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| PRELIMINARY DATA SHEET MSP 3410 B Multistandard Sound Processor Edition Nov. 20, 1995 6251-366-9PD MSP 3410 B Contents Page 4 5 5 5 5 6 6 6 9 9 9 9 10 10 10 10 10 11 11 11 11 11 12 13 14 14 14 14 14 14 14 15 15 15 16 16 17 17 18 18 19 20 2 Section 1. 2. 2.1. 2.2. 2.3. 3. 3.1. 3.2. 4. 4.1. 4.1.1. 4.1.2. 4.1.3. 4.1.4. 4.1.5. 4.1.6. 4.1.7. 4.1.8. 4.1.9. 4.1.10. 4.2. 4.3. 4.4. 5. 5.1. 5.2. 5.2.1. 5.2.2. 5.2.3. 5.2.4. 5.3. 6. 7. 8. 9. 10. 11. 11.1. 11.2. 11.2.1. 11.2.2. 11.2.3. Title Introduction Features of the MSP 3410 B Features of the Demodulator and Decoder Sections Features of the DSP-Section Features of the Analog Section Application Fields of the MSP 3410 B NICAM plus FM-Mono German 2-Carrier System (DUAL FM System) Architecture of the MSP 3410 B Demodulator Block Analog Sound IF - Input Section Quadrature Mixers Lowpass Filtering Block for Mixed Sound IF Signals CORDIC Block Differentiate Lowpass Filter Block for Demodulated Signals High Deviation FM Mode MSP-Mute Function in the Dual Carrier FM Mode DQPSK-Decoder NICAM-Decoder Analog Section and SCART Switches MSP 3410 B Audio Baseband Processing Dual Carrier FM Stereo/Bilingual Detection Control Bus Interface Protocol Description Proposal for MSP 3410 B I2C Telegrams Symbols Write Telegrams Read Telegrams Examples Start Up Sequence N-Bus Interface Pay-TV Interface Audio PLL and Crystal Specifications S-Bus Interface I2S Bus Interface Programming the Demodulator Part Write Registers: Table and Addresses Write Registers: Functions and Values Setting of Parameter AD_CV Control Register 'MODE_REG' FIR-Parameter PRELIMINARY DATA SHEET ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Contents, continued Page 21 22 22 23 24 24 24 24 24 25 25 26 26 31 32 34 34 35 38 39 41 41 42 47 54 54 54 55 56 57 58 60 61 63 63 63 63 64 65 Section 11.2.4. 11.3. 11.4. 11.5. 11.6. 11.6.1. 11.6.2. 11.6.3. 11.6.4. 11.6.5. 11.6.6. 12. 12.1. 12.2. 12.3. 13. 13.1. 13.2. 13.3. 13.4. 13.5. 13.5.1. 13.5.2. 13.5.3. 14. 14.1. 14.2. 14.3. 14.4. 15. 16. 17. 18. 19. 19.1. 19.2. 19.3. 20. 21. Title DCO-Increments Read Registers: Listing and Addresses Read Registers: Functions and Values Sequences to Transmit Parameters and Start of Processing Software Proposals for Multistandard TV-Sets Multistandard Including System B/G with NICAM/FM-Mono only Multistandard Including System I with NICAM/FM-Mono only Multistandard Including System B/G with NICAM/FM-Mono and German DUAL FM Satellite Mode Automatic Search Function for FM-Carrier Detection Automatic Standard Detection Programming the Audio Processing Part Summary of the DSP Control Registers Exclusions Summary of Readable Registers Specifications Outline Dimensions Pin Connections and Descriptions Pin Configuration Pin Circuits Electrical Characteristics Absolute Maximum Ratings Recommended Operating Conditions Characteristics Timing Diagrams Power-up Sequence I2C Bus Timing Diagram I2S Bus Timing Diagram SBUS Timing Diagram Application Circuit DMA Application I2S Bus in Master/Slave Configuration with Standby Mode APPENDIX A: MSP 3410/3400B Technical Code History APPENDIX B: Documentation History MSP 3400 MSP 3410 and MSP 3400 MSP 3410 B and MSP 3400 B APPENDIX C: Documentation of known hardware restrictions for TC15 Index ITT Semiconductors 3 MSP 3410 B Multistandard Sound Processor Release Notes: PRELIMINARY DATA SHEET The hardware description in this document is valid for the MSP 3410 B version F7 and following versions. The suffix "B" in the name denotes the requirements of the crystal with modified specifications. For a brief history survey, please see appendix "MSP 3410 B Technical Code History". The present document is version 0.8. Revision bars indicate significant changes to revision 0.7. 1. Introduction The MSP 3410 B is a single-chip Multistandard Sound Processor for applications in analog and digital TV sets, satellite receivers and video recorders. The MSP-family, which goes back to the MSP 2400, demonstrates in an impressive way the progressive development towards highly integrated ICs, offering more and more features and flexibility. The development of the MSP 2410 included an automatic gain control but reduced the amount of external components. The MSP 2410 reached a high level of performance and is the basis for the new generation. The MSP 3410 B increases function integration in a spectacular way. By including the MSP2410 as a library cell and combining it with AD/DA converters and high performance digital signal processing, the chip offers a wide range of features. The complete TV-sound-processing, starting at the Sound-IF domain, will be performed by one single IC. The inputs of the IC are analog audio signals in baseband and at intercarrier position. The MSP 3410 B covers the sound processing of a wide range of TV-standards. Some examples are listed in Table 3-1. The MSP 3410 B is produced in 1.0 m CMOS technology and is available in 68-pin PLCC and in 64-pin PSDIP packages. SBUS I2S I2C 4 4 2 Sound IF 1 Sound IF 2 MONO IN SCART1 IN SCART2 IN SCART3 IN 2 2 2 2 2 LOUDSPEAKER OUT HEADPHONE OUT MSP 3410 B 2 2 SCART1 OUT SCART2 OUT Fig. 1-1: Main I/O Signals MSP 3410 B 4 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 2.2. Features of the DSP-Section - flexible selection of audio sources to be processed 2. Features of the MSP 3410 B 2.1. Features of the Demodulator and Decoder Sections The MSP 3410 B is designed to simultaneously perform digital demodulation and decoding of NICAM-coded TV stereo sound, as well as demodulation of FM-mono TV sound. Alternatively, two carrier FM systems according to the German or Korean terrestrial specs or the satellite specs can be processed with the MSP 3410 B. Since it is simple and economic to demodulate AM sound carriers with conventional sound-IF-mixing units, the AM demodulation feature of the MSP will seldom be used. However, for FM carrier detection in satellite operation the AM demodulation offers a powerful feature to calculate the carrier field strength, which can be used for automatic search algorithms. So the IC facilitates a first step towards multistandard capability with its very flexible application and may be used in TV-sets, satellite tuners and video recorders. The MSP 3410 B facilitates profitable multistandard capability, offering the following advantages: - two selectable analog inputs (TV- and SAT-IF sources) - Automatic Gain Control (AGC) for analog input: input range: 0.14 - 3 Vpp - integrated A/D converter for sound-IF inputs - all demodulation and filtering is performed on chip and is individually programmable - simple realization of both digital NICAM standards (UK/Scandinavia) - no external filter hardware is required - only one crystal clock (18.432 MHz) is necessary - Pay-TV for NICAM-mode - FM carrier level calculation for automatic search algorithms and carrier mute function - high deviation FM-mono mode (max. deviation: approx. 360 kHz) - digital input and output interfaces via S-Bus for DMAvia AMU, and via I2S-Bus for external DSP-Processors featuring Graphic Equalizer, Surround Sound etc. - performance of all deemphasis systems including adaptive Wegener Panda 1 without external components or controlling - performance of D2MAC audio together with an AMU 2481 - digitally performed FM-identification decoding and dematrixing - digital baseband processing: volume, bass, treble, pseudostereo and basewidth enlargement - simplified controlling of volume, bass, treble etc. - increased audio bandwidth for FM-Audio-signals (20 Hz - 15 kHz , 1 dB) 2.3. Features of the Analog Section - three selectable analog pairs of audio baseband inputs (=three SCART inputs) Input level: 2 V RMS; input impedance: 25 k - one selectable analog mono input (i.e. AM sound); Input level: 2 V RMS; input impedance: 10 k - two high quality A/D converters; S/N-Ratio: 85 dB - 20 Hz to 20 kHz Bandwidth for SCART-to-SCARTCopy facilities - MAIN (loudspeaker) and AUX (headphones): two pairs of 4-fold oversampled D/A-converters Output level per channel: max. 1.4 VRMS Output resistance: max. 5 k S/N-Ratio: 85 dB at maximum volume max. noise voltage in mute mode: 10 V (BW: 20 Hz ... 16 kHz) - one pair of four-fold oversampled D/A-converters supplying two selectable pairs of SCART-Outputs. Output level per channel: max. 2 V RMS, output resistance: max. 0.5 k, S/N-Ratio: 85 dB (20 Hz ... 16 kHz) ITT Semiconductors 5 MSP 3410 B 3. Application Fields of the MSP 3410 B In the following sections, a brief overview about the two main TV sound standards, NICAM 728 and German FMStereo, demonstrates the complex requirements of a multistandard audio IC. 3.1. NICAM plus FM-Mono According to the British, Scandinavian and Spanish TVstandards, high quality stereo sound is transmitted digitally. The systems allow two high quality digital sound channels to be added to the already existing FM channel. The sound coding follows the format of the so-called Near Instantaneous Companding System (NICAM 728). Transmission is performed using Differential Quadrature Phase Shift Keying (DQPSK). Table 3-2 gives some specifications of the sound coding (NICAM); Table 3-3 offers an overview of the modulation parameters. PRELIMINARY DATA SHEET In the case of NICAM/FM mode there are three different audio channels available: NICAM A,NICAM B and FMmono. NICAM A and B may belong either to a stereo or to a dual language transmission. Information about operation mode and about the quality of the NICAM signal can be read by the CCU via the control bus. In the case of low quality (high bit error rate) the CCU may decide to switch to the analog FM-mono sound. 3.2. German 2-Carrier System (DUAL FM System) Since September 1981, stereo and dual sound programs have been transmitted in Germany using the 2-carrier system. Sound transmission consists of the already existing first sound carrier and a second sound carrier additionally containing an identification signal. Some more details of this standard are given in Table 3-4. Table 3-1: European TV standards TV-System B/G B/G L I D,K M Satellite Satellite Position of Sound Carrier /MHz 5.5/5.74 5.5/5.85 6.5/5.85 6.0/6.552 6.5 4.5 6.5 7.02/7.2 Sound Modulation FM-Stereo FM-Mono/NICAM AM-Mono/NICAM FM-Mono/NICAM FM-Mono FM-Mono FM-Mono FM-Stereo Color System PAL PAL SECAM PAL SECAM NTSC PAL PAL Country Germany Scandinavia,Spain France UK USSR USA Europe (ASTRA) Europe (ASTRA) Table 3-2: Summary of NICAM 728 sound coding characteristics Characteristics Audio sampling frequency Number of channels Initial resolution Companding characteristics Coding for compressed samples Preemphasis Audio overload level Values 32 kHz 2 14 bit/sample near instantaneous, with compression to 10 bits/sample in 32-samples (1 ms) blocks 2's complement CCITT Recommendation J.17 (6.5 dB attenuation at 800 Hz) +12 dBm0 measured at the unity gain frequency of the preemphasis network (2 kHz) 6 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Table 3-3: Summary of NICAM 728 sound modulation parameters Specification Carrier frequency of digital sound Transmission rate Type of modulation Spectrum shaping Roll-off Roll off factor 1.0 Carrier frequency of analog sound component Power ratio between vision carrier and analog sound carrier Power ratio between analog and modulated digital sound carrier 6.0 MHz FM mono 10 dB 10 dB UK 6.552 MHz Scandinavia/Spain 5.85 MHz 728 kBit/s 1 part/million Differentially encoded quadrature phase shift keying (DQPSK) by means of Roll-off filters 0.4 5.5 MHz FM mono 13 dB 7 dB 0.4 6.5 MHz AM mono terrestric 10 dB 17 dB cable 16 dB 11 dB France 5.85 MHz Table 3-4: Key parameters for German 2-carrier sound system Sound Carriers Intercarrier frequencies Vision/sound power difference Sound bandwidth Pre-emphasis Frequency deviation Sound Signal Components Mono transmission Stereo transmission Dual sound transmission mono (L+R)/2 language A mono R language B Channel FM1 5.5 MHz 13 dB Channel FM2 5.7421875 MHz 20 dB 40 Hz to 15 kHz 50 s 50 kHz Identification of Transmission Mode on Channel 2 Pilot carrier frequency Type of modulation Modulation depth Modulation frequency 54.6875 kHz AM 50% mono: stereo: dual: unmodulated 117.5 Hz 274.1 Hz ITT Semiconductors 7 MSP 3410 B 33 34 39 MHz 5 9 MHz PRELIMINARY DATA SHEET SAW Filter Sound IF Mixer Sound IF Filter Tuner Loudspeaker Vision Demodulator AM Sound MSP 3410 B SCART1 2 2 2 2 2 Headphone SCART1 SCART2 Composite Video SCART Inputs SCART Outputs SCART2 SCART3 I 2S optional Feature Processor SBUS AMU DMA According to the mixing characteristics of the Sound-IF mixer, the Sound-IF filter may be omitted. . Fig. 3-1: Typical MSP 3410 B application 8 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B sound IF mixer ICs however show large picture components on their outputs. In this case filtering is recommended. It was found, that the high pass filters formed by the coupling capacitors at pins ANA_IN1+ and ANA_IN2+ (as shown in the application diagram) are sufficient in most cases. 4.1.2. Quadrature Mixers The digital input coming from the integrated A/D converter may contain audio information at a frequency range of theoretically 0 to 9 MHz corresponding to the selected standards. By means of two programmable quadrature mixers two different audio sources, for example NICAM and FM-mono, may be shifted into baseband position. In the following, the two main channels are provided to process either: - NICAM (channel 1) and FM mono (channel 2) simultaneously or, alternatively, - FM2 (channel 1) and FM1 (channel 2). Two independent digital oscillators are provided to generate two pairs of sin/cos-functions. Two programmable increments, to be divided up into Low- and High Part, determine frequency of the oscillator, which corresponds to the frequency of the desired audio carrier. In section 11.1., format and values of the increments are listed. 4. Architecture of the MSP 3410 B Fig. 4-1 shows a simplified block diagram of the IC. Its architecture is split into three functional blocks: 1. demodulator and decoder section 2. digital signal processing (DSP) section performing audio baseband processing 3. analog section containing two A/D-converters, 6 D/A-converters, and channel selection 4.1. Demodulator Block 4.1.1. Analog Sound IF - Input Section The input pins ANA_IN1+, ANA_IN2+ and ANA_IN- offer the possibility to connect two different sound IF sources to the MSP 3410 B. By means of bit [8] of AD_CV (see Table 11-2) either terrestrial or satellite sound IF signals can be selected. The analog-to-digital conversion of the preselected sound IF signal is done by a flash-converter, whose output can be used to control an analog automatic gain circuit (AGC), providing optimum level for a wide range of input levels. It is possible to switch between automatic gain control and a fixed (setable) input gain. In the optimum case, the input range of the AD converter is completely covered by the sound if source. Some combinations of SAW filters and S_DA_OUT S_CL S_ID S_DA_IN I2S_DA_OUT I2S_CL I2S_WS I2S_DA_IN SBUS Interface I2S Interface S1...4 I2SL/R I2SL/R LOUDSPEAKER L LOUDSPEAKER R Sound IF ANA_IN1+ ANA_IN2+ Demodulator FM1 FM2 NICAM A NICAM B D/A D/A DACM_L Loudspeaker DACM_R DFP Mono MONO_IN IDENT IDENT HEADPHONE L D/A D/A DACA_L Headphone DACA_R SC1_IN_L HEADPHONE R SCART1 SC1_IN_R A/D A/D SCART_L SC2_IN_L SCART_R SCART2 SC2_IN_R SCART_L SCART_R D/A D/A SC1_OUT_L SCART 1 SC1_OUT_R SC2_OUT_L SC3_IN_L SCART3 SC3_IN_R SCART Switching Facilities SCART 2 SC2_OUT_R Fig. 4-1: Architecture of the MSP 3410 B ITT Semiconductors 9 MSP 3410 B PRELIMINARY DATA SHEET N_DA N_CL DCO1 MODE_REG[6,7,10] Oscillator FIR_REG_1 Phase Mixer VREFTOP Lowpass CORDIC Differentiator Mute Lowpass FM2 DQPSK Decoder NICAM Decoder NICAMA NICAMB FRAME CW_DA CW_CL MSP sound IF channel 1 AD_CV[7:1] ANA_IN1+ AGC ANA_IN2+ AD_CV[8] AD Amplitude Carrier Detect Mixer AD_CV[9] IDENT Carrier Detect ANA_IN- MSP sound IF channel 2 Mixer Lowpass Amplitude Mute CORDIC Phase FRAME NICAMA DCO2 Pins Internal signal lines (see fig. 4-5) Control registers DCO2 Oscillator FIR_REG_2 MODE_REG[8] Differentiator Lowpass FM1/AM Fig. 4-2: Demodulator architecture 4.1.3. Lowpass Filtering Block for Mixed Sound IF Signals By means of decimation filters the sampling rate is reduced. Then, data shaping and/or FM bandwidth limitation is performed by a linear phase Finite Impulse Response (FIR-filter). Just like the oscillators' increments the filter coefficients are programmable and are written into the IC by the CCU via the control bus. Thus, for example, different NICAM versions can easily be implemented. Two not necessarily different sets of coefficients are required, one for channel 1 (NICAM or FM2) and one for channel 2 (FM1=FM-mono). In section 11.2.3. several coefficient sets are proposed. Since both MSP channels are designed to process the German FM Stereo System with the same FIR coefficient set (despite 7 dB power level difference of the two sound carriers), the MSP channel 1 has an internal overall gain of 6 dB. To process two carriers of identical power level these 6 dBs have to be taken into account by decreasing the values of the channel 1 coefficient set, which has already been done in table 11-7. 4.1.4. CORDIC Block The filtered sound IF signals are demodulated by transforming the incoming signals from Cartesian into polar format by means of a CORDIC processor block. On the output, the phase and amplitude is available for further 10 processing. AM signals are derived from the amplitude information whereas the phase information serves for FM and NICAM (DQPSK) demodulation. 4.1.5. Differentiators FM demodulation is completed by differentiating the phase information output of the CORDIC block. 4.1.6. Lowpass Signals Filter Block for Demodulated The demodulated FM and AM signals are further lowpass filtered and decimated to a final sampling frequency of 32 kHz. The usable bandwidth of the final baseband signals is about 15 kHz. 4.1.7. High Deviation FM Mode By means of MODE_REG [9], the maximum FM-deviation can be extended to approximately 360 kHz. Since this mode can be applied only for the MSP sound IF channel 2, the corresponding matrices in the baseband processing must be set to sound A. Apart from this, the coefficient sets 380 kHz FIR_REG2 or 500 kHz FIR_REG2 must be chosen for the FIR_REG_2. In relation to the normal FM-mode, the audio level of the highdeviation mode is reduced by 6 dB. ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B S2 and S3 maintain their position and function. This facilitates the copying from selected SCART-inputs to SCART-outputs in the TV-set's standby mode. SCART_IN SC1_IN_L/R MONO_IN SC1_IN_L/R 11 SC3_IN_L/R S1 ACB[3:2] 00 01 10 from Audio Baseband Processing (DFP) SCARTL/R SC1_OUT_L/R D A 11 S2 ACB[5:4] 00 01 10 S3 SC2_OUT_L/R SCART_OUT ACB[1:0] 00 01 10 to Audio Baseband Processing (DFP_IN) A D SCARTL/R 4.1.8. MSP-Mute Function in the Dual Carrier FM Mode To prevent noise effects or FM identification problems in the absence of one of the two FM carriers the MSP 3410 B offers a carrier detection feature, which must be activated by means of AD_CV[9], see section 11.2.1. If no FM carrier is available at the MSP channel 1, the corresponding channel FM2 (and S-Bus output samples 3 and 4) are muted. If no FM carrier is available at the MSP channel 2, the corresponding channel FM1 (and S-Bus output samples 1 and 2) are muted. In case of the absence of both FM carriers pure noise will be amplified by the input AGC. Therefore a proper mute function depends on the noise quality of the TV set's IF part and cannot be guaranteed. The mute function is not recommended for the satellite mode. 4.1.9. DQPSK-Decoder In case of NICAM-mode the phase samples are decoded according the DQPSK-Coding scheme. The output of this block contains the original NICAM-bitstream, which is available at the N-Bus interface. 4.1.10. NICAM-Decoder Before any NICAM decoding can start, the MSP must lock to the NICAM frame structure by searching and synchronizing to the so-called Frame Alignment Words (FAW). To reconstruct the original digital sound samples the NICAM-bitstream has to be descrambled, deinterleaved and rescaled. Also bit error detection and correction (concealment) is performed in this NICAM specific block. To facilitate the Central Control Unit CCU to switch the TV-set to the actual sound mode, control information on the NICAM mode and bit error rate are supplied by the the NICAM-Decoder. It can be read out via the I2C-Bus. 4.2. Analog Section: SCART Switches and Standby Mode The analog input and output sections offer a wide range of switching facilities, which are shown in Fig. 4-3.To design a TV set with 3 pairs of SCART-inputs and two pairs of SCART-outputs, no external switching hardware is required. The switches are controlled by the ACB bits defined in the audio processing interface (see section 12. Programming the Audio Processing Part). If the MSP 3410 B is switched off by first pulling STANDBYQ low and then disconnecting the 5V but keeping the 8V power supply (`Standby'-mode), the switches S1, ITT Semiconductors Fig. 4-3: SCART-Switching Facilities Bold lines determine the default configuration In case of power-on start or starting from standby, the IC switches automatically to the default configuration, shown in the figure above. This action takes place after the first I2C transmission into the DFP part. By transmitting the ACB register first, the individual default setting mode of the TV set can be defined. 4.3. MSP 3410 B Audio Baseband Processing By means of the DFP processor all audio baseband functions are performed by digital signal processing (DSP). The DSP functions are grouped into three processing parts: Input preprocessing, channel selection and channel postprocessing. The input preprocessing is intended to prepare the various signals of all input sources in order to form a standardized signal at the input to the channel selector. The signals can be adjusted in volume, are processed with the appropriate deemphasis and are dematrixed if necessary. Having prepared the signals that way, the channel selector makes it possible to distribute all possible source signals to the desired output channels. The ability to route in an external coprocessor for special effects like graphic equalizer, surround processing, and sound field processing is of special importance. Routing can be done with each input source and output channel via the I2S inputs and outputs. All input and output signals can be processed simultaneously with the exception that FM2 cannot be pro11 MSP 3410 B cessed at the same time as NICAM. Note that the NICAM input signals are only available in the MSP 3410 B version. While processing the adaptive deemphasis, no dual carrier stereo (German or Korean) or NICAM processing is possible. Identification values are not valid either. PRELIMINARY DATA SHEET operation mode, the MSP 3410 B detects the so-called identification signal. Information is supplied via the Stereo Detection Register to an external CCU. Stereo Detection Filter IDENT AM Demodulation Bilingual Detection Filter Level Detect Level Detect Stereo Detection Register 4.4. Dual Carrier FM Stereo/Bilingual Detection In the German and Korean TV standard, audio information can be transmitted in three modes: Mono, stereo or bilingual. To obtain information about the current audio - Fig. 4-4: Stereo/bilingual detection Analog Inputs SCARTL SCARTR DC level readout FM1 FM1 FM2 Adaptive Deemphasis Deemphasis 50/75 s J17 Prescale Loudspeaker Channel Matrix Bass Treble Loudness Spatial Effects Volume Balance Loudspeaker L Loudspeaker Outputs Loudspeaker R Prescale FM-Matrix Beeper Demodulated IF Inputs DC level readout FM2 NICAMA NICAMB Prescale Channel Select Deemphasis J17 Headphone Channel Matrix Volume Headphone L Headphone Outputs Headphone R SBUS1 SBUS2 SBUS Inputs SBUS3 SBUS4 SCART Channel Matrix Volume SCARTL SCART Outputs SCARTR I 2S Channel Matrix I 2SL I 2SR I 2S Outputs I 2SL I 2S Bus Inputs I 2SR Quasi peak readout L Quasi-Peak Detector Quasi peak readout R Note: Actually, the source of the Quasi-Peak Detector is always the signal of the loudspeaker channels. Fig. 4-5: Audio baseband processing (DFP-Firmware) NICAMA Internal signal lines (see fig. 4-2) Table 4-1: Some examples for recommended channel assignments for demodulator and audio processing part Mode B/G-Stereo B/G-Bilingual MSP Sound IFChannel 1 FM2 (5.74 MHz): 2R FM2 (5.74 MHz): Sound B MSP Sound IFChannel 2 FM1 (5.5 MHz): L+R FM1 (5.5 MHz): Sound A FMMatrix B/G Stereo No Matrix ChannelSelect Speakers: FM Speakers: FM H. Phone: FM Speakers: NICAM H. Phone: FM Speakers: FM Speakers: FM Speakers: FM H. Phone: FM Speakers: FM H. Phone: FM Channel Matrix Stereo Speakers: Sound A H. Phone: Sound B Speakers: Stereo H. Phone: Sound A Sound A Stereo Speakers: Sound A H. Phone: Sound B=C Speakers: Sound A H. Phone: Sound A NICAM-I-ST/ FM-mono Sat-Mono Sat-Stereo Sat-Bilingual NICAM (6.552 MHz) FM (6.0 MHz): mono No Matrix not used 7.2 MHz: R 7.38 MHz: Sound C FM (6.5 MHz): mono 7.02 MHz: L 7.02 MHz: Sound A No Matrix No Matrix No Matrix Sat-High Dev. Mode don't care 6.552 MHz No Matrix 12 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B read address (81 hex or 85 hex) and reading two bytes of data. Refer to Fig. 5-1: I2C Bus Protocol and section 5.2. Proposal for MSP 3410 B I2C Telegrams. Due to the internal architecture of the MSP 3410 B, the IC cannot react immediately to an I2C request. The typical response time is about 0.3 ms for the DFP processor part and 1 ms for the FP processor part if NICAM processing is active. If the receiver (MSP) can't receive another complete byte of data until it has performed some other functions, for example servicing an internal interrupt, it can hold the clock line I2C_CL LOW to force the transmitter into a wait state. The positions within a transmission where this may happen are indicated by 'Wait' in section 5.1. The maximum Wait-period of the MSP during normal operation mode is less than 7 ms. I2C-Bus error conditions (valid only from TC17 on): In case of any internal error, the MSPs wait-period is extended to 7.07 ms. Afterwards the MSP does not acknowledge (NAK) the device address. The data line will be left HIGH by the MSP and the clock line will be released. The master can then generate a STOP condition to abort the transfer. By means of NAK, the master is able to recognize the error state and to reset the IC via I2C-Bus. While transmitting the reset protocoll (s. 5.2.4.) to `CONTROL', the master must ignore the not acknowledge bits (NAK) of the MSP. 5. Control Bus Interface As a slave receiver, the MSP 3410 B can be controlled via I2C bus. Access to internal memory locations is achieved by subaddressing. The FP processor and the DFP processor parts have two separate subaddressing register banks. In order to allow for more MSP 3410 B IC's to be connected to the control bus, an ADR_SEL pin has been implemented. With ADR_SEL pulled to high, the MSP 3410 B responds to changed device addresses, thus two identical devices can be selected. Other devices of the same family will have different subaddresses (e.g. 34X0). By means of the RESET bit in the CONTROL register all devices with the same device address are reset. The IC is selected by asserting a special device address in the address part of a I2C transmission. A device address pair is defined as a write address (80 hex or 84 hex) and a read address (81 hex or 85 hex). Writing is done by sending the device write address first, followed by the subaddress byte, two address bytes, and two data bytes. For reading, the read address has to be transmitted first by sending the device write address (80 hex or 84 hex) followed by the subaddress byte and two address bytes. Without sending a stop condition, reading of the addressed data is done by sending the device Table 5-1: I2C Bus Device and Subaddresses Name Binary Value Hex Value ADR_SEL=low Hex Value ADR_SEL=high Mode Function MSP CONTROL TEST WR_FP RD_FP WR_DFP RD_DFP 1000 000x 0000 0000 0000 0001 0001 0000 0001 0001 0001 0010 0001 0011 80/81 00 01 10 11 12 13 84/85 R/W W W W W W W MSP device address software reset only for internal use write address FP read address FP write address DFP read address DFP Table 5-2: Control Register Name CONTROL MSB RESET 14 0 13..1 0 LSB 0 ITT Semiconductors 13 MSP 3410 B 5.1. Protocol Description Write to DFP or FP S hex 80 Wait ACK sub-addr ACK addr-byte high ACK addr-byte low ACK PRELIMINARY DATA SHEET data-byte high ACK data-byte low ACK P Read from DFP or FP S hex 80 Wait ACK sub-addr ACK addr-byte high ACK addr-byte low ACK S hex 81 Wait ACK data-byte high Write to Control or Test Registers S hex 80 Wait ACK sub-addr ACK data-byte high ACK data-byte low Note: S = P= ACK = NAK = Wait = I2C-Bus Start Condition from master I2C-Bus Stop Condition from master Acknowledge-Bit: LOW on I2C_DA from slave (= MSP, grey) or master (= CCU, hatched) Not Acknowledge-Bit: HIGH on I2C_DA from master (= CCU, hatched) to indicate `End of Read' or from MSP indicating internal error state (not illustrated, only for version F7 on.) I2C-Clock line held low by the slave (= MSP) while interrupt is serviced (< 7 ms) I2C_DA S I2C_CL Fig. 5-1: I2C bus protocol 1 0 P (MSB first; data must be stable while clock is high) 5.2. Proposal for MSP 3410 B I2C Telegrams 5.2.1. Symbols < > aa dd Start Condition Stop Condition Address Byte Data Byte 5.2.4. Examples <80 00 80 00> <80 00 00 00> <80 12 00 08 01 20> RESET all MSP's statically clear RESET set loudspeaker channel source to NICAM and Matrix to STEREO 5.3. Start Up Sequence 5.2.2. Write Telegrams <80 00 dd dd> <80 10 aa aa dd dd> <80 12 aa aa dd dd> software RESET write data into FP register write data into DFP register 5.2.3. Read Telegrams <80 11 aa aa <81 dd dd> read data from FP register <80 13 aa aa <81 dd dd> read data from DFP register After power on or RESET the IC is in an inactive state. The CCU has to transmit the required coefficient set for a given operation via the I2C bus. Initialization must start with the demodulator part. If required for any reason, from version F7 on, the audio processing part can be loaded before the demodulator part. 14 CCC CCC CCC CCC CCC CCC ACK data-byte low NAK P ACK P ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 8. Audio PLL and Crystal Specifications The MSP 3410 B requires a 18.432 MHz (10 pF, parallel) crystal. The clock supply of the whole system depends on the MSP 3410 B operation mode: 1. FM-Stereo: The system clock runs free on the crystal's 18.432 MHz. 2. D2-MAC operation: In this case, the system clock is locked to a synchronizing signal (DMA_SYNC) supplied by the D2-MAC chip. The DMA and the AMU chips can be driven by the MSP 3410 B audio clock (AUD_CL_OUT). 3. NICAM and FM_mono: An integrated clock PLL uses the 364 kHz baud-rate, accomplished in the NICAM demodulator block, to lock the system clock to the bit rate respective 32 kHz sampling rate of the NICAM transmitter. As a result, the whole audio system is supplied with a controlled 18.432 MHz clock. Remark on using the crystal: External capacitors at each crystal pin to ground are required. They are necessary for tuning the open-loop frequency of the internal PLL and for stabilizing the frequency in closed-loop operation. The higher the capacitors, the lower the clock frequency results. The nominal free running frequency should match the center of the tolerance range between 18.433 and 18.431 MHz as closely as possible. 6. N-Bus Interface The N-Bus interface consists of two lines, N-data and N-clock. The pure NICAM_728 data stream (before descrambling) is available together with a 728 kHz clock signal for the purpose of data transmission. N-Bus signals are based on TTL-levels. Data are latched with the falling clock edge. 7. Pay-TV Interface The MSP 3410 B facilitates the reception of encrypted NICAM sound, which is provided by Pay-TV systems. By means of bit 1 of the control word `MODE_REG' the operation mode `PAY-TV' can be activated. The MSP 3410 B inherent descrambler generally uses a 9-bit start sequence, which initializes a pseudo random sequence generator each ms. In normal operation mode the 9-bit sequence exists of 9 bits having each high level, which are loaded automatically into the descrambler's shift register. In the Pay-TV mode these bits have to be loaded via the two pins CW_DA and CW_CL into the mentioned shift register. The time window to load one complete 9-bit sequence is given by the high time of the frame signal which is available on pin 5. It is not necessary to load a new sequence at each ms, because if no new sequence has been transmitted, the old one is saved. If less than 9 new bits at each ms are loaded, one has to consider that any new incoming bit shifts the old ones by one position inside the shift register. A complete timing diagram is illustrated in Fig. 7-1. Frame 8 Bits 720 Bits Start of Descrambler End T CW-Clock CW-Data CW-Clock Min: 10 kHz Max: 4 MHz 1 2 3 4 5 6 7 8 9 Period to load CW-Word T 7E-6 s Fig. 7-1: Timing for Pay-TV signals ITT Semiconductors 15 MSP 3410 B 9. S-Bus Interface Digital audio information provided by the DMA2381 via the AMU is serially transmitted to the MSP 3410 B via the S-Bus. The MSP 3410 B always has the master function. The S-Bus interface consists of four pins: 1. S_DA_IN: Four channels (4*16 bits) per sampling cycle (32 kHz) are transmitted. 2. S_CL: Gives the timing for the transmission of S-DATA (4.608 MHz). 3. S_ID: After 64 S-CLOCK cycles the S_ID determines the end of one sampling period. 4. S_DA_OUT: FM-Demodulator or NICAM decoder output for test purpose. 10. I2S Bus Interface PRELIMINARY DATA SHEET By means of this standardized interface, additional feature processors can be connected to the MSP 3410 B. Two possible formats are supported: The standard mode (MODE_REG[4]=0) selects the SONY format, where the I2S_WS signal changes at the word boundaries. The so-called PHILIPS format, which is characterized by a change of the I2S_WS signal one I2S_CL period before the word boundaries, is selected by setting MODE_REG[4]=1. The MSP 3410 B normally serves as the master on the I2S interface. Here the clock and word strobe lines are driven by the MSP 3410 B. By setting MODE_REG[3]=1, the MSP 3410 B is switched to a slave mode. Now these lines are input to the MSP 3410 B and the master clock is synchronized to 576 times the I2S_WS rate (32 kHz). No NICAM or D2MAC operation is possible in this mode. The I2S bus interface consists of four pins: 1. I2S_DA_IN: For input, two channels (2*16 bits) per sampling cycle (32 kHz) are transmitted. 2. I2S_DA_OUT: For output, two channels (2*16 bits) per sampling cycle (32 kHz) are transmitted. 3. I2S_CL: Gives the timing for the transmission of I2S serial data (1.024 MHz). 4. I2S_WS: The I2S_WS word strobe line defines the left and right sample. 16 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Accessing a process address starts specific actions in the FP processor. For example addressing register 60hex activates the internal transfer of all preloaded data (MODE_REG, DCO1_LO/HI) into their final hardware registers. It's only the access of the address 60hex that counts, the two data bytes in the transmission have no meaning. Table 4-1 explains how to assign FM carriers to the MSP-Sound IF channels and the corresponding matrix modes in the audio processing part. 11. Programming the Demodulator Part 11.1. Write Registers: Table and Addresses In Table 11-1 all Write Registers are listed. All transmissions on the control bus are 16 bits wide. Data for the demodulator part (FP) have 8 or 12 significant bits. These data have to be inserted LSB bound and filled with zero bits into the 16 bit transmission word. Table 11-1: MSP 3410 B write registers Register Write Address (hex) 00BB 0083 0001 0005 0093 009B 00A3 00AB 0107 010F Function AD_CV MODE_REG FIR_REG_1 FIR_REG_2 DCO1_LO DCO1_HI DCO2_LO DCO2_HI FAWCT_SOLL FAW_ER_TOL input selection, configuration of AGC and Mute Function and selection of A/Dconverter mode register serial shift register for 6 8 bit, filter coefficient channel 1 (48 bit) serial shift register for 6 8 bit, + 2 12 bit off set (total 72 bit) increment channel 1 Low Part increment channel 1 High Part increment channel 2 Low Part increment channel 2 High Part To synchronize to the frame structure of the NICAM bit stream, the MSP checks the data for Frame Alignment Words (FAWs). After having captured the first one, the MSP continues to check for n frame periods. On having found at least n-m FAWs after this period, the frame synchronism is achieved and the MSP switches to active NICAM-decoding. The value for n has to be loaded into FAWCT_SOLL; the one for m into FAW_ER_TOL. Proposal : n=12; m=2 audio PLL in case of NICAM operation mode Function After switch on or changing the TV system (B/G to I, I to B/G) all write-parameters have to be transmitted via I2C-Bus into the MSP 3410 B. Then `Load_REG_1/2' writes them into the corresponding registers. FM-processing starts. These are MODE_REG, DCO1/2_LO/HI. In the case of a TV-Standard change in MSP channel 1, only new channel 1 parameters have to be transmitted into the IC via I2C-Bus. These are: MODE_REG, DCO1_LO/HI. LOAD_REG_1 sets up the MSP channel 1 without interrupting the MSP channel 2 (FM1 or MONO channel). To start the NICAM-processing, this address has to be transmitted into the FP. Check of the FP ALU (for testing only) 0 always open 1 to be closed = default AUDIO_PLL Process LOAD_REG_1/2 02D7 Address (hex) 0056 LOAD_REG_1 0060 SEARCH_NICAM SELF_TEST 0078 0792 Note: The WRITE-Addresses cannot be used to read back the corresponding register values. ITT Semiconductors 17 MSP 3410 B 11.2. Write Registers: Functions and Values In the following, the functions of some registers are explained and their (default) values are defined: 11.2.1. Setting of Parameter AD_CV Table 11-2: AD_CV Register AD_CV 00BBhex Bit AD_CV [0] AD_CV [6:1] Meaning test Reference level in case of Automatic Gain Control = on (see Table 11-3). Constant gain factor when Automatic Gain Control = off (see Table 11-4). Determination of Automatic Gain or Constant Gain Selection of analog input MSP-Carrier-Mute Function PRELIMINARY DATA SHEET Settings 0 = on (default) 1 = off (for testing) AD_CV [7] AD_CV [8] AD_CV [9] 0 = constant gain 1 = automatic gain 0 = ANALOG IN1 1 = ANALOG IN2 0 = off (no mute) 1 = on (mute as described in section 4.1.) 0 = on (default) 1 = off (for testing) 0 AD_CV[10] AD_CV[15:11] NICAM-FIFO-Watchdog (only for test mode) reserved Table 11-3: Reference values for active AGC (AD_CV[7] = 1) Application Terrestrial TV Input Signal Contains 2 FM Carriers or 1 FM and 1 NICAM Carrier 1 or more FM Carriers 1 NICAM Carrier only AD_CV [6:1] Ref. Value 101000 AD_CV [6:1] in integer 40 Range of Input Signal at pin 41 or 43 0.14 - 3 Vpp1) SAT NICAM only 1) 100011 010100 35 20 0.14 - 3 Vpp1) 0.07 - 1.0 Vpp For signals above 1.4 Vpp, the minimum gain of 3 dB is switched and overflow of the AD 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. 18 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Table 11-4: AD_CV parameters for constant input gain (AD_CV[7]=0) Step 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 1) AD_CV [6:1] Constant Gain 000000 000001 000010 000011 000100 000101 000110 000111 001000 001001 001010 001011 001100 001101 001110 001111 010000 010001 010010 010011 010100 Gain 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 Input Level at pin ANA_IN1+ and ANA_IN2+ maximum input level: 3 Vpp (FM) or 1 Vpp (NICAM)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 AD 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. 11.2.2. Control Register `MODE_REG' The register `MODE_REG' contains the control bits determining the operation mode of the MSP 3410 B; Table 11-5 explains all bit positions. Table 11-5: Control word `MODE_REG': all bits are "0" after power-on-reset MODE_REG 0083hex Bit [0] [1] [2] [3] [4] [5] [6] Function DMA_SYNC1) PAYTV_EN DESCR_DIS I2S Mode1) I2S_WS Mode Audio_CL_OUT NICAM1) Comment Synchronization to DMA Pay-TV NICAM-Descrambler Master/Slave mode of the I2S bus WS due to the Sony or Philips-Format Switch Audio_Clock_Output to tristate MSP-channel 1 mode Definition 0 = NICAM (intern. Sync) 1 = D2MAC (ext. Sync) 0 = off 1 = on 0 = on 1 = off 0 = Master 1 = Slave 0 = Sony 1 = Philips 0 = on 1 = tristate 0 = FM 1 = Nicam Recommendation X 0 0 X X X X ITT Semiconductors 19 MSP 3410 B PRELIMINARY DATA SHEET MODE_REG 0083hex Bit [7] [8] [9] Function FM1 FM2 FM AM HDEV Comment MSP-channel 1 mode MSP-channel 1/2 mode High Deviation Mode (channel matrix must be sound A) configuration of internal sound bus mode of sound bus3) reserved Definition 0 = Nicam 1 = FM 0 = FM 1 = AM 0 = normal 1 = high deviation mode 0 = Nicam/FM-Mono 1 = Two Carrier FM 0 = Tristate 1 = Active must be 0 Recommendation X 0 0 [10] [11] [15:12] 1) S-Bus Setting S-Bus Mode2) reserved X 0 0 X: Depending on mode In case of NICAM operation, I2S-slave mode or synchronization to DMA not possible. In case of synchonization to DMA, no I2S-slave mode or NICAM is allowed. In case of I2S-slave mode, no synchonization to DMA or NICAM is allowed. 2) The normal operation mode is `Active' 3) To reduce radiation, the pins S_DA_OUT, S_CL, and S_ID should be switched to tristate if not used. IF S-Bus Mode = `tristate', pins `Frame', N_CL, and N_DA are also switched to tristate. 11.2.3. FIR-Parameter The following data values (see Table 11-6) are to be transferred 8 bits at a time embedded LSB-bound in a 16 bit word. Note: These sequences must be obeyed. To change a coefficient set, the complete block FIR_REG_1 or FIR_REG_2 must be transmitted. The new coefficient set will be active without a load_reg routine. Table 11-6: Loading sequence for FIR-coefficients FIR_REG_1 0001hex No. 1 2 3 4 5 6 Symbol Name NICAM/FM2_Coeff. (5) NICAM/FM2_Coeff. (4) NICAM/FM2_Coeff. (3) NICAM/FM2_Coeff. (2) NICAM/FM2_Coeff. (1) NICAM/FM2_Coeff. (0) (Channel 1: NICAM/FM2) Bits 8 8 8 8 8 8 Value see Table 11-7. FIR_REG_2 0005hex No. 1 2 3 4 5 6 7 8 9 Symbol Name (Channel 2: FM1/FM mono) Bits 8 8 8 8 8 8 8 8 8 Value 04 HEX 40 HEX 00 HEX see Table 11-7. * IMREG1 (8 LSBS) * IMREG1 / IMREG2 (4 MSBs / 4 LSBs) * IMREG2 (8 MSBs) FM_Coef (5) FM_Coef (4) FM_Coef (3) FM_Coef (2) FM_Coef (1) FM_Coef (0) * IMREG_1/2: Two 12-bit off-set constants IMREG1 and IMREG2 are used to compensate for DCoffset, which are inherent to the FIR filter structure. IMREG1 is valid for the FIR_REG_1, IMREG2 for FIR_REG_2. In the Table above, IMREG1= IMREG2 = 004. Due to the partitioning to 8 bit units, the values 04hex, 40hex, and 00hex arise. ITT Semiconductors 20 PRELIMINARY DATA SHEET MSP 3410 B Table 11-7: 8 bit FIR-coefficients (decimal integer) for MSP 3410 B FIR_REG_1 0001hex and FIR_REG_2 0005hex NICAM FMTerrestrial B/G, I FM - Satellite FIR filtering corresponds to a bandpass filtering with a band width of B = 130 kHz, 180 kHz, 200 kHz, ... 380 kHz B fc frequency Autosearch or AM Bandwidth (see also Table FM Volume Prescale) C (i) SC/ SP/ F FIR_ REG1 UK FIR_ REG1 German Dual FM FIR_ REG1 and 2 3 18 27 48 66 72 130 kHz FIR_ REG1 1) 130 kHz FIR_ REG2 1) 180 kHz FIR_ REG1 180 kHz FIR_ REG2 200 kHz FIR_ REG1 200 kHz FIR_ REG2 280 kHz FIR_ REG1 280 kHz FIR_ REG2 380 kHz FIR_ REG1 380 kHz FIR_ REG2 500 kHz FIR_ REG2 FIR_ REG2 0 1 2 3 4 5 1) -2 -8 -10 10 50 86 2 4 -6 -4 40 94 37 27 32 60 51 65 73 53 64 119 101 127 4 9 14 23 27 32 9 18 28 47 55 64 1 9 14 24 33 37 3 18 27 48 66 72 -4 -4 2 19 41 57 -8 -8 4 36 78 107 -1 -6 -9 4 38 70 -1 -9 -16 5 65 123 -1 -1 -8 2 59 126 75 19 36 35 39 40 The 130 kHz coefficients are based on subcarriers, which are 7 dB below an existent main carrier. INCRdez = int(f/fs 224) with: int = integer function f = IF-frequency in MHz fS = sampling frequency (18.432 MHz) Conversion of INCR into hex-format and separation of the 12-bit low and high parts lead to the required increments. (DCO1_HI or _LO for channel 1, DCO2_HI or LO for channel 2). 11.2.4. DCO-Increments For a chosen TV standard a corresponding set of 24-bit increments determining the mixing frequencies of the quadrature mixers, has to be written into the IC. In Table 11-8 some examples of DCO increments are listed. It is necessary to divide them up into low part and high part. The formula for the calculation of the increments for any chosen IF-Frequency is as follows: Table 11-8: DCO increments for the MSP 3410 B; frequency in MHz, increments in Hex DCO1_LO 0093hex, DCO1_HI 009Bhex; DCO2_LO 00A3hex, DCO2_HI 00ABhex Frq. MHz 4.5 5.04 5.5 5.58 5.7421875 6.0 6.2 6.5 6.552 7.02 7.38 DCO_HI 3E8 460 4C6 4D8 4FC 535 561 5A4 5B0 618 668 DCO_LO 000 000 38E 000 0AA 555 C71 71C 000 000 000 5.76 5.85 5.94 6.6 6.65 6.8 7.2 7.56 500 514 528 5BA 5C5 5E7 640 690 000 000 000 AAA C71 1C7 000 000 Frq. MHz DCO_HI DCO_LO ITT Semiconductors 21 MSP 3410 B 11.3. Read Registers: Listing and Addresses The following 8-bit parameters can be read out of the RAM of the MSP 3410 B; functionally they all belong to the NICAM decoding process; their addresses are listed in Table 11-9. All transmissions take place in 16 bit words. The valid 8 bit data are the 8 LSBs of the received data word. To enable correct switching to NICAM sound, at least the register C_AD_BITS must be read and evaluated by the CCU. Additional data bits and CIB bits, if supplied by the NICAM transmitter, as well as information about the signal quality can be obtained by reading the remaining registers. Format: MSB 7 A[10] 6 A[9] 5 A[8] PRELIMINARY DATA SHEET ADD_BITS 0038hex 4 A[7] 3 A[6] 2 A[5] 1 A[4] LSB 0 A[3] CIB_BITS: cib bits 1 and 2 (see NICAM 728 specifications) Format: MSB 7 x 6 x 5 x CIB_BITS 003Ehex 4 x 3 x 2 x 1 CIB1 LSB 0 CIB2 Table 11-9: Addresses of read registers Read Registers C_AD_BITS FAWCT_IST ADD_BITS CIB_BITS CONC_CT HEX 0023 0025 0038 003E 0058 FAWCT_IST: The contents of this register give information on the actual position of the FAW-counter. For optimum NICAM performance, the value should be identical with or little below the value of 'FAW_SOLL'. If it reaches 0 the FP-software mutes and stops the NICAM-decoding automatically by searching for FAW synchronization once more. CONC_CT: This register contains the actual number of bit errors of the previous 728 bit data frame. It may happen that in spite of acceptable FAWCT_IST the bit error rate result is too high for appropriate sound performance. In this case the CCU can switch to the analog FMsound assumed to have the same program (Control bit C4). Table 11-10: NICAM operation modes as defined by the EBU NICAM 728 specification C4 C3 0 0 0 0 0 0 0 C2 0 0 1 1 0 0 1 C1 0 1 0 1 0 1 0 Operation Mode Stereo sound (NICAMA/B), independent mono sound (FM1) Two independent mono signals (NICAMA, FM1) Three independent mono channels (NICAMA, NICAMB, FM1) Data transmission only; no audio Stereo sound (NICAMA/B), FM1 carries same channel One mono signal (NICAMA). FM1 carries same channel as NICAMA Two independent mono channels (NICAMA, NICAMB). FM1 carries same channel as NICAMA Data transmission only; no audio Unimplemented sound coding option (not yet defined by EBU NICAM 728 specification) 11.4. Read Registers: Functions and Values C_AD_BITS: NICAM operation mode control bits and A[0-2] of the additional data bits. Format: MSB 7 A[2] 6 A[1] 5 A[0] C_AD_BITS 0023hex 4 C4 3 C3 2 C2 1 C1 LSB 0 0 S 1 0 0 0 Important: "S" = Bit[0] indicates correct NICAM-synchronization (S=1). If S = 0, no correct frame or sequence synchronization have been found yet and the read registers are not valid. The operation mode is coded by C4-C1 as shown in Table 11-10. ADD_BITS: Contains the remaining 8 of the 11 additional data bits. The additional data bits are yet not defined by the NICAM 728 system. 22 1 1 1 x 0 1 1 x 1 x ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B For NICAM operation the following steps listed in `NICAM_START, _READ and _Check' in Table 11-11 must be taken. For FM-stereo operation the evaluation of the identification signal must be performed. For positive identification check, the MSP 3410 B sound channels have to be switched corresponding to the detected operation mode. 11.5. Sequences to Transmit Parameters and to Start Processing After having been switched on, the MSP has to be initialized by transmitting the parameters according to the LOAD_SEQ_1/2 of Table 11-11. To make the data active, the load routine LOAD_REG_1/2 must be activated. Table 11-11: Sequences to initialize and start the MSP 3410 B LOAD_SEQ_1/2: General Initialization, followed by LOAD_REG_1/2 Write into MSP 3410 B: 0. AD_CV 1. Audio_PLL 2. FAWCT_SOLL 3. FAW_ER_TOL 4. FIR_REG_1 5. FIR_REG_2 6. MODE_REG 7. DCO1_LO 8. DCO1_HI 9. DCO2_LO 10. DCO2_HI 11. start LOAD_REG_1/2 process; FM-processing starts NICAM_START: Start of the NICAM Software Write into MSP 3410 B: 1. Start SEARCH_NICAM Process 2. Wait at least 0.5 s NICAM_READ: Read NICAM specific information Read out of MSP 3410 B: 1. FAWCT_IST 2. C_AD_BITS 3. CONC_CT NICAM_CHECK: CCU checks for presence, operation mode and quality of NICAM signal 1. Evaluation of all three parameters in the CCU (see section 11.4.) 2. If necessary, switch the corresponding sound channels within the audio processing part FM_IDENT_CHECK: Decoding of the identification signal 1. Evaluation of the stereo detection register (DFP register 0018hex, high part) 2. If necessary, switch the corresponding sound channels within the audio processing part LOAD_SEQ_1: Reinitialization of Channel 1 without affecting Channel 2, followed by LOAD_REG_1 Write into MSP 3410 B: 1. FIR_REG_1 2. MODE_REG 3. DCO1_LO 4. DCO1_HI 5. start LOAD_REG_1 process (6 8 bit) (12 bit) (12 bit) In the case "NICAM only" operation, the steps 9. and 10. can be skipped Note: To ensure software compatibility to the MSP3400 B, before any modification of a demodulator parameter concerning an active output channel, this channel should be muted (only for NICAM mode) (only for NICAM mode) PAUSE: Duration of "Pause" determines the repetition rate of the NICAM or the FM_IDENT-check AUDIO PROCESSING INIT: Initialization of Audio Processing Part, which may be customer dependant (see section 12.) ITT Semiconductors 23 MSP 3410 B 11.6. Software Proposals for Multistandard TV-Sets To familiarize the reader with the programming scheme of the MSP 3410 B demodulator part, three examples in the shape of flow diagrams are shown in the following sections. PRELIMINARY DATA SHEET the MSP 3410 B must be switched to the FM-mono sound. 11.6.2. Multistandard Including System I with NICAM/FM-Mono only This case is identical to the one above. The only difference consists in selecting the UK parameters for DCO1_LO/HI, DCO2_LO/HI and FIR_REG_1. 11.6.1. Multistandard Including System B/G with NICAM/FM-Mono only Fig. 11-1 shows a flow diagram for the CCU software, applied for the MSP 3410 B in a TV set, which facilitates NICAM and FM-mono sound. For the instructions, please refer to Table 11-11. 11.6.3. Multistandard Including System B/G with NICAM/FM-Mono and German DUAL FM Fig. 11-3 shows a flow diagram for the CCU software, applied for the MSP 3410 B in a TV set, which facilitates all standards according to System B/G. For the instructions used in the diagram, please refer to Table 11-11. After having switched on the TV-set and having initialized the MSP 3410 B (LOAD_SEQ_1/2), FM-mono sound is available. Fig. 11-3 shows that to check for any stereo or bilingual audio information in channel 1, its parameter should be loaded with NICAM and FM2 parameters alternately (LOAD_SEQ_1). In the case of success the MSP 3410 B has to switch to the desired audio mode. START LOAD_SEQ_1/2 Channel 1: NICAM Parameter Audio Processing Init NICAM_START 11.6.4. Satellite Mode Fig. 11-2 shows the simple flow diagram to be used for the MSP 3410 B in a satellite receiver. For FM-mono operation the corresponding FM carrier should preferably be processed at the MSP-channel 2. Pause NICAM_READ Yes NICAM_CHECK NICAM ? START LOAD_SEQ_1/2 MSP-Channel 1: FM2-Parameter MSP-Channel 2: FM1-Parameter No LOAD_REG_1 Fig. 11-1: CCU software flow diagram: Standard B/G/I NICAM/FM mono only Audio Processing Init If the program is changed, resulting in another program within the Scandinavian System B/G no parameters of the MSP 3410 B have to be modified. To facilitate the check for NICAM the CCU has only to continue at the 'NICAM_START' instruction. During the 'NICAM_CHECK' 24 STOP Fig. 11-2: CCU software flow diagram: SAT-mode ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 11.6.5. Automatic Search Function for FM-Carrier Detection The AM demodulation ability of the MSP 3410 B offers the possibility to calculate the "field strength" of the momentarily selected FM carrier which can be read out by the CCU. In SAT receivers this feature can be used to realize an automatic FM carrier search. Therefore, the MSP has to be switched to AM-mode (Bit 8 of MODE_REG). 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). 1) START LOAD_SEQ_1/2 Channel 1: NICAM Parameter Audio Processing Init NICAM_START NICAM_READ 1) After each incrementation there is a field strength value available at the DC level register FM1, which must be examined for relative maxima by the CCU. This results in either continuing search or switching the MSP back to FM demodulation mode. During the search process the FIR_REG_2 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 "DC Level Readout FM1") also gives information on whether a main FM carrier or a subcarrier was detected, and as a practical consequence the FM bandwidth (FIR_REG_1/2) and the deemphasis (50 s or adaptive) can be switched automatically. For a detailed description of the automatic search function please refer to the corresponding MUBI program. 11.6.6. Automatic Standard Detection The AM demodulation ability of the MSP 3410 B enables also a simple method to decide between standard B/G (FM-carrier at 5.5 MHz) and standard I (FM-carrier at 6.0 MHz). It is achieved by tuning the MSP in the AM-mode to the two discrete frequencies and evaluating the field strength via the DC level register. Pause NICAM_READ Yes NICAM_CHECK NICAM ? No LOAD_SEQ_1 Channel 1: FM2 Parameter Pause Yes FM_ IDENT_CHECK Pilot? No LOAD_SEQ_1 Channel 1: NICAM Parameter Fig. 11-3: CCU software flow diagram: Standard B/G with NICAM or FM stereo 1) The first READ could result in incorrect values. ITT Semiconductors 25 MSP 3410 B 12. Programming the Audio Processing Part 12.1. Summary of the DSP Control Registers Control registers are 16 bit wide. Transmissions via I2C Name Volume loudspeaker channel Balance loudspeaker channel [L/R] Bass loudspeaker channel Treble loudspeaker channel Loudness loudspeaker channel Spatial effect loudspeaker channel Volume headphone channel Volume SCART channel Loudspeaker channel source Loudspeaker channel matrix Headphone channel source Headphone channel matrix SCART channel source SCART channel matrix I2S I2S channel source channel matrix 000chex 000bhex 000ahex 0009hex I2C Bus Address 0000hex 0001hex 0002hex 0003hex 0004hex 0005hex 0006hex 0007hex 0008hex High/ Low H H H H H H H H H L H L H L H L H H H L PRELIMINARY DATA SHEET bus have to take place in 16 bit words. Single data entries are 8 bit. Some of the defined 16 bit words are divided into low and high byte, thus holding two different control entities.All control registers are readable. Adjustable Range, Operational Modes [+12 dB ... -94 dB, MUTE] [0..100% / 100% or 100% / 0..100%] [+12 dB ... -12 dB] [+12 dB ... -12 dB] [0 dB ... +17 dB] [OFF, ON] [+12 dB ... -77 dB, MUTE] [00hex ... 7Fhex] [FM, NICAM, SCART, SBUS12, SBUS34, [SOUNDA, SOUNDB, STEREO] [FM, NICAM, SCART, SBUS12, SBUS34, [SOUNDA, SOUNDB, STEREO] [FM, NICAM, SCART, SBUS12, SBUS34, [SOUNDA, SOUNDB, STEREO] [FM, NICAM, SCART, SBUS12, SBUS34, [SOUNDA, SOUNDB, STEREO] [FM, NICAM, SCART, SBUS12, SBUS34, [00hex ... 7Fhex] [00hex ... 7Fhex] I2S] I2S] I2S] I2S] I2S] Reset Mode MUTE 100%/100% 0 dB 0 dB 0 dB OFF MUTE 00hex FM SOUNDA FM SOUNDA FM SOUNDA FM SOUNDA FM (see note) 00hex 00hex EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E E EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E EE E EEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEEE E EE E Quasi-peak detector source Prescale SCART Prescale FM FM matrix 000dhex 000ehex [NO_MAT, GSTEREO, KSTEREO] [OFF, 50 s, 75 s, J17] [OFF, WP1] [00hex ... 7Fhex] [OFF, J17] Bits [7..0] NO_MAT (see note) 50 s OFF (s. note) 00hex 00hex Deemphasis FM Adaptive Deemphasis FM Prescale NICAM 0010hex 0011hex 0013hex 0014hex 0015hex 0016hex 000fhex H L H H H CCCCCCCCCCCCCCCCCCC C C C CC C C CCCCCCCCCCCCCCCCC CCCCCC C CC C CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC CCCCCCCCCCCCCCCCCCCCCCCCCCCCC Deemphasis NICAM J17 (s. note) ACB Register (SCART Switches and DIG_OUT Pins) Beeper H/L L [00hex ... 7Fhex]/[00hex ... 7Fhex] [B/G, M] reserved for future use 0/0 (s. note) B/G - Identification Mode Special SCART Mode Unused parts of the 16 bit registers must be zero. Note: For future compatibility to new technical codes of the MSP3410 B or the MSP3400 B some coefficients concerning features not implemented or not changeable yet must nevertheless be initialized. Please consider the following compatibility restrictions: - Quasi peak source must always be the same as the speaker source - NICAM deemphasis switching facility not yet implemented, NICAM deemphasis must be switched on - Panda1, if switched on, must always be activated together with 75 s deemphasis - Panda1 must be switched off if NICAM is selected - FM dematrix must be switched off if Panda1 is selected - Beeper off: set frequency to 0 and volume to 0; - Beeper on: set frequency to 40hex and set volume; beeper frequency not yet variable 26 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Balance Loudspeaker Channel H 7Fhex 7Ehex 74hex 73hex 72hex Left 100%, Right 99.2% 26hex 15hex 0- 14hex Left 100%, Right 0.8% Left 100%, Right muted 1000 0010 1000 0001 Balance loudspeaker channel [L/R] Left muted, Right 100% Left 0.8%, Right 100% Left 99.2%, Right 100% Left 100%, Right 100% 0001hex 0111 1111 0111 1110 0000 0001 0000 0000 RESET 1111 1111 H 7Fhex 7Ehex 01hex 00hex FFhex 82hex 81hex Volume Loudspeaker Channel Volume loudspeaker channel +12 dB +11 dB +1 dB 0 dB -1 dB -77 dB -94 dB Mute 0000hex 0111 1111 0111 1110 0111 0100 0111 0011 0111 0010 0010 0110 0001 0101 0000 0000... 0001 0100 The highest positive 8 bit number yields in a maximum possible gain of 12 dB. Decreasing the volume register by 1 LSB decreases volume by 1 dB. The minimum volume without loudness is -77 dB. Together with loudness, the volume range can be increased by the actual loudness setting. Setting loudness to 17 dB, the lowest possible volume is -94 dB. Volume settings lower than the given minimum mute the output. With large scale input signals, positive volume settings may lead to signal clipping. To prevent severe clipping effects with bass or treble boosts, the internal volume is automatically limited to a level where in combination with either bass or treble setting the amplification does not exceed 12 dB. For example: setting bass to +9 dB and treble to +5, the maximum possible volume is +3 dB. Values higher than +3 dB are internally limited to +3 dB. Please consider that even if the loudspeaker or the headphone or both channels are not used ( i.e. satellite receiver, video recorder), they must be initialized after reset according to the tables Volume Loudspeaker Channel shown above and Volume Headphone Channel on page 28. Positive balance settings reduce the left channel without affecting the right channel, negative settings reduce the right channel leaving the left channel at 100%. A step by 1 LSB decreases or increases the balance by about 0.8% (exact figure: 100/127). Bass Loudspeaker Channel Bass loudspeaker channel +12 dB +11 dB +1 dB 0 dB -1 dB -11 dB -12 dB 0002hex 0110 0000 0101 1000 0000 1000 0000 0000 RESET 1111 1000 1010 1000 1010 0000 H 60hex 58hex 08hex 00hex F8hex A8hex A0hex With positive bass settings internal overflow 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. ITT Semiconductors 27 MSP 3410 B Treble Loudspeaker Channel Treble loudspeaker channel +12 dB +11 dB +1 dB 0 dB -1 dB -11 dB -12 dB 0003hex 0110 0000 0101 1000 0000 1000 0000 0000 RESET 1111 1000 1010 1000 1010 0000 H 60hex 58hex 08hex 00hex F8hex A8hex A0hex Stereo Basewidth Enlargement (SBE) or Pseudo Stereo Effect (PSE) PRELIMINARY DATA SHEET Spatial Effects Loudspeaker Channel Spatial effect loudspeaker channel OFF 0005hex 0000 0000 RESET 0011 1111 H 00hex 3Fhex The kind of spatial effect depends on the source mode. If the incoming signal is in mono mode, Pseudo Stereo Effect is active, for stereo signals Stereo Basewidth Enlargement is effective. With positive treble settings internal overflow 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 a overall positive gain. Loudness Loudspeaker Channel Loudness loudspeaker channel +17 dB +16 dB +1 dB 0 dB 0004hex 0100 0100 0100 0000 0000 0100 0000 0000 RESET H 44hex 40hex Volume Headphone Channel Volume Headphone Channel +12 dB +11 dB +1 dB 0 dB -1 dB -77 dB 0000hex 0111 1111 0111 1111 0111 0100 0111 0011 0111 0010 0010 0110 0000 0000... 0010 0101 H 7Fhex 7Ehex 74hex 73hex 72hex 26hex 0- 25hex 04hex 00hex Mute Loudness increases the volume of low and high frequency signals while keeping the amplitude of the 1 kHz 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 a overall positive gain. Mode Loudness Normal (constant volume at 1 kHz) Super Bass (constant volume at 2 kHz) 00004hex 0000 0000 Reset 0000 0100 L 00hex 04hex Volume SCART Channel Volume SCART channel OFF 0 dB gain (digital full scale (FS) to 2 VRMS output) +6 dB gain (-6 dBFS to 2 VRMS output) 0007hex 00hex RESET 40hex H 7Fhex By means of `Mode Loudness', 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. 28 The highest positive 8 bit number yields in a maximum possible gain of 12 dB. Decreasing the volume register by 1 LSB decreases volume by 1 dB. The minimum volume is -77 dB. Lower volume settings mute the output. With large scale input signals, positive volume settings may lead to signal clipping. ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B SCART Prescale 0008hex 0009hex 000ahex 000bhex 000chex 0000 0000 RESET 0000 0001 0000 0010 0000 0011 0000 0100 0000 0101 H H H H H 00hex 01hex 02hex 03hex 04hex 05hex Maximum Volume (28 kHz deviation 1) recommended FIRbandwidth: 130 kHz) Deviation 50 kHz1) recommended FIRbandwidth: 200 kHz Deviation 75 kHz1) recommended FIRbandwidth: 200 or 280 kHz Deviation 150 kHz1) recommended FIRbandwidth: 380 kHz Maximum deviation 192 kHz1) recommended FIRbandwidth: 380 kHz Prescale for adaptive deemphasis WP1 recommended FIRbandwidth: 130 kHz Volume Prescale SCART OFF 0 dB gain (2 VRMS input to digital full scale) +14 dB gain (400 mVRMS input to digital full scale) FM Prescale Volume Prescale FM (normal FM mode) OFF 000ehex 00hex RESET 7Fhex H 000dhex 00hex RESET 19hex 7Fhex H Channel Source Modes Loudspeaker channel source Headphone channel source SCART channel source I2S channel source Quasi-peak detector source FM NICAM1) SCART SBUS12 SBUS34 I2S 1) NICAM only possible if adaptive Deemphasis = off 48hex Channel Matrix Modes (see also Table 4-1) Loudspeaker channel matrix Headphone channel matrix SCART channel matrix I2S channel matrix SOUNDA SOUNDB STEREO 0008hex 0009hex 000ahex 000bhex 0000 0000 RESET 0001 0000 0010 0000 L L L L 00hex 10hex 20hex 30hex 18hex 13hex 10hex ITT Semiconductors 29 MSP 3410 B FM Fixed Deemphasis Deemphasis FM 0011 0000 30hex 50 s 75 s 0001 0011 13hex J17 OFF PRELIMINARY DATA SHEET Volume Prescale FM (High Deviation Mode) Deviation 150 kHz1) recommended FIRbandwidth: 380 kHz Maximum deviation 384 kHz1) recommended FIRbandwidth: 500 kHz 000ehex H 000fhex 0000 0000 RESET 0000 0001 0000 0100 0011 1111 H 00hex 01hex 04hex 3Fhex FM Adaptive Deemphasis For the High Deviation Mode, the FM prescaling values can be used in the range between 13hex to 30hex. Please consider the internal reduction of 6 dB for this mode. The FIR-bandwidth should be selected to 500 kHz. 1) Given Adaptive Deemphasis FM OFF 000fhex 0000 0000 RESET 0011 1111 L 00hex 3Fhex deviations will result in internal digital full scale signals. Appropriate clipping headroom has to be set by the customer. This can be done by decreasing the listed values by a specific factor. WP1 FM Matrix Modes (see also Table 4-1) FM matrix NO MATRIX GSTEREO KSTEREO 000ehex 0000 0000 RESET 0000 0001 0000 0010 L Must be set to 'OFF' in case of NICAM or dual carrier stereo (German or Korean). If 'ON' FM fixed deemphasis must be set to 75 s and FM matrix mode must be set to 'NO MATRIX'. NICAM Prescale 00hex 01hex 02hex Volume Prescale NICAM OFF 0 dB gain 0010hex 00hex RESET 20hex 7Fhex H NO_MATRIX is used for terrestrial mono or satellite stereo sound. GSTEREO dematrixes (L+R, 2R) to (2L, 2R) and is used for German dual carrier stereo system (Standard B/G). KSTEREO dematrixes (L+R, L-R) to (2L, 2R) and is used for the Korean dual carrier stereo system (Standard M). +12 dB gain NICAM Deemphasis (not yet switchable, see note in section 12.1.) Deemphasis NICAM J17 OFF 0011hex 0000 0000 RESET 0011 1111 H 00hex 3Fhex 30 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B ACB Register (see Fig. 4-3), Definition of the SCART-Switches and DIG_CTR_OUT Pins ACB Register DFP In Selection SCART1_IN MONO_IN SCART2_IN SCART3_IN SCART1_OUT Selection SCART3_IN SCART2_IN MONO_IN DA_SCART SCART2_OUT Selection DA_SCART SCART1_IN MONO_IN DIG_CTR_OUT1 low high DIG_CTR_OUT2 low high 0013hex xxxx xxxx xxxx xxxx xx00 xx01 xx10 xx11 H RESET Beeper Frequency Lowest Frequency (16 Hz) about 1 kHz Maximum Frequency (4 kHz) 0014hex 0000 0001 0100 0000 1111 1111 L 01hex 40hex FFhex xxxx xxxx xxxx xxxx 00xx 01xx 10xx 11xx RESET A squarewave beeper can be added to the loudspeaker channel and the headphone channel. The addition point is just before the volume adjustment. Identification Mode Identification Mode 0015hex 0000 0000 RESET 0000 0001 0011 1111 L 00hex 01hex 3Fhex xx00 xxxx xx01 xxxx xx10 xxxx x0xx xxxx x1xx xxxx 0xxx xxxx 1xxx xxxx RESET Standard B/G (German Stereo) Standard M (Korean Stereo) RESET Reset of Ident-Filter RESET RESET: The RESET state is taken at the time of the first write transmission on the control bus to the audio processing part (DFP). By writing to the ACB register first, the RESET state can be redefined. Note: If "MONO_IN" is selected at the DFP_IN selection, the channel matrix mode of the corresponding output channel(s) must be set to "sound A". To shorten the response time of the identification algorithm after a program change between two FM-stereo capable programs, the reset of ident-filter can be applied. Sequence: 1. Program change 2. Reset ident-filter 3. Set identification mode back to standard B/G or M 4. Wait approx. 1 sec. 5. Read stereo detection register Beeper (Frequency not yet variable, see note in section 12.1.) Beeper Volume OFF Maximum Volume (full digital scale DFS) 0014hex 0000 0000 RESET 1111 1111 H 00hex 7Fhex 12.2. Exclusions In general, all functions can be switched independently of the others. Some exceptions exist: 1. NICAM cannot be processed simultaneously to the FM2 channel. 2. If the adaptive deemphasis is activated (Reg. 000fhex L), the NICAM channels and the identification register (0018hex H) are no longer valid. The FM fixed deemphasis (Reg. 000fhex H) must be set to 75 s and the FM matrix mode (Reg 000ehex H) must be set to `NO MATRIX'. ITT Semiconductors 31 MSP 3410 B 12.3. Summary of Readable Registers All readable registers are 16 bit wide. Transmissions via I2C bus have to take place in 16 bit words. Single data entries are 8 bit. 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. Name Stereo detection register Quasi peak readout left Quasi peak readout right DC level readout FM1 DC level readout FM2 DFP software version1) FP software version1) MSP family code MSP hardware version1) 1) PRELIMINARY DATA SHEET Address 0018hex 0019hex 001ahex 001bhex 001chex 001ehex High/Low H H&L H&L H&L H&L H L Output Range [80hex ... 7Fhex] [00hex ... 7FFFhex] [00hex ... 7FFFhex] [00hex ... 7FFFhex] [00hex ... 7FFFhex] [00hex ... FFhex] [00hex ... FFhex] [00hex ... FFhex] [00hex ... FFhex] 8 bit two's complement 16 bit binary 16 bit binary 16 bit binary 16 bit binary 001fhex H L Only for internal use. Subject to change without notice! 32 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B used for seek functions in satellite receivers and for IF FM frequencies fine tuning. For further processing, the DC content of the demodulated FM signals is suppressed. The time constant , defining the transition time of the DC Level Register, is approximately 28 ms. DFP Software Version DFP software version DFP software version number 001ehex [00hex ... FFhex] H Stereo Detection Register Stereo Detection Register Stereo Mode MONO STEREO BILINGUAL 0018hex H Reading (two's complement) near zero positive value (ideal reception: 7Fhex) negative value (ideal reception: 80hex) FP Software Version Quasi Peak Detector FP software version Quasi peak readout left Quasi peak readout right Quasi peak readout 0019hex 001ahex H+L FP software version number H+L MSP Family Code MSP Family Code The quasi peak readout register can be used to read out the quasi peak level of any input source, in order to adjust all inputs to the same normal listening level. The refresh rate is 32 kHz. The feature is based on a filter time constant: attack-time: 1.3 ms decay-time: 37 ms DC Level Register DC level readout FM1 DC level readout FM2 DC Level 001bhex 001chex H+L H+L MSP Hardware Version MSP hardware version MSP technical code number (TC)1) 1) TC27 001ehex [00hex ... FFhex] L [0hex ... 7FFFhex] values are 16 bit binary 001fhex 0000 0000 0000 1010 0000 1010 H MSP 3400 C MSP 3400 B MSP 3410 B By means of the MSP-Family Code, the control processor is able to decide whether or not NICAM-controlling should be accomplished. 001fhex [00hex ... FFhex] L [0hex ... 7FFFhex] values are 16 bit binary The DC level register measures the DC component of the incoming FM signals (FM1 and FM2). This can be denotes the version F7 ITT Semiconductors 33 MSP 3410 B 13. Specifications 13.1. Outline Dimensions 2.4 1+0.2 x 45 9 10 2 9 25 +0.25 0.711 24.2 0.1 2 1 61 60 0.457 PRELIMINARY DATA SHEET 16 x 1.27 0.1 = 20.32 0.1 1.27 0.1 1.2 x 45 2.4 1.27 0.1 15 24.2 0.1 9 26 27 25 +0.25 43 44 1.9 1.5 4.05 4.75 0.15 0.2 0.1 Fig. 13-1: 68-Pin Plastic Leaded Chip Carrier Package (PLCC68) Weight approximately 4.8 g Dimensions in mm 15 28 33 4 0.1 64 1 32 3.8 0.1 19.3 0.1 18 0.1 4.8 0.2 57.7 0.1 (1) 3.2 0.2 1.9 0.27 0.1 1.778 0.05 0.457 0.1 1 0.05 20.1 0.5 1.29 31 x 1.778 = 55.118 0.1 Fig. 13-2: 64-Pin Plastic Shrink Dual Inline Package (PSDIP64) Weight approximately 9.0 g Dimensions in mm 34 ITT Semiconductors 16 x 1.27 0.1 = 20.32 0.1 PRELIMINARY DATA SHEET MSP 3410 B S.T.B. = shorted to BAGNDI if not used DVSS: if not used, connect to DVSS X = obligatory; connect as described in circuit diagram AHVSS: connect to AHVSS Type Short Description 13.2. Pin Connections and Descriptions NC = not connected; leave vacant LV = if not used, leave vacant Pin No. PLCC 68-pin PSDIP 64-pin Connection (if not used) Pin Name 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 16 - 15 14 13 12 11 10 9 8 7 6 5 4 3 2 - 1 64 63 62 61 60 LV S_ID NC OUT SBUS ident Not connected LV LV LV LV LV X X DVSS X X LV LV DVSS DVSS S_DA_IN I2S_DA_IN I2S_DA_OUT I2S_WS I2S_CL I2C_DA I2C_CL D_CTR_IN STANDBYQ ADR_SEL D_CTR_OUT0 D_CTR_OUT1 CW_DA CW_CL NC IN IN OUT OUT OUT I/OUT IN IN IN IN OUT OUT IN IN SBUS data input I2S data input I2S data output I2S wordstrobe I2S clock I2C data I2C clock for future use Standby (low-active) Control bus address select Digital control output0 Digital control output1 Pay-TV control data Pay-TV control clock Not connected LV DVSS X X X LV AUD_CL_OUT DMA_SYNC XTAL_OUT XTAL_IN TESTIO1 ANA_IN2+ OUT IN OUT IN IN IN Audio clock output DMAC-sync: signal Crystal oscillator Crystal oscillator Test pin 1 IF input 2 (if ANA_IN1+ is used only, connect to AVSS with 50 pF Capacitor) IF common IF input 1 Analog power supply +5 V Analog ground 24 25 26 27 28 59 58 57 56 55 LV LV X X S.T.B. ANA_IN- ANA_IN1+ AVSUP AVSS MONO_IN IN IN IN Mono input ITT Semiconductors 35 MSP 3410 B PRELIMINARY DATA SHEET Pin No. PLCC 68-pin PSDIP 64-pin Connection (if not used) Pin Name Type Short Description 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 54 53 52 51 50 49 48 47 46 - 45 44 43 42 41 40 39 38 37 36 35 34 33 - 32 31 30 29 28 27 X S.T.B. S.T.B. AHVSS S.T.B. S.T.B. AHVSS S.T.B. S.T.B. AHVSS LV X X X X X X X X LV LV X LV LV AHVSS X X X LV LV X or VREFTOP SC1_IN_R SC1_IN_L ASG1 SC2_IN_R SC2_IN_L ASG2 SC3_IN_R SC3_IN_L NC BAGNDI PDMC2 PDMC1 AGNDC AHVSS CAPL_M AHVSUP CAPL_A SC1_OUT_L SC1_OUT_R VREF1 SC2_OUT_L SC2_OUT_R ASG3 C_DACS_L C_DACS_R TESTIO2 DACM_L DACM_R VREF2 IN OUT OUT OUT OUT OUT OUT IN IN IN IN IN IN Reference voltage IF A/D converter Scart input1 in, right Scart input1 in, left Analog Shield Ground1 Scart input2 in, right Scart input 2 in, left Analog Shield Ground2 Scart input3 in, right Scart input3 in, left Not connected Buffered AGNDC Capacitor to BAGNDI Capacitor to BAGNDI Analog reference voltage high voltage part Analog ground Volume capacitor MAIN Analog power supply 8.0 V Volume capacitor AUX Scart output1, left Scart output1, right Reference ground1 high voltage part Scart output 2, left Scart output 2, right Analog Shield Ground3 SCART output capacitor to ground SCART output capacitor to ground Test pin 2 Analog output MAIN, left Analog output MAIN, right Reference ground2 high voltage part 36 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Pin No. PLCC 68-pin PSDIP 64-pin Connection (if not used) Pin Name Type Short Description 59 60 61 62 63 64 65 66 67 68 26 25 24 23 22 21 20 19 18 17 LV LV X LV LV LV LV X X LV DACA_L DACA_R RESETQ N_DA N_CL FRAME S_DA_OUT DVSS DVSUP S_CL OUT OUT IN OUT OUT OUT OUT Analog output AUX, left Analog output AUX, right Power-on-reset NBUS data NBUS clock NBUS frame SBUS data output (FM/NICAM-test) Digital ground Digital power supply +5 V OUT SBUS clock ITT Semiconductors 37 MSP 3410 B 13.3. Pin Configurations S_ID NC S_DA_IN I2S_DA_IN I2S_DA_OUT I2S_WS I2S_CL I2C_DA I2C_CL S_CL DVSUP DVSS S_DA_OUT FRAME N_CL N_DA RESETQ AUD_CL_OUT PRELIMINARY DATA SHEET 1 2 3 4 5 6 7 8 9 10 11 12 64 63 62 61 60 59 58 57 56 55 54 53 DMA_SYNC XTAL_OUT XTAL_IN TESTIO1 ANA_IN2+ ANA_IN- ANA_IN1+ AVSUP AVSS MONO_IN VREFTOP SC1_IN_R SC1_IN_L ASG1 SC2_IN_R SC2_IN_L ASG2 SC3_IN_R SC3_IN_L BAGNDI PDMC2 PDMC1 AGNDC AHVSS CAPL_M AHVSUP CAPL_A SC1_OUT_L SC1_OUT_R VREF1 SC2_OUT_L SC2_OUT_R CW_CL CW_DA D_CTR_IN STANDBYQ ADR_SEL D_CTR_OUT0 D_CTR_OUT1 CW_DA CW_CL NC AUD_CL_OUT DMA_SYNC XTAL_OUT XTAL_IN TESTIO1 ANA_IN2+ ANA_IN- ANA_IN1+ AVSUP 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 9 8 7 6 5 4 3 2 1 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 DACA_R DACA_L VREF2 DACM_R DACM_L TESTIO2 C_DACS_R C_DACS_L ASG3 SC2_OUT_R SC2_OUT_L VREF1 SC1_OUT_R SC1_OUT_L CAPL_A AHVSUP CAPL_M D_CTR_OUT1 D_CTR_OUT0 ADR_SEL STANDBYQ D_CTR_IN I2C_CL I2C_DA I2S_CL I2S_WS I2S_DA_OUT I2S_DA_IN S_DA_IN S_ID S_CL DVSUP DVSS S_DA_OUT FRAME N_CL 51 50 49 48 47 46 45 44 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 MSP 3410 B MSP 3410 B 52 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 AVSS MONO_IN VREFTOP SC1_IN_R SC1_IN_L ASG1 SC2_IN_R SC2_IN_L ASG2 NC SC3_IN_L SC3_IN_R AHVSS AGNDC PDMC1 PDMC2 BAGNDI N_DA RESETQ DACA_R DACA_L VREF2 DACM_R DACM_L TESTIO2 C_DACS_R C_DACS_L Fig. 13-3: 68-pin PLCC package Fig. 13-4: 64-pin PSDIP package 38 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 13.4. Pin Circuits (pin numbers refer to PLCC68 package) VSUP P N N GND Fig. 13-5: Input Pins 3, 4 (S_DA_IN, I2S_DA_IN) Fig. 13-9: Input Pins 10, 11, 12, 15, 16, 22, and 55 (D_CTR_IN, STANDBYQ, ADR_SEL, CW_DA, CW_CL, TESTIO1, TESTIO2) GND DVSUP AVSUP AVSUP P DVSUP P 3-30 pF 500 k N Pin 18 AUD_CL_OUT N GND P GND N GND Fig. 13-6: Output Pins 1, 5, 13, 14, 64, 65, and 68 (S_ID, I2S_DA_OUT, D_CTR_OUT0/1, FRAME, S_DA_OUT, S_CL) 3-30 pF Fig. 13-10: Output Pins 18 and 20; Input Pin 21 (AUD_CL_OUT, XTALOUT; XTALIN) DVSUP P 2.5 V N GND Fig. 13-7: Output Pins 6, 7, 62, and 63 (I2S_WS, I2S_CL, N_DA, N_CL) ANAIN1+ ANAIN2+ A D Fig. 13-11: Input Pin 19 (DMA_SYNC) ANAIN- VREFTOP N GND Fig. 13-8: Input/Output Pins 8 and 9 (I2C_DA, I2C_CL) Fig. 13-12: Input Pins 23-25 and 29 (ANA_IN2+, ANA_IN-, ANA_IN1+, VREFTOP) ITT Semiconductors 39 MSP 3410 B PRELIMINARY DATA SHEET 16 K 3.75 V 40 pF 80 K Fig. 13-13: Input Pin 28 (MONO_IN) Pins 53, 54 CDACSL, R 3.75 V 300 SC1-3_INL/R 40 K Pins 40, 41 PDMC1,2 3.75 V Fig. 13-17: Output Pins 47, 48, 50, 51, 53, and 54 (SC_1/2_OUT_L/R, C_DACS_L/R) Fig. 13-14: Input Pins 30, 31, 33, 34, 36, and 37 (SC1-3_IN_L/R) AHVSUP Pin 42 125 K 3.75 V 0...1.2 mA Pin 39 Fig. 13-15: Pins 39 and 42 (BAGNDI, AGNDC) 3.3 K Fig. 13-18: Output Pins 56, 57, 59, and 60 (DACA_L/R, DACM_L/R) AHVSUP 0...2 V Fig. 13-16: Capacitor Pins 44 and 46 (CAPL_M, CAPL_A) Fig. 13-19: Input Pin 61 (RESETQ) 40 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 13.5. Electrical Characteristics 13.5.1. Absolute Maximum Ratings Symbol TA TS VSUP1 VSUP2 VSUP3 dVSUP23 PTOT Parameter Ambient Operating Temperature Storage Temperature First Supply Voltage Second Supply Voltage Third Supply Voltage Voltage between AVSUP and DVSUP Chip Power Dissipation PLCC68 without Heat Spreader PSDIP64 without Heat Spreader Input Voltage, all Digital Inputs Input Current, all Digital Pins Input Voltage, all Analog Inputs Input Voltage, all Digital Inputs Input Current, all Analog Inputs Output Current, all SCART Outputs Output Current, all Analog Outputs except SCART Outputs Output Current, other pins connected to capacitors SCn_IN_s,2) MONO_IN SCn_OUT_s2) DACp_s2) PDMCs,2) C_DACS_s,2) CAPL_p,2) AGNDC, BAGNDI - SCn_IN_s,2) MONO_IN Pin Name - - AHVSUP DVSUP AVSUP AVSUP, DVSUP AHVSUP, DVSUP, AVSUP -0.3 -20 -0.3 -0.3 -5 3), 4) 3) Min. 0 -40 -0.3 -0.3 -0.3 -0.5 Max. 70 125 9.0 6.0 6.0 0.5 Unit C C V V V V 1100 1300 VSUP2+0.3 +20 VSUP1+0.3 VSUP2+0.3 +5 3), 4) 3) mW mW V mA1) V V mA1) VIdig IIdig VIana VIdig IIana IOana IOana ICana 3) 3) 1) 2) 3) 4) positive value means current flowing into the circuit "n" means "1", "2" or "3", "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. ITT Semiconductors 41 MSP 3410 B 13.5.2. Recommended Operating Conditions (at TA = 0 to 70 C) Symbol VSUP1 VSUP2 VSUP3 VREIL VREIH tREIL VDMAIL VDMAIH tDMA RDMA VDIGIL Parameter First Supply Voltage Second Supply Voltage Third Supply Voltage RESET Input Low Voltage RESET Input High Voltage RESET Low Time after DVSUP Stable and Oscillator Startup Sync Input Low Voltage Sync Input High Voltage Sync Input Frequency Sync Input Clock High-Level Time Digital Input Low Voltage D_CTR_IN, CW_DA, CW_CL, STANDBYQ, STANDBYQ ADR_SEL, TESTIO1, TESTIO2, STANDBYQ, DVSUP 500 DMA_SYNC b) PRELIMINARY DATA SHEET Pin Name AHVSUP DVSUP AVSUP RESETQ Min. 7.6 4.75 4.75 Nom. 8.0 5.0 5.0 Max. 8.4 5.25 5.25 0.8 Unit V V V V V s 2.4 5 a) V V 18.0 kHz ns 0.8 V VDIGIH Digital Input High Voltage 2.4 V tSTBYQ1 STANDBYQ Setup Time before Turn-off of Second Supply Voltage 1 s I2C-Bus Recommendations VIMIL VIMIH fIM tI2C1 tI2C2 tI2C3 tI2C4 tI2C5 tI2C6 tI2C7 I2C-BUS Input Low Voltage I2C-BUS Input High Voltage I2C-BUS Frequency I2C START Condition Setup Time I2C STOP Condition Setup Time I2C-Clock Low Pulse Time I2C-Clock High Pulse Time I2C-Data Setup Time Before Rising Edge of Clock I2C-Data Hold Time after Falling Edge of Clock I2C-Slew Rate at I2C-Clock = 1 MHz I2C_CL, I2C_DA I2C_CL, C_DA I2C DA 3.0 I2C_CL I2C_CL, C_DA I2C DA I2C_CL 120 120 500 500 55 55 50 1.0 1.5 V V MHz ns ns ns ns ns ns V/s a) DVSUP * 300 mV 2 b) DVSUP ) 300 mV 2 42 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Symbol Parameter Pin Name Min. Nom. Max. Unit I2S-Bus Recommendations VI2SIL II2SIL VI2STRIG tI2S1 tI2S2 VI2SIDL VI2SIDH fI2SCL RI2SCL fI2SWS I2S-Data Input Low Voltage I2S-Data Input Low Current I2S-Data Input Trigger Voltage I2S-Data Input Setup Time before Rising Edge of Clock I2S-Data Input Hold Time after Falling Edge of Clock I2S-Input Low Voltage when MSP 3410 B in I2S-Slave-Mode I2S-Input High Voltage when MSP 3410 B in I2S-Slave-Mode I2S-Clock Input Frequency when MSP 3410 B in I2S-Slave-Mode I2S-Clock Input Ratio when MSP 3410 B in I2S-Slave-Mode I2S-Wordstrobe Input Frequency when MSP 3410 B in I2S-Slave-Mode I2S-Wordstrobe Input Setup Time before Rising Edge of Clock when MSP 3410 B in I2S-Slave-Mode I2S-Wordstrobe Input Hold Time after Falling Edge of Clock when MSP 3410 B in I2S-Slave-Mode SBUS-Data Input Low Voltage SBUS-Data Input Low Current SBUS-Data Input Trigger Voltage SBUS-Data Input Setup Time before Rising Edge of Clock SBUS-Data Input Hold Time after Falling Edge of Clock S_DA_IN, S_CL S_DA_IN 0.9 0.8 10 0 1.7 I2S_WS I2S_CL 0.9 32.0 I2S_CL, I2S_WS 2.4 1.024 1.1 I2S_DA_IN, I2S_CL I2S_DA_IN 0.9 0.8 20 0 0.8 1.7 0.6 3.2 1.2 V mA V ns ns V V MHz MHz kHz tI2SWS1 I2S_WS, I2S_CL 60 ns tI2SWS2 0 ns VSBUSIL ISBUSIL VSBUSTRIG tSBUS1 tSBUS2 0.6 3.2 1.2 V mA V ns ns ITT Semiconductors 43 MSP 3410 B PRELIMINARY DATA SHEET Symbol Parameter Pin Name Min. Nom. Max. Unit Crystal Recommendations for Master-Slave Applications fP fTOL DTEM RR C0 C1 Parallel Resonance Frequency at 12 pF Load Capacitance Accuracy of Adjustment Frequency Variation versus Temperature Series Resistance Shunt (Parallel) Capacitance Motional (Dynamic) Capacitance 19 -20 -20 8 6.2 24 18.432 +20 +20 25 7.0 MHz ppm ppm pF fF Load Capacitance Recommendations for Master-Slave Applications CL fCL External Load Capacitance1) Required Open Loop Clock Frequency (Tamb = 25 C) XTAL_IN, XTAL_OUT PSDIP PLCC 18.431 1.5 3.3 18.433 pF pF MHz Crystal Recommendations for FM / NICAM Applications (No Master-Slave Mode possible) fP fTOL DTEM RR C0 C1 Parallel Resonance Frequency at 12 pF Load Capacitance Accuracy of Adjustment Frequency Variation vs Temp. Series Resistance Shunt (Parallel) Capacitance Motional (Dynamic) Capacitance 15 -30 -30 8 6.2 18.432 +30 +30 25 7.0 MHz ppm ppm pF fF Load Capacitance Recommendations for FM / NICAM Applications (No Master-Slave Mode possible) CL fCL External Load Capacitance1) Required Open Loop Clock Frequency (Tamb = 25 C) XTAL_IN, XTAL_OUT PSDIP PLCC 18.4305 1.5 3.3 18.4335 pF pF MHz Amplitude Recommendation for Operation with External Clock Input VXCA External Clock Amplitude XTAL_IN 0.7 Vpp 1) 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. The higher the capacitors, the lower the clock frequency results. The nominal free running frequency should match 18.432 MHz as closely as possible. Due to different layouts of customer PCBs the matching capacitor size should be defined in the application. The suggested values are figures based on experience with various PCB layouts. 44 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Symbol Parameter Pin Name Min. Nom. Max. Unit Analog Input and Output Recommendations CAGNDC AGNDC-Filter-Capacitor Ceramic Capacitor in Parallel CPDM PDM-Capacitor between PDMCx and BAGNDI1 (Low Loss type, e.g. ceramic type1) DC-Decoupling Capacitor in front of SCART Inputs SCART Input Level Input Level, Mono Input Filter Capacitor for SCART DACs SCART Load Resistance SCART Load Capacitance Main/AUX Volume Capacitor Main/AUX Filter Capacitor CAPL_M, CAPL_A DACM_s, DACA_s2) -10% 10 1 +10% MONO_IN C_DACS_s2) SCn_OUT_s2) -10% 10 500 390 PDMC1, PDMC2, BAGNDI1 SCn_IN_s2) AGNDC -20% -20% -5% 3.3 100 470 +20% +20% +5% F nF pF CinSC VinSC VinMONO CDACS RLSC CLSC CVMA CFMA 2) -20% 330 +20% 2.0 2.0 +10% nF VRMS VRMS pF k pF F nF "n" means "1", "2" or "3", "s" means "L" or "R", "p" means "M" or "A" ITT Semiconductors 45 MSP 3410 B PRELIMINARY DATA SHEET Symbol Parameter Pin Name Min. Nom. Max. Unit Recommendations for Analog Sound IF Input Signal VIF RFMNI Analog Input Range (Complete Sound IF, 0 - 9 MHz) Ratio: NICAM Carrier/FM Carrier (unmodulated carriers)3) BG: I: Ratio: FM-Main/FM-Sub Satellite Ratio: FM1/FM2 German FM-System Ratio: Main FM Carrier/Color Carrier Ratio: Main FM Carrier/Luma Components Passband Ripple Suppression of Spectrum Above 9.0 MHz Maximum FM-Deviation normal mode high deviation mode 15 15 - 15 ANA_IN1+, ANA_IN2+, ANA_IN- ANA IN 0.14 0.8 34) Vpp -17 -20 -7 -10 7 7 - - - 0 0 dB dB dB dB RFM RFM1/FM2 RFC RFV PRIF SUPHF FMMAX - - 2 dB - apprx 192 apprx 360 dB dB dB dB kHz 3) Measuring modulated NICAM carriers, the amplitude of the highest frequency components are about 5-6 dB low- er than the unmodulated carrier. The MSP 3410 B will work down to -23 dB (BG) and -25 dB (I) respectively. 4) Under normal conditions of FM/NICAM or FM1/FM2 ratio. For signals above 1.4 Vpp, overflow of the AD 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. 46 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 13.5.3. Characteristics at TA = 0 to 70 C, fCLOCK = 18.432 MHz, TJ = Junction Temperature Symbol fCLOCK DCLOCK tJITTER VxtalDC tStartup ISUP1A Parameter Clock Input Frequency Clock High to Low Ratio Clock Jitter (Verification not provided in Production test) DC-Voltage Oscillator Oscillator Startup Time at VDD Slew-rate of 1 V/1 s First Supply Current (active) Analog Volume for Main and Aux at 0dB Analog Volume for Main and Aux at -30dB Pin Name XTAL_IN Min. Typ. 18.432 Max. Unit MHz Test Condition 45 55 50 % ps 2.5 XTAL_IN, XTAL_OUT AHVSUP 11 7.5 15.8 11.0 25.0 17.4 0.4 1.0 V ms at Tj = 27 C ISUP2A ISUP3A ISUP1S mA mA f = 18.432 MHz AHVSUP = 8 V DVSUP = 5 V AVSUP = 5 V f = 18.432 MHz DVSUP = 5 V f = 18.432 MHz AVSUP = 5 V STANDBYQ = low VSUP = 8 V load = 40 pF Imax = 0.2 mA VAPUDC - VAPUAC VAPUDC + VAPUAC NICAM-mode, PLL closed Load = 30 pF Second Supply Current (active) DVSUP 100 115 150 mA Third Supply Current (active) AVSUP 25 mA First Supply Current (standby mode) at Tj = 27 C Audio Clock Output AC Voltage Audio Clock Output DC Voltage Audio Clock Output Low Current Audio Clock Output High Current Audio Clock Output Frequency Audio Clock Output Transition Time Digital Output Low Voltage Digital Output High Voltage NBUS Output Low Voltage NBUS Output High Voltage I2C-Data Output Low Voltage I2C-Data Output High Current I2C-Data Output Hold Time after Falling Edge of Clock I2C-Data Output Setup Time before Rising Edge of Clock SBUS-Data Output Low Voltage SBUS-Data Output High Current SBUS-Clock Frequency AHVSUP 4.9 7.0 11.1 mA VAPUAC VAPUDC IAPUOL IAPUOH fAPU tAPU AUD_CL_OUT 1.2 0.4 0.6 -2 2 18432 15 Vpp VSUP1 mA mA kHz ns VDCTROL VDCTROH VNBOL VNBOH VIMOL IIMOL tIMOL1 tIMOL2 D_CTR_OUT0 D_CTR_OUT1 D CTR OUT1 4.0 N_CL, N_DA. N DA. FRAME I2C_DA 0.4 V V IDDCTR = 1 mA IDDCTR = -1 mA IDDNB = 1 mA IDDNB = -1 mA IMOL = 3 mA VIMOH = 5 V 0.4 4.0 0.4 1 V V V A ns I2C_DA, I2C_CL 15 100 ns fIM = 1 MHz DVSUP = 5 V ISBOL = 6 mA VSBOH = 5 V DVSUP = 5 V, NICAM-PLL closed VSBOL ISBOL fSB tSB1/SB2 S_CL, S_ID, S ID, S_DA_OUT S_CL 4608 0.4 1 V A kHz SBUS-Clock High/Low-Ratio 0.9 1.0 1.1 ns ITT Semiconductors 47 MSP 3410 B PRELIMINARY DATA SHEET Symbol tSB3 tSB4 tS5 tS6 VI2SOL VI2SOH fI2SCL fI2SWS tI2S1/I2s2 tI2S3 tI2S4 tI2S5 tI2S6 Parameter SBUS-Clock Setup Time before Ident End Pulse SBUS-Data Setup Time before Rising Edge of Clock SBUS-Data Stable Time SBUS-Ident End Pulse Time I2S Output Low Voltage I2S Output High Voltage I2S-Clock Output Frequency I2S-Wordstrobe Output Frequency I2S-Clock High/Low-Ratio I2S-Data Setup Time before Rising Edge of Clock I2S-Data Hold Time after Falling Edge of Clock I2S-Wordstrobe Setup Time before Rising Edge of Clock I2S-Wordstrobe Hold Time after Falling Edge of Clock Pin Name S_CL, S_ID S_CL, S_DA_OUT Min. 210 Typ. Max. Unit ns Test Condition DVSUP = 5.25 V 50 ns DVSUP = 4.75 V 120 S_ID I2S_WS, S_CL, I2S CL, I2S_DA_OUT I2S_CL I2S_WS I2S_CL I2S_CL, I2S_DA_OUT 210 0.4 4.0 1204 ns ns V V kHz DVSUP = 5.25 V DVSUP = 5.25 V II2SOL = 2 mA II2SOH = -2 mA DVSUP = 5 V, NICAM-PLL closed DVSUP = 5 V, NICAM-PLL closed 32.0 kHz 0.9 200 1.0 1.1 ns DVSUP = 4.75 V 12 I2S_CL, I2S_WS ns DVSUP = 5.25 V 100 ns DVSUP = 4.75 V 50 ns DVSUP = 5.25 V Analog Ground VAGNDC0 dVBAGNDI RoutBAGN AGNDC Open Circuit Voltage Deviation of BAGNDI1 Voltage from AGNDC Voltage BAGNDI1 Output Resistance AGNDC BAGNDI1, AGNDC BAGNDI1 3.73 -20 3.83 3.93 +20 V mV Rload 10 M 6 fsignal = 1 kHz, I = 0.1 mA Analog Input Resistance RinSC SCART Input Resistance at Tj = 27 C from TA = 0 to 70 C MONO Input Resistance at Tj = 27 C from TA = 0 to 70 C SCn_IN_s1) 26 25 MONO_IN 10.5 10 16 23 25 k k 40 56 61 k k fsignal = 1 kHz, I = 0.1 mA fsignal = 1 kHz, I = 0.05 mA RinMONO Audio Analog-to-Digital-Converter VAICL Effective Analog Input Clipping Level for Analog-to-DigitalConversion SCn_IN_s,1) MONO_IN 2.02 2.12 2.22 VRMS SCART Outputs RoutSC SCART Output Resistance at Tj = 27 C from TA = 0 to 70 C Deviation of DC-Level at SCART Output from AGNDC Voltage "s" means "L" or "R", SCn_OUT_s1) 0.215 0.21 -50 0.33 0.46 0.5 +50 k k mV fsignal = 1 kHz, I = 0.1 mA dVOUTSC 1) "n" means "1", "2" or "3", "p" means "M" or "A" 48 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Symbol ASCtoSC frSCtoSC Parameter Gain from Analog Input to SCART Output Frequency Response from Analog Input to SCART Output bandwidth: 0 to 20000 Hz Effective Signal Level at SCARTOutput during full-scale digital input signal from DSP Pin Name SCn_IN_s1) MONO_IN SCn_OUT_s1) Min. Typ. Max. Unit Test Condition fsignal = 1 kHz -1.0 0 +0.5 dB with resp. to 1 kHz -0.5 0 +0.5 dB VoutSC SCn_OUT_s1) 1.8 1.9 2.0 VRMS fsignal = 1 kHz Main and AUX Outputs RoutMA Main/AUX Output Resistance at Tj = 27 C from TA = 0 to 70 C DC-Level at Main/AUX-Output for Analog Volume at 0 dB for Analog Volume at -30 dB Effective Signal Level at Main/ AUX-Output during full-scale digital input signal from DSP for Analog Volume at 0 dB DACp_s1) 2.1 2.1 3.3 4.6 5.0 k k fsignal = 1 kHz, I = 0.1 mA VoutDCMA 1.74 - 1.94 61 2.14 - V mV VoutMA 1.23 1.37 1.51 VRMS fsignal = 1 kHz Analog Performance SNR Signal-to-Noise Ratio from Analog Input to DSP MONO_IN, SCn_IN_s1) 82 88 dB Input Level = -20 dB with resp. to VAICL, fsig=1 kHz, equally weighted 20 Hz ... 16 kHz2) Input Level = -20 dB, fsig = 1 kHz, equally weighted 20 Hz ... 20 kHz Input Level = -20 dB, fsig = 1 kHz, equally weighted 20 Hz ... 15 kHz3) Input Level = -20 dB, fsig =1 kHz, equally weighted 20 Hz ... 15 kHz3) from Analog Input to SCART Output MONO_IN, SCn_IN_s1) SCn_OUT_s1) SCn_OUT_s1) 93 96 dB from DSP to SCART Output 85 88 dB from DSP to Main/AUX-Output for Analog Volume at 0 dB for Analog Volume at -30 dB DACp_s1) 85 78 "p" means "M" or "A" 88 83 dB dB 1) 2) 3) "n" means "1", "2" or "3", "s" means "L" or "R", DSP measured at I2S-Output DSP Input at I2S-Input ITT Semiconductors 49 MSP 3410 B PRELIMINARY DATA SHEET Symbol THD Parameter Total Harmonic Distortion from Analog Input to DSP Pin Name Min. Typ. Max. Unit Test Condition MONO_IN, SCn_IN_s1) 0.05 % Input Level = -3 dBr with resp. to VAICL, fsig = 1 kHz, equally weighted 20 Hz ... 16 kHz2) Input Level = -3 dBr, fsig = 1 kHz, equally weighted 20 Hz ... 20 kHz Input Level = -3 dBr, fsig = 1 kHz, equally weighted 20 Hz ... 16 kHz3) Input Level = -3 dBr, fsig = 1 kHz, equally weighted 20 Hz ... 16 kHz3) Input Level = -3 dB, fsig = 1 kHz, unused analog inputs connected to ground by Z < 1 k equally weighted 20 Hz ... 20 kHz from Analog Input to SCART Output MONO_IN, SCn_IN_s SCn_OUT_s1) SCn_OUT_s1) 0.01 0.03 % from DSP to SCART Output 0.01 0.03 % from DSP to Main or AUX Output DACA_s, DACM_s1) 0.01 0.03 % XTALK Crosstalk attenuation - PLCC68 - PSDIP64 between left and right channel within SCART Input/Output pair (LR, RL) SCn_IN SCn_OUT1) SC1_IN or SC2_IN DSP1) SC3_IN DSP1) DSP SCn_OUT1) PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 80 80 80 80 75 75 80 70 dB dB dB dB dB dB dB dB 2) 3) between left and right channel within Main or AUX Output pair DSP DACp1) PLCC68 PSDIP64 80 75 dB dB equally weighted 20 Hz ... 16 kHz 3) 1) 2) 3) "n" means "1", "2" or "3", "s" means "L" or "R", DSP measured at I2S-Output DSP Input at I2S-Input "p" means "M" or "A" 50 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Symbol XTALK Parameter between SCART Input/Output pairs1) D = disturbing program O = observed program D: MONO/SCn_IN SCn_OUT O: MONO/SCn_IN SCn_OUT1) D: MONO/SC1/2_IN SCn_OUT O: or unsel. MONO/SCn_IN DSP1) D: SC3_IN SCn_OUT O: or unsel. MONO/SCn_IN DSP1) D: MONO/SCn_IN SC1_OUT O: DSP SC2_OUT1) D: MONO/SCn_IN SC2_OUT O: DSP SC1_OUT1) D: MONO/SCn_IN unselected O: DSP SC1_OUT1) Pin Name Min. Typ. Max. Unit Test Condition (equally weighted 20 Hz ... 20 kHz) same signal source on left and right disturbing channel, nel effect on each observed output channel PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 100 100 95 95 75 75 100 100 80 85 100 100 dB dB dB dB dB dB dB dB dB dB dB dB 2) 2) 3) 3) 3) Crosstalk between Main and AUX Output pairs DSP DACp1) PLCC68 PSDIP64 95 90 dB dB (equally weighted 20 Hz ... 16 kHz)3) same signal source on left and right disturbing channel, effect on each observed output channel (equally weighted 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 D: MONO/SCn_IN/DSP SCn_OUT O: DSP DACp1) D: MONO/SCn_IN/DSP SCn_OUT O: DSP DACp1) D: DSP DACp O: MONO/SCn_IN SCn_OUT1) D: DSP DACM O: DSP SCn_OUT1) D: DSP DACA O: DSP SCn_OUT1) 1) 2) 3) PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 PLCC68 PSDIP64 90 85 95 85 100 95 83 74 100 90 dB dB dB dB dB dB dB dB dB dB SCART output load resistance 10 k SCART output load resistance 30 k 3) "n" means "1", "2" or "3", "s" means "L" or "R", DSP measured at I2S-Output DSP Input at I2S-Input "p" means "M" or "A" ITT Semiconductors 51 MSP 3410 B PRELIMINARY DATA SHEET Symbol Parameter Pin Name Min. Typ. Max. Unit Test Condition PSRR: rejection of noise on AHVSUP at 1 kHz AGNDC BAGNDI From Analog Input to DSP AGNDC BAGNDI MONO_IN, SCn_IN_s1) MONO_IN, SCn_IN_s1) SCn_OUT_s1) SCn_OUT_s1) DACp_s1) DACp_s, SCn_OUT_s1) 70 80 80 69 dB dB dB From Analog Input to SCART Output 77 dB From DSP to SCART Output From DSP to MAIN/AUX Output S/NFM FM Input to Main/AUX/SCART Output 67 71 - dB dB dB 1 FM-carrier 5.5 MHz, 50 s, 1 kHz, 40 kHz deviation; RMS, unweighted 0 to 15 kHz; full input range S/NNICAM Signal to Noise ratio of NICAM baseband signal on Main/AUX/ SCART outputs Signal to Noise ratio of D2MAC baseband signal on Main/AUX/ SCART outputs Total Harmonic Distortion + Noise of FM demodulated signal on Main/AUX/SCART output Total Harmonic Distortion + Noise of NICAM baseband signal on Main/AUX/SCART output Total Harmonic Distortion + Noise of D2MAC baseband signal for Main/AUX/SCART output NICAM: Bit Error Rate DACp_s, SCn_OUT_s1) TBD - dB S/ND2MAC DACp_s, SCn_OUT_s1) TBD - dB THDFM DACp_s, SCn_OUT_s1) - 0.3 % 1 FM-carrier 5.5 MHz, 1 kHz, 50 s; 40 kHz deviation; full input range 2.12 kHz, Modulator input level = 0 dBref THDNICAM DACp_s, SCn_OUT_s1) - 0.01 0.1 % THDD2MAC DACp_s, SCn_OUT_s1) - 0.01 0.1 % 2.12 kHz, Modulator input level = 0 dBref BERNI RIFIN - - - 10-7 /s FM+NICAM, norm conditions Gain AGC = 20 dB Gain AGC = 3 dB VSUPANALOG = 5 V VSUPANALOG = 5 V VSUPANALOG = 5 V 1 FM-carrier, 50 s, 1 kHz 40 kHz deviation; RMS 2.12 kHz, Modulator input level = 0 dBref 2.12 kHz, Modulator input level = 0 dBref 1 FM-carrier 5.5 MHz, 50 s, Modulator input level = -14.6 dBref; RMS Input Impedance ANA_IN1+, ANA_IN2+, ANA_IN- VREFTOP ANA_IN1+, ANA_IN2+ ANA_IN- DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) 1.2 6.0 - - 2.0 9.1 2.67 1.5 3.1 13.8 - - kOhm kOhm V V DCVREFTOP DCANA_IN+ DCANA_IN- dVFMOUT dVNICAMOUT DC voltage at VREFTOP DC voltage on active IF input DC voltage on common IF input Tolerance of output voltage of FM demodulated signal Tolerance of output voltage of NICAM baseband signal Tolerance of output voltage of D2MAC baseband signal FM Frequency Response on Main/ AUX/SCART Outputs, Bandwidth 20 to 15000 Hz "s" means "L" or "R", - -1.5 1.5 - +1.5 V dB -1.5 +1.5 dB dVD2MACOUT -1.5 +1.5 dB fRFM -1.0 +1.0 dB 1) "n" means "1", "2" or "3", "p" means "M" or "A" 52 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Symbol fRNICAM Parameter NICAM Frequency Response on Main/AUX/SCART Outputs, Bandwidth 20 to 15000 Hz D2MAC Frequency Response on Main/AUX/SCART Outputs, Bandwidth 20 to 15000 Hz FM Channel Separation (Stereo) Pin Name DACp_s, SCn_OUT_s1) Min. -1.0 Typ. Max. +1.0 Unit dB Test Condition Modulator input level = -12 dB dBref; RMS fRD2MAC DACp_s, SCn_OUT_s1) -1.0 +1.0 dB Modulator input level = -12 dB dBref; RMS SEPFM DACp_s, SCn_OUT_s1) 50 dB 2 FM-carriers 5.5/5.74 MHz, 50 s, 1 kHz, 40 kHz deviation; RMS SEPNICAM SEPD2MAC XTALKFM NICAM Channel Separation (Stereo) D2MAC Channel Separation (Stereo) FM Crosstalk Attenuation (Dual) DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) 80 dB 80 dB 80 dB 2 FM-carriers 5.5/5.74 MHz, 50 s, 1 kHz, 40 kHz deviation; RMS XTALKNICAM NICAM Crosstalk Attenuation (Dual) D2MAC Crosstalk Attenuation (Dual) "s" means "L" or "R", DACp_s, SCn_OUT_s1) DACp_s, SCn_OUT_s1) 80 dB XTALKD2MAC 1) 80 dB "n" means "1", "2" or "3", "p" means "M" or "A" ITT Semiconductors 53 MSP 3410 B 14. Timing Diagrams 14.1. Power-up Sequence PRELIMINARY DATA SHEET The reset should not reach high level before the oscillator has started. This requires a reset delay of > 1 ms (see Fig.14-1). Power-On-Reset 4.75 V Power On DVSUP, AVSUP Crystal Oscillator Reset <1 ms should be >1 ms 5 s 0.8 V Fig. 14-1: Power-up sequence 14.2. I2C Bus Timing Diagram (Data: MSB first) FIM I2C_CL TI2C4 TI2C3 TI2C1 I2C_DA as input TI2C5 TI2C6 TI2C2 TIMOL2 I2C_DA as output TIMOL1 Fig. 14-2: I2C bus timing diagram 54 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 14.3. I2S Bus Timing Diagram (Data: MSB first) FI2SWS I2S_WS SONY Mode PHILIPS Mode PHILIPS/SONY Mode programmable by MODE_REG[4] I2S_CL Detail A I2S_DAIN R LSB L MSB SONY Mode PHILIPS Mode Detail C L LSB R MSB R LSB L LSB 16 bit left channel Detail B I2S_DAOUT R LSB L MSB L LSB R MSB 16 bit right channel R LSB L LSB 16 bit left channel 16 bit right channel Detail C I2S_CL FI2SCL TI2SWS1 TI2SWS2 I2S_WS as INPUT TI2S5 TI2S6 I2S_WS as OUTPUT Detail A,B I2S_CL TI2S1 TI2S2 I2S_DA_IN TI2S3 TI2S4 I2S_DA_OUT ITT Semiconductors 55 MSP 3410 B 14.4. SBUS Timing Diagram (Data: LSB first) PRELIMINARY DATA SHEET H S-Ident L H S-Clock L H S-Data L 16 Bit Sound 1 16 Bit Sound 2 16 Bit Sound 3 16 Bit Sound 4 64 Clock Cycles A Section A B Section B tS6 H S-Ident L tS1 H S-Clock 4.608 MHz L tS4 H S-Data L tS5 tS2 tS3 LSB of Sound 1 MSB of Sound 4 56 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 15. Application Circuit IF 2 IN if ANA_IN2+ not used Tuner 2 Signal GND IF 1 IN 10 F - + 3.3 100 F nF 50 pF 50 pF 50 pF + 100 nF 18.432 MHz NO TAG pF +8.0 V Tuner 1 + + 10 F 10 F XTAL_OUT (63) 20 VREFTOP (54) 29 XTAL_IN (62) 21 Ana_IN1+ (58) 25 Ana_IN2+ (60) 23 CAPL_M (40) 44 Ana_IN- (59) 24 CAPL_A (38) 46 AGNDC (42) 42 1F 1F DACM_L (29) 56 28 (55) MONO_IN 330 nF 52 (30) ASG3 DACM_R (28) 57 31 (52) SC1_IN_L 330 nF 30 (53) SC1_IN_R 330 nF AHVSS 330 nF 33 (50) SC2_IN_R 330 nF AHVSS 330 nF 36 (47) SC3_IN_R 330 nF 41 (43) PDMC1 470pF 40 (44) PDMC2 470pF SC1_OUT_L (37) 47 SC1_OUT_R (36) 48 SC2_OUT_L (34) 50 SC2_OUT_R (33) 51 D_CTR_IN (8) 10 D_CTR_OUT0 (5) 13 D_CTR_OUT1 (4) 14 N_DA (23) 62 N_CL (22) 63 CW_DA (3) 15 CW_CL (2) 16 FRAME (21) 64 AUD_CL_OUT (1) 18 DMA_SYNC (64) 19 TESTIO1 (61) 22 TESTIO2 (30) 55 61 (24) RESETQ 45 (39) AHVSUP 67 (18) DVSUP 43 (41) AHVSS 26 (57) AVSUP 49 (35) VREF1 58 (27) VREF2 C_DACS_R (31) 54 35 (48) ASG2 C_DACS_L (32) 53 37 (46) SC3_IN_L 1 nF 32 (51) ASG1 34 (49) SC2_IN_L DACA_R (25) 60 DACA_L (26) 59 1 nF 1 nF 1 nF MAIN 1F 1F HEAD PHONE 390 pF 390 pF 100 22 F 100 22 F + + MSP 3410 B 5V 5V DVSS DVSS 39 (45) BAGNDI 11 (7) STANDBY Q 12 (6) ADR_SEL 100 22 F + 100 22 F + 2 8 9 (10) I2C_DA (11) I2C_CL 2 DVSS 1 (16) S_ID 68 (17) S_CL 65 (20) S_DA_OUT 3 (15) S_DA_IN 6 (12) I2S_WS 7 (11) I2S_CL 4 (14) I2S_DA_IN 5 (13) I2S_DA_OUT 2 2 2 AVSS 66 (19) DVSS 27 (56) AVSS 100 nF ResetQ (from CCU, see fig. NO TAG 100 nF AVSS 100 nF Alternative circuit for Ana_INi+for more attenuation of video components: 22 p 50 p 5V 5V 8.0 V Ana_INi+ 1K ITT Semiconductors 57 MSP 3410 B 16. DMA Application + 5 Volt 5K S_DATA 66 S_IDENT 64 S_CLOCK 67 open PRELIMINARY DATA SHEET 9 S_DATA_IN 15 S_IDENT 8 S_CLOCK AMU 2481 DMA 2381 Software: SBS = 1 ACS = 1 ACF = 0 DCOF= 1 (addr. 204, 214) ACLK 65 S_Bus Slave_mode S_DATA_OUT 6 13 AUDIO_CLOCK 17 16 18.432 MHz 1 nF 68 S_CL 1 S_ID 3 S_DA_IN MSP 3400 C C6... MSP 3410/00 B TC15/F7 MODE_REG[0] = 1 Clock Inverter (see below) +2...3 V 18 AUD_CL_OUT 4.7 nF 19 DMA_SYNC 65 ACLK 66 S_DATA 64 S_IDENT Clock Inverter +5 V DMA 2386 To DMA 2381/86 and AMU 2481 100 nF 120 6k8 10 nF BC 848C 82 3k8 Fig. 16-1: DMA application with MSP 3410 TC15 or F7 Note: Pin numbers refer to PLCC packages for DMA 2381 and MSP3410, and to PSDIP package for AMU 2481. 58 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B MSP Clock Output Clock Inverter Output typ. 20 ns at inverter output Timing window for the low to high edge at pin 17 of DMA 2381 (XTAL2) > 10 ns < 42 ns Fig. 16-2: Timing requirements for the clock signal at the DMA 2381 clock input In the following table, the input/output clock-specification of the D2MAC circuit is shown. Table 16-1: Clock input and output specification for MSPs MSP 3400 C -C6 new Version XTAL_IN min (minimum amplitude) C input (after Reset) AUD_CL_OUT min with C load Rout (HF) typ. > 0.7 MSP 3410/00B -F7 new Version > 0.7 MSP 3410/00B TC15 actual Version > 0.7 Vpp Vpp Vpp 22 pF > 1.2 22 pF > 1.2 Vpp 40 pF 31 pF > 1.0 Vpp 43 pF Vpp 40 pF 150 120 120 Table 16-2: Clock input and output specification for ICs connected to MSP DMA 2381 XTAL_IN min Clock-in min (minimal amplitude) C input 24 pF 10 pF with: Adr. 204,14=1 For the DMA_SYNC input specification of the MSP, please refer to page 42 "VDMAIL, VDMAIH." 7pF 7pF > 0.7 DMA 2386 > 0.7 AMU2481 > 0.7 Vpp Vpp Vpp ITT Semiconductors 59 MSP 3410 B 17. I2S Bus in Master/Slave Configuration with Standby Mode In a master/slave application, both MSP, after power up and reset, will start as master by default. This means that before the slave MSP is set to slave-mode, relatively large current-pulses (~20 mA) in the I2S_CL and I2S_WS lines can cause some crackling noise during startup time, if the the MSP is demuted before the slave MSP is set to slave mode. These high current pulses are also possible, if the active I2S_CL and I2S_WS outputs of the master MSP are clipped by the correspondent inputs of the slave MSP, which is switched to standby mode. To avoid this, it is recommended, that the I2S-bus lines I2S_CL and I2S_WS are current-limited to about 5 mA with series resistors of about 390 (330...470 ). Fig. 17-1 depicts the recommended application circuit for two MSP 3410/00B or MSP 3400 C, which are connected via I2S Bus in a master/slave configuration, and where the slave MSP can be switched in standby mode (+5 Volt power is switched off). PRELIMINARY DATA SHEET Standby control +5 V 18.432 MHz 18.432 MHz 62 63 I2S_DA_IN 14 18 DVSUP 13 I2S_DA_OUT 14 I2S_DA_IN 12 I2S_WS R C 11 I2S_CL 7 STANDBYQ 62 63 MSP 3410/00B MSP 3400 C (master) I2S_DA_OUT 13 I2S_WS 12 MSP 3410/00 B MSP 3400 C (slave) I2S_CL 11 minimal corner frequency = 4 MHz with R = 390 (330-470 ) Fig. 17-1: I2S master/slave application 60 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B TC08 Hardware and software of TC04 with aluminium corrections. TC09 Satellite version based on TC06 without I2C-Bus problem and startup-problem of TC06. TC10 Projected final hardware. Software completed, but without D2MAC. TC12 1. As TC10, but without start-up problem. 2. I2S slave mode not working 3. High deviation mode switchable by `HDEV' = 1 and `FM1FM2' = 0 TC13 Emulator version for software development. TC14 Alternative I2C Device Address (84/85), new bass/treble characteristics, new carrier mute algorithm (not working properly yet), switchable AUDIO_CLOCK_OUT. TC15 New features: 1. High deviation mode ok 2. Open loop frequency of crystal oscillator is approx. 0.5 kHz higher. 3. FM-carrier mute improved 4. Various internal modifications to minimize radiation problems 5. Slightly modified loudness characteristic 6. Reset facility for identification filters 7. Beeper no longer effected by loudness 18. APPENDIX A: MSP 3410/3400 B Technical Code History TC01 First hardware release with basic software for TV sets. Date: December 1992. Missing software features: Identification, spatial effects, DC level readout, adaptive Deemphasis, D2MAC processing, full feature volume control, quasi peak detector, balance, loudness, beeper. Bug list: 1. no NICAM-synchronisation with digital test signals 2. Error in the d/a-converter; this fault is notable with full scale output signals. 3. insufficient THD quality of the Main a. Aux outputs 4. Software reset has no effect to the FP. 5. I2C-Bus: DFP-RAM-Address `6' causes troubles: The problem preliminary can be solved by means of a trick in the control program. TC02 Emulator version of TC01. TC03 Hardware as in TC01 with additional software features: Identification, spatial effects, DC level readout, adaptive Deemphasis (first release with bugs). TC04 Second hardware release with new pinning (given in this document), new I2C bus protocol and completed software for basic TV receivers. Date: June 1993. Missing features to full spec: adaptive Deemphasis, D2MAC processing. TC05 Reserved technical code for emulator version of TC04. TC06 Same hardware version as TC04 but with basic software for satellite applications (D2MAC and Wegener). Missing features: Identification, spatial effects, MQ oversampling switchable, full feature volume control, quasi peak detector, balance, loudness, bass, treble, NICAM, beeper (see diagram below). Note: TC04 and TC06 unfortunately show a number of failures. For a detailed list, together with application notes, see separate document. TC07 Emulator version for software development. ITT Semiconductors 8. Beeper gain reduced by 6 dB 9. Volume-main effects beeper in 1 dB steps 10. I2S slave mode o.k. Known restrictions: 1. I2C bus problem for multibus systems (see Appendix C). This problem was resident in all technical codes before. 2. I2C-problem concerning Time_Out_Enable: This bit should not be set and will have no function for future technical codes. 3. Mute positions for volume of loudspeaker and headphone channels are to be modified. 61 MSP 3410 B F7 1. DFP-part now controllable before having loaded any demodulator parameters. 2. switchable loudness characteristic 3. Nicam-processing: overload level increased by 6 dB 4. I2C-bus: - Time-out bit CONTROL[14] is cancelled and must be set to 0. - I2C-clock will no longer be pulled down for more than 1 ms in the non-error condition. - I2C-error condition is now indicated by NAKs after a 7 ms low period of the I2C-clock. - I2C-bus problem for multibus systems is solved. 5. Oscillator: modified crystal specs 6. Various minor changes to reduce radiation, i.e. SBUS can be switched to tristate by means of MODE_REG[11], modified clock buffer, and decoupling capacities on-chip. 7. Audio_Clock_Output AC voltage 1.0 1.2 Vpp PRELIMINARY DATA SHEET 62 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B 6251-366-6PD: Sixth preliminary release of the data sheet and data sheet "MSP 3400 Multistandard Sound Processor Preliminary" March 28, 1994, 6251-378-1PD: First preliminary release of the data sheet. Major changes: - D2MAC registers 12hex and 20hex-2fhex no longer supported. - New recommendation for FM prescale for adaptive deemphasis. - Appendix C: Documentation of known hardware restrictions. - Table 3-3: "Summary of NICAM 728 sound modulation paramters": Specification for France inserted. - Table 4-1: "Some examples for recommended channel assignments for demodulator and audio processing part": New modes inserted. 2. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.6, July 12, 1994, 6251-366-7PD: Seventh preliminary release of the data sheet and data sheet "MSP 3400 Multistandard Sound Processor Preliminary" July 12, 1994, 6251-378-2PD: Second preliminary release of the data sheet. - new volume table for loudspeaker and headphone channel - new I2C-Bus failure mode - modified crystal specs 3. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.7, Oct. 6, 1995, 6251-366-8PD: Eighth preliminary release of the data sheet and data sheet "MSP 3400 Multistandard Sound Processor Preliminary", Oct. 6 1995, 6251-378-3PD: Third preliminary release of the data sheet. - switchable loudness characteristic - oscillator: modified crystal specs - section 13.4.: pin circuits new - new circuit recommendations for MSP-DMA applications 19.3. MSP 3410 B and MSP 3400 B With this release of the data sheet, two versions are available: The MSP 3410 B and the MSP 3400 B version. 1. Data sheet "MSP 3410 B Multistandard Sound Processor Preliminary" version 0.8, Nov. 20, 1995, 6251-366-9PD: Ninth preliminary release of the data sheet and data sheet "MSP 3400 B Multistandard Sound Processor Preliminary", Nov. 20, 1995, 6251-378-4PD: Fourth preliminary release of the data sheet. Major changes: - Fig. 13-1: PLCC68 package dimensions changed - Fig. 13-2: PSDIP64 package dimensions changed - Fig. 4-3: changes have been made to improve comprehension 63 19. APPENDIX B: Documentation History 19.1. MSP 3410 1. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.0, April 1993, 6251-366-1PD: First preliminary release of the data sheet. 2. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.1, June 1993, 6251-366-2PD: Second preliminary release of the data sheet. Major changes: - definition of standby mode - definition of the DSP software features of TC04 - correction of I2C read operation - new chapter S-Bus interface - new chapter I2S-Bus interface - new definition of volume, balance, loudness and beeper control registers - some changes in the specification chapter - timing diagrams of I2C, I2S, and S-BUS - application diagram for D2MAC operations - changes in the application diagram: use of 50 pF caps for IF inputs, pins STANDBYQ, ADR_SEL and D_CTR_IN0 should not be left open. 3. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.2, September 1993, 6251-366-3PD: Third preliminary release of the data sheet. Major changes: - high deviation FM mode - compatibility restrictions regarding future Technical Codes and MSP3400 - new I2C-Bus alternative address - complemented application circuit 4. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.3, January 19, 1994, 6251-366-4PD: Fourth preliminary release of the data sheet. Major changes: - Table 10-1: Recommended channel assignments for demodulator and audio processing part 5. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.4, February 15, 1994, 6251-366-5PD: Fifth preliminary release of the data sheet. No major changes. Changes have been made to improve comprehension. 19.2. MSP 3410 and MSP 3400 With this release of the data sheet, two versions are available: The MSP 3410 and the MSP 3400 version. 1. Data sheet "MSP 3410 Multistandard Sound Processor Preliminary" version 0.5, April 12, 1994, ITT Semiconductors MSP 3410 B 20. APPENDIX C: Documentation of known hardware restrictions for TC 15 I2C-Bus PRELIMINARY DATA SHEET The I2C-Clock line must not be clocked in between two data transmissions (from last stop condition to next start condition). This may occur in multi bus I2C-systems with shared clock line (s. Figure 1), if protocol 1 is applied. As a preliminary workaround we recommend using protocol 2. Figure 1 MSP 3410 B other I2C Devices Data2 Data1 I2C_CL I2C_Data1 I2C_Data2 C Protocol 1 not working! I2C_CL Start MSP-DATA Stop Start other data Stop I2C_D1 I2C_D2 Protocol 2 suggested workaround I2C_CL Start MSP-DATA Stop Start MSP-Pseudo-Data Start other data Stop Stop I2C_D1 I2C_D2 No problem was found in multi bus I2C-systems with shared data line and multiple clock lines (s. Figure 2): Figure 2 MSP 3410 B other I2C Devices Clock2 Clock1 I2C_Data I2C_CL1 I2C_CL2 C Start MSP-DATA Stop Start other data Stop I2C_D I2C_C1 I2C_C2 64 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B CONC_CT, 22 Crystal, specs, 15 21. Index A A/D converter, 9 Absolute Maximum Ratings, 41 ACB Register, 31 AD_CV, 9, 17, 19 ADD_BITS, 22 AGC, 9, 17, 19 AM, 5, 24 Application circuit, 54, 55, 56, 57, 58 AUDIO, PLL, 15 Audio Processing Part, 26 Automatic search function, 25 D D2-MAC, 15 DC Level Register. See Readable Registers DC level register, 25 DC-offset, 20 DCO increments, 17, 21 oscillator, 9, 21 DCO, oscillator, 21 Decimation, 10 Descrambler, 15 DFP Software Version. See Readable Registers DIG_CTR_OUT Pins, 31 Digital input, 16 DMA Application, 58 DQPSK, 6 DSP Control Registers, 26 B B/G standard, 5, 24 Balance Loudspeaker Channel. See Loudspeaker Channels Bandwidth, 10 Bass Loudspeaker Channel. See Loudspeaker Channels Beeper, 31 Frequency, 31 Volume, 31 Bit error rate, 22 Bit rate, 7 E Electrical Characteristics, 41-52 Exclusions, 31 F FAW_ER_TOL, 17 FAWCT_IST, 22 FAWCT_SOLL, 17, 22 Filter channel 1/2, 9 coefficient, FIR, 20, 21 FIR_REG_1/2, 17, 21 FM Adaptive Deemphasis, 30 demodulation, 10 Fixed Deemphasis, 30 max. frequency deviation, 46 modulation, 7 stereo/mono, 5, 7, 15, 17, 23, 24 FM Matrix Modes, 30 FM Prescale, 29 FM_COEF, 20, 21 FM1/FM2, 9, 20, 24 65 C C_AD_BITS, 22 Carrier frequency, 6, 7, 9, 21 Channel Matrix Modes, 29 Source Modes, 29 Channel Matrix Modes Headphone, 29 I2S, 29 Loudspeaker, 29 SCART, 29 Characteristics, 47 CIB_BITS, 22 Clock, PLL, 15 ITT Semiconductors MSP 3410 B FMAM, 20 FP processor LOAD_REG_1/2, 17 processing start, 17 FP Software Version. See Readable Registers PRELIMINARY DATA SHEET N N-Bus, 15 NICAM, 19 additional data bits, 22 coding, 6 modes, 22 operation modes, 22 sampling frequency, 6 timing recovery, 15 Nicam, addresses, 22 NICAM Deemphasis, 30 NICAM Prescale, 30 G Gain, parameter, 19 German DUAL FM system, 5, 7, 24 I I2C Bus Timing, 54 I2S Bus Timing, 55 Identification FM, 10 NICAM, 22 Identification Mode, 31 IMREG, 20 Input level, 19 O Operation mode register, 19 Outline Dimensions, 34 P PAL, 6 Pay-TV, 15 Pilot frequency, 7 Pin Circuits, 39 Configurations, 38 Connections and Descriptions, 35 PLL, 15 Power-up Sequence, 54 Preemphasis, 6 PWM converter, 9 J J17, 30 L Loudness Loudspeaker Channel. See Loudspeaker Channels Loudspeaker Channel Balance, 27 Bass, 27 Loudness, 28 Spatial Effects, 28 Treble, 28 Volume, 27 Q Quadrature mixer, 9 Quasi Peak Detector. See Readable Registers M Mixer frequency, 21 MODE_REG, 19 Modulation frequency, 7 MSP Family Code. See Readable Registers MSP Hardware Version. See Readable Registers Multistandard, 24 Mute function, 11, 18 66 R RAM_TEST, 17 Read registers ADD_BITS, 22 C_AD_BITS, 22 CIB_BITS, 22 CONC_CT, 22 FAWCT_IST, 22 Readable Registers, 32 DC Level Register, 33 DFP Software Version, 33 ITT Semiconductors PRELIMINARY DATA SHEET MSP 3410 B Stereo Detection Register. See Readable Registers Subcarrier, 21 FP Software Version, 33 MSP Family Code, 33 MSP Hardware Version, 33 Quasi Peak Detector, 33 Stereo Detection, 33 Recommended Operating Conditions, 42 Register. See Read/Write registers Reset, 19 T Timing Pay-TV, 15 recovery, 15 Timing Diagrams, 54-57 Transmission rate, 7 Treble Loudspeaker Channel. See Loudspeaker Channels S S-Bus, 16 mode, 20 setting, 20 Sampling frequency, 6, 10 Satellite TV mode, 24 sound, 21 SBUS Timing, 56 SCART Prescale, 29 SCART Switches, 31 Search function, 25 Software flow diagram, 24 IM-Bus, 22 Sound carrier, 5 Spatial Effects Loudspeaker Channel. See Loudspeaker Channels Specifications, 34-52 Standard Detection, 25 Standards, 4, 6 V Volume Headphone Channel, 28 SCART Channel, 28 Volume Loudspeaker Channel. See Loudspeaker Channels W Write addresses, FP-jumps/routines, 17 Write register A/D-converter, AD_CV, 19 ADD_BITS, 22 AUDIO_PLL, 17 DCO1_LO/HI, 21 DCO2_LO/HI, 21 FIR_REG1/2, 21 MODE_REG, 19 ITT Semiconductors 67 MSP 3410 B PRELIMINARY DATA SHEET ITT Semiconductors Group World Headquarters INTERMETALL 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 Printed in Germany Order No. 6251-366-9PD Reprinting is generally permitted, indicating the source. However, our consent must be obtained in all cases. Information furnished by ITT is believed to be accurate and reliable. However, no responsibility is assumed by ITT for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of ITT. The information and suggestions are given without obligation and cannot give rise to any liability; they do not indicate the availability of the components mentioned. Delivery of development samples does not imply any obligation of ITT to supply larger amounts of such units to a fixed term. To this effect, only written confirmation of orders will be binding. 68 ITT Semiconductors |
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