Micronas MSP3441G Multistandard sound processor family with virtual dolby surround Datasheet

PRELIMINARY DATA SHEET
MICRONAS
Edition Jan. 19, 2001
6251-511-2PD
MSP 34x1G
Multistandard
Sound Processor Family
with Virtual Dolby
Surround
MICRONAS
MSP 34x1G
PRELIMINARY DATA SHEET
Contents
Page
Section
Title
6
7
7
8
1.
1.1.
1.2.
1.3.
Introduction
Features of the MSP 34x1G Family and Differences to MSP 34xxD
MSP 34x1G Version List
MSP 34x1G Versions and their Application Fields
9
10
10
10
10
11
11
11
11
13
13
13
13
13
13
14
14
14
14
14
14
14
15
15
15
15
15
16
16
16
16
2.
2.1.
2.2.
2.2.1.
2.2.2.
2.2.3.
2.2.4.
2.2.5.
2.3.
2.4.
2.5.
2.5.1.
2.5.2.
2.5.3.
2.5.4.
2.5.5.
2.5.5.1.
2.5.5.2.
2.5.5.3.
2.6.
2.6.1.
2.6.2.
2.6.3.
2.6.4.
2.7.
2.7.1.
2.7.2.
2.8.
2.9.
2.10.
2.11.
Functional Description
Architecture of the MSP 34x1G Family
Sound IF Processing
Analog Sound IF Input
Demodulator: Standards and Features
Preprocessing of Demodulator Signals
Automatic Sound Select
Manual Mode
Preprocessing for SCART and I2S Input Signals
Source Selection and Output Channel Matrix
Audio Baseband Processing
Automatic Volume Correction (AVC)
Loudspeaker and Headphone Outputs
Subwoofer Output
Quasi-Peak Detector
Micronas Dynamic Bass (MDB)
Dynamic Amplification
Adding Harmonics
MDB Parameters
Virtual Surround System Application Tips
Sweet Spot
Clipping
Loudspeaker Requirements
Cabinet Requirements
SCART Signal Routing
SCART DSP In and SCART Out Select
Stand-by Mode
I2S Bus Interface
ADR Bus Interface
Digital Control I/O Pins and Status Change Indication
Clock PLL Oscillator and Crystal Specifications
17
17
17
18
18
19
19
19
19
19
3.
3.1.
3.1.1.
3.1.2.
3.1.3.
3.1.4.
3.1.4.1.
3.1.4.2.
3.1.4.3.
3.1.4.4.
Control Interface
I2C Bus Interface
Internal Hardware Error Handling
Description of CONTROL Register
Protocol Description
Proposals for General MSP 34x1G I2C Telegrams
Symbols
Write Telegrams
Read Telegrams
Examples
2
Micronas
PRELIMINARY DATA SHEET
MSP 34x1G
Contents, continued
Page
Section
Title
19
19
19
23
24
24
24
26
28
29
44
45
45
45
45
45
46
46
46
46
46
46
3.2.
3.3.
3.3.1.
3.3.2.
3.3.2.1.
3.3.2.2.
3.3.2.3.
3.3.2.4.
3.3.2.5.
3.3.2.6.
3.3.2.7.
3.4.
3.5.
3.5.1.
3.5.2.
3.5.3.
3.5.4.
3.5.5.
3.5.6.
3.5.7.
3.5.8.
3.5.9.
Start-Up Sequence: Power-Up and I2C-Controlling
MSP 34x1G Programming Interface
User Registers Overview
Description of User Registers
STANDARD SELECT Register
Refresh of STANDARD SELECT Register
STANDARD RESULT Register
Write Registers on I2C Subaddress 10hex
Read Registers on I2C Subaddress 11hex
Write Registers on I2C Subaddress 12hex
Read Registers on I2C Subaddress 13hex
Programming Tips
Examples of Minimum Initialization Codes
SCART1 Input to Loudspeaker in Stereo Sound
SCART1 Input to Loudspeaker in 3D-PANORAMA Sound
Noise Sequencer for 3D-PANORAMA Sound
B/G-FM (A2 or NICAM)
BTSC-Stereo
BTSC-SAP with SAP at Loudspeaker Channel
FM-Stereo Radio
Automatic Standard Detection
Software Flow for Interrupt driven STATUS Check
48
48
50
53
56
60
62
62
63
63
63
64
65
66
66
67
68
69
70
72
73
73
74
77
4.
4.1.
4.2.
4.3.
4.4.
4.5.
4.6.
4.6.1.
4.6.2.
4.6.2.1.
4.6.2.2.
4.6.2.3.
4.6.2.4.
4.6.3.
4.6.3.1.
4.6.3.2.
4.6.3.3.
4.6.3.4.
4.6.3.5.
4.6.3.6.
4.6.3.7.
4.6.3.8.
4.6.3.9.
4.6.3.10.
Specifications
Outline Dimensions
Pin Connections and Short Descriptions
Pin Descriptions
Pin Configurations
Pin Circuits
Electrical Characteristics
Absolute Maximum Ratings
Recommended Operating Conditions (TA = 0 to 70 °C)
General Recommended Operating Conditions
Analog Input and Output Recommendations
Recommendations for Analog Sound IF Input Signal
Crystal Recommendations
Characteristics
General Characteristics
Digital Inputs, Digital Outputs
Reset Input and Power-Up
I2C-Bus Characteristics
I2S-Bus Characteristics
Analog Baseband Inputs and Outputs, AGNDC
Sound IF Inputs
Power Supply Rejection
Analog Performance
Sound Standard Dependent Characteristics
Micronas
3
MSP 34x1G
PRELIMINARY DATA SHEET
Contents, continued
Page
Section
Title
81
81
82
83
83
84
84
5.
5.1.
5.2.
5.3.
5.4.
5.5.
5.6.
Appendix A: Overview of TV-Sound Standards
NICAM 728
A2-Systems
BTSC-Sound System
Japanese FM Stereo System (EIA-J)
FM Satellite Sound
FM-Stereo Radio
85
85
86
87
87
87
87
89
89
90
91
93
93
95
95
95
95
96
96
96
96
97
97
97
97
97
98
98
98
98
98
98
99
99
99
101
101
101
6.
6.1.
6.2.
6.3.
6.3.1.
6.3.1.1.
6.3.1.2.
6.3.2.
6.3.3.
6.3.4.
6.3.5.
6.3.6.
6.3.7.
6.4.
6.4.1.
6.4.2.
6.4.3.
6.4.4.
6.4.5.
6.4.6.
6.4.7.
6.5.
6.5.1.
6.5.2.
6.5.3.
6.5.4.
6.5.5.
6.5.6.
6.5.7.
6.6.
6.6.1.
6.6.2.
6.7.
6.7.1.
6.7.2.
6.8.
6.9.
6.10.
Appendix B: Manual/Compatibility Mode
Demodulator Write and Read Registers for Manual/Compatibility Mode
DSP Write and Read Registers for Manual/Compatibility Mode
Manual/Compatibility Mode: Description of Demodulator Write Registers
Automatic Switching between NICAM and Analog Sound
Function in Automatic Sound Select Mode
Function in Manual Mode
A2 Threshold
Carrier-Mute Threshold
Register AD_CV
Register MODE_REG
FIR-Parameter, Registers FIR1 and FIR2
DCO-Registers
Manual/Compatibility Mode: Description of Demodulator Read Registers
NICAM Mode Control/Additional Data Bits Register
Additional Data Bits Register
CIB Bits Register
NICAM Error Rate Register
PLL_CAPS Readback Register
AGC_GAIN Readback Register
Automatic Search Function for FM-Carrier Detection in Satellite Mode
Manual/Compatibility Mode: Description of DSP Write Registers
Additional Channel Matrix Modes
Volume Modes of SCART1/2 Outputs
FM Fixed Deemphasis
FM Adaptive Deemphasis
NICAM Deemphasis
Identification Mode for A2 Stereo Systems
FM DC Notch
Manual/Compatibility Mode: Description of DSP Read Registers
Stereo Detection Register for A2 Stereo Systems
DC Level Register
Demodulator Source Channels in Manual Mode
Terrestric Sound Standards
SAT Sound Standards
Exclusions of Audio Baseband Features
Phase Relationship of Analog Outputs
Compatibility Restrictions to MSP 34xxD
4
Micronas
PRELIMINARY DATA SHEET
MSP 34x1G
Contents, continued
Page
Section
Title
102
7.
Appendix D: MSP 34x1G Version History
103
8.
Appendix E: Application Circuit
104
9.
Data Sheet History
License Notice:
1)
"Dolby", “Virtual Dolby Surround” and the double-D symbol are trademarks of Dolby Laboratories.
Supply of this implementation of Dolby Technology does not convey a license nor imply a right under any patent, or any other industrial or intellectual property right of Dolby Laboratories, to use this implementation in any finished end-user or ready-to-use final product. Companies planning to
use this implementation in products must obtain a license from Dolby Laboratories Licensing Corporation before designing such products.
Micronas
5
MSP 34x1G
PRELIMINARY DATA SHEET
Multistandard Sound Processor Family with Virtual
Dolby Surround
Release Note: Revision bars indicate significant
changes to the previous edition.The hardware and
software description in this document is valid for
the MSP 34x1G version B8 and following versions.
1. Introduction
The MSP 34x1G family of single-chip Multistandard
Sound Processors covers the sound processing of all
analog TV-Standards worldwide, as well as the NICAM
digital sound standards. The full TV sound processing,
starting with analog sound IF signal-in, down to processed analog AF-out, is performed on a single chip.
Figure 1–1 shows a simplified functional block diagram
of the MSP 34x1G.
The MSP 34x1G has all functions of the MSP 34x0G
with the addition of a virtual surround sound feature.
Surround sound can be reproduced to a certain extent
with two loudspeakers. The MSP 34x1G includes the
Micronas virtualizer algorithm “3D-PANORAMA” which
has been approved by the Dolby1) Laboratories for
compliance with the "Virtual Dolby Surround" technology. In addition, the MSP 34x1G includes the “PANORAMA” algorithm.
These TV sound processing ICs include versions for
processing the multichannel television sound (MTS)
ADC
Sound IF2
Demodulator
I2S1
Other processed standards are the Japanese FM-FM
multiplex standard (EIA-J) and the FM Stereo Radio
standard.
Current ICs have to perform adjustment procedures in
order to achieve good stereo separation for BTSC and
EIA-J. The MSP 34x1G has optimum stereo performance without any adjustments.
All MSP 34xxG versions are pin compatible to the
MSP 34xxD. Only minor modifications are necessary
to adapt a MSP 34xxD controlling software to the
MSP 34xxG. The MSP 34x1G further simplifies controlling software. Standard selection requires a single
I2C transmission only.
The MSP 34x1G has built-in automatic functions: The
IC is able to detect the actual sound standard automatically (Automatic Standard Detection). Furthermore,
pilot levels and identification signals can be evaluated
internally with subsequent switching between mono/
stereo/bilingual; no I2C interaction is necessary (Automatic Sound Selection).
The ICs are produced in submicron CMOS technology.
The MSP 34x1G is available in the following packages:
PLCC68 (not intended for new designs), PSDIP64,
PSDIP52, PQFP80, and PLQFP64.
Preprocessing
Prescale
I2S2
Source Select
Sound IF1
signal conforming to the standard recommended by
the Broadcast Television Systems Committee (BTSC).
The DBX noise reduction, or alternatively, Micronas
Noise Reduction (MNR) is performed alignment free.
Loudspeaker
Sound
Processing
DAC
Headphone
Sound
Processing
DAC
Loudspeaker
Subwoofer
Headphone
I2S
SCART1
DAC
SCART2
SCART3
SCART
DSP
Input
Select
SCART1
ADC
Prescale
SCART4
MONO
DAC
SCART
Output
Select
SCART2
Fig. 1–1: Simplified functional block diagram of the MSP 34x1G
6
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
1.1. Features of the MSP 34x1G Family and Differences to MSP 34xxD
Feature
(New features not available for MSP 34xxD are shaded gray.)
3401
3411
3421
3441
3451
3461
3D-PANORAMA virtualizer (approved by Dolby Laboratories) with noise generator
X
X
X
X
X
X
PANORAMA virtualizer algorithm
X
X
X
X
X
X
Standard Selection with single I C transmission
X
X
X
X
X
X
Automatic Standard Detection of terrestrial TV standards/Automatic Carrier Mute function
X
X
X
X
X
X
Automatic Sound Selection (mono/stereo/bilingual), new registers MODUS, STATUS
X
X
X
X
X
X
Two selectable sound IF (SIF) inputs
X
X
X
X
X
X
Interrupt output programmable (indicating status change)
X
X
X
X
X
X
Loudspeaker / Headphone channel with volume, balance, bass, treble, loudness
X
X
X
X
X
X
Loudspeaker channel with MDB (Micronas Dynamic Bass)
X
X
X
X
X
X
AVC: Automatic Volume Correction
X
X
X
X
X
X
Subwoofer output with programmable low-pass and complementary high-pass filter
X
X
X
X
X
X
5-band graphic equalizer for loudspeaker channel
X
X
X
X
X
X
Spatial effect for loudspeaker channel; processing of all deemphasis filtering
X
X
X
X
X
X
Four Stereo SCART (line) inputs, one Mono input; two Stereo SCART outputs
X
X
X
X
X
X
Complete SCART in/out switching matrix
X
X
X
X
X
X
Two I2S inputs; one I2S output
X
X
X
X
X
X
All analog FM-Stereo A2 and satellite standards
X
X
All analog Mono sound carriers including AM-SECAM L
X
X
2
Simultaneous demodulation of (very) high-deviation FM-Mono and NICAM
X
X
X
X
X
X
X
Adaptive deemphasis for satellite (Wegener-Panda, acc. to ASTRA specification)
X
X
X
X
ASTRA Digital Radio (ADR) together with DRP 3510A
X
X
X
X
X
X
All NICAM standards
Demodulation of the BTSC multiplex signal and the SAP channel
X
Alignment free digital DBX noise reduction for BTSC Stereo and SAP
X
X
X
X
Alignment free digital Micronas Noise Reduction (MNR) for BTSC Stereo and SAP
X
BTSC stereo separation (MSP 3421/41G also EIA-J) significantly better than spec.
X
X
X
SAP and stereo detection for BTSC system
X
X
X
X
X
X
Alignment-free Japanese standard EIA-J
X
X
X
Demodulation of the FM-Radio multiplex signal
X
X
X
Korean FM-Stereo A2 standard
X
X
1.2. MSP 34x1G Version List
Version
Status
Description
MSP 3401G
available
FM Stereo (A2) Version
MSP 3411G
available
NICAM and FM Stereo (A2) Version
MSP 3421G
available
NTSC Version (A2 Korea, BTSC with Micronas Noise Reduction (MNR), Japanese EIA-J system)
MSP 3441G
not confirmed
NTSC Version (A2 Korea, BTSC with DBX noise reduction, Japanese EIA-J system)
MSP 3451G
available
Global Version (all sound standards)
MSP 3461G
not confirmed
Global Mono Version (all sound Standards)
Micronas
7
MSP 34x1G
PRELIMINARY DATA SHEET
1.3. MSP 34x1G Versions and their Application Fields
Table 1–1 provides an overview of TV sound standards
that can be processed by the MSP 34x1G family. In
addition, the MSP 34x1G is able to handle the FMRadio standard. With the MSP 34x1G, a complete
multimedia receiver covering all TV sound standards
together with terrestrial/cable and satellite radio sound
can be built; even ASTRA Digital Radio can be processed (with a DRP 3510A coprocessor).
Table 1–1: TV Stereo Sound Standards covered by the MSP 34x1G IC Family (details see Appendix A)
TVSystem
3401
MSP Version
Position of Sound
Carrier /MHz
Sound
Modulation
Color
System
Broadcast e.g. in:
5.5/5.7421875
FM-Stereo (A2)
PAL
Germany
5.5/5.85
FM-Mono/NICAM
PAL
Scandinavia, Spain
L
6.5/5.85
AM-Mono/NICAM
SECAM-L
France
I
6.0/6.552
FM-Mono/NICAM
PAL
UK, Hong Kong
6.5/6.2578125
FM-Stereo (A2, D/K1)
SECAM-East
Slovak. Rep.
6.5/6.7421875
FM-Stereo (A2, D/K2)
PAL
currently no broadcast
6.5/5.7421875
FM-Stereo (A2, D/K3)
SECAM-East
Poland
6.5/5.85
FM-Mono/NICAM (D/K, NICAM)
PAL
China, Hungary
6.5
7.02/7.2
7.38/7.56
etc.
FM-Mono
FM-Stereo
PAL
Europe Sat.
ASTRA
4.5/4.724212
FM-Stereo (A2)
NTSC
Korea
4.5
FM-FM (EIA-J)
NTSC
Japan
4.5
BTSC-Stereo + SAP
NTSC, PAL
USA, Argentina
10.7
FM-Stereo Radio
3411
3401
B/G
3451
D/K
3421, 3441
3401
Satellite
M/N
FM-Radio
3461
ASTRA Digital Radio (ADR)
with DRP 3510A
USA, Europe
all Standards, but Mono demodulation only
33
34 39 MHz
4.5 9 MHz
SAW Filter
Sound
IF
Mixer
Tuner
Loudspeaker
1
Subwoofer
Mono
Vision
Demodulator
MSP 34x1G
2
SCART1
Headphone
2
SCART
Inputs
Composite
Video
SCART2
2
2
2
2
SCART3
SCART4
I2S1
Dolby
Pro Logic
Processor
DPL 351xA
ADR
SCART1
SCART2
SCART
Outputs
I2S2
ADR
Decoder
DRP 3510A
Fig. 1–2: Typical MSP 34x1G application
8
Micronas
A
D
DEMODULATOR
(incl. Carrier Mute)
Deemphasis:
50/75 µs, J17
DBX/MNR
Panda1
FM/AM
Prescale
FM/AM
Stereo or A/B
Loudspeaker
Channel
Matrix
0
1
(0Ehex)
ANA_IN2+
ADR-Bus
Interface
Decoded
Standards:
− NICAM
− A2
− AM
− BTSC
− EIA-J
− SAT
− FM-Radio
NICAM
Deemphasis
J17
Prescale
Virtualizer
Stereo or B
Bass/
Treble
or
Equalize
(29hex)
(08hex)
Stereo or A
AVC
Complementary Spatial Balance
Highpass Effects
Loudness
Σ
(02hex)
(03hex)
(04hex)
3
(05hex)
Lowpass
Noise
Generator
4
(2Dhex)
0.5
Beeper
(2Dhex)
(14hex)
D
DACM_L
Volume
DACM_R
(01hex)
Level
Adjust
(2Chex)
A
MDB
DACM_SUB
(00hex)
(10hex)
Standard
and Sound
Detection
I2C
Read
Register
I S1
I2S
Interface
(16hex)
2
I S2
I2S
Interface
I2S_DA_IN2
Bass/
Treble
Σ
Loudness
(31/32hex)
(09hex)
I2S
Channel
Matrix
D
DACA_L
Balance
A
5
Prescale
Source Select
I2S_DA_IN1
Volume
Headphone
Channel
Matrix
2
PRELIMINARY DATA SHEET
AGC
Automatic
Sound Select
Standard Selection
2. Functional Description
Micronas
ANA_IN1+
(33hex)
I2S
Interface
(30hex)
(06hex)
DACA_R
I2S_DA_OUT
6
(0Bhex)
Prescale
(12hex)
Quasi-Peak
Channel
Matrix
Quasi-Peak
Detector
I2C
Read
Register
(19hex)
(1Ahex)
(13hex)
SC1_IN_L
SC1_IN_R
SC2_IN_L
SC3_IN_L
Prescale
(0Dhex)
SCART1
Channel
Matrix
(0Ahex)
SCART2
Channel
Matrix
(41hex)
Volume
D
SCART1_L/R
A
(07hex)
Volume
SC1_OUT_L
D
SCART2_L/R
A
(40hex)
SC1_OUT_R
SC2_OUT_L
SC2_OUT_R
SC3_IN_R
SC4_IN_L
SC4_IN_R
MONO_IN
(13hex)
Fig. 2–1: Signal flow block diagram of the MSP 34x1G (input and output names correspond to pin names)
9
MSP 34x1G
SC2_IN_R
2
D
SCART Output Select
SCART DSP Input Select
(0Chex)
SCART
A
MSP 34x1G
2.1. Architecture of the MSP 34x1G Family
Fig. 2–1 on page 9 shows a simplified block diagram of
the IC. The block diagram contains all features of the
MSP 3451G. Other members of the MSP 34x1G family
do not have the complete set of features: The demodulator handles only a subset of the standards presented
in the demodulator block; NICAM processing is only
possible in the MSP 3411G and MSP 3451G.
PRELIMINARY DATA SHEET
BTSC-Mono + SAP: Detection and FM demodulation
of the aural carrier resulting in the MTS/MPX signal.
Detection and evaluation of the pilot carrier, detection
and FM demodulation of the SAP subcarrier. Processing of DBX noise reduction or Micronas Noise Reduction (MNR).
Japan Stereo: Detection and FM demodulation of the
aural carrier resulting in the MPX signal. Demodulation
and evaluation of the identification signal and FM
demodulation of the (L−R)-carrier.
2.2. Sound IF Processing
2.2.1. Analog Sound IF Input
The input pins ANA_IN1+, ANA_IN2+, and ANA_IN−
offer the possibility to connect two different sound IF
(SIF) sources to the MSP 34x1G. The analog-to-digital
conversion of the preselected sound IF signal is done
by an A/D-converter. An analog automatic gain circuit
(AGC) allows a wide range of input levels. The highpass filters formed by the coupling capacitors at pins
ANA_IN1+ and ANA_IN2+ see Section 8. “Appendix
E: Application Circuit” on page 103 are sufficient in
most cases to suppress video components. Some
combinations of SAW filters and sound IF mixer ICs,
however, show large picture components on their outputs. In this case, further filtering is recommended.
FM-Satellite Sound: Demodulation of one or two FM
carriers. Processing of high-deviation mono or narrow
bandwidth mono, stereo, or bilingual satellite sound
according to the ASTRA specification.
FM-Stereo-Radio: Detection and FM demodulation of
the aural carrier resulting in the MPX signal. Detection
and evaluation of the pilot carrier and AM demodulation of the (L−R)-carrier.
The demodulator blocks of all MSP 34x1G versions
have identical user interfaces. Even completely different systems like the BTSC and NICAM systems are
controlled the same way. Standards are selected by
means of MSP Standard Codes. Automatic processes
handle standard detection and identification without
controller interaction. The key features of the
MSP 34x1G demodulator blocks are
2.2.2. Demodulator: Standards and Features
The MSP 34x1G is able to demodulate all TV-sound
standards worldwide including the digital NICAM system. Depending on the MSP 34x1G version, the following demodulation modes can be performed:
A2 Systems: Detection and demodulation of two separate FM carriers (FM1 and FM2), demodulation and
evaluation of the identification signal of carrier FM2.
NICAM Systems: Demodulation and decoding of the
NICAM carrier, detection and demodulation of the analog (FM or AM) carrier. For D/K-NICAM, the FM carrier
may have a maximum deviation of 384 kHz.
Very high deviation FM-Mono: Detection and robust
demodulation of one FM carrier with a maximum deviation of 540 kHz.
BTSC-Stereo: Detection and FM demodulation of the
aural carrier resulting in the MTS/MPX signal. Detection and evaluation of the pilot carrier, AM demodulation of the (L−R)-carrier and detection of the SAP subcarrier. Processing of DBX noise reduction or Micronas
Noise Reduction (MNR).
10
Standard Selection: The controlling of the demodulator is minimized: All parameters, such as tuning frequencies or filter bandwidth, are adjusted automatically by transmitting one single value to the
STANDARD SELECT register. For all standards, specific MSP standard codes are defined.
Automatic Standard Detection: If the TV sound standard is unknown, the MSP 34x1G can automatically
detect the actual standard, switch to that standard, and
respond the actual MSP standard code.
Automatic Carrier Mute: To prevent noise effects or
FM identification problems in the absence of an FM
carrier, the MSP 34x1G offers a configurable carrier
mute feature, which is activated automatically if the TV
sound standard is selected by means of the STANDARD SELECT register. If no FM carrier is detected at
one of the two MSP demodulator channels, the corresponding demodulator output is muted. This is indicated in the STATUS register.
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
2.2.3. Preprocessing of Demodulator Signals
The NICAM signals must be processed by a deemphasis filter and adjusted in level. The analog demodulated signals must be processed by a deemphasis filter, adjusted in level, and dematrixed. The correct
deemphasis filters are already selected by setting the
standard in the STANDARD SELECT register. The
level adjustment has to be done by means of the FM/
AM and NICAM prescale registers. The necessary
dematrix function depends on the selected sound standard and the actual broadcasted sound mode (mono,
stereo, or bilingual). It can be manually set by the FM
Matrix Mode register or automatically by the Automatic
Sound Selection.
– “Stereo or A” channel: Analog or digital mono
sound, stereo if available. In case of bilingual broadcast, it contains language A (on left and right).
– “Stereo or B” channel: Analog or digital mono
sound, stereo if available. In case of bilingual broadcast, it contains language B (on left and right).
Fig. 2–2 and Table 2–2 show the source channel
assignment of the demodulated signals in case of
Automatic Sound Select mode for all sound standards.
Note: The analog primary input channel contains the
signal of the mono FM/AM carrier or the L+R signal of
the MPX carrier. The secondary input channel contains
the signal of the 2nd FM carrier, the L-R signal of the
MPX carrier, or the SAP signal.
2.2.4. Automatic Sound Select
The demodulator supports the identification check by
switching between mono-compatible standards (standards that have the same FM-Mono carrier) automatically and non-audible. If B/G-FM or B/G-NICAM is
selected, the MSP will switch between these standards. The same action is performed for the standards: D/K1-FM, D/K2-FM, D/K3-FM and D/K-NICAM.
Switching is only done in the absence of any stereo or
bilingual identification. If identification is found, the
MSP keeps the detected standard.
In case of high bit-error rates, the MSP 34x1G automatically falls back from digital NICAM sound to analog FM or AM mono.
primary
channel
FM/AM
secondary
channel
Prescale
NICAM A
NICAM
NICAM B
Prescale
Automatic
Sound
Select
FM/AM
0
Stereo or A/B
1
Stereo or A
3
Stereo or B
4
LS Ch.
Matrix
Source Select
In the Automatic Sound Select mode, the dematrix
function is automatically selected based on the identification information in the STATUS register. No I2C
interaction is necessary when the broadcasted sound
mode changes (e.g. from mono to stereo).
Fig. 2–2: Source channel assignment of demodulated
signals in Automatic Sound Select Mode
2.2.5. Manual Mode
Fig. 2–3 shows the source channel assignment of
demodulated signals in case of manual mode. If manual mode is required, more information can be found in
Section 6.7. “Demodulator Source Channels in Manual
Mode” on page 99.
Table 2–1 summarizes all actions that take place when
Automatic Sound Select is switched on.
LS Ch.
Matrix
FM/AM
FM-Matrix
secondary
channel
Prescale
NICAM A
NICAM
NICAM B
Prescale
FM/AM
0
Source Select
primary
channel
To provide more flexibility, the Automatic Sound Select
block prepares four different source channels of
demodulated sound (Fig. 2–2). By choosing one of the
four demodulator channels, the preferred sound mode
can be selected for each of the output channels (loudspeaker, headphone, etc.). This is done by means of
the Source Select registers.
Output-Ch.
matrices
must be set
once to
stereo.
NICAM
(Stereo or A/B)
1
Output-Ch.
matrices
must be set
according to
the standard.
The following source channels of demodulated sound
are defined:
Fig. 2–3: Source channel assignment of demodulated
signals in Manual Mode
– “FM/AM” channel: Analog mono sound, stereo if
available. In case of NICAM, analog mono only
(FM or AM mono).
2.3. Preprocessing for SCART and
I2S Input Signals
– “Stereo or A/B” channel: Analog or digital mono
sound, stereo if available. In case of bilingual broadcast, it contains both languages A (left) and B
(right).
The SCART and I2S inputs need only be adjusted in
level by means of the SCART and I2S prescale registers.
Micronas
11
MSP 34x1G
PRELIMINARY DATA SHEET
Table 2–1: Performed actions of the Automatic Sound Selection
Selected TV Sound Standard
Performed Actions
B/G-FM, D/K-FM, M-Korea,
and M-Japan
Evaluation of the identification signal and automatic switching to mono, stereo, or bilingual. Preparing four
demodulator source channels according to Table 2–2.
B/G-NICAM, L-NICAM, I-NICAM,
and D/K-NICAM
Evaluation of NICAM-C-bits and automatic switching to mono, stereo, or bilingual. Preparing four
demodulator source channels according to Table 2–2.
In case of bad or no NICAM reception, the MSP switches automatically to FM/AM mono and switches
back to NICAM if possible. A hysteresis prevents periodical switching.
B/G-FM, B/G-NICAM
or
D/K1-FM, D/K2-FM, D/K3-FM,
and D/K-NICAM
Automatic searching for stereo/bilingual-identification in case of mono transmission. Automatic and nonaudible changes between Dual-FM and FM-NICAM standards while listening to the basic FM-Mono sound
carrier.
Example: If starting with B/G-FM-Stereo, there will be a periodical alternation to B/G-NICAM in the
absence of FM-Stereo/Bilingual or NICAM-identification. Once an identification is detected, the MSP
keeps the corresponding standard.
BTSC-STEREO, FM Radio
Evaluation of the pilot signal and automatic switching to mono or stereo. Preparing four demodulator
source channels according to Table 2–2. Detection of the SAP carrier.
BTSC-SAP
In the absence of SAP, the MSP switches to BTSC-Stereo if available. If SAP is detected, the MSP
switches automatically to SAP (see Table 2–2).
Table 2–2: Sound modes for the demodulator source channels with Automatic Sound Select
Source Channels in Automatic Sound Select Mode
Broadcasted
Sound
Standard
Selected
MSP Standard
Code3)
Broadcasted
Sound Mode
FM/AM
Stereo or A/B
Stereo or A
Stereo or B
(source select: 0)
(source select: 1)
(source select: 3)
(source select: 4)
M-Korea
B/G-FM
D/K-FM
M-Japan
02
03, 081)
04, 05, 07, 0B1)
30
MONO
Mono
Mono
Mono
Mono
STEREO
Stereo
Stereo
Stereo
Stereo
BILINGUAL:
Languages A and B
Left = A
Right = B
Left = A
Right = B
A
B
NICAM not available or
error rate too high
analog Mono
analog Mono
analog Mono
analog Mono
MONO
analog Mono
NICAM Mono
NICAM Mono
NICAM Mono
STEREO
analog Mono
NICAM Stereo
NICAM Stereo
NICAM Stereo
BILINGUAL:
Languages A and B
analog Mono
Left = NICAM A
Right = NICAM B
NICAM A
NICAM B
MONO
Mono
Mono
Mono
Mono
STEREO
Stereo
Stereo
Stereo
Stereo
MONO+SAP
Mono
Mono
Mono
Mono
STEREO+SAP
Stereo
Stereo
Stereo
Stereo
MONO+SAP
Left = Mono
Right = SAP
Left = Mono
Right = SAP
Mono
SAP
STEREO+SAP
Left = Mono
Right = SAP
Left = Mono
Right = SAP
Mono
SAP
MONO
Mono
Mono
Mono
Mono
STEREO
Stereo
Stereo
Stereo
Stereo
B/G-NICAM
L-NICAM
I-NICAM
D/K-NICAM
D/K-NICAM
08, 032)
09
0A
0B, 042), 052)
0C, 0D
(with high
deviation FM)
20, 21
20
BTSC
21
FM Radio
1)
2)
3)
12
40
The Automatic Sound Select process will automatically switch to the mono compatible analog standard.
The Automatic Sound Select process will automatically switch to the mono compatible digital standard.
The MSP Standard Codes are defined in Table 3–7 on page 23.
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
2.4. Source Selection and Output Channel Matrix
2.5.2. Loudspeaker and Headphone Outputs
The Source Selector makes it possible to distribute all
source signals (one of the demodulator source channels, SCART, or I2S input) to the desired output channels (loudspeaker, headphone, etc.). All input and output signals can be processed simultaneously. Each
source channel is identified by a unique source
address.
The following baseband features are implemented in
the loudspeaker and headphone output channels:
bass/treble, loudness, balance, and volume. A square
wave beeper can be added to the loudspeaker and
headphone channel. The loudspeaker channel additionally performs: equalizer (not simultaneously with
bass/treble), spatial effects, and a subwoofer crossover filter.
For each output channel, the sound mode can be set
to sound A, sound B, stereo, or mono by means of the
output channel matrix.
If Automatic Sound Select is on, the output channel
matrix can stay fixed to stereo (transparent) for
demodulated signals.
2.5. Audio Baseband Processing
2.5.1. Automatic Volume Correction (AVC)
Different sound sources (e.g. terrestrial channels, SAT
channels, or SCART) fairly often do not have the same
volume level. Advertisements during movies usually
have a higher volume level than the movie itself. This
results in annoying volume changes. The AVC solves
this problem by equalizing the volume level.
To prevent clipping, the AVC’s gain decreases quickly
in dynamic boost conditions. To suppress oscillation
effects, the gain increases rather slowly for low level
inputs. The decay time is programmable by means of
the AVC register (see page 33).
2.5.3. Subwoofer Output
The subwoofer signal is created by combining the left
and right channels directly behind the loudness block
using the formula (L+R)/2. Due to the division by 2, the
D/A converter will not be overloaded, even with full
scale input signals. The subwoofer signal is filtered by
a third-order low-pass with programmable corner frequency followed by a level adjustment. At the loudspeaker channels, a complementary high-pass filter
can be switched on. Subwoofer and loudspeaker output use the same volume (Loudspeaker Volume Register).
2.5.4. Quasi-Peak Detector
The quasi-peak readout register can be used to read
out the quasi-peak level of any input source. The feature is based on following filter time constants:
attack time: 1.3 ms
decay time: 37 ms
For input signals ranging from −24 dBr to 0 dBr, the
AVC maintains a fixed output level of −18 dBr. Fig. 2–4
shows the AVC output level versus its input level. For
prescale and volume registers set to 0 dB, a level of
0 dBr corresponds to full scale input/output. This is
– SCART input/output 0 dBr = 2.0 Vrms
– Loudspeaker output 0 dBr = 1.4 Vrms
output level
[dBr]
−18
−24
−30
−24
−18
−12
−6
0
input level
[dBr]
Fig. 2–4: Simplified AVC characteristics
Micronas
13
MSP 34x1G
PRELIMINARY DATA SHEET
The Micronas Dynamic Bass system (MDB) extends
the frequency range of loudspeakers or headphones.
Amplitude (db)
2.5.5. Micronas Dynamic Bass (MDB)
After the adaption of MDB to the loudspeakers and the
cabinet, further customizing of MDB allows individual
fine tuning of the sound.
The MDB is placed in the subwoofer path. For applications without a subwoofer, the enhanced bass signal
can be added back onto the Left/Right channels (see
Fig. 2–1 on page 9). Micronas Dynamic Bass combines two effects: dynamic amplification and adding
harmonics.
Frequency
MDB_HP
Fig. 2–6: Adding harmonics
2.5.5.3. MDB Parameters
2.5.5.1. Dynamic Amplification
Low frequency signals can be boosted while the output
signal amplitude is measured. If the amplitude comes
close to a definable limit, the gain is reduced automatically in dynamic Volume mode. Therefore, the system
adapts to the signal amplitude which is really present
at the output of the MSP device. Clipping effects are
avoided.
Several parameters allow tuning the characteristics of
MDB according to the TV loudspeaker, the cabinet,
and personal preferences (see Table 3–11). For more
detailed information on how to set up MDB, please
refer to the corresponding application note on the
Micronas homepage.
2.6. Virtual Surround System Application Tips
Amplitude
(db)
2.6.1. Sweet Spot
Signal Level
MDB_LIMIT
Good results are only obtained in a rather close area
along the middle axis between the two loudspeakers:
the sweet spot. Moving away from this position
degrades the effect.
2.6.2. Clipping
Frequency
MDB_HP
MDB_LP
SUBW_FREQ
Fig. 2–5: Dynamic amplification
2.5.5.2. Adding Harmonics
MDB exploits the psychoacoustic phenomenon of the
‘missing fundamental’. Adding harmonics of the frequency components below the cutoff frequency gives
the impression of actually hearing the low frequency
fundamental. In other words: The listener has the
impression that a loudspeaker system seems to reproduce frequencies althoug physically not possible.
14
For the test at Dolby Labs, it is very important to have
no clipping effects even with worst case signals. That
is, 2 Vrms input signal may not clip. The SCART Input
Prescale register has to be set to values of 19hex
(25dec) or lower (see SCART Input Prescale on page
30).
Test signals: sine sweep with 2 VRMS; L only, R only,
L&R equal phase, L&R anti phase.
Listening tests: Dolby Trailers (train trailer, city trailer,
canyon trailer...)
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
2.6.3. Loudspeaker Requirements
2.7. SCART Signal Routing
The loudspeakers used and their positioning inside the
TV set will greatly influence the performance of the virtualizer. The algorithm works with the direct sound
path. Reflected sound waves reduce the effect. So it’s
most important to have as much direct sound as possible, compared to indirect sound.
2.7.1. SCART DSP In and SCART Out Select
To obtain the approval for a TV set, Dolby Laboratories
require mounting the loudspeakers in front of the set.
Loudspeakers radiating to the side of the TV set will
not produce convincing effects. Good directionality of
the loudspeakers towards the listener is optimal.
The virtualizer was specially developed for implementation in TV sets. Even for rather small stereo TV's,
sufficient sound effects can be obtained. For small
sets, the loudspeaker placement should be to the side
of the CRT; for large screen sets (or 16:9 sets), mounting the loudspeakers below the CRT is acceptable
(large separation is preferred, low frequency speakers
should be outmost to avoid cancellation effects). Using
external loudspeakers with a large stereo base will not
create optimal effects.
The loudspeakers should be able to reproduce a wide
frequency range. The most important frequency range
starts from 160 Hz and ranges up to 5 kHz.
The SCART DSP Input Select and SCART Output
Select blocks include full matrix switching facilities. To
design a TV set with four pairs of SCART-inputs and
two pairs of SCART-outputs, no external switching
hardware is required. The switches are controlled by
the ACB user register (see page 41).
2.7.2. Stand-by Mode
If the MSP 34x1G is switched off by first pulling
STANDBYQ low and then (after >1 µs delay) switching
off DVSUP and AVSUP, but keeping AHVSUP
(‘Stand-by’-mode), the SCART switches maintain
their position and function. This allows the copying
from SCART-input to SCART-output in the TV set’s
stand-by mode.
In case of power on or starting from stand-by (switching on the DVSUP and AVSUP, RESETQ going high
2 ms later), all internal registers except the ACB register (page 41) are reset to the default configuration (see
Table 3–5 on page 20). The reset position of the ACB
register becomes active after the first I2C transmission
into the Baseband Processing part. By transmitting the
ACB register first, the reset state can be redefined.
Great care has to be taken with systems that use one
common subwoofer: A single loudspeaker cannot
reproduce virtual sound locations. The crossover frequency must be lower than 120 Hz.
2.6.4. Cabinet Requirements
During listening tests at Dolby Laboratories, no resonances in the cabinet should occur.
Good material to check for resonances are the Dolby
Trailers or other dynamic sound tracks.
Micronas
15
MSP 34x1G
PRELIMINARY DATA SHEET
2.8. I2S Bus Interface
2.9. ADR Bus Interface
The MSP 34x1G has a synchronous master/slave
input/output interface running on 32 kHz.
For the ASTRA Digital Radio System (ADR), the
MSP 3401G, MSP 3411G, and MSP 3451G performs
preprocessing such as carrier selection and filtering.
Via the 3-line ADR-bus, the resulting signals are transferred to the DRP 3510A coprocessor, where the
source decoding is performed. To be prepared for an
upgrade to ADR with an additional DRP board, the following lines of MSP 34x1G should be provided on a
feature connector:
The interface accepts two formats:
1. I2S_WS changes at the word boundary
2. I2S_WS changes one I2S-clock period before the
word boundaries.
All I2S options are set by means of the MODUS and
the I2S_CONFIGURATION registers.
The I2S bus interface consists of five pins:
– I2S_DA_IN1, I2S_DA_IN2:
I2S serial data input: 16, 18....32 bits per sample
– I2S_DA_OUT:
I2S serial data output: 16, 18...32 bits per sample
– I2S_CL:
I2S serial clock
– I2S_WS:
I2S word strobe signal defines the left and right
sample
If the MSP 34x1G serves as the master on the I2S
interface, the clock and word strobe lines are driven by
the IC. In this mode, only 16 or 32 bits per sample can
be selected. In slave mode, these lines are input to the
IC and the MSP clock is synchronized to 576 times the
I2S_WS rate (32 kHz). NICAM operation is not possible in slave mode.
An I2S timing diagram is shown in Fig. 4–28 on
page 71.
– AUD_CL_OUT
– I2S_DA_IN1 or I2S_DA_IN2
– I2S_DA_OUT
– I2S_WS
– I2S_CL
– ADR_CL, ADR_WS, ADR_DA
For more details, please refer to the DRP 3510A data
sheet.
2.10. Digital Control I/O Pins and
Status Change Indication
The static level of the digital input/output pins
D_CTR_I/O_0/1 is switchable between HIGH and
LOW via the I2C-bus by means of the ACB register
(see page 41). This enables the controlling of external
hardware switches or other devices via I2C-bus.
The digital input/output pins can be set to high impedance by means of the MODUS register (see page 26).
In this mode, the pins can be used as input. The current state can be read out of the STATUS register (see
page 28).
Optionally, the pin D_CTR_I/O_1 can be used as an
interrupt request signal to the controller, indicating any
changes in the read register STATUS. This makes polling unnecessary, I2C bus interactions are reduced to a
minimum (see STATUS register on page 28 and
MODUS register on page 26).
2.11. Clock PLL Oscillator and Crystal Specifications
The MSP 34x1G derives all internal system clocks
from the 18.432-MHz oscillator. In NICAM or in I2SSlave mode, the clock is phase-locked to the corresponding source. Therefore, it is not possible to use
NICAM and I2S-Slave mode at the same time.
For proper performance, the MSP clock oscillator
requires a 18.432-MHz crystal. Note that for the
phase-locked modes (NICAM, I2S-Slave), crystals with
tighter tolerance are required.
16
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
3. Control Interface
response time is about 0.3 ms. If the MSP cannot
accept another byte of data (e.g. while servicing an
internal interrupt), it holds the clock line I2C_CL low to
force the transmitter into a wait state. The I2C Bus
Master must read back the clock line to detect when
the MSP is ready to receive the next I2C transmission.
The positions within a transmission where this may
happen are indicated by ’Wait’ in Section 3.1.3. The
maximum wait period of the MSP during normal operation mode is less than 1 ms.
3.1. I2C Bus Interface
The MSP 34x1G is controlled via the I2C bus slave
interface.
The IC is selected by transmitting one of the
MSP 34x1G device addresses. In order to allow up to
three MSP ICs to be connected to a single bus, an
address select pin (ADR_SEL) has been implemented.
With ADR_SEL pulled to high, low, or left open, the
MSP 34x1G responds to different device addresses. A
device address pair is defined as a write address and a
read address (see Table 3–1).
3.1.1. Internal Hardware Error Handling
In case of any hardware problems (e.g. interruption of
the power supply of the MSP), the MSP’s wait period is
extended to 1.8 ms. After this time period elapses, the
MSP releases data and clock lines.
Writing is done by sending the write device address,
followed by the subaddress byte, two address bytes,
and two data bytes.
Indication and solving the error status:
Reading is done by sending the write device address,
followed by the subaddress byte and two address
bytes. Without sending a stop condition, reading of the
addressed data is completed by sending the device
read address and reading two bytes of data.
To indicate the error status, the remaining acknowledge bits of the actual I2C-protocol will be left high.
Additionally, bit[14] of CONTROL is set to one. The
MSP can then be reset via the I2C bus by transmitting
the RESET condition to CONTROL.
Refer to Section 3.1.3. for the I2C bus protocol and to
Section 3.4. “Programming Tips” on page 45 for proposals of MSP 34x1G I2C telegrams. See Table 3–2
for a list of available subaddresses.
Indication of reset:
Besides the possibility of hardware reset, the MSP can
also be reset by means of the RESET bit in the CONTROL register by the controller via I2C bus.
Any reset, even caused by an unstable reset line etc.,
is indicated in bit[15] of CONTROL.
A general timing diagram of the I2C bus is shown in
Fig. 4–27 on page 69.
Due to the architecture of the MSP 34x1G, the IC cannot react immediately to an I2C request. The typical
Table 3–1: I2C Bus Device Addresses
ADR_SEL
Low
(connected to DVSS)
High
(connected to DVSUP)
Left Open
Mode
Write
Read
Write
Read
Write
Read
MSP device address
80hex
81hex
84hex
85hex
88hex
89hex
Table 3–2: I2C Bus Subaddresses
Name
Binary Value
Hex Value
Mode
Function
CONTROL
0000 0000
00
Read/Write
Write: Software reset of MSP (see Table 3–3)
Read: Hardware error status of MSP
WR_DEM
0001 0000
10
Write
write address demodulator
RD_DEM
0001 0001
11
Write
read address demodulator
WR_DSP
0001 0010
12
Write
write address DSP
RD_DSP
0001 0011
13
Write
read address DSP
Micronas
17
MSP 34x1G
PRELIMINARY DATA SHEET
3.1.2. Description of CONTROL Register
Table 3–3: CONTROL as a Write Register
Name
Subaddress
Bit[15] (MSB)
Bits[14:0]
CONTROL
00hex
1 : RESET
0 : normal
0
Table 3–4: CONTROL as a Read Register
Name
Subaddress
Bit[15] (MSB)
Bit[14]
Bits[13:0]
CONTROL
00hex
RESET status after last reading of
CONTROL:
Internal hardware status:
0 : no error occured
1 : internal error occured
not of interest
0 : no reset occured
1 : reset occured
Reading of CONTROL will reset the bits[15,14] of CONTROL. After Power-on, bit[15] of CONTROL will be set; it must be
read once to be reset.
3.1.3. Protocol Description
Write to DSP or Demodulator
S
Wait
write
device
address
ACK sub-addr ACK addr-byte ACK addr-byte ACK data-byte ACK data-byte ACK P
high
low
high
low
Read from DSP or Demodulator
S
Wait
write
device
address
ACK sub-addr ACK addr-byte ACK addr-byte ACK S
high
low
read
device
address
Wait
ACK data-byte- ACK data-byte NAK P
high
low
Write to Control Register
S
Wait
write
device
address
ACK sub-addr ACK data-byte ACK data-byte ACK P
high
low
Read from Control Register
S
Wait
write
device
address
ACK
00hex
ACK S
read
device
address
Wait
ACK data-byte- ACK data-byte NAK P
high
low
I2C-Bus Start Condition from master
I2C-Bus Stop Condition from master
Acknowledge-Bit: LOW on I2C_DA from slave (= MSP, light gray) or master (= controller, dark gray)
Not Acknowledge-Bit: HIGH on I2C_DA from master (dark gray) to indicate ‘End of Read’
or from MSP indicating internal error state
Wait = I2C-Clock line is held low, while the MSP is processing the I2C command.
This waiting time is max. 1 ms
Note: S =
P=
ACK =
NAK =
18
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
1
0
I2C_DA
S
P
I2C_CL
Fig. 3–1: I2C bus protocol (MSB first; data must be stable while clock is high)
3.1.4. Proposals for General MSP 34x1G
I2C Telegrams
3.2. Start-Up Sequence:
Power-Up and I2C-Controlling
3.1.4.1. Symbols
After POWER-ON or RESET (see Fig. 4–26), the IC is
in an inactive state. All registers are in the Reset position (see Table 3–5 and Table 3–6), the analog outputs
are muted. The controller has to initialize all registers
for which a non-default setting is necessary.
write device address (80hex, 84hex or 88hex)
read device address (81hex, 85hex or 89hex)
Start Condition
Stop Condition
Address Byte
Data Byte
daw
dar
<
>
aa
dd
3.3. MSP 34x1G Programming Interface
3.3.1. User Registers Overview
3.1.4.2. Write Telegrams
<daw 00 d0 00>
<daw 10 aa aa dd dd>
<daw 12 aa aa dd dd>
write to CONTROL register
write data into demodulator
write data into DSP
3.1.4.3. Read Telegrams
The MSP 34x1G is controlled by means of user registers. The complete list of all user registers is given in
Table 3–5 and Table 3–6. The registers are partitioned
into the Demodulator section (subaddress 10hex for
writing, 11hex for reading) and the Baseband Processing sections (subaddress 12hex for writing, 13hex for
reading).
<daw 00 <dar dd dd>
read data from
CONTROL register
<daw 11 aa aa <dar dd dd> read data from demodulator
<daw 13 aa aa <dar dd dd> read data from DSP
Write and read registers are 16 bit wide, whereby the
MSB is denoted bit[15]. Transmissions via I2C bus have
to take place in 16-bit words (two byte transfers, with the
most significant byte transferred first). All write registers,
except the demodulator write registers are readable.
3.1.4.4. Examples
Unused parts of the 16-bit write registers must be zero.
Addresses not given in this table must not be
accessed.
<80
<80
<80
<80
<80
00
00
10
11
12
80
00
00
02
00
00>
RESET MSP statically
00>
Clear RESET
20 00 03>
Set demodulator to stand. 03hex
00 <81 dd dd> Read STATUS
08 01 20>
Set loudspeaker channel
source to NICAM and
Matrix to STEREO
For reasons of software compatibility to the
MSP 34xxD, a Manual/Compatibility Mode is available.
More read and write registers together with a detailed
description can be found in “Appendix B: Manual/Compatibility Mode” on page 85.
More examples of typical application protocols are
listed in Section 3.4. “Programming Tips” on page 45.
Micronas
19
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–5: List of MSP 34x1G Write Registers
Write Register
Address
(hex)
Bits
Description and Adjustable Range
Reset
See
Page
Initial Programming of the Demodulator
00 00
24
00 00
26
00 00
27
32
I2C Subaddress = 10hex ; Registers are not readable
STANDARD SELECT
00 20
[15:0]
MODUS
00 30
[15:0]
Demodulator, Automatic and
I2S CONFIGURATION
00 40
[15:0]
Configuration of I2S options
2
I2 S
options
2
I C Subaddress = 12hex ; Registers are all readable by using I C Subaddress = 13hex
Volume loudspeaker channel
00 00
Volume / Mode loudspeaker channel
Balance loudspeaker channel [L/R]
00 01
Balance mode loudspeaker
[15:8]
[+12 dB ... −114 dB, MUTE]
MUTE
[7:0]
1/8 dB Steps,
Reduce Volume / Tone Control / Compromise /
Dynamic
00hex
[15:8]
[0...100 / 100% and 100 / 0...100%]
[−127...0 / 0 and 0 / −127...0 dB]
100%/100%
[7:0]
[Linear / logarithmic mode]
linear mode
33
Bass loudspeaker channel
00 02
[15:8]
[+20 dB ... −12 dB]
0 dB
34
Treble loudspeaker channel
00 03
[15:8]
[+15 dB ... −12 dB]
0 dB
35
Loudness loudspeaker channel
00 04
[15:8]
[0 dB ... +17 dB]
0 dB
36
[7:0]
[NORMAL, SUPER_BASS]
NORMAL
[15:8]
[−100%...OFF...+100%]
OFF
[7:0]
[SBE, SBE+PSE]
SBE+PSE
[15:8]
[+12 dB ... −114 dB, MUTE]
MUTE
[7:0]
1/8 dB Steps, Reduce Volume / Tone Control
00hex
[15:8]
[+12 dB ... −114 dB, MUTE]
MUTE
40
[15:8]
2
[FM/AM, NICAM, SCART, I S1, I S2]
FM/AM
31
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
[15:8]
[FM/AM, NICAM, SCART, I2S1, I2S2]
FM/AM
31
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
[15:8]
[FM/AM, NICAM, SCART, I2S1, I2S2]
FM/AM
31
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
Loudness filter characteristic
Spatial effect strength loudspeaker ch.
00 05
Spatial effect mode/customize
Volume headphone channel
00 06
Volume / Mode headphone channel
Volume SCART1 output channel
Loudspeaker source select
00 07
00 08
Loudspeaker channel matrix
Headphone source select
00 09
Headphone channel matrix
SCART1 source select
00 0A
SCART1 channel matrix
2
I S source select
00 0B
I2S channel matrix
Quasi-peak detector source select
00 0C
Quasi-peak detector matrix
2
2
2
37
32
[15:8]
[FM/AM, NICAM, SCART, I S1, I S2]
FM/AM
31
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
FM/AM
31
I2S1, I2S2]
[15:8]
[FM/AM, NICAM, SCART,
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
Prescale SCART input
00 0D
[15:8]
[00hex ... 7Fhex]
00hex
30
Prescale FM/AM
00 0E
[15:8]
[00hex ... 7Fhex]
00hex
29
[7:0]
[NO_MAT, GSTEREO, KSTEREO]
NO_MAT
30
00 10
[15:8]
[00hex ... 7Fhex] (MSP 3411G, MSP 3451G only)
00hex
30
Prescale I S2
00 12
[15:8]
[00hex ... 7Fhex]
10hex
30
ACB : SCART Switches a. D_CTR_I/O
00 13
[15:0]
Bits [15..0]
00hex
41
Beeper
00 14
[15:0]
[00hex ... 7Fhex]/[00hex ... 7Fhex]
00/00hex
41
Prescale I2S1
00 16
[15:8]
[00hex ... 7Fhex]
10hex
30
FM matrix
Prescale NICAM
2
20
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–5: List of MSP 34x1G Write Registers, continued
Write Register
Address
(hex)
Bits
Description and Adjustable Range
Reset
See
Page
Mode tone control
00 20
[15:8]
[BASS/TREBLE, EQUALIZER]
BASS/TREB
34
Equalizer loudspeaker ch. band 1
00 21
[15:8]
[+12 dB ... −12 dB]
0 dB
35
Equalizer loudspeaker ch. band 2
00 22
[15:8]
[+12 dB ... −12 dB]
0 dB
35
Equalizer loudspeaker ch. band 3
00 23
[15:8]
[+12 dB ... −12 dB]
0 dB
35
Equalizer loudspeaker ch. band 4
00 24
[15:8]
[+12 dB ... −12 dB]
0 dB
35
Equalizer loudspeaker ch. band 5
00 25
[15:8]
[+12 dB ... −12 dB]
0 dB
35
Automatic Volume Correction
00 29
[15:8]
[off, on, decay time]
off
33
Subwoofer level adjust
00 2C
[15:8]
[+12 dB ... −30 dB, mute]
0 dB
38
Subwoofer corner frequency
00 2D
[15:8]
[50 Hz ... 400 Hz]
00hex
38
[7:0]
[off, on, MDB to Main]
off
38
[15:8]
[0...100 / 100% and 100 / 0...100%]
[−127...0 / 0 and 0 / −127...0 dB]
100%/100%
33
[7:0]
[Linear mode / logarithmic mode]
linear mode
Subwoofer complementary high-pass
Balance headphone channel [L/R]
00 30
Balance mode headphone
Bass headphone channel
00 31
[15:8]
[+20 dB ... −12 dB]
0 dB
34
Treble headphone channel
00 32
[15:8]
[+15 dB ... −12 dB]
0 dB
35
Loudness headphone channel
00 33
[15:8]
[0 dB ... +17 dB]
0 dB
36
[7:0]
[NORMAL, SUPER_BASS]
NORMAL
Loudness filter characteristic
Volume SCART2 output channel
00 40
[15:8]
[+12 dB ... −114 dB, MUTE]
00hex
40
SCART2 source select
00 41
[15:8]
[FM, NICAM, SCART, I2S1, I2S2]
FM
31
[7:0]
[SOUNDA, SOUNDB, STEREO, MONO...]
SOUNDA
31
SCART2 channel matrix
Virtual Surround OFF/ON switch
00 48
[15:8]
[OFF/ON]
00hex
42
Virtual Surround spatial effect strength
00 49
[15:8]
[0% - 100%]
00hex
42
Virtual Surround 3D effect strength
00 4A
[15:8]
[0% - 100%]
00hex
42
Virtual Surround mode
00 4B
[15:0]
[PANORAMA/3D-PANORAMA]
00hex
42
Noise generator
00 4D
[15:0]
[OFF/ON, Noise_L, Noise_C, Noise_R, Noise_S]
00hex
43
MDB Effect Strength
00 68
[15:8]
[0 dB ... 127 dB, off]
off
38
MDB Amplitude Limit
00 69
[15:8]
[0 dBFS... -32 dBFS]
0 dBFS
38
MDB Harmonic Content
00 6A
[15:8]
[0% ... 100%]
0%
39
MDB Low Pass Corner Frequency
00 6B
[15:8]
[50 Hz ... 300 Hz]
0 Hz
39
MDB High Pass Corner Frequency
00 6C
[15:8]
[20 Hz ... 300 Hz]
0 Hz
39
Micronas
21
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–6: List of MSP 34x1G Read Registers
Read Register
Address
(hex)
Bits
Description and Adjustable Range
See
Page
I2C Subaddress = 11hex ; Registers are not writable
STANDARD RESULT
00 7E
[15:0]
Result of Automatic Standard Detection (see Table 3–8)
28
STATUS
02 00
[15:0]
Monitoring of internal settings e.g. Stereo, Mono, Mute etc. .
28
2
I C Subaddress = 13hex ; Registers are not writable
Quasi peak readout left
00 19
[15:0]
[00hex ... 7FFFhex] 16 bit two’s complement
44
Quasi peak readout right
00 1A
[15:0]
[00hex ... 7FFFhex] 16 bit two’s complement
44
MSP hardware version code
00 1E
[15:8]
[00hex ... FFhex]
44
[7:0]
[00hex ... FFhex]
44
[15:8]
[00hex ... FFhex]
44
[7:0]
[00hex ... FFhex]
44
MSP major revision code
MSP product code
MSP ROM version code
22
00 1F
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2. Description of User Registers
Table 3–7: Standard Codes for STANDARD SELECT register
MSP Standard Code
(Data in hex)
TV Sound Standard
Sound Carrier
Frequencies in MHz
MSP 34x1G Version
Automatic Standard Detection
00 01
Starts Automatic Standard Detection and sets
detected standard
all
Standard Selection
00 02
M-Dual FM-Stereo
4.5/4.724212
3401, -11, -21, -41, -51
00 03
B/G -Dual
FM-Stereo1)
5.5/5.7421875
3401, -11, -51
00 04
D/K1-Dual FM-Stereo2)
6.5/6.2578125
00 05
D/K2-Dual FM-Stereo2)
6.5/6.7421875
3)
00 06
D/K -FM-Mono with HDEV3 , not detectable by Automatic
Standard Detection,
HDEV33) SAT-Mono (i.e. Eutelsat, s. Table 6–18)
6.5
00 07
D/K3-Dual FM-Stereo
6.5/5.7421875
00 08
B/G -NICAM-FM1)
5.5/5.85
00 09
L -NICAM-AM
6.5/5.85
00 0A
I -NICAM-FM
6.0/6.552
00 0B
D/K -NICAM-FM2)
6.5/5.85
00 0C
D/K -NICAM-FM with HDEV24), not detectable by Automatic
Standard Detection, for China
6.5/5.85
00 0D
D/K -NICAM-FM with HDEV33), not detectable by Automatic
Standard Detection, for China
6.5/5.85
00 20
BTSC-Stereo
4.5
3421, -41, -51
00 21
BTSC-Mono + SAP
00 30
M-EIA-J Japan Stereo
4.5
3421, -41, -51
00 40
FM-Stereo Radio with 75 µs Deemphasis
10.7
3421, -41, -51
00 50
SAT-Mono (s. Table 6–18)
6.5
3401, -11, -51
00 51
SAT-Stereo (s. Table 6–18)
7.02/7.20
00 60
SAT ADR (Astra Digital Radio)
6.12
1)
2)
3)
4)
3411, -51
In case of Automatic Sound Select, the B/G-codes 3hex and 8hex are equivalent.
In case of Automatic Sound Select, the D/K-codes 4hex, 5hex, 7hexand Bhex are equivalent.
HDEV3: Max. FM deviation must not exceed 540 kHz
HDEV2: Max. FM deviation must not exceed 360 kHz
Micronas
23
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2.1. STANDARD SELECT Register
3.3.2.2. Refresh of STANDARD SELECT Register
The TV sound standard of the MSP 34x1G demodulator is determined by the STANDARD SELECT register.
There are two ways to use the STANDARD SELECT
register:
A general refresh of the STANDARD SELECT register
is not allowed. However, the following method
enables watching the MSP 34x1G “alive” status and
detection of accidental resets (only versions B6 and
later):
– Setting up the demodulator for a TV sound standard
by sending the corresponding standard code with a
single I2C bus transmission.
– Starting the Automatic Standard Detection for terrestrial TV standards. This is the most comfortable
way to set up the demodulator. Within 0.5 s, the
detection and setup of the actual TV sound standard
is performed. The detected standard can be read
out of the STANDARD RESULT register by the control processor. This feature is recommended for the
primary setup of a TV set. Outputs should be muted
during Automatic Standard Detection.
– After Power-on, bit[15] of CONTROL will be set; it
must be read once to enable the reset-detection
feature.
– Reading of the CONTROL register and checking
the reset indicator bit[15] .
– If bit[15] is “0”, any refresh of the STANDARD
SELECT register is not allowed.
– If bit[15] is “1”, indicating a reset, a refresh of the
STANDARD SELECT register and all other MSPG
registers is required.
The Standard Codes are listed in Table 3–7.
3.3.2.3. STANDARD RESULT Register
Selecting a TV sound standard via the STANDARD
SELECT register initializes the demodulator. This
includes: AGC-settings and carrier mute, tuning frequencies, FIR-filter settings, demodulation mode (FM,
AM, NICAM), deemphasis and identification mode.
TV stereo sound standards that are unavailable for a
specific MSP version are processed in analog mono
sound of the standard. In that case, stereo or bilingual
processing will not be possible.
For a complete setup of the TV sound processing from
analog IF input to the source selection, the transmissions as shown in Section 3.5. are necessary.
For reasons of software compatibility to the
MSP 34xxD, a Manual/Compatibility mode is available.
A detailed description of this mode can be found on
page 85.
If Automatic Standard Detection is selected in the
STANDARD SELECT register, status and result of the
Automatic Standard Detection process can be read out
of the STANDARD RESULT register. The possible
results are based on the mentioned Standard Code
and are listed in Table 3–8.
In cases where no sound standard has been detected
(no standard present, too much noise, strong interferers, etc.) the STANDARD RESULT register contains
00 00hex. In that case, the controller has to start further
actions (for example set the standard according to a
preference list or by manual input).
As long as the STANDARD RESULT register contains
a value greater than 07 FFhex, the Automatic Standard
Detection is still active. During this period, the MODUS
and STANDARD SELECT register must not be written.
The STATUS register will be updated when the Automatic Standard Detection has finished.
If a present sound standard is unavailable for a specific MSP-version, it detects and switches to the analog mono sound of this standard.
Example:
The MSPs 3421G and 3441G will detect a B/G-NICAM
signal as standard 3 and will switch to the analog FMMono sound.
24
Micronas
PRELIMINARY DATA SHEET
MSP 34x1G
Table 3–8: Results of the Automatic Standard
Detection
Broadcasted Sound
Standard
STANDARD RESULT Register
Read 007Ehex
Automatic Standard
Detection could not
find a sound standard
0000hex
B/G-FM
0003hex
B/G-NICAM
0008hex
I
000Ahex
FM-Radio
0040hex
M-Korea
M-Japan
M-BTSC
0002hex (if MODUS[14,13]=00)
0020hex (if MODUS[14,13]=01)
0030hex (if MODUS[14,13]=10)
L-AM
D/K1
D/K2
D/K3
0009hex (if MODUS[12]=0)
L-NICAM
D/K-NICAM
0009hex (if MODUS[12]=0)
0004hex (if MODUS[12]=1)
000Bhex (if MODUS[12]=1)
Automatic Standard
Detection still active
Micronas
>07FFhex
25
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2.4. Write Registers on I2C Subaddress 10hex
Table 3–9: Write Registers on I2C Subaddress 10hex
Register
Address
Function
Name
00 20hex
STANDARD SELECTION Register
STANDARD_SEL
Defines TV Sound or FM-Radio Standard
bit[15:0]
00 30hex
00 01hex
00 02hex
...
00 60hex
start Automatic Standard Detection
Standard Codes (see Table 3–7)
MODUS Register
MODUS
Preference in Automatic Standard Detection:
bit[15]
0
undefined, must be 0
0
1
2
3
detected 4.5 MHz carrier is interpreted as:1)
standard M (Korea)
standard M (BTSC)
standard M (Japan)
chroma carrier (M/N standards are ignored)
0
1
detected 6.5 MHz carrier is interpreted as:1)
standard L (SECAM)
standard D/K1, D/K2, D/K3, or D/K NICAM
bit[14:13]
bit[12]
General MSP 34x1G Options
bit[11:9]
0
undefined, must be 0
bit[8]
0/1
ANA_IN1+/ANA_IN2+; select analog sound IF input pin
bit[7]
0/1
active/tristate state of audio clock output pin
AUD_CL_OUT
bit[6]
0
1
bit[5]
0/1
master/slave mode of I2S interface (must be set to 0
(= Master) in case of NICAM mode)
bit[4]
0/1
active/tristate state of I2S output pins
bit[3]
0
1
1)
26
I2S word strobe alignment
WS changes at data word boundary
WS changes one clock cycle in advance
state of digital output pins D_CTR_I/O_0 and _1
active: D_CTR_I/O_0 and _1 are output pins
(can be set by means of the ACB register.
see also: MODUS[1])
tristate: D_CTR_I/O_0 and _1 are input pins
(level can be read out of STATUS[4,3])
bit[2]
0
undefined, must be 0
bit[1]
0/1
disable/enable STATUS change indication by means of
the digital I/O pin D_CTR_I/O_1
Necessary condition: MODUS[3] = 0 (active)
bit[0]
0/1
off/on: Automatic Sound Select
Valid at the next start of Automatic Standard Detection.
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–9: Write Registers on I2C Subaddress 10hex, continued
Register
Address
Function
Name
00 40hex
I2S CONFIGURATION Register
I2S_CONFIG
bit[15:1]
0
not used, must be set to “0”
0
1
I2S_CL frequency and I2S data sample length for
master mode
2 x 16 bit (1.024 MHz)
2 x 32 bit (2.048 MHz)
bit[0]
Micronas
27
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2.5. Read Registers on I2C Subaddress 11hex
Table 3–10: Read Registers on I2C Subaddress 11hex
Register
Address
Function
Name
00 7Ehex
STANDARD RESULT Register
STANDARD_RES
Readback of the detected TV Sound or FM-Radio Standard
bit[15:0]
00 00hex
Automatic Standard Detection could not find
a sound standard
MSP Standard Codes (see Table 3–8)
00 02hex
...
00 40hex
>07 FFhex Automatic Standard Detection still active
02 00hex
STATUS Register
STATUS
Contains all user relevant internal information about the status of the MSP
bit[15:10]
undefined
bit[8]
0/1
“1” indicates bilingual sound mode or SAP present
(internally evaluated from received analog or digital identification signals)
bit[7]
0/1
“1” indicates independent mono sound (only for
NICAM)
bit[6]
0/1
mono/stereo indication
(internally evaluated from received analog or digital identification signals)
bit[5,9]
00
01
10
11
analog sound standard (FM or AM) active
this pattern will not occur
digital sound (NICAM) available
bad reception condition of digital sound (NICAM) due
to:
a. high error rate
b. unimplemented sound code
c. data transmission only
bit[4]
0/1
low/high level of digital I/O pin D_CTR_I/O_1
bit[3]
0/1
low/high level of digital I/O pin D_CTR_I/O_0
bit[2]
0
1
detected secondary carrier (2nd A2 or SAP sub-carrier)
no secondary carrier detected
bit[1]
0
1
detected primary carrier (Mono or MPX carrier)
no primary carrier detected
bit[0]
undefined
If STATUS change indication is activated by means of MODUS[1]: Each
change in the STATUS register sets the digital I/O pin D_CTR_I/O_1 to high
level. Reading the STATUS register resets D_CTR_I/O_1.
28
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2.6. Write Registers on I2C Subaddress 12hex
Table 3–11: Write Registers on I2C Subaddress 12hex
Register
Address
Function
Name
PREPROCESSING
00 0Ehex
FM/AM Prescale
bit[15:8]
00hex
...
7Fhex
00hex
PRE_FM
Defines the input prescale gain for the demodulated
FM or AM signal
off (RESET condition)
For all FM modes except satellite FM and AM-mode, the combinations of prescale value and FM deviation listed below lead to internal full scale.
FM mode
bit[15:8]
7Fhex
48hex
30hex
24hex
18hex
13hex
28 kHz FM deviation
50 kHz FM deviation
75 kHz FM deviation
100 kHz FM deviation
150 kHz FM deviation
180 kHz FM deviation (limit)
FM high deviation mode (HDEV2, MSP Standard Code = Chex)
bit[15:8]
30hex
14hex
150 kHz FM deviation
360 kHz FM deviation (limit)
FM very high deviation mode (HDEV3, MSP Standard Code = 6 and Dhex)
bit[15:8]
20hex
1Ahex
450 kHz FM deviation
540 kHz FM deviation (limit)
Satellite FM with adaptive deemphasis
bit[15:8]
10hex
recommendation
AM mode (MSP Standard Code = 9)
bit[15:8]
7Chex
recommendation for SIF input levels from
0.1 Vpp to 0.8 Vpp
(Due to the AGC being switched on, the AM-output level
remains stable and independent of the actual SIF-level in
the mentioned input range)
Micronas
29
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
(continued)
FM Matrix Modes
FM_MATRIX
00 0Ehex
Defines the dematrix function for the demodulated FM signal
bit[7:0]
00hex
01hex
02hex
03hex
04hex
no matrix (used for bilingual and unmatrixed stereo sound)
German stereo (Standard B/G)
Korean stereo (also used for BTSC, EIA-J and FM Radio)
sound A mono (left and right channel contain the mono
sound of the FM/AM mono carrier)
sound B mono
In case of Automatic Sound Select = on, the FM Matrix Mode is set automatically. Writing to the FM/AM prescale register (00 0Ehex high part) is still allowed.
In order not to disturb the automatic process, the low part of any I2C transmission to this register is ignored. Therefore, any FM-Matrix readback values may
differ from data written previously.
In case of Automatic Sound Select = off, the FM Matrix Mode must be set as
shown in Table 6–17 of Appendix B.
To enable a Forced Mono Mode set A2 THRESHOLD as described in
Section 6.3.2.on page 89
00 10hex
NICAM Prescale
PRE_NICAM
Defines the input prescale value for the digital NICAM signal
bit[15:8]
00hex ... 7Fhex prescale gain
examples:
00hex
off
0 dB gain
20hex
9 dB gain (recommendation)
5Ahex
+12 dB gain (maximum gain)
7Fhex
00 16hex
00 12hex
I2S1 Prescale
I2S2 Prescale
PRE_I2S1
PRE_I2S2
Defines the input prescale value for digital I2S input signals
bit[15:8]
00hex ... 7Fhex prescale gain
examples:
00hex
off
0 dB gain (recommendation)
10hex
+18 dB gain (maximum gain)
7Fhex
00 0Dhex
SCART Input Prescale
PRE_SCART
Defines the input prescale value for the analog SCART input signal
bit[15:8]
00hex ... 7Fhex prescale gain
examples:
00hex
off
0 dB gain (2 VRMS input leads to digital full scale)
19hex
Due to the Dolby requirements, this is the maximum
value allowed to prohibit clipping of a 2 VRMS input signal.
+14 dB gain (400 mVRMS input leads to digital full scale)
7Fhex
30
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
SOURCE SELECT AND OUTPUT CHANNEL MATRIX
00 08hex
00 09hex
00 0Ahex
00 41hex
00 0Bhex
00 0Chex
Source for:
Loudspeaker Output
Headphone Output
SCART1 DA Output
SCART2 DA Output
I2S Output
Quasi-Peak Detector
bit[15:8]
0
“FM/AM”: demodulated FM or AM mono signal
1
“Stereo or A/B”: demodulator Stereo or A/B signal
(in manual mode, this source is identical to the NICAM
source in the MSP 3410D)
3
“Stereo or A”: demodulator Stereo Sound or
Language A (only defined for Automatic Sound Select)
4
“Stereo or B”: demodulator Stereo Sound or
Language B (only defined for Automatic Sound Select)
2
SCART input
5
I2S1 input
6
I2S2 input
SRC_MAIN
SRC_AUX
SRC_SCART1
SRC_SCART2
SRC_I2S
SRC_QPEAK
For demodulator sources, see Table 2–2.
00 08hex
00 09hex
00 0Ahex
00 41hex
00 0Bhex
00 0Chex
Matrix Mode for:
Loudspeaker Output
Headphone Output
SCART1 DA Output
SCART2 DA Output
I2S Output
Quasi-Peak Detector
bit[7:0]
MAT_MAIN
MAT_AUX
MAT_SCART1
MAT_SCART2
MAT_I2S
MAT_QPEAK
Sound A Mono (or Left Mono)
00hex
Sound B Mono (or Right Mono)
10hex
Stereo (transparent mode)
20hex
30hex
Mono (sum of left and right inputs divided by 2)
special modes are available (see Section 6.5.1. on page 97)
In Automatic Sound Select mode, the demodulator source channels are set
according to Table 2–2. Therefore, the matrix modes of the corresponding output channels should be set to “Stereo” (transparent).
Micronas
31
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
LOUDSPEAKER AND HEADPHONE PROCESSING
00 00hex
00 06hex
Volume Loudspeaker
Volume Headphone
bit[15:8]
volume table with 1 dB step size
+12 dB (maximum volume)
7Fhex
+11 dB
7Ehex
...
74hex
+1 dB
0 dB
73hex
−1 dB
72hex
...
−113 dB
02hex
−114 dB
01hex
00hex
Mute (reset condition)
Fast Mute (needs about 75 ms until the signal is comFFhex
pletely ramped down)
bit[7:5]
higher resolution volume table
0
+0 dB
1
+0.125 dB increase in addition to the volume table
...
7
+0.875 dB increase in addition to the volume table
bit[4]
0
bit[3:0]
clipping mode
0
reduce volume
1
reduce tone control
2
compromise
3
dynamic
VOL_MAIN
VOL_AUX
must be set to 0
With large scale input signals, positive volume settings may lead to signal clipping.
The MSP 34x1G loudspeaker and headphone volume function is divided into a
digital and an analog section. With Fast Mute, volume is reduced to mute position by digital volume only. Analog volume is not changed. This reduces any
audible DC plops. To turn volume on again, the volume step that has been used
before Fast Mute was activated must be transmitted.
If the clipping mode is set to “reduce volume”, the following rule is used: To prevent severe clipping effects with bass, treble, or equalizer boosts, the internal
volume is automatically limited to a level where, in combination with either bass,
treble, or equalizer setting, the amplification does not exceed 12 dB.
If the clipping mode is “reduce tone control”, the bass or treble value is
reduced if amplification exceeds 12 dB. If the equalizer is switched on, the gain
of those bands is reduced, where amplification together with volume exceeds
12 dB.
If the clipping mode is “compromise”, the bass or treble value and volume are
reduced half and half if amplification exceeds 12 dB. If the equalizer is switched
on, the gain of those bands is reduced half and half, where amplification
together with volume exceeds 12 dB.
If the clipping mode is “dynamic”, volume is reduced automatically if the signal
amplitudes would exceed −2 dBFS within the IC. For operation of MDB, dynamic mode must be switched on.
32
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 29hex
Automatic Volume Correction (AVC) Loudspeaker Channel
AVC
00 01hex
00 30hex
bit[15:12] 00hex
08hex
AVC off (and reset internal variables)
AVC on
bit[11:8]
8 sec decay time
4 sec decay time
2 sec decay time
20 ms decay time (should be used for approx. 100 ms
after channel change)
08hex
04hex
02hex
01hex
Balance Loudspeaker Channel
Balance Headphone Channel
bit[15:8]
Linear Mode
Left muted, Right 100%
7Fhex
Left 0.8%, Right 100%
7Ehex
...
01hex
Left 99.2%, Right 100%
Left 100%, Right 100%
00hex
Left 100%, Right 99.2%
FFhex
...
Left 100%, Right 0.8%
82hex
81hex
Left 100%, Right muted
bit[15:8]
Logarithmic Mode
7Fhex
Left −127 dB, Right 0 dB
Left −126 dB, Right 0 dB
7Ehex
...
Left −1 dB, Right 0 dB
01hex
00hex
Left 0 dB, Right 0 dB
Left 0 dB, Right −1 dB
FFhex
...
Left 0 dB, Right −127 dB
81hex
Left 0 dB, Right −128 dB
80hex
bit[7:0]
Balance Mode
00hex
linear
logarithmic
01hex
BAL_MAIN
BAL_AUX
Positive balance settings reduce the left channel without affecting the right
channel; negative settings reduce the right channel leaving the left channel
unaffected.
Micronas
33
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 20hex
Tone Control Mode Loudspeaker Channel
TONE_MODE
bit[15:8]
00hex
FFhex
bass and treble is active
equalizer is active
Defines whether Bass/Treble or Equalizer is activated for the loudspeaker channel. Bass and Equalizer cannot work simultaneously. If Equalizer is used, Bass,
and Treble coefficients must be set to zero and vice versa.
00 02hex
00 31hex
Bass Loudspeaker Channel
Bass Headphone Channel
bit[15:8]
BASS_MAIN
BASS_AUX
extended range
+20 dB
7Fhex
+18 dB
78hex
70hex
+16 dB
+14 dB
68hex
normal range
+12 dB
60hex
+11 dB
58hex
...
08hex
+1 dB
0 dB
00hex
−1 dB
F8hex
...
−11 dB
A8hex
−12 dB
A0hex
Higher resolution is possible: an LSB step in the normal range results in a gain
step of about 1/8 dB, in the extended range about 1/4 dB.
With positive bass settings, internal clipping may occur even with overall volume
less than 0 dB. This will lead to a clipped output signal. Therefore, it is not recommended to set bass to a value that, in conjunction with volume, would result
in an overall positive gain.
34
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 03hex
00 32hex
Treble Loudspeaker Channel
Treble Headphone Channel
TREB_MAIN
TREB_AUX
bit[15:8]
78hex
70hex
...
08hex
00hex
F8hex
...
A8hex
A0hex
+15 dB
+14 dB
+1 dB
0 dB
−1 dB
−11 dB
−12 dB
Higher resolution is possible: an LSB step results in a gain step of about 1/8 dB.
With positive treble settings, internal clipping may occur even with overall volume less than 0 dB. This will lead to a clipped output signal. Therefore, it is not
recommended to set treble to a value that, in conjunction with volume, would
result in an overall positive gain.
00 21hex
00 22hex
00 23hex
00 24hex
00 25hex
Equalizer Loudspeaker Channel Band 1 (below 120 Hz)
Equalizer Loudspeaker Channel Band 2 (center: 500 Hz)
Equalizer Loudspeaker Channel Band 3 (center: 1.5 kHz)
Equalizer Loudspeaker Channel Band 4 (center: 5 kHz)
Equalizer Loudspeaker Channel Band 5 (above: 10 kHz)
bit[15:8]
60hex
58hex
...
08hex
00hex
F8hex
...
A8hex
A0hex
EQUAL_BAND1
EQUAL_BAND2
EQUAL_BAND3
EQUAL_BAND4
EQUAL_BAND5
+12 dB
+11 dB
+1 dB
0 dB
−1 dB
−11 dB
−12 dB
Higher resolution is possible: an LSB step results in a gain step of about 1/8 dB.
With positive equalizer settings, internal clipping may occur even with overall
volume less than 0 dB. This will lead to a clipped output signal. Therefore, it is
not recommended to set equalizer bands to a value that, in conjunction with volume, would result in an overall positive gain.
Micronas
35
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 04hex
00 33hex
Loudness Loudspeaker Channel
Loudness Headphone Channel
LOUD_MAIN
LOUD_AUX
bit[15:8]
Loudness Gain
+17 dB
44hex
+16 dB
40hex
...
04hex
+1 dB
+0.75 dB
03hex
+0.5 dB
02hex
+0.25 dB
01hex
0 dB
00hex
bit[7:0]
Loudness Mode
00hex
normal (constant volume at 1 kHz)
Super Bass (constant volume at 2 kHz)
04hex
Higher resolution of Loudness Gain is possible: An LSB step results in a gain
step of about 1/4 dB.
Loudness increases the volume of low- and high-frequency signals, while keeping the amplitude of the reference frequency constant. The intended loudness
has to be set according to the actual volume setting. Because loudness introduces gain, it is not recommended to set loudness to a value that, in conjunction
with volume, would result in an overall positive gain.
The corner frequency for bass amplification can be set to two different values. In
Super Bass mode, the corner frequency is shifted up. The point of constant volume is shifted from 1 kHz to 2 kHz.
36
Micronas
PRELIMINARY DATA SHEET
MSP 34x1G
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 05hex
Spatial Effects Loudspeaker Channel
SPAT_MAIN
bit[15:8]
Effect Strength
Enlargement 100%
7Fhex
Enlargement 50%
3Fhex
...
01hex
Enlargement 1.5%
Effect off
00hex
reduction 1.5%
FFhex
...
reduction 50%
C0hex
reduction 100%
80hex
bit[7:4]
Spatial Effect Mode
0hex
Stereo Basewidth Enlargement (SBE) and
Pseudo Stereo Effect (PSE). (Mode A)
Stereo Basewidth Enlargement (SBE) only. (Mode B)
2hex
bit[3:0]
Spatial Effect High-Pass Gain
0hex
max. high-pass gain
2/3 high-pass gain
2hex
4hex
1/3 high-pass gain
min. high-pass gain
6hex
automatic
8hex
Spatial effects should not be used together with 3D-PANORAMA or
PANORAMA.
There are several spatial effect modes available:
In mode A (low byte = 00hex), the spatial effect depends on the source mode. If
the incoming signal is mono, Pseudo Stereo Effect is active; for stereo signals,
Pseudo Stereo Effect and Stereo Basewidth Enlargement is effective. The
strength of the effect is controllable by the upper byte. A negative value reduces
the stereo image. A strong spatial effect is recommended for small TV sets
where loudspeaker spacing is rather close. For large screen TV sets, a more
moderate spatial effect is recommended.
In mode B, only Stereo Basewidth Enlargement is effective. For mono input signals, the Pseudo Stereo Effect has to be switched on.
It is worth mentioning, that all spatial effects affect amplitude and phase
response. With the lower 4 bits, the frequency response can be customized. A
value of 0hex yields a flat response for center signals (L = R), but a high-pass
function for L or R only signals. A value of 6hex has a flat response for L or R
only signals, but a low-pass function for center signals. By using 8hex, the frequency response is automatically adapted to the sound material by choosing an
optimal high-pass gain.
Micronas
37
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
SUBWOOFER OUTPUT CHANNEL
00 2Chex
Subwoofer Level Adjustment
bit[15:8]
bit[7:0]
0Chex
...
01hex
00hex
FFhex
...
E3hex
E2hex
...
80hex
+12 dB
00hex
must be zero
SUBW_LEVEL
+1 dB
0 dB (default)
−1 dB
−29 dB
−30 dB
Mute
If MDB is added onto the main channel, this register should be set to 00hex
00 2Dhex
Subwoofer Corner Frequency
bit[15:8]
5...40
SUBW_FREQ
corner frequency in 10 Hz steps
(range: 50...400 Hz)
If MDB is active, SUBW_FREQ must be set to a value higher than the MDB Lowpass
Frequency (MDB_LP). Choosing the corner frequency of the subwoofer closer to
MDB_LP results in a narrower MDB frequency range. Recommended value:
1.5×MDB_LP
Subwoofer Complementary High-Pass Filter
bit[7:0]
00hex
01hex
02hex
loudspeaker channel unfiltered
a complementary high-pass is processed in the loudspeaker output channel
MDB added onto main channel
SUBW_HP
MDB CONTROL REGISTERS
00 68hex
MDB Effect Strength
MDB_STR
bit[15:8]
00hex
7Fhex
MDB OFF (default)
maximum MDB
bit[7:0]
00hex
must be zero
The MDB effect strength can be adjusted in 1 dB steps. A value of 44hex will
yield a medium MDB effect.
00 69hex
MDB Amplitude Limit
bit[15:8]
bit[7:0]
00hex
FFhex
...
E0hex
−32 dBFS
00hex
must be zero
MDB_LIM
0 dBFS (default limitation)
−1 dBFS
The MDB Amplitude Limit defines the maximum allowed amplitude at the output
of the MDB relative to 0 dbFS. If the amplitude exceeds MDB_LIM, the gain of
the MDB is automatically reduced. Note that the Volume Clipping Mode must be
set to “dynamic” (see page 32).
38
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
00 6Ahex
MDB Harmonic Content
MDB_HMC
bit[15:8]
00hex
64hex
7Fhex
no harmonics are added (default)
50% fundamentals + 50% harmonics
100% harmonics
bit[7:0]
00hex
must be zero
MDB creates harmonics of the frequencies below the MDB highpass frequency
(MDB_HP). The variable MDB_HMC describes the ratio of the harmonics
towards the original signal.
00 6Bhex
MDB Low Pass Corner Frequency
bit[15:8]
bit[7:0]
5
6
...
30
300 Hz
00hex
must be zero
MDB_LP
50 Hz
60 Hz
The MDB lowpass corner frequency (range 50...300 Hz) defines the upper corner frequency of the MDB bandpass filter. Recommended values are the same
as for the MDB highpass corner frequency (MDB_HP).
00 6Chex
MDB High Pass Corner Frequency
bit[15:8]
bit[7:0]
2
3
...
30
300 Hz
00hex
must be zero
MDB_HP
20 Hz
30 Hz
The MDB highpass corner frequency defines the lower corner frequency of the
MDB bandpass filter. The highpass filter avoids loading the loudspeakers with
low frequency components that are below the speakers’ cut off frequency. Recommended values for subwoofer systems are around 5 (=50 Hz), for regular TV
sets around 10 (=100 Hz).
Micronas
39
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
SCART OUTPUT CHANNEL
00 07hex
00 40hex
40
Volume SCART1 Output Channel
Volume SCART2 Output Channel
bit[15:8]
volume table with 1 dB step size
+12 dB (maximum volume)
7Fhex
+11 dB
7Ehex
...
74hex
+1 dB
0 dB
73hex
−1 dB
72hex
...
−113 dB
02hex
−114 dB
01hex
00hex
Mute (reset condition)
bit[7:5]
higher resolution volume table
0
+0 dB
1
+0.125 dB increase in addition to the volume table
...
7
+0.875 dB increase in addition to the volume table
bit[4:0]
01hex
VOL_SCART1
VOL_SCART2
this must be 01hex
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
SCART SWITCHES AND DIGITAL I/O PINS
00 13hex
ACB Register
ACB_REG
Defines the level of the digital output pins and the position of the SCART switches
bit[15]
0/1
low/high of digital output pin D_CTR_I/O_1
(MODUS[3]=0)
bit[14]
0/1
low/high of digital output pin D_CTR_I/O_0
(MODUS[3]=0)
bit[13:5]
SCART DSP Input Select
xxxx00xx0 SCART1 to DSP input (RESET position)
xxxx01xx0 MONO to DSP input (Sound A Mono must be selected in
the channel matrix mode for the corresponding output
channels)
xxxx10xx0 SCART2 to DSP input
xxxx11xx0 SCART3 to DSP input
xxxx00xx1 SCART4 to DSP input
xxxx11xx1 mute DSP input
bit[13:5]
SCART1 Output Select
xx00xxx0x SCART3 input to SCART1 output (RESET position)
xx01xxx0x SCART2 input to SCART1 output
xx10xxx0x MONO input to SCART1 output
xx11xxx0x SCART1 DA to SCART1 output
xx00xxx1x SCART2 DA to SCART1 output
xx01xxx1x SCART1 input to SCART1 output
xx10xxx1x SCART4 input to SCART1 output
xx11xxx1x mute SCART1 output
bit[13:5]
SCART2 Output Select
00xxxx0xx SCART1 DA to SCART2 output (RESET position)
01xxxx0xx SCART1 input to SCART2 output
10xxxx0xx MONO input to SCART2 output
00xxxx1xx SCART2 DA to SCART2 output
01xxxx1xx SCART2 input to SCART2 output
10xxxx1xx SCART3 input to SCART2 output
11xxxx1xx SCART4 input to SCART2 output
11xxxx0xx mute SCART2 output
The RESET position becomes active at the time of the first write transmission
on the control bus to the audio processing part. By writing to the ACB register
first, the RESET state can be redefined.
BEEPER
00 14hex
Micronas
Beeper Volume and Frequency
bit[15:8]
Beeper Volume
off
00hex
maximum volume
7Fhex
bit[7:0]
Beeper Frequency
01hex
16 Hz (lowest)
1 kHz
40hex
4 kHz
FFhex
BEEPER
41
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
VIRTUAL SURROUND PROCESSING
00 48hex
Virtual Surround OFF/ON Switch
VIRT_ON
bit[15:8]
bit[7:0]
00hex
01hex
virtual surround sound off (normal baseband processing)
virtual surround processing
00hex
must be 0
Be sure to switch off Spatial Effects Loudspeaker Channel (register 0005hex) if
3D-PANORAMA is in use.
00 49hex
Virtual Surround Spatial Effects
bit[15:8]
Spatial Effect Strength
Enlargement 100%
7Fhex
Enlargement 50%
3Fhex
...
01hex
Enlargement 1.5%
Effect off
00hex
bit[7:0]
00hex
VIRT_SPAT
must be 0
Increases the perceived basewidth of the reproduced left and right front channels. Recommended value: 50% = 40hex. In contrast to the Spatial Effects
Loudspeaker Channel, the Surround Spatial Effects is optimized for virtual surround.
00 4Ahex
Virtual Surround 3D Effect Strength
bit[15:8]
Virtual Surround Effect Strength
Effect 100%
7Fhex
3Fhex
Effect 50%
...
Effect 1.5%
01hex
Effect off
00hex
bit[7:0]
00hex
VIRT_3DEFF
must be 0
Strength of the surround effect in PANORAMA or 3D-PANORAMA mode.
Recommended value: 66% = 54hex.
00 4Bhex
42
Virtual Surround Mode
bit[15:8]
00hex
must be 0
bit[7:0]
50hex
60hex
PANORAMA virtualizer
3D-PANORAMA virtualizer
VIRT_MODE
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 3–11: Write Registers on I2C Subaddress 12hex, continued
Register
Address
Function
Name
NOISE GENERATOR
00 4Dhex
Noise Generator
NOISE_CHAN
bit[15:8]
00hex
80hex
Noise generator off
Noise generator on
bit[7:0]
A0hex
B0hex
C0hex
D0hex
Noise on left channel
Noise on center channel
Noise on right channel
Noise on surround channel
Determines the active channel for the noise generator.
Micronas
43
MSP 34x1G
PRELIMINARY DATA SHEET
3.3.2.7. Read Registers on I2C Subaddress 13hex
Table 3–12: Read Registers on I2C Subaddress 13hex
Register
Address
Function
Name
QUASI-PEAK DETECTOR READOUT
00 19hex
00 1Ahex
Quasi-Peak Detector Readout Left
Quasi-Peak Detector Readout Right
bit[15:0]
QPEAK_L
QPEAK_R
0hex... 7FFFhex values are 16 bit two’s complement (only positive)
MSP 34x1G VERSION READOUT REGISTERS
00 1Ehex
MSP Hardware Version Code
bit[15:8]
02hex
MSP_HARD
MSP 34x1G - B8
A change in the hardware version code defines hardware optimizations that
may have influence on the chip’s behavior. The readout of this register is identical to the hardware version code in the chip’s imprint.
MSP Major Revision Code
bit[7:0]
07hex
MSP_REVISION
MSP 34x1G - B8
The major revision code of the MSP 34x1G is 7.
00 1Fhex
MSP Product Code
bit[15:8]
01hex
0Bhex
15hex
29hex
33hex
3Dhex
MSP_PRODUCT
MSP 3401G - B8
MSP 3411G - B8
MSP 3421G - B8
MSP 3441G - B8
MSP 3451G - B8
MSP 3461G - B8
By means of the MSP-Product Code, the control processor is able to decide
which TV sound standards have to be considered.
MSP ROM Version Code
bit[7:0]
41hex
42hex
48hex
MSP_ROM
MSP 34x1G - A1
MSP 34x1G - A2
MSP 34x1G - B8
A change in the ROM version code defines internal software optimizations,
that may have influence on the chip’s behavior, e.g. new features may have
been included. While a software change is intended to create no compatibility
problems, customers that want to use the new functions can identify new
MSP 34x1G versions according to this number.
To avoid compatibility problems with MSP 3410B and MSP 34x0D, an offset of
40hex is added to the ROM version code of the chip’s imprint.
44
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
3.4. Programming Tips
3.5. Examples of Minimum Initialization Codes
This section describes the preferred method for initializing the MSP 34x1G. The initialization is grouped into
four sections:
Initialization of the MSP 34x1G according to these listings reproduces sound of the selected standard on the
loudspeaker output. All numbers are hexadecimal. The
examples have the following structure:
– SCART Signal Path (analog signal path)
– Demodulator
– SCART and I2S Inputs
– Output Channels
See Fig. 2–1 on page 9 for a complete signal flow.
1. Perform an I2C controlled reset of the IC.
2. Write MODUS register
(with Automatic Sound Select).
3. Set Source Selection for loudspeaker channel
(with matrix set to STEREO).
4. Set Prescale
(FM and/or NICAM and dummy FM matrix).
SCART Signal Path
1. Select analog input for the SCART baseband processing (SCART DSP Input Select) by means of the
ACB register.
2. Select the source for each analog SCART output
(SCART Output Select) by means of the ACB register.
5. Write STANDARD SELECT register.
6. Set Volume loudspeaker channel to 0 dB.
3.5.1. SCART1 Input to Loudspeaker in
Stereo Sound
<80 00 80 00>
// reset
<80 00 00 00>
Demodulator
For a complete setup of the TV sound processing from
analog IF input to the source selection, the following
steps must be performed:
1. Set MODUS register to the preferred mode and
Sound IF input.
<80 12 00 08 02 20>
// source loudspeaker = scart, stereo
<80 12 00 0d 19 00>
// prescale scart
<80 12 00 00 73 00>
// volume main = 0dB
3.5.2. SCART1 Input to Loudspeaker in
3D-PANORAMA Sound
<80 00 80 00>
// reset
2. Choose preferred prescale (FM and NICAM) values.
<80 00 00 00>
3. Write STANDARD SELECT register.
<80 12 00 08 02 20>
// source loudspeaker = scart, stereo
<80 12 00 0d 19 00>
// prescale scart
4. If Automatic Sound Select is not active:
Choose FM matrix repeatedly according to the
sound mode indicated in the STATUS register.
SCART and I2S Inputs
1. Select preferred prescale for SCART.
2. Select preferred prescale for I2S inputs
(set to 0 dB after RESET).
<80 12 00 00 73 00>
// volume main = 0dB
<80 12 00 48 01 00>
// virtual surround sound: on
<80 12 00 49 40 00>
// Surround spatial effect = 50%
<80 12 00 4a 54 00>
// panorama sound effect = 66%
<80 12 00 4b 00 60>
// Surround mode = 3d_panorama
<80 12 00 4d 00 00>
// Noise Sequencer = off
3.5.3. Noise Sequencer for 3D-PANORAMA Sound
// switch into 3D-PANORAMA sound (s.a.). Then:
<80 12 00 4d 80 a0>
Output Channels
1. Select the source channel and matrix for each output channel.
<80 12 00 4d 80 b0>
2. Set audio baseband processing.
<80 12 00 4d 80 c0>
3. Select volume for each output channel.
// noise L
[wait for 2 seconds]
// noise C
[wait for 2 seconds]
// noise R
[wait for 2 seconds]
<80 12 00 4d 80 d0>
// noise S
[wait for 2 seconds]
// switch back to normal operation
<80 12 00 4d 00 00>
Micronas
// Noise Sequencer = off
45
MSP 34x1G
PRELIMINARY DATA SHEET
3.5.4. B/G-FM (A2 or NICAM)
3.5.7. FM-Stereo Radio
<80 00 80 00>
<80 00 80 00>
// Softreset
<80 00 00 00>
// Softreset
<80 00 00 00>
<80 10 00 30 20 03>
// MODUS-Register: Automatic = on
<80 10 00 30 20 03>
// MODUS-Register: Automatic = on
<80 12 00 08 03 20>
// Source Sel. = (St or A) & Ch. Matr. = St
<80 12 00 08 03 20>
// Source Sel. = (St or A) & Ch. Matr. = St
<80 12 00 0E 24 03>
// FM/AM-Prescale = 24hex,
FM-Matrix = MONO/SOUNDA
<80 12 00 0E 24 03>
// FM/AM-Prescale = 24hex,
FM-Matrix = Sound A Mono
<80 12 00 10 5A 00>
// NICAM-Prescale = 5Ahex
<80 10 00 20 00 40>
// Standard Select: FM-STEREO-RADIO
<80 10 00 20 00 03>
or
<80 10 00 20 00 08>
// Standard Select: A2 B/G or NICAM B/G
<80 12 00 00 73 00>
// Loudspeaker Volume 0 dB
<80 12 00 00 73 00>
// Loudspeaker Volume 0 dB
3.5.8. Automatic Standard Detection
A detailed software flow diagram is shown in Fig. 3–2
on page 47.
3.5.5. BTSC-Stereo
<80 00 80 00>
// Softreset
<80 00 80 00>
<80 00 00 00>
<80 10 00 30 20 03>
// MODUS-Register: Automatic = on
<80 12 00 08 03 20>
// Source Sel. = (St or A) & Ch. Matr. = St
<80 12 00 0E 24 03>
// FM/AM-Prescale = 24hex,
FM-Matrix = Sound A Mono
<80 10 00 20 00 20>
// Standard Select: BTSC-STEREO
<80 12 00 00 73 00>
// Loudspeaker Volume 0 dB
<80 10 00 30 20 03>
// MODUS-Register: Automatic = on
<80 12 00 08 03 20>
// Source Sel. = (St or A) & Ch. Matr. = St
<80 12 00 0E 24 03>
// FM/AM-Prescale = 24hex,
FM-Matrix = Sound A Mono
<80 12 00 10 5A 00>
// NICAM-Prescale = 5Ahex
// Standard Select:
Automatic Standard Detection
<80 10 00 20 00 01>
3.5.6. BTSC-SAP with SAP at Loudspeaker Channel
<80 00 80 00>
// Softreset
// Softreset
<80 00 00 00>
// Wait till STANDARD RESULT contains a value ≤ 07FF
// IF STANDARD RESULT contains 0000
// do some error handling
<80 00 00 00>
<80 10 00 30 20 03>
// MODUS-Register: Automatic = on
<80 12 00 08 04 20>
// Source Sel. = (St or B) & Ch. Matr. = St
<80 12 00 0E 24 03>
// FM/AM-Prescale = 24hex,
FM-Matrix = Sound A Mono
<80 10 00 20 00 21>
// Standard Select: BTSC-SAP
<80 12 00 00 73 00>
// Loudspeaker Volume 0 dB
// ELSE
<80 12 00 00 73 00>
// Loudspeaker Volume 0 dB
3.5.9. Software Flow for Interrupt driven STATUS
Check
A detailed software flow diagram is shown in Fig. 3–2
on page 47.
If the D_CTR_I/O_1 pin of the MSP 34x1G is connected to an interrupt input pin of the controller, the following interrupt handler can be applied to be automatically called with each status change of the
MSP 34x1G. The interrupt handler may adjust the TV
display according to the new status information.
Interrupt Handler:
<80 11 02 00 <81 dd dd> // Read STATUS
// adjust TV display with given status information
// Return from Interrupt
46
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Write MODUS Register:
Example for the essential bits:
[0] = 1
Automatic Sound Select = on
[1] = 1
Enable interrupt if STATUS changes
[8] = 0
ANA_IN1+ is selected
Define Preference for Automatic Standard
Detection:
[12] = 0
If 6.5 MHz, set SECAM-L
[14:13] = 3 Ignore 4.5 MHz carrier
Write SOURCE SELECT Settings
Example:
set loudspeaker Source Select to "Stereo or A"
set headphone Source Select to "Stereo or B"
set SCART_Out Source Select to "Stereo or A/B"
set Channel Matrix mode for all outputs to "Stereo"
Write FM/AM-Prescale
Write NICAM-Prescale
Write 01 into
STANDARD SELECT Register
(Start Automatic Standard Detection)
set previous standard or
set standard manually according
picture information
yes
Result = 0
?
no
expecting MSPG-interrupt
In case of MSPGInterrupt to Controller:
Read STATUS
Adjust TV-Display
If Bilingual, adjust Source Select setting if required
Fig. 3–2: Software flow diagram for a Minimum demodulator setup for a European Multistandard TV set applying the
Automatic Sound Select feature
Micronas
47
MSP 34x1G
PRELIMINARY DATA SHEET
4. Specifications
0.9 ± 0.2
4.1. Outline Dimensions
1.1 x 45°
1
1.2 x 45°
61
2
1.27
60
2
7.5
24.2 ± 0.1
0.71 ± 0.05
25.14 ± 0.12
23.3 ± 0.3
9
16 x 1.27 = 20.32 ± 0.1
10
0.48 ± 0.06
9
16 x 1.27 = 20.32 ± 0.1
1.27
7.5
26
0.23 ± 0.04
9
44
27
1.9 ±0.05
43
4.05 ±0.1
25.14 ± 0.12
4.75 ±0.15
24.2 ± 0.1
0.1
SPGS704000-1(P68)/1E
Fig. 4–1:
68-Pin Plastic Leaded Chip Carrier Package (not intended for new designs)
(PLCC68)
Weight approximately 4.8 g
Dimensions in mm
SPGS703000-1(P52)/1E
SPGS703000-1(P64)/1E
64
33
27
1
26
32
47.0 ±0.1
19.3 ±0.1
18 ±0.05
0.8 ±0.2
3.8 ±0.1
57.7 ±0.1
15.6 ±0.1
14 ±0.1
0.6 ±0.2
4.0 ±0.1
1
52
1 ±0.05
1.778
0.48 ±0.06
3.2 ±0.2
0.28 ±0.06
31 x 1.778 = 55.1 ±0.1
Fig. 4–2:
64-Pin Plastic Shrink Dual-Inline Package
(PSDIP64)
Weight approximately 9.0 g
Dimensions in mm
48
20.3 ±0.5
1.778
0.48 ±0.06
2.8 ±0.2
0.28 ±0.06
1 ±0.05
16.3 ±1
25 x 1.778 = 44.4 ±0.1
Fig. 4–3:
52-Pin Plastic Shrink Dual-Inline Package
(PSDIP52)
Weight approximately 5.5 g
Dimensions in mm
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
23 x 0.8 = 18.4 ± 0.1
0.17 ± 0.04
41
40
80
25
1
14 ± 0.1
0.37 ± 0.04
17.2 ± 0.15
0.8
65
15 x 0.8 = 12.0 ± 0.1
64
0.8
1.3 ± 0.05
24
2.7 ± 0.1
23.2 ± 0.15
3 ±0.2
20 ± 0.1
0.1
SPGS705000-3(P80)/1E
Fig. 4–4:
80-Pin Plastic Quad Flat Pack
(PQFP80)
Weight approximately 1.61 g
Dimensions in mm
15 x 0.5 = 7.5 ± 0.1
0.145 ± 0.055
64
17
0.22 ± 0.05
1.75
1
16
1.4 ± 0.05
1.75
12 ± 0.2
15 x 0.5 = 7.5 ± 0.1
32
12 ± 0.2
49
0.5
33
10 ± 0.1
48
0.5
1.5 ± 0.1
0.1
10 ± 0.1
D0025/3E
Fig. 4–5:
64-Pin Plastic Low-Profile Quad Flat Pack
(PLQFP64)
Weight approximately 3.5 g
Dimensions in mm
Micronas
49
MSP 34x1G
PRELIMINARY DATA SHEET
4.2. Pin Connections and Short Descriptions
NC = not connected; leave vacant
LV = if not used, leave vacant
X = obligatory; connect as described in circuit diagram
DVSS: if not used, connect to DVSS
AHVSS: connect to AHVSS
Pin No.
Pin Name
Type
Connection
Short Description
(if not used)
PLCC
68-pin
PSDIP
64-pin
PSDIP
52-pin
PQFP
80-pin
PLQFP
64-pin
1
16
14
9
8
ADR_WS
2
−
−
−
−
NC
3
15
13
8
7
ADR_DA
4
14
12
7
6
5
13
11
6
6
12
10
7
11
8
LV
ADR word strobe
LV
Not connected
OUT
LV
ADR data output
I2S_DA_IN1
IN
LV
I2S1 data input
5
I2S_DA_OUT
OUT
LV
I2S data output
5
4
I2S_WS
IN/OUT
LV
I2S word strobe
9
4
3
I2S_CL
IN/OUT
LV
I2S clock
10
8
3
2
I2C_DA
IN/OUT
X
I2C data
9
9
7
2
1
I2C_CL
IN/OUT
X
I2C clock
10
8
−
1
64
NC
LV
Not connected
11
7
6
80
63
STANDBYQ
IN
X
Stand-by (low-active)
12
6
5
79
62
ADR_SEL
IN
X
I2C Bus address select
13
5
4
78
61
D_CTR_I/O_0
IN/OUT
LV
D_CTR_I/O_0
14
4
3
77
60
D_CTR_I/O_1
IN/OUT
LV
D_CTR_I/O_1
15
3
−
76
59
NC
LV
Not connected
16
2
−
75
58
NC
LV
Not connected
17
−
−
−
−
NC
LV
Not connected
18
1
2
74
57
AUD_CL_OUT
LV
Audio clock output
(18.432 MHz)
19
64
1
73
56
TP
LV
Test pin
20
63
52
72
55
XTAL_OUT
OUT
X
Crystal oscillator
21
62
51
71
54
XTAL_IN
IN
X
Crystal oscillator
22
61
50
70
53
TESTEN
IN
X
Test pin
23
60
49
69
52
ANA_IN2+
IN
AVSS via
56 pF / LV
IF input 2 (can be left
AVSS via
56 pF / LV
IF common (can be left
24
50
59
48
68
51
ANA_IN−
OUT
OUT
IN
vacant, only if IF input 1 is
also not in use)
vacant, only if IF input 1 is
also not in use)
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Pin No.
Pin Name
Type
Connection
Short Description
(if not used)
PLCC
68-pin
PSDIP
64-pin
PSDIP
52-pin
PQFP
80-pin
PLQFP
64-pin
25
58
47
67
50
ANA_IN1+
26
57
46
66
49
−
−
−
65
−
−
−
−
−
27
LV
IF input 1
AVSUP
X
Analog power supply 5 V
−
AVSUP
X
Analog power supply 5 V
64
−
NC
LV
Not connected
−
63
−
NC
LV
Not connected
56
45
62
48
AVSS
X
Analog ground
−
−
−
61
−
AVSS
X
Analog ground
28
55
44
60
47
MONO_IN
LV
Mono input
−
−
−
59
−
NC
LV
Not connected
29
54
43
58
46
VREFTOP
X
Reference voltage IF
A/D converter
30
53
42
57
45
SC1_IN_R
IN
LV
SCART 1 input, right
31
52
41
56
44
SC1_IN_L
IN
LV
SCART 1 input, left
32
51
−
55
43
ASG
AHVSS
Analog Shield Ground
33
50
40
54
42
SC2_IN_R
IN
LV
SCART 2 input, right
34
49
39
53
41
SC2_IN_L
IN
LV
SCART 2 input, left
35
48
−
52
40
ASG
AHVSS
Analog Shield Ground
36
47
38
51
39
SC3_IN_R
IN
LV
SCART 3 input, right
37
46
37
50
38
SC3_IN_L
IN
LV
SCART 3 input, left
38
45
−
49
37
ASG
AHVSS
Analog Shield Ground
39
44
−
48
36
SC4_IN_R
IN
LV
SCART 4 input, right
40
43
−
47
35
SC4_IN_L
IN
LV
SCART 4 input, left
41
−
−
46
−
NC
LV or AHVSS
Not connected
42
42
36
45
34
AGNDC
X
Analog reference voltage
43
41
35
44
33
AHVSS
X
Analog ground
−
−
−
43
−
AHVSS
X
Analog ground
−
−
−
42
−
NC
LV
Not connected
−
−
−
41
−
NC
LV
Not connected
44
40
34
40
32
CAPL_M
X
Volume capacitor MAIN
45
39
33
39
31
AHVSUP
X
Analog power supply 8 V
46
38
32
38
30
CAPL_A
X
Volume capacitor AUX
47
37
31
37
29
SC1_OUT_L
LV
SCART output 1, left
Micronas
IN
IN
OUT
51
MSP 34x1G
PRELIMINARY DATA SHEET
Pin No.
Pin Name
Type
Connection
Short Description
(if not used)
PLCC
68-pin
PSDIP
64-pin
PSDIP
52-pin
PQFP
80-pin
PLQFP
64-pin
48
36
30
36
28
SC1_OUT_R
49
35
29
35
27
VREF1
50
34
28
34
26
SC2_OUT_L
51
33
27
33
25
SC2_OUT_R
52
−
−
32
−
53
32
−
31
54
31
26
55
30
56
LV
SCART output 1, right
X
Reference ground 1
OUT
LV
SCART output 2, left
OUT
LV
SCART output 2, right
NC
LV
Not connected
24
NC
LV
Not connected
30
23
DACM_SUB
LV
Subwoofer output
−
29
22
NC
LV
Not connected
29
25
28
21
DACM_L
OUT
LV
Loudspeaker out, left
57
28
24
27
20
DACM_R
OUT
LV
Loudspeaker out, right
58
27
23
26
19
VREF2
X
Reference ground 2
59
26
22
25
18
DACA_L
OUT
LV
Headphone out, left
60
25
21
24
17
DACA_R
OUT
LV
Headphone out, right
−
−
−
23
−
NC
LV
Not connected
−
−
−
22
−
NC
LV
Not connected
61
24
20
21
16
RESETQ
X
Power-on-reset
62
23
−
20
15
NC
LV
Not connected
63
22
−
19
14
NC
LV
Not connected
64
21
19
18
13
NC
LV
Not connected
65
20
18
17
12
I2S_DA_IN2
LV
I2S2-data input
66
19
17
16
11
DVSS
X
Digital ground
−
−
−
15
−
DVSS
X
Digital ground
−
−
−
14
−
DVSS
X
Digital ground
67
18
16
13
10
DVSUP
X
Digital power supply 5 V
−
−
−
12
−
DVSUP
X
Digital power supply 5 V
−
−
−
11
−
DVSUP
X
Digital power supply 5 V
68
17
15
10
9
ADR_CL
LV
ADR clock
52
OUT
OUT
IN
IN
OUT
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.3. Pin Descriptions
Pin numbers refer to the 80-pin PQFP package.
Pins 22, 23, NC – Pins not connected.
Pin 1, NC – Pin not connected.
Pins 24, 25, DACA_R/L – Headphone Outputs
(Fig. 4–21)
Output of the headphone signal. A 1-nF capacitor to
AHVSS must be connected to these pins. The DC offset on these pins depends on the selected headphone
volume.
Pin 2, I2C_CL – I2C Clock Input/Output (Fig. 4–18)
Via this pin, the I2C-bus clock signal has to be supplied. The signal can be pulled down by the MSP in
case of wait conditions.
Pin 3, I2C_DA – I2C Data Input/Output (Fig. 4–18)
Via this pin, the I2C-bus data is written to or read from
the MSP.
Pin 4, I2S_CL – I2S Clock Input/Output (Fig. 4–19)
Clock line for the I2S bus. In master mode, this line is
driven by the MSP; in slave mode, an external I2S
clock has to be supplied.
Pin 5, I2S_WS – I2S Word Strobe Input/Output
(Fig. 4–19)
Word strobe line for the I2S bus. In master mode, this
line is driven by the MSP; in slave mode, an external
I2S word strobe has to be supplied.
Pin 6, I2S_DA_OUT – I2S Data Output (Fig. 4–23)
Output of digital serial sound data of the MSP on the
I2S bus.
Pin 7, I2S_DA_IN1 – I2S Data Input 1 (Fig. 4–15)
First input of digital serial sound data to the MSP via
the I2S bus.
Pin 26, VREF2 – Reference Ground 2
Reference analog ground. This pin must be connected
separately to ground (AHVSS). VREF2 serves as a
clean ground and should be used as the reference for
analog connections to the loudspeaker and headphone outputs.
Pins 27, 28, DACM_R/L – Loudspeaker Outputs
(Fig. 4–21)
Output of the loudspeaker signal. A 1-nF capacitor to
AHVSS must be connected to these pins. The DC offset on these pins depends on the selected loudspeaker volume.
Pin 29, NC – Pin not connected.
Pin 30, DACM_SUB – Subwoofer Output (Fig. 4–21)
Output of the subwoofer signal. A 1-nF capacitor to
AHVSS must be connected to this pin. Due to the low
frequency content of the subwoofer output, the value
of the capacitor may be increased for better suppression of high-frequency noise. The DC offset on this pin
depends on the selected loudspeaker volume.
Pin 8, ADR_DA – ADR Bus Data Output (Fig. 4–23)
Output of digital serial data to the DRP 3510A via the
ADR bus.
Pins 31, 32 NC – Pin not connected.
Pin 9, ADR_WS – ADR Bus Word Strobe Output
(Fig. 4–23)
Word strobe output for the ADR bus.
Pins 33, 34, SC2_OUT_R/L – SCART2 Outputs
(Fig. 4–22)
Output of the SCART2 signal. Connections to these
pins must use a 100-Ω series resistor and are intended
to be AC-coupled.
Pin 10, ADR_CL – ADR Bus Clock Output (Fig. 4–23)
Clock line for the ADR bus.
Pins 11, 12, 13, DVSUP* – Digital Supply Voltage
Power supply for the digital circuitry of the MSP. Must
be connected to a +5 V power supply.
Pins 14, 15, 16, DVSS* – Digital Ground
Ground connection for the digital circuitry of the MSP.
Pin 17, I2S_DA_IN2 – I2S Data Input 2 (Fig. 4–15)
Second input of digital serial sound data to the MSP
via the I2S bus.
Pin 35, VREF1 – Reference Ground 1
Reference analog ground. This pin must be connected
separately to ground (AHVSS). VREF1 serves as a
clean ground and should be used as the reference for
analog connections to the SCART outputs.
Pins 36, 37, SC1_OUT_R/L – SCART1 Outputs
(Fig. 4–22)
Output of the SCART1 signal. Connections to these
pins must use a 100-Ω series resistor and are intended
to be AC-coupled.
Pins 18, 19, 20, NC – Pins not connected.
Pin 21, RESETQ – Reset Input (Fig. 4–11)
In the steady state, high level is required. A low level
resets the MSP 34x1G.
Micronas
53
MSP 34x1G
Pin 38, CAPL_A – Volume Capacitor Headphone
(Fig. 4–24)
A 10-µF capacitor to AHVSUP must be connected to
this pin. It serves as a smoothing filter for headphone
volume changes in order to suppress audible plops.
The value of the capacitor can be lowered to 1-µF if
faster response is required. The area encircled by the
trace lines should be minimized; keep traces as short
as possible. This input is sensitive for magnetic induction.
Pin 39, AHVSUP* – Analog Power Supply High Voltage
Power is supplied via this pin for the analog circuitry of
the MSP (except IF input). This pin must be connected
to the +8 V supply.
Pin 40, CAPL_M – Volume Capacitor Loudspeaker
(Fig. 4–24)
A 10-µF capacitor to AHVSUP must be connected to
this pin. It serves as a smoothing filter for loudspeaker
volume changes in order to suppress audible plops.
The value of the capacitor can be lowered to 1 µF if
faster response is required. The area encircled by the
trace lines should be minimized; keep traces as short
as possible. This input is sensitive for magnetic induction.
PRELIMINARY DATA SHEET
Pins 53, 54 SC2_IN_L/R – SCART2 Inputs (Fig. 4–14)
The analog input signal for SCART2 is fed to this pin.
Analog input connection must be AC-coupled.
Pin 55, ASG – Analog Shield Ground
Analog ground (AHVSS) should be connected to this
pin to reduce cross-coupling between SCART inputs.
Pins 56, 57 SC1_IN_L/R – SCART1 Inputs (Fig. 4–14)
The analog input signal for SCART1 is fed to this pin.
Analog input connection must be AC-coupled.
Pin 58, VREFTOP – Reference Voltage IF A/D Converter (Fig. 4–16)
Via this pin, the reference voltage for the IF A/D converter is decoupled. It must be connected to AVSS
pins with a 10-µF and a 100-nF capacitor in parallel.
Traces must be kept short.
Pin 59, NC – Pin not connected.
Pin 60 MONO_IN – Mono Input (Fig. 4–14)
The analog mono input signal is fed to this pin. Analog
input connection must be AC-coupled.
Pins 61, 62, AVSS* – Analog Power Supply Voltage
Ground connection for the analog IF input circuitry of
the MSP.
Pins 41, 42, NC – Pins not connected.
Pins 63, 64, NC – Pins not connected.
Pins 43, 44, AHVSS* – Ground for Analog Power Supply High Voltage
Ground connection for the analog circuitry of the MSP
(except IF input).
Pin 45, AGNDC – Internal Analog Reference Voltage
This pin serves as the internal ground connection for
the analog circuitry (except IF input). It must be connected to the VREF pins with a 3.3-µF and a 100-nF
capacitor in parallel. This pins shows a DC level of typically 3.73 V.
Pin 46, NC – Pin not connected.
Pins 47, 48, SC4_IN_L/R – SCART4 Inputs
(Fig. 4–14)
The analog input signal for SCART4 is fed to this pin.
Analog input connection must be AC-coupled.
Pin 49, ASG – Analog Shield Ground
Analog ground (AHVSS) should be connected to this
pin to reduce cross-coupling between SCART inputs.
Pins 50, 51, SC3_IN_L/R – SCART3 Inputs
(Fig. 4–14)
The analog input signal for SCART3 is fed to this pin.
Analog input connection must be AC-coupled.
Pins 65, 66, AVSUP* – Ground for Analog Power Supply Voltage
Power is supplied via this pin for the analog IF input circuitry of the MSP. This pin must be connected to the
+5 V supply.
Pin 67, ANA_IN1+ – IF Input 1 (Fig. 4–16)
The analog sound IF signal is supplied to this pin.
Inputs must be AC-coupled. This pin is designed as
symmetrical input: ANA_IN1+ is internally connected
to one input of a symmetrical op amp, ANA_IN- to the
other.
Pin 68, ANA_IN− – IF Common (Fig. 4–16)
This pins serves as a common reference for ANA_IN1/
2+ inputs.
Pin 69, ANA_IN2+ – IF Input 2 (Fig. 4–16)
The analog sound if signal is supplied to this pin.
Inputs must be AC-coupled. This pin is designed as
symmetrical input: ANA_IN2+ is internally connected
to one input of a symmetrical op amp, ANA_IN− to the
other.
Pin 70, TESTEN – Test Enable Pin (Fig. 4–12)
This pin enables factory test modes. For normal operation, it must be connected to ground.
Pin 52, ASG – Analog Shield Ground
Analog ground (AHVSS) should be connected to this
pin to reduce cross-coupling between SCART inputs.
54
Micronas
PRELIMINARY DATA SHEET
MSP 34x1G
Pins 71, 72 XTAL_IN, XTAL_OUT – Crystal Input and
Output Pins (Fig. 4–20)
These pins are connected to an 18.432 MHz crystal
oscillator which is digitally tuned by integrated shunt
capacitances. An external clock can be fed into
XTAL_IN. The audio clock output signal AUD_CL_OUT
is derived from the oscillator. External capacitors at
each crystal pin to ground (AVSS) are required. It
should be verified by layout, that no supply current for
the digital circuitry is flowing through the ground connection point.
Pin 73, TP – This pin enables factory test modes. For
normal operation, it must be left vacant.
Pin 74, AUD_CL_OUT – Audio Clock Output
(Fig. 4–20)
This is the 18.432 MHz main clock output.
Pins 75, 76, NC – Pins not connected.
Pins 77, 78, D_CTR_I/O_1/0 – Digital Control Input/
Output Pins (Fig. 4–19)
General purpose input/output pins. Pin D_CTR_I/O_1
can be used as an interrupt request pin to the controller.
Pin 79, ADR_SEL – I2C Bus Address Select
(Fig. 4–17)
By means of this pin, one of three device addresses for
the MSP can be selected. The pin can be connected to
ground (I2C device addresses 80/81hex), to +5 V supply (84/85hex), or left open (88/89hex).
Pin 80, STANDBYQ – Stand-by
In normal operation, this pin must be high. If the
MSP 34x1G is switched off by first pulling STANDBYQ
low and then (after >1µs delay) switching off DVSUP
and AVSUP, but keeping AHVSUP (‘Standby’-mode),
the SCART switches maintain their position and function.
* Application Note:
All ground pins should be connected to one low-resistive ground plane. All supply pins should be connected
separately with short and low-resistive lines to the
power supply. Decoupling capacitors from DVSUP to
DVSS, AVSUP to AVSS, and AHVSUP to AHVSS are
recommended as closely as possible to these pins.
Decoupling of DVSUP and DVSS is most important.
We recommend using more than one capacitor. By
choosing different values, the frequency range of
active decoupling can be extended. In our application
boards we use: 220 pF, 470 pF, 1.5 nF, and 10 µF. The
capacitor with the lowest value should be placed nearest to the DVSUP and DVSS pins.
The ASG pins should be connected as closely as possible to the MSP ground. If they are lead with the
SCART-inputs as shielding lines, they should not be
connected to ground at the SCART connector.
Micronas
55
MSP 34x1G
PRELIMINARY DATA SHEET
4.4. Pin Configurations
ADR_WS
NC
ADR_CL
ADR_DA
DVSUP
I2S_DA_IN1
DVSS
I2S_DA_OUT
I2S_DA_IN2
I2S_WS
NC
I2S_CL
NC
I2C_DA
NC
I2C_CL
RESETQ
9
8
7
6
5
4
3
2
1
68 67 66 65 64 63 62 61
NC
10
60
DACA_R
STANDBYQ
11
59
DACA_L
ADR_SEL
12
58
VREF2
D_CTR_I/O_0
13
57
DACM_R
D_CTR_I/O_1
14
56
DACM_L
NC
15
55
NC
NC
16
54
DACM_SUB
NC
17
53
NC
AUD_CL_OUT
18
52
NC
TP
19
51
SC2_OUT_R
XTAL_OUT
20
50
SC2_OUT_L
XTAL_IN
21
49
VREF1
TESTEN
22
48
SC1_OUT_R
ANA_IN2+
23
47
SC1_OUT_L
ANA_IN−
24
46
CAPL_A
ANA_IN1+
25
45
AHVSUP
AVSUP
26
44
CAPL_M
MSP 34x1G
27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43
AHVSS
AVSS
MONO_IN
AGNDC
VREFTOP
NC
SC1_IN_R
SC4_IN_L
SC1_IN_L
SC4_IN_R
ASG
ASG
SC2_IN_R
SC3_IN_L
SC2_IN_L
SC3_IN_R
ASG
Fig. 4–6: 68-pin PLCC package (not intended for new designs)
56
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
64
TP
TP
1
52
XTAL_OUT
2
63
XTAL_OUT
AUD_CL_OUT
2
51
XTAL_IN
NC
3
62
XTAL_IN
D_CTR_I/O_1
3
50
TESTEN
D_CTR_I/O_1
4
61
TESTEN
D_CTR_I/O_0
4
49
ANA_IN2+
D_CTR_I/O_0
5
60
ANA_IN2+
ADR_SEL
5
48
ANA_IN−
ADR_SEL
6
59
ANA_IN−
STANDBYQ
6
47
ANA_IN1+
STANDBYQ
7
58
ANA_IN+
I2C_CL
7
46
AVSUP
NC
8
57
AVSUP
I2C_DA
8
45
AVSS
I2C_CL
9
56
AVSS
I2S_CL
9
44
MONO_IN
I2C_DA
10
55
MONO_IN
I2S_WS
10
43
VREFTOP
I2S_CL
11
54
VREFTOP
I2S_DA_OUT
11
42
SC1_IN_R
I2S_WS
12
53
SC1_IN_R
I2S_DA_IN1
12
41
SC1_IN_L
I2S_DA_OUT
13
52
SC1_IN_L
ADR_DA
13
40
SC2_IN_R
I2S_DA_IN1
14
51
ASG
ADR_WS
14
39
SC2_IN_L
ADR_DA
15
50
SC2_IN_R
ADR_CL
15
38
SC3_IN_R
ADR_WS
16
49
SC2_IN_L
DVSUP
16
37
SC3_IN_L
ADR_CL
17
48
ASG
DVSS
17
36
AGNDC
DVSUP
18
47
SC3_IN_R
I2S_DA_IN2
18
35
AHVSS
DVSS
19
46
SC3_IN_L
NC
19
34
CAPL_M
I2S_DA_IN2
20
45
ASG
RESETQ
20
33
AHVSUP
NC
21
44
SC4_IN_R
DACA_R
21
32
CAPL_A
NC
22
43
SC4_IN_L
DACA_L
22
31
SC1_OUT_L
NC
23
42
AGNDC
VREF2
23
30
SC1_OUT_R
RESETQ
24
41
AHVSS
DACM_R
24
29
VREF1
DACA_R
25
40
CAPL_M
DACM_L
25
28
SC2_OUT_L
DACA_L
26
39
AHVSUP
DACM_SUB
26
27
SC2_OUT_R
VREF2
27
38
CAPL_A
DACM_R
28
37
SC1_OUT_L
DACM_L
29
36
SC1_OUT_R
NC
30
35
VREF1
DACM_SUB
31
34
SC2_OUT_L
NC
32
33
SC2_OUT_R
MSP 34x1G
1
NC
MSP 34x1G
AUD_CL_OUT
Fig. 4–8: 52-pin PSDIP package
Fig. 4–7: 64-pin PSDIP package
Micronas
57
MSP 34x1G
PRELIMINARY DATA SHEET
SC2_IN_L
SC2_IN_R
ASG
SC3_IN_R
ASG
SC3_IN_L
SC1_IN_L
ASG
SC1_IN_R
SC4_IN_R
VREFTOP
SC4_IN_L
NC
NC
MONO_IN
AGNDC
AVSS
AHVSS
AVSS
AHVSS
NC
NC
NC
NC
AVSUP
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41
65
40
CAPL_M
AVSUP
66
39
AHVSUP
ANA_IN1+
67
38
CAPL_A
ANA_IN−
68
37
SC1_OUT_L
ANA_IN2+
69
36
SC1_OUT_R
TESTEN
70
35
VREF1
XTAL_IN
71
34
SC2_OUT_L
XTAL_OUT
72
33
SC2_OUT_R
TP
73
32
NC
AUD_CL_OUT
74
31
NC
NC
75
30
DACM_SUB
NC
76
29
NC
D_CTR_I/O_1
77
28
DACM_L
D_CTR_I/O_0
78
27
DACM_R
ADR_SEL
79
26
VREF2
STANDBYQ
80
25
10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
MSP 34x1G
1
2
3
4
5
6
7
8
9
DACA_L
DACA_R
NC
I2C_CL
NC
I2C_DA
NC
I2S_CL
RESETQ
I2S_WS
NC
I2S_DA_OUT
NC
I2S_DA_IN1
NC
ADR_DA
I2S_DA_IN2
ADR_WS
DVSS
ADR_CL
DVSS
DVSUP
DVSUP
DVSS
DVSUP
Fig. 4–9: 80-pin PQFP package
58
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
SC2_IN_L
ASG
SC2_IN_R
SC3_IN_R
ASG
SC3_IN_L
SC1_IN_L
ASG
SC1_IN_R
SC4_IN_R
VREFTOP
SC4_IN_L
MONO_IN
AGNDC
AVSS
AHVSS
48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33
AVSUP
49
32
CAPL_M
ANA_IN1+
50
31
AHVSUP
ANA_IN−
51
30
CAPL_A
ANA_IN2+
52
29
SC1_OUT_L
TESTEN
53
28
SC1_OUT_R
XTAL_IN
54
27
VREF1
XTAL_OUT
55
26
SC2_OUT_L
TP
56
25
SC2_OUT_R
AUD_CL_OUT
57
24
NC
NC
58
23
DACM_SUB
NC
59
22
NC
D_CTR_I/OUT1
60
21
DACM_L
D_CTR_I/OUT0
61
20
DACM_R
ADR_SEL
62
19
VREF2
STANDBYQ
63
18
DACA_L
NC
64
17
DACA_R
MSP 34x1G
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16
RESETQ
I2C_CL
I2C_DA
NC
I2S_CL
NC
I2S_WS
NC
I2S_DA_OUT
I2S_DA_IN2
I2S_DA_IN1
ADR_DA
ADR_WS
DVSS
DVSUP
ADR_CL
Fig. 4–10: 64-pin PLQFP package
Micronas
59
MSP 34x1G
PRELIMINARY DATA SHEET
4.5. Pin Circuits
ANA_IN1+
ANA_IN2+
>300 k
A
D
DVSS
Fig. 4–11: Input Pin: RESETQ
ANA_IN−
VREFTOP
AVSUP
Fig. 4–16: Input Pins:
VREFTOP, ANA_IN1+, ANA_IN-, ANA_IN2+
200 k
Fig. 4–12: Input Pin TESTEN
DVSUP
23 kΩ
24 kΩ
≈ 3.75 V
23 kΩ
Fig. 4–13: Input Pin: MONO_IN
GND
ADR_SEL
Fig. 4–17: Input Pin: ADR_SEL
40 kΩ
≈ 3.75 V
Fig. 4–14: Input Pins: SC4-1_IN_L/R
Fig. 4–15: Input Pins:
I2S_DA_IN1, I2S_DA_IN2, STANDBYQ
60
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
AHVSUP
0...1.2 mA
N
GND
Fig. 4–18: Input/Output Pins: I2C_CL, I2C_DA
3.3 kΩ
Fig. 4–21: Output Pins:
DACA_R/L, DACM_R/L, DACM_SUB
DVSUP
P
N
26 pF
GND
120 kΩ
Fig. 4–19: Input/Output Pins:
I2S_CL, I2S_WS, D_CTR_I/O_1, D_CTR_I/O_0
300 Ω
≈ 3.75 V
P
3−30 pF
Fig. 4–22: Output Pins:
SC_2_OUT_R/L, SC_1_OUT_R/L
500 kΩ
N
DVSUP
2.5 V
P
3−30 pF
Fig. 4–20: Input/Output Pins:
XTAL_IN, XTAL_OUT, AUD_CL_OUT
N
GND
Fig. 4–23: Output Pins:
I2S_DA_OUT, ADR_DA, ADR_WS, ADR_CL
0...2 V
Fig. 4–24: Capacitor Pins: CAPL_A, CAPL_M
125 kΩ
≈ 3.75 V
Fig. 4–25: Pin 45: AGNDC
Micronas
61
MSP 34x1G
PRELIMINARY DATA SHEET
4.6. Electrical Characteristics
4.6.1. Absolute Maximum Ratings
Symbol
Parameter
Pin Name
Min.
Max.
Unit
TA
Ambient Operating Temperature
−
0
70
°C
TS
Storage Temperature
−
−40
125
°C
VSUP1
First Supply Voltage
AHVSUP
−0.3
9.0
V
VSUP2
Second Supply Voltage
DVSUP
−0.3
6.0
V
VSUP3
Third Supply Voltage
AVSUP
−0.3
6.0
V
dVSUP23
Voltage between AVSUP
and DVSUP
AVSUP,
DVSUP
−0.5
0.5
V
PTOT
Power Dissipation
PSDIP64
PSDIP52
PQFP80
PLQFP64
AHVSUP,
DVSUP,
AVSUP
1300
1200
1000
960
mW
mW
mW
mW
−0.3
VSUP2+0.3
V
VIdig
Input Voltage, all Digital Inputs
IIdig
Input Current, all Digital Pins
−
−20
+20
mA1)
VIana
Input Voltage, all Analog Inputs
SCn_IN_s,2)
MONO_IN
−0.3
VSUP1+0.3
V
IIana
Input Current, all Analog Inputs
SCn_IN_s,2)
MONO_IN
−5
+5
mA1)
IOana
Output Current, all SCART Outputs
SCn_OUT_s2)
3) 4)
3) 4)
IOana
Output Current, all Analog Outputs
except SCART Outputs
DACp_s2)
3)
3)
ICana
Output Current, other pins
connected to capacitors
CAPL_p,2)
AGNDC
3)
3)
1)
2)
3)
4)
,
,
positive value means current flowing into the circuit
“n” means “1”, “2”, “3”, or “4”, “s” means “L” or “R”, “p” means “M” or “A”
The analog outputs are short-circuit proof with respect to First Supply Voltage and ground.
Total chip power dissipation must not exceed absolute maximum rating.
Stresses beyond those listed in the “Absolute Maximum Ratings” may cause permanent damage to the device. This
is a stress rating only. Functional operation of the device at these or any other conditions beyond those indicated in
the “Recommended Operating Conditions/Characteristics” of this specification is not implied. Exposure to absolute
maximum ratings conditions for extended periods may affect device reliability.
62
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.2. Recommended Operating Conditions (TA = 0 to 70 °C)
4.6.2.1. General Recommended Operating Conditions
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
VSUP1
First Supply Voltage
(AHVSUP = 8 V)
AHVSUP
7.6
8.0
8.7
V
4.75
5.0
5.25
V
First Supply Voltage
(AHVSUP = 5V)
VSUP2
Second Supply Voltage
DVSUP
4.75
5.0
5.25
V
VSUP3
Third Supply Voltage
AVSUP
4.75
5.0
5.25
V
tSTBYQ1
STANDBYQ Setup Time before
Turn-off of Second Supply Voltage
STANDBYQ,
DVSUP
1
µs
4.6.2.2. Analog Input and Output Recommendations
Symbol
Parameter
Pin Name
Min.
Typ.
CAGNDC
AGNDC-Filter-Capacitor
AGNDC
−20%
3.3
µF
−20%
100
nF
−20%
330
nF
Ceramic Capacitor in Parallel
SCn_IN_s1)
CinSC
DC-Decoupling Capacitor in front of
SCART Inputs
VinSC
SCART Input Level
VinMONO
Input Level, Mono Input
MONO_IN
RLSC
SCART Load Resistance
SCn_OUT_s1)
CLSC
SCART Load Capacitance
CVMA
Main/AUX Volume Capacitor
CAPL_M,
CAPL_A
CFMA
Main/AUX Filter Capacitor
DACM_s,
DACA_s1)
1)
Max.
2.0
VRMS
2.0
VRMS
10
kΩ
6.0
1
nF
µF
10
−10%
Unit
+10%
nF
“n” means “1”, “2”, or “3”, “s” means “L” or “R”, “p” means “M” or “A”
Micronas
63
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.2.3. Recommendations for Analog Sound IF Input Signal
Symbol
Parameter
Pin Name
Min.
Typ.
CVREFTOP
VREFTOP-Filter-Capacitor
VREFTOP
−20 %
10
µF
−20 %
100
nF
Ceramic Capacitor in Parallel
Max.
Unit
FIF_FMTV
Analog Input Frequency Range
for TV Applications
FIF_FMRADIO
Analog Input Frequency for
FM-Radio Applications
VIF_FM
Analog Input Range FM/NICAM
0.1
0.8
3
Vpp
VIF_AM
Analog Input Range AM/NICAM
0.1
0.45
0.8
Vpp
RFMNI
Ratio: NICAM Carrier/FM Carrier
(unmodulated carriers)
BG:
I:
−20
−23
−7
−10
0
0
dB
dB
−25
−11
0
dB
ANA_IN1+,
ANA_IN2+,
ANA_IN−
0
9
10.7
MHz
MHz
RAMNI
Ratio: NICAM Carrier/AM Carrier
(unmodulated carriers)
RFM
Ratio: FM-Main/FM-Sub Satellite
7
dB
RFM1/FM2
Ratio: FM1/FM2
German FM-System
7
dB
RFC
Ratio: Main FM Carrier/
Color Carrier
15
−
−
dB
RFV
Ratio: Main FM Carrier/
Luma Components
15
−
−
dB
PRIF
Passband Ripple
−
−
±2
dB
SUPHF
Suppression of Spectrum
above 9.0 MHz (not for FM Radio)
15
−
dB
FMMAX
Maximum FM-Deviation (approx.)
normal mode
HDEV2: high deviation mode
HDEV3: very high deviation mode
±180
±360
±540
kHz
kHz
kHz
64
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.2.4. Crystal Recommendations
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
General Crystal Recommendations
fP
Crystal Parallel Resonance Frequency at 12 pF Load Capacitance
18.432
RR
Crystal Series Resistance
8
25
Ω
C0
Crystal Shunt (Parallel) Capacitance
6.2
7.0
pF
CL
External Load Capacitance1)
XTAL_IN,
XTAL_OUT
MHz
PSDIP approx. 1.5
P(L)QFP approx. 3.3
pF
pF
Crystal Recommendations for Master-Slave Applications (MSP-clock must perform synchronization to I2S clock)
fTOL
Accuracy of Adjustment
−20
+20
ppm
DTEM
Frequency Variation
versus Temperature
−20
+20
ppm
C1
Motional (Dynamic) Capacitance
19
fCL
Required Open Loop Clock
Frequency (Tamb = 25 °C)
AUD_CL_OUT
18.431
24
fF
18.433
MHz
Crystal Recommendations for FM / NICAM Applications (No MSP-clock synchronization to I2S clock possible)
fTOL
Accuracy of Adjustment
−30
+30
ppm
DTEM
Frequency Variation
versus Temperature
−30
+30
ppm
C1
Motional (Dynamic) Capacitance
15
fCL
Required Open Loop Clock
Frequency (Tamb = 25 °C)
AUD_CL_OUT
18.4305
fF
18.4335
MHz
Crystal Recommendations for all analog FM/AM Applications (No MSP-clock synchronization to I2S clock possible)
fTOL
Accuracy of Adjustment
−100
+100
ppm
DTEM
Frequency Variation
versus Temperature
−50
+50
ppm
fCL
Required Open Loop Clock
Frequency (Tamb = 25 °C)
18.429
18.435
MHz
AUD_CL_OUT
Amplitude Recommendation for Operation with External Clock Input (Cload after reset typ. 22 pF)
VXCA
1)
External Clock Amplitude
XTAL_IN
0.7
Vpp
External capacitors at each crystal pin to ground are required. They are necessary to tune the open-loop frequency of the internal PLL and to stabilize the frequency in closed-loop operation.
Due to different layouts, the accurate capacitor size should be determined with the customer PCB. The suggested values (1.5...3.3 pF) are figures based on experience and should serve as “start value”.
To define the capacitor size, reset the MSP without transmitting any further I2C telegrams. Measure the frequency at AUD_CL_OUT-pin. Change the capacitor size until the free running frequency matches 18.432 MHz
as closely as possible. The higher the capacity, the lower the resulting clock frequency.
Micronas
65
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3. Characteristics
at TA = 0 to 70 °C, fCLOCK = 18.432 MHz, VSUP1 = 7.6 to 8.7 V, VSUP2 = 4.75 to 5.25 V for min./max. values
at TA = 60 °C, fCLOCK = 18.432 MHz, VSUP1 = 8 V, VSUP2 = 5 V for typical values,
TJ = Junction Temperature
MAIN (M) = Loudspeaker Channel, AUX (A) = Headphone Channel
4.6.3.1. General Characteristics
Symbol
Parameter
Pin Name
First Supply Current (active)
(AHVSUP = 8 V)
AHVSUP
Min.
Typ.
Max.
Unit
Test Conditions
17
11
25
16
mA
mA
Vol. Main and Aux = 0 dB
Vol. Main and Aux = -30dB
11
8
17
11
mA
mA
Vol. Main and Aux = 0 dB
Vol. Main and Aux = -30 dB
Supply
ISUP1A
First Supply Current (active)
(AHVSUP = 5 V)
ISUP2A
Second Supply Current (active)
DVSUP
55
70
mA
ISUP3A
Third Supply Current (active)
AVSUP
30
38
mA
ISUP1S
First Supply Current
(AHVSUP = 8 V)
AHVSUP
5.6
7.7
mA
3.7
5.1
mA
First Supply Current
(AHVSUP = 5 V)
STANDBYQ = low
Clock
fCLOCK
Clock Input Frequency
DCLOCK
Clock High to Low Ratio
tJITTER
Clock Jitter (Verification not
provided in Production Test)
VxtalDC
DC-Voltage Oscillator
tStartup
Oscillator Startup Time at
VDD Slew-rate of 1 V/1 µs
XTAL_IN,
XTAL_OUT
VACLKAC
Audio Clock Output AC Voltage
AUD_CL_OUT
VACLKDC
Audio Clock Output DC Voltage
routHF_ACL
HF Output Resistance
66
XTAL_IN
18.432
45
MHz
55
%
50
ps
2.5
0.4
1.2
V
2
1.8
0.4
0.6
140
ms
Vpp
load = 40 pF
VSUP3
Imax = 0.2 mA
Ω
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.2. Digital Inputs, Digital Outputs
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
0.2
VSUP2
Test Conditions
Digital Input Levels
VDIGIL
Digital Input Low Voltage
STANDBYQ
D_CTR_I/O_0/1
VDIGIH
Digital Input High Voltage
ZDIGI
Input Impedance
IDLEAK
Digital Input Leakage Current
VDIGIL
Digital Input Low Voltage
VDIGIH
Digital Input High Voltage
0.8
IADRSEL
Input Current Address Select Pin
−500
0.5
VSUP2
−1
ADR_SEL
5
pF
1
µA
0.2
VSUP2
0 V < UINPUT< DVSUP
D_CTR_I/O_0/1: tri-state
VSUP2
−220
220
µA
UADR_SEL= DVSS
500
µA
UADR_SEL= DVSUP
0.4
V
IDDCTR = 1 mA
V
IDDCTR = −1 mA
Digital Output Levels
VDCTROL
Digital Output Low Voltage
VDCTROH
Digital Output High Voltage
Micronas
D_CTR_I/O_0
D_CTR_I/O_1
VSUP2
−0.3
67
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.3. Reset Input and Power-Up
Symbol
Parameter
Pin Name
Min.
RESETQ
Typ.
Max.
Unit
0.3
0.4
VSUP2
0.45
0.55
VSUP2
Test Conditions
RESETQ Input Levels
VRHL
Reset High-Low Transition Voltage
VRLH
Reset Low-High Transition Voltage
ZRES
Input Capacitance
5
pF
IRES
Input High Current
20
µA
URESETQ = DVSUP
DVSUP
AVSUP
4.5 V
t/ms
RESETQ
Note: The reset should
not reach high level
before the oscillator has
started. This requires a
reset delay of >2 ms
Low-to-High
Threshold
0.45× DVSUP
High-to-Low
Threshold
0.3...0.4× DVSUP
0.45 x DVSUP means
2.25 Volt with
DVSUP = 5.0 V
t/ms
Reset Delay
>2 ms
Internal
Reset
High
Low
t/ms
Fig. 4–26: Power-up sequence
68
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.4. I2C-Bus Characteristics
Symbol
Parameter
Pin Name
VI2CIL
I2C-Bus Input Low Voltage
I2C_CL,
I2C_DA
VI2CIH
I2C-Bus Input High Voltage
0.6
VSUP2
tI2C1
I2C Start Condition Setup Time
120
ns
tI2C2
I2C Stop Condition Setup Time
120
ns
tI2C5
I2C-Data Setup Time
before Rising Edge of Clock
55
ns
tI2C6
I2C-Data Hold Time
after Falling Edge of Clock
55
ns
tI2C3
I2C-Clock Low Pulse Time
500
ns
tI2C4
I2C-Clock High Pulse Time
500
ns
fI2C
I2C-BUS Frequency
VI2COL
I2C-Data Output Low Voltage
II2COH
I2C-Data Output
High Leakage Current
tI2COL1
I2C-Data Output Hold Time
after Falling Edge of Clock
15
ns
tI2COL2
I2C-Data Output Setup Time
before Rising Edge of Clock
100
ns
I2C_CL
Min.
Typ.
I2C_CL,
I2C_DA
Max.
Unit
0.3
VSUP2
Test Conditions
1.0
MHz
0.4
V
II2COL = 3 mA
1.0
µA
VI2COH = 5 V
fI2C = 1 MHz
1/FI2C
TI2C4
I2C_CL
TI2C1
TI2C5
TI2C3
TI2C6
TI2C2
I2C_DA as input
TI2COL2
TI2COL1
I2C_DA as output
Fig. 4–27: I2C bus timing diagram
Micronas
69
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.5. I2S-Bus Characteristics
Symbol
Parameter
Pin Name
VI2SIL
Input Low Voltage
VI2SIH
Input High Voltage
I2S_CL
I2S_WS
I2S_DA_IN1/2
ZI2SI
Input Impedance
ILEAKI2S
Input Leakage Current
VI2SOL
I2S Output Low Voltage
VI2SOH
I2S Output High Voltage
I2S_CL
I2S_WS
I2S_DA_OUT
fI2SOWS
I2S-Word Strobe Output Frequency
I2S_WS
32.0
kHz
fI2SOCL
I2S-Clock Output Frequency
I2S_CL
1.024
2.048
MHz
MHz
I2S_CONFIG[0] = 0
I2S_CONFIG[0] = 1
RI2S10/I2S20
I2S-Clock Output High/Low-Ratio
ts_I2S
I2S Input Setup Time
before Rising Edge of Clock
12
ns
for details see Fig. 4–28
“I2S bus timing diagram”
th_I2S
I2S Input Hold Time
after Rising Edge of Clock
40
ns
td_I2S
I2S Output Delay Time
after Falling Edge of Clock
I2S_CL
I2S_WS
I2S_DA_OUT
fI2SWS
I2S-Word Strobe Input Frequency
I2S_WS
32.0
kHz
fI2SCL
I2S-Clock Input Frequency
I2S_CL
1.024
MHz
RI2SCL
I2S-Clock Input High/Low Ratio
70
Min.
Typ.
Unit
0.2
VSUP2
0.5
5
pF
1
µA
0 V < UINPUT< DVSUP
0.4
V
II2SOL = 1 mA
V
II2SOH = −1 mA
VSUP2
− 0.3
0.9
1.0
1.1
28
0.9
Test Conditions
VSUP2
−1
I2S_CL
I2S_DA_IN1/2
Max.
ns
CL = 30 pF
1.1
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
1/FI2SWS
I2S_WS
MODUS[6] = 0
MODUS[6] = 1
Detail C
I2S_CL
Detail A
I2S_DA_IN
L LSB R MSB
R LSB L MSB
R LSB L LSB
16/32 bit left channel
16/32 bit right channel
Detail B
I2S_DA_OUT R LSB
L LSB R MSB
L MSB
R LSB L LSB
16/32 bit left channel
16/32 bit right channel
Data: MSB first, I2S master
1/FI2SWS
I2S_WS
MODUS[6] = 0
MODUS[6] = 1
Detail C
I2S_CL
Detail A
I2S_DA_IN
L LSB R MSB
R LSB L MSB
R LSB L LSB
16, 18...32 bit right channel
16,18...32 bit left channel
Detail B
I2S_DA_OUT R LSB
16, 18...32 bit left channel
L LSB R MSB
L MSB
R LSB L LSB
16, 18...32 bit right channel
Data: MSB first, I2S slave
Detail C
Detail A,B
1/FI2SCL
I2S_CL
I2S_CL
Ts_I2S
Th_I2S
Ts_I2S
I2S_DA_IN1/2
I2S_WS as INPUT
Td_I2S
Td_I2S
I2S_WS as OUTPUT
I2S_DA_OUT
Fig. 4–28: I2S bus timing diagram
Micronas
71
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.6. Analog Baseband Inputs and Outputs, AGNDC
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
3.77
V
Rload ≥10 MΩ
2.51
V
Analog Ground
VAGNDC0
AGNDC Open Circuit Voltage
(AHVSUP = 8 V)
AGNDC
AGNDC Open Circuit Voltage
(AHVSUP = 5 V)
RoutAGN
AGNDC Output Resistance
(AHVSUP = 8 V)
70
125
180
kΩ
AGNDC Output Resistance
(AHVSUP = 5 V)
47
83
120
kΩ
3 V ≤ VAGNDC ≤ 4 V
Analog Input Resistance
RinSC
SCART Input Resistance
from TA = 0 to 70 °C
SCn_IN_s1)
25
40
58
kΩ
fsignal = 1 kHz, I = 0.05 mA
RinMONO
MONO Input Resistance
from TA = 0 to 70 °C
MONO_IN
15
24
35
kΩ
fsignal = 1 kHz, I = 0.1 mA
SCn_IN_s,1)
MONO_IN
2.00
2.25
VRMS
fsignal = 1 kHz
1.13
1.51
VRMS
460
500
Ω
Ω
−70
+70
mV
Audio Analog-to-Digital-Converter
VAICL
Analog Input Clipping Level for
Analog-to-DigitalConversion
(AHVSUP = 8 V)
Analog Input Clipping Level for
Analog-to-DigitalConversion
(AHVSUP = 5 V)
SCART Outputs
RoutSC
SCART Output Resistance
dVOUTSC
Deviation of DC-Level at SCART
Output from AGNDC Voltage
ASCtoSC
Gain from Analog Input
to SCART Output
frSCtoSC
Frequency Response from Analog
Input to SCART Output
VoutSC
Signal Level at SCART Output
(AHVSUP = 8 V)
SCn_OUT_s1)
200
200
72
“n” means “1”, “2”, “3”, or “4”;
fsignal = 1 kHz, I = 0.1 mA
Tj = 27 °C
TA = 0 to 70 °C
SCn_IN_s,1)
MONO_IN
→
SCn_OUT_s1)
−1.0
+0.5
dB
fsignal = 1 kHz
−0.5
+0.5
dB
with resp. to 1 kHz
Bandwidth: 0 to 20000 Hz
SCn_OUT_s1)
1.8
1.9
2.0
VRMS
fsignal = 1 kHz
Volume 0 dB
Full Scale input from I2S
1.17
1.27
1.37
VRMS
Signal Level at SCART Output
(AHVSUP = 5V)
1)
330
“s” means “L” or “R”;
“p” means “M” or “A”
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
2.1
2.1
3.3
4.6
5.0
kΩ
kΩ
fsignal = 1 kHz, I = 0.1 mA
Tj = 27 °C
TA = 0 to 70 °C
Main and AUX Outputs
DACp_s1)
RoutMA
Main/AUX Output Resistance
VoutDCMA
DC-Level at Main/AUX-Output
(AHVSUP = 8 V)
1.80
2.04
61
2.28
V
mV
Volume 0 dB
Volume −30 dB
DC-Level at Main/AUX-Output
(AHVSUP = 5 V)
1.12
1.36
40
1.60
V
mV
Volume 0 dB
Volume −30 dB
Signal Level at Main/AUX-Output
(AHVSUP = 8 V)
1.23
1.37
1.51
VRMS
fsignal = 1 kHz
Volume 0 dB
Full scale input from I2S
Signal Level at Main/AUX-Output
(AHVSUP = 5 V)
0.76
0.90
1.04
VRMS
VoutMA
1)
“n” means “1”, “2”, “3”, or “4”;
“s” means “L” or “R”;
“p” means “M” or “A”
4.6.3.7. Sound IF Inputs
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
RIFIN
Input Impedance
ANA_IN1+,
ANA_IN2+,
ANA_IN−
1.5
6.8
2
9.1
2.5
11.4
kΩ
kΩ
Gain AGC = 20 dB
Gain AGC = 3 dB
DCVREFTOP
DC Voltage at VREFTOP
VREFTOP
2.45
2.65
2.75
V
DCANA_IN
DC Voltage on IF Inputs
ANA_IN1+,
ANA_IN2+,
ANA_IN−
1.3
1.5
1.7
V
XTALKIF
Crosstalk Attenuation
40
dB
BWIF
3 dB Bandwidth
ANA_IN1+,
ANA_IN2+,
ANA_IN−
10
MHz
AGC
AGC Step Width
0.85
fsignal = 1 MHz
Input Level = −2 dBr
dB
4.6.3.8. Power Supply Rejection
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
PSRR: Rejection of Noise on AHVSUP at 1 kHz
PSRR
1)
AGNDC
AGNDC
80
dB
From Analog Input to I2S Output
MONO_IN,
SCn_IN_s1)
70
dB
From Analog Input to
SCART Output
MONO_IN,
SCn_IN_s1)
SCn_OUT_s1)
70
dB
From I2S Input to SCART Output
SCn_OUT_s1)
60
dB
From I2S Input to MAIN or AUX
Output
DACp_s1)
80
dB
“n” means “1”, “2”, “3”, or “4”;
Micronas
“s” means “L” or “R”;
“p” means “M” or “A”
73
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.9. Analog Performance
Symbol
Parameter
Pin Name
Min.
Typ.
from Analog Input to I2S Output
MONO_IN,
SCn_IN_s1)
85
from Analog Input to
SCART Output
MONO_IN,
SCn_IN_s1)
→
SCn_OUT_s1)
from I2S Input to SCART Output
SCn_OUT_s1)
from I2S Input to Main/AUX-Output
for Analog Volume at 0 dB
for Analog Volume at −30 dB
DACp_s1)
Max.
Unit
Test Conditions
88
dB
Input Level = −20 dB with
resp. to VAICL, fsig = 1 kHz,
unweighted
20 Hz...16 kHz
93
96
dB
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...20 kHz
85
88
dB
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
85
78
88
83
dB
dB
Specifications for AHVSUP = 8 V
SNR
THD
1)
74
Signal-to-Noise Ratio
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
Total Harmonic Distortion
from Analog Input to I2S Output
MONO_IN,
SCn_IN_s1)
0.01
0.03
%
Input Level = −3 dBr with
resp. to VAICL, fsig = 1 kHz,
unweighted
20 Hz...16 kHz
from Analog Input to
SCART Output
MONO_IN,
SCn_IN_s
→
SCn_OUT_s1)
0.01
0.03
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...20 kHz
from I2S Input to SCART Output
SCn_OUT_s1)
0.01
0.03
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
from I2S Input to Main or AUX Output
DACA_s,
DACM_s1)
0.01
0.03
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
“n” means “1”, “2”, “3”, or “4”;
“s” means “L” or “R”;
“p” means “M” or “A”
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Symbol
Parameter
Pin Name
Min.
Typ.
from Analog Input to I2S Output
MONO_IN,
SCn_IN_s1)
82
from Analog Input to
SCART Output
MONO_IN,
SCn_IN_s1)
→
SCn_OUT_s1)
from I2S Input to SCART Output
SCn_OUT_s1)
from I2S Input to Main/AUX-Output
for Analog Volume at 0 dB
for Analog Volume at −30 dB
DACp_s1)
Max.
Unit
Test Conditions
85
dB
Input Level = −20 dB with
resp. to VAICL, fsig = 1 kHz,
unweighted
20 Hz...16 kHz
90
93
dB
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...20 kHz
82
85
dB
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
82
75
85
80
dB
dB
Specifications for AHVSUP = 5 V
SNR
THD
1)
Signal-to-Noise Ratio
Total Harmonic Distortion
0.1
%
Input Level = −3 dBr with
resp. to VAICL, fsig = 1 kHz,
unweighted
20 Hz...16 kHz
MONO_IN,
SCn_IN_s
→
SCn_OUT_s1)
0.1
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...20 kHz
from I2S Input to SCART Output
SCn_OUT_s1)
0.1
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
from I2S Input to Main or AUX Output
DACA_s,
DACM_s1)
0.1
%
Input Level = −3 dBr,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
from Analog Input to I2S Output
MONO_IN,
SCn_IN_s1)
from Analog Input to
SCART Output
“n” means “1”, “2”, “3”, or “4”;
Micronas
Input Level = −20 dB,
fsig = 1 kHz,
unweighted
20 Hz...16 kHz
“s” means “L” or “R”;
0.03
“p” means “M” or “A”
75
MSP 34x1G
Symbol
PRELIMINARY DATA SHEET
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
CROSSTALK Specifications for AHVSUP = 8 V and 5 V
XTALK
Crosstalk Attenuation
− PLCC68
− PSDIP64
Input Level = −3 dB,
fsig = 1 kHz, unused analog inputs connected to
ground by Z < 1 kΩ
between left and right channel within
SCART Input/Output pair (L→R, R→L)
unweighted
20 Hz...20 kHz
SCn_IN → SCn_OUT1)
PLCC68
PSDIP64
80
80
dB
dB
SC1_IN or SC2_IN → I2S Output
PLCC68
PSDIP64
80
80
dB
dB
SC3_IN → I2S Output
PLCC68
PSDIP64
80
80
dB
dB
I2S Input → SCn_OUT1)
PLCC68
PSDIP64
80
80
dB
dB
between left and right channel within
Main or AUX Output pair
I2S Input → DACp1)
unweighted
20 Hz...16 kHz
PLCC68
PSDIP64
80
75
dB
dB
between SCART Input/Output pairs
D = disturbing program
O = observed program
D: MONO/SCn_IN → SCn_OUT
O: MONO/SCn_IN → SCn_OUT1)
PLCC68
PSDIP64
100
100
dB
dB
D: MONO/SCn_IN → SCn_OUT or unsel.
O: MONO/SCn_IN → I2S Output
PLCC68
PSDIP64
100
95
dB
dB
D: MONO/SCn_IN → SCn_OUT
O: I2S Input → SCn_OUT1)
PLCC68
PSDIP64
100
100
dB
dB
D: MONO/SCn_IN → unselected
O: I2S Input → SC1_OUT1)
PLCC68
PSDIP64
100
100
dB
dB
Crosstalk between Main and AUX Output pairs
I2S Input → DACp1)
XTALK
PLCC68
PSDIP64
95
90
dB
dB
76
unweighted
20 Hz...16 kHz
same signal source on left
and right disturbing channel, effect on each
observed output channel
unweighted
20 Hz...20 kHz
same signal source on left
and right disturbing channel, effect on each
observed output channel
Crosstalk from Main or AUX Output to SCART Output
and vice versa
D = disturbing program
O = observed program
1)
unweighted
20 Hz...20 kHz
same signal source on left
and right disturbing channel, effect on each
observed output channel
D: MONO/SCn_IN/DSP → SCn_OUT
O: I2S Input → DACp1)
PLCC68
PSDIP64
85
80
dB
dB
SCART output load resistance 10 kΩ
D: MONO/SCn_IN/DSP → SCn_OUT
O: I2S Input → DACp1)
PLCC68
PSDIP64
90
85
dB
dB
SCART output load resistance 30 kΩ
D: I2S Input → DACp
O: MONO/SCn_IN → SCn_OUT1)
PLCC68
PSDIP64
100
95
dB
dB
D: I2S Input → DACM
O: I2S Input → SCn_OUT1)
PLCC68
PSDIP64
100
95
dB
dB
“n” means “1”, “2”, “3”, or “4”;
“s” means “L” or “R”;
“p” means “M” or “A”
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
4.6.3.10. Sound Standard Dependent Characteristics
Symbol
Parameter
Pin Name
Min.
DACp_s,
SCn_OUT_s1)
−1.5
Typ.
Max.
Unit
Test Conditions
+1.5
dB
2.12 kHz, Modulator input
level = 0 dBref
dB
NICAM: −6 dB, 1 kHz, RMS
unweighted
0 to 15 kHz, Vol = 9 dB
NIC_Presc = 7Fhex
Output level 1 VRMS at
DACp_s
NICAM Characteristics (MSP Standard Code = 8)
dVNICAMOUT
Tolerance of Output Voltage
of NICAM Baseband Signal
S/NNICAM
S/N of NICAM Baseband Signal
THDNICAM
Total Harmonic Distortion + Noise
of NICAM Baseband Signal
0.1
%
2.12 kHz, Modulator input
level = 0 dBref
BERNICAM
NICAM: Bit Error Rate
1
10−7
FM+NICAM, norm conditions
fRNICAM
NICAM Frequency Response ,
20...15000 Hz
−1.0
+1.0
dB
Modulator input
level = −12 dB dBref; RMS
XTALKNICAM
NICAM Crosstalk Attenuation (Dual)
80
dB
SEPNICAM
NICAM Channel Separation (Stereo)
80
dB
72
FM Characteristics (MSP Standard Code = 3)
−1.5
dVFMOUT
Tolerance of Output Voltage
of FM Demodulated Signal
S/NFM
S/N of FM Demodulated Signal
THDFM
Total Harmonic Distortion + Noise
of FM Demodulated Signal
fRFM
FM Frequency Response
20...15000 Hz
−1.0
XTALKFM
FM Crosstalk Attenuation (Dual)
SEPFM
FM Channel Separation (Stereo)
DACp_s,
SCn_OUT_s1)
+1.5
73
dB
1 FM-carrier, 50 µs, 1 kHz,
40 kHz deviation; RMS
dB
1 FM-carrier 5.5 MHz, 50 µs,
1 kHz, 40 kHz deviation;
RMS, unweighted
0 to 15 kHz (for S/N);
full input range, FM-Prescale = 46hex, Vol = 0 dB
→ Output Level 1 VRMS at
DACp_s
0.1
%
+1.0
dB
1 FM-carrier 5.5 MHz,
50 µs, Modulator input
level = −14.6 dBref; RMS
80
dB
2 FM-carriers 5.5/5.74 MHz,
50 µs, 1 kHz, 40 kHz deviation; Bandpass 1 kHz
50
dB
2 FM-carriers 5.5/5.74 MHz,
50 µs, 1 kHz, 40 kHz deviation; RMS
55
dB
45
dB
SIF level: 0.1−0.8 Vpp
AM-carrier 54% at 6.5 MHz
Vol = 0 dB, FM/AM
prescaler set for
output = 0.5 VRMS at
Loudspeaker out;
Standard Code = 09hex
no video/chroma
components
AM Characteristics (MSP Standard Code = 9)
S/NAM(1)
S/N of AM Demodulated Signal
measurement condition: RMS/Flat
S/NAM(2)
S/N of AM Demodulated Signal
measurement condition: QP/CCIR
THDAM
Total Harmonic Distortion + Noise
of AM Demodulated Signal
fRAM
AM Frequency Response
50...12000 Hz
1) “n” means “1” or “2”;
Micronas
“s” means “L” or “R”;
DACp_s,
SCn_OUT_s1)
−2.5
0.6
%
+1.0
dB
“p” means “M’’ or ‘‘A’’
77
MSP 34x1G
Symbol
Parameter
PRELIMINARY DATA SHEET
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
68
dB
57
dB
1 kHz L or R or SAP, 100%
modulation, 75 µs deemphasis, RMS unweighted 0 to 15
kHz
BTSC Characteristics (MSP Standard Code = 20hex, 21hex)
S/NBTSC
S/N of BTSC Stereo Signal
S/N of BTSC-SAP Signal
THDBTSC
DACp_s,
SCn_OUT_s1)
THD+N of BTSC Stereo Signal
0.1
%
THD+N of BTSC SAP Signal
0.5
%
1 kHz L or R or SAP, 100%
75 µs EIM2), DBX NR or
MNR, RMS unweighted
0 to 15 kHz
Frequency Response of BTSC
Stereo, 50 Hz...12 kHz
−1.0
1.0
dB
Frequency Response of BTSCSAP, 50 Hz...9 kHz
−1.0
1.0
dB
Frequency Response of BTSC
Stereo, 50 Hz...12 kHz
−2.0
2.0
dB
L or R 5%...66% EIM2), MNR
Frequency Response of BTSCSAP, 50 Hz...9 kHz
−2.0
2.0
dB
SAP, white noise, 10% Modulation, MNR
Stereo → SAP
76
dB
SAP → Stereo
80
dB
1 kHz L or R or SAP, 100%
modulation, 75 µs deemphasis, Bandpass 1 kHz
Stereo Separation DBX NR
50 Hz...10 kHz
50 Hz...12 kHz
35
30
dB
dB
SEPMNR
Stereo Separation MNR
30
dB
FMpil
Pilot deviation threshold
fRDBX
fRMNR
XTALKBTSC
SEPDBX
Stereo off → on
fPilot
ANA_IN1+,
ANA_IN2+
3.2
3.5
kHz
Stereo on → off
1.2
1.5
kHz
Pilot Frequency Range
15.563
15.843
kHz
L or R or SAP,
1%...66% EIM2), DBX NR
L or R 1%...66% EIM2), DBX
NR
L = 300 Hz, R = 3.1 kHz
14% Modulation, MNR
4.5 MHz carrier modulated
with fh = 15.734 kHz
SIF level = 100 mVpp
indication: STATUS Bit[6]
standard BTSC stereo signal,
sound carrier only
1) “n” means “1” or “2”;
“s” means “L” or “R”; “p” means “M’’ or ‘‘A’’
2) EIM refers to 75-µs Equivalent Input Modulation. It is defined as the audio-signal level which results in a stated percentage modulation,
when the DBX encoding process is replaced by a 75-µs preemphasis network.
78
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Symbol
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
BTSC Characteristics (MSP Standard Code = 20hex, 21hex)
with a minimum IF input signal level of 70 mVpp (measured without any video/chroma signal components)
S/NBTSC
S/N of BTSC Stereo Signal
S/N of BTSC-SAP Signal
THDBTSC
fRDBX
fRMNR
XTALKBTSC
SEPDBX
SEPMNR
DACp_s,
SCn_OUT_s1)
64
dB
55
dB
THD+N of BTSC Stereo Signal
0.15
%
THD+N of BTSC SAP Signal
0.8
%
1 kHz L or R or SAP, 100%
modulation, 75 µs deemphasis, RMS unweighted 0 to 15
kHz
1 kHz L or R or SAP, 100%
75 µs EIM2), DBX NR or
MNR, RMS unweighted
0 to 15 kHz
Frequency Response of BTSC
Stereo, 50 Hz...12 kHz
−1.0
1.0
dB
Frequency Response of BTSCSAP, 50 Hz...9 kHz
−1.0
1.0
dB
Frequency Response of BTSC
Stereo, 50 Hz...12 kHz
−2.0
2.0
dB
L or R 5%...66% EIM2), MNR
Frequency Response of BTSCSAP, 50 Hz...9 kHz
−2.0
2.0
dB
SAP, white noise, 10% Modulation, MNR
Stereo → SAP
75
dB
SAP → Stereo
75
dB
1 kHz L or R or SAP, 100%
modulation, 75 µs deemphasis, Bandpass 1 kHz
Stereo Separation DBX NR
50 Hz...10 kHz
50 Hz...12 kHz
35
30
dB
dB
Stereo Separation MNR
30
dB
L or R or SAP,
1%...66% EIM2), DBX NR
L or R 1%...66% EIM2), DBX
NR
L = 300 Hz, R = 3.1 kHz
14% Modulation, MNR
1) “n” means “1” or “2”;
“s” means “L” or “R”; “p” means “M’’ or ‘‘A’’
EIM refers to 75-µs Equivalent Input Modulation. It is defined as the audio-signal level which results in a stated percentage modulation,
when the DBX encoding process is replaced by a 75-µs preemphasis network.
2)
Micronas
79
MSP 34x1G
Symbol
PRELIMINARY DATA SHEET
Parameter
Pin Name
Min.
Typ.
Max.
Unit
Test Conditions
60
dB
60
dB
1 kHz L or R,
100% modulation,
75 µs deemphasis,
RMS unweighted
0 to 15 kHz
EIA-J Characteristics (MSP Standard Code = 30hex)
S/NEIAJ
S/N of EIA-J Stereo Signal
S/N of EIA-J Sub-Channel
THDEIAJ
fREIAJ
XTALKEIAJ
SEPEIAJ
DACp_s,
SCn_OUT_s1)
THD+N of EIA-J Stereo Signal
0.2
%
THD+N of EIA-J Sub-Channel
0.3
%
Frequency Response of EIA-J
Stereo, 50 Hz...12 kHz
−0.5
0.5
dB
Frequency Response of EIA-J
Sub-Channel, 50 Hz...12 kHz
−1.0
0.5
dB
Main → SUB
66
dB
Sub → MAIN
80
dB
Stereo Separation
50 Hz...5 kHz
50 Hz...10 kHz
35
28
dB
dB
68
dB
100% modulation,
75 µs deemphasis
1 kHz L or R, 100% modulation, 75 µs deemphasis,
Bandpass 1 kHz
EIA-J Stereo Signal, L or R
100% modulation
FM-Radio Characteristics (MSP Standard Code = 40hex)
S/NUKW
S/N of FM-Radio Stereo Signal
THDUKW
THD+N of FM-Radio Stereo Signal
fRUKW
Frequency Response of
FM-Radio Stereo
50 Hz...15 kHz
−1.0
SEPUKW
Stereo Separation 50 Hz...15 kHz
45
fPilot
Pilot Frequency Range
1) “n” means “1” or “2”;
80
“s” means “L” or “R”;
DACp_s,
SCn_OUT_s1)
0.1
ANA_IN1+
ANA_IN2+
18.844
+0.5
%
1 kHz L or R, 100% modulation, 75 µs deemphasis, RMS
unweighted
0 to 15 kHz
L or R, 1%...100% modulation, 75 µs deemphasis
dB
dB
19.125
kHz
standard FM radio
stereo signal
“p” means “M’’ or ‘‘A’’
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
5. Appendix A: Overview of TV-Sound Standards
5.1. NICAM 728
Table 5–1: Summary of NICAM 728 sound modulation parameters
Specification
I
B/G
L
D/K
Carrier frequency of
digital sound
6.552 MHz
5.85 MHz
5.85 MHz
5.85 MHz
Transmission rate
728 kbit/s
Type of modulation
Differentially encoded quadrature phase shift keying (DQPSK)
Spectrum shaping
Roll-off factor
by means of Roll-off filters
Carrier frequency of
analog sound component
1.0
0.4
6.0 MHz
FM mono
5.5 MHz
FM mono
0.4
0.4
6.5 MHz AM mono
terrestrial
cable
6.5 MHz
FM mono
Power ratio between
vision carrier and
analog sound carrier
10 dB
13 dB
10 dB
16 dB
13 dB
Power ratio between
analog and modulated
digital sound carrier
10 dB
7 dB
17 dB
11 dB
China/
Hungary
Poland
12 dB
7 dB
Table 5–2: Summary of NICAM 728 sound coding characteristics
Characteristics
Values
Audio sampling frequency
32 kHz
Number of channels
2
Initial resolution
14 bit/sample
Companding characteristics
near instantaneous, with compression to 10 bits/sample in 32-samples (1 ms) blocks
Coding for compressed samples
2’s complement
Preemphasis
CCITT Recommendation J.17 (6.5 dB attenuation at 800 Hz)
Audio overload level
+12 dBm measured at the unity gain frequency of the preemphasis network (2 kHz)
Micronas
81
MSP 34x1G
PRELIMINARY DATA SHEET
5.2. A2-Systems
Table 5–3: Key parameters for A2 Systems of Standards B/G, D/K, and M
Characteristics
Sound Carrier FM1
Sound Carrier FM2
TV-Sound Standard
B/G
D/K
M
B/G
D/K
M
Carrier frequency in MHz
5.5
6.5
4.5
5.7421875
6.2578125
6.7421875
5.7421875
4.724212
Vision/sound power difference
13 dB
20 dB
Sound bandwidth
Preemphasis
Frequency deviation (nom/max)
40 Hz to 15 kHz
50 µs
75 µs
±27/±50 kHz
±17/±25 kHz
50 µs
75 µs
±27/±50 kHz
±15/±25 kHz
Transmission Modes
Mono transmission
Stereo transmission
Dual sound transmission
mono
(L+R)/2
language A
mono
(L+R)/2
R
(L−R)/2
language B
Identification of Transmission Mode
Pilot carrier frequency
54.6875 kHz
Max. deviation portion
±2.5 kHz
Type of modulation / modulation depth
AM / 50%
Modulation frequency
82
mono: unmodulated
stereo: 117.5 Hz
dual: 274.1 Hz
55.0699 kHz
149.9 Hz
276.0 Hz
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
5.3. BTSC-Sound System
Table 5–4: Key parameters for BTSC-Sound Systems
Aural
Carrier
Carrier frequency
(fhNTSC = 15.734 kHz)
(fhPAL = 15.625 kHz)
4.5 MHz
BTSC-MPX-Components
(L+R)
Pilot
(L−R)
SAP
Prof. Ch.
Baseband
fh
2 fh
5 fh
6.5 fh
Sound bandwidth in kHz
0.05 - 15
0.05 - 15
0.05 - 12
0.05 - 3.4
Preemphasis
75 µs
DBX
DBX
150 µs
50 kHz1)
15 kHz
3 kHz
AM
10 kHz
FM
3 kHz
FM
Max. deviation to Aural Carrier
73 kHz
(total)
25 kHz1)
5 kHz
Max. Freq. Deviation of Subcarrier
Modulation Type
1)
Sum does not exceed 50 kHz due to interleaving effects
5.4. Japanese FM Stereo System (EIA-J)
Table 5–5: Key parameters for Japanese FM-Stereo Sound System EIA-J
Aural
Carrier
FM
(L+R)
(L−R)
Identification
4.5 MHz
Baseband
2 fh
3.5 fh
Sound bandwidth
0.05 - 15 kHz
0.05 - 15 kHz
−
Preemphasis
75 µs
75 µs
none
25 kHz
20 kHz
2 kHz
10 kHz
FM
60%
AM
Carrier frequency (fh = 15.734 kHz)
Max. deviation portion to Aural Carrier
47 kHz
EIA-J-MPX-Components
Max. Freq. Deviation of Subcarrier
Modulation Type
Transmitter-sided delay
20 µs
0 µs
0 µs
Mono transmission
L+R
−
unmodulated
Stereo transmission
L+R
L−R
982.5 Hz
Bilingual transmission
Language A
Language B
922.5 Hz
Micronas
83
MSP 34x1G
PRELIMINARY DATA SHEET
5.5. FM Satellite Sound
Table 5–6: Key parameters for FM Satellite Sound
Carrier Frequency
Maximum
FM Deviation
Sound Mode
Bandwidth
Deemphasis
6.5 MHz
85 kHz
Mono
15 kHz
50 µs
7.02/7.20 MHz
50 kHz
Mono/Stereo/Bilingual
15 kHz
adaptive
7.38/7.56 MHz
50 kHz
Mono/Stereo/Bilingual
15 kHz
adaptive
7.74/7.92 MHz
50 kHz
Mono/Stereo/Bilingual
15 kHz
adaptive
5.6. FM-Stereo Radio
Table 5–7: Key parameters for FM-Stereo Radio Systems
Aural
Carrier
Carrier frequency (fp = 19 kHz)
10.7 MHz
FM-Radio-MPX-Components
(L+R)
Pilot
(L−R)
RDS/ARI
Baseband
fp
2 fp
3 fh
Sound bandwidth in kHz
0.05 - 15
0.05 - 15
Preemphasis:
− USA
− Europe
75 µs
50 µs
75 µs
50 µs
Max. deviation to Aural Carrier
84
75 kHz
(100%)
90%
10%
90%
5%
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6. Appendix B: Manual/Compatibility Mode
To adapt the modes of the STANDARD SELECT register to individual requirements and for reasons of compatibility to the MSP 34x0D, the MSP 34x1G offers
an Manual/Compatibility Mode, which provides sophisticated programming of the MSP 34x1G.
Using the STANDARD SELECT register generally provides a more economic way to program the
MSP 34x1G and will result in optimal behavior. Therefore, it is not recommend to use the Manual/Compatibility mode. In those cases, where the
MSP 34xxD is to be substituted by the MSP 34x1G,
the tips given in Section 6.10. on page 101 have to be
obeyed by the controller software.
6.1. Demodulator Write and Read Registers for Manual/Compatibility Mode
Table 6–1: Demodulator Write Registers; Subaddress: 10hex; these registers are not readable!
Demodulator
Write Registers
Address
(hex)
MSPVersion
Description
Reset
Mode
Page
AUTO_FM/AM
00 21
3411,
3451
1. MODUS[0]=1 (Automatic Sound Select): Switching Level threshold of
Automatic Switching between NICAM and FM/AM in case of bad NICAM
reception
00 00
87
2. MODUS[0]=0 (Manual Mode): Activation and configuration of Automatic
Switching between NICAM and FM/AM in case of bad NICAM reception
A2_Threshold
00 22
all
A2 Stereo Identification Threshold
00 19hex
89
CM_Threshold
00 24
all
Carrier-Mute Threshold
00 2Ahex
89
AD_CV
00 BB
all
SIF-input selection, configuration of AGC, and Carrier-Mute Function
00 00
90
MODE_REG
00 83
3411,
3451
Controlling of MSP-Demodulator and Interface options. As soon as this
register is applied, the MSP 34x1G works in the MSP 34x0D Compatibility
Mode.
00 00
91
Warning: In this mode, BTSC, EIA-J, and FM-Radio are disabled. Only
MSP 34x0D features are available; the use of MODUS and STATUS register
is not allowed.
The MSP 34x1G is reset to the normal mode by first programming the
MODUS register followed by transmitting a valid standard code to the
STANDARD SELECTION register.
FIR1
FIR2
00 01
00 05
FIR1-filter coefficients channel 1 (6 ⋅ 8 bit)
FIR2-filter coefficients channel 2 (6 ⋅ 8 bit), + 3 ⋅ 8 bit offset (total 72 bit)
00 00
93
DCO1_LO
DCO1_HI
00 93
00 9B
Increment channel 1 Low Part
Increment channel 1 High Part
00 00
93
DCO2_LO
DCO2_HI
00 A3
00 AB
Increment channel 2 Low Part
Increment channel 2 High Part
PLL_CAPS
00 1F
Not of interest for the customer
Switchable PLL capacitors to tune open-loop frequency
00 56
96
Note: All registers except AUTO_FM/AM, A2_Threshold, and CM_Threshold are initialized during STANDARD SELECTION and are
automatically updated when Automatic Sound Select (MODUS[0]=1) is on.
Micronas
85
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–2: Demodulator Read Registers; Subaddress: 11hex; these registers are not writable!
Demodulator
Read Registers
Address
(hex)
MSPVersion
Description
Page
C_AD_BITS
00 23
3411,
3451
NICAM-Sync bit, NICAM-C-Bits, and three LSBs of additional data bits
95
ADD_BITS
00 38
NICAM: bit[10:3] of additional data bits
95
CIB_BITS
00 3E
NICAM: CIB1 and CIB2 control bits
95
ERROR_RATE
00 57
NICAM error rate, updated with 182 ms
96
PLL_CAPS
02 1F
Not for customer use
96
AGC_GAIN
02 1E
Not for customer use
96
6.2. DSP Write and Read Registers for Manual/Compatibility Mode
Table 6–3: DSP-Write Registers; Subaddress: 12hex, all registers are readable as well
Write Register
Address
(hex)
Bits
Operational Modes and Adjustable Range
Reset
Mode
Page
Volume SCART1 channel: Ctrl. mode
00 07
[7:0]
[Linear mode / logarithmic mode]
00hex
97
FM Fixed Deemphasis
00 0F
[15:8]
[50 µs, 75 µs, J17, OFF]
50 µs
97
[7:0]
[OFF, WP1]
OFF
97
FM Adaptive Deemphasis
Identification Mode
00 15
[7:0]
[B/G, M]
B/G
98
FM DC Notch
00 17
[7:0]
[ON, OFF]
ON
98
Volume SCART2 channel: Ctrl. mode
00 40
[7:0]
[Linear mode / logarithmic mode]
00hex
97
Table 6–4: DSP Read Registers; Subaddress: 13hex, all registers are not writable
Additional Read Registers
Address
(hex)
Bits
Output Range
Stereo detection register for
A2 Stereo Systems
00 18
[15:8]
[80hex ... 7Fhex]
8 bit two’s complement
98
DC level readout FM1/Ch2-L
00 1B
[15:0]
[8000hex ... 7FFFhex]
16 bit two’s complement
98
DC level readout FM2/Ch1-R
00 1C
[15:0]
[8000hex ... 7FFFhex]
16 bit two’s complement
98
86
Page
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.3. Manual/Compatibility Mode:
Description of Demodulator Write Registers
6.3.1. Automatic Switching between NICAM and
Analog Sound
In case of bad NICAM reception or loss of the
NICAM-carrier, the MSP 34x1G offers an Automatic
Switching (fall back) to the analog sound (FM/AMmono), without the necessity for the controller of reading
and evaluating any parameters. If a proper NICAM signal returns, switching back to this source is performed
automatically as well. The feature evaluates the NICAM
ERROR_RATE and switches, if necessary, all output
channels which are assigned to the NICAM-source, to
the analog source, and vice versa.
An appropriate hysteresis algorithm avoids oscillating
effects (see Fig. 6–1). STATUS[9] and C_AD_BITS[11]
(Addr: 0023 hex) provide information about the actual
NICAM-FM/AM-status.
6.3.1.1. Function in Automatic Sound Select Mode
The Automatic Sound Select feature (MODUS[0]=1)
includes the procedure mentioned above. By default, the
internal ERROR_RATE threshold is set to 700dec. i.e.:
– NICAM → analog Sound if ERROR_RATE > 700
– analog Sound → NICAM if ERROR_RATE < 700/2
The ERROR_RATE value of 700 corresponds to a
BER of approximately 5.46*10-3 /s.
Individual configuration of the threshold can be done
using Table 6–5. However, the internal setting used by
the standard selection is recommended.
The optimum NICAM sound can be assigned to the
MSP output channels by selecting one of the “Stereo
or A/B”, “Stereo or A”, or “Stereo or B” source channels
6.3.1.2. Function in Manual Mode
Selected Sound
NICAM
analog
sound
ERROR_RATE
threshold/2
threshold
Fig. 6–1: Hysteresis for Automatic Switching
If the manual mode (MODUS[0]=0) is required, the
activation and configuration of the Automatic Switching
feature has to be done as described in Table 6–6.
Note, that the channel matrix of the corresponding output-channels must be set according to the
NICAM-mode and need not to be changed in the FM/
AM-fallback case.
Example:
Required threshold = 500: bits[10:1] = 00 1111 1010
Table 6–5: Coding of Automatic NICAM/Analog Sound Switching;
Automatic Sound Select is on (MODUS[0] = 1)
Mode
Description
AUTO_FM [11:0]
Addr. = 00 21hex
ERROR_RATEThreshold/dec
Source Select:
Input at NICAM Path1)
1
Default
Automatic Switching with
internal threshold
bit[11:0] = 0
700
NICAM or FM/AM,
depending on
ERROR_RATE
2
Automatic Switching with
external threshold
(Customizing of Automatic
Sound Select)
bit[11]
=0
bit[10:1] = 25...1000
= threshold/2
bit[0]
=1
set by customer;
recommended
range: 50...2000
3
Forced Analog Mono
bit[11]
=1
bit[10:1] = ignored
bit[0]
=1
1)
always FM/AM
The NICAM path may be assigned to “Stereo or A/B”, “Stereo or A”, or “Stereo or B” source channels
(see Table 2–2 on page 12).
Micronas
87
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–6: Coding of Automatic NICAM/Analog Sound Switching;
Automatic Sound Select is off (MODUS[0] = 0)
Mode
Description
AUTO_FM [11:0]
Addr. = 00 21hex
ERROR_RATEThreshold/dec
Source Select:
Input at NICAM Path
0
reset
status
Forced NICAM
(Automatic Switching disabled)
bit[11]
=0
bit[10:1] = 0
bit[0]
=0
none
always NICAM; Mute in
case of no NICAM available
1
Automatic Switching with
internal threshold
(Default, if Automatic Sound
Select is on)
bit[11]
=0
bit[10:1] = 0
bit[0]
=1
700
NICAM or FM/AM,
depending on
ERROR_RATE
2
Automatic Switching with
external threshold
(Customizing of Automatic
Sound Select)
bit[11]
=0
bit[10:1] = 25...1000
= threshold/2
bit[0]
=1
set by customer;
recommended
range: 50...2000
3
Forced Analog Mono
(Automatic Switching disabled)
bit[11]
=1
bit[10:1] = 0
bit[0]
=1
none
88
always FM/AM
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.3.2. A2 Threshold
The threshold between Stereo/Bilingual and Mono
Identification for the A2 Standard has been made programmable according to the user’s preferences. An
internal hysteresis ensures robustness and stability.
Table 6–7: Write Register on I2C Subaddress 10hex : A2 Threshold
Register
Address
Function
Name
A2 THRESHOLD Register
A2_THRESH
THRESHOLDS
00 22hex (write)
Defines threshold of all A2 and EIA_J standards for Stereo and Bilingual
detection
bit[15:0]
07F0hex
...
0190hex
...
00A0hex
force Mono Identification
default setting after reset
minimum Threshold for stable detection
recommended range : 00A0hex...03C0hex
6.3.3. Carrier-Mute Threshold
The Carrier-Mute threshold has been made programmable according to the user’s preferences. An internal
hysteresis ensures stable behavior.
Table 6–8: Write Register on I2C Subaddress 10hex : Carrier-Mute Threshold
Register
Address
Function
Name
Carrier-Mute THRESHOLD Register
CM_THRESH
THRESHOLDS
00 24hex (write)
Defines threshold for the carrier mute feature
bit[15:0]
0000hex
...
002Ahex
...
07FFhex
Carrier-Mute always ON (both channels muted)
default setting after reset
Carrier-Mute always OFF
(both channels forced on)
recommended range : 0014hex...0050hex
Micronas
89
MSP 34x1G
PRELIMINARY DATA SHEET
6.3.4. Register AD_CV
The use of this register is no longer recommended.
Use it only in cases where compatibility to the
MSP 34x0D is required. Using the STANDARD
SELECTION register together with the MODUS register provides a more economic way to program the
MSP 34x1G.
Table 6–9: AD_CV Register; reset status: all bits are “0”
AD_CV
(00 BBhex)
Automatic setting by
STANDARD SELECT Register
Bit
Function
Settings
2-8, 0A-60hex
9
[0]
not used
must be set to 0
0
0
[1:6]
Reference level in case of Automatic Gain
Control = on (see Table 6–10). Constant
gain factor when Automatic Gain Control =
off (see Table 6–11).
101000
100011
[7]
Determination of Automatic Gain or
Constant Gain
0 = constant gain
1 = automatic gain
1
1
[8]
Selection of Sound IF source
(identical to MODUS[8])
0 = ANA_IN1+
1 = ANA_IN2+
X
X
[9]
MSP-Carrier-Mute Feature
0 = off: no mute
1 = on: mute as described in section 2.2.2.
1
0
[10:15]
not used
must be set to 0
0
0
X : not affected while choosing the TV sound standard by means of the STANDARD SELECT Register
Note: This register is initialized during STANDARD SELECTION and is automatically updated when Automatic
Sound Select (MODUS[0]=1) is on.
Table 6–10: Reference Values for Active AGC (AD_CV[7] = 1)
Application
Input Signal Contains
AD_CV [6:1]
Ref. Value
AD_CV [6:1]
in integer
Range of Input Signal
at pin ANA_IN1+
and ANA_IN2+
− FM Standards
1 or 2 FM Carriers
101000
40
0.10 − 3 Vpp1)
− NICAM/FM
1 FM and 1 NICAM Carrier
101000
40
0.10 − 3 Vpp1)
− NICAM/AM
1 AM and 1 NICAM Carrier
100011
35
0.10 − 1.4 Vpp
(recommended: 0.10 − 0.8 Vpp)
− NICAM only
1 NICAM Carrier only
010100
20
0.05 − 1.0 Vpp
SAT
1 or more FM Carriers
100011
35
0.10 − 3 Vpp1)
ADR
FM and ADR carriers
see DRP 3510A data sheet
Terrestrial TV
1)
90
For signals above 1.4 Vpp, the minimum gain of 3 dB is switched, and overflow of the A/D converter may result. Due to the
robustness of the internal processing, the IC works up to and even more than 3 Vpp, if norm conditions of FM/NICAM or
FM1/FM2 ratio are supposed. In this overflow case, a loss of FM-S/N ratio of about 10 dB may appear.
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–11: AD_CV parameters for Constant Input Gain (AD_CV[7]=0)
Step
AD_CV [6:1]
Constant Gain
Gain
Input Level at pin ANA_IN1+ and ANA_IN2+
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
000000
000001
000010
000011
000100
000101
000110
000111
001000
001001
001010
001011
001100
001101
001110
001111
010000
010001
010010
010011
010100
3.00 dB
3.85 dB
4.70 dB
5.55 dB
6.40 dB
7.25 dB
8.10 dB
8.95 dB
9.80 dB
10.65 dB
11.50 dB
12.35 dB
13.20 dB
14.05 dB
14.90 dB
15.75 dB
16.60 dB
17.45 dB
18.30 dB
19.15 dB
20.00 dB
maximum input level: 3 Vpp (FM) or 1 Vpp (NICAM)1)
1)
maximum input level: 0.14 Vpp
For signals above 1.4 Vpp, the minimum gain of 3 dB is switched and overflow of the A/D converter may result. Due to the
robustness of the internal processing, the IC works up to and even more than 3 Vpp, if norm conditions of FM/NICAM or
FM1/FM2 ratio are supposed. In this overflow case, a loss of FM-S/N ratio of about 10 dB may appear.
6.3.5. Register MODE_REG
Note: The use of this register is no longer recommended. It should be used only in cases where software compatibility to the MSP 34x0D is required.
Using the STANDARD SELECTION register together
with the MODUS register provides a more economic
way to program the MSP 34x1G.
As soon as this register is applied, the MSP 34x1G
works in the MSP 34x0D Manual/Compatibility
Mode. In this mode, BTSC, EIA-J, and FM-Radio are
disabled. Only MSP 34x0D features are available; the
use of MODUS and STATUS register is not allowed.
The MSP 34x1G is reset to the normal mode by first
programming the MODUS register, followed by transmitting a valid standard code to the STANDARD
SELECTION register.
The register ‘MODE_REG’ contains the control bits
determining the operation mode of the MSP 34x1G in
the MSP 34x0D Manual/Compatibility Mode; Table 6–
12 explains all bit positions.
Micronas
91
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–12: Control word ‘MODE_REG’; reset status: all bits are “0”
MODE_REG 00 83hex
Bit
Function
[0]
not used
[1]
DCTR_TRI
[2]
Definition
2-5
8, A, B
9
0 : must be used
0
0
0
Digital control out
0/1 tri-state
0 : active
1 : tri-state
X
X
X
I2S_TRI
I2S outputs tri-state
(I2S_CL, I2S_WS,
I2S_DA_OUT)
0 : active
1 : tri-state
X
X
X
[3]
I2S Mode1)
Master/Slave mode
of the I2S bus
0 : Master
1 : Slave
X
X
X
[4]
I2S_WS Mode
WS due to the Sony or
Philips-Format
0 : Sony
1 : Philips
X
X
X
[5]
Audio_CL_OUT
Switch
Audio_Clock_Output
to tri-state
0 : on
1 : tri-state
X
X
X
[6]
NICAM1)
Mode of MSP-Ch1
0 : FM
1 : Nicam
0
1
1
[7]
not used
0 : must be used
0
0
0
[8]
FM AM
Mode of MSP-Ch2
0 : FM
1 : AM
0
0
1
[9]
HDEV
High Deviation Mode
(channel matrix must be
sound A)
0 : normal
1 : high deviation mode
0
0
0
[11:10]
not used
0 : must be used
0
0
0
[12]
MSP-Ch1 Gain
see also Table 6–14
0 : Gain = 6 dB
1 : Gain = 0 dB
0
0
0
[13]
FIR1-Filter
Coeff. Set
see also Table 6–14
0 : use FIR1
1 : use FIR2
1
0
0
[14]
ADR
Mode of MSP-Ch1/
ADR-Interface
0 : normal mode/tri-state
1 : ADR-mode/active
0
0
0
[15]
AM-Gain
Gain for AM
Demodulation
0 : 0 dB (default. of MSPB)
1 :12 dB (recommended)
1
1
1
1)
92
Comment
Automatic setting by
STANDARD SELECT Register
NICAM and I2S-Master mode are not allowed simultaneously
X: not affected by
STANDARD SELECT Register
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–13: Loading sequence for FIR-coefficients
FIR1 00 01hex (MSP-Ch1: NICAM/FM2)
No.
Symbol Name
Bits
1
NICAM/FM2_Coeff. (5)
8
2
NICAM/FM2_Coeff. (4)
8
3
NICAM/FM2_Coeff. (3)
8
4
NICAM/FM2_Coeff. (2)
8
5
NICAM/FM2_Coeff. (1)
8
6
NICAM/FM2_Coeff. (0)
8
The loading sequences must be obeyed. To change a
coefficient set, the complete block FIR1 or FIR2 must
be transmitted.
Value
Note: For compatibility with MSP 3410B, IMREG1 and
IMREG2 have to be transmitted. The value for
IMREG1 and IMREG2 is 004. Due to the partitioning to
8-bit units, the values 04hex, 40hex, and 00hex arise.
see Table 6–14
6.3.7. DCO-Registers
Note: The use of this register is no longer recommended. It should be used only in cases where software-compatibility to the MSP 34x0D is required.
Using the STANDARD SELECTION register together
with the MODUS register provides a more economic
way to program the MSP 34x1G.
FIR2 00 05hex (MSP-Ch2: FM1/AM)
No.
Symbol Name
Bits
Value
1
IMREG1
8
04hex
2
IMREG1/ IMREG2
8
40hex
3
IMREG2
8
00hex
4
FM/AM_Coef (5)
8
5
FM/AM_Coef (4)
8
6
FM/AM_Coef (3)
8
7
FM/AM_Coef (2)
8
If manual setting of the tuning frequency is required, a
set of 24-bit registers determining the mixing frequencies of the quadrature mixers can be written manually
into the IC. In Table 6–15, some examples of DCO registers are listed. It is necessary to divide them up into
low part and high part. The formula for the calculation
of the registers for any chosen IF frequency is as follows:
8
FM/AM_Coef (1)
8
INCRdec = int(f/fs ⋅ 224)
9
FM/AM_Coef (0)
8
with: int = integer function
f = IF frequency in MHz
fS = sampling frequency (18.432 MHz)
see Table 6–14
6.3.6. FIR-Parameter, Registers FIR1 and FIR2
Note: The use of this register is no longer recommended. It should be used only in cases where software compatibility to the MSP 34x0D is required.
Using the STANDARD SELECTION register together
with the MODUS register provides a more economic
way to program the MSP 34x1G.
When selecting a TV-sound standard by means of the
STANDARD SELECT register, all frequency tuning is
performed automatically.
Conversion of INCR into hex-format and separation of
the 12-bit low and high parts lead to the required register values (DCO1_HI or _LO for MSP-Ch1, DCO2_HI
or LO for MSP-Ch2).
Data-shaping and/or FM/AM bandwidth limitation is
performed by a pair of linear phase Finite Impulse
Response filters (FIR-filter). The filter coefficients are
programmable and are either configured automatically
by the STANDARD SELECT register or written manually by the control processor via the control bus. Two
not necessarily different sets of coefficients are
required: one for MSP-Ch1 (NICAM or FM2) and one
for MSP-Ch2 (FM1 = FM-mono). In Table 6–14 several
coefficient sets are proposed.
To load the FIR-filters, the following data values are to
be transferred 8 bits at a time embedded
LSB-bound in a 16-bit word.
Micronas
93
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–14: 8-bit FIR-coefficients (decimal integer); reset status: all coefficients are “0”
Coefficients for FIR1 00 01hex and FIR2 00 05hex
Terrestrial TV Standards
FM - Satellite
FIR filter corresponds to a
band-pass with a bandwidth of B = 130 to 500 kHz
B
frequency
fc
B/G-, D/KNICAM-FM
Coef(i)
INICAM-FM
LNICAM-AM
B/G-, D/K-,
M-Dual FM
130
kHz
180
kHz
200
kHz
280
kHz
380
kHz
500
kHz
Autosearch
FIR2
FIR2
FIR2
FIR2
FIR2
FIR2
FIR2
FIR2
FIR1
FIR2
FIR1
FIR2
FIR1
FIR2
0
−2
3
2
3
−2
−4
3
73
9
3
−8
−1
−1
−1
1
−8
18
4
18
−8
−12
18
53
18
18
−8
−9
−1
−1
2
−10
27
−6
27
−10
−9
27
64
28
27
4
−16
−8
−8
3
10
48
−4
48
10
23
48
119
47
48
36
5
2
2
4
50
66
40
66
50
79
66
101
55
66
78
65
59
59
5
86
72
94
72
86
126
72
127
64
72
107
123
126
126
ModeREG[12]
0
0
0
0
1
1
1
1
1
1
0
ModeREG[13]
0
0
0
1
1
1
1
1
1
1
0
For compatibility, except for the FIR2-AM and the Autosearch-sets, the FIR-filter programming as used for the MSP 3410B is also possible.
ADR coefficients are listed in the DRP data sheet.
Table 6–15: DCO registers for the MSP 34x1G; reset status: DCO_HI/LO = “0000”
DCO1_LO 00 93hex, DCO1_HI 00 9Bhex; DCO2_LO 00 A3hex, DCO2_HI 00 ABhex
Freq. MHz
DCO_HI/hex
DCO_LO/hex
Freq. MHz
DCO_HI/hex
DCO_LO/hex
4.5
03E8
000
5.04
5.5
5.58
5.7421875
0460
04C6
04D8
04FC
0000
038E
0000
00AA
5.76
5.85
5.94
0500
0514
0528
0000
0000
0000
6.0
6.2
6.5
6.552
0535
0561
05A4
05B0
0555
0C71
071C
0000
6.6
6.65
6.8
05BA
05C5
05E7
0AAA
0C71
01C7
7.02
0618
0000
7.2
0640
0000
7.38
0668
0000
7.56
0690
0000
94
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.4. Manual/Compatibility Mode:
Description of Demodulator Read Registers
Table 6–16: NICAM operation modes as defined by
the EBU NICAM 728 specification
Note: The use of these register is no longer recommended. It should be used only in cases where software compatibility to the MSP 34x0D is required.
Using the STANDARD SELECTION register together
with the STATUS register provides a more economic
way to program the MSP 34x1G and to retrieve information from the IC.
All registers except C_AD_BITs are 8 bits wide. They
can be read out of the RAM of the MSP 34x1G if the
MSP 34x0D Compatibility Mode is required.
All transmissions take place in 16-bit words. The valid
8-bit data are the 8 LSBs of the received data word.
If the Automatic Sound Select feature is not used, the
NICAM or FM-identification parameters must be read
and evaluated by the controller in order to enable
appropriate switching of the channel select matrix of
the baseband processing part. The FM-identification
registers are described in section 6.6.1. To handle the
NICAM-sound and to observe the NICAM-quality, at
least the registers C_AD_BITS and ERROR_RATE
must be read and evaluated by the controller. Additional data bits and CIB bits, if supplied by the NICAM
transmitter, can be obtained by reading the registers
ADD_BITS and CIB_BITS.
C4
C3
C2
C1
Operation Mode
0
0
0
0
Stereo sound (NICAMA/B),
independent mono sound (FM1)
0
0
0
1
Two independent mono signals
(NICAMA, FM1)
0
0
1
0
Three independent mono channels
(NICAMA, NICAMB, FM1)
0
0
1
1
Data transmission only; no audio
1
0
0
0
Stereo sound (NICAMA/B), FM1
carries same channel
1
0
0
1
One mono signal (NICAMA). FM1
carries same channel as NICAMA
1
0
1
0
Two independent mono channels
(NICAMA, NICAMB). FM1 carries
same channel as NICAMA
1
0
1
1
Data transmission only; no audio
x
1
x
x
Unimplemented sound coding
option (not yet defined by EBU
NICAM 728 specification)
AUTO_FM: monitor bit for the AUTO_FM Status:
0: NICAM source is NICAM
1: NICAM source is FM
Note: It is no longer necessary to read out and evaluate the C_AD_BITS. All evaluation is performed in the
MSP and indicated in the STATUS register.
6.4.1. NICAM Mode Control/Additional Data Bits
Register
NICAM operation mode control bits and A[2:0] of the
additional data bits.
Format:
6.4.2. Additional Data Bits Register
11
...
7
6
5
4
3
2
1
0
Contains the remaining 8 of the 11 additional data bits.
The additional data bits are not yet defined by the
NICAM 728 system.
Auto
_FM
...
A[2]
A[1]
A[0]
C4
C3
C2
C1
S
Format:
MSB
C_AD_BITS 00 23hex
LSB
Important: “S” = Bit[0] indicates correct NICAM-synchronization (S = 1). If S = 0, the MSP 3411/3451G
has not yet synchronized correctly to frame and
sequence, or has lost synchronization. The remaining
read registers are therefore not valid. The MSP mutes
the NICAM output automatically and tries to synchronize again as long as MODE_REG[6] is set.
The operation mode is coded by C4-C1 as shown in
Table 6–16.
MSB
ADD_BITS 00 38hex
7
6
5
4
3
2
1
0
A[10]
A[9]
A[8]
A[7]
A[6]
A[5]
A[4]
A[3]
6.4.3. CIB Bits Register
CIB bits 1 and 2 (see NICAM 728 specifications).
Format:
MSB
Micronas
LSB
CIB_BITS 00 3Ehex
LSB
7
6
5
4
3
2
1
0
x
x
x
x
x
x
CIB1
CIB2
95
MSP 34x1G
PRELIMINARY DATA SHEET
6.4.4. NICAM Error Rate Register
ERROR_RATE
00 57hex
Error free
0000hex
maximum error rate
07FFhex
6.4.7. Automatic Search Function for FM-Carrier
Detection in Satellite Mode
The AM demodulation ability of the MSP 34x1G offers
the possibility to calculate the “field strength” of the
momentarily selected FM carrier, which can be read
out by the controller. In SAT receivers, this feature can
be used to make automatic FM carrier search possible.
Average error rate of the NICAM reception in a time
interval of 182 ms, which should be close to 0. The initial and maximum value of ERROR_RATE is 2047.
This value is also active if the NICAM bit of
MODE_REG is not set. Since the value is achieved by
filtering, a certain transition time (approx. 0.5 sec) is
unavoidable. Acceptable audio may have error rates
up to a value of 700 int. Individual evaluation of this
value by the controller and an appropriate threshold
may define the fallback mode from NICAM to FM/
AM-Mono in case of poor NICAM reception.
The bit error rate per second (BER) can be calculated
by means of the following formula:
BER = ERROR_RATE * 12.3*10−6 /s
6.4.5. PLL_CAPS Readback Register
It is possible to read out the actual setting of the
PLL_CAPS. In standard applications, this register is
not of interest for the customer.
PLL_CAPS
02 1Fhex L
minimum frequency
1111 1111
FFhex
nominal frequency
0101 0110
RESET
56hex
maximum frequency
0000 0000
00hex
PLL_CAPS
02 1Fhex H
PLL open
xxxx xxx0
PLL closed
xxxx xxx1
For this, the MSP has to be switched to AM-mode
(MODE_REG[8]), FM-Prescale must be set to
7Fhex = +127dec, and the FM DC notch (see section
6.5.7.) must be switched off. The sound-IF frequency
range must now be “scanned” in the MSP-channel 2 by
means of the programmable quadrature mixer with an
appropriate incremental frequency (i.e. 10 kHz). After
each incrementation, a field strength value is available
at the quasi-peak detector output (quasi-peak detector
source must be set to FM), which must be examined
for relative maxima by the controller. This results in
either continuing search or switching the MSP back to
FM demodulation mode.
During the search process, the FIR2 must be loaded
with the coefficient set “AUTOSEARCH”, which
enables small bandwidth, resulting in appropriate field
strength characteristics. The absolute field strength
value (can be read out of “quasi-peak detector output
FM1”) also gives information on whether a main FM
carrier or a subcarrier was detected; and as a practical
consequence, the FM bandwidth (FIR1/2) and the
deemphasis (50 µs or adaptive) can be switched
accordingly.
Due to the fact that a constant demodulation frequency
offset of a few kHz leads to a DC level in the demodulated signal, further fine tuning of the found carrier can
be achieved by evaluating the “DC Level Readout
FM1”. Therefore, the FM DC Notch must be switched
on, and the demodulator part must be switched back to
FM-demodulation mode.
For a detailed description of the automatic search
function, please refer to the corresponding MSP Windows software.
6.4.6. AGC_GAIN Readback Register
It is possible to read out the actual setting of
AGC_GAIN in Automatic Gain Mode. In standard
applications, this register is not of interest for the customer.
AGC_GAIN
02 1Ehex
max. amplification
(20 dB)
0001 0100
14hex
min. amplification
(3 dB)
0000 0000
00hex
96
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.5. Manual/Compatibility Mode:
Description of DSP Write Registers
6.5.2. Volume Modes of SCART1/2 Outputs
6.5.1. Additional Channel Matrix Modes
Loudspeaker Matrix
00 08hex
L
Headphone Matrix
00 09hex
L
SCART1 Matrix
00 0Ahex
L
SCART2 Matrix
00 41hex
L
I2S Matrix
00 0Bhex
L
Quasi-Peak
Detector Matrix
00 0Chex
L
SUM/DIFF
0100 0000
40hex
AB_XCHANGE
0101 0000
50hex
PHASE_CHANGE_B
0110 0000
60hex
PHASE_CHANGE_A
0111 0000
70hex
A_ONLY
1000 0000
80hex
B_ONLY
1001 0000
90hex
Volume Mode SCART1
00 07hex
[3:0]
Volume Mode SCART2
00 40hex
[3:0]
linear
0000
RESET
0hex
logarithmic
0001
1hex
Volume SCART1
00 07hex
H
Volume SCART2
00 40hex
H
OFF
0000 0000
RESET
00hex
0 dB gain
(digital full scale (FS) to 2
VRMS output)
0100 0000
40hex
+6 dB gain (−6 dBFS to 2
VRMS output)
0111 1111
7Fhex
Linear Mode
This table shows additional modes for the channel
matrix registers.
The sum/difference mode can be used together with
the quasi-peak detector to determine the sound material mode. If the difference signal on channel B (right)
is near to zero, and the sum signal on channel A (left)
is high, the incoming audio signal is mono. If there is a
significant level on the difference signal, the incoming
audio is stereo.
Note: SCART Volume linear mode will not be supported in the future (documented for compatibility reasons only).
6.5.3. FM Fixed Deemphasis
FM Deemphasis
00 0Fhex
H
50 µs
0000 0000
RESET
00hex
75 µs
0000 0001
01hex
J17
0000 0100
04hex
OFF
0011 1111
3Fhex
Note: This register is initialized during STANDARD
SELECTION and is automatically updated when Automatic Sound Select (MODUS[0]=1) is on.
6.5.4. FM Adaptive Deemphasis
FM Adaptive
Deemphasis WP1
00 0Fhex
L
OFF
0000 0000
RESET
00hex
WP1
0011 1111
3Fhex
Note: This register is initialized during STANDARD
SELECTION and is automatically updated when Automatic Sound Select (MODUS[0]=1) is on.
Micronas
97
MSP 34x1G
PRELIMINARY DATA SHEET
6.5.5. NICAM Deemphasis
6.6. Manual/Compatibility Mode:
Description of DSP Read Registers
A J17 Deemphasis is always applied to the NICAM
signal. It is not switchable.
6.5.6. Identification Mode for A2 Stereo Systems
Identification Mode
00 15hex
L
Standard B/G
(German Stereo)
0000 0000
RESET
00hex
Standard M
(Korean Stereo)
0000 0001
01hex
Reset of Ident-Filter
0011 1111
3Fhex
To shorten the response time of the identification algorithm after a program change between two FM-Stereo
capable programs, the reset of the ident-filter can be
applied.
Sequence:
All readable registers are 16-bit wide. Transmissions
via I2C bus have to take place in 16-bit words. Some of
the defined 16-bit words are divided into low and high
byte, thus holding two different control entities.
These registers are not writable.
6.6.1. Stereo Detection Register
for A2 Stereo Systems
Stereo Detection
Register
00 18hex
Stereo Mode
Reading
(two’s complement)
MONO
near zero
STEREO
positive value (ideal
reception: 7Fhex)
BILINGUAL
negative value (ideal
reception: 80hex)
1. Program change
2. Reset ident-filter
3. Set identification mode back to standard B/G or M
4. Wait approx. 500 ms
H
Note: It is no longer necessary to read out and evaluate the A2 identification level. All evaluation is performed in the MSP and indicated in the STATUS register.
5. Read stereo detection register
Note: This register is initialized during STANDARD
SELECTION and is automatically updated when Automatic Sound Select (MODUS[0]=1) is on.
6.5.7. FM DC Notch
The DC compensation filter (FM DC Notch) for FM
input can be switched off. This is used to speed up the
automatic search function (see Section 6.4.7.). In normal FM-mode, the FM DC Notch should be switched
on.
FM DC Notch
00 17hex
L
ON
0000 0000
Reset
00hex
OFF
0011 1111
3Fhex
98
6.6.2. DC Level Register
DC Level Readout
FM1 (MSP-Ch2)
00 1Bhex
H+L
DC Level Readout
FM2 (MSP-Ch1)
00 1Chex
H+L
DC Level
[8000hex ... 7FFFhex]
values are 16 bit two’s
complement
The DC level register measures the DC component of
the incoming FM signals (FM1 and FM2). This can be
used for seek functions in satellite receivers and for IF
FM frequencies fine tuning. A too low demodulation
frequency (DCO) results in a positive DC-level and
vice versa. For further processing, the DC content of
the demodulated FM signals is suppressed. The time
constant τ, defining the transition time of the DC Level
Register, is approximately 28 ms.
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.7. Demodulator Source Channels in Manual Mode
6.7.1. Terrestric Sound Standards
Table 6–17 shows the source channel assignment of
the demodulated signals in case of manual mode for
all terrestric sound standards. See Table 2–2 for the
assignment in the Automatic Sound Select mode. In
manual mode for terrestric sound standards, only two
demodulator sources are defined.
6.7.2. SAT Sound Standards
Table 6–18 shows the source channel assignment of
the demodulated signals for SAT sound standards.
Table 6–17: Manual Sound Select Mode for Terrestric Sound Standards
Source Channels of Sound Select Block
Broadcasted
Sound
Standard
Selected MSP
Standard
Code
Broadcasted
Sound Mode
FM Matrix
B/G-FM
D/K-FM
M-Korea
M-Japan
03
04, 05
02
30
MONO
B/G-NICAM
L-NICAM
I-NICAM
D/K-NICAM
D/K-NICAM
(with high
deviation FM)
08
09
0A
0B
0C
0D
20
BTSC
FM/AM
Stereo or A/B
(use 0 for channel select)
(use 1 for channel select)
Sound A Mono
Mono
Mono
STEREO
German Stereo
Korean Stereo
Stereo
Stereo
BILINGUAL,
Languages A and B
No Matrix
Left = A
Right = B
Left = A
Right = B
NICAM not available
or NICAM error rate
too high
Sound A Mono1)
analog Mono
no sound
MONO
Sound A Mono1)
analog Mono
NICAM Mono
STEREO
Sound A Mono1)
analog Mono
NICAM Stereo
BILINGUAL,
Languages A and B
Sound A Mono1)
analog Mono
Left = NICAM A
Right = NICAM B
MONO
Sound A Mono
Mono
Mono
STEREO
Korean Stereo
Stereo
Stereo
MONO + SAP
Sound A Mono
Mono
Mono
STEREO + SAP
Korean Stereo
Stereo
Stereo
Sound A Mono
Mono
Mono
No Matrix
Left = Mono
Right = SAP
Left = Mono
Right = SAP
MONO
Sound A Mono
Mono
Mono
STEREO
Korean Stereo
Stereo
Stereo
MONO
21
with AUTO_FM:
analog Mono
STEREO
MONO + SAP
STEREO + SAP
FM-Radio
1)
40
Automatic refresh to Sound A Mono, do not write any other value to the register FM Matrix!
Micronas
99
MSP 34x1G
PRELIMINARY DATA SHEET
Table 6–18: Manual Sound Select Modes for SAT-Standards
Source Channels of Sound Select Block for SAT-Modes
Broadcasted
Sound
Standard
FM SAT
100
Selected
MSP Standard
Code
Broadcasted
Sound Mode
FM Matrix
FM/AM
Stereo or A/B
Stereo or A
Stereo or B
(source select: 0)
(source select: 1)
(source select: 3)
(source select: 4)
6, 50hex
MONO
Sound A Mono
Mono
Mono
Mono
Mono
51hex
STEREO
No Matrix
Stereo
Stereo
Stereo
Stereo
BILINGUAL
No Matrix
Left = A (FM1)
Right = B (FM2)
Left = A (FM1)
Right = B (FM2)
A (FM1)
B (FM2)
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
6.8. Exclusions of Audio Baseband Features
6.10. Compatibility Restrictions to MSP 34xxD
In general, all functions can be switched independently.
Two exceptions exist:
The MSP 34x1G is fully hardware compatible to the
MSP 34xxD. However, to substitute a MSP 34xxD by
the corresponding MSP 34x1G, the controller software
has to be adapted slightly:
1. NICAM cannot be processed simultaneously with
the FM2 channel.
1. The register FM-Matrix (00 0Ehex low part) must be
changed from “no matrix (00hex)” to “sound A mono
(03hex)” during mono transmission of all TV-sound
standards (see also Table 6–17).
2. FM adaptive deemphasis cannot be processed
simultaneously with FM-identification.
6.9. Phase Relationship of Analog Outputs
The analog output signals: Loudspeaker, headphone,
and SCART2 all have the same phases. The user
does not need to correct output phases when using
these analog outputs directly. The SCART1 output has
opposite phase.
2. With the MSP 34x1G, the STANDARD SELECTION
initializes the FM-deemphasis, which is not the case
for the MSP 34xxD. So, if STANDARD SELECTION
is applied, this I2C instruction can be omitted.
Using the I2S-outputs for other DSPs or D/A converters, care must be taken to adjust for the correct phase.
If the attached coprocessor is one of the MSP family,
the following schematics help to determine the phase
relationship.
I2S_IN1/2
I2S_OUT1/2
Loudspeaker
Headphone
SCART1-Ch.
Audio
Baseband
Processing
SCART1
SCART1
SCART2
SCART3
SCART4
SCART
DSP
Input
Select
SCART2-Ch.
SCART2
MONO
MONO, SCART1...4
SCART
Output Select
Fig. 6–2: Phase diagram of the MSP 34x1G
Micronas
101
MSP 34x1G
PRELIMINARY DATA SHEET
7. Appendix D: MSP 34x1G Version History
MSP 3451G-A1
First release
MSP 3451G-A2
– CONTROL register now readable for more status
information
– new D/K standard for Poland
– improved I2C hardware problem handling
– improved AM-performance
MSP 34x1G-B8
– fine-tuning of A2-identification and carrier mute
– EIA-J identification: faster transition time stereo/
bilingual to mono
– J17 FM-deemphasis implemented
– input specification for RESETQ and TESTEN
changed
– MDB implemented
102
Micronas
MSP 34x1G
PRELIMINARY DATA SHEET
8. Appendix E: Application Circuit
SIF 2 IN
if ANA_IN2+ not used
Signal GND
100
nF
8 V(5 V)
+
3.3
µF
ANA_IN1/2+
+
+
10 µF
XTAL_OUT
AGNDC
VREFTOP
ANA_IN−
56 pF
18.432
MHz
+
56 pF
ANA_IN2+
56 pF
ANA_IN1+
56 pF
100
nF
100 pF
1 kΩ
10 µF
Alternative circuit for
SIF-inputs for more
attenuation of video
components:
CAPL_A
10
µF -
SIF 1 IN
XTAL_IN
Tuner 1
C s. section 4.6.2.
CAPL_M
Tuner 2
1 µF
DACM_L
330 nF
MONO_IN
1 nF
1 µF
1 nF
1 µF
LOUD
SPEAKER
DACM_R
330 nF
330 nF
AHVSS
SC1_IN_L
SC1_IN_R
DACM_SUB
ASG
330 nF
330 nF
AHVSS
1 nF
SC2_IN_L
1 µF
SC2_IN_R
ASG
330 nF
DACA_L
SC3_IN_L
1 nF
SC3_IN_R
330 nF
AHVSS
ASG
330 nF
5V
330 nF
1 nF
SC4_IN_L
MSP 34x1G
SC4_IN_R
SC1_OUT_L
STANDBYQ
5V
HEAD
PHONE
1 µF
DACA_R
SC1_OUT_R
DVSS
ADR_SEL
SC2_OUT_L
DVSS
I2C_DA
I2C_CL
SC2_OUT_R
ADR_WS
100 Ω 22 µF
+
100 Ω 22 µF
+
100 Ω 22 µF
+
100 Ω 22 µF
+
ADR_CL
ADR_DA
D_CTR_I/O_0
I2S_WS
D_CTR_I/O_1
I2S_CL
I2S_DA_IN1
AUD_CL_OUT
I2S_DA_IN2
TESTEN
I2S_DA_OUT
Micronas
VREF1
VREF2
AHVSS
AHVSS
AHVSUP
AVSS
DVSS
AVSUP
5V
AHVSS
5V
470
pF
1.5
nF
10
µF
AHVSS
(from Controller, see section 4.6.3.3.)
220
pF
470
pF
1.5
nF
10
µF
470
pF
1.5
nF
10
µF
AVSS
RESETQ
DVSUP
RESETQ
AHVSS
8V
(5 V)
103
MSP 34x1G
PRELIMINARY DATA SHEET
9. Data Sheet History
1. Preliminary data sheet: “MSP 34x1G Multistandard
Sound Processor Family with Virtual Dolby Surround”,
Edition Oct. 15, 1999, 6251-511-1PD. First release of
the preliminary data sheet.
2. Preliminary data sheet: “MSP 34x1G Multistandard
Sound Processor Family with Virtual Dolby Surround”,
Jan. 19, 2001, 6251-511-2PD. Second release of the
preliminary data sheet. Major changes:
– specification for version B8 added
(see Appendix D: Version History)
– MSP 3461 added, MSP 3431 removed
– description for MDB added
– specification for MNR added
– I2C-bus description changed
– ACB register: documentation for bit allocation
D_CTR_I/O changed
Micronas GmbH
Hans-Bunte-Strasse 19
D-79108 Freiburg (Germany)
P.O. Box 840
D-79008 Freiburg (Germany)
Tel. +49-761-517-0
Fax +49-761-517-2174
E-mail: [email protected]
Internet: www.micronas.com
Printed in Germany
Order No. 6251-511-2PD
104
All information and data contained in this data sheet are without any
commitment, are not to be considered as an offer for conclusion of a
contract, nor shall they be construed as to create any liability. Any new
issue of this data sheet invalidates previous issues. Product availability
and delivery are exclusively subject to our respective order confirmation
form; the same applies to orders based on development samples delivered. By this publication, Micronas GmbH does not assume responsibility for patent infringements or other rights of third parties which may
result from its use.
Further, Micronas GmbH reserves the right to revise this publication and
to make changes to its content, at any time, without obligation to notify
any person or entity of such revisions or changes.
No part of this publication may be reproduced, photocopied, stored on a
retrieval system, or transmitted without the express written consent of
Micronas GmbH.
Micronas
Similar pages