PRELIMINARY DATA SHEET MICRONAS Edition Oct. 14, 1999 6251-475-2PD MSP 3405D, MSP 3415D Multistandard Sound Processors MICRONAS MSP 34x5D PRELIMINARY DATA SHEET Contents Page Section Title 5 5 5 5 5 1. 1.1. 1.2. 1.3. 1.4. Introduction Common Features of MSP 34x5D Specific MSP 3415D Features Unsupported MSP 34x0D Functions MSP 34x0D Inputs and Outputs not included in the MSP 34x5D 6 6 6 6 2. 2.1. 2.2. 2.3. Basic Features of the MSP 34x5D Demodulator and NICAM Decoder Section DSP-Section (Audio Baseband Processing) Analog Section 7 7 7 3. 3.1. 3.2. Application Fields of the MSP 34x5D NICAM plus FM/AM-Mono German 2-Carrier System (DUAL FM System) 10 10 10 11 11 12 12 12 12 12 12 12 13 13 13 13 13 14 14 15 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. 4.2.1. 4.2.2. 4.3. 4.3.1. 4.4. 4.5. 4.6. Architecture of the MSP 34x5D Demodulator and NICAM Decoder Section Analog Sound IF – Input Section Quadrature Mixers Low-pass Filtering Block for Mixed Sound IF Signals Phase and AM Discrimination Differentiators Low-pass Filter Block for Demodulated Signals High Deviation FM Mode FM-Carrier-Mute Function in the Dual Carrier FM Mode DQPSK-Decoder (MSP 3415D only) NICAM-Decoder (MSP 3415D only) Analog Section SCART Switching Facilities Stand-by Mode DSP-Section (Audio Baseband Processing) Dual Carrier FM Stereo/Bilingual Detection Audio PLL and Crystal Specifications Digital Control Output Pins I2S Bus Interface 16 17 18 18 18 18 18 19 5. 5.1. 5.2. 5.2.1. 5.2.2. 5.2.3. 5.2.4. 5.3. I2C Bus Interface: Device and Subaddresses Protocol Description Proposal for MSP 34x5D I2C Telegrams Symbols Write Telegrams Read Telegrams Examples Start-Up Sequence: Power-Up and I2C-Controlling 2 Micronas PRELIMINARY DATA SHEET MSP 34x5D Contents, continued Page Section Title 20 20 21 21 22 22 23 24 24 26 27 29 29 30 31 31 31 31 32 32 32 32 32 34 34 6. 6.1. 6.2. 6.3. 6.4. 6.4.1. 6.4.2. 6.5. 6.5.1. 6.5.2. 6.5.3. 6.5.4. 6.6. 6.6.1. 6.6.2. 6.6.3. 6.6.4. 6.6.5. 6.6.6. 6.6.7. 6.6.8. 6.6.9. 6.7. 6.8. 6.8.1. 34 34 34 6.8.2. 6.8.3. 6.8.4. Programming the Demodulator Section Short-Programming and General Programming of the Demodulator Part Demodulator Write Registers: Table and Addresses Demodulator Read Registers: Table and Addresses Demodulator Write Registers for Short-Programming: Functions and Values Demodulator Short-Programming AUTO_FM/AM: Automatic Switching between NICAM and FM/AM-Mono (MSP 3415D only) Demodulator Write Registers for the General Programming Mode: Functions and Values Register ‘AD_CV’ Register ‘MODE_REG’ FIR-Parameter DCO-Registers Demodulator Read Registers: Functions and Values Autodetect of Terrestrial TV-Audio Standards C_AD_BITS (MSP 3415D only) ADD_BITS [10...3] (MSP 3415D only) CIB_BITS (MSP 3415D only) ERROR_RATE (MSP 3415D only) CONC_CT (for compatibility with MSP 3410B) FAWCT_IST (for compatibility with MSP 3410B) PLL_CAPS AGC_GAIN Sequences to Transmit Parameters and to Start Processing Software Proposals for Multistandard TV-Sets Multistandard Including System B/G or I (NICAM/FM-Mono only) or SECAM L (NICAM/AM-Mono only) Multistandard Including System B/G with NICAM/FM-Mono and German DUAL FM Satellite Mode Automatic Search Function for FM-Carrier Detection 36 36 37 38 38 39 39 40 40 40 41 41 41 42 42 43 43 43 7. 7.1. 7.2. 7.3. 7.3.1. 7.3.2. 7.3.3. 7.3.4. 7.3.5. 7.3.6. 7.3.7. 7.3.8. 7.3.9. 7.3.10. 7.3.11. 7.3.12. 7.3.13. 7.3.14. Programming the DSP Section (Audio Baseband Processing) DSP Write Registers: Table and Addresses DSP Read Registers: Table and Addresses DSP Write Registers: Functions and Values Volume Loudspeaker Channel Balance Loudspeaker Channel Bass Loudspeaker Channel Treble Loudspeaker Channel Loudness Loudspeaker Channel Spatial Effects Loudspeaker Channel Volume SCART1 Channel Source Modes Channel Matrix Modes SCART Prescale FM/AM Prescale FM Matrix Modes FM Fixed Deemphasis FM Adaptive Deemphasis Micronas 3 MSP 34x5D PRELIMINARY DATA SHEET Contents, continued Page Section Title 43 43 43 43 44 44 44 44 45 45 45 45 46 46 46 46 46 7.3.15. 7.3.16. 7.3.17. 7.3.18. 7.3.19. 7.3.20. 7.3.21. 7.3.22. 7.4. 7.5. 7.5.1. 7.5.2. 7.5.3. 7.5.4. 7.5.5. 7.5.6. 7.5.7. NICAM Prescale (MSP 3415D only) NICAM Deemphasis (MSP 3415D only) I2S1 and I2S2 Prescale ACB Register Beeper Identification Mode FM DC Notch Automatic Volume Correction (AVC) Exclusions for the Audio Baseband Features DSP Read Registers: Functions and Values Stereo Detection Register Quasi-Peak Detector DC Level Register MSP Hardware Version Code MSP Major Revision Code MSP Product Code MSP ROM Version Code 47 47 49 52 55 57 57 58 62 8. 8.1. 8.2. 8.3. 8.4. 8.5. 8.5.1. 8.5.2. 8.5.3. Specifications Outline Dimensions Pin Connections and Short Descriptions Pin Configurations Pin Circuits Electrical Characteristics Absolute Maximum Ratings Recommended Operating Conditions Characteristics 66 9. Application Circuit 67 10. Appendix A: MSP 34x5D Version History 68 11. Data Sheet History 4 Micronas MSP 34x5D PRELIMINARY DATA SHEET Multistandard Sound Processor – Bass, treble, volume, loudness, and spatial effects processing Release Notes: The hardware description in this document is valid for the MSP 34x5D version A2 and following versions. Revision bars indicate significant changes to the previous edition. – Full SCART in/out matrix without restrictions – Improved FM-identification (as in MSPC) – Demodulator short programming – Autodetection for terrestrial TV-sound standards 1. Introduction – Improved carrier mute algorithm (as in MSPD) The MSP 34x5D is designed as a single-chip Multistandard Sound Processor for applications in analog and digital TV sets, video recorders, and PC-cards. As derivative versions of the MSP 34x0D, the MSP 34x5D combines all demodulator features of the MSP 34x0D with less I/O and reduced audio baseband processing. – Improved AM-demodulation (as in MSPD) The IC is produced in submicron CMOS technology, combined with high-performance digital signal processing. The MSP 34x5D is available in the following packages: PLCC68, PSDIP64, PSDIP52, PQFP80, and PMQFP44. 1.2. Specific MSP 3415D Features Note: The MSP 34x5D version has reduced control registers and less functional pins. The remaining registers are software compatible to the MSP 3410D. The pinning is compatible to the MSP 3410D. – Digital control output pins D_CTR_OUT0/1 – Reduction of necessary controlling – Less external components – All NICAM standards – Precise bit-error rate indication – Automatic switching from NICAM to FM/AM or vice versa – Improved NICAM synchronization algorithm 1.3. Unsupported MSP 34x0D Functions – Equalizer 1.1. Common Features of MSP 34x5D – Dolby Pro Logic together with DPL 351xA – Analog sound IF input 1.4. MSP 34x0D Inputs and Outputs not included in the MSP 34x5D – 2nd IF input – No external filters required – 3rd and 4th SCART input – Stereo baseband input via integrated A/D converters – 2nd SCART output – Two pairs of D/A converters – 2nd SCART DA – Two carrier FM – Headphone output – I2S Interface for version B3 and later versions – AVC: Automatic Volume Correction I2C 2 – Subwoofer output – ADR interface I2S 5 Sound IF 1 2 Loudspeaker OUT 2 SCART OUT MONO IN SCART1 IN 2 SCART2 IN 2 MSP 34x5D Fig. 1–1: Main I/O signals of the MSP 34x5D Micronas 5 MSP 34x5D PRELIMINARY DATA SHEET 2. Basic Features of the MSP 34x5D 2.3. Analog Section 2.1. Demodulator and NICAM Decoder Section – two selectable analog pairs of audio baseband inputs (= two SCART inputs) input level: ≤2 V RMS, input impedance: ≥25 kΩ The MSP 3415D is designed to simultaneously perform digital demodulation and decoding of NICAM-coded TV stereo sound, as well as demodulation of FM or AMmono TV sound. Alternatively, two carrier FM systems according to the German terrestrial specs can be processed with the MSP 34x5D. The MSP 34x5D facilitates profitable multistandard capability, offering the following advantages: – Automatic Gain Control (AGC) for analog input: input range: 0.10 – 3 Vpp – integrated A/D converter for sound IF input – all demodulation and filtering is performed on chip and is individually programmable – easy realization of all digital NICAM standards (B/G, I, L and D/K, not for MSP 3405D) – FM-demodulation of all terrestrial standards (including identification decoding) – no external filter hardware is required – only one crystal clock (18.432 MHz) is necessary – one selectable analog mono input (i.e. AM sound): input level: ≤2 V RMS, input impedance: ≥15 kΩ – two high-quality A/D converters, S/N-Ratio: ≥85 dB – 20 Hz to 20 kHz bandwidth for SCART-to-SCART-copy facilities – loudspeaker: one pair of four-fold oversampled D/A-converters output level per channel: max. 1.4 VRMS output resistance: max. 5 kΩ S/N-ratio: ≥85 dB at maximum volume max. noise voltage in mute mode: ≤10 µV (BW: 20 Hz ...16 kHz) – one pair of four-fold oversampled D/A converters supplying a pair of SCART-outputs. output level per channel: max. 2 V RMS, output resistance: max. 0.5 kΩ, S/N-Ratio: ≥85 dB (20 Hz...16 kHz) – high deviation FM-mono mode (max. deviation: approx. ±360 kHz) 2.2. DSP-Section (Audio Baseband Processing) – two digital inputs and one digital output via I2S bus for external signal processors like the DPL 351x. – flexible selection of audio sources to be processed – performance of terrestrial deemphasis systems (FM, NICAM) – digitally performed FM-identification decoding and dematrixing – digital baseband processing: volume, bass, treble, loudness, and spatial effects – simple controlling of volume, bass, treble, loudness, and spatial effects 6 Micronas MSP 34x5D PRELIMINARY DATA SHEET 3. Application Fields of the MSP 34x5D 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/AM-Mono According to the British, Scandinavian, Spanish, and French TV-standards, high-quality stereo sound is transmitted digitally. The systems allow two high-quality digital sound channels to be added to the already existing FM/AM-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. In the case of NICAM/FM (AM) mode, there are three different audio channels available: NICAM A, NICAM B, and FM/AM-mono. 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/AM-mono sound. Alternatively, an automatic NICAM-FM/AM switching may be applied. 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. More details of this standard are given in Tables 3–1 and 3–4. For D/K and M-Korea, very similar systems are used. Table 3–1: TV standards TV-System Position of Sound Carrier [MHz] Sound Modulation Color System Country B/G 5.5/5.7421875 FM-Stereo PAL Germany B/G 5.5/5.85 FM-Mono/NICAM PAL Scandinavia,Spain L 6.5/5.85 AM-Mono/NICAM SECAM-L France I 6.0/6.552 FM-Mono/NICAM PAL UK D/K 6.5 /6.2578125 D/K1 6.5/6.7421875 D/K2 6.5/5.85 D/K-NICAM FM-Stereo SECAM-East USSR M M-Korea 4.5 4.5/4.724212 FM-Mono FM-Stereo NTSC USA Korea Satellite Satellite 6.5 7.02/7.2 FM-Mono FM-Stereo PAL PAL Europe (ASTRA) Europe (ASTRA) Micronas FM-Mono/NICAM Hungary 7 MSP 34x5D PRELIMINARY DATA SHEET Table 3–2: Summary of NICAM 728 sound coding characteristics Characteristics Values Audio sampling frequency 32 kHz Number of channels 2 Initial resolution 14 bit/sample Companding characteristics near instantaneous, with compression to 10 bits/sample in 32-samples (1 ms) blocks Coding for compressed samples 2’s complement Preemphasis CCITT Recommendation J.17 (6.5 dB attenuation at 800 Hz) Audio overload level +12 dBm measured at the unity gain frequency of the preemphasis network (2 kHz) Table 3–3: Summary of NICAM 728 sound modulation parameters Specification I B/G L D/K Carrier frequency of digital sound 6.552 MHz 5.85 MHz 5.85 MHz 5.85 MHz Transmission rate 728 kBit/s Type of modulation Differentially encoded quadrature phase shift keying (DQPSK) Spectrum shaping Roll off factor Roll-off by means of Roll-off filters Carrier frequency of analog sound component 8 1.0 0.4 0.4 0.4 6.0 MHz FM mono 5.5 MHz FM mono 6.5 MHz AM mono 6.5 MHz FM mono terrestrial cable Power ratio between vision carrier and analog sound carrier 10 dB 13 dB 10 dB 16 dB 13 dB Power ratio between analog and modulated digital sound carrier 10 dB 7 dB 17 dB 11 dB Hungary Poland 12 dB 7 dB Micronas MSP 34x5D PRELIMINARY DATA SHEET Table 3–4: Key parameters for B/G, D/K, and M 2-carrier sound system Sound Carriers Carrier FM1 B/G D/K Vision/sound power difference Carrier FM2 M B/G D/K 13 dB M 20 dB Sound bandwidth 40 Hz to 15 kHz 50 µs Pre-emphasis 75 µs ±50 kHz Frequency deviation 50 µs ±25 kHz 75 µs ±50 kHz ±25 kHz Sound Signal Components Mono transmission mono Stereo transmission mono (L+R)/2 Dual sound transmission (L+R)/2 R language A (L–R)/2 language B Identification of Transmission Mode on Carrier FM2 Pilot carrier frequency in kHz 54.6875 55.0699 Type of modulation AM Modulation depth 50% Modulation frequency mono: unmodulated stereo: 117.5 Hz dual: 274.1 Hz 33 34 39 MHz 5 149.9 Hz 276.0 Hz 9 MHz According to the mixing characteristics of the Sound-IF mixer, the Sound-IF filter may be omitted. SAW Filter Sound IF Filter Sound IF Mixer Tuner Vision Demodulator Composite Video Loudspeaker Mono SCART Inputs SCART1 SCART2 1 MSP 34x5D 2 2 Micronas SCART Output 2 I 2S1 Fig. 3–1: Typical MSP 34x5D application SCART1 Dolby Pro Logic Processor DPLA I 2S2 Digital Signal Source 9 MSP 34x5D PRELIMINARY DATA SHEET 4. Architecture of the MSP 34x5D 4.1. Demodulator and NICAM Decoder Section Fig. 4–1 shows a simplified block diagram of the IC. Its architecture is split into three main functional blocks: 4.1.1. Analog Sound IF – Input Section The input pins ANA_IN1+ and ANA_IN– offer the possibility to connect sound IF (SIF) sources to the MSP 34x5D. The analog-to-digital conversion of the preselected sound IF signal is done by an A/D-converter, whose output can be used to control an analog automatic gain circuit (AGC), providing an optimal 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 optimal case, the input range of the A/D converter is completely covered by the sound IF source. Some combinations of SAW filters and 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 pin ANA_IN1+ (as shown in the application diagram) are sufficient in most cases. 1. demodulator and NICAM decoder section 2. digital signal processing (DSP) section performing audio baseband processing 3. analog section containing two A/D-converters, four D/A-converters, and SCART switching facilities. I2S_CL I2S_DA_OUT I2S_WS I2S_DA_IN1 I2S_DA_IN2 XTAL_IN I2S Interface I2S1/2L/R XTAL_OUT Audio PLL 2 I2S_L/R D_CTR_OUT0/1 Sound IF ANA_IN1+ FM1/AM Demodulator and NICAM Decoder FM2 NICAM A NICAM B IDENT Mono LOUDSPEAKER L D/A DACM_L LOUDSPEAKER R D/A DACM_R SCART1_L D/A SC1_OUT_L SCART1_R D/A SC1_OUT_R Loudspeaker DSP MONO_IN SC1_IN_L SCART1 A/D SCART L A/D SCART R SC1_IN_R SCART SC2_IN_L SCART2 SC2_IN_R SCART Switching Facilities Fig. 4–1: Architecture of the MSP 34x5D 10 Micronas MSP 34x5D PRELIMINARY DATA SHEET 4.1.3. Low-pass Filtering Block for Mixed Sound IF Signals 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 (MSP-Ch1) and FM/AM mono (MSP-Ch2) simultaneously or, alternatively, Data shaping and/or FM bandwidth limitation is performed by a linear phase Finite Impulse Response (FIRfilter). Just like the oscillators’ frequency, 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 MSP-Ch1 (NICAM or FM2) and one for MSPCh2 (FM1 = FM-mono). In section 6.5.3., several coefficient sets are proposed. – FM2 (MSP-Ch1) and FM1 (MSP-Ch2). NICAM is not possible with MSP 3405D. Two programmable registers, 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 6.2., format and values of the registers are listed. DCO1 MSP 3415D only MODE_REG[6] Oscillator FIR1 DQPSK Decoder NICAM Decoder Differentiator Mute NICAMA NICAMB Phase Mixer Lowpass Phase and AM Discrimination Lowpass FM2 Mixer IDENT VREFTOP MSP sound IF channel 1 (MSP-Ch1: FM2, NICAM) AD_CV[7:1] ANA_IN1+ AGC Amplitude Carrier Detect AD_CV[9] AD Carrier Detect MSP sound IF channel 2 (MSP-Ch2: FM1, AM) ANA_IN- Mixer Lowpass Amplitude Phase and AM Discrimination Mute Lowpass FM1/AM Differentiator Phase FRAME NICAMA DCO2 FIR2 Pins Internal signal lines (see fig. 4–5) MODE_REG[8] Oscillator Demodulator Write Registers DCO2 Fig. 4–2: Demodulator architecture of MSP 34x5D Micronas 11 MSP 34x5D 4.1.4. Phase and AM Discrimination The filtered sound IF signals are demodulated by means of the phase and amplitude discriminator block. On the output, the phase and amplitude is available for further processing. AM signals are derived from the amplitude information, whereas the phase information serves for FM and NICAM (DQPSK) demodulation. PRELIMINARY DATA SHEET 4.1.8. FM-Carrier-Mute Function in the Dual Carrier FM Mode 4.1.5. Differentiators To prevent noise effects or FM identification problems in the absence of one of the two FM carriers, the MSP 3415 D offers a carrier detection feature, which must be activated by means of AD_CV[9]. If no FM carrier is available at the MSPD channel 1, the corresponding channel FM2 is muted. If no FM carrier is available at the MSPD channel 2, the corresponding channel FM1 is muted. FM demodulation is completed by differentiating the phase information output. 4.1.9. DQPSK-Decoder (MSP 3415D only) 4.1.6. Low-pass Filter Block for Demodulated Signals 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. 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 FIR2 or 500 kHz FIR2 must be chosen for the FIR2. In relation to the normal FM-mode, the audio level of the high-deviation mode is reduced by 6 dB. The FM-prescaler should be adjusted accordingly. In high deviation FM-mode, neither FM-stereo nor FMidentification nor NICAM processing is possible simultaneously. 12 4.1.10. NICAM-Decoder (MSP 3415D only) 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. An automatic switching facility (AUTO_FM) between NICAM and FM/AM reduces the amount of CCU-instructions in case of bad NICAM reception. Micronas MSP 34x5D PRELIMINARY DATA SHEET 4.2. Analog Section 4.3. DSP-Section (Audio Baseband Processing) 4.2.1. SCART Switching Facilities All audio baseband functions are performed by digital signal processing (DSP). The DSP functions are grouped into three processing parts: input preprocessing, channel source selection, and channel postprocessing (see Fig. 4–5 and section 7.). The analog input and output sections include full matrix switching facilities, which are shown in Fig. 4–3. The switches are controlled by the ACB bits defined in the audio processing interface (see section 7. Programming the DSP Section). SCART_IN ACB[5,9,8] SC1_IN_L/R to Audio Baseband Processing (DSP_IN) SC2_IN_L/R A D SCARTL/R MONO_IN S1 ACB[6,11,10] intern. signal lines SCART_OUT 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. All input and output signals can be processed simultaneously with the exception that FM2 cannot be processed at the same time as NICAM. FM-identification and adaptive deemphasis are not possible simultaneously (if adaptive deemphasis is active, the ID-level in stereo detection register is not valid). pins SC1_OUT_L/R from Audio Baseband Processing (DSP_OUT) SCART1_L/R 4.3.1. Dual Carrier FM Stereo/Bilingual Detection D A S2 Fig. 4–3: SCART switching facilities (see 7.3.18.) Switching positions show the default configuration after power-on reset. Note: SCART_OUT is undefined after RESET! For the terrestrial dual FM carrier systems, audio information can be transmitted in three modes: mono, stereo, or bilingual. To obtain information about the current audio operation mode, the MSP 34x5D detects the socalled identification signal. Information is supplied via the Stereo Detection Register to an external CCU. 4.2.2. Stand-by Mode If the MSP 34x5D is switched off by first pulling STANDBYQ low, and then disconnecting the 5 V, but keeping the 8 V power supply (‘Stand-by’-mode), the switches S1 and S2 (see Fig. 4–3) maintain their position and function. This facilitates the copying from selected SCART-inputs to SCART-outputs in the TV-set’s standby mode. Stereo Detection Filter IDENT Level Detect AM Demodulation – Bilingual Detection Filter Stereo Detection Register Level Detect Fig. 4–4: Stereo/bilingual detection In case of power-on start or starting from stand-by, the IC switches automatically to the default configuration, shown in Fig. 4–3. This action takes place after the first I2C transmission into the DSP part. By transmitting the ACB register first, the individual default setting mode of the TV set can be defined. Micronas 13 MSP 34x5D Analog Inputs SCARTL PRELIMINARY DATA SHEET SCART Loudspeaker Channel Matrix Prescale SCARTR AVC ȍ Bass Treble Volume Loudspeaker L Balance Loudspeaker R Volume SCART1_L Loudspeaker Outputs Loudness DC level readout FM1 Beeper FM1/AM Deemphasis 50/75 µs FM /AM FM-Matrix Prescale FM2 NICAMA Deemphasis J17 Channel Souce Select DC level readout FM2 Demodulated IF Inputs NICAM Prescale NICAMB SCART1 Channel Matrix SCART Output SCART1_R Quasi peak readout L MSP 3415D only Quasi-Peak Detector Quasi peak readout R I 2S1L I 2S1 I 2S1R Prescale 2S I 2S2L I 2S2 I 2S2R Prescale I 2SL I 2S Channel Matrix Bus nputs I 2S Outputs I 2SR NICAMA Internal signal lines (see Fig. 4–2 and Fig. 4–3) Fig. 4–5: Audio Baseband Processing (DSP-Firmware) Table 4–1: Some examples for recommended channel assignments for demodulator and audio processing part Mode MSP Sound IFChannel 1 MSP Sound IFChannel 2 FMMatrix ChannelSelect Channel Matrix B/G-Stereo FM2 (5.74 MHz): R FM1 (5.5 MHz): (L+R)/2 B/G Stereo Speakers: FM Stereo B/G-Bilingual FM2 (5.74 MHz): Sound B FM1 (5.5 MHz): Sound A No Matrix Speakers: FM Speakers: Sound A H. Phone: Sound B NICAM-I-ST/ FM-mono NICAM (6.552 MHz) FM (6.0 MHz): mono No Matrix Speakers: NICAM Speakers: Stereo H. Phone: Sound A Sat-Mono not used FM (6.5 MHz): mono No Matrix Speakers: FM Sound A Sat-Stereo 7.2 MHz: R 7.02 MHz: L No Matrix Speakers: FM Stereo Sat-Bilingual 7.38 MHz: Sound C 7.02 MHz: Sound A No Matrix Speakers: FM Speakers: Sound A H. Phone: Sound B=C Sat-High Dev. Mode don’t care 6.552 MHz No Matrix Speakers: FM Speakers: Sound A H. Phone: Sound A 4.4. Audio PLL and Crystal Specifications The MSP 34x5D requires a 18.432 MHz (12 pF, parallel) crystal. The clock supply of the whole system depends on the MSP 34x5D operation mode: 1. FM-Stereo, FM-Mono: The system clock runs free on the crystal’s 18.432 MHz. 2. NICAM: 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, respectively, 32 kHz sampling rate of the NICAM transmitter. As a re14 sult, 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 (see General Crystal Recommendations on page 60). 4.5. Digital Control Output Pins The static level of two output pins of the MSP 34x5D (D_CTR_OUT0/1) is switchable between HIGH and LOW by means of the I2C-bus. This enables the controlling of external hardware controlled switches or other devices via I2C-bus (see section 7.3.18.). Micronas MSP 34x5D PRELIMINARY DATA SHEET 4.6. I2S Bus Interface The I2S bus interface consists of five pins: By means of this standardized interface, additional feature processors can be connected to the MSP 34x0D. 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 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. 1. I2S_DA_IN1, I2S_DA_IN2: For input, four channels (two channels per line, 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). The MSP 34x5D normally serves as the master on the I2S interface. Here, the clock and word strobe lines are driven by the MSP. By setting MODE_REG[3]=1, the MSP 34x5D is switched to a slave mode. Now, these lines are input to the MSP and the master clock is synchronized to 576 times the I2S_WS rate (32 kHz). NICAM operation is not possible in this mode. 4. I2S_WS: The I2S_WS word strobe line defines the left and right sample. A precise I2S timing diagram is shown in Fig. 4–6. (Data: MSB first) 1/FI2SWS I2S_WS SONY Mode PHILIPS Mode SONY Mode PHILIPS Mode PHILIPS/SONY Mode programmable by MODE_REG[4] Detail C I2S_CL Detail A I2S_DAIN R LSB L MSB L LSB R MSB R LSB L LSB 16 bit left channel 16 bit right channel Detail B I2S_DAOUT R LSB L MSB L LSB R MSB R LSB L LSB 16 bit left channel Detail C 1/FI2SCL 16 bit right channel Detail A,B I2S_CL I2S_CL TI2SWS1 TI2S1 TI2SWS2 I2S_WS as INPUT TI2S2 I2S_DA_IN TI2S5 I2S_WS as OUTPUT TI2S3 TI2S6 TI2S4 I2S_DA_OUT Fig. 4–6: I2S bus timing diagram Micronas 15 MSP 34x5D PRELIMINARY DATA SHEET 5. I2C Bus Interface: Device and Subaddresses As a slave receiver, the MSP 34x5D can be controlled via I2C bus. Access to internal memory locations is achieved by subaddressing. The demodulator and the DSP processor parts have two separate subaddressing register banks. In order to allow for more MSP 34x5D ICs to be connected to the control bus, an ADR_SEL pin has been implemented. With ADR_SEL pulled to high, low, or left open, the MSP 34x5D responds to changed device addresses. Thus, three identical devices can be selected. 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 an I2C transmission. A device address pair is defined as a write address (80, 84, or 88hex) and a read address (81, 85, or 89hex) (see Table 5–1). Writing is done by sending the device write address, followed by the subaddress byte, two address bytes, and two data bytes. Reading is done by sending the device write address, followed by the subaddress byte and two address bytes. Without sending a stop condition, reading of the addressed data is completed by sending the device read address (81, 85, or 89hex) and reading two bytes of data (see Fig. 5–1: “I2C Bus Protocol” and section 5.2. “Proposal for MSP 34x5D I2C Telegrams”). Due to the internal architecture of the MSP 34x5D the IC cannot react immediately to an I2C request. The typical response time is about 0.3 ms for the DSP processor part and 1 ms for the demodulator part if NICAM processing is active. If the receiver (MSP) can’t receive another complete byte of data until it has performed some other function; 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 1 ms. I2C bus error caused by MSP hardware problems: In case of any internal error, the MSPs wait-period is extended to 1.8 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 protocol (see section 5.2.4. on page 18) to ‘CONTROL’, the master must ignore the not acknowledge bits (NAK) of the MSP. A general timing diagram of the I2C bus is shown in Fig. 5–2 on page 18. Table 5–1: I2C Bus Device Addresses ADR_SEL Low High Left Open Mode Write Read Write Read Write Read MSP device address 80hex 81hex 84hex 85hex 88hex 89hex Table 5–2: I2C Bus Subaddresses 16 Name Binary Value Hex Value Mode Function CONTROL 0000 0000 00 W software reset TEST 0000 0001 01 W only for internal use WR_DEM 0001 0000 10 W write address demodulator RD_DEM 0001 0001 11 W read address demodulator WR_DSP 0001 0010 12 W write address DSP RD_DSP 0001 0011 13 W read address DSP Micronas MSP 34x5D PRELIMINARY DATA SHEET Table 5–3: Control Register (Subaddress: 00hex) Name Subaddress MSB 14 13..1 LSB CONTROL 00 hex 1 : RESET 0 : normal 0 0 0 5.1. Protocol Description Write to DSP or Demodulator S write device address Wait ACK sub-addr ACK addr-byte high ACK addr-byte low ACK data-byte high Read from DSP or Demodulator S write device address Wait ACK sub-addr ACK addr-byte high ACK addr-byte low ACK S read device address Wait ACK ACK data-byte low ACK ÇÇÇ ÇÇ ÇÇÇ ÇÇ ÇÇÇ ÇÇ data-byte high ACK data-byte low NAK P P Write to Control or Test Registers S write device address Wait ACK sub-addr ACK data-byte high ACK data-byte low ACK P I2C-Bus Start Condition from master I2C-Bus Stop Condition from master Acknowledge-Bit: LOW on I2C_DA from slave (= MSP, gray) 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 I2C-Clock line held low by the slave (= MSP) while interrupt is serviced (<1.8 ms) Note: S = P= ACK = NAK = Wait = I2C_DA S 1 0 P I2C_CL Fig. 5–1: I2C bus protocol Micronas (MSB first; data must be stable while clock is high) 17 MSP 34x5D PRELIMINARY DATA SHEET 1/fI2C TI2C4 I2C_CL TI2C1 TI2C5 TI2C3 TI2C6 TI2C2 I2C_DA as input Data: MSB first TI2COL2 TI2COL1 I2C_DA as output Fig. 5–2: I2C bus timing diagram 5.2. Proposal for MSP 34x5D I2C Telegrams 5.2.1. Symbols daw dar < > aa dd write device address read device address Start Condition Stop Condition Address Byte Data Byte 5.2.2. Write Telegrams <daw 00 d0 00> <daw 10 aa aa dd dd> <daw 12 aa aa dd dd> write to CONTROL register write data into demodulator write data into DSP 5.2.3. Read Telegrams <daw 11 aa aa <dar dd dd> <daw 13 aa aa <dar dd dd> read data from demodulator read data from DSP 5.2.4. Examples <80 00 80 00> <80 00 00 00> <80 12 00 08 01 20> 18 RESET MSP statically clear RESET set loudspeaker channel source to NICAM and Matrix to STEREO Micronas MSP 34x5D PRELIMINARY DATA SHEET 5.3. Start-Up Sequence: Power-Up and I2C-Controlling After power-on or RESET (see Fig. 5–3), 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 should start with the demodulator part. If required for any reason, the audio processing part can be loaded before the demodulator part. DVSUP AVSUP 4.5 V t/ms RESETQ Low-to-High Threshold 0.7 × DVSUP 0.45...0.55× DVSUP High-to-Low Threshold t/ms Reset Delay >2 ms Internal Reset High Low t/ms Power-up reset: threshold and timing Note: 0.7 × DVSUP means 3.5 Volt with DVSUP = 5.0 Volt Note: The reset should not reach high level before the oscillator has started. This requires a reset delay of >2 ms Fig. 5–3: Power-up sequence Micronas 19 MSP 34x5D PRELIMINARY DATA SHEET 6. Programming the Demodulator Section 6.1. Short-Programming and General Programming of the Demodulator Part The Demodulator Part of the MSP 34x5D can be programmed in two different modes: 1. Demodulator Short-Programming facilitates a comfortable way to set up the demodulator for many terrestrial TV-sound standards with one single I2C-Bus transmission. The coding is listed in section 6.4.1.. If a parameter doesn’t coincide with the individual programming concept, it simply can be overwritten by using the General Programming mode. Some bits of the registers AD_CV (see section 6.5.1. ) and MODE_REG (see section 6.5.2. ) are not affected by the short-programming. They must be transmitted once if their reset status does not fit. The Demodulator Short-Programming is not compatible to MSP 3410B and MSP 3400C. Autodetection for terrestrial TV standards (as part of the below Demodulator Short-Programming) provides the most comfortable way to set up the MSPD-demodulator. This feature facilitates within 0.5 s the detection and set-up of the actual TV-sound standard. Since the detected standard is readable by the control processor, the autodetection feature is mainly recommended for the primary set-up of a TV-set: after having determined once the corresponding TV-channels, their sound standards can be stored and later on programmed by the Demodulator Short-Programming (see sections 6.4.1. and 6.6.1.). 20 2. General Programming ensures the software compatibility to other MSPs. It offers a very flexible way to apply all of the MSP 34x5D demodulator facilities. All registers except 0020hex have to be written with values corresponding to the individual requirements. For satellite applications, with their many variations, this mode must be selected. All transmissions on the control bus are 16 bits wide. However, data for the demodulator part have only 8 or 12 significant bits. These data have to be inserted LSBbound and filled with zero bits into the 16-bit transmission word. 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. Micronas MSP 34x5D PRELIMINARY DATA SHEET 6.2. Demodulator Write Registers: Table and Addresses Table 6–1: Demodulator Write Registers; Subaddress: 10hex; these registers are not readable! Demodulator Write Registers Address (hex) Function Demodulator ShortProgramming 0020 Write into this register to apply Demodulator Short Programming (see section 6.4.1.). If the internal setting coincidences with the individual requirements no more of the remaining Demodulator Write Registers have to be transferred. AUTO_FM/AM 0021 Only for NICAM (MSP 3415D): Automatic switching between NICAM and FM/AM in case of bad NICAM reception (see section 6.4.2.) Write Registers necessary for General Programming Mode only AD_CV 00BB input selection, configuration of AGC, Mute Function and selection of A/D-converter, FM-Carrier-Mute on/off MODE_REG 0083 mode register FIR1 FIR2 0001 0005 filter coefficients channel 1 (6 ⋅ 8 bit) filter coefficients channel 2 (6 ⋅ 8 bit), + 3 ⋅ 8 bit offset (total 72 bit) DCO1_LO DCO1_HI 0093 009B increment channel 1 Low Part increment channel 1 High Part DCO2_LO DCO2_HI 00A3 00AB increment channel 2 Low Part increment channel 2 High Part PLL_CAPS 001F switchable PLL capacitors to tune open-loop frequency; to use only if NICAM of MODE_REG = 0 normally not of interest for the customer 6.3. Demodulator Read Registers: Table and Addresses Table 6–2: Demodulator Read Registers; Subaddress: 11hex; these registers are not writeable! Demodulator Read Registers Address (hex) Function Result of Autodetection 007E see Table 6–13 C_AD_BITS 0023 NICAM-Sync bit, NICAM-C-Bits, and three LSBs of additional data bits ADD_BITS 0038 NICAM: bit [10:3] of additional data bits CIB_BITS 003E NICAM: CIB1 and CIB2 control bits ERROR_RATE 0057 NICAM error rate, updated with 182 ms CONC_CT 0058 only to be used in MSPB compatibility mode FAWCT_IST 0025 only to be used in MSPB compatibility mode PLL_CAPS 021F Not for customer use. AGC_GAIN 021E Not for customer use. Note: All NICAM relevant registers are “0” for MSP 3405D. Micronas 21 MSP 34x5D PRELIMINARY DATA SHEET 6.4. Demodulator Write Registers for Short-Programming: Functions and Values In the following, the functions of some registers are explained and their (default) values are defined: 6.4.1. Demodulator Short-Programming Table 6–3: MSP 34x5D Demodulator Short-Programming Demodulator Short-Programming TV-Sound Standard Description Code (hex) 0020hex Internal Setting AD_CV2) (see Table 6–5) MODE_ REG2) DCO1 (MHz) DCO2 (MHz) FIR1/2 Coefficients (see Table 6–8) Identification Mode Autodetection 0001 Detects and sets one of the standards listed below, if available. Results are to be read out of the demodulator read register ”Result of Autodetection” (Section 6.6.1.) M Dual-FM 0002 AD_CV-FM M1 4.72421 4.5 B/G Dual-FM 0003 AD_CV-FM M1 5.74218 5.5 D/K1 Dual-FM 0004 AD_CV-FM M1 6.25781 6.5 D/K2 Dual-FM 0005 AD_CV-FM M1 6.74218 6.5 0006/ 0007 reserved for future Dual FM Standards Reset, then Standard M see Table 6–11: Terrestrial TVStandards Reset, then Reset Standard B/G AUTO_ FM/AM NICAM-Modes for MSP 3415D only; MSP 3405D responds with FM/AM Mono B/G-NICAM-FM 0008 AD_CV-FM M2 5.85 5.5 L-NICAM-AM 0009 AD_CV-AM M3 5.85 6.5 I-NICAM-FM 000A AD_CV-FM M2 6.552 6.0 D/K-NICAM-FM 000B AD_CV-FM M2 5.85 6.5 >000B reserved for future NICAM Standards see Table 6–11: Terrestrial TVTV Standards 1) 1) corresponds to the actual setting of AUTO_FM (Address = 0021hex) Bits of AD_CV or MODE_REG, which are not affected by the short-programming, must be transmitted separately if their reset status does not fit. 2) Note: All parameters in the DSP section (Audio Baseband Processing), except the identification mode register, are not affected by the Demodulator Short-Programming . They still have to be defined by the control processor. 22 Micronas MSP 34x5D PRELIMINARY DATA SHEET 6.4.2. AUTO_FM/AM: Automatic Switching between NICAM and FM/AM-Mono (MSP 3415D only) There are two possibilities to define the threshold deciding for NICAM or FM/AM-mono (see Table 6–4): In case of bad NICAM transmission or loss of the NICAM-carrier, the MSPD offers a comfortable mode to switch back to the FM/AM-mono signal. If automatic switching is active, the MSP internally evaluates the ERROR_RATE. All output channels which are assigned to the NICAM-source are switched back to the FM/AMmono source without any further CCU instruction, if the NICAM-carrier fails or the ERROR_RATE exceeds the definable threshold. 1. default value of the MSPD (internal threshold=700, i.e. switch to FM/AM if ERROR_RATE > 700) 2. definable by the customer (recommendable range: threshold = 50....2000, i. e. Bits [10:1] = 25...1000). Note: The auto_fm feature is only active if the NICAM-bit of MODE_REG is set. Note, that the channel matrix of the corresponding output-channels must be set according to the NICAM-mode and need not be changed in the FM/AM-fall-back case. An appropriate hysteresis algorithm avoids oscillating effects. Bit 11 of the register C_AD_BITS (Address: 0023hex) informs about the actual NICAM-FM/AM-Status (see section 6.6.2.). Table 6–4: Coding of automatic NICAM-FM/AM switching; reset status: mode 0 Mode Auto_fm [11....0] Addr. = 0021hex Selected Sound at the NICAM Channel Select Threshold Comment 0. default Bit [0] =0 Bits [11...1] = 0 always NICAM none Compatible to MSP 3410B, i.e. automatic switching is disabled 1. Bit [0] =1 Bit [11:1] = 0 NICAM or FM/AM, depending on ERROR_RATE 700 dec automatic switching with internal threshold 2. Bit [0] =1 Bit [10:1] = 25...1000 int = threshold/2 Bit [11] =0 NICAM or FM/AM, depending on ERROR_RATE set by customer automatic switching with external threshold 3. Bit [11] = [0] = 1 Bit [10...1]= 0 always FM/AM none Forced FM-mono mode, i.e. automatic switching is disabled Micronas 23 MSP 34x5D PRELIMINARY DATA SHEET 6.5. Demodulator Write Registers for the General Programming Mode: Functions and Values 6.5.1. Register ‘AD_CV’ Table 6–5: AD_CV Register; reset status: all bits are “0” AD_CV 00BBhex Set by Short-Programming Bit Meaning Settings AD_CV-FM AD_CV-AM AD_CV [0] not used must be set to 0 0 0 AD_CV [6:1] Reference level in case of Automatic Gain Control = on (see Table 6–6). Constant gain factor when Automatic Gain Control = off (see Table 6–7). 101000 100011 AD_CV [7] Determination of Automatic Gain or Constant Gain 0 = constant gain 1 = automatic gain 1 1 AD_CV [8] not used must be set to 0 not affected not affected AD_CV [9] MSP-Carrier-Mute Function (Must be switched off in High Deviation Mode) 0 = off: no mute 1 = on: mute as described in section 4.1.8. on page 12 1 0 AD_CV [15–10] not used must be set to 0 0 0 Table 6–6: Reference values for active AGC (AD_CV[7] = 1) Application Input Signal Contains AD_CV [6:1] Ref. Value AD_CV [6:1] in integer Range of Input Signal at pin ANA_IN1+ and ANA_IN2+ FM-Stereo 2 FM Carriers 101000 40 0.10 – 3 Vpp1) FM/NICAM 1 FM and 1 NICAM Carrier 101000 40 0.10 – 3 Vpp1) AM/NICAM 1 AM and 1 NICAM carrier 100011 35 0.10 – 1.4 Vpp recommended: 0.10 – 0.8Vpp NICAM only 1 NICAM Carrier only 010100 20 0.05 – 1.0 Vpp SAT 1 or more FM Carriers 100011 35 0.10 – 3 Vpp1) Terrestrial TV 1) For signals above 1.4 Vpp, the minimum gain of 3 dB is switched, and overflow of the A/D converter may result. Due to the robustness of the internal processing, the IC works up to and even more than 3 Vpp, if norm conditions of FM/NICAM or FM1/FM2 ratio are supposed. In this overflow case, a loss of FM-S/N-ratio of about 10 dB may appear. 24 Micronas MSP 34x5D PRELIMINARY DATA SHEET Table 6–7: AD_CV parameters for constant input gain (AD_CV[7]=0) Step AD_CV [6:1] Constant Gain Gain (dB) 0 000000 3.00 1 000001 3.85 2 000010 4.70 3 000011 5.55 4 000100 6.40 5 000101 7.25 6 000110 8.10 7 000111 8.95 8 001000 9.80 9 001001 10.65 10 001010 11.50 11 001011 12.35 12 001100 13.20 13 001101 14.05 14 001110 14.90 15 001111 15.75 16 010000 16.60 17 010001 17.45 18 010010 18.30 19 010011 19.15 20 010100 20.00 Input Level at pin ANA_IN1+ maximum input level: 3 Vpp (FM) or 1 Vpp (NICAM)1) maximum input level: 0.14 Vpp 1) For signals above 1.4 Vpp, the minimum gain of 3 dB is switched, and overflow of the A/D converter may result. Due to the robustness of the internal processing, the IC works up to and even more than 3 Vpp, if norm conditions of FM/NICAM or FM1/FM2 ratio are supposed. In this overflow case, a loss of FM-S/N-ratio of about 10 dB may appear. Micronas 25 MSP 34x5D PRELIMINARY DATA SHEET 6.5.2. Register ‘MODE_REG’ The register ‘MODE_REG’ contains the control bits determining the operation mode of the MSP 34x5D; Table 6–8 explains all bit positions. Table 6–8: Control word ‘MODE_REG’; reset status: all bits are “0” MODE_REG 0083hex Bit Function [0] not used [1] DCTR_TRI [2] Definition M1 M2 M3 0 : strongly recommended 0 0 0 Digital Control Outputs active / tri-state 0 : active 1 : tri-state X X X I2S_TRI I2S Outputs (I2S_CL, I2S_WS, I2S_DA_OUT) active / tri-state 0 : active 1 : tri-state X X X [3] I2S Mode1) Master / Slave Mode of the I2S Bus 0 : Master 1 : Slave X X X [4] I2S_WS Mode WS due to the Sony or Philips format 0 : Sony 1 : Philips X X X [5] not used 1 : recommended X X X [6] NICAM 1) 0 : FM 1 : Nicam 0 1 1 [7] not used 0 : strongly recommended 0 0 0 [8] FM AM Mode of MSP-Ch2 0 : FM 1 : AM 0 0 1 [9] HDEV High Deviation Mode (channel matrix must be sound A) 0 : normal 1 : high deviation mode 0 0 0 [11:10] not used 0 : strongly recommended 0 0 0 [12] MSP-Ch1 Gain see Table 6–11 0 : Gain = 6 dB 1 : Gain = 0 dB 0 0 0 [13] FIR1-Filter Coeff. Set see Table 6–11 0 : use FIR1 1 : use FIR2 1 0 0 [14] not used 0 : strongly recommended 0 0 0 [15] AM-Gain 0 : 0 dB (default. of MSPB) 1 : 12 dB (recommended) 1 1 1 1) 26 Comment Set by Short-Programming Mode of MSP-Ch1 MSP 3405D: always FM Gain for AM Demodulation In case of NICAM operation, I2S slave mode is not possible. In case of I2S slave mode, no synchronization to NICAM is allowed. X: not affected by short-programming Micronas MSP 34x5D PRELIMINARY DATA SHEET Table 6–9: Channel modes ‘MODE_REG [6, 8, 9]‘ NICAM bit[6] FM AM bit[8] HDEV bit[9] MSP-Ch1 MSP-Ch2 1 0 0 NICAM FM1 1 1 0 0 0 0 FM2 FM1 0 0 1 – High Deviation FM (undefined sound for MSP 3405D) AM 6.5.3. FIR-Parameter The following data values (see Table 6–10) are to be transferred 8 bits at a time embedded LSB-bound in a 16-bit word. The loading sequences must be obeyed. To change a coefficient set, the complete block FIR1 or FIR2 must be transmitted. Note: For compatibility with MSP 3410B, IMREG1 and IMREG2 have to be transmitted. The value for IMREG1 and IMREG2 is 004. Due to the partitioning to 8-bit units, the values 04hex, 40hex, and 00hex arise. Table 6–10: Loading sequence for FIR-coefficients FIR1 0001hex (MSP-Ch1: NICAM/FM2) No. Symbol Name Bits 1 NICAM/FM2_Coeff. (5) 8 2 NICAM/FM2_Coeff. (4) 8 3 NICAM/FM2_Coeff. (3) 8 4 NICAM/FM2_Coeff. (2) 8 5 NICAM/FM2_Coeff. (1) 8 6 NICAM/FM2_Coeff. (0) 8 Value see Table 6–11 6 11 FIR2 0005hex (MSP-Ch2: FM1/AM ) No. Symbol Name Bits Value 1 IMREG1 8 04hex 2 IMREG1 / IMREG2 8 40hex 3 IMREG2 8 00hex 4 FM/AM_Coef (5) 8 5 FM/AM_Coef (4) 8 6 FM/AM_Coef (3) 8 7 FM/AM_Coef (2) 8 8 FM/AM_Coef (1) 8 9 FM/AM_Coef (0) 8 6 11 see Table 6–11 Micronas 27 MSP 34x5D PRELIMINARY DATA SHEET Table 6–11: 8-bit FIR-coefficients (decimal integer) for MSP 34x5D; reset status: all coefficients are “0” Coefficients for FIR1 0001hex and FIR2 0005hex FM - Satellite FIR filter corresponds to a bandpass with a bandwidth of B = 130 to 500 kHz Terrestrial TV-Standards B fc B/G-, D/KNICAM-FM Coef(i) FIR1 FIR2 INICAM-FM FIR1 FIR2 LNICAM-AM frequency B/G-,D/K-, M-Dual FM 130 kHz 180 kHz 200 kHz 280 kHz 380 kHz 500 kHz Autosearch FIR2 FIR2 FIR2 FIR2 FIR2 FIR2 FIR1 FIR2 FIR2 FIR2 0 –2 3 2 3 –2 –4 3 73 9 3 –8 –1 –1 –1 1 –8 18 4 18 –8 –12 18 53 18 18 –8 –9 –1 –1 2 –10 27 –6 27 –10 –9 27 64 28 27 4 –16 –8 –8 3 10 48 –4 48 10 23 48 119 47 48 36 5 2 2 4 50 66 40 66 50 79 66 101 55 66 78 65 59 59 5 86 72 94 72 86 126 72 127 64 72 107 123 126 126 MODEREG[12] 0 0 0 0 1 1 1 1 1 1 0 MODEREG[13] 0 0 0 1 1 1 1 1 1 1 0 For compatibility, except for the FIR2-AM and the autosearch sets, the FIR-filter programming as used for the MSP 3410B is also possible. 28 Micronas MSP 34x5D PRELIMINARY DATA SHEET 6.6. Demodulator Read Registers: Functions and Values 6.5.4. DCO-Registers For a chosen TV standard, a corresponding set of 24-bit registers determining the mixing frequencies of the quadrature mixers, has to be written into the IC. In Table 6–12, some examples of DCO registers are listed. It is necessary to divide them up into low part and high part. The formula for the calculation of the registers for any chosen IF-Frequency is as follows: INCRdec = int ( f / fs ⋅ 224) with: int f fS = integer function = IF-frequency in MHz = 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 register values (DCO1_HI or _LO for MSP-Ch1, DCO2_HI or LO for MSP-Ch2). All registers except C_AD_BITs are 8 bit wide. They can be read out of the RAM of the MSP 34x5D. All transmissions take place in 16-bit words. The valid 8 bit data are the 8 LSBs of the received data word. To enable appropriate switching of the channel select matrix of the baseband processing part, the NICAM or FM-identification parameters must be read and evaluated by the CCU. The FM-identification registers are described in section 7.2. To handle the NICAM-sound and to observe the NICAM-quality, at least the registers C_AD_BITS and ERROR_RATE must be read and evaluated by the CCU. Additional data bits and CIB bits, if supplied by the NICAM transmitter, can be obtained by reading the registers ADD_BITS and CIB_BITS. Observing the presence and quality of NICAM can be delegated to the MSP 34x5D, if the automatic switching feature (AUTO_FM, section 6.4.2.) is applied. Table 6–12: DCO registers for the MSP 34x5D; reset status: DCO_HI/LO = ”0000” DCO1_LO 0093hex, DCO1_HI 009Bhex; DCO2_LO 00A3hex, DCO2_HI 00ABhex Freq. [MHz] DCO_HIhex DCO_LOhex Freq. [MHz] DCO_HIhex DCO_LOhex 4.5 03E8 000 5.04 5.5 5.58 5.7421875 0460 04C6 04D8 04FC 0000 038E 0000 00AA 5.76 5.85 5.94 0500 0514 0528 0000 0000 0000 6.0 6.2 6.5 6.552 0535 0561 05A4 05B0 0555 0C71 071C 0000 6.6 6.65 6.8 05BA 05C5 05E7 0AAA 0C71 01C7 7.02 0618 0000 7.2 0640 0000 7.38 0668 0000 7.56 0690 0000 Micronas 29 MSP 34x5D PRELIMINARY DATA SHEET 6.6.1. Autodetect of Terrestrial TV-Audio Standards By means of autodetect, the MSP 34x5D offers a simple and fast (<0.5 s) facility to detect the actual TV-audio standard. The algorithm checks for the FM-mono and NICAM carriers of all common TV-Sound Standards. The following notes must be considered when applying the autodetect feature: 1. Since there is no way to distinguish between AM and FM-carrier, a carrier detected at 6.5 MHz is interpreted as an AM-carrier. If video detection results in SECAM-East, the MSPD result “9” of autodetect must be reinterpreted as “Bhex” in case of CAD_BITS[0] = 1, or as “4” or “5” by using the demodulator short programming mode. A simple decision can be made between the two D/K FM-stereo standards by setting D/K1 and D/K2 using the short programming mode and checking the identification of both versions (see Table 6–13). 2. During active autodetect, I2C-transfers are not recommended except for reading the autodetect result. Under no circumstances should the following parameters: Prescale FM/AM, FM Matrix, Deemphasis FM, Quasi-Peak Detector Source, and Quasi-Peak Detector Matrix be written. Results exceeding 07FFhex indicate an active autodetect. 3. The results are to be understood as static information, i.e. no evaluation of FM or NICAM identification concerning the dynamic mode (stereo, bilingual, or mono) are done. 4. Before switching to autodetect, the audio processing part should be muted. Do not forget to demute after having received the result. Table 6–13: Result of Autodetection Result of Autodetect 007Ehex Code (Data) hex Detected TV-Sound Standard Note: After detection the detected standard is set automatically according to Table 6–3. >07FF autodetect still active 0000 no TV Sound Standard was detected; select sound standard manually 0002 M Dual-FM, even if only FM1 is available 0003 B/G Dual-FM, even if only FM1 is available 0008 B/G-FM-NICAM, only if NICAM is available (MSP 3415D only) L_AM-NICAM, whenever a 6.5 MHz carrier is detected, even if NICAM is not available. If also D/K might be possible a decision has to be made according to the video-mode: Video = SECAM_EAST 0009 CAD_BITS[0] = 0 Video = SECAM_L → no more activities necessary To be set by means of the short programming mode: D/K1 or D/K2 see section 6.6.1. 000A CAD_BITS[0] = 1 D/K-NICAM (standard 000Bhex) I-FM-NICAM, even if NICAM is not available Note: Similar as for the Demodulator Short-Programming, the Autodetection does not affect most of the parameters of the DSP section (Audio Baseband Processing): The following exceptions are to be considered: – identification mode: Autodetection resets and sets the corresponding identification mode. – Prescale FM/AM and FM matrix and Deemphasis FM are undefined after Autodetection. 30 Micronas MSP 34x5D PRELIMINARY DATA SHEET 6.6.2. C_AD_BITS (MSP 3415D only) 6.6.3. ADD_BITS [10...3] (MSP 3415D only) NICAM operation mode control bits and A[2...0] of the additional data bits. Contains the remaining 8 of the 11 additional data bits. The additional data bits are not yet defined by the NICAM 728 system. Format: MSB C_AD_BITS 0023hex LSB 11 ... 7 6 5 4 3 2 1 0 Auto _FM ... A[2] A[1] A[0] C4 C3 C2 C1 S Important: “S” = Bit [0] indicates correct NICAM-synchronization (S=1). If S = 0, the MSP 34x5D has not yet synchronized correctly to frame and sequence, or has lost synchronization. The remaining read registers are therefore not valid. The MSP 34x5D mutes the NICAM output automatically and tries to synchronize again as long as MODE_REG[6] is set. The operation mode is coded by C4-C1 as shown in Table 6–14. Format: MSB ADD_BITS 0038hex LSB 7 6 5 4 3 2 1 0 A[10] A[9] A[8] A[7] A[6] A[5] A[4] A[3] 6.6.4. CIB_BITS (MSP 3415D only) Cib bits 1 and 2 (see NICAM 728 specifications) Format: MSB CIB_BITS 003Ehex LSB 7 6 5 4 3 2 1 0 x x x x x x CIB1 CIB2 Table 6–14: NICAM operation modes as defined by the EBU NICAM 728 specification Operation Mode 6.6.5. ERROR_RATE (MSP 3415D only) C4 C3 C2 C1 0 0 0 0 Stereo sound (NICAMA/B), independent mono sound (FM1) 0 0 0 1 Two independent mono signals (NICAMA, FM1) 0 0 1 0 Three independent mono channels (NICAMA, NICAMB, FM1) 0 0 1 1 Data transmission only; no audio 1 0 0 0 Stereo sound (NICAMA/B), FM1 carries same channel 1 0 0 1 One mono signal (NICAMA). FM1 carries same channel as NICAMA The bit error rate per second (BER) can be calculated by means of the following formula: 1 0 1 0 Two independent mono channels (NICAMA, NICAMB). FM1 carries same channel as NICAMA BER = ERROR_RATE * 12.3*10–6 /s 1 0 1 1 Data transmission only; no audio x 1 x x Unimplemented sound coding option (not yet defined by EBU NICAM 728 specification) AUTO_FM: monitor bit for the AUTO_FM Status: 0: NICAM source is NICAM 1: NICAM source is FM Micronas Average error rate of the NICAM reception in a time interval of 182 ms, which should be close to 0.. The initial and maximum value of ERROR_RATE is 2047. This value is also active, if the NICAM bit of MODE_REG is not set. Since the value is achieved by filtering, a certain transition time (appr. 0.5 sec) is unavoidable. Acceptable audio may have error_rates up to a value of 700int. Individual evaluation of this value by the CCU and an appropriate threshold may define the fallback mode from NICAM to FM/AM-mono in case of poor NICAM reception. If the automatic switching feature (AUTO_FM; section 6.4.2. on page 23) is applied, reading of ERROR_RATE can be omitted. ERROR_RATE 0057hex Error free 0000hex maximum error rate 07FFhex 31 MSP 34x5D PRELIMINARY DATA SHEET 6.6.6. CONC_CT (for compatibility with MSP 3410B) This register contains the actual number of bit errors of the previous 728-bit data frame. Evaluation of CONC_CT is no longer recommended. 6.6.7. FAWCT_IST (for compatibility with MSP3410B) For compatibility with MSP 3410B this value equals 12 as long as NICAM quality is sufficient. It decreases to 0 if NICAM reception gets poor. Evaluation of FAWCT_IST is no longer recommended. 6.7. 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 6–15. The data are immediately active after transmission into the MSP. It is no longer necessary to transmit LOAD_REG_1/2 or LOAD_REG_1 as it was for MSP 3410B. Nevertheless, transmission of LOAD_REG_1/2 or LOAD_REG_1 does no harm. For NICAM operation, the following steps listed in ‘NICAM_WAIT, _READ and _Check’ in Table 6–15 must be taken. 6.6.8. PLL_CAPS It is possible to read out the actual setting of the PLL_CAPS. In standard applications, this register is not of interest for the customer. PLL_CAPS 0021Fhex minimum frequency 0111 1111 7Fhex nominal frequency 0101 0110 RESET 56hex maximum frequency 0000 0000 00hex For FM-stereo operation, the evaluation of the identification signal must be performed. For a positive identification check, the MSP 34x5D sound channels have to be switched corresponding to the detected operation mode. 6.6.9. AGC_GAIN It is possible to read out the actual setting of AGC_GAIN in Automatic Gain Mode. In standard applications, this register is not of interest for the customer. 32 AGC_GAIN 0021Ehex max. amplification (20 dB) 0001 0100 14hex min. amplification (3 dB) 0000 0000 00hex Micronas MSP 34x5D PRELIMINARY DATA SHEET Table 6–15: Sequences to initialize and start the MSP 34x5D LOAD_SEQ_1/2: General Initialization General Programming Mode Demodulator Short Programming Write into MSP 34x5D: Write into MSP 34x5D: 1. AD_CV 2. FIR1 3. FIR2 4. MODE_REG 5. DCO1_LO 6. DCO1_HI 7. DCO2_LO 8. DCO2_HI For example: Addr: 0020hex, Data 0008hex Alternatively, for terrestrial reception, the autodetect feature can be applied. AUDIO PROCESSING INIT Initialization of Audio Baseband Processing section, which may be customer dependant (see section 7.). NICAM_WAIT: Automatic Start of the NICAM-Decoder if Bit[6] of MODE_REG is set to 1 1. Wait at least 0.25 s NICAM_CHECK: Read NICAM specific information and check for presence, operation mode, and quality of NICAM signal. DO NOT read and DO NOT evaluate Stereo Detection register. Read out of MSP 34x5D (For MSP 3405D, all NICAM read registers contain “0”): 1. C_AD_BITS 2. CONC_CT or ERROR_RATE; if AUTO_FM is active, reading of CONC_CT or ERROR_RATE can be omitted. Evaluation of C_AD_BITS and CONC_CT or ERROR_RATE in the CCU (see section 6.6.). If necessary, switch the corresponding sound channels within the audio baseband processing section. FM_WAIT: Automatic start of the FM-identification process if Bit[6] of MODE_REG is set to 0. 1. Ident Reset 2. Wait at least 0.5 s FM_IDENT_CHECK: Read Stereo Detection register and check for operation mode of dual carrier FM. DO NOT read and DO NOT evaluate NICAM specific information. Read out of MSP 34x5D: 1. Stereo Detection register (DSP register 0018hex, high part) Evaluation of the Stereo Detection register (see section 7.5.1.) If necessary, switch the corresponding sound channels within the audio baseband processing section. LOAD_SEQ_1: Reinitialization of Channel 1 without affecting Channel 2 Write into MSP 34x5D: 1. FIR1 2. MODE_REG 3. DCO1_LO 4. DCO1_HI Write into MSP 34x5D: (6 ⋅ 8 bit) (12 bit) (12 bit) For example: Addr: 0020hex, Data: 0003hex PAUSE: Duration of “Pause” determines the repetition rate of the NICAM or the FM_IDENT-check. Micronas 33 MSP 34x5D PRELIMINARY DATA SHEET 6.8. Software Proposals for Multistandard TV-Sets To familiarize the reader with the programming scheme of the MSP 34x5D demodulator part, three examples in the shape of flow diagrams are shown in the following sections. 6.8.2. Multistandard Including System B/G with NICAM/FM-Mono and German DUAL FM Fig. 6–3 shows a flow diagram for the CCU software, applied for the MSP 34x5D in a TV set, which supports all standards according to System B/G. For the instructions used in the diagram, please refer to Table 6–15. 6.8.1. Multistandard Including System B/G or I (NICAM/FM-Mono only) or SECAM L (NICAM/AM-Mono only) After having switched on the TV-set and having initialized the MSP 34x5D (LOAD_SEQ_1/2), FM-mono sound is available. Fig. 6–1 shows a flow diagram for the CCU software, applied for the MSP 34x5D in a TV set, which facilitates NICAM and FM/AM-mono sound. For the instructions, please refer to Table 6–15. Fig. 6–3 shows that to check for any stereo or bilingual audio information, the sound standards 0008hex (B/GNICAM) and 0003hex must simply be set alternately. If successful, the MSP 3415D must switch to the desired audio mode. If the program is changed, resulting in another program within the same TV-sound system, no parameters of the MSP 34x5D need be modified. To facilitate the check for NICAM, the CCU has only to continue at the ’NICAM_WAIT’ instruction. During the NICAM-identification process, the MSP 34x5D must be switched to the FM-mono sound. 6.8.3. Satellite Mode Fig. 6–2 shows the simple flow diagram to be used for the MSP 34x5D in a satellite receiver. For FM-mono operation, the corresponding FM carrier should preferably be processed at the MSP-channel 2. START START LOAD_SEQ_1/2 MSP-Channel 1 FM2-Parameter Set Sound Standard 0008hex MSP-Channel 2 FM1-Parameter Alternatively: 0009hex 000Ahex Audio Processing Init Audio Processing Init STOP NICAM_WAIT Fig. 6–2: CCU software flow diagram: SAT-mode 6.8.4. Automatic Search Function for FM-Carrier Detection Pause NICAM_CHECK Fig. 6–1: CCU software flow diagram for NICAM/FM or AM mono with Demodulator Short Programming The AM demodulation ability of the MSP 34x5D 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 make automatic FM carrier search possible. Therefore, the MSPD has to be switched to AM-mode (MODE_REG[8]), FM-Prescale must be set to 7Fhex = +127dec, and the FM DC notch must be switched off. The sound-IF frequency range must now be “scanned” in the MSPD-channel 2 by means of the programmable quadrature mixer with an appropriate incremental frequency (i.e. 10 kHz). 34 Micronas MSP 34x5D PRELIMINARY DATA SHEET START LOAD_SEQ_1/2 Set Sound Standard 0008hex Audio Processing Init NICAM_WAIT Pause Yes NICAM_CHECK NICAM ? No After each incrementation, a field strength value is available at the quasi-peak detector output (quasi-peak detector source must be set to FM), which must be examined for relative maxima by the CCU. This results in either continuing search or switching the MSP 34x5D back to FM demodulation mode. During the search process, the FIR2 must be loaded with the coefficient set “AUTOSEARCH”, which enables small bandwidth, resulting in appropriate field strength characteristics. The absolute field strength value (can be read out of “quasi peak detector output FM1”) also gives information on whether a main FM carrier or a subcarrier was detected, and as a practical consequence, the FM bandwidth (FIR1/2) and the deemphasis (50 µs or adaptive) can be switched automatically. Due to the fact that a constant demodulation frequency offset of a few kHz, leads to a DC-level in the demodulated signal, further fine tuning of the found carrier can be achieved by evaluating the “DC Level Readout FM1”. Therefore, the FM DC Notch must be switched on, and the demodulator part must be switched back to FM-demodulation mode. LOAD_SEQ_1 Set Sound Standard 0003hex FM_WAIT Pause Stereo/Biling. FM_ IDENT_CHECK For a detailed description of the automatic search function, please refer to the corresponding MSP 3400C Windows software. Note: The automatic search is still possible by evaluating only the DC Level Readout FM1 (DC Notch On) as it is described with the MSP 3410B, but the above mentioned method is faster. If this DC Level method is applied with the MSP 34x5D, it is recommended to set MODE_REG[15] to 1 (AM-Gain= 12 dB) and to use the new Autosearch FIR2 coefficient set as given in Table 6–11. Mono LOAD_SEQ_1 Set Sound Standard 0008hex Fig. 6–3: CCU software flow diagram: standard B/G with NICAM or FM stereo with Demodulator Short Programming Mode Micronas 35 MSP 34x5D PRELIMINARY DATA SHEET 7. Programming the DSP Section (Audio Baseband Processing) 7.1. DSP Write Registers: Table and Addresses Table 7–1: DSP Write Registers; Subaddress: 12hex; if necessary these registers are readable as well. DSP Write Register Address High/ Low Adjustable Range, Operational Modes Reset Mode Volume loudspeaker channel 0000hex H [+12 dB ... –114 dB, MUTE] MUTE L 1/8 dB Steps, Reduce Volume / Tone Control 00hex H [0..100 / 100 % and vv][–127..0 / 0 dB and vv] 100%/100% L [Linear mode / logarithmic mode] linear mode Volume / Mode loudspeaker channel Balance loudspeaker channel [L/R] 0001hex Balance Mode loudspeaker Bass loudspeaker channel 0002hex H [+12 dB ... –12 dB] 0 dB Treble loudspeaker channel 0003hex H [+12 dB ... –12 dB] 0 dB Loudness loudspeaker channel 0004hex H [0 dB ... +17 dB] 0 dB L [NORMAL, SUPER_BASS] NORMAL H [–100%...OFF...+100%] OFF L [SBE, SBE+PSE] SBE+PSE H [00hex ... 7Fhex],[+12 dB ... –114 dB, MUTE] 00hex L [Linear mode / logarithmic mode] linear mode H [FM/AM, NICAM, SCART, I2S1, I2S2] FM/AM L [SOUNDA, SOUNDB, STEREO, MONO] SOUNDA H [FM/AM, NICAM, SCART, I2S1, I2S2] FM/AM L [SOUNDA, SOUNDB, STEREO, MONO] SOUNDA Loudness Filter Characteristic Spatial effect strength loudspeaker ch. 0005hex Spatial effect mode/customize Volume SCART1 channel 0007hex Volume / Mode SCART1 channel Loudspeaker channel source 0008hex Loudspeaker channel matrix SCART1 channel source 000Ahex SCART1 channel matrix I2S channel source 000Bhex I2S1, I2S2] H [FM/AM, NICAM, SCART, FM/AM L [SOUNDA, SOUNDB, STEREO, MONO] SOUNDA H [FM/AM, NICAM, SCART, I2S1, I2S2] FM /AM L [SOUNDA, SOUNDB, STEREO, MONO] SOUNDA ÉÉÉÉÉÉÉÉÉÉÉÉ ÉÉÉÉ ÉÉÉ ÉÉÉÉÉÉÉÉÉÉÉÉÉÉ ÉÉÉÉÉÉ ÉÉÉÉÉÉÉÉÉÉÉÉ ÉÉÉÉ ÉÉÉ ÉÉÉÉÉÉÉÉÉÉÉÉÉÉ ÉÉÉÉÉÉ ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ ÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉÉ I2S channel matrix Quasi-peak detector source 000Chex Quasi-peak detector matrix Prescale SCART 000Dhex H [00hex ... 7Fhex] 00hex Prescale FM/AM 000Ehex H [00hex ... 7Fhex] 00hex L [NO_MAT, GSTEREO, KSTEREO] NO_MAT H [OFF, 50 µs, 75 µs, J17] 50 µs L [OFF, WP1] OFF FM matrix Deemphasis FM 000Fhex Adaptive Deemphasis FM Prescale NICAM (MSP 3415D only) 0010hex H [00hex ... 7Fhex] 00hex Prescale I2S2 0012hex H [00hex ... 7Fhex] 10hex ACB Register (SCART Switching Facilities) 0013hex H/L Bits [15..0] 00hex Beeper 0014hex H/L [00hex ... 7Fhex]/[00hex ... 7Fhex] 0/0 Identification Mode 0015hex L [B/G, M] B/G Prescale I2S1 0016hex H [00hex ... 7Fhex] 10hex FM DC Notch 0017hex L [ON, OFF] ON Automatic Volume Correction 0029hex H [off, on, decay time] OFF 36 Micronas MSP 34x5D PRELIMINARY DATA SHEET 7.2. DSP Read Registers: Table and Addresses Table 7–2: DSP Read Registers; Subaddress: 13hex; these registers are not writable DSP Read Register Address High/Low Output Range Stereo detection register 0018hex H [80hex ... 7Fhex] 8 bit two’s complement Quasi peak readout left 0019hex H&L [00hex ... 7FFFhex] 16 bit two’s complement Quasi peak readout right 001Ahex H&L [00hex ... 7FFFhex] 16 bit two’s complement DC level readout FM1/Ch2-L 001Bhex H&L [8000hex ... 7FFFhex] 16 bit two’s complement DC level readout FM2/Ch1-R 001Chex H&L [8000hex ... 7FFFhex] 16 bit two’s complement MSP hardware version code 001Ehex H [00hex ... FFhex] MSP major revision code 001Ehex L [00hex ... FFhex] MSP product code 001Fhex H [05hex , 0Fhex] MSP ROM version code 001Fhex L [00hex ... FFhex] Micronas 37 MSP 34x5D PRELIMINARY DATA SHEET 7.3. DSP Write Registers: Functions and Values Write registers are 16 bit wide, whereby the MSB is denoted bit [15]. Transmissions via I2C bus have to take place in 16-bit words. Some of the defined 16-bit words are divided into low [7..0] and high [15..8] byte, or in an other manner, thus holding two different control entities. All write registers are readable. Unused parts of the 16-bit registers must be zero. Addresses not given in this table must not be written at any time! 7.3.1. Volume Loudspeaker Channel Volume Loudspeaker 0000hex [15..4] +12 dB 0111 1111 0000 7F0hex +11.875 dB 0111 1110 1110 7EEhex +0.125 dB 0111 0011 0010 732hex 0 dB 0111 0011 0000 730hex –0.125 dB 0111 0010 1110 –113.875 dB 0000 0001 0010 012hex –114 dB 0000 0001 0000 010hex Mute 0000 0000 0000 000hex RESET Fast Mute 1111 1111 1110 72Ehex FFEhex Clipping Mode Loudspeaker 0000hex [3..0] Reduce Volume 0000 RESET 0hex Reduce Tone Control 0001 1hex Compromise Mode 0010 2hex If the clipping mode is set to “Reduce Volume”, the following clipping procedure is used: 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. If the clipping mode is “Reduce Tone Control”, the bass or treble value is reduced if amplification exceeds 12 dB. If the clipping mode is “Compromise Mode”, the bass or treble value and volume are reduced half and half if amplification exceeds 12 dB. Example: Vol.: +6 dB Bass: +9 dB Treble: +5 dB Red. Volume 3 9 5 Red. Tone Con. 6 6 5 Compromise 4.5 7.5 5 The highest given positive 8-bit number (7Fhex) yields in a maximum possible gain of 12 dB. Decreasing the volume register by 1 LSB decreases the volume by 1 dB. Volume settings lower than the given minimum mute the output. With large scale input signals, positive volume settings may lead to signal clipping. The MSP 34x5D loudspeaker volume function is divided up in a digital and an analog section. With Fast Mute, volume is reduced to mute position by digital volume only. Analog volume is not changed. This reduces any audible DC plops. Going back from Fast Mute should be done to the volume step before Fast Mute was activated. The Fast Mute facility is activated by the I2C command. After 75 ms (typically), the signal is completely ramped down. 38 Micronas MSP 34x5D PRELIMINARY DATA SHEET 7.3.2. Balance Loudspeaker Channel 7.3.3. Bass Loudspeaker Channel Positive balance settings reduce the left channel without affecting the right channel; negative settings reduce the right channel leaving the left channel unaffected. In linear mode, a step by 1 LSB decreases or increases the balance by about 0.8% (exact figure: 100/127). In logarithmic mode, a step by 1 LSB decreases or increases the balance by 1 dB. Balance Mode Loudspeaker 0001hex [3..0] linear 0000 RESET 0hex logarithmic 0001 1hex Linear Mode Bass Loudspeaker 0002hex H +20 dB 0111 1111 7Fhex +18 dB 0111 1000 78hex +16 dB 0111 0000 70hex +14 dB 0110 1000 68hex +12 dB 0110 0000 60hex +11 dB 0101 1000 58hex +1 dB 0000 1000 08hex +1/8 dB 0000 0001 01hex 0 dB 0000 0000 RESET 00hex Balance Loudspeaker Channel [L/R] 0001hex H –1/8 dB 1111 1111 FFhex Left muted, Right 100% 0111 1111 7Fhex –1 dB 1111 1000 F8hex Left 0.8%, Right 100% 0111 1110 7Ehex –11 dB 1010 1000 A8hex Left 99.2%, Right 100% 0000 0001 01hex –12 dB 1010 0000 A0hex Left 100%, Right 100% 0000 0000 RESET 00hex Left 100%, Right 99.2% 1111 1111 FFhex Left 100%, Right 0.8% 1000 0010 82hex Left 100%, Right muted 1000 0001 81hex 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. Logarithmic Mode Balance Loudspeaker Channel [L/R] 0001hex H Left –127 dB, Right 0 dB 0111 1111 7Fhex Left –126 dB, Right 0 dB 0111 1110 7Ehex Left –1 dB, Right 0 dB 0000 0001 01hex Left 0 dB, Right 0 dB 0000 0000 RESET 00hex Left 0 dB, Right –1 dB 1111 1111 FFhex Left 0 dB, Right –127 dB 1000 0001 81hex Left 0 dB, Right –128 dB 1000 0000 80hex Micronas 39 MSP 34x5D PRELIMINARY DATA SHEET to set loudness to a value that, in conjunction with volume, would result in an overall positive gain. 7.3.4. Treble Loudspeaker Channel Treble Loudspeaker 0003hex H +15 dB 0111 1000 78hex +14 dB 0111 0000 70hex +1 dB 0000 1000 08hex +1/8 dB 0000 0001 01hex 0 dB 0000 0000 RESET 00hex –1/8 dB 1111 1111 FFhex –1 dB 1111 1000 F8hex –11 dB 1010 1000 A8hex –12 dB 1010 0000 A0hex 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 an overall positive gain. 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. 7.3.6. Spatial Effects Loudspeaker Channel Spatial Effect Strength Loudspeaker 0005hex H Enlargement 100% 0111 1111 7Fhex Enlargement 50% 0011 1111 3Fhex Enlargement 1.5% 0000 0001 01hex Effect off 0000 0000 RESET 00hex Reduction 1.5% 1111 1111 FFhex Reduction 50% 1100 0000 C0hex Reduction 100% 1000 0000 80hex Spatial Effect Mode Loudspeaker 0005hex [7:4] Stereo Basewidth Enlargement (SBE) and Pseudo Stereo Effect (PSE). (Mode A) 0000 RESET 0000 0hex Stereo Basewidth Enlargement (SBE) only. (Mode B) 0010 2hex Spatial Effect Customize Coefficient Loudspeaker 0005hex [3:0] 7.3.5. Loudness Loudspeaker Channel Loudness Loudspeaker 0004hex H +17 dB 0100 0100 44hex +16 dB 0100 0000 40hex +1 dB 0000 0100 04hex 0 dB 0000 0000 RESET 00hex Mode Loudness Loudspeaker 0004hex L Normal (constant volume at 1 kHz) 0000 0000 RESET 00hex max high pass gain 0000 RESET 0hex Super Bass (constant volume at 2 kHz) 0000 0100 04hex 2/3 high pass gain 0010 2hex 1/3 high pass gain 0100 4hex min high pass gain 0110 6hex automatic 1000 8hex 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 40 0hex Micronas MSP 34x5D PRELIMINARY DATA SHEET There are several spatial effect modes available: Mode A (low byte = 00hex) is compatible to the formerly used spatial effect. Here, 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, Pseudo Stereo Effect and Stereo Basewidth Enlargement is effective. The strength of the effect is controllable by the upper byte. A negative value reduces the stereo image. A rather strong spatial effect is recommended for small TV sets where loudspeaker spacing is rather close. For large screen TV sets, a more moderate spatial effect is recommended. In mode A, even in case of stereo input signals, Pseudo Stereo Effect is active, which reduces the center image. In Mode B, only Stereo Basewidth Enlargement is effective. For mono input signals, the Pseudo Stereo Effect has to be switched on. It is worth mentioning, that all spatial effects affect amplitude and phase response. With the lower 4 bits, the frequency response can be customized. A value of 0000bin yields a flat response for center signals (L = R) but a high pass function of L or R only signals. A value of 0110bin has a flat response for L or R only signals but a lowpass function for center signals. By using 1000bin, the frequency response is automatically adapted to the sound material by choosing an optimal high pass gain. Logarithmic Mode Volume SCART1 0007hex [15..4] +12 dB 0111 1111 0000 7F0hex +11.875 dB 0111 1110 1110 7EEhex +0.125 dB 0111 0011 0010 732hex 0 dB 0111 0011 0000 730hex –0.125 dB 0111 0010 1110 –113.875 dB 0000 0001 0010 012hex –114 dB 0000 0001 0000 010hex Mute 0000 0000 0000 000hex RESET 7.3.8. Channel Source Modes Loudspeaker Source 0008hex H SCART1 Source 000Ahex H I2S Source 000Bhex H Quasi-Peak Detector Source 000Chex H FM/AM 0000 0000 RESET 00hex NICAM (MSP 3415D only) 0000 0001 01hex SCART 0000 0010 02hex I2S1 0000 0101 05hex I2S2 0000 0110 06hex 7.3.7. Volume SCART1 Volume Mode SCART1 0007hex [3..0] linear 0000 RESET 0hex 0001 1hex logarithmic 72Ehex 7.3.9. Channel Matrix Modes Linear Mode Volume SCART1 0007hex H OFF 0000 0000 RESET 00hex 0 dB gain (digital full scale (FS) to 2 VRMS output) 0100 0000 40hex +6 dB gain (–6 dBFS to 2 VRMS output) 0111 1111 Micronas 7Fhex Loudspeaker Matrix 0008hex L SCART1 Matrix 000Ahex L I2S Matrix 000Bhex L Quasi-Peak Detector Matrix 000Chex L SOUNDA / LEFT / MSP-IF-CHANNEL2 0000 0000 RESET 00hex SOUNDB / RIGHT / MSP-IF-CHANNEL1 0001 0000 10hex STEREO 0010 0000 20hex MONO 0011 0000 30hex 41 MSP 34x5D PRELIMINARY DATA SHEET 7.3.11. FM/AM Prescale 7.3.10. SCART Prescale Volume Prescale SCART 000Dhex H Volume Prescale FM (Normal FM Mode) 000Ehex H OFF 0000 0000 RESET 00hex OFF 0000 0000 RESET 00hex 0 dB gain (2 VRMS input to digital full scale) 0001 1001 19hex 0111 1111 7Fhex +14 dB gain (400 mVRMS input to digital full scale) 0111 1111 7Fhex Maximum Volume (28 kHz deviation 1) recommended FIRbandwidth: 130 kHz) Deviation 50 kHz1) recommended FIRbandwidth: 200 kHz 0100 1000 48hex Deviation 75 kHz1) recommended FIRbandwidth: 200 or 280 kHz 0011 0000 30hex Deviation 150 kHz1) recommended FIRbandwidth: 380 kHz 0001 1000 1) Given 18hex 0001 0011 13hex 2) In the mentioned SIF-level range, the AM-output level Maximum deviation 192 kHz1) recommended FIRbandwidth: 380 kHz Prescale for adaptive deemphasis WP1 recommended FIRbandwidth: 130 kHz 0001 0000 10hex Volume Prescale FM (High Dev.- Mode) 000Ehex H OFF 0000 0000 RESET 00hex Deviation 150 kHz1) recommended FIRbandwidth: 380 kHz 0011 0000 30hex Maximum deviation 384 kHz1) recommended FIRbandwidth: 500 kHz 0001 0100 14hex Volume Prescale AM 000Ehex H OFF 0000 0000 RESET 00hex 0111 1100 7Chex <7Chex Comments for the FM/AM-Prescaling: For the High Deviation Mode, the FM prescaling values can be used in the range from 13hex to 30hex. Please consider the internal reduction of 6 dB for this mode. The FIR-bandwidth should be selected to 500 kHz. 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. remains stable and independent of the actual SIF-level. In this case, only the AM degree of audio signals above 40 Hz determines the AM-output level. SIF input level: 0.1 Vpp – 0.8 Vpp 1) 2) 0.8 Vpp – 1.4 Vpp 1) Note: For AM, the bit MODE_REG[15] must be 1. 42 Micronas MSP 34x5D PRELIMINARY DATA SHEET 7.3.17. I2S1 and I2S2 Prescale 7.3.12. FM Matrix Modes FM Matrix 000Ehex L Prescale I2S1 0016hex H NO MATRIX 0000 0000 RESET 00hex Prescale I2S2 0012hex H OFF 0000 0000 GSTEREO 0000 0001 01hex 00hex 0 dB gain KSTEREO 0000 0010 02hex 0001 0000 RESET 10hex +18 dB gain 0111 1111 7Fhex NO_MATRIX is used for terrestrial mono or satellite stereo sound. GSTEREO dematrixes [(L+R)/2, R] to [L, R] and is used for German dual carrier stereo system (Standard B/G). KSTEREO dematrixes [(L+R)/2, (L–R)/2] to [L, R] and is used for the Korean dual carrier stereo system (Standard M). 7.3.18. ACB Register (see Fig. 4–3); [15:14] = 0 ! Definition of Digital Control Output Pins 7.3.13. FM Fixed Deemphasis Deemphasis FM 000Fhex H 50 µs 0000 0000 RESET 00hex 75 µs 0000 0001 01hex J17 0000 0100 04hex OFF 0011 1111 3Fhex ACB Register 0013hex D_CTR_OUT0 low (RESET) high x0 x1 D_CTR_OUT1 low (RESET) high 0x 1x [15..14] Definition of SCART Switching Facilities 7.3.14. FM Adaptive Deemphasis FM Adaptive Deemphasis WP1 000Fhex L OFF 0000 0000 RESET 00hex WP1 0011 1111 3Fhex 7.3.15. NICAM Prescale (MSP 3415D only) Volume Prescale NICAM 0010hex H OFF 0000 0000 RESET 00hex 0 dB gain 0010 0000 20hex +12 dB gain 0111 1111 7Fhex ACB Register 0013hex [13..0] DSP IN Selection of Source: * SC1_IN_L/R MONO_IN SC2_IN_L/R Mute xx xx xx xx xx00 xx01 xx10 xx11 xx00 xx00 xx00 xx10 0000 0000 0000 0000 SC1_OUT_L/R Selection of Source: SC2_IN_L/R MONO_IN SCART1 via D/A SC1_IN_L/R Mute xx xx xx xx xx 01xx 10xx 11xx 01xx 11xx x0x0 x0x0 x0x0 x1x0 x1x0 0000 0000 0000 0000 0000 * = RESET position, which becomes active at the time of the first write transmission on the control bus to the audio processing part (DSP). By writing to the ACB register first, the RESET state can be redefined. Note: After RESET, SC1_OUT_L/R is undefined! 7.3.16. NICAM Deemphasis (MSP 3415D only) A J17 Deemphasis is always applied to the NICAM signal. It is not switchable. Micronas Note: If “MONO_IN” is selected at the DSP_IN selection, the channel matrix mode of the corresponding output channel(s) must be set to “sound A”. 43 MSP 34x5D PRELIMINARY DATA SHEET 7.3.21. FM DC Notch 7.3.19. Beeper Beeper Volume 0014hex H OFF 0000 0000 RESET 00hex Maximum Volume (full digital scale FDS) 0111 1111 7Fhex Beeper Frequency 0014hex L 16 Hz (lowest) 0000 0001 01hex 1 kHz 0100 0000 40hex 4 kHz (highest) 1111 1111 FFhex The DC compensation filter (FM DC Notch) for FM input can be switched off. This is used to speed up the automatic search function (see section 6.8.4.). In normal FMmode, the FM DC Notch should be switched on. FM DC Notch 0017hex L ON 0000 0000 Reset 00hex OFF 0011 1111 3Fhex 7.3.22. Automatic Volume Correction (AVC) A squarewave beeper can be added to the loudspeaker channel. The addition point is just before volume adjustment. 7.3.20. Identification Mode AVC on/off 0029hex [15:12] AVC off and Reset of int. variables 0000 RESET 0hex AVC on 1000 8hex Identification Mode 0015hex L AVC Decay Time 0029hex [11:8] Standard B/G (German Stereo) 0000 0000 RESET 00hex Standard M (Korean Stereo) 0000 0001 01hex 8 sec 4 sec 2 sec 20 ms (long) (middle) (short) (very short)1) 1000 0100 0010 0001 8hex 4hex 2hex 1hex Reset of Ident-Filter 0011 1111 3Fhex 1) intended for quick adaptation to the average volume level after channel change To shorten the response time of the identification algorithm after a program change between two FM-stereo capable programs, the reset of the ident-filter can be applied. Sequence: 1. Program change 2. Reset ident-filter 3. Set identification mode back to standard B/G 4. Wait approx. 0.5 sec. 5. Read stereo detection register Different sound sources (e.g. terrestrial channels, SAT channels, or SCART) fairly often do not have the same volume level. Advertisements during movies usually have a higher volume level than the movie itself. This results in annoying volume changes. The AVC solves this problem by equalizing the volume level. To prevent clipping, the AVC’s gain decreases quickly in dynamic boost conditions. To suppress oscillation effects, the gain increases rather slowly for low-level inputs. The decay time is programmable by the AVC register bits [11:8]. For input signals ranging from −24 dBr to 0 dBr, the AVC maintains a fixed output level of −18 dBr. Fig. 7–1 shows the AVC output level versus its input level. For prescale and volume registers set to 0 dB, a level of 0 dBr corresponds to full scale input/output. This is – SCART in-, output 0 dBr = 2.0 Vrms – Loudspeaker and Aux output 0 dBr = 1.4 Vrms 44 Micronas MSP 34x5D PRELIMINARY DATA SHEET 7.5.1. Stereo Detection Register output level [dBr] –12 Stereo Detection Register 0018hex Stereo/Bilingual Mode Reading ID-level (two’s complement) MONO near zero STEREO positive value (ideal reception: 7Fhex) BILINGUAL negative value (ideal reception: 80hex) –18 –24 –30 –24 –18 –12 –6 0 +6 input level [dBr] Fig. 7–1: Simplified AVC characteristics To reset the internal variables, the AVC should be switched off and on during any channel or source change. For standard applications, the recommended decay time is 4 sec. Note: AVC should not be used in any Dolby Pro Logic mode. H If FM Adaptive Deemphasis WP1 is active, the ID-level in Stereo Detection Register is not valid. A control processor evaluating the content of the Stereo Detection Register (ID-level), should use the threshold recommendations, shown in Fig. 7–2 for switching to Stereo/Bilingual and back to Mono mode. Mode Stereo 7.4. Exclusions for the Audio Baseband Features In general, all functions can be switched independently of the others. One exception exists: –25 –20 Mono 20 1. NICAM cannot be processed simultaneously with the FM2 channel (MSP 3415D only). 25 ID-level [Dec] Biling. 2. FM adaptive deemphasis WPI cannot be processed simultaneously with the FM-identification. Fig. 7–2: Recommended thresholds for Stereo/ Mono/Bilingual switching 7.5. DSP Read Registers: Functions and Values 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 writeable. 7.5.2. Quasi-Peak Detector Quasi-Peak Readout Left 0019hex H+L Quasi-Peak Readout Right 001Ahex H+L Quasi peak readout [0hex ... 7FFFhex] values are 16 bit two’s complement 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 Micronas 45 MSP 34x5D PRELIMINARY DATA SHEET 7.5.5. MSP Major Revision Code 7.5.3. DC Level Register DC Level Readout FM1 (MSP-Ch2) 001Bhex H+L DC Level Readout FM2 (MSP-Ch1) 001Chex H+L DC Level [8000hex ... 7FFFhex] values are 16 bit two’s complement The DC level register measures the DC component of the incoming FM signals (FM1 and FM2). This can be used for seek functions in satellite receivers and for IF FM frequencies fine tuning. A too low demodulation frequency (DCO) results in a positive DC-Level and vice versa. For further processing, the DC content of the demodulated FM signals is suppressed. The time constant τ, defining the transition time of the DC Level Register, is approximately 28 ms. 7.5.4. MSP Hardware Version Code Hardware Version 001Ehex Hardware Version Major Revision 001Ehex MSP 34x5D 04hex L The MSP 34x5D is the fourth generation of ICs in the MSP family. 7.5.6. MSP Product Code Product 001Fhex MSP 3405D 05hex MSP 3415D 0Fhex H By means of the MSP-Product Code, the control processor is able to decide whether or not NICAM-controlling should be accomplished. 7.5.7. MSP ROM Version Code H ROM Version 001Fhex [00hex ... FFhex] Major software revision [00hex ... FFhex] MSP 34x5D – A2 01hex MSP 34x5D – A2 22hex MSP 34x5D – B3 02hex MSP 34x5D – B3 23hex A change in the hardware version code defines hardware optimizations that may have influence on the chip’s behavior. The readout of this register is identical to the hardware version code in the chip’s imprint. L A change in the ROM version code defines internal software optimizations, that may have influence on the chip’s behavior, e.g. new features may have been included. While a software change is intended to create no compatibility problems, customers that want to use the new functions can identify new MSP 34x5D versions according to this number. To avoid compatibility problems with the MSPB series, an offset of 20hex is added to the ROM version code of the chip’s imprint. 46 Micronas MSP 34x5D PRELIMINARY DATA SHEET 8. Specifications 0.9 ± 0.2 8.1. Outline Dimensions 1.1 x 45 ° 1.2 x 45° 61 2 1.27 60 10 2 7.5 24.2 ± 0.1 0.71 ± 0.05 25.14 ± 0.12 23.3 ± 0.3 9 16 x 1.27 = 20.32 ± 0.1 1 0.48 ± 0.06 9 16 x 1.27 = 20.32 ± 0.1 1.27 7.5 26 0.23 ± 0.04 9 44 27 1.9 ±0.05 43 4.05 ±0.1 25.14 ± 0.12 4.75 ±0.15 24.2 ± 0.1 0.1 Fig. 8–1: 68-Pin Plastic Leaded Chip Carrier Package (PLCC68) Weight approximately 4.8 g Dimensions in mm SPGS0027-2(P68)/1E SPGS0016-5(P52)/1E SPGS0016-5(P64)/1E 64 33 27 1 26 32 47.0 ±0.1 19.3 ±0.1 18 ±0.05 0.8 ±0.2 3.8 ±0.1 57.7 ±0.1 15.6 ±0.1 14 ±0.1 0.6 ±0.2 4.0 ±0.1 1 52 1 ±0.05 1.778 0.48 ±0.06 3.2 ±0.2 0.28 ±0.06 31 x 1.778 = 55.1 ±0.1 Fig. 8–2: 64-Pin Plastic Shrink Dual Inline Package (PSDIP64) Weight approximately 9.0 g Dimensions in mm Micronas 20.3 ±0.5 1.778 0.48 ±0.06 2.8 ±0.2 0.28 ±0.06 1 ±0.05 16.3 ±1 25 x 1.778 = 44.4 ±0.1 Fig. 8–3: 52-Pin Plastic Shrink Dual In Line Package (PSDIP52) Weight approximately 5.5 g Dimensions in mm 47 MSP 34x5D PRELIMINARY DATA SHEET 23 x 0.8 = 18.4 ± 0.1 0.17 ± 0.04 64 0.8 41 16 14 ± 0.1 0.37 ± 0.05 17.2 ± 0.15 9.8 80 8 1.8 10.3 5 0.8 8 1.8 15 x 0.8 = 12.0 ± 0.1 40 65 25 1 1.3 ± 0.05 24 2.7 ± 0.1 23.2 ± 0.15 3 ±0.2 20 ± 0.1 0.1 Fig. 8–4: 80-Pin Plastic Quad Flat Package (PQFP80) Weight approximately 1.61 g Dimensions in mm SPGS705000-1(P80)/1E 10 x 0.8 = 8 ± 0.1 0.17 ± 0.06 12 44 1 11 1.75 10 ± 0.1 0.375 ± 0.075 13.2 ± 0.2 1.75 1.3 0.8 22 34 2.0 ± 0.1 13.2 ± 0.2 2.15 ± 0.2 Fig. 8–5: 44-Pin Plastic Metric Quad Flat Package (PMQFP44) Weight approx. 0.4 g Dimensions in mm 48 0.8 23 10 x 0.8 = 8 ± 0.1 33 0.1 10 ± 0.1 SPGS0006-3(P44)/1E Micronas MSP 34x5D PRELIMINARY DATA SHEET 8.2. Pin Connections and Short Descriptions NC = not connected (leave vacant for future compatibility reasons) TP = Test Pin (leave vacant; pin is used for production test only) LV = leave vacant X = obligatory; connect as described in application circuit diagram Pin No. Pin Name Type Connection (if not used) sed) Short Description – TP OUT LV Test pin – – NC LV Not connected 13 8 – TP OUT LV Test pin 14 12 7 17 I2S_DA_IN1 IN LV I2S1 data input 5 13 11 6 16 I2S_DA_OUT OUT LV I2S data output 6 12 10 5 15 I2S_WS IN/OUT LV I2S word strobe 7 11 9 4 14 I2S_CL IN/OUT LV I2S clock 8 10 8 3 13 I2C_DA IN/OUT X I2C data 9 9 7 2 12 I2C_CL IN/OUT X I2C clock 10 8 – 1 – NC LV Not connected 11 7 6 80 11 STANDBYQ IN X Standby (low-active) 12 6 5 79 10 ADR_SEL IN X I2C Bus address select 13 5 4 78 9 D_CTR_OUT0 OUT LV Digital control output 0 14 4 3 77 8 D_CTR_OUT1 OUT LV Digital control output 1 15 3 – 76 – NC LV Not connected 16 2 – 75 – NC LV Not connected 17 – – – – NC LV Not connected 18 1 2 74 – NC LV Not connected 19 64 1 73 7 TP LV Test pin 20 63 52 72 6 XTAL_OUT OUT X Crystal oscillator 21 62 51 71 5 XTAL_IN IN X Crystal oscillator 22 61 50 70 4 TESTEN IN X Test pin 23 60 49 69 – NC LV Not connected 24 59 48 68 3 ANA_IN– IN LV IF common 25 58 47 67 2 ANA_IN1+ IN LV IF input 1 26 57 46 66 1 AVSUP X Analog power supply +5 V – – – 65 – AVSUP X Analog power supply +5 V – – – 64 – NC LV Not connected – – – 63 – NC LV Not connected PLCC 68-pin PSDIP 64-pin PSDIP 52-pin PQFP 80-pin PMQFP 44-pin 1 16 14 9 2 – – 3 15 4 Micronas 1) 49 MSP 34x5D PRELIMINARY DATA SHEET Pin No. Pin Name Connection (if not used) Short Description AVSS X Analog ground – AVSS X Analog ground 60 43 MONO_IN LV Mono input – 59 – NC LV Not connected 54 43 58 42 VREFTOP X Reference voltage IF A/D converter 30 53 42 57 41 SC1_IN_R IN LV Scart 1 input, right 31 52 41 56 40 SC1_IN_L IN LV Scart 1 input, left 32 51 – 55 39 ASG1 AHVSS Analog shield ground 1 33 50 40 54 38 SC2_IN_R IN LV Scart 2 input, right 34 49 39 53 37 SC2_IN_L IN LV Scart 2 input, left 35 48 – 52 – NC LV or AHVSS Not connected 36 47 38 51 – NC LV Not connected 37 46 37 50 – NC LV Not connected 38 45 – 49 – NC LV Not connected 39 44 – 48 – NC LV Not connected 40 43 – 47 – NC LV Not connected 41 – – 46 – NC LV Not connected 42 42 36 45 36 AGNDC X Analog reference voltage high voltage part 43 41 35 44 35 AHVSS X Analog ground – – – 43 – AHVSS X Analog ground – – – 42 – NC LV Not connected – – – 41 – NC LV Not connected 44 40 34 40 34 CAPL_M X Volume capacitor MAIN 45 39 33 39 33 AHVSUP X Analog power supply +8 V 46 38 32 38 32 NC LV Not connected 47 37 31 37 31 SC1_OUT_L OUT LV Scart 1 output, left 48 36 30 36 30 SC1_OUT_R OUT LV Scart 1 output, right 49 35 29 35 29 VREF1 X Reference ground 1 high voltage part 50 34 28 34 28 NC LV Not connected 51 33 27 33 – NC LV Not connected 52 – – 32 – NC LV Not connected PLCC 68-pin PSDIP 64-pin PSDIP 52-pin PQFP 80-pin PMQFP 44-pin 27 56 45 62 44 – – – 61 28 55 44 – – 29 50 1) Type IN Micronas MSP 34x5D PRELIMINARY DATA SHEET Pin No. Pin Name Connection (if not used) Short Description NC LV Not connected – NC LV Not connected 29 – NC LV Not connected 25 28 27 DACM_L OUT LV Loudspeaker out, left 28 24 27 26 DACM_R OUT LV Loudspeaker out, right 58 27 23 26 25 VREF2 X Reference ground 2 high voltage part 59 26 22 25 24 NC LV Not connected 60 25 21 24 23 NC LV Not connected – – – 23 – NC LV Not connected – – – 22 – NC LV Not connected 61 24 20 21 22 RESETQ X Power-on-reset 62 23 – 20 – NC LV Not connected 63 22 – 19 – NC LV Not connected 64 21 19 18 – NC LV Not connected 65 20 18 17 21 I2S_DA_IN2 LV I2S2 data input 66 19 17 16 – DVSS X Digital ground – – – 15 – DVSS X Digital ground – – – 14 20 DVSS X Digital ground 67 18 16 13 19 DVSUP X Digital power supply +5 V – – – 12 – DVSUP X Digital power supply +5 V – – – 11 – DVSUP X Digital power supply +5 V 68 17 15 10 18 TP_CO LV Test pin (Use this pin to define the capacitor size at crystal oscillator.) PLCC 68-pin PSDIP 64-pin PSDIP 52-pin PQFP 80-pin PMQFP 44-pin 53 32 – 31 – 54 31 26 30 55 30 – 56 29 57 Type IN IN OUT 1) Note: For PQFP80 package ONLY and for A2 version ONLY, the following pin-allocation is valid: Pin 74 = TP, Pin 52 = ASG2 Micronas 51 MSP 34x5D PRELIMINARY DATA SHEET 8.3. Pin Configurations TP NC TP_CO TP DVSUP I2S_DA_IN1 DVSS I2S_DA_OUT I2S_DA_IN2 I2S_WS NC I2S_CL NC I2C_DA NC I2C_CL RESETQ 9 8 7 6 5 4 3 2 1 68 67 66 65 64 63 62 61 NC 10 60 NC STANDBYQ 11 59 NC ADR_SEL 12 58 VREF2 D_CTR_OUT0 13 57 DACM_R D_CTR_OUT1 14 56 DACM_L NC 15 55 NC NC 16 54 NC NC 17 53 NC NC 18 52 NC TP 19 51 NC XTAL_OUT 20 50 NC XTAL_IN 21 49 VREF1 TESTEN 22 48 SC1_OUT_R NC 23 47 SC1_OUT_L ANA_IN– 24 46 NC ANA_IN1+ 25 45 AHVSUP AVSUP 26 44 CAPL_M MSP 34x5D 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 AVSS AHVSS MONO_IN AGNDC VREFTOP NC SC1_IN_R NC SC1_IN_L NC ASG1 NC SC2_IN_R NC SC2_IN_L NC NC Fig. 8–6: 68-pin PLCC package 52 Micronas MSP 34x5D PRELIMINARY DATA SHEET 64 TP TP 1 52 XTAL_OUT 2 63 XTAL_OUT NC 2 51 XTAL_IN NC 3 62 XTAL_IN D_CTR_OUT1 3 50 TESTEN D_CTR_OUT1 4 61 TESTEN D_CTR_OUT0 4 49 NC D_CTR_OUT0 5 60 NC ADR_SEL 5 48 ANA_IN– ADR_SEL 6 59 ANA_IN– STANDBYQ 6 47 ANA_IN1+ STANDBYQ 7 58 ANA_IN1+ I2C_CL 7 46 AVSUP NC 8 57 AVSUP I2C_DA 8 45 AVSS I2C_CL 9 56 AVSS I2S_CL 9 44 MONO_IN I2C_DA 10 55 MONO_IN I2S_WS 10 43 VREFTOP I2S_CL 11 54 VREFTOP I2S_DA_OUT 11 42 SC1_IN_R I2S_WS 12 53 SC1_IN_R I2S_DA_IN1 12 41 SC1_IN_L I2S_DA_OUT 13 52 SC1_IN_L TP 13 40 SC2_IN_R I2S_DA_IN1 14 51 ASG1 TP 14 39 SC2_IN_L TP 15 50 SC2_IN_R TP_CO 15 38 NC TP 16 49 SC2_IN_L DVSUP 16 37 NC TP_CO 17 48 NC DVSS 17 36 AGNDC DVSUP 18 47 NC I2S_DA_IN2 18 35 AHVSS DVSS 19 46 NC NC 19 34 CAPL_M I2S_DA_IN2 20 45 NC RESETQ 20 33 AHVSUP NC 21 44 NC NC 21 32 NC NC 22 43 NC NC 22 31 SC1_OUT_L NC 23 42 AGNDC VREF2 23 30 SC1_OUT_R RESETQ 24 41 AHVSS DACM_R 24 29 VREF1 NC 25 40 CAPL_M DACM_L 25 28 NC NC 26 39 AHVSUP NC 26 27 NC VREF2 27 38 NC DACM_R 28 37 SC1_OUT_L DACM_L 29 36 SC1_OUT_R NC 30 35 VREF1 NC 31 34 NC NC 32 33 NC MSP 34x5D 1 MSP 34x5D NC NC Fig. 8–8: 52-pin PSDIP package Fig. 8–7: 64-pin PSDIP package Micronas 53 MSP 34x5D PRELIMINARY DATA SHEET SC2_IN_L SC2_IN_R NC NC ASG1 NC SC1_IN_L NC SC1_IN_R NC VREFTOP NC NC NC MONO_IN AGNDC AVSS AHVSS AVSS AHVSS NC NC NC NC AVSUP 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 65 40 CAPL_M AVSUP 66 39 AHVSUP ANA_IN1+ 67 38 NC ANA_IN– 68 37 SC1_OUT_L NC 69 36 SC1_OUT_R TESTEN 70 35 VREF1 XTAL_IN 71 34 NC XTAL_OUT 72 33 NC TP 73 32 NC NC 74 31 NC NC 75 30 NC NC 76 29 NC D_CTR_OUT1 77 28 DACM_L D_CTR_OUT0 78 27 DACM_R ADR_SEL 79 26 VREF2 STANDBYQ 80 25 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 MSP 34x5D 1 2 3 4 5 6 7 8 9 NC NC NC NC I2C_CL NC I2C_DA RESETQ I2S_CL NC I2S_WS NC I2S_DA_OUT NC I2S_DA_IN1 I2S_DA_IN2 TP DVSS TP DVSS TP_CO DVSUP DVSUP DVSS DVSUP Fig. 8–9: 80-pin PQFP package 54 Micronas MSP 34x5D PRELIMINARY DATA SHEET NC VREF1 DACM_L SC1_OUT_R DACM_R SC1_OUT_L VREF2 NC NC AHVSUP NC 33 32 31 30 29 28 27 26 25 24 23 CAPL_M 34 22 RESETQ AHVSS 35 21 I2S_DA_IN2 AGNDC 36 20 DVSS SC2_IN_L 37 19 DVSUP SC2_IN_R 38 18 TP_CO ASG1 39 17 I2S_DA_IN1 SC1_IN_L 40 16 I2S_DA_OUT SC1_IN_R 41 15 I2S_WS VREFTOP 42 14 I2S_CL MONO_IN 43 13 I2C_DA AVSS 44 12 I2C_CL MSP 34x5D 1 2 3 4 5 6 7 8 9 10 11 STANDBYQ AVSUP ADR_SEL ANA_IN+ D_CTR_OUT0 ANA_IN– D_CTR_OUT1 TESTEN TP XTAL_IN XTAL_OUT Fig. 8–10: 44-pin PMQFP package 8.4. Pin Circuits (pin numbers refer to PLCC68 package) DVSUP P Fig. 8–11: Input Pins 4, 11, 12, 61, and 65 (I2S_DA_IN1, STANDBYQ, ADR_SEL, RESETQ, and I2S_DA_IN2) N GND Fig. 8–13: Input/Output pins 6 and 7 (I2S_WS, I2S_CL) DVSUP P N N GND Fig. 8–12: Output pins 5, 13, 14, and 68 (I2S_DA_OUT, D_CTR_OUT0/1, TP_CO) Micronas GND Fig. 8–14: Input/Output Pins 8 and 9 (I2C_DA, I2C_CL) 55 MSP 34x5D PRELIMINARY DATA SHEET 125 k P 3–30 pF ≈ 3.75 V Fig. 8–19: Pin 42 (AGNDC) 500 k N 3–30 pF 0...2 V Fig. 8–15: Input/Output Pins 20 and 21 (XTAL_OUT/IN) Fig. 8–20: Capacitor Pin 44 (CAPL_M) ANA_IN1+ A D ANA_IN– VREFTOP 40 pF 80 k 300 Fig. 8–16: Input Pins 24, 25, and 29 (ANA_IN–, ANA_IN1+, VREFTOP) ≈ 3.75 V Fig. 8–21: Output Pins 47, 48 (SC1_OUT_L/R) 24 k ≈ 3.75 V Fig. 8–17: Input Pin 28 (MONO_IN) AHVSUP 0...1.2 mA 40 k ≈ 3.75 V Fig. 8–18: Input Pins 30, 31, 33, and 34 (SC1–2_IN_L/R) 56 3.3 k Fig. 8–22: Output Pins 56, 57 (DACM_L/R) Micronas MSP 34x5D PRELIMINARY DATA SHEET 8.5. Electrical Characteristics 8.5.1. Absolute Maximum Ratings Symbol Parameter Pin Name Min. Max. Unit TA Ambient Operating Temperature – 0 701) °C TS Storage Temperature – –40 125 °C VSUP1 First Supply Voltage AHVSUP –0.3 9.0 V VSUP2 Second Supply Voltage DVSUP –0.3 6.0 V VSUP3 Third Supply Voltage AVSUP –0.3 6.0 V dVSUP23 Voltage between AVSUP and DVSUP AVSUP, DVSUP –0.5 0.5 V PTOT Package Power Dissipation PLCC68 without Heat Spreader PSDIP64 without Heat Spreader PSDIP52 without Heat Spreader PMQFP44 without Heat Spreader AHVSUP, DVSUP, AVSUP 1200 1300 1200 9101) mW –0.3 VSUP2+0.3 V VIdig Input Voltage, all Digital Inputs IIdig Input Current, all Digital Pins – –20 +20 mA2) VIana Input Voltage, all Analog Inputs SCn_IN_s,3) MONO_IN –0.3 VSUP1+0.3 V IIana Input Current, all Analog Inputs SCn_IN_s,3) MONO_IN –5 +5 mA2) IOana Output Current, all SCART Outputs SC1_OUT_s 4), 5) 4), 5) IOana Output Current, all Analog Outputs except SCART Outputs DACM_s3) 4) 4) ICana Output Current, other pins connected to capacitors CAPL_M AGNDC 4) 4) 1) 2) 3) 4) 5) For PMQFP44 package, max. ambient operating temperature is 65 °C. positive value means current flowing into the circuit “n” means “1” or “2”, “s” means “L” or “R” 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. Micronas 57 MSP 34x5D PRELIMINARY DATA SHEET 8.5.2. Recommended Operating Conditions (at TA = 0 to 70 °C) Symbol Parameter Pin Name Min. VSUP1 First Supply Voltage AHVSUP 7.6 VSUP2 Second Supply Voltage DVSUP VSUP3 Third Supply Voltage VRLH RESET Input Low-to-High Transition Voltage VRHL RESET Input High-to-Low Transition Voltage (see also Fig. 5–3 on page 19) VDIGIL Digital Input Low Voltage VDIGIH Digital Input High Voltage VDIGIL Digital Input Low Voltage VDIGIH Digital Input High Voltage MSP 34x5D version A1, A2 MSP 34x5D version B3 and later tSTBYQ1 STANDBYQ Setup Time before Turn-off of Second Supply Voltage Typ. Max. Unit 8.0 8.71) V 4.75 5.0 5.25 V AVSUP 4.75 5.0 5.25 V RESETQ 0.7 0.8 DVSUP 0.45 0.55 DVSUP 0.2 VSUP2 ADR_SEL 0.8 STANDBYQ STANDBYQ, DVSUP VSUP2 0.2 VSUP2 0.8 0.5 VSUP2 VSUP2 1 µs I2C-Bus Recommendations VI2CIL I2C-Bus Input Low Voltage VI2CIH I2C-Bus Input High Voltage tI2C1 0.3 VSUP2 0.6 VSUP2 I2C Start Condition Setup Time 120 ns tI2C2 I2C Stop Condition Setup Time 120 ns tI2C5 I2C-Data Setup Time before Rising Edge of Clock 55 ns tI2C6 I2C-Data Hold Time after Falling Edge of Clock 55 ns tI2C3 I2C-Clock Low Pulse Time 500 ns tI2C4 I2C-Clock High Pulse Time 500 ns fI2C I2C-Bus Frequency 1) 58 I2C_CL, I2C_DA I2C DA I2C_CL 1.0 MHz For MSP 34x5D-A1 and -A2 versions in PMQFP44 package, only 8.4 V is allowed. Micronas MSP 34x5D PRELIMINARY DATA SHEET Symbol Parameter Pin Name Min. Typ. Max. Unit 0.25 0.2 VSUP2 VSUP2 I2S-Bus Recommendations VI2SIH VI2SIL I2S-Data Input Low Voltage MSP 34x5D version A1, A2 MSP 34x5D version B3 and later I2S_DA_IN1/2 I2S-Data Input High Voltage MSP 34x5D version A1, A2 MSP 34x5D version B3 and later tI2S1 I2S-Data Input Setup Time before Rising Edge of Clock tI2S2 I2S-Data Input Hold Time after falling Edge of Clock fI2SCL I2S-Clock Input Frequency when MSP in I2S-Slave Mode RI2SCL I2S-Clock Input Ratio when MSP in I2S-Slave Mode fI2SWS I2S-Word Strobe Input Frequency when MSP in I2S-Slave Mode I2S_WS VI2SIDL I2S-Input Low Voltage when MSP in I2S-Slave Mode MSP 34x5D version A1, A2 MSP 34x5D version B3 and later I2S_CL I2S_WS VI2SIDH I2S-Input High Voltage when MSP in I2S-Slave Mode MSP 34x5D version A1, A2 MSP 34x5D version B3 and later I2S_DA_IN1/2 I2S_CL 0.75 0.5 VSUP2 VSUP2 20 ns 0 ns I2S_CL 1.024 0.9 MHz 1.1 32.0 kHz 0.25 0.2 VSUP2 VSUP2 0.75 0.5 VSUP2 VSUP2 tI2SWS1 I2S-Word Strobe Input Setup Time before Rising Edge of Clock when MSP in I2S-Slave Mode 60 ns tI2SWS2 I2S-Word Strobe Input Hold Time after falling Edge of Clock when MSP in I2S-Slave Mode 0 ns Micronas 59 MSP 34x5D Symbol Parameter PRELIMINARY DATA SHEET Pin Name Min. Typ. Max. Unit General Crystal Recommendations fP Crystal Parallel Resonance Frequency at 12 pF Load Capacitance 18.432 RR Crystal Series Resistance 8 25 Ω C0 Crystal Shunt (Parallel) Capacitance 6.2 7.0 pF CL External Load Capacitance1) 1.5 pF pF pF XTAL_IN, XTAL_OUT PSDIP PLCC P(M)QFP MHz 3.3 3.3 Crystal Recommendations for Master-Slave Applications fTOL Accuracy of Adjustment –20 +20 ppm DTEM Frequency Variation vs Temp. –20 +20 ppm C1 Motional (Dynamic) Capacitance 19 fCL Required Open Loop Clock Frequency (Tamb = 25 °C) XTAL_IN, XTAL_OUT 24 18.431 fF 18.433 MHz Crystal Recommendations for FM / NICAM Applications (No Master-Slave Mode possible) fTOL Accuracy of Adjustment –30 +30 ppm DTEM Frequency Variation vs Temp. –30 +30 ppm C1 Motional (Dynamic) Capacitance 15 fCL Required Open Loop Clock Frequency (Tamb = 25 °C) XTAL_IN, XTAL_OUT 18.4305 fF 18.4335 MHz Crystal Recommendations for FM Applications (No Master-Slave Mode possible) fTOL Accuracy of Adjustment –100 +100 ppm DTEM Frequency Variation versus Temperature –50 +50 ppm Amplitude Recommendation for Operation with External Clock Input (Cload after reset = 22 pF) VXCA 1) External Clock Amplitude XTAL_IN 0.7 Vpp External capacitors at each crystal pin to ground are required. They are necessary to tune the open-loop frequency of the internal PLL and to stabilize the frequency in closed-loop operation. Due to different layouts, the accurate capacitor size should be determined with the customer PCB. The suggested values (1.5...3.3 pF) are figures based on experience and should serve as “start value”. To define the capacitor size, reset the MSP without transmitting any further I2C telegrams. Set MODE_REG 0083hex Bit [14]=1. Measure the frequency at pin TP_CO (see pin description in table on page 51). Change the capacitor size until the free running frequency at pin TP_CO matches 6.144000 MHz (=18.432000 MHz / 3) as closely as possible. The higher the capacity, the lower the resulting clock frequency. 60 Micronas MSP 34x5D PRELIMINARY DATA SHEET Symbol Parameter Pin Name Min. Typ. Max. Unit AGNDC –20% 3.3 µF –20% 100 nF –20% 330 Analog Input and Output Recommendations CAGNDC AGNDC-Filter-Capacitor Ceramic Capacitor in Parallel SCn_IN_s1) CinSC DC-Decoupling Capacitor in front of SCART Inputs VinSC SCART Input Level VinMONO Input Level, Mono Input MONO_IN RLSC SCART Load Resistance SC1_OUT_s1) CLSC SCART Load Capacitance CVMA Main Volume Capacitor CAPL_M CFMA Main Filter Capacitor DACM_s1) +20% nF 2.0 VRMS 2.0 VRMS 10 kΩ 6.0 nF µF 10 –10% 1 +10% nF –20% 10 µF Ceramic Capacitor in Parallel –20% 100 nF FIF_FM Analog Input Frequency Range 0 VIF_FM Analog Input Range FM/NICAM 0.1 VIF_AM Analog Input Range AM/NICAM RFMNI Ratio: NICAM Carrier/FM Carrier (unmodulated carriers) BG: I: Recommendations for Analog Sound IF Input Signal CVREFTOP VREFTOP-Filter-Capacitor VREFTOP 9 MHz 0.8 3 Vpp 0.1 0.45 0.8 Vpp –20 –23 –7 –10 0 0 dB dB –25 –11 0 dB dB RAMNI Ratio: NICAM Carrier/AM Carrier (unmodulated carriers) RFM Ratio: FM-Main/FM-Sub Satellite RFM1/FM2 Ratio: FM1/FM2 German FM-System RFC Ratio: Main FM Carrier/ Color Carrier 15 – – dB RFV Ratio: Main FM Carrier/ Luma Components 15 – – dB PRIF Passband Ripple – – ±2 dB SUPHF Suppression of Spectrum Above 9.0 MHz 15 – dB FMMAX Maximum FM-Deviation (apprx.) normal mode high deviation mode ±180 ±360 kHz 1) ANA_IN1+, ANA_IN– 7 dB 7 dB “n” means “1” or “2”, “s” means “L” or “R” Micronas 61 MSP 34x5D PRELIMINARY DATA SHEET 8.5.3. Characteristics at TA = 0 to 70 °C, fCLOCK = 18.432 MHz, VSUP1 = 7.6 to 8.7 V, VSUP2 = 4.75 to 5.25 V for min./max. values at TA = 60 °C, fCLOCK = 18.432 MHz, VSUP1 = 8 V, VSUP2 = 5 V for typical values, TJ = Junction Temperature MAIN (M) = Loudspeaker Channel Symbol Parameter Pin Name fCLOCK Clock Input Frequency XTAL_IN DCLOCK Clock High to Low Ratio tJITTER Clock Jitter (Verification not provided in production test) VxtalDC DC-Voltage Oscillator tStartup Oscillator Startup Time at VDD Slew-rate of 1 V/1 µs XTAL_IN, XTAL_OUT ISUP1A First Supply Current (active) AHVSUP Min. Typ. Max. 18.432 45 Unit Test Conditions MHz 55 % 50 ps 2.5 V 0.4 2 ms Analog Volume for Main and Aux at 0 dB Analog Volume for Main and Aux at –30 dB 9.6 6.3 17.1 11.2 24.6 16.1 mA mA ISUP1S First Supply Current (standby mode) at Tj = 27 °C 3.5 5.6 7.7 mA ISUP2A Second Supply Current (active) MSP 34x5D version A1, A2 MSP 34x5D version B3 and later DVSUP 86 50 95 70 102 85 mA mA Third Supply Current (active) MSP 34x5D version A1, A2 MSP 34x5D version B3 and later AVSUP 15 20 25 35 35 45 mA mA 0.4 V IDCTR = 1 mA V IDCTR = –1 mA 0.4 V II2COL = 3 mA 1.0 µA VI2COH = 5 V ISUP3A STANDBYQ = low Digital Contol Outputs VDCTROL Digital Output Low Voltage VDCTROH Digital Output High Voltage D_CTR_OUT0 D_CTR_OUT1 D CTR OUT1 4.0 I2C-Bus VI2COL I2C-Data Output Low Voltage II2COH I2C-Data Output High Current tI2COL1 I2C-Data Output Hold Time after Falling Edge of Clock tI2COL2 I2C-Data Output Setup Time before Rising Edge of Clock 62 I2C_DA I2C_DA, I2C_CL 15 ns 100 ns fI2C = 1 MHz Micronas MSP 34x5D PRELIMINARY DATA SHEET Symbol Parameter Pin Name VI2SOL I2S Output Low Voltage VI2SOH I2S Output High Voltage I2S_WS I2S_CL I2S CL I2S_DA_OUT fI2SWS I2S Word Strobe Output Frequency I2S_WS fI2SCL I2S Clock Output Frequency I2S_CL tI2S1/I2S2 I2S Clock High/Low Ratio tI2S3 I2S Data Setup Time before Rising Edge of Clock tI2S4 I2S Data Hold Time after Falling Edge of Clock tI2S5 I2S Word Strobe Setup Time before Rising Edge of Clock tI2S6 I2S Word Strobe Hold Time after Falling Edge of Clock Min. Typ. Max. Unit Test Conditions 0.4 V II2SOL = 1 mA V II2SOH = –1 mA 32.0 kHz NICAM-PLL closed 1024 kHz I2S-Bus 4.0 0.9 I2S_CL I2S_DA_OUT 1 1.1 200 ns 180 I2S_CL I2S_WS 200 CL = 30 pF ns ns 180 ns Analog Ground VAGNDC0 AGNDC Open Circuit Voltage RoutAGN AGNDC Output Resistance AGNDC 3.67 3.77 3.87 V Rload ≥ 10 MΩ 70 125 180 kΩ 3 V ≤ VAGNDC ≤ 4 V Analog Input Resistance RinSC SCART Input Resistance from TA = 0 to 70 °C SCn_IN_s1) 25 40 58 kΩ fsignal = 1 kHz, I = 0.05 mA RinMONO MONO Input Resistance from TA = 0 to 70 °C MONO_IN 15 24 35 kΩ fsignal = 1 kHz, I = 0.1 mA SCn_IN_s1), MONO_IN 2.00 2.25 VRMS fsignal = 1 kHz 460 500 Ω Ω –70 +70 mV SCn_IN_s1) MONO_IN → SC1_OUT_s1) –1.0 +0.5 dB fsignal = 1 kHz –0.5 +0.5 dB with resp. to 1 kHz SC1_OUT_s1) 1.8 2.0 VRMS fsignal = 1 kHz Audio Analog-to-Digital-Converter VAICL Effective Analog Input Clipping Level for Analog-to-DigitalConversion SCART Outputs RoutSC SCART Output Resistance at Tj = 27 °C from TA = 0 to 70 °C dVOUTSC Deviation of DC-Level at SCART Output from AGNDC Voltage ASCtoSC Gain from Analog Input to SCART Output frSCtoSC Frequency Response from Analog Input to SCART Output, Bandwidth: 0 to 20000 Hz VoutSC Effective Signal Level at SCARTOutput during full-scale Digital Input Signal from DSP 1) “n” means “1”, or “2”; Micronas SC1_OUT_s1) 200 200 330 1.9 fsignal = 1 kHz, I = 0.1 mA “s” means “L” or “R” 63 MSP 34x5D Symbol PRELIMINARY DATA SHEET Parameter Pin Name Main Output Resistance at Tj = 27 °C from TA = 0 to 70 °C DACM_s1) Min. Typ. Max. Unit Test Conditions 2.1 2.1 3.3 4.6 5.0 kΩ kΩ 1.8 2.04 61 2.28 V mV 1.23 1.37 1.51 VRMS fsignal = 1 kHz 93 96 dB Input Level = –20 dB, fsig = 1 kHz, equally weighted 20 Hz ... 20 kHz % Input Level = –3 dBr, fsig = 1 kHz, equally weighted 20 Hz ... 20 kHz Main Outputs RoutMA VoutDCMA VoutMA DC-Level at Main-Output for Analog Volume at 0 dB for Analog Volume at –30 dB Effective Signal Level at Main-Output during full-scale Digital Input Signal from DSP for Analog Volume at 0 dB fsignal = 1 kHz, I = 0.1 mA Analog Performance SNR Signal-to-Noise Ratio from Analog Input to SCART Output THD Total Harmonic Distortion from Analog Input to SCART Output XTALK MONO_IN, SCn_IN_s1) → SC1_OUT_s1) MONO_IN, SCn_IN_s1) → SC1_OUT_s1) 0.01 0.03 Crosstalk Attenuation between left and right channel within SCART Input/Output pair (L→R, R→L) SCn_IN → SC1_OUT1) 80 dB Input Level = –3 dB, fsig = 1 kHz, unused analog inputs connected to ground by Z < 1 kΩ equally weighted 20 Hz ... 20 kHz PSRR: rejection of noise on AHVSUP at 1 kHz PSRR AGNDC AGNDC 80 dB From Analog Input to SCART Output MONO_IN, SCn_IN_s1) SC1_OUT_s1) 70 dB S/NFM FM Input to Main/SCART Output DACM_s1), SC1_OUT_s1) THDFM Total Harmonic Distortion and Noise of FM demodulated signal on Main/SCART Outputs DACM_s1), SC1_OUT_s1) S/NNICAM Signal-to-Noise Ratio of NICAM Baseband Signal on Main/SCART Outputs DACM_s1), SC1_OUT_s1) 1) 64 73 dB 0.1 72 % dB 1 FM-carrier 5.5 MHz, 50 µs, 1 kHz, 40 kHz deviation; RMS, unweighted 0 to 15 kHz (for ( S/N); ) full input range, FM-Prescale = 46h, Vol = 0 dB → Output Level 1 Vrms at DACM_s; SPM = 3 NICAM: –6 dB, 1 kHz, RMS unweighted 0 to 15 kHz, NICAM_Prescale = 7Fh, Vol = 9 dB → Output level 1 VRMS at DACM_s; SPM = 8 “n” means “1” or “2”; “s” means “L” or “R” SPM: Short Programming Mode Micronas MSP 34x5D PRELIMINARY DATA SHEET Symbol Parameter Pin Name THDNICAM Total Harmonic Distortion and Noise of NICAM Baseband Signal on Main/SCART Outputs BERNI Max. Unit Test Conditions DACM_s1), SC1_OUT_s1) 0.1 % 2.12 kHz, modulator input level = 0 dBref SPM = 8 NICAM: Bit Error Rate – 1 10–7 FM and NICAM, norm conditions S/NAM Signal-to-Noise Ratio of AM Baseband Signal on Main/SCART Outputs DACM_s1), SC1_OUT_s1) dB THDAM Total Harmonic Distortion and Noise of AM Demodulated Signal on Main/SCART Outputs DACM_s1), SC1_OUT_s1) SIF input range: 0.1–0.8 Vpp; AM= 70%, 1 kHz, RMS unweighted (S/N); 0 to 15 kHz, FM/AM Prescale = 3Chex FM/AM-Prescale h , Vol = 0 dB → Output level: 0.5 VRMS at DACM_s AM + NICAM, norm conditions; SPM = 9 RIFIN Input Impedance ANA_IN1+, ANA_IN– 1.5 10.5 DCVREFTOP DC Voltage at VREFTOP VREFTOP DCANA_IN DC Voltage on IF inputs XTALKIF Crosstalk Attenuation BWIF 3 dB Bandwidth AGC AGC Step Width dVFMOUT Tolerance of Output Voltage of FM Demodulated Signal DACM_s1), SC1_OUT_s1) –1.5 +1.5 dB 1 FM-carrier, 50 µs, 1 kHz 40 kHz deviation; RMS dV- Tolerance of Output Voltage of NICAM Baseband Signal DACM_s1), SC1_OUT_s1) –1.5 +1.5 dB 2.12 kHz, modulator input level = 0 dBref fRFM FM Frequency Response on Main/ SCART Outputs, Bandwidth 20 to 15000 Hz DACM_s1), SC1_OUT_s1) –1.0 +1.0 dB 1 FM-carrier 5.5 MHz, 50 µs, modulator input level = –14.6 dBref; RMS fRNICAM NICAM Frequency Response on Main/SCART Outputs, Bandwidth 20 to 15000 Hz DACM_s1), SC1_OUT_s1) –1.0 +1.0 dB Modulator input level = –12 dB dBref; RMS SEPFM FM Channel Separation (Stereo) DACM_s1), SC1_OUT_s1) 50 dB 2 FM-carriers 5.5/5.74 MHz, 50 µs, 1 kHz, 40 kHz deviation; RMS SEPNICAM NICAM Channel Separation (Stereo) DACM_s1), SC1_OUT_s1) 80 dB XTALKFM FM Crosstalk Attenuation (Dual) DACM_s1), SC1_OUT_s1) 80 dB XTALK- NICAM Crosstalk Attenuation (Dual) DACM_s1), SC1_OUT_s1) 80 dB NICAMOUT NICAM 1) Min. Typ. 48 0.3 % 2 14.1 2.5 17.6 kΩ kΩ 2.56 2.66 2.76 V ANA_IN1+, ANA_IN– 1.3 1.5 1.7 V ANA_IN1+, ANA_IN– ANA IN 40 dB 10 MHz 0.85 Gain AGC = 20 dB Gain AGC = 3 dB fsignal = 1 MHz Input Level = –2 2 dBr dB 2 FM-carriers 5.5/5.74 MHz, 50 µs, 1 kHz, 40 kHz deviation; RMS “n” means “1” or “2”; “s” means “L” or “R” SPM: Short Programming Mode Micronas 65 MSP 34x5D PRELIMINARY DATA SHEET 9. Application Circuit Signal GND C s. section 8.5.2. IF 1 IN 100 nF 3.3 µF 18.432 MHz 100 nF + 10 µF XTAL_OUT (63) 20 AGNDC (42) 42 VREFTOP (54) 29 ANA_IN– (59) 24 100 p 56 p ANA_IN1+ CAPL_M (40) 44 + 56 pF ANA_IN1+ (58) 25 56 pF Alternative circuit for ANA_IN1+ for more attenuation of video components: +8.0 V + XTAL_IN (62) 21 Tuner 1 10 µF – 1K 28 (55) MONO_IN 330 nF 1 µF DACM_L (29) 56 1 nF 31 (52) SC1_IN_L 1 µF MAIN DACM_R (28) 57 330 nF 30 (53) SC1_IN_R 330 nF 32 (51) ASG1 AHVSS 34 (49) SC2_IN_L 330 nF 33 (50) SC2_IN_R 330 nF MSP 34x5D 5V SC1_OUT_L (37) 47 100Ω 22 µF + 11 (7) STANDBYQ 5V DVSS 12 (6) ADR_SEL SC1_OUT_R (36) 48 DVSS 100Ω 22 µF + 8 (10) I2C_DA 9 (9) I2C_CL D_CTR_OUT0 (5) 13 6 (12) I2S_WS D_CTR_OUT1 (4) 14 7 (11) I2S_CL 4 (14) I2S_DA_IN1 TESTEN (61) 22 65 (20) I2S_DA_IN2 58 (27) VREF2 49 (35) VREF1 43 (41) AHVSS 45 (39) AHVSUP 27 (56) AVSS 26 (57) AVSUP AVSS 66 (19) DVSS 67 (18) DVSUP 61 (24) RESETQ 5 (13) I2S_DA_OUT 100 nF 100 nF 100 nF 5V 5V AVSS ResetQ (from CCU, see section.5.3.) 8.0 V Note: Pin numbers refer to the PLCC68 package, numbers in brackets refer to the PSDIP64 package. 66 Micronas PRELIMINARY DATA SHEET MSP 34x5D 10. Appendix A: MSP 34x5D Version History A1 First hardware release MSP 3415D A2 Second hardware release MSP 3405D and MSP 3415D B3 – I2S Bus supported with version B3 and later versions – digital input specification changed with version B3 and later versions (see section ... ) – max. analog high supply voltage AHVSUP 8.7 V Micronas 67 MSP 34x5D PRELIMINARY DATA SHEET 11. Data Sheet History 1. Preliminary Data Sheet: “MSP 34x5D Multistandard Sound Processors”, Aug. 5, 1998, 6251-475-1PD. First release of the preliminary data sheet. 2. Preliminary Data Sheet: “MSP 34x5D Multistandard Sound Processors”, Oct. 14, 1999, 6251-475-2PD. Second release of the preliminary data sheet. Major changes: – specification for version B3 added (see Appendix A: Version History) – specification for I2S interface added – section 8.1.: Outline Dimensions for all packages changed Micronas GmbH Hans-Bunte-Strasse 19 D-79108 Freiburg (Germany) P.O. Box 840 D-79008 Freiburg (Germany) Tel. +49-761-517-0 Fax +49-761-517-2174 E-mail: [email protected] Internet: www.micronas.com Printed in Germany Order No. 6251-475-2PD 68 All information and data contained in this data sheet are without any commitment, are not to be considered as an offer for conclusion of a contract, nor shall they be construed as to create any liability. Any new issue of this data sheet invalidates previous issues. Product availability and delivery are exclusively subject to our respective order confirmation form; the same applies to orders based on development samples delivered. By this publication, Micronas GmbH does not assume responsibility for patent infringements or other rights of third parties which may result from its use. Further, Micronas GmbH reserves the right to revise this publication and to make changes to its content, at any time, without obligation to notify any person or entity of such revisions or changes. No part of this publication may be reproduced, photocopied, stored on a retrieval system, or transmitted without the express written consent of Micronas GmbH. Micronas MSP 34xxD Preliminary Data Sheet Supplement Subject: Compatibility Differences Data Sheet Concerned: All MSP 34xxD Data Sheets: 6251-482-2PD, 6251-475-2PD, 6251-486-2PD Supplement: No. 3/ 6251-526-3PDS Edition: Oct. 11, 2000 MSP 34xxD Family Compatibility Differences: The MSP-family (MSP 3410D, MSP 3400D, MSP 3415D, MSP 3405D, MSP 3417D, MSP 3407D) is currently available in different technologies (0.8 µ, 0.5 µ, and 0.45 µ). The specific differences of the various implementations are listed in the attached table. Micronas page 1 of 1 Micronas Compatibility Differences between 0.5/0.45µ and 0.8µ MSPD Devices MSP-Type MSP 3410D / MSP 3400D Version Code B4 Technology 0.8µ Mask Iteration Code Feature 67, 6B, 6G C5 MSP 3415D / MSP 3405D B3 A2 0.5µ 0.45µ 8C and 94 G1, G4 H1, H3 0.8µ 6C, 6D MSP 3417D / MSP 3407D B2 A1 0.5µ 0.45µ 8D G2, G5 H2, H4 0.8µ 6E, 6F 0.5µ 0.45µ 8F G3, G6, H5 Documented in Datasheet Reference MSP 3400D, MSP 3410D Edit. May 1999 MSP 3405D, MSP 3415D Edit Oct. 1999 MSP 3407D, MSP 3417D Edit Jan. 2000 General Hardware Power Consumption Datasheet 910 mW 600 mW less due to less Power Consumption 910 mW VAGNDC0 typical Datasheet 3.73 V 3.77 V DCVREFTOP typical Datasheet 2.6 V Maximum Vsup1 Datasheet 8.4 V Digital Input Pin characteristics (I2S_IN1/2, I2S_WS/CL, StANDBYQ) Datasheet - Total Electromagnetic Radiation (EMR) - 640 mW 600 mW less due to less Power Consumption 910 mW 3.73 V 3.77 V 3.73 V 3.77 V 2.66 V 2.6 V 2.66 V 2.6 V 2.66 V 8.7 V modified specifications (see datasheet) 8.4 V 8.7 V modified specifications (see datasheet) 8.4 V 8.7 V modified specifications (see datasheet) - - 640 mW - - 640 mW 600 mW less due to less Power Consumption Demodulator Carrier Mute - AM-Frequency Response - Automatic Standard Detection - slightly slower, but more stable: 64ms mute, 500 ms demute more flat faster, more stable and with mutefunction - slightly slower, but more stable: 64ms mute, 500 ms demute more flat faster, more stable and with mutefunction - slightly slower, but more stable: 64ms mute, 500 ms demute more flat faster, more stable and with mutefunction Baseband Processing J17-Deemphasis for FM-Input channels Datasheet Supplement I2S-Bus Datasheet Frequency response of 50/75µs Deemphasis DC_Level (DSP-Reg.: 1Bhex/1Chex ) Date: 11.10.00 available not available (75µs instead of J17) available - more flat - Level increased by appr. 15% 1*) available not available (75µs instead of J17) not available available - more flat - Level increased by appr. 15% 1*) available not available (75µs instead of J17) not available - more flat - Level increased by appr. 15% 1*) Page 1 of 2 Pages Micronas MSP-Type MSP 3410D / MSP 3400D Version Code B4 Technology 0.8µ Mask Iteration Code Feature 67, 6B, 6G C5 MSP 3415D / MSP 3405D B3 A2 0.5µ 0.45µ 8C and 94 G1, G4 H1, H3 0.8µ 6C, 6D MSP 3417D / MSP 3407D B2 A1 0.5µ 0.45µ 8D G2, G5 H2, H4 0.8µ 6E, 6F 0.5µ 0.45µ 8F G3, G6, H5 Documented in D/A-Outputs improved - S/N-ratio improved - - improved not connected Pinning SCART2_Out pin Datasheet connected not connected connected DAC-Headphone pins Datasheet connected connected Audio_Clock_Out Datasheet connected not connected not connected (s. Datasheet P.51) connected not connected not connected The following pins refer to PQFP80: ASG2 ASG2 ASG2 not connected (s. Datasheet P.51) MSP 34x7D not available in 80-PQFP ASG3 not connected (s. Datasheet P.51) MSP 34x7D not available in 80-PQFP Pin 52 Datasheet ASG2 Pin 32 Datasheet ASG3 Pin 14 Datasheet not connected DVSS DVSS not connected DVSS DVSS MSP 34x7D not available in 80-PQFP Pin 16 Datasheet DVSS not connected not connected DVSS not connected not connected MSP 34x7D not available in 80-PQFP not connected (s. Datasheet P.59) *1) In spite of increased DC-level controller-algorithms for automatic Sat-Carrier detection should run properly Date: 11.10.00 Page 2 of 2 Pages