[AK4569] AK4569 20-Bit Stereo CODEC with IPGA & HP-AMP GENERAL DESCRIPTION The AK4569 is a 20bit CODEC with built-in Input PGA and Headphone Amplifier. The AK4569 includes a microphone/line input selector and an ALC circuit for input, and a Mono line output buffer, analog volume controls and stereo headphone amplifier for output. The AK4569 also features an analog mixing circuit that allows easy interfacing in mobile phone and portable communication designs. The integrated headphone amplifier features “pop-free” power-on/off, a mute control and delivers 8.7mW of power into 16Ω load via 6.8Ω series resistor. The AK4569 is housed in a 28pin QFN package, making it suitable for portable applications. FEATURE 2ch 20bit ADC - S/N: 89dB - Single-ended input - 2 stereo inputs selector - Analog input PGA: +32dB ∼ −19dB, Mute, 0.5dB step (MIC input) +20dB ∼ −31dB, Mute, 0.5dB step (LINE input) - Digital HPF for DC-offset cancellation - I/F format: 20bit MSB justified, I2S 2ch 20bit DAC - I/F Format: I2S, 20bit MSB justified, 20bit/16bit LSB justified - Digital ATT: 0dB ∼ −127dB, Mute, 0.5dB step (soft transition) - Soft mute - Digital De-emphasis Filter: 32kHz, 44.1kHz and 48kHz - Bass Boost Function Sampling Rate: 8kHz ∼ 48kHz System clock: 256fs/384fs/512fs - Input level: CMOS or 1Vpp Analog Input Analog Mixing Circuit Mono Lineout - Analog volume: 0dB ∼ −30dB, Mute, 2dB step Headphone Amplifier - Output Power: 8.7mW x 2ch @16Ω load & 6.8Ω series resistor - S/N: 90dB µP Interface: 3-wire Power management Power supply: 2.7V ∼ 3.6V Power dissipation: 15mA Ta: −40 ∼ 85°C Small Package: 28pin QFN (5.2mm x 5.2mm, 0.5mm pitch) MS0292-E-02 2012/12 -1- [AK4569] AVDD VREF VREF VCOM VCOM DVDD IPGA & ADC AINL1 AINL2 IPGA MCLK ADC HPF BICK AINR1 AINR2 HP-amp Audio I/F Controller DAC HPL LRCK SDTO HP-Amp DAC BOOST DATT SDTI HPR Control MOUT CSN CCLK Register MOUT CDTI LIN RIN MIN PDN HVDD HVSS MUTET AVSS DVSS Figure 1. Block diagram MS0292-E-02 2012/12 -2- [AK4569] ■ Ordering Guide AK4569VN AKD4569 −40 ∼ +85°C 28pin QFN (0.5mm pitch) Evaluation board for AK4569 AINL1 AINR1 AINL2 AINR2 AVDD AVSS VCOM 28 27 26 25 24 23 22 ■ Pin Layout PDN 1 21 VREF CSN 2 20 LIN CCLK 3 19 RIN CDTI 4 18 MIN LRCK 5 17 MOUT MCLK 6 16 MUTET BICK 7 15 HPL 8 9 10 11 12 13 14 SDTI SDTO DVDD DVSS HVSS HVDD HPR Top View ■ Comparison Table between AK4566 and AK4569 Function DAC Digital Filter Stopband Attenuation (min) Passband Ripple (max) Frequency Response including Analog Filter (0 ∼ 20.0kHz) The condition to stop the external clocks. AK4566 AK4569 43dB ±0.06dB 59dB ±0.01dB ±0.5dB ±1.0dB PDN pin = “L” PDN pin = “L” or PMADC=PMDAC bits = “0” MS0292-E-02 2012/12 -3- [AK4569] PIN/FUNCTION No. Pin Name I/O 1 PDN I 2 3 4 CSN CCLK CDTI I I I 5 LRCK I 6 MCLK I 7 BICK I 8 SDTI I 9 SDTO O 10 11 12 13 DVDD DVSS HVSS HVDD - 14 HPR O 15 HPL O 16 MUTET O 17 MOUT O 18 19 20 MIN RIN LIN I I I 21 VREF O 22 VCOM O 23 24 25 26 27 28 AVSS AVDD AINR2 AINL2 AINR1 AINL1 I I I I Function Power-down Pin When “L”, the AK4569 is in power-down mode and is held in reset. The AK4569 should always be reset upon power-up. Control Data Chip Select Pin Control Clock Input Pin Control Data Input Pin L/R Clock Pin This clock determines which audio channel is currently being output on SDTO pin and input on SDTI pin. Master Clock Input Pin Serial Bit Clock Pin This clock is used to latch audio data. Audio Data Input Pin Audio Data Output Pin SDTO pin goes to DVSS when PDN pin is “L”. Digital Power Supply Pin Digital Ground Pin Ground Pin for Headphone Amplifier Power Supply Pin for Headphone Amplifier Rch Headphone Amplifier Output Pin HPR pin goes to HVSS when PDN pin is “L”. Lch Headphone Amplifier Output Pin HPL pin goes to HVSS when PDN pin is “L”. Mute Time Constant Control Pin A capacitor for mute time constant should be connected between MUTET pin and HVSS pin. MUTET pin goes to HVSS when PDN pin is “L”. Mono Analog Output Pin MOUT pin goes to Hi-Z when PDN pin is “L”. Mono Analog Input Pin Rch Analog Input Pin Lch Analog Input Pin Reference Voltage Output Pin, 2.1V (typ, respect to AVSS) Normally connected to AVSS pin with 0.1μF ceramic capacitor in parallel with a 4.7μF electrolytic capacitor. VREF pin goes to AVSS when PDN pin is “L”. Common Voltage Output Pin, 1.25V (typ, respect to AVSS) Normally connected to AVSS pin with 0.1μF ceramic capacitor in parallel with a 2.2μF electrolytic capacitor. VCOM pin goes to AVSS when PDN pin is “L”. Analog Ground Pin Analog Power Supply Pin Rch Analog Input 2 Pin for ADC (MIC Input) Lch Analog Input 2 Pin for ADC (MIC Input) Rch Analog Input 1 Pin for ADC (LINE Input) Lch Analog Input 1 Pin for ADC (LINE Input) Note: No digital input pins must be left floating. MS0292-E-02 2012/12 -4- [AK4569] ■ Handling of Unused Pin The unused I/O pins should be processed appropriately as below. Classification Analog Digital Pin Name HPR, HPL, MOUT, AINR2, AINL2, AINR1, AINL1 SDTO SDTI Setting These pins should be open. This pin should be open. This pin should be connected to DVSS. ABSOLUATE MAXIMUM RATING (AVSS, DVSS, HVSS=0V; Note 1) Parameter Symbol min max Power Supplies Analog AVDD −0.3 4.6 DVDD 4.6 Digital −0.3 HVDD 4.6 HP-AMP −0.3 ΔGND1 0.3 |AVSS – HVSS| (Note 2) |AVSS – DVSS| (Note 2) 0.3 ΔGND2 Input Current (any pins except for supplies) IIN ±10 Analog Input Voltage (Note 3) VINA (AVDD+0.3) or 4.6 −0.3 Digital Input Voltage (Note 4) VIND (DVDD+0.3) or 4.6 −0.3 Ambient Temperature Ta 85 −40 Storage Temperature Tstg 150 −65 Note 1. All voltages with respect to ground. Note 2. AVSS, DVSS and HVSS must be connected to the same analog ground plane. Note 3. MIN, RIN, LIN, AINR2, AINL2, AINR1, AINL1 pins. Max is smaller value between (AVDD+0.3) and 4.6V. Note 4. PDN, CSN, CCLK, CDTI, LRCK, MCLK, BICK, SDTI pins. Max is smaller value between (DVDD+0.3) and 4.6V. Units V V V V V mA V V °C °C WARNING: Operation at or beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes. RECOMMEND OPERATING CONDITIONS (AVSS, DVSS, HVSS=0V; Note 1) Parameter Symbol min typ max Units Power Supplies Analog 2.5 AVDD 3.0 3.6 V Digital (Note 5) DVDD 2.5 or (AVDD−0.3) 3.0 3.6 or (AVDD+0.3) V HP-AMP HVDD 3.0 3.6 V 2.5 Note 1. All voltages with respect to ground. Note 5. Min is larger value between 2.5V and (AVDD−0.3). Max is smaller value between 3.6V and (AVDD+0.3). * AKM assumes no responsibility for usage beyond the conditions in this datasheet. MS0292-E-02 2012/12 -5- [AK4569] ANALOG CHARACTERISTICS (Ta=25°C; AVDD=DVDD=HVDD=3.0V, AVSS =DVSS=HVSS=0V; fs=44.1kHz; BOOST OFF; Signal Frequency =1kHz; Measurement band width=20Hz ∼ 20kHz; unless otherwise specified) Parameter min Typ max Units 20 bit ADC Resolution IPGA Characteristics: (AINL1, AINR1 pins) (LINE IN) Input Voltage 1.35 1.5 1.65 Vpp Input Resistance 25 50 75 kΩ Step Size 0.1 0.5 0.9 dB Gain Control Range +20 dB −31 IPGA Characteristics: (AINL2, AINR2 pins) (MIC IN) Input Voltage 1.35 1.5 1.65 Vpp Input Resistance 6 12.5 19 kΩ Step Size 0.1 0.5 0.9 dB Gain Control Range +32 dB −19 ADC Characteristics: (Note 6) 74 84 dB S/(N+D) (−1dB Input) 82 89 dB D-Range (−60dB Input, A-weighted)) S/N (A-weighted) 82 89 dB Interchannel Isolation 80 100 dB Interchannel Gain Mismatch 0.2 0.5 dB 50 dB Power Supply Rejection (Note 11) 20 bit DAC Resolution Headphone-Amp: (HPL/HPR pins) (Note 7) Load impedance is a serial connection with RL =22.8Ω and CL=100μF. S/(N+D) (0dBFS Output) 50 70 dB 82 90 dB D-Range (−60dBFS Output, A-weighted) S/N (A-weighted) 82 90 dB Interchannel Isolation 70 90 dB Interchannel Gain Mismatch 0.2 0.5 dB Load Resistance (Note 8) 20 Ω 30 pF Load Capacitance (C1 in Figure 2) (Note 9) 300 pF (C2 in Figure 2) Output Voltage 1.35 1.5 1.65 Vpp 50 dB Power Supply Rejection (Note 11) Mono Output: (MOUT pin) (Note 10) S/(N+D) (0dBFS Output) 70 84 dB S/N (A-weighted) 82 90 dB Load Resistance (Note 8) 10 kΩ Load Capacitance 30 pF Output Voltage 1.35 1.5 1.65 Vpp 50 dB Power Supply Rejection (Note 11) Output Volume: (MOUT pin) Step Size 1 2 3 dB Gain Control Range 0 dB −30 Note 6. The signal inputs are AINL1/AINR1 or AINL2/AINR2. The value of the IPGA is set to 0dB. On-chip HPF cancels the IPGA and ADC offsets. Note 7. DACL=DACR= “1”, MINL=MINR=LIN=RIN= “0”, and ATTL=ATTR=0dB. Note 8. AC Load Note 9. A resistor greater than 6.8Ω is inserted in series. Note 10. DACM= “1”, LINM=RINM=MINM= “0”, ATTL=ATTR=ATTM=0dB, and common mode signal is input to L/Rch of DAC. Note 11. PSR is applied to AVDD, DVDD and HVDD with 1kHz, 50mVpp. MS0292-E-02 2012/12 -6- [AK4569] Parameter min typ max Units Analog Input: (LIN/RIN/MIN pins) Input Resistance 25 50 75 kΩ Gain dB −6 −5 −7 LIN/RIN→MOUT dB 0 +1 −1 MIN→MOUT, LIN/MIN→HPL, RIN/MIN→HPR Power Supplies Power Supply Current Normal Operation (PDN= “H”) AVDD + DVDD + HVDD (Note 12) 15 24 mA Power-Down Mode (PDN= “L”) AVDD + DVDD + HVDD (Note 13) 1 100 μA Note 12. All blocks are powered-up (PMVCM=PMADC=PMDAC=PMHPL=PMHPR=PMMO= “1”), and HP-Amp output is off. AVDD=9mA(typ), DVDD=3mA(typ), HVDD=3mA(typ). 9mA(typ) at playback only (PMVCM=PMDAC=PMHPL=PMHPR=PMMO= “1”, PMADC= “0”). AVDD=4mA(typ), DVDD=2mA(typ), HVDD=3mA(typ). Note 13. All digital input pins including clock pins (MCLK, BICK and LRCK) are held at DVDD or DVSS. PDN pin is held at DVSS. HP-Amp + HPL, HPR > 6.8 C1 100uF + C2 16Ω Figure 2. Headphone amp output circuit MS0292-E-02 2012/12 -7- [AK4569] FILTER CHARACTERISTICS (Ta=25°C; AVDD, DVDD, HVDD=2.5 ∼ 3.6V; fs=44.1kHz; DEM=OFF; BOOST=OFF) Parameter Symbol min typ max Units ADC Digital Filter (LPF): PB 0 Passband (Note 15) 17.4 kHz ±0.1dB 20.0 kHz −1.0dB 21.1 kHz −3.0dB Stopband (Note 15) SB 25.7 kHz Passband Ripple PR dB ±0.1 Stopband Attenuation SA 65 dB Group Delay (Note 16) GD 17.0 1/fs Group Delay Distortion 0 ΔGD μs ADC Digital Filter (HPF): Frequency Response (Note 15) −3dB FR 3.4 Hz 10 Hz −0.5dB 22 Hz −0.1dB DAC Digital Filter: (Note 14) Passband (Note 15) ±0.1dB PB 0 19.6 kHz 20.0 kHz −0.7dB 22.05 kHz −6.0dB Stopband (Note 15) SB 25.2 kHz Passband Ripple PR dB ±0.01 Stopband Attenuation SA 59 dB Group Delay (Note 16) GD 16.8 1/fs Group Delay Distortion 0 ΔGD μs DAC Digital Filter + Analog Filter: (Note 14)(Note 17) FR dB Frequency Response 0 ∼ 20.0kHz ±1.0 BOOST Filter: (Note 17) (Note 18) 20Hz Frequency Response FR dB 5.74 100Hz dB MIN 2.92 1kHz dB 0 20Hz FR dB 5.94 100Hz dB MID 4.71 1kHz dB 0.14 20Hz FR dB 16.04 dB MAX 100Hz 10.55 1kHz dB 0.3 Note 14. BOOST OFF (BST1-0 = “00”) Note 15. The passband and stopband frequencies scale with fs. For example (DAC), PB=0.44*fs(@±0.1dB), SB=0.57*fs(@−59dB). Note 16. This is the calculated delay time caused by digital filtering. This time is measured from the input of analog signal to setting the 20 bit data of both channels on input register to the output register of ADC. This time also includes group delay of HPF. For DAC, this time is from setting the 20 bit data of both channels on input register to the output of analog signal. Note 17. DACL Æ HPL, DACR Æ HPR, DACL/R Æ MOUT. Note 18. These frequency responses scale with fs. If high-level signal is input, the AK4569 clips at low frequency. MS0292-E-02 2012/12 -8- [AK4569] Boost Frequency (fs=44.1kHz) Output Level [dB] 0 MAX -5 MID -10 -15 -20 MIN -25 0.01 0.1 1 10 Frequency [kHz] Figure 3. Boost Frequency (fs=44.1kHz) DC CHARACTERISTICS (Ta=25°C; AVDD, DVDD, HVDD = 2.5 ∼ 3.6V) Parameter Symbol min High-Level Input Voltage VIH 70%DVDD Low-Level Input Voltage VIL Input Voltage at AC Coupling (Note 19) VAC 1.0 VOH High-Level Output Voltage (Iout = −100μA) DVDD−0.4 VOL Low-Level Output Voltage (Iout = 100μA) Input Leakage Current Iin Note 19. When AC coupled capacitor is connected to MCLK pin. MS0292-E-02 typ max 30%DVDD - 0.4 ±10 Units V V Vpp V V μA 2012/12 -9- [AK4569] SWITCHING CHARACTERISTICS (Ta=25°C; AVDD, DVDD, HVDD = 2.5 ∼ 3.6V: CL = 20pF) Parameter Symbol min typ max Units Master Clock Timing fCLK 2.048 24.576 MHz Frequency tCLKL 0.4/fCLK ns Pulse Width Low (Note 20) tCLKH 0.4/fCLK ns Pulse Width High (Note 20) tACW 0.4/fCLK ns AC Pulse Width (Note 21) LRCK Timing fs 8 44.1 48 kHz Frequency Duty 45 55 % Duty Cycle Serial Interface Timing (Note 22) tBCK 325.5 ns BICK Period tBCKL 130 ns BICK Pulse Width Low tBCKH 130 ns Pulse Width High tLRB 50 ns LRCK Edge to BICK “↑” (Note 23) tBLR 50 ns BICK “↑” to LRCK Edge (Note 23) tLRS 80 ns LRCK to SDTO(MSB) tBSD 80 ns BICK “↓” to SDTO tSDH 50 ns SDTI Hold Time tSDS 50 ns SDTI Setup Time Control Interface Timing tCCK 200 CCLK Period ns tCCKL 80 CCLK Pulse Width Low ns tCCKH 80 Pulse Width High ns tCDS 40 CDTI Setup Time ns tCDH 40 CDTI Hold Time ns tCSW 150 CSN “H” Time ns tCSS 50 ns CSN “↓” to CCLK “↑” tCSH 50 ns CCLK “↑” to CSN “↑” Power-down & Reset Timing tPD 150 ns PDN Pulse Width (Note 24) tPDV 2081 1/fs PMADC “↑” to SDTO valid (Note 25) Note 20. Except AC coupling. Note 21. Pulse width to ground level when MCLK is connected to a capacitor in series and a resistor is connected to ground. (Refer to Figure 4.) Note 22. Refer to “Serial Data Interface”. Note 23. BICK rising edge must not occur at the same time as LRCK edge. Note 24. The AK4569 can be reset by bringing PDN= “L” to “H” only upon power up. Note 25. This is the count of LRCK “↑” from PMADC bit=”1”. MS0292-E-02 2012/12 - 10 - [AK4569] ■ Timing Diagram 1/fCLK tACW 1000pF MCLK Input tACW Measurement Point 100kΩ AVSS AVSS Figure 4. MCLK AC Coupling Timing 1/fCLK VIH MCLK VIL tCLKH tCLKL 1/fs VIH LRCK VIL tBCK VIH BICK VIL tBCKH tBCKL Figure 5. Clock Timing MS0292-E-02 2012/12 - 11 - [AK4569] VIH LRCK VIL tLRB tBLR VIH BICK VIL tLRS tBSD 50%DVDD SDTO tSDS tSDH VIH SDTI VIL Figure 6. Serial Interface Timing VIH CSN VIL tCSS tCCKL tCCKH VIH CCLK VIL tCDS CDTI C1 tCDH C0 R/W VIH A4 VIL Figure 7. WRITE Command Input Timing tCSW VIH CSN VIL tCSH VIH CCLK CDTI VIL D3 D2 D1 D0 VIH VIL Figure 8. WRITE Data Input Timing MS0292-E-02 2012/12 - 12 - [AK4569] VIH CSN VIL tPDV 50%DVDD SDTO tPD PDN VIL Figure 9. Power-down & Reset Timing MS0292-E-02 2012/12 - 13 - [AK4569] OPERATION OVERVIEW ■ System Clock The external clocks required to operate the AK4569 are MCLK(256fs/384fs/512fs), LRCK(fs) and BICK. The master clock (MCLK) should be synchronized with sampling clock (LRCK). The phase between these clocks does not matter. The frequency of MCLK is detected automatically, and the internal master clock becomes the appropriate frequency. Table 1 shows system clock example. LRCK fs 8kHz 11.025kHz 12kHz 16kHz 22.05kHz 24kHz 32kHz 44.1kHz 48kHz 256fs 2.048 2.8224 3.072 4.096 5.6448 6.144 8.192 11.2896 12.288 MCLK (MHz) 384fs 3.072 4.2336 4.608 6.144 8.4672 9.216 12.288 16.9344 18.432 512fs 4.096 5.6448 6.144 8.192 11.2896 12.288 16.384 22.5792 24.576 BICK (MHz) 64fs 0.512 0.7056 0.768 1.024 1.4112 1.536 2.048 2.8224 3.072 Table 1. System Clock Example External clocks (MCLK, BICK and LRCK) are needed to operate ADC or DAC. All external clocks (MCLK, BICK and LRCK) should always be present whenever the ADC or DAC is in normal operation mode (PMADC bit = “1” or PMDAC bit = “1”). If these clocks are not provided, the AK4569 may draw excess current and will not operate properly because it utilizes these clocks for internal dynamic refresh of registers. If the external clocks are not present, AK4569 should be placed in power-down mode (PDN pin = “L” or PMADC bit = PMDAC bit = “0”). When MCLK is input with AC coupling, the MCKAC bit should be set to “1”. If MCLK with AC coupling stops, MCKPD bit should be set to “1”. For low sampling rates, outband noise causes both DR and S/N to degrade. DR and S/N are improved by setting DFS bit to “1”. Table 2 shows S/N of DAC output for both the HP-amp and MOUT. When the DFS bit is “1”, MCLK needs 512fs. During normal operation, when the ADC or DAC sampling frequency is changed (PMADC bit = “1” or PMDAC bit = “1”), the DAC output should be soft-muted or “0” data should be input to avoid pop noise. DFS fs MCLK 0 1 8kHz∼48kHz 8kHz∼24kHz 256fs/384fs/512fs 512fs S/N (fs=8kHz, A-weighted) HP-amp MOUT 84dB 84dB 90dB 88dB Default Table 2. Relationship among fs, MCLK frequency and S/N of HP-amp and MOUT MS0292-E-02 2012/12 - 14 - [AK4569] ■ Serial Data Interface The AK4569 interfaces with external systems via the BICK, LRCK, SDTO and SDTI pins. Four data formats are available and are selected by setting DIF1 and DIF0 bits (Table 3). Mode 0 of SDTI is compatible with existing 16bit DACs and digital filters. Mode 1 of SDTI is a 20bit version of Mode 0. Mode 2 of SDTI is similar to AKM ADCs and many DSP serial ports. Mode 3 is compatible with the I2S serial data protocol. In SDTI Modes 2 and 3, the following formats are also valid: 16-bit data followed by four zeros and 18-bit data followed by two zeros. In all modes, the serial data is MSB first and 2’s complement format. Mode 0 1 2 3 DIF1 0 0 1 1 DIF0 0 1 0 1 SDTO 20bit, MSB justified 20bit, MSB justified 20bit, MSB justified IIS (I2S) SDTI 16bit, LSB justified 20bit, LSB justified 20bit, MSB justified IIS (I2S) BICK ≥ 32fs ≥ 40fs ≥ 40fs 32fs or ≥ 40fs LRCK H/L H/L H/L L/H Default Table 3. Audio Data Format LRCK 0 1 2 16 17 18 19 20 21 31 0 1 2 16 17 18 19 20 21 31 0 1 BICK(64fs) SDTO(o) 19 18 SDTI(i) 4 3 Don’t Care 0 1 2 1 0 15 14 13 12 8 2 9 10 11 4 19 18 11 12 1 13 14 Don’t Care 0 15 3 0 1 2 1 0 15 14 13 2 8 9 10 19 12 11 11 12 1 13 14 0 15 0 1 BICK(32fs) SDTO(o) 19 18 12 11 SDTI(i) 15 14 8 7 10 9 8 7 6 5 4 19 18 6 5 4 3 2 1 0 15 14 12 11 8 10 9 8 7 6 5 4 19 6 5 4 3 2 1 0 15 7 Lch Data Rch Data Figure 10. Mode 0 Timing LRCK 0 1 2 12 13 14 20 21 31 0 1 2 12 13 14 20 21 31 0 1 BICK(64fs) SDTO(o) SDTI(i) 19 18 Don’t Care 8 7 6 0 19 18 12 19 18 11 1 0 Don’t Care Lch Data 8 7 6 0 19 18 12 19 11 1 0 Rch Data Figure 11. Mode 1 Timing MS0292-E-02 2012/12 - 15 - [AK4569] LRCK 0 1 2 15 16 17 18 19 20 30 31 0 1 2 15 16 17 18 19 20 30 31 0 1 BICK(64fs) SDTO(o) 19 18 4 SDTI(i) 16bit 15 14 0 SDTI(i) 18bit 17 16 2 1 0 SDTI(i) 20bit 19 18 4 3 2 3 2 1 0 1 0 19 18 4 3 Don’t Care 15 14 0 Don’t Care 17 16 2 1 0 Don’t Care 19 18 4 3 2 Lch Data 2 1 0 1 19 0 Don’t Care 15 Don’t Care 17 Don’t Care 19 Rch Data Figure 12. Mode 2 Timing LRCK 0 1 2 3 16 17 18 19 20 21 30 31 0 1 2 3 16 17 18 19 20 21 30 31 0 1 BICK(64fs) SDTO(o) 19 18 4 SDTI(i) 16bit 15 14 0 SDTI(i) 18bit 17 16 2 1 0 SDTI(i) 20bit 19 18 4 3 2 0 1 2 3 8 3 9 2 10 1 0 1 11 0 12 19 18 4 Don’t Care 15 14 0 Don’t Care 17 16 2 1 0 Don’t Care 19 18 4 3 2 13 14 15 0 1 2 3 8 3 2 1 0 Don’t Care 9 10 Don’t Care 1 11 Don’t Care 0 12 13 14 15 0 1 BICK(32fs) SDTO(o) 4 19 18 SDTI(i) 0 15 14 12 11 8 7 10 9 8 7 6 5 4 19 18 6 5 4 3 2 1 0 15 14 Lch Data 12 11 8 7 10 9 8 7 6 5 4 6 5 4 3 2 1 0 Rch Data Figure 13. Mode 3 Timing ■ Digital High Pass Filter The AK4569 has a Digital High Pass Filter (HPF) to cancel DC-offsets in the ADC and IPGA. The cut-off frequency of the HPF is 3.4Hz at fs=44.1kHz. This filter scales with the sampling frequency (fs). MS0292-E-02 2012/12 - 16 - [AK4569] ■ ALC Operation [1] ALC Limiter Operation During the ALC limiter operation, when either Lch or Rch exceeds ALC limiter detection level (LMTH), IPGA value is attenuated by ALC limiter ATT step (LMAT1-0) automatically. The IPGA is then set to the same value for both channels. When ZELMN = “1”, the timeout period is set by LTM1-0 bits. The attenuation operation is done continuously until the input signal level becomes LMTH or less. After finishing the attenuation operation, if ALC bit does not change to “0”, the operation repeats when the input signal level exceeds LMTH. When ZELMN = “0”, the ALC limiter operation is attenuated by the ZTM1-0 bits setting. The IPGA value is automatically attenuated using zero crossing detection. The ALC operation of the AK4569 corresponds to the impulse noise. If the impulse noise is supplied at ZELMN = “0”, the ALC limiter operation becomes faster period than a set of ZTM1-0 bits. In case of ZELMN = “1”, it becomes the same period as LTM1-0 bits. [2] ALC Recovery Operation The ALC recovery operation waits for the WTM1-0 bits to be set after completing the ALC limiter. If the input signal does not exceed “ALC recovery waiting counter reset level (LMTH)”, the ALC recovery operation is done. The IPGA value is automatically incremented by this operation up to the set reference level (REF6-0) with zero crossing detection which timeout period is set by ZTM1-0 bits. Then the IPGA value is set for both Lch and Rch. The ALC recovery operation is done at a period set by WTM1-0 bits. When zero cross is detected at the IPGA output during the wait period set by WTM1-0 bits, the ALC recovery operation waits until WTM1-0 period and the next recovery operation is done. During the ALC recovery operation or the recovery waiting, when either input signal level of Lch or Rch in IPGA exceeds the ALC limiter detection level (LMTH), the ALC recovery operation changes into the ALC limiter operation immediately. When (ALC recovery waiting counter reset level: LMTH) ≤ (IPGA output level) < (ALC limiter detection level: LMTH) during the ALC recovery operation, the ALC recovery operation wait timer is reset. Therefore, when (ALC recovery waiting counter reset level: LMTH) > (IPGA output level), the ALC recovery operation wait timer starts. The ALC operation of the AK4569 corresponds to the impulse noise. If the impulse noise is supplied, the ALC recovery operation becomes faster period than a set of ZTM1-0 or WTM1-0 bits. Others: When either channel enters the limiter operation while waiting time for a zero crossing, the present ALC recovery operation stops, according as the small value of IPGA (a channel waiting zero crossing), the ALC limiter operation is done. When both channels are waiting for the next ALC recovery operation, the ALC limiter operation is done from the IPGA value of a point in time. ZTM1-0 bits set zero crossing timeout and WTM1-0 bits set the ALC recovery operation period. When the ALC recovery waiting time (WTM1-0 bits) is shorter than zero crossing timeout period (ZTM1-0 bits), the ALC recovery is operated by the zero crossing timeout period. Therefore, in this case, the ALC recovery operation period is not constant. MS0292-E-02 2012/12 - 17 - [AK4569] [3] ALC Operation Example The following registers should not be changed during the ALC operation: LTM1-0, LMTH, LMAT1-0, WTM1-0, ZTM1-0, RATT, REF6-0, ZELMN. Manual mode WR (Power Management Control & Signal Select) WR (ZTM1-0, WTM1-0, LTM1-0) WR (LMAT1-0, RATT, LMTH) WR (REF6-0) WR (IPGA6-0) * The value of IPGA should be the same or smaller than REF’s. WR (ALC= “1”,ZELMN) ALC Operation No Finish ALC mode? Yes WR (ALC=”0”) Finish ALC mode and return to Manual mode Figure 14. Registers set-up sequence at ALC operation (WR=Write) MS0292-E-02 2012/12 - 18 - [AK4569] ■ IPGA Operation [Write Operation at ALC Enabled] The values of IPGA6-0 bits are ignored during ALC operation. [Write Operation at ALC Disabled] Channel independent zero crossing detection is used. If there are no zero crossings, then the level will change after a timeout. The ZTM1-0 bits set the zero crossing timeout. When a μP writes to the IPGA6-0 bits, the zero crossing counter is reset and starts. When the IPGA output signal detects zero crossing or a zero crossing timeout, the written value from the μP becomes valid. When writing to the IPGA6-0 bits continually, the control register should be written by an interval more than zero crossing timeout. If not, there is a possibility that each IPGA of L/R channels has a different gain. [IPGA Gain after completing ALC operation] The IPGA6-0 bits are not updated by the actual gain of IPGA changed during ALC operation. In order to set the actual gain of IPGA with the IPGA6-0 bits, the IPGA6-0 bits should be written after zero crossing timeout period when completing ALC operation (ALC bit= “1” Æ “0”). MS0292-E-02 2012/12 - 19 - [AK4569] ■ Digital Attenuator The AK4569 has a channel-independent digital attenuator (256 levels, 0.5dB step). This digital attenuator is placed before the D/A converter. ATTL/R7-0 bits set the attenuation level (0dB to −127dB or MUTE) for each channel (Table 19). At DATTC= “1”, ATTL7-0 bits control both Lch and Rch attenuation levels. At DATTC= “0”, ATTL7-0 bits control the Lch level and ATTR7-0 bits control the Rch level. The ATS bit sets the transition time between set values of ATT7-0 bits as either 1061/fs or 7424/fs (Table 15). When ATS= “0”, a soft transition between the set values occurs(1062 levels). It takes 1061/fs (24ms@fs=44.1kHz) from FFH(0dB) to 00H(MUTE). The ATTs are 00H when the PMDAC bit is “0”. When the PMDAC returns to “1”, the ATTs fade to their current value. Digital attenuator is independent of the soft mute function. ■ Soft Mute Soft mute operation is performed in the digital domain. When SMUTE bit goes to “1”, the output signal is attenuated by −∞ (“0”) via the cycle set by TM1-0 bit (Table 18). When SMUTE bit returns to “0”, the mute is cancelled and the output attenuation gradually changes to 0dB via the cycle set by TM1-0 bits. If the soft mute is cancelled within the cycle set by TM1-0 bits after starting the operation, the attenuation is discontinued and returned to 0dB. The soft mute is effective for changing the signal source without stopping the signal transmission. SMUTE bit TM1-0 bit TM1-0 bit 0dB (1) (3) Attenuation -∞ GD (2) GD Analog Output Figure 15. Soft Mute Function NOTE: (1) The output signal is attenuated until −∞ (“0”) by the cycle set by TM1-0 bits. (2) Analog output corresponding to digital input has the group delay (GD). (3) If the soft mute is cancelled within the cycle set by TM1-0 bits, the attenuation is discontinued and returned to 0dB(the setting value). MS0292-E-02 2012/12 - 20 - [AK4569] ■ De-emphasis Filter The AK4569 includes a digital de-emphasis filter (tc = 50/15μs) by IIR filter corresponding to three sampling frequencies (32kHz, 44.1kHz and 48kHz). The de-emphasis filter is enabled by setting DEM1-0 bits (Table 16). ■ Bass Boost Function By controlling BST1-0 bits, the low frequency boost signal can be output from DAC. The setting value is common in Lch and Rch (Table 17). The cut-off frequency (fc) of HPF depends on the external resistor and capacitor values. Table 4 shows the relationship of external resistor, capacitor, fc and output power, where load resistance of headphone is 16Ω. Output level of headphone amp is 1.5Vpp (typ). HP-AMP R C Headphone 16Ω AK4569 Figure 16. External Circuit Example of Headphone fc [Hz] fc [Hz] Output Power [mW] BOOST=OFF BOOST=MID 47 148.6 65 6.8 8.7 100 69.8 27 47 105.8 43 16 4.4 100 49.7 20 Table 4. Relationship of external circuit, output power and frequency response R [Ω] C [μF] Note: Cut-off frequency (fc) at BOOST=MID is approximate value. ■ System Reset The AK4569 should be reset once by bringing PDN “L” upon power-up. After exiting reset, VCOM, IPGA, ADC, DAC, HPL, HPR and MOUT switch to the power-down state. The contents of the control register are maintained until the reset is done. ADC exits reset and power down state by MCLK after PMADC bit is changed to “1”, and then ADC is powered up and the internal timing starts clocking by LRCK “↑”. ADC is in the power-down mode until MCLK and LRCK are input. DAC also exits reset and power down state when MCLK and LRCK are input after PMDAC= “1”. MS0292-E-02 2012/12 - 21 - [AK4569] ■ Power-Up/Down Sequence 1) ADC Power Supply (1) >150ns PDN pin HPLMT, HPRMT bit (2) >0 PMVCM bit Don’t care (4) Clock Input Don’t care PMADC bit (3) >0 ADC Internal State (6) 2081/fs PD(Power-down) Init Cycle (6) 2081/fs Normal Operation PD (5) AIN pin (Hi-Z) Init Cycle Normal Operation (Hi-Z) (7) GD (7) GD (7) GD SDTO pin Figure 17. Power-up/down sequence of ADC PDN pin should be set to “H” at least 150ns after the power is supplied. HPLMT, HPRMT and PMVCM bits should be changed to “1” after PDN pin goes to “H”. PMADC bit should be changed to “1” after HPLMT, HPRMT and PMVCM bits are changed to “1”. External clocks (MCLK, BICK, LRCK) are needed to operate ADC. When PMADC bit is changed to “1”, each AIN pin is biased to VCOM voltage. Rising time constant is determined by input capacitor for AC coupling and input resistance. In case of AINL2/AINR2 and 1µF input capacitor, time constant is τ = 1µF x 12.5kΩ = 12.5ms (typ) (6) The analog part of ADC is initialized during 2081/fs(=47ms@fs=44.1kHz) after exiting the power-down state. SDTO is “L” at that time. (7) Digital output corresponding to analog input has the group delay (GD) of 17.0/fs(=385µs@fs=44.1kHz). (1) (2) (3) (4) (5) MS0292-E-02 2012/12 - 22 - [AK4569] 2) DAC → HP-amp Power supply voltage for headphone amp is supplied from HVDD pin and centered on VCOM. Load resistance of headphone output is min.20Ω. When PMHPL and PMHPR bit are “0”, headphone amplifiers are powered-down perfectly. Then HPL and HPR pins are fixed to “L” (HVSS) and a capacitor of MUTET pin works to avoid pop noise. Power Supply (9) (1) >150ns PDN pin (2) >0 PMVCM bit Don’t care Don’t care (4) Clock Input (3) >0 PMDAC bit DAC Internal State Normal Operation PD PD Normal Operation PD SDTI pin PMHPL/R bit HPLMT, HPRMT bit ATTL/R7-0 bit FFH(0dB) 00H(MUTE) (7) GD (5) 00H(MUTE) (8) 1061/fs (7) (8) FFH(0dB) (7) (6) (5) (8) 00H(MUTE) (7) (8) (6) HPL/R pin Figure 18. Power-up/down sequence of DAC and HP-amp (1) PDN pin should be set to “H” at least 150ns after the power is supplied. (2) HPLMT, HPRMT and PMVCM bits should be changed to “1” after PDN pin goes to “H”. (3) PMDAC, PMHPL, PMHPR bits should be changed to “1” and HPLMT, HPRMT bits should be changed to “0” after HPLMT, HPRMT, PMVCM bits are changed to “1”. Once PMHPL and PMHPR bits are changed to “1”, HPLMT and HPRMT bits should be inverted from PMHPL and PMHPR bits respectively. (4) External clocks (MCLK, BICK, LRCK) are needed to operate DAC. When PMDAC bit = “0”, these clocks can be stopped. Headphone amp can operate without these clocks. (5) Rise time of headphone amp is determined by external capacitor of MUTET pin. When C=1µF, Rise Time Constant of Headphone Amp: τ = 100ms (6) Fall time of headphone amp is determined by output capacitor for AC coupling. When C=100µF, Fall Time Constant of Headphone Amp: τ = 200ms (7) Analog output corresponding to digital input has the group delay (GD) of 16.8/fs(=381µs@fs=44.1kHz). (8) ATS bit sets transition time of digital attenuator. Default value is 1061/fs(=24ms@fs=44.1kHz). (9) Power supply should be switched off after headphone amp is powered down (HPL/R pins become “L”). MS0292-E-02 2012/12 - 23 - [AK4569] 3) DAC → MOUT Power Supply (1) >150ns PDN pin HPLMT, HPRMT bit (2) >0 PMVCM bit Don’t care (4) Clock Input Don’t care PMDAC bit (3) >0 DAC Internal State PD Normal Operation PD(Power-down) Normal Operation SDTI pin PMMO bit ATTL/R7-0 bit MMUTE, ATTM3-0 bit (Hi-Z) FFH(0dB) 0FH(0dB) 10H(MUTE) (6) GD MOUT pin 00H(MUTE) FFH(0dB) 00H(MUTE) (7) 1061/fs (6) (5) (7) (6) (7) (5) (5) (Hi-Z) Figure 19. Power-up/down sequence of DAC and MOUT PDN pin should be set to “H” at least 150ns after the power is supplied. HPLMT, HPRMT and PMVCM bits should be changed to “1” after PDN pin goes to “H”. PMDAC and PMMO bits should be changed to “1” after HPLMT, HPRMT and PMVCM bits are changed to “1”. External clocks (MCLK, BICK, LRCK) are needed to operate DAC. When PMDAC= “0”, these clocks can be stopped. MOUT buffer can operate without these clocks. (5) When PMMO bit is changed to “1”, pop noise is output from MOUT pin. (6) Analog output corresponding to digital input has the group delay (GD) of 16.8/fs(=381µs@fs=44.1kHz). (7) ATS bit sets transition time of digital attenuator. Default value is 1061/fs(=24ms@fs=44.1kHz). (1) (2) (3) (4) MS0292-E-02 2012/12 - 24 - [AK4569] 4) LIN/RIN/MIN → HP-amp, MOUT Power Supply (1) >150ns PDN pin (2) >0 PMVCM bit Don’t care (3) >0 PMHPL/R bit, PMMO bit HPLMT, HPRMT bit (Hi-Z) (4) LIN/RIN/MIN pin (Hi-Z) (6) (5) (5) HPL/R pin MMUTE, ATTM3-0 bit MOUT pin 10H(MUTE) (Hi-Z) 0FH(0dB) (7) (7) (7) (Hi-Z) Figure 20. Power-up/down sequence of LIN/RIN/MIN, HP-amp and MOUT (1) PDN pin should be set to “H” at least 150ns after the power is supplied. (2) HPLMT, HPRMT and PMVCM bits should be changed to “1” after PDN pin goes to “H”. (3) PMHPL, PMHPR, PMMO bits should be changed to “1” and HPLMT, HPRMT bits should be changed to “0” after HPLMT, HPRMT, PMVCM bits are changed to “1”. Once PMHPL and PMHPR bits are changed to “1”, HPLMT and HPRMT bits should be inverted from PMHPL and PMHPR bits respectively. (4) When PMHPL, PMHPR or PMMO bit is changed to “1”, LIN, RIN and MIN are biased to VCOM voltage. Rising time constant is determined by input capacitor for AC coupling and input resistance 50kΩ (typ). In case of 0.1µF input capacitor, time constant is τ = 0.1µF x 50kΩ = 5ms (typ) (5) Rise time of headphone amp is determined by external capacitor of MUTET pin. When C=1µF, Rise Time Constant of Headphone Amp: τ = 100ms (6) Fall time of headphone amp is determined by output capacitor for AC coupling. When C=100µF, Fall Time Constant of Headphone Amp: τ = 200ms (7) When PMMO bit is changed to “1”, pop noise is output from MOUT pin. MS0292-E-02 2012/12 - 25 - [AK4569] ■ Serial Control Interface Internal registers may be written via to the 3 wire µP interface pins (CSN, CCLK and CDTI). The data on this interface consists of Chip address (2bits, Fixed to “10”), Read/Write (1bit, Fixed to “1”, Write only), Register address (MSB first, 5bits) and Control data (MSB first, 8bits). Address and data is clocked in on the rising edge of CCLK. For write operations, data is latched after a low-to-high transition of CSN. The clock speed of CCLK is 5MHz(max). The value of internal registers is initialized at PDN= “L”. 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 (Fixed to “10”) R/W: Read/Write (Fixed to “1” : Write only) A4-A0: Register Address D7-D0: Control Data Figure 21. Control Interface MS0292-E-02 2012/12 - 26 - [AK4569] ■ Register Map Addr 00H 01H 02H 03H 04H 05H 06H 07H 08H 09H 0AH 0BH 0CH Register Name Power Management Input Select Timer Select ALC Mode Control 1 ALC Mode Control 2 IPGA Control Mode Control DAC Control Output Select 0 Output Select 1 DAC Lch ATT DAC Rch ATT MOUT ATT D7 D6 HPRMT HPLMT 0 0 0 0 0 0 0 0 REF6 IPGA6 MCKAC MCKPD TM1 0 0 ATTL7 ATTR7 0 TM0 0 0 ATTL6 ATTR6 0 D5 PMMO 0 ZTM1 ALC REF5 IPGA5 0 D4 D3 D2 D1 D0 PMHPR PMHPL PMDAC PMADC PMVCM ADM ZTM0 INR2 WTM1 INR1 WTM0 ZELMN LMAT1 LMAT0 REF4 IPGA4 ATS REF2 IPGA2 DIF1 BST0 MINL RINM ATTL2 ATTR2 INL2 LTM1 RATT REF1 IPGA1 DIF0 DEM1 LINL LINM ATTL1 ATTR1 INL1 LTM0 LMTH REF0 IPGA0 DFS DEM0 DACL DACM ATTL0 ATTR0 ATTM2 ATTM1 ATTM0 SMUTE DATTC MINR 0 ATTL5 ATTR5 0 RINR 0 ATTL4 ATTR4 REF3 IPGA3 HPM BST1 DACR MINM ATTL3 ATTR3 MMUTE ATTM3 All registers inhibit writing at PDN pin = “L”. Note: Unused bits must contain a “0” value. Note: For addresses from 0DH to 1FH, data must not be written. MS0292-E-02 2012/12 - 27 - [AK4569] ■ Register Definitions Addr 00H Register Name Power Management Default D7 D6 HPRMT HPLMT 0 0 D5 PMMO 0 D4 D3 D2 D1 D0 PMHPR PMHPL PMDAC PMADC PMVCM 0 0 0 0 0 PMVCM: Power Management for VCOM Block 0: Power OFF (Default) 1: Power ON PMADC: Power Management for IPGA and ADC Blocks 0: Power OFF (Default) 1: Power ON MCLK should be present when PMADC bit= “1”. PMDAC: Power Management for DAC Blocks 0: Power OFF (Default) 1: Power ON When PMDAC bit is changed from “0” to “1”, DAC is powered-up to the current register values (ATT value, sampling rate, etc). PMHPL: Power Management for Lch of Headphone Amp 0: Power OFF (Default). HPL pin becomes HVSS(0V). 1: Power ON PMHPR: Power Management for Rch of Headphone Amp 0: Power OFF (Default). HPR pin becomes HVSS(0V). 1: Power ON PMMO: Power Management for Mono Output 0: Power OFF (Default) MOUT pin becomes Hi-Z. 1: Power ON HPLMT: Mute for Lch of Headphone Amp 0: Normal operation (Default). MUTET pin is connected to VCOM pin internally. 1: Mute. MUTET pin is connected to HPL pin internally. HPLMT: Mute for Rch of Headphone Amp 0: Normal operation (Default). MUTET pin is connected to VCOM pin internally. 1: Mute. MUTET pin is connected to HPR pin internally. HPLMT HPRMT MUTET 0 0 Connected to VCOM 0 1 Connected to HPR 1 0 Connected to HPL 1 1 Connected to HPL,HPR Table 5. MUTET internal connection All blocks can be powered-down by setting the PDN pin to “L” regardless of register values setup. In this case, all control register values are initialized. MS0292-E-02 2012/12 - 28 - [AK4569] Addr 01H Register Name Input Select Default D7 0 0 D6 0 0 D5 0 0 D4 ADM 0 D3 INR2 0 D2 INR1 1 D1 INL2 0 D0 INL1 1 INL2-1: Select ON/OFF of IPGA Lch input. 0: OFF 1: ON Default: INL2=0, INL1=1 INR2-1: Select ON/OFF of IPGA Rch input. 0: OFF 1: ON Default: INR2=0, INR1=1 ADM: Mono Recording Mode 0: Stereo (Default) 1: MONO When ADM= “1”, input signal to AINL1 or AINL2 pin is input to both Lch and Rch of ADC. MS0292-E-02 2012/12 - 29 - [AK4569] Addr 02H Register Name Timer Select Default D7 0 0 D6 0 0 D5 ZTM1 0 D4 ZTM0 0 D3 WTM1 0 D2 WTM0 0 D1 LTM1 0 D0 LTM0 0 LTM1-0: ALC limiter operation period (Table 6) When zero crossing is disabled (ZELMN = “1”), the IPGA value is changed immediately by ALC limiter operation. When the IPGA value is changed continuously, the change is done by the period specified by LTM1-0 bits. Default: “00”. ALC Limiter Operation Period 8kHz 16kHz 44.1kHz 0 0.5/fs Default 63μs 31μs 11μs 1 1/fs 125μs 63μs 23μs 0 2/fs 250μs 125μs 45μs 1 4/fs 500μs 250μs 91μs Table 6. ALC Limiter Operation Period at zero crossing disable (ZELMN bit= “1”) LTM1 0 0 1 1 LTM0 WTM1-0: ALC Recovery Waiting Period (Table 7) WTM1-0 bits set the recovery operation period when any limiter operation does not occur during an ALC operation. Default: “00”. WTM1 WTM0 0 0 1 1 0 1 0 1 ALC Recovery Operation Waiting Period 8kHz 16kHz 44.1kHz 128/fs 16ms 8ms 2.9ms 256/fs 32ms 16ms 5.8ms 512/fs 64ms 32ms 11.6ms 1024/fs 128ms 64ms 23.2ms Table 7. ALC Recovery Operation Waiting Period Default ZTM1-0: ALC Zero Crossing Timeout Period (Table 8) When IPGA output detects zero crossing or timeout, the IPGA value is changed by a μP WRITE operation, ALC recovery operation, or ALC limiter operation. Default: “00”. ZTM1 ZTM0 0 0 1 1 0 1 0 1 Zero Crossing Timeout Period 8kHz 16kHz 44.1kHz 128/fs 16ms 8ms 2.9ms 256/fs 32ms 16ms 5.8ms 512/fs 64ms 32ms 11.6ms 1024/fs 128ms 64ms 23.2ms Table 8. Zero Crossing Timeout Period MS0292-E-02 Default 2012/12 - 30 - [AK4569] Addr 03H Register Name ALC Mode Control 1 Default D7 0 0 D6 0 0 D5 ALC 0 D4 D3 D2 ZELMN LMAT1 LMAT0 0 0 0 D1 RATT 0 D0 LMTH 0 LMTH: ALC Limiter Detection Level / Recovery Waiting Counter Reset Level (Table 9) LMTH 0 1 ALC Limiter Detection Level ALC Recovery Waiting Counter Reset Level ADC Input ≥ −6.0dBFS −6.0dBFS > ADC Input ≥ −8.0dBFS ADC Input ≥ −4.0dBFS −4.0dBFS > ADC Input ≥ −6.0dBFS Table 9. ALC1 Limiter Detection Level / Recovery Waiting Counter Reset Level Default RATT: ALC Recovery GAIN Step (Table 10) During the ALC recovery operation, the number of steps changed from the current IPGA value is set. For example, when the current IPGA value is 3FH, RATT = “1” is set, the IPGA changes to 41H due to the ALC recovery operation, the output signal level is gained by 1dB (=0.5dB x 2). When the IPGA value exceeds the reference level (REF6-0 bits), the IPGA value does not increase. RATT GAIN STEP 0 1 Default 1 2 Table 10. ALC Recovery Gain Step Setting LMAT1-0: ALC Limiter ATT Step (Table 11) During the ALC limiter operation, when either Lch or Rch exceeds the ALC limiter detection level set by LMTH bit, LMAT1-0 bits set the number of steps attenuated from the current IPGA value. For example, when the current IPGA value is 3FH when LMAT1-0 bit = “11”, the IPGA value changes to 3BH by the ALC limiter operation, the input signal level is attenuated by 2dB (=0.5dB x 4). When the attenuation value exceeds IPGA = “00H” (Mute), it clips to “00H”. LMAT1 LMAT0 ATT STEP 0 0 1 Default 0 1 2 1 0 3 1 1 4 Table 11. ALC Limiter ATT Step Setting ZELMN: Zero Crossing Detection Enable at ALC Limiter Operation 0: Enable (Default) 1: Disable In case of ZELMN = “0”, when IPGA output detects zero crossing or timeout, the IPGA value is changed by the ALC operation. Zero crossing timeout is the same as ALC recovery operation. In case of ZELMN = “1”, the IPGA value is changed immediately. ALC: ALC Enable Flag 0: ALC Disable (Default) 1: ALC Enable ALC is enabled at ALC bit is “1”. Default: “0” (Disable). MS0292-E-02 2012/12 - 31 - [AK4569] Addr 04H Register Name ALC Mode Control 2 Default D7 0 0 D6 REF6 0 D5 REF5 1 D4 REF4 1 D3 REF3 1 D2 REF2 1 D1 REF1 1 D0 REF0 1 REF6-0: Reference Value at ALC Recovery Operation, 0.5dB step, 103 levels, Default: “3FH” (Table 12) During the ALC recovery operation, if the IPGA value exceeds the set reference value by gain operation, IPGA does not become larger than the reference value. For example, when REF= “40H”, RATT= “1” (2 step) and IPGA= “3FH”, then IPGA is going to become 3FH + 2step = 41H, but IPGA becomes 40H in fact, since REF=40H. GAIN AINL1, AINR1 AINL2, AINR2 (LINE IN) (MIC IN) 67H +20.0dB +32.0dB 66H +19.5dB +31.5dB 65H +19.0dB +31.0dB : : : 3FH 0dB +12.0dB Default : : : 27H 0dB −12.0dB : : : 02H −30.5dB −18.5dB 01H −31.0dB −19.0dB 00H MUTE (−∞) MUTE (−∞) Table 12. Reference Value Setting at ALC Recovery Operation DATA Addr 05H Register Name IPGA Control Default D7 0 0 D6 IPGA6 0 D5 IPGA5 1 D4 IPGA4 1 D3 IPGA3 1 D2 IPGA2 1 D1 IPGA1 1 D0 IPGA0 1 IPGA6-0: Input Analog PGA, 0.5dB step, 103 levels, Default: “3FH” (Table 13) When IPGA gain is changed, IPGA6-0 bits should be written while PMADC bit is “1” and ALC bit is “0”. IPGA gain is reset when PMADC bit is “0”, and then IPGA operation starts from the default value when PMADC is changed to “1”. When ALC bit is changed from “1” to “0”, IPGA holds the last gain value set by ALC operation. DATA 67H 66H 65H : 3FH : 27H : 02H 01H 00H GAIN AINL1, AINR1 AINL2, AINR2 (LINE IN) (MIC IN) +20.0dB +32.0dB +19.5dB +31.5dB +19.0dB +31.0dB : : 0dB +12.0dB : : 0dB −12.0dB : : −30.5dB −18.5dB −31.0dB −19.0dB MUTE (−∞) MUTE (−∞) Table 13. Input Gain Setting MS0292-E-02 Default 2012/12 - 32 - [AK4569] Addr 06H Register Name Mode Control Default D7 D6 MCKAC MCKPD 0 0 D5 0 0 D4 ATS 0 D3 HPM 0 D2 DIF1 1 D1 DIF0 0 D0 DFS 0 DFS: Sampling Speed Mode Select (Table 2) DIF1-0: Audio Data Interface Format Default: “10” (Mode 2) HPM: Mono Output Select of Headphone 0: Normal Operation (Default) 1: Mono. (L+R)/2 signals from the DAC are output to both Lch and Rch of headphone. Setting of HPM bit is enabled only at DACL=DACR= “1”. DACL 0 1 HPM x 0 1 HPL pin Output No output from DAC Output from Lch of DAC Output (L+R)/2 from DAC Default Table 14. Mono Output Select of Headphone (Note. Rch is same.) ATS: Digital attenuator transition time setting (Table 15) ATS 0 1 ATT speed 0dB to MUTE 1 step 1061/fs 4/fs 7424/fs 29/fs Default Table 15. Transition time between set values of ATT7-0 bits MCKPD: MCLK Input Buffer Control 0: Enable (Default) 1: Disable When MCLK input with AC coupling is stopped, MCKPD bit should be set to “1”. MCKAC: MCLK Input Mode Select 0: CMOS input (Default) 1: AC coupling input MS0292-E-02 2012/12 - 33 - [AK4569] Addr 07H Register Name DAC Control Default D7 TM1 0 D6 TM0 0 D5 D4 SMUTE DATTC 0 0 D3 BST1 0 D2 BST0 0 D1 DEM1 0 D0 DEM0 1 DEM1-0: De-emphasis Filter Frequency Select DEM1 DEM0 De-emphasis 0 0 44.1kHz 0 1 OFF Default 1 0 48kHz 1 1 32kHz Table 16. De-emphasis Filter Frequency Select BST1-0: Low Frequency Boost Function Select BST1 BST0 BOOST 0 0 OFF Default 0 1 MIN 1 0 MID 1 1 MAX Table 17. Low Frequency Boost Select DATTC: DAC Digital Attenuator Control Mode Select 0: Independent (Default) 1: Dependent At DATTC= “1”, ATTL7-0 bits control both Lch and Rch attenuation level, while register values of ATTL7-0 bits are not written to ATTR7-0 bits. At DATTC= “0”, ATTL7-0 bits control Lch level and ATTR7-0 bits control Rch level. SMUTE: Soft Mute Control 0: Normal operation (Default) 1: DAC outputs soft-muted TM1-0: Soft Mute Time Select TM1 0 0 1 1 TM0 Cycle 0 1024/fs Default 1 512/fs 0 256/fs 1 128/fs Table 18. Soft Mute Time Setting MS0292-E-02 2012/12 - 34 - [AK4569] Addr 08H Register Name Output Select 0 Default D7 0 0 D6 0 0 D5 MINR 0 D4 RINR 0 D3 DACR 0 D2 MINL 0 D1 LINL 0 D0 DACL 0 DACL: DAC Lch output signal is added to Lch of headphone amp. 0: OFF (Default) 1: ON LINL: Input signal to LIN pin is added to Lch of headphone amp. 0: OFF (Default) 1: ON MINL: Input signal to MIN pin is added to Lch of headphone amp. 0: OFF (Default) 1: ON DACR: DAC Rch output signal is added to Rch of headphone amp. 0: OFF (Default) 1: ON RINR: Input signal to RIN pin is added to Rch of headphone amp. 0: OFF (Default) 1: ON MINR: Input signal to MIN pin is added to Rch of headphone amp. 0: OFF (Default) 1: ON R LIN/RIN pin LINL/RINR bit R R MIN pin MINL/MINR bit R - DACL/DACR DACL/DACR bit HPL/HPR pin + HP-Amp Figure 22. Summation circuit for headphone amp output At HPM=0, gain of summation is 0dB for all input path. MS0292-E-02 2012/12 - 35 - [AK4569] Addr 09H Register Name Output Select 1 Default D7 0 0 D6 0 0 D5 0 0 D4 0 0 D3 MINM 0 D2 RINM 0 D1 LINM 0 D0 DACM 0 DACM: DAC Lch and Rch outputs are added to MOUT buffer amp. Summation gain is −6dB for each channel. 0: OFF (Default) 1: ON LINM: Input signal to LIN pin is added to MOUT buffer amp. 0: OFF (Default) 1: ON RINM: Input signal to RIN pin is added to MOUT buffer amp. 0: OFF (Default) 1: ON MINM: Input signal to MIN pin is added to MOUT buffer amp. 0: OFF (Default) 1: ON 2R LIN pin 2R LINM bit RIN pin R RINM bit R MIN pin 2R MINM bit DACL 2R - DACR + MOUT pin DACM bit Figure 23. Summation circuit for MOUT Gain of summation is 0dB for MIN and −6dB for LIN, RIN, DACL and DACR. MS0292-E-02 2012/12 - 36 - [AK4569] Addr 0AH 0BH Register Name DAC Lch ATT DAC Rch ATT Default D7 ATTL7 ATTR7 0 D6 ATTL6 ATTR6 0 D5 ATTL5 ATTR5 0 D4 ATTL4 ATTR4 0 D3 ATTL3 ATTR3 0 D2 ATTL2 ATTR2 0 D1 ATTL1 ATTR1 0 D0 ATTL0 ATTR0 0 ATTL7-0: Setting of the attenuation value of output signal from DACL ATTR7-0: Setting of the attenuation value of output signal from DACR The AK4569 has channel-independent digital attenuator (256 levels, 0.5dB step). This digital attenuator is placed before D/A converter. ATTL/R7-0 bits set the attenuation level (0dB to −127dB or MUTE) of each channel. Digital attenuator is independent of soft mute function. ATTL/R7-0 Attenuation FFH 0dB FEH −0.5dB FDH −1.0dB FCH −1.5dB : : : : 02H −126.5dB 01H −127.0dB 00H Default MUTE (−∞) Table 19. Digital Volume ATT values Addr 0CH Register Name MOUT ATT Default D7 0 0 D6 0 0 D5 0 0 D4 D3 D2 D1 D0 MMUTE ATTM3 ATTM2 ATTM1 ATTM0 1 0 0 0 0 ATTM3-0: Analog volume control for MOUT MMUTE: Mute control for MOUT 0: Normal operation. ATTM3-0 bits control attenuation value. 1: Mute. ATTM3-0 bits are ignored. (Default) MMUTE 0 1 ATTM3-0 Attenuation 0FH 0dB 0EH −2dB 0DH −4dB 0CH −6dB : : : : 01H −28dB 00H −30dB x MUTE Table 20. MOUT Volume ATT values MS0292-E-02 Default 2012/12 - 37 - [AK4569] SYSTEM DESIGN Figure 24 shows the system connection diagram. An evaluation board [AKD4569] is available which demonstrates the optimum layout, power supply arrangements and measurement results. + 2.2µ 0.1µ µP VCOM 22 AVSS 23 AVDD 24 AINR2 25 AINL2 26 AINR1 27 AINL1 28 0.1µ 1 PDN VREF 21 2 CSN LIN 20 3 CCLK MIN 18 Top View 5 LRCK MOUT 17 6 MCLK MUTET 16 HPL 15 14 HPR 13 HVDD 12 HVSS 11 DVSS 10 DVDD 8 SDTI 9 SDTO 7 BICK 0.1µ 0.1µ DIR 10 Digital Ground 4.7µ + RIN 19 AK4569 4 CDTI DSP 0.1µ 1µ 6.8 100µ Headphone + 16 6.8 100µ + 16 + Analog Supply: 2.5 ∼ 3.6V Analog Ground Figure 24. Typical Connection Diagram MS0292-E-02 2012/12 - 38 - 10µ [AK4569] 1. Grounding and Power Supply Decoupling The AK4569 requires careful attention to power supply and grounding arrangements. AVDD is usually supplied from the analog power supply in the system and DVDD is supplied from AVDD via a 10Ω resistor. Alternatively if AVDD, DVDD and HVDD are supplied separately, the power up sequence is not critical. AVSS, DVSS and HVSS must be connected to the analog ground plane. System analog ground and digital ground should be connected together near to where the supplies are brought onto the printed circuit board. Decoupling capacitors should be as close to the AK4569 as possible, with the small value ceramic capacitors being the nearest. 2. Internal Voltage Reference Internal voltage reference is output on the VREF pin (typ. 2.1V). An electrolytic capacitor 4.7μF in parallel with a 0.1μF ceramic capacitor is attached between VREF and AVSS to eliminate the effects of high frequency noise. VCOM is 1.25V(typ) and is a signal ground of this chip. A 2.2μF electrolytic capacitor in parallel with a 0.1μF ceramic capacitor should be connected between VCOM and AVSS to eliminate the effects of high frequency noise. A ceramic capacitor should be connected to VCOM pin and located as close as possible to the AK4569. No load current may be drawn from VREF and VCOM pins. All signals, especially clocks, should be kept away from the VCOM and VREF pins in order to avoid unwanted coupling into the AK4569. 3. Analog Inputs The analog inputs are single-ended and the input resistance 50kΩ (typ) for AINL1/AINR1 pins and 12.5kΩ (typ) for AINL2/AINR2 pins. The input signal range is 1.5Vpp centered on VCOM voltage. Usually, the input signal cuts DC with a capacitor. The cut-off frequency is fc=(1/2πRC). The AK4569 can accept input voltages from AVSS to AVDD. The ADC output data format is 2’s complement. The ADC’s DC offset is removed by the internal HPF (fc=3.4Hz@fs=44.1kHz). 4. Analog Outputs The analog outputs are single-ended outputs and 1.5Vpp(typ) centered on the VCOM voltage. The input data format is 2’s compliment. The output voltage is a positive full scale for 7FFFFH(@20bit) and negative full scale for 80000H(@20bit). The ideal output is VCOM voltage for 00000H(@20bit). If the noise generated by the delta-sigma modulator beyond the audio band causes problems, attenuation by an external filter is required. DC offsets on the analog outputs is eliminated by AC coupling since the analog outputs have a DC offset equal to VCOM plus a few mV. MS0292-E-02 2012/12 - 39 - [AK4569] ■ Application Circuit Example AVDD VREF VREF VCOM VCOM DVDD AK4569 IPGA & ADC AINL1 AINL2 IPGA AK4116 MCLK ADC BICK AINR1 AINR2 HP-amp MCKO RX BICK XTI S/PDIF HPF Audio I/F Controller DAC LRCK LRCK SDTO HPL CSN CCLK DAUX CDTI HP-Amp DAC BOOST SDTI DATT SDTO CDTO HPR DSP MOUT BICK CLKOUT MOUT LIN LRCK RIN SDTI MIN PDN HVDD CSN Control CCLK Register CDTI HVSS MUTET AVSS DVSS SDTO uP Figure 25. Application Circuit Example MS0292-E-02 2012/12 - 40 - [AK4569] <Clock and Data Flow> 1) Analog Recording AVDD VREF VREF VCOM VCOM DVDD AK4569 IPGA & ADC AINL1 AINL2 IPGA AK4116 MCLK ADC BICK AINR1 AINR2 HP-amp MCKO RX BICK XTI HPF Audio I/F Controller DAC LRCK LRCK SDTO HPL CSN CCLK DAUX CDTI HP-Amp DAC BOOST SDTI DATT SDTO CDTO HPR DSP MOUT BICK CLKOUT MOUT LIN LRCK RIN SDTI MIN PDN HVDD CSN Control CCLK Register CDTI HVSS MUTET AVSS SDTO uP DVSS Figure 26. Clock and Data Flow during Analog Recording (with DAC monitor) MS0292-E-02 2012/12 - 41 - [AK4569] 2) Digital Recording AVDD VREF VREF VCOM VCOM DVDD AK4569 IPGA & ADC AINL1 AINL2 IPGA AK4116 MCLK ADC BICK AINR1 AINR2 HP-amp MCKO RX BICK XTI S/PDIF HPF Audio I/F Controller DAC LRCK LRCK SDTO HPL CSN CCLK DAUX CDTI HP-Amp DAC BOOST SDTI DATT SDTO CDTO HPR DSP MOUT BICK CLKOUT MOUT LRCK LIN SDTI RIN MIN PDN HVDD CSN Control CCLK Register CDTI HVSS MUTET AVSS SDTO uP DVSS Figure 27. Clock and Data Flow during Digital Recording (with DAC monitor) MS0292-E-02 2012/12 - 42 - [AK4569] 3) Playback AVDD VREF VREF VCOM VCOM DVDD AK4569 IPGA & ADC AINL1 AINL2 IPGA AK4116 MCLK ADC BICK AINR1 AINR2 HP-amp MCKO RX BICK XTI HPF Audio I/F Controller DAC LRCK LRCK SDTO HPL CSN CCLK DAUX CDTI HP-Amp DAC BOOST SDTI DATT SDTO CDTO HPR DSP MOUT BICK CLKOUT MOUT LRCK LIN SDTI RIN MIN PDN HVDD CSN Control CCLK Register CDTI HVSS MUTET AVSS SDTO uP DVSS Figure 28. Clock and Data Flow during Playback MS0292-E-02 2012/12 - 43 - [AK4569] PACKAGE 28pin QFN (Unit: mm) 4 -C 5.2 ± 0.20 5.0 ± 0.10 28 22 0. 6 0.60 ± 0.10 22 5.2 ± 0.20 5.0 ± 0.10 15 14 8 - 0.02 0.02 + 0.03 0.05 7 0.80 ±0.1 0.50 0. 10 0.05 M 0.21 ± 0.05 0.22 ± 0.05 14 ± 45 15 0.78 ± 0.05 8 28 0. 25 1 45 7 10 0. 20 . -0 21 21 1 2 0. + Note: The black parts of back package should be open. ■ Package & Lead frame material Package molding compound: Epoxy Lead frame material: Cu Lead frame surface treatment: Solder (Pb free) plate MS0292-E-02 2012/12 - 44 - [AK4569] MARKING 4569 XXXX 1 XXXX : Date code identifier (4 digits) Revision History Date (Y/M/D) 04/02/20 05/07/19 Revision 00 01 Reason First Edition Error Correction Page Contents 21 Bass Boost Function Figure 16: “AK4566” Æ “AK4569” System Design Figures 24 to 28: “AK4566” Æ “AK4569” Marking “4566” Æ “4569” PACKAGE 0.78(+0.17, -0.28) Æ 0.78 (±0.05) 0.80(+0.20, -0.00) Æ 0.80 (±0.1) 38-43 45 12/12/20 02 Error Correction 44 MS0292-E-02 2012/12 - 45 - [AK4569] 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 Descriptions of external circuits, application circuits, software and other related information contained in this document are provided only to illustrate the operation and application examples of the semiconductor products. You are fully responsible for the incorporation of these external circuits, application circuits, software and other related information in the design of your equipments. AKM assumes no responsibility for any losses incurred by you or third parties arising from the use of these information herein. AKM assumes no liability for infringement of any patent, intellectual property, or other rights in the application or use of such 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. MS0292-E-02 2012/12 - 46 -