ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 Low-Power, 16-Bit, 500kSPS, 4-/8-Channel Unipolar Input ANALOG-TO-DIGITAL CONVERTERS with Serial Interface Check for Samples: ADS8331, ADS8332 FEATURES DESCRIPTION • Low-Power, Flexible Supply Range: – 2.7V to 5.5V Analog Supply – 8.7mW (250kSPS in Auto-Nap Mode, VA = 2.7V, VBD = 1.65V) – 14.2mW (500kSPS, VA = 2.7V, VBD = 1.65V) • Up to 500kSPS Sampling Rate • Excellent DC Performance: – ±1.2 LSB Typ, ±2 LSB Max INL at 2.7V – ±0.6 LSB Typ, –1.0/1.5 LSB Max DNL at 2.7V – 16-Bit NMC Over Temperature • Excellent AC Performance at 5V, fIN = 1kHz: – 91.5dB SNR, 101dB SFDR, –100dB THD • Flexible Analog Input Arrangement: – On-Chip 4-/8-Channel Mux with Breakout – Auto/Manual Channel Select and Trigger • Other Hardware Features: – On-Chip Conversion Clock (CCLK) – Software/Hardware Reset – Programmable Status/Polarity EOC/INT – Daisy-Chain Mode – Global CONVST (Independent of CS) – Deep, Nap, and Auto-Nap Powerdown Modes – SPI™/DSP Compatible Serial Interface – Separate I/O Supply: 1.65V to VA – SCLK up to 40MHz (VA = VBD = 5V) • 24-Pin 4x4 QFN and 24-Pin TSSOP(1) Packages The ADS8331 is a low-power, 16-bit, 500k samples-per-second (SPS) analog-to-digital converter (ADC) with a unipolar, 4-to-1 multiplexer (mux) input. The device includes a 16-bit capacitor-based successive approximation register (SAR) ADC with inherent sample and hold. 1 234 The ADS8332 is based on the same core and includes a unipolar 8-to-1 input mux. Both devices offer a high-speed, wide-voltage serial interface and are capable of daisy-chain operation when multiple converters are used. These converters are available in 24-pin, 4x4 QFN and 24-pin TSSOP (1) packages and are fully specified for operation over the industrial –40°C to +85°C temperature range. Low-Power, High-Speed, SAR Converter Family RESOLUTION/TYPE Communications Transducer Interfaces Medical Instruments Magnetometers Industrial Process Control Data Acquisition Systems Automatic Test Equipment 500kSPS 1MHz 1 ADS8327 ADS8329 2 ADS8328 ADS8330 4 ADS8331 — 8 ADS8332 — 1 — ADS7279 2 — ADS7280 4 ADS8301 — 8 ADS8302 — 1 — ADS7229 2 — ADS7230 16-Bit Pseudo-Diff 14-Bit Pseudo-Diff 12-Bit Pseudo-Diff BLANKSPACE Functional Block Diagram APPLICATIONS • • • • • • • CHANNELS MUXOUT IN[0:3] or IN[0:7] ADCIN SAR M U X + _ COM Output Latch and 3-State Driver SDO CDAC FS/CS Comparator REF+ REF- Conversion and Control Logic SCLK SDI CONVST EOC/INT/CDI RESET (1) TSSOP (PW) package available Q1, 2010. 1 2 3 4 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. TMS320 is a trademark of Texas Instruments. SPI is a trademark of Motorola, Inc.. All other trademarks are the property of their respective owners. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2009, Texas Instruments Incorporated ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. ORDERING INFORMATION (1) PRODUCT ADS8331I MAXIMUM INTEGRAL LINEARITY (LSB) MAXIMUM DIFFERENTIAL LINEARITY (LSB) ±3 PACKAGE-LEAD PACKAGE DESIGNATOR SPECIFIED TEMPERATURE RANGE TSSOP-24 (2) PW –40°C to +85°C TSSOP-24 ±2 (2) TSSOP-24 (2) ±3 TSSOP-24 (2) ±2 (2) RGE ADS8331IRGET Small tape and reel, 250 ADS8331IRGER Tape and reel, 3000 PW –40°C to +85°C ADS8331IBPWT Tube 90 ADS8331IBPWR Tape and reel, 2000 ADS8331IBRGET Small tape and reel, 250 ADS8331IBRGER Tape and reel, 3000 –40°C to +85°C RGE PW –40°C to +85°C ADS8332IPWT Tube, 90 ADS8332IPWR Tape and reel, 2000 ADS8332IRGET Small tape and reel, 250 ADS8332IRGER Tape and reel, 3000 –40°C to +85°C RGE PW –40°C to +85°C ADS8332IBPWT Tube, 90 ADS8332IBPWR Tape and reel, 2000 ADS8332IBRGET Small tape and reel, 250 ADS8332IBRGER Tape and reel, 3000 –40°C to +85°C –1/+1.5 4X4 QFN-24 (1) Tube, 90 Tape and reel, 2000 –1/+2 4X4 QFN-24 ADS8332IB ADS8331IPWT ADS8331IPWR –1/+1.5 4X4 QFN-24 ADS8332I TRANSPORT MEDIA, QUANTITY –1/+2 4X4 QFN-24 ADS8331IB ORDERING INFORMATION RGE –40°C to +85°C For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI website at www.ti.com. TSSOP (PW) package available Q1, 2010. ABSOLUTE MAXIMUM RATINGS Over operating free-air temperature range, unless otherwise noted. (1) ADS8331, ADS8332 UNIT –0.3 to VA + 0.3 V –0.3 to 0.3 V VA to AGND –0.3 to 7 V VBD to BDGND –0.3 to 7 V –0.3 to 0.3 V Digital input voltage to BDGND –0.3 to VBD + 0.3 V Digital output voltage to BDGND –0.3 to VBD + 0.3 V Operating free-air temperature range, (TA) –40 to +85 °C Storage temperature range, (TSTG) –65 to +150 °C +150 °C Voltage Voltage range INX, MUXOUT, ADCIN, REF+ to AGND COM, REF– to AGND AGND to BDGND Junction temperature (TJ Max) 4x4 QFN-24 Package Power dissipation TSSOP-24 Package Power dissipation (1) 2 (TJMax – TA)/θJA W 47 °C/W θJA thermal impedance (TJMax – TA)/θJA W 47 °C/W θJA thermal impedance Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 ELECTRICAL CHARACTERISTICS: VA = 2.7V At TA = –40°C to +85°C, VA = 2.7V, VBD = 1.65V to 2.7V, VREF = 2.5V, and fSAMPLE = 500kSPS, unless otherwise noted. ADS8331I, ADS8332I PARAMETER TEST CONDITIONS MIN TYP ADS8331IB, ADS8332IB MAX MIN VREF TYP MAX UNIT 0 VREF V VA + 0.2 AGND – 0.2 VA + 0.2 V ANALOG INPUT Full-scale input voltage (1) Absolute input voltage INX – COM, ADCIN – COM 0 INX, ADCIN AGND – 0.2 COM AGND – 0.2 Input capacitance ADCIN Input leakage current Unselected ADC input AGND + 0.2 AGND – 0.2 40 –1 45 1 40 –1 AGND + 0.2 V 45 pF 1 nA SYSTEM PERFORMANCE Resolution 16 16 Bits No missing codes 16 INL Integral linearity –3 ±2 3 –2 ±1.2 2 LSB (2) DNL Differential linearity –1 ±0.6 2 –1 ±0.6 1.5 LSB (2) –0.5 ±0.15 0.5 –0.5 ±0.15 0.5 EO Offset error (3) Offset error drift ±1 Offset error matching EG –0.25 Gain error drift –0.06 –0.003 mV PPM/°C ±0.2 0.25 –0.25 0.003 –0.003 ±0.4 Gain error matching Bits ±1 ±0.2 Gain error PSRR 16 –0.06 mV 0.25 ±0.4 %FSR PPM/°C 0.003 %FSR Transition noise 28 28 μV RMS Power-supply rejection ratio 74 74 dB 18 CCLK SAMPLING DYNAMICS tCONV tSAMPLE1 tSAMPLE2 Conversion time 18 Manual-Trigger mode Acquisition time Auto-Trigger mode 3 3 3 Throughput rate CCLK 3 500 CCLK 500 kSPS Aperture delay 15 15 ns Aperture jitter 10 10 ps Step response 100 100 ns Overvoltage recovery 100 100 ns VIN = 2.5VPP at 1kHz –101 –101 dB VIN = 2.5VPP at 10kHz –95 –95 dB VIN = 2.5VPP at 1kHz 88 89 dB VIN = 2.5VPP at 10kHz 86.5 87.5 dB VIN = 2.5VPP at 1kHz 87.5 88.5 dB VIN = 2.5VPP at 10kHz 86 87 dB VIN = 2.5VPP at 1kHz 103 103 dB VIN = 2.5VPP at 10kHz 98 98 dB VIN = 2.5VPP at 1kHz 125 125 dB VIN = 2.5VPP at 100kHz 108 108 dB INX – COM with MUXOUT tied to ADCIN 17 17 MHz ADCIN – COM 30 30 MHz DYNAMIC CHARACTERISTICS THD Total harmonic distortion SNR (4) Signal-to-noise ratio SINAD SFDR Signal-to-noise + distortion Spurious-free dynamic range Crosstalk –3dB small-signal bandwidth (1) (2) (3) (4) Ideal input span; does not include gain or offset error. LSB means least significant bit. Measured relative to an ideal full-scale input (INX – COM) of 2.5V when VA = 2.7V. Calculated on the first nine harmonics of the input frequency. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 3 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com ELECTRICAL CHARACTERISTICS: VA = 2.7V (continued) At TA = –40°C to +85°C, VA = 2.7V, VBD = 1.65V to 2.7V, VREF = 2.5V, and fSAMPLE = 500kSPS, unless otherwise noted. ADS8331I, ADS8332I PARAMETER TEST CONDITIONS ADS8331IB, ADS8332IB MIN TYP MAX MIN TYP MAX UNIT 10.5 11 12.2 10.5 11 12.2 MHz 25 MHz MHz CLOCK Internal conversion clock frequency Used as I/O clock only SCLK external serial clock Used as both I/O clock and conversion clock 25 1 21 1 21 1.2 2.525 1.2 2.525 0.1 –0.1 EXTERNAL VOLTAGE REFERENCE INPUT VREF Input reference range (5) Resistance (REF+) – (REF–) (REF–) – AGND (6) –0.1 Reference input 0.1 20 20 CMOS CMOS V V kΩ DIGITAL INPUT/OUTPUT Logic family VIH High-level input voltage VA ≥ VBD ≥ 1.65V 0.65 × (VBD) VBD + 0.3 0.65 × (VBD) VBD + 0.3 V VIL Low-level input voltage VA ≥ VBD ≥ 1.65V –0.3 0.25 × (VBD) –0.3 0.25 × (VBD) V II Input current VIN = VBD or DGND –50 50 –50 50 nA CI Input capacitance 5 VOH High-level output voltage VA ≥ VBD ≥ 1.65V, IO = 100μA VOL Low-level output voltage VA ≥ VBD ≥ 1.65V, IO = –100μA CO SDO pin capacitance Hi-Z state CL Load capacitance 5 VBD – 0.6 VBD VBD – 0.6 VBD V 0 0.4 0 0.4 V 5 5 30 Data format pF Straight binary pF 30 pF V Straight binary POWER-SUPPLY REQUIREMENTS VA Analog supply voltage (5) 2.7 3.6 2.7 3.6 VBD Digital I/O supply voltage 1.65 VA + 0.2 1.65 VA + 0.2 IA IBD Analog supply current Digital I/O supply current Power dissipation 5.2 fSAMPLE = 250kSPS in Auto-Nap mode 3.2 Nap mode, SCLK = VBD or DGND 325 400 325 400 μA Deep PD mode, SCLK = VBD or DGND 50 250 50 250 nA fSAMPLE = 500kSPS 0.1 0.4 0.1 0.4 mA fSAMPLE = 250kSPS in Auto-Nap mode 0.05 VA = 2.7V, VBD = 1.65V, fSAMPLE = 500kSPS 14.2 VA = 2.7V, VBD = 1.65V, fSAMPLE = 250kSPS in Auto-Nap mode 8.72 6.5 5.2 6.5 V fSAMPLE = 500kSPS 3.2 mA 0.05 18.2 14.2 mA mA 18.2 8.72 mW mW TEMPERATURE RANGE TA (5) (6) 4 Operating free-air temperature –40 +85 –40 +85 °C The ADS8331/32 operates with VA between 2.7V and 5.5V, and VREF between 1.2V and VA. However, the device may not meet the specifications listed in the Electrical Characteristics when VA is between 3.6V and 4.5V. Can vary ±30%. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 ELECTRICAL CHARACTERISTICS: VA = 5V At TA = –40°C to +85°C, VA = 5V, VBD = 1.65V to 5V, VREF = 4.096V, and fSAMPLE = 500kSPS, unless otherwise noted. ADS8331I, ADS8332I PARAMETER TEST CONDITIONS MIN TYP ADS8331IB, ADS8332IB MAX MIN VREF TYP MAX UNIT 0 VREF V VA + 0.2 AGND – 0.2 VA + 0.2 V ANALOG INPUT Full-scale input voltage (1) Absolute input voltage INX – COM, ADCIN – COM 0 INX, ADCIN AGND – 0.2 COM AGND – 0.2 Input capacitance ADCIN Input leakage current Unselected ADC input AGND + 0.2 AGND – 0.2 40 –1 45 1 40 –1 AGND + 0.2 V 45 pF 1 nA SYSTEM PERFORMANCE Resolution 16 16 Bits No missing codes 16 INL Integral linearity –3 ±2 3 –2 ±1 2 LSB (2) DNL Differential linearity –1 ±1 2 –1 ±0.5 1.5 LSB (2) –1 ±0.23 1 –1 ±0.23 1 EO Offset error (3) Offset error drift ±1 Offset error matching EG –0.125 Gain error –0.25 Gain error drift –0.06 –0.003 Bits ±1 0.125 –0.125 0.25 –0.25 0.003 –0.003 ±0.02 Gain error matching PSRR 16 –0.06 mV PPM/°C 0.125 mV 0.25 %FSR ±0.02 PPM/°C 0.003 %FSR Transition noise 30 30 μV RMS Power-supply rejection ratio 78 78 dB 18 CCLK SAMPLING DYNAMICS tCONV tSAMPLE1 tSAMPLE2 Conversion time 18 Manual-Trigger mode Acquisition time Auto-Trigger mode 3 3 3 Throughput rate CCLK 3 500 CCLK 500 kSPS Aperture delay 10 10 ns Aperture jitter 10 10 ps Step response 100 100 ns Overvoltage recovery 100 100 ns VIN = 4.096VPP at 1kHz –100 –100 dB VIN = 4.096VPP at 10kHz –94 –95 dB VIN = 4.096VPP at 1kHz 90.5 91.5 dB VIN = 4.096VPP at 10kHz 88 88 dB VIN = 4.096VPP at 1kHz 90 91 dB VIN = 4.096VPP at 10kHz 87 87 dB VIN = 4.096VPP at 1kHz 101 101 dB VIN = 4.096VPP at 10kHz 96 96 dB VIN = 4.096VPP at 1kHz 119 119 dB VIN = 4.096VPP at 100kHz 107 107 dB INX – COM with MUXOUT tied to ADCIN 22 22 MHz ADCIN – COM 40 40 MHz DYNAMIC CHARACTERISTICS THD Total harmonic distortion SNR (4) Signal-to-noise ratio SINAD SFDR Signal-to-noise + distortion Spurious-free dynamic range Crosstalk –3dB small-signal bandwidth (1) (2) (3) (4) Ideal input span; does not include gain or offset error. LSB means least significant bit. Measured relative to an ideal full-scale input (INX – COM) of 4.096V when VA = 5V. Calculated on the first nine harmonics of the input frequency. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 5 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com ELECTRICAL CHARACTERISTICS: VA = 5V (continued) At TA = –40°C to +85°C, VA = 5V, VBD = 1.65V to 5V, VREF = 4.096V, and fSAMPLE = 500kSPS, unless otherwise noted. ADS8331I, ADS8332I PARAMETER TEST CONDITIONS ADS8331IB, ADS8332IB MIN TYP MAX MIN TYP MAX UNIT 10.9 11.5 12.6 10.9 11.5 12.6 MHz 40 MHz 21 MHz 4.2 V CLOCK Internal conversion clock frequency Used as I/O clock only SCLK external serial clock Used as both I/O clock and conversion clock 40 1 21 1 4.2 1.2 0.1 –0.1 EXTERNAL VOLTAGE REFERENCE INPUT VREF Input reference range (5) Resistance (REF+) – (REF–) 1.2 (REF–) – AGND (6) 4.096 –0.1 Reference input 4.096 0.1 20 20 CMOS CMOS V kΩ DIGITAL INPUT/OUTPUT Logic family VIH High-level input voltage VA ≥ VBD ≥ 1.65V 0.65 × (VBD) VBD + 0.3 0.65 × (VBD) VBD + 0.3 V VIL Low-level input voltage VA ≥ VBD ≥ 1.65V –0.3 0.25 × (VBD) –0.3 0.25 × (VBD) V II Input current VIN = VBD or DGND –50 50 –50 50 nA CI Input capacitance 5 VOH High-level output voltage VA ≥ VBD ≥ 1.65V, IO = 100μA VOL Low-level output voltage VA ≥ VBD ≥ 1.65V, IO = –100μA CO SDO pin capacitance Hi-Z state CL Load capacitance 5 VBD – 0.6 VBD VBD – 0.6 VBD V 0 0.4 0 0.4 V 5 5 30 Data format pF Straight binary pF 30 pF 5.5 V Straight binary POWER-SUPPLY REQUIREMENTS VA Analog supply voltage (5) 4.5 VBD Digital I/O supply voltage 1.65 IA IBD Analog supply current Digital I/O supply current Power dissipation 5 5.5 4.5 VA + 0.2 1.65 7.75 5 VA + 0.2 6.6 7.75 V fSAMPLE = 500kSPS 6.6 fSAMPLE = 250kSPS in Auto-Nap mode 4.2 Nap mode, SCLK = VBD or DGND 390 500 390 500 μA Deep PD mode, SCLK = VBD or DGND 80 250 80 250 nA fSAMPLE = 500kSPS 1.2 2.0 1.2 2.0 mA fSAMPLE = 250kSPS in Auto-Nap mode 0.7 VA = 5.0V, VBD = 5.0V, fSAMPLE = 500kSPS 39 VA = 5.0V, VBD = 5.0V, fSAMPLE = 250kSPS in Auto-Nap mode 24.5 4.2 mA 0.7 48.75 39 mA mA 48.75 24.5 mW mW TEMPERATURE RANGE TA (5) (6) 6 Operating free-air temperature –40 +85 –40 +85 °C The ADS8331/32 operates with VA between 2.7V and 5.5V, and VREF between 1.2V and VA. However, the device may not meet the specifications listed in the Electrical Characteristics when VA is between 3.6V and 4.5V. Can vary ±30%. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 TIMING CHARACTERISTICS: VA = 2.7V At TA = –40°C to +85°C, VA = 2.7V, and VBD = 1.65V, unless otherwise noted. (1) (2) PARAMETER MIN External, fCCLK = 1/2 fSCLK fCCLK Frequency, conversion clock, CCLK Internal TYP 0.5 10.5 11 MAX UNIT 10.5 MHz 12.2 MHz tSU1 Setup time, rising edge of CS to EOC 1 CCLK tH1 Hold time, rising edge of CS to EOC 25 ns tWL1 Pulse duration, CONVST low 40 ns tWH1 Pulse duration, CS high 40 ns tSU2 Setup time, rising edge of CS to EOS 25 ns tH2 Hold time, rising edge of CS to EOS 25 ns tSU3 Setup time, falling edge of CS to first falling edge of SCLK 14 ns tWL2 Pulse duration, SCLK low 17 tSCLK – 17 ns tWH2 Pulse duration, SCLK high 12 tSCLK – 12 ns I/O clock only 40 I/O and conversion clocks tSCLK Cycle time, SCLK I/O clock, daisy-chain mode I/O and conversion clocks, daisy-chain mode 47.6 ns 1000 40 47.6 ns ns 1000 tD1 Delay time, falling edge of SCLK to SDO invalid 10pF load tD2 Delay time, falling edge of SCLK to SDO valid 10pF load 35 ns tD3 Delay time, falling edge of CS to SDO valid, SDO MSB output 10pF load 35 ns tSU4 Setup time, SDI to falling edge of SCLK 8 tH3 Hold time, SDI to falling edge of SCLK 8 tD4 Delay time, rising edge of CS to SDO 3-state tSU5 Setup time, last falling edge of SCLK before rising edge of CS tD5 Delay time, falling edge of CS to deactivation of INT tD6 Delay time, CDI to SDO in daisy-chain mode (1) (2) 8 ns ns ns ns 10 10 10pF load ns ns 40 ns 35 ns All input signals are specified with tr = tf = 1.5ns (10% to 90% of VBD) and timed from a voltage level of (VIL + VIH)/2. See the Timing Diagrams section. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 7 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com TIMING CHARACTERISTICS: VA = 5V At TA = –40°C to +85°C, and VA = VBD = 5V, unless otherwise noted. (1) (2) PARAMETER MIN External, fCCLK = 1/2 fSCLK fCCLK Frequency, conversion clock, CCLK Internal TYP 0.5 10.9 11.5 MAX UNIT 10.5 MHz 12.6 MHz tSU1 Setup time, rising edge of CS to EOC 1 CCLK tH1 Hold time, rising edge of CS to EOC 20 ns tWL1 Pulse duration, CONVST low 40 ns tWH1 Pulse duration, CS high 40 ns tSU2 Setup time, rising edge of CS to EOS 20 ns tH2 Hold time, rising edge of CS to EOS 20 ns tSU3 Setup time, falling edge of CS to first falling edge of SCLK 8 ns tWL2 Pulse duration, SCLK low 12 tSCLK – 12 ns tWH2 Pulse duration, SCLK high 11 tSCLK – 11 ns I/O clock only 25 I/O and conversion clocks tSCLK Cycle time, SCLK I/O clock, daisy-chain mode I/O and conversion clocks, daisy-chain mode 47.6 ns 1000 25 47.6 ns ns 1000 tD1 Delay time, falling edge of SCLK to SDO invalid 10pF load tD2 Delay time, falling edge of SCLK to SDO valid 10pF load 20 ns tD3 Delay time, falling edge of CS to SDO valid, SDO MSB output 10pF load 20 ns tSU4 Setup time, SDI to falling edge of SCLK 8 tH3 Hold time, SDI to falling edge of SCLK 8 tD4 Delay time, rising edge of CS to SDO 3-state tSU5 Setup time, last falling edge of SCLK before rising edge of CS tD5 Delay time, falling edge of CS to deactivation of INT tD6 Delay time, CDI to SDO in daisy-chain mode (1) (2) 8 5 ns ns ns ns 10 10 10pF load ns ns 20 ns 20 ns All input signals are specified with tr = tf = 1.5ns (10% to 90% of VBD) and timed from a voltage level of (VIL + VIH)/2. See the Timing Diagrams section. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 TIMING DIAGRAMS tWL1 CONVST EOC (active low) tSU2 tH1 tSU5 CS tSCLK SCLK tD1 SDO High-Z MSB MSB - 1 MSB - 2 MSB - 3 tD3 SDI '1' LSB + 1 tD2 LSB TAG2 X X tD4 TAG1 TAG0 '0' High-Z '0' tSU4 '1' '0' X '1' X X X X tH3 Figure 1. Read While Sampling (Shown with Manual-Trigger Mode) CONVST 21 Conversion Clock Cycles EOC (active low) tH2 tSU1 CS tWL2 tSU3 SCLK tWH2 High-Z SDO MSB LSB MSB - 1 MSB - 2 MSB - 3 TAG2 TAG1 High-Z TAG0 tD4 SDI '1' '1' '0' X '1' X X X X Figure 2. Read While Converting (Shown with Auto-Trigger Mode at 500 kSPS) CS tSU3 tSU5 SCLK tH3 MSB SDI tD3 SDO MSB - 1 tD1 MSB MSB - 2 LSB + 1 LSB tD2 MSB - 1 MSB - 2 LSB + 1 LSB Don’t Care tD4 ‘0’ Figure 3. SPI I/O Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 9 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com TIMING DIAGRAMS (continued) CS tH1 EOC (active low) tD5 INT (active low) Figure 4. Relationship among CS, EOC, and INT PIN ASSIGNMENTS MUXOUT IN4/NC(1) 1 18 IN5/NC(1) 2 17 IN6/NC(1) 3 IN7/NC(1) 4 RESET 5 EOC/INT/CDI 6 IN1 1 24 IN0 IN2 2 23 COM IN3 3 22 MUXOUT IN4/NC(3) 4 21 ADCIN IN5/NC(3) 5 20 AGND ADCIN IN6/NC(3) 6 19 REF- AGND IN7/NC(3) 7 18 REF+ RESET 8 17 VA EOC/INT/CDI 9 16 VBD SCLK 10 15 CONVST FS/CS 11 14 DGND SDI 12 13 SDO 19 COM PW PACKAGE TSSOP-24 (TOP VIEW) 20 IN0 21 IN1 22 IN2 23 24 IN3 RGE PACKAGE 4x4 QFN-24 (TOP VIEW) ADS8331 ADS8332 Thermal Pad(2) (Bottom Side) 16 REF- 15 REF+ 14 VA 13 VBD 10 7 8 9 10 11 12 SCLK FS/CS SDI SDO DGND CONVST (3) (1) NC = No internal connection (ADS8331 only). (2) Connect thermal pad to analog ground. ADS8331 ADS8332 NC = No internal connection (ADS8331 only). Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 ADS8331 PIN DESCRIPTIONS PIN NO. NAME TSSOP QFN I/O ADCIN 21 18 I ADC input AGND 20 17 – Analog ground DGND 14 11 – Digital interface ground COM 23 20 I Common ADC input (usually connected to AGND) CONVST 15 12 I Conversion start. Freezes sample and hold, starts conversion. EOC/INT/CDI 9 6 O/O/I DESCRIPTION Status output. If programmed as end-of-conversion (EOC), this pin is low (default) when a conversion is in progress. If programmed as an interrupt (INT), this pin is low (default) after the end of conversion and returns high after FS/CS goes low. The polarity of EOC or INT is programmable. This pin can also be used as a chain data input (CDI) when operated in daisy-chain mode. FS/CS 11 8 I Frame sync signal for DSP (such as TMS320™ DSP) or chip select input for SPI. IN[0:3] 1-3, 24 21-24 I Mux inputs NC 4-7 1-4 – No connection MUXOUT 22 19 O Mux output REF+ 18 15 I External reference input REF– 19 16 – External reference ground (connect to AGND through an individual via on the printed circuit board) RESET 8 5 I External reset (active low) SCLK 10 7 I SPI clock for serial interface SDI 12 9 I SPI serial data in SDO 13 10 O SPI serial data out VA 17 14 – Analog supply, +2.7V to +5.5V VBD 16 13 – Digital interface supply ADS8332 PIN DESCRIPTIONS PIN NO. TSSOP QFN I/O ADCIN NAME 21 18 I ADC input AGND 20 17 – Analog ground DGND 14 11 – Digital interface ground COM 23 20 I Common ADC input (usually connected to AGND) CONVST 15 12 I Conversion start. Freezes sample and hold, starts conversion. EOC/INT/CDI 9 6 O/O/I DESCRIPTION Status output. If programmed as end-of-conversion (EOC), this pin is low (default) when a conversion is in progress. If programmed as an interrupt (INT), this pin is low (default) after the end of conversion and returns high after FS/CS goes low. The polarity of EOC or INT is programmable. This pin can also be used as a chain data input (CDI) when operated in daisy-chain mode. FS/CS 11 8 I IN[0:7] 1-7, 24 1-4, 21-24 Frame sync signal for DSP (such as TMS320™ DSP) or chip select input for SPI. I MUXOUT 22 19 O Mux output REF+ 18 15 I External reference input REF– 19 16 – External reference ground (connect to AGND through an individual via on the printed circuit board) RESET 8 5 I External reset (active low) SCLK 10 7 I SPI clock for serial interface SDI 12 9 I SPI serial data in SDO 13 10 O SPI serial data out VA 17 14 – Analog supply, +2.7 V to +5.5 V VBD 16 13 – Digital interface supply Mux inputs Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 11 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com TYPICAL CHARACTERISTICS: DC Performance At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, and fSAMPLE = 500kSPS, unless otherwise noted. INTEGRAL LINEARITY ERROR vs CODE 3 INTEGRAL LINEARITY ERROR vs CODE 3 VA = VBD = 2.7V VREF = 2.500V 2 2 1 ILE (LSB) ILE (LSB) 1 0 0 -1 -1 -2 -2 -3 0000h 4000h 8000h Output Code C000h -3 0000h FFFFh C000h Figure 6. DIFFERENTIAL LINEARITY ERROR vs CODE DIFFERENTIAL LINEARITY ERROR vs CODE 3 VA = VBD = 2.7V VREF = 2.500V 2 FFFFh VA = VBD = 5.0V VREF = 4.096V 2 1 DLE (LSB) 1 DLE (LSB) 8000h Output Code 4000h Figure 5. 3 0 0 -1 -1 -2 -2 -3 0000h 4000h 8000h Output Code C000h FFFFh -3 0000h 8000h Output Code 4000h C000h Figure 7. Figure 8. ANALOG SUPPLY CURRENT vs ANALOG SUPPLY VOLTAGE ANALOG SUPPLY CURRENT IN NAP MODE vs ANALOG SUPPLY VOLTAGE FFFFh 500 8.0 7.5 VREF = 4.096V VREF = 4.096V 450 Nap Current (mA) 7.0 IA (mA) VA = VBD = 5.0V VREF = 4.096V 6.5 VREF = 2.500V 6.0 5.5 VREF = 2.500V 400 350 5.0 4.5 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6 4.5 4.6 4.7 4.8 4.9 5.0 5.1 5.2 5.3 5.4 5.5 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6 4.5 4.6 4.7 4.8 4.9 5.0 5.1 5.2 5.3 5.4 5.5 300 4.0 VA (V) VA (V) Figure 9. 12 Figure 10. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 TYPICAL CHARACTERISTICS: DC Performance (continued) At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, and fSAMPLE = 500kSPS, unless otherwise noted. ANALOG SUPPLY CURRENT vs SAMPLING RATE IN AUTO-NAP MODE DEEP POWER-DOWN CURRENT vs TEMPERATURE 120 8 VA = VBD = 5.0V VREF = 4.096V 6 IA (mA) Deep Power-Down Current (nA) 7 5 4 3 VA = VBD = 2.7V VREF = 2.500V 2 1 100 80 60 40 50 100 150 200 250 300 Sampling Rate (kHz) 350 400 0 -50 450 25 50 Temperature (°C) Figure 12. INTERNAL CLOCK FREQUENCY vs ANALOG SUPPLY VOLTAGE CHANGE IN GAIN vs TEMPERATURE 75 100 75 100 4 D Gain (LSB relative to +25°C) 11.7 Frequency (MHz) 0 -25 Figure 11. 12.2 VREF = 4.096V VREF = 2.500V 11.2 10.7 10.2 VA = VBD = 2.7V VREF = 2.500V 2 1 0 VA = VBD = 5.0V VREF = 4.096V -1 -2 -3 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6 4.5 4.6 4.7 4.8 4.9 5.0 5.1 5.2 5.3 5.4 5.5 0 -25 25 50 Temperature (°C) Figure 13. Figure 14. CHANGE IN OFFSET vs TEMPERATURE CHANGE IN ANALOG SUPPLY CURRENT vs TEMPERATURE 6 1.0 5 DIA (mA relative to +25°C) 0.8 4 VA = VBD = 2.7V VREF = 2.500V 3 2 1 0 -1 -2 VA = VBD = 5.0V VREF = 4.096V -3 -4 -5 -6 -50 3 -4 -50 VA (V) D Offset (LSB relative to +25°C) VA = VBD = 2.7V VREF = 2.500V 20 0 0 VA = VBD = 5.0V VREF = 4.096V 0.6 0.4 0.2 0 VA = VBD = 2.7V VREF = 2.500V -0.2 -0.4 -0.6 VA = VBD = 5.0V VREF = 4.096V -0.8 -25 0 25 50 Temperature (°C) 75 100 -1.0 -50 -25 Figure 15. 0 25 50 Temperature (°C) 75 100 Figure 16. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 13 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com TYPICAL CHARACTERISTICS: DC Performance (continued) At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, and fSAMPLE = 500kSPS, unless otherwise noted. CHANGE IN DIGITAL SUPPLY CURRENT vs TEMPERATURE CHANGE IN INTERNAL CLOCK FREQUENCY vs TEMPERATURE 150 D Frequency (kHz relative to +25°C) 1.0 DIBD (mA relative to +25°C) 0.8 0.6 VA = VBD = 2.7V VREF = 2.500V 0.4 0.2 0 -0.2 VA = VBD = 5.0V VREF = 4.096V -0.4 -0.6 -0.8 -1.0 -50 -25 0 25 50 Temperature (°C) 75 125 100 VA = VBD = 2.7V VREF = 2.500V 75 50 25 0 -25 -50 VA = VBD = 5.0V VREF = 4.096V -75 -100 -125 -150 -50 100 0 -25 Figure 17. 25 50 Temperature (°C) 75 100 Figure 18. CHANGE IN ANALOG SUPPLY CURRENT IN NAP MODE vs TEMPERATURE D Nap Current Relative to +25°C (mA) 25 VA = VBD = 2.7V VREF = 2.500V 20 15 10 5 VA = VBD = 5.0V VREF = 4.096V 0 -5 -10 -15 -20 -25 -50 -25 0 25 50 Temperature (°C) 75 100 Figure 19. 14 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 TYPICAL CHARACTERISTICS: AC Performance At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, fSAMPLE = 500kSPS, and fIN = 10kHz, unless otherwise noted. OUTPUT CODE HISTOGRAM FOR A DC INPUT (8192 Conversions) OUTPUT CODE HISTOGRAM FOR A DC INPUT (8192 Conversions) VA = VBD = 2.7V VREF = 2.500V 6336 4791 1665 1643 1088 768 53 7FFD 7FFE 7FFF 8000 40 0 8001 7FFD 7FFF Code Figure 20. Figure 21. FREQUENCY SPECTRUM (8192 Point FFT, fIN = 1.0376kHz, –0.2dB) FREQUENCY SPECTRUM (8192 Point FFT, fIN = 1.0376kHz, –0.2dB) 7FFE 8000 8001 0 VA = VBD = 2.7V VREF = 2.500V -20 VA = VBD = 5.0V VREF = 4.096V -20 -40 Amplitude (dB) -40 Amplitude (dB) 0 Code 0 -60 -80 -100 -60 -80 -100 -120 -120 -140 -140 -160 -160 0 50 100 150 200 250 0 50 Frequency (kHz) 100 150 200 250 Frequency (kHz) Figure 22. Figure 23. FREQUENCY SPECTRUM (8192 Point FFT, fIN = 10.0708kHz, –0.2dB) FREQUENCY SPECTRUM (8192 Point FFT, fIN = 10.0708kHz, –0.2dB) 0 0 VA = VBD = 2.7V VREF = 2.500V -20 VA = VBD = 5.0V VREF = 4.096V -20 -40 Amplitude (dB) -40 Amplitude (dB) VA = VBD = 5.0V VREF = 4.096V -60 -80 -100 -60 -80 -100 -120 -120 -140 -140 -160 -160 0 50 100 150 200 250 0 Frequency (kHz) 50 100 150 200 250 Frequency (kHz) Figure 24. Figure 25. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 15 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com TYPICAL CHARACTERISTICS: AC Performance (continued) At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, fSAMPLE = 500kSPS, and fIN = 10kHz, unless otherwise noted. SIGNAL-TO-NOISE + DISTORTION vs TEMPERATURE SIGNAL-TO-NOISE RATIO vs INPUT FREQUENCY 95 93 fIN = 1.03760kHz, -0.2dB 90 91 SNR (dB) SINAD (dB) VA = VBD = 5.0V VREF = 4.096V VA = VBD = 5.0V VREF = 4.096V 92 90 VA = VBD = 2.7V VREF = 2.500V 85 89 VA = VBD = 2.7V VREF = 2.500V 88 80 87 -50 -25 0 25 50 75 10 1 100 Figure 27. TOTAL HARMONIC DISTORTION vs INPUT FREQUENCY SPURIOUS-FREE DYNAMIC RANGE vs INPUT FREQUENCY 105 -70 100 -75 95 -80 SFDR (dB) THD (dB) Figure 26. -65 VA = VBD = 5.0V VREF = 4.096V -85 100 250 fIN (kHz) Temperature (°C) -90 VA = VBD = 2.7V VREF = 2.500V 90 VA = VBD = 5.0V VREF = 4.096V 85 80 75 -95 VA = VBD = 2.7V VREF = 2.500V -100 70 65 -105 1 10 100 250 10 1 100 250 fIN (kHz) fIN (kHz) Figure 28. Figure 29. SIGNAL-TO-NOISE + DISTORTION vs INPUT FREQUENCY 95 VA = VBD = 5.0V VREF = 4.096V SINAD (dB) 90 85 VA = VBD = 2.7V VREF = 2.500V 80 75 70 65 1 10 100 250 fIN (kHz) Figure 30. 16 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 TYPICAL CHARACTERISTICS: AC Performance (continued) At TA = +25°C, VREF (REF+ – REF–) = 4.096V when VA = VBD = 5V or VREF (REF+ – REF–) = 2.5V when VA = VBD = 2.7V, fSCLK = 21MHz, fSAMPLE = 500kSPS, and fIN = 10kHz, unless otherwise noted. EFFECTIVE NUMBER OF BITS vs INPUT FREQUENCY POWER-SUPPLY REJECTION RATIO vs POWER-SUPPLY RIPPLE FREQUENCY 16.0 VA = VBD = 5.0V VREF = 4.096V 15.5 15.0 PSRR (dB) ENOB (Bits) 14.5 14.0 13.5 VA = VBD = 2.7V VREF = 2.500V 13.0 12.5 12.0 11.5 11.0 1 10 100 95 90 85 80 75 70 65 60 55 50 45 40 35 250 VRIPPLE = 0.5VPP VA = VBD = 2.7V VREF = 2.500V VA = VBD = 5.0V VREF = 4.096V 0.1 1 fIN (kHz) Figure 31. 10 Ripple Frequency (kHz) 100 500 Figure 32. CROSSTALK vs INPUT FREQUENCY -95 Crosstalk (dB) -100 -105 -110 VA = VBD = 5.0V VREF = 4.096V -115 -120 VA = VBD = 2.7V VREF = 2.500V -125 -130 1 10 100 250 fIN (kHz) Figure 33. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 17 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com THEORY OF OPERATION DESCRIPTION The ADS8331/32 is a high-speed, low-power, successive approximation register (SAR) analog-to-digital converter (ADC) that uses an external reference. The architecture is based on charge redistribution, which inherently includes a sample/hold function. The ADS8331/32 has an internal clock that is used to run the conversion. However, the ADS8331/32 can be programmed to run the conversion based on the external serial clock (SCLK). The analog input to the ADS8331/32 is provided to two input pins: one of the INX input channels and the shared COM pin. When a conversion is initiated, the differential input on these pins is sampled on the internal capacitor array. While a conversion is in progress, both INX and COM inputs are disconnected from any internal function. The ADS8331 has four analog inputs while the ADS8332 has eight inputs. All inputs share the same common pin, COM. Both the ADS8331 and ADS8332 can be programmed to select a channel manually or can be programmed into the auto channel select mode to sweep through the input channels automatically. SIGNAL CONDITIONING The ADS8331/32 has the flexibility to add signal conditioning between the MUXOUT and ADCIN pins, such as a programmable gain amplifier (PGA) or filter. This feature reduces the system component count and cost because each input channel does not require separate signal conditioning circuits, especially if the source impedance connected to each channel is similar in value. ANALOG INPUT When the converter enters the hold mode, the voltage difference between the INX and COM inputs is captured on the internal capacitor array. The voltage on the COM pin is limited between (AGND – 0.2V) and (AGND + 0.2V). This limitation allows the ADS8331/32 to reject small signals that are common to both the INX and COM inputs. The INX inputs have a range of –0.2V to (VA + 0.2V). The input span of (INX – COM) is limited to 0V to VREF. The peak input current through the analog inputs depends upon a number of factors: reference voltage, sample rate, input voltage, and source impedance. The current flowing into the ADS8331/32 charges the internal capacitor array during the sample period. After this capacitance has been fully charged, there is no further input current. The source of the analog input voltage must be able to charge the maximum input capacitance (45pF) to a 16-bit settling level within the minimum acquisition time (238ns). When the converter goes into hold mode, the input impedance is greater than 1GΩ. Care must be taken regarding the absolute analog input voltage. To maintain linearity of the converter, the INX inputs, the COM input, and the input span of (INX – COM) should be within the limits specified. If these inputs are outside of these ranges, the linearity of the converter may not meet specifications. To minimize noise, low-bandwidth input signals with low-pass filters should be used. Care should be taken to ensure that the output impedance of the sources driving the INX and COM inputs are matched, as shown in Figure 34. If this matching is not observed, the two inputs could have different settling times, which may result in an offset error, gain error, and linearity error that change with temperature and input voltage. MUXOUT ADCIN Device in Hold Mode 50W 40W 40pF 55W 40pF IN0 50W 4pF VA INX 4pF AGND COM AGND Figure 34. Input Equivalent Circuit 18 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 Driver Amplifier Choice In order to take advantage of the high sample rate offered by the ADS8331/32, the analog inputs to the converter should be driven with low-noise operational amplifiers (op amps), such as the OPA365, OPA211, OPA827, or THS4031. An RC filter is recommended at each of the input channels to low-pass filter noise generated by the input driving sources. These channels can accept unipolar signals with voltages between INX and COM in the range of 0V to VREF. If RC filters are not used between the op amps and the input channels, the minimum –3dB bandwidth required by the driving op amps for the sampled signals to settle to within 1/2 LSB of the final voltage can be calculated using Equation 1: (n + 1) ´ ln(2) f-3dB ³ 2p ´ tSAMPLE_MIN (1) Where: n = resolution of the converter (n = 16 for the ADS8331/32). tSAMPLE_MIN = minimum acquisition time. The minimum value of tSAMPLE in the Electrical Characteristics tables is 238ns (3 CCLKs with the internal oscillator at 12.6MHz). Substituting these values for n and tSAMPLE_MIN into Equation 1 shows f–3dB must be at least 7.9MHz. This bandwidth can be relaxed if the acquisition time is increased or an RC filter is added between the driving op amp and the corresponding input channel (refer to Texas Instruments' Application Report SBAA173 and associated references for additional information, available for download at www.ti.com). The OPA365 used in the source-follower (unity-gain) configuration is shown in Figure 35 with recommended values for the RC filter. Input Signal (0V to 4V) MUXOUT ADCIN VA 20W OPA365 5V ADS8331 ADS8332 INX 1000pF COM Figure 35. Unipolar Input Drive Configuration Bipolar to Unipolar Driver In systems where the input signal is bipolar, op amps such as the OPA365 and OPA211 can be used in the inverting configuration with a dc bias applied to the noninverting input in order to keep the input signal to the ADS8331/32 within its rated operating voltage range. This configuration is also recommended when the ADS8331/32 is used in signal-processing applications where good SNR and THD performance is required. The dc bias can be derived from low-noise reference voltage ICs such as the REF5025 or REF5040. The input configuration shown in Figure 36 is capable of delivering better than 91dB SNR and –99dB THD at an input frequency of 1kHz. If bandpass filters are used to filter the input to the driving op amp, the signal swing at the input of the bandpass filter should be small enough to minimize the distortion introduced by the filter. In these cases, the gain of the circuit shown in Figure 36 can be increased to maintain a large enough input signal to the ADS8331/32 to keep the system SNR as high as possible. MUXOUT ADCIN 5V 2.048VDC VA 20W 600W OPA211 INX 1000pF Input Signal (-2V to +2V) 600W ADS8331 ADS8332 COM Figure 36. Bipolar Input Drive Configuration Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 19 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com REFERENCE The ADS8331/32 can operate with an external reference with a range from 1.2V to 4.2V. A clean, low-noise reference voltage on this pin is required to ensure good converter performance. A low-noise band-gap reference such as the REF5025 or REF5040 can be used to drive this pin. A 10μF ceramic bypass capacitor is required between the REF+ and REF– pins of the converter. This capacitor should be placed as close as possible to the pins of the device. Note that the REF– pin should not be connected to the AGND pin of the converter; instead, the REF– pin must be connected to the analog ground plane with a separate via. CONVERTER OPERATION The ADS8331/32 has an internal oscillator that can be used as the conversion clock (CCLK) source. The minimum frequency of this oscillator is 10.5MHz. The internal oscillator is only active during the conversion period unless the converter is using Auto-Trigger and/or Auto-Nap modes. The minimum acquisition/sampling time for the ADS8331/32 is 3 CCLKs (250ns with a 12MHz conversion clock), while the minimum conversion time is 18 CCLKs (1500ns with a 12MHz conversion clock). As shown in Figure 37, the ADS8331/32 can also be programmed to run conversions using the external serial clock (SCLK). This feature allows system designers to achieve system synchronization. Each rising edge of SCLK toggles the state of the conversion clock (CCLK), which reduces the frequency of SCLK by a factor of two before it is used as CCLK. For example, a 21MHz SCLK provides a 10.5MHz CCLK. If the start of a conversion must occur on a specific rising edge of SCLK when the external serial clock is used for the conversion clock (and Manual-Trigger mode is enabled), a minimum setup time of 20ns between the falling edge of CONVST and the rising edge of SCLK must be met. This timing ensures the conversion is completed in 18 CCLKs (36 SCLKs). The duty cycle of SCLK is not critical, as long as the minimum high and low times (11ns for VA = 5.0V) are satisfied. Because the ADS8331/32 is designed for high-speed applications, a high-frequency serial clock must be supplied to maintain the high throughput of the interface. This requirement can be accomplished if the period of SCLK is at most 1μs when SCLK is used as the conversion clock (CCLK). The 1μs maximum period for SCLK is also set by the leakage of charge from the capacitors in the capacitive digital-to-analog converter (CDAC) block in the ADS8331/32. If SCLK is used as the conversion clock, the SCLK source must have minimal rise/fall times and low jitter to provide the best converter performance. CFR_D10 Conversion Clock (CCLK) =1 Oscillator SPI Serial Clock (SCLK) =0 Divide by 2 Figure 37. Conversion Clock Source Manual Channel Select Mode Manual Channel Select mode is enabled through the Configuration register (CFR) by setting the CFR_D11 bit to '0' (see Table 5). The acquisition process starts with selecting an input channel. This selection is done by writing the desired channel number to the Command register (CMR); see Table 4 for further details. The associated timing diagram is shown in Figure 38. CS SCLK < 30ns Mux switch CHOLD CHNEW Figure 38. Manual Channel Select Timing 20 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 Auto Channel Select Mode Channel selection can also be done automatically if Auto Channel Select mode (default) is enabled (CFR_D11 = '1'). If the device is programmed for Auto Channel Select mode, then signals from all channels are acquired in a fixed order. In Auto Channel Select mode, the first conversion after entering this mode is always from the channel of the last conversion completed before this mode is enabled. The channels are then sequentially scanned up to and including the last channel (that is, channel 3 for the ADS8331 and channel 7 for the ADS8332) and then back to the channel that started the sequence. For example, if the last channel used in the conversion before enabling Auto Channel Select mode was channel 2, the sequence for the ADS8332 would be: 2, 3, 4, 5, 6, 7, 2, etc., as shown in Figure 39. If the last channel in Manual Channel Select mode happened to be channel 7, the sequence would be: 7, 7, 7, etc. Figure 40 shows when the next channel in the sequence activates during Auto Channel Select mode. This timing allows the next channel to settle before it is acquired. This automatic sequencing stops the cycle after CFR_D11 is set to '0'. Manual Channel Select Channel 2 Enable Auto Channel Select Conversion Start is Automatic or Manual Manual- or Auto-Trigger Mode Ch 2 Ch 7 Ch 3 Ch 6 Ch 4 Ch 5 Figure 39. Auto Channel Select for the ADS8332 CCLK EOC (active low) Channel # 1 CCLK Minimum N-1 N Figure 40. Channel-Number Update in Auto Channel Select Mode Timing Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 21 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com Start of a Conversion The end of acquisition is the same as the start of a conversion. This process is initiated by bringing the CONVST pin low for a minimum of 40ns. After the minimum requirement has been met, the CONVST pin can be brought high. CONVST acts independently of FS/CS so it is possible to use one common CONVST for applications that require simultaneous sample/hold with multiple converters. The ADS8331/32 switches from sample to hold mode on the falling edge of the CONVST signal. The ADS8331/32 requires 18 conversion clock (CCLK) cycles to complete a conversion. The conversion time is equivalent to 1500ns with a 12MHz internal clock. The minimum time between two consecutive CONVST signals is 21 CCLKs. A conversion can also be initiated without using CONVST if the ADS8331/32 is programmed for Auto-Trigger mode (CFR_D9 = '0'). When the converter is configured in this mode, and with CFR_D8 = '0', the next conversion is automatically started three conversion clocks (CCLK) after the end of a conversion. These three conversion clocks (CCLK) are used for the acquisition time. In this case, the time to complete one acquisition and conversion cycle is 21 CCLKs. Table 1 summarizes the different conversion modes. Table 1. Different Types of Conversion MODE Automatic SELECT CHANNEL Auto-Trigger Mode No need to write channel number to CMR. Use internal sequencer for ADS8331/32. Start a conversion based on conversion clock CCLK Manual (1) START CONVERSION Auto Channel Select (1) Manual Channel Select Manual-Trigger Mode Write channel number to CMR Start a conversion with CONVST Auto channel select should be used with Auto-Trigger mode and TAG bit output enabled. Status Output Pin (EOC/INT) The status output pin is programmable. It can be used as an EOC output (CFR_D[7:6] = '11') where the low time is equal to the conversion time. When the status pin is programmed as EOC and the polarity is set as active low, the pin works in the following manner: the EOC output goes low immediately following CONVST going low with Manual-Trigger mode enabled. EOC stays low throughout the conversion process and returns high when the conversion has ended. If Auto-Trigger mode is enabled, the EOC output remains high for three conversion clocks (CCLK) after the previous rising edge of EOC . This status pin can also be used as an interrupt output, INT (CFR_D[7:6] = '10'), which is set low at the end of a conversion, and is brought high (cleared) by the next read cycle. The polarity of this pin, whether used as EOC or INT, is programmable through the CFR_D7 bit. 22 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 Power-Down Modes and Acquisition Time There are three power-down modes that reduce power dissipation: Nap, Deep, and Auto-Nap. The first two, Nap and Deep Power-Down modes, are enabled/disabled by bits CFR_D3 and CFR_D2, respectively, in the Configuration register (see Table 5 for details). Deep Power-Down mode provides maximum power savings. When this mode is enabled, the analog core in the converter is shut down, and the analog supply current falls from 6.6mA (VA = 5.0V) to 1μA in 2μs. The wakeup time from Deep Power-Down mode is 1μs. The device can wake up from Deep Power-Down mode by either disabling this mode, issuing the wakeup command, loading the default value into the CFR, or performing a reset (either with the software reset command, CFR_D0 bit, or the external reset). See Table 4 and Table 5 along with the Reset Function section for further information. In Nap Power-Down mode, the bias currents for the analog core of the device are significantly reduced. Because the bias currents are not completely shut off, the ADS8331/32 can wake up from this power-down mode much faster than from Deep Power-Down mode. After Nap Power-Down mode is enabled, the analog supply current falls from 6.6mA (VA = 5.0V) to 0.39mA in 200ns. The wakeup time from this mode is three conversion clock cycles (CCLK). The device can wake up from Nap Power-Down mode in the same manner as waking up from Deep Power-Down mode. The third power-down mode, Auto-Nap, is enabled/disabled by bit CFR_D4 in the Configuration register (see Table 5 for details). Once this mode is enabled, the device is controlled by the digital core logic on the chip. The device is automatically placed into Nap Power-Down mode after the next end of conversion (EOC). The analog supply current falls from 6.6mA (VA = 5.0V) to 0.39mA in 200ns. A conversion start wakes up the device in three conversion clock cycles. Issuing the wake-up command, loading the default value into the CFR, disabling Auto-Nap Power-Down mode, issuing a manual channel select command, or resetting the device can wake the ADS8331/32 from Auto-Nap Power-Down mode. A comparison of the three power-down modes is listed in Table 2. Table 2. Comparison of Power-Down Modes POWER CONSUMPTION (VA = 5.0V) POWER-DOWN BY: POWER-DOWN TIME WAKEUP BY: WAKEUP TIME Normal operation 6.6mA — — — — — Deep power-down 1μA Setting CFR_D2 2μs Wakeup command 1011b 1μs Set CFR_D2 Nap power-down 0.39mA Setting CFR_D3 200ns Wakeup command 1011b 3 CCLKs Set CFR_D3 Auto-Nap power-down 0.39mA EOC (end of conversion) 200ns CONVST, any channel select command, default command 1111b, or wakeup command 1011b. 3 CCLKs Set CFR_D4 TYPE OF POWER-DOWN ENABLE The default acquisition time is three conversion clock (CCLK) cycles. Figure 41 shows the timing diagram for CONVST, EOC, and auto-nap power-down signals in Manual-Trigger mode. As shown in the diagram, the device wakes up after a conversion is triggered by the CONVST pin going low. However, a conversion is not yet started at this time. The conversion start signal to the analog core of the chip is internally generated no less than six conversion clock (CCLK) cycles later, to allow at least three CCLKs for wake up and three CCLKs for acquisition. The ADS8331/32 enters Nap Power-Down mode one conversion cycle after the end of conversion (EOC). CCLK CONVST CONVST_OUT (internal) 3 + 3 = 6 Cycles 1 Cycle NAP_ACTIVE (internal) EOC (active low) Figure 41. Timing for CONVST, EOC, and Auto-Nap Power-Down Signals in Manual-Trigger Mode (Three Conversion Clock Cycles for Acquisition) Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 23 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com The ADS8331/32 can support sampling rates of up to 500kSPS in Auto-Trigger mode. This rate is selectable by programming the CFR_D8 bit in the Configuration register. In 500kSPS mode, consecutive conversion start pulses to the analog core are generated 21 conversion clock cycles apart. In 250kSPS mode, consecutive conversion-start pulses are 42 conversion clock cycles apart. The Nap and Deep Power-Down modes are available with either sampling rate; however, Auto-Nap mode is available only with a sampling rate of 250kSPS when Auto-Trigger mode is enabled. The analog core cannot be powered down when the Auto-Nap mode sampling rate is 500kSPS because at that rate, there is no period of time when the analog core is not actively being used. Figure 42 shows the timing diagram for conversion start and auto-nap power-down signals for a 250kSPS sampling rate in Auto-Trigger mode. For a 16-bit ADC output word, consecutive new conversion start pulses are generated 2 × (18 + 3) cycles apart. NAP_ACTIVE (the signal to power down the analog core in Nap and Auto-Nap modes) goes low six (3 + 3) conversion clock cycles before the conversion start falling edge, thus powering up the analog core. It takes three conversion clock cycles after NAP_ACTIVE goes low to power up the analog core. The analog core is powered down a cycle after the end of a conversion. For a 16-bit ADC with a 500kSPS sampling rate and three conversion clock cycle sampling, consecutive conversion start pulses are generated 21 conversion clock cycles apart. 1 2 3 19 20 21 37 38 42 43 CCLK CONVST_OUT (internal) EOC (active low) NAP_ACTIVE (internal) Figure 42. Timing for Conversion Start and Auto-Nap Power-Down Signals in Auto-Trigger Mode (250kSPS Sampling and Three Conversion Clock Cycles for Acquisition) Timing diagrams for reading from the ADS8331/32 with various trigger and power-down modes are shown in Figure 43 through Figure 45. The total (acquisition + conversion) times for the different trigger and power-down modes are listed in Table 3. Table 3. Total Acquisition + Conversion Times MODE = 21 CCLK Manual-Trigger ≥ 21 CCLK Manual-Trigger with Deep Power-Down ≥ 4 SCLK + 1μs + 3 CCLK + 18 CCLK + 16 SCLK + 2μs Manual-Trigger with Nap Power-Down ≥ 4 SCLK + 3 CCLK + 3 CCLK + 18 CCLK + 16 SCLK + 200ns Manual-Trigger with Auto-Nap Power-Down 24 ACQUISITION + CONVERSION TIME Auto-Trigger at 500kSPS ≥ 4 SCLK + 3 CCLK + 3 CCLK + 18 CCLK + 1 CCLK + 200ns (using wakeup to resume) ≥ 3 CCLK + 3 CCLK + 18 CCLK + 1 CCLK + 200ns (using CONVST to resume) Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 EOS EOC EOS EOC (active low) Sample (N + 1) Conversion N tH2 Read While Converting CS EOC (N+1) N CONVST Conversion (N + 1) tSU1 Read Result (N - 1) Read While Sampling tSU2 tH1 CS Read Result N Figure 43. Read While Converting vs Read While Sampling (Manual-Trigger Mode) BLANKSPACE Wakeup Sample N Conversion N ³ 3 CCLK = 18 CCLK Read Result (N - 1) Note (2) Power-Down Wakeup Sample (N + 1) Conversion (N + 1) ³ 3 CCLK = 18 CCLK Note (2) Read Result (N - 1) Note (1) Power-Down tH2 Note (3) Note (2) Note (3) Note (2) Read Result N tSU2 Read While Sampling CS Note (1) tH2 Read While Converting CS EOS EOC EOS Converter State EOC (N+1) N CONVST Note (3) tSU2 Read Result N (1) Converter is in acquisition mode between end of conversion and activation of Nap or Deep Power-Down mode. (2) Command on SDI pin to wake up converter (minimum of four SCLKs). (3) Command on SDI pin to place converter into Nap or Deep Power-Down mode (minimum of 16 SCLKs). Note (3) Figure 44. Read While Converting vs Read While Sampling with Nap or Deep Power-Down (Manual-Trigger Mode) Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 25 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com MANUAL TRIGGER CASE 1 (Wakeup Using CONVST): tWL1 (N+1) N CONVST Converter State Wakeup Sample N Conversion N ³ 3 CCLK = 18 CCLK ³ 6 CCLK Note (1) tH2 Read While Converting Power-Down Wakeup Sample (N + 1) Conversion (N + 1) ³ 3 CCLK = 18 CCLK ³ 6 CCLK tSU1 tSU1 tSU2 Read Result N Read Result (N - 1) CS Power-Down Read Result N tSU2 Read While Sampling Note (1) tH2 Read Result (N - 1) CS EOC EOS EOS EOC EOC (active low) MANUAL TRIGGER CASE 2 (Wakeup Using Wakeup Command): tWL1 (N+1) N CONVST Converter State Wakeup Sample N Conversion N ³ 3 CCLK = 18 CCLK tH2 Read While Converting CS Power-Down Wakeup Conversion (N + 1) ³ 3 CCLK = 18 CCLK Read Result (N - 1) Note (1) tH2 Note (2) Power-Down tSU1 Read Result N tSU2 Note (2) EOC Sample (N + 1) tSU1 Read Result (N - 1) Note (2) Read While Sampling CS Note (1) EOS EOS EOC EOC (active low) tSU2 Note (2) (1) Time between end of conversion and Nap Power-Down mode is 1 CCLK. (2) Command on SDI to wake up converter (minimum of four SCLKs). Read Result N Figure 45. Read While Converting vs Read While Sampling with Auto-Nap Power-Down 26 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 DIGITAL INTERFACE The serial interface is designed to accommodate the latest high-speed processors with an SCLK frequency of up to 40MHz (VA = VBD = 5.0V). Each cycle starts with the falling edge of FS/CS. The internal data register content, which is made available to the output register at the end of conversion, is presented on the SDO output pin on the falling edge of FS/CS. The first bit is the most significant bit (MSB). The output data bits are valid on the falling edge of SCLK with the tD2 delay (see the Timing Characteristics)so that the host processor can read the data on the falling edge. Serial data input is also read on the falling edge of SCLK. The complete serial I/O cycle starts after the falling edge of FS/CS and ends 16 falling edges of SCLK later (see NOTE). The serial interface works with CPOL = '1', CPHA = '0'. This setting means the falling edge of FS/CS may fall while SCLK is high. The same timing relaxation applies to the rising edge of FS/CS where SCLK may be high or low as long as the last SCLK falling edge happens before the rising edge of FS/CS. NOTE There are cases where a cycle can be anywhere from 4 SCLKs up to 24 SCLKs, depending on the read mode combination. See Table 4 for details. Internal Register The internal register consists of two parts: four bits for the Command register (CMR) and 12 bits for the Configuration register (CFR). Table 4. Command Set Defined by Command Register (CMR) (1) (1) (2) D[15:12] HEX D[11:0] WAKE UP FROM AUTO-NAP 0000b 0h Select analog input channel 0 Don't care Y 4 W 0001b 1h Select analog input channel 1 Don't care Y 4 W 0010b 2h Select analog input channel 2 Don't care Y 4 W 0011b 3h Select analog input channel 3 Don't care Y 4 W 0100b 4h Select analog input channel 4 (2) Don't care Y 4 W 0101b 5h Select analog input channel 5 (2) Don't care Y 4 W 0110b 6h Select analog input channel 6 (2) Don't care Y 4 W 0111b 7h Select analog input channel 7 (2) Don't care Y 4 W 1000b 8h Reserved Reserved — — — 1001b 9h Reserved Reserved — — — 1010b Ah Reserved Reserved — — — 1011b Bh Wake up Don't care Y 4 W 1100b Ch Read CFR Don't care — 16 R 1101b Dh Read data Don't care — 16 R 1110b Eh Write CFR CFR Value — 16 W 1111b Fh Default mode (load CFR with default value) Don't care Y 4 W COMMAND MINIMUM SCLKs REQUIRED R/W The first four bits from SDO after the falling edge of FS/CS are the four MSBs from the previous conversion result. The next 12 bits from SDO are the contents of the CFR. These commands apply only to the ADS8332; they are reserved (not availble) for the ADS8331. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 27 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com WRITING TO THE CONVERTER There are two different types of writes to the register: a 4-bit write to the CMR and a full 16-bit write to the CMR plus CFR. The command set is listed in Table 4 and the configuration register map is listed in Table 5. A simple command requires only four SCLKs; the write takes effect on the fourth falling edge of SCLK. A 16-bit write or read takes at least 16 SCLKs (see Table 7 for exceptions that require more than 16 SCLKs). Configuring the Converter and Default Mode The converter can be configured with command 1110b (write to the CFR) or command 1111b (default mode). A write to the CFR requires a 4-bit command followed by 12 bits of data. A 4-bit command takes effect on the fourth falling edge of SCLK. A write to the CFR takes effect on the 16th falling edge of SCLK. The CFR default value for each bit is '1'. The default values are applied to the CFR after issuing command 1111b or when the device is reset with a power-on reset (POR), software reset, or external reset using the RESET pin (see the Reset Function section). READING THE CONFIGURATION REGISTER The host processor can read back the value programmed in the CFR by issuing command 1100b. The timing is similar to reading a conversion result except CONVST is not used. There is also no activity on the EOC/INT pin. The CFR value readback contains the first four bits (MSBs) of the previous conversion data plus the 12-bit CFR contents. Table 5. Configuration Register (CFR) Map CFR SDI BIT (Default = FFFh) DEFINITION BIT = '0' Channel select mode D11 28 BIT = '1' Manual channel select enabled. Use channel Auto channel select enabled. Channels are select commands to access a desired sampled and converted sequentially until the channel. cycle after this bit is set to 0. D10 Conversion clock (CCLK) source select D9 Trigger (conversion start) select: start Auto-Trigger: conversions automatically start conversion at the end of sampling (EOS). If three conversion clocks after EOC at D9 = '0' and D8 = '0', the D4 setting is 500kSPS ignored. Conversion clock (CCLK) = SCLK/2 D8 Sample rate for Auto-Trigger mode 500kSPS (21 CCLKs) 250kSPS (42 CCLKs) D7 Pin 10 polarity select when used as an output (EOC/INT) EOC/INT active high EOC/INT active low D6 Pin 10 function select when used as an output (EOC/INT) Pin used as INT Pin used as EOC D5 Pin 10 I/O select for daisy-chain mode operation Pin 10 is used as CDI input (daisy-chain mode enabled) Pin 10 is used as EOC/INT output D4 Auto-Nap Power-Down enable/disable. This bit setting is ignored if D9 = '0' and D8 ='0'. Auto-Nap Power-Down mode enabled (not activated) Auto-Nap Power-Down mode disabled D3 Nap Power-Down. This bit is set to 1 automatically by wake-up command. Nap Power-Down enabled Nap Power-Down disabled (resume normal operation) D2 Deep Power-Down. This bit is set to 1 automatically by wake-up command. Deep Power-Down enabled Deep Power-Down disabled (resume normal operation) D1 TAG bit output enable TAG bit output disabled TAG bit output enabled. TAG bits appear after conversion data D0 Software reset System reset, returns to '1' automatically Normal operation Submit Documentation Feedback Conversion clock (CCLK) = internal OSC Manual-Trigger: conversions manually start on falling edge of CONVST Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 READING THE CONVERSION RESULT The conversion result is available to the input of the output data register (ODR) at EOC and presented to the output of the output register at the next falling edge of FS/CS. The host processor can then shift the data out via the SDO pin at any time except during the quiet zone. This duration is 20ns before and 20ns after the end of sampling (EOS) period. End of sampling (EOS) is defined as the falling edge of CONVST when Manual-Trigger mode is used or the end of the third conversion clock (CCLK) after EOC if Auto-Trigger mode is used. The falling edge of FS/CS should not be placed at the precise moment at the end of a conversion (by default when EOC goes high). Otherwise, the data could be corrupt. If FS/CS is placed before the end of a conversion, the previous conversion result is read. If FS/CS is placed after the end of a conversion, the current conversion result is read. The conversion result is 16-bit data in straight binary format as shown in Table 6. Generally 16 SCLKs are necessary, but there are exceptions when more than 16 SCLKs are required (see Table 7). Data output from the serial output (SDO) is left-adjusted MSB first. The trailing bits are filled with three TAG bits first (if enabled) plus all '0's. SDO remains low until FS/CS is brought high again. SDO is active when FS/CS is low. The rising edge of FS/CS 3-states the SDO output. NOTE Whenever SDO is not in 3-state (that is, when FS/CS is low and SCLK is running), a portion of the conversion result is output at the SDO pin. The number of bits depends on how many SCLKs are supplied. For example, a manual channel select command cycle requires 4 SCLKs. Therefore, four MSBs of the conversion result are output at SDO. The exception is when SDO outputs all '1's during the cycle immediately after any reset (POR, software reset, or external reset). If SCLK is used as the conversion clock (CCLK) and a continuous SCLK is used, it is not possible to clock out all 16 bits from SDO during the sampling time (6 SCLKs) because of the quiet zone requirement. In this case, it is better to read the conversion result during the conversion time (36 SCLKs or 48 SCLKs in Auto-Nap mode). Table 6. Ideal Input Voltages and Output Codes DESCRIPTION Full-scale range Least significant bit (LSB) Full-scale Midscale Midscale – 1 LSB Zero ANALOG VALUE VREF DIGITAL OUTPUT STRAIGHT BINARY VREF/65536 BINARY CODE HEX CODE VREF – 1 LSB 1111 1111 1111 1111 FFFF VREF/2 1000 0000 0000 0000 8000 VREF/2– 1 LSB 0111 1111 1111 1111 7FFF 0V 0000 0000 0000 0000 0000 TAG Mode The ADS8331/32 includes a TAG feature that can be used to indicate which channel sourced the converted result. If TAG mode is enabled, three address bits are added after the LSB of the conversion data is read out from SDO to indicate which channel corresponds to the result. These address bits are '000' for channel 0, '001' for channel 1, '010' for channel 2, '011' for channel 3, '100' for channel 4, '101' for channel 5, '110' for channel 6, and '111' for channel 7. The converter requires at least 19 SCLKs when TAG mode is enabled in order to transfer the 16-bit conversion result and the three TAG bits. Daisy-Chain Mode The ADS8331/32 can operate as a single converter or in a system with multiple converters. System designers can take advantage of the simple, high-speed, SPI-compatible serial interface by cascading converters in a single chain when multiple converters are used. The CFR_D5 bit in the Configuration register is used to reconfigure the EOC/INT status pin as the chain data input (CDI) pin, a secondary serial data input, for the conversion result from an upstream converter. This configuration is called daisy-chain mode operation. A typical connection of three converters in daisy-chain mode is shown in Figure 46. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 29 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com MICROCONTROLLER INT CS1 CS2 CS3 SDI SCLK CONVST CS SDI SCLK CS ADS8331/32 #1 SDO EOC/INT CONVST Program Device #1: CFR_D5 = ‘1’ SDI SCLK CS ADS8331/32 #2 CDI SDO SCLK SDO SDI CONVST ADS8331/32 #3 CDI SDO Program Devices #2 and #3: CFR_D5 = ‘0’ Figure 46. Multiple Converters Connected Using Daisy-Chain Mode When multiple converters are used in daisy-chain mode, the first converter is configured in regular mode while the rest of the converters downstream are configured in daisy-chain mode. When a converter is configured in daisy-chain mode, the CDI input data go straight to the output register. Therefore, the serial input data passes through the converter with either a 16 SCLK (if the TAG feature is disabled) or 24 SCLK delay, as long as CS is active. See Figure 47 for detailed timing. In this timing diagram, the conversion in each converter is performed simultaneously. Manual Trigger, Read While Sampling (Use internal CCLK, EOC active low, and TAG mode disabled) Conversion N EOS EOC EOC #1 (active low) EOS CONVST #1 CONVST #2 CONVST #3 tSAMPLE1 = 3 CCLK min tCONV = 18 CCLK tSU2 CS #1 SCLK #1 SCLK #2 SCLK #3 SDO #1 CDI #2 1. . . . . . . . . . . . . .16 High-Z 1. . . . . . . . . . . . . .16 1. . . . . . . . . . . . . .16 High-Z Conversion N from Device #1 tSU2 CS #2 CS #3 SDO #2 CDI #3 SDO #3 SDI #1 SDI #2 SDI #3 High-Z High-Z Don't Care High-Z Conversion N from Device #2 Conversion N from Device #1 Conversion N from Device #3 Conversion N from Device #2 Conversion N from Device #1 Read Data Read Data Configure High-Z Don't Care Figure 47. Simplified Dasiy-Chain Mode Timing with Shared CONVST and Continuous CS 30 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 The multiple CS signals must be handled with care when the converters are operating in daisy-chain mode. The different chip select signals must be low for the entire data transfer (in this example, 48 bits for three conversions). The first 16-bit word after the falling chip select is always the data from the chip that received the chip select signal. Case 1: If chip select is not toggled (CS stays low), the next 16 bits of data are from the upstream converter, and so on. This configuration is shown in Figure 47. Case 2: If the chip select is toggled during a daisy-chain mode data transfer cycle, as illustrated in Figure 48, the same data from the converter are read out again and again in all three discrete 16-bit cycles. This state is not a desired result. Manual Trigger, Read While Sampling (Use internal CCLK, EOC active low, and TAG mode disabled) Conversion N EOS EOC EOC #1 (active low) EOS CONVST #1 CONVST #2 CONVST #3 tCONV = 18 CCLK tWH1 tSAMPLE1 = 3 CCLK min tWH1 tSU2 CS #1 SCLK #1 SCLK #2 SCLK #3 SDO #1 CDI #2 1. . . . . . . . . . . . . .16 High-Z Conversion N from Device #1 1. . . . . . . . . . . . . .16 High-Z tWH1 Conversion N from Device #1 1. . . . . . . . . . . . . .16 High-Z tWH1 Conversion N from Device #1 High-Z tSU2 CS #2 CS #3 SDO #2 CDI #3 SDO #3 SDI #1 SDI #2 SDI #3 High-Z High-Z Don't Care Conversion N from Device #2 Conversion N from Device #3 Configure High-Z High-Z Don't Care Conversion N from Device #2 Conversion N from Device #3 Read Data High-Z High-Z Don't Care Conversion N from Device #2 Conversion N from Device #3 Read Data High-Z High-Z Don't Care Figure 48. Simplified Daisy-Chain Mode Timing with Shared CONVST and Noncontinuous CS Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 31 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com Figure 49 shows a slightly different scenario where CONVST is not shared with the second converter. Converters #1 and #3 have the same CONVST signal. In this case, converter #2 simply passes previous conversion data downstream. Manual Trigger, Read While Sampling (Use internal CCLK, EOC active low, and TAG mode disabled) CONVST #1 CONVST #3 Conversion N EOS EOS EOC #1 (active low) EOC CONVST #2 tSAMPLE1 = 3 CCLK min tCONV = 18 CCLK tSU2 CS #1 SCLK #1 SCLK #2 SCLK #3 SDO #1 CDI #2 1. . . . . . . . . . . . . .16 High-Z 1. . . . . . . . . . . . . .16 1. . . . . . . . . . . . . .16 High-Z Conversion N from Device #1 tSU2 CS #2 CS #3 SDO #2 CDI #3 SDO #3 SDI #1 SDI #2 SDI #3 (1) High-Z High-Z High-Z Conversion (N - 1) from Device #2(1) Conversion N from Device #1 Conversion N from Device #3 Conversion (N - 1) from Device #2(1) Conversion N from Device #1 Read Data Read Data Don't Care Configure High-Z Don't Care Data from device #2 is from previous converison. Figure 49. Simplified Daisy-Chain Mode Timing with Separate CONVST and Continuous CS The number of SCLKs required for a serial read cycle depends on the combination of different read modes, TAG mode, daisy-chain mode, and the manner in which a channel is selected (for example, Auto Channel Select mode). The required number of SCLKs for different readout modes are listed in Table 7. Table 7. Required SCLKs For Different Readout Mode Combinations DAISY-CHAIN MODE CFR_D5 TAG MODE CFR_D1 NUMBER OF SCLK CYCLES PER SPI READ 1 0 16 1 1 ≥ 19 0 0 16 None 0 1 24 TAG bits plus 5 zeros 32 Submit Documentation Feedback TRAILING BITS None TAG bits plus up to 5 zeros Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 SCLK skew between converters and data path delay through the converters configured in daisy-chain mode can affect the maximum frequency of SCLK. The delay can also be affected by supply voltage and loading. It may be necessary to slow down the SCLK when the devices are configured in daisy-chain mode. Typical delays are shown in Figure 50. ADS8331/32 #3 SDO CDI Logic Delay Plus PAD 2.7ns D Logic Delay <=8.3ns Logic Delay Plus PAD 8.3ns Q CLK Serial data output ADS8331/32 #2 SDO CDI Logic D Delay <= . ns Logic Delay Plus PAD 2.7ns Logic Delay Plus PAD 8.3ns Q CLK ADS8331/32 #1 CDI Serial data input SDO Logic Delay Plus PAD 2.7ns D Logic Delay <=8.3ns CLK Q Logic Delay Plus PAD 8.3ns SCLK input Figure 50. Typical Delays Through Converters Configured in Daisy-Chain Mode RESET FUNCTION The ADS8331/32 can be reset with three different methods: internal POR, software reset, and external reset using the RESET pin. The internal POR circuit is activated when power is initially applied to the converter. This internal circuit eliminates the need for commands to be sent to the converter after power-on in order to set the default mode of operation (see the Power-On Sequence Timing section for further details). Software reset can be used to place the converter in the default mode by setting the CFR_D0 bit to '0' in the Configuration register (see Table 5). This bit is automatically returned to '1' (default) after the converter is reset. This reset method is useful in systems that cannot dedicate a separate control signal to the RESET pin. In these situations, the RESET pin must be connected to VBD in order for the ADS8331/32 to operate properly. If communication in the system becomes corrupted and a software reset cannot be issued, the RESET pin can be used to reset the device manually. In order to reset the device and return the device to default mode, this pin must held low for a minimum of 25ns. After the ADS8331/32 detects a reset condition, the minimum time before the device can be reconfigured by FS/CS going low and data clocking in on SDI is 2μs. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 33 ADS8331 ADS8332 SBAS363 – DECEMBER 2009 www.ti.com APPLICATION INFORMATION TYPICAL CONFIGURATION EXAMPLE Figure 51 illustrates a typical circuit configuration using the ADS8331/32. Analog +5V 4.7mF AGND External Reference Input 22mF Analog Input AGND VA REF+ REF- AGND MUXOUT ADCIN INX COM Interface Supply +1.8V FS/CS SDO SDI SCLK 4.7mF DGND Host Processor ADS8331/32 CONVST VBD EOC/INT Figure 51. Typical Circuit Configuration POWER-ON SEQUENCE TIMING During power-on of the ADS8331/32, the digital interface supply voltage (VBD) should not exceed the analog supply voltage (VA). This condition is specified in the Power-Supply Requirements section of the Electrical Characteristics tables. If the analog and digital interface supplies for the converter are not generated by a single voltage source, it is recommended to power-on the analog supply and wait for it to reach its final value before the digital interface supply is activated. Furthermore, the voltages applied to the analog input pins (INX, ADCIN) and digital input pins (RESET, FS/CS, SCLK, SDI, and CONVST) should not exceed the voltages on VA and VBD, respectively, during the power-on sequence. This requirement prevents these input pins from powering the ADS8331/32 through the ESD protection diodes/circuitry and causing a latch-up condition (see the Electrical Characteristic tables and Figure 34 for further details). Communication with the ADS8331/32, such as initiating a conversion with CONVST or writing to the Configuration register, should not occur for a minimum of 2μs after the analog and digital interface supplies have finished the power-on sequence and reached the respective final values in the system. This time is required for the internal POR to activate and place the digital core of the device into the default mode of operation. This minimum delay time must also be adhered to whenever a reset condition occurs (see the Reset Function section for additional information). 34 Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 ADS8331 ADS8332 www.ti.com SBAS363 – DECEMBER 2009 LAYOUT For optimum performance, care should be taken with the physical layout of the ADS8331/32 circuitry. This consideration is particularly true if the reference voltage is low and/or the conversion rate is high. With a conversion clock of 12MHz, the ADS8331/32 makes a bit decision every 83ns. That is, for each subsequent bit decision, the capacitor array must be switched and charged, and the input to the comparator settled to a 16-bit level, all within one conversion clock cycle. The basic SAR architecture is sensitive to spikes on the power supply, reference, and ground connections that occur just prior to latching the comparator output. Thus, during any single conversion for an n-bit SAR converter, there are n windows in which large external transient voltages can easily affect the conversion result. Such spikes might originate from switching power supplies, digital logic, and high-power devices, to name a few potential sources. This particular source of error can be very difficult to track down if the glitch is almost synchronous to the converter CCLK signal because the phase difference between the two changes with time and temperature, causing sporadic misoperation. With this possibility in mind, power to the ADS8331/32 should be clean and well-bypassed. A 0.1μF ceramic bypass capacitor should be placed as close as possible to the ADS8331/32 package. In addition, a 1μF to 10μF capacitor and a 5Ω or 10Ω series resistor may be used to low-pass filter a noisy supply. The reference should be similarly bypassed with a 22μF capacitor. Again, a series resistor and large capacitor can be used to low-pass filter the reference voltage. If the reference voltage originates from an op amp, make sure that the op amp can drive the bypass capacitor without oscillation (the series resistor can help in this case). Although the ADS8331/32 draws very little current from the reference on average, there can still be instantaneous current demands placed on the external input and reference circuitry. The OPA365 or OPA211 from Texas Instrumets provide optimum performance for buffering the signal inputs; the OPA350 can be used to effectively buffer the reference input. Also, keep in mind that the ADS8331/32 offers no inherent rejection of noise or voltage variation in regards to the reference input. This consideration is of particular concern when the reference input is tied to the power supply. Any noise and ripple from the supply will appear directly in the digital results. While high-frequency noise can be filtered, voltage variation resulting from the line frequency (50Hz or 60Hz) can be difficult to remove. The AGND pin on the ADS8331/32 should be placed on a clean ground point. In many cases, this location is the analog ground. Avoid connecting the AGND pin too close to the grounding point for a microprocessor, microcontroller, or digital signal processor. If needed, run a ground trace directly from the converter to the power-supply connection point. The ideal layout includes an analog ground plane for the converter and associated analog circuitry. Submit Documentation Feedback Copyright © 2009, Texas Instruments Incorporated Product Folder Link(s): ADS8331 ADS8332 35 PACKAGE OPTION ADDENDUM www.ti.com 27-Feb-2010 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty ADS8331IBRGER ACTIVE VQFN RGE 24 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8331IBRGET ACTIVE VQFN RGE 24 250 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8331IRGER ACTIVE VQFN RGE 24 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8331IRGET ACTIVE VQFN RGE 24 250 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8332IBRGER ACTIVE VQFN RGE 24 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8332IBRGET ACTIVE VQFN RGE 24 250 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8332IRGER ACTIVE VQFN RGE 24 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR ADS8332IRGET ACTIVE VQFN RGE 24 250 CU NIPDAU Level-2-260C-1 YEAR Green (RoHS & no Sb/Br) Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. 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