Out-of-Band Rejection (Note 8) -55 - - dB
Group Delay (48 KHz sample rate) - - 1 ms
Power Supply Rejection Ratio (1 KHz) - -70 - dB
Power Supply Rejection Ratio (20 KHz) - -40 - dB
Any Analog Input to LINE_OUT Crosstalk
(10 KHz Signal Frequency) --80 -dB
Any Analog Input to LINE_OUT Crosstalk
(1 KHz Signal Frequency) - -100 - dB
Spurious Tone Rejection - -100 - dB
Attenuation, Gain Step Size - 1.5 - dB
Input Impedance - 50 - K
Input Capacitance - 15 - pF
VREFout - 0.5 X AVdd - V
VREF - 0.45X AVdd - V
Interchannel Gain Mismatch ADC - - 0.5 dB
Interchannel Gain Mismatch DAC - - 0.5 dB
Gain Drift - 100 - ppm/ºC
DAC Offset Voltage - 10 20 mV
Deviation from Linear Phase - - 1 degrees
LINE_OUT / MONO_OUT Load Resistance 10 - - K
LINE_OUT / MONO_OUT Load Capacitance - - 50 pF
HEADPHONE_OUT Load Resistance - 32 -
HEADPHONE_OUT Load Capacitance - - 100 pF
Mute Attenuation 90 96 - dB
Parameter Min Typ Max Unit
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Note: 1. With +30dB Boost on, 1.00 Vrms with Boost off.
2. Ratio of Full Scale signal to noise output with -60dB signal, measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
3. ± 1dB limits for Line Output & 0 dB gain, at -20dBV
4. Ratio of Full Scale signal to THD+N output with -3dB signal, measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
48 KHz Sample Frequency
5. Ratio of Full Scale signal to idle channel noise output is measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
(AES17-1991 Idle Channel Noise or EIAJ CP-307 Signal-to-noise Ratio).
6. Peak-to-Peak Ripple over Passband meets ± 0.25dB limits, 48 KHz Sample Frequency.
7. Stop Band rejection determines filter requirements. Out-of-Band rejection determines audible noise.
8. The integrated Out-of-Band noise generated by the DAC process, during normal PCM audio playback, over a bandwidth
28.8 to 100 KHz, with respect to a 1 Vrms DAC output.
2.1.6. STAC9753 3.3V Analog Performance Characteristics
(Tambient = 25 ºC, AVdd = DVdd = 3.3 V ± 5%, AVss=DVss=0 V; 1 KHz input sine wave; Sample Fre-
quency = 48 KHz; 0 dB = 1 Vrms, with a 10 KW, 50 pF load, Testbench Characterization BW: 20 Hz
to 20 KHz, 0 dB settings on all gain stages)
PLL lock time - 100 200 sec
PLL 24.576 MHz clock jitter - - 750 psec
PLL frequency multiplication tolerance - - 12.5 ppm
PLL bit clock jitter - - 750 psec
Parameter Min Typ Max Unit
Full Scale Input Voltage:
All Analog Inputs except Microphone - 1.00 - Vrms
Microphone Inputs (Note 1) - 0.03 - Vrms
Full Scale Output:
Line Output - 0.5 - Vrms
PCM (DAC) to LINE_OUT - 0.5 - Vrms
MONO_OUT - 0.5 - Vrms
HEADPHONE_OUT (32 load) per channel (peak) - 12.5 - mW
Dynamic Range: -60dB signal level (Note 2)
CD to LINE_OUT - 85 - dB
LINE / AUX / VIDEO to LINE_OUT - 85 - dB
PCM (DAC) to LINE_OUT 75 82 - dB
PCM (DAC) in BYPASS Mode to LINE_OUT - 83 - dB
LINE_IN to A/D 75 85 - dB
LINE_IN to HEADPHONE_OUT - 85 - dB
Analog Frequency Response (Note 3) 10 - 30,000 Hz
Total Harmonic Distortion + Noise (-3dB): (Note 4)
CD to LINE_OUT - -85 - dB
LINE / AUX / VIDEO to LINE_OUT - -85 - dB
PCM (DAC) to LINE_OUT (full scale) - -81 - dB
PCM (DAC) in BYPASS Mode to LINE_OUT - -84 - dB
LINE_IN to A/D (-3dBV input Level) - -85 - dB
Parameter Min Typ Max Unit
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Note: 1. With +30 dB Boost on, 1.00 Vrms with Boost off.
2. Ratio of Full Scale signal to noise output with -60dB signal, measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
3. ± 1dB limits for Line Output & 0 dB gain, at -20dBV
HEADPHONE_OUT (32 load) --68 -dB
HEADPHONE_OUT (10 kload) --77 -dB
SNR (idle channel) (Note 5)
DAC to LINE_OUT 75 85 - dB
DAC in BYPASS Mode - 87 - dB
LINE / AUX / VIDEO to LINE_OUT - 86 - dB
LINE_IN to A/D with High Pass Filter enabled - 88 - dB
A/D & D/A Digital Filter Pass Band (Note 6) 20 - 19,200 Hz
A/D & D/A Digital Filter Transition Band 19,200 - 28,800 Hz
A/D & D/A Digital Filter Stop Band 28,800 - - Hz
A/D & D/A Digital Filter Stop Band Rejection (Note 7) -100 - - dB
DAC Out-of-Band Rejection (Note 8) -55 - - dB
Group Delay (48 KHz sample rate) - - 1 ms
Power Supply Rejection Ratio (1 KHz) - -70 - dB
Power Supply Rejection Ratio (20 KHz) - -40 - dB
Any Analog Input to LINE_OUT Crosstalk
(10 KHz Signal Frequency) --80 -dB
Any Analog Input to LINE_OUT Crosstalk
(1 KHz Signal Frequency) - -100 - dB
Spurious Tone Rejection - -100 - dB
Attenuation, Gain Step Size - 1.5 - dB
Input Impedance - 50 - K
Input Capacitance - 15 - pF
VREFout - 0.5 X AVdd - V
VREF - 0.41X AVdd - V
Interchannel Gain Mismatch ADC - - 0.5 dB
Interchannel Gain Mismatch DAC - - 0.5 dB
Gain Drift - 100 - ppm/ºC
DAC Offset Voltage - 10 20 mV
Deviation from Linear Phase - - 1 degrees
LINE_OUT/MONO_OUT Load Resistance 10 - - K
LINE_OUT/MONO_OUT Load Capacitance - - 50 pF
HEADPHONE_OUT Load Resistance - 32 -
HEADPHONE_OUT Load Capacitance - - 100 pF
Mute Attenuation - 96 - dB
PLL lock time - 100 200 sec
PLL 24.576 MHz clock jitter - - 750 psec
PLL frequency multiplication tolerance - - 12.5 ppm
Parameter Min Typ Max Unit
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4. Ratio of Full Scale signal to THD+N output with -3dB signal, measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
48 KHz Sample Frequency
5. Ratio of Full Scale signal to idle channel noise output is measured “A-weighted” over a 20 Hz to a 20 KHz bandwidth.
(AES17-1991 Idle Channel Noise or EIAJ CP-307 Signal-to-noise Ratio).
6. Peak-to-Peak Ripple over Passband meets ± 0.25dB limits, 48 KHz Sample Frequency.
7. Stop Band rejection determines filter requirements. Out-of-Band rejection determines audible noise.
8. The integrated Out-of-Band noise generated by the DAC process, during normal PCM audio playback, over a bandwidth
28.8 to 100 KHz, with respect to a 1 Vrms DAC output.
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2.2. AC Timing Characteristics
(Tambient = 25 °C, AVdd = 3.3 V or 5 V ± 5%, DVdd = 3.3 V ± 5%, AVss=DVss=0 V; 75 pF external
load for BIT_CLK and 60 pF external load for SDATA_IN)
2.2.1. Cold Reset
Figure 2. Cold Reset Timing
Note: BIT_CLK and SDATA_IN are in a high impedance state during reset.
2.2.2. Warm Reset
Figure 3. Warm Reset Timing
Parameter Symbol Min Typ Max Units
RESET# active low pulse width Tres_low 1.0 - - s
RESET# inactive to SDATA_IN or BIT_CLK active delay Tri2actv - - 25 ns
RESET# inactive to BIT_CLK startup delay Trst2clk 0.01628 - 400 s
BIT_CLK active to RESET# asserted (Not shown in diagram) Tclk2rst 0.416 - - s
Parameter Symbol Min Typ Max Units
SYNC active high pulse width Tsync_high 1.0 1.3 - s
SYNC inactive to BIT_CLK startup delay Tsync2clk 162.8 - - ns
Tres_low
Trst2clk
RESET#
BIT_CLK
SDATA_IN
Ttri2actv
Ttri2actv
Tsync_high
Tsync_2clk
SYNC
BIT_CLK
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2.2.3. Clocks
Figure 4. Clocks Timing
2.2.4. STAC9752/9753 Crystal Elimination Circuit and Clock Frequencies
The STAC9752/9753 supports several clock frequency inputs as described in the following table. In
general, when a 24.576 MHz crystal is not used, the XTALOUT pin should be tied to ground. This
short to ground configures the part into an alternate clock mode and enables an on board PLL.
CODEC Modes:
P = The STAC9752/9753 as a Primary CODEC.
S = The STAC9752/9753 as a Secondary CODEC.
Parameter Symbol Min Typ Max Units
BIT_CLK frequency - 12.288 - MHz
BIT_CLK period Tclk_period - 81.4 - ns
BIT_CLK output jitter - 750 - ps
BLT_CLK high pulse width (Note 1) Tclk_high 36 40.7 45 ns
BIT_CLK low pulse width (Note 1) Tclk_low 36 40.7 45 ns
SYNC frequency - 48.0 - KHz
SYNC period Tsync_period - 20.8 - s
SYNC high pulse width Tsync_high - 1.3 - s
SYNC low pulse width Tsync_low - 19.5 - s
Note: 1. Worst case duty cycle restricted to 45/55.
Table 1. Clock Mode Configuration
XTL_OUT Pin Config CID1 Pin Config CID0 Pin Config Clock Source Input CODEC Mode CODEC ID
XTAL float float 24.576 MHz xtal P 0
XTAL or open float pulldown 12.288 MHz bit clk S 1
XTAL or open pulldown float 12.288 MHz bit clk S 2
XTAL or open pulldown pulldown 12.288 MHz bit clk S 3
short to ground float float 14.31818 MHz source P 0
short to ground float pulldown 27 MHz source P 0
SYNC
BIT_CLK Tclk_high
Tclk_low
Tclk_period
Tsync_high
Tsync_period
Tsync_low
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2.2.5. Data Setup and Hold
(50 pF external load)
Figure 5. Data Setup and Hold Timing
2.2.6. Signal Rise and Fall Times
(BIT_CLK: 75 pF external load; from 10% to 90% of Vdd)
(SDATA_IN: 60 pF external load; from 10% to 90% of Vdd)
short to ground pulldown float 48 MHz source P 0
short to ground pulldown pulldown 24.576 MHz source P 0
Table 2. Common Clocks and Sources
Clock Source Clock Frequency
XTAL 24.576 MHz
BIT_CLK 12.288 MHz
VGA 14.31818 MHz
Digital Video 27 MHz
USB 48 MHz
Parameter Symbol Min Typ Max Units
Setup to falling edge of BIT_CLK Tsetup 10 - - ns
Hold from falling edge of BIT_CLK Thold 10 - - ns
Output Valid Data from rising edge of BIT_CLK tco - - 15 ns
Note: Setup and hold time parameters for SDATA_IN are with respect to the AC'97 controller.
Table 1. Clock Mode Configuration
XTL_OUT Pin Config CID1 Pin Config CID0 Pin Config Clock Source Input CODEC Mode CODEC ID
BIT_CLK
Thold
Tsetup
SDATA_OUT
SDATA_IN
SYNC
tco
Vih Vil
Voh
Vol
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Figure 6. Signal Rise and Fall Times Timing
2.2.7. AC-Link Low Power Mode Timing
Figure 7. AC-Link Low Power Mode Timing
2.2.8. ATE Test Mode
Figure 8. ATE Test Mode Timing
Note: 1. All AC-Link signals are normally low through the trailing edge of RESET#. Bringing SDATA_OUT high for the trailing edge
of RESET# causes the STAC9752/9753 AC-Link outputs to go high-impedance which is suitable for ATE in circuit testing.
Parameter Symbol Min Typ Max Units
BIT_CLK rise time Triseclk - - 6 ns
BIT_CLK fall time Tfallclk - - 6 ns
SDATA_IN rise time Trisedin - - 6 ns
SDATA_IN fall time Tfalldin - - 6 ns
Parameter Symbol Min Typ Max Units
End of Slot 2 to BIT_CLK, SDATA_IN low Ts2_pdown - - 1.0 s
Parameter Symbol Min Typ Max Units
Setup to trailing edge of RESET# (also applies to SYNC) Tsetup2rst 15.0 - - ns
Rising edge of RESET# to Hi-Z delay Toff - - 25.0 ns
BIT_CLK
SDATA_IN
TfallclkTriseclk
Trisedin Tfalldin
BIT_CLK
SDATA_IN
Note: BIT_CLK not to scale
Ts2_pdown
Don't care
Data PR4
Write to
0x20
Slot 2Slot 1
SDATA_OUT
SYNC
Tsetup2rst
Hi-Z
Toff
RESET#
SDATA_OUT
SDATA_IN, BIT_CLK
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2. Once the test mode has been entered, the STAC9752/9753 must be issued another RESET# with all AC-Link signals low
to return to the normal operating mode.
3. The pound sign (#) appended to the end of a signal name denotes that the signal is active low.
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3. TYPICAL CONNECTION DIAGRAM
Figure 9. Typical Connection Diagram
NOTE: PIN 48: TO ENABLE SPDIF, USE AN 1 KW TO10 KW EXTERNAL PULLDOWN. TO DISABLE SPDIF, USE AN 1 KW
TO10 KW EXTERNAL PULLUP. DO NOT LEAVE PIN 48 FLOATING.
Note: The CD_GND signal is an AC signal return for the two CD input channels. It is normally
biased at about 2.5 V. The name of the pin in the AC’97 specification is CD_GND, and this has
confused many designers. It should not have any DC path to GND. Connecting the CD_GND
signal directly to ground will change the internal bias of the entire CODEC, and cause serious
distortion. If there is no analog CD input, then this pin can be No-Connect.
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3.1. Split Independent Power Supply Operation
In PC applications, one power supply input to the STAC9752/9753 may be derived from a supply
regulator and the other directly from the PCI power supply bus. When power is applied to the PC, the
regulated supply input to the IC will be applied some time delay after the PCI power supply. Without
proper on-chip partitioning of the analog and digital circuitry, some manufacturer's CODECs would
be subject to on-chip SCR type latch-up.
TSI’s STAC9752/9753 specifically allows power-up sequencing delays between the analog (AVddx)
and digital (VDddx) supply pins. These two power supplies can power-up independently and at dif-
ferent rates with no adverse effects to the CODEC. The IC is designed with independent analog and
digital circuitry that prevents on-chip SCR type latch-up.
However, the STAC9752/9753 is not designed to operate for extended periods with only the analog
supply active.
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Figure 10. Split Independent Power Supply Operation
NOTE: PIN 48: TO ENABLE SPDIF, USE AN 1 KW TO 10 KW EXTERNAL PULLDOWN RESISTOR. TO DISABLE SPDIF,
USE AN 1 KW TO 10 KW EXTERNAL PULLUP RESISTOR. DO NOT LEAVE PIN 48 FLOATING.
0.1 µF 1 µF 0.1 µF 0.1 µF 10 µF 0.1 µF
*Suggested
AVdd1 AVdd2 DVdd1 DVdd2
XTL_IN
XTL_OUT
913825
PC_BEEP
12
PHONE
13
AUX_L
14
AUX_R
15
VIDEO_L
16
VIDEO_R
17
CD_L
18
CD_GND
19
CD_R
20
MIC1
21
MIC2
22
LINE_IN_L
23
LINE_IN_R
41
820 pF 29
30
820 pF
AVss1 AVss2
26 42 4 7
DVss1 DVss2 HP_OUT_R
*Terminate ground
plane as close to codec
as possible
Analog
Ground
Digital
Ground
HP_OUT_L 39
37
MONO_OUT
36
LINE_OUT_R
35
LINE_OUT_L
43
44
40
48
34
33
31
27
VREFOUT
EAPD
CID1
CID0
28
47
46
45
11
RESET#
10
SYNC
24
BIT_CLK
SDATA_OUT 5
6
827 pF
22 EMI
Filter
3.3V ± 5%3.3V or 5V ± 5%
TUNE TO LAYOUT
CAP2
AFILT1
AFILT2
GPIO0
GPIO1
HP_COMM
SPDIF
NC
NC
NC
VREF
SDATA_IN
STAC9752 (5V Analog)
or
STAC9753 (3.3V Analog)
1 µF
HP_COMM should be tied to
ground at the headphone pin.
32
*OPTIONAL
0.1 µF
1 µF*
27 pF
27 pF
24.576 MHz
CLOCK_IN*
*Add resistive divider
when using 5V clock.
(Near Clk source)
0
OPTIONAL
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4. CONTROLLER, CODEC AND AC-LINK
This section describes the physical and high-level functional aspects of the AC‘97 Controller to
CODEC interface, referred to as AC-Link.
4.1. AC-Link Physical Interface
The STAC9752/9753 communicates with its companion Digital Controller via the AC-Link digital
serial interface. AC-Link has been defined to support connections between a single Controller and
up to four CODECs. All digital audio, modem and handset data streams, as well as all control (com-
mand/status) information are communicated over this serial interconnect, which consists of a clock
(BIT_CLK), frame synchronization (SYNC), serial data in (SDATA_IN), serial data out (SDATA_OUT)
and a reset (RESET#).
4.2. Controller to Single CODEC
The simplest and most common AC‘97 system configuration is a point-to-point AC-Link connection
between Controller and the STAC9752/9753, as illustrated in Figure 11.
Figure 11. AC-Link to its Companion Controller
A primary CODEC may act as either a source or a consumer of the bit clock (BIT_CLK), depending
on the configuration.
While RESET# is asserted, if a clock is present at the BIT_CLK pin for at least five cycles before
RESET# is de-asserted, then the CODEC is a consumer of BIT_CLK, and must not drive BIT_CLK
when RESET# is de-asserted. The clock is being provided by other than the primary CODEC, for
instance by the controller or an independent clock chip. In this case the primary CODEC must act as
a consumer of the BIT_CLK signal as if it were a secondary CODEC.
This clock source detection must be done each time the RESET# line is asserted. In the case of a
warm reset, where the clock is halted but RESET# is not asserted, the CODEC must remember the
clock source, and not begin generating the clock on the assertion of SYNC, if the CODEC had previ-
ously determined that it was a consumer of BIT_CLK.
SYNC
Digital DC'97
Controller AC'97 Codec
BIT_CLK
SDATA_OUT
SDATA_IN
RESET#
XTAL_IN
XTAL_OUT
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Figure 12. CODEC Clock Source Detection
The STAC9752/9753 uses the XTAL_OUT Pin (Pin 3) and the CID0 and CID1 pins (Pins 45 & 46) to
determine its alternate clock frequencies. See section 2.2.4: page 18 for additional information on
Crystal Elimination and for supported clock frequencies.
If, when the RESET# signal has been de-asserted, the CODEC has not detected a signal on
BIT_CLK as defined in the previous paragraph, then the AC‘97 CODEC derives its clock internally
from an externally attached 24.576 MHz crystal or oscillator, or optionally from an external
14.31 MHz oscillator, and drives a buffered 12.288 MHz clock to its digital companion Controller over
AC-Link under the signal name “BIT_CLK”. Clock jitter at the DACs and ADCs is a fundamental
impediment to high quality output, and the internally generated clock will provide AC‘97 with a clean
clock that is independent of the physical proximity of AC‘97’s companion Digital Controller (hence-
forth referred to as “the Controller”).
If BIT_CLK begins toggling while the RESET# signal is still asserted, the clock is being provided by
other than the primary CODEC, for instance by the controller or by a discrete clock source. In this
case, the primary CODEC must act as a consumer of the BIT_CLK signal as if it were a secondary
CODEC.
The beginning of all audio sample packets, or Audio Frames, transferred over AC-Link is synchro-
nized to the rising edge of the SYNC signal. SYNC is driven by the Controller. The Controller gener-
ates SYNC by dividing BIT_CLK by 256 and applying some conditioning to tailor its duty cycle. This
AC'97 Clock Source
Detection
RESET# Signal Asserted
BIT_CLK Toggling?
12.288MHz signal on BIT_CLK is
being generated externally; codec
uses this signal as the clock.
Yes
No
After RESET# Signal
Deasserted
24.576MHz
crystal present?
24.576MHz Crystal on XTL_IN
and XTL_OUT used by codec to
generate clock on BIT_CLK
Yes
24.576MHz
oscillator present?
No
24.576 MHz signal on XTL_IN
used by codec to generate
12.288MHz clock on BIT_CLK
Yes
14.318MHz
oscillator presnent?
No
14.318 MHz signal on XTL_IN
used by codec to generate
12.288MHz clock on BIT_CLK
Yes
Error condition - no clock
source present
No
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yields a 48 KHz SYNC signal whose period defines an audio frame. Data is transitioned on AC-Link
on every rising edge of BIT_CLK, and subsequently sampled by the receiving device on the receiv-
ing side of AC-Link on each immediately following falling edge of BIT_CLK.
4.3. Controller to Multiple CODECs
Several vendor specific methods of supporting multiple CODEC configurations on AC-Link have
been implemented or proposed, including CODECs with selective AC-Link pass-through and con-
trollers with duplicate AC-Links.
Potential implementations include:
6-channel audio using 3 x 2-channel CODECs
Separate CODECs for independent audio and modem AFE
Docking stations, where one CODEC is in the laptop and another is in the dock
This specification defines support for up to four CODECs on the AC-Link. By definition there can be
one Primary CODEC (ID 00) and up to three Secondary CODECs (IDs 01,10, and 11). The CODEC
ID functions as a chip select. Secondary devices therefore have completely orthogonal register sets;
each is individually accessible and they do not share registers.
Multiple CODEC AC-Link implementations must run off a common BIT_CLK. They can potentially
save Controller pins by sharing SYNC, SDATA_OUT, and RESET# from the AC‘97 Digital Controller.
Each device requires its own SDATA_IN pin back to the Controller. This prevents contention of multi-
ple devices on one serial input line.
Support for multiple CODEC operation necessitates a specially designed Controller. An AC‘97 Digi-
tal Controller that supports multiple CODEC configurations implements multiple SDATA_IN inputs,
supporting one Primary CODEC and up to three Secondary CODECs.
4.3.1. Primary CODEC Addressing
Primary AC‘97 CODECs respond to register read and write commands directed to CODEC ID 00
(see Section 10 for details of the Primary and Secondary CODEC addressing protocols). Primary
devices must be configurable (by hardwiring, strap pin(s), or other methods) as CODEC ID 00, and
reflect this in the two-bit CODEC ID field(s) of the Extended Audio and/or Extended Modem ID Reg-
ister(s).
The Primary CODEC may either drive the BIT_CLK signal or consume a BIT_CLK signal provided
by the digital controller or other clock generator.
4.3.2. Secondary CODEC Addressing
Secondary AC‘97 CODECs respond to register read and write commands directed to CODEC IDs
01, 10, or 11. Secondary devices must be configurable (via hardwiring, strap pin(s), or other meth-
ods) as CODEC IDs 01, 10, or 11 in the two-bit field(s) of the Extended Audio and/or Extended
Modem ID Register(s).
CODECs configured as Secondary must power up with the BIT_CLK pin configured as an input.
Using the provided BIT_CLK signal is necessary to ensure that everything on the AC-Link is syn-
chronous. BIT_CLK is the clock source (multiplied by 2 so that the internal rate is 24.576 MHz).
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4.3.3. CODEC ID Strapping
Audio CODECs in the 48-pin package use pins 45 and 46 (defined as ID0# and ID1#) as strapping
(i.e. configuration) pins to configure the CODEC ID. The ID0# and ID1# strapping bits adopt inverted
polarity and default to 00 = Primary (via a weak internal pullup) when left floating. This eliminates the
need for external resistors for CODECs configured as Primary, and maintains backward compatibility
with existing layouts that treat pins 45 and 46 as “no connect” or cap to ground. Pulldowns are typi-
cally 0-10 kW and connected to Digital (not Analog) Ground.
Table 3. Recommended CODEC ID strapping
4.4. Clocking for Multiple CODEC Implementations
To keep the system synchronous, all Primary and Secondary CODEC clocking must be derived from
the same clock source, so all CODECs are operating on the same time base. In addition, all AC-Link
protocol timing must be based on the BIT_CLK signal, to ensure that everything on the AC-Link will
be synchronous.
The following are potential 24.576 MHz clock options available to a Secondary CODEC:
Using an external 24.576 MHz signal source (external oscillator or AC‘97 Digital Controller).
Using the Primary’s XTAL_OUT.
Using the Primary’s BIT_CLK output to derive 24.576 MHz.
See section 2.2.4: page 18 for supported clock frequencies and configurations.
4.5. STAC9752/9753 as a Primary CODEC
Primary devices are required to support correctly any of the following clocking options:
24.576 MHz crystal attached to XTAL_IN and XTAL_OUT.
24.576 MHz external oscillator provided to XTAL_IN.
12.288 MHz oscillator provided to the BIT_CLK input.
The Primary device may also, optionally, support the following clocking option:
14.318 MHz external oscillator provided to XTAL_IN.
See section 2.2.4: page 18 for supported clock frequencies and configurations.
4.5.1. STAC9752/9753 as a Secondary CODEC
Secondary devices are required to function correctly using one or more of the following clocking
options:
24.576 MHz external oscillator provided to XTAL_IN (synchronous and in phase with Primary
24.576 MHz clock).
BIT_CLK input provided by the Primary. In this mode, a clock at XTAL_IN (Pin 2) is ignored.
CID1 (pin 46) CID0 (pin 45) Configuration
NC NC Primary ID = 00
NC pulldown Secondary ID = 01
pulldown NC Secondary ID = 10
pulldown pulldown Secondary ID = 11
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See section 2.2.4: page 18 for supported clock frequencies and configurations.
4.6. AC-Link Power Management
4.6.1. Powering down the AC-Link
The AC-Link signals can be placed in a low power mode. When the AC‘97’s Powerdown Register
(26h) is programmed to the appropriate value, both BIT_CLK and SDATA_IN are brought to and held
at a logic low voltage level. After signaling a reset to AC‘97, the AC‘97 Controller should not attempt
to play or capture audio data until it has sampled a CODEC Ready indication from AC‘97.
Figure 13. STAC9752/9753 Powerdown Timing
BIT_CLK and SDATA_IN are transitioned low immediately following decode of the write to the Pow-
erdown Register (26h) with PR4. When the AC‘97 Controller driver is at the point where it is ready to
program the AC-Link into its low power mode, slots 1 and 2 are assumed to be the only valid stream
in the audio output frame.
After programming the AC‘97 device to this low power, halted mode, the AC‘97 Controller is required
to drive and keep SYNC and SDATA_OUT low.
Once the AC‘97 CODEC has been instructed to halt BIT_CLK, a special “wake-up” protocol must be
used to bring the AC-Link to the active mode since normal audio output and input frames can not be
communicated in the absence of BIT_CLK.
4.6.2. Waking up the AC-Link
There are two methods for bringing the AC-Link out of a low power, halted mode. Regardless of the
method, it is the AC‘97 Controller that performs the wake-up task.
4.6.2.1. Controller Initiates Wake-up
The AC-Link protocol provides for a “Cold AC‘97 Reset”, and a “Warm AC‘97 Reset”. The current
powerdown state ultimately dictates which form of AC‘97 reset is appropriate. Unless a “cold” or
“register” reset (a write to the Reset Register) is performed, wherein the AC‘97 registers are initial-
ized to their default values, registers are required to keep state during all powerdown modes.
SYNC
BIT_CLK
SDATA_OUT
Note: BIT_CLK not to scale
SDATA_IN
TAG Write to
0x20
slot 2
per
frame
DATA
PR4
TAG
slot 2
per
frame
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Once powered down, re-activation of the AC-Link via re-assertion of the SYNC signal must not occur
for a minimum of four audio frame times following the frame in which the powerdown was triggered.
When AC-Link powers up, the CODEC indicates readiness via the CODEC Ready bit (input slot 0,
bit 15).
4.6.2.2. CODEC Initiates Wake-up
The STAC9752/9753 (running off Vaux) can trigger a wake event (PME#) by transitioning SDATA_IN
from low to high and holding it high until either a warm or cold reset is observed on the AC-Link. This
functionality is typically implemented in modem CODECs that detect ring, Caller ID, etc.
Note that when the AC-Link is either programmed to the low power mode or shut off completely,
BIT_CLK may stop if the primary CODEC is supplying the clock, which shuts down the AC-Link clock
to the Secondary CODEC1. In order for a Secondary CODEC to react to an external event (phone
ringing), it must support an independent clocking scheme for any PME# associated logic that must
be kept alive when the AC-Link is down. This includes logic to asynchronously drive SDATA_IN to a
logic high-level which signals a wake request to the AC‘97 Digital Controller.
4.6.3. CODEC Reset
There are three types of AC‘97 reset:
•a cold reset where all AC‘97 logic (most registers included) is initialized to its default state
•a warm reset where the contents of the AC‘97 register set are left unaltered
•a register reset which only initializes the AC‘97 registers to their default states
4.6.3.1. Cold AC‘97 Reset
A cold reset is achieved by asserting RESET# (low) for the minimum specified time, then subse-
quently de-asserting RESET# (high). BIT_CLK and SDATA_IN will be activated, or re-activated as
the case may be, and all AC‘97 control registers will be initialized to their default power on reset val-
ues.
RESET# is an asynchronous AC‘97 input.
4.6.3.2. Warm AC‘97 Reset
A warm AC‘97 reset will re-activate the AC-Link without altering the current AC‘97 register values. A
warm reset is signaled by driving SYNC high for a minimum of 1 ms in the absence of BIT_CLK.
Within normal audio frames, SYNC is a synchronous AC‘97 input. However, in the absence of
BIT_CLK, SYNC is treated as an asynchronous input used in the generation of a warm reset to
AC‘97.
AC‘97 MUST NOT respond with the activation of BIT_CLK until SYNC has been sampled low again
by AC‘97. This will preclude the false detection of a new audio frame.
4.6.3.3. Register AC‘97 Reset
Most registers in an AC device can be restored to their default values by performing a write (any
value) to the Reset Register, 00h.
1. Secondary CODECs always configure the BIT_CLK pin as an input.
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5. AC-LINK DIGITAL INTERFACE
5.1. Overview
AC-Link is the 5 pin digital serial interface that links the AC‘97 CODEC to the Controller. The AC-Link
protocol is a bi-directional, fixed clock rate, serial digital stream. AC-Link handles multiple input and
output PCM audio streams, as well as control register accesses employing a time division multi-
plexed (TDM) scheme that divides each audio frame into 12 outgoing and 12 incoming data streams,
each with 20-bit sample resolution.
The STAC9752/9753 DACs, ADCs, and SPDIF can be assigned to slots 3&4, 6&9, 7&8 or 10&11.
Figure 14. Bi-directional AC-Link Frame with Slot assignments
Table 4. AC-Link output slots (transmitted from the Controller)
Slot Name Description
0 SDATA_OUT TAG MSBs indicate which slots contain valid data; LSBs convey
CODEC ID
1 Control CMD ADDR write port Read/write command bit plus 7-bit CODEC register address
2 Control DATA write port 16-bit command register write data
3, 4 PCM L&R DAC playback 20-bit PCM data for Left and Right channels
5 Modem Line 1 DAC 16-bit modem data for modem Line 1 output
6, 7, 8, 9 PCM Center, Surround L&R, LFE 20-bit PCM data for Center, Surround L&R, LFE channels
10 Modem Line 2 DAC 16-bit modem data for modem Line 2 output
11 Modem handset DAC 16-bit modem data for modem Handset output
12 Modem I/O control GPIO write port for modem Control
12 CODEC IRQ Can be used by CODEC if a modem CODEC is not present.
10-11 SPDIF Out Optional AC-Link bandwidth for SPDIF output
10-12 Double rate audio Optional AC-Link bandwidth for 88.2 KHz or 96 KHz on L, C, R
channels
PCM
MIC
Vendor
RSVD
Vendor
RSVD
LINE2
ADC
HSET
ADC
Vendor
RSVD
STATUS
ADDR
OUTGOING STREAMS
(Controller output - SDATA_OUT)
INCOMING STREAMS
(codec output - SDATA_IN)
SYNC
TAG PHASE
DATA PHASE
PCM
LEFT
CMD
ADDR NA PCM
LSURR
PCM
LFE SPDIFTAG CMD
DATA
PCM
RT
PCM
CTR
PCM
RSURR SPDIF IO
CTRL
PCM
LEFT
LINE1
ADC
TAG STATUS
DATA
PCM
RT
IO
STATUS
SLOTS 0123456789101112
Slot 12 can be used by the
AC'97 Codec if a Modem
Codec is not present.
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5.2. AC-Link Serial Interface Protocol
The AC‘97 Controller signals synchronization of all AC-Link data transactions. The AC‘97 CODEC,
Controller, or external clock source drives the serial bit clock (BIT_CLK) onto AC-Link, which the
AC‘97 Controller then qualifies with a synchronization signal (SYNC) to construct audio frames.
SYNC, fixed at 48 KHz, is derived by dividing down the serial bit clock (BIT_CLK). BIT_CLK, fixed at
12.288 MHz, provides the necessary clocking granularity to support 12 20-bit outgoing and incoming
time slots. AC-Link serial data is transitioned on each rising edge of BIT_CLK. The receiver of
AC-Link data (CODEC for outgoing data and Controller for incoming data) samples each serial bit on
the falling edges of BIT_CLK.
The AC-Link protocol provides for a special 16-bit time slot (Slot 0) wherein each bit conveys a valid
tag for its corresponding time slot within the current audio frame. A 1 in a given bit position of slot 0
indicates that the corresponding time slot within the current audio frame has been assigned to a data
stream, and contains valid data. If a slot is tagged invalid, it is the responsibility of the source of the
data (AC‘97 CODEC for the input stream, AC‘97 Controller for the output stream), to stuff all bit posi-
tions with 0 during that slot’s active time.
SYNC remains high for a total duration of 16 BIT_CLKs at the beginning of each audio frame. The
portion of the audio frame where SYNC is high is defined as the “Tag Phase”. The remainder of the
audio frame where SYNC is low is defined as the “Data Phase”.
Additionally, for power savings, all clock, sync, and data signals can be halted. This requires that an
AC‘97 CODEC be implemented as a static design to allow its register contents to remain intact when
entering a power savings mode.
5.2.1. AC-Link Variable Sample Rate Operation
The AC-Link serial interconnect defines a digital data and control pipe between the Controller and
the CODEC. The AC-Link supports 12 20-bit slots at 48 KHz on SDATA_IN and SDATA_OUT. The
time division multiplexed (TDM) “slot-based” architecture supports a per-slot valid tag infrastructure
that the source of each slot’s data sets or clears to indicate the validity of the slot data within the cur-
rent audio frame. This tag infrastructure can be used to support transfers between Controller and
CODEC at any sample rate.
5.2.2. Variable Sample Rate Signaling Protocol
AC-Link’s tag infrastructure imposes FIFO requirements on both sides of the AC-Link. For example,
in passing a 44.1 KHz stream across the AC-Link, for every 480 audio output frames that are sent
across, 441 of them must contain valid sample data. Does the AC‘97 Digital Controller pass all 441
PCM samples followed by 39 invalid slots? Or does the AC‘97 Digital Controller evenly interleave
Table 5. The AC-Link input slots (transmitted from the CODEC)
Slot Name Description
0 SDATA_IN TAG MSBs indicate which slots contain valid data
1 STATUS ADDR read port MSBs echo register address; LSBs indicate which slots request data
2 STATUS DATA read port 16-bit command register read data
3, 4 PCM L&R ADC record 20-bit PCM data from Left and Right inputs
5 Modem Line 1 ADC 16-bit modem data from modem Line1 input
6-11 PCM ADC Record 20-bit PCM data - Alternative Slots for Input
12 GPIO Status GPIO read port and interrupt status
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valid and non-valid slots? Each possible method brings with it different FIFO requirements. To
achieve interoperability between AC‘97 Digital Controllers and CODECs designed by different man-
ufacturers, it is necessary to standardize the scheme for at least one side of the AC-Link so that the
FIFO requirements will be common to all designs. The CODEC side of the AC-Link is the focus of
this standardization.
The new standard approach calls for the addition of “on demand” slot request flags. These flags are
passed from the CODEC to the AC‘97 Digital Controller during every audio input frame. Each time
the AC‘97 Digital Controller sees one or more of the newly-defined slot request flags set active (low)
in a given audio input frame, it knows that it must pass along the next PCM sample for the corre-
sponding slot(s) in the AC-Link output frame that immediately follows.
The VRA (Variable Rate Audio) bit in the Extended Audio Status and Control Register must be set to
1 to enable variable sample rate audio operation. Setting the VRA = 1 has two functions:
1. Enables PCM DAC/ADC conversions at variable sample rates by write enabling Sample Rate
Registers 2Ch through 34h.
2. Enables the on demand CODEC-to-Controller signaling protocol using SLOTREQ bits that
becomes necessary when a DAC’s sample rate varies from the 48 KHz AC-Link serial frame
rate.
The table below summarizes the behavior:
Note: If more than one CODEC is being used with the SAME controller DMA engine, VRA should
NOT be used.
For variable sample rate output, the CODEC examines its sample rate control registers, the state of
its FIFOs, and the incoming SDATA_OUT tag bits at the beginning of each AC-Link output frame to
determine which SLOTREQ bits to set active (low). SLOTREQ bits asserted during the current
AC-Link input frame signal which active output slots require data from the AC‘97 Digital Controller in
the next audio output frame. An active output slot is defined as any slot supported by the CODEC
that is not in a power-down state. For fixed 48 KHz operation the SLOTREQ bits are always set
active (low) and a sample is transferred in each frame.
For variable sample rate input, the tag bit for each input slot indicates whether valid data is present
or not. Thus, even in variable sample rate mode, the CODEC is always the master: for SDATA_IN
(CODEC to Controller), the CODEC sets the TAG bit; for SDATA_OUT (Controller to CODEC), the
CODEC sets the SLOTREQ bit and then checks for the TAG bit in the next frame.
The VRM (Variable Rate Microphone Audio) bit in the Extended Audio Status and Control Register
controls the optional MIC ADC input behavior in the same way that VRA = 1 controls the PCM ADC.
5.2.2.1. SLOTREQ Behavior and Power Management
SLOTREQ bits for fixed rate, powered down, and all unsupported Slots should be driven low (zero)
for maximum compatibility with the original AC'97 Component Specification. When a DAC channel is
powered down, it disappears completely from the serial frame: output tag and slot are ignored, and
the SLOTREQ bit is absent (forced to zero).
Table 6. VRA Behavior
AC‘97 Functionality VRA = 0 VRA = 1
SLOTREQ bits always 0 (data each frame) 0 or 1 (data on demand)
sample rate registers forced to 48 KHz writable
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When the Controller wants to power-down a channel, all it needs to do is:
1. Disable source of DAC samples in Controller
2. Set PR bit for DAC channel in Registers 26h, 2Ah, or 3Eh
When it wants to power up the channel, all it needs to do is:
1. Clear PR bit for DAC channel in Registers 26h, 2Ah, or 3Eh
2. Enable source of DAC samples in Controller
5.2.3. Primary and Secondary CODEC Register Addressing
The 2-bit CODEC ID field in the LSBs of Output Slot 0 is an addition to the original AC-Link protocol
that enables an AC‘97 Digital Controller to independently access Primary and Secondary CODEC
registers.
For Primary CODEC access, the AC‘97 Digital Controller:
1. Sets the AC-Link Frame valid bit (Slot 0, bit 15)
2. Validates the tag bits for Slot 1 and 2 Command Address and Data (Slot 0, bits 14 and 13)
3. Sets a zero value (00) into the CODEC ID field (Slot 0, bits 1 and 0)
4. Transmits the desired Primary CODEC Command Address and Command Data in Slots 1 and 2
For Secondary CODEC access, the AC‘97 Digital Controller:
1. Sets the AC-Link Frame valid bit (Slot 0, bit 15)
2. Places a non-zero value (01, 10, or 11) into the CODEC ID field (Slot 0, bits 1 and 0)
3. Transmits the desired Secondary CODEC Command Address and Command Data in Slots 1
and 2
Secondary CODECs disregard the Command Address and Command Data (Slot 0, bits 14 and 13)
tag bits. In a sense the Secondary CODEC ID field functions as an alternative Valid Command
Address (for Secondary reads and writes) and Command Data (for Secondary writes) tag indicator.
Secondary CODECs must monitor the Frame Valid bit, and ignore the frame (regardless of the state
of the Secondary CODEC ID bits) if it is not valid. AC‘97 Digital Controllers should set the frame valid
bit for a frame with a Secondary register access, even if no other bits in the output tag slot except the
Secondary CODEC ID bits are set.
5.3. AC-Link Output Frame (SDATA_OUT)
The AC-Link output frame data streams correspond to the multiplexed bundles of all digital output
data targeting AC‘97’s DAC inputs and control registers. As mentioned earlier, each AC-Link output
frame supports up to 12 20-bit outgoing data time slots. Slot 0 is a special reserved time slot contain-
ing 16-bits which are used for AC-Link protocol infrastructure.
Figure 15 illustrates the time slot based AC-Link protocol.
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Figure 15. AC-Link Audio Output Frame
A new AC-Link output frame begins with a low to high transition of SYNC. SYNC is synchronous to
the rising edge of BIT_CLK. On the immediately following falling edge of BIT_CLK, the AC‘97
CODEC samples the assertion of SYNC. This falling edge marks the time when both sides of
AC-Link are aware of the start of a new audio frame. On the next rising of BIT_CLK, the AC‘97 Con-
troller transitions SDATA_OUT into the first bit position of slot 0 (Valid Frame bit). Each new bit posi-
tion is presented to AC-Link on a rising edge of BIT_CLK, and subsequently sampled by the AC‘97
CODEC on the following falling edge of BIT_CLK. This sequence ensures that data transitions and
subsequent sample points for both incoming and outgoing data streams are time aligned.
Figure 16. Start of an Audio Output Frame
SDATA_OUT’s composite stream is sent MSB first, with all non-valid slots bit positions stuffed with 0
by the AC‘97 Controller. If there are less than 20 valid bits within an assigned and valid time slot, the
AC‘97 Controller always stuffs the trailing non-valid bit positions of the 20-bit slot with 0.
As an example, consider an 8-bit sample stream that is being played out to one of the
STAC9752/9753 DACs. The first 8 bit-positions are presented to the DAC (MSB first) followed by the
next 12 bit-positions which are stuffed with 0 by the AC‘97 Controller. This ensures that regardless of
the resolution of the implemented DAC (16, 18 or 20-bit), no DC biasing will be introduced by the
least significant bits.
When mono audio sample streams are output from the AC‘97 Controller, it is necessary that BOTH
left and right sample stream time slots be filled with the same data.
SYNC
BIT_CLK
SDATA_OUT slot1 slot2
End of previous audio frame
slot(12) "0" 19
Data Phase
20.8 uS (48 kHZ)Tag Phase
12.288 MHz
Time Slot "Valid" Bits Slot 1 Slot 2 Slot 3 Slot 12
("1" = time slot contains valid PCM data)
CID1 CID0
valid "0" 19 19"0"
Frame 19"0" "0"
SYNC
BIT_CLK
SDATA_OUT slot1 slot2
End of previous audio fram e
valid
Fram e
SYNC
asserted
first
SDATA_OUT
bit of fram e
SYNC
detected by
codec
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5.3.1. Slot 0: TAG / CODEC ID
Table 7. Output Slot 0 Bit Definitions
Within slot 0, the first bit is a global bit (SDATA_OUT slot 0, bit 15) which flags the validity for the
entire audio frame. If the “Valid Frame” bit is a 1, this indicates that the current audio frame contains
at least one time slot of valid data. The next 12 bit positions sampled by AC‘97 indicate which of the
corresponding 12 time slots contain valid data. In this way data streams of differing sample rates can
be transmitted across AC-Link at its fixed 48 KHz audio frame rate.
The two LSBs of Slot 0 transmit the CODEC ID used to distinguish Primary and Secondary CODEC
register access.
5.3.2. Slot 1: Command Address Port
The command port is used to control features and monitor status (see AC-Link input frame Slots 1
and 2) for AC‘97 CODEC functions including, but not limited to, mixer settings, and power manage-
ment (refer to the control register section of this specification).
The control interface architecture supports up to 64 16-bit read/write registers, addressable on even
byte boundaries. Only the even registers (00h, 02h, etc.) are currently defined, odd register (01h,
03h, etc.) accesses are reserved for future expansion.
Note that shadowing of the control register file on the AC‘97 Controller is an option left open to the
implementation of the AC‘97 Controller. The AC97 CODEC’s control register file is nonetheless
required to be readable as well as writeable to provide more robust testability.
Bit Description
15 Frame Valid
14 Slot 1 Primary CODEC Valid Command Address bit (Primary CODEC only)
13 Slot 2 Primary CODEC Valid Command Data bit (Primary CODEC only)
Slot 3-12 Valid Data bits
12 Slot 3: PCM Left channel
11 Slot 4: PCM Right channel
10 Slot 5: Modem Line 1 (not used on STAC9752/9753)
9 Slot 6: Alternative PCM1 Left
8 Slot 7: Alternative PCM2 Left
7 Slot 8: Alternative PCM2 Right
6 Slot 9: Alternative PCM1 Right
5 Slot 10: SPDIF Left
4 Slot 11: SPDIF Right
3 Slot 12: Audio GPIO
2 Reserved (Set to 0)
1-0 2-bit CODEC ID field (00 reserved for Primary; 01, 10, 11 indicate Secondary)
Note: The DAC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
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AC-Link output frame slot 1 communicates control register address, and write/read command infor-
mation to the STAC9752/9753.
The first bit (MSB) sampled by AC‘97 indicates whether the current control transaction is a read or a
write operation. The following 7 bit positions communicate the targeted control register address. The
trailing 12 bit positions within the slot are reserved and must be stuffed with 0 by the AC‘97 Control-
ler.
5.3.3. Slot 2: Command Data Port
The command data port is used to deliver 16-bit control register write data in the event that the cur-
rent command port operation is a write cycle (as indicated by Slot 1, bit 19).
Bit(19:4) Control Register Write Data (Stuffed with 0 if current operation is a read)
Bit(3:0) Reserved (Stuffed with 0)
If the current command port operation is a read then the entire slot time must be stuffed with 0 by the
AC‘97 Controller.
5.3.4. Slot 3: PCM Playback Left Channel
AC-Link output frame slot 3 is the composite digital audio left playback stream. In a typical “Games
Compatible” PC this slot is composed of standard PCM (.wav) output samples digitally mixed (on the
AC‘97 Controller or host processor) with music synthesis output samples. If a sample stream of res-
olution less than 20-bits is transferred, the AC‘97 Controller must stuff all trailing non-valid bit posi-
tions within this time slot with 0.
The DAC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.3.5. Slot 4: PCM Playback Right Channel
AC-Link output frame slot 4 is the composite digital audio right playback stream. In a typical “Games
Compatible” PC this slot is composed of standard PCM (.wav) output samples digitally mixed (on the
AC‘97 Controller or host processor) with music synthesis output samples. If a sample stream of res-
olution less than 20-bits is transferred, the AC‘97 Controller must stuff all trailing non-valid bit posi-
tions within this time slot with 0.
The DAC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.3.6. Slot 5: Modem Line 1 Output Channel
Audio output frame slot 5 is reserved for modem operation and is not used by the STAC9752/9753.
Table 8. Command Address Port Bit Assignments
Bit Description Comments
19 Read/Write command 1= read, 0 = write
18:12 Control Register Index Sixty-four 16-bit locations, addressed on even byte boundaries
11:0 Reserved Stuffed with 0
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5.3.7. Slot 6 - 11: DAC
The DAC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.3.8. Slot 12: Audio GPIO Control Channel
AC-Link output frame slot 12 contains the audio GPIO control outputs.
5.4. AC-Link Input Frame (SDATA_IN)
The AC-Link input frame data streams correspond to the multiplexed bundles of all digital input data
targeting the AC‘97 Controller. As is the case for audio output frame, each AC-Link input frame con-
sists of 12 20-bit time slots. Slot 0 is a special reserved time slot containing 16-bits which are used
for AC-Link protocol infrastructure.
The following diagram illustrates the time slot-based AC-Link protocol.
Figure 17. STAC9752/9753 Audio Input Frame
A new AC-Link input frame begins with a low to high transition of SYNC. SYNC is synchronous to
the rising edge of BIT_CLK. On the immediately following falling edge of BIT_CLK, the AC‘97
CODEC samples the assertion of SYNC. This falling edge marks the time when both sides of
AC-Link are aware of the start of a new audio frame. On the next rising of BIT_CLK, the AC‘97
CODEC transitions SDATA_IN into the first bit position of slot 0 (“CODEC Ready” bit). Each new bit
position is presented to AC-Link on a rising edge of BIT_CLK, and subsequently sampled by the
AC‘97 Controller on the falling edge of BIT_CLK. This sequence ensures that data transitions and
subsequent sample points for both incoming and outgoing data streams are time aligned.
Figure 18. Start of an Audio Input Frame
SYNC
BIT_CLK
SDATA_IN slot1 slot2
End of previous audio frame
slot(12) "0" 19
Data Phase
20.8 uS (48 kHZ)Tag Phase
12.288 MHz
Time Slot "Valid" Bits Slot 1 Slot 2 Slot 3 Slot 12
("1" = time slot contains valid PCM data)
valid "0" 19 19"0"
Frame 19"0" "0""0" "0"
SYNC
BIT_CLK
SDATA_IN slot1 slot2
End of previous audio fram e
Codec
R eady
SYNC
detected
firs t
SDATA_OUT
bit of fram e
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SDATA_IN’s composite stream is MSB first with all non-valid bit positions (for assigned and/or unas-
signed time slots) stuffed with 0 by the AC‘97 CODEC. SDATA_IN data is sampled on the falling
edges of BIT_CLK.
5.4.1. Slot 0: TAG
Within slot 0 the first bit is a global bit (SDATA_IN slot 0, bit 15) which flags whether the AC‘97
CODEC is in the “CODEC Ready” state or not. If the “CODEC Ready” bit is a 0, this indicates that
the AC‘97 CODEC is not ready for normal operation. This condition is normal following the deasser-
tion of power-on-reset for example, while the AC‘97 CODEC’s voltage references settle. When the
AC-Link “CODEC Ready” indicator bit is a 1, it indicates that the AC-Link and AC‘97 CODEC control
and status registers are in a fully operational state. The CODEC must assert “CODEC Ready” within
400 ms after it starts receiving valid SYNC pulses from the controller, to provide indication of connec-
tion to the link and Control/Status registers are available for access. The AC‘97 Controller and
related software must wait until all of the lower four bits of the Control/Status Register, 26h, are set
before attempting any register writes, or attempting to enable any audio stream, to avoid undesirable
audio artifacts.
Prior to any attempts at putting an AC‘97 CODEC into operation, the AC‘97 Controller should poll the
first bit in the AC-Link input frame (SDATA_IN slot 0, bit 15) for an indication that CODEC has gone
“CODEC Ready”. Once an AC‘97 CODEC is sampled “CODEC Ready”1, then the next 12 bit posi-
tions sampled by the AC‘97 Controller indicate which of the corresponding 12 time slots are
assigned to input data streams, and whether they contain valid data.
5.4.2. Slot 1: Status Address Port / SLOTREQ signalling bits
5.4.2.1. Status Address Port
The status port is used to monitor status for the STAC9752/9753 functions including, but not limited
to, mixer settings and power management. AC-Link input frame slot 1’s stream echoes the control
register index, for historical reference, for the data to be returned in slot 2 (assuming that slots 1 and
2 had been tagged “valid” by the AC‘97 CODEC during slot 0).
The first bit (MSB) generated by AC‘97 is always stuffed with a 0. The following 7 bit positions com-
municate the associated control register address, the next 10 bits support AC‘97’s variable sample
rate signaling protocol, and the trailing 2 bit positions are stuffed with 0 by AC‘97.
5.4.2.2. SLOTREQ signaling bits
AC-Link input frame Slot #1, the Status Address Port, now delivers CODEC control register read
address and variable sample rate slot request flags for all output slots. Ten of the formerly reserved
least significant bits have been defined as data request flags for output slots 3-12.
1. There are several subsections within an AC‘97 CODEC that can independently go busy/ready. It is the responsibility of the
AC’97 Controller to probe more deeply into the AC‘97 CODEC’s register file to determine which subsections are actually ready.
Table 9. Status Address Port Bit Assignments
Bit Description Comments
19 Reserved Stuffed with 0
18:12 Control Register Index Echo of register index for which data is being returned
11:2 SLOTREQ See Next Section
1:0 Reserved Stuffed with 0
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The AC-Link input frame Slot 1 tag bit is independent of the bit 11-2 slot request field, and ONLY indi-
cates valid Status Address Port data (Control Register Index). The CODEC should only set
SDATA_IN tag bits for Slot 1 (Address) and Slot 2 (Data) to 1 when returning valid data from a previ-
ous register read. They should otherwise be set to 0. SLOTREQ bits have validity independent of the
Slot 1 tag bit.
SLOTREQ bits are always 0 in the following cases:
fixed rate mode (VRA = 0)
inactive (powered down) ADC channel
SLOTREQ bits are only set to 1 by the CODEC in the following case:
Variable rate audio mode (VRA = 1) AND active (power ready) ADC AND a non-48 KHz ADC
sample rate AND CODEC does not need a sample
5.4.3. Slot 2: Status Data Port
The status data port delivers 16-bit control register read data.
If Slot 2 is tagged invalid by AC‘97, then the entire slot will be stuffed with 0 by AC‘97.
5.4.4. Slot 3: PCM Record Left Channel
Audio input frame slot 3 is the left channel output of STAC9752/9753 input MUX, post-ADC.
STAC9752/9753 ADCs are implemented to support 20-bit resolution.
NOTE: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.4.5. Slot 4: PCM Record Right Channel
Audio input frame slot 4 is the right channel output of STAC9752/9753 input MUX, post-ADC.
STAC9752/9753 ADCs are implemented to support 20-bit resolution.
NOTE: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.4.6. Slot 5: Modem Line 1 ADC
Audio input frame slot 5 is not used by the STAC9752/9753 and is always stuffed with 0.
5.4.7. Slot 6 - 9: ADC
The left and right ADC channels of the STAC9752/9753 may be assigned to slots 6&9 by Register
6Eh.
NOTE: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
Table 10. Status Data Port Bit Assignments
Bit Description Comments
19:4 Control Register Read Data Stuffed with 0 if tagged “invalid”
3:0 Reserved Stuffed with 0
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5.4.8. Slots 7 & 8: Vendor Reserved
The left and right ADC channels of the STAC9752/9753 may be assigned to slots 7&8 by Register
6Eh.
NOTE: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.4.9. Slot 10 & 11: ADC
The left and right ADC channels of the STAC9752/9753 may be assigned to slots 10&11 by Register
6Eh.
NOTE: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
5.4.10. Slot 12: Reserved
AC-Link input frame slot 12 contains the GPIO status inputs and allows for audio interrupts. Slot 12
can not be used by the AC’97 CODEC because a modem CODEC is not present.
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5.5. AC-Link Interoperability Requirements and Recommendations
5.5.1. “Atomic slot” Treatment of Slot 1 Address and Slot 2 Data
Command or Status Address and Data cannot be split across multiple AC-Link frames. The following
transactions require that valid Slot 1 Address and valid Slot 2 Data be treated as “atomic” (insepara-
ble) with Slot 0 Tag bits for Address and Data set accordingly (that is, both valid):
1. AC‘97 Digital Controller write commands to Primary CODECs
2. AC‘97 CODEC status responses
Whenever the AC‘97 Digital Controller addresses a Primary CODEC or an AC‘97 CODEC responds
to a read command, Slot 0 Tag bits should always be set to indicate actual Slot 1 and Slot 2 data
validity.
When the AC‘97 Digital Controller addresses a Secondary CODEC, the Slot 0 Tag bits for Address
and Data must be 0. A non-zero, 2-bit CODEC ID in the LSBs of Slot 0 indicates a valid Read or
Write Address in Slot 1, and the Slot 1 R/W bit indicates presence or absence of valid Data in Slot 2.
Table 11. Primary CODEC Addressing: Slot 0 Tag Bits
Function
Slot 0, bit 15
(Valid
Frame)
Slot 0, bit 14
(Valid Slot 1
Address)
Slot 0, bit 13
(Valid Slot 2 Data)
Slot 0, Bits 1-0
(CODEC ID)
AC‘97 Digital Controller Primary
Read Frame N, SDATA_OUT 11 000
AC‘97 Digital Controller Primary
Write Frame N, SDATA_OUT 11 100
AC‘97 CODEC Status Frame
N+1, SDATA_IN 11 100
Table 12. Secondary CODEC Addressing: Slot 0 Tag Bits
Function
Slot 0, bit 15
(Valid
Frame)
Slot 0, bit 14
(Valid Slot 1
Address)
Slot 0, bit 13
(Valid Slot 2
Data)
Slot 0, Bits
1-0
(CODEC ID)
AC‘97 Digital Controller
Secondary Read Frame N,
SDATA_OUT
1 0 0 01, 10, or 11
AC‘97 Digital Controller
Secondary Write Frame N,
SDATA_OUT
1 0 0 01, 10, or 11
AC‘97 CODEC Status Frame N+1,
SDATA_IN 11 100
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5.6. Slot Assignments for Audio
Figure 19. Bi-directional AC-Link Frame with Slot assignments
Note: The DAC & ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
The AC-Link output slots dedicated to audio are defined as follows:
The AC-Link input slots dedicated to audio are defined as follows:
Note: The ADC can be assigned to slots 3&4, 6&9, 7&8, or 10&11.
Table 13. AC-Link Slot Definitions
Slot Name Description
3 PCM L DAC playback 20-bit PCM data for Left channel
4 PCM R DAC playback 20-bit PCM data for Right channel
6 PCM Center 20-bit PCM data for Center channel
7 PCM L Surround 20-bit PCM data for L Surround channel
8 PCM R Surround 20-bit PCM data for R Surround channel
9 PCM LFE 20-bit PCM data for LFE channel
10:11 SPDIF Out 20-bit SPDIF Output
12 Reserved Reserved
Table 14. AC-Link Input Slots Dedicated To Audio
Slot Name Description
3 PCM L ADC record 20-bit PCM data from Left input
4 PCM R ADC record 20-bit PCM data from Right inputs
6 Dedicated Microphone ADC 20-bit PCM data from optional 3rd ADC input
7 Vendor reserved Vendor specific (enhanced input for docking, array mic, etc.)
8 Vendor reserved Vendor specific (enhanced input for docking, array mic, etc.)
9 Vendor reserved Vendor specific (enhanced input for docking, array mic, etc.)
12 Audio Interrupt Provides optional interrupt capability for Audio CODEC (not usable when
a modem is present)
PCM
MIC
Vendor
RSVD
Vendor
RSVD
LINE2
ADC
HSET
ADC
Vendor
RSVD
STATUS
ADDR
OUTGOING STREAMS
(Controller output - SDATA_OUT)
INCOMING STREAMS
(codec output - SDATA_IN)
SYNC
TAG PHASE
DATA PHASE
PCM
LEFT
CMD
ADDR NA PCM
LSURR
PCM
LFE SPDIFTAG CMD
DATA
PCM
RT
PCM
CTR
PCM
RSURR SPDIF IO
CTRL
PCM
LEFT
LINE1
ADC
TAG STATUS
DATA
PCM
RT
IO
STATUS
SLOTS 0123456789101112
Slot 12 can be used by the
AC'97 Codec if a Modem
Codec is not present.
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Table 15. Audio Interrupt Slot Definitions
Bit Description
19-1 Reserved (Audio CODEC will return zeros in bits 19-1)
0Optional: Assertion = 1 will cause interrupt to be propagated to Audio controller system interrupt. See
register 24h definition for enabling mechanism.
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6. STAC9752/9753 MIXER
The STAC9752/9753 includes an analog mixer for maximum flexibility. The analog mixer is designed
to the AC'97 specification to manage the playback and record of all digital and analog audio sources
in the PC environment. The analog mixer also includes several extensions of the AC’97 specification
to support “all analog record” capability as well as “POP BYPASS” mode for all digital playback. The
analog sources include:
System Audio: digital PCM input and output for business, games & multimedia
CD/DVD: analog CD/DVD-ROM audio with internal connections to CODEC mixer
Mono microphone: choice of desktop microphone, with programmable boost and gain
Speakerphone: use of system microphone and speakers for telephone, DSVD, and video con-
ferencing
Video: TV tuner or video capture card with internal connections to CODEC mixer
AUX/synth: analog FM or wavetable synthesizer, or other internal source
Line in: external analog line level source from consumer audio, video camera, etc.
Source Function Connection
PC_BEEP PC BEEP pass through to LINE_OUT from PC_BEEP output
PHONE MONO input from telephony subsystem
MIC1 desktop microphone from microphone jack
MIC2 second microphone from second microphone jack
LINE_IN external audio source from line-in jack
CD audio from CD-ROM cable from CD-ROM
VIDEO audio from TV tuner or video camera cable from TV or VidCap card
AUX upgrade synth or other external source internal connector
PCM_OUT digital audio output from AC'97 Controller AC-Link
Destination Function Connection
HP_OUT stereo mix of all sources To headphone out jack
LINE_OUT stereo mix of all sources To output jack
MONO_OUT microphone or MONO Analog mixer output to telephony subsystem
PCM_IN digital data from the CODEC to the AC'97 Controller AC-Link
SPDIF SPDIF digital audio output To SPDIF output connector
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7. MIXER FUNCTIONAL DIAGRAMS
Figure 20. STAC9752 2-Channel Mixer Functional Diagram
Figure 21. STAC9753 2-Channel Mixer Functional Diagram
0Ah
0Ch
0Eh
10h
12h
16h
14h
PC _ BEEP
Phone
CD
AU X
VID EO
LINEIN
MIC1
MIC2
20h:D8
10, 20 or
30 dB
AllAnalog
vs
AllRecord
6E h:D12
-6dB
MU X
ADC
04h
Mono
Volume
Ma s t e r
Volume
3D LINE_OUT
3D
HP_OUT
02h
06h
MUX
1Ch
20h:D15
An a lo g
Au d io
So ur c e s
Slot
Select
Slot
Select
MUX
PCM to
SPDIF SPDIF
PC MO u t
2Ah:D5-D4
28h: D5-D4
PCMIn
20h:D13
22h:D2-D3
1A h
-6dB
MonoAnalog
StereoAnalog
Digi tal
KEY
20h:D9
ADCRecord
MUX
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
MUX
DAC
Record
Volume
6A h:D1
18h
Headphone
Volume
MONO_OUT
0E h:D6 & 6E:D2
Slot
Select
Digi tal
PCBeep
38h:D5-D4
20h:D13
22h:D2-D3
0Ah
0Ch
0Eh
10h
12h
16h
14h
PC _ BEEP
Phone
CD
AU X
VID EO
LINEIN
MIC 1
MIC 2
20h:D8
10, 20 or
30 dB
AllAnalog
vs
AllRec ord
6Eh:D12
-6dB
MUX
ADC
04h
Mo n o
Volume
Ma s t e r
Volume
3D LINE_OUT
3D
HP_OUT
02h
06h
MUX
1Ch
20h:D15
Analog
Au d io
Sources
Slot
Select
Slot
Select
MUX
PCM to
SPDIF SPDIF
PC MO ut
2Ah:D5-D4
28h: D5-D4
PCMIn
20h:D13
22h:D2-D3
1Ah
-6dB
MonoAnalog
StereoAnalog
Digital
KEY
20h:D9
ADCRecord
MUX
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
vol mute
MUX
DAC
Record
Volume
6Ah:D1
18h
Headphone
Volume
MONO_OUT
0Eh:D6 & 6E :D2
Slot
Select
Digital
PCBeep
38h:D5-D4
20h:D13
22h:D2-D3
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7.1. Analog Mixer Input
The mixer provides recording and playback of any audio sources or output mix of all sources. The
STAC9752/9753 supports the following input sources:
any mono or stereo source
mono or stereo mix of all sources
2-channel input w/mono output reference (microphone or stereo mix)
Note: All unused inputs should be tied together and connected to ground through a capacitor (0.1
mF suggested).
Note: The MIC should be tied to ground through a separate 0.1 mF capacitor.
7.2. Mixer Analog Output
The mixer generates three distinct outputs:
A stereo mix of all sources for output to the LINE_OUT
A stereo mix of all sources for output to HP_OUT
A mono, microphone only, or mix of all sources, for MONO_OUT
7.3. SPDIF Digital Mux
The STAC9752/9753 incorporates a digital output that supports SPDIF formats. A multiplexer deter-
mines which of two digital input streams are used for the digital output conversion process. These
two streams include the PCM_OUT data from the audio controller and the ADC recorded output. The
normal analog LINE_OUT signal can be converted to the SPDIF formats by using the internal ADC
to record the “MIX” output, which is the combination of all analog and all digital sources. In the case
of digital controllers with support for 4 or more channels, the SPDIF output mode can be used to sup-
port compressed 6-channel output streams for delivery to home theater systems. These can be
routed on alternate AC-Link slots to the SPDIF output, while the standard 2-channel output is deliv-
ered as selected by bits D5 and D4 in Register 6E. If the digital controller supports 6 channels, a
SPDIF output with 4 analog channels can also be configured.
If the Digital Controller has independent DMA engines, SPDIF and Analog can be used simultane-
ously and independently.
PIN 48: TO ENABLE SPDIF, USE AN 1 KW TO 10 KW EXTERNAL PULLDOWN. TO DISABLE SPDIF,
USE AN 1 KW TO 10 KW EXTERNAL PULLUP. DO NOT LEAVE PIN 48 FLOATING.
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7.4. PC Beep Implementation
The STAC9752/9753 offers 2 styles of PC BEEP, Analog and Digital. The digital PC Beep is a new
feature added to the AC’97 Specification Rev 2.3. This style of PC Beep will eventually replace the
analog style, thus eliminating the need for a PC Beep pin. Until this feature is widely accepted, TSI
will provide BOTH styles of PC Beep. Both PC Beep styles use Reg 0Ah. Additional information
about Reg 0Ah can be found in Section 8.1.5: page 53.
7.4.1. Analog PC Beep
PC Beep is active on power up and defaults to an un-muted state. The PC_BEEP input is routed
directly to the MONO_OUT, LINE_OUT and HP_OUT pins of the CODEC. Because the PC_BEEP
input drive is often a full scale digital signal, some resistive attenuation of the PC_BEEP input is rec-
ommended to keep the beep tone within reasonable volume levels. The user should mute this input
before using any other mixer input because the PC Beep input can contribute noise to the lineout
during normal operation. This style of PC Beep is related to the AC’97 Specification Rev 2.2. To use
the analog PC Beep, a value of 00h written to bits F[7:0] (D[12:5]) disables the Digital PC Beep gen-
eration. PV[3:0] (D[4:1]) controls the volume level from 0 to 45dB of attenuation in 3dB steps.
7.4.2. Digital PC Beep
The Digital PC Beep uses the identical register as the analog style, Reg 0Ah. This register controls
the level and frequency for the PC Beep. The beep frequency is the result of dividing the 48 KHz
clock by 4 times the number specified in F[7:0], allowing tones from 47 Hz to 12 KHz. A value of 00h
written to bits F[7:0] disables the digital PC Beep generation and enables the analog PC Beep. The
volume control bits, PV[3:0] operate identically to the analog PC Beep mode. Applying a signal to the
PC Beep pin, pin 12, may cause the digital PC Beep signal to become distorted or inaudible. When
using the digital PC Beep feature, we recommend leaving the PC Beep input pin unconnected or
connected to analog ground through a capacitor. Connecting a capacitor from the PC Beep input pin
to ground will create a more pleasing sound by changing the digital output to a more sinusoidal like
output.
This will be programmed directly by the BIOS.
Table 16. Digital PC Beep Examples
Value Reg 0Ah, bits[7:0] Frequency
1 0x01 12,000 Hz
10 0x0A 1200 Hz
25 0x19 480 Hz
50 0x32 240 Hz
100 0x64 120 Hz
127 0x7F 94.48 Hz
255 0xFF 47.05 Hz
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8. PROGRAMMING REGISTERS
Table 17. Programming Registers
Address Name Default Location
00h Reset 6A90h 8.1.1; page 50
02h Master Volume 8000h 8.1.2; page 50
04h HP_OUT Mixer Volume 8000h 8.1.3; page 51
06h Master Volume MONO 8000h 8.1.4; page 52
0Ah PC Beep Mixer Volume 0000h 8.1.5; page 53
0Ch Phone Mixer Volume 8008h 8.1.6; page 53
0Eh Microphone Mixer Volume 8008h 8.1.7; page 54
10h Line In Mixer Volume 8808h 8.1.8; page 54
12h CD Mixer Volume 8808h 8.1.9; page 56
14h Video Mixer Volume 8808h 8.1.10; page 56
16h Aux Mixer Volume 8808h 8.1.11; page 58
18h PCM Out Mixer Volume 8808h 8.1.12; page 58
1Ah Record Select 0000h 8.1.13; page 59
1Ch Record Gain 8000h 8.1.14; page 59
20h General Purpose 0000h 8.1.15; page 60
22h 3D Control 0000h 8.1.16; page 60
24h Audio Int. & Paging 0000h 8.1.17: page 61
26h Powerdown Ctrl/Stat 000Fh 8.1.18; page 62
28h Extended Audio ID 0A05h 8.1.19; page 64
2Ah Extended Audio Control/Status 0400h* 8.1.20; page 65
2Ch PCM DAC Rate BB80h 8.1.22; page 67
32h PCM LR ADC Rate BB80h 8.1.23; page 67
3Ah SPDIF Control 2000h 8.1.24; page 67
3Eh Extended Modem Stat/Ctl 0100h 8.2.4; page 69
4Ch GPIO Pin Configuration 0003h 8.2.5; page 69
4Eh GPIO Pin Polarity/Type FFFFh 8.2.6; page 70
50h GPIO Pin Sticky 0000h 8.2.7; page 70
52h GPIO Wake-up 0000h 8.2.8; page 70
54h GPIO Pin Status 0000h 8.2.9; page 71
60h CODEC Class/Rev 1201h 8.3; page 72
62h (Page 01h) PCI SVID FFFFh 8.4.2; page 74
64h (Page 01h) PCI SSID FFFFh 8.4.3; page 74
66h (Page 01h) Function Select 0000h 8.4.4; page 75
68h (Page 01h) Function Information xxxxh 8.4.5; page 76
6Ah Digital Audio Control 0000h 8.4.6; page 77
6Ah (Page01h) Sense Details NA 8.4.7: page 78
6Ch Revision Code xxxxh 8.4.7; page 78
6Ch (Page01h) Reserved 0000h NA
6Eh Analog Special 1000h 8.4.9: page 80
6Eh (Page01h) Reserved 0000h NA
70h Enable Register 0000h NA
72h Analog Current Adjust 0000h 8.4.10; page 81
74h EAPD Access 0800h 8.4.11; page 81
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8.1. Register Descriptions
8.1.1. Reset (00h)
Default: 6A90h
Writing any value to this register performs a register reset, which causes all registers to revert to
their default values. This register reset also resets all the digital block. Reading this register returns
the ID code of the part.
8.1.2. Master Volume Registers (02h)
Default: 8000h
78h High Pass Filter Bypass 0000h 8.4.12; page 82
7Ah Reserved NA NA
7Ch Vendor ID1 8384h 8.5.1; page 83
7Eh Vendor ID2 7652h 8.5.2; page 83
Note: * depends upon CODEC ID
D15 D14 D13 D12 D11 D10 D9 D8
RSRVD SE4 SE3 SE2 SE1 SE0 ID9 ID8
D7 D6 D5 D4 D3 D2 D1 D0
ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0
Bit(s) Reset Value Name Description
15 0 RESERVED Bit not used, should read back 0
14:10 11010 SE4:SE0 TSI ID for SS3D
9 1 ID9 20-bit ADC resolution (supported)
8 0 ID8 18-bit ADC resolution
7 1 ID7 20-bit DAC resolution (supported)
6 0 ID6 18-bit DAC resolution
5 0 ID5 Loudness (bass boost)
4 1 ID4 Headphone Out (supported)
3 0 ID3 Simulated Stereo (mono to stereo)
2 0 ID2 Bass & Treble Control
1 0 ID1 Reserved
0 0 ID0 Dedicated MIC PCM IN channel
D15 D14 D13 D12 D11 D10 D9 D8
Mute RSRVD ML5 ML4 ML3 ML2 ML1 ML0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED MR5 MR4 MR3 MR2 MR1 MR0
Table 17. Programming Registers (Continued)
Address Name Default Location
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8.1.3. Headphone Volume Registers (04h)
Default: 8000h
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mutes both left & right channels
14 0 RESERVED Bit not used, should read back 0
13 0 ML5 0 = Lineout attenuation is a function of bits12-8
1 = Forces register bits 12-8 to be 11111. Always reads back 0.
12:8 0 ML<4:0>
Left Lineout Volume Control
00000 = 0dB attenuation
00001 = 1.5dB attenuation
.....
11111 = 46.5dB attenuation
7:6 0 RESERVED Bits not used, should read back 0
50 MR5
0 = Lineout attenuation is a function of bits 4-0
1 = Forces register bits 4-0 to be 11111
Always reads back 0
4:0 0 MR<4:0>
Right Channel Lineout Volume Control
00000 = 0dB attenuation
00001 = 1.5dB attenuation
.....
11111 = 46.5dB attenuation
D15 D14 D13 D12 D11 D10 D9 D8
Mute RSRVD HPL5 HPL4 HPL3 HPL2 HPL1 HPL0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED HPR5 HPR4 HPR3 HPR2 HPR1 HPR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mutes both left & right channels
14 0 RESERVED Bit not used, should read back 0
13 0 ML5 0 = Headphone attenuation is a function of bits12-8
1 = Forces register bits 12-8 to be 11111. Always reads back 0
12:8 0 ML<4:0>
Left Headphone Volume Control
00000 = 0dB attenuation
00001 = 1.5dB attenuation
.....
11111 = 46.5dB attenuation
7:6 0 RESERVED Bits not used, should read back 0
50 MR5
0 = Headphone attenuation is a function of bits 4-0
1 = Forces register bits 4-0 to be 11111. Always reads back 0
4:0 0 MR<4:0>
Right Channel Headphone Volume Control
00000 = 0dB attenuation
00001 = 1.5dB attenuation
.....
11111 = 46.5dB attenuation
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8.1.4. Master Volume MONO (06h)
Default: 8000h
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED MM5 MM4 MM3 MM2 MM1 MM0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute mono
14:6 0 RESERVED Bit not used, should read back 0
5 0 MM5 0 = Mono attenuation is a function of bits 4-0
1 = Forces register bits 4-0 to be 11111. Always reads back 0
4:0 0 MM<4:0>
Mono Volume Control
00000 = 0dB attenuation
00001 = 1.5dB attenuation
.....
11111 = 46.5dB attenuation
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8.1.5. PC BEEP Volume (0Ah)
Default: 0000h
Additional information on the PC Beep can be found in Section 7.4: page 48.
8.1.6. Phone Volume (Index 0Ch)
Default: 8008h.
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED F7 F6 F5 F4 F3
D7 D6 D5 D4 D3 D2 D1 D0
F2 F1 F0 PV3 PV2 PV1 PV0 RSRVD
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute PC BEEP
14:13 0 RESERVED Bit not used, should read back 0
12:5 00h F[7:0]
The Beep frequency is the result of dividing the 48 KHz clock by 4 times
the value of the number specified in F[7:0], allowing tones from 47 Hz to
12 KHz.
A value of 00h in bits F[7:0] disables internal PC BEEP generation and
enables external PC BEEP input, if available.
4:1 0 PV(3:0)
PCBEEP Volume Control
0000 = 0dB attenuation
0001 = 3dB attenuation
.....
1111 = 45dB attenuation
0 0 RESERVED Bit not used, should read back 0
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GN4 GN3 GN2 GN1 GN0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute phone
14:5 0 RESERVED Bit not used, should read back 0
4:0 0 GN<4:0>
Phone Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
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8.1.7. Mic Volume (Index 0Eh)
Default: 8008h.
8.1.8. LineIn Volume (Index 10h)
Default: 8808h.
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED BOOSTEN RESERVED GN4 GN3 GN2 GN1 GN0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute phone
14:7 0 RESERVED Bit not used, should read back 0
60 BOOSTEN
Works with MICGAINVAL (Register 6Eh, Bit D2)
BOOSTEN MICGAINVAL = Microphone Gain Boost
0 0 = 0 dB
0 1 = 10 dB
1 0 = 20 dB
1 1 = 30 dB
5 0 RESERVED
4:0 0 GN<4:0>
Phone Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL4 GL3 GL2 GL1 GR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR4 GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute linein
14:13 0 RESERVED Bit not used, should read back 0
12:8 0 GL<4:0>
Left LineIn Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
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7:5 0 RESERVED Bit not used, should read back 0
4:0 0 GR<4:0>
Right LineIn Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
Bit(s) Reset Value Name Description
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8.1.9. CD Volume (Index 12h)
Default: 8808h.
8.1.10. Video Volume (Index 14h)
Default: 8808h.
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL4 GL3 GL2 GL1 GR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR4 GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute CD
14:13 0 RESERVED Bit not used, should read back 0
12:8 0 GL<4:0>
Left CD Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
7:5 0 RESERVED Bit not used, should read back 0
4:0 0 GR<4:0>
Right CD Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL4 GL3 GL2 GL1 GR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR4 GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute video
14:13 0 RESERVED Bit not used, should read back 0
12:8 0 GL<4:0>
Left Video Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
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7:5 0 RESERVED Bit not used, should read back 0
4:0 0 GR<4:0>
Right video Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
Bit(s) Reset Value Name Description
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8.1.11. Aux Volume (Index 16h)
Default: 8808h.
8.1.12. PCMOut Volume (Index 18h)
Default: 8808h.
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL4 GL3 GL2 GL1 GR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR4 GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute AUX
14:13 0 RESERVED Bit not used, should read back 0
12:8 0 GL<4:0>
Left Aux Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
7:5 0 RESERVED Bit not used, should read back 0
4:0 0 GR<4:0>
Right Aux Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL4 GL3 GL2 GL1 GR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR4 GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
15 1 Mute 0 = No mute
1 = Mute PCM OUT
14:13 0 RESERVED Bit not used, should read back 0
12:8 0 GL<4:0>
Left PCM Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
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8.1.13. Record Select (1Ah)
Default: 0000h (corresponding to Microphone in)
Used to select the record source independently for right and left.
8.1.14. Record Gain (1Ch)
Default: 8000h (corresponding to 0 dB gain with mute on)
7:5 0 RESERVED Bit not used, should read back 0
4:0 0 GR<4:0>
Right PCM Volume Control
00000 = 12dB gain
00001 = 10.5dB gain
.....
01000 = 0dB gain
.....
11111 = -34.5dB gain
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED SL2 SL1 SL0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED SR2 SR1 SR0
Bit(s) Reset Value Name Description
15:11 0 RESERVED Bits not used, should read back 0
10:8 0 SL2:SL0
LEFT CHANNEL INPUT SELECT
000 = Microphone
001 = CD In (left)
010 = Video In (left)
011 = Aux In (left)
100 = Line In (left)
101 = Stereo Mix (left)
110 = Mono Mix
111 = Phone
7:3 0 RESERVED Bits not used, should read back 0
2:0 0 SR2:SR0
RIGHT CHANNEL INPUT SELECT
000 = Microphone
001 = CD In (right)
010 = Video In (right)
011 = Aux In (right)
100 = Line In (right)
101 = Stereo Mix (right)
110 = Mono Mix
111 = Phone
D15 D14 D13 D12 D11 D10 D9 D8
Mute RESERVED GL3 GL2 GL1 GL0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GR3 GR2 GR1 GR0
Bit(s) Reset Value Name Description
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8.1.15. General Purpose (20h)
Default: 0000h
8.1.16. 3D Control (22h)
Default: 0000h
Bit(s) Reset Value Name Description
15 1 MUTE Mutes RECORD GAIN
14:12 0 RESERVED Bits not used, should read back 0
11:8 0 GL<3:0>
Left Channel Volume Control
0000 = 0dB gain
0001 = 1.5dB gain
....
1111 = 22.5dB gain
7:4 0 RESERVED Bits not used, should read back 0
3:0 0 GR<3:0>
Right Channel Volume Control
0000 = 0dB gain
0001 = 1.5dB gain
....
1111 = 22.5dB gain
D15 D14 D13 D12 D11 D10 D9 D8
POP BYP RESERVED 3D RESERVED MIX MS
D7 D6 D5 D4 D3 D2 D1 D0
LOOPBACK RESERVED
Bit(s) Reset Value Name Description
15 0 POP BYPASS
0 = Normal
1 = DAC bypasses mixer and connects directly to Line Out, Headphone
Out and Mono Out.
14 0 RESERVED Bit not used, should read back 0
13 0 3D 0 = 3D EFFECT disabled
1 = 3D EFFECT enabled
12:10 0 RESERVED Bits not used, should read back 0
9 0 MIX Mono Output select (0 = Mix, 1 = Microphone)
8 0 MS Microphone select (0 = Microphone1, 1 = Microphone2)
7 0 LOOPBACK
1 = Enables ADC to DAC Loopback Test
0 = Loopback Disabled
Do not send in conflicting data on AC-Link while running this.
6:0 0 RESERVED Bits not used, should read back 0
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED DP3 DP2 RESERVED
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This register is used to control the 3D stereo enhancement function, TSI Surround 3D (SS3D), built
into the AC'97 component. Note that register bits DP3-DP2 are used to control the separation ratios
in the 3D control for LINE_OUT. SS3D provides for a wider soundstage extending beyond the nor-
mal 2-speaker arrangement. Note that the 3D bit in the general purpose register (20h) must be set to
1 to enable SS3D functionality to allow the bits in 22h to take effect. The three separation ratios are
implemented. The separation ratio defines a series of equations that determine the amount of depth
difference (High, Medium, and Low) perceived during 2-channel playback. The ratios provide for
options to narrow or widen the soundstage.
8.1.17. Audio Interrupt and Paging (24h)
Default: 0000h
Bit(s) Reset Value Name Description
15:4 0 RESERVED Bits not used, should read back 0
3:2 0 DP3, DP2
LINE_OUT SEPARATION RATIO
DP3 DP2 effect
0 0 0 ( OFF )
0 1 3 ( LOW )
1 0 4.5 ( MED )
1 1 6 ( HIGH )
1:0 0 RESERVED Bits not used, should read back 0
D15 D14 D13 D12 D11 D10 D9 D8
I4 I3 I2 I1 I0 RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED PG3 PG2 PG1 PG0
Bit(s) Reset Value Access Name Description
15 0 Read / Write I4
0 = Interrupt is clear
1 = Interrupt is set
Interrupt event is cleared by writing a 1 to this bit.
The interrupt bit will change regardless of condition of interrupt
enable (I0) status. An interrupt in the GPI in slot 12 in the ACLink
will follow this bit change when interrupt enable (I0) is unmasked.
14-13 0 Read Only I3-I2
Interrupt Cause
00 = Reserved
01 = Sense Cycle Complete, sense info available.
10 = Change in GPIO input status
11 = Sense Cycle Complete and Change in GPIO input status.
These bits will reflect the general cause of the first interrupt event
generated. It should be read after interrupt status has been
confirmed as interrupting. The information should be used to scan
possible interrupting events in proper pages.
12 0 Read / Write I1
Sense Cycle
0 = Sense Cycle not in Progress
1 = Sense Cycle Start.
Writing a 1 to this bit causes a sense cycle start if supported. If
sense cycle is not supported this bit is read only.
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8.1.18. Powerdown Ctrl/Stat (26h)
Default: 000Fh
11 0 Read / Write I0
Interrupt Enable
0 = Interrupt generation is masked.
1 = Interrupt generation is un-masked.
The driver should not un-mask the interrupt unless ensured by the
AC ‘97 controller that no conflict is possible with modem slot 12 -
GPI functionality. Some AC’97 2.2 compliant controllers will not
likely support audio CODEC interrupt infrastructure. In either case,
S/W should poll the interrupt status after initiating a sense cycle
and wait for Sense Cycle Max Delay to determine if an interrupting
event has occurred.
10:4 0 Read Only RESERVED Bits not used, should read back 0
3:0 0 Read / Write PG3:PG0
Page Selector
0h = Vendor Specific
1h = Page ID 01 (See Section 8.4 for additional information on the
Paging Registers)
Fh = Reserved Pages
This register is used to select a descriptor of 16 word pages
between registers 60h to 6Fh. Value 0h is used to select vendor
specific space to maintain compatibility with AC’97 2.2 vendor
specific registers.
System S/W determines implemented pages by writing the page
number and reading the value back. All implemented pages must
be consecutive. (i.e., page 2h cannot be implemented without page
1h).
These registers are NOT reset on RESET#.
D15 D14 D13 D12 D11 D10 D9 D8
EAPD PR6 PR5 PR4 PR3 PR2 PR1 PR0
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED REF ANL DAC ADC
Bit(s) Reset Value Name Description
15 0 EAPD 1 = Forces EAPD pad to Vdd
0 = Forces EAPD pad to GND
14 0 PR6 0 = Headphone Amp powered up
1 = Headphone Amp powered down
13 0 PR5 0 = Digital Clk active
1 = Digital Clk disable.
12 0 PR4 0 = digital active
1 = Powerdown: PLL, AC-Link, Xtal oscillator;
11 0 PR3
0 = VREF and VREFOUT are active
1 = VREF and VREFOUT are powered down, and PR2 is asserted in
analog block
10 0 PR2 0 = analog active
1 = all signal path analog is powered down
90 PR1
0 = DAC powered up
1 = DAC powered down
Bit(s) Reset Value Access Name Description
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8.1.18.1. Ready Status
The lower half of this register is read only status, a 1 indicating that each subsection is “ready”.
Ready is defined as the subsection's ability to perform in its nominal state. When this register is writ-
ten, the bit values that come in on AC-Link will have no effect on read-only bits 0-7.
When the AC-Link “CODEC Ready” indicator bit (SDATA_IN slot 0, bit 15) is a 1, it indicates that the
AC-Link and AC'97 control and status registers are in a fully operational state. The AC'97 controller
must further probe this Powerdown Control/Status Register to determine exactly which subsections,
if any, are ready. When this register is written, the bit values that come in on AC-Link will have no
effect on read-only bits 0-7.
8.1.18.2. Powerdown Controls
The STAC9752/9753 is capable of operating at reduced power when no activity is required. The
state of power down is controlled by the Powerdown Register (26h). See the section “Low Power
Modes” for more information.
8.1.18.3. External Amplifier Power Down Control Output
The EAPD bit 15 of the Powerdown Control/Status Register (Index 26h) directly controls the output
of the EAPD output, pin 45, and produces a logical 1 when this bit is set to logic high. This function is
used to control an external audio amplifier power down. EAPD = 0 places approximately 0V on the
output pin, enabling an external audio amplifier. EAPD = 1 places approximately DVdd on the output
pin, disabling the external audio amplifier. Audio amplifiers that operate with reverse polarity will
likely require an external inverter to maintain software driver compatibility.
EAPD can also act as a GPIO. See Section 8.4.11: page 81. The GPIO controls in Section 8.2:
page 68 have no effect on EAPD.
80 PR0
0 = ADC powered up
1 = ADC powered down
7:4 0 RESERVED Bit not used, should read back 0
31 REF
Read Only --- VREF status
1 = VREFs enabled
21 ANL
Read Only ---- ANALOG MIXERS, etc. Status
1 = Analog Mixers ready.
11 DAC
Read Only ---- DAC Status
1 = DAC ready to playback
01 ADC
Read Only ---- ADC Status
1 = ADC ready to record
Bit(s) Reset Value Name Description
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8.1.19. Extended Audio ID (28h)
Default: 0A05h
The Extended Audio ID register is a read only register except for bits D4 and D5. ID1 and ID0 echo
the configuration of the CODEC as defined by the programming of pins 45 and 46 externally. The pri-
mary CODEC returns “00”, while any other code identifies the CODEC as one of three secondary
CODEC possibilities. The AMAP bit, D9, will return a 1 indicating that the CODEC supports the
optional “AC’97 2.3 compliant AC-Link slot to audio DAC mappings”.The default condition assumes
that 0 is loaded into the DSA0 and DSA1 bits of the Extended Audio ID (Index 28h). With 0 in the
DSA1 and DSA0 bits, the CODEC slot assignments are as per the AC’97 specification recommenda-
tions. If the DSA1 and DSA0 bits do not contain 0, the slot assignments are as per the table in the
section describing the Extended Audio ID (Index 28h). The VRA bit, D0, will return a 1 indicating that
the CODEC supports the optional variable sample rate conversion as defined by the AC’97 specifi-
cation.
D15 D14 D13 D12 D11 D10 D9 D8
ID1 ID0 RESERVED AMAP RSVD
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED DSA1 DSA0 RSVD SPDIF RSVD VRA
Table 18. Extended Audio ID Register Functions
Bit Name Access Reset Value Function
15:14 ID [1,0] Read only variable 0,0 = XTAL_OUT grounded (Note 1)
CID1#, CID0# = XTAL_OUT crystal or floating
13:12 RESERVED Read only 00 Bits not used, should read back 00
11:10 REV[1:0] Read only 10 Indicates CODEC is AC’97 Rev 2.3 compliant
9:6 RSVD Read only 0 Reserved
5:4 DSA [1,0] Read/Write 00
DAC slot assignment
If CID[1:0] = 00 then DSA[1:0] resets to 00
If CID[1:0] = 01 then DSA[1:0] resets to 01
If CID[1:0] = 10 then DSA[1:0] resets to 01
If CID[1:0] = 11 then DSA[1:0] resets to 10
00 = left slot 3, right slot 4
01 = left slot 7, right slot 8
10 = left slot 6, right slot 9
11 = left slot 10, right slot 11
3 RSVD Read only 0 RESERVED
2 SPDIF Read only 1 0 = SPDIF pulled high on reset, SPDIF disabled
1 = default, SPDIF enabled (Note 2)
1 RSVD Read only 0 RESERVED
0 VRA Read only 1 Variable sample rates supported (Always = 1)
1. External CID pin status (from analog) these bits are the logical inversion of the pin polarity (pin 45-46).
These bits are zero if XTAL_OUT is grounded with an alternate external clock source in primary mode
only. Secondary mode can either be through BIT CLK driven or 24 MHz clock driver, with XTAL_OUT
floating.
2. If pin 48 is held high at powerup, this bit will be held to zero, to indicate the SPDIF is not available.
PIN 48: TO ENABLE SPDIF, USE AN EXTERNAL 1 K
-10 K
PULLDOWN RESISTOR. TO DISABLE SPDIF, USE AN
EXTERNAL 1 K
-10 K
PULLUP RESISTOR. DO NOT LEAVE PIN 48 FLOATING.
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8.1.20. Extended Audio Control/Status (2Ah)
Default: 0400h* (*default depends on CODEC ID)
Note: If pin 48 is held high at powerup, the SPDIF is not available and bits D15:D1 can not be
written and will read back zero.
PIN 48: TO ENABLE SPDIF, USE AN EXTERNAL 1 KW -10 KW PULLDOWN RESISTOR. TO DISABLE SPDIF, USE AN
EXTERNAL 1 KW -10 KW PULLUP RESISTOR. DO NOT LEAVE PIN 48 FLOATING.
D15 D14 D13 D12 D11 D10 D9 D8
VCFG RESERVED SPCV RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED SPSA1 SPSA0 RSRVD SPDIF RSRVD VRA enable
Bit(s) Reset Value Name Description
15 VCFG
Determines the SPDIF transmitter behavior when data is not being
transmitted. When asserted, this bit forces the deassertion of the SPDIF
“Validity” flag, which is bit 28 transmitted by the SPDIF sub-frame. The “V” bit
is defined in the SPDIF Control Register (Reg 3Ah).
If “V” = 1 and “VCFG” = 0, then for each S/PDIF sub-frame (Left & Right),
bit[28] “Validity” flag reflects whether or not an internal CODEC transmission
error has occurred. Specifically an internal CODEC error should result in the
“Validity” flag being set to 1.
If “V” = 0 and “VCFG” = 1, In the case where the S/PDIF transmitter does not
receive a valid sample from the AC'97 controller, (Left or Right), the S/PDIF
transmitter should set the “Validity” flag to “0” and pad the “Audio Sample
Word” with “0”s for sub-frame in question. If a valid sample (Left or Right) was
received and successfully transmitted, the “Validity” flag should be “0” for that
sub-frame.
Default state, coming out of reset, for “V” and “VCFG” should be 0 and 0.
These bits can be set via driver .inf options.
14-11 Reserved Reserved
10 0 SPCV 0 = Invalid SPDIF configuration
1 = Valid SPDIF configuration
9:6 0 Reserved Bit not used, should read back 0
5:4 0 SPSA1:SPSA0
SPDIF slot assignment
If CID[1:0] = 00 then SPSA[1:0] resets to 01
If CID[1:0] = 01 then SPSA[1:0] resets to 10
If CID[1:0] = 10 then SPSA[1:0] resets to 10
If CID[1:0] = 11 then SPSA[1:0] resets to 11
00 = left slot 3, right slot 4
01 = left slot 7, right slot 8
10 = left slot 6, right slot 9
11 = left slot 10, right slot 11
3 Reserved Reserved
2 0 SPDIF
0 = Disables SPDIF (SPDIF_OUT is high Z) (note 1)
1 = Enable SPDIF
SPDIF is a control register for Reg 3Ah, this bit must be set low i.e. SPDIF
disabled in order to write to Reg 3Ah Bits D15,D13:D0.
1 0 Reserved Bit not used, should read back 0
0 0 VRA Enable
0 = VRA Disabled, DAC and ADC set to 48 KHz (Registers 2Ch and 32h
loaded with the value BB80h)
1 = VRA Enabled, Reg. 2Ch & 32h control sample rate
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8.1.20.1. Variable Rate Sampling Enable
The Extended Audio Status Control register also contains one active bit to enable or disable the Vari-
able Sampling Rate capabilities of the DACs and ADCs. If the VRA (bit D0) is 1, the variable sample
rate control registers (2Ch and 32h) are active, and “on-demand” slot data required transfers are
allowed. If the VRA bit is 0, the DACs and ADCs will operate at the default 48 KHz data rate.
The STAC9752/9753 supports “on-demand” slot request flags. These flags are passed from the
CODEC to the AC’97 controller in every audio input frame. Each time a slot request flag is set (active
low) in a given audio frame, the controller will pass the next PCM sample for the corresponding slot
in the audio frame that immediately follows. The VRA enable bit must be set to 1 to enable
“on-demand” data transfers. If the VRA enable bit is not set, the CODEC defaults to 48 KHz transfers
and every audio frame includes an active slot request flag and data transfers every frame.
For variable sample rate output, the CODEC examines its sample rate control registers, the state of
the FIFOs, and the incoming SDATA_OUT tag bits at the beginning of each audio output frame to
determine which SLOTREQ bits to set active (low). SLOTREQ bits are asserted during the current
audio input frame for active output slots, which will require data in the next audio output frame.
For variable sample rate input, the tag bit for each input slot indicates whether valid data is present
or not. Thus, even in variable sample rate mode, the CODEC is always the master: for SDATA_IN
(CODEC to Controller), the CODEC sets the TAG bit; for SDATA_OUT (Controller to CODEC), the
CODEC sets the SLOTREQ bit and then checks for the TAG bit in the next frame. Whenever VRA is
set to 0, the PCM rate registers (2Ch and 32h) are overwritten with BB80h (48 KHz).
8.1.20.2. SPDIF
The SPDIF bit in the Extended Audio Status Control Register is used to enable and disable the
SPDIF functionality within the STAC9752/9753. If the SPDIF is set to a 1, then the function is
enabled, and when set to a 0 it is disabled.
8.1.20.3. SPCV (SPDIF Configuration Valid)
The SPCV bit is read only and indicates whether or not the SPDIF system is set up correctly. When
SPCV is a 0, it indicates the SPDIF configuration is invalid. When SPCV is a 1, it indicates the
SPDIF configuration is valid.
8.1.20.4. SPSA1, SPSA0 (SPDIF Slot Assignment)
SPSA1 and SPSA0 combine to provide the slot assignments for the SPDIF data. The following
details the slot assignment relationship between SPSA1 and SPSA0.
The STAC9752/9753 are AMAP compliant with the following table.
Table 19. AMAP compliant
CODEC
ID Function SPSA = 00
slot assignment
SPSA = 01
slot assignment
SPSA = 10
slot assignment
SPSA = 11
slot assignment
00 2-ch Primary w/SPDIF 3 & 4 7 & 8* 6 & 9 10 & 11
01 2-ch Dock CODEC w/SPDIF 3 & 4 7 & 8 6 & 9* 10 & 11
10 +2-ch Surr w/ SPDIF 3 & 4 7 & 8 6 & 9* 10 & 11
11 +2-ch Cntr/LFE w/ SPDIF 3 & 4 7 & 8 6 & 9 10 & 11*
Note: * indicates the default slot assignment
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8.1.21. PCM DAC Rate Registers (2Ch and 32h)
The internal sample rate for the DACs and ADCs are controlled by a value in these read/write regis-
ters (that contain a 16-bit unsigned value between 0 and 65535) representing the conversion rate in
Hertz (Hz). In VRA mode (register 2Ah bit D0 = 1), if the value written to these registers is supported,
that value will be echoed back when read; otherwise the closest (higher in the case of a tie) sample
rate is supported and returned. Per PC 99 / PC 2001 specification, independent sample rates are
supported for record and playback.
Whenever VRA is set to 0 the PCM rate registers (2Ch and 32h) will be loaded with BB80h (48 KHz).
If VRA is set to a 0, any write to this address will be ignored and the rate remains at 48 KHz.
8.1.22. PCM DAC Rate (2Ch)
Default: BB80h (see table 20: page 67)
8.1.23. PCM LR ADC Rate (32h)
Default: BB80h (see table 20: page 67)
8.1.24. SPDIF Control (3Ah)
Default: 2000h
Table 20. Hardware Supported Sample Rates
Sample Rate SR[15:0] Value
8 KHz 1F40h
11.025 KHz 2B11h
16 KHz 3E80h
22.05 KHz 5622h
32 KHz 7D00h
44.1 KHz AC44h
48 KHz BB80h
D15 D14 D13 D12 D11 D10 D9 D8
SR15 SR14 SR13 SR12 SR11 SR10 SR9 SR8
D7 D6 D5 D4 D3 D2 D1 D0
SR7 SR6 SR5 SR4 SR3 SR2 SR1 SR0
D15 D14 D13 D12 D11 D10 D9 D8
SR15 SR14 SR13 SR12 SR11 SR10 SR9 SR8
D7 D6 D5 D4 D3 D2 D1 D0
SR7 SR6 SR5 SR4 SR3 SR2 SR1 SR0
D15 D14 D13 D12 D11 D10 D9 D8
V DRS SPSR1 SPSR2 L CC6 CC5 CC4
D7 D6 D5 D4 D3 D2 D1 D0
CC3 CC2 CC1 CC0 PRE COPY /AUDIO PRO
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8.2. General Purpose Input & Outputs
8.2.1. EAPD
EAPD can act as a GPIO, but is unaffected by the following registers. To use EAPD as a GPIO, use
Register 74h, the EAPD Access Register located in Section 8.4.11: page 81. Additional information
about EAPD can also be found in Section 8.1.18.3: page 63.
8.2.2. GPIO Pin Definitions
GPIO pins are programmable to have input/output functionality. The data values (status) for these
pins are all in one register with input/output configuration in a separate register. Control of GPIO pins
configured for output is achieved by setting the corresponding bit in output slot 12; status of GPIO
pins configured for input is returned on input slot 12. The CODEC must constantly set the GPIO pins
that are configured for output, based upon the value of the corresponding bit position of the control
slot 12. The CODEC should ignore output slot 12 bits that correspond to GPIO control pins config-
ured as inputs. The CODEC must constantly update status on input slot 12, based upon the logic
level detected at each GPIO pin configured for input. A GPIO output pin value that is written via
slot 12 in the current frame will not affect the GPIO status that is returned in that particular write
frame.
Bit(s) Reset Value Access Name Description (note 1-2)
15 in 2.3 V
Validity: This bit affects the “Validity” flag, bit[28] transmitted in
each S/PDIF subframe, and enables the S/PDIF transmitter to
maintain connection during error or mute conditions. Subframe
bit[28] = 0 indicates that data is valid for conversion at the
receiver, 1 indicates invalid data (not suitable for conversion at
the receiver).
If “V” = 1, then each S/PDIF subframe (Left & Right) should have
bit[28] “Validity” flag = 1 or set based on the assertion or
de-assertion of the AC'97 “VFORCE” bit within the Extended
Audio Status and Control Register (D15, register 2Ah).
14 0 Read Only DRS 1 = Double Rate SPDIF support (always = 0)
13:12 10 Read & Write SPSR[1,0]
SPDIF Sample Rate.
00 - 44.1 KHz Rate
01 - Reserved
10 - 48 KHz Rate (default)
11 - 32 KHz Rate
11 0 Read & Write L Generation Level is defined by the IEC standard, or as
appropriate.
10:4 0 Read & Write CC[6, 0] Category Code is defined by the IEC standard or as appropriate
by media.
3 0 Read & Write PRE 0 = Pre-emphasis = 0 sec
1 = Pre-emphasis = 50/15 sec
2 0 Read & Write COPY 0 = Copyright not asserted
1 = Copyright is asserted
1 0 Read & Write /AUDIO 0 = PCM data
1 = Non-Audio or non-PCM format
0 0 Read & Write PRO 0 = Consumer use of the channel
1 = Professional use of the channel
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This slot-12 based control/status protocol minimizes the latency and complexity, especially for
host-based Controllers and host data pump software, and provides high speed monitoring and con-
trol, above what could be achieved with command/status slots. For host-based implementations,
most AC‘97 registers can be shadowed by the driver in order to provide immediate response when
read by the processor, and GPIO pins configured as inputs should be capable of triggering an inter-
rupt upon a change of status.
The AC-Link request for GPIO pin status is always delayed by at least one frame time. Read-Mod-
ify-Write operations across the AC-Link will incur latency that must be accounted for by the software
driver or AC‘97 Digital Controller firmware. PCI retries should be kept to a minimum wherever possi-
ble.
8.2.3. GPIO Pin Implementation
The GPIOs are set to a high impedance state on power-on or a cold reset. It is up to the AC‘97 Digi-
tal Controller to first enable the output after setting it to the desired state.
8.2.4. Extended Modem Status and Control Register (3Eh)
Default: 0100h
8.2.5. GPIO Pin Configuration Register (4Ch)
Default: 0003h
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED PRA
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GPIO
Bit(s) Access Reset Value Name Description
15:9 Read Only 0 RESERVED Bit not used, should read back 0
8 Read / Write 1 PRA 0 = GPIO powered up / enabled
1 = GPIO powered down / disabled
7:1 Read Only 0 RESERVED Bit not used, should read back 0
0 Read Only 0 GPIO 0 = GPIO not ready (powered down)
1 = GPIO ready (powered up)
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GC1
(GPIO1)
GC0
(GPIO0)
Bit(s) Access Reset Value Name Description
15:2 Read Only 0 RESERVED Bit not used, should read back 0
1 Read / Write 1 GC1 0 = GPIO1 configured as output
1 = GPIO1 configured as input
0 Read / Write 1 GC0 0 = GPIO0 configured as output
1 = GPIO0 configured as input
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8.2.6. GPIO Pin Polarity/Type Register (4Eh)
Default: FFFFh
8.2.7. GPIO Pin Sticky Register (50h)
Default: 0000h
8.2.8. GPIO Pin Mask Register (52h)
Default: 0000h
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GP1
(GPIO1)
GP0
(GPIO0)
Bit(s) Access Reset Value Name Description
15:2 Read Only 0 RESERVED Bit not used, should read back 0
1 Read / Write 1 GP1
0 = GPIO1 Input Polarity Inverted, CMOS output drive.
1 = GPIO1 Input Polarity Non-inverted, Open-Drain output
drive.
0 Read / Write 1 GP0
0 = GPIO0 Input Polarity Inverted, CMOS output drive.
1 = GPIO0 Input Polarity Non-inverted, Open-Drain output
drive.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GS1
(GPIO1)
GS0
(GPIO0)
Bit(s) Access Reset Value Name Description
15:2 Read Only 0 RESERVED Bit not used, should read back 0
1 Read / Write 0 GS1 0 = GPIO1 Non Sticky configuration.
1 = GPIO1 Sticky configuration.
0 Read / Write 0 GS0 0 = GPIO0 Non Sticky configuration.
1 = GPIO0 Sticky configuration.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GW1
(GPIO1)
GW0
(GPIO0)
Bit(s) Access Reset Value Name Description
15:2 Read Only 0 RESERVED Bit not used, should read back 0
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8.2.9. GPIO Pin Status Register (54h)
Default: 0000h
1 Read / Write 0 GW1 0 = GPIO1 interrupt not passed to GPIO_INT slot 12.
1 = GPIO1 interrupt is passed to GPIO_INT slot 12.
0 Read / Write 0 GW0 0 = GPIO0 interrupt not passed to GPIO_INT slot 12.
1 = GPIO0 interrupt is passed to GPIO_INT slot 12.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED GI1 (GPIO1) GI0 (GPIO0)
Bit(s) Access Reset Value Name Description
15:2 Read Only 0 RESERVED Bits not used, should read back 0
1 Read / Write x GI1
When GPIO1 is configured as output and Register h74 bit[0] = 0
(default), the value of this register will be placed on the GPIO1 pad.
When GPIO1 is configured as output and Register h74 bit[0] =1,
the GPIO1 pad will get its value from slot12.
When GPIO1 is configured as input and configured as a sticky bit,
writing a 1 does nothing, writing a 0 clears this bit.
When GPIO1 is configured as input, this register reflects the value
on the GPIO1 pad after interpretation of the polarity and sticky
configurations.
0 Read / Write x GI0
When GPIO0 is configured as output and Register h74 bit[0] = 0
(default), the value of this register will be placed on the GPIO0 pad.
When GPIO0 is configured as output and Register h74 bit[0] =1,
the GPIO0 pad will get its value from slot12.
When GPIO0 is configured as input and configured as a sticky bit,
writing a 1 does nothing, writing a 0 clears this bit.
When GPIO0 is configured as input, this register reflects the value
on the GPIO0 pad after interpretation of the polarity and sticky
configurations.
Bit(s) Access Reset Value Name Description
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8.3. Extended CODEC Registers Page Structure Definition
Registers 60h-68h are the Extended CODEC Registers: These registers allow for the defi-
nition of further capabilities. These bits provide a paged address space for extended
CODEC information. The Page Selector bits in the Audio Interrupt and Paging register
(Register 24h bits 3:0) control the page of information viewed through this page window.
8.3.1. Extended Registers Page 00
Page 00 of the Extended CODEC Registers is reserved for vendor specific use. Driver writ-
ers should not access these registers unless the Vendor ID register has been checked first
to ensure that the vendor of the AC'97 component has been identified and the usage of the
vendor defined registers understood.
8.3.2. Extended Registers Page 01
The usage of Page 01 of the Extended CODEC Registers is defined in Register 24h found
in Section 8.1.17: page 61.
8.3.3. Extended Registers Page 02, 03
Pages 02 and 03 of the Extended CODEC Registers are reserved for future use.
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8.4. STAC9752/9753 Paging Registers
The AC’97 Specification Rev 2.3 uses a paging mechanism in order to increase the number of regis-
ters. The registers currently used in the paging are 60h to 6Eh. For additional information about the
Extended CODEC Registers, please refer to Section 8.3: page 72.
One of two pages can be made active at any time, set in Register 24h. Register 24h is the Audio
Interrupt and Paging Register. Additional details about Register 24h is located in Section 8.1.17:
page 61.
If page 00h is active, registers 60h to 6Eh are Vendor Specific.
If page 01h is active, registers 60h to 6Eh have the following functionality:
8.4.1. CODEC Class/Rev (60h Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: 12xxh
Reg NAME FUNCTION Location
60h CODEC Class/Revision Provides the CODEC Class and a Vendor specified revision
identifier. 8.4.1: page 73
62h PCI SVID Allows for population by the system BIOS to identify the PCI
Sub System Vendor ID. 8.4.2: page 74
64h PCI SSID Allows for population by the system BIOS to identify the PCI
Sub System ID. Note:: page 74
66h Function Select Provides the type of audio function being selected and which
jack conductor the selected value is measured from. Note:: page 75
68h Function Information Includes information about Gain, Inversion, Buffer delays,
Information Validity, and Function Information presence. 8.4.5: page 76
6Ah Sense Register
Includes information about the connector/jack location, Input
verses Output sensing, the order of the sense results, and
the TSI specific sense results.
8.4.7: page 78
6Ch Reserved
6Eh Reserved
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED CL4 CL3 CL2 CL1 CL0
D7 D6 D5 D4 D3 D2 D1 D0
RV7 RV6 RV5 RV4 RV3 RV2 RV1 RV0
Bit(s) Reset Value Name Description
15-13 Reserved Reserved-not defined
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8.4.2. PCI SVID (62h Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: FFFFh
Note: This register is populated by the BIOS and does not reset on RESET#.
8.4.3. PCI SSID (64h Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: FFFFh
12-8 CL4:CL0
CODEC Compatibility Class (RO)
This is a CODEC vendor specific field to define software compatibility for the
CODEC. Software reads this field together with the CODEC vendor ID (reg 7C-7Eh)
to determine vendor specific programming interface compatibility. Software can rely
on vendor specific register behavior to be compatible among vendor CODECs of
the same class.
00h - Field not implemented
01h-1Fh - Vendor specific compatibility class code
Equals Vendor ID2 (Reg 7Eh) bits D7 to D0
7-0 RV7:RV0
Revision ID: (RO)
This register specifies a device specific revision identifier. The value is chosen by
the vendor. Zero is an acceptable value. This field should be viewed as a vendor
defined extension to the CODEC ID. This number changes with new CODEC
stepping of the same CODEC ID.
Equals Major Rev bits (Reg 6Ch) bits D7 to D0.
D15 D14 D13 D12 D11 D10 D9 D8
PVI15 PVI14 PVI13 PVI12 PVI11 PVI10 PVI9 PVI8
D7 D6 D5 D4 D3 D2 D1 D0
PVI7 PVI6 PVI5 PVI4 PVI3 PVI2 PVI1 PVI0
Bit(s) Reset Value Name Description
15-0 PVI15:PVI0
PCI Sub System Vendor ID:
This field provides the PCI Sub System Vendor ID of the Audio or Modem Sub
Assembly Vendor (i.e., CNR Manufacturer, Motherboard Vendor). This is NOT the
CODEC vendor PCI Vendor ID, nor the AC'97 Controller PCI Vendor ID.
If data is not available, returns FFFFh.
D15 D14 D13 D12 D11 D10 D9 D8
PI15 PI14 PI13 PI12 PI11 PI10 PI9 PI8
D7 D6 D5 D4 D3 D2 D1 D0
PI7 PI6 PI5 PI4 PI3 PI2 PI1 PI0
Bit(s) Reset Value Name Description
15-0 PI15:PVI0
PCI Sub System ID:
This field provides the PCI Sub System ID of the Audio or Modem Sub Assembly
(i.e., CNR Model, Motherboard SKU). This is NOT the CODEC vendor PCI ID, nor
the AC'97 Controller PCI ID. Information in this field must be available for AC'97
controller reads when CODEC Ready is asserted in AC-Link. If data is not
available, returns FFFFh.
Bit(s) Reset Value Name Description
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Note: This register is populated by the BIOS and does not reset on RESET#.
8.4.4. Function Select (66h Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: 0000h
Note: This register does not reset on RESET#.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED FC3 FC2 FC1 FC0 T/R
Bit(s) Reset Value Name Description
15-5 Reserved Reserved
4-1 00h FC3:FC0
Function Code bits:
00h - Line Out (Master Out)
01h - Head Phone Out (AUX Out)
Setting the T/R bit to 0 = Left,1 = Right
02h - DAC 3 (C/LFE) - Not Supported
03h - SPDIF out
04h - Phone In
05h - Mic1 (Microphone select = 0)
06h - Mic2 (Microphone select = 1)
07h - Line In
08h - CD In
09h - Video In
0Ah - Aux In
0Bh - Mono Out
0C-0Fh - Reserved
For supported Jack and Microphone Sense Functions, see Table 21: page 75.
The Function Code Bits are used to read Register 68h (Page 01h) and Register
6Ah (Page 01h).
Mono I/O should report relevant sense and function information on Tip, and report
Not-Supported on Ring.
Setting the function code to unsupported values will return a 0 when accessing the
Information Valid Bit in Page 01, Register 68h, bit 5.
00 T/R
Tip or Ring Selection Bit.This bit sets which jack conductor the sense value is
measured from. Software will program the corresponding the Ring/Tip selector bit
together with the I/O number in bits FC[3:0].
0 - Tip (Left)
1 - Ring (Right)
Table 21. Supported Jack and Microphone Sense Functions
Function Code I/O Sense Capability
00h Line_Out Jack Sense
01h Headphone_Out Jack Sense
05h Mic1 Microphone Sense
06h Mic2 Microphone Sense
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8.4.5. Function Information (68h Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: 00xxh, see table 22: page 77.
D15 D14 D13 D12 D11 D10 D9 D8
G4 G3 G2 G1 G0 INV DL4 DL3
D7 D6 D5 D4 D3 D2 D1 D0
DL2 DL1 DL0 IV RESERVED FIP
Bit(s) Reset Value Name Description
15 0 G4
Gain Sign Bit: The CODEC updates this bit with the sign of the gain value
present in G[3:0]. The BIOS updates this to take into consideration external
amplifiers or other external logic when relevant.
G[4] indicates whether the value is a gain or attenuation.
Gain in the G4 bit is in terms of dB.
This bit is Read/Write and is only reset on POR and not by RESET#.
14-11 0 G3:G0
Gain Bits: The CODEC updates these bits with the gain value (db relative to
level-out) in 1.5dBV increments. The BIOS updates these to take into
consideration external amplifiers or other external logic when relevant.
G[0:3] indicates the magnitude of the gain. G[4] indicates whether the value is a
gain or attenuation.
For Gain/Attenuation settings, see Table 23: page 77.
These bits are read/write and are not reset on RESET#.
10 INV
Inversion bit: Indicates that the CODEC presents a 180 degree phase shift to the
signal.
0h - No inversion reported
1h - Inverted
This bit is read/write and is not reset on RESET#.
BIOS should invert for each inverting gain stage.
9-5 DL4:DL0
Buffer delays: CODEC will provide number a delay measurement for the input
and output channels. Software will use this value to accurately calculate audio
stream position with respect to what is been reproduced or recorded. These
values are in 20.83 s (1/48000 second) units.
For output channels, this timing is from the end of AC Link frame in which the
sample is provided, until the time the analog signal appears at the output pin. For
input streams, this is from when the analog signal is presented at the pin until the
representative sample is provided on the AC Link.
Analog in and out paths are not considered as part of this delay.
The measurement is a “typical” measurement, at a 48 KHz sample rate, with
minimal in-CODEC processing (i.e., 3D effects are turned off.)
00h - Information not provided
01h…1Eh - Buffer delay in 20.83 s units
1Fh - reserved
These bits are read/write and are not reset on RESET#.
The default value is the delay internal to the CODEC. The BIOS may add to this
value the known delays external to the CODEC, such as for an external amplifier.
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8.4.6. Digital Audio Control (6Ah, Page 00h)
To access Register 6Ah, Page 00h must be selected in Register 24h.
41 IV
Information Valid Bit: Indicates whether a sensing method is provided by the
CODEC and if information field is valid. This field is updated by the CODEC.
0 - After CODEC RESET# de-assertion, it indicates the CODEC does NOT
provides sensing logic and this bit will be Read Only. After a sense cycle is
completed, indicates that no information is provided on the sensing method.
1 - After CODEC RESET# de-assertion, it indicates the CODEC provides
sensing logic for this I/O and this bit is Read/Write. After clearing this bit by
writing 1, when a sense cycle is completed the assertion of this bit indicates that
there is valid information in the remaining descriptor bits. Writing 0 to this bit has
no effect.
BIOS should NOT write this bit, as it is reset on RESET#.
3-1 0 RESERVED Bits not used, should read back 0
0NA FIP
Function Information Present
This bit set to a 1 indicates that the G[4:0], INV, DL[4:0] (Register 68h, Page 01h)
and ST[2:0] (register 6Ah, Page 01h) are supported and R/W capable.
This bit is Read Only.
Table 22. Reg 68h Default Values
Reg 66h Function Code Reg 68h Default Value
00h Line Out 0010h
01h Headphone Out 0010h
05h Mic1 0010h
06h Mic2 0010h
All other Function Codes 0000h
For RESET#: Reg 68h default value is 0000h.
Table 23. Gain or Attenuation Examples
G[4:0] Gain or Attenuation (dB relative to level-out)
00000 0 dBV
00001 +1.5 dBV
01111 +24 dBV
10001 -1.5 dBV
11111 -24 dBV
Table 24. Register 68h/Page 01h Bit Overview
Bit Bit R/W Overview
D15:D5 Read/Write and only reset on POR (Power on Reset) and not by RESET#.
D4 Read/Write and should NOT be set by the BIOS
D3:1 Reserved
D0 Read Only.
Bit(s) Reset Value Name Description
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Default: 0000h
8.4.7. Sense Details (6Ah Page 01h)
Register 24h must be set to Page 01h to access this register.
Default: NA
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED SPOR DO1 RSVD
Bit(s) Reset Value Name Description
15:3 0 RESERVED Bits not used, should read back 0
2 0 SPOR
Over-ride Register 2Ah, D12 write-lock when SPDIF_EN = 1.
All bits except SPDIF sample-rate are affected (D13-D12). Allows for sub-code
changing on-the-fly.
10 DO1
SPDIF Digital Output Source Selection:
DO1 = 0; PCM data from the AC-Link to SPDIF
DO1 = 1; ADC record data to SPDIF
0 0 RESERVED Bits not used, should read back 0
D15 D14 D13 D12 D11 D10 D9 D8
ST2 ST1 ST0 S4 S3 S2 S1 S0
D7 D6 D5 D4 D3 D2 D1 D0
OR1 OR0 SR5 SR4 SR3 SR2 SR1 SR1
Bit(s) Reset Value Name Description
15-13 ST2:ST0
Connector/Jack location bits
This field describes the location of the jack in the system.
0h - Rear I/O Panel
1h - Front Panel
2h - Motherboard
3h - Dock/External
4h:6h - Reserved
7h - No Connection/unused I/O
These bits are Read/Write.
12-8 S4:S0
Sensed bits meaning relates to the I/O being sense as output or inputs.
Sensed bits (outputs): See Table 25: page 79.
This field allows for the reporting of the type of output peripheral/device plugged in
the jack. Values specified below should be interrogated in conjunction with the
SR[5:0] and OR[1:0] bits for accurate reporting.
Sensed bits (inputs): See Table 26: page 79.
This field allows for the reporting of the type of input peripheral/device plugged in
the jack. Values specified below should be interrogated in conjunction with the
SR[5:0] and OR[1:0] bits for accurate reporting.
This field is Read Only.
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8.4.8. Revision Code (6Ch)
To access Register 6Ch, Page 00h must be selected in Register 24h.
7-6 OR1:0
Order Bits. These bits indicate the order the sense result bits SR[5:0] are using.
00 - 100 (i.e., Ohms)
01 - 101 (i.e., 10 Ohms)
10 - 102 (i.e., 100 Ohms)
11 - 103 (i.e., 1K Ohms)
5-0 SR5:SR0
Sense Result bits
These bits are used to report a vendor specific fingerprint or value. (Resistance,
impedance, reactance, etc.). This field is Read Only.
Table 25. Sensed Bits (Outputs)
Reported Value Output Peripheral/Device
0h Data not valid. Indicates that the reported value(s) is (are) invalid.
1h No connection. Indicates that there are no connected devices.
2h Fingerprint. Indicates a specific fingerprint value for devices that are not specified or unknown.
3h Speakers (8 ohms)
4h Speakers (4 ohms)
5h Powered Speakers
6h Stereo Headphone
7h Reserved
8h Reserved
9h Headset (mono speaker left channel and microphone.)
Ah Other. Allows a vendor to report sensing other type of devices/peripherals. SR[5:0] together with
OR[1:0] provide information regarding the type of device sensed.
Bh-Eh Reserved
Fh Unknown (use fingerprint)
Table 26. Sensed Bits (Inputs)
Reported Value Input Peripheral/Device
0h Data not valid. Indicates that the reported value(s) is (are) invalid.
1h No connection. Indicates that there are no connected devices.
2h Fingerprint. Indicates a specific fingerprint value for devices that are not specified.
3h Microphone (mono)
4h Reserved
5h Stereo Line In (CE device attached)
6h Reserved
7h Reserved
8h Reserved
9h Headset (mono speaker left channel and microphone.)
Ah Other. Allows a vendor to report sensing other type of devices/peripherals. SR[5:0] together with
OR[1:0] provide information regarding the type of device sensed.
Bh-Eh Reserved
Fh Unknown (use fingerprint)
Bit(s) Reset Value Name Description
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Default: 00xxh
8.4.9. Analog Special (6Eh)
To access Register 6Eh, Page 00h must be selected in Register 24h.
Default: 1000h
D15 D14 D13 D12 D11 D10 D9 D8
MINORREV
D7 D6 D5 D4 D3 D2 D1 D0
MAJORREV
Bit(s) Reset Value Name Description
15:8 00h MINORREV Minor Revision ID. These bits are read only and will be updated based on minor
device changes which will not require software changes.
7:0 xxh MAJORREV Major Revision ID. These bits are read only and will be updated based on major
device changes.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED AC97MIX RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RSVD MUTEFIX
DISABLE ADCSLT1 ADCSLT0 RSVD MIC GAIN
VAL SPLYOVR EN SPLYOVR VAL
Bit(s) Reset Value Name Description
15:13 0 RESERVED Bits not used, should read back 0
12 1 AC97MIX
0 = Mixer record contains a mix of all mono and stereo analog input signals,
not the DAC (ALL ANALOG mode).
1 = Mixer record contains a mix of all mono and stereo analog input signals
plus the DAC signal (AC’97 mode).
This bit only has an effect when either Stereo Mix or Mono Mix is selected as
the record source in Reg 1Ah.
The “ALL” mode is useful in conjunction with the POP BYPASS mode (Reg
20h; D15) to record all analog sources, perform further processing in the
digital domain, including combining with other PCM data, and routing through
the DACs directly to Line Out, Headphone Out, or Mono Out.
A Stereo Mix recording will be affected by the setting of the 3D Effects bit
(Reg 20h; D13)
11:7 0 RESERVED Bits not used, should read back 0
60 MUTEFIX
DISABLE
0 = MUTE FIX Enabled
1 = MUTE FIX Disabled
When this bit is zero, and either channel is set to -46.5dB attenuation (1Fh),
then that channel is fully muted. When this bit is one, then operation is per
AC’97 specification.
5:4 0 ADCSLT1:0
Select slots for ADC data on ACLINK
00 = Left slot 3, right slot 4
01 = Left slot 7, right slot 8
10 = Left slot 6, right slot 9
11 = Left slot 10, right slot 11
3 0 RESERVED RESERVED
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8.4.10. Analog Current Adjust (72h)
To unlock Register 72h, write 0xABBA to Register 70h.
Default: 0000h
8.4.11. EAPD Access Register (74h)
Default: 0800h
2 0 MIC GAIN VAL
Adds +10dB gain to the selected MIC input. Use in conjunction with
BOOSTEN (Reg. 0Eh;D6)
BOOSTEN MICGAINVAL
0 0 = 0 dB
0 1 = 10 dB
1 0 = 20 dB
1 1 = 30 dB
1 0 SPLYOVR_EN
Supply Override bit allows override of the supply detect.
0 = No override on supply detect
1 = Override supply detect with bit 0
0 0 SPLYOVR_VAL
Supply Override Value provides the analog voltage operation values.
0 = Force 3.3 v operation
1 = Force 5 V operation
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
INT APOP RESERVED
Bit(s) Reset Value Name Description
15:8 0 Reserved Reserved
7 0 INT_APOP
0 = Anti Pop Enabled
1 = Anti Pop Disabled
The STAC9752/9753 includes an internal power supply anti-pop circuit that
prevents audible clicks and pops from being heard when the CODEC is powered
on and off. This function is accomplished by delaying the charge/discharge of the
VREF capacitor (Pin 27). A CVREF value of 1 F will cause a turn-on delay of
roughly 3 seconds, which will allow the power supplies to stabilize before the
CODEC outputs are enabled. The delay will be extended to 30 seconds if a
CVREF value of 10 F is used. The CODEC outputs are also kept stable for the
same amount of time at power-off to allow the system to be gracefully turned off.
The Anti Pop bit allows this delay circuit to be bypassed for rapid production
testing. Any external component anti-pop circuit is unaffected by the internal
circuit.
6:0 0 Reserved Reserved
D15 D14 D13 D12 D11 D10 D9 D8
EAPD RESERVED EAPD_OEN RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED INTDIS GPIOACC GPIOSLT12
Bit(s) Reset Value Name Description
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8.4.12. High Pass Filter Bypass (78h)
To unlock Register 78h, write 0xABBA to Register 76h.
Default: 0000h
Bit(s) Reset Value Name Description
15 0 EAPD
EAPD data Enable
EAPD data is output on the EAPD pin when bit D11 = 1
EAPD data is input on the EAPD pin when bit D11 = 0
14:12 0 Reserved Bits not used, should read back 0
11 1 EAPD_OEN
EAPD Pin Enable
0 = EAPD configured as input pin
1 = EAPD configured as output pin
10:3 0 Reserved Bits not used, should read back 0
20 INTDIS
Interrupt disable option.
Interrupts cleared by writing a 1 to I4 (Reg24h:D15)
0 = Will clear both SENSE and GPIO interrupts
1 = Will only clear SENSE interrupts. GPIO interrupts will have to be cleared in
Reg54h.
10GPIOACC
GPIO ACCESS
0 = ACLINK access from GPIO Pads
1 = ACLINK access from GPIO Register 54h
00GPIOSLT12
0 = GPIO0/1 access via Reg 54h when GPIO is set as an output, for input, Slot
12 data will be 0h.
1 = GPIO0/1 access via Slot 12 when GPIO is set as an output, for inputs,
Reg 54h will not be updated.
This can only be used if a modem CODEC is not present in the system and using
Slot 12.
D15 D14 D13 D12 D11 D10 D9 D8
RESERVED
D7 D6 D5 D4 D3 D2 D1 D0
RESERVED ADC HPF BYP
Bit(s) Reset Value Name Description
15:1 0 RESERVED Bits not used, should read back 0
0 0 ADC HPF BYP 0 = ADC High Pass Filter active, (Normal operation)
1 = ADC High Pass Filter Bypass
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8.5. Vendor ID1 and ID2 (Index 7Ch and 7Eh)
These two registers contain four 8-bit ID codes. The first three codes have been assigned by Micro-
soft using their Plug and Play Vendor ID methodology. The fourth code is a manufacturer assigned
code identifying the STAC9752/9753. The ID1 register (index 7Ch) contains the value 8384h, which
is the first (83h) and second (84h) bytes of the Microsoft ID code. The ID2 register (index 7Eh) con-
tains the value 7652h, which is the third (76h) byte of the Microsoft ID code, and 52h which is the
STAC9752/9753 ID code.
8.5.1. Vendor ID1 (7Ch)
Default: 8384h
8.5.2. Vendor ID2 (7Eh)
Default: 7652h
D15 D14 D13 D12 D11 D10 D9 D8
10000011
D7 D6 D5 D4 D3 D2 D1 D0
10000100
D15 D14 D13 D12 D11 D10 D9 D8
01110110
D7 D6 D5 D4 D3 D2 D1 D0
01010010
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9. LOW POWER MODES
The STAC9752/9753 is capable of operating at reduced power when no activity is required. The
state of power down is controlled by the Powerdown Register (26h). There are 7 commands of sep-
arate power down. The power down options are listed in Table 27. The first three bits, PR[2:0], can
be used individually or in combination with each other, and control power distribution to the ADCs,
DACs and Mixer. The last analog power control bit, PR3, affects analog bias and reference voltages,
and can only be used in combination with PR0, PR1, and PR2. PR3 essentially removes power from
all analog sections of the CODEC, and is generally only asserted when the CODEC will not be
needed for long periods. PR0 and PR1 control the PCM ADCs and DACs only. PR2 and PR3 do not
need to be “set” before a PR4, but PR0 and PR1 should be “set” before PR4. PR5 disables the DSP
clock and does not require an external cold reset for recovery. PR6 disables the headphone driver
amplifier for additional analog power saving.
Figure 22. Example of STAC9752/9753 Powerdown/Powerup flow
The Figure 22 illustrates one example procedure to do a complete powerdown of STAC9752/9753.
From normal operation, sequential writes to the Powerdown Register are performed to power down
STAC9752/9753 a section at a time. After everything has been shut off, a final write (of PR4) can be
executed to shut down the AC-Link. The part will remain in sleep mode with all its registers holding
their static values. To wake up, the AC'97 controller will send an extended pulse on the sync line,
issuing a warm reset. This will restart the AC-Link (resetting PR4 to zero). The STAC9752/9753 can
also be woken up with a cold reset. A cold reset will reset all of the registers to their default states
(Paged Registers are semi-exempt). When a section is powered back on, the Powerdown Con-
trol/Status register (index 26h) should be read to verify that the section is ready (stable) before
attempting any operation that requires it.
Table 27. Low Power Modes
GRP Bits Function
PR0 PCM_In ADCs & Input Mux Powerdown
PR1 PCM_Out DACs Powerdown
PR2 Analog Mixer powerdown (VREF still on)
PR3 Analog Mixer powerdown (VREF off)
PR4 Digital Interface (AC-Link) powerdown (BIT_CLK forced low)
PR5 Digital Clock disable, BIT_CLK still on
PR6 Powerdown HEADPHONE_OUT
Warm Reset
Cold ResetReady =1
Normal ADCs off PR0 DACs off PR1 Analog off
PR2 or PR3
Digital I/F off
PR4
Shut off
AC-Link
Default
PR0=0 & ADC=1 PR1=0 & DAC=1 PR2=0 & ANL=1
PR0=1 PR1=1 PR2=1 PR4=1
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Figure 23. Powerdown/Powerup flow with analog still alive
Figure 23 illustrates a state when all the mixers should work with the static volume settings that are
contained in their associated registers. This configuration can be used when playing a CD (or exter-
nal LINE_IN source) through STAC9752/9753 to the speakers, while most of the system in low
power mode. The procedure for this follows the previous except that the analog mixer is never shut
down.
Warm Reset
Normal ADCs off PR0 DACs off PR1 Digital I/F off
PR4
Shut off
AC-Link
PR0=0 & ADC=1 PR1=0 & DAC=1
PR0=1 PR1=1 PR4=1
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10.MULTIPLE CODEC SUPPORT
The STAC9752/9753 provides support for the multi-CODEC option according to the Intel AC'97, rev
2.3 specification. By definition, there can be only one Primary CODEC (CODEC ID 00) and up to
three Secondary CODECs (CODEC IDs 01,10, and 11). The CODEC ID functions as a chip select.
Secondary devices therefore have completely orthogonal register sets; each is individually accessi-
ble and they do not share registers.
10.1. Primary/Secondary CODEC Selection
In a multi-CODEC environment the CODEC ID is provided by external programming of pins 45 and
46 (CID0 and CID1). The CID pin electrical function is logically inverted from the CODEC ID desig-
nation. The corresponding pin state and its associated CODEC ID are listed in the “CODEC ID
Selection” table.
10.1.1. Primary CODEC Operation
As a Primary device, the STAC9752/9753 is completely compatible with existing AC'97 definitions
and extensions. Primary CODEC registers are accessed exactly as defined in the AC'97 Component
Specification and AC'97 Extensions. The STAC9752/9753 operates as Primary by default, and the
external ID pins (45 and 46), have internal pull-ups so that these pins may be left as no-connects for
operation as a primary.
When used as the Primary CODEC, the STAC9752/9753 generates the master AC-Link BIT_CLK
for both the AC'97 Digital Controller and any Secondary CODECs. The STAC9752/9753 can support
up to four loads of 10 KW and 50 pF on the BIT_CLK output. This is to ensure that up to four
CODEC implementations will not load down the clock output.
10.1.2. Secondary CODEC Operation
When the STAC9752/9753 is configured as a Secondary device the BIT_CLK pin is configured as an
input at power up. Using the BIT_CLK provided by the Primary CODEC insures that everything on
the AC-Link will be synchronous. As a Secondary device it can be defined as CODEC ID 01, 10, or
11 in the two-bit field(s) of the Extended Audio and/or Extended Modem ID Register(s).
Table 28. CODEC ID Selection
CID1 State CID0 State CODEC ID CODEC Status
Dvdd or floating Dvdd or floating 00 Primary
Dvdd or floating 0 V 01 Secondary
0 V Dvdd or floating 10 Secondary
0 V 0 V 11 Secondary
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10.2. Secondary CODEC Register Access Definitions
The AC'97 Digital Controller can independently access Primary and Secondary CODEC registers by
using a 2-bit CODEC ID field (chip select) which is defined as the LSBs of Output Slot 0. For Sec-
ondary CODEC access, the AC'97 Digital Controller must invalidate the tag bits for Slot 1 and 2
Command Address and Data (Slot 0, bits 14 and 13) and place a non-zero value (01, 10, or 11) into
the CODEC ID field (Slot 0, bits 1 and 0).
As a Secondary CODEC, the STAC9752/9753 will disregard the Command Address and Command
Data (Slot 0, bits 14 and 13) tag bits when it sees a 2-bit CODEC ID value (Slot 0, bits 1 and 0) that
matches its configuration. In a sense the Secondary CODEC ID field functions as an alternative
Valid Command Address (for Secondary reads and writes) and Command Data (for Secondary
writes) tag indicator.
Secondary CODECs must monitor the Frame Valid bit, and ignore the frame (regardless of the state
of the Secondary CODEC ID bits) if it is not valid. AC'97 Digital Controllers should set the frame valid
bit for a frame with a secondary register access, even if no other bits in the output tag slot except the
Secondary CODEC ID bits are set.
This method is designed to be backward compatible with existing AC'97 controllers and CODECs.
There is no change to output Slot 1 or 2 definitions.
Using three CODECs typically requires a controller to support SDATA_IN2.
Table 29. Secondary CODEC Register Access Slot 0 Bit Definitions
Output Tag Slot (16-bits)
Bit Description
15 Frame Valid
14 Slot 1 Valid Command Address bit (†Primary CODEC only)
13 Slot 2 Valid Command Data bit (†Primary CODEC only)
12-3 Slot 3-12 Valid bits as defined by AC'97
2 Reserved (Set to 0)
†1-0 2-bit CODEC ID field
(00 reserved for Primary; 01, 10, 11 indicate Secondary)
Note: New definitions for Secondary CODEC Register Access
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11. TESTABILITY
The STAC9752/9753 has two test modes. One is for ATE in-circuit test and the other is restricted for
manufacturer’s internal use. The STAC9752/9753 enters the ATE in-circuit test mode if SDATA_OUT
is sampled high at the trailing edge of RESET#. Once in the ATE test mode, the digital AC-Link out-
puts (BIT_CLK and SDATA_IN) are driven to a high impedance state. This allows ATE in-circuit test-
ing of the AC'97 controller. Use of the ATE test mode is the recommended means of removing the
CODEC from the AC-Link when another CODEC is to be used as the primary. This case will never
occur during standard operating conditions. Once either of the two test modes have been entered,
the STAC9752/9753 must be issued another RESET# with all AC-Link signals held low to return to
the normal operating mode.
11.0.1. ATE Test Mode
ATE test mode allows for in-circuit testing to be completed at the board level. For this to work, the
outputs of the device must be driven to a high impedance state (Z). Internal pullups for digital I/O
pins must be disabled in this mode. This mode initiates on the rising edge of RESET# pin. Only a
cold reset will exit the ATE Test Mode.
Note: Pins 31, 33, and 34 are NO CONNECTS.
Table 30. Test Mode Activation
SYNC SDATA_OUT Description
0 0 Normal AC'97 operation
0 1 ATE Test Mode
1 0 TSI Internal Test Mode
1 1 Reserved
Table 31. ATE Test Mode Operation
Pin Name Pin # Function Description
SDATA_OUT 5 1 Must be held high at the rising edge of RESET#
BIT_CLK 6 Z
SDATA_IN 8 Z
SYNC 10 0 Must be held low at rising edge of RESET#
RESET# 11 1
N.C. 31 Z Always an input
N.C. 33 Z Always an input
N.C. 34 Z Always an input
GPIO0 43 Z
GPIO1 44 Z
CID0 45 Z
CID1 46 Z
EAPD 47 Z
SPDIF 48 Z
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12.PIN DESCRIPTION
DVdd1 1
XTL_IN 2
XTL_OUT 3
DVss1 4
SDATA_OUT 5
BIT_CLK 6
DVss2 7
SDATA_IN 8
DVdd2 9
SYNC 10
RESET# 11
PC_BEEP 12
24 LINE_IN_R
23 LINE_IN_L
22 MIC2
21 MIC1
20 CD_R
19 CD_GND
18 CD_L
17 VIDEO_R
16 VIDEO_L
15 AUX_R
14 AUX_L
13 PHONE
MONO_OUT 37
AVdd2 38
HP_OUT_L 39
HP_COMM 40
HP_OUT_R 41
AVss2 42
GPIO0 43
GPIO1 44
CID0 45
CID1 46
EAPD 47
SPDIF 48
Figure 24. Pin Description Drawing
PIN 48: TO ENABLE SPDIF, USE A 1 K
-10 K
EXTERNAL PULLDOWN. TO DISABLE SPDIF, USE A 1 K
-10 K
EXTERNAL PULLUP. DO NOT LEAVE PIN 48 FLOATING.
The CD_GND signal is an AC signal return for the two CD input channels. It is normally
biased at about 2.5V. The name of the pin in the AC97 specification is CD_GND, and this
has confused many designers. It should not have any DC path to GND. Connecting the
CD_GND signal directly to ground will change the internal bias of the entire CODEC, and
cause serious distortion. If there is no analog CD input, then this pin can be No-Connect.
48-Pin TQFP
36 LINE_OUT_R
35 LINE_OUT_L
34 NC
33 NC
32 CAP2
31 NC
30 AFILT2
29 AFILT1
28 VREFout
27 VREF
26 AVss1
25 AVdd1
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12.1. Digital I/O
These signals connect the STAC9752/9753 to its AC'97 controller counterpart, an external crystal,
multi-CODEC selection and external audio amplifier.
Note: Pins 31, 33, and 34 are NO CONNECTS.
Table 32. Digital Connection Signals
Pin Name Pin # Type Description
XTL_IN 2 I 24.576 MHz Crystal or External Clock Source
XTL_OUT 3 I/O 24.576 MHz Crystal
SDATA_OUT 5 I Serial, time division multiplexed, AC'97 input stream
BIT_CLK 6 I/O 12.288 MHz serial data clock
SDATA_IN 8 O Serial, time division multiplexed, AC'97 output stream
SYNC 10 I 48 KHz fixed rate sample sync
RESET# 11 I AC'97 Master H/W Reset
N.C. 31 I TSI Internal Test mode only.
N.C. 33 I TSI Internal Test mode only
N.C. 34 I/O TSI Internal Test mode only
GPIO0 43 I/O General Purpose I/O
GPIO1 44 I/O General Purpose I/O
CID0 45 I Multi-CODEC ID select – bit 0
CID1 46 I Multi-CODEC ID select – bit 1
EAPD 47 I/O External Amplifier Power Down/GPIO
SPDIF 48 I/O
SPDIF digital output
PIN 48: TO ENABLE SPDIF, USE AN 1 K
- 10 K
EXTERNAL
PULLDOWN. TO DISABLE SPDIF, USE AN 1 K
- 10 K
EXTERNAL
PULLUP. DO NOT LEAVE PIN 48 FLOATING.
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12.2. Analog I/O
These signals connect the STAC9752/9753 to analog sources and sinks, including microphones and
speakers.
Note: * Unused input pins should be tied together and connected to ground through a capacitor
(0.1 µF suggested), except the MIC inputs which should have a separate capacitor to ground.
Note: The CD_GND signal is an AC signal return for the two CD input channels. It is normally
biased at about 2.5V. The name of the pin in the AC97 specification is CD_GND, and this has
confused many designers. It should not have any DC path to GND. Connecting the CD_GND
signal directly to ground will change the internal bias of the entire CODEC, and cause serious
distortion. If there is no analog CD input, then this pin can be No-Connect.
Table 33. Analog Connection Signals
Pin Name Pin # Type Description
PC_BEEP 12 I* PC Speaker beep pass-through
PHONE 13 I* From telephony subsystem speakerphone
AUX_L 14 I* Aux Left Channel
AUX_R 15 I* Aux Right Channel
VIDEO_L 16 I* Video Audio Left Channel
VIDEO_R 17 I* Video Audio Right Channel
CD_L 18 I* CD Audio Left Channel
CD_GND19 I* CD Audio analog signal return (Do NOT ground. See note.)
CD_R 20 I* CD Audio Right Channel
MIC1 21 I* Desktop Microphone Input
MIC2 22 I* Second Microphone Input
LINE_IN_L 23 I* Line In Left Channel
LINE_IN_R 24 I* Line In Right Channel
LINE_OUT_L 35 O Line Out Left Channel
LINE_OUT_R 36 O Line Out Right Channel
MONO_OUT 37 O To telephony subsystem speakerphone
HP_OUT_L 39 O Headphone Out Left Channel
HP_COMM 40 O Headphone Ground Return
HP_OUT_R 41 O Headphone Out Right Channel
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12.3. Filter/References
These signals are connected to resistors, capacitors, or specific voltages.
12.4. Power and Ground Signals
Table 34. Filtering and Voltage References
Signal Name Pin Number Type Description
VREF 27 O Analog ground (0.45 * Vdd, at 5 V; or 0.41 * Vdd at 3 V)
VREFOUT 28 O Reference Voltage out 5 mA drive (intended for microphone
bias) (~Vdd/2)
AFILT1 29 O Anti-Aliasing Filter Cap - ADC left channel
AFILT2 30 O Anti-Aliasing Filter Cap - ADC right channel
CAP2 32 O ADC reference Cap
Table 35. Power and Ground Signals
Pin Name Pin # Type Description
AVdd1 25 I Analog Vdd = 5.0 V or 3.3 V
AVdd2 38 I Analog Vdd = 5.0 V or 3.3 V
AVss1 26 I Analog Gnd
AVss2 42 I Analog Gnd
DVdd1 1 I Digital Vdd = 3.3 V
DVdd2 9 I Digital Vdd = 3.3 V
DVss1 4 I Digital Gnd
DVss2 7 I Digital Gnd
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13.ORDERING INFORMATION
yy = 2 digit revision. Contact Sales for complete ordering number.
Add an “R” to the end of the Part number for Tape and Reel delivery. Minimum order quantitiy is 2ku.
14.PACKAGE DRAWING
Part Number Package Temp Range Supply Range
STAC9752XXTAEyyX 48-pin RoHS QFP 7mm x 7mm x 1.4mm 0° C to +70° C DVdd = 3.3V, AVdd = 5.0V
STAC9753XXTAEyyX 48-pin RoHS QFP 7mm x 7mm x 1.4mm 0° C to +70° C DVdd = 3.3V, AVdd = 3.3V
Key
LQFP Dimensions in mm
Min. Nom. Max.
A 1.40 1.50 1.60
A1 0.05 0.10 0.15
A2 1.35 1.40 1.45
D 8.80 9.00 9.20
D1 6.90 7.00 7.10
E 8.80 9.00 9.20
E1 6.90 7.00 7.10
L 0.45 0.60 0.75
e0.50
c 0.09 - 0.20
b 0.17 0.22 0.27
48 pin LQFP
E
E1
D
D1
Pin 1
b
A
A2
A1
c
e
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15.SOLDER REFLOW PROFILE
15.1. Standard Reflow Profile Data
Note: These devices can be hand soldered at 360 oC for 3 to 5 seconds.
FROM: IPC / JEDEC J-STD-020C “Moisture/Reflow Sensitivity Classification for Nonhermetic Solid
State Surface Mount Devices” (www.jedec.org/download).
Figure 25. Reflow Profile
15.2. Pb Free Process - Package Classification Reflow Temperatures
Profile Feature Pb Free Assembly
Average Ramp-Up Rate (Tsmax - Tp) 3 oC / second max
Preheat
Temperature Min (Tsmin)
Temperature Max (Tsmax)
Time (tsmin - tsmax)
150 oC
200 oC
60 - 180 seconds
Time maintained above Temperature (TL)
Time (tL)
217 oC
60 - 150 seconds
Peak / Classification Temperature (Tp) See “Package Classification Reflow Temperatures” on page 95.
Time within 5 oC of actual Peak Temperature (tp) 20 - 40 seconds
Ramp-Down rate 6 oC / second max
Time 25 oC to Peak Temperature 8 minutes max
Note: All temperatures refer to topside of the package, measured on the package body surface.
Package Type MSL Reflow Temperature
TQFP 48-pin 3 260 oC*
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16.APPENDIX A: PROGRAMMING REGISTERS
Reg # Name D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 Default
00h Reset RSRVD SE4 SE3 SE2 SE1 SE0 ID9 ID8 ID7 ID6 ID5 ID4 ID3 ID2 ID1 ID0 6A90h
02h Master Volume Mute RSRVD ML5 ML4 ML3 ML2 ML1 ML0 RESERVED MR5 MR4 MR3 MR2 MR1 MR0 8000h
04h HP_OUT
Mixer Volume Mute RSRVD HPL5 HPL4 HPL3 HPL2 HPL1 HPL0 RESERVED HPR5 HPR4 HPR3 HPR2 HPR1 HPR0 8000h
06h Master Volume Mono Mute RESERVED MM5 MM4 MM3 MM2 MM1 MM0 8000h
0Ah PC_BEEP Volume Mute X X F7 F6 F5 F F3 F2 F1 F0 PV3 PV2 PV1 PV0 RSRVD 0000h
0Ch Phone volume Mute RESERVED GN4 GN3 GN2 GN1 GN0 8008h
0Eh Mic Volume Mute RESERVED boosten RSVD GN4 GN3 GN2 GN1 GN0 8008h
10h Line In Volume Mute RESERVED GL4 GL3 GL2 GL1 GL0 RESERVED GR4 GR3 GR2 GR1 GR0 8808h
12h CD Volume Mute RESERVED GL4 GL3 GL2 GL1 GL0 RESERVED GR4 GR3 GR2 GR1 GR0 8808h
14h Video Volume Mute RESERVED GL4 GL3 GL2 GL1 GL0 RESERVED GR4 GR3 GR2 GR1 GR0 8808h
16h AUX Volume Mute RESERVED GL4 GL3 GL2 GL1 GL0 RESERVED GR4 GR3 GR2 GR1 GR0 8808h
18h PCM Out Volume Mute RESERVED GL4 GL3 GL2 GL1 GL0 RESERVED GR4 GR3 GR2 GR1 GR0 8808h
1Ah Record Select RESERVED SL2 SL1 SL0 RESERVED SR2 SR1 SR0 0000h
1Ch Record Gain Mute RESERVED GL3 GL2 GL1 GL0 RESERVED GR3 GR2 GR1 GR0 8000h
20h General Purpose POP
BYP RSRVD 3D RESERVED MIX MS LPBK RESERVED 0000h
22h 3D Control RESERVED DP3 DP2 RESERVED 0000h
24h Audio Int. & Paging I4 I3 I2 I1 I0 RESERVED PG3 PG2 PG1 PG0 0000h
26h Powerdown Ctrl/Stat EAPD PR6 PR5 PR4 PR3 PR2 PR1 PR0 RESERVED REF ANL DAC ADC 000Fh
28h Extended Audio ID ID1 ID0 RESERVED REV1 REV0 AMAP LDAC SDAC CDAC DSA1 DSA0 RSVD SPDIF DRA VRA 0A05h
2Ah Extended Audio Control/Status VCFG PRL/RS
VD
PRK/RS
VD
PRJ/RS
VD
PRI/RS
VD SPCV MADC/
RSVD
LDAC/R
SVD
SDAC/R
SVD
CDAC/R
SVD SPSA1 SPSA0 VRM/R
SVD SPDIF DRA/RSV
DVRA 0400h*
2Ch PCM DAC Rate SR15 SR14 SR13 SR12 SR11 SR10 SR9 SR8 SR7 SR6 SR5 SR4 SR3 SR2 SR1 SR0 BB80h
32h PCM LR
ADC Rate SR15 SR14 SR13 SR12 SR11 SR10 SR9 SR8 SR7 SR6 SR5 SR4 SR3 SR2 SR1 SR0 BB80h
3Ah SPDIF Control V DRS SPSR1 SPSR2 L CC6 CC5 CC4 CC3 CC2 CC1 CC0 PRE COPY #PCM/AU
DIO PRO 2000h
3Eh Extended Modem Status RESERVED PRA RESERVED GPIO 0100h
4Ch GPIO Pin Config RESERVED GC1
(GPIO1)
GC0
(GPIO0) 0300h
4Eh GPIO Pin Polarity/Type RESERVED GP1
(GPIO1)
GP0
(GPIO0) FFFFh
50h GPIO Pin Sticky RESERVED GS1
(GPIO1)
GS0
(GPIO0) 0000h
52h GPIO Pin Mask RESERVED GW1
(GPIO1)
GW0
(GPIO0) 0000h
54h GPIO Pin Status RESERVED GI1
(GPIO1)
GI0
(GPIO0) 0000h
60h
Page
01h
CODEC Class/Rev RESERVED CL4 CL3 CL2 CL1 CL0 RV7 RV6 RV5 RV4 RV3 RV2 RV1 RV0 12xxh
62h VENDOR RESERVED
62h
Page
01h
PCI SVID PVI15 PVI14 PVI13 PVI12 PVI11 PVI10 PVI9 PVI8 PVI7 PVI6 PVI5 PVI4 PVI3 PVI2 PVI1 PVI0 FFFFh
64h VENDOR RESERVED
64h
Page
01h
PCI SID PI15 PI14 PI13 PI12 PI11 PI10 PI9 PI8 PI7 PI6 PI5 PI4 PI3 PI2 PI1 PI0 FFFFh
66h VENDOR RESERVED
66h
Page
01h
Function Select RESERVED FC3 FC2 FC1 FC0 T/R 0000h
68h VENDOR RESERVED
68h
Page
01h
Function Information G4 G3 G2 G1 G0 INV DL4 DL3 DL2 DL1 DL0 IV RESERVED FIP xxxxh
6Ah Digital Audio
Control RESERVED SPOR DO1 RSVD 0000h
6Ah
Page
01h
Sense Details ST2 ST1 ST0 S4 S3 S2 S1 S0 OR1 OR0 SR5 SR4 SR3 SR2 SR1 SR0 NA
6Ch Revision Code 0 0 0 0 0 0 0 0 0 0 0 0 x x x x 00xxh
6Ch
Page
01h
RESERVED
6Eh Analog Special RESERVED
AC97
ALL
MIX
RESERVED
MUTE
FIX
DISABLE
ADC
slot1
ADC
slot0 RSVD MIC GAIN
VALUE
SPLY OVR
EN
SPLY OVR
VAL 1000h
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*depends upon chip ID
6Eh
Page
01h
RESERVED
70h VENDOR RESERVED 0000h
72h Analog Current Adjust RESERVED INT
APOP RESERVED 0000h
74h EAPD Access EAPD RESERVED EAPD_
OEN RESERVED INTDIS GPIO ACC GPIO
SLT12 0800h
76h VENDOR RESERVED 0000h
78h High Pass Filter Bypass RSESERVED ADC HPF
BYP 0000h
7Ah Reserved RESERVED 0000h
7Ch Vendor ID1 1 00000111 0 000 1 0 08384h
7Eh Vendor ID2 9752 0 1 1 1 0 1 1 0 0 1 0 1 0 0 1 0 7652h
Reg # Name D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 Default
STAC9752/9753
Two-Channel, 20-Bit, AC’97 2.3 Codecs with Headphone Drive, SPDIF Output Microphone & Jack Sensing
www.temposemi.com
8627 N. MoPac Expwy Suite 130
Austin, Texas 78759
DISCLAIMER Tempo Semiconductor, Inc. (TSI) and its subsidiaries reserve the right to modify the products and/or specifications described
herein at any time and at TSI’s sole discretion. All information in this document, including descriptions of product features and performance, is
subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the
independent state and are not guaranteed to perform the same way when installed in customer products. The information contained herein is
provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability of TSI’s products
for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This docu-
ment is presented only as a guide and does not convey any license under intellectual property rights of TSI or any third parties.
TSI’s products are not intended for use in life support systems or similar devices where the failure or malfunction of an TSI product can be
reasonably expected to significantly affect the health or safety of users. Anyone using an TSI product in such a manner does so at their own
risk, absent an express, written agreement by TSI.
Tempo Semiconductor, TSI and the TSI logo are registered trademarks of TSI. Other trademarks and service marks used herein, including
protected names, logos and designs, are the property of TSI or their respective third party owners.
Copyright 2014. All rights reserved.
17.REVISION HISTORY
Revision Date Description of Change
3.2 October 2003
-Removed “Preliminary” tag on front page.
-Removed BIT_CLK as an input option from clocking table, it was incorrectly included in 3.1
version.
-Added CD_GND elaboration note on connection diagram, pin list and pin out diagrams:
“The CD_GND signal is an AC signal return for the two CD input channels. It is normally biased
at about 2.5 V. The name of the pin in the AC’97 specification is CD_GND, and this has
confused many designers. It should not have any DC path to GND. Connecting the CD_GND
signal directly to ground will change the internal bias of the entire CODEC, and cause serious
distortion. If there is no analog CD input, then this pin can be No-Connect. “
3.2 3 October 2006 Release in TSI format.
3.3 December 2006 Updated part ordering information to longer orderable part number related to previously issued
PCN.
3.4 October 2014 Released in TSI format
Mouser Electronics
Authorized Distributor
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