CXD2510Q CD Digital Signal Processor Description The CXD2510Q is a digital signal processor LSI for CD players and is equipped with the following functions. • Wide frame jitter margin (±28 frames) due to a builtin 32K RAM • Bit clock, which strobes the EFM signal, is generated by the digital PLL • EFM data demodulation • Enhanced EFM frame sync signal protection • Refined super strategy-based powerful error correction C1: double correction, C2: quadruple correction • Quadruple-speed, double-speed and variable pitch playback • Noise reduction during track jumps • Auto zero-cross mute • Subcode demodulation and Sub Q data error correction • Digital spindle servo (built-in oversampling filter) • 16-bit traverse counter • Asymmetry compensation circuit • Serial bus-based CPU interface • Error correction monitor signals are output from a new CPU interface. • Servo auto sequencer • Fine search which performs high-precision track jumps • Digital audio interface output • Digital level meter, peak meter • Bilingual compatible Features • All digital signals processed with a single chip during playback • High-integrated mounting possible due to a built-in RAM Structure Silicon gate CMOS IC Absolute Maximum Ratings VDD • Supply voltage –0.3 to +7.0 V • Input voltage VI –0.3 to +7.0 V (VSS – 0.3V to VDD + 0.3V) • Output voltage VO –0.3 to +7.0 V • Storage temperature Tstg –40 to +125 °C • Supply voltage difference Vss – AVss –0.3 to +0.3 V VDD – AVDD –0.3 to +0.3 V -L01 80 pin QFP (Plastic) -L051 Recommended Operating Conditions 4.50 to 5.50 V • Supply voltage VDD∗ • Operating temperature Topr –20 to +75 °C ∗ The VDD (min.) for the CXD2510Q varies according to the playback speed and built-in VCO selection. The VDD (min.) is 4.50 V when high speed VCO and quadruple-speed playback are selected (variable pitch off). The VDD (min.) for the CXD2510Q under various conditions are as shown in the following table. VDD (min.) [V] Playback speed VCO high-speed VCO normal-speed ×4 4.50 — × 2∗1 4.00 — ×2 3.40 4.00 ×1 3.40 3.40 × 1∗2 3.40 3.40 Dashes indicate that there is no assurance of the processor operating. All values are for variable pitch off. ∗1 When the internal operation of the LSI is set to normal-speed playback and the operating clock of the signal processor is doubled, double-speed playback results. ∗2 When the internal operation of the LSI is set to double-speed mode and the crystal oscillating frequency is halved in low power consumption mode, normal-speed playback results. Input/output Capacitances • Input capacitance CI • Output capacitance CO Note) Measurement conditions 12 (max.) pF 12 (max.) pF for high impedance VDD = VI = 0V fM = 1MHz Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits. –1– E94412A11 CXD2510Q 17 16 54 55 56 53 VPCO VCKI XTSL XTAO XTAI FSTT Block Diagram 23 AVDD FSOF 57 21 AVSS Clock generator C16M 58 33 VDD 32K RAM PDO 11 VCOO 8 73 VDD Digital PLL vari-pitch double speed PCO 20 EFM demodulator Address generator Priority encoder Serial/parallel processor 9 Register VCOI FILI 19 8 FILO 18 Sync protector CLTV 22 D/A data processor RF 24 ASYI 26 ∗ 12 VSS 52 VSS 30 PSSL DA01 to 16 16 68 MUTE MIX ASYO 27 ASYE 28 Peak detector Timing generator 1 WFCK 62 SCOR 63 Digital out Subcode P-W processor EXCK 65 SBSO 64 EMPH 61 SQSO 66 Noise shaper TEST 10 DATO 79 CLKO 78 XLTO 4 ∗ Asymmetry FOK CNIN MIRR SEIN 1 correction. DA09 DA08 DA07 DA06 DA05 DA04 DA03 SENS 75 69 80 76 WDCK DA02 DA01 APTL LRCK APTR APTR VSS XTAI XTAO XTSL APTL LOCK FSTT C16M MD2 DOUT Pin Configuration 50 51 32 31 6 XRST SBSO BIAS TEST0 70 FSOF 13 25 EMPH 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 DA11 SQCK 67 38 DA12 MUTE 68 37 DA13 SENS 69 36 DA14 XRST 70 35 DA15 DATA 71 34 DA16 XLAT 72 33 VDD VDD 73 32 LRCK CLOK 74 31 WDCK SEIN 75 30 PSSL CNIN 76 29 NC DATO 77 28 ASYE XLTO 78 27 ASYO CLKO 79 26 ASYI MIRR 80 25 BIAS –2– RF AVDD CLTV AVSS PCO FILI FILO 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 VCKI 8 VPCO 7 NC 6 NC 5 VSS 4 TEST0 3 PDO 2 TEST 1 VCOI 39 VCOO DA10 66 NC 40 SQSO LOCK EXCK 65 MDS NC 77 Servo auto sequencer Timing generator 2 18-times ever sampling filter WFCK 5 MDP 4 MDS 72 XLAT MON MDP 74 CLOK CLV processor SCOR 2 FSW 3 FSW 71 DATA CPU interface FOK MON Error corrector Subcode Q processor SQCK 67 60 DOUT 59 MD2 CXD2510Q Pin Description Pin No. Symbol I/O Description 1 FOK I 2 FSW O Z, 0 Spindle motor output filter switching output. 3 MON O 1, 0 Spindle motor on/off control output. 4 MDP O 1, Z, 0 Spindle motor servo control. 5 MDS O 1, Z, 0 Spindle motor servo control. 6 LOCK O 1, 0 7 NC 8 VCOO O 9 VCOI I Analog EFM PLL oscillation circuit input. fLOCK = 8.6436MHz. 10 TEST I TEST pin. Normally GND. 11 PDO O 12 Vss 13 TEST0 — 14 NC — 15 NC — 16 VPCO O 17 VCKI I 18 FILO O 19 FILI I 20 PCO O 21 AVss 22 CLTV 23 AVDD 24 RF I EFM signal input. 25 BIAS I Constant current input of the asymmetry circuit. 26 ASYI I Asymmetry comparator voltage input. 27 ASYO O 28 ASYE I 29 NC 30 PSSL I 31 WDCK O 1, 0 D/A interface for 48-bit slot. Word clock f = 2Fs. 32 LRCK O 1, 0 D/A interface for 48-bit slot. LR clock f = Fs. 33 VDD Focus OK input. Used for SENS output and the servo auto sequencer. GFS is sampled at 460Hz; when GFS is high, this pin outputs a high signal. If GFS is low eight consecutive samples, this pin outputs low. — 1, 0 1, Z, 0 Analog EFM PLL oscillation circuit output. Analog EFM PLL charge pump output. GND 1, Z, 0 TEST output pin. Normally open. Variable pitch PLL charge pump output. Variable pitch clock input from the external VCO. fc center = 16.9344MHz. Analog Master PLL filter output. Master PLL filter input. 1, Z, 0 Master PLL charge pump output. Analog GND. I Master VCO control voltage input. Analog power supply (5V). 1, 0 EFM full-swing output (low = Vss, high = VDD). Low: asymmetry circuit off; high: asymmetry circuit on — Audio data output mode switching input. Low: serial output; high: parallel output. Power supply (5V). –3– CXD2510Q Pin No. Symbol 34 DA16 O 1, 0 DA16 (MSB) output when PSSL = 1. 48-bit slot serial data (two's complement, MSB first) when PSSL = 0. 35 DA15 O 1, 0 DA15 output when PSSL = 1. 36 DA14 O 1, 0 DA14 output when PSSL = 1. 64-bit slot serial data (two's complement, LSB first) when PSSL = 0. 37 DA13 O 1, 0 DA13 output when PSSL = 1. 64-bit slot bit clock when PSSL = 0. 38 DA12 O 1, 0 DA12 output when PSSL = 1. 64-bit slot LR clock when PSSL = 0. 39 DA11 O 1, 0 DA11 output when PSSL = 1. GTOP output when PSSL = 0. 40 DA10 O 1, 0 DA10 output when PSSL = 1. XUGF output when PSSL = 0. 41 DA09 O 1, 0 DA09 output when PSSL = 1. XPLCK output when PSSL = 0. 42 DA08 O 1, 0 DA08 output when PSSL = 1. GFS output when PSSL = 0. 43 DA07 O 1, 0 DA07 output when PSSL = 1. RFCK output when PSSL = 0. 44 DA06 O 1, 0 DA06 output when PSSL = 1. C2PO output when PSSL = 0. 45 DA05 O 1, 0 DA05 output when PSSL = 1. XRAOF output when PSSL = 0. 46 DA04 O 1, 0 DA04 output when PSSL = 1. MNT3 output when PSSL = 0. 47 DA03 O 1, 0 DA03 output when PSSL = 1. MNT2 output when PSSL = 0. 48 DA02 O 1, 0 DA02 output when PSSL = 1. MNT1 output when PSSL = 0. 49 DA01 O 1, 0 DA01 output when PSSL = 1. MNT0 output when PSSL = 0. 50 APTR O 1, 0 Aperture compensation control output. This pin outputs a high signal when the right channel is used. 51 APTL O 1, 0 Aperture compensation control output. This pin outputs a high signal when the left channel is used. 52 Vss 53 XTAI I 54 XTAO O 55 XTSL I 56 FSTT O 1, 0 2/3 frequency divider output for Pins 53 and 54. This pin does not change with the variable pitch. 57 FSOF O 1, 0 1/4 frequency divider output for Pins 53 and 54. This pin does not change with the variable pitch. 58 C16M O 1, 0 16.9344MHz output. This pin changes simultaneously with the variable pitch. 59 MD2 I 60 DOUT O 1, 0 Digital-out output. 61 EMPH O 1, 0 Outputs a high signal when the playback disc has emphasis, and a low signal when there is no emphasis. 62 WFCK O 1, 0 WFCK (write frame clock) output. 63 SCOR O 1, 0 Outputs a high signal when either subcode sync S0 or S1 is detected. 64 SBSO O 1, 0 Sub P to W serial output. 65 EXCK I I/O Description 48-bit slot bit clock when PSSL = 0. GND 16.9344MHz crystal oscillation circuit input. Also the 33.8688MHz input. 1, 0 16.9344MHz crystal oscillation circuit output. Crystal selector input. The crystal is low for 16.9344MHz, and high for 33.8688MHz. Digital-out on/off control. High: on; low: off SBSO readout clock input. –4– CXD2510Q Pin No. Symbol 66 SQSO O 67 SQCK I SQSO readout clock input. 68 MUTE I High: mute; low: release 69 SENS — 70 XRST I System reset. Reset when low. 71 DATA I Serial data input from CPU. 72 XLAT I Latch input from CPU. Serial data is latched at the falling edge. 73 VDD 74 CLOK I Serial data transfer clock input from CPU. 75 SEIN I SENS input from SSP. 76 CNIN I Track jump count signal input. 77 DATO O 1, 0 Serial data output to SSP. 78 XLTO O 1, 0 Serial data latch output to SSP. Latched at the falling edge. 79 CLKO O 1, 0 Serial data transfer clock output to SSP. 80 MIRR I I/O 1, 0 1, Z, 0 Description Sub Q 80-bit and PCM peak and level data 16-bit output. SENS output to CPU. Power supply (5V). Mirror signal input. Notes) • The 64-bit slot is an LSB first, two's complement output, and the 48-bit slot is an MSB first, two's complement output. • GTOP is used to monitor the frame sync protection status. (High: sync protection window open.) • XUGF is the negative pulse for the frame sync obtained from the EFM signal. It is the signal before sync protection. • XPLCK is the inverse of the EFM PLL clock. The PLL is designed so that the falling edge and the EFM signal transition point coincide. • GFS goes high when the frame sync and the insertion protection timing match. • RFCK is derived from the crystal accuracy, and has a cycle of 136µ. • C2PO represents the data error status. • XRAOF is generated when the 32K RAM exceeds the ±28F jitter margin. –5– CXD2510Q Electrical Characteristics DC Characteristics (VDD = AVDD = 5.0V ± 10%, Vss = AVss = 0V, Topr = –20 to +75°C) Item Conditions Input voltage (1) High level input voltage VIH (1) Low level input voltage VIL (1) Input voltage (2) High level input voltage VIH (2) Low level input voltage VIL (2) Input voltage VIN (3) Output voltage (1) High level output voltage VOH (1) IOH = –1mA Low level output voltage VOL (1) IOL = 1mA Output voltage (2) High level output voltage VOH (2) IOH = –1mA Low level output voltage Input voltage (3) Output voltage (3) Output voltage (4) Min. Typ. Max. 0.7VDD V 0.3VDD Schmitt input Unit 0.8VDD Applicable pins ∗1 V V ∗2 0.2VDD V Vss VDD V ∗3 VDD – 0.5 VDD V ∗4 0 0.4 V VDD – 0.5 VDD V VOL (2) IOL = 2mA 0 0.4 V Low level output voltage VOL (3) IOL = 2mA 0 0.4 V ∗6 High level output voltage VOH (4) IOH = –0.28mA VDD – 0.5 VDD V ∗7 Low level output voltage VOL (4) IOL = 0.36mA 0 0.4 V Analog input ∗5 Input leak current ILI VI = 0 to 5.50V –5 5 µA ∗1, 2, 3 Tri-state pin output leak current ILO VO = 0 to 5.50V –5 5 µA ∗8 Applicable pins ∗1 XTSL, DATA, XLAT, MD2, PSSL ∗2 CLOK, XRST, EXCK, SQCK, MUTE, FOK, SEIN, CNIN, MIRR, VCKI, ASYE ∗3 CLTV, FILI, RF ∗4 MDP, PDO, PCO, VPCO ∗5 ASYO, DOUT, FSTT, FSOF, C16M, SBSO, SQSO, SCOR, EMPH, MON, LOCK, WDCK, DATO, CLKO, XLTO, SENS, MDS, DA01 to DA16, APTR, APTL, LRCK, WFCK ∗6 FSW ∗7 FILO ∗8 SENS, MDS, MDP, FSW, PDO, PCO, VPCO –6– CXD2510Q AC Characteristics 1. XTAI pin, VCOI pin (1) When using self-oscillation (Topr = –20 to +75°C, VDD = AVDD = 5.0V ± 10%) Item Symbol Oscillation frequency Min. fMAX Typ. 7 Max. Unit 34 MHz (2) When inputting pulses to XTAI and VCOI (Topr = –20 to +75°C, VDD = AVDD = 5.0V ± 10%) Item Symbol Min. Typ. Max. Unit High level pulse width tWHX 13 500 ns Low level pulse width tWLX 13 500 ns Pulse cycle tCX 26 1,000 ns Input high level VIHX VDD – 1.0 Input low level VILX 0.8 V Rise time, fall time tR, tF 10 ns V tCX tWLX tWHX VIHX VIHX × 0.9 VDD/2 XTAI VIHX × 0.1 VILX tR tF (3) When inputting sine waves to XTAI and VCOI pins via a capacitor (Topr = –20 to +75°C, VDD = AVDD = 5.0V ± 10%) Item Input amplitude Symbol Min. VI 2.0 Typ. Max. Unit VDD+0.3 Vp-p –7– CXD2510Q 2. CLOK, DATA, XLAT, CNIN, SQCK EXCK pins (VDD = AVDD = 5.0V ± 10%, VSS = AVSS = 0V, Topr = –20 to +75°C) Item Symbol Clock frequency fCK Clock pulse width Latch pulse width tWCK tSU tH tD tWL EXCK SQCK frequency fT Setup time Hold time Delay time Min. Typ. Max. Unit 0.65 MHz 750 ns 300 ns 300 ns 300 ns 750 ns 0.65 EXCK SQCK pulse width tWT CNIN freqency ∗ fT CNIN pulse width ∗ tWT 750 MHz ns 65 7.5 kHz µs ∗ When $44 and $45 are excuted. 1/fCK tWCK tWCK CLOK DATA XLAT tSU tH EXCK CNIN SQCK tD tWT tWL tWT 1/fT SBSO SQSO tSU tH Description of Functions §1. CPU Interface and Instructions • CPU interface This interface uses DATA, CLOK, and XLAT to set the modes. The interface timing chart is shown below. 750ns or more CLOK DATA D1 D2 Data D3 D0 D1 D2 D3 750ns or more Address XLAT Registers 4 to E Valid 300ns max • Information on each address and the data is provided in Table 1-1. • The internal registers are initialized by a reset when XRST = 0; the initialization data is shown in Table 1-2. –8– 0 Auto sequence (N) track jump count setting MODE specification 7 8 –9– 1 1 Audio CTRL Traverse monitor counter setting Spindle servo coefficient setting CLV CTRL CLV mode A B C D E 1 1 1 Function specification 9 1 1 0 0 Sled_kick, brake (D) Kick (F) Brake (B) Blind (A, E), Overflow (C, G) 6 5 0 4 Auto sequence D3 Command Register name Command Table 1 1 1 0 0 0 0 1 1 1 1 D2 1 0 0 1 1 0 0 1 1 0 0 D1 Address 0 1 0 1 0 1 0 1 0 1 0 D0 D2 D1 D0 D3 D2 D1 Data 2 D0 D3 TR2 TR1 TR0 — KF2 — DOUT D.out WSEL Mute Mute-F 0 — Table 1-1. CM3 CM2 CM1 CM0 TP — TB Gain CLVS DCLV PWM MD 0 Gain Gain Gain Gain MDP1 MDP0 MDS1 MDS0 — — Gain DCLV0 — — 0 32,76816,384 8,192 4,096 2,048 1,024 512 Vari Vari Mute ATT PCT1 PCT2 Up Down BiliGL FLFC MAIN SUB VCO ASHS SOCT SEL DCLV DSPB ASEQ DPLL BiliGL ON-OFF ON-OFF ON-OFF ON-OFF CDROM — — — 0 256 0 0 0 256 KF1 KF0 — 32,76816,384 8,192 4,096 2,048 1,024 512 SD3 SD2 SD1 SD0 KF3 TR3 — — — 128 — — — 128 — — AS3 AS2 AS1 AS0 MT3 MT2 MT1 MT0 LSSL D3 Data 1 — — — 64 — — — 64 — — 0 D2 — — — 32 — — — 32 — — 0 D1 Data 3 — — — 16 — — — 16 — — 0 D0 — — — 8 — — — 8 — — — D3 — — — 4 — — — 4 — — — D2 — — — 2 — — — 2 — — — D1 Data 4 — — — 1 — — — 1 — — — D0 CXD2510Q 1 1 1 1 1 1 Audio CTRL Traverse monitor counter setting Servo coefficient setting CLV CTRL CLV mode A B C D E 1 MODE specification 8 Function specification 0 Auto sequence (N) track jump count setting 7 9 0 0 Sled_kick, brake (D) Kick (F) Brake (B) Blind (A, E), Overflow (C, G) 6 5 0 4 Auto sequence D3 Command Register name Reset Initialization – 10 – 1 1 1 0 0 0 0 1 1 1 1 D2 1 0 0 1 1 0 0 1 1 0 0 D1 Address 0 1 0 1 0 1 0 1 0 1 0 D0 0 0 0 0 0 1 0 0 0 0 0 D3 0 0 1 0 0 0 0 0 1 1 0 D2 0 0 1 0 1 0 0 0 1 0 0 0 0 0 0 1 1 0 0 1 1 0 D0 — — 0 0 0 0 0 0 0 — 0 D3 Table 1-2. D1 Data 1 — — 0 0 0 0 0 0 0 — 0 D2 — — 0 0 0 0 0 0 0 — 0 D1 Data 2 — — 0 1 0 0 0 1 0 — 0 D0 — — — — — — 0 — — 0 — — — — 0 — — — D2 0 — — 0 D3 — — — 0 — — — 0 — — — D1 Data 3 — — — 0 — — — 0 — — — D0 — — — 0 — — — 0 — — — D3 — — — 0 — — — 0 — — — D2 — — — 0 — — — 0 — — — D1 Data 4 — — — 0 — — — 0 — — — D0 CXD2510Q CXD2510Q The meaning of the data for each address is explained below. $4X commands Register name 4 AS3 Data 1 Data 2 Data 3 Command MAX timer value Timer range AS2 AS1 Command AS0 MT3 MT2 MT1 MT0 LSSL 0 0 AS3 AS2 AS1 AS0 Cancel 0 0 0 0 FineSearch 0 1 0 RXF Focus-On 0 1 1 1 1 TrackJump 1 0 0 RXF 10 TrackJump 1 0 1 RXF 2N TrackJump 1 1 0 RXF 0 RXF = 0 Forward RXF = 1 Reverse • When the FOCUS-ON command ($47) is canceled, $02 is sent and the auto sequence is interrupted. • When the TRACK JUMP commands ($44 to $45, $48 to $4D) are canceled, $25 is sent and the auto sequence is interrupted. Max. timer value Timer range MT3 MT2 MT1 MT0 LSSL 0 0 0 23.2ms 11.6ms 5.8ms 2.9ms 0 0 0 0 1.49s 0.74s 0.37s 0.18s 1 0 0 0 • To invalidate the MAX timer, set the MAX timer value to 0. $5X commands Timer TR3 TR2 TR1 TR0 Blind (A, E), Overflow (C, G) 0.18ms 0.09ms 0.045ms 0.022ms Brake (B) 0.36ms 0.18ms 0.09ms 0.045ms $6X commands Register name 6 SD3 Data 1 Data 2 KICK (D) KICK (F) SD2 SD1 Timer SD0 KF3 KF2 KF1 KF0 SD3 SD2 SD1 SD0 When executing KICK (D) $44 or $45 23.2ms 11.6ms 5.8ms 2.9ms When executing KICK (D) $4C or $4D 11.6ms 5.8ms 2.9ms 1.45ms Timer KF3 KF2 KF1 KF0 0.72ms 0.36ms 0.18ms 0.09ms KICK (F) – 11 – CXD2510Q $7X commands Auto sequence track jump count setting Data 1 Command Data 2 Data 3 Data 4 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 Auto sequencer track jump count setting 215 214 213 212 211 210 29 28 27 26 25 24 23 22 21 20 This command is used to set N when a 2N track jump is executed, and the jump count setting when fine search is executed for auto sequence. • The maximum track count is 65,535, but note that with 2N track jumps the maximum track jump count is determined by the mechanical limitations of the optical system. • When N is from 0 to 15, the number of 2N track jumps is counted according to the signals input from the CNIN pin. When N is 16 or over, it is counted according to the signals input from the MIRR pin. $8X commands Data 1 Command MODE specification Data 2 D3 D2 D1 CDROM DOUT Mute D.out Mute-F D0 D3 WSEL VCO SEL D2 D1 D0 ASHS SOCT 0 Command bit C2PO timing CDROM = 1 See the Timing Chart 1-3 CDROM mode; average value interpolation and pre-value hold are not performed. CDROM = 0 See the Timing Chart 1-3 Audio mode; average value interpolation and pre-value hold are performed. Command bit Processing Processing DOUT Mute = 1 When Digital out is on (MD2 pin = 1), DOUT output is muted. DOUT Mute = 0 When Digital out is on, DOUT output is not muted. Command bit Processing D. out Mute F = 1 When Digital out is on (MD2 pin = 1), DA output is muted. D. out Mute F = 0 DA output mute is not affected when Digital out is either on or off. – 12 – CXD2510Q MD2 Other mute conditions∗ 0 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 0 1 0 0 0 1 0 1 0 1 1 0 0 1 1 1 1 0 0 0 1 0 0 1 1 0 1 0 1 0 1 1 1 1 0 0 1 1 0 1 1 1 1 0 1 1 1 1 DOUT Mute D.out Mute F DOUT output DA output 0dB off –∞dB 0dB 0dB –∞dB 0dB –∞dB –∞dB ∗ See mute conditions (1), (2), and (4) to (6) under $AX commands for other mute conditions. Command bit Sync protection window width Application WSEL = 1 ±26 channel clock∗ Anti-rolling is enhanced. WSEL = 0 ±6 channel clock Sync window protection is enhanced. ∗ In normal-speed playback, channel clock = 4.3218MHz. Command bit Processing Use VCOSEL = 0 The built-in VCO is set to normal-speed. Used for normal-speed and double-speed (double correction) playback. VCOSEL = 1 The built-in VCO is set to high-speed. Used for quadruple-speed and double-speed (quadruple correction) playback. Command bit Function Use ASHS = 0 The command transfer rate to SSP is set Used for normal-speed and double-speed to normal-speed. (double correction) playback. ASHS = 1 The command transfer rate to SSP is set Used for quadruple-speed and double-speed to half-speed. (quadruple correction) playback. Command bit Function SOCT = 0 Sub Q is output from the SQSO pin. SOCT = 1 Each output signal is output from the SQSO pin. Input the readout clock to SQCK. (See the Timing Chart 2-4.) – 13 – CXD2510Q $9X commands Command Data 1 D3 D2 Data 2 D1 Function DCLV DSPB A.SEQ D.PLL specifications ON-OFF ON-OFF ON-OFF ON-OFF Command bit DCLV on/off = 0 DCLV on/off = 1 (FSW, MON not required) D3 D2 D1 D0 BiliGL MAIN BiliGL SUB FLFC 0 D0 CLV mode Contents During CLVS mode FSW = low, MON = high, MDS = Z; MDP = servo control signal, carrier frequency of 230Hz at TB = 0, and 460Hz at TB = 1. During CLVP mode FSW = Z, MON = high; MDS = speed control signal, carrier frequency of 7.35kHz; MDP = phase control signal, carrier frequency of 1.8kHz. During CLVS and CLVP modes MDS = PWM polarity signal, carrier frequency of When DCLV 132kHz. PWM and MD = 1 MDP = PWM absolute value output (binary), carrier frequency of 132kHz. MDS = Z When DCLV MDP = ternary PWM output, carrier frequency PWM and MD = 0 of 132kHz. When DCLV on/off = 1 for the Digital CLV servo, the sampling frequency of the internal digital filter switches simultaneously with the CLVP/CLVS switching. Therefore, the cut-off frequency for the CLVS is fc = 70Hz when TB = 0, and fc = 140Hz when TB = 1. Command bit Processing DSPB = 0 Normal-speed playback, C2 error correction quadruple correction, variable pitch possible. DSPB = 1 Double-speed playback, C2 error correction double correction, variable pitch prohibited. FLFC is normally 0. – 14 – CXD2510Q SENS output Microcomputer serial register value (latching not required) ASEQ = 0 ASEQ = 1 $0X Z SEIN (FZC) $1X Z SEIN (A.S) $2X Z SEIN (T.Z.C) $3X Z SEIN (SSTOP) $4X Z XBUSY $5X Z FOK $6X Z SEIN (Z) $AX GFS GFS $BX COMP COMP $CX COUT COUT $EX OV64 OV64 $7X, 8X, 9X, DX, FX Z 0 Description of SENS signals SENS output Meaning Z The SENS pin is high impedance. XBUSY Low while the auto sequencer is in operation, high when operation terminates. FOK Outputs the same signal as the FOK pin. High for "focus OK". GFS High when the played back frame sync is obtained with the correct timing. COMP Measures the number of tracks set with Reg B. High when Reg B is latched, low when the initial Reg B number is input by CNIN. COUT Measures the number of tracks set with Reg B. High when Reg B is latched, toggles each time the Reg B number is input by CNIN. While $44 and $45 are being executed, toggles with each CNIN 8-count instead of the Reg B number. OV64 Low when the EFM signal, after passing through the sync detection filter, is lengthened by 64 channel clock pulses or more. Command bit Meaning DPLL = 0∗ RFPLL is analog. PDO, VCOI and VCOO are used. DPLL = 1 RFPLL is digital. PDO is impedance. ∗ External parts for Pins 18 to 20 are required even when analog PLL is selected. Command bit BiliGL MAIN = 0 BiliGL MAIN = 1 BiliGL SUB = 0 STEREO MAIN BiliGL SUB = 1 SUB Mute Definition of bilingual capable MAIN, SUB and STEREO: The left channel input is output to the left and right channels for MAIN. The right channel input is output to the left and right channels for SUB. The left and right channel inputs are output to the left and right channels for STEREO. – 15 – CXD2510Q $AX commands Data 1 Command Audio CTRL Data 2 D3 D2 D1 D0 D3 D2 D1 D0 Vari Up Vari Down Mute ATT PCT1 PCT2 0 0 XTal 0% VCO 0% +0.1% +0.2% +0.3% +0.2% +0.1% +0% Vari Up Vari Down Pitch Command bit Command bit Meaning Mute = 0 Mute off if other mute conditions are not set. Mute = 1 Mute on. Peak register reset. –0.1% –0.2% XTal 0% Meaning ATT = 0 Attenuation off. ATT = 1 –12dB Mute conditions (1) When register A mute = 1. (2) When MUTE pin = 1. (3) When register 8 D.out mute = 1 and the Digital out is on (MD2 pin = 1). (4) When GFS stays low for over 35ms (at normal speed). (5) When register 9 BiliGL MAIN = Sub = 1. (6) When register A PCT1 = 1 and PCT2 = 0. (1) to (4) perform zero-cross muting with a 1ms time limit. Command bit Meaning PCM Gain ECC correction ability Normal mode × 0dB C1: double; C2: quadruple 1 Level meter mode × 0dB C1: double; C2: quadruple 1 0 Peak meter mode Mute C1: double; C2: double 1 1 Normal mode × 0dB C1: double; C2: double PCT1 PCT2 0 0 0 Description of level meter mode (see the Timing Chart 1-4.) • When this LSI is set to this mode, it can possess digital level meter functions. • When the 96-bit clock is input to SQCK, 96 bits of data are output to SQSO. The initial 80 bits of data are Sub Q data (see §2. Subcode Interface). The last 16 bits are LSB first 15-bit PCM data (absolute values). The final bit is PCM data. However, it is high when generated by the left channel and low when generated by the right channel. • PCM data is reset and the L/R flag is reversed after one readout. The maximum value for this status is then measured until the next readout. – 16 – CXD2510Q Description of peak meter mode (see the Timing Chart 1-5.) • When the LSI is set to this mode, the maximum PCM data value is detected regardless of if it comes from the left or right channel. The 96-bit clock must be input to SQCK to read out this data. • When the 96-bit clock is input, 96 bits of data are output to SQSO and the LSI internal register is reset. In other words, the PCM maximum value detection register is not reset by the readout. • To reset the PCM maximum value register, set PCT1 = PCT2 = 0 or set the $AX mute. • The Sub Q absolute time is automatically controlled in this mode. In other words, after the maximum value is generated, the absolute time for CRC to become OK is retained in the memory. Relative time operates as normal. • The final bit (L/R flag) of the 96-bit data is normally 0. • The pre-value hold and average value interpolation data are fixed to level (–∞) for this mode. $BX commands This command sets the traverse monitor count. Data 1 Command Data 2 Data 3 Data 4 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 Traverse monitor count setting 215 214 213 212 211 210 29 28 27 26 25 24 23 22 21 20 • When the set number of tracks are counted during fine search, the sled control for the traverse cycle control goes off. • The traverse monitor count is set when the traverse status is monitored by the SENS output COMP and COUT. $CX commands Data 1 Command D3 D1 D2 Data 2 D0 Servo coefficient Gain Gain Gain Gain MDP1 MDP0 MDS1 MDS0 setting D3 D2 D1 D0 0 Gain DCLV0 0 0 Gain CLVS CLV CTRL ($DX) Explanation Valid only when DCLV = 1. Valid when DCLV = 1 or 0. The spindle servo gain is externally set when DCLV = 1. • CLVS mode gain setting: GCLVS Gain MDS1 Gain MDS0 Gain CLVS GCLVS 0 0 0 –12dB 0 0 1 –6dB 0 1 0 –6dB 0 1 1 0dB 1 0 0 0dB 1 0 1 +6dB Note) When DCLV = 0, the CLVS gain is as follows. When Gain CLVS = 0, GCLVS = –12dB. When Gain CLVS = 1, GCLVS = 0dB. – 17 – CXD2510Q • CLVP mode gain setting: GMDP: GMDS Gain MDP1 Gain MDP0 GMDP Gain MDS1 Gain MDS0 GMDS 0 0 –6dB 0 0 –6dB 0 1 0dB 0 1 0dB 1 0 +6dB 1 0 +6dB • DCLV overall gain setting: GDCLV Gain DCLV0 GDCLV 0 0dB 1 +6dB $DX commands Command D3 D2 D1 D0 CLV CTRL DCLV PWM MD TB TP Gain CLVS See the $CX commands Command bit Explanation (See the Timing Chart 1-6.) DCLV PWM MD = 1 Digital CLV PWM mode specified. Both MDS and MDP are used. DCLV PWM MD = 0 Digital CLV PWM mode specified. Ternary MDP values are output. Command bit Explanation TB = 0 Bottom hold in CLVS and CLVH modes at a cycle of RFCK/32. TB = 1 Bottom hold in CLVS and CLVH modes at a cycle of RFCK/16. TP = 0 Peak hold in CLVS mode at a cycle of RFCK/4. TP = 1 Peak hold in CLVS mode at a cycle of RFCK/2. Note) Peak hold is performed at 34kHz in CLVH mode. – 18 – CXD2510Q $EX commands Command D3 D2 D1 D0 CLV mode CM3 CM2 CM1 CM0 CM3 CM2 CM1 CM0 Mode Explanation 0 0 0 0 STOP See the Timing Chart 1-7. 1 0 0 0 KICK See the Timing Chart 1-8. 1 0 1 0 BRAKE See the Timing Chart 1-9. 1 1 1 0 CLVS 1 1 0 0 CLVH 1 1 1 1 CLVP 0 1 1 0 CLVA STOP KICK BRAKE CLVS CLVP CLVA : Spindle motor stop mode. : Spindle motor forward rotation mode. : Spindle motor reverse rotation mode. : Rough servo mode. When the RF-PLL circuit lock is disengaged, this mode is used to pull the disc rotations within the RF-PLL capture range. : PLL servo mode. : Automatic CLVS/CLVP switching mode. This mode is normally used during playback. – 19 – – 20 – C2PO CDROM = 1 C2PO CDROM = 0 WDCK LRCK Timing Chart 1-3 C2 Pointer for lower 8bits Rch C2 Pointer C2 Pointer for upper 8bits Rch 16bit C2 Pointer C2 Pointer for lower 8bits Lch C2 Pointer C2 Pointer for upper 8bits Lch 16bit C2 Pointer If C2 Pointer = 1, data is NG 48 bit slot CXD2510Q – 21 – SQSO SQCK WFCK SQSO CRCF SQCK Timing Chart 1-4 2 L/R 2 3 Sub Q Data See "Sub Code Interface" 3 96 bit data Hold section 1 96 clock pulses 1 D0 CRCF 81 D2 1 Level Meter Timing 16 bit 96 clock pulses D1 Peak data of this section 80 D4 D5 D6 R/L 2 3 CRCF 15-bit peak-data Absolute value display, LSB first D3 750ns to 120µs D13 D14 L/R Peak data L/R flag 96 CXD2510Q SQCK WFCK – 22 – 96 clock pulses Measurement CRCF Timing Chart 1-5 1 2 3 Peak Meter Timing Measurement CRCF 96 clock pulses 1 2 3 Measurement CRCF CXD2510Q CXD2510Q Timing Chart 1-6 DCLV PWM MD = 0 Z MDS n · 236 (ns) n = 0 to 31 Acceleration MDP Z 132kHz 7.6µs Deceleration DCLV PWM MD = 1 MDS Deceleration Acceleration MDP n · 236 (ns) n=0 to 31 7.6µs Output Waveforms with DCLV = 1 Timing Chart 1-7 DCLV = 0 STOP MDS Z MDP L FSW L MON L DCLV = 1 DCLV PWM MD = 0 STOP MDS Z MDP Z FSW and MON are the same as for DCLV = 0 – 23 – CXD2510Q DCLV = 1 DCLV PWM MD = 1 STOP MDS L MDP FSW and MON are the same as for DCLV = 0 Timing Chart 1-8 DCLV = 0 KICK MDS Z MDP H FSW L MON H DCLV = 1 DCLV PWM MD = 0 KICK Z MDS MDP H Z 7.6µs FSW and MON are the same as for DCLV = 0 DCLV = 1 DCLV PWM MD = 1 KICK H MDS MDP H L FSW and MON are the same as for DCLV = 0 – 24 – CXD2510Q Timing Chart 1-9 BRAKE DCLV = 0 MDS Z MDP L FSW L MON H DCLV = 1 DCLV PWM MD = 0 BRAKE MDS Z MDP Z L FSW and MON are the same as for DCLV = 0 DCLV =1 DCLV PWM MD = 1 L MDS MDP H L FSW and MON are the same as for DCLV = 0 – 25 – CXD2510Q §2. Subcode Interface This section explains the subcode interface. There are two methods for reading out a subcode externally. The 8-bit subcodes P to W can be read from SBSO by inputting EXCK. Sub Q can be read out after the CRC check of the 80 bits of information in the subcode frame. This is accomplished, after checking SCOR and CRCF, by inputting 80 clock pulses to SQCK and reading data from the SQSO pin. §2-1. P to W Subcode Read Data can be read out by inputting EXCK immediately after WFCK falls. (See the Timing Chart 2-1.) §2-2. 80-bit Sub Q read Fig. 2-2 shows the peripheral block of the 80-bit Sub Q register. • First, Sub Q, regenerated at one bit per frame, is input to the 80-bit serial/parallel register and the CRC check circuit. • 96-bit Sub Q is input, and if the CRC is OK, it is output to SQSO with CRCF = 1. In addition, the 80 bits are loaded into the parallel/serial register. When SQSO goes high after SCOR is output, the CPU determines that new data (which passed the CRC check) has been loaded. • In the CXD2510Q, when 80-bit data is loaded, the order of the MSB and LSB is inverted for each byte. As a result, although the sequence of bytes is the same, the bits within the bytes are now ordered LSB first. • Once the fact that the 80-bit data has been loaded is confirmed, SQCK is input so that the data can be read. In this LSI, the SQCK input is detected, and the retriggerable monostable multivibrator is reset during low. • The retriggerable monostable multivibrator has a time constant from 270 to 400µs. When the duration that SQCK is high is less than this time constant, the monostable multivibrator is kept reset; during this interval, the S/P register is not loaded into the P/S register. • While the monostable multivibrator is being reset, data cannot be loaded in the peak detection parallel/serial register or the 80-bit parallel/serial register. In other words, while reading out with a clock cycle shorter than the monostable multivibrator time constant, the register will not be rewritten by CRCOK and others. • In this LSI, the previously mentioned peak detection register can be connected to the shift-in of the 80-bit P/S register. Input and output for ring control 1 are shorted in peak meter or level meter mode. Ring control 2 is shorted in peak meter mode. This is because the register is reset with each readout in level meter mode, and to prevent readout destruction in peak meter mode. As a result, the 96-bit clock must be input in peak meter mode. • In addition, as previously mentioned, the absolute time after peak is generated is stored in the memory in peak meter mode. Fig. 2-3 shows the Timing Chart. • Although a clock is input from the SQCK pin to actually perform these operations, the high and low intervals for this clock should be between 750ns and 120µs. – 26 – CXD2510Q Timing Chart 2-1 Internal PLL clock 4.3218 ±DMHz WFCK SCOR EXCK 750ns max SBSO S0 · S1 Q R WFCK SCOR EXCK SBSO S0•S1 Q R S T U V W S0•S1 Same P1 Q R S T U V W P1 Same Subcode P.Q.R.S.T.U.V.W Read Timing – 27 – P2 P3 SUBQ Block Diagram 2-2 SI 8 (ASEC) LD Order Inversion 8 (AMIN) LD SUBQ LD – 28 – LD LD Peak detection 16 16 bit P/S register Monostable multivibrator 8 SI 8 8 Ring control 2 SHIFT 8 LD SO LOAD CONTROL CRCC 80 bit P/S Register 8 80 bit S/P Register SHIFT 8 CRCF Mix 8 ADDRS CTRL LD Ring control 1 ABS time load control for peak value H G F E D C B A A B C D E F G H SIN (AFRAM) SQCK SO SQSO CXD2510Q LD – 29 – SQSO SQCK SQCK SQSO SCOR WFCK Timing Chart 2-3 CRCF Monostable Multivibrator (Internal) CRCF1 1 2 3 2 1 ADR1 94 ADR2 ADR3 CTL0 270 to 400µs when SQCK = high. Register load forbidder CRCF1 Determined by mode 93 92 91 80 or 96 Clock 750ns to 120µs 300ns max ADR0 3 95 CTL1 96 CTL2 97 CTL3 CRCF2 98 CXD2510Q Signal 750ns or more C1F0 C1F1 C1F2 C2F0 C2F1 C2F2 FOK GFS LOCK EMPH – 30 – High when the frame sync and the insertion protection timing match. GFS is sampled at 460 Hz; when GFS is high, this pin outputs a high signal. If GFS is low eight consecutive samples, this pin outputs low. Outputs a high signal when the playback disc has emphasis. GFS LOCK EMPH C1F1 0 0 1 1 0 0 1 1 C1F2 0 0 0 0 1 1 1 1 1 0 1 0 1 0 1 0 C1F0 ; C1 pointer set ; C1 pointer set ; C1 pointer reset ; C1 pointer reset C1 correction impossible ; C1 pointer set Two C1 errors corrected ; C1 pointer set One C1 error corrected No C1 errors — — One C1 error corrected No C1 errors Description C2F1 0 0 1 1 0 0 1 1 C2F2 0 0 0 0 1 1 1 1 1 0 1 0 1 0 1 0 C2F0 ; C2 pointer reset C2 correction impossible ; C2 pointer set C2 correction impossible ; C1 pointer copy — Four C2 errors corrected ; C2 pointer reset Three C2 errors corrected ; C2 pointer reset Two C2 errors corrected ; C2 pointer reset ; C2 pointer set Description One C2 error corrected No C2 errors ∗ RF jitter amount, PER0 to PER7 is output in binary code.When RF jitter amount is little, value of binary code is small. Focus OK FOK RF jitter amount (used to adjust the focus bias). 8bit binary data in PER0 = LSB, PER7 = MSB. Explanation PER1 PER2 PER3 PER4 PER5 PER6 PER7 Internal signal latch PER0 PER0 to PER7 ∗ SQSO SQCK XLAT Set SQCK and EXCK high during this interval. Example: $802 latch Timing Chart 2-4 CXD2510Q CXD2510Q §3. Description of Other Functions §3-1. Channel Clock Regeneration by the Digital PLL Circuit • The channel clock is necessary for demodulating the EFM signal regenerated by the optical system. Assuming T as the channel clock cycle, the EFM signal is modulated in an integer multiple of T from 3T to 11T. In order to read the information in the EFM signal, this integer value must be read correctly. As a result, T, that is the channel clock, is necessary. In an actual player, PLL is necessary to regenerate the channel clock because the fluctuation in the spindle rotation alters the width of the EFM signal pulses. The block diagram of this PLL is shown in Fig. 3-1. The CXD2510Q has a built-in three-stage PLL. • The first-stage PLL regenerates the variable pitch. LPF and VCO are necessary as external parts. The minimum variable amount of the pitch is 0.1%. The output of this first-stage PLL is used as a reference for all clocks within the LSI. Input the XTAO output to the VCKI pin when variable pitch is not used. • The second-stage PLL regenerates a high-frequency clock needed by the third-stage digital PLL. • The third-stage PLL is a digital PLL that regenerates the actual channel clock, and has a ±150kHz (normal state) or more capture range. • The digital PLL has a secondary loop, and is controlled by the primary loop (phase) and the secondary loop (frequency). When FLFC = 1, the secondary loop can be turned off . • High-frequency components such as 3T and 4T may contain deviations. In such a case, turning the secondary loop off yields better playability. However, in this case the capture range becomes 50kHz. – 31 – CXD2510Q Block Diagram 3-1 16.9344MHz (384Fs) 1/4 1/1000 Phase comparator OSC X'Tal XTSL 1/4 1/1000 + n LPF VPCO VCO 19.78 to 13.26MHz VCKI 2/1 MUX Vari-Pitch Up down counter n = –217 to 168 Microcomputer control Vari-Pitch Phase comparator I/M I/N PCO FILI FILO VCO CLTV Digital PLL VDD RFPLL CXD2510Q – 32 – CXD2510Q §3-2. Frame Sync Protection • In a CD player operating at normal speed, a frame sync is recorded approximately every 136µs (7.35kHz). This signal is used as a reference to know which data is the data within a frame. Conversely, if the frame sync cannot be recognized, the data is processed as error data because the data cannot be recognized. As a result, recognizing the frame sync properly is extremely important for improving playability. • In the CXD2510Q, window protection and forward protection/backward protection have been adopted for frame sync protection. The adoption of these functions achieves very powerful frame sync protection. There are two window widths: one for cases where a rotational disturbance affects the player and the other for cases where there is no rotational disturbance (WSEL = 0/1). In addition, the forward protection counter is fixed to 13, and the backward protection counter to 3. In other words, when the frame sync is being played back normally and then cannot be detected due to scratches, a maximum of 13 frames are inserted. If frame sync cannot be detected for 13 frames or more, the window is released and the frame sync is resynchronized. In addition, immediately after the window is released and the resynchronization is executed, if a proper frame sync cannot be detected within 3 frames, the window is released immediately. §3-3. Error correction • In the CD format, one 8-bit data contains two error correction codes, C1 and C2. For C1 correction, the code is created with 28-byte information and 4-byte C1 parity. For C2 correction, the code is created with 24-byte information and 4-byte parity. Both C1 and C2 are Reed Solomon codes with a minimum distance of 5. • The CXD2510Q uses refined super strategy to achieve double correction for C1 and quadruple correction for C2. • In addition, to prevent C2 miscorrection, a C1 pointer is attached to data after C1 correction according to the C1 error status, the playback status of the EFM signal, and the operating status of the player. • The correction status can be monitored outside the LSI. See the Table 3-2. • When the C2 pointer is high, the data in question was uncorrectable. Either the pre-value was held or an average value interpolation was made for the data. MNT3 MNT2 MNT1 MNT0 0 0 0 0 No C1 errors ; C1 pointer reset 0 0 0 1 One C1 error corrected ; C1 pointer reset 0 0 1 0 — 0 0 1 1 — 0 1 0 0 No C1 errors ; C1 pointer set 0 1 0 1 One C1 error corrected ; C1 pointer set 0 1 1 0 Two C1 errors corrected ; C1 pointer set 0 1 1 1 C1 correction impossible ; C1 pointer set 1 0 0 0 No C2 errors ; C2 pointer reset 1 0 0 1 One C2 error corrected ; C2 pointer reset 1 0 1 0 Two C2 errors corrected ; C2 pointer reset 1 0 1 1 Three C2 errors corrected ; C2 pointer reset 1 1 0 0 Four C2 errors corrected ; C2 pointer reset 1 1 0 1 1 1 1 0 C2 correction impossible ; C1 pointer copy 1 1 1 1 C2 correction impossible ; C2 pointer set Description — Table 3-2. – 33 – CXD2510Q Timing Chart 3-3 Normal-speed PB 400 to 500ns RFCK t = Dependent on error condition MNT3 C1 correction C2 correction MNT2 MNT1 MNT0 Strobe Strobe §3-4. DA Interface • The CXD2510Q has two modes as DA interfaces. a) 48-bit slot interface This interface includes 48 cycles of the bit clock within one LRCK cycle, and is MSB first. When LRCK is high, the data is for the left channel. b) 64-bit slot interface This interface includes 64 cycles of the bit clock within one LRCK cycle, and is LSB first. When LRCK is low, the data is for the left channel. – 34 – R0 1 2 – 35 – DA16 WDCK DA15 (4.23M) LRCK (88.2K) R0 1 2 3 4 5 Lch MSB (15) Lch MSB (15) 48bit slot Double-Speed Playback DA16 WDCK DA15 (2.12M) LRCK (44.1K) 48bit slot Normal-Speed Playback PSSL = L Timing Chart 3-4 6 7 8 9 L14 10 L13 11 L12 12 L0 24 L11 L9 Rch MSB L10 L8 L7 L6 L5 L4 L3 L2 L1 L0 24 RMSB CXD2510Q – 36 – DA14 DA13 (5.64M) DA12 (88.2K) DA14 DA13 (2.82M) DA12 (44.1K) 2 3 4 5 L15 1 2 3 4 5 64 Bit slot Double- Speed PB 1 64 Bit slot Normal Speed PB PSSL = L Timing Chart 3-5 6 9 10 10 R ch LSB (0) 8 R ch LSB (0) 7 11 12 15 13 14 15 1 2 3 20 4 1 5 2 6 3 20 7 8 25 4 9 5 7 9 10 30 31 32 8 10 11 12 13 14 15 6 11 13 L ch LSB 12 30 32 14 R15 31 L ch LSB (0) CXD2510Q CXD2510Q §3-5. Digital Out There are three digital out formats: the type 1 format for broadcasting stations, the type 2 form 1 format for home use, and the type 2 form 2 format for the manufacture of software. The CXD2510Q supports type 2 form 1. In addition, regarding the clock accuracy of the channel status, level III is set automatically when the crystal clock is used and level II is variable pitch. In addition, Sub Q data which are matched twice in succession after a CRC check are input to the first four bits (bit 0 to 3). DOUT is output when the crystal is 34MHz, the variable pitch is reset, and DSPB = 1. Therefore, set MD2 to 0 and turn DOUT off. bit 0 to 3 -Sub Q control bits that matched twice with CRCOK Digital Out C bit 0 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0/1 0 0 From sub Q 0 ID0 16 1 0 ID1 COPY Emph 0 0 0 32 48 0 176 bit 0 to 3 – Sub Q control bits that matched twice with CRCOK bit29 – Varipitch: 1 X'Tal: 0 Table 3-6. §3-6. Servo Auto Sequence This function performs a series of controls, including auto focus and track jumps. When the auto sequence command is received from the CPU, auto focus, 1 track jump, 2N track jumps, and fine search are executed automatically. SSP (servo signal processor LSI) is used in an exclusive manner during the auto sequence execution (when XBUSY = low), so that commands from the CPU are not transferred to the SSP, but can be sent to the CXD2510Q. In addition, when using the auto sequence, connect the CPU, RF and SSP as shown in Fig. 3-7, and turn the A.SEQ of register 9 on. When CLOK goes from low to high while XBUSY is low, XBUSY does not become high for a maximum of 100µs after that point. This is designed to prevent the transfer of erroneous data to the SSP when XBUSY changes from low to high by the monostable multivibrator, which is reset by CLOK being low (when XBUSY is low). – 37 – CXD2510Q In addition, a MAX timer is built in as a countermeasure against abnormal operation due to external disturbances, etc. When the auto sequence command is sent from the CPU, this command assumes a $4XY format, in which X specifies the command and Y sets the MAX timer value and timer range. If the executed auto sequence command does not terminate within the set timer value, the auto sequence is interrupted (like $40). See §1-2, $4X commands concerning the timer value and range. Also, the MAX timer is invalidated by inputting $4X0. Although this command is explained in the format of $4X in the following command descriptions, the timer value and timer range are actually sent together from the CPU. (a) Auto focus ($47) Focus search up is performed, FOK and FZC are checked, and the focus servo is turned on. If $47 is received from the CPU, the focus servo is turned on according to Fig. 3-8. The auto focus is executed after focus search up, and the pickup should be lowered beforehand (focus search down). In addition, blind E of register 5 is used to eliminate FZC chattering. In other words, the focus servo is turned on at the falling edge of FZC after FZC has been continuously high for a longer time than E. Connection diagram for using the auto sequencer (example) RF MIRR FOK MIRR FOK DATA CXD2510Q CLOK Micro-computer XLAT SSP C. out CNIN SENS SEIN DATA DATO CLK CLKO XLT XLTO Fig. 3-7. – 38 – SENS CXD2510Q Auto focus Focus search up FOK = H NO YES FZC = H NO YES FZC = L Check whether FZC is continuously high for the period of time E set with register 5. NO YES Focus servo ON END Fig. 3-8. (a) Auto Focus Flow Chart $47latch XLAT FOK SEIN (FZC) BUSY Command for SSP Blind E $08 $03 Fig. 3-8. (b) Auto Focus Timing Chart – 39 – CXD2510Q (b) Track jump 1, 10, and 2N-track jumps are performed respectively. Always use this when focus, tracking, and sled servo are on. Note that tracking gain up and braking on ($17) should be sent beforehand because they are not performed. • 1-track jump When $48 ($49 for REV) is received from the CPU, a FWD (REV) 1-track jump is performed in accordance with Fig. 3-9. Set blind A and brake B with register 5. • 10-track jump When $4A ($4B for REV) is received from the CPU, a FWD (REV) 10-track jump is performed in accordance with Fig. 3-10. The principal difference between the 10-track jump and the 1-track jump is whether to kick the sled or not. In addition, after kicking the actuator, when 5 tracks have been counted through CNIN, the brake is applied to the actuator. Then, when the actuator speed is found to have slowed up enough (determined by the CNIN cycle becoming longer than the overflow C set in register 5), the tracking and sled servos are turned on. • 2N-track jump When $4C ($4D for REV) is received from the CPU, a FWD (REV) 2N-track jump is performed in accordance with Fig. 3-11. The track jump count "N" is set in register 7. Although N can be set to 216 tracks, note that the setting is actually limited by the actuator. CNIN is used for counting the number of jumps when N is less than 16, and MIRR is used when N is 16 or higher. Although the 2N-track jump basically follows the same sequence as the 10-track jump, the one difference is that after the tracking servo is turned on, the sled continues to move only for "D", set in register 6. • Fine search When $44 ($45 for REV) is received from the CPU, a FWD (REV) fine search (N-track jump) is performed in accordance with Fig. 3-12. The one difference from a 2N-track jump is that a higher precision is achieved by controlling the traverse speed. The track jump count is set in register 7. N can be set to 216 tracks. After kicking the actuator and sled, the traverse speed is controlled based on the overflow G. Set kick D and F in register 6 and overflow G in register 5. After N tracks have been counted through CNIN, the brake is applied to the actuator and sled. This is performed by turning the tracking servo for the actuator on, and by kicking the sled in the opposite direction. The cancel command $40 is sent from the CPU when track jump is terminated. Set overflow G to the speed required to slow up just before the track jump terminates. The speed should be such that it will come on-track when the tracking servo turns on at the termination of the track jump. (Set the target track count N-α for the traverse monitor counter which is set in register B, and COMP will be monitored. When the falling edge of this COMP is detected, overflow G can be reset.) – 40 – CXD2510Q 1 Track Track kick sled servo (REV kick for REV jump) WAIT (Blind A) CNIN = NO YES Track REV kick (FWD kick for REV jump) WAIT (Brake B) Track sled servo ON END Fig. 3-9. (a) 1-Track Jump Flow Chart $48 (REV = $49) latch XLAT CNIN BUSY Brake B Blind A Command for SSP $28 ($2C) $2C ($28) Fig. 3-9. (b) 1-Track Jump Timing Chart – 41 – $25 CXD2510Q 10 Track Track, sled FWD kick WAIT (Blind A) CNIN = 5 ? NO (Counts CNIN × 5) NO Checks whether the CNIN cycle is longer than overflow C. YES Track, REV kick C = Overflow ? YES Track, sled servo ON END Fig. 3-10. (a) 10-Track Jump Flow Chart $4A (REV = $4B) latch XLAT CNIN BUSY Blind A CNIN 5count Overflow C Command for SSP $2E ($2B) $2A ($2F) Fig. 3-10. (b) 10-Track Jump Timing Chart – 42 – $25 CXD2510Q 2N Track Track, sled FWD kick WAIT (Blind A) CNIN (MIRR) = N NO Counts CINI for the first 16 times and MIRR for more times. YES Track REV kick C = Overflow NO YES Track servo ON WAIT (Kick D) Sled servo ON END Fig. 3-11. (a) 2N-Track Jump Flow Chart $4C (REV = $4D) latch XLAT CNIN (MIRR) BUSY Blind A Command $2A ($2F) for SSP CNIN (MIRR) N count Overflow $2E ($2B) $26 ($27) Fig. 3-11. (b) 2N-Track Jump Timing Chart – 43 – Kick D $25 CXD2510Q Fine Search Track Servo ON Sled FWD Kick WAIT (Kick D) Track Sled FWD Kick WAIT (Kick F) Traverse Speed Ctrl (Overflow G) CNIN = N ? NO YES Track Servo ON Sled REV Kick Track jump is terminated by sending and latching $40 from the CPU. END Fig. 3-12. (a) Fine Search Flow Chart $44 (REV = $45) latch $40 (cancel) latch XLAT CNIN Kick D $26 ($27) Command for SSP Kick F Traverse Speed Control (Overflow G) & CNIN N count $2A ($2F) $27 ($26) $25 Fig. 3-12. (b) Fine Search Timing Chart – 44 – CXD2510Q §3-7. Digital CLV Fig. 3-13 shows the block diagram. Digital CLV makes PWM output in CLVS, CLVP and other modes with the MDS error or MDP error signal sampling frequency increased to 130kHz during normal-speed operation. In addition, the digital spindle servo can set the gain. Digital CLV CLVS U/D Gain CLVS CLV P/S MDS Error MDP Error Measure Measure Over Sampling Filter-1 2/1 MUX Gain MDS Gain MDP 1/2 CLV P Mux CLV S Gain DCLV Over Sampling Filter-2 CLV-P/S Noise Shape KICK, BRAKE STOP Modulation Mode Select DCLVMD CLVS U/D: Up/down signal from the CLV-S servo. MDS error: Frequency error for CLV-P servo. MDP error: Phase error for CLV-P servo. Fig. 3-13. Block Diagram – 45 – MDP MDS CXD2510Q §3-8. Asymmetry Compensation Fig. 3-14 shows the block diagram and circuit example. D2510 28 ASYE ASYO 27 R1 RF 24 R1 R2 R1 ASYI 26 R1 25 BIAS R1 2 = R2 5 Fig. 3-14. Example of an Asymmetry Compensation Application Circuit §3-9. Playback Speed In the CXD2510Q, the following playback modes can be selected through different combinations of the crystal, XTSL pin, double-speed command (DSPB), VCO selection command (VCOSEL) and command transfer rate selector (ASHS). Also, the minimum operating voltage changes according to the playback mode. (See the Recommended Operating Conditions.) Playback modes Mode X'tal XTSL DSPB VCOSEL ASHS Playback speed 1 768Fs 1 0 0/1 0 ×1 C1: double; C2: quadruple 2 768Fs 1 1 0/1 0 ×2 C1: double; C2: double 3 768Fs 0 0 1 1 ×2 C1: double; C2: quadruple 4 768Fs 0 1 1 1 ×4 C1: double; C2: double 5 384Fs 0 0 0/1 0 ×1 C1: double; C2: quadruple 6 384Fs 0 1 0/1 0 ×2 C1: double; C2: double 7 384Fs 1 1 0/1 0 ×1 C1: double; C2: double However, Fs = 44.1kHz. – 46 – Error correction GND SSTOP GND SPIND-D GND SLED-D GND FOCUS-D GND TRACK-D TD GND R5 R2 R1 GND R9 GND TG2 AVCC TA0 TA– 10 11 12 R14 R11 C35 GND GND R10 GND R6 C28 TGU SRCH 8 7 FE– FLB 4 FEO FS3 5 FGD 2 3 6 VC 1 9 C27 C23 C26 C10 C9 GND R7 GND SLD SPD FD C15 C16 VCC RF TE CXA1372AQ C13 R13 R12 GND R4 R3 28 27 26 25 SENS COUT XRST DFCT 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 GND VCOI 9 CXD2510Q FSTT VCOO 8 NC NC VPCO VCKI FILO FILI PCO 14 15 16 17 18 19 20 RF 24 GND 52 VSS 49 48 MNT0 MNT1 43 42 41 RFCK GFS XPLCK GND 45 44 C2PO 46 MNT3 MNT2 47 50 APTR APTL 51 53 XTAI 54 55 56 57 58 59 XRAOF 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 200p 1M AVDD 23 AVDD CLTV 22 AVSS TEST0 13 21 VSS 12 XTSL FSOF NC 7 XTAO C16M LOCK PDO MD2 MDS 5 6 TEST DOUT MDP 4 11 61 EMPH MON 3 10 63 WFCK 62 FSW 2 60 SBSO 64 SCOR FOK 1 DEMP LRCK DATA BCLK C2PO DOUT WFCK GTOP XUGF XPLCK GFS RFCK XRAOF Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. 13 14 15 16 17 18 19 20 21 22 23 24 29 MIRR 30 31 32 33 34 35 36 FOK DGND DFCT ASY EFM FOK CC2 CC1 DVCC C17 MIRR GND MIRR BIAS GND GND VDD CLKO ASYI RF XLTO ASYO LDON C14 48 47 46 45 44 43 42 41 40 39 38 37 C12 FDFCT SL+ GND FE SL0 MUTE DATO ASYE GND FZC SL– SQCK SEIN PSSL FE C11 ATSC FSET SUBQ CLOK WDCK(48) TDFCT ISET GFS VDD LRCK (48) VDD TE SSTOP CLK XLAT DATA (48) DVCC DIRC XLT DATA BCLK (48) TZC AVCC DATA XRST DATA (64) VO RF0 LOCK XRST SENS BCLK (64) VCC RF1 CLK SENS MUTE LRCK (64) TE CP XLT FOK SQCK GTOP GND CB DATA EXCK FE GND SCOR CNIN NC GND GND GND GND GND GND LDON SQSO XUGF RV2 VSS GND GND MUTE GND GND WDCK RV1 GND – 47 – VCC GND Application Circuit GND MNT3 MNT2 MNT1 MNT0 GND CXD2510Q CXD2510Q Unit: mm 80PIN QFP (PLASTIC) 23.9 ± 0.4 + 0.1 0.15 – 0.05 + 0.4 20.0 – 0.1 64 0.15 41 65 16.3 + 0.4 14.0 – 0.1 17.9 ± 0.4 40 A 80 + 0.2 0.1 – 0.05 1 24 0.8 0.12 + 0.15 0.35 – 0.1 M 0.8 ± 0.2 25 + 0.35 2.75 – 0.15 0° to 10° DETAIL A PACKAGE STRUCTURE SONY CODE QFP-80P-L01 EIAJ CODE ∗QFP080-P-1420-A JEDEC CODE PACKAGE MATERIAL EPOXY RESIN LEAD TREATMENT SOLDER PLATING LEAD MATERIAL COPPER / 42 ALLOY PACKAGE WEIGHT 1.6g QFP 80PIN (PLASTIC) 23.9 ± 0.2 ∗20.0 ± 0.2 0.15 ± 0.05 15° 24 1 0.35 ± 0.1 .2 15° 25 80 A 4 – 1.0 40 ∗14.0 ± 0.2 4 – 0.8 0.15 M 1.45 0.8 ± 0.15 0.15 0° to 10° DETAIL A NOTE: Dimension “∗” does not include mold protrusion. PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE QFP-80P-L051 LEAD TREATMENT SOLDER PLATING EIAJ CODE ∗QFP080-P-1420-AH LEAD MATERIAL 42 ALLOY PACKAGE WEIGHT 1.6g JEDEC CODE – 48 – 1.95 ± 0.15 15° 2.94 ± 0.15 15° 0.24 ± 0.15 + 0.20 2.7 – 0.16 17.9 ± 0.2 65 0.8 41 64 C1 Package Outline