[AK4392] AK4392 High Performance 120dB Premium 32-Bit DAC GENERAL DESCRIPTION AK4392 is a 32-bit DAC, which corresponds to DVD-Audio systems. An internal circuit includes newly developed 32bit Digital Filter for better sound quality achieving low distortion characteristics and wide dynamic range. The AK4392 has full differential SCF outputs, removing the need for AC coupling capacitors and increasing performance for systems with excessive clock jitter. The AK4392 accepts 192kHz PCM data and 1-bit DSD data, ideal for a wide range of applications including Blu-Ray, DVD-Audio and SACD. FEATURES • 128x Over sampling • Sampling Rate: 30kHz ∼ 216kHz • 32Bit 8x Digital Filter (Minimum delay option GD=7/fs) - Ripple: ±0.005dB, Attenuation: 100dB • High Tolerance to Clock Jitter • Low Distortion Differential Output • DSD data input • Digital De-emphasis for 32, 44.1, 48kHz sampling • Soft Mute • Digital Attenuator (255 levels and 0.5dB step) • Mono Mode • External Digital Filter Mode • THD+N: -103dB • DR, S/N: 120dB • I/F Format: 24/32bit MSB justified, 16/20/24/32bit LSB justified, I2S, DSD • Master Clock: 30kHz ~ 32kHz: 1152fs 30kHz ~ 54kHz: 512fs or 768fs 30kHz ~ 108kHz: 256fs or 384fs 108kHz ~ 216kHz: 128fs or 192fs • Power Supply: 4.75 ∼ 5.25V • Digital Input Level: TTL • Package: 44pin LQFP MS1045-E-02 2009/04 -1- [AK4392] ■ Block Diagram DVDD BICK/DCLK LRCK/DSDR/WCK SDATA/DSDL VSS3 PDN DINL VSS4 VSS2 VDDL PCM Data Interface 8X Interpolator SCF AOUTLP AOUTLN DSD Data Interface BCK AVDD DATT Soft Mute Bias Vref ΔΣ Modulator External DF Interface SCF VCML VREFHL VREFLL VREFLR VREFLL VCMR AOUTRP AOUTRN DINR CSN/SMUTE CCLK/DEM0 Control Register VDDR Clock Divider CDTI/DEM1 VSS1 CAD0 CAD1/DIF0 PSN DZFL/DIF1 DIF2 MCLK DZFR Block Diagram MS1045-E-02 2009/04 -2- [AK4392] ■ Ordering Guide −10 ∼ +70°C 44pin LQFP (0.8mm pitch) Evaluation Board for AK4392 AK4392EQ AKD4392 AOUTLN VSS2 VDD L VREFHL VREFLL NC VREFLR VREFHR VDDR VSS1 AOUTRN 33 32 31 30 29 28 27 26 25 24 23 ■ Pin Layout AOU TL P 34 22 AOUTRP VCML 35 21 VCMR NC 36 20 NC NC 37 19 DI NL NC 38 18 DI NR NC 39 17 NC 16 BCK 15 TST2/DZFR AK4392 VSS3 40 AVDD 41 MCL K 42 14 PSN VSS4 43 13 NC NC 44 12 DI F2 7 8 9 10 11 DEM1/CDTI DIF0/CAD1 DIF1/DZFL 5 LRCK/DSDR/WCK TST1/CAD0 4 MS1045-E-02 DEM0/CCLK 3 BICK/DCLK SDATA/DSDL 6 2 PDN SMUTE/CSN 1 DVDD Top View 2009/04 -3- [AK4392] PIN/FUNCTION No. Pin Name I/O Function Digital Power Supply Pin, 4.75 ∼ 5.25V Power-Down Mode Pin When at “L”, the AK4392 is in power-down mode and is held in reset. The AK4392 should always be reset upon power-up. Audio Serial Data Clock Pin in PCM Mode DSD Clock Pin in DSD Mode Audio Serial Data Input Pin in PCM Mode DSD Lch Data Input Pin in DSD Mode L/R Clock Pin in PCM Mode DSD Rch Data Input Pin in DSD Mode Word Clock input pin Soft Mute Pin in Parallel Control Mode When this pin is changed to “H”, soft mute cycle is initiated. When returning “L”, the output mute releases. Chip Select Pin in Serial Control Mode Test Pin in Parallel Control Mode (Internal pull-down pin) Chip Address 0 Pin in Serial Control Mode (Internal pull-down pin) De-emphasis Enable 0 Pin in Parallel Control Mode Control Data Clock Pin in Serial Control Mode De-emphasis Enable 1 Pin in Parallel Control Mode Control Data Input Pin in Serial Control Mode Digital Input Format 0 Pin in PCM Mode Chip Address 1 Pin in Serial Control Mode Digital Input Format 1 Pin in PCM Mode Lch Zero Input Detect Pin in Serial Control Mode 1 DVDD - 2 PDN I BICK DCLK SDATA DSDL LRCK DSDR WCK I I I I I I I SMUTE I CSN TST1 CAD0 DEM0 CCLK DEM1 CDTI DIF0 CAD1 DIF1 DZFL I I I I I I I I I I O 12 DIF2 I 13 NC - 3 4 5 6 7 8 9 10 11 Digital Input Format 2 Pin in PCM Mode No internal bonding. Connect to GND. Note: All input pins except internal pull-up/down pins must not be left floating. MS1045-E-02 2009/04 -4- [AK4392] 14 PSN I TST2 I DZFR O 16 BCK I 17 NC - 18 19 DINR DINL I I 20 NC - 21 VCMR - 22 23 24 25 26 27 AOUTRP AOUTRN VSS1 VDDR VREFHR VREFLR O O I I 28 NC - 29 30 31 32 33 34 VREFLL VREFHL VDDL VSS2 AOUTLN AOUTLP I I O O 35 VCML - 36 NC - 37 NC - 38 NC - 39 NC - 40 41 42 43 VSS3 AVDD MCLK VSS4 I - 44 NC - 15 Parallel or Serial Select Pin (Internal pull-up pin) “L”: Serial Control Mode, “H”: Parallel Control Mode Test pin in Parallel Control Mode. Connect to GND. Rch Zero Input Detect Pin in Serial Control Mode Audio Serial Data Clock Pin (Internal pull-down pin) No internal bonding. Connect to GND. Rch Audio Serial Data Input Pin (Internal pull-down pin) Lch Audio Serial Data Input Pin (Internal pull-down pin) No internal bonding. Connect to GND. Right channel Common Voltage Pin, Normally connected to VSS with a 10uF electrolytic cap. Rch Positive Analog Output Pin Rch Negative Analog Output Pin Ground Pin Rch Analog Power Supply Pin, 4.75 ∼ 5.25V Rch High Level Voltage Reference Input Pin Rch Low Level Voltage Reference Input Pin No internal bonding. Connect to GND. Lch Low Level Voltage Reference Input Pin Lch High Level Voltage Reference Input Pin Lch Analog Power Supply Pin, 4.75 ∼ 5.25V Ground Pin Lch Negative Analog Output Pin Lch Positive Analog Output Pin Left channel Common Voltage Pin, Normally connected to VSS with a 10uF electrolytic cap. No internal bonding. Connect to GND. No internal bonding. Connect to GND. No internal bonding. Connect to GND. No internal bonding. Connect to GND. Ground Pin Analog Power Supply Pin, 4.75 ∼ 5.25V Master Clock Input Pin Ground Pin No internal bonding. Connect to GND. Note: All input pins except internal pull-up/down pins must not be left floating. MS1045-E-02 2009/04 -5- [AK4392] ■ Handling of Unused Pin The unused I/O pins should be processed appropriately as below. (1) Parallel Mode (PCM Mode only) Classification Pin Name AOUTLP, AOUTLN AOUTRP, AOUTRN SMUTE TST1 TST2 Analog Digital Setting These pins must be open. These pins must be open. This pin must be connected to VSS4. This pin must be open. This pin must be connected to VSS4. (2) Serial Mode 1. PCM Mode Classification Analog Digital Pin Name AOUTLP, AOUTLN AOUTRP, AOUTRN DIF2 DZFL, DZFR Setting These pins must be open. These pins must be open. These pins must be connected to VSS4. These pins must be open. 2. DSD Mode Classification Pin Name Analog AOUTLP, AOUTLN AOUTRP, AOUTRN DZFL, DZFR Setting These pins must be open. These pins must be open. These pins must be open. MS1045-E-02 2009/04 -6- [AK4392] ABSOLUTE MAXIMUM RATINGS (VSS1-4 =0V; Note 1) Parameter Power Supplies: Analog Analog Digital Input Current, Any Pin Except Supplies Digital Input Voltage Ambient Temperature (Power applied) Storage Temperature Symbol AVDD VDDL/R DVDD IIN VIND Ta Tstg min −0.3 −0.3 −0.3 −0.3 −10 −65 max 6.0 6.0 6.0 ±10 DVDD+0.3 70 150 Units V V V mA V °C °C Note 1. All voltages with respect to ground. Note 2. VSS1-4 must be connected to the same analog ground plane. WARNING: Operation at or beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes. RECOMMENDED OPERATING CONDITIONS (VSS1-4 =0V; Note 1) Parameter Symbol min typ 5.0 4.75 AVDD Analog Power Supplies 5.0 4.75 VDDL/R Analog (Note 3) 5.0 4.75 DVDD Digital AVDD−0.5 VREFHL/R “H” voltage reference Voltage VSS VREFLL/R “L” voltage reference Reference 3.0 ΔVREF VREFH − VREFL (Note 4) max 5.25 5.25 5.25 AVDD AVDD Units V V V V V V Note 1. All voltages with respect to ground. Note 3. The power up sequence between AVDD, VDDL/R and DVDD is not critical. Note 4. The analog output voltage scales with the voltage of (VREFH − VREFL). AOUT (typ.@0dB) = (AOUT+) − (AOUT−) = ±2.8Vpp × (VREFHL/R − VREFLL/R)/5. * AKM assumes no responsibility for the usage beyond the conditions in this data sheet. MS1045-E-02 2009/04 -7- [AK4392] ANALOG CHARACTERISTICS (Ta=25°C; AVDD=VDDL/R=DVDD=5.0V; VSS1-4 =0V; VREFHL/R=AVDD, VREFLL/R= VSS; Input data = 24bit; RL ≥ 1kΩ; BICK=64fs; Signal Frequency = 1kHz; Sampling Frequency = 44.1kHz; Measurement bandwidth = 20Hz ~ 20kHz; External Circuit: Figure 20; unless otherwise specified.) Parameter min typ max Resolution 24 Dynamic Characteristics (Note 5) 0dBFS -103 93 fs=44.1kHz THD+N BW=20kHz −60dBFS -57 0dBFS 100 fs=96kHz BW=40kHz −60dBFS -54 0dBFS 100 fs=192kHz BW=40kHz −60dBFS -54 BW=80kHz -51 −60dBFS Dynamic Range (−60dBFS with A-weighted) (Note 6) 114 120 S/N (A-weighted) (Note 7) 114 120 Interchannel Isolation (1kHz) 110 120 DC Accuracy Interchannel Gain Mismatch 0.15 0.3 Gain Drift (Note 8) 20 Output Voltage (Note 9) ±2.65 ±2.8 ±2.95 Load Capacitance 25 Load Resistance (Note 10) 1 Power Supplies Power Supply Current Normal operation (PDN pin = “H”) AVDD + VDDL/R 60 90 43 DVDD (fs ≤ 96kHz) 46 70 DVDD (fs = 192kHz) Power down (PDN pin = “L”) (Note 11) AVDD+VDDL/R+DVDD 10 100 Units Bits dB dB dB dB dB dB dB dB dB dB dB ppm/°C Vpp pF kΩ mA mA mA μA Note 5. Measured by Audio Precision, System Two. Averaging mode. Refer to the evaluation board manual. Note 6. Figure 20 External LPF Circuit Example 2. 101dB for 16-bit data and 118dB for 20-bit data. Note 7. Figure 20 External LPF Circuit Example 2. S/N does not depend on input data size. Note 8. The voltage on (VREFH − VREFL) is held +5V externally. Note 9. Full-scale voltage(0dB). Output voltage scales with the voltage of (VREFHL/R − VREFLL/R). AOUT (typ.@0dB) = (AOUT+) − (AOUT−) = ±2.8Vpp × (VREFHL/R − VREFLL/R)/5. Note 10. Regarding Load Resistance, AC load is 1kΩ (min) with a DC cut capacitor (Figure 20). DC load is 1.5k ohm (min) without a DC cut capacitor (Figure 19). The load resistance value is with respect to ground. Analog characteristics are sensitive to capacitive load that is connected to the output pin. Therefore the capacitive load must be minimized. Note 11. In the power down mode. The P/S pin = DVDD, and all other digital input pins including clock pins (MCLK, BICK and LRCK) are held VSS4. MS1045-E-02 2009/04 -8- [AK4392] SHARP ROLL-OFF FILTER CHARACTERISTICS (fs = 44.1kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Normal Speed Mode; DEM=OFF; SD bit=“0”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 20.0 kHz −6.0dB 22.05 kHz Stopband (Note 12) SB 24.1 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 100 dB Group Delay (Note 13) GD 36 1/fs Digital Filter + SCF Frequency Response: 0 ∼ 20.0kHz ±0.2 dB SHARP ROLL-OFF FILTER CHARACTERISTICS (fs = 96kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Double Speed Mode; DEM=OFF; SD bit=“0”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 43.5 kHz −6.0dB 48.0 kHz Stopband (Note 12) SB 52.5 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 95 dB Group Delay (Note 13) GD 36 1/fs Digital Filter + SCF Frequency Response: 0 ∼ 40.0kHz ±0.3 dB SHARP ROLL-OFF FILTER CHARACTERISTICS (fs = 192kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Quad Speed Mode; DEM=OFF; SD bit=“0”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 87.0 kHz −6.0dB 96.0 kHz Stopband (Note 12) SB 105 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 90 dB Group Delay (Note 13) GD 36 1/fs Digital Filter + SCF Frequency Response: 0 ∼ 80.0kHz +0/−1 dB Note 12. The passband and stopband frequencies scale with fs. For example, PB=0.4535×fs (@±0.01dB), SB=0.546×fs. Note 13. The calculating delay time which occurred by digital filtering. This time is from setting the 16/20/24bit data of both channels to input register to the output of analog signal. MS1045-E-02 2009/04 -9- [AK4392] MINIMUM DELAY FILTER CHARACTERISTICS (fs = 44.1kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Normal Speed Mode; DEM=OFF; SD bit=“1”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 20.0 kHz −6.0dB 22.05 kHz Stopband (Note 12) SB 24.1 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 100 dB Group Delay (Note 13) GD 7 1/fs Digital Filter + SCF Frequency Response : 0 ∼ 20.0kHz ±0.2 dB MINIMUM DELAY FILTER CHARACTERISTICS (fs = 96kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Double Speed Mode; DEM=OFF; SD bit=“1”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 43.5 kHz −6.0dB 48.0 kHz Stopband (Note 12) SB 52.5 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 95 dB Group Delay (Note 13) GD 7 1/fs Digital Filter + SCF Frequency Response : 0 ∼ 40.0kHz ±0.3 dB MINIMUM DELAY FILTER CHARACTERISTICS (fs = 192kHz) (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V; Quad Speed Mode; DEM=OFF; SD bit=“1”) Parameter Symbol min typ max Units Digital Filter Passband (Note 12) ±0.01dB PB 0 87.0 kHz −6.0dB 96.0 kHz Stopband (Note 12) SB 105 kHz Passband Ripple PR ±0.005 dB Stopband Attenuation SA 90 dB Group Delay (Note 13) GD 7 1/fs Digital Filter + SCF Frequency Response : 0 ∼ 80.0kHz +0/−1 dB MS1045-E-02 2009/04 - 10 - [AK4392] DC CHARACTERISTICS (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V) Parameter Symbol min High-Level Input Voltage VIH 2.4 Low-Level Input Voltage VIL High-Level Output Voltage (Iout=−100μA) VOH DVDD−0.5 Low-Level Output Voltage (Iout=100μA) VOL Input Leakage Current (Note 14) Iin - typ - max 0.8 0.5 ±10 Units V V V V μA Note 14. The TST1/CAD0 and PSN pins have internal pull-up devices, nominally 100kΩ. Therefore The TST1/CAD0 and PSN pins are not included. MS1045-E-02 2009/04 - 11 - [AK4392] SWITCHING CHARACTERISTICS (Ta=25°C; AVDD=VDDL/R=4.75 ∼ 5.25V, DVDD=4.75 ∼ 5.25V) Parameter Symbol min Master Clock Timing Frequency fCLK 7.7 Duty Cycle dCLK 40 LRCK Frequency (Note 15) 1152fs, 512fs or 768fs fsn 30 256fs or 384fs fsd 54 128fs or 192fs fsq 108 Duty Cycle Duty 45 PCM Audio Interface Timing BICK Period 1/128fsn tBCK 1152fs, 512fs or 768fs 1/64fsd tBCK 256fs or 384fs 1/64fsq tBCK 128fs or 192fs 30 tBCKL BICK Pulse Width Low 30 tBCKH BICK Pulse Width High 20 tBLR BICK “↑” to LRCK Edge (Note 16) 20 tLRB LRCK Edge to BICK “↑” (Note 16) 20 tSDH SDATA Hold Time 20 tSDS SDATA Setup Time External Digital Filter Mode 27 tB BICK Period 10 tBL BCK Pulse Width Low 10 tBH BCK Pulse Width High 5 tBW BCK “↑” to WCK Edge 5 tWB WCK Edge to BCK “↑” 54 tWCK WCK Pulse Width Low 54 tWCH WCK Pulse Width High 5 tDH DATA Hold Time 5 tDS DATA Setup Time DSD Audio Interface Timing 1/64fs tDCK DCLK Period 160 tDCKL DCLK Pulse Width Low 160 tDCKH DCLK Pulse Width High −20 tDDD DCLK Edge to DSDL/R (Note 17) Control Interface Timing 200 tCCK CCLK Period 80 tCCKL CCLK Pulse Width Low 80 tCCKH Pulse Width High 50 tCDS CDTI Setup Time 50 tCDH CDTI Hold Time 150 tCSW CSN High Time 50 tCSS CSN “↓” to CCLK “↑” 50 tCSH CCLK “↑” to CSN “↑” Reset Timing PDN Pulse Width (Note 18) tPD 150 MS1045-E-02 typ max Units 41.472 60 MHz % 54 108 216 55 kHz kHz kHz % ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 20 ns ns ns ns ns ns ns ns ns ns ns ns ns 2009/04 - 12 - [AK4392] Note 15. When the 1152fs, 512fs or 768fs /256fs or 384fs /128fs or 192fs are switched, the AK4392 should be reset by the PDN pin or RSTN bit. Note 16. BICK rising edge must not occur at the same time as LRCK edge. Note 17. DSD data transmitting device must meet this time. Note 18. The AK4392 can be reset by bringing the PDN pin “L” to “H” upon power-up. ■ Timing Diagram 1/fCLK VIH MCLK VIL tCLKH tCLKL dCLK=tCLKH x fCLK, tCLKL x fCLK 1/fs VIH LRCK VIL tBCK VIH BICK VIL tBCKH tBCKL 1/fs VIH WCK VIL tB VIH BCK VIL tBH tBL Clock Timing MS1045-E-02 2009/04 - 13 - [AK4392] VIH LRCK VIL tLRB tBLR VIH BICK VIL tSDH tSDS VIH SDATA VIL Audio Interface Timing (PCM Mode) tDCK tDCKL tDCKH VIH DCLK VIL tDDD VIH DSDL DSDR VIL Audio Serial Interface Timing (DSD Normal Mode, DCKB bit = “0”) tDCK tDCKL tDCKH VIH DCLK VIL tDDD tDDD VIH DSDL DSDR VIL Audio Serial Interface Timing (DSD Phase Modulation Mode, DCKB bit = “0”) MS1045-E-02 2009/04 - 14 - [AK4392] VIH CSN VIL tCSS tCCKL tCCKH VIH CCLK VIL tCDS C1 CDTI tCDH C0 R/W VIH A4 VIL WRITE Command Input Timing tCSW VIH CSN VIL tCSH VIH CCLK CDTI VIL D3 D2 D1 D0 VIH VIL WRITE Data Input Timing MS1045-E-02 2009/04 - 15 - [AK4392] tPD PDN VIL Power Down & Reset Timing VIH WCK VIL tBW tWB VIH BCK VIL tDS tDH VIH DATA VIL External Digital Filter I/F mode MS1045-E-02 2009/04 - 16 - [AK4392] OPERATION OVERVIEW ■ D/A Conversion Mode In serial mode, the AK4392 can perform D/A conversion for either PCM data or DSD data. The D/P bit controls PCM/DSD mode. When DSD mode, DSD data can be input from DCLK, DSDL and DSDR pins. When PCM mode, PCM data can be input from BICK, LRCK and SDATA pins. When PCM/DSD mode is changed by D/P bit, the AK4392 should be reset by RSTN bit. It takes about 2/fs to 3/fs to change the mode. In parallel mode, the AK4392 performs for only PCM data. DP bit Interface 0 PCM 1 DSD Table 1. PCM/DSD Mode Control When DP bit= “0”, an internal digital filter or external digital filter can be selected. When using an external digital filter (EX DF I/F mode), data is input to each MCLK, BCK, WCK, DINL and DINR pin. EXDF bit controls the modes. When switching internal and external digital filters, the AK4392 must be reset by RSTN bit. A Digital filter switching takes 2~3k/fs. Ex DF bit Interface 0 PCM 1 EX DF I/F Table 2. Digital Filter Control (DP bit = “0”) ■ System Clock [1] PCM Mode The external clocks, which are required to operate the AK4392, are MCLK, BICK and LRCK. MCLK should be synchronized with LRCK but the phase is not critical. The MCLK is used to operate the digital interpolation filter and the delta-sigma modulator. Sampling speed and MCLK frequency are detected automatically and then the initial master clock is set to the appropriate frequency (Table 3). When external clocks are changed, the AK4392 should be reset by the PDN pin or RSTN bit. The AK4392 is automatically placed in reset state when MCLK and LRCK are stopped during a normal operation (PDN pin =“H”), and the analog output becomes Hi-Z. When MCLK and LRCK are input again, the AK4392 exit reset state and starts the operation. After exiting system reset (PDN pin =“L”→“H”) at power-up and other situations, the AK4392 is in power-down mode until MCLK and LRCK are supplied. The MCLK frequency corresponding to each sampling speed should be provided (Table 4). MCLK 1152fs 512fs 256fs 128fs Mode Normal 768fs Normal 384fs Double 192fs Quad Table 3. Sampling Speed MS1045-E-02 Sampling Rate 30kHz~32kHz 30kHz~54kHz 30kHz~108kHz 108kHz~216kHz 2009/04 - 17 - [AK4392] LRCK fs 32.0kHz 44.1kHz 48.0kHz 88.2kHz 96.0kHz 176.4kHz 192.0kHz MCLK (MHz) 128fs 192fs 256fs 384fs 512fs 768fs N/A N/A 8.1920 12.2880 16.3840 24.5760 N/A N/A 11.2896 16.9344 22.5792 33.8688 N/A N/A 12.2880 18.4320 24.5760 36.8640 N/A N/A 22.5792 33.8688 N/A N/A N/A N/A 24.5760 36.8640 N/A N/A 22.5792 33.8688 N/A N/A N/A N/A 24.5760 36.8640 N/A N/A N/A N/A Table 4. System Clock Example (Parallel Control Mode) (N/A: Not available) 1152fs 36.8640 N/A N/A N/A N/A N/A N/A MCLK= 256fs/384fs supports sampling rate of 30kHz~108kHz (Table 5). But, when the sampling rate is 30kHz~54kHz, DR and S/N will degrade by approximately 3dB as compared to when MCLK= 512fs/768fs. MCLK DR,S/N 256fs/384fs 117dB 512fs/768fs 120dB Table 5. Relationship between MCLK frequency and DR, S/N (fs= 44.1kHz) [2] DSD Mode The external clocks, which are required to operate the AK4392, are MCLK and DCLK. MCLK should be synchronized with DCLK but the phase is not critical. The frequency of MCLK is set by DCKS bit. The AK4392 is automatically placed in reset state when MCLK is stopped during a normal operation (PDN pin =“H”), and the analog output becomes Hi-Z. After exiting system reset (PDN pin =“L”→“H”) at power-up and other situations, the AK4392 is in power-down mode until MCLK is supplied. DCKS bit 0 1 MCLK Frequency DCLK Frequency 512fs 64fs 768fs 64fs Table 6. System Clock (DSD Mode) MS1045-E-02 (default) 2009/04 - 18 - [AK4392] ■ Audio Interface Format [1] PCM Mode Data is shifted in via the SDATA pin using BICK and LRCK inputs. Eight data formats are supported and selected by the DIF2-0 pins (Parallel control mode) or DIF2-0 bits (Serial control mode) as shown in Table 7. In all formats the serial data is MSB-first, 2's compliment format and is latched on the rising edge of BICK. Mode 2 can be used for 20-bit and 16-bit MSB justified formats by zeroing the unused LSBs. Settings should be made by DIF2-0 pins in parallel mode and DIF2-0 bits in serial mode. Mode 0 1 2 3 4 5 6 7 DIF2 0 0 0 0 1 1 1 1 DIF1 0 0 1 1 0 0 1 1 DIF0 Input Format 0 16bit LSB justified 1 20bit LSB justified 0 24bit MSB justified 1 24bit I2S Compatible 0 24bit LSB justified 1 32bit LSB justified 0 32bit MSB justified 1 32bit I2S Compatible Table 7. Audio Interface Format BICK ≥ 32fs ≥ 48fs ≥ 48fs ≥ 48fs ≥ 48fs ≥ 64fs ≥64fs ≥ 64fs Figure Figure 1 Figure 2 Figure 3 Figure 4 Figure 2 Figure 5 Figure 6 Figure 7 (default) LRCK 0 1 10 11 12 13 14 15 0 1 10 11 12 13 14 15 0 1 BICK (32fs) SDATA Mode 0 15 0 14 6 1 5 14 4 15 3 2 16 17 1 0 31 15 0 14 6 5 14 1 4 15 3 16 2 17 1 0 31 15 14 0 1 0 1 BICK (64fs) SDATA Mode 0 Don’t care 15 14 15 Don’t care 0 14 0 15:MSB, 0:LSB Lch Data Rch Data Figure 1. Mode 0 Timing LRCK 0 1 8 9 10 11 12 31 0 1 8 9 10 11 12 31 BICK (64fs) SDATA Mode 1 Don’t care 19 0 Don’t care 19 0 Don’t care 19 0 19 0 19:MSB, 0:LSB SDATA Mode 4 Don’t care 23 22 21 20 23 22 21 20 23:MSB, 0:LSB Lch Data Rch Data Figure 2. Mode 1/4 Timing MS1045-E-02 2009/04 - 19 - [AK4392] LRCK 0 1 2 22 23 24 30 31 0 1 2 22 23 24 30 31 0 1 BICK (64fs) SDATA 23 22 1 0 Don’t care 23 22 0 1 Don’t care 23 22 0 1 23:MSB, 0:LSB Lch Data Rch Data Figure 3. Mode 2 Timing LRCK 0 1 2 3 23 24 25 31 0 1 2 3 23 24 25 31 BICK (64fs) SDATA 1 23 22 0 Don’t care 23 22 0 1 23 Don’t care 23:MSB, 0:LSB Lch Data Rch Data Figure 4. Mode 3 Timing LRCK 0 1 2 20 21 22 32 33 63 0 1 2 20 21 22 32 33 63 0 1 BICK(128fs) SDATA 31 0 1 2 12 13 14 23 1 24 0 31 31 0 1 2 12 13 14 23 1 24 0 31 0 1 BICK(64fs) SDATA 31 30 20 19 18 9 8 1 0 31 30 Lch Data 20 19 18 9 8 1 0 31 Rch Data 31: MSB, 0:LSB Figure 5. Mode 5 Timing MS1045-E-02 2009/04 - 20 - [AK4392] LRCK 0 1 2 20 21 22 32 33 63 0 1 2 20 21 22 32 33 63 0 1 BICK(128fs) SDATA 31 30 0 1 12 11 10 2 12 13 0 14 31 30 23 24 31 0 1 12 2 11 10 12 13 0 14 31 23 24 31 0 1 BICK(64fs) SDATA 31 30 20 19 18 8 9 0 1 31 30 20 19 18 Lch Data 8 9 0 1 31 Rch Data 31: MSB, 0:LSB Figure 6. Mode 6 Timing LRCK 0 1 2 20 21 22 33 34 63 0 1 2 20 21 22 33 34 63 24 25 31 0 1 BICK(128fs) SDATA 31 0 1 13 12 11 2 12 13 0 14 31 24 25 31 0 1 13 2 12 11 12 0 13 14 0 1 BICK(64fs) SDATA 0 31 21 20 19 8 9 1 2 0 31 21 20 19 Lch Data 9 8 2 1 0 Rch Data 31: MSB, 0:LSB Figure 7. Mode 7 Timing [2] DSD Mode In case of DSD mode, DIF2-0 pins and DIF2-0 bits are ignored. The frequency of DCLK is fixed to 64fs. DCKB bit can invert the polarity of DCLK. DCLK (64fs) DCKB=1 DCLK (64fs) DCKB=0 DSDL,DSDR Normal D0 DSDL,DSDR Phase Modulation D0 D1 D1 D2 D1 D2 D3 D2 D3 Figure 8. DSD Mode Timing MS1045-E-02 2009/04 - 21 - [AK4392] [3] External Digital Filter Mode (EX DF I/F Mode) DW indicates the number of BCK in one WCK cycle. The audio data is input by MCLK, BCK and WCK from the DINL and DINR pins. Three formats are available (Table 9) by DIF2-0 bits setting. The data is latched on the rising edge of BCK. The BCK and MCLK clocks must be the same frequency and must not burst. BCK and MCLK frequencies for each sampling speed are shown in Table 8. The AK4392 is automatically placed in reset state when MCLK and WCK are stopped during a normal operation (PDN pin =“H”), and the analog output becomes Hi-Z. When MCLK and WCK are input again, the AK4392 exit reset state and starts the operation. After exiting system reset (PDN pin =“L”→“H”) at power-up and other situations, the AK4392 is in power-down mode until MCLK and WCK are supplied. Sampling Speed[kHz] 44.1(30~54) 44.1(30~54) 96(54~108) 96(54~108) 192(108~216) 192(108~216) MCLK&BCK [MHz] 128fs N/A 512fs 768fs 22.5792 33.8688 48 11.2896 32 16.9344 32 N/A 33.8688 N/A 24.576 36.864 N/A 96 N/A 48 12.288 32 18.432 32 N/A 36.864 N/A N/A 24.576 36.864 N/A 96 N/A N/A N/A 32 N/A 48 N/A N/A 256fs N/A WCK 384fs N/A N/A 192fs N/A 48 48 N/A N/A N/A N/A 96 Table 8 System Clock Example (EX DF I/F mode) (N/A: Not available) 36.864 16fs DW 8fs DW 8fs DW 4fs DW 4fs DW 2fs DW ECS 0 1 0 1 0 1 Mode DIF2 DIF1 DIF0 Input Format 0 0 0 0 16bit LSB justified 1 0 0 1 N/A 2 0 1 0 N/A 3 0 1 1 N/A 4 1 0 0 24bit LSB justified 5 1 0 1 32bit LSB justified 6 1 1 0 N/A 7 1 1 1 N/A Table 9 Audio Interface Format (EX DF I/F mode) (N/A: Not available) MS1045-E-02 2009/04 - 22 - [AK4392] 1/16fs or 1/8fs or 1/4fs or 1/2fs WCK 0 1 8 9 10 11 16 17 26 27 28 29 30 31 0 1 BCK DINL or DINR 31 0 30 1 24 23 5 22 6 21 7 20 8 17 16 47 15 48 14 6 5 65 49 4 3 92 2 93 1 94 0 95 0 1 BCK DINL or DINR Don’t care 0 1 Don’t care 5 6 7 Don’t care 8 23 24 31 17 25 44 1 2 3 45 46 0 Don’t care 47 0 1 BCK DINL or DINR Don’t care Don’t care Don’t care 31 3 2 1 0 Don’t care Figure 9 EX DF I/F Mode Timing MS1045-E-02 2009/04 - 23 - [AK4392] ■ D/A Conversion Mode Switching Timing RSTN bit ≥4/fs D/A Mode PCM Mode DSD Mode ≥0 D/A Data PCM Data DSD Data Figure 10. D/A Mode Switching Timing (PCM to DSD) RSTN bit D/A Mode DSD Mode PCM Mode ≥4/fs D/A Data DSD Data PCM Data Figure 11. D/A Mode Switching Timing (DSD to PCM) Note. The signal range is identified as 25% ~ 75% duty ratios in DSD mode. DSD signal must not go beyond this duty range at the SACD format book (Scarlet Book). ■ De-emphasis Filter A digital de-emphasis filter is available for 32kHz, 44.1kHz or 48kHz sampling rates (tc = 50/15µs) and is enabled or disabled with DEM1-0 pins or DEM1-0 bits. In case of 256fs/384fs and 128fs/192fs, the digital de-emphasis filter is always off. When DSD mode, DEM1-0 bits are ignored. The setting value is held even if PCM mode and DSD mode are switched. DEM1 0 0 1 1 DEM0 Mode 0 44.1kHz 1 OFF (default) 0 48kHz 1 32kHz Table 10. De-emphasis Control ■ Output Volume The AK4392 includes channel independent digital output volumes (ATT) with 255 levels at linear step including MUTE. These volume control is in front of the DAC and it can attenuate the input data from 0dB to –127dB and mute. When changing output levels, transitions are executed in soft change; thus no switching noise occurs during these transitions. MS1045-E-02 2009/04 - 24 - [AK4392] ■ Zero Detection (PCM mode, DSD mode) The AK4392 has channel-independent zeros detect function. When the input data at each channel is continuously zeros for 8192 LRCK cycles, the DZF pin of each channel goes to “H”. The DZF pin of each channel immediately return to “L” if the input data of each channel is not zero after going to “H”. If the RSTN bit is “0”, the DZF pins of both channels go to “H”. The DZF pins of both channels go to “L” at 4 ~ 5/fs after RSTN bit returns to “1”. If DZFM bit is set to “1”, the DZF pins of both channels go to “H” only when the input data for both channels are continuously zeros for 8192 LRCK cycles. The zero detect function can be disabled by setting the DZFE bit. In this case, DZF pins of both channels are always “L”. The DZFB bit can invert the polarity of the DZF pin. ■ Mono Output The AK4392 can select input/output for both output channels by setting the MONO bit and SELLR bit. This function is available for any audio format. MONO bit 0 0 1 1 SELLR bit 0 1 0 1 Lch Out Lch In Rch In Lch In Rch In Rch Out Rch In Lch In Lch In Rch In Table 11 MONO Mode Output Select MS1045-E-02 2009/04 - 25 - [AK4392] ■ Soft Mute Operation The soft mute operation is performed at digital domain. When the SMUTE pin goes to “H” or the SMUTE bit set to “1”, the output signal is attenuated by −∞ during ATT_DATA × ATT transition time from the current ATT level. When the SMUTE pin is returned to “L” or the SMUTE bit is returned to “0”, the mute is cancelled and the output attenuation gradually changes to the ATT level during ATT_DATA × ATT transition time. If the soft mute is cancelled before attenuating −∞ after starting the operation, the attenuation is discontinued and returned to ATT level by the same cycle. The soft mute is effective for changing the signal source without stopping the signal transmission. S M U T E pin or S M U T E bit (1) (1) AT T _Level (3) A ttenuation -∞ GD (2) GD (2) AOUT D ZF pin (4) 8192/fs Notes: (1) ATT_DATA × ATT transition time. For example, this time is 1020LRCK cycles (1020/fs) at ATT_DATA=255 in Normal Speed Mode. (2) The analog output corresponding to the digital input has group delay (GD). (3) If the soft mute is cancelled before attenuating −∞ after starting the operation, the attenuation is discontinued and returned to ATT level by the same cycle. (4) When the input data for each channel is continuously zeros for 8192 LRCK cycles, the DZF pin for each channel goes to “H”. The DZF pin immediately returns to “L” if input data are not zero. Figure 12. Soft Mute Function ■ System Reset The AK4392 should be reset once by bringing the PDN pin = “L” upon power-up. It initializes register settings of the device. The AK4392 exits this system reset (power-down mode) by MCLK and LRCK after the PDN pin = “H”, and the analog block exits power-down mode. The digital block exits power-down mode after the internal counter counts MCLK for 4/fs. MS1045-E-02 2009/04 - 26 - [AK4392] ■ Power ON/OFF timing The AK4392 is placed in the power-down mode by bringing the PDN pin “L” and the registers are initialized. the analog outputs are floating (Hi-Z). As some click noise occurs at the edge of the PDN pin signal, the analog output should be muted externally if the click noise influences system application. The DAC can be reset by setting RSTN bit to “0”. In this case, the registers are not initialized and the corresponding analog outputs go to VCML/R. As some click noise occurs at the edge of RSTN signal, the analog output should be muted externally if click noise aversely affect system performance. Power PDN pin (1) Internal State Normal Operation DAC In (Digital) “0”data “0”data GD DAC Out (Analog) (3) Reset (2) (4) GD (4) (3) (5) Clock In MCLK,LRCK,BICK Don’t care Don’t care (7) DZFL/DZFR External Mute (6) Mute ON Mute ON Notes: (1) After AVDD and DVDD are powered-up, the PDN pin should be “L” for 150ns. (2) The analog output corresponding to digital input has group delay (GD). (3) Analog outputs are floating (Hi-Z) in power-down mode. (4) Click noise occurs at the edge of PDN signal. This noise is output even if “0” data is input. (5) MCLK, BICK and LRCK clocks can be stopped in power-down mode (PDN pin= “L”). (6) Mute the analog output externally if click noise (3) adversely affect system performance The timing example is shown in this figure. (7) DZFL/R pins are “L” in the power-down mode (PDN pin = “L”). Figure 13. Power-down/up Sequence Example MS1045-E-02 2009/04 - 27 - [AK4392] ■ Reset Function (1) RESET by RSTN bit = “0” When the RSTN bit = “0”, the AK4392’s digital block is powered down, but the internal register values are not initialized. In this time, the analog outputs go to VCML/R voltage and DZFL/DZFR pins are “H”. Figure 14 shows an example of reset by RSTN bit. RSTN bit 3~4/fs (5) 2~3/fs (5) Internal RSTN bit Internal State Normal Operation P D/A In (Digital) d “0 ” data (1) D/A Out (Analog) Normal O peration D igital Block GD GD (3) (2) (3) (1) 2/ fs(4) DZF (6) Notes: (1) The analog output corresponding to digital input has group delay (GD). (2) Analog outputs settle to VCOM voltage. (3) Small pop noise occurs at the edges(“↑ ↓”) of the internal timing of RSTN bit. This noise is output even if “0” data is input. (4) The DZF pins change to “H” when the RSTN bit becomes “0”, and return to “L” at 2/fs after RSTN bit becomes “1”. (5) There is a delay, 3~4/fs from RSTN bit “0” to the internal RSTN bit “0”, and 2~3/fs from RSTN bit “1” to the internal RSTN bit “1”. (6) Mute the analog output externally if click noise (3) and Hi-Z (2) adversely affect system performance Figure 14. Reset Sequence Example 1 MS1045-E-02 2009/04 - 28 - [AK4392] (2) RESET by MCLK or LRCK/WCK Stop The AK4392 is automatically placed in reset state when MCLK or LRCK is stopped during PDM mode (RSTN pin =“H”), and the analog outputs are floating (Hi-Z). When MCLK and LRCK are input again, the AK4392 exits reset state and starts the operation. Zero detect function is disable when MCLK or LRCK is stopped. In DSD mode the AK4392 is in reset state when MCLK is stopped, and it is in reset state when MCLK and WCK are stopped in external digital filter mode. AVDD pin DVDD pin RSTB pin (1) Internal State Power-down D/A In (Digital) Power-down Normal O peration Normal Operation (3) GD D/A Out (Analog) Digital Circuit P ower-down (2) GD (4) Hi-Z (5) (2) (4) (4) (5) Clock In MCLK, BICK, LRCK Stop MCLK, BICK, LRCK External MUTE (6) (6) (6) Notes: (1) After AVDD and DVDD are powered-up, the PDN pin should be “L” for 150ns. (2) The analog output corresponding to digital input has group delay (GD). (3) The digital data can be stopped. Click noise after MCLK, BICK and LRCK are input again can be reduced by inputting “0” data during this period. (4) Click noise occurs within 3 ~ 4LRCK cycles from the riding edge (“↑”) of the PDN pin or MCLK inputs. This noise occurs even when “0” data is input. (5) Clocks (MCLK, BICK, LRCK) can be stopped in the reset state (MCLK or LRCK is stopped). (6) Mute the analog output externally if click noise (4) influences system applications. The timing example is shown in this figure. Figure 15. Reset Sequence Example 2 MS1045-E-02 2009/04 - 29 - [AK4392] ■ Register Control Interface Pins (parallel control mode) or registers (serial control mode) can control the functions of the AK4392. In parallel control mode, the register setting is ignored, and in serial control mode the pin settings are ignored. When the state of the PSN pin is changed, the AK4392 should be reset by the PDN pin. The serial control interface is enabled by the PSN pin = “L”. In this mode, pin settings must be all “L”. Internal registers may be written to through3-wire µP interface pins: CSN, CCLK and CDTI. The data on this interface consists of Chip address (2-bits, C1/0), Read/Write (1-bit; fixed to “1”), Register address (MSB first, 5-bits) and Control data (MSB first, 8-bits). The AK4392 latches the data on the rising edge of CCLK, so data should be clocked in on the falling edge. The writing of data is valid when CSN “↑”. The clock speed of CCLK is 5MHz (max). Function Parallel Control Mode Serial Control Mode Audio Format Y Y De-emphasis Y Y SMUTE Y Y DSD Mode Y EX DF I/F Y Minimum delay Filter Y Digital Attenuator Y Table 12. Function List1 (Y: Available, -: Not available) Setting the PDN pin to “L” resets the registers to their default values. In serial control mode, the internal timing circuit is reset by the RSTN bit, but the registers are not initialized. CSN 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CCLK CDTI C1 C0 R/W A4 A3 A2 A1 A0 D7 D6 D5 D4 D3 D2 D1 D0 C1-C0: Chip Address (C1 bit =CAD1 pin, C0 bit =CAD0 pin) R/W: READ/WRITE (Fixed to “1”, Write only) A4-A0: Register Address D7-D0: Control Data Figure 16. Control I/F Timing * The AK4392 does not support the read command. * When the AK4392 is in power down mode (PDN pin = “L”) or the MCLK is not provided, a writing into the control registers is prohibited. * The control data can not be written when the CCLK rising edge is 15 times or less or 17 times or more during CSN is “L”. MS1045-E-02 2009/04 - 30 - [AK4392] Function List Function Attenuation Level Default 0dB Address 03H 04H 00H 00H 00H 01H 01H 01H 01H 01H 02H 02H Bit ATT7-0 External Digital Filter I/F Mode Disable EXDF Ex DF I/F mode clock setting 16fs(fs=44.1kHz) ESC Audio Data Interface Modes 24bit MSB justified DIF2-0 Data Zero Detect Enable Disable DZFE Data Zero Detect Mode Separated DZFM Minimum delay Filter Enable Sharp roll-off filter SD De-emphasis Response OFF DEM1-0 Soft Mute Enable Normal Operation SMUTE DSD/PCM Mode Select PCM mode DP Master Clock Frequency Select at 512fs DCKS DSD mode MONO mode Stereo mode select Stereo 02H MONO Inverting Enable of DZF “H” active 02H DZFB The data selection of L channel and R channel 02H SELLR R channel Table 13. Function List2 (Y: Available, -: Not available) MS1045-E-02 PCM DSD Ex DF I/F Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y Y - - Y - Y Y Y Y Y - Y Y Y Y - 2009/04 - 31 - [AK4392] ■ Register Map Addr 00H 01H 02H 03H 04H Register Name Control 1 Control 2 Control 3 Lch ATT Rch ATT D7 0 DZFE DP ATT7 ATT7 D6 EXDF DZFM 0 ATT6 ATT6 D5 ECS SD DCKS ATT5 ATT5 D4 0 0 DCKB ATT4 ATT4 D3 DIF2 0 MONO ATT3 ATT3 D2 DIF1 DEM1 DZFB ATT2 ATT2 D1 DIF0 DEM0 SELLR ATT1 ATT1 D0 RSTN SMUTE 0 ATT0 ATT0 Notes: Data must not be written into addresses from 05H to 1FH. When the PDN pin goes to “L”, the registers are initialized to their default values. When RSTN bit is set to “0”, only the internal timing is reset, and the registers are not initialized to their default values. When the state of the PSN pin is changed, the AK4392 should be reset by the PDN pin. ■ Register Definitions Addr Register Name 00H Control 1 Default D7 0 0 D6 EXDF 0 D5 ECS 0 D4 0 0 D3 DIF2 0 D2 DIF1 1 D1 DIF0 0 D0 RSTN 1 RSTN: Internal Timing Reset 0: Reset. All registers are not initialized. 1: Normal Operation (default) When internal clocks are changed, the AK4392 should be reset by the PDN pin or RSTN bit. DIF2-0: Audio Data Interface Modes (Table 7) Initial value is “010” (Mode 2: 24-bit MSB justified). ECS: Ex DF I/F mode clock setting (Table 8) 0: Disable: Internal Digital Filter mode (default) 1: Enable: External Digital Filter mode EXDF: External Digital Filter I/F Mode (Serial mode only) 0: Disable: Internal Digital Filter mode (default) 1: Enable: External Digital Filter mode MS1045-E-02 2009/04 - 32 - [AK4392] Addr Register Name 01H Control 2 Default D7 DZFE 0 D6 DZFM 0 D5 SD 0 D4 0 0 D3 0 0 D2 DEM1 0 D1 DEM0 1 D0 SMUTE 0 SMUTE: Soft Mute Enable 0: Normal Operation (default) 1: DAC outputs soft-muted. DEM1-0: De-emphasis Response (Table 10) Initial value is “01” (OFF). SD: Minimum delay Filter Enable 0: Sharp roll-off filter (default) 1: Minimum delay filter DZFM: Data Zero Detect Mode 0: Channel Separated Mode (default) 1: Channel ANDed Mode If the DZFM bit is set to “1”, the DZF pins of both channels go to “H” only when the input data at both channels are continuously zeros for 8192 LRCK cycles. DZFE: Data Zero Detect Enable 0: Disable (default) 1: Enable Zero detect function can be disabled by DZFE bit “0”. In this case, the DZF pins of both channels are always “L”. MS1045-E-02 2009/04 - 33 - [AK4392] Addr Register Name 02H Control 3 Default D7 DP 0 D6 0 0 D5 DCKS 0 D4 DCKB 0 D3 MONO 0 D2 DZFB 0 D1 SELLR 0 D0 0 0 SELLR: The data selection of L channel and R channel, when MONO mode 0: All channel output R channel data, when MONO mode. (default) 1: All channel output L channel data, when MONO mode. It is enabled when MONO bit is “1”, and outputs Rch date to both channels when “0”,outputs Lch data to both channels when “1”. DZFB: Inverting Enable of DZF 0: DZF pin goes “H” at Zero Detection (default) 1: DZF pin goes “L” at Zero Detection MONO: MONO mode Stereo mode select 0: Stereo mode (default) 1: MONO mode When MONO bit is “1”, MONO mode is enabled. DCKB: Polarity of DCLK (DSD Only) 0: DSD data is output from DCLK falling edge. (default) 1: DSD data is output from DCLK rising edge. DCKS: Master Clock Frequency Select at DSD mode (DSD only) 0: 512fs (default) 1: 768fs DP: DSD/PCM Mode Select 0: PCM Mode (default) 1: DSD Mode When D/P bit is changed, the AK4392 should be reset by RSTN bit. Addr Register Name 03H Lch ATT 04H Rch ATT Default D7 ATT7 ATT7 1 D6 ATT6 ATT6 1 D5 ATT5 ATT5 1 D4 ATT4 ATT4 1 D3 ATT3 ATT3 1 D2 ATT2 ATT2 1 D1 ATT1 ATT1 1 D0 ATT0 ATT0 1 ATT7-0: Attenuation Level 256 levels, 0.5dB step Data FFH FEH FDH : : 02H 01H 00H Attenuation 0dB -0.5dB -1.0dB : : -126.5dB -127.0dB MUTE (-∞) The transition between set values is soft transition of 7425 levels. It takes 7424/fs (168ms@fs=44.1kHz) from FFH (0dB) to 00H (MUTE). If the PDN pin goes to “L”, the ATTs are initialized to FFH. The ATTs are FFH when RSTN bit= “0”. When RSTN return to “1”, the ATTs fade to their current value. This digital attenuator is independent of soft mute function. MS1045-E-02 2009/04 - 34 - [AK4392] SYSTEM DESIGN Figure 17 shows the system connection diagram. Figure 19, Figure 20 and Figure 21 show the analog output circuit examples. The evaluation board (AKD4392) demonstrates the optimum layout, power supply arrangements and measurement results. Master clock Analog5.0V Digital 5.0V + 1 0u 10u + + 34 VCML 35 Lch LPF DVD D 2 PDN VSS2 32 3 BIC K VDDL 31 Audio Data 4 SDATA fs 5 LRCK 6 CSN MicroController 7 CAD 0 8 CCLK 9 CDTI VREFLL 29 10u + + 0.1u 10u NC 28 VREFLR 27 VR EFHR 26 To p View 0 .1u VSS1 24 10u + + VDDR 25 0 .1u 10u 21 VCMR 20 NC 19 DINL 18 DINR 17 NC 15 DZFR 16 BCK 14 PSN 13 NC 12 DIF2 22 AOUTRP AOUTRN 23 DZFL + 10u Digital 0 .1u VREFHL 30 AK4392EQ 10 CAD 1 11 Lch Out AOUTLN 33 1 Reset & PD 64fs Lch Mute AOUTLP NC 36 NC 37 NC 38 NC 39 VSS3 40 AVDD 41 VSS4 43 0.1u 10u + MCLK 42 NC 44 0.1u Rch LPF Rch Mute Rch Out Analog G + d Electrolytic Capacitor Ceramic Capacitor Notes: - Chip Address = “00”. BICK = 64fs, LRCK = fs - Power lines of AVDD and DVDD should be distributed separately from the point with low impedance of regulator etc. - VSS1-4 must be connected to the same analog ground plane. - When AOUT drives a capacitive load, some resistance should be connected in series between AOUT and the capacitive load. - All input pins except pull-down/pull-up pins should not be allowed to float. Figure 17. Typical Connection Diagram (AVDD=VDDL/R=5V, DVDD=5V, Serial control mode) MS1045-E-02 2009/04 - 35 - [AK4392] AOUTLP 34 N C 36 VCML 35 NC 37 NC 38 NC 39 VSS3 40 AVDD 41 DVDD 2 PDN VSS2 32 3 BICK/DCLK VDDL 31 4 SDATA/DSDL AK4392EQ VREFHL 30 VREFLL 29 NC 28 5 LRCK/DSDR/WCK 6 SMUTE/CSN 7 DFS0/CAD0 8 DEM0/CCLK VREFHR 26 9 DEM1/CDTI VDDR 25 10 DIF0/CAD1 VSS1 24 VREFLR 27 22 AOUTRP 21 VCMR 20 NC 19 DINL 18 DIN R AOUTRN 23 17 NC 14 PSN 12 DIF2 13 NC 11 DIF1/DZFL 16 BCK Controller AOUTLN 33 1 15 ACKS/DZFR System MCLK 42 NC 44 Analog Ground VSS4 43 Digital Ground Figure 18. Ground Layout 1. Grounding and Power Supply Decoupling To minimize coupling by digital noise, decoupling capacitors should be connected to AVDD, VDDL/R and DVDD respectively. AVDD and VDDL/R are supplied from analog supply in system and DVDD is supplied from digital supply in system. Power lines of AVDD, VDDL/R and DVDD should be distributed separately from the point with low impedance of regulator etc. The power up sequence between AVDD, VDDL/R and DVDD is not critical. VSS1-4 must be connected to the same analog ground plane. Decoupling capacitors for high frequency should be placed as near as possible to the supply pin. 2. Voltage Reference The differential voltage between VREFHL/R and VREFLL/R sets the analog output range. The VREFHL/R pin is normally connected to AVDD, and the VREFLL/R pin is normally connected to VSS1/2/3. VREFHL/R and VREFLL/R should be connected with a 0.1µF ceramic capacitor as near as possible to the pin to eliminate the effects of high frequency noise. No load current may be drawn from VCML/R pin. All signals, especially clocks, should be kept away from the VREFHL/R and VREFLL/R pins in order to avoid unwanted noise coupling into the AK4392. 3. Analog Outputs The analog outputs are full differential outputs and 2.8Vpp (typ, VREFHL/R − VREFLL/R = 5V) centered around AVDD/2. The differential outputs are summed externally, VAOUT = (AOUT+) − (AOUT−) between AOUT+ and AOUT−. If the summing gain is 1, the output range is 5.6Vpp (typ, VREFHL/R − VREFLL/R = 5V). The bias voltage of the external summing circuit is supplied externally. The input data format is 2's complement. The output voltage (VAOUT) is a positive full scale for 7FFFFFH (@24bit) and a negative full scale for 800000H (@24bit). The ideal VAOUT is 0V for 000000H(@24bit). The internal switched-capacitor filters attenuate the noise generated by the delta-sigma modulator beyond the audio passband. Figure 19 shows an example of external LPF circuit summing the differential outputs by an op-amp. Figure 20 shows an example of differential outputs and LPF circuit example by three op-amps. MS1045-E-02 2009/04 - 36 - [AK4392] AK4392 1.5k AOUT- 1.5k 390 1n +Vop 2.2n 1.5k AOUT+ 1.5k Analog Out 390 1n -Vop Figure 19. External LPF Circuit Example 1 for PCM (fc = 99.2kHz, Q=0.704) Frequency Response Gain 20kHz −0.011dB 40kHz −0.127dB 80kHz −1.571dB Table 14. Frequency Response of External LPF Circuit Example 1 for PCM +15 3.3n + AOUTL- + 10k 330 180 0.1u 7 3 2 + 4 3.9n -15 10u 6 NJM5534D + 10u 0.1u 620 620 3.3n + 100u 330 3.9n 2 - 4 + 3 7 100 6 Lch 1.0n NJM5534D 10u 0.1u 7 3 + 2 4 6 NJM5534D 1.2k 10k AOUTL+ 180 + +10u 1.0n 1.2k 680 0.1u 560 560 100u 680 + 0.1u 10u + 10u 0.1u Figure 20. External LPF Circuit Example 2 for PCM 1st Stage 2nd Stage Total Cut-off Frequency 182kHz 284kHz Q 0.637 Gain +3.9dB -0.88dB +3.02dB 20kHz -0.025 -0.021 -0.046dB Frequency 40kHz -0.106 -0.085 -0.191dB Response 80kHz -0.517 -0.331 -0.848dB Table 15. Frequency Response of External LPF Circuit Example 2 for PCM MS1045-E-02 2009/04 - 37 - [AK4392] It is recommended for SACD format book (Scarlet Book) that the filter response at SACD playback is an analog low pass filter with a cut-off frequency of maximum 50kHz and a slope of minimum 30dB/Oct. The AK4392 can achieve this filter response by combination of the internal filter (Table 16) and an external filter (Figure 21). Frequency Gain 20kHz −0.4dB 50kHz −2.8dB 100kHz −15.5dB Table 16. Internal Filter Response at DSD Mode 2.0k 1.8k 4.3k AOUT1.0k 270p 2.8Vpp 2200p +Vop 3300p 2.0k 1.8k 1.0k AOUT+ + 2.8Vpp 4.3k 270p Analog Out 6.34Vpp -Vop Figure 21. External 3rd Order LPF Circuit Example for DSD Frequency Gain 20kHz −0.05dB 50kHz −0.51dB 100kHz −16.8dB DC gain = 1.07dB Table 17. 3rd Order LPF (Figure 21) Response MS1045-E-02 2009/04 - 38 - [AK4392] PACKAGE 44pin LQFP (Unit: mm) 1.60max 12.0 1.40 ±0.05 0.10±0.05 10.0 23 33 1.00 0.80 12.0 22 10.0 34 12 44 1 11 0.37 +0.08 –0.07 0.20 M 0.145±0.055 0°∼7° S 0.6±0.15 0.10 S ■ Material & Lead finish Package molding compound: Lead frame material: Lead frame surface treatment: Epoxy, Halogen (bromine and chlorine) free Cu Solder (Pb free) plate MS1045-E-02 2009/04 - 39 - [AK4392] MARKING AK4392EQ XXXXXXX AKM 1 1) Pin #1 indication 2) AKM Logo 3) Date Code: XXXXXXX(7 digits) 4) Marking Code: AK4392 5) Audio 4 pro Logo REVISION HISTORY Date (YY/MM/DD) 09/01/09 09/02/25 Revision 00 01 Reason First Edition Error Correct 09/04/27 02 Description Change Page Contents 37 Figure 19 was changed. Table 14 was changed. Short Delay Filter → Minimum Delay Filter MS1045-E-02 2009/04 - 40 - [AK4392] IMPORTANT NOTICE z These products and their specifications are subject to change without notice. When you consider any use or application of these products, please make inquiries the sales office of Asahi Kasei Microdevices Corporation (AKM) or authorized distributors as to current status of the products. z AKM assumes no liability for infringement of any patent, intellectual property, or other rights in the application or use of any information contained herein. z Any export of these products, or devices or systems containing them, may require an export license or other official approval under the law and regulations of the country of export pertaining to customs and tariffs, currency exchange, or strategic materials. z AKM products are neither intended nor authorized for use as critical componentsNote1) in any safety, life support, or other hazard related device or systemNote2), and AKM assumes no responsibility for such use, except for the use approved with the express written consent by Representative Director of AKM. As used here: Note1) A critical component is one whose failure to function or perform may reasonably be expected to result, whether directly or indirectly, in the loss of the safety or effectiveness of the device or system containing it, and which must therefore meet very high standards of performance and reliability. Note2) A hazard related device or system is one designed or intended for life support or maintenance of safety or for applications in medicine, aerospace, nuclear energy, or other fields, in which its failure to function or perform may reasonably be expected to result in loss of life or in significant injury or damage to person or property. z It is the responsibility of the buyer or distributor of AKM products, who distributes, disposes of, or otherwise places the product with a third party, to notify such third party in advance of the above content and conditions, and the buyer or distributor agrees to assume any and all responsibility and liability for and hold AKM harmless from any and all claims arising from the use of said product in the absence of such notification. MS1045-E-02 2009/04 - 41 -