CXD3009Q CD Digital Signal Processor Description The CXD3009Q is a digital signal processor LSI for CD players and is equipped with built-in digital filters, zero detection circuit, 1-bit DAC, and analog low-pass filter on a single chip. Features Digital Signal Processor (DSP) Block • Playback mode supporting CAV (Constant Angular Velocity) – Frame jitter-free – Allows 0.5 to double-speed continuous playback – Allows relative rotational velocity readout – Supports external spindle control • Wide capture range playback mode – Spindle rotational velocity following method – Supports normal-speed and double-speed playback • 16K RAM • EFM data demodulation • Enhanced EFM frame sync protection • SEC strategy-based error correction • Subcode demodulation and Sub Q data error detection • Digital spindle servo • 16-bit traverse counter • Asymmetry compensation circuit • Serial bus-based CPU interface • Error correction monitor signals, etc. are output from a new CPU interface. • Servo auto sequencer • Digital audio interface output • Digital peak meter • CD-TEXT data demodulation Digital Filter, DAC, Analog Low-Pass Filter Block • DBB (Digital Bass Boost) • Supports double-speed playback • Digital de-emphasis • Digital attenuation function • Zero detection function • 8Fs oversampling digital filter 80 pin QFP (Plastic) Structure Silicon gate CMOS IC Absolute Maximum Ratings –0.3 to +4.6 V • Supply voltage VDD • Input voltage VI –0.3 to +4.6 V (Vss – 0.3V to VDD + 0.3V) • Output voltage VO –0.3 to +4.6 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 Note) AVDD includes XVDD, and AVSS includes XVSS. Recommended Operating Conditions • Supply voltage VDD 2.5 to 3.6 • Operating temperature Topr –20 to +75 Input/Output Capacitances • Input capacitance CI 12 (max.) • Output capacitance CO 12 (max.) Note) Measurement conditions VDD = VI = 0V fM = 1MHz V °C pF pF Applications CD players 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– E97322B01-PS CXD3009Q PCMDI SYSM 55 40 42 44 62 BCKI EMPHI 43 LRCKI BCK 47 49 54 56 LRCK 50 39 41 C2PO WFCK EMPH GFS PCMD 27 28 XUGF V16M 51 25 26 VCTL VPCO VCKI XTSL Block Diagram 24 TES1 23 TEST OSC Clock Generator C4M 52 Error Corrector 79 XRST D/A Interface EFM demodurator RF 35 Serial-In Interface ASYI 37 ASYO 38 Asymmetry Corrector XPCK 48 Digital PLL FILI 31 3rd-Order Noise Shaper Digital OUT FILO 30 Sub Code Processor PCO 29 PWM CLTV 33 22 53 74 75 76 67 66 65 SQCK MDP PWMI DOUT LOUT2 AIN2 AOUT2 LOUT1 AOUT1 –2– AIN1 21 SQSO SPOA 4 SBSO XLAT 17 57 58 59 5 EXCK 9 15 16 SCOR 8 XLON 7 SPOB 6 CLOK PWM Digital CLV DATA CPU Interface SENS XLTO 12 13 14 CLKO CNIN 11 Servo Auto Sequencer DATO FOK 18 SEIN 10 LMUT 71 XTAO Over Sampling Digital Filter 16K RAM RMUT 2 70 XTAI Timing Logic BIAS 36 3 CXD3009Q PCMD PCMDI BCKI BCK Vss VDD XUGF XPCK GFS C2PO XTSL C4M DOUT EMPH EMPHI WFCK SCOR SBSO EXCK Vss Pin Configuration 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 VDD 61 40 LRCKI SYSM 62 39 LRCK AVss 63 38 ASYO AVDD 64 37 ASYI AOUT1 65 36 BIAS 35 RF AIN1 66 LOUT1 67 34 AVDD AVss 68 33 CLTV XVDD 69 32 AVss XTAI 70 31 FILI XTAO 71 30 FILO XVss 72 29 PCO AVss 73 28 VCTL LOUT2 74 27 V16M AIN2 75 26 VCKI AOUT2 76 25 VPCO AVDD 77 24 TES1 AVss 78 23 TEST XRST 79 22 PWMI VDD 80 –3– Vss VDD FOK XLON SPOB SPOA CLKO XLTO DATA 9 10 11 12 13 14 15 16 17 18 19 20 DATO SENS 8 SEIN 7 CNIN 6 XLAT 5 CLOK 4 SQCK 3 SQSO 2 LMUT Vss 1 RMUT 21 MDP CXD3009Q Pin Description Pin No. Symbol I/O Description GND 1 VSS — — 2 LMUT O 1, 0 Left-channel zero detection flag. 3 RMUT O 1, 0 Right-channel zero detection flag. 4 SQCK I 5 SQSO O 1, 0 Sub Q 80-bit serial output. 6 SENS O 1, 0 SENS output to CPU. 7 DATA I Serial data input from CPU. 8 XLAT I Latch input from CPU. Serial data is latched at the falling edge. 9 CLOK I Serial data transfer clock input from CPU. 10 SEIN I SENS input from SSP. 11 CNIN I Track jump count signal input. 12 DATO O 1, 0 Serial data output to SSP. 13 XLTO O 1, 0 Serial data latch output to SSP. Latched at the falling edge. 14 CLKO O 1, 0 Serial data transfer clock output to SSP. 15 SPOA I Microcomputer extended interface (input A). 16 SPOB I Microcomputer extended interface (input B). 17 XLON O 18 FOK I 19 VDD — — Power supply (+3V). 20 VSS — — GND 21 MDP O 22 PWMI I Spindle motor external control input. 23 TEST I TEST pin; normally GND. 24 TES1 I TEST pin; normally GND. 25 VPCO O 26 VCKI I 27 V16M O 28 VCTL I 29 PCO O 1, Z, 0 Master PLL charge pump output. 30 FILO O Analog Master PLL (slave = digital PLL) filter output. 31 FILI I 32 AVSS — 33 CLTV I 34 AVDD — 35 RF I SQSO readout clock input. 1, 0 Microcomputer extended interface (output). Focus OK input. Used for SENS output and the servo auto sequencer. 1, Z, 0 Spindle motor servo control. 1, Z, 0 Charge pump output for the wide-band EFM PLL. VCO2 oscillation input for the wide-band EFM PLL. 1, 0 VCO2 oscillation output for the wide-band EFM PLL. VCO2 control voltage input for the wide-band EFM PLL. Master PLL filter input. — Analog GND. Master VCO control voltage input. — Analog power supply (+3V). EFM signal input. –4– CXD3009Q Pin No. Symbol I/O Description 36 BIAS I Constant current input of the asymmetry circuit. 37 ASYI I Asymmetry comparator voltage input. 38 ASYO O 1, 0 EFM full-swing output (low = VSS, high = VDD). 39 LRCK O 1, 0 D/A interface. LR clock output f = Fs. 40 LRCKI I 41 PCMD O 42 PCMDI I 43 BCK O 44 BCKI I 45 VSS — — GND 46 VDD — — Power supply (+3V). 47 XUGF O 1, 0 XUGF output. Switched to MNT1 or RFCK output by a command. 48 XPCK O 1, 0 XPLCK output. Switched to MNT0 output by a command. 49 GFS O 1, 0 GFS output. Switched to MNT3 or XRAOF output by a command. 50 C2PO O 1, 0 C2PO output. Switched to GTOP output by a command. 51 XTSL I 52 C4M O 1, 0 4.2336MHz output. 1/4 frequency-divided VCKI output in CAV-W mode. 53 DOUT O 1, 0 Digital Out output. 54 EMPH O 1, 0 Outputs a high signal when the playback disc has emphasis, and a low signal when there is no emphasis. 55 EMPHI I 56 WFCK O 1, 0 WFCK output. 57 SCOR O 1, 0 Outputs a high signal when either subcode sync S0 or S1 is detected. 58 SBSO O 1, 0 Sub P to W serial output. 59 EXCK I 60 VSS — — GND 61 VDD — — Power supply (+3V). 62 SYSM I 63 AVSS — — Analog GND. 64 AVDD — — Analog power supply (+3V). 65 AOUT1 O Left-channel analog output. 66 AIN1 I Left-channel operational amplifier input. 67 LOUT1 O Left-channel LINE output. 68 AVSS — 69 XVDD 70 XTAI I Crystal oscillation circuit input. Input the external master clock via this pin. 71 XTAO O Crystal oscillation circuit output. LR clock input. 1, 0 D/A interface. Serial data output (two's complement, MSB first). D/A interface. Serial data input (two's complement, MSB first). 1, 0 D/A interface. Bit clock output. D/A interface. Bit clock input. Crystal selector input. Low: 16.9344MHz; high: 33.8688MHz. Inputs a high signal when de-emphasis is on, and a low signal when de-emphasis is off. SBSO readout clock input. Mute input. Active when high. — Analog GND. Power supply for master clock. –5– CXD3009Q Pin No. Symbol I/O Description GND for master clock. 72 XVSS 73 AVSS — 74 LOUT2 O Right-channel LINE output. 75 AIN2 I Right-channel operational amplifier input. 76 AOUT2 O Right-channel analog output. 77 AVDD — — Analog power supply (+3V). 78 AVSS — — Analog GND. 79 XRST I 80 VDD — — Analog GND. System reset. Reset when low. — Power supply (+3V). Notes) • PCMD 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 frame sync obtained from the EFM signal, and a negative pulse. 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 of XPLCK and the EFM signal transition point coincide. • GFS goes high when the frame sync and the insertion protection timing match. • RFCK is derived with the crystal accuracy. This signal has a cycle of 136µs (during normal speed). • C2PO represents the data error status. • XRAOF is generated when the 16K RAM exceeds the ±4F jitter margin. –6– CXD3009Q Electrical Characteristics DC Characteristics (VDD = AVDD = 3.3V ± 5%, VSS = AVSS = 0V, Topr = –20 to +75°C) ∗ Item Conditions Min. Input voltage High level input voltage VIH (1) (1) Low level input voltage VIL (1) 0.7VDD Input voltage High level input voltage VIH (2) Schmitt input (2) Low level input voltage VIL (2) 0.7VDD Input voltage Input voltage (3) Typ. Max. V 0.2VDD VIN (3) Analog input Unit V 0.2VDD V Vss VDD V VDD – 0.4 VDD V 0 0.4 V VDD – 0.4 VDD V 0 0.4 V High level output voltage VOH (1) IOH = –4mA Output voltage (2) High level output voltage VOH (2) IOH = –2mA Output voltage (4) High level output voltage VOH (4) IOH = –0.28mA VDD – 0.4 VDD V Low level output voltage VOL (4) IOL = 0.36mA 0 0.4 V Low level output voltage VOL (2) IOL = 4mA ∗1 V Output voltage (1) Low level output voltage VOL (1) IOL = 4mA Applicable pins ∗2 ∗3 ∗4 ∗5 ∗6 Input leak current ILI VI = 0 to 3.60V –5 5 µA ∗1, ∗2, ∗3 Tri-state pin output leak current ILO VO = 0 to 3.60V –5 5 µA ∗7 Applicable pins ∗1 XTSL, DATA, XLAT, PWMI, SYSM, EMPHI, PCMDI ∗2 CLOK, XRST, EXCK, SQCK, FOK, SEIN, CNIN, VCKI, LRCKI, BCKI, SPOA, SPOB ∗3 CLTV, FILI, RF, VCTL, AIN1, AIN2 ∗4 MDP, PCO, VPCO ∗5 ASYO, DOUT, C4M, SBSO, SQSO, SCOR, EMPH, DATO, CLKO, XLTO, SENS, WFCK, V16M, LMUT, RMUT, XLON, LRCK, PCMD, BCK, XUGF, XPCK, GFS, RFCK, C2PO ∗6 FILO ∗7 SENS, PCO, VPCO ∗note) : XVDD and XVSS are included for AVPP and AVSS, respectively. Those are the same for the explanation from the next page. –7– CXD3009Q AC Characteristics 1. XTAI pin (1) When using self-excited oscillation (Topr = –20 to +75°C, VDD = AVDD = 3.3V ± 5%) Item Symbol Oscillation frequency fMAX Min. Typ. 7 Max. Unit 34 MHz (2) When inputting pulses to XTAI pin (Topr = –20 to +75°C, VDD = AVDD = 3.3V ± 5%) Item Symbol tWHX Low level pulse width tWLX High level pulse width Max. Unit 13 500 ns 13 500 ns 1,000 ns Min. Typ. Pulse cycle tCK 26 Input high level VIHX 0.7VDD Input low level VILX 0.2VDD V Rise time, fall time tR, tF 10 ns V tCK tWLX tWHX VIHX VIHX × 0.9 VDD/2 XTAI VIHX × 0.1 VILX tR tF (3) When inputting sine waves to XTAI pin via a capacitor (Topr = –20 to +75°C, VDD = AVDD = 3.3V ± 5%) Item Input amplitude Symbol V1 Min. 0.5VDD Typ. Max. Unit VDD + 0.3 Vp-p –8– CXD3009Q 2. CLOK, DATA, XLAT, CNIN, SQCK and EXCK pins (VDD = AVDD = 3.3V ± 5%, 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 EXCK SQCK pulse width Min. Typ. Max. Unit 0.65 MHz 750 ns 300 ns 300 ns 300 ns 750 ns 0.65∗ MHz 750∗ fWT ns 1/fCK tWCK tWCK CLK DATA XLT tSU tH EXCK CNIN SQCK tD tWT tWL tWT 1/fT SQSO SBSO tSU tH ∗ In pseudo double-speed playback mode, except when SQSO is Sub Q Read, the maximum operating frequency for SQCK is 300kHz and the minimum pulse width is 1.5µs. 3. BCKI, LRCKI and PCMDI pins Item (VDD = AVDD = 3.3V ± 5%, VSS = AVSS = 0V, Topr = –20 to +75°C) Symbol Conditions BCK pulse width tW tSU tH tSU DATAL, R setup time DATAL, R hold time LRCK setup time Min. Typ. Unit 94 ns 18 ns 18 ns 18 ns tW(BCKI) tW(BCKI) BCKI Max. VDD/2 VDD/2 tSU tH (PCMDI) (PCMDI) PCMDI tSU (LRCKI) LRCKI –9– CXD3009Q 1-bit DAC, LPF Block Analog Characteristics Analog Characteristics (VDD = AVDD = 3.3V, VSS = AVSS = 0V, Ta = 25°C) Symbol Item Total harmonic distortion THD S/N ratio S/N Typ. Max. 384Fs 0.015 0.025 768Fs 0.015 0.025 Min. Crystal Conditions 1kHz, 0dB data 1kHz, 0dB data (using A-weighting filter) 384Fs 90 94 768Fs 90 94 For both items, Fs = 44.1kHz. The total harmonic distortion and S/N ratio measurement circuits are shown below. 12k AOUT1 (2) 680p 12k 12k SHIBASOKU (AM51A) AIN1 (2) 150p LOUT1 (2) Audio Analyzer 22µ 100k LPF External Circuit Diagram 768Fs/384Fs DATA TEST DISC Rch A Lch B RF CXD3009Q Block Diagram for Measuring Analog Characteristics – 10 – Audio Analyzer Unit % dB CXD3009Q (VDD = AVDD = 3.3V, VSS = AVSS = 0V, Topr = – 20 to +75°C) Item Symbol Output voltage VOUT Load resistance RL Min. Typ. 0.70∗ 20 Max. Unit Applicable pins Vrms ∗1 kΩ ∗1 ∗ Measured using the circuits on the previous page when a sine wave of 1kHz and 0dB is output. Applicable pins ∗1 LOUT1, LOUT2 – 11 – CXD3009Q Description of Functions 1. CPU Interface and Commands • 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 is low; the initialization data is shown in Table 1-2. Note) When XLAT is low, SQCK must be set high. – 12 – – 13 – 1 1 1 1 Serial bus CTRL Servo coefficient setting CLV CTRL CLV mode B C D E 0 0 1 1 1 1 1 1 0 0 1 0 1 1 0 0 1 Audio CTRL 1 A 0 0 1 MODE specification 8 9 0 0 0 Auto sequence (N) track jump count 7 Function specification 1 1 0 Kick (D) 6 1 0 1 0 Blind (A, E), Overflow (C) Brake (B) 5 1 0 1 0 Auto sequence 4 D1 D2 Address D3 Command Register name Command Table 0 1 0 1 0 0 1 1 0 1 0 1 0 D0 D2 D1 D0 — — — D3 — — — D2 — — — D1 Data 2 0 0 Mute ATT Mute ATT 0 SL0 CPUSR 0 0 DSPB ON/OFF TB TP SYCOF SYCOF OPSL1 MCSL 1 OPSL1 MCSL 0 0 0 0 0 0 4 — — — D2 ZDPL ZMUT ZDPL ZMUT 0 8 — — — D3 0 — VCO2 THRU 2 — — — D1 0 — 0 1 — — — D0 0 — 0 — — DCOF — 0 — — — — — — D2 D3 0 — 0 — — — — D1 Data 5 0 — 0 — — — — — — D2 — — — — D1 — — — — D0 — — — — — — — — — — — — TXON TXOUT OUTL1 OUTL0 — — — — — — D3 D0 Data 6 — — — 0 0 — Table 1-1 — — — Gain Gain CAV1 CAV0 — — 0 Gain VP7 VP6 VP5 VP4 VP3 VP2 VP1 VP0 CLVS — 0 0 — — — 0 — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — — OPSL2 EMPH SMUT AD10 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 FMUT LRWO BSBST BBSL 1 — — 16 — — — D0 — — 32 — — — D1 Data 4 OPSL2 EMPH SMUT AD10 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 0 0 64 — — — D2 VCO KSL3 KSL2 KSL1 KSL0 SEL2 128 — — — D3 Data 3 CM3 CM2 CM1 CM0 EPWM SPDC ICAP SFSL VC2C HIFC LPWR VPON 0 0 0 0 0 SOCT 256 — — — D0 TRMI TRMO MTSL1 MTSL0 0 0 0 0 0 0 DSPB ON/OFF 0 0 VCO DOUT DOUT WSEL SEL1 Mute ON/OFF Gain Gain Gain Gain MDP1 MDP0 MDS1 MDS0 SL1 0 0 0 0 CDROM 32768 16384 8192 4096 2048 1024 512 11.6ms 5.8ms 2.9ms 1.45ms 0.36ms 0.18ms 0.09ms 0.05ms 0.18ms 0.09ms 0.05ms 0.02ms AS3 AS2 AS1 AS0 D3 Data 1 CXD3009Q – 14 – 1 Servo coefficient setting CLV CTRL CLV mode C D E 1 1 1 1 Function specification 9 Serial bus CTRL 1 MODE specification 8 B 0 Auto sequence (N) track jump count setting 7 1 0 Kick (D) 6 Audio CTRL 0 Blind (A, E), Overflow (C) Brake (B) 5 A 0 Auto sequence 4 D3 Command Register name Reset Initialization 0 0 1 1 1 1 1 0 0 1 0 0 0 0 1 1 1 1 0 0 1 1 D1 D2 Address 0 1 0 1 0 1 0 1 0 1 0 D0 0 0 0 0 0 0 0 0 0 0 0 D3 0 0 1 0 0 0 0 0 1 1 0 D2 0 0 1 1 1 0 0 0 1 0 0 D1 Data 1 0 0 0 0 1 0 0 0 1 1 0 D0 0 1 — 0 0 0 0 0 — — — D3 0 1 — 1 0 0 0 0 — — — D2 0 1 — 0 0 0 0 0 — — — D1 Data 2 0 0 — 0 0 0 0 0 — — — D3 0 0 — 0 0 0 0 0 — — — D2 Table 1-2 0 0 — 0 0 0 0 1 — — — D0 0 0 — 0 0 0 1 0 — — — D1 Data 3 0 0 — 0 0 0 0 0 — — — D0 0 — — — 0 0 0 0 — — — D3 0 — — — 0 0 0 0 — — — D2 0 — — — 0 0 1 0 — — — D1 Data 4 0 — — — 0 0 0 0 — — — D0 — — — — 0 0 0 — — — — D3 — — — — 0 0 0 — — — — D2 — — — — 0 0 0 — — — — D1 Data 5 — — — — 0 0 0 — — — — D0 — — — — 0 — 0 — — — — D3 — — — — 0 — 0 — — — — D2 — — — — 0 — 0 — — — — D1 Data 6 — — — — 0 — 0 — — — — D0 CXD3009Q CXD3009Q 1-1. The meaning of the data for each address is explained below. $4X commands AS3 AS2 AS1 AS0 CANCEL 0 0 0 0 FOCUS-ON 0 1 1 1 1 TRACK JUMP 1 0 0 RXF 10 TRACK JUMP 1 0 1 RXF 2N TRACK JUMP 1 1 0 RXF N TRACK MOVE 1 1 1 RXF Command 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/move commands ($48 to $4F) are canceled, $25 is sent and the auto sequence is interrupted. $5X commands Auto sequence timer setting Setting timers: A, E, C, B Command D3 D2 D1 D0 Blind (A, E), Over flow (C) 0.18ms 0.09ms 0.05ms 0.02ms Brake (B) 0.36ms 0.18ms 0.09ms 0.05ms Ex.) D2 = D0 = 1, D3 = D1 = 0 (Initial Reset) A = E = C = 0.11ms B = 0.23ms $6X commands Auto sequence timer setting Setting timer: D Command KICK (D) D3 D2 D1 D0 11.6ms 5.8ms 2.9ms 1.45ms Ex.) D3 = 0, D2 = D1 = D0 = 1 (Initial Reset) D = 10.15ms $7X commands Auto sequence track jump/move count setting (N) 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 sequence track jump 15 14 13 12 11 10 2 2 2 2 2 2 count setting 29 28 27 26 25 24 23 22 21 20 This command is used to set N when a 2N-track jump and an N-track move are 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. • The number of tracks jumped is counted according to the signals input from the CNIN pin. – 15 – CXD3009Q $8X commands Data 1 Command D3 D2 D1 Data 2 D0 D3 DOUT DOUT VCO MODE CDROM WSEL Mute ON/OFF SEL1 specification Data 3 D2 D1 D0 D3 D2 D1 D0 0 SOCT VCO SEL2 KSL3 KSL2 KSL1 KSL0 See the $BX commands. Data 4 Data 5 Data 6 D3 D2 D1 D0 D3 D2 D1 D0 0 0 VCO2 THRU 0 0 0 0 0 D3 D2 D1 D0 TXON TXOUT OUTL1 OUTL0 Command bit C2PO timing Processing CDROM = 1 See Timing Chart 1-1. CDROM mode; average value interpolation and pre-value hold are not performed. CDROM = 0 See Timing Chart 1-1. Audio mode; average value interpolation and pre-value hold are performed. Command bit Processing DOUT Mute = 1 Digital Out output is muted. (DA output is not muted.) DOUT Mute = 0 When no other mute conditions are set, Digital Out output is not muted. Command bit Processing DOUT ON/OFF = 1 Digital Out is output from the DOUT pin. DOUT ON/OFF = 0 Digital Out is not output from the DOUT pin. WSEL = 1 Sync protection window width ±26 channel clock∗1 Anti-rolling is enhanced. WSEL = 0 ±6 channel clock Sync window protection is enhanced. Command bit Application ∗1 In normal-speed playback, channel clock = 4.3218MHz. – 16 – CXD3009Q Command bit Processing VCOSEL1 KSL3 KSL2 0 0 0 Multiplier PLL VCO1 is set to normal speed, and the output is 1/1 frequency-divided. 0 0 1 Multiplier PLL VCO1 is set to normal speed, and the output is 1/2 frequency-divided. 0 1 0 Multiplier PLL VCO1 is set to normal speed, and the output is 1/4 frequency-divided. 0 1 1 1 0 0 1 0 1 1 1 0 1 1 1 Multiplier PLL VCO1 is set to normal speed, and the output is 1/8 frequency-divided. Multiplier PLL VCO1 is set to high speed∗1, and the output is 1/1 frequency-divided. Multiplier PLL VCO1 is set to high speed∗1, and the output is 1/2 frequency-divided. Multiplier PLL VCO1 is set to high speed∗1, and the output is 1/4 frequency-divided. Multiplier PLL VCO1 is set to high speed∗1, and the output is 1/8 frequency-divided. ∗1 Approximately twice the normal speed. Command bit Processing VCOSEL2 KSL1 KSL0 0 0 0 Wide-band PLL VCO2 is set to normal speed, and the output is 1/1 frequency-divided. 0 0 1 Wide-band PLL VCO2 is set to normal speed, and the output is 1/2 frequency-divided. 0 1 0 Wide-band PLL VCO2 is set to normal speed, and the output is 1/4 frequency-divided. 0 1 1 1 0 0 1 0 1 1 1 0 1 1 1 Wide-band PLL VCO2 is set to normal speed, and the output is 1/8 frequency-divided. Wide-band PLL VCO2 is set to high speed∗2, and the output is 1/1 frequency-divided. Wide-band PLL VCO2 is set to high speed∗2, and the output is 1/2 frequency-divided. Wide-band PLL VCO2 is set to high speed∗2, and the output is 1/4 frequency-divided. Wide-band PLL VCO2 is set to high speed∗2, and the output is 1/8 frequency-divided. ∗2 Approximately twice the normal speed. – 17 – CXD3009Q Command bit VCO2 THRU = 0 Processing V16M output is connected to VCKI inside the IC. Set VCKI to low in this time. VCO2 THRU = 1 V16M output is not connected to VCKI inside the IC. Input the clock from VCKI in this time. ∗ These commands are used to set the internal or external connection of VCO2 used in CAV-W mode. Command bit TXON = 0 Processing Set TXON to 0 when the CD-TEXT data is not demodulated. TXON = 1 Set TXON to 1 when the CD-TEXT data is demodulated. ∗ See "4-9. CD-TEXT Data Demodulation". Command bit Processing TXOUT = 0 Various signals except CD-TEXT are output from SQSO pin. See $BX commands. TXOUT = 1 CD-TEXT data is output from SQSO pin. ∗ See "4-9. CD-TEXT Data Demodulation". Command bit Processing OUTL1 = 0 WFCK, XPCK and C4M are output. OUTL1 = 1 WFCK, XPCK and C4M outputs are set to low. Command bit Processing OUTL0 = 0 PCMD, BCK, LRCK and EMPH are output. OUTL0 = 1 PCMD, BCK, LRCK and EMPH outputs are set to low. PCMD and PCMDI, BCK and BCKI, LRCK and LRCKI, EMPH and EMPHI are connected inside the IC, respectively. At this time, set PCMDI = BCKI = LRCKI = EMPHI = low. – 18 – – 19 – C2PO CDROM = 1 C2PO CDROM = 0 LRCK Timing Chart 1-1 C2 Pointer for lower 8-bits Rch C2 Pointer C2 Pointer for upper 8-bits Rch 16-bit C2 Pointer C2 Pointer for lower 8-bits Lch C2 Pointer C2 Pointer for upper 8-bits Lch 16-bit C2 Pointer If C2 Pointer = 1, data is NG CXD3009Q CXD3009Q ∗ Data 2 D0 and subsequent data are DF/DAC function settings. $9X commands (OPSL1= 0) Data 1 Command Function specification D3 D2 D1 0 DSPB ON/OFF 0 Data 2 D0 D3 to D1 D0 0 Data 4 Data 3 000 SYCOF D3 D2 D1 D0 0 MCSL 0 0 D3 ZDPL ZMUT OPSL1 Function specification Data 1 D3 D2 D1 0 DSPB ON/OFF 0 D1 D0 — — Data 5 D3 D2 D1 D0 — — — — ∗ Data 2 D0 and subsequent data are DF/DAC function settings. $9X commands (OPSL1= 1) Command D2 Data 3 Data 2 D0 D3 to D1 D0 0 000 SYCOF Data 4 D3 D2 D1 D0 1 MCSL 0 0 D3 D2 ZDPL ZMUT OPSL1 DSPB = 1 Double-speed playback (CD-DSP block) DSPB = 0 Normal-speed playback (CD-DSP block) SYCOF = 1 LRCK asynchronous mode SYCOF = 0 Normal operation D1 D0 0 DCOF 0 0 Processing OPSL1 = 1 DCOF can be set. OPSL1 = 0 DCOF cannot be set. Command bit Processing MCSL = 1 DF/DAC block master clock selection. Crystal = 768Fs (33.8688MHz) MCSL = 0 DF/DAC block master clock selection. Crystal = 384Fs (16.9344MHz) – 20 – 0 D2 ∗ Set SYCOF = 0 in advance when setting the $AX command LRWO to 1. Command bit 0 D3 Processing Command bit D0 Data 5 Processing Command bit D1 CXD3009Q Processing Command bit ZDPL = 1 LMUT and RMUT pins are high when muted. ZDPL = 0 LMUT and RMUT pins are low when muted. ∗ See "Mute flag output" for the mute flag output conditions. Processing Command bit ZMUT = 1 Zero detection mute is on. ZMUT = 0 Zero detection mute is off. Processing Command bit DCOF = 1 DC offset is off. DCOF = 0 DC offset is on. ∗ DCOF can be set when OPSL1 = 1. ∗ Set DC offset to off when zero detection mute is on. ∗ Data 2 and subsequent data are DF/DAC function settings. $AX commands (OPSL2 = 0) Command Audio CTRL Data 1 Data 3 Data 2 D3 D2 D1 D0 D3 D2 D1 0 0 Mute ATT 0 0 0 D0 D3 D2 EMPH SMUT AD10 OPSL2 Data 3 Data 4 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 AD0 — — — — ∗ Data 2 and subsequent data are DF/DAC function settings. $AX commands (OPSL2 = 1) Command Audio CTRL Data 6 Data 5 Data 3 Data 2 Data 1 D3 D2 D1 D0 D3 D2 D1 0 0 Mute ATT 0 0 1 D0 D3 D2 EMPH SMUT AD10 OPSL2 Data 3 Data 4 Data 6 Data 5 D1 D0 D3 D2 D1 D0 D3 D2 D1 AD9 AD8 AD7 AD6 AD5 AD4 AD3 AD2 AD1 – 21 – D0 D3 D2 D1 D0 AD0 FMUT LRWO BSBST BBSL CXD3009Q Processing Command bit Mute = 1 CD-DSP block mute is on. 0 data is output from the CD-DSP block. Mute = 0 CD-DSP block mute is off. Processing Command bit ATT = 1 CD-DSP block output is attenuated (–12dB). ATT = 0 CD-DSP block attenuation is off. Meaning Command bit OPSL2 = 1 FMUT, LRWO, BSBST and BBSL can be set. OPSL2 = 0 FMUT, LRWO, BSBST and BBSL cannot be set. Processing Command bit EMPH = 1 De-emphasis is on. EMPH = 0 De-emphasis is off. ∗ If either the EMPHI pin or EMPH is high, de-emphasis is on. Processing Command bit SMUT = 1 Soft mute is on. SMUT = 0 Soft mute is off. ∗ If either the SMUT pin or SMUT is high, soft mute is on. Meaning Command bit AD9 to 0 Attenuation data. The attenuation data consists of 10 bits, and is set as follows. Attenuation data Audio output 400h 0dB 3FFh 3FEh : 001h –0.0085dB –0.017dB The attenuation data (AD10 to AD0) consists of 11bits, and can be set in 1024 different ways. The audio output from 001h to 400h is obtained using the following equation. –60.206dB Audio output = 20log 000h –∞ – 22 – Attenuation data 1024 [dB] CXD3009Q Command bit Meaning FMUT = 1 Forced mute is on. FMUT = 0 Forced mute is off. ∗ FMUT can be set when OPSL2 = 1. Meaning Command bit LRWO = 1 Forced synchronization mode Note) LRWO = 0 Normal operation. ∗ LRWO can be set when OPSL2 = 1. Note) Synchronization is performed at the first falling edge of LRCK during reset, so there is normally no need to set this mode. However, synchronization can be forcibly performed by setting LRWO = 1. Processing Command bit BSBST = 1 Bass boost is on. BSBST = 0 Bass boost is off. ∗ BSBST can be set when OPSL2 = 1. Processing Command bit BBSL = 1 Bass boost is Max. BBSL = 0 Bass boost is Mid. ∗ BBSL can be set when OPSL2 = 1. – 23 – 1 0 0 0 1 1 – 24 – 1 0 1 0 1 0 1 0 0 L1 SPOB L0 mode D Peak meter PER1 PER0 mode C PER2 VF1 PER1 C B A SubQ D SENS L2 0 PER2 VF2 PER3 Peak meter SubQ mode CPUSR D1 VF0 SPOA D2 SL0 SL0 PER0 SL1 D3 Data 1 mode B mode A SQCK XLAT 1 1 0 1 0 0 1 0 0 1 SL1 SOCT Serial bus CTRL Command $BX commands L3 WFCK PER3 VF3 PER4 0 D0 D2 D1 D0 L4 SCOR PER4 VF4 PER5 L5 GFS PER5 VF5 PER6 L6 GTOP PER6 VF6 PER7 L7 EMPH PER7 VF7 C1F1 R0 FOK 0 ALOCK C1F2 R1 LOCK C1F1 C1F1 0 0 0 C2F2 R2 R3 RFCK XRAOF C1F2 C1F2 C2F1 R4 C1F1 C2F1 C2F1 0 R5 C1F2 C2F2 C2F2 FOK R6 C2F1 0 0 GFS R7 C2F2 FOK FOK LOCK The SQSO pin output can be switched to the various signals by setting the SOCT command of $8X and the SL1 and SL0 commands of $BX. Set SQCK to high at the falling edge of XLAT. Except for Sub Q and peak meter, the signals are loaded to the register when they are set at the falling edge of XLAT. Sub Q is loaded to the register with each SCOR, and Peak meter is loaded when a peak is detected. TRM1 TRM0 MTSL1 MTSL0 D3 Data 2 GFS GFS LOCK LOCK EMPH ALOCK EMPH EMPH VF0 VF1 VF2 VF3 VF4 VF5 VF6 VF7 CXD3009Q CXD3009Q Signal Description PER0 to 7 RF jitter amount (used to adjust the focus bias). 8-bit binary data in PER0 = LSB, PER7 = MSB. FOK Focus OK GFS High when the frame sync and the insertion protection timing match. LOCK GFS is sampled at 460Hz; when GFS is high, a high signal is output. If GFS is low eight consecutive samples, a low signal is output. EMPH High when the playback disc has emphasis. ALOCK GFS is sampled at 460Hz; when GFS is high eight consecutive samples, a high signal is output. If GFS is low eight consecutive samples, a low signal is output. VF0 to 7 Used in CAV-W mode. Results of measuring the disc rotational velocity. (See Timing Chart 2-3.) VF0 = LSB, VF7 = MSB. SPOA, B SPOA and B pin inputs. WFCK Write frame clock output. SCOR High when either subcode sync S0 or S1 is detected. GTOP High when the sync protection window is open. RFCK Read frame clock output. XRAOF Low when the built-in 16K RAM exceeds the ±4 frame jitter margin. L0 to L7, R0 to R7 Peak meter register output. L0 to 7 are the left-channel and R0 to 7 are the right-channel peak data. L0 and R0 are LSB. C1F1 C1F2 0 0 1 1 C1 correction status C2F1 C2F2 No Error 0 0 No Error 0 Single Error Correction 1 0 Single Error Correction 1 Irretrievable Error 1 1 Irretrievable Error Processing Command bit CPUSR = 1 XLON pin is high. CPUSR = 0 XLON pin is low. – 25 – C2 correction status CXD3009Q Peak meter XLAT SQCK SQSO L0 L1 L2 L3 L4 L5 L6 L7 R0 R1 R2 R3 R4 R5 R6 R7 (Peak meter) Setting the SOCT command of $8X to 0 and the SL1 and SL0 commands of $BX to 0 and 1, respectively, results in peak detection mode. The SQSO output is connected to the peak register. The maximum PCM data values (absolute value, upper 8bits) for the left and right channels can be read from SQSO by inputting 16 clocks to SQCK. Peak detection is not performed during SQCK input, and the peak register does not change during readout. This SQCK input judgment uses a retriggerable monostable multivibrator with a time constant of 270µs to 400µs. The time during which SQCK input is high should be 270µs or less. Also, peak detection is restarted 270µs to 400µs after SQCK input. The peak register is reset with each readout (16 clocks input to SQCK). The maximum value in peak detection mode is detected and held in this status until the next readout. When switching to peak detection mode, readout should be performed one time initially to reset the peak detection register. Peak detection can also be performed for previous value hold and average value interpolation data. Traverse monitor count value setting These bits are set when monitoring the traverse condition of the SENS output according to the CNIN frequency division. Command bit Processing TRM1 TRM0 0 0 1/64 frequency division 0 1 1/128 frequency division 1 0 1/256 frequency division 1 1 1/512 frequency division Monitor output switching The monitor output can be switched to the various signals by setting the MTSL1 and MTSL0 commands of $B. Mode description Pin No. Command bit 47 48 49 50 MTSL1 MTSL0 0 0 XUGF XPCK GFS C2PO 0 1 MNT1 MNT0 MNT3 C2PO 1 0 RFCK XPCK XROF GTOP – 26 – CXD3009Q $CX commands Command Servo coefficient setting D3 D2 D1 D0 Gain MDP1 Gain MDP0 Gain MDS1 Gain MDS0 Gain CLVS CLV CTRL ($DX) • CLV 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 • 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 – 27 – CXD3009Q $DX commands Command CLV CTRL Data 1 Data 3 Data 2 D3 D2 D1 D0 D3 D2 D1 D0 D3 D2 D1 D0 0 TB TP Gain CLVS VP7 VP6 VP5 VP4 VP3 VP2 VP1 VP0 See the $CX commands. Command bit Description TB = 0 Bottom hold at a cycle of RFCK/32 in CLVS mode. TB = 1 Bottom hold at a cycle of RFCK/16 in CLVS mode. TP = 0 Peak hold at a cycle of RFCK/4 in CLVS mode. TP = 1 Peak hold at a cycle of RFCK/2 in CLVS mode. The rotational velocity R of the spindle can be expressed with the following equation. Command bit Description VP0 to 7 = F0 (H) Playback at half (normal) speed to Playback at normal (double) speed : VP0 to 7 = E0 (H) R= 256 – n 32 R: Relative velocity at normal speed = 1 n: VP0 to 7 setting value Note) • Values in parentheses are for when DSPB is 1. • Values when crystal is 16.9344MHz and XTSL is low or when crystal is 33.8688MHz and XTSL is high. • VP0 to 7 setting values are valid in CAV-W mode. R – Relative velocity [multiple] 2 1.5 B= 1 P DS 1 DSP B=0 0.5 F0 VP0 to 7 setting value [HEX] Fig. 1-1 – 28 – E0 CXD3009Q $EX commands Data 1 Command CLV mode Data 2 D3 D2 D1 CM3 CM2 CM1 D0 D2 D3 Data 3 D1 D0 CM0 EPWM SPDC ICAP Command bit Mode D3 SFSL VC2C D2 D1 D0 HIFC LPWR VPON Description CM3 CM2 CM1 CM0 0 0 0 0 STOP Spindle stop mode.∗1 1 0 0 0 KICK Spindle forward rotation mode.∗1 1 0 1 0 BRAKE 1 1 1 0 CLVS Rough servo mode. When the RF-PLL circuit isn't locked, this mode is used to pull the disc rotations within the RFPLL capture range. 1 1 1 1 CLVP PLL servo mode. 0 1 1 0 CLVA Automatic CLVS/CLVP switching mode. Used for normal playback. Spindle reverse rotation mode. Valid only when LPWR = 0, in any mode.∗1 ∗1 See Timing Charts 1-2 to 1-6. Command bit EPWM SPDC Mode ICAP SFSL VC2C HIFC LPWR VPON Description 0 0 0 0 0 0 0 0 CLV-N Crystal reference CLV servo. 0 0 0 0 1 1 0 0 CLV-W Used for normal-speed playback in CLV-W mode.∗2 0 1 1 0 0 1 0 1 CAV-W Spindle control with VP0 to 7. 1 0 1 0 0 1 0 1 CAV-W Spindle control with the external PWM. ∗2 Figs. 3-1 and 3-2 show the control flow with the microcomputer software in CLV-W mode. – 29 – CXD3009Q Data 4 Command SPD mode D3 D2 Gain Gain CAV1 CAV0 Gain CAV1 Gain CAV0 Gain 0 0 0dB 0 1 –6dB 1 0 –12dB 1 1 –18dB Mode CLV-N LPWR 0 0 CLV-W 1 0 CAV-W 1 D1 D0 0 0 • This sets the gain when controlling the spindle with the phase comparator in CAV-W mode. Command Timing chart KICK 1-2 (a) BRAKE 1-2 (b) STOP 1-2 (c) KICK 1-3 (a) BRAKE 1-3 (b) STOP 1-3 (c) KICK 1-4 (a) BRAKE 1-4 (b) STOP 1-4 (c) KICK 1-5 (a) BRAKE 1-5 (b) STOP 1-5 (c) KICK 1-6 (a) BRAKE 1-6 (b) STOP 1-6 (c) Mode LPWR Timing chart CLV-N 0 1-7 0 1-8 1 1-9 0 1-10 (EPWM = 0) 1 1-11 (EPWM = 0) 0 1-12 (EPWM = 1) 1 1-13 (EPWM = 1) CLV-W CAV-W – 30 – CXD3009Q Timing Chart 1-2 CLV-N mode LPWR = 0 KICK BRAKE Z H MDP STOP MDP Z MDP L (a) KICK (b) BRAKE Z (c) STOP Timing Chart 1-3 CLV-W mode (when following the spindle rotational velocity) LPWR = 0 KICK MDP BRAKE STOP Z H MDP Z (b) BRAKE (a) KICK Z MDP L (c) STOP Timing Chart 1-4 CLV-W mode (when following the spindle rotational velocity) LPWR = 1 KICK BRAKE H MDP Z MDP Z (a) KICK STOP MDP (b) BRAKE Z (c) STOP Timing Chart 1-5 CAV-W mode LPWR = 0 KICK BRAKE STOP H MDP MDP (a) KICK L MDP (b) BRAKE Z (c) STOP Timing Chart 1-6 CAV-W mode LPWR = 1 KICK MDP H (a) KICK BRAKE MDP Z (b) BRAKE – 31 – STOP MDP Z (c) STOP CXD3009Q Timing Chart 1-7 CLV-N mode LPWR = 0 n · 236 (ns) n = 0 to 31 Acceleration MDP Z 132kHz Deceleration 7.6µs Timing Chart 1-8 CLV-W mode LPWR = 0 Acceleration MDP Z 264kHz 3.8µs Deceleration Timing Chart 1-9 CLV-W mode LPWR = 1 Acceleration MDP Z 264kHz 3.8µs The BRAKE pulse is masked when LPWR = 1. Timing Chart 1-10 CAV-W mode EPWM = LPWR = 0 Acceleration MDP Z 264kHz 3.8µs Deceleration Timing Chart 1-11 CAV-W mode EPWM = LPWR = 1 Acceleration MDP Z 264kHz 3.8µs The BRAKE pulse is masked when LPWR = 1. – 32 – CXD3009Q Timing Chart 1-12 CAV-W mode EPWM = 1, LPWR = 0 H PWMI L Acceleration H MDP L Deceleration Timing Chart 1-13 CAV-W mode EPWM = LPWR = 1 H PWMI L Acceleration H MDP Z The BRAKE pulse is masked when LPWR = 1. – 33 – CXD3009Q 1-2. Description of SENS Output The following signals are output from SENS, depending on the microcomputer serial register value (latching not required). Microcomputer serial register value (latching not required) SENS output $0X, 1X, 2X, 3X SEIN SEIN, a signal input to this LSI from the SSP, is output. $4X XBUSY Low while the auto sequencer is in operation, high when operation terminates. $5X FOK Outputs the signal input to the FOK pin. Normally, FOK (from RF) is input. High for "focus OK". $6X SEIN SEIN, a signal input to this LSI from the SSP, is output. $AX GFS High when the regenerated frame sync is obtained with the correct timing. $EX OV64 Low when the EFM signal, after passing through the sync detection filter, is lengthened by 64 channel clock pulses or more. $7X, 8X, 9X, BX, DX, FX “L” $CX CNIN division Meaning SENS pin is fixed to low. Calculates the number of tracks from the frequency division ratio set by $B.High when $C is latched; toggles each time CNIN is input the number of times set in register B. Note that the SENS output can be read out from the SQSO pin when SOCT = 0, SL1 = 1 and SL0 = 0. (See the $BX commands.) 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 to the CXD3009Q. Sub Q can be read out after checking the CRC of the 80bits in the subcode frame. Sub Q can be read out from the SQSO pin by inputting 80 clock pulses to the SQCK pin when SCOR comes correctly and CRCF is high. 2-1. P to W Subcode Readout Data can be read out by inputting EXCK immediately after WFCK falls. (See Timing Chart 2-1.) 2-2. 80-bit Sub Q Readout Fig. 2-1 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, 80bits are loaded into the parallel/serial register. When SQSO goes high 400µs (monostable multivibrator time constant) or more after subcode readout, the CPU determines that new data (which passed the CRC check) has been loaded. • When the 80-bit data is loaded, the order of the MSB and LSB is inverted within 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 80-bit data load is confirmed, SQCK is input so that the data can be read. The SQCK input is detected, and the retriggerable monostable multivibrator is reset while the input is low. • The retriggerable monostable multivibrator has a time constant from 270µs to 400µs. When the duration when SQCK is high is less than this time constant, the monostable multivibrator is kept reset; during this interval, the serial/parallel register is not loaded into the parallel/serial register. • While the monostable multivibrator is being reset, data cannot be loaded in the 80-bit parallel/serial register. In other words, while reading out with a clock cycle shorter than this time constant, the register will not be rewritten by CRCOK and others. (See Timing Chart 2-2.) • The high and low intervals for SQCK should be between 750ns and 120µs. – 34 – CXD3009Q Timing Chart 2-1 Internal PLL clock 4.3218 ± ∆MHz WFCK SCOR EXCK 400ns 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 Sub Code P.Q.R.S.T.U.V.W Read Timing – 35 – P2 P3 SUBQ SI LD H G F E D C B A A B C D E F G H SIN Order Inversion – 36 – CRCC SUBQ 8 LD 8 (AMIN) 80-bit P/S Register 8 80-bit S/P Register Mono/Multi LD (ASEC) SHIFT LD (AFRAM) 8 8 8 8 LD Mix CRCF 8 SHIFT SQSO 8 ADDRS CTRL LD Fig. 2-1. Block Diagram SQCK SO CXD3009Q LD LD – 37 – SQSO SQCK CRCF Mono/multi (Internal) SQCK SQSO SCOR WFCK Timing Chart 2-2 CRCF1 1 2 Order Inversion ADR1 3 2 1 94 Determined by mode 93 92 91 ADR2 ADR3 CTL0 270µs to 400µs for SQCK = High Register load forbidder 80 Clock 750ns to 120µs 300ns max ADR0 3 95 L CTL1 96 CTL2 97 CTL3 CRCF2 98 CXD3009Q CXD3009Q Timing Chart 2-3 Measurement interval (approximately 3.8µs) Reference window (132.2kHz) Measurement pulse (VCKI/2) Measurement counter Load m VF0 to 7 The relative velocity R of the disc can be expressed with the following equation. R= m+1 32 (R: Relative velocity, m: Measurement results) VF0 to 7 is the result obtained by counting VCKI/2 pulses while the reference signal (132.2kHz) generated from the crystal (384Fs) is high. This count is 31 when the disc is rotating at normal speed and 63 when it is rotating at double speed (when DSPB is low). – 38 – CXD3009Q 3. Description of Modes This LSI has three basic operating modes using a combination of spindle control and the PLL. The operations for each mode are described below. 3-1. CLV-N Mode This mode is compatible with the CXD2507AQ, and operation is the same as for the conventional control. The PLL capture range is ±150kHz. 3-2. CLV-W Mode This is the wide capture range mode. This mode allows the PLL to follow the rotational velocity of the disc. This rotational following control has two types: using the built-in VCO2 or providing an external VCO. The spindle is the same CLV servo as for the conventional series. Operation using the built-in VCO2 is described below. (When using an external VCO, input the signal from the VPCO pin to the low-pass filter, use the output from the low-pass filter as the control voltage for the external VCO, and input the oscillation output from the VCO to the VCKI pin.) While starting to rotate a disc and/or speeding up to the lock range from the condition where the disc is stopped, CAV-W mode should be used. Specifically, first send $E6650 to set CAV-W mode and kick the disc, then send $E60C0 to set CLV-W mode if ALOCK is high, which can be read out serially from the SQSO pin. CLV-W mode can be used while ALOCK is high. The microcomputer monitors the serial data output, and must return the operation to the speed adjusting state (CAV-W mode) when ALOCK becomes low. The control flow according to the microcomputer software is shown in Fig. 3-2. In CLV-W mode (normal), low power consumption is achieved by setting LPWR to high. Control was formerly performed by applying acceleration and deceleration pulses to the spindle motor. However, when LPWR is set to high, deceleration pulses are not output, thereby achieving low power consumption mode. Note) The capture range for CLV-W mode has theoretically the range up to the signal processing limit. 3-3. CAV-W Mode This is CAV mode. In this mode, the external clock is fixed and it is possible to control the spindle to the desired rotational velocity. The rotational velocity is determined by the VP0 to 7 setting values or the external PWM. When controlling the spindle with VP0 to 7, setting CAV-W mode with the $E6650 command and controlling VP0 to 7 with the $DX commands allows the rotational velocity to be varied from low-speed to double-speed. (See the $DX commands.) Also, when controlling the spindle with the external PWM, the PWMI pin is binary input which becomes KICK during high intervals and BRAKE during low intervals. The microcomputer can know the rotational velocity using V16M. The reference for the velocity measurement is a signal of 132.2kHz obtained by dividing the crystal (384Fs) by 128. The velocity is obtained by counting V16M/2 pulses while the reference is high, and the result is output from the new CPU interface as 8 bits (VF0 to 7). These measurement results are 31 when the disc is rotating at normal speed or 63 when it is rotating at double speed. These values match those of the 256-n for control with VP0 to 7. In CAV-W mode, the spindle is set to the desired rotational velocity and the operation speed for the entire system follows this rotational velocity. Therefore, the cycles for the Fs system clock, PCM data and all other output signals from this LSI change according to the rotational velocity of the disc (excluding DATO, CLKO and XLTO). Note) The capture range for this mode is theoretically up to the signal processing limit. – 39 – CXD3009Q CAV-W CLV-W Operation mode Rotational velocity CLVS CLVP Spindle mode Target velocity KICK Time LOCK ALOCK Fig. 3-1. Disc Stop to Normal Condition in CLV-W Mode CLV-W Mode CLV-W MODE START KICK $E8000 Mute OFF $A0XXXXX CAV-W $E6650 (CLVA) NO ALOCK = H ? YES CLV-W $E60C0 (CLVA) (WFCK PLL) YES ALOCK = L ? NO Fig. 3-2. CLV-W Mode Flow Chart – 40 – CXD3009Q 4. Description of Other Functions 4-1. 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, a 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. 4-1. The CXD3009Q has a built-in three-stage PLL. • The first-stage PLL is a wide-band PLL. When using the internal VCO2, an external LPF is necessary; when not using the internal VCO2, external LPF and VCO are necessary. The output of this first-stage PLL is used as a reference for all clocks within the LSI. • The second-stage PLL generates the high-frequency clock needed by the third-stage digital PLL. • The third-stage PLL is a digital PLL that regenerates the actual channel clock. • A new digital PLL has been provided for CLV-W mode to follow the rotational velocity of the disc in addition to the conventional secondary loop. – 41 – CXD3009Q Block Diagram 4-1 CLV-W CAV-W Spindle rotation information 1/32 XTSL 1/2 1/n Phase comparator 1/2 Selector OSC VPCO CLV-N CLV-W CAV-W /CLV-N Microcomputer control n = 1 to 256 (VP7 to 0) 1/K (KSL1, 0) LPF VCOSEL2 VCTL VCO2 V16M 2/1 MUX VCKI VPON 1/M 1/N Phase comparator X'tal PCO FILI FILO 1/K (KSL3, 2) CLTV VCO1 VCOSEL1 Digital PLL RFPLL CXD3009Q – 42 – CXD3009Q 4-2. Frame Sync Protection • In normal-speed playback, a frame sync is recorded approximately every 136µs (7.35kHz). This signal is used as a reference to recognize 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 CXD3009Q, window protection and forward protection/backward protection have been adopted for frame sync protection. These functions achieve 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. Concretely, 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 the frame sync cannot be detected for 13 frames or more, the window opens to resynchronize the frame sync. In addition, immediately after the window opens and the resynchronization is executed, if a proper frame sync cannot be detected within 3 frames, the window opens immediately. 4-3. 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 CXD3009Q's SEC strategy uses powerful frame sync protection and C1 and C2 error correction to achieve high playability. • The correction status can be monitored externally. See Table 4-1. • 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 MNT1 MNT0 Description 0 0 0 No C1 errors 0 0 1 One C1 error corrected 0 1 1 C1 correction impossible 1 0 0 No C2 errors 1 0 1 One C2 error corrected 1 1 1 C2 correction impossible Table 4-1. – 43 – CXD3009Q Timing Chart 4-1 Normal-speed PB t = Dependent on error condition MNT3 C1 correction C2 correction MNT1 MNT0 Strobe Strobe 4-4. DA Interface • The CXD3009Q DA interface is as described below. 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. – 44 – R0 1 2 3 – 45 – PCMD BCK (4.23M) LRCK (88.2k) R0 1 2 4 5 Lch MSB (15) Lch MSB (15) 48-bit slot Double-Speed Playback PCMD BCK (2.12M) LRCK (44.1k) 48-bit slot Normal-Speed Playback Timing Chart 4-2 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 CXD3009Q CXD3009Q 4-5. 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 CXD3009Q supports type 2 form 1. Sub Q data which are matched twice in succession after a CRC check are input to the first four bits (bits 0 to 3) of the channel status. 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 Bits 0 to 3...Sub Q control bits that matched twice with CRCOK Bit 29..........1 when VPON is 1 Table 4-2. 4-6. 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 N-track move 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 CXD3009Q. Connect the CPU, RF and SSP as shown in Fig. 4-2. 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 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). – 46 – CXD3009Q (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. 4-3. The auto focus starts with 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 auto sequencer (example) RF FOK FOK DATA CXD3009Q SSP CLOK Microcomputer XLAT C. out CNIN SENS SEIN DATA DATO CLK CLKO XLT XLTO SENS Fig. 4-2. Auto focus Focus search up FOK = H NO YES (Checks whether FZC is continuously high for the period of time E set with register 5) FZC = H NO YES FZC = L NO YES Focus servo ON END Fig. 4-3-(a). Auto Focus Flow Chart – 47 – CXD3009Q $47latch XLT FOK SEIN (FZC) BUSY Command for SSP Blind E $08 $03 Fig. 4-3-(b). Auto Focus Timing Chart (b) Track Jump 1, 10, and 2N-track jumps are performed respectively. Always use this when the focus, tracking, and sled servos are on. Note that tracking gain-up and braking-on should be sent beforehand because they are not involved in this sequence. • 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. 4-4. 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. 4-5. The principal difference from the 1-track jump is to kick the sled. 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 with 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. 4-6. The track jump count N is set with 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. 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 with register 6. • N-track move When $4E ($4F for REV) is received from the CPU, a FWD (REV) N-track move is performed in accordance with Fig. 4-7. N can be set to 216 tracks. CNIN is used for counting the number of jumps. This N-track move is executed only by moving the sled, and is therefore suited for moving across several thousand to several ten-thousand tracks. – 48 – CXD3009Q Track Track FWD kick sled servo OFF (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. 4-4-(a). 1-Track Jump Flow Chart $48 (REV = $49) latch XLT CNIN BUSY Brake B Blind A Command for SSP $28 ($2C) $2C ($28) Fig. 4-4-(b). 1-Track Jump Timing Chart – 49 – $25 CXD3009Q 10 Track Track, sled FWD kick WAIT (Blind A) CNIN = 5 ? (Counts CNIN × 5) NO YES Track, REV kick C = Overflow ? NO (Checks whether the CNIN cycle is longer than overflow C) YES Track, sled servo ON END Fig. 4-5-(a). 10-Track Jump Flow Chart $4A (REV = $4B) latch XLT CNIN BUSY Blind A CNIN 5 count Overflow C Command for SSP $2E ($2B) $2A ($2F) Fig. 4-5-(b). 10-Track Jump Timing Chart – 50 – $25 CXD3009Q 2N Track Track, sled FWD kick WAIT (Blind A) CNIN = N NO YES Track REV kick C = Overflow NO YES Track servo ON WAIT (Kick D) Sled servo ON END Fig. 4-6-(a). 2N-Track Jump Flow Chart $4C (REV = $4D) latch XLT CNIN BUSY CNIN N count Blind A Command for SSP $2A ($2F) Overflow $2E ($2B) $26 ($27) Fig. 4-6-(b). 2N-Track Jump Timing Chart – 51 – Kick D $25 CXD3009Q N Track move Track servo OFF Sled FWD kick WAIT (Blind A) CNIN = N NO YES Track, sled servo OFF END END Fig. 4-7-(a). N-Track Move Flow Chart $4E (REV = $4F) latch XLT CNIN BUSY Blind A Command for SSP CNIN N count $20 $22 ($23) Fig. 4-7-(b). N-Track Move Timing Chart – 52 – CXD3009Q 4-7. Digital CLV Fig. 4-8 shows the Block Diagram. Digital CLV outputs MDS error and MDP error signals with PWM, with the signal sampling frequency increased up to 130kHz during normal-speed playback in CLVS, CLVP and other modes. In addition, the digital spindle servo gain is variable. Digital CLV CLVS U/D MDS Error MDP Error Measure Measure Over Sampling Filter-1 2/1 MUX CLV P/S Gain MDS Gain MDP 1/2 MUX Over Sampling Filter-2 CLV P/S Noise Shape Modulation KICK, BRAKE, STOP PWMI LPWR Mode Select MDP CLVS U/D: MDS error: MDP error: PWMI: Up/down signal from CLVS servo Frequency error for CLVP servo Phase error for CLVP servo Spindle drive signal from the microcomputer for CAV servo Fig. 4-8. Block Diagram – 53 – CXD3009Q 4-8. Asymmetry Compensation CXD3009Q ASYO 47 R1 RF 35 R1 R2 R1 ASYI 46 R1 36 BIAS R1 2 = R2 5 Fig. 4-9. Example of Asymmetry Compensation Application Circuit 4-9. CD-TEXT Data Demodulation • In order to demodulate the CD-TEXT data, set Data 6 D3 TXON command of $8 to 1. During TXON = 1, the EXCK pin should be set to low and the SBSO output data should not be used because the CD-TEXT demodulation circuit uses EXCK and SBSO exclusively. It requires 26.7ms (max.) to demodulate the CD-TEXT data properly after TXON is set to 1. • The CD-TEXT data is output after the SQSO pin is switched by the command. The CD-TEXT data can be output by setting Data 6 D2 TXOUT command of $8 to 1. The readout clock should be input to SQCK in order to read the data. • The data which can be read out is the CRC calculation results for each pack (CRC), CD-TEXT data excluding CRC data (16 bytes). • When the CD-TEXT data is read, the order of the MSB and LSB is inverted within each byte. As a result, although the sequence of bytes is the same, the bits within the bytes are now ordered LSB first. • The data which can be stored in the IC is for 1 packet (4 packs). TXON CD-TEXT Decoder EXCK SBSO Subcode Decoder SQCK SQSO TXOUT Fig. 4-10. CD-TEXT Demodulation Circuit Block Diagram – 54 – – 55 – TXOUT (command) SQCK SQSO TXOUT (command) SQCK SQSO SCOR 4 3 2 1 0 0 80 Clock Subcode Q Data CRC CRC CRC CRC CRC Data CRCF Fig. 4-11. CD-TEXT Data Timing Chart 0 0 S2 LSB R2 S1 R1 U3 T3 S3 U2 Pack4 16Byte R3 W2 V2 ID2 (Pack1) Pack3 Pack2 520 Clock 16Byte 16Byte MSB LSB Pack1 16Byte T1 ID1 (Pack1) 0 4bit W1 V1 U1 CRC 4bit T2 W4 V4 MSB LSB U4 T4 ID3 (Pack1) CRCF S4 CXD3009Q CXD3009Q 5. 1bit DAC Block 5-1. DAC Block Input Timing Timing Chart 5-1 shows the input timing for the DAC block. The data from the CD signal processor block to the DAC block can be connected inside the IC by setting the OUTL command of $8X to 1. Set OUTL1 to 0 when the data is send to the DAC block via the audio DSP and the like. 5-2. Description of DAC Block Functions Zero data detection When the condition where the lower 4bits of the input data are DC and the remaining upper bits are all "0" or all "1" has continued for approximately 300ms, zero data is detected. Zero data detection is performed independently for the left and right channels. Mute flag output The LMUT and RMUT pins go active when any one of the following conditions is met. The polarity can be selected by the ZDPL command of $9X. • When zero data is detected • When a high signal is input to the SYSM pin • When the SMUT command of $AX is set Attenuation operation Assuming attenuation data X1, X2 and X3 (X1 > X3 > X2), the corresponding audio outputs are Y1, Y2 and Y3 (Y1 > Y3 > Y2). First, X1 is sent, followed by X2. If X2 is sent before X1 reaches Y1 (A in the figure), X1 continues approaching Y2. Next, if X3 is sent before X1 reaches Y2 (B or C in the figure), X1 then approaches Y3 from the value (B or C in the figure) at that point. 0dB 7F (H) A Y1 B Y3 C Y2 –∞ 00 (H) 23.2 [ms] – 56 – CXD3009Q DAC block mute operation Soft mute Soft mute results and the input data is attenuated to zero when any one of the following conditions is met. • When attenuation data of "000" (high) is set • When the SMUT command of $AX is set to 1 • When a high signal is input to the SYSM input pin Soft mute off Soft mute on Soft mute off 0dB – ∞dB 23.2 [ms] 23.2 [ms] Forced mute Forced mute results when the FMUT command of $AX is set to 1. Forced mute fixes the PWM output that is input to the LPF block to low. ∗ When setting FMUT, set OPSL2 to 1. (See the $AX commands.) Zero detection mute Forced mute is applied when the ZMUT command of $9X is set to 1 and the zero data is detected for the left and right channels. (See "Zero data detection".) – 57 – 1 – 58 – PCMDI BCKI (4.23M) LRCKI (88.2k) R0 1 2 2 3 Lch MSB (15) Double-Speed Playback PCMDI R0 BCKI (2.12M) LRCKI (44.1k) Normal-Speed Playback Timing Chart 5-1 5 Lch MSB (15) 4 6 7 8 L14 10 L13 11 L12 12 L0 24 L11 Rch MSB L10 Input Timing for DAC Block 9 L9 L8 L7 L6 L5 L4 L3 L2 L1 L0 24 RMSB CXD3009Q CXD3009Q LRCK Synchronization Synchronization is performed at the first falling edge of the LRCK input during reset. After that, synchronization is lost when the LRCK input frequency changes and resynchronization must be performed. The LRCK input frequency changes when the master clock of the LSI is switched and the playback speed changes such as the following cases. • When the XTSL pin switches between high and low • When the DSPB command of $9X setting changes • When the MCSL command of $9X setting changes LRCK switching may also be performed if there are other ICs between the CD-DSP block and the DAC block. Resynchronization must be performed in this case as well. For resynchronization, set the LRWO command of $AX to 1, wait for one LRCK cycle or more, and then set LRWO to 0. ∗ When setting LRWO, set OPSL2 to 1. (See the $AX commands.) SYCOF When LRCK, PCMD and BCK are connected directly with LRCKI, PCMDI and BCKI, respectively, playback can be performed easily in CAV-W mode by setting SYCOF of address 9 to 1. Normally, the memory proof, etc., is used for playback in CAV-W mode. In CAV-W mode, the LRCK output conforms not to the crystal but to the VCO. Therefore, synchronization is frequently lost. Setting SYCOF of address 9 to 1 ignores that the LRCKI input synchronization is lost, facilitating playback. However, the playback is not perfect because pre-value hold or data skip occurs due to the wow flutter in the LRCKI input. ∗ Set SYCOF to 0 except when connecting LRCK, PCMD and BCK directly with LRCKI, PCMDI and BCKI, respectively, and performing playback in CAV-W mode. ∗ Set SYCOF to 0 in advance when LRCK resynchronization is applied with LRWO=1. Digital Bass Boost Bass boost without external parts is possible using the built-in digital filter. The boost strength has two levels: Mid. and Max. BSBST and BBSL of address A are used for the setting. See Graph 5-2 for the digital bass boost frequency response. 10.00 8.00 Normal 6.00 DBB MID 4.00 DBB MAX 2.00 [dB] 0.00 –2.00 –4.00 –6.00 –8.00 –10.00 –12.00 –14.00 10 30 100 300 1k 3k Digital Bass Boost Frequency Response [Hz] Graph 5-2. – 59 – 10k 30k CXD3009Q 6. LPF Block The CXD3009Q contains an initial-stage secondary active LPF with numerous resistors and capacitors and an operational amplifier with reference voltage. The resistors and capacitors are attached externally, allowing the cut-off frequency fc to be determined flexibly. The reference voltage (VC) is (AVDD – AVSS)/2. The LPF block application circuit is shown below. In this circuit, the cut-off frequency is fc ≈ 40kHz. The external capacitors' values when fc = 30kHz and 50kHz are noted below as a reference. The resistors' values do not change at this time. • When fc ≈ 30kHz: C1 = 200pF, C2 = 910pF • When fc ≈ 50kHz: C1 = 120pF, C2 = 560pF LPF Block Application Circuit 12k AOUT1 (2) C2 680p 12k AIN1 (2) Vc C1 150p 12k Analog out LOUT1 (2) Fig. 6-1. LPF External Circuit – 60 – CXD3009Q 7. Setting Method of the CXD3009Q Playback Speed (in CLV-N mode) (A) CD-DSP block The playback modes shown below can be selected by the combination of the crystal, XTSL pin and DSPB command of $9X. CD-DSP block playback speed X'tal XTSL DSPB CD-DSP block playback speed 768Fs 1 0 1× 768Fs 1 1 2× 384Fs 0 0 1× 384Fs 0 1 384Fs 1 1 2× 1×∗1 Fs = 44.1kHz ∗1 Low power consumption mode. The CD-DSP processing speed is halved, allowing the power consumption to be decreased. (B) 1-bit DAC block The operating speed of the DAC block is determined by the crystal and the MCSL command of $9X regardless of the operating conditions of the CD-DSP block mentioned above. This allows the playback mode for the DAC block and CD-DSP block to be set independently. 1-bit DAC block playback speed X'tal MCSL DAC block playback speed 768Fs 1 1× 768Fs 0 2× 384Fs 0 1× Fs = 44.1kHz – 61 – XPCK BCK BCKI Vss XUGF GFS DATO C2PO CNIN XTSL SEIN DOUT XLAT C4M CLOK EMPHI EMPH WFCK SBSO RMUT SCOR SQCK EXCK RF 35 74 LOUT2 80 VDD 79 XRST 78 AVss 77 AVDD 2 Vss 1 76 AOUT2 75 AIN2 4 7 6 5 8 9 PCO 29 3 FILO 30 71 XTAO 72 XVss LMUT SSP LS DRIVER RF 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. 10 11 12 13 14 15 16 17 18 19 20 MDP 21 PWMI 22 TEST 23 TES1 24 VPCO 25 VCKI 26 V16M 27 VCTL 28 FILI 31 70 XTAI 73 AVss CLTV 33 AVss 32 SQSO 69 XVDD SENS FOK SENS XRST DATA XLAT CLK GFS SQSO SQCK SCOR MUTE DATA 68 AVss AVDD 34 67 LOUT1 66 AIN1 BIAS 36 CLKO ASYI 37 SPOB 65 AOUT1 XLON ASYO 38 FOK 63 AVss LRCKI 40 LRCK 39 PCMD 64 AVDD XLTO 61 VDD VDD Vss 62 SYSM PCMDI 60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 VDD SPOA VDD Vss – 62 – Vss Application Circuit CXD3009Q CXD3009Q Unit: mm 80PIN QFP (PLASTIC) + 0.35 1.5 – 0.15 + 0.1 0.127 – 0.05 16.0 ± 0.4 + 0.4 14.0 – 0.1 0.1 60 41 40 80 21 (15.0) 61 + 0.15 0.1 – 0.1 20 + 0.15 0.3 – 0.1 0.5 ± 0.2 1 0.65 ± 0.12 M 0° to 10° PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE QFP-80P-L03 LEAD TREATMENT SOLDER PLATING EIAJ CODE LQFP080-P-1414 LEAD MATERIAL 42/COPPER ALLOY PACKAGE MASS 0.6g JEDEC CODE 80PIN QFP (PLASTIC) 16.0 ± 0.2 1.6MAX 14.0 ± 0.1 1.4 60 41 61 40 (15.0) B A 80 21 1 20 0.65 b 0.1 M 0.1 S b = 0.32 ± 0.1 + 0.03 0.17 – 0.05 S 0.1 ± 0.1 0.5 ± 0.15 Package Outline 0° to 10° DETAIL A DETAIL B PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE QFP-80P-L052 LEAD TREATMENT SOLDER PLATING EIAJ CODE P-QFP80-14X14-0.65 LEAD MATERIAL 42 ALLOY PACKAGE MASS 1.6 g JEDEC CODE – 63 – S