[AK8443] AK8443 16bit 30MSPS video ADC with CCD/CIS interface Features CCD I/F Channel number D-Range CDS circuit ADC Max. Conversion Rate Resolution Offset DAC Range Resolution PGA Range Resolution Output format Power supply CPU I/F Power consumption Operation Temperature: Package 3ch (2ch.) 1.764Vpp / 2.341Vpp ( typ.) Pos. /Neg. polarity 30MSPS (10MSPS/ch) 16bit (straight binary code) ±321mV (normal input range) 8bit 0dB~22dB 7bit 8bit x 2 Æ 16bit or 4bit x 4 Æ 16bit 3.3V±0.3V 3 Wire Serial Interface 365 mW (typ.) 0°C~70°C 28pin QFN with radiation PAD in solder side VCLP AVDD Black Correction CCDIN0 CDS / Clamp 7b 16bit ADC Reg. 7b Reg. LIMIT + Output Control 8b or 4b Serial I/F 7b SHR D1(SDATA) SDENB Reg. RESETB CKGEN SHD D2∼D7 D0(SDCLK) PGA 8bit DAC VCOM sign+17b PGA CDS / Clamp VRN Reference Voltage 3:1 MUX CDS / Clamp 8bit DAC CCDIN2 VRP PGA 8bit DAC CCDIN1 AVSS MCLK DVDD MS1280-E-00 DVSS 2011/8 1 [AK8443] Circuit Block Clamp, CDS Block The clamp circuit and correlated double sample circuits are provided for CCD output signal. In CDS mode, the difference between the feed threw level of signal and the data level is sampled. In clamp mode, the difference between the internal reference VCLP and the data level of signal is sampled. Clamp pull the feed threw level into VCLP level when SHR is high. Black Correction Circuit to add an offset voltage to the sampled signal level. Voltage range of DAC which generates Offset is ±321 mV(typ.) and its resolution is 8 bit. MUX Block MUX is a select switch that selects one signal from three ADC output signals sequentially. The AK8443 has 2-channel mode and 3-channel mode. Each mode is selected by control register. ADC Block The ADC coverts PGA output signal to digital data. The resolution is 16-bit and the maximum conversion rate is 30MSPS. The output code is straight binary. The output data corresponding to black is 0000h, and the data corresponding to white is FFFFh. Output Control Block The output control multiplexes a 16-bit word ADC data into two cycle 8-bit word data or four cycle 4-bit word data. Reference Voltage Gen1erator Block All reference voltage is generated internally. MS1280-E-00 2011/8 2 [AK8443] Pin descriptions No. 1 Name VCLP IO I/O @PD VSS (note1) 2 3 CCDIN0 VCOM I O Hi-Z 4 5 6 7 8 9 10 11 12 13 CCDIN1 AVSS AVDD CCDIN2 NC NC MCLK SHR SHD I P P I I I I O Low Description CDS, Clamp mode: Clamp Voltage output, Connect capacitor0.1uF between AVSS and this pin. DC direct mode: sensor reference voltage input Sensor signal input ADC reference voltage. Connect capacitor0.1uF between AVSS and this pin. Sensor signal input Analog ground Analog VDD Sensor signal input No connection(note 2) No connection(note 2) Main clock Reference level sampling clock Data level sampling clock Data output (MSB) 14 15 16 17 18 19 D7 D6 D5 D4 DVDD DVSS D3 O O O P P O Low Low Low Data output Data output Data output Digital VDD Digital Ground Low Data output 20 D2 O Low 21 D1/SDATA I/O Data output Data output / Serial I/F Data input 22 D0/SDCLK I/O Low (note 3) Low (note 3) 23 24 25 26 27 SDENB RESETB AVDD AVSS VRN I I P P O VSS 28 VRP O VSS Data output (LSB) / Serial I/F Clock input Serial I/F Enable. Reset input. Pull-up 100kΩ to AVDD. Analog VDD Analog ground ADC reference voltage; Negative side. Connect capacitor0.1uF between AVSS and this pin. And connect capacitor 1uF between VRP and this pin. ADC reference voltage; Positive side. Connect capacitor0.1uF between AVSS and this pin. And connect capacitor 1uF between VRN and this pin. (note1) It is connect with VSS via internal resistance by CDS, Clamp mode or DC direct mode (note2) Do not connect it anywhere. (note3) When SDENB is Hi, it will be output condition as VSS. When SDENB is Low, it will be input condition. MS1280-E-00 2011/8 3 [AK8443] Pin Layout D5 15 D4 16 DVDD 17 DVSS 18 D3 19 D2 20 D1/SDATA 21 D0/SDCLK 22 14 D6 SDENB 23 13 D7 RESETB 24 12 SHD AK8443VN Top View AVDD 25 11 SHR AVSS 26 10 MCLK VRN 27 9 NC VRP 28 8 NC 7 CCDIN2 6 AVDD CCDIN1 5 AVSS 4 3 VCOM 2 CCDIN0 1 VCLP MS1280-E-00 2011/8 4 [AK8443] Absolute Maximum Ratings All voltage defined to their corresponding ground. AVSS=DVSS==0V Item Symbol Min. Max. Unit Analog Supply AVDD −0.3 4.6 V Digital Supply DVDD −0.3 4.6 V VINA −0.3 AVDD+0.3 V Input Voltage Remarks Storage Temperature Tstg −65 150 °C Stress above these ratings may cause permanent damage to the device. Functional operation of the device at these ratings is not implied. Recommended Operating Conditions All voltage defined to their corresponding ground, AVSS=DRVSS=0V Item Symbol Min. Typ. Max. Unit Analog Supply AVDD 3.0 3.3 3.6 V Digital Supply DVDD 3.0 3.3 3.6 V Ta 0 70 °C Operating Temperature Remarks **At the power up, the device must be reset once by RESETB pin. **When power on AVDD, please set up the same time with DVDD or DVDD first. **When power down AVDD, please set up the same time with DVDD or before DVDD. **| AVDD-DVDD | < = 0.3V MS1280-E-00 2011/8 5 [AK8443] Electrical Characteristics Analog Characteristics Item (AVDD=DVDD=3.3V, Ta= 25°C, MCLK=30MHz unless otherwise specified) Symbol Condition min typ max Unit Negative, Normal range 2.2 2.3 2.4 V Negative, Large range 2.5 2.6 2.7 V Positive, Normal range 0.7 0.8 0.9 V Positive, Large range 0.5 0.6 0.7 V 0.94 1.1 1.26 V VCOM 1.15 1.25 1.35 V VRP 1.7 1.8 1.9 V VRN 0.6 0.7 0.8 V Normal range 1.56 1.764 Vpp Large range 2.07 2.341 Vpp DC direct mode 1.1 Vpp noise 100mVpp 0.5MHz -30 dB 2080 usec Reference Voltage Block Clamp voltage DC direct VCLP VCLP External input reference level Common voltage ADC positive reference voltage ADC negative reference voltage Clamp and CDS Block Input range (*note 1) CDS effect VI CDS (note 2) Clamp bandwidth PGA gain=0dB setting Signal CLPBW 1.6Vpp 2MHz (Design target value) External cap=0.1uF These characteristics are a value at the time of the external part value which was shown in the external-circuit instance. (note 1) Be careful an input signal which doesn't cross a power supply voltage in case of the positive-polarity and large-range. DC direct mode only use normal range, when input is 1.1Vpp, PGA is 30H setting, it will be full scale. (@VCLP voltage=1.1V) (note 2) When SHR width is minimum. MS1280-E-00 2011/8 6 [AK8443] Item (AVDD=DVDD=3.3V, Ta= 25°C, MCLK=30MHz unless otherwise specified) Symbol Condition min typ max Unit Offset DAC Resolution DRES Range DRNG 8 Input conversion value (note 1) Range2 DRNG2 DRNG3 Positive 271 321 371 mV Negative -373.5 -323.5 -273.5 mV Input conversion value (note 2) Range3 Positive 350.7 mV Negative -353.5 mV 307 mV Input conversion value (note 3) Positive Negative Differential DNL nonlinearity bit The -309.4 Monotonicity -1.0 +1.0 mV LSB guarantee These characteristics are a value at the time of the external part value which was shown in the external-circuit instance. (note 1) Normal range input. (note 2) Large range input. (note 3) DC direct mode. MS1280-E-00 2011/8 7 [AK8443] (AVDD=DVDD=3.3V, Ta= 25°C, MCLK=30MHz unless otherwise specified.) Item Maximum gain Symbol GMAX Condition PGA CCDIN~ADC min typ max Unit 20.3 21.3 22.3 dB 0.001 0.06 Relative value to 0dB setting Step width GSTA The Monotonicity dB guarantee ADC Resolution Differential nonlinearity RES DNL No input noise (note 1) Offset voltage (note 2) NI Crosstalk XTALK1 XTALK2 VOFST CCDIN~ADC 12bit accuracy No missing code 16 +16 −16 Noise, Internal offset, Crosstalk PGA gain=0dB PGA gain=21.3dB CDS, Clamp(normal input) -120 CDS, Clamp(Large input) -145 DC Direct −100 PGA gain=0dB (note 3) (note 4) Power consumption (note 5) (note 6) 9 65 bit LSB LSBrms 120 145 100 128 64 mV LSB LSB Normal AVDD 97.1 123 mA operation DVDD 13.4 27.5 Power down IPD 0.1 mA These characteristics are a value at the time of the external part value which was shown in the external-circuit instance. (note 1) This is defined as sigma of the ADC output cord scattering at no input. (note 2) Definition is that the Offset DAC setting value in no input signal condition exists between Offset DAC setting values, (equivalent to an input-referred – 120mV) and (equivalent to an input-referred + 120mV) where ADC output code changes from 000h to 001h. Since a total adjustable range of Offset Adjust DAC includes this internal Offset adjust range, a practical adjustable range of input signal is reduced by the internal Offset amount. (note 3) Definition at MCLK=30MHz, 3ch, CDS mode. PGA gain of the channel to be measured is set at its maximum value, all other channels’ PGA gains are set at minimum values. Then measure how much the output code of the target channel to be measured fluctuates when input to the measures channel is fixed and a full-scale minus 1 dB step signal is input on all other channels. (note 4) Definition at MCLK=30MHz, 3ch, CDS mode. All channels’ PGA gains at minimum values. Then measure how much the output code of the target channel to be measured fluctuates when input to the measures channel is fixed and a full-scale minus 1 dB step signal is input on all other channels. (note 5) At MCLK=30MHz, and 1.569 Vpp, 1MHz sine-wave signal fed on all 3 channel. (note 6) At the capacitive load is 20pF. MS1280-E-00 2011/8 8 [AK8443] 2) Digital DC Characteristics (AVDD=DVDD=3.0V~3.6V,Ta= 0~70°C) Item Symbol Pin Min. High level input voltage VIH **1 0.7*AVDD Low level input voltage VIL **1 High level output VOH **2 level output VOL **2 ILIKG **1 voltage Low 0.8*DVDD −10 Unit Remark V 0.3*AVDD voltage Input leakage current Max. V V IOH=-1mA 0.2*DVDD V IOL=1mA 10 μA **1 MCLK, SHR, SHD,D0(SDCLK), D1(SDATA), SDENB, RESETB **2 D0~D7 MS1280-E-00 2011/8 9 [AK8443] Switching characteristics (AVDD=DVDD=3.0V~3.6V,Ta=0~70°C, 8bit bus, unless otherwise specified) No. Item Pin Min. Typ. Max. ns 1 MCLK cycle time(T) MCLK 33.3 2 MCLK Low width MCLK 15 ns 3 MCLK High width MCLK 15 ns 4 SHR,SHD cycle time SHR 100 3T 6000 SHD 66.7 2T 4000 5 SHR pulse width SHR 8 ns 6 SHR delay (referenced to SHD↓) SHR 2 ns 7 SHD↑delay (referenced to SHR↓) SHD 2 ns 8 SHD pulse width SHD 8 ns 9 SHD setup time (referenced to MCLK↑) SHD 0 ns 10 SHD delay (referenced to MCLK↓) SHD 10 ns 11 SHR aperture delay SHR 2 ns 12 SHD aperture delay D0~7 output delay SHD 2 ns 13 ( referenced 2000 Unit Condition ns to D7~D0 Pipeline delay (SHD conversion) SHD=”H” 15 2ch Hold 2 12 ns MCLK↑or MCLK↓) 14 3ch setup C=20pF 3 D7~D0 4 clock 3ch mode 2ch mode inhibition period ( After referenced to SHD T+10 ns 3ch mode 2ch mode SHD↓, first MCLK↑) MS1280-E-00 2011/8 10 [AK8443] (AVDD=DVDD=3.0V~3.6V,Ta=0~70°C, 4 bit bus, unless otherwise specified) No. Item Pin Min. Typ. Max. ns 1 MCLK cycle time (T) MCLK 33.3 2 MCLK Low width MCLK 15 ns 3 MCLK High width MCLK 15 ns 4 SHR,SHD cycle time SHR 199.8 6T 12000 SHD 133.2 4T 8000 5 SHR pulse width SHR 8 ns 6 SHR delay (referenced to SHD↓) SHR 2 ns 7 SHD↑ delay (referenced to SHR↓) SHD 2 ns 8 SHD pulse width SHD 8 ns 9 SHD setup time (referenced to MCLK↑) SHD 0 ns 10 SHD delay time (referenced to MCLK↑) SHD 10 ns 11 SHR aperture delay SHR 2 ns 12 SHD aperture delay D0~7 delay time SHD 2 ns 13 (reference to MCLK ↑or 2000 Unit Condition ns D3~D0 2 12 ns SHD=”H” 15 setup C=20pF Pipeline delay (MCLK 2ch hold MCLK ↓) 14 3ch conversion) D3~D0 15 clock 3ch mode 2ch mode inhibition period ( After referenced to SHD 2T+10 ns 3ch mode 2ch mode SHD↓, first MCLK↑) MS1280-E-00 2011/8 11 [AK8443] CCDIN 0 1 2 3 MCLK SHR SHD D7~0 M L CCDIN0 M L CCDIN1 M L CCDIN2 M L CCDIN0 M L CCDIN1 M L CCDIN2 0 M L CCDIN0 1 L among D7 to D0 indicates LSB data, and M indicates MSB data. CCDIN0(n) CCDIN0(n+1) CCDIN1(n) CCDIN1(n+1) CCDIN2(n) CCDIN2(n+1) CCDIN 11 7 5 6 12 SHR 10 4 8 9 15 SHD 1 3 4 2 MCLK 13 D7~0 MSB LSB CCDIN1(n-4) MSB 13 LSB CCDIN2 (n-4) MSB LSB MSB CCDIN0(n-3) LSB MSB LSB CCDIN1(n-3) CCDIN2 (n-3) MSB LSB CCDIN0(n-2) MSB LSB CCDIN1(n-2) 3ch and 8bit bus mode MS1280-E-00 2011/8 12 [AK8443] CCDIN 0 1 2 3 MCLK SHR SHD 15clock 目 D3~0 CCDIN0 CCDIN1 CCDIN2 0 D3 ~ D0 output order is ADout[15:12]→ADout[11:8]→ADout[7:4]→ADout[3:0]. CCDIN0(n+1) CCDIN0(n) CCDIN1(n) CCDIN1(n+1) CCDIN2(n) CCDIN2(n+1) CCDIN 11 7 5 12 6 SHR 10 8 4 9 15 SHD 3 1 4 2 MCLK 13 13 ADout15~12 ADout7~4 D3~0 ADout11~8 CCDIN2(n-4) CCDIN0(n-3) CCDIN1(n-3) CCDIN2(n-3) ADout3~0 CCDIN0(n-2) CCDIN1(n-2) CCDIN2(n-2) 3ch and 4bit bus mode MS1280-E-00 2011/8 13 [AK8443] CCDIN 0 1 2 3 MCLK SHR SHD D7~0 M L CCDIN0 M L CCDIN1 M L M CCDIN0 L CCDIN1 M L M CCDIN0 0 L CCDIN1 M L CCDIN0 1 2 L among D7 to D0 indicates LSB data, and M indicates MSB data. CCDIN CCDINO(n) CCDIN0(n+1) CCDIN0(n+2) CCDIN1(n) CCDIN1(n+1) CCDIN1(n+2) 11 7 5 6 12 SHR 10 4 8 9 15 SHD 1 3 4 2 MCLK 13 D7~0 MSB LSB CCDIN0(n-5) MSB 13 LSB CCDIN1 (n-5) MSB LSB CCDIN0(n-4) MSB LSB CCDIN1(n-4) MSB LSB CCDIN0 (n-3) MSB LSB CCDIN1(n-3) MSB LSB CCDIN0(n-2) 2ch and 8 bit bus mode MS1280-E-00 2011/8 14 [AK8443] CCDIN 0 2 1 3 4 5 6 MCLK SHR SHD 15clock 目 D3~0 CCDIN0 CCDIN1 0 D3 ~ D0 output order is ADout[15:12]→ADout[11:8]→ADout[7:4]→ADout[3:0]. CCDIN CCDIN0(n) CCDIN0(n+1) CCDIN0(n+2) CCDIN1(n) CCDIN1(n+1) CCDIN1(n+2) 11 12 7 5 6 SHR 10 8 4 9 15 SHD 1 3 4 2 MCLK ADout11~8 ADout3~0 13 13 D3~0 ADout15~12 ADout7~4 CCDIN1(n-5) CCDIN0(n-4) CCDIN1(n-4) CCDIN0(n-3) CCDIN1(n-3) CCDIN0(n-2) 2ch and 4bit bus mode MS1280-E-00 2011/8 15 [AK8443] Serial Interface switching characteristics No. 1 2 3 4 5 6 7 8 9 10 11 12 (AVDD=3.0~3.6V, DVDD=3.0~3.6V ,Ta= 0~70°C unless otherwise specified.) Item Pin Min. Typ. Max. Unit Condition Clock cycle SDCLK 0.1 10 MHz Clock pulse width(High) SDCLK 40 ns Clock pulse width(Low) SDCLK 40 ns SDENB setup time SDENB 80 ns ( to SDCLK rising↑) SDENB hold time SDENB 80 ns ( from SDCLK rising↑) Data High-Z delay D0, D1 0 40 ns ( from SDENB falling↓) Data enable delay D0, D1 0 40 ns ( to SDENB rising↑) SDATA setup time SDATA 40 ns ( to SDCLK rising↑) SDATA hold time SDATA 40 ns ( from SDCLK rising↑) SDENB SDCLK,SDENB rising time SDCLK 6 ns SDENB SDCLK,SDENB falling time SDCLK 6 ns SDENB SDENB High level width SDENB 40 ns 12 SDENB 0.7AVDD 0.7AVDD 0.3AVDD 0.3AVDD 11 10 6 7 0.7DVDD D0 0.3DVDD 4 1 5 0.7AVDD SDCLK 0.3AVDD 6 10 3 2 11 7 0.7DVDD D1 SDATA 0.3DVDD 0.7AVDD 0.3AVDD 8 9 Serial interface write timing MS1280-E-00 2011/8 16 [AK8443] Clock Input pin SDCLK and Data Input pin SDATA for Serial Interface are shared with A/D Data Output pins, D0 and D1 respectively. When SDENB becomes low, D0 and D1 are put into High-Z conditions and it is enabled to input SDCLK and SDATA. SDATA is captured at the rising edge of SDCLK. SDATA is 16 Bit long. Write “zeros“ from first Bit to 4th Bit. 5th ~8th Bits are assigned for Register Address where the 5th Bit is MSB and the 8th Bit is LSB. 9th~ 16th Bits are assigned for Data where the 9th Bit is MSB and the 16th Bit is LSB. 16 and more rising edges of SDCLK are required while SDENB is low, from the time to fall to the time to rise. When it is less than 16 rises, registers will not be written properly. If it is more than 16 rises while SDENB is low, from falling to rising, the last 16 edges become effective. There is a possibility that an erroneous data will be written into registers if noises occur on D0 Output / SDCLK input pin and D1 Output / SDATA input pin when these pins are at High-Z conditions. To avoid this, resistors should be connected between D0 / SDCLK pin, D1 / SDATA pin and AVSS respectively to pull-down these pins. SDENB High-Z D0 SDCLK High-Z D1 SDATA 0 0 0 0 A3 A2 A1 A0 B7 B6 B5 B4 B3 B2 B1 B0 0 0 Wright Register MS1280-E-00 2011/8 17 [AK8443] - Power on reset AVDD 100kΩ RESETB 0.33μF AK8443 0.9xAVDD AVDD AVDD rise time max. 10ms It becomes possible for the register writing after 100 ms. RESETB max. 100ms Power on reset At the power-on, Power-On-Reset must be executed by using RESETB pin. When a 0.33 μF external capacitor on RESETB pin is used, the rise time of AVDD must be shorter than 10 ms in order to assure proper Power-On-Reset operation. Maximum time from AVDD power-on to the release from Power-On-Reset is 100 ms. Registers should be written after waiting for longer than 100 ms after AVDD power-on. As electric charge is retained in the external capacitor even after AVDD is made to 0V, voltage on RESETB pin does not go to 0V immediately. If AVDD is powered-up again before RESETB pin returns to 0V, a proper Power-On-Reset operation is not made. In order to assure proper Power-On-Reset operation when to power-up AVDD again, it is required that AVDD time to be kept at 0V is longer than 300 ms. If the 300 ms AVDD time to be kept at 0V, is not obtainable, the device must be reset by applying a low pulse externally on RESETB pin. When the condition doesn’t fill above, please make the RESETB high after power supply start-up, Without CAP connect to RESETB pin. MS1280-E-00 2011/8 18 [AK8443] In RESETB pin use Trst1 Trst2 0.9×AVDD AVDD RESETB 0.3×AVDD 0.3×AVDD 0.3×AVDD (AVDD=DVDD=3.0~3.6V、Ta=0~70 ) Item Symbol Pin min Reset period 1 Trst1 RESETB 100 ns Reset period 2 Trst2 RESETB 100 ns MS1280-E-00 typ max Unit Condition 2011/8 19 [AK8443] Register map Sub Adrs Bits Default Register Function 1H 6 5 4 3 2:0 7:0 Value *0****** **0***** ***0**** ****0*** *****000 00000000 Name TEST BUS INPUTRANG REVERSE MODE OFF0 Test register Output bus setting Input range setting Input inverted setting Operation mode setting CCDIN0 offset setting 2H 7:0 00000000 OFF1 CCDIN1 offset setting 3H 7:0 00000000 OFF2 CCDIN2 offset setting 4H 6:0 *0000000 GAIN0 CCDIN0 gain setting 5H 6:0 *0000000 GAIN1 CCDIN1 gain setting 6H 6:0 *0000000 GAIN2 CCDIN2 gain setting 7H 1:0 ******00 DIRECT DC direct mode setting register 0H Address “08H”~”0EH” is test register. Please do not access the test register. MS1280-E-00 2011/8 20 [AK8443] Operation mode setting (Address “00H”) Reset *000 0000 Please set “0” to test register Output mode setting register BUS Output mode 0 8bit bus mode 1 4bit bus mode Input range change register Input Range Input range 0 1.764V 1 2.341V Input inverted mode register Reverse 0 Input mode Input downstream from VCLP 1 Input upstream from VCLP Operation mode setting MODE Operation mode 000 Power down 100 101 3ch 2ch(0, 1ch active) 110 2ch(1, 2ch active) 111 2ch(0, 1ch active) Other Inhibition (*) Unused input pin be Hi-z by 2ch mode. MS1280-E-00 2011/8 21 [AK8443] Offset setting (Address “01H”~ “03H”) 01H CCDIN0 offset setting 02H CCDIN1 offset setting 03H CCDIN2 offset setting Reset 0000 0000 OFF*[7:0] Offset 0111 1111 Normal range +321.0mV 0111 1110 ・・・ +318.5mV 0000 0001 +2.5mV 0000 0000 0 -2.5mV ・・・ 1111 1111 ・・・ ・・・ -321.0mV 1000 0001 -323.5mV 1000 0000 Note1) At an offset of +2.5 mV, the signal fraction is corrected toward 2.5 mV subtraction. Note2) The value for the normal range input. By large range, 1.093 times x normal range. By DC direct mode, 0.956 times x normal range. Gain setting (Address “04H”~ “06H”) 04H CCDIN0 gain setting 05H CCDIN1 gain setting 06H CCDIN2 gain setting Reset *000 0000 GAIN* gain 000 0000 0 0.06 dB 000 0001 000 0010 ・・・ 0.13 dB 111 1110 20.58 dB ・・・ 21.28 dB 111 1111 Note) Gain is expressed by the following equations. This value is relative gain from “000 0000” setting Vout = 204 × Vin 12 + (127 − x) ( x = 0 ~ 127) Input range=1.764V Vout = 168 × Vin 12 + (127 − x) ( x = 0 ~ 127) Input range=2.341V MS1280-E-00 2011/8 22 [AK8443] Operation mode setting 2 (Address “07H”) Reset **** **00 DC direct mode setting register DIRECT 00 CDS mode, Clamp mode 11 DC direct mode When DC direct mode setting, internal VCLP pin connect GND via 12kΩ. MS1280-E-00 2011/8 23 [AK8443] IO Pin Connection Information Input Output equivalent circuit SHR, SHD, MCLK AVDD P N AVSS RESETB AVDD DVDD P 100kΩ N AVSS AVSS SDENB DVDD AVDD P N AVSS AVSS MS1280-E-00 2011/8 24 [AK8443] CCDIN, VCLP AVDD CCDIN SHR AVSS SHR AVDD VCLP Clamp AMP AVSS VRP, VCOM, VRN 5.5k AVDD reference VGB VRP(1.8V) (1.152V) AVSS 1.54k 0.98k AVDD VCOM(1.25V) AVSS 4.52k AVDD VRN(0.7V) AVSS 7k MS1280-E-00 2011/8 25 [AK8443] D0 3-state Hi-Z : SDENB=”L” Enable: SDENB=”H” DVDD P DVDD D0 DVSS AVDD N AVSS SDCLK AVSS D1 3-state Hi-Z : SDENB=”L” Enable: SDENB=”H” DVDD P DVDD D0 DVSS AVDD N AVSS SDATA AVSS D2 ~ D7 DVDD P DVDD D2 ~ D7 DVSS N AVSS MS1280-E-00 2011/8 26 [AK8443] External circuit example CDS, Clamp mode DVDD:3.3V 0.1μF min.10 kΩ DVSS 15 D5 D4 DVDD 22 0.33μF 16 17 18 DVSS D3 19 D2 20 D1 21 min.10 kΩ 14 D0 D6 23 13 SDENB D7 24 AK8443 RESETB 0.1μF 12 25 AVDD 11 SHR 26 10 0.1μF AVSS 27 9 1μF VRN NC 28 8 MCLK CCDIN2 7 0.1μF 0.1μF AVDD 6 AVSS 5 CCDIN1 4 0.1μF 0.1μF VCOM 3 CCDIN0 2 1 VCLP VRP 0.1μF AVDD 3.3V SHD Top View NC 0.1μF 0.1μF AVSS DC Direct mode DVDD:3.3V min.10 kΩ 0.1μF DVSS 15 D5 16 D4 17 DVDD 18 DVSS 19 D3 20 D2 21 D1 min.10 kΩ 22 D0 0.33μF 14 D6 23 SDENB 13 D7 24 RESETB 0.1μF 12 AK8443 SHD Top View 25 AVDD 11 1μF MCLK 27 VRN 9 NC 7 CCDIN2 6 0.1μF AVDD 5 AVSS 4 CCDIN1 3 VCOM 2 CCDIN0 1 VCLP 0.1μF 10 AVSS 28 VRP 3.3V SHR 26 0.1μF AVDD 8 NC 0.1μF AVSS * The radiation PAD on the package solder side connects with analog ground (AVSS). MS1280-E-00 2011/8 27 [AK8443] Package Package dimension unit [mm] Marking 1. Marketing code :8443 2. Date code :XXX Week code :Y The company management code 8443 XXXY Marking MS1280-E-00 2011/8 28 [AK8443] 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. MS1280-E-00 2011/8 29