Part Number Hot Search : 
HDK5361 M781039 FM120 07010 28L400 02016 AN7515SH B3844AM
Product Description
Full Text Search
 

To Download STV8247 Datasheet File

  If you can't view the Datasheet, Please click here to try to view without PDF Reader .  
 
 


  Datasheet File OCR Text:
 (R)
STV82x7
Digital Audio Decoder/Processor for A2 and NICAM Television/Video Recorders
PRELIMINARY DATA
Key Features
Full-Automatic Multi-Standard Demodulation
B / G / I / L / M / N / D / K Standards Mono AM and FM FM 2-Carrier (German and Korean Zweiton) and NICAM

Multi-Channel Capability
3 IS digital inputs, S/PDIF (in/out) 5.1 analog outputs Dolby(R) Pro Logic(R) Dolby(R) Pro Logic II(R)

Virtual or true, multi-channel capabilities and easy digital links make them ideal for digital audio low cost consumer applications. Starting from enhanced stereo up to independent control of 5 loudspeakers and a subwoofer (5.1 channels), the STV82x7 family offers standard and advanced features plus sound enhancements, spatial and virtual effects to enhance television viewer comfort and entertainment.
Typical Applications
Analog and digital TV with virtual surround sound Analog and digital TV with multi-channel surround sound DVD and HDD recorders "Palm size" portable TV

Sound Processing
ST royalty-free processing: ST WideSurround, ST OmniSurround, ST Dynamic Bass, SRS(R) WOWTM, SRS(R) TruSurround XTTM which is Virtual Dolby(R) Surround and Virtual Dolby(R) Digital compliant Independent Volume / Balance for Loudspeakers and Headphone Loudspeakers: Smart Volume Control (SVC), 5-band equalizer and loudness Headphone: Smart Volume Control (SVC), BassTreble, Loudness and SRS(R) TruBassTM
82 TV S
x7
(R)
Analog Audio Matrix
4 stereo inputs 3 stereo outputs THRU mode

Audio Delay for Audio Video Synchronization
Embedded stereo delay up to 120 ms for lip-sync function (up to 180 ms for tuner input) Independent delay on headphone and loudspeaker channels
(c) 2004 SRS Labs, Inc. All rights reserved, SRS and the SRS logo are registered trademarks of SRS Labs, Inc.
The STV82x7 family, based on audio digital signal processors (DSP), performs high quality and advanced dedicated digital audio processing.These devices provide all of the necessary resources for automatic detection and demodulation of analog audio transmissions for European and Asian terrestrial TV broadcasts.
"Dolby", "Pro Logic", and the double-D symbol are trademarks of Dolby Laboratories.
Rev. 3 February 2005 1/149
CLK_SEL
XTALIN
XTALOUT
2/149
IS
clocks
IRQ S/PDIF In / Out
data
Block Diagram
Loudspeakers
Headphone Detection
Stereo Audio DAC
0.9 VRMS
Control Logic
IS Interface
Pre-scaler
Sound IF SIF
Headphone Digital Audio Processing Volume, Balance, Loudness, Smart Volume Control, Bass/Treble, SRS(R) TrubassTM
Stereo Audio DAC Stereo Audio DAC
Loudspeakers Digital Audio Processing Volume, Equalizer, Balance, Dolby(R) Pro Logic(R) Dolby(R) Pro Logic II(R), ST WideSurround, ST Dynamic Bass, ST OmniSurround, Loudness,Smart Volume Control, Bass Management, Beeper SRS(R) WOWTM or TruSurround XTTM
LS_L LS_R LS_C LS_SUB
AGC
A/D
Digital Audio Matrix
0.9 VRMS
Digital FM/AM NICAM FM 2-carrier Demodulation
Headphone / Surround HP_LSS_L HP_LSS_R
Mono Input MONO_IN Audio A/D
SC1_IN_L SC1_IN_R
2 VRMS
SC1_OUT_L SC1_OUT_R
SC2_IN_L SC2_IN_R
SC3_IN_L SC3_IN_R Clock Generator
Input Analog Audio Matrix
Output Analog Audio Matrix
2 VRMS
SC2_OUT_L SC2_OUT_R
SC4_IN_L SC4_IN_R
IC Interface
Power Supply Management
2 VRMS
SC3_OUT_L SC3_OUT_R SCART Outputs
SCART Inputs SDA
SCL IC
STV82x7
STV82x7
Table of Contents
Chapter 1
1.1
General Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
STV82x7 Overview .............................................................................................................. 8
1.1.1 Core Features ............................................................................................................................................8 1.1.2 Software Information .................................................................................................................................9 1.1.3 Device Input Modes ...................................................................................................................................9 1.1.4 Electrical Features ...................................................................................................................................10
1.2 1.3
Typical Applications ........................................................................................................... 10 Pin Descriptions and Application Diagrams ....................................................................... 14
Chapter 2 Chapter 3
3.1 3.2
System Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20 Digital Demodulator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
Sound IF Signal .................................................................................................................. 21 Demodulation ..................................................................................................................... 22
Chapter 4
4.1 4.2 4.3 4.4 4.5 4.6
Dedicated Digital Signal Processor (DSP) . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Back-end Processing ......................................................................................................... 24 Audio Processing ............................................................................................................... 25 ST WideSurround ............................................................................................................... 28 ST OmniSurround .............................................................................................................. 28 Dolby Pro Logic II Decoder ................................................................................................ 28 Bass Management ............................................................................................................. 28
4.6.1 Bass Management Configuration 0 .........................................................................................................29 4.6.2 Bass Management Configuration 1 .........................................................................................................30 4.6.3 Bass Management Configuration 2 .........................................................................................................31 4.6.4 Bass Management Configuration 3 .........................................................................................................32 4.6.5 Bass Management Configuration 4 .........................................................................................................33
4.7
SRS WOW and TruSurround XT ...................................................................................... 33
4.7.1 SRS TruSurround ....................................................................................................................................33 4.7.2 SRS WOW ...............................................................................................................................................34
4.8 4.9 4.10 4.11 4.12 4.13 4.14
Smart Volume Control (SVC) ............................................................................................. 34 ST Dynamic Bass .............................................................................................................. 35 5-Band Audio Equalizer ..................................................................................................... 35 Bass/Treble Control ........................................................................................................... 35 Automatic Loudness Control .............................................................................................. 36 Volume/Balance Control .................................................................................................... 36 Soft Mute Control ............................................................................................................... 37
3/149
STV82x7
4.15 Beeper ................................................................................................................................ 37
Chapter 5 Chapter 6
6.1 6.2
Analog Audio Matrix (In / Out) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .39 IS Interface (In / Out) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
IS Inputs ............................................................................................................................ 40 IS Output ........................................................................................................................... 41
Chapter 7 Chapter 8
8.1
S/PDIF Input/Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .42 Power Supply Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .43
Standby Mode (Loop-through mode) ................................................................................. 43
Chapter 9
9.1 9.2 9.3
Additional Controls and Flag . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .44
Headphone Detection ........................................................................................................ 44 IRQ Generation .................................................................................................................. 44 IC Bus Expander ............................................................................................................... 44
Chapter 10 Chapter 11
11.1 11.2
STV82x7 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .45 IC Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .46
IC Address and Protocol ................................................................................................... 46 Start-up and Configuration Change Procedure .................................................................. 47
Chapter 12
12.1 12.2 12.3 12.4 12.5 12.6 12.7 12.8 12.9 12.10 12.11
Register List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .48
IC Register Map ................................................................................................................ 49 STV82x7 General Control Registers .................................................................................. 55 Clocking 1 .......................................................................................................................... 56 Demodulator ....................................................................................................................... 59 Demodulator Channel 1 ..................................................................................................... 62 Demodulator Channel 2 ..................................................................................................... 66 NICAM Registers ............................................................................................................... 71 Stereo Mode ....................................................................................................................... 73 Analog Control ................................................................................................................... 74 Clocking 2 .......................................................................................................................... 76 DSP Control ....................................................................................................................... 77
4/149
STV82x7
12.12 12.13 12.14 12.15 12.16 12.17 12.18 12.19 12.20 12.21 12.22 12.23 12.24 Automatic Standard Recognition ........................................................................................ 81 Audio Preprocessing and Selection Registers ................................................................... 85 Matrixing ............................................................................................................................. 93 Audio Processing ............................................................................................................... 98 5-Band Equalizer / Bass-Treble for Loudspeakers .......................................................... 112 Headphone Bass-Treble .................................................................................................. 113 Volume ............................................................................................................................. 116 Beeper .............................................................................................................................. 126 Mute ................................................................................................................................. 127 S/PDIF .............................................................................................................................. 128 Headphone Configuration ................................................................................................ 128 DAC Control ..................................................................................................................... 129 AutoStandard Coefficients Settings ................................................................................. 130
Chapter 13
13.1 13.2 13.3 13.4 13.5 13.6 13.7 13.8 13.9 13.10 13.11 13.12 13.13 13.14
Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .132
Absolute Maximum Ratings ............................................................................................ 132 Thermal Data .................................................................................................................. 132 Power Supply Data .......................................................................................................... 132 Crystal Oscillator ............................................................................................................. 133 Analog Sound IF Signal .................................................................................................. 133 SIF to IS Output Path Characteristics ............................................................................. 134 SCART to SCART Analog Path Characteristics .............................................................. 134 SCART and MONO IN to IS Path Characteristics .......................................................... 135 I2S to LS/HP/SUB/C Path Characteristics ....................................................................... 135 IS to SCART Path Characteristics .................................................................................. 136 MUTE Characteristics ...................................................................................................... 136 Digital I/Os Characteristics ............................................................................................... 136 IC Bus Characteristics .................................................................................................. 137
I2S Bus Interface .............................................................................................................. 138
Chapter 14 Chapter 15 Chapter 16
Input/Output Groups . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .140 Package Mechanical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .145
Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .146
5/149
General Description
STV82x7
1
General Description
The STV82x7 is a multistandard TV sound demodulator and audio processor which integrates SRS(R) WOWTM, SRS(R) TruSurround XTTM, Dolby(R) Pro Logic(R), Dolby(R) Pro Logic II(R),Virtual Dolby(R) Surround (VDS) and Virtual Dolby(R) Digital (VDD) capability. ST advanced algorithms such as ST OmniSurround, ST WideSurround, ST Dynamic Bass are also available in this audio sound processor. ST OmniSurround is a certified Dolby(R) algorithm for the Virtual Dolby(R) Digital (VDD) and the Virtual Dolby(R) Surround (VDS). When using VDD or VDS, either a Dolby(R) Digital or a Pro Logic(R) (or Pro Logic II(R)) decoder is mandatory respectively. This chip performs automatic multistandard analog TV stereo sound identification and demodulation (no specific IC programming is required). It offers various audio processing functions such as equalization, loudness, beeper, volume, balance, and surround effects. It provides a cost-effective solution for analog and digital TV designs. The STV82x7 is perfectly suited to current and future digital TV platforms, based on audio/video digital chips (STD2000, (DTV100 platform) and the future WorldWide iDTV one chip) which include an internal digital decoder (MPEG, Dolby(R) Digital...). In the case where a Dolby(R) Digital decoder is embedded in the audio/video digital chip, Virtual Dolby(R) Digital could be obtained. For the CTV100/120 platform, the device is offered as an alternative solution to the first-generation chassis that uses the STV82x6.
6/149
STV82x7
General Description
Table 1: STV82x7 Version List
STV8247 S T V 8 2 0 7 S T V 8 2 1 7 S T V 8 2 2 7 S T V 8 2 3 7 S T V 8 2 4 7 D S X STV8257 S T V 8 2 5 7 D S T V 8 2 5 7 D S X STV8267 S T V 8 2 6 7 D S X STV8277 S T V 8 2 7 7 D S X STV8287 S T V 8 2 8 7 D S X
S T V 8 2 4 7 D
S T V 8 2 5 7
S T V 8 2 6 7 D
S T V 8 2 7 7
S T V 8 2 7 7 D
S T V 8 2 8 7 D
Demodulation AM/FM - Mono, FM 2-carrier NICAM Multi-Channel Capability 3 x IS In or 1 IS Out, S/PDIF (Pass-thru) 5.1 Analog Out for Loudspeakers Virtual Dolby(R) Surround Virtual Dolby(R) Digital capability1 Dolby(R) Pro Logic(R) Dolby(R) Pro Logic II(R) Audio Processing SRS(R) WOWTM SRS(R) TruSurround XTTM ST Voice, ST Dynamic Bass, ST WideSurround ST OmniSurround2
X
X X
X
X X
X X
X X
X X
X X
X X
X X
X X
X X
X X
X X
X X
X X
X
X
X X X X
X X
X X X
X X X X X
X X X X
X X X X
X
X X
X X
X X
X
X X X
X X
X
X
X
X X X X X X X X X X X X X X X X X X X X X X X X X X
X
X
X
X
X X
X X
1. Virtual Dolby Digital capability is obtained with the use of external Dolby Digital decoder (for example STD05x0). 2. When using VDD or VDS with ST OmniSurround or SRS TruSurround XTTM, either a Dolby(R) Digital or a Pro Logic(R) (or Pro Logic II(R)) decoder is mandatory respectively.
Figure 1: Package Ordering Information
Order Code: STV82x7 (Tray) STV82x7/T (Tape & Reel)
TQ
80 FP
(R)
For Example: STV8257DSX/T will be delivered in Tape & Reel conditioning
7/149
General Description
STV82x7
1.1
1.1.1
STV82x7 Overview
Core Features
Single audio source processing: -- IF source and/or analog stereo input (SCART) -- one digital source with a maximum of 6 synchronous channels (5.1 is obtained across three IS)

SIF input signal with Automatic Gain Control (AGC) Digital Demodulator with automatic standard detection and demodulation for AM, FM mono, FM 2 carriers (German or Korean FM 2-carrier) and NICAM Audio processor working at 32 kHz, 44.1 kHz or 48 kHz with specific features: -- For Loudspeakers (L, R, LS, RS, SubW, C): Dolby(R) Pro Logic II (R) Decoder with Bass Management SRS(R) WOWTM or TruSurround XTTM including Virtual Dolby(R) Surround and Virtual Dolby(R) Digital ST WideSurround ST OmniSurround ST Dynamic Bass 5-band Equalizer or Bass-Treble Loudness Smart Volume Control Volume/Balance/Soft-mute Beeper Video Processing Delay Compensation -- For Headphone: SRS(R) TruBassTM Smart Volume Control Bass-Treble Loudness Volume/Balance/Soft-mute Beeper Video Processing Delay Compensation

Shared outputs for headphone and loudspeakers (surround channels); Analog matrix with: -- five external inputs: four SCART inputs (2 VRMS capable) one analog mono input (0.5 VRMS) -- one internal input from a digital matrix via a DAC -- three external outputs (2 VRMS capable) -- one internal output for the digital matrix (using an internal ADC)
Digital matrix with: -- three input modes (Demodulator/SCART, SCART only and IS) -- three stereo outputs (Loudspeakers, Headphone and SCART)

High-end audio DAC S/PDIF output for connection with an external amplifier/decoder Internal multiplexer for the S/PDIF output (to share the internal S/PDIF output and the S/PDIF output generated by the external decoder of the digital broadcast)
8/149
STV82x7

General Description
Specific stand-by mode (Loop-through) Control by IC bus (two IC addresses) System PLL and Clock Generation using either a single quartz oscillator or a differential clock input
1.1.2
Software Information
The different software combinations are listed in Table 2.
Table 2: Input/Output Software Configurations
Output (Number of Channels)
Input (Number of Channels) 2 (+1) 1 2 (L and R) ST WideSurround or SRS(R) WOWTM ST WideSurround or SRS(R) WOWTM ST WideSurround or SRS(R) TruSurround XTTM or ST OmniSurround or Dolby(R) Pro Logic(R) + SRS(R) TruSurround XTTM or Dolby(R) Pro Logic(R) +ST OmniSurround SRS(R) TruSurround XTTM or ST OmniSurround or Downmix SRS(R) TruSurround XTTMor ST OmniSurround or Downmix 4 (+1) 5 (+1)
2 (LT and RT)
Dolby(R) Pro Logic(R)
4 (+1)
No processing
5 (+1)
Downmix
No processing
Note: Note:
In addition to the above sound processing, it is always possible to add ST Voice and also ST Dynamic Bass algorithms. The SRS(R) TruSurround(R) and ST OmniSurround are approved by Dolby as Virtual Dolby Surround (VDS) and Virtual Dolby Digital (VDD). The SRS(R) TruSurround XTTM system is composed of:

SRS(R) TruSurround(R) SRS(R) WOWTM
The SRS(R) WOWTM system also includes:

SRS(R) Dialog ClarityTM SRS(R) TruBassTM
1.1.3
Device Input Modes

Demodulator and SCART Mode (with output fS = 32 kHz) SCART Only Mode (with output fS = 48 kHz) IS Mode (with output fS = 32, 44.1 or 48 kHz)
9/149
General Description
STV82x7
-- External audio input interface using 3 x IS (for decoded streams such as Dolby(R) Digital and/or standard stereo streams)
1.1.4
Electrical Features
Multi Power Supply: 1.8 V, 3.3 V and 8 V. Power Consumption:

lower than 1 W in Functional mode (full features) 200 mW in Loop-through mode corresponding to Switch-off of all digital blocks
1.2
Typical Applications
The STV82x7 is specified to enable flexible, analog and digital TV chassis design (refer to Figure 2, Figure 3, Figure 4 and Figure 5). The main considerations are:

all necessary connections between devices can be provided through the TV set, pseudo stand-by mode used to copy to VCR or the DVD sources when the TV set is OFF, possible application compatibility with STV82x6 (TQFP80 package) TV design, pin-to-pin compatibility with STV82x8 (TQFP80 package) TV design.
The STV82x7 is used to process a single audio source (analog or digital). However, it is possible to process two audio sources simultaneously using an STV82x7 interconnection (two chips can be easily connected). In the case of a single audio source, it is possible to hear and record in the same time: the same audio stream can be simultaneously output on headphone, loudspeakers, S/PDIF and the SCART connectors. Note: Headphone and loudspeakers can be used simultaneously for dual-language purposes or for different sound settings (e.g. volume). In this case, certain restrictions occur (see Section 4.2: Audio Processing). For more connections, the SCART-to-SCART path can be used. The use of these full analog paths implies that the sound is not digitally processed.
10/149
STV82x7
General Description
Figure 2: STV8237 Typical Application (Enhanced Stereo)
Tuner
R
STV8237
or Multistandard Demodulation - FM 2-carrier and NICAM Sound Processing - Volume, Balance, 5-Band Equalizer - ST WideSurround - SRS(R) WOWTM
SubW
L
Left Right
Figure 3: STV8247 Typical Application (Analog Virtual Sound)
Tuner
R
STV8247
or Multistandard Demodulation - FM 2-carrier and NICAM Sound Processing - Volume, Balance, 5-Band Equalizer - SRS(R) TruSurround XTTM - ST OmniSurround - Virtual Dolby(R) Surround1 SubW
L
Left Right
1. When using VDS with ST OmniSurround or SRS TruSurround XTTM, a Pro Logic(R) decoder is mandatory.
11/149
General Description
Figure 4: STV8257 Typical Application (Digital: Virtual Sound)
STV82x7
Multi-Channel Digital Decoder (Dolby(R) Digital)
R S/PDIF Pass-thru SubW
IS
Tuner
STV8257
Multistandard Demodulation - FM 2-carrier and NICAM Audio Processing - Volume, Balance, 5-Band Equalizer - SRS(R) TruSurround XTTM - ST OmniSurround - Virtual Dolby(R) Surround1 - Virtual Dolby(R) Digital2
or
L
Left Right
1. When using VDS with ST OmniSurround or SRS TruSurround XTTM, a Pro Logic(R) decoder is mandatory. 2. When using VDD with ST OmniSurround or SRS TruSurround XTTM, a Dolby(R) Digital decoder is mandatory.
Figure 5: STV8277 Typical Application (Digital TV: Multi-Channel and Virtual Sound)
Multi-Channel Digital Decoder (Dolby(R) Digital)
R S/PDIF Pass-thru RS
SubW
IS
Tuner
STV8277
Multistandard Demodulation - FM 2-carrier and NICAM Audio Processing - Volume, Balance, 5-Band Equalizer - Dolby(R) Pro Logic II(R) - 5.1 Analog Outputs - SRS(R) TruSurround XTTM - Virtual Dolby(R) Surround1 - Virtual Dolby(R) Digital2
C LS L
or
Left Right
1. When using VDS with ST OmniSurround or SRS TruSurround XTTM, a Pro Logic(R) decoder is mandatory. 2. When using VDD with ST OmniSurround or SRS TruSurround XTTM, a Dolby(R) Digital decoder is mandatory.
12/149
STV82x7
Figure 6: STV8217 Typical Application (Digital Recorder)
General Description
MPEG Codec
Tuner
IS
or
STV8217
Multistandard Demodulation - FM 2-carrier and NICAM
Left Right
13/149
General Description
STV82x7
1.3
Pin Descriptions and Application Diagrams

AP DP I O OD B A
= Analog Power = Digital Power = Input = Output = Open-Drain = Bi-Directional = Analog
Table 3: TQFP80 Pin Description (Sheet 1 of 3)
Pin No.
1 2 3 4 5 6 7 8 9 10
STV82x7 Pin Name
SC1_OUT_L SC1_OUT_R VCC_H GND_H SC3_OUT_L SC3_OUT_R VCC33_SC GND33_SC SC1_IN_L SC1_IN_R
Type (STV82x7)
A A AP AP A A AP AP A A
Function for STV82x7 (Function for STV82x6 in italic characters)
SCART1 Audio Output Left SCART1 Audio Output Right 8V Power for Audio I/O & ESD High Current Ground for Audio Outputs SCART3 Audio Output Left SCART3 Audio Output Right 3.3V Power for Audio Buffers & DAC / ADC Ground for Audio Buffers & DAC / ADC SCART1 Audio Input Left SCART1 Audio Input Right Audio Bias Voltage Decoupling 1.55V (Switched VREF decoupling pin for Audio Converters (VMCP)) Ground for DACs Bandgap Voltage Reference Decoupling 1.2V (VREF decoupling pin for Audio Converters (VMC)) SCART2 Audio Input Left SCART2 Audio Input Right 3.3V Power for Audio DACs (3.3V Power Supply for Audio Buffers and SCART) Ground for Audio DACs (Ground for Audio Buffers and SCART) SCART2 Audio Output Left SCART2 Audio Output Right Polarization of the NISO (connected to 3.3V) (8V / 5V Power supply for SCART & Audio buffers) Ground for DAC 1.8 to 3.3V Converters 3.3V Power for DAC 1.8 to 3.3V Converters (Voltage Reference for Audio buffers) AO1L
STV82x6 Pin Name
AO1R Not connected Connected to Ground Not connected Not connected VDDC GNDC AI1L AI1R
11 12 13 14 15 16 17 18 19 20 21 22
VREFA GND_SA VBG SC2_IN_L SC2_IN_R VCC33_LS GND33_LS SC2_OUT_L SC2_OUT_R VCC_NISO VSS33_CONV VDD33_CONV
A AP A A A AP AP A A AP AP AP
VMC1 Connected to Ground VMC2 AI2L AI2R VDDA GNDAH AO2L AO2R VDDH Connected to Ground VREFA
14/149
STV82x7
Table 3: TQFP80 Pin Description (Sheet 2 of 3) Pin No.
23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52
General Description
STV82x7 Pin Name
SC3_IN_L SC3_IN_R SCL_FLT SCR_FLT LS_C LS_L LS_R LS_SUB HP_LSS_L HP_LSS_R VSS18_CONV VDD18_CONV HP_DET ADR_SEL VSS18 VDD18 SCL SDA VSS18 VDD18 RST S/PDIF_IN S/PDIF_OUT VDD33_IO1 VSS33_IO1 CK_TST_CTRL VSS18 VDD18 CLK_SEL XTALIN_CLKXTP
Type (STV82x7)
A A A A A A A A A A DP DP I I DP DP OD OD DP DP I I O DP DP D DP DP I I
Function for STV82x7 (Function for STV82x6 in italic characters)
SCART3 Audio Input Left SCART3 Audio Input Right SCART Filtering Left SCART Filtering Right (Bandgap Voltage Source Decoupling) Center Output Left Loudspeaker Output Right Loudspeaker Output Subwoofer Output Left Headphone Output or Left Surround Output Right Headphone Output or Right Surround Output Ground for Digital part of the DAC/ADC (Substrate Analog/Digital Shield) 1.8V Power for Digital part of the DAC/ADC Headphone Detection Hardware Address selection for IC Bus Ground for Digital part 1.8V Power for Digital part IC Clock Input IC Data I/O Ground for Digital part 1.8V Power for Digital part (5V Power Regulator Control) Main Reset Input Serial Audio Data Input (System Clock output) Serial Audio Data Output (IS Master Clock output) 3.3V Power for Digital part Ground for Digital part To be Grounded Ground for Digital part 1.8V Power for Digital part Clock Input Format Selection Crystal Oscillator Input or Differential Input Positive (Crystal Oscillator Input) AI3L AI3R
STV82x6 Pin Name
Not connected BGAP Not connected LSL LSR SW HPL HPR GNDSA Not connected HPD ADR Connected to Ground Not connected SCL SDA Connected to Ground REG RESET SYSCK MCK VDD1 GND1 Not connected GNDSP Not connected Not connected XTI
15/149
General Description
Table 3: TQFP80 Pin Description (Sheet 3 of 3) Pin No.
53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80
STV82x7
STV82x7 Pin Name
XTALOUT_CLKXTM VCC18_CLK1 GND18_CLK1 GND18_CLK2 VCC18_CLK2 VSS33_IO2 VDD33_IO2 I2S_PCM_CLK I2S_SCLK I2S_LR_CLK I2S_DATA0 I2S_DATA1 I2S_DATA2 VDD18 VSS18 BUS_EXP IRQ GND_PSUB VDD18_ADC VSS18_ADC SIF_P SIF_N GNDPW_IF VCC18_IF GND18_IF MONO_IN SC4_IN_L SC4_IN_R
Type (STV82x7)
O AP AP AP DP DP DP I/O I/O I/O I/O I I DP DP O O AP DP DP A A AP AP AP A A A
Function for STV82x7 (Function for STV82x6 in italic characters)
Crystal Oscillator Output or Differential Input Negative (Crystal Oscillator Output) 1.8V Power for Clock PLL Analog & Crystal Oscillator 1/2 (3.3V Power supply for Analog PLL Clock) Ground for Clock PLL Analog & Crystal Oscillator 1/2 Ground for Clock PLL Digital 1/2 1.8V Power for Clock PLL Digital 1/2 (3.3V Power supply for Digital core, DSPs & IO Cells) Ground for Digital IO pins 60 to 69 3.3V power for Digital IO pins 60 to 69 IS Slave Clock Input/Output Channel 1, 2 & 3 IS Clock Input/Output Channel 1, 2 & 3 (IS bus data output) IS Word Select Input/Output Channel 1,2 & 3 (Stereo Detection output / IS Bus Data input) IS Data Input/Output Stereo Channel 1 (IS Bus Word Select output) IS Data Input Stereo Channel 2 (IS Bus Clock output) IS Data Input Stereo Channel 3 (Bus Expander Output 1) 1.8V Power for Digital Core & I/O Cells Pin Ground for Digital Core & I/O Cells Pin Bus Expander Function (Bus Expander Output 2) Interrupt Request to Microprocessor Ground Substrate Connection VDD 1.8V for ADC (Digital Part) Ground to Complement 1.8V VDD for ADC Sound IF input (positive) Sound IF input (negative) (ADC VTOP Decoupling pin) Polarization for the IF block (Voltage Reference for AGC Decoupling pin) 1.8V Power for IF AGC & ADC Ground for IF AGC & ADC Mono Input (for AM Mono) SCART4 Audio Input Left SCART4 Audio Input Right XTO
STV82x6 Pin Name
VDDP GNDP GND2 VDD2 Connected to Ground Not connected Not connected SDO ST/SDI WS SCK BUS1 Not connected Connected to Ground BUS0 IRQ Connected to Ground Not connected Connected to Ground SIF VTOP VREFIF VDDIF GNDIF MONOIN Not connected Not connected
16/149
STV82x7
LS Center
LS Left
LS Right
Subwoofer
HP Left/LS surround Left
HP Right/LS surround Right
L17 L2 10H + C9 330F L18 C10 100nF 100H L14 1
1
+1.8V C69 33nF C68 100H 33nF C67 33nF C66 33nF C65 33nF C64 33nF
100H L15
L16 100H
Headphone detection
+3.3V SL1 100H 2 3
3
100H L13
100nF C12 Address select C13 100nF
+
C63 33nF C62 33nF
+
SCL
SDA
40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21
C14 100nF C15 C75 220 C58 100nF C74 220 C57 100nF 330pF R8 330pF 100nF + L1 10H +3.3V R9
R1
+3.3V
+
470K
C16 470nF
Reset
+
SPDIF IN
SDA SCL VDD18 VSS18 ADR_SEL HP_DET VDD18_CONV VSS18_CONV HL_LSS_R HP_LSS_L LS_SUB LS_R LS_L LS_C SCR_FLT SCL_FLT SC3_IN_R SC3_IN_L VDD33_CONV VSS33_CONV
+
SPDIF OUT
+
L4 C18 100nF TQFP80 C19 100nF IC1 STV82x7
+3.3V
+
10H
+ C17 10F
+
C46 1F
+
10F C45 1F SC1 IN Right C73 C47 330pF
+
R7 R6 220 C72 330pF C42 100nF R5 220 330pF R4 220 + C41 10F
C25 100nF
220 C44 100nF 10F
+
+
+1.8V C26 100nF C27 100nF
61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80
C21
41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 VSS18 VDD18 RST_N SPDIF_IN SPDIF_OUT VDD33_IO VSS33_IO CK_TST_CTRL VSS18 VDD18 CLK_SEL XTALIN/CLKXTP XTALOUT/CLKXTM VCC18_CLK1 GND18_CLK1 GND18_CLK2 VCC18_CLK2 VSS33_IO VDD33_IO I2S_PCM_CLK 10H L12 C71 C70 330pF +8V VCC_NISO SC2_OUT_R SC2_OUT_L GND33_LS VCC33_LS SC2_IN_R SC2_IN_L VBG GND_SA VREFA SC1_IN_R SC1_IN_L GND33_SC VCC33_SC SC3_OUT_R SC3_OUT_L GND_H VCC_H SC1_OUT_R SC1_OUT_L
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
1.8V
27pF
+
+
I2S_SCLK I2S_LR_CLK I2S_DATA0 I2S_DATA1 I2S_DATA2 VDD18 VSS18 BUS_EXP IRQ GND_PSUB VDD18_ADC VSS18_ADC SIF_P SIF_N GND_PWIF VCC18_IF GND18_IF MONO_IN SC4_IN_L SC4_IN_R
C22
XT1 27MHz CRYSTAL
+
1.8V
Figure 7: STV82x7 Application Diagram
27pF
C37
+
+
C33 100nF + C43 47F L10 10H C34 22nF C35 IRQ
R3 560
L6
1.8V
C32 220nF
10H
+ C23
47F
10H
C29 100nF C30 100nF
L11
+ C61 1F C60 1F C59 47F C56 10F C55 10F C53 1F C54 1F C52 100nF C51 10F C50 100nF C49 C48 10F C40 10F C39 10F C38 1F 1F C36 1F +1.8V 100pF
+
+
+
+
C8 1F
C7 1F
C6 1F
C5 1F
C4 1F
C3 1F
+
SC3 IN Right SC3 IN Left
SC2 OUT Right SC2 OUT Left
SC2 IN Right SC2 IN Left
SC1 IN Left SC3 OUT Right SC3 OUT Left SC1 OUT Right SC1 OUT Left SC4 IN Right SC4 IN Left Mono IN
SIF
BUS EXPANDER I2S DATA 2 I2S DATA 1 I2S DATA 0 I2S LR CLK I2S SCLK I2S PCM CLK
General Description
17/149
L17
+1.8V + C9 330F L18 C69 33nF 100H C68 33nF C67 33nF C66 33nF C65 33nF C64 33nF
L8
*
10H
*
L16 100H
C10 100nF L15
100H
* *
L14
Headphone detection 100H 1
1
*
L13
+3.3V SL1 100H 2 C63 3 Address select 10F C13 100nF
+ 3
100H
*
+ C78
100nF C12 C62 33nF
+
SCL
SDA
40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21
C14 100nF +3.3V 0 R13 220 C58 100nF + C77 10F 220 C57 100nF 0 R11 330 0 + R19 C74 330pF R10 R8 C75 330pF R9
L2 10H
+8V
R1
+3.3V
+
470K
Reset
C16 470nF C15 100nF 0 C76 10F
+
SPDIF IN
SDA SCL VDD18 VSS18 ADR_SEL HP_DET VDD18_CONV VSS18_CONV HL_LSS_R HP_LSS_L LS_SUB LS_R LS_L LS_C SCR_FLT SCL_FLT SC3_IN_R SC3_IN_L VDD33_CONV VSS33_CONV
R14
+
SPDIF OUT
+8V
+
L7
+3.3V C19 100nF TQFP80 IC1 STV82x6 / STV82x7
+
10H
+ C17 10F
R18
0
C18 100nF
+
C46 1F
+
10F C45 1F SC1 IN Right C73 C41 10F R12 82 +8V 330pF C47
+
+1.8V R7 220 C72 330pF C42 100nF R5 220 330pF R4 220 + C43 10F R6 220 C25 100nF
+
1
+1.8V
SL2
C44 100nF
C21 C26 100nF C27 100nF
61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80
+
2
41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 VSS18 VDD18 RST_N SPDIF_IN SPDIF_OUT VDD33_IO VSS33_IO CK_TST_CTRL VSS18 VDD18 CLK_SEL XTALIN/CLKXTP XTALOUT/CLKXTM VCC18_CLK1 GND18_CLK1 GND18_CLK2 VCC18_CLK2 VSS33_IO VDD33_IO I2S_PCM_CLK VCC_NISO SC2_OUT_R SC2_OUT_L GND33_LS VCC33_LS SC2_IN_R SC2_IN_L VBG GND_SA VREFA SC1_IN_R SC1_IN_L GND33_SC VCC33_SC SC3_OUT_R SC3_OUT_L GND_H VCC_H SC1_OUT_R SC1_OUT_L 10H L3 C71 C70 330pF +8V
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
+
3
1
+1.8V
+
SL3
270k
0
I2S_SCLK I2S_LR_CLK I2S_DATA0 I2S_DATA1 I2S_DATA2 VDD18 VSS18 BUS_EXP IRQ GND_PSUB VDD18_ADC VSS18_ADC SIF_P SIF_N GND_PWIF VCC18_IF GND18_IF MONO_IN SC4_IN_L SC4_IN_R
XT1 27MHz CRYSTAL
R2
R15
+
C40 10F C39 10F
C37
+
2
+
C22 C33 0 100nF C32 220nF + C79 47F
R16 C36 L4 +3.3V 10H L5 +1.8V 10H C34 C35
1F
1.8V
10H
3
L6
+ C23
47F
560
10H
Figure 8: STV82x6/STV82x7 Compatible Application Electrical Diagram
C29 100nF C30 100nF
L11
22nF R17 C31 100nF 0
R3
100pF
STV82x7
Note :
components with * are only mandatory
in case of DOLBY certification
+
+
+
+
+
+
+
+
18/149
with C8 1F C7 1F C6 1F C5 1F C4 1F C3 1F Part L1 L2 L3 L4 L5,L6 L8 L13,L14 L15,L16 L17,L18 R2 R10 R11 R12 R13 R14 R15 R16 R17 R18 R19 C3 C9 C10,C13 C15,C18 C21,C22 C23 C27,C29 C30 C31 C41 C42 C43 C59 C63 C64,C65 C66,C67 C68,C69 C70,C71 C72,C73 C74,C75 C76,C77 C78 C79 SL2 SL3 with STV82x6 Not Connected 10H Not Connected 10H Not Connected Not Connected strap strap strap 270K 330 Not Connected 82 Not Connected 0 ohm 0 ohm Not Connected Not Connected 0 ohm Not Connected Not Connected Not Connected Not Connected Not Connected 22 pF Not Connected Not Connected Not Connected 100 nF 10 F Not Connected Not Connected 10 F 100 nF Not Connected Not Connected Not Connected Not Connected Not Connected Not Connected 10 F 10 F 10 F between 2-3 between 2-3 STV82x7 10H Not Connected 10H Not Connected 10H 10H 100H * 100H * 100H * Not Connected Not Connected 0 ohm Not Connected 0 ohm Not Connected Not Connected 0 ohm 0 ohm Not Connected 0 ohm 1 F 330 F 100 nF 100 nF 27 pF 47 F 100 nF 100 nF Not Connected Not Connected 100 nF 10 F 47 F 33 nF 33 nF 33 nF 33 nF 330 pF 330 pF 330 pF Not Connected Not Connected 47 F between 1-2 between 1-2 SC3 IN Right SC3 IN Left C61 1F C60 1F C59 47F L1 10H SC2 OUT Right SC2 OUT Left C56 10F C55 10F SC2 IN Right SC2 IN Left 100nF C51 10F C50 100nF C49 C53 1F C54 1F C52 SC1 IN Left 10F C48 10F SC3 OUT Right SC3 OUT Left SC1 OUT Right SC1 OUT Left C38 1F 1F SC4 IN Right SC4 IN Left Mono IN SIF IRQ BUS EXPANDER / BUS0 I2S DATA 2 / BUS1 I2S DATA 1 / SCK I2S DATA 0 / WS I2S LR CLK / SDI I2S SCLK / SDO I2S PCM CLK
LS Center
LS Left
LS Right
Subwoofer
HP Left/LS surround Left
General Description
HP Right/LS surround Right
LS Center
STV82x7
LS Left
LS Right
Subwoofer
HP Left/LS surround Left
HP Right/LS surround Right
Table 1 : SL1 configuration + C65 33nF C64 33nF C63 33nF C62 33nF + C66 33nF L13 * 100H + C67 33nF L14 * 100H SL1 + L17 * + C9 330F L18 * C10 100nF L15 * 100H 1 100H L16 * 100H C69 33nF C68 33nF 100H + C13 C8 1F STV82x7 : between 2 and 3 (pin 20 connected to 3.3V) STV82x8 : between 1 and 2 (pin 20 connected to ground) C7 1F C6 1F C5 1F C4 1F C3 1F + 100nF C12
+1.8V
L2
10H
Headphone detection
1
2
3 Address select
+3.3V
3
+
+
SCL
100nF
SC3 IN Right SC3 IN Left
C61 1F C60 1F
SDA +3.3V
C14 100nF
R1
40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21
3
+3.3V C75
470K
C15
R9 220 330pF SL1 ( see Table 1) R8 C74 220 C57 100nF 330pF
+
C16 470nF
Reset
2
C58 100nF
+
100nF
SPDIF IN
1
+
SDA SCL VDD18 VSS18 ADR_SEL HP_DET VDD18_CONV VSS18_CONV HL_LSS_R HP_LSS_L LS_SUB LS_R LS_L LS_C SCR_FLT SCL_FLT SC3_IN_R SC3_IN_L VDD33_CONV VSS33_CONV
SPDIF OUT
+
L4 C19 100nF TQFP80 IC1 STV82x7 or STV82x8
+3.3V
+
10H
+ C17 10F
C18 100nF
+
C46 1F
10F
+ +
+
R7 220 C73 C72 330pF C42 100nF R5 220 330pF R4 220 C71 + + 10H L12 +8V C41 10F R6 220
C25 100nF
330pF
C44 100nF
+
+1.8V
C21
+
1.8V C27 100nF
C26 100nF
41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 VSS18 VDD18 RST_N SPDIF_IN SPDIF_OUT VDD33_IO VSS33_IO CK_TST_CTRL VSS18 VDD18 CLK_SEL XTALIN/CLKXTP XTALOUT/CLKXTM VCC18_CLK1 GND18_CLK1 GND18_CLK2 VCC18_CLK2 VSS33_IO VDD33_IO I2S_PCM_CLK
+
VCC_NISO SC2_OUT_R SC2_OUT_L GND33_LS VCC33_LS SC2_IN_R SC2_IN_L VBG GND_SA VREFA SC1_IN_R SC1_IN_L GND33_SC VCC33_SC SC3_OUT_R SC3_OUT_L GND_H VCC_H SC1_OUT_R SC1_OUT_L
20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
27pF
+
I2S_SCLK I2S_LR_CLK I2S_DATA0 I2S_DATA1 I2S_DATA2 VDD18 VSS18 BUS_EXP IRQ GND_PSUB VDD18_ADC VSS18_ADC SIF_P SIF_N GND_PWIF VCC18_IF GND18_IF MONO_IN SC4_IN_L SC4_IN_R
C22
XT1 27MHz CRYSTAL
C70 330pF C37 1F
+
1.8V
27pF
61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80
+
+
R11
L6 100nF L10 10H +
1.8V
C32 220nF C43 47F
10H
+ C23
+1.8V SIF C34 22nF C35 IRQ 100pF
47F
10K
C33
R3
560
10H
C29 100nF C30 100nF
L11
Figure 9: STV82x7/STV82x8 Compatible Application Electrical Diagram (TQFP80)
General Description
19/149
Note : components with * are only mandatory in case of Dolby certification
+ L1 10H C40 10F C39 10F C36 1F
C59 47F
SC2 OUT Right SC2 OUT Left
C56 10F C55 10F
SC2 IN Right SC2 IN Left 100nF C51 10F C50 100nF C49
C53 1F C54 1F C52
C45 1F
SC1 IN Right C47 10F C48 10F SC1 IN Left SC3 OUT Right SC3 OUT Left SC1 OUT Right SC1 OUT Left C38 1F R12 10K SC4 IN Right SC4 IN Left Mono IN
BUS EXPANDER I2S DATA 2 I2S DATA 1 I2S DATA 0 I2S LR CLK I2S SCLK I2S PCM CLK
System Clock
STV82x7
2
System Clock
The System Clock integrates 2 independent frequency synthesizers. The first frequency synthesizer can be used in one of two modes:

In Mode 1, it is used by the demodulator, and the frequecy is 49.152 MHz. In Mode 2, it is used by the IS input and is synchronous with the input frequency (fS = 32, 44.1 or 48 kHz) and the frequency is 49.152 MHz (for fS = 32 or 48 KHz) or 45.1584 MHz (for fS = 44.1 KHz).
The second frequency synthesizer is used by the DSP core and can be adjusted between 100 and 150 MHz depending on the application (around 106 MHz at reset value). The default values are designed for a standard 27-MHz reference frequency provided by a stable single crystal or an external differential clock signal (for example, from the STV35x0) depending on the CLK_SEL pin configuration (CLK_SEL = 1 means a single crystal, 0 means an external differential clock). The 27-MHz value is the recommended frequency for minimizing potential RF interference in the application. The sinusoidal clock frequency, and any harmonic products, remain outside the TV picture and sound IFs (PIF/SIF) and Band-I RF. Note: A change in the reference frequency is compatible with other default IC programming values, including those of the built-in Automatic Standard Recognition System.
20/149
STV82x7
Digital Demodulator
3
Digital Demodulator
The Digital Demodulator (see Figure 10) is composed of two channels. The first channel demodulates an FM or an AM signal. The second channel demodulates FM 2-carrier or NICAM signals (stereo demodulation). All channel parameters are programmed automatically by the built-in Automatic Standard Recognition System (Autostandard) in order to find the correct sound standard. Channels can also be programmed manually via the IC interface for very specific standards not included among the known standards.
Figure 10: Demodulator Block Diagram
Channel 1 = Mono Left AM Demodulator DCO1+ Mixer CAROFFSET1 (22h) Channel Filter FIR1 FM Demodulator AM
AM/FM Mono (To Sound Preprocessing) FML
AUTOSTD_STATUS (8Eh) SIF AGC Amp A/D AUTOSTD AGC Control AGC_CTRL (0Eh) AGC_GAIN (0Fh) AUTOSTD_TIMERS (8Dh) AUTOSTD_CTRL (8Ah) AUTOSTD_STANDARD_DETECT (8Bh) AUTOSTD_STEREO_DETECT (8Ch) FM Demodulator DCO2 + Mixer Channel Filter FIR2 CAROFFSET2 (3Ah) Channel 2 = Stereo/Mono Right DQPSK Demodulator NICAM Decoder Zweiton Decoder DEMOD_STAT(0Dh) ZWT_STAT (42h) NICAM_STAT(3Fh)
FM Stereo (To Sound Preprocessing)
NICAM L NICAM R (To Sound Preprocessing)
3.1
Sound IF Signal
The Analog Sound Carrier IF is connected to the STV82x7 via the SIF pin. Before Analog-to-Digital Conversion (ADC), an Automatic Gain Control (AGC) is performed to adjust the incoming IF signal to the full scale of the ADC. A preliminary video rejection is recommended to optimize conversion and demodulation performances. The AGC system provides a gain value allowing for a wide range of SIF input levels and is activated for all standards, except L/L'. In this particular case, the sound carrier is AM-modulated and an automatic level adjustment would only damage the transmitted audio signal. A preset IC parameter is provided to define the gain of the AGC used in Manual mode (Registers AGC_CTRL and AGC_GAIN).
Note:
For optimum AM demodulation performance, it is recommended to use the MONO Input.
21/149
Digital Demodulator
STV82x7
3.2
Demodulation
The demodulation system operates by default in Automatic mode. In this mode, the STV82x7 is able to identify and demodulate any TV sound standard including NICAM and A2 systems (see Table 4) without any external control via the IC interface. It consists of the two demodulation channels (Channel 1 = Mono Left and Channel 2 = Mono Right/Stereo) to simultaneously process two sound carriers in order to handle all transmission modes (stereo and up to three mono languages). The built-in Automatic Standard Recognition System (Autostandard) automatically programs the appropriate bits in the IC registers which are forced to Read-only mode for users (see Section 12.1). The programming is optimized for each standard to be identified and demodulated. Each mono and stereo standard can be removed (or added) from the List of Standards to be recognized by programming registers AUTOSTD_STANDARD_DETECT and AUTOSTD_STEREO_DETECT, respectively. The identified standard is displayed in register AUTOSTD_STATUS and any change to standard is flagged to the host system via pin IRQ. This flag must be reset by re-programming the MSBs of register AUTOSTD_CTRL while checking the detected standard status by reading registers AUTOSTD_STATUS, NICAM_STAT and ZWT_STAT. Moreover, the detection of Stereo mode during demodulation is also flagged in register AUTOSTD_STATUS. Important: L/L' and D/K standards cannot be automatically processed because the same frequency is used for the MONO carrier. An exclusive L/DK selection must programmed in register AUTOSTD_CTRL. This may be externally controlled by detecting the RF modulation sign, which is negative for all TV standards except L/L'. To recover out-of standard FM deviations or the Sound Carrier Frequency Offset, additional IC controls are provided without interfering with the Automatic Standard Recognition System (Autostandard). DK-NICAM Overmodulation Recovery: Four different FM deviation ranges can be selected (via register AUTOSTD_CTRL) for the DK standard while the Autostandard system remains active. The maximum FM deviation is 500 kHz in DK Mono mode and 350 kHz in DK NICAM mode (limited by overlapping FM and NICAM spectrum values). The demodulated signal peak level (proportional to the FM deviation) is detected by the Peak Detector and written to registers PEAK_DET_L and PEAK_DET_R. This value is used to implement Automatic Overmodulation Detection via an external IC control. Important: Only the selection of the 50 kHz FM deviation standard is compatible with the other DKA2* standards (DK1, DK2 or DK3). These standards must be removed from the list of standards (registers AUTOSTD_STANDARD_DETECT and AUTOSTD_STEREO_DETECT) when programming larger FM deviations reserved only for DK-NICAM standards.
Table 4: Recognized Standards Type Name Carrier 1 (MHz) 5.5 5.5 A2 5.5 6.5 6.5 A2* 6.5 5.850 6.258 27 50 80 J17 50 s 40 54.6875 5.850 5.742 27 27 50 50 80 80 J17 50 s 40 54.6875 Carrier 2 (MHz) Roll Pilot De-off Frequency emphasis (%) (kHz) Nom. Max. Over FM Deviation
System
Sound Type FM Mono
B/G
FM/NICAM FM 2-Carrier FM Mono
D/K FM/NICAM D/K1 22/149 FM 2-Carrier
STV82x7
Table 4: Recognized Standards (Continued) Type Name A2* A2* Carrier 1 (MHz) 6.5 6.5 6.0 6.0 6.5 4.5 A2+ 4.5 4.724 6.552 5.850 15 15 27 27 50 50 27 50 80 Carrier 2 (MHz) 6.742 5.742
Digital Demodulator
System D/K2 D/K3 I
Sound Type FM 2-Carrier FM 2-Carrier FM Mono FM/NICAM
Roll Pilot Deemphasis -off Frequency (%) (kHz) Nom. Max. Over 50 s 50 s 54.6875 54.6875
FM Deviation
J17 J17 75 s 75 s
100 40
L M/N
AM/NICAM FM Mono FM 2-Carrier
55.069
For Chinese TV transmissions (DK-NICAM) which are subject to overmodulation, different FM deviations are proposed for sound demodulation. Sound Carrier Frequency Offset Recovery: Both Mono and Stereo IF Carrier frequencies can be adjusted independently (registers CAROFFSET1 and CAROFFSET2) within a large range (up to 120 kHz for standard mono FM deviations) while the Automatic Standard Recognition System remains active. The frequency offset estimation is written in registers DC_REMOVAL_L and DC_REMOVAL_R (Mono Left / Channel 1 and Mono Right / Channel 2, respectively) and can be used to implement the Automatic Frequency Control (AFC) via an external IC control. Manual Mode: If required, the Automatic Standard Recognition System system can be disabled (Manual mode) and the user can control all registers including those only controlled by the Automatic Standard Recognition System function when active. Manual mode is selected in register AUTOSTD_STANDARD_DETECT (bit LDK_SCK, I_SCK, BG_SCK and MN_SCK set to 0).
23/149
Dedicated Digital Signal Processor (DSP)
STV82x7
4
Dedicated Digital Signal Processor (DSP)
A dedicated Digital Signal Processor (DSP) takes charge of all audio processing features and the low frequency signal processing features of the demodulator. The internal 24-bit architecture will ensure a high quality signal treatment and an excellent dynamic.
4.1
Back-end Processing
The "back-end" processing corresponds to the low frequency signal processing (32 kHz or higher frequencies) of the demodulator and other inputs (IS, ADC). Figure 11 shows a flowchart of the back-end processing tasks. However, the figure shows that the processing is only a SINGLE SOURCE PROCESSING flow (no processing is possible with "Demod + SCART" and IS inputs simultaneously) and that the selection of a headphone output restricts the loudspeakers configuration to 2+1 instead of 5+1.
Figure 11: Back-end Audio Processing
"Demod + SCART" or "SCART only" Input Modes
Autostandard
FM Channel1 FM Channel2
DC Removal Stereo Peak Detector: 9D, bit 7 = 1
FM De-emphasis
FM Prescale
FM Dematrix Stereo Peak Detector: 9D, bit 7 = 0
2
LS
Digital Audio Matrix
(L and R)
NICAM L NICAM R
DC Removal
NICAM De-emphasis
NICAM Prescale
NICAM Dematrix
2
HP
(L and R)
2
SCART
(L and R)
SCART L SCART R
DC Removal
SCART Prescale
Stereo Peak Detector: 9D, bit 7 = 1
Stereo Peak Detector: 9D, bit 7 = 0
"I2S" Input Mode
I2S in 1 I2S in 2 I2S in 3
2 to 6
LS
(L,R,C,LFE,Ls,Rs)
SRC X2/X4
IS Prescale
DownMix
2
HP
(L and R)
2
SCART
(L and R)
24/149
STV82x7
The main features depend on the path:
Dedicated Digital Signal Processor (DSP)
FM Channel -- DC Removal -- Prescaling -- De-emphasis (50 or 75 us) -- Stereo Dematrix
NICAM Channel -- DC Removal -- Prescaling -- De-emphasis (J17) -- Dematrix
Input SCART Channel -- DC Removal -- Prescaling
Input IS Channel -- IS Prescaling Digital Audio Matrix -- Audio Channel Multiplexer between the different sources (IF, IS, SCART) towards all outputs (S/PDIF, LS, HP or SCART).
Autostandard management -- device configuration depending on the standard to be detected -- freeze the device when a standard is detected -- once a standard detected, check that there is no change in the detection status -- set the correct action depending on any change in the detection status (mono backup or mute setup and new standard detection)
SCART -- Downmixing: LT / RT or L0 / R0 (see AC-3 specification) -- Soft Mute
4.2
Audio Processing
The following software is provided for main loudspeakers (L, R, C, LS, RS, SubW):

Downmix Dolby(R) Pro Logic II(R) Decoder (LT, RT L, R, C, Ls, Rs, SubW) with Bass Management ST WideSurround, ST OmniSurround, SRS(R) WOWTM or SRS(R) TruSurround XT(R) (certified
Virtual Dolby(R) Surround and Virtual Dolby(R) Digital)

ST Dynamic Bass Smart Volume Control (SVC) 5-band Equalizer or Bass-Treble Loudness Volume with independent channels (Smooth Volume Control) Master Volume Control Mute/soft-mute
25/149
Dedicated Digital Signal Processor (DSP)

STV82x7
Balance Beeper Pink Noise Generator (used to position the loudspeakers) Programmable Delay for each loudspeaker Adjustable Delay for "lip sync" up to 120 ms (to compensate audio/video latency) in SCART Only Mode and up to 180 ms in Demodulator and SCART Mode
The following software is provided for the headphone or auxiliary output:

Downmix SRS(R) TruBassTM Smart Volume Control (SVC) Bass/Treble Loudness Independent Volume for each channel (Smooth Volume Control) Soft Mute Balance Beeper Adjustable Delay for "lip sync" up to 120 ms (to compensate audio/video latency) in SCART Only Mode and up to 180 ms in Demodulator and SCART Mode
The following software is provided for SCART or S/PDIF outputs:

Downmix Soft Mute
26/149
STV82x7
S/PDIF Input
S/PDIF Select
Digital Soft Mute S/PDIF Output
L SCART Volume Balance SCART Output Digital Soft Mute
R SCART
L SRS TruBass Volume Balance Digital Soft Mute
R
Adjustable Delay
ST Wide Surround
ST Bass / Dynamic Treble or 5 bands Bass Equalizer
S
LS Output
1to2/2to2 Volume
or
SRS TruSurround XT Digital Soft Mute
C 2/0 and 3/2 SVC Loud- Bass ness Mgmt. Volume
Dolby Pro Logic or Pro Logic II Decoder
Center Output
LFE
ST OmniSurnd
Digital Soft Mute
Subwoofer Output
Ls Volume Balance
Rs
Digital Soft Mute
Surround Output
R HP
Adjustable Delay SRS TruBass SVC
Bass/ Treble
Loudness
Volume Balance
Digital Soft Mute
S
Beeper
Figure 12: Audio Processing for Loudspeakers, Headphone, SCART and S/PDIF outputs
Headphone Output
output Select
L HP
Dedicated Digital Signal Processor (DSP)
27/149
Dedicated Digital Signal Processor (DSP)
STV82x7
4.3
ST WideSurround
STV82x7 offers three preset ST WideSurround Sound effects on the Loudspeakers path:

Music, a concert hall effect Movie, for films on TV Simulated Stereo, which generates a pseudo-stereo effect from mono source
"ST WideSurround Sound" is an extension of the conventional stereo concept which improves the spatial characteristics of the sound. This could be done simply by adding more speakers and coding more channels into the source signal as is done in the cinema, but this approach is too costly for normal home use. The ST WideSurround system exploits a method of phase shifting to achieve a similar result using only two speakers. It restores spatiality by adding artificial phase differences. The Surround/Pseudo-stereo mode is automatically selected by the Automatic Standard Recognition System (Autostandard) depending on the detected stereo or mono source. By default, "Movie" is selected for Surround mode. This value may be changed to "Music" by the STSRND_MODE bit in the STSRND_CONTROL register. Additional user controls are provided to better adapt the spatial effect to the source. The ST WideSurround Gain (STSRND_LEVEL) and ST WideSurround Frequency (STSRND_FREQ) registers can be used to enhance Music Predominancy in Music mode and Theater effect and Voice Predominancy in Movie mode.
4.4
ST OmniSurround
STV82x7 offers a spatial virtualizer to output any multi-channel input in stereo on the Loudspeakers path: "ST OmniSurround" will recreate a multi-channel spatial sound environment using only the Left and Right front speakers. It can be adapted to any input configuration (OMNISRND_INPUT_MODE). ST Voice will allow you to enhance the voice content of your program to increase the intellegibility and the presence of the sound.
4.5
Dolby Pro Logic II Decoder
Dolby(R) Pro Logic II(R) is a matrix decoder that decodes the five channels of surround sound that have been encoded onto the stereo sound tracks of Dolby(R) Surround program material such as DVD movies and TV shows. It is even possible to decode standard stereo signals like music or non encoded movies. Furthermore, it is an active process designed to enhance sound localization through the use of very high-separation decoding techniques. The Dolby(R) Pro Logic II(R) decoder is also able to emulate the former Dolby(R) Pro Logic(R) decoder in a specific mode.
4.6
Bass Management
This processing will generate the subwoofer signal and adjust all loudspeakers channels gain and bandwidth. Speakers capable of reproducing the entire frequency range will be referred to as "full range speakers", then signals sent to full range speaker will be full bandwidth (no filtering).
28/149
STV82x7
Dedicated Digital Signal Processor (DSP)
Speakers that have limited bass handling capabilities will be referred to as "satellite speakers", then signals sent to satellite speaker will be high-pass filtered to remove bass information below 100 Hz. In the STV82x7, five output configuration modes have been implemented according to "Dolby Digital Consumer Decoder" specifications. They are described below.
4.6.1
Bass Management Configuration 0
In some cases, the bass management filters are available in the decoder itself, so there is no need to reproduce these filters. The output configuration shown in Figure 13 offers this possibility.
Figure 13: Bass Management Configuration 0 (with Pro Logic switch indicating its reset state) L L
R
R
C
C
Ls
Ls
Rs -15 dB LFE -5 dB +
Rs
SubW
29/149
Dedicated Digital Signal Processor (DSP) 4.6.2 Bass Management Configuration 1
STV82x7
Configuration 1, shown in Figure 14, assumes that all five speakers are not full range and that all of the bass information will be redirected to and reproduced by a single subwoofer. This configuration is intended for use with 5 satellite speakers. To prevent signal overload, the five main channels are attenuated by 15 dB, while the LFE channel is attenuated by 5dB to maintain the proper mixing ratio.
Figure 14: Bass Management Configuration 1 (with Pro Logic switch indicating its reset state) L
L
R
R
C
C
Ls
Ls
Rs -15 dB LFE -5 dB +
Rs
SubW
30/149
STV82x7 4.6.3 Bass Management Configuration 2
Dedicated Digital Signal Processor (DSP)
Configuration 2 assumes that the left and right speakers, are full range while the center and surround speakers are smaller speakers. Also, all bass data is redirected to the left and right speakers. This configuration include output level adjustment that allows 12 dB attenuation for the 3 smaller speakers (C, Ls, Rs). When the level adjustment will be disabled the decoder boosts by 12 dB the full range speakers (Left, Right).
Figure 15: Bass Management Configuration 2 (all switches indicate their reset state)
Level Adjustment OFF Switch L -12 dB + -1.5 dB C -12 dB C R +12 dB -1.5 dB Ls -12 dB + Rs -15 dB LFE -5 dB + SubW -12 dB Rs Subwoofer ON Switch Ls L
+12 dB
R
-12 dB
+
31/149
Dedicated Digital Signal Processor (DSP) 4.6.4 Bass Management Configuration 3
STV82x7
The third configuration, shown in Figure 16, assumes that all speakers except the center are full range, then all bass information will be directed to and reproduced by the front left and front right and both surround speakers. In order to provide more flexibility to this configuration, a switch will offer an option which will produce a subwoofer channel by the LFE channel. When the Subwoofer Switch is OFF, the input channels will be attenuated by 8 dB. Configuration 3 is required in certain high-end products.
Figure 16: Bass Management Configuration 3 (all switches indicate their reset state) Level Adjustment OFF Switch + L
L
-8dB -4dB
+
+8dB +4dB +8dB +4dB
C
C
-8dB -4dB -4.5dB
R
-8dB -4dB
+
+
+8dB +4dB + +8dB +4dB + +8dB +4dB
R
Ls
Ls
-8dB -4dB -8dB -4dB
Rs
Rs
LFE
-8dB -4dB Subwoofer ON Switch Subwoofer ON Switch +10dB SubW
32/149
STV82x7 4.6.5 Bass Management Configuration 4
Dedicated Digital Signal Processor (DSP)
This configuration implements the Simplified Dolby configuration. The center, left surround and right surround channels are summed and then filtered by the LPF. The composite bass information is either summed back into the left and right channels or summed with the LFE channel and sent to the subwoofer output, see Figure 17.
Figure 17: Implementation of the Bass Management Configuration 4 (Simplified Configuration)
L
+
L
C
C
R
+
R
Ls
Ls
Rs -4.5dB Subwoofer ON Switch -10.5dB -5dB +
Rs
+
LFE
SubW
4.7
SRS WOW and TruSurround XT
The SRS(R) TruSurround XTTM is a processing system that can accept from 1 to 6 channels on input and that will generate a 2-channel output signal. This processing system includes the latest SRS(R) algorithms:

SRS(R) WOWTM SRS(R) TruSurround(R) (Multi-channel signal virtualizer)
4.7.1
SRS TruSurround
The SRS(R) TruSurround(R) is a processing that can accept from 2 to 5 channels on input and that will generate a 2-channel output signal. SRS(R) TruSurround(R) uses Head-Related Transfer Function (HRTF) -based frequency tailoring of (L/R) difference signals to extend the sound image out past the physical boundaries of the speaker placements to surround channel information. These rear channel HRTF curves have much greater peak to valley differences at center frequencies. These were chosen to cause rear channel difference signals to virtualize farther behind the listener and directed to a different virtual position as compared to front channel signals. Information that is equal (L+R) in the rear surround channels
33/149
Dedicated Digital Signal Processor (DSP)
STV82x7
is processed by an identical HRTF curve but mixed in at a much lower amount. This HRTF processing of equal (L/R) signals was again used to virtualize information to the rear of the listener. The SRS(R) TruSurround(R) is certified by Dolby Laboratories to be a Virtual Dolby(R) Digital and Virtual Dolby(R) Surround.
4.7.2
SRS WOW
The SRS(R) WOWTM is an a sound processing system including:

SRS(R) 3D Mono/StereoTM SRS(R) Dialog ClarityTM SRS(R) TruBassTM
4.7.2.1 SRS 3D Mono/Stereo This system is used to create a pseudo-stereo signal for mono inputs or a three-dimensional spatial signal for stereo inputs. 4.7.2.2 SRS Dialog Clarity This system is used to enhance dialog perception. 4.7.2.3 SRS TruBass The SRS(R) TruBassTM audio enhancement technology provides deep, rich bass to small speaker systems without the need for a subwoofer or additional extra physical components. For systems with a subwoofer, TruBassTM complements and enhances bass performance. Psycho-acoustically, when the human ear is presented with a low frequency sound signal that is missing the fundamental harmonic, it will fill in the fundamental frequency based on the higher harmonics that are present. By accentuating the second and higher frequency harmonics of the bass portion of a signal, TruBassTM gives the perception of greatly improved bass response. SRS(R) TruBassTM is implemented on loudspeakers path, headphone path or on both in parallel.
4.8
Smart Volume Control (SVC)
The Smart Volume Control regulates the audio signal level before audio processing. This regulation is necessary in order for the signal level to be independent from the source (terrestrial channels, I2S or SCART), its modulation (AM, FM or NICAM) and annoying volume changes (advertising, etc.). The Smart Volume Control works as an audio compressor/expander; i.e. when the input signal exceeds the threshold level, a very rapid attenuation (-2 dB/ms) is applied to rescale the signal down to the threshold value. When the input signal is below the threshold level, the previous attenuation is reduced slowly in order to retrieve the original input level (0dB gain). If the input signal is too low, an addition gain of 6 dB can be provided. To personalize the action of the SVC, five parameters are available: 1. Threshold: Maximum quasi-peak level that can be expected on output 2. Peak measurement mode: Select the channel on which the peak measurement must be performed (Left, Right, Center...) 3. Release time: Gain slope applied to the amplification phase 4. Expander switch: To allow a +6dB amplification of small signals in order to reduce the output dynamic range 5. Make up gain: Allows compensation of the signal amplitude limitation thanks to a 0 to 24 dB adjustable gain.
34/149
STV82x7
Dedicated Digital Signal Processor (DSP)
The SVC is implemented on the loudspeakers path, headphone path or on both in parallel (independent settings). Also, the SVC can be applied in six-channel mode (L, R, LS, RS, C and SubW).
4.9
ST Dynamic Bass
STV82x7 offers dynamic bass boost processing on the Loudspeakers path: ST Dynamic Bass is a bass boost process that can dramatically increase the bass content of any program without any output level saturation. 3 cutoff frequencies (BASS_FREQ) can be chosen, 100Hz, 150Hz and 200Hz to adapt the effect to your loudspeakers. The amount of bass (BASS_LEVEL) can also be fine tuned in order to adapt the effect loudness.
4.10
5-Band Audio Equalizer
The loudspeakers audio spectrum is split into 5 frequency bands and the gain of each of band can be adjusted within a range from -12 dB to +12 dB in steps of 0.25 dB. The Audio Equalizer may be used to pre-define frequency band enhancement features dedicated to various kinds of music or to attenuate frequency resonances of loudspeakers or the listening environment. The Equalizer is enabled by the LS_EQ_ON bit in the LS_EQ_BT_CTRL register. The gain value for Band X is programmed in register EQ_BANDX_GAIN. The 5-Band Audio Equalizer is exclusive with Bass-Treble control. Bit LS_EQ_BT_SW in register LS_EQ_BT_CTRL is used to select either the 5-Band Audio Equalizer or the Bass-Treble control for the Loudspeakers path. Depending on the LS Equalizer or LS Bass-Treble value, the volume level can be clamped to the LS output to prevent any possible signal clipping from occuring using the ANTICLIP_LS_VOL_CLAMP bit in the VOLUME_MODES (D7h) register.
Figure 18: Equalizer f1 = 100 Hz, f2 = 316 Hz, f3 = 1 kHz, f4 = 3.16 kHz and f5 = 10 kHz
4.11
Bass/Treble Control
The gain of bass and treble frequency bands for Headphone can be also tuned within a range from -12 dB to +12 dB in steps of 0.25 dB. It may be used to pre-define frequency band enhancement features dedicated to various kinds of music. The Headphone Bass/Treble feature is enabled by setting the HP_BT_ON bit in the HP_BT_CONTROL register. The Bass and Treble gain values are adjusted in registers HP_BASS_GAIN and HP_TREBLE_GAIN, respectively. Depending on the HP Bass-Treble value, the volume level can be clamped to the HP output to prevent any possible signal clipping from occuring using the ANTICLIP_HP_VOL_CLAMP bit in the VOLUME_MODES (D7h) register.
35/149
Dedicated Digital Signal Processor (DSP)
STV82x7
4.12
Automatic Loudness Control
As the human ear does not hear the audio frequency range the same way depending on the power of the audio source, the Loudness Control corrects this effect by sensing the volume level and then boosting bass and treble frequencies proportionally to middle frequencies at lower volume. While maintaining the amplitude of the 1 kHz components at an approximately constant value, the gain values of lower and higher frequencies are automatically progressively amplified up to +18 dB when the audio volume level decreases.The maximum treble amplification can be adjusted from 0 dB (first order loudness) to +18 dB (second order loudness) in steps of 0.125 dB. As the volume is proportional to the external audio amplification power, the loudness amplification threshold is programmable in order to tune the absolute level. The Loudspeakers Loudness function is enabled by setting the LS_LOUD_ON bit in register LS_LOUDNESS. The Loudspeakers Loudness Threshold and Maximum Treble Gain values are also programmed in this register. The Headphone Loudness function is enabled by setting the HP_LOUD_ON bit in register HP_LOUDNESS. The Headphone Loudness Threshold and Maximum Treble Gain values are also programmed in this register. The loudness cut-off frequency is 100 Hz.
4.13
Volume/Balance Control
The STV82x7 provides a Volume/Balance Control for all output channels configuration (except for S/PDIF) with different volume level per channel (L, R, C, LS, RS, SubW, SCART). Its wide range (from +11.875 to -116 dB, in a dB linear scale with a 0.125 dB step) largely covers typical home applications (approx. 60 dB) while maintaining a good S/N ratio.
Figure 19: Volume Control
Output Gain
+11.875 dB
-116 dB Mute 00h IC Control 3FFh
An extra Master Volume Control can apply an extra gain/attenuation on L, R, C, LS, RS and SubW channels. The Volume/Balance Control can operate in one of two different modes:
In Differential mode (default value), the volume control is a common volume value for both the Left and Right Loudspeakers or Headphone channels (see Figure 19) and complimentary balance control is used (see Figure 20).
36/149
STV82x7
Dedicated Digital Signal Processor (DSP)
In Independent mode, the volume for the Left and Right channels for Loudspeakers or Headphone is controlled independently.
Figure 20: Differential Balance
Output Gain
100%
R ig ht C ha nn el C ft Le el nn ha
Mute 200h 000h IC Control (10 bits) 1FFh
4.14
Soft Mute Control
The Digital Soft Mute is applied smoothly (20 ms for 120 dB range) to avoid any switch noise on output. It is available on all output channels pairs:

S/PDIF channel (Left/Right) SCART channels (Left/Right) Loudspeakers channels (Left/Right) Center Subwoofer Headphone/Surround channels (Left/Right)
Another soft mute (analog) is also available on each DAC output.
4.15
Beeper
The beeper is used to generate a tone on the Loudspeakers or/and Headphone outputs. The beeper sound (square wave) is added to the audio signal which is attenuated by 20 dB. The beep sound amplitude includes a smooth attack and decay to avoid any parasitic noise when starting and stopping. It can be used for various applications such as beep sounds for remote control, alarm clock or other features. The Beeper operates in one of two modes:
Pulse mode (beep applications): A tone with a programmable short duration (0.1, 0.25, 0.5 and 1.0 s) is generated. Afterwards, the beeper is automatically disabled and the output is switched back to the audio signal, see Figure 21. Continuous mode (alarm application): A tone with a programmable long duration is generated. Its start and stop controls must be programmed by IC, see Figure 22.
The Beeper function is enabled by setting the BEEPER_ON bit in register BEEPER_ON. Beeper parameters are controlled in register BEEPER_MODE. The beeper tone level and frequency are programmed in register BEEPER_FREQ_VOL. The level (or volume) ranges between 0 dB and -93 dB in steps of 3 dB and the tone frequency ranges between 62.2 Hz and 8 kHz in steps of 1 octave.
37/149
Dedicated Digital Signal Processor (DSP)
STV82x7
A beep generator is shared only by the Loudspeakers or Headphone outputs. Therefore, in the event of simultaneous beeps when in Pulse mode, only the first beep will define the effective duration that will be the same for both outputs.
Figure 21: Pulse Mode
BEEP_ON = 1
BEEP_ON = 0
0.1, 0.25, 0.5 and 1.0 s T predefined
62.5 Hz < f < 8 kHz
Figure 22: Continuous Mode
BEEP_ON = 1 T defined by IC write
BEEP_ON = 0
62.5 Hz < F < 8 kHz
38/149
STV82x7
Analog Audio Matrix (In / Out)
5
Analog Audio Matrix (In / Out)
The analog part of the audio matrix can be divided into two parts: the SCART input matrix and the SCART output matrix.
Figure 23: SCART Input Matrix
S1in S2in S3in S4in MONO_in Select
Audio ADC 2
Digital Matrix
The SCART input matrix is an input for the digital matrix (after the ADC) which select which source will be sent to the DSP.
Figure 24: SCART1/2/3 Output Matrix
S1in S2in S3in S4in Stereo DAC MONO_in
2 Soft mute S1out
Select or Mute
The SCART output matrix selects the sound to output, which can be directly a SCART input or the output of the DSP. A mute function is provided to switch off the outputs. A soft-mute function is provided to avoid all spurious sounds when switching from one position to another position. The SCART 2 and 3 output matrices have the same functions as the SCART 1 output matrix. The particularity of the matrix is to accept input signal of 2 VRMS and to have the capability to output such level. In this case, the power supply must be 8 V. The Mono audio input is able to accept signals with a 0.5 VRMS amplitude.
39/149
IS Interface (In / Out)
STV82x7
6
IS Interface (In / Out)
The STV82x7 offers three input/output choices: one IS input, three IS inputs or one IS output.
6.1
IS Inputs
The STV82x7 can interface with a digital sound decoder. In this case, the digital data can be input at a speed of 0.384 Mbytes/s (3.072 MHz for a 48 kHz sampling frequency with 32 bits of data).In compliance with Dolby(R) specifications, only the sampling frequency is subject to restrictions. All other requirements are extracted from other various specifications.
Table 5: IS Characteristics
Sampling Frequency (kHz) Data Size PCMCLK 8, 11.025, 12,16, 22.05, 24, 32, 44.1 and 48 16, 18*, 20*, 24*, 32 512 x fS1 2
1. means that the number is the number of effective bits but the transmission is with 32 bits. 2. 512 x fs is used by the DACs if 512 x fs is present.
The PCMCLK (possible clock for upsampling) is provided by the master which is the digital sound decoder. A sample rate conversion (SRC) will be necessary in the second case (STV82x7 slave) in order to have a fixed frequency output from this block (either 32 kHz, 44.1 kHz or 48 kHz). Note: The SRC function is only available in single IS input mode. The IS interface is used in two ways depending on the package: 1. The interface with one IS (IS_DATA0) connection (only stereo or stereo-coded Dolby(R) Pro Logic(R)); 2. One interface with three IS connections connected to the DSP to allow the processing of a multi-channel signal (maximum of 6 channels).
Figure 25: IS Block Diagram
IS_DATA0 fS Input = 8 to 48 kHz
SRC x 2 SRC x 4 Audio Processing
IS_DATA1 fS Input = 32 to 48 kHz IS_DATA2 fS Input = 32 to 48 kHz
40/149
STV82x7
Table 6: IS Frequency Configuration IS (Max. Number of Channels)
1 (IS_DATA0) 1 (IS_DATA0) 3 1 (IS_DATA0) 1 (IS_DATA0) 3 1 (IS_DATA0) 1 (IS_DATA0) 3
IS Interface (In / Out)
fS Input (kHz)
8 16 32 11.025 22.05 44.1 12 24 48
fS Output (kHz) after SRC
32.0 32.0 32.0 44.1 44.1 44.1 48.0 48.0 48.0
SRC Use
x4 x2 No x4 x2 No x4 x2 No
Both standard and non-standard modes are available, see Figure 26.
6.2
IS Output
A digital stereo output (IS compatible) is also available for routing the demodulated signal or a converted input audio signal to an external device. In this case the IS_DATA0 signal and all clock signals are set as outputs by setting bit D6 in register RESET to 1. The STV82x7 IS drives the serial bus (SCLK, LR_CLK, IS_DATA0) in master mode in 64.fs format with a sampling frequency (fs) of 32 kHz. The IS_PCM_CLK signal can be used as a master clock in 512.fs format if required for the slave interface. Both standard and non-standard modes are available, see Figure 26.
Note:
The Input and Output modes for IS are exclusive.
Figure 26: IS Data Format: Lch = LOW, Rch = HIGH (IS Input or Output mode)
1/fs Lch
IS_LR_CLK
Rch
IS_SCLK (= 64fs)
IS_DATAx (standard mode)
1
2
3
22
23
24
1
2
3
22
23
24
1
2
MSB IS_DATAx (non-standard mode) 1 2 3 22 23 24
LSB 1 2
MSB 3 22 23 24
LSB 1 2 3
MSB
LSB
MSB
LSB
41/149
S/PDIF Input/Output
STV82x7
7
S/PDIF Input/Output
An S/PDIF output is available for connection with an external decoder/amplifier. An internal multiplexer allows selection of either the internal signal or the external signal connected on the SPDIF input (for example, the signal provided by the external MPEG audio / Dolby Digital decoder). The outputted internal signal can be selected from:

L/R C/Sub HP or Surround SCART.
A mute facility is also provided on the SPDIF output.
42/149
STV82x7
Power Supply Management
8
Power Supply Management
A mixed supply voltage environment requires the following voltages:

3.3V capable inputs/outputs for digital pins; 1.8V digital core; 8V capable inputs/outputs for analog audio interfaces (capability to output 2 VRMS for SCART requirements); 3.3V for stereo ADC and DAC (analog part); 1.8V for stereo ADC and DAC (digital part); 1.8V for IF ADC and AGC.

These voltages will be delivered by the application with an accuracy of 5%. For more information, refer to Section 13.3: Power Supply Data. Other specific DC voltages or features are provided:

Voltage Reference and Biasing Generation (AGC, ADCs, DACs), Bandgap reference.
8.1
Standby Mode (Loop-through mode)
The STV82x7 provides a Loop-through mode configuration that bypasses IC functions via a SCART I/O pin (Full Analog Path only). In this case, only a minimum power of 200 mW is required. In Standby mode, the digital and analog power supplies are switched off, except for pins VCC_H, VCC33_LS, VCC33_SC, and VCC_NISO which are used to maintain the SCART path with the last configuration programmed by analog matrixing (register SCART1_2_OUTPUT_CTRL and SCART3_OUTPUT_CTRL). When switching back to normal Full Power mode, all IC registers are reset except for those used in Standby mode to maintain the original configuration. In Standby mode, the IC bus does not operate. However, the bus can still be used by other ICs since the IC I/O pins (SDA and SCL) of the STV82x7 are forced into a high-impedance configuration.
43/149
Additional Controls and Flag
STV82x7
9
Additional Controls and Flag
This logic contains:

the headphone detection, the IRQ generation, signal to be output to the MCU, the IC bus expander output pin.
9.1
Headphone Detection
For headphone, the HP_DET input can be used to automatically mute the Loudspeakers and Subwoofer outputs when the HP_LS_MUTE bit is set in register HEADPHONE_CONFIG (active low). When a headphone is detected (the HP_DET pin is set to 0) and the Mute function is enabled. Each change on the HP_DET pin generates an IRQ request to the microprocessor on the IRQ pin.
9.2
IRQ Generation
Four IRQs are generated by the STV82x7. On each IRQ generation, the IRQ pin is set to 1. The pending IRQ status must be read at the I2S address 81h and the acknowledge is done by writing 0 to this register. The four availables IRQs are: IRQ0: The identified TV sound standard is displayed in register AUTOSTD_STATUS. Each change in the detected standard is flagged to the host system via hardware pin IRQ. The flag must be reset by re-programming the IRQ bit in register AUTOSTD_CTRL and then checking the detected standard status by reading registers AUTOSTD_STATUS, NICAM_STAT, and ZWT_STAT. IRQ1: This IRQ is enabled only in digital input mode. In case of I2S synchronisation loss, this IRQ is set to 1. IRQ2: This IRQ is set to 1 when the device detects any change on the HP Detection pin (Headphone connection or deconnection). IRQ3: On the STV82x7, same pins are used for both Headphone and Surround loudspeaker signal output. A change in the Headphone configuration (HP active or not active) will lead to a signal switch on those hardware pins. In order to ensure a smooth audio transition, the output is soft muted before the signal is switched. The IRQ3 is then set to 1 to advise the master processor that the signal has been switched and to request a HP/Srnd Ouput Un-Mute.
9.3
IC Bus Expander
Pin BUS_EXP can be used to control external switchable IF SAW filters or audio switches. This pin can be directly programmed by register RESET.
44/149
STV82x7
STV82x7 Reset
10
STV82x7 Reset
All STV82x7 features are controlled via the IC bus. The STV82x7 can be "reset" in 2 ways: 1. By Software via the IC bus: This clears all synchronous logic, except for the IC bus registers. 2. By Hardware via the RESET pin: In addition to clearing all synchronous logic, the RESET input (active on the low level) resets all the IC bus registers to the default values listed below.
Table 7: RESET Default Values Function
Demodulation Auto-standard Scanned Standards FM Deviation Audio Outputs Automatic Mute Mode Loudspeaker Source Loudspeaker Volume Loudspeaker L/R Balance Subwoofer Headphone Source Headphone Automatic Detection Headphone Volume Headphone L/R Balance SCART-1 out SCART-2 out SCART Volume IS out Audio Processing Loudspeaker/Headphone SVC Loudspeaker Surround Loudspeaker 5-Band Equalizer Loudspeaker Loudness Headphone Bass/Treble Loudspeaker/Headphone Beeper OFF, 0 dB Reference Value OFF OFF, 0 dB (Flat Band) OFF OFF, 0 dB (Flat Band) -40 dB / OFF ON Demodulated Sound -40 dB, differential mode, muted L/R = 100% -40 dB / OFF Demodulated Sound ON -40 dB, differential mode, muted L/R = 100% Demodulated Sound SCART1 Source -5.5 dB, independent mode, muted OFF ON M/N, B/G, I, L/L' 125 kHz (Max.)
Default mode
45/149
IC Interface
STV82x7
11
11.1
IC Interface
IC Address and Protocol
The STV82x7 IC interface works in Slave mode and is fully compliant with IC standards in Fast mode (maximum frequency of 400 kHz). Two pairs of IC chip addresses are used to connect two STV82x7 chips to the same IC serial bus. The device address pairs are defined by the polarity of the ADR_SEL pin and are listed in the following table:
Table 8: IC Read/Write Addresses ADR
LOW (connected to GND1) HIGH (connected to VDD1)
Write Address (W)
80h 84h
Read Address (R)
81h 85h
Protocol Description
Write Protocol
Start WA Sub-address A Data A .... A Data A Stop
Read Protocol
Start WA Sub-address A Stop Start R A Data A .... A Data N

W = Write address, R = Read address, A = Acknowledge, N = No acknowledge. Sub-address is the register address pointer; this value auto-increments for both write and read.
46/149
STV82x7
IC Interface
11.2
Start-up and Configuration Change Procedure
Figure 27: Flow chart
Power ON
Hardware Reset (by pin 43)
NOTE: This HW reset after Power ON is mandatory to avoid bad device configuration
Clock PLLs progammation
(for Crystal value different than 27 MHz)
(FS1 & FS2 registers)
Load Patch File
(by IC transfer)
HW_RESET bit = 1 (bit 2 in HOST_CMD register)
(DSP RUN)
INIT_MEM bit ? (bit 0 in DSP_STATUS register)
=0
(DSP inititialization)
=1
Device Configuration Set-up
(analog or digital)
HOST_RUN bit = 1 (bit 0 in DSP_RUN register)
(start DSP processing)
INIT_MEM bit = 0
(change configuration)
HOST_NO_INIT bit = 1 (bit 1 in DSP_RUN register)
(OPTIONAL)
(registers 85h to FFh are not reset)
HOST_RUN bit = 0
(stop DSP processing)
47/149
Register List
STV82x7
12
Note:
Register List
The unused bits (defined as `Reserved') in the IC registers must be kept to zero. The system clock registers (from address 08h to 0Bh and from address 5Ah to 5Dh) do not need to be modified if a standard 27 MHz quartz crystal oscillator is used. The default values of the demodulator registers (from address 0Ch to 55h) are for optimum performances and any change is not recommended, except for:

AGC_GAIN (0Fh) to adjust AGC gain for AM carrier in L/L' standard (AGC used in open loop). CAROFFSET1 (22h) and CAROFFSET2 (3Ah) to compensate IF carrier frequency with an out-of-standard offset. Soundlevel Prescaling PRESCALE_AM (94h), PRESCALE_FM (95h), PRESCALE_NICAM (96h) and PRESCALE_SCART (97h) to equalize demodulated or external audio signal before audio processing. Peak detector registers PEAK_DET_INPUT (9Dh), PEAK_DET_L (9Eh), PEAK_DET_R (9Fh), PEAK_DET_L_R (A0h) can be used to measure internal sound level.
Sound source selection for each audio output channel Loudspeakers, Headphone and SCART to be done using AUDIO_MATRIX_INPUT (A2h). In Multi-lingual mode, AUDIO_MATRIX_LANGUAGE (A4h) selects separately the language for each audio output channel. Register AUTOSTD_CTRL (8Ah) is used to select between L/L' or D/K/K1/K2/K3 standard which can be discriminated automatically. To be used also to change maximum FM deviation (125 kHz, by default) in case of wide overmodulation. AUTOSTD_STANDARD_DETECT (8Bh) and AUTOSTD_STEREO_DETECT (8Ch) to define the list of mono and stereo standards to be recognized automatically. Note: () used in reset value column means that the bit or the byte is read-only. (S) symbol indicates that the field value is represented in signed binary format. (*) The field AGC_ERR[4:0] (AGC_GAIN) can be written by user if the bit AGC_CMD (AGC_CTRL) is set to one (by default controlled by Automatic Standard Recognition System). To be used to adjust manually the input gain of analog AGC amplifier for AM carrier (L/L').
48/149
STV82x7
Register List
12.1
IC Register Map
By default, all IC registers controlled by Automatic Standard Recognition System (Autostandard) are forced to Read-only mode for the user. These registers and bits are shaded in Table 9.
Table 9: List of IC Registers (Sheet 1 of 6)
Name
IC General Control
CUT_ID RESET
Addr.
Reset
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
00h 01h
(0000 0001) 0000 0000
0 BUS_EXP
0 IS_OUTPUT 0 EN_STBY
CUT_NUMBER[5:0] 0 SOFT_ LRST2 0 SOFT_ LRST1 LR_OFF SOFT_RST LOCK_ FLAG
I2S_STAT I2S_SYNC_OFFSET
05h 06h
(0000 0000) (0000 0000)
0
0
0
0
0 RESERVED
Clocking 1
SYS_CONFIG FS1_DIV FS1_MD FS1_PE_H FS1_PE_L 07h 08h 09h 0Ah 0Bh 0000 0000 0001 0010 0001 0001 0011 0110 0000 0000 I2S_CH_NB[1:0] EN_PROG 0 0 0 0 PE_H1[7:0] PE_L1[7:0] NDIV1[1:0] INPUT_FREQ[3:0] 0 MD1[4:0] INPUT_CONFIG[1:0] SDIV1[2:0]
Demodulator
DEMOD_CTRL DEMOD_STAT AGC_CTRL AGC_GAIN DC_ERR_IF 0Ch 0Dh 0Eh 0Fh 10h 0000 0110 (0000 0000) 0001 0001 (0000 0000) (0000 0000) 0 0 AGC_ CMD 0 0 0 0 FAR_MODE GAP_MODE 0 0 QPSK_LK AM_SEL FM2_CAR AGC_REF[2:0] AGC_ERR[4:0] DC_ERR[7:0] FM2_SQ DEMOD_MODE[2:0] FM1_CAR FM1_SQ
AGC_CST[1:0] SIG_OVER SIG_ UNDER
Demodulator Channel 1
CARFQ1H CARFQ1M CARFQ1L FIR1C0 FIR1C1 FIR1C2 FIR1C3 FIR1C4 FIR1C5 FIR1C6 FIR1C7 ACOEFF1 BCOEFF1 CRF1 CETH1 SQTH1 12h 13h 14h 15h 16h 17h 18h 19h 1Ah 1Bh 1Ch 1Dh 1Eh 1Fh 20h 21h 0011 1110 1000 0000 0000 0000 0000 0000 1111 1110 1111 1100 1111 1101 0000 0010 0000 1101 0001 1000 0001 1111 0010 0011 0001 0010 (0000 0000) 0010 0000 0011 1100 CARFQ1[23:16] CARFQ1[15:8] CARFQ1[7:0] FIR1C0[7:0] (S) FIR1C1[7:0] (S) FIR1C2[7:0] (S) FIR1C3[7:0] (S) FIR1C4[7:0] (S) FIR1C5[7:0] (S) FIR1C6[7:0]6 (S) FIR1C7[7:0] (S) ACOEFF1[7:0] BCOEFF1[7:0] CRF1[7:0] (S) CETH1[7:0] SQTH1[7:0]
49/149
Register List
Table 9: List of IC Registers (Sheet 2 of 6) Name
CAROFFSET1
STV82x7
Addr.
22h
Reset
0000 0000
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
CAROFFSET1[7:0] (S)
Demodulator Channel 2
IAGCR IAGCC IAGCS CARFQ2H CARFQ2M CARFQ2L FIR2C0 FIR2C1 FIR2C2 FIR2C3 FIR2C4 FIR2C5 FIR2C6 FIR2C7 ACOEFF2 BCOEFF2 SCOEFF SRF CRF2 CETH2 SQTH2 CAROFFSET2 25h 26h 27h 28h 29h 2Ah 2Bh 2Ch 2Dh 2Eh 2Fh 30h 31h 32h 33h 34h 35h 36h 37h 38h 39h 3Ah 1000 1000 0000 0011 (0000 0000) 0100 0100 0100 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 1111 1111 0000 0100 0001 0100 0010 0101 1001 0000 1010 1100 0001 1100 (0000 0000) (0000 0000) 0010 0000 0011 1100 0000 0000 IAGC_ OFF FAR_FLT_EN MONO_FLT _EN IAGC_REF[7:0] BG_SEL MONO_PRO G IAGC_CST[2:0]
IAGC_CTRL[7:0] CARFQ2[23:16] CARFQ2[15.8] CARFQ2[7:0] FIR2C0[7:0] (S) FIR2C1[7:0] (S) FIR2C2[7:0] (S) FIR2C3[7:0] (S) FIR2C4[7:0] (S) FIR2C5[7:0] (S) FIR2C6[7:0] (S) FIR2C7[7:0] (S) ACOEFF2[7:0] BCOEFF2[7:0] SCOEFF[7:0] SRF[7:0] (S) CRF2[7:0] (S) CETH2[7:0] SQTH2[7:0] CAROFFSET2[7:0] (S)
NICAM
NICAM_CTRL NICAM_BER NICAM_STAT 3Dh 3Eh 3Fh 0000 0000 (0000 0000) (0000 0000) NIC_DET F_MUTE LOA 0 0 0 0 0 ERROR[7:0] CBI[3:0] NIC_MUTE DIF_POL ECT MAE
Stereo FM
ZWT_CTRL ZWT_TIME ZWT_STAT 40h 41h 42h 0011 0001 0000 0100 (0000 0000) LRST_ TONE_OFF 0 0 STD_MODE 0 0 0 0 0 0 THRESH[3:0] 0 ZW_STAT_ RDY ZW_DET TSCTRL[1:0] ZWT_TIME[2:0] ZW_ST ZW_DM
Analog Control
ADC_CTRL SCART1_2_OUTPUT_CTRL SCART3_OUTPUT_CTRL 56h 57h 58h 0000 1000 1010 1000 0000 1011 I2S_DATA0_CTRL[1:0] SC2_MUTE 0 0 0 0 ADC_ POWER_UP SC1_MUTE 0 SC3_MUTE ADC_INPUT_SEL[2:0] SC1_OUTPUT_SEL[2:0] SC3_OUTPUT_SEL[2:0]
SC2_OUTPUT_SEL[2:0] 0
Clocking 2
50/149
STV82x7
Table 9: List of IC Registers (Sheet 3 of 6) Name
FS2_DIV FS2_MD FS2_PE_H FS2_PE_L
Register List
Addr.
5Ah 5Bh 5Ch 5Dh
Reset
0001 0001 0001 0001 0101 1100 0010 1001
Bit 7
0 0
Bit 6
Bit 5
NDIV2[1:0]
Bit 4
Bit 3
0
Bit 2
Bit 1
SDIV2[2:0]
Bit 0
0
0 PE_H2[7:0] PE_L2[7:0]
MD2[4:0]
DSP Control
HOST_CMD 80h 0000 0000 IT_IN_DSP 0 0 0 0 IRQ3 (HP/Srnd unmute ready) SOFT_VERSION[7:0] 0 0 PRO_LOGIC _SELECT 0 NICAM 0 I2S_INPUT 0 TRUBASS 0 0 LOCK_ MODE_EN LRCLK_STA RT LRCLK_ POLARITY TRU SURROUND 0 0 SCLK_ POLARITY PRO_LOGIC 0 HOST_ NO_INIT DATA_CFG MULTICHANE L INIT_MEM HOST_RUN HW_RESET
IRQ_STATUS
81h
0000 0000
IRQ2 IRQ1 (HP detected) (I2S sync lost)
IRQ0 (autostd)
SOFT_VERSION ONCHIP_ALGOS DSP_STATUS DSP_RUN
82h 83h 84h 85h
(0000 0002) (0000 0000) 0000 0000 0000 0000
I2S_IN_CONFIG AV_DELAY
86h 89h
1000 1110 0000 0000
0
SYNC
I2S_MODE DELAY_ON
DELAY_TIME[6:0]
Automatic Standard Recognition System
AUTOSTD_CTRL 8Ah 0000 0001 0 0 NICAM_ C4_OFF LDK_ZWT2 0 NICAM_GA P_MODE LDK_SWT1 FORCE_ SQUELCH NICAM_ MONO_IN LDK_ NICAM SINGLE_ SHOT LDK_SCK DK_DEV[1:0] LDK_SW
AUTOSTD_STANDARD_DETECT
8Bh
0010 1111
0
I_SCK
BG_SCK
MN_SCK
AUTOSTD_STEREO_DETECT AUTOSTD_TIMERS AUTOSTD_STATUS
8Ch 8Dh 8Eh
0001 1111 1010 0100 (0000 0000)
LDK_ZWT3
I_NICAM
BG_ZWT
BG_NICAM ZWEITON_TIME[2:0]
MN_ZWT
FM_TIME[1:0] STEREO_ ID STEREO_ OK MONO_ OK
NICAM_TIME[2:0] AUTOSTD_O N STEREO_SID[1:0]
MONO_SID[1:0]
Audio Preprocessing & Selection
DC_REMOVAL_INPUT DC_REMOVAL_L DC_REMOVAL_R PRESCALE_SELECT PRESCALE_AM PRESCALE_FM PRESCALE_NICAM PRESCALE_SCART PRESCALE_I2S_0 PRESCALE_I2S_1 PRESCALE_I2S_2 90h 91h 92h 93h 94h 95h 96h 97h 98h 99h 9Ah 0000 0111 (0000 0000) (0000 0000) 0000 0000 0000 0000 0000 1100 0001 1010 0000 0000 0000 0000 0000 0000 0000 0000 0 0 0 0 0 0 0 0 0 0 0 0 NICAM_ DEMATRIX NICAM_ DEEMPH_ BYPASS 0 0 0 0 0 0 0 DC_SCART DC_NICAM DC_ DEMOD
DC_REMOVAL_L[7:0] (S) DC_REMOVAL_R[7:0] (S) 0 0 PRESCALE_AM[6:0] (S) PRESCALE_FM[6:0] (S) PRESCALE_NICAM[6:0] (S) PRESCALE_SCART[5:0] (S) PRESCALE_I2S_0[5:0] (S) PRESCALE_I2S_1[5:0] (S) PRESCALE_I2S_2[5:0] (S) FM_DEEMPH FM_DEEMPH _BYPASS _SW 0 0 AM_FM_ SELECT
DEEMPHASIS_DEMATRIX
9Bh
0000 0000
0
0
FM_DEMATRIX[1:0]
51/149
Register List
Table 9: List of IC Registers (Sheet 4 of 6) Name
PEAK_DET_INPUT
STV82x7
Addr.
9Dh
Reset
0000 0000 0(0000 0000) 0(0000 0000) 0(0000 0000)
Bit 7
PEAK_ LOCATION OVERLOAD_L [7:0] OVERLOAD_ R[7:0] OVERLOAD_L _R[7:0]
Bit 6
0
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PEAK_L_R_RANGE
PEAK_DET_INPUT[1:0]
PEAK_DET_L
9Eh
PEAK_L[6:0]
PEAK_DET_R
9Fh
PEAK_R[6:0]
PEAK_DET_L_R
A0h
PEAK_L_R[6:0
Matrixing
AUDIO_MATRIX_INPUT A2h 0000 0000 0 0 0 0 0 SCART_ INPUT_ SOURCE HP_INPUT_ SOURCE LS_INPUT_ SOURCE
AUDIO_MATRIX_CONFIG
A3h
0000 0000
0 MUTE_ STEREO 0 0 0 0
0 MUTE_ ALL 0
0
SCART_ MATRIX
DEMOD_MATRIX[3:0]
AUDIO_MATRIX_LANGUAGE DOWNMIX_IN_MODE DOWNMIX_OUT_MODE DOWNMIX_DUAL_MODE DOWNMIX_CONFIG
A4h A6h A7h A8h A9h
0000 0000 0000 0010 0100 1010 0000 0000 0000 0001
SCART_LANGUAGE[1:0] 0 0
HP_LANGUAGE[1:0] LFE_IN
LS_LANGUAGE[1:0] MIX_IN_MODE[2:0] MIX_OUT_MODE[2:0] HP_DUAL_SELECT[1:0] LR_UPMIX NORMALIZE
HP_MODE[1:0] DUAL_ON 0
SCART_MODE[1:0]
LS_DUAL_SELECT[1:0] SRND_FACTOR[1:0]
SCART_DUAL_SELECT [1:0] CENTER_FACTOR[1:0]
Audio Processing
PRO_LOGIC2_CONTROL PCM_SRND_DELAY PCM_CENTER_DELAY PRO_LOGIC2_CONFIG PRO_LOGIC2_DIMENSION PRO_LOGIC2_LEVEL NOISE_GENERATOR AAh ABh ACh ADh AEh AFh B0h 0011 1010 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 10_DB_ ATTENUATE SRIGHT_ NOISE TRUSRND_ MONO_ SRND SLEFT_ NOISE PL2_LFE 0 0 0 0 PL2_OUTPUT_DOWNMIX[2:0] 0 0 0 0 0 0 PL2_C_WIDTH 0 PL2_SRND_FILTER 0 PL2_LEVEL SUB_ NOISE CENTER_ NOISE RIGHT_ NOISE LEFT_ NOISE TRUSRND_ MODE NOISE_ON PL2_MODES[2:0] SNRD_DELAY[4:0] CENTER_DELAY[3:0] PL2_RS_ POLARITY PL2_ PANORAMA PL2_DIMENSION PL2_AUTO BALANCE PL2_ACTIVE
TRUSRND_CONTROL
B1h
0000 0000
0
TRUSRND_INPUT_MODE[3:0]
TRUSRND_ ON
TRUSRND_INPUT_GAIN TRUSRND_HP_DCL TRUSRND_DC_ELEVATION TRUBASS_LS_CONTROL TRUBASS_LS_LEVEL TRUBASS_HP_CONTROL TRUBASS_HP_LEVEL SVC_LS_CONTROL SVC_LS_TIME_TH SVC_HP_CONTROL
B6h B7h B8h BAh BBh BCh BDh BEh BFh C0h
0000 0000 0000 0000 0000 1100 0000 0110 00001 1001 0000 0110 0000 1001 0000 0010 1001 1000 0000 0010 0 0 0 SVC_LS_TIME[2:0] 0 0 0 0 0 0 0 0 0 0 0 0
TRUSRND_INPUT_GAIN[7:0] 0 0 DIALOG_ HEADPHONE CLARITY_ON _ON 0
TRUSRND_DC_ELEVATION[7:0] TRUBASS_LS_SIZE[3:0] TRUBASS_LS_LEVEL[7:0] TRUBASS_HP_SIZE[3:0] TRUBASS_HP_LEVEL[7:0] 0 SVC_LS_INPUT[1:0] SVC_ LS_AMP SVC_ LS_ON TRUBASS_ HP_ON TRUBASS_ LS_ON
SVC_LS_THRESHOLD[4:0] 0 0 0 SVC_ LHP_AMP SVC_ HP_ON
52/149
STV82x7
Table 9: List of IC Registers (Sheet 5 of 6) Name
SVC_HP_TIME_TH SVC_LS_GAIN SVC_HP_GAIN STSRND_CONTROL STSRND_FREQ STSRND_LEVEL OMNISURROUND_CONTROL
Register List
Addr.
C1h C2h C3h C4h C5h C6h C7h
Reset
1001 1000 0000 0000 0000 0000 0000 0000 0001 0101 1000 0000 0000 0000
Bit 7
Bit 6
SVC_HP_TIME[2:0]
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SVC_HP_THRESHOLD[4:0] 0 0 SVC_LS_MAKE_UP_GAIN[4:0] SVC_HP_MAKE_UP_GAIN[4:0] STSRND_ STEREO STSRND_ MODE STSRND_ ON
0 0
0 0
0
0
STSRND_BASS[1:0]
STSRND_MEDIUM[1:0]
STSRND_TREBLE[1:0]
STSRND_GAIN[7:0] ST_VOICE OMNISRND_INPUT_MODE OMNISRND_ ON DYN_BASS_ ON LS_EQ_ON
ST_DYNAMIC_BASS
C8h
0000 0000
BASS_LEVEL
BASS_FREQ LS_EQ_BT_ SW
LS_EQ_BT_CTRL LS_EQ_BAND1 LS_EQ_BAND2 LS_EQ_BAND3 LS_EQ_BAND4 LS_EQ_BAND5 LS_BASS_GAIN LS_TREBLE_GAIN HP_BT_CONTROL HP_BASS_GAIN HP_TREBLE_GAIN OUTPUT_BASS_MNGT
C9h CAh CBh CCh CDh CEh CFh D0h D1h D2h D3h D4h
0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000 0000
0
0
0
0
0
0
EQ_BAND1[7:0] (S) EQ_BAND2[7:0] (S) EQ_BAND3[7:0] (S) EQ_BAND4[7:0] (S) EQ_BAND5[7:0] (S) LS_BASS[7:0] (S) LS_TREBLE[7:0] (S) 0 0 0 0 0 0 0 HP_BT_ON
HP_BASS[7:0] (S) HP_TREBLE[7:0] (S) BASS_ MANAGE_ON 0 0 SUB_ ACTIVE GAIN_ SWITCH 0 OCFG_NUM[2:0] LS_ LOUD_ON HP_ LOUD_ON
LS_LOUDNESS
D5h
0000 0100
LS_LOUD_THRESHOLD[2:0]
LS_LOUD_GAIN_HR[2:0]
HP_LOUDNESS
D6h
0000 0100
0
HP_LOUD_THRESHOLD[2:0]
HP_LOUD_GAIN_HR[2:0]
Volume
VOLUME_MODES D7h 1100 0111 ANTCLIP_HP _VOL_CLAMP ANTICLIP_ LS_VOL_ CLAMP 0 0 SCART_ VOLUME_ MODE SRND_ VOLUME_ MODE HP_ VOLUME_ MODE LS_ VOLUME_ MODE
LS_L_VOLUME_MSB LS_L_VOLUME_LSB LS_R_VOLUME_MSB LS_R_VOLUME_LSB LS_C_VOLUME_MSB LS_C_VOLUME_LSB LS_SUB_VOLUME_MSB LS_SUB_VOLUME_LSB LS_SL_VOLUME_MSB LS_SL_VOLUME_LSB LS_SR_VOLUME_MSB
D8h D9h DAh DBh DCh DDh DEh DFh E0h E1h E2h
1001 1000 0000 0000 0000 0000 0000 0000 1001 1000 0000 0000 1001 1000 0000 0000 1001 1000 0000 0000 0000 0000 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
LS_L_VOLUME_MSB[7:0] 0 0 0 LS_L_VOLUME_LSB[1:0]
LS_R_VOLUME_MSB[7:0] 0 0 0 LS_R_VOLUME_LSB[1:0]
LS_C_VOLUME_MSB[7:0] 0 0 0 LS_C_VOLUME_LSB[1:0]
LS_SUB_VOLUME_MSB[7:0] 0 0 0 LS_SUB_VOLUME_LSB[1:0]
LS_SL_VOLUME_MSB[7:0] 0 0 0 LS_SL_VOLUME_LSB[1:0]
LS_SR_VOLUME_MSB[7:0]
53/149
Register List
Table 9: List of IC Registers (Sheet 6 of 6) Name
LS_SR_VOLUME_LSB LS_MASTER_VOLUME_MSB LS_MASTER_VOLUME_LSB HP_L_VOLUME_MSB HP_L_VOLUME_LSB HP_R_VOLUME_MSB HP_R_VOLUME_LSB SCART_L_VOLUME_MSB SCART_L_VOLUME_LSB SCART_R_VOLUME_MSB SCART_R_VOLUME_LSB
STV82x7
Addr.
E3h E4h E5h E6h E7h E8h E9h EAh EBh ECh EDh
Reset
0000 0000 1110 1000 0000 0000 1001 1000 0000 0000 0000 0000 0000 0000 1101 1101 0000 0000 1101 1101 0000 0000
Bit 7
0
Bit 6
0
Bit 5
0
Bit 4
0
Bit 3
0
Bit 2
0
Bit 1
Bit 0
LS_SR_VOLUME_LSB[1:0]
LS_MASTER_VOLUME_MSB[7:0] 0 0 0 0 0 0 LS_MASTER_VOLUME_ LSB[1:0]
HP_L_VOLUME_MSB[7:0] 0 0 0 0 0 0 HP_L_VOLUME_LSB[1:0]
HP_R_VOLUME_MSB[7:0] 0 0 0 0 0 0 HP_R_VOLUME_ LSB[1:0]
SCART_L_VOLUME_MSB[7:0] 0 0 0 0 0 0 SCART_L_VOLUME_ LSB[1:0]
SCART_R_VOLUME_MSB[7:0] 0 0 0 0 0 0 SCART_R_VOLUME_ LSB[1:0]
Beeper
BEEPER_ON EEh 0000 0000 0 0 0 0 0 0 BEEPER_ PULSE 0 BEEPER_ ON
BEEPER_MODE BEEPER_FREQ_VOL
EFh F0h
0000 0011 0111 0000
0
0 BEEPER_FREQ[2:0]
0
BEEPER_DURATION[1:0]
BEEPER_PATH[1:0]
BEEPER_VOLUME[4:0]
Mute
MUTE_DIGITAL F1h 1001 1111 AUTOSTD_ MUTE_ON 0 0 SCART_ D_MUTE SRND_HP_ D_MUTE SUB_ D_MUTE C_ D_MUTE LS_ D_MUTE
S/PDIF
S/PDIF_OUT_CONFIG F2h 0000 0100 0 0 0 0 0 SPDIF_OUT_ MUTE S/PDIF_OUT_SELECT[2:0]
Headphone Configuration
HEADPHONE_CONFIG F3h 0000 001(0) 0 0 0 0 HP_FORCE HP_LS_ MUTE HP_DET_ ACTIVE HP_ DETECTED
DAC Control
DAC_CONTROL SPDIF_CHANNEL_STATUS F4h F9h 0001 1111 0000 0000 0 0 S/PDIF_ MUX DAC_SCART _MUTE EMPHASIS DAC_SHP_ MUTE DAC_CSUB_ MUTE COPYRIGHT DAC_LSLR_ MUTE NON_AUDIO POWER_ UP PRO_CON
CHANNEL_STATUS
AutoStandard Coefficients Settings
AUTOSTD_COEFF_CTRL FBh 0000 0001 0 0 0 0 0 0 AUTOSTD_COEFF_ CTRL[1:0] AUTOSTD_ COEFF_ INDEX_MSB
AUTOSTD_COEFF_INDEX_MSB
FCh
0000 0000
0
0
0
0
0
0
0
AUTOSTD_COEFF_INDEX_LSB AUTOSTD_COEFF_VALUE
FDh FEh
0000 0000 0000 0000
AUTOSTD_COEFF_INDEX_LSB[7:0] AUTOSTD_COEFF_VALUE[7:0]
54/149
STV82x7
Register List
12.2
STV82x7 General Control Registers
CUT_ID Version Identification
Address: 00h Type: R Bit 7 0 Bit 6 0 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
CUT_NUMBER[5:0]
Bit Name
Bits[7:6] CUT_NUMBER[5:0]
Reset
00 Reserved
Function
000001 Dice Version Identification
RESET
Address: 01h Type: R/W Bit 7 BUS_EXP Bit 6 IS_OUTPUT Bit 5 0
Software Reset Register
Bit 4 EN_STBY
Bit 3 0
Bit 2
Bit 1
Bit 0 SOFT_RST
SOFT_LRST2 SOFT_LRST1
Description The built-in Automatic Standard Recognition System (Autostandard) can be disabled. In this case, the Software Reset function (bits SOFT_LRST1 and SOFT_LRST2) can be used to implement the Automatic Standard Recognition by IC Software. This is not required if the built-in Automatic Standard Recognition System function is used (default).
Bit Name
BUS_EXP IS_OUTPUT Bit[5] EN_STBY
Reset
0 0 0 0
Function
Static control by I2C of hardware pin BUS_EXP 0 = IS Input (IS output will be provided on I2S_DATA0 pin) 1 = IS Output (512 x fs will be provided on I2S_PCM_CLK pin) Reserved. Standby mode enabling 0: Normal mode 1: To lock the digital signals before to settle the device in standby mode
Bit 3 SOFT_LRST2 SOFT_LRST1 SOFTR_RST
0 0 0 0
Reserved. Softreset (active high) of Channel 2 detectors only. Softreset (active high) of Channel 1 detectors only. General softreset (active high) to reset all hardware registers except for IC data.
55/149
Register List I2S_CTRL
Address: 04h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 LR_OFF
STV82x7 I2S Synchronization Control Register
Bit 0 LOCK_FLAG
Bit Name
Bits[7:2] LR_OFF
Reset
0 0 Reserved. LR Signal Detection 0: LR signal detected and correct 1: Missing LR pulses detected
Function
LOCK_FLAG
0
Lock Flag allowing unmute of Audio Output
I2S_STAT
Address: 05h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
IS Synchronization Status Register
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1 LR_OFF
Bit 0 LOCK_FLAG
Bit Name
Bits[7:2] LR_OFF
Reset
0 0 Reserved. LR Signal Detection 0: LR signal detected and correct 1: Missing LR pulses detected
Function
LOCK_FLAG
0
Lock Flag allowing unmute of Audio Output
I2S_SYNC_OFFSET
Address: 06h Type: R/W
IS Synchronization Offset Frequency Register
12.3
Clocking 1
A low-jitter PLL Clock is integrated and can be fully reprogrammed using the registers described below. By default, the programming is defined for a 27-MHz quartz crystal frequency, which is the frequency recommended for reducing potential RF interference in the application. However, if
56/149
STV82x7
Register List
necessary, the PLL Clock can be re-programmed for other quartz crystal frequencies within a range from 23 to 30 MHz. Other quartz crystal frequencies can be programmed on your demand. Note: A Crystal Frequency change is compatible with other default IC programming including the built-in Automatic Standard Recognition System.
SYS_CONFIG
Address: 07h Type: R/W Bit 7 Bit 6 Bit 5
System Configuration Control Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
I2S_CH_NB[1:0]
INPUT_FREQ[3:0]
INPUT_CONFIG[1:0]
Bit Name
I2S_CH_NB[1:0]
Reset
00 Number of I2S channels input 00: N/A 01: 2 channels 10: 4 channels 11: 6 channels
Function
INPUT_FREQ[3:0]
0000
I2S Input frequency 0000 : 32 kHz 0001: 44.1 kHz 0010: 48 kHz 0011: 8 kHz (I2S input, 2 channels only) 0100 : 11.025 kHz (I2S input, 2 channels only) 0101 : 12 kHz (I2S input, 2 channels only) 0110 : 16 kHz (I2S input, 2 channels only) 0111 : 22.05 kHz (I2S input, 2 channels only) 1000 : 24 kHz (I2S input, 2 channels only)
INPUT_CONFIG[1:0]
0
Input stream to process 0 : SIF & SCART input (32 kHz) 1 : SCART input only (48 kHz) 2 : I2S input only
FS1_DIV
Address: 08h Type: R/W Bit 7 EN_PROG Bit 6 0 Bit 5 NDIV1[1:0]
FS1 I/O Divider Programming Register
Bit 4
Bit 3 0
Bit 2
Bit 1 SDIV1[2:0]
Bit 0
Bit Name
EN_PROG
Reset
0 FS1 programmation enable
Function
0: FS1 I2C registers programmation ignored by system - FS1 pre-programmed automatically by SYS-CONFIG register (normal use with standard quartz of 27 MHz) 1: FS1 I2C registers programmation used by system - FS1 pre-programmation by SYS-CONFIG desactivated (to be used in case of no standard quartz, different from 27 MHz)
57/149
Register List
STV82x7
Bit Name
Bit 6 NDIV1[1:0] Bit 3 SDIV1[2:0]
Reset
0 01 0 010 Reserved. FS1 Input clock divider selection Reserved. FS1 Output clock divider selection
Function
FS1_MD
Address: 09h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
FS1 Coarse Selection Register
Bit 4
Bit 3
Bit 2 MD1[4:0]
Bit 1
Bit 0
Bit Name
Bits[7:5] MD1[4:0]
Reset
000 10001 Reserved. FS1 Coarse Selection
Function
FS1_PE_H
Address: 0Ah Type: R/W Bit 7 Bit 6 Bit 5
FS1 Fine Selection Register (MSBs)
Bit 4 PE_H1[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
PE_H1[7:0]
Reset
0011 0110 FS1 Fine Selection (MSBs)
Function
FS1_PE_L
Address: 0Bh Type: R/W Bit 7 Bit 6 Bit 5
FS1 Fine Selection Register (LSBs)
Bit 4 PE_L1[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
58/149
STV82x7
Register List
Bit Name
PE_L1[7:0]
Reset
0000 0000 FS1 Fine Selection (LSBs)
Function
12.4
Demodulator
DEMOD_CTRL Demodulator Control Register
Address: 0Ch Type: R/W Bit 7 0 Bit 6 0 Bit 5 FAR_MODE Bit 4 GAP_MODE Bit 3 AM_SEL Bit 2 Bit 1 DEMOD_MODE[2:0] Bit 0
Bit Name
bit [7:6] FAR_MODE GAP_MODE
Reset
000 0 0 Reserved 1: Farrow and Mono filter for NICAM active
Function
Defines the clock gapping mode of the demodulator 0: (default), the FS1 freq is controlled by stl-error (clock-pll mode) to align the instantaneous value of the internal clock with respect to the received NICAM clock 1: the FS1 freq is fixed and the mean value of the internal clock is aligned by variable gapping (src-error) with respect to the received NICAM clock
AM_SEL
0
Demodulator Configuration Select 0: FM configuration of demodulator (Default) 1: AM configuration of demodulator
DEMOD_MODE[2:0]
110
Demodulator Mode Select CH1 FM 000: 001: 010: 011: 100: 101: 110: 111: Normal Wide Normal Wide Normal Wide Normal Wide CH2 FM/QPSK FM Normal FM Wide QPSK System B/G/L/D/K QPSK System B/G/L/D/K FM Wide FM Normal QPSK System I QPSK System I
DEMOD_STAT
Address: 0Dh Type: R Bit 7 0 Bit 6 0 Bit 5 0
Demodulator Detection Status Register
Bit 4 QPSK_LK
Bit 3 FM2_CAR
Bit 2 FM2_SQ
Bit 1 FM1_CAR
Bit 0 FM1_SQ
59/149
Register List
STV82x7
Bit Name
Bit [7:5] QPSK_LK
Reset
000 0 Reserved. QPSK Lock Detection Flag 0: Not detected 1: Detected
Function
FM2_CAR
0
Channel 2 FM/AM Carrier Detection Flag 0: Not detected 1: Detected
FM2_SQ
0
Channel 2 FM Squelch Detection Flag 0: Not detected 1: Detected
FM1_CAR
0
Channel 1 FM/AM Carrier Detection Flag 0: Not detected 1: Detected
FM1_SQ
0
Channel 1 FM Squelch Detection Flag 0: Not detected 1: Detected
Note:
These registers allow direct access to the demodulator signal detectors.
AGC_CTRL
Address: 0Eh Type: R/W Bit 7 AGC_CMD Bit 6 0 Bit 5 0
IF AGC Control Register
Bit 4
Bit 3 AGC_REF[2:0]
Bit 2
Bit 1
Bit 0
AGC_CST[1:0]
Bit Name
AGC_CMD
Reset
0 Automatic Gain Control Command Mode
Function
Normally set to 0 enabling automatic mode. For L/L' standards, the AGC should be switched off due to the presence of the AM sound carrier. In this case, a fixed gain value should be set using the AGCS register. 0: Automatic mode. AGC controlled by the Autostandard function. (Default) 1: Manual/Forced mode Bits[6:5] AGC_REF[2:0] 00 100 Reserved. This bitfield is used to defines the clipping level which adjusts the allowable proportion of samples at the input of the ADC which will be clipped. The AGC tries to maximize the use of the full scale range of the ADC. The default setting gives a ratio of 1/256. Clipping Ratio 000: 001: 010: 011: 1/16 (Single carrier) 1/32 1/64 1/128 100: 101: 110: 111: Clipping Ratio 1/256 (Default) 1/512 1/1024 1/2048 (Multiple carriers)
60/149
STV82x7
Register List
Bit Name
AGC_CST[1:0]
Reset
01 AGC Time Constant
Function
This is the time constant between each step of 1.5 dB by the AGC. Step Duration (ms) 00 01 10 11 1.33 2.66 5.33 10.66
AGC_GAIN
Address: 0Fh Type: R/W Bit 7 0 Bit 6 Bit 5
IF AGC Control and Status Register
Bit 4 AGC_ERR[4:0]
Bit 3
Bit 2
Bit 1 SIG_OVER
Bit 0 SIG_UNDER
Bit Name
Bit 7 AGC_ERR[4:0]
Reset
0 00000 Reserved. Amplifier Gain Control
Function
This is the Gain Control value of AGC. There are 20 steps of +1.5 dB (see Note below). 00000: Gain-min 10100: Gain-min + 30db 11111: Gain-min + 30db SIG_OVER 0 AGC Input SIgnal Upper Threshold 0: Normal signal 1: Signal too large and AGC is overloaded SIG_UNDER 0 AGC Input SIgnal Lower Threshold 0: Normal signal 1: Signal too small and AGC is underloaded When the AGC is in Automatic mode (AGC_CMD = 0), bits SIG_OVER and SIG_UNDER indicate if the input signal is too small/large and the AGC is under/overloaded. This is useful when setting the STV82x7 SIF input level.
Note:
When AGC_CMD = 0, AGC_ERR[4:0] can be read -- indicating the input level. It can also be written to -- presetting the AGC level which will then adjust itself to the final value. When AGC_CMD = 1, the AGC is off and writing to AGC_ERR[4:0] directly controls the AGC amplifier gain. Reading AGC_ERR just confirms the fixed value.
61/149
Register List DC_ERR_IF
Address: 10h Type: R Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
STV82x7 DC Offset Status for IF ADC
Bit 0
DC_ERR[7:0]
Bit Name
DC_ERR[7:0]
Reset
00000000 DC offset error of IF ADC output
Function
12.5
Demodulator Channel 1
CARFQ1H, CARFQ1M, CARFQ1L Channel 1 Carrier DCO Frequency
Address: 12h to 14h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
CARFQ1[23:16], CARFQ1[15:8], CARFQ1[7:0]
Bit Name
CARFQ1[23:16] CARFQ1[15:8] CARFQ1[7:0]
Reset
00111110 10000000 00000000
Function
Channel 1 DCO Carrier Frequency (8 MSBs) Channel 1 DCO Carrier Frequency Channel 1 DCO Carrier Frequency (8 LSBs), see Table 10.
Table 10: Mono Carrier Frequencies by System System
M/N B/G I L D/K/K1/K2
Mono Carrier Freq. (MHz)
4.5 5.5 6.0 6.5 6.5
CARFQ1[23:0] (dec)
3072000 3754667 4096000 4453717 4437333
CARFQ1[23:0]
2EE000h 394AABh 3E8000h 43F555h 43B555h
Note:
Carrier Freq: CARFQ1(dec).fS / 224 with fS = 24.576 MHz (crystal oscillator frequency independent)
62/149
STV82x7 FIR1C[0:7]
Address: 15h to 1Ch Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
Register List Channel 1 FIR Coefficients
Bit 0
FIR1C0[7:0] to FIR1C7[7:0]
Table 11: Channel 1 FIR Coefficients Description Bitfield
(reset state) FM 27 kHz FIR1C0[7:0] FIR1C1[7:0] FIR1C2[7:0] FIR1C3[7:0] FIR1C4[7:0] FIR1C5[7:0] FIR1C6[7:0] FIR1C7[7:0] FFh FEh FEh 00h 06h 0Eh 16h 1Bh FM 50 kHz 00h FEh FCh FDh 02h 0Dh 18h 1Fh FM 200 kHz 00h 01h 01h FCh 08h F6h F8h 4Ah FM 350 kHz 02h 01h FCh 03h 04h F2h 06h 43h FM 500 kHz 01h 00h 04h FAh 05h 00h F2h 4Dh AM 00h FEh FDh FEh 04h 0Dh 16h 1Dh
ACOEFF1
Channel 1 Baseband PLL Loop Filter Proportional Coefficient
Address: 1Dh Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
ACOEFF1[7:0]
Bit Name
ACOEFF1[7:0]
Reset
00100011
Function
Used to program the Proportional Coefficient of the baseband PLL loop filter (Channel 1) Defines the damping factor of the loop. For values, refer to Table 12.
63/149
Register List BCOEFF1
STV82x7 Channel 1 Baseband PLL Loop Filter Integral Coefficient & DCO Gain
Address: 1Eh Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
BCOEFF1[7:0]
Bit Name
BCOEFF1[7:0]
Reset
00010010
Function
Used to program the Integral Coefficient of the baseband PLL loop filter and DCO gain Defines the bandwidth of the loop. For values, refer to Table 12.
Table 12: Baseband PLL Loop Filter Adjustment (FM Mode) FM Mode
ACOEFF BCOEFF FM_DEV max (kHz) DCO Range (kHz)
Small
10h 1Ah 62.5 96
Standard
22h 12h 125 192
Medium
2Ch 0Ah 250 384
Wide*
2Ch 0Ah 500 768
A2 Standard
10h 11h 125 192
(*)
Refer to DEMOD_CTRL (DEMOD_MODE[2:0])
CRF1
Address: 1Fh Type: R Bit 7 Bit 6 Bit 5
Channel 1 Baseband PLL Demodulator Offset
Bit 4 CRF1[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
CRF1[7:0]
Reset
(00000000) Channel 1 Carrier Recovery Frequency
Function
Displays the instantaneous frequency offset of the Channel 1 Baseband PLL Demodulator.
CETH1
Address: 20h Type: R/W Bit 7 Bit 6 Bit 5
Channel 1 FM/AM Carrier Level Threshold
Bit 4 CETH1[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
64/149
STV82x7
Register List
Bit Name
CETH1[7:0]
Reset
00100000
Function
This register is used to compare the carrier level in the channel and the threshold value. This level is measured after the channel filter and is relative to the full scale reference level (0 dB). This is used as part of the validation of an FM signal, if the carrier level is below the threshold, the signal is considered to be non-valid. CETH FFh 80h 40h 20h Threshold (dB) -6 -12 -18 -24 (Default) CETH 10h 08h 00h Threshold (dB) -32 (Recommended Value) -38 OFF (all carrier levels are accepted)
SQTH1
Address: 21h Type: R/W Bit 7 Bit 6 Bit 5
Channel 1 FM Squelch Threshold Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SQTH1[7:0]
Bit Name
SQTH1[7:0]
Reset
00111100
Function
The squelch detector measures the level of high frequency noise (> 40 kHz) and compares it to the threshold level (SQTH). If the level is below this value, the S/N of the FM signal is considered to be acceptable. Values are given for FM with standard deviation. SQTH FAh 77h 3Ch 23h 19h S/N (dB) 0 10 15 (Default) 20 25
CAROFFSET1
Address: 22h Type: R/W Bit 7 Bit 6 Bit 5
Channel 1 DCO Carrier Offset Compensation
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
CAROFFSET1[7:0] (S)
Bit Name
CAROFFSET1[7:0]
Reset
00000000
Function
This value is used to correct the carrier frequency offset of the incoming IF signal. Automatic frequency control in FM mode can be implemented by registers DC_REMOVAL_L and DC_REMOVAL_R. A DCO frequency offset (in two's complement format) is added to the pre-programming value by AUTOTSD in the CARFQ1 registers (corresponding to the standard IF carrier frequency). The programmable carrier offset ranges from -192 kHz to +190.5 kHz with a resolution of 1.5 kHz. For standard FM deviation, the value displays by DC_REMOVAL_L and DC_REMOVAL_R can be directly loaded in CAROFFSET1 to exactly compensate the carrier offset on Channel 1
65/149
Register List
STV82x7
12.6
Demodulator Channel 2
IAGCR Channel 2 Internal AGC Reference for QPSK
Address: 25h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
IAGC_REF[7:0]
Bit Name
IAGC_REF[7:0]
Reset
10001000
Function
Sets the mean value of the internal AGC, used for QPSK demodulation. The default setting corresponds to half full scale amplitude at the baseband PLL input.
IAGCC
Address: 26h Type: R/W Bit 7 IAGC_OFF Bit 6
FAR_FLT_EN
Channel 2 Internal AGC Time Constant for QPSK
Bit 5
MONO_FLT_EN
Bit 4
BG_SEL
Bit 3
MONO_PROG
Bit 2
Bit 1 IAGC_CST[2:0]
Bit 0
Bit Name
IAGC_OFF
Reset
0 AGC Disable 0: Internal AGC is active 1: Internal AGC is disabled 1: Enable Farrow filter for NICAM 1: Enable Mono filter for NICAM 1: BG NICAM Mono filter selected 1: Enable programmation of Mono filter
Function
FAR_FLT_EN MONO_FLT_EN BG_SEL MONO_PROG IAGC_CST[2:0]
0 0 0 0 011
Internal AGC Programmable Step Constant. These bits control the time per step (values given for QPSK mode). The default value defines the optimum trade-off between fast settling time (for the fastest NICAM identification) and the noise immunity (minimum BER degradation) Step time (us) Time Response (ms) 000 001 010 011 100 101 110 111 703 352 176 88 44 22 11 5.5 128 64 32 16 8 4 2 0.82
66/149
STV82x7 IAGCS
Address: 27h Type: R Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
Register List Channel 2 Internal AGC Status for QPSK
Bit 0
IAGC_CTRL[7:0]
Bit Name
IAGC_CTRL[7:0]
Reset
Function
00000000 Indicates the value of the internal AGC gain control
CARFQ2H, CARFQ2M, CARFQ2L
Address: 28H to 2Ah Type: R/W Bit 7 Bit 6 Bit 5 Bit 4
Channel 2 Carrier DCO Frequency
Bit 3
Bit 2
Bit 1
Bit 0
CARFQ2[23:16], CARFQ2[15.8], CARFQ2[7:0]
Bit Name
CARFQ2[23:16] CARFQ2[15.8] CARFQ2[7:0]
Reset
01000100 01000000 00000000
Function
Channel 2 DCO Carrier Frequency (8 MSBs) Channel 2 DCO Carrier Frequency Channel 2 DCO Carrier Frequency (8 LSBs) See Table 13.
Table 13: Stereo Carrier Frequencies by System System
M/N A2+ B/G NICAM BG A2 I NICAM L NICAM DK NICAM DK1 A2* DK2 A2* DK3 A2*
Stereo Carrier Freq. (MHz)
4.724212 5.85 5.7421875 6.552 5.85 5.85 6.258125 6.7421875 5.7421875
CARFQ2[23:0] (Dec)
3225062 3993600 3920000 4472832 3993600 3993600 4272000 4602667 3920000
CARFQ2[23:0]
3135E6h 3CF000h 3BD080h 444000h 3CF000h 3CF000h 412F80h 463B2Bh 3BD080h
67/149
Register List FIR2C[0:7]
Address: 2Bh to 32h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
STV82x7 Channel 2 FIR Coefficients
Bit 0
FIR2C0[7:0] to FIR2C7[7:0]
Table 14: Channel 2 FIR Coefficients Description Bitfield
FM 27 kHz FIR2C0[7:0] FIR2C1[7:0] FIR2C2[7:0] FIR2C3[7:0] FIR2C4[7:0] FIR2C5[7:0] FIR2C6[7:0] FIR2C7[7:0] FFh FEh FEh 00h 06h 0Eh 16h 1Bh FM 50 kHz 00h FEh FCh FDh 02h 0Dh 18h 1Fh QPSK 40% 00h 00h FFh 03h 00h F4h 0Ah 3Dh (reset state) QPSK100% 00h 00h 00h 00h FFh 04h 14h 25h
ACOEFF2
Channel 2 Baseband PLL Loop Filter Proportional Coefficient
Address: 33h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
ACOEFF2[7:0]
Bit Name
ACOEFF2[7:0]
Reset
10010000
Function
This value defines the loop clamping factor used to program the Proportional Coefficient of the baseband PLL loop filter (Channel 2). See Table 15 and Table 16.
BCOEFF2
Channel 2 Baseband PLL Loop Filter Integral Coefficient & DCO Gain
Address: 34h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
BCOEFF2[7:0]
68/149
STV82x7
Register List
Bit Name
BCOEFF2[7:0]
Reset
10101100
Function
This value defines the loop bandwidth used to program the Integral Coefficient of the Baseband PLL loop filter and DCO gain. See Table 15 and Table 16.
Table 15: Baseband PLL Loop Filter Adjustments (FM Mode) FM mode
ACOEFF BCOEFF FM_DEV max (kHz) DCO Range (kHz)
Small
10h 1Ah 62.5 96
Standard
22h 12h 125 192
Mid
2Ch 0Ah 250 384
Wide
2Ch 0Ah 500 768
A2 standard
10h 11h 125 192
Table 16: Baseband PLL Loop Filter Adjustments (QPSK Mode) QPSK mode
ACOEFF BCOEFF DCO_DEV max (kHz)
Small
90h ACh 2.84375
Medium
90h A3h 5.6875
Large
90h 9Ah 11.375
Extra-large
90h 91h 22.75
SCOEFF
Address: 35h Type: R/W Bit 7 Bit 6 Bit 5
Channel 2 Symbol Tracking Loop Coefficients
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SCOEFF[7:0]
Bit Name
SCOEFF[7:0]
Reset
00011100
Function
This value is used to program the proportional and integral coefficients of the QPSK Symbol tracking loop. See Table 17 and Table 18.
Table 17: QPSK System - BG/L/DK Standards (40% Roll-off) Extra-Small
SCOEFF 1Eh
Small
25h
Medium
24h
Large
26h
Extra-Large
2Ah
Open Loop
80h
Table 18: QPSK System - I Standard (100% Roll-off) Extra-Small
SCOEFF 16h
Small
1Dh
Medium
1Ch
Large
23h
Extra-Large
22h
69/149
Register List SRF
Address: 36h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 SRF[7:0] Bit 3 Bit 2 Bit 1
STV82x7 Channel 2 Symbol Tracking Loop Frequency
Bit 0
Bit Name
SRF[7:0]
Reset
00000000
Function
Displays in two's complement format the frequency deviation between the incoming NICAM bitstream and the quartz clocks. The maximum error is 250 ppm.
CRF2
Address: 37h Type: R Bit 7 Bit 6 Bit 5
Channel 2 Baseband PLL Demodulator Offset
Bit 4 CRF2[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
CRF2[7:0]
Reset
00000000
Function
Channel 2 Carrier Recovery Frequency. Displays the instantaneous frequency offset of the Channel 2 Baseband PLL
CETH2
Address: 38h Type: R/W Bit 7 Bit 6 Bit 5
Channel 2 FM Carrier Level Threshold
Bit 4 CETH2[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
CETH2[7:0]
Reset
00100000
Function
This register is used to compare the carrier level in the channel and the threshold value. This level is measured after the channel filter and is relative to the full scale reference level (0 dB). This is used as part of the validation of an FM signal, if the carrier level is below the threshold, the signal is considered to be non-valid. CETH FFh 80h 40h 20h Threshold (dB) -6 -12 -18 -24 (Default CETH 10h 08h 00h Threshold (dB) -32 -38 OFF (All carrier levels are accepted)
70/149
STV82x7 SQTH2
Address: 39h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
Register List Channel 2 FM Squelch Threshold
Bit 0
SQTH2[7:0]
Bit Name
SQTH2[7:0]
Reset
00111100
Function
The squelch detector measures the level of high frequency noise (> 40 kHz) and compares it to the threshold level (SQTH). If the level is below this value, the S/N of the FM signal is considered to be acceptable. Values are given for FM with standard deviation. SQTH FAh 77h 3Ch 23h 19h S/N (dB) 0 10 15 (Default) 20 25
CAROFFSET2
Address: 3Ah Type: R/W Bit 7 Bit 6 Bit 5
Channel 2 DCO Carrier Offset Compensation
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
CAROFFSET2[7:0] (S)
Bit Name
Reset
Function
This value is used to correct the carrier frequency offset of the incoming IF signal. Automatic frequency control in FM mode can be implemented by registers DC_REMOVAL_L and DC_REMOVAL_R. A DCO frequency offset (in two's complement format) is added to the pre-programming value by AUTOTSD in the CARFQ2 registers (corresponding to the standard IF carrier frequency). The programmable carrier offset ranges from -192 kHz to +190.5 kHz with a resolution of 1.5 kHz. For standard FM deviation, the value displayed by register DC_REMOVAL_R can be directly loaded in register CAROFFSET2 to exactly compensate the carrier offset on Channel 2.
CAROFFSET2[7:0] 00000000
12.7
NICAM Registers
NICAM_CTRL NICAM Decoder Control Register
Address: 3Dh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 DIF_POL Bit 1 ECT Bit 0 MAE
71/149
Register List
STV82x7
Bit Name
Bits[7:3] DIF_POL ECT
Reset
00000 0 0 Reserved.
Function
0: No polarity inversion (Default) 1: Polarity inversion of the differential decoding Error Counter Timer: Defines the NICAM error measurement period 0: 128 ms (Default) 1: 64 ms
MAE
0
Max. Allowed Errors. Defines the NICAM error decoding for mute function. 0: 511 Max (Default) 1: 255 Max
NICAM_BER
Address: 3Eh Type: R Bit 7 Bit 6 Bit 5
NICAM Bit Error Rate Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
ERROR[7:0]
Bit Name
ERROR[7:0]
Reset
00000000 NICAM Error Counter Value
Function
NICAM_STAT
Address: 3Fh Type: R Bit 7 NIC_DET Bit 6 F_MUTE Bit 5 LOA
NICAM Detection Status Register
Bit 4
Bit 3 CBI[3:0]
Bit 2
Bit 1
Bit 0 NIC_MUTE
Bit Name
NIC_DET 0
Reset
NICAM Signal Detect 0: NICAM signal no detected 1: NICAM signal detected
Function
F_MUTE
0
Frame Mute 0: No mute 1: Mute due to Superframe Alignment Loss
LOA
0
Loss of Frame Alignment Word (FAW) 0: No Alignment Lost 1: Frame Alignment Word Lost
CBI[3:0] NIC_MUTE
0000 0
Indicates the received NICAM control bits Indicates the NICAM decoder mute
72/149
STV82x7
Register List
12.8
Stereo Mode
ZWT_CTRL Zweiton Detector Control Register
Address: 40h Type: R/W Bit 7 LRST_TONE_OFF Bit 6 STD_MODE Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
THRESH[3:0]
TSCTRL[1:0]
Bit Name
LRST_TONE_OFF
Reset
0 Control of the reset of the tone detector
Function
0: Periodical reset of tone detection enabled 1: Periodical reset of tone detection disabled STD_MODE_C THRESH[3:0] 0 1100 0: German standard (Default) 1: Korean standard Defines the threshold of the detector for pilot and tone frequencies. Level (% of the mid scale) 0000 0001 0010 0011 0100 0101 0110 0111 TSCTRL[1:0] 00 0 6.25 12.5 18.75 25 31.25 37.5 43.75 1000 1001 1010 1011 1100 (Default) 1101 1110 1111 Level (% of the mid scale) 50 56.25 62.5 68.75 75 81.25 87.5 93.75
Defines both the detection time and the error probability (reliability of the detection). Sample Accumulation 00 01 (Default) 10 11 1024 1024 2048 2048 Decision Count 2 3 2 3 Time (ms) 256 384 512 768 Error Probability 10-4 10-6 10-7 10-9
ZWT_TIME
Address: 41h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Zweiton Detector Timing Register
Bit 4 0
Bit 3 0
Bit 2
Bit 1 ZWT_TIME[2:0]
Bit 0
Bit Name
Bit [7:3]
Reset
00000 Reserved.
Function
73/149
Register List
STV82x7
Bit Name
ZWT_TIME[2:0]
Reset
100
Function
Defines the period of the reset tone used for tone detection system reset. Duration (ms) 000 001 010 011 100 101 110 111 256 512 768 1024 1280 1536 1792 2040
ZWT_STAT
Address: 42h Type: R Bit 7 LRST_TONE_ OFF Bit 6 0 Bit 5 0
Zweiton Status Register
Bit 4 0
Bit 3 ZW_STAT_ RDY
Bit 2 ZW_DET
Bit 1 ZW_ST
Bit 0 ZW_DM
Bit Name
LRST_TONE_OFF
Reset
0
Function
Indicates the status of the control bit programmed in the reg ZWT-CTRL 0: Periodical reset of tone detection enabled 1: Periodical reset of tone detection disabled
Bits[6:4] ZW_STAT_RDY ZW_DET ZW_ST ZW_DM
000 0 0 0 0
Reserved. Periodic flag indicating when the tone detection flags are updated and ready to be read Pilot Detection Flag Stereo Tone Detection Flag Dual Mono Tone Detection Flag
12.9
Analog Control
ADC_CTRL Register Description
Address: 56h Type: R/W Bit 7 Bit 6 Bit 5 0 Bit 4 0 Bit 3 ADC_POWER _UP Bit 2 Bit 1 ADC_INPUT_SEL[2:0] Bit 0
I2S_DATA0_CTRL[1:0]
74/149
STV82x7
Register List
Bit Name
I2S_DATA0_CTRL[1:0]
Reset
00 00 = SCART 01 = L, R 10 = HP or Srnd 11 = C/Sub Reserved.
Function
Bits[7:4] ADC_POWER_UP
0000 1
Control of the power up of the Audio ADC 0: ADC in power down mode 1: Wake up of the ADC
ADC_INPUT_SEL [2:0]
000
Selection of the ADC input signal 000: SCART 1 (Default) 001: SCART 2 010: SCART 3 011: SCART 4 100: Mono input Other: reserved
SCART1_2_OUTPUT_CTRL
Address: 57h Type: R/W Bit 7 SC2_MUTE Bit 6 Bit 5 SC2_OUTPUT_SEL[2:0]
Register Description
Bit 4
Bit 3 SC1_MUTE
Bit 2
Bit 1 SC1_OUTPUT_SEL[2:0]
Bit 0
Bit Name
SC2_MUTE
Reset
1
Function
Mute command for the output SCART 2 0: output not muted 1: output muted
010 SC2_OUTPUT_SEL[2:0]
Selection of the output SCART 2 configuration: 000: DSP 001: Mono input 010: Input SCART 1 (Default) 011: Input SCART 2 100: Input SCART 3 101: Input SCART 4 Other: Reserved
1 SC1_MUTE
Mute command for the output scart 1 0: output not muted 1: output muted
SC1_OUTPUT_SEL[2:0]
000
Selection of the output SCART 1 configuration: 000: DSP (Default) 001: Mono input 010: Input SCART 1 011: Input SCART 2 100: Input SCART 3 101: Input SCART 4 Other: Reserved
75/149
Register List SCART3_OUTPUT_CTRL
Address: 58h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 SC3_MUTE Bit 2 Bit 1
STV82x7 Register Description
Bit 0
SC3_OUTPUT_SEL[2:0]
Bit Name
Bits[7:4]
Reset
0000 1 Reserved.
Function
Mute command for the output SCART 3 0: output not muted 1: output muted
SC3_MUTE
SC3_OUTPUT_SEL[2:0]
011
Selection of the output SCART 3 configuration: 000: DSP 001: Mono input 010: Input SCART 1 011: Input SCART 2 (Default) 100: Input SCART 3 101: Input SCART 4 Other: Reserved
12.10 Clocking 2
FS2_DIV
Address: 5Ah Type: R/W Bit 7 0 Bit 6 0 Bit 5 NDIV2[1:0] Bit 4 Bit 3 Bit 2 Bit 1 SDIV2[2:0] Bit 0
FS2 I/O Divider Programming Register
Bit Name
Bit [7:6] NDIV2[1:0] Bit 4 SDIV2[2:0] 0
Reset
Reserved. FS2 Input clock divider selection Reserved. FS2 Output clock divider selection
Function
01 0 001
FS2_MD
Address: 5Bh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
FS2 Coarse Selection Register
Bit 4
Bit 3
Bit 2 MD2[4:0]
Bit 1
Bit 0
76/149
STV82x7
Register List
Bit Name
Bits[7:5] MD2[4:0]
Reset
000 10001 Reserved. FS2 Coarse Selection
Function
FS2_PE_H
Address: 5Ch Type: R/W Bit 7 Bit 6 Bit 5
FS2 Fine Selection Register (MSBs)
Bit 4 PE_H2[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
PE_H2[7:0]
Reset
0101 1100 FS2 Fine Selection (MSBs)
Function
FS2_PE_L
Address: 5Dh Type: R/W Bit 7 Bit 6 Bit 5
FS2 Fine Selection Register (LSBs)
Bit 4 PE_L2[7:0]
Bit 3
Bit 2
Bit 1
Bit 0
Bit Name
PE_L2[7:0]
Reset
0010 1001 FS2 Fine Selection (LSBs)
Function
12.11 DSP Control
HOST_CMD
Address: 80h Type: R/W Bit 7 IT_IN_DSP Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 HW_RESET Bit 1 Bit 0
DSP Hardware Control Register
Bit Name
IT_IN_DSP Bits[6:3]
Reset
0 0000 Valid I2C table. Reserved.
Function
77/149
Register List
STV82x7
Bit Name
HW_RESET Bits[1:0]
Reset
0 00 DSP Hardware reset when set. Reserved.
Function
IRQ_STATUS
Address: 81h Type: R/W Bit 7 IRQ7 Bit 6 IRQ6 Bit 5 IRQ5
IRQ Status Register
Bit 4 IRQ4
Bit 3 IRQ3
Bit 2 IRQ2
Bit 1 IRQ1
Bit 0 IRQ0
Bit Name
Bits[7:4] IRQ3 IRQ2 IRQ1 IRQ0
Reset
0000 0 0 0 0 Reserved. Unmute HP/Srnd DAC IRQ HP connection/deconnectionIRQ I2S lock lostIRQ Auto-Standard IRQ
Function
SOFT_VERSION
Address: 82h Type: R Bit 7 Bit 6 Bit 5
Embedded Software Version Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SOFT_VERSION[7:0]
Bit Name
SOFT_VERSION[7:0]
Reset
0000 0002 Version of the Embedded software.
Function
ONCHIP_ALGOS
Address: 83h Type: R Bit 7 0 Bit 6 PRO_LOGIC_ SELECT Bit 5 NICAM
Register Description
Bit 4 I2S_INPUT
Bit 3 TRUBASS
Bit 2 TRU SURROUND
Bit 1
Bit 0
PRO_LOGIC MULTICHANNEL
78/149
STV82x7
Register List
Bit Name
Bit 7 PRO_LOGIC_SELECT NICAM I2S_INPUT DIALOG_CLARITY TRUBASS TRUSURROUND PRO_LOGIC MULTICHANNEL
Reset
0 0 0 0 0 0 0 0 0 Reserved. 0: Dolby Pro Logic I 1: Dolby Pro Logic II NICAM Demodulator is present when set. 0: 1 I2S input 1: 3 I2S inputs
Function
SRS Dialog Clarity algorithm is present when set. SRS Trubass algorithm is present when set. SRS Trusurround algorithm is present when set. Dolby Pro Logic algorithm is present when set. Multichannels output is present when set.
DSP_STATUS
Address: 84h Type: R Bit 7 0 Bit 6 0 Bit 5 0
DSP Status Register
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1 0
Bit 0 INIT_MEM
Bit Name
Bits[7:1] INIT_MEM
Reset
0000000 Reserved. DSP Initialization 0 0: DSP is not initialized. 1: DSP is initialized.
Function
DSP_RUN
Address: 85h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3 0
Bit 2 0
Bit 1 HOST_ NO_INIT
Bit 0 HOST_RUN
TEST_MODE
Bit Name
TEST_MODE_ INPUT[7:6]
Reset
00
Function
active in TEST_MODE = 1 (bypass processing) 0: I2S_0 copied to SCART and SPDIF outputs 1: I2S_1 copied to SCART and SPDIF outputs 2: I2S_2 copied to SCART and SPDIF outputs
79/149
Register List
STV82x7
Bit Name
TEST_MODE[5:4]
Reset
00 0: standard configuration 1: bypass processing configuration 2: Clock Loop test Reserved
Function
Bits[3:2] HOST_ NO_INIT HOST_RUN
00 0 0
0: I2C register table is initialized when we soft reset 1: I2C register table is not initialized when we soft reset 0: soft reset DSP 1: start DSP processing
I2S_IN_CONFIG
Address: 86h Type: R/W Bit 7 LOCK_MODE _EN Bit 6 0 Bit 5 SYNC
IS Configuration Register
Bit 4 LRCLK_START
Bit 3 LRCLK_ POLARITY
Bit 2 SCLK_ POLARITY
Bit 1 DATA_CFG
Bit 0 I2S_MODE
Bit Name
LOCK_MODE_EN Bit 6
Reset
1 0 0: Disable Lock Mode for external I2S input 1: Enable Lock Mode for external I2S input Reserved. I2S synchronisation:
Function
SYNC
0
0: Capture directly 1: Wait for synchro according to LRCLK POLARITY, first data take:
LRCLK_START 0
0: Left 1: Right Polarity of the left data 0: Falling edge 1: Rising edge 0: LSB First 1: MSB First 0: Non standard mode 1: Standard mode (Refer to Figure 26)
LRCLK_POLARITY SCLK_POLARITY DATA_CFG I2S_MODE
0 1 1 0
AV_DELAY
Address: 89h Type: R/W Bit 7 Bit 6 Bit 5
Audio/Video Delay Register
Bit 4 DELAY_TIME
Bit 3
Bit 2
Bit 1
Bit 0 DELAY_ON
80/149
STV82x7
Register List
Bit Name
DELAY_TIME
Reset
Audio Delay Time 0000000: 0 ms 0000000 ... 0111100: 60 ms (48kHz) ... 1011010: 90 ms (32kHz)
Function
DELAY_ON
0
Audio/video delay is enabled when set.
Note:
AV_DELAY acts on both LS and HP paths simultaneously (same delay).
12.12 Automatic Standard Recognition
AUTOSTD_CTRL
Address: 8Ah Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 LDK_SW
Automatic Standard Recognition Control Register
FORCE_SQUE SINGLE_SHOT LCH
DK_DEV[1:0]
Bit Name
Bits[7:5] FORCE_SQUELCH
Reset
000 Reserved. Allow to force squelch detection 0
Function
0: FM squelch is taken into consideration for MONO detection 1: FM squelch is not taken into consideration for MONO detection
SINGLE_SHOT 0
Single Shot Mode Selection 0: Single Shot mode is not selected 1: Single Shot mode is selected1 Selects FM deviation configuration to take into account of overmodulation in DK_NICAM standard. 00 00: FM 50 kHz (Default) 01: FM 200 kHz 10: FM 350 kHz 11: FM 500 kHz
DK_DEV[1:0]
LDK_SW 1
Makes exclusive the auto search of DK/K1/K2/K3 and L/L' standard 0: DK/K1/K2/K3 standard auto-search / L/L' disabled 1: L/L' standard auto-search / DK/K1/K2/K3 disabled
1. Single_Shot mode can be used before disabling the Automatic Standard Recognition
(Autostandard) to pre-program demodulator registers in a defined standard and reduce IC programming in Manual mode
Note:
Only standard deviation FM 50K kHz is compatible with other D/K1/K2/K3 standards in Automatic Standard Recognition Search mode. FM deviation superior to 350 kHz will degrade strongly NICAM reception due to overlapping of FM and QPSK IF spectrum in DK-NICAM standard.
81/149
Register List
STV82x7
L/L' and DK/K1/K2/K3 standard cannot be discriminated in Automatic Standard Recognition Search mode because the same frequency is used for the mono IF carrier.
AUTOSTD_STANDARD_DETECTAuto Standard Check Standard Register
Address: 8Bh Type: R/W Bit 7 0 Bit 6 Bit 5 Bit 4 Bit 3 LDK_SCK Bit 2 I_SCK Bit 1 BG_SCK Bit 0 MN_SCK
NICAM_C4_O NICAM_GAP_ NICAM_MON FF MODE O_IN
Bit Name
NICAM_C4_OFF NICAM_GAP_MODE NICAM_MONO_IN LDK_SCK
Reset
0 1 0
Function
0: Autostandard will consider the C4 bit for MONO backup 1: Autostandard will ignore the C4 bit for MONO backup 0: NICAM, fast search 1: NICAM, slow search (no perturbations on LEFT channel in search mode) 0: the MONO backup for NICAM comes from internal demodulator 1: the MONO backup for NICAM comes from MONO input L/L' or D/K Mono Standard Enable
1
0: Disabled 1: Enabled I Mono Standard Enable
I_SCK 1
0: Disabled 1: Enabled B/G Mono Standard Enable
BG_SCK 1
0: Disabled 1: Enabled M/N Mono Standard Enable
MN_SCK 1
0: Disabled 1: Enabled
Note:
Autostandard is off when all mono standards are disabled (LDK_SCK = 0, I_SCK = 0, BG_SCK = 0 and MN_SCK = 0).
AUTOSTD_STEREO_DETECT Auto Standard Check Stereo Register
Address: 8Ch Type: R/W Bit 7 LDK_ZWT3 Bit 6 LDK_ZWT2 Bit 5 LDK_ZWT1 Bit 4 LDK_NIC Bit 3 I_NIC Bit 2 BG_ZWT Bit 1 BG_NIC Bit 0 MN_ZWT
82/149
STV82x7
Register List
Bit Name
LDK_ZWT3
Reset
Function
D/K3 Zweiton (A2*) Stereo Standard Enable
0
0: Disabled 1: Enabled D/K2 Zweiton (A2*) Stereo Standard Enable
LDK_ZWT2 0
0: Disabled 1: Enabled D/K1 Zweiton (A2*) Stereo Standard Enable
LDK_ZWT1 0
0: Disabled 1: Enabled D/K NICAM Stereo Standard Enable
LDK_NIC 1
0: Disabled 1: Enabled I NICAM Stereo Standard Enable
I_NIC 1
0: Disabled 1: Enabled B/G Zweiton (A2) Standard Enable
BG_ZWT 1
0: Disabled 1: Enabled B/G NICAM Standard Enable
BG_NIC 1
0: Disabled 1: Enabled M/N Zweiton (A2+) Standard Enable
MN_ZWT 1
0: Disabled 1: Enabled
Note:
Stereo standard covers all transmission modes (stereo or multi-language) of the NICAM or Zweiton (A2, A2* or A2+) system.
AUTOSTD_TIMERS
Address: 8Dh Type: R/W Bit 7 Bit 6 Bit 5
Detection Time Out Register
Bit 4 NICAM_TIME[2:0]
Bit 3
Bit 2
Bit 1 ZWEITON_TIME[2:0]
Bit 0
FM_TIME[1:0]
Bit Name
FM_TIME[1:0]
Reset
FM/AM Detection Time-out 10 00 : 16 ms 01: 32 ms 10: 48 ms (Default) 11: 64 ms
Function
NICAM_TIME[2:0] 100
NICAM Detection Time-out 000: 96 ms 001: 128 ms 010: 160 ms 011: 192 ms 100: 224 ms (Default) 101: 256 ms 110: 288 ms 111: 320 ms
83/149
Register List
STV82x7
Bit Name
ZWEITON_TIME[2:0]
Reset
Zweiton Detection Time-out 100 000: forbidens 001: 512 ms 010: 768 ms 011: 1024 ms
Function
100: 1280 ms (Default) 101: 1536 ms 110: 1792 ms 111: 2040 ms
Note:
The time-out default value is optimum and does not normally need to be changed.
AUTOSTD_STATUS
Address: 8Eh Type: R Bit 7 STEREO_ID Bit 6 STEREO_OK Bit 5 MONO_OK
Detection Standard Status Register
Bit 4 AUTOSTD_ON
Bit 3
Bit 2
Bit 1
Bit 0
STEREO_SID[1:0]
MONO_SID[1:0]
Bit Name
STEREO_ID
Reset
Function
Stereo Mode Detection flag activated when a stereo standard coming from the demodulator selected on Loudspeakers output. Stereo transmission modes are: - Zweiton Stereo Carrier AND Stereo Modulation (indifferently German or Korean standard) - NICAM stereo with backup (CBI = 1000) - NICAM stereo with no backup (CBI = 0000) Automatic Standard Recognition System Status
0
AUTOSTD_ON 0
0: Automatic Standard Recognition System is OFF 1: Automatic Standard Recognition System is ON Identification of the detected TV sound standard. See Table 19.
STEREO_SID[1:0] MONO_SID[1:0] STEREO_OK MONO_OK
00 00 0 0 STEREO STANDARD DETECTED MONO STANDARD DETECTED
Table 19: TV Sound Standards System
M/N B/G I
Mono Sound (MHz)
4.5 (FM 27k) 5.5 (FM 50k) 6.0 (FM 50k)
MONO_SID [1:0]
00 01
LDK_SW
X X X
DK_DEV [1:0]
XX XX XX XX
Stereo Sound (MHz)
4.724 (Zweiton A2+) 5.85 (NICAM 40%) 5.742 (Zweiton A2) 6.552 (NICAM 100%)
STEREO_SID [1:0]
00 00 01 00
10
X
84/149
STV82x7
Table 19: TV Sound Standards System
L
Register List
Mono Sound (MHz)
6.5 (AM) 6.5 (FM 50k) 6.5 (FM 200k)
MONO_SID [1:0]
LDK_SW
1
DK_DEV [1:0]
XX 00 01
Stereo Sound (MHz)
5.85 (NICAM 40%)
STEREO_SID [1:0]
00
D/K 6.5 (FM 350k) 6.5 (FM 500k) 11
0 10 11 0 XX XX XX XX
5.85 (NICAM 40%)
00
5.85 (NICAM 40%) 6.258 (Zweiton A2*) 6.742 (Zweiton A2*) 5.742 (Zweiton A2*)
00 01 10 11
D/K1/K2/ K3
0 6.5 (FM 50k) 0 0
Note:
X means don't care.
12.13 Audio Preprocessing and Selection Registers
DC_REMOVAL_INPUT
Address: 90h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 DC_SCART Bit 1 DC_NICAM Bit 0 DC_DEMOD
DC Removal Register
Bit Name
Bits[7:3] DC_SCART
Reset
00000 1 Reserved. 0: SCART input, DC removal inactive 1: SCART input, DC removal active 0: NICAM input, DC removal inactive 1: NICAM input, DC removal active 0: FM input, DC removal inactive 1: FM input, DC removal active
Function
DC_NICAM
1
DC_DEMOD
1
85/149
Register List DC_REMOVAL_L
Address: 91h Type: R Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
STV82x7 FM DC Offset Left Registerl
Bit 0
DC_REMOVAL_L[7:0]
Bit Name
DC_REMOVAL_L[7:0]
Reset
Function
Displays (in two's complement format) the FM (or AM) DC offset level after demodulation on channel 1 (and removed automatically).
0000 0000 In FM mode, the DC offset value gives a direct value of the carrier frequency offset which is used to compensate the DCO with the CAROFFSET1 value in the event of an out-of-standard offset. The range and the resolution depend upon the FM bandwidth programmed defined in register BCOEFF1. See Table 20.
DC_REMOVAL_R
Address: 92h Type: R Bit 7 Bit 6 Bit 5
FM DC Offset Right Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
DC_REMOVAL_R[7:0]
Bit Name
DC_REMOVAL_R[7:0]
Reset
Function
Displays (in two's complement format) the FM (or AM) DC offset level after demodulation on channel 2 (and removed automatically).
0000 0000
In FM mode, the DC offset value gives a direct value of the carrier frequency offset which is used to compensate the DCO with the CAROFFSET2 value in the event of an out-ofstandard offset. The range and the resolution depend upon the FM bandwidth programmed defined in register BCOEFF2. See Table 20.
Table 20: DC_REMOVAL_L/R Range and Resolution FM mode
Small Standard & A2 Standard Medium Large
Range (kHz)
96 192 384 768
Resolution (kHz)
0.750 1.5 3 6
86/149
STV82x7 PRESCALE_SELECT
Address: 93h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 0
Register List AM/FM Prescaling Select Register
Bit 0 AM_FM_ SELECT
Bit Name
Bits[7:1] AM_FM_SELECT
Reset
0000000 Reserved. 0
Function
0: FM prescale is applied to demodulator channels 1: AM prescale is applied to demodulator channels
PRESCALE_AM
Address: 94h Type: R/W Bit 7 0 Bit 6 Bit 5
AM Prescaling Register
Bit 4
Bit 3 PRESCALE_AM
Bit 2
Bit 1
Bit 0
Bit Name
Bit 7 PRESCALE_AM[6:0] 0
Reset
Reserved.
Function
0000000 -12 to + 24 dB AM prescaling to normalize the AM demodulated signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = 0 dB) 0110000 0101111 0101110 0101101 0101100 G (dB) +24 +23.5 +23 +22.5 +22 etc. 1101100 1101011 1101010 1101001 1101000 G (dB) -10 -10.5 -11 -11.5 -12
PRESCALE_FM
Address: 95h Type: R/W Bit 7 0 Bit 6 Bit 5
FM Prescaling Register
Bit 4
Bit 3 PRESCALE_FM
Bit 2
Bit 1
Bit 0
87/149
Register List
STV82x7
Bit Name
Bit 7 0
Reset
Reserved.
Function
PRESCALE_FM[6:0] 0001100 -12 to + 24 dB FM prescaling to normalize the FM demodulated signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = +6 dB) 0110000 0101111 0101110 0101101 0101100 G (dB) +24 +23.5 +23 +22.5 +22 etc. 1101100 1101011 1101010 1101001 1101000 G (dB) -10 -10.5 -11 -11.5 -12
PRESCALE_NICAM
Address: 96h Type: R/W Bit 7 0 Bit 6 Bit 5
NICAM Prescaling Register
Bit 4
Bit 3 PRESCALE_NICAM
Bit 2
Bit 1
Bit 0
Bit Name
Bit 7 0
Reset
Reserved.
Function
PRESCALE_NICAM[6:0] 011010
-6 to + 24 dB NICAM prescaling to normalize the NICAM demodulated signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = +13 dB) 0110000 0101111 0101110 0101101 0101100 G (dB) +24 +23.5 +23 +22.5 +22 etc. 1111000 1110111 1110110 1110101 1110100 G (dB) -4 -4.5 -5 -5.5 -6
PRESCALE_SCART
Address: 97h Type: R/W Bit 7 0 Bit 6 0 Bit 5
SCART Prescaling Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PRESCALE_SCART
Bit Name
Bit [7:6]
Reset
00 Reserved.
Function
88/149
STV82x7
Register List
Bit Name
PRESCALE_ SCART[5:0]
Reset
Function
0000000 -12 to + 12 dB SCART prescaling to normalize the SCART signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = 0 dB) 011000 010111 010110 010101 010100 G (dB) +12 +11.5 +11 +10.5 +10 etc. 101100 101011 101010 101001 101000 G (dB) -10 -10.5 -11 -11.5 -12
PRESCALE_I2S_0
Address: 98h Type: R/W Bit 7 0 Bit 6 0 Bit 5
I2S_0 Prescaling Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PRESCALE_I2S_0[5:0]
Bit Name
Bits [7:6] PRESCALE_I2S_0[5:0]
Reset
00 000000 Reserved.
Function
-12 to + 12 dB I2S_0 prescaling to normalize the I2S_0 signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = 0 dB) 011000 010111 010110 010101 010100 G (dB) +12 +11.5 +11 +10.5 +10 etc. 101100 101011 101010 101001 101000 G (dB) -10 -10.5 -11 -11.5 -12
PRESCALE_I2S_1
Address: 99h Type: R/W Bit 7 0 Bit 6 0 Bit 5
I2S_1 Prescaling Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PRESCALE_I2S_1[5:0]
Bit Name
Bits [7:6]
Reset
00 Reserved.
Function
89/149
Register List
STV82x7
Bit Name
Reset
Function
-12 to + 12 dB I2S_1 prescaling to normalize the I2S_1 signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = 0 dB) 011000 010111 010110 010101 010100 G (dB) +12 +11.5 +11 +10.5 +10 etc. 101100 101011 101010 101001 101000 G (dB) -10 -10.5 -11 -11.5 -12
PRESCALE_I2S_1[5:0] 000000
PRESCALE_I2S_2
Address: 9Ah Type: R/W Bit 7 0 Bit 6 0 Bit 5
I2S_2 Prescaling Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PRESCALE_I2S_2[5:0]
Bit Name
Bits [7:6]
Reset
00 Reserved.
Function
PRESCALE_I2S_2[5:0] 000000
-12 to + 12 dB I2S_2 prescaling to normalize the I2S_2 signal level before audio processing. Auto level control can be implemented by I2C software using the Peak Level Detector. (Default value = 0 dB) 011000 010111 010110 010101 010100 G (dB) +12 +11.5 +11 +10.5 +10 etc. 101100 101011 101010 101001 101000 G (dB) -10 -10.5 -11 -11.5 -12
DEEMPHASIS_DEMATRIX
Address: 9Bh Type: R/W Bit 7 0 Bit 6 0 Bit 5 NICAM_ DEMATRIX
Deemphasis-Dematrix Register
Bit 4 NICAM_ DEEMPH_BY PASS
Bit 3
Bit 2
Bit 1
Bit 0
FM_DEMATRIX
FM_DEEMPH FM_DEEMPH _BYPASS _SW
Bit Name
Bits [7:6]
Reset
00 Reserved.
Function
90/149
STV82x7
Register List
Bit Name
NICAM_DEMATRIX 0
Reset
Dematrixing for NICAM demodulator input: 00: L=ch0, R=ch1 01: L=ch1, R=ch0
Function
NICAM_DEEMPH_ 0 BYPASS FM_DEMATRIX[3:2] 00
0: NICAM deemphasis is not bypassed. 1: NICAM deepmhasis is bypassed. Dematrixing for FM demodulator input: 00: L=ch0, R=ch1 01: L=ch0+ch1, R=ch0-ch1 10: L=2ch0-ch1, R=ch1 11: L=(ch0+ch1)/2, R=(ch0-ch1)/2
FM_DEEMPH_ BYPASS FM_DEEMPH_SW
0 0
0: FM deemphasis is not bypassed. 1: FM deepmhasis is bypassed. 0: 50 s FM deemphasis.| 1: 75 s FM deepmhasis.
PEAK_DET_INPUT
Address: 9Dh Type: R Bit 7 PEAK_LOCATION Bit 6 0 Bit 5
Peak Detector Input source Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PEAK_L_R_RANGE
PEAK_DET_INPUT[1:0]
Bit Name
PEAK_LOCATION 0
Reset
Function
Peak detector location : 0: Peak detector placed between FM/NICAM Dematrix and Audio Matrix or between IS Prescale and DownMix 1: Peak detector placed before DC removal (For input saturation detection) Reserved. Peak L-R range. 0000 : 0 dBFS to -42 dBFS 0001 : -6 dBFS to -48 dBFS 0010 : -12 dBFS to -54 dBFS 0011 : -18 dBFS to -60 dBFS ... Peak Level Detector Source Selection 00: AM/FM or I2S 0 01: NICAM or I2S 1 10: SCART or I2S 2
Bit 6 PEAK_L_R_RANGE
0 0000
PEAK_DET_INPUT[1:0] 00
PEAK_DET_L
Address: 9Eh Type: R Bit 7 OVERLOAD_L Bit 6 Bit 5
Peak Level Detector Status Register (L channel)
Bit 4
Bit 3 PEAK_L[6:0]
Bit 2
Bit 1
Bit 0
91/149
Register List
STV82x7
Bit Name
OVERLOAD_L[7] PEAK_L[6:0] 0
Reset
Function
Memorise overload on the peak detection. This field can be reset. Displays the Absolute Peak Level of the audio source selected. The measured value is updated continuously every 64 ms. The range varies linearly from the full scale (0 dB) down to 1/ 256 of the full scale (-48 dB). In AM/FM Mono mode, only the PEAK_L[7:0] value must be taken into account. In FM Mono mode, the audio peak level range depends upon the programmed FM bandwidth. The unique difference is that the measurement is done after Sound pre-processing (DC offset removal, Prescaling, De-emphasis and Dematrixing). In FM Stereo mode, the maximum value may be used to check if the incoming signal level is correctly adjusted by the prescaling factor or if there are no FM overmodulation problems (clipping). Programmable values are listed in Table 20.
00000000
PEAK_DET_R
Address: 9Fh Type: R Bit 7 OVERLOAD_R Bit 6 Bit 5
Peak Level Detector Status Register (R channel)
Bit 4
Bit 3 PEAK_R[6:0]
Bit 2
Bit 1
Bit 0
Bit Name
OVERLOAD_R[7] PEAK_R[7:0] 0
Reset
Function
Memorise overload on the peak detection. This field can be reset. Displays the Absolute Peak Level of the audio source selected. The measured value is updated continuously every 64 ms. The range varies linearly from the full scale (0 dB) down to 1/256 of the full scale (-48 dB). For more information, refer to register PEAK_DET_L.
0000000
PEAK_DET_L_R
Address: A0h Type: R Bit 7 OVERLOAD_L_R Bit 6 Bit 5
Peak Level Detector Status Register (L - R)
Bit 4
Bit 3 PEAK_L_R[6:0]
Bit 2
Bit 1
Bit 0
Bit Name
OVERLOAD_L_R[7] 0 PEAK_L_R[7:0]
Reset
Function
Memorise overload on the peak detection. This field can be reset. Displays the Difference between L and R (L - R) channels for the audio source selected. For more information, refer to register PEAK_DET_L.
0000000
92/149
STV82x7
Register List
12.14 Matrixing
AUDIO_MATRIX_INPUT
Address: A2h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 SCART_ INPUT_ SOURCE Bit 1 HP_INPUT_ SOURCE Bit 0 LS_INPUT_ SOURCE
Audio Matrix Input Selection Register
Bit Name
Bits [7:3] SCART_INPUT_ SOURCE
Reset
00000 0 Reserved. Select input source for SCART output: 0: Demod 1: SCART input 0 Select input source for HP output: 0: Demod 1: SCART input 0 Select input source for LS output: 0: Demod 1: SCART input
Function
HP_INPUT_ SOURCE
LS_INPUT_ SOURCE
AUDIO_MATRIX_CONFIG
Address: A3h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 SCART_ MATRIX
Bit 3
Bit 2
Bit 1
Bit 0
DEMOD_MATRIX[3:0]
Bit Name
Bits [7:5] SCART_MATRIX DEMOD_MATRIX [3:0]
Reset
000 0 0000 Reserved.
Function
Indicates the SCART input signal matrixing (see Table 22) Indicates the demod input signal matrixing (see Table 21)
93/149
Register List
Table 21: Demod Matrix Input Mode Language -> demod_mx
Mono AM/FM with backup Mono AM/FM no backup Zwt St Zwt Dual NICAM Mn, backup NICAM Dual backup NICAM St, backup NICAM Mn, no backup NICAM Dual, no backup NICAM St, no backup 0000 0001 0100 0101 1000 1001 1010 1100 1101 1110 FM_L FM_M1
STV82x7
Stereo L
FM FM_R FM_M2
Mono A R L
FM (FM_L + FM_R)/2 FM_M1 NIC_M1 NIC_M1 (NIC_L + NIC_R)/2 NIC_M1 NIC_M1 (NIC_L + NIC_R)/2
Mono B L
FM (FM_L + FM_R)/2 FM_M2 NIC_M1 NIC_M2 (NIC_L + NIC_R)/2 NIC_M1 NIC_M2 (NIC_L + NIC_R)/2
Mono C L
FM FM (FM_L + FM_R)/2 (FM_M1 + FM_M2)/2 FM FM FM FM FM FM
Backup mode
R
R
R
NIC_M1 NIC_M1 NIC_L NIC_M2 NIC_R
Mono AM/FM with backup Mono AM/FM with backup Mono AM/FM with backup Mono AM/FM no backup Mono AM/FM no backup Mono AM/FM no backup
NIC_M1 NIC_M1 NIC_L NIC_M2 NIC_R
Note:
Switching between Stereo and Forced Mono modes can be done using (FM_L + FM_R)/2 or (NIC_L + NIC_R)/2 configurations.
Table 22: SCART Matrix Stereo SCART_MX Left
0 1 SCART_L SCART_R
Mono A Left Right Left
Mono B Right Left
Mono C Right
Right
SCART_R SCART_L
SCART_L SCART_R
SCART_R SCART_L
(SCART_L + SCART_R)/2 (SCART_L + SCART_R)/2
AUDIO_MATRIX_LANGUAGE
Address: A4h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
MUTE_STEREO MUTE_ALL
SCART_LANGUAGE[1:0]
HP_LANGUAGE[1:0]
LS_LANGUAGE[1:0]
94/149
STV82x7
Register List
Bit Name
MUTE_STEREO MUTE_ALL SCART_ LANGUAGE[1:0] 0 0
Reset
Mute outputs with stereo signal input Mute all outputs Select language for SCART output Select language for HPoutput Select language for LS output 00: stereo 01: mono A 10: mono B 11: mono C
Function
00
HP_LANGUAGE[1:0] 00 00 LS_LANGUAGE[1:0]
DOWNMIX_IN_MODE
Address: A6h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 LFE_IN
Bit 2
Bit 1 MIX_IN_MODE[2:0]
Bit 0
Bit Name
Bits[7:4] LFE_IN
Reset
0000 0 Reserved
Function
0: LFE signal is not inputed throught Downmix Block 1: LFE signal is inputed throught Downmix Block see Table 23
MIX_IN_MODE[2:0] 010
Table 23: DownMix IN modes Parameter Coding (Decimal Format)
0 1 2 3 4 5 6 7
Parameter Field Lebel
MODE11 MODE10 MODE20 MODE30 MODE21 MODE31 MODE22 MODE32
Function
Mode not used in STV82x7 1/0 (C) 2/0 (L,R) 3/0 (L,R,C) 2/1 (L,R,S) 3/1 (L,R,C,S) 2/2 (L,R,Ls,Rs) 3/2 (L,R,C,Ls,Rs)
95/149
Register List DOWNMIX_OUT_MODE
Address:A7h Type: R/W Bit 7 0 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 LS_OUT_MODE[2:0]
STV82x7 Register Description
Bit 0
HP_MODE[1:0]
SCART_MODE[1:0]
Bit Name
Bit 7 HP_MODE[1:0] SCART_MODE[1:0] 0
Reset
Reserved. see Table 24 see Table 24 see Table 25
Function
10 01
LS_OUT_MODE [2:0] 010
Table 24: DownMix SCART/HP modes Parameter Coding (Decimal Format)
0 1 2 3
Parameter Field Label
MIX_VCR_OFF MIX_VCR_PROLOGIC MIX_VCR_STEREO MIX_COSTOM
Function
Switch off the VCR table setup VCR table setup for Tape outputs (for later decoding by a Dolby Prologic decoder - Lt,Rt) VCR table setup for Stereo and headphone listening (Lo,Ro) reserved
Table 25: DownMix LS OUT modes Parameter Coding (Decimal Format)
0 1 2 3 4 5 6 7
Parameter Field Label
MODE20t MODE10 MODE20 MODE30 MODE21 MODE31 MODE22 MODE32
Function
2/0 Dolby Surround (Lt,Rt) 1/0 (C) 2/0 (L,R) 3/0 (L,R,C) 2/1 (L,R,S) 3/1 (L,R,C,S) 2/2 (L,R,Ls,Rs) 3/2 (L,R,C,Ls,Rs)
96/149
STV82x7 DOWNMIX_DUAL_MODE
Address: A8h Type: R/W Bit 7 0 Bit 6 DUAL_ON Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
Register List Register Description
Bit 0
LS_DUAL_SELECT[1:0]
SCART_DUAL_SELECT[1:0]
HP_DUAL_SELECT[1:0]
Bit Name
Bit 7 DUAL_ON LS_DUAL_SELECT[1:0] 0 0
Reset
Reserved. 0: dual mode disable 1: dual mode enable Dual Mono Mode on LS output 00: LS dual stereo 00: LS dual left mono 10: LS dual right mono 11: LS dual mixed
Function
00
SCART_DUAL_SELECT[1:0]
00
Dual Mono Mode on SCART output 00: SCART dual stereo 01: SCART dual left mono 10: SCART dual right mono 11: SCART dual mixed
HP_DUAL_SELECT[1:0]
00
Dual Mono Mode on HP output 00: HP dual stereo 01: HP dual left mono 10: HP dual right mono 11: HP dual mixed
DOWNMIX_CONFIG
Address: A9h Type: R/W Bit 7 0 Bit 6 0 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1 LR_UPMIX
Bit 0 NORMALIZE
SRND_FACTOR[1:0]
CENTER_FACTOR[1:0]
Bit Name
Bits[7:6] SRND_FACTOR [1:0]
Reset
00 00 00: -3dB 01: -4.5dB 10: -6dB 11: -6dB 00: -3dB 01: -4.5dB 10: -6dB 11: -4.5dB
Function
CENTER_FACTOR [1:0] 00
97/149
Register List
STV82x7
Bit Name
LR_UPMIX NORMALIZE 0 1
Reset
0: disable upmixing 1: enable upmixing (DTS specified) 0: disable normalization 1: enable normalization
Function
12.15 Audio Processing
PRO_LOGIC2_CONTROL
Address: AAh Type: R/W Bit 7 PL2_LFE Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 PL2_MODES[2:0] Bit 1 Bit 0 PL2_ACTIVE
Register Description
PL2_OUTPUT_DOWNMIX[2:0]
Bit Name
PL2_LFE 0
Reset
0: Reset the LFE channel 1: Bypass the LFE channel
Function
PL2_OUTPUT_ DOWNMIX[2:0]
000
000: not applicable 001: not applicable 010: not applicable 011: 3/0 output mode (L,R,C) 100: 2/1 output mode (L,R,Ls - phantom) 101: 3/1 output mode (L,R,C,Ls) 110: 2/2 output mode (L,R,Ls,Rs - phantom) 111: 3/2 output mode (L,R,C,Ls,Rs) 000: Pro Logic 1 Emulation (forced if DPL version) 001: Virtual (DPL2 version only) 010: Music (DPL2 version only) 011: Movie (standard) (DPL2 version only) 100: Matrix (DPL2 version only) 101: Custom (DPL2 version only) 110: not applicable (DPL2 version only) 111: not applicable (DPL2 version only) 0: Dolby Prologic 2 is not active 1: Dolby Prologic 2 is active
PL2_MODES[2:0]
000
PL2_ACTIVE
0
Table 26: Prologic II Decode Mode Configuration PL2 Mode 0 1 2 Decode Mode Pro Logic Emulation Virtual Music Dimension Center Width AutoBalance
1 1 0
Panorama
Surround Coherence
0 1 1
SUR Filtering
2 0 1
3 3 x
0 0 x
0 0 x
98/149
STV82x7
Table 26: Prologic II Decode Mode Configuration (Continued) PL2 Mode 3 4 5 Decode Mode Movie/ Standard Matrix Custom Dimension Center Width AutoBalance
1 0 x
Register List
Panorama
Surround Coherence
0 1 x
SUR Filtering
0 1 x
3 3 x
0 0 x
0 0 x
Note:
(x = user defined parameter)
PCM_SRND_DELAY
Address: ABh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4
Bit 3
Bit 2 SNRD_DELAY[4:0]
Bit 1
Bit 0
Bit Name
Bits[7:5]
Reset
000 Reserved. Surround Channel Delay range: 0 to 30 (in ms)
Function
SNRD_DELAY[4:0] 00000
PCM_CENTER_DELAY
Address: ACh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3
Bit 2
Bit 1
Bit 0
CENTER_DELAY[3:0]
Bit Name
Bits[7:4]
Reset
0000 Reserved. Center Channel Delay range: 0 to 10 (in ms)
Function
CENTER_DELAY[3:0] 0000
99/149
Register List PRO_LOGIC2_CONFIG
Address: ADh Type: R/W Bit 7 PL2_LFE Bit 6 0 Bit 5 0 Bit 4 Bit 3 Bit 2 PL2_RS_ POLARITY Bit 1 PL2_ PANORAMA
STV82x7 Register Description
Bit 0 PL2_ AUTOBALANCE
PL2_SRND_FILTER[1:0]
Bit Name
Bits[7:6]
Reset
00 Reserved.
Function
PL2_SRND_FILTR[1:0] 00
00: 0: Off 01: 1: Shelf Filter (for music and matrix modes) 10: 2: 7kHz LP 11: 3: not applicable 0: Rs polarity normal 1: Rs polarity inverted 0: Panorama Off 1: Panorama On 0: Autobalance Off 1: Autobalance On
PL2_RS_POLARITY PL2_PANORAMA PL2_AUTOBALANCE
0 0 0
See Table 26: Prologic II Decode Mode Configuration for programmation of these bits depending on the decode mode.
PRO_LOGIC2_DIMENSION
Address: AEh Type: R/W Bit 7 0 Bit 6 Bit 5 PL2_C_WIDTH
Register Description
Bit 4
Bit 3 0
Bit 2
Bit 1 PL2_DIMENSION
Bit 0
Bit Name
Bit 7 0
Reset
Reserved. 000: 0, no spread = OFF 001: 20 010: 28 011: 36 100: 54 101: 62 110:69 111: 90, phantom Reserved.
Function
PL2_C_WIDTH[2:0]
000
Bit 3
0
100/149
STV82x7
Register List
Bit Name
Reset
000: -3, most surround 001: -2 010: -1 011: 0, neutral = OFF 100: 1 101: 2 110:3, most center 111: not applicable
Function
PL2_DIMENSION[2:0] 000
See Table 26: Prologic II Decode Mode Configuration for programmation of these bits depending on the decode mode.
PRO_LOGIC2_LEVEL
Address: AFh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PL2_LEVEL
Bit Name
Reset
Input Gain attenuation: 0000 0000: 0dB 00000000 0000 0001: -0.5dB ... 1111 1111: -127.5dB
Function
PL2_LEVEL[7:0]
NOISE_GENERATOR
Address: B0h Type: R/W Bit 7 10_DB_ ATTENUATE Bit 6 SRIGHT_ NOISE Bit 5 SLEFT_ NOISE
Register Description
Bit 4 SUB_ NOISE
Bit 3 CENTER_ NOISE
Bit 2 RIGHT_ NOISE
Bit 1 LEFT_ NOISE
Bit 0 NOISE_ON
Bit Name
10_DB_ATTENUATE 0 SRIGHT_NOISE SLEFT_NOISE SUB_NOISE CENTER_NOISE RIGHT_NOISE 0 0 0 0 0
Reset
Function
0: noise is outputed with full range 1: noise is outputed with a 10dB attenuation 1: Generates noise on LS right surround output 1: Generates noise on LS left surround output 1: Generates noise on LS subwoofer output 1: Generates noise on LS center output 1: Generates noise on LS right output
101/149
Register List
STV82x7
Bit Name
LEFT_NOISE NOISE_ON 0 0
Reset
1: Generates noise on LS left output 0: Noise Generation not active 1: Noise Generation is active
Function
TRUSRND_CONTROL
Address: B1h Type: R/W Bit 7 0 Bit 6 TRUSRND_ MONO_SRND Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1 TRUSRND_ MODE
Bit 0 TRUSRND_ ON
TRUSRND_INPUT_ MODE[3:0]
Bit Name
Bit 7 0
Reset
Reserved. 0: Left mono Srnd mode 1: Right mono Srnd mode
Function
TRUSRND_MONO 0 _SRND TRUSRND_ INPUT_ MODE[3:0]
0000
0000: Mono 0001: L/R stereo (SRS mode) 0010: L/R/S (SRS mode, Prologic 1 Process) 0011: L/R/Ls/Rs (SRS mode) 0100: L/R/C (TruSurround mode) 0101: L/R/C/S (TruSurround mode, Prologic 1 Process) 0110: L/R/C/Ls/Rs (TruSurround mode) 0111: Lt/Rt (TruSurround mode) 1000: L/R/C/Ls/Rs (SRS mode, BS Digital Broadcast) 1001: L/R/C/Ls/Rs (TruSurround, Prologic 2 Music mode) 0: TruSurround mode 1: Bypass mode 0: TruSurround OFF 1: TruSurround ON
TRUSRND_MODE
0 0
TRUSRND_ON
TRUSRND_INPUT_GAIN
Address: B6h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
TRUSRND_INPUT_GAIN[7:0]
102/149
STV82x7
Register List
Bit Name
Reset
Input Gain attenuation: 0000 0000: 0dB 0000 0001: -0.5dB ... 1111 1111: -127.5dB
Function
TRUSRND_INPUT_ 0000 GAIN[7:0] 0000
TRUSRND_HP_DCL
Address: B7h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2
Bit 1
Bit 0 0
DIALOG_ HEADPHONE CLARITY_ON _ON
Bit Name
Bits[7:2] DIALOG_ CLARITY_ON HEADPHONE_ON
Reset
00000 0 0 Reserved. 0: Dialog Clarity OFF 1: Dialog Clarity ON Activate HP mode in TruSurround XT: 0: HP mode OFF 1: HP mode ON
Function
Bit [0]
0
Reserved.
TRUSRND_DC_ELEVATION
Address: B8h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4
Register Description
Bit 3
Bit 2
Bit 1
Bit 0
TRUSRND_DC_ELEVATION[7:0]
Bit Name
TRUSRND_DC_ ELEVATION[7:0]
Reset
0000 1100 Dialog Calrity Elevation: 0000 0000: 0dB 0000 0001: -0.5dB ... 1111 1111: -127.5dB
Function
103/149
Register List TRUBASS_LS_CONTROL
Address: BAh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 Bit 2 TRUBASS_LS_SIZE[2:0] Bit 1
STV82x7 Register Description
Bit 0 TRUBASS_ LS_ON
Bit Name
Bits[7:3] TRUBASS_LS_SIZE[2:0]
Reset
00000 Reserved. 000: LF response at 40Hz 001: LF response at 60Hz 010: LF response at 100Hz 011: LF response at 150Hz 100: LF response at 200Hz 101: LF response at 250Hz 110: LF response at 300Hz 111: LF response at 400Hz 0: LS TruBass OFF 1: LS TruBass ON
Function
011
TRUBASS_LS_ON
0
TRUBASS_LS_LEVEL
Address: BBh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
TRUBASS_LS_LEVEL[7:0]
Bit Name
TRUBASS_LS_ LEVEL[7:0]
Reset
0000 1001
Function
Define the amount of SRS TruBass effect for LS outputs: 0000 0000: 0dB 0000 0001: -0.5dB ... 1111 1111: -127.5dB
TRUBASS_HP_CONTROL
Address: BCh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3
Bit 2 TRUBASS_HP_SIZE[2:0]
Bit 1
Bit 0 TRUBASS_HP _ON
104/149
STV82x7
Register List
Bit Name
Bits[7:3] TRUBASS_HP_ SIZE[2:0]
Reset
00000 Reserved. 000: LF response at 40Hz 001: LF response at 60Hz 010: LF response at 100Hz 011: LF response at 150Hz 100: LF response at 200Hz 101: LF response at 250Hz 110: LF response at 300Hz 111: LF response at 400Hz 0: HP TruBass OFF 1: HP TruBass ON
Function
011
TRUBASS_HP_ON
0
TRUBASS_HP_LEVEL
Address: BDh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
TRUBASS_HP_LEVEL[7:0]
Bit Name
TRUBASS_HP_ LEVEL[7:0]
Reset
0000 1001
Function
Define the amount of SRS TruBass effect for HP outputs: 0000 0000: 0dB 0000 0001: -0.5dB ... 1111 1111: -127.5dB
SVC_LS_CONTROL
Address: BEh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3
Bit 2
Bit 1 SVC_LS_AMP
Bit 0 SVC_LS_ON
SVC_LS_INPUT[1:0]
Bit Name
Bits[7:4] SVC_LS_INPUT[1:0]
Reset
0000 Reserved.
Function
Select input for peak detection in multichannel mode: 00 00: Left/Right 01: Center 10: Left/Right/Center 0: 0dB amplification in auto-mode 1: +6dB amplification in auto-mode 0: Manual mode(simple prescaler) 1: Automatic mode
SVC_LS_AMP SVC_LS_ON
1 0
105/149
Register List SVC_LS_TIME_TH
Address: BFh Type: R/W Bit 7 Bit 6 SVC_LS_TIME[2:0] Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
STV82x7 Register Description
Bit 0
SVC_LS_THRESHOLD[4:0]
Bit Name
SVC_LS_TIME[2:0]
Reset
Function
Time constant for the amplification (6dB gain step) in automatic mode: 000: 30ms 001: 200ms 010: 500ms 011: 1s 100: 16s 101: 32s 110: 64s 111: 128s see Table 27 and Table 28.
100
SVC_LS_ THRESHOLD[4:0]
11000
Table 27: Gain (threshold field) values in Manual mode Manual Mode
00101 00100 00011 00010 00001 00000 11111 11110 11101 11100 11011 11010 11001 11000 10111 10110
Gain (dB)
+15.5 +12 +9.5 +6 +3.5 0 -2.5 -6 -8.5 -12 -14.5 -18 -20.5 -24 -26.5 -30
106/149
STV82x7
Table 28: Threshold values in Automatic mode Automatic Mode
11111 11110 11101 11100 11011 11010 11001 11000 10111 10110
Register List
Threshold (dB)
-2.5 -6 -8.5 -12 -14.5 -18 -20.5 -24 -26.5 -30
SVC_HP_CONTROL
Address: C0h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1 SVC_ LHP_AMP
Bit 0 SVC_HP_ON
Bit Name
Bits[7:2] SVC_LHP_AMP SVC_HP_ON
Reset
000000 1 0 Reserved. 0: 0dB amplification in auto-mode 1: +6dB amplification in auto-mode 0: Manual mode (simple prescaler) 1: Automatic mode
Function
SVC_HP_TIME_TH
Address: C1h Type: R/W Bit 7 Bit 6 SVC_HP_TIME[2:0] Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SVC_HP_THRESHOLD[4:0]
107/149
Register List
STV82x7
Bit Name
Reset
Function
Time constant for the amplification (6dB gain step) in automatic mode: 000: 30ms 001: 200ms 010: 500ms 011: 1s 100: 16s 101: 32s 110: 64s 111: 128s
SVC_HP_TIME[2:0] 100
SVC_HP_ THRESHOLD[4:0]
11000
see Table 27 and Table 28
SVC_LS_GAIN
Address: C2h Type: R/W Bit 7 0 Bit 6 Bit 5
Register Description
Bit 4
Bit 3 SVC_LS_GAIN[6:0]
Bit 2
Bit 1
Bit 0
Bit Name
Bit 7 SVC_LS_GAIN[6:0] 0
Reset
Reserved.
Function
Set "make-up" gain applied at SVC LS output: 0000000: +0dB 0000001: +0.5dB 0000000 ... 0101110: +23dB 0101111: +23.5dB 0110000: +24dB
SVC_HP_GAIN
Address: C3h Type: R/W Bit 7 0 Bit 6 Bit 5
Register Description
Bit 4
Bit 3 SVC_HP_GAIN[6:0]
Bit 2
Bit 1
Bit 0
Bit Name
Bit 7 0
Reset
Reserved.
Function
108/149
STV82x7
Register List
Bit Name
SVC_HP_GAIN[6:0]
Reset
Function
Set "make-up" gain applied at SVC HP output: 0000000: +0dB 0000001: +0.5dB 0000000 ... 0101110: +23dB 0101111: +23.5dB 0110000: +24dB
STSRND_CONTROL
Address: C4h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
ST WideSurround Control Register
Bit 4 0
Bit 3 0
Bit 2 STSRND_ STEREO
Bit 1 STSRND_ MODE
Bit 0 STSRND_ON
Bit Name
Bits[7:3]
Reset
00000 Reserved. ST WideSurround Mode
Function
STSRND_STEREO 0
0: ST WideSurround Sound in Mono mode (Default) 1: ST WideSurround Sound in Stereo mode STSRND_MODE 0 ST WideSurround Sound Stereo Mode 0: Movie Mode 1: Music Mode STSRND_ON 0 ST WideSurround Sound Enable 0: ST WideSurround Sound is disabled 1: ST WideSurround Sound is enabled
STSRND_FREQ
Address: C5h Type: R/W Bit 7 0 Bit 6 0 Bit 5
ST WideSurround Sound Frequency
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
STSRND_BASS[1:0]
STSRND_MEDIUM[1:0]
STSRND_TREBLE[1:0]
Bit Name
Bits[7:6] STSRND_BASS[1:0]
Reset
00 01 Reserved.
Function
Defines the bass frequency effect for ST WideSurround Sound. Programmable values are listed in Table 29. Defines the medium frequency effect for ST WideSurround Sound in Movie or Mono mode (no effect in Music mode). Programmable values are listed in Table 29.
STSRND_MEDIUM[1:0] 01
109/149
Register List
STV82x7
Bit Name
Reset
Function
Defines the treble frequency effect for ST WideSurround Sound in Movie or Mono mode (no effect in Music mode). Programmable values are listed in Table 29.
STSRND_TREBLE[1:0] 01
Table 29: Phase Shifter Center Frequencies Phase Shifter Center Frequency BASS_FREQ[1:0]
00 01 (Default) 10 11 40 Hz 90 Hz 120 Hz 160 Hz
MEDIUM_FREQ[1:0]
202 Hz 416 Hz 500 Hz 588 Hz
TREBLE_FREQ[1:0]
2 kHz 4 kHz 5 kHz 6 kHz
STSRND_LEVEL
Address: C6h Type: R/W Bit 7 Bit 6 Bit 5
ST WideSurround Gain Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
STSRND_GAIN[7:0]
Bit Name
Reset
Function
Defines the ST WideSurround Sound component gain in linear scale. Level (%) 1000 0000 (Default) 0111 1111 0111 1110 0111 1101 ........ 100% 99.2% 98.4% 97.6% 0000 0100 0000 0011 0000 0010 0000 0001 0000 0000 Level (%) 3.1% 2.3% 1.6% 0.8% 0%
STSRND_GAIN[7:0] 10000000
OMNISURROUND_CONTROL Register Description
Address: C7h Type: R/W Bit 7 LFE Bit 6 Bit 5 Bit 4 FRONT_ BYPASS Bit 3 Bit 2 Bit 1 Bit 0 OMNISRND_ON
ST_VOICE[1:0]
OMNI_SURND_INPUT_MODE[3:0]
Bit Name
LFE 0
Reset
0: Do not use LFE channel 1: Generate LFE channel
Function
110/149
STV82x7
Register List
Bit Name
Reset
00: OFF 01: Low 10: Mid 11: High Forced to 0 000: Mono 001: L/R stereo 010: L/R/S 011: L/R/Ls/Rs 100: L/R/C 101: L/R/C/S 110: L/R/C/Ls/Rs 111: Lt/Rt (Passive matrix) 0: OmniSurround OFF 1: OmniSurround ON
Function
ST_VOICE[1:0]
00
FRONT_BYPASS OMNISRND_ INPUT_ MODE[3:0]
0
0000
OMNISURND_ON
0
ST_DYNAMIC_BASS
Address: C8h Type: R/W Bit 7 Bit 6 Bit 5 BASS_LEVEL[4:0]
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0 DYN_BASS_ ON
BASS_FREQ[1:0]
Bit Name
BASS_LEVEL[4:0]
Reset
00000 Set ST Dynamic Bass effect level: 00000: +0d B 00001: +0.5 dB ... 11101: +14.5 dB 11110: +15 dB 11111: +15.5 dB 00: 100 Hz Cut-Off frequency 01: 150 Hz Cut-Off frequency 10: 200 Hz Cut-Off frequency 11: Reserved 0: ST Dynamic Bass OFF 1: ST Dynamic Bass ON
Function
BASS_FREQ[1:0]
00
DYN_BASS_ON
0
111/149
Register List
STV82x7
12.16 5-Band Equalizer / Bass-Treble for Loudspeakers
LS_EQ_BT_CTRL
Address: C9h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 LS_EQ_BT_ SW Bit 0 LS_EQ_ON
Loudspeakers Equalizer Control Register
Bit Name
Bits[7:2] LS_EQ_BT_SW
Reset
000000 0 Reserved.
Function
5-Band Equalizer or Bass-Teble selection 0: 5-Band Equalizer is selected for Loudspeakers. 1: Bass-Treble is selected for Loudspeakers.
LS_EQ_ON
1
5-Band Equalizer/Bass-Treble for loudspeakers Enable 0: 5-Band Equalizer/Bass-Teble is disabled 1: 5-Band Equalizer/Bass-Teble is enabled (Default)
EQ_BANDX_GAIN
Address: CAh to CEh Type: R/W Bit 7 Bit 6 Bit 5
Loudspeakers Equalizer Gain Register for BandX
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
EQ_BANDX
Bit Name
EQ_BANDX[7:0]
Reset
0000 0000
Function
BandX gain adjustment within a range from -12 dB to +12 dB in steps of 0.25 dB. Band1: 100 Hz, Band2: 330 Hz, Band3: 1 KHz, Band4: 3.3 KHz, Band5: 10 KHz, see Table 30.
Table 30: Loudspeakers Equalizer/Bass-Treble Gain Values (and Headphone Bass-Treble Gain Values) Value
00110000 00101111 00101110 ................ 00000000 (Default) ................ 10101110
Gain G (dB)
+12 +11.75 +11.50 ..... 0 ..... -11.50
112/149
STV82x7
Register List
Table 30: Loudspeakers Equalizer/Bass-Treble Gain Values (and Headphone Bass-Treble Gain Values) Value
10101111 10110000
Gain G (dB)
-11.75 -12
LS_BASS_GAIN
Address: CFh Type: R/W Bit 7 Bit 6 Bit 5
Loudspeakers Bass Gain Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_BASS[7:0]
Bit Name
LS_BASS[7:0]
Reset
0000 0000
Function
Bass gain adjustment within a range from -12 dB to +12 dB in steps of 0.25 dB.
LS_TREBLE_GAIN
Address: D0h Type: R/W Bit 7 Bit 6 Bit 5
Loudspeakers Treble Gain Register
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_TREBLE
Bit Name
LS_TREBLE[7:0]
Reset
0000 0000
Function
Treble gain adjustment within a range from -12 dB to +12 dB in steps of 0.25 dB.
12.17 Headphone Bass-Treble
HP_BT_CONTROL
Address: D1h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 0 Bit 0 HP_BT_ON
Headphone Bass-Treble Control Register
Bit Name
Bits [7:1]
Reset
0000000 Reserved.
Function
113/149
Register List
STV82x7
Bit Name
HP_EQ_ON 1
Reset
Bass-Treble for headphone Enable 0: Bass-Teble is disabled 1: Bass-Teble is enabled (Default)
Function
HP_BASS_GAIN
Address: D2h Type: R/W Bit 7 Bit 6 Bit 5
Headphone Bass Gain
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
HP_BASS_GAIN[7:0]
Bit Name
HP_BASS_ GAIN[7:0]
Reset
Function
00000000 Gain Tuning of Headphone Bass Frequency Gain may be programmed within a range between +12 dB and -12 dB in steps of 0.25 dB. Programmable values are listed in Table 30.
HP_TREBLE_GAIN
Address: D3h Type: R/W Bit 7 Bit 6 Bit 5
Headphone Treble Gain
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
HP_TREBLE_GAIN[4:0]
Bit Name
HP_TREBLE_ GAIN[7:0]
Reset
Function
00000000 Gain Tuning of Headphone Treble Frequency Gain may be programmed within a range between +12 dB and -12 dB in steps of 0.25 dB. Programmable values are listed in Table 30.
OUTPUT_BASS_MNGT
Address: D4h Type: R/W Bit 7 BASS_ MANAGE_ON Bit 6 0 Bit 5 SUB_ACTIVE
Register Description
Bit 4 GAIN_ SWITCH
Bit 3 0
Bit 2
Bit 1 OCFG_NUM[2:0]
Bit 0
114/149
STV82x7
Register List
Bit Name
BASS_MANAGE_ON Bit 6 SUB_ACTIVE GAIN_ SWITCH OCFG_NUM
Reset
1 0 0 0 000 0: BassManagement disables 1: BassManagement enabled Reserved.
Function
0: Subwoofer output is disabled (only in config 2,3,4) 1: Subwoofer output is active 0: Level adjustment ON 1: Level adjustment OFF 000: Bass Management Configuration 0 (refer to Figure 13) 001: Bass Management Configuration 1 (refer to Figure 14) 010: Bass Management Configuration 2 (refer to Figure 15) 011: Bass Management Configuration 3 (refer to Figure 16) 100: Bass Management Configuration 4 (refer to Figure 17)
Bit 3
0
Reserved.
LS_LOUDNESS
Address: D5h Type: R/W Bit 7 0 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2 LS_LOUD_GAIN_HR[2:0]
Bit 1
Bit 0 LS_ LOUD_ON
LS_LOUD_THRESHOLD[2:0]
Bit Name
Bit 7 LS_LOUD_ THRESHOLD[2:0]
Reset
0 000 Reserved.
Function
Define the volume threshold level since which loudness effect is applied : 000: 0dB 001: -6dB 010: -12dB 011: -18dB 100: -24dB 101: -32dB 110: -36dB 111: -42dB
LS_LOUD_GAIN_ HR[2:0]
010
Define the amount of Treble added by loudness effect: 000: 0dB 001: 3dB 010: 6dB 011: 9dB 100: 12dB 101: 15dB 110: 18dB
LS_LOUD_ON
0
0: Loudness is not active on LS output 1: Loudness is active on LS output
115/149
Register List HP_LOUDNESS
Address: D6h Type: R/W Bit 7 0 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 HP_LOUD_GAIN_HR[2:0] Bit 1
STV82x7 Register Description
Bit 0 HP_ LOUD_ON
HP_LOUD_THRESHOLD[2:0]
Bit Name
Bit 7 HP_LOUD_ THRESHOLD[2:0]
Reset
0 000 Reserved.
Function
Define the volume threshold level since which loudness effect is applied : 000: 0dB 001: -6dB 010: -12dB 011: -18dB 100: -24dB 101: -32dB 110: -36dB 111: -42dB
HP_LOUD_GAIN_ HR[2:0]
010
Define the amount of Treble added by loudness effect: 000: 0dB 001: 3dB 010: 6dB 011: 9dB 100: 12dB 101: 15dB 110: 18dB
HP_LOUD_ON
0
0: Loudness is not active on HP output 1: Loudness is active on HP output
12.18 Volume
VOLUME_MODES
Address: D7h Type: R/W Bit 7 Bit 6 Bit 5 0 Bit 4 0 Bit 3 SCART_ VOLUME_ MODE Bit 2 SRND_ VOLUME_ MODE Bit 1 HP_ VOLUME_ MODE Bit 0 LS_ VOLUME_ MODE
Set the Volume Modes
ANTICLIP_HP ANTICLIP_LS _VOL_CLAMP _VOL_CLAMP
Bit Name
ANTICLIP_HP_VOL _CLAMP
Reset
1
Function
The output level is clamped depending on the HP Bass-Treble value to avoid any possible signal clipping on HP output. 0: Volume clamp on HP output is not active 1: Volume clamp on HP output is active
116/149
STV82x7
Register List
Bit Name
ANTICLIP_LS_VOL _CLAMP
Reset
1
Function
The output level is clamped depending on the LS Equalizer or LS Bass-Treble value to avoid any possible signal clipping on LS output. 0: Volume clamp on LS output is not active 1: Volume clamp on LS output is active
Bits[5:4] SCART_VOLUME_ MODE
00 0
Reserved. Volume mode for SCART output: 0: Independant 1: Differential
SRND_VOLUME_ MODE
1
Volume mode for Headphone output: 0: Independant 1: Differential
HP_VOLUME_ MODE
1
Volume mode for Surround output: 0: Independant 1: Differential
LS_VOLUME_ MODE
1
Volume mode for LS output: 0: Independant 1: Differential
LS_L_VOLUME_MSB
Address: D8h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_L_VOLUME_MSB[7:0]
Bit Name
LS_L_VOLUME_ MSB[7:0]
Reset
1001 1000
Function
LS 10 bits volume Left channel 8 MSB in independent mode or LS 10 bits volume Left and Right channels 8 MSB in differential mode. See Figure 19: Volume Control on page 36 for range values.
LS_L_VOLUME_LSB
Address: D9h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
LS_L_VOLUME_LSB[1:0]
Bit Name
Bits[7:2]
Reset
000000 Reserved.
Function
117/149
Register List
STV82x7
Bit Name
LS_L_VOLUME_ LSB[1:0]
Reset
00
Function
LS 10 bits volume Left channel 2 LSB in independent mode or LS 10 bits volume Left and Right channels 2 LSB in differential mode. See Figure 19: Volume Control on page 36 for range values.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_L_VOLUME_MSB x 0.5 + Decimal value of LS_L_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
LS_R_VOLUME_MSB
Address: DAh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_R_VOLUME_MSB[7:0]
Bit Name
LS_R_VOLUME_ MSB[7:0]
Reset
Function
0000000 LS 10 bits volume Right channel 8 MSB in independent mode or LS 10 bits Left and Right balance 0 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
LS_R_VOLUME_LSB
Address: DBh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
LS_R_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] LS_R_VOLUME_ LSB[1:0]
Reset
000000 Reserved. 00
Function
LS 10 bits volume Right channel 2 LSB in independent mode or LS 10 bits Left and Right balance 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
LS_C_VOLUME_MSB
Address: DCh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_C_VOLUME_MSB[7:0]
118/149
STV82x7
Register List
Bit Name
LS_C_VOLUME_ MSB[7:0]
Reset
1001 1000 LS 10 bits volume Center channel 8 MSB
Function
See Figure 19: Volume Control on page 36 for range values.
LS_C_VOLUME_LSB
Address: DDh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
LS_C_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] LS_C_VOLUME_ LSB[1:0]
Reset
000000 Reserved. 00 LS 10 bits volume Center channel 2 LSB
Function
See Figure 19: Volume Control on page 36 for range values.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_C_VOLUME_MSB x 0.5 + Decimal value of LS_C_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
LS_SUB_VOLUME_MSB
Address: DEh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_SUB_VOLUME_MSB[7:0]
Bit Name
LS_SUB_ VOLUME_MSB[7:0]
Reset
1001 1000
Function
LS 10 bits volume Subwoofer channel 8 MSB See Figure 19: Volume Control on page 36 for range values.
119/149
Register List LS_SUB_VOLUME_LSB
Address: DFh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1
STV82x7 Register Description
Bit 0
LS_SUB_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] LS_SUB_ VOLUME_LSB[1:0]
Reset
000000 Reserved. 00
Function
LS 10 bits volume Subwoofer channel 2 LSB See Figure 19: Volume Control on page 36 for range values.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_SUB_VOLUME_MSB x 0.5 + Decimal value of LS_SUB_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
LS_SL_VOLUME_MSB
Address: E0h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_SL_VOLUME_MSB[7:0]
Bit Name
LS_SL_VOLUME_ MSB[7:0]
Reset
1001 1000
Function
LS 10 bits volume Left surround channel 8 MSB in independent mode or LS 10 bits Left and Right surround volume 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
120/149
STV82x7 LS_SL_VOLUME_LSB
Address: E1h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1
Register List Register Description
Bit 0
LS_LS_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] LS_LS_VOLUME_ LSB[1:0]
Reset
000000 Reserved. 00
Function
LS 10 bits volume Left surround channel 2 LSB in independent mode or LS 10 bits Left and Right surround volume 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_SL_VOLUME_MSB x 0.5 + Decimal value of LS_SL_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
LS_SR_VOLUME_MSB
Address: E2h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_SR_VOLUME_MSB[7:0]
Bit Name
LS_SR_VOLUME_ MSB[7:0]
Reset
Function
00000000 LS 10 bits volume Right channel 8 MSB in independent mode or LS 10 bits surround Left and Right balance 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
LS_SR_VOLUME_LSB
Address: E3h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
LS_SR_VOLUME_LSB[1:0]
Bit Name
Bits[7:2]
Reset
000000 Reserved.
Function
121/149
Register List
STV82x7
Bit Name
LS_SR_VOLUME_ LSB[1:0]
Reset
00
Function
LS 10 bits volume Right channel 8 MSB in independent mode or LS 10 bits surround Left and Right balance 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_SR_VOLUME_MSB x 0.5 + Decimal value of LS_SR_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
LS_MASTER_VOLUME_MSB
Address: E4h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LS_MASTER_VOLUME_MSB[7:0]
Bit Name
Reset
Function
LS_MASTER_ 1110100 LS 10 bits volume Master channel 8 MSB VOLUME_MSB[7:0] 0 See Figure 19: Volume Control on page 36 for range values.
LS_MASTER_VOLUME_LSB
Address: E5h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
LS_MASTER_VOLUME _LSB[1:0]
Bit Name
Bits[7:2] LS_MASTER_ VOLUME_LSB[1:0]
Reset
000000 Reserved. 00 LS 10 bits volume Master channel 2 LSB
Function
See Figure 19: Volume Control on page 36 for range values.
The volume value is defined by the following formula: Vol (dB) = Decimal value of LS_MASTER_VOLUME_MSB x 0.5 + Decimal value of LS_MASTER_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
122/149
STV82x7 HP_L_VOLUME_MSB
Address: E6h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1
Register List Register Description
Bit 0
HP_L_VOLUME_MSB[7:0]
Bit Name
HP_L_VOLUME_ MSB[7:0]
Reset
1001 1000
Function
HP 10 bits volume Left channel 8 MSB in independent mode or HP 10 bits Left and Right volume 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
HP_L_VOLUME_LSB
Address: E7h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
HP_L_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] HP_L_VOLUME_ LSB[1:0]
Reset
000000 Reserved. 00
Function
HP 10 bits volume Left channel 2 LSB in independent mode or HP 10 bits Left and Right volume 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
The volume value is defined by the following formula: Vol (dB) = Decimal value of HP_L_VOLUME_MSB x 0.5 + Decimal value of HP_L_VOLUME_LSB x 0.125 - 116 dB (each step is 0.125 dB).
HP_R_VOLUME_MSB
Address: E8h Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
HP_R_VOLUME_MSB[7:0]
Bit Name
HP_R_VOLUME_ MSB[7:0]
Reset
Function
0000000 HP 10 bits volume Right channel 8 MSB in independent mode or HP 10 bits Left and Right balance 0 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
123/149
Register List HP_R_VOLUME_LSB
Address: E9h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1
STV82x7 Register Description
Bit 0
HP_R_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] HP_R_VOLUME_ LSB[1:0]
Reset
000000 Reserved. 00
Function
HP 10 bits volume Right channel 2 LSB in independent mode or HP 10 bits Left and Right balance 2LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
SCART_L_VOLUME_MSB
Address: EAh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SCART_L_VOLUME_MSB[7:0]
Bit Name
Reset
Function
SCART_L_ 1101110 1 SCART 10 bits volume Left channel 8 MSB in independent mode or SCART10 bits Left and Right VOLUME_MSB[7:0] volume 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
124/149
STV82x7 SCART_L_VOLUME_LSB
Address: EBh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1
Register List Register Description
Bit 0
SCART_L_VOLUME_LSB[1:0]
Bit Name
Bits[7:2] SCART_L_ VOLUME_LSB[1:0]
Reset
000000 Reserved. 00
Function
SCART 10 bits volume Left channel 2 LSB in independent mode or SCART10 bits Left and Right volume 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
The volume value is defined by the following formula: Vol (dB) = Decimal value of SCART_L_VOLUME_MSB x 0.5 + Decimal value of SCART_L_VOLUME_LSB x 0.125 116 dB (each step is 0.125 dB).
SCART_R_VOLUME_MSB
Address: ECh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SCART_R_VOLUME_MSB[7:0]
Bit Name
Reset
Function
SCART_R_ 11011101 SCART 10 bits volume Right channel 8 MSB in independent mode or SCART10 bits Left and Right VOLUME_MSB[7:0] balance 8 MSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
SCART_R_VOLUME_LSB
Address: EDh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Register Description
Bit 4 0
Bit 3 0
Bit 2 0
Bit 1
Bit 0
SCART_R_VOLUME_LSB[1:0]
Bit Name
Bits[7:2]
Reset
000000 Reserved.
Function
125/149
Register List
STV82x7
Bit Name
SCART_R_ VOLUME_LSB[1:0]
Reset
00
Function
SCART 10 bits volume Right channel 2 LSB in independent mode or SCART10 bits Left and Right balance 2 LSB in differential mode. See Figure 19: Volume Control on page 36 or Figure 20: Differential Balance on page 37.
12.19 Beeper
BEEPER_ON
Address: EEh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 0 Bit 0 BEEPER_ON
Beeper Activation Register
Bit Name
Bits [7:1] BEEPER_ON
Reset
0000000 Reserved. 0 Beeper Enable 0: Beeper muted (Default.) 1: Beeper enabled.
Function
BEEPER_MODE
Address: EFh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0
Beeper Control Register
Bit 4
Bit 3
Bit 2 BEEPER_ PULSE
Bit 1
Bit 0
BEEPER_DURATION
BEEPER_PATH
Bit Name
Bits [7:5] BEEPER_ DURATION [4:3] BEEPER_PULSE
Reset
000 00 0 Reserved.
Function
Define beeper duration when set to pulse mode. Set beeper pulse mode 0: Pulse mode selected. 1: Continuous mode selected.
BEEPER_PATH [1:0] 11
Set the output channels when beeper is active 00: no channels. 01: Loudspeakers only. 10: Headphone only. 11: Loudspeakers and Headphone selected.
126/149
STV82x7 BEEPER_FREQ_VOL
Address: F0h Type: R/W Bit 7 Bit 6 BEEP_FREQ[2:0] Bit 5 Bit 4 Bit 3 Bit 2 BEEP_VOL[4:0] Bit 1
Register List Beeper Frequency and Volume Settings Register
Bit 0
Bit Name
BEEP_FREQ[2:0]
Reset
011
Function
Defines the frequency of the beeper tone from 62.5 Hz to 8 kHz in octaves 000: 62.5 Hz 001: 125 Hz 010: 250 Hz 011: 500 Hz (Default) 100: 1 kHz 101: 2 kHz 110: 4 kHz 111: 8 kHz
BEEP_VOL[4:0]
10000
Defines the Beeper volume from 0 to -93 dB in steps of 3 dB. 11111: 0 dB (1 VRMS) 11110: -3 dB 11101: -6 dB ... 10000: -48 dB (Default) ... 00011: -84 dB 00010: -87 dB 00001: -90 dB 00000: -93 dB
12.20 Mute
MUTE_DIGITAL
Address: F1h Type: R/W Bit 7 AUTOSTD_ MUTE_ON Bit 6 0 Bit 5 0 Bit 4 SCART_ D_MUTE Bit 3 SRND_HP_D_ MUTE Bit 2 SUB_ D_MUTE Bit 1 C_ D_MUTE Bit 0 LS_ D_MUTE
Register Description
Bit Name
AUTOSTD_MUTE_ON Bit s[6:5] 1
Reset
Function
0: autostandard can not mute outputs 1: autostandard can mute outputs when no signal is detected
00 1 SCART left/right digital soft mute 0: signal un-muted 1: signal muted 1 LS Surround/HP left/right digital soft mute 0: signal un-muted 1: signal muted 1 LS Subwoofer digital soft mute 0: signal un-muted 1: signal muted
SCART_D_MUTE
SRND_HP_D_MUTE
SUB_D_MUTE
127/149
Register List
STV82x7
Bit Name
1 C_D_MUTE
Reset
LS Center digital soft mute 0: signal un-muted 1: signal muted 1 LS left/right digital soft mute 0: signal un-muted 1: signal muted
Function
LS_D_MUTE
12.21 S/PDIF
S/PDIF_OUT_CONFIG
Address: F2h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 S/PDIF_OUT_ MUTE Bit 1 Bit 0
S/PDIF Output Configuration Register
S/PDIF_OUT_SELECT
Bit Name
Bits [7:3] S/PDIF_OUT_ MUTE
Reset
00000 1 Reserved. S/PDIF Output Mute: 0: S/PDIF Output unmuted. 1: S/PDIF Output muted. 00 S/PDIF Output channel selection: 00: output SCART signal 01: output LS L-R signal 10: output C/SUB signal 11: ouptut Sur/HP signal
Function
S/PDIF_OUT_ SELECT[1:0]
12.22 Headphone Configuration
HEADPHONE_CONFIG
Address: F3h Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 HP_FORCE Bit 2 HP_LS_ MUTE Bit 1 HP_DET_ ACTIVE Bit 0 HP_ DETECTED
Headphone Configuration Register
Bit Name
Bits [7:4]
Reset
0000 Reserved.
Function
128/149
STV82x7
Register List
Bit Name
HP_FORCE HP_LS_MUTE 0 0 1 HP_DET_ACTIVE HP_DETECTED 0
Reset
Function
1: force output of the HP signal (bypass surround) 0: when HP is detected and active, LS are not muted 1: when HP is detected and active, LS are muted 0: HP detection is not active 1: HP detection is active, when HP detected, Surround signal is bypassed and HP signal is output on HP 1: When a signal is detected on HP_DET pin (STATUS)
12.23 DAC Control
DAC_CONTROL
Address: F4h Type: R/W Bit 7 0 Bit 6 0 Bit 5 S/PDIF_MUX Bit 4 DAC_SCART_ MUTE Bit 3 DAC_SHP_ MUTE Bit 2 DAC_CSUB_ MUTE Bit 1 DAC_LSLR_ MUTE Bit 0 POWER_UP
DAC Control Register
Bit Name
Bits [7:6]
Reset
00 0 Reserved.
Function
redirect external or internal S/PDIF source to S/PDIF output : 0: internal S/PDIF 1: external S/PDIF
S/PDIF_MUX
1 DAC_SCART_MUTE
SCART left/right analog soft mute 0: signal un-muted 1: signal muted
1 DAC_SHP_MUTE
Surround/HP left/right analog soft mute 0: signal un-muted 1: signal muted
1 DAC_CSUB_MUTE
Center/Subwoofer analog soft mute 0: signal un-muted 1: signal muted
1 DAC_LSLR_MUTE
LS left/right analog soft mute 0: signal un-muted 1: signal muted
POWER_UP
1
0: DACs Power OFF 1: Power ON
129/149
Register List SPDIF_CHANNEL_STATUS
Address: F9h Type: R/W Bit 7 Bit 6 Bit 5 Bit 4 EMPHASIS Bit 3 Bit 2 COPYRIGHT Bit 1 NON_AUDIO
STV82x7 Register Description
Bit 0 PRO_CON
CHANNEL_STATUS
Bit Name
Reset
Channel status mode:
Function
CHANNEL_STATUS[7:6]
00
00: Mode zero other values: reserved Emphasis: according to IEC60958 specification Copyright:
EMPHASIS[5:3]
000
COPYRIGHT
0
0: Asserted 1: Not asserted Non-audio:
NON_AUDIO
0
0: Linear PCM 1: Non-audio signal Select Professional or Consumer modes:
PRO_CON
0
0: Consumer 1: Professional
12.24 AutoStandard Coefficients Settings
AUTOSTD_COEFF_CTRL
Address: FBh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 Bit 0
Register Description
AUTOSTD_COEFF_ CTRL[1:0]
Bit Name
Bits [7:2]
Reset
000000 Reserved. Control the Demod filter coeff table settings 01: init Coeffs to ROM values 10: Update Coeffs with I2C value
Function
AUTOSTD_COEFF 01 _CTRL[1:0]
130/149
STV82x7 AUTOSTD_COEFF_INDEX_MSB
Address: FCh Type: R/W Bit 7 0 Bit 6 0 Bit 5 0 Bit 4 0 Bit 3 0 Bit 2 0 Bit 1 0
Register List Register Description
Bit 0 AUTOSTD_ COEFF_ INDEX_MSB
Bit Name
Bits [7:2] AUTOSTD_COEFF _INDEX_MSB
Reset
0000000 Reserved. 0 FIR Coefficients table index (MSB)
Function
AUTOSTD_COEFF_INDEX_LSB
Address: FDh Type: R/W Bit 7 Bit 6 Bit 5 Bit 4
Register Description
Bit 3
Bit 2
Bit 1
Bit 0
AUTOSTD_COEFF_INDEX_LSB[7:0]
Bit Name
AUTOSTD_COEFF _INDEX_LSB[7:0]
Reset
0000 0000 FIR Coefficients table index (LSB)
Function
AUTOSTD_COEFF_VALUE
Address: FEh Type: R/W Bit 7 Bit 6 Bit 5
Register Description
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
AUTOSTD_COEFF_VALUE[7:0]
Bit Name
AUTOSTD_COEFF _VALUE[7:0]
Reset
0000 0000 Reserved
Function
131/149
Electrical Characteristics
STV82x7
13
Electrical Characteristics
Test Conditions: TOPER = 25 C, VCC_H = 8 V, VXX_18 = 1.8V, VXX_33 = 3.3V, Crystal at 27MHz, default register values for synthesizer, otherwise specified.
13.1
Absolute Maximum Ratings
Parameter
Analog and Digital 1.8 V Supply Voltage (VCC18_CLK1, VCC18_CLK2, VCC18_IF, VDD18, VDD18_CONV, VDD18_ADC) Analog and Digital 3.3 V Supply Voltage (VCC33_SC, VCC33_LS, VDD33_IO1, VDD33_IO2, VDD33_CONV, VCC_NISO) Analog Supply High Voltage (VCC_H) Capacitor 100 pF discharged via 1.5 k serial resistor (Human Body Model) Operating Ambient Temperature Storage Temperature 4.0 8.8 4 0, +70 -55 to +150 V V kV C C 2.5 V
Symbol
VXX_18
Value
Units
VXX_33 HVCC VESD TOPER TSTG
13.2
Thermal Data
Parameter
Junction-to-Ambient Thermal Resistance
Symbol
RthJA
Value
42
Units
C/W
13.3
Power Supply Data
Parameter
Analog and Digital 1.8 V Supply Voltage (VCC18_CLK1, VCC18_CLK2, VCC18_IF, VDD18, VDD18_CONV, VDD18_ADC) Analog and Digital 3.3 V Supply Voltage (VCC33_SC, VCC33_LS, VDD33_IO1, VDD33_IO2, VDD33_CONV, VCC_NISO) Analog Supply High Voltage (VCC_H) Current Consumption for Digital 1.8 V Supply (VCC18_CLK2, VDD18, VDD18_CONV, VDD18_ADC) Current Consumption for Digital 3.3 V Supply ( VDD33_IO1, VDD33_IO2) Current Consumption for Analog 1.8 V Supply (VCC18_CLK1, VCC18_IF) Current Consumption for Analog 3.3 V Supply (VCC33_SC, VCC33_LS, VDD33_CONV, VCC_NISO) Current Consumption for Analog Supply High Voltage (8 V) Total Power Dissipation 3.13 7.6 3.30 8.0 210 10 50 65 4 750 3.47 8.4 V V mA mA mA mA mA mW 1.70 1.80 1.90 V
Symbol
VXX_18
Min.
Typ.
Max.
Units
VXX_33 HVCC IVDD18 IVDD33 IVCC18 IVCC33 IVCC_H PDTOT
132/149
STV82x7
Electrical Characteristics
13.4
Crystal Oscillator
Parameter
Crystal Series Resonance Frequency (at C21 = C22 = 27 pF load capacitor) Frequency Tolerance at 25 C Frequency Stability versus Temperature within a range from 0 to 70 C Motional Capacitor Serial Resistance Shunt Capacitance -30 -30
Symbol
fP DF/FP DF/FT C1 RS CS
Min.
Typ.
27
Max.
Units
MHz
+30 +30 15 30 7
ppm ppm fF pF
13.5
Analog Sound IF Signal
Parameter
SIF Frequency Flatness SIF Input Resistance SIF Input DC Level SIF Input Capacitance
Symbol
BANDSIF RINSIF DCINSIF CINSIF FM Carrier
Test Conditions
AGC_ERR at 0, frequency range from 4 to 7MHz
Min.
Typ.
0.6
Max.
3 85
Units
dB k V pF
60
72 0.9 3
VSIFFM
SIF Input Sensitivity
SNR 40dB RMS unweighted, 20Hz-15kHz, Standard B/G 27 kHz FM Deviation,1kHz FM50k (Standard) FM200k
350
VPP
15 Signal Lost, DK mode, FM prescale at 0
50 200 350 500 1
115 320 kHz 560 700 5 120 kHz kHz
DEVFM
FM Maximum Deviation FM350k FM500k Standard (FM50k)
DFSIFFM
SIF Carrier Accuracy for FM
Shifted Standard (FM50k with DCO compensation) NICAM mute, FAR_MODE is active, standard BG, 100mVPP level for FM carrier
RFM/QPSK AM Carrier
Carrier Ratio FM/QPSK for NICAM System
40
dB
VSIFAM
SIF Input Sensitivity
Unmodulated, -3 dB at output amplitude AGC_ERR at 21d Standard L, 54% AM Depth, 1 kHz Unmodulated, THD at 1%, 54% AM Depth, AGC_ERR at 0 THD at 1%
19
mVPP
VMAX_SIFAM SIF Maximum Input Level DEVAM Modulation Depth for AM
1.3 0 100
VPP %
133/149
Electrical Characteristics
STV82x7
Symbol
DFSIFAM RAM/QPSK AGC AGCstep AGCdyn IF AGC Step
Parameter
SIF Carrier Accuracy for AM AM/QPSK Carrier Ratio for NICAM System
Test Conditions
Min.
Typ.
1
Max.
5 36
Units
kHz dB
NICAM Mute, 100mVPP AM carrier
1.4 Valid from step 21 to step 31 29
1.5 30
1.6 31
dB dB
Relative maximum gain to step 0
13.6
SIF to IS Output Path Characteristics
Test Conditions: SIF amplitude = 100mVpp, otherwise specified, IS output.
Symbol
FM Demodulation BANDFM SNRFM THDFM SEPFM
Parameter
Test Conditions
Min.
Typ.
Max.
Units
Frequency Response Signal to Noise Total Harmonic Distortion Stereo Channel Separation
20Hz - 15kHz RMS unweighted, 20Hz-15kHz, Standard B/G 27 kHz FM Deviation,1kHz Standard B/G stereo A2, 27 kHz FM deviation, 1 kHz 66
0.7
dB dB
0.05 48
% dB
NICAM Demodulation BANDNIC SNRNIC THDNIC Frequency Response Signal to Noise Total Harmonic Distortion 20Hz - 15kHz 200Hz - 60dBFS, trap filter 200 Hz RMS unweighted, 20Hz-15kHz, Standard B/G mono NICAM,1 kHz 74 0.04 0.2 dB dB %
AM Demodulation BANDAM SNRAM THDAM Frequency Response Signal to Noise Total Harmonic Distortion 20 Hz - 15 kHz RMS unweighted 2 0Hz-15 kHz, Standard L, 54% AM Depth, 1 kHz AGC: 13d 60 0.4 0.5 dB dB %
13.7
SCART to SCART Analog Path Characteristics
Test Conditions: RloadMAX = 10k, CloadMAX = 330pF, MONO_IN voltage = 0.5 VRMS
Symbol
Parameter
Test Conditions
Min.
Typ.
Max.
Units
Analog-to-Analog STEREO and MONO RINSCART ROUTSCART SCART Input Resistance Output Resistance for SCARTs 29 34 40 1.57 3.64 39 75 k V V
VDCINSCART SCART Input DC Level VDCOUTSCART SCART Output DC Level
134/149
STV82x7
Electrical Characteristics
Symbol
Parameter
Clipping input level from SCART input
Test Conditions
Min.
2.0
Typ.
Max.
Units
VRMS VRMS
CLIPSCART
Clipping SCART
At 1 kHz 1% THD Clipping input level from MONO_IN input THD from SCART input 1 VRMS, at 1 KHz 0.5 0.02 0.02 0.05 0.05
% %
THDSCART
THD SCART
THD from MONO_IN input SCART input
0.25 VRMS, at 1 KHz 1 VRMS, 20 Hz to 20 kHz Bandwidth, RMS unweighted 0.25 VRMS, 20 Hz to 20 kHz Bandwidth, RMS unweighted 20 Hz to 20 kHz 20 Hz to 20 kHz 1 VRMS @ 1 kHz on ref signal, the other one grounded -0.5 11.5 80
82
dB
SNRSCART
Signal to Noise Ratio MONO_IN input Frequency Flatness SCART input MONO_IN input
76 0.5 12 90 12.5
dB dB dB dB
BANDSCART
XTALKL/R XTALKIN
Left/Right Crosstalk
Audio Crosstalk from Input Channel n to 1 VRMS @ 1 kHz on ref signal, all Input Channel m other inputs grounded Audio Crosstalk from Output Channel n to Output Channel m 1 VRMS @ 1 kHz on reference output, signal on a single input, all other inputs grounded
80
90
dB
XTALKOUT
80
90
dB
13.8
SCART and MONO IN to IS Path Characteristics
Test Conditions: Sampling Frequency = 32KHz, Maximum MONO_IN voltage = 0.5 VRMS.
Symbol
Parameter
THD from SCART input
Test Conditions
VIN = 2 VRMS at 1 KHz
Min.
Typ.
0.006 0.006
Max.
0.05 0.05
Units
% %
THDADC
THD ADC THD from V = 0.5 VRMS at 1 KHz MONO_IN input IN
SNRADC BANDADC XTALKADC
Signal to Noise Ratio Frequency Flatness Left Right Crosstalk
20 to 15 kHz Bandwidth, RMS unweighted VIN = 200 mVRMS SCART input 20 Hz to 15 kHz at 1 KHz, VIN = 1 VRMS
62 0.5 95
dB dB dB
13.9
I2S to LS/HP/SUB/C Path Characteristics
Test Conditions: Sampling Frequency = 32KHz, LLOAD = 100 H, CLOAD = 33nF, RLOAD = 30K.
Symbol
ROUTDAC VDCOUTDAC
Parameter
Output Resistance for Main Outputs MAIN Output DC Level
Test Conditions
LS_L, LS_R, LS_SUB, LS_C, HP_LSS_R and HP_LSS_L pins
Min.
Typ.
90 1.54
Max.
140
Units
V
135/149
Electrical Characteristics
STV82x7
Symbol
THDDAC SNRDAC
Parameter
Total Harmonic Distortion Signal to Noise Ratio
Test Conditions
90% Full-scale Range at 1 kHz 20 to 15 kHz Bandwidth, RMS unweighted, at -20dB full range 100% Full-scale Range at 1 kHz at 1 KHz, -20dBFS
Min.
Typ.
Max.
0.06
Units
% dB
75 900 87
VOUTAMPDAC MAIN Output Amplitude XTALKDAC Left Right Crosstalk
mVRMS dB
13.10 IS to SCART Path Characteristics
Test Conditions: Sampling Frequency = 32KHz, CLOAD = 33nF on DAC SCART pins, DAC SCART prescale at -5.5dB.
Symbol
THDDACSCART SNRDACSCART VODACSCART
Parameter
Total Harmonic Distortion Signal to Noise Ratio MAIN Output Amplitude
Test Conditions
90% Full-scale Range at 1 kHz 20 Hz to 15 kHz Bandwidth unweighted, -20dB Full Range 100% Full-scale Range at 1 kHz at 1 KHz, -20 dBFS
Min.
Typ.
0.08
Max.
0.12
Units
% dB
73 2 80
VRMS dB
XTALKDACSCART Left Right Crosstalk
13.11 MUTE Characteristics
Symbol
MUTEDAC MUTESCART
Parameter
DAC Mute analog SCART Mute
Test Conditions
I2S to DAC at 1 kHz 2 VRMS @ 1 kHz on ref signal, all other inputs grounded
Min.
90 81
Typ.
Max.
Units
dB dB
13.12 Digital I/Os Characteristics
Symbol
V V
IL
Parameter
Low Level Input Voltage High Level Input Voltage Input Current CLK_SEL Low Level Input Voltage CLK_SEL High Level Input Voltage Low Level Output Voltage High Level Output Voltage
Test Conditions
except SDA, SCL and CLK_SEL, 3.3V power supply except SDA, SCL and CLK_SEL, 3.3V power supply
Min.
Typ.
Max.
0.5
Units
V V
IH
2.0 1
IIN VILCLK_SEL VIHCLK_SEL V V
A V
1.8V power supply
0.3
1.8V power supply S/PDIF_OUT, IRQ, BUS_EXP S/PDIF_OUT, IRQ, BUS_EXP
1.2 0.3 3.0
V V V
OL
OH
136/149
STV82x7
Electrical Characteristics
13.13 IC Bus Characteristics
Symbol
SCL VIL VIH IIL fSCL tR tF CI SDA VIL VIH IIL tR tF VOL tF CL CI IC Timing tLOW tHIGH tSU,DAT tHD,DAT tSU,STO tBUF tHD,STA tSU,STA Clock Low period Clock High period Data Set-up Time Data Hold Time Set-up Time from Clock High to Stop Start Set-up Time following a Stop Start Hold Time Start Set-up Time following Clock Low to High Transition 1.3 0.6 100 0 0.6 1.3 0.6 0.6 900 s s ns ns s s s s Low Level Input Voltage High Level Input Voltage Input Leakage Current Input Rise Time Input Fall Time Low Level Output Voltage Output Fall Time Load Capacitance Input Capacitance VIN = 0 to 5.0 V 1 V to 2 V 2 V to 1 V IOL = 3 mA 2 V to 1 V -0.3 2.3 -10 1.5 5.5 10 300 300 0.4 250 400 10 V V A ns ns V ns pF pF Low Level Input Voltage High Level Input Voltage Input Leakage Current Clock Frequency Input Rise Time Input Fall Time Input Capacitance 1 V to 2 V 2 V to 1 V VIN = 0 to 5.0 V -0.3 2.3 -10 1.5 5.5 10 400 300 300 10 V V A kHz ns ns pF
Parameter
Test Conditions
Min.
Typ
Max.
Unit
137/149
Electrical Characteristics
Figure 28: IC Bus Timing
STV82x7
SDA
tBUF tLOW tSU,DAT
SCL tHD,STA tR tHD,DAT tHIGH tF tSU,STO
SDA
tSU,STA
13.14 I2S Bus Interface
See timing for I2s on page 41.
Symbol
IS Input VI2S_IL VI2S_IH ZI2S II2S_Leak tI2S_Su tI2S_Ho fI2S_LR0 Input I2S Low Level Voltage Input I2S High Level Voltage Input I2S Impedance I2S Leakage Current See Figure 29 -1 30 2 5 1 0.8 V V pF A ns
Parameter
Test Conditions
Min.
Typ
Max.
Unit
I2S Input Setup Time before Rising Edge of Clock I2S Input Hold Time after Rising Edge of Clock I2S Left Right Strobe Input Frequency (I2S_DATA0 only) I2S Serial Clock Input Frequency (I2S_DATA0 only) I2S Left Right Strobe Input Frequency (I2S_DATA0,1 ,2) I2S Serial Clock Input Frequency (I2S_DATA0 ,1,2) I2S Serial Clock Input Ratio
See Figure 29
100
ns
deviation =+-250ppm
8
48
KHz
fI2S_SCL0
0.512
3.072
MHz
fI2S_LR
deviation =+-250ppm
32
48
KHz
fI2S_SCL RI2S_SCL
2.048 0.9
3.072 1.1
MHz
I2S Output (I2S_DATA0 only) VI2SOL VI2SOH fI2S_OLR Output I2S Low Level Voltage Output I S High Level voltage I2S Left Right Strobe Output Frequency
2
IOL = 2 mA IOH = 2 mA deviation =+-250ppm 2.4 8
0.4
V V
48
KHz
138/149
STV82x7
Electrical Characteristics
Symbol
fI2S_OSCl RI2S_SCL tI2S_Del
Parameter
I2S Serial Clock Output Frequency I2S Serial Clock Output Ratio I2S Output Delay After Falling Edge of Clock
Test Conditions
Min.
0.512 0.9
Typ
Max.
3.072 1.1 30
Unit
MHz
See Figure 29, Cl=30pF
ns
Figure 29: IS Input Bus Timing
I2S_SCLK tI2S_Su I2S_DATA tI2S_Su I2S_LR_CLK tI2S_Ho
139/149
Input/Output Groups
STV82x7
14
Input/Output Groups
Pin numbers apply to SDIP package only.
VCC18_IF
VCC_H
VCC18_IF
SIF_P73
50K 50K
SC1_OUTL SC1_OUTR SC2_OUTL SC2_OUTR SC3_OUTL SC3_OUTR
1 2 5 6 18 19
50K GND_PSUB GND_PSUB
VCC33_LS
VCC33_LS
LS_L SCR_FLT LS_C LS_L LS_R LS_SUB HP_LSS_L HP_LSS_R
25 26 27 28 29 30 31 32
150
MONO_IN 78
30K
VREFA
GND_PSUB
GND 33_LS
VCC18_IF
VCC_H
VCC18_IF
SIF_N
74
REF
SC1_IN_L SC1_IN_R SC2_IN_L SC2_IN_R SC3_IN_L SC3_IN_R SC4_IN_L SC4_IN_R
9 10 14 15 23 24 79 80
VREFA
7K5 22K5
GNDIF
GND_PSUB
140/149
STV82x7
Input/Output Groups
VCC33_LS
VCC33_LS
VB G (1.2V)
10K
VREFA 11
5K4
VB G
13
BAND-GAP=1.2V
16K8
GND33_LS
GND33_LS
VDD33_I01
VDD33_I01
VDD33_I01
HP_DET ADR_SEL RST_N CLK_TST_CTRL
35 36 43 48
S/PDIF_OUT 45
VSS
VSS
VDD33_I02
VDD33_I02
VDD33_I01
BUS_EXD IRQ
68 69
S/PDIF_IN
44
VSS
VSS
141/149
Input/Output Groups
STV82x7
VDD33_I02
VDD18
I2S_PCM_CLK I2S_LR_CLK I2S_DATA0 I2S_DATA1 I2S_DATA2
60 61 62 63 64
CLK_SEL
51
VSS
VSS
VCC18_CLK1
XTALIN_CLKXTP
52
SCL SDA
35 40
GND18_CLK1 VCC18_CLK1 500K
XTALOUT_CLKXTM
VSS
53
GND18_CLK1
142/149
STV82x7
Input/Output Groups
VDD33_I02
59
VCC18_CLK2 57 VCC18_CLK1 54 VDD33_I01 VDD18 46 38 42 50 66
VSS
37 41 47 49 58 67
GND18_CLK1 55
GND18_CLK2 56
GND_PSUB
21 70
143/149
Input/Output Groups
STV82x7
VDD18_CONV VDD33_CONV VCC_NISO VCC33_LS VCC33_SC VCC_H VDD18_ADC VCC18_IF
34 22 20 16 7 3 71 76
GND18_IF
77
GNDPW_IF
75
VSS18_ADC
72
GND_PSUB
70 21
GND33_LS
17
GND_H
4
GND33_SC
8
GND_SA
12
VSS18_CONV
33
144/149
STV82x7
Package Mechanical Data
15
Package Mechanical Data
Figure 30: 80-Pin Thin Plastic Quad Flat Package
D D1 A1
A A2
b
e E1 E
L1 L h
c
Table 31: Package Mechanical Dimensions mm Dim. Min.
A A1 A2 b C D D1 E E1 e K L L1 0 0.45 0.05 1.35 0.22 0.09 16.00 14.00 16.00 14.00 0.65 3.5 0.60 1.00 0.75 0.75 0 0.018 1.40 0.32
inches Max.
1.60 0.15 1.45 0.38 0.20 0.002 0.053 0.009 0.004 0.630 0.551 0.630 0.551 0.026 3.5 0.024 0.039 0.75 0.030 0.055 0.013
Typ.
Min.
Typ.
Max.
0.063 0.006 0.057 0.015 0.008
145/149
Revision History
STV82x7
16
Revision History
Date
April 2004 April 2004 Preliminary Datasheet - First Issue. Updates to Chapter 13: Electrical Characteristics on page 132. Added Figure 8: STV82x6/STV82x7 Compatible Application Electrical Diagram on page 18. Added Section 11.2: Start-up and Configuration Change Procedure on page 47. Update of Table 21: Demod Matrix on page 94. Changes to function descriptions in Section 12.18: Volume on page 116. Other minor corrections. Updates to Table 3: TQFP80 Pin Description on page 14, Section 13.5: Analog Sound IF Signal on page 133, Section 13.9: I2S to LS/HP/SUB/C Path Characteristics on page 135, Section 13.10: IS to SCART Path Characteristics on page 136 and Section 13.12: Digital I/Os Characteristics on page 136. Updates to Table 7: RESET Default Values on page 45, Table 12: Audio Processing for Loudspeakers, Headphone, SCART and S/PDIF outputs on page 27, Table 19: Volume Control on page 36, Table 27: Flow chart on page 47 and Section 12.1: IC Register Map on page 49. Added Register : SPDIF_CHANNEL_STATUS. Other minor corrctions and modifications. Added logos to page 1. Added notes to Figure 3, Figure 4 and Figure 5. Removed "Pro Logic OFF Switch" from Table 12, Table 13, Table 14 and Table 16. Other minor modifications and cosmetic changes. Added ST Voice logo to page 1. Modification to ST OmniSurround version in Table 1. Modifications to text in Section 4.1: Back-end Processing on page 24. Other minor modifications and cosmetic changes. Update of bits I2S_OUT_SELECT[1:0] of ADC_CTRL register (56h). Modified STSRND-STEREO on page 52 (removed shading), ADC-CTRL register I2S0_DATA0_CTRL field modification on page 74 and OFF added in PL2_C_WIDTH and PL2_DIMENSION on page 102.
Revision
1.96 1.97
Modification
1.98
April 2004
1.99
June 2004
2.0
June 2004
2.01
July 2004
2.02 2.03 3
July 2004 January 2005 February 2005
146/149
STV82x7
Index
A
Analog-to-Digital Conversion ............................. 21 Audio Matrix Analog .......................................................... 39 Automatic Frequency Control ............................ 23 Automatic Gain Control ...................................... 21 Automatic Overmodulation Detection ................ 22 Automatic Standard Recognition System .... 22, 49
I
IC Address ........................................................ 46 IC Protocol ........................................................ 46 IS Interface ....................................................... 40 I2C ................................................................... 138 I2C Address ....................................................... 46
L
Loudness Control Automatic ..................................................... 36
B
Back-end Processing ......................................... 24 Bass-Treble Control ........................................... 35 Beeper ............................................................... 37
P
Package Mechanical Data ............................... 145 Peak Detector .................................................... 22 Power Supply Management ............................... 43
C
Clock Generator ................................................ 20
R D
Demodulation .................................................... 22 Dolby Pro Logic II Decoder .................................... 28 Registers 5-Band Equalizer / Bass-Treble ......... 110, 112 Analog Control ............................................. 74 Audio Preprocessing and Selection ............. 85 Audio Processing ......................................... 98 Automatic Standard Recognition ................. 81 AutoStandard Coefficients Settings ........... 130 Beeper ....................................................... 126 Clocking 1 .................................................... 56 Clocking 2 .................................................... 76 DAC Control ............................................... 129 Demodulator ................................................ 59 Demodulator Channel 1 ............................... 62 Demodulator Channel 2 ............................... 66 DSP Control ................................................. 77 General Control ........................................... 55 Headphone Bass-Treble ............................ 113 Headphone Configuration .......................... 128 IC Map ........................................................ 49 Matrixing ...................................................... 93 Mute ........................................................... 127 NICAM ......................................................... 71 Stereo Mode ................................................ 73 Volume ....................................................... 116
E
Electrical Characteristics ................................. 132 Absolute Maximum Ratings ....................... 132 Analog Sound IF Signal ............................. 133 Crystal Oscillator ........................................ 133 Digital I/Os ................................................. 136 IC Bus ....................................................... 137 I2S to LS/HP/SW Path ............................... 135 I2S to SCART Path .................................... 136 MUTE Performance ................................... 136 SCART to LS/HP/SW Path ........................ 135 SCART to SCART Analog Path ................. 134 SIF to LS/HP/SCART Path ........................ 134 Supply Data ............................................... 132 Thermal Data ............................................. 132 Equalizer 5-Band Audio ............................................... 35
147/149
STV82x7
S
SIF Signal Analog .......................................................... 21 Signal Processor Dedicated Digital .......................................... 24 Signal to Noise ................................................ 134 Smart Volume Control ....................................... 34 Soft Mute Control ............................................... 37 Software Information ........................................... 9 SRS TruBass ....................................................... 34 TruSurround ................................................. 33 WOW ........................................................... 33 SRS TruSurround XT ....................................... 33 ST Dynamic Bass .............................................. 35 ST OmniSurround .............................................. 28 ST WideSurround .............................................. 28
T
Total Harmonic Distortion ................................ 134
V
Volume/Balance Control .................................... 36
148/149
STV82x7
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a registered trademark of STMicroelectronics All other names are the property of their respective owners (c) 2005 STMicroelectronics - All rights reserved STMicroelectronics GROUP OF COMPANIES Australia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States www.st.com
149/149


▲Up To Search▲   

 
Price & Availability of STV8247

All Rights Reserved © IC-ON-LINE 2003 - 2022  

[Add Bookmark] [Contact Us] [Link exchange] [Privacy policy]
Mirror Sites :  [www.datasheet.hk]   [www.maxim4u.com]  [www.ic-on-line.cn] [www.ic-on-line.com] [www.ic-on-line.net] [www.alldatasheet.com.cn] [www.gdcy.com]  [www.gdcy.net]


 . . . . .
  We use cookies to deliver the best possible web experience and assist with our advertising efforts. By continuing to use this site, you consent to the use of cookies. For more information on cookies, please take a look at our Privacy Policy. X