ADS8320 ® 16-Bit, High-Speed, 2.7V to 5V Micro Power Sampling ANALOG-TO-DIGITAL CONVERTER FEATURES DESCRIPTION ● 100kHz SAMPLING RATE The ADS8320 is a 16-bit sampling analog-to-digital converter with guaranteed specifications over a 2.7V to 5.25V supply range. It requires very little power even when operating at the full 100kHz data rate. At lower data rates, the high speed of the device enables it to spend most of its time in the power-down mode— the average power dissipation is less than 100µW at 10kHz data rate. ● MICRO POWER: 1.8mW at 100kHz and 2.7V 0.3mW at 10kHz and 2.7V ● POWER DOWN: 3µA max ● 8-LEAD MSOP PACKAGE ● PIN-COMPATIBLE TO ADS7816 AND ADS7822 The ADS8320 also features operation from 2.0V to 5.25V, a synchronous serial (SPI/SSI compatible) interface, and a differential input. The reference voltage can be set to any level within the range of 500mV to VCC. Ultra-low power and small size make the ADS8320 ideal for portable and battery-operated systems. It is also a perfect fit for remote data acquisition modules, simultaneous multi-channel systems, and isolated data acquisition. The ADS8320 is available in an 8-lead MSOP package. ● SERIAL (SPI/SSI) INTERFACE APPLICATIONS ● BATTERY OPERATED SYSTEMS ● REMOTE DATA ACQUISITION ● ISOLATED DATA ACQUISITION ● SIMULTANEOUS SAMPLING, MULTI-CHANNEL SYSTEMS ● INDUSTRIAL CONTROLS ● ROBOTICS ● VIBRATION ANALYSIS Control SAR VREF DOUT +In Serial Interface CDAC –In S/H Amp Comparator DCLOCK CS/SHDN International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 Twx: 910-952-1111 • Internet: http://www.burr-brown.com/ • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132 © 1999 Burr-Brown Corporation PDS-1504B Printed in U.S.A. September, 1999 SPECIFICATIONS: +VCC = +5V At –40°C to +85°C, VREF = +5V,–IN = GND, fSAMPLE = 100kHz, and fCLK = 24 • fSAMPLE, unless otherwise specified. ADS8320E PARAMETER CONDITIONS MIN TYP ADS8320EB MAX RESOLUTION MIN TYP 16 ANALOG INPUT Full-Scale Input Span Absolute Input Range +In – (–In) +In –In 0 –0.1 –0.1 Capacitance Leakage Current VREF VCC + 0.1 +1.0 ✻ ✻ ✻ 14 DYNAMIC CHARACTERISTICS Total Harmonic Distortion SINAD Spurious Free Dynamic Range SNR REFERENCE INPUT Voltage Range Resistance VCC ✻ 80 3 ✻ ✻ ✻ CS = VCC TEMPERATURE RANGE Specified Performance –40 ✻ ✻ ✻ ✻ 0.4 V GΩ GΩ µA µA µA V V V V ✻ Straight Binary 900 200 4.5 0.3 Clk Cycles Clk Cycles kHz MHz ✻ VCC + 0.3 0.8 4.75 2.0 Bits % of FSR mV µV/°C % ppm/°C µVrms LSB(1) dB dB dB dB ✻ ✻ ✻ ✻ ✻ ✻ CMOS 3.0 –0.3 4.0 ✻ ✻ ✻ –86 84 86 92 5 5 40 0.8 0.1 fSAMPLE = 10kHz(3, 4) Power Dissipation Power Down 100 2.9 0.5 Specified Performance ±0.012 ±1 ✻ –84 82 84 90 IIH = +5µA IIL = +5µA IOH = –250µA IOL = 250µA V V V pF nA ✻ 0.024 CS = GND, fSAMPLE = 0Hz CS = VCC ✻ ✻ ✻ ±0.024 16 VIN = 5Vp-p at 10kHz VIN = 5Vp-p at 10kHz VIN = 5Vp-p at 10kHz Bits ✻ ✻ ✻ 4.5 fSAMPLE = 10kHz CS = VCC POWER SUPPLY REQUIREMENTS VCC VCC Range(2) Quiescent Current ±0.006 ±0.5 ✻ ±0.05 Current Drain DIGITAL INPUT/OUTPUT Logic Family Logic Levels: VIH VIL VOH VOL Data Format ±0.018 ±2 ±0.3 20 3 +4.7V < VCC < 5.25V ✻ 15 ±0.008 ±1 ±3 SAMPLING DYNAMICS Conversion Time Acquisition Time Throughput Rate Clock Frequency Range UNITS ✻ ✻ 45 1 SYSTEM PERFORMANCE No Missing Codes Integral Linearity Error Offset Error Offset Temperature Drift Gain Error Gain Temperature Drift Noise Power Supply Rejection Ratio MAX 5.25 5.25 1700 ✻ ✻ ✻ ✻ ✻ ✻ 8.5 3 +85 ✻ ✻ ✻ ✻ ✻ ✻ V V µA µA mW µA ✻ °C ✻ Specifications same as grade to the left. NOTES: (1) LSB means Least Significant Bit. (2) See Typical Performance Curves for more information. (3) f CLK = 2.4MHz, CS = VCC for 216 clock cycles out of every 240. (4) See the Power Dissipation section for more information regarding lower sample rates. The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant any BURR-BROWN product for use in life support devices and/or systems. ® ADS8320 2 SPECIFICATIONS: +VCC = +2.7V At –40°C to +85°C, VREF = 2.5V, –IN = GND, fSAMPLE = 100kHz, and fCLK = 24 • fSAMPLE, unless otherwise specified. ADS8320E PARAMETER CONDITIONS MIN TYP ADS8320EB MAX RESOLUTION ANALOG INPUT Full-Scale Input Span Absolute Input Range +In – (–In) +In –In 0 –0.1 –0.1 REFERENCE INPUT Voltage Range Resistance ±0.018 ±2 ±0.006 ±0.5 ✻ ±0.05 ±0.3 20 3 +2.7V < VCC < +3.3V ✻ ✻ ✻ 100 2.4 VCC 5 5 20 0.1 ✻ 2.0 –0.3 2.1 50 3 VCC + 0.3 0.8 ✻ ✻ ✻ 2.7 2.0 2.0 650 100 1.8 0.3 CS = VCC TEMPERATURE RANGE Specified Performance –40 Clk Cycles Clk Cycles kHz MHz dB dB dB dB ✻ ✻ ✻ ✻ ✻ 0.4 fSAMPLE = 10kHz(4,5) Bits % of FSR mV µV/°C ±0.024 % of FSR ppm/°C µVrms LSB(1) ±0.012 ±1 V GΩ GΩ µA µA ✻ V V V V ✻ Straight Binary See Note 2 V V V pF nA ✻ ✻ ✻ ✻ ✻ CMOS Specified Performance ✻ ✻ ✻ –88 86 88 90 0.5 IIH = +5µA IIL = +5µA IOH = –250µA IOL = 250µA Bits ✻ ✻ ✻ –86 84 86 88 CS = GND, fSAMPLE = 0Hz CS = VCC ✻ ✻ 0.024 VIN = 2.7Vp-p at 1kHz VIN = 2.7Vp-p at 1kHz VIN = 2.7Vp-p at 1kHz UNITS ✻ 16 4.5 Quiescent Current Power Dissipation Power Down 15 ±0.008 ±1 ±3 CS = VCC POWER SUPPLY REQUIREMENTS VCC VCC Range(3) ✻ ✻ ✻ MAX ✻ ✻ 14 Current Drain DIGITAL INPUT/OUTPUT Logic Family Logic Levels: VIH VIL VOH VOL Data Format VREF VCC + 0.1 +0.5 45 1 SAMPLING DYNAMICS Conversion Time Acquisition Time Throughput Rate Clock Frequency Range DYNAMIC CHARACTERISTICS Total Harmonic Distortion SINAD Spurious Free Dynamic Range SNR TYP 16 Capacitance Leakage Current SYSTEM PERFORMANCE No Missing Codes Integral Linearity Error Offset Error Offset Temperature Drift Gain Error Gain Temperature Drift Noise Power Supply Rejection Ratio MIN 3.3 5.25 2.7 1300 ✻ ✻ ✻ ✻ ✻ ✻ ✻ 3.8 3 +85 ✻ ✻ ✻ ✻ ✻ ✻ ✻ V V V µA µA mW µA ✻ °C ✻ Specifications same as grade to the left. Notes: (1) LSB means Least Significant Bit. With VREF equal to +5V, one LSB is 0.039mV. (2) The maximum clock rate of the ADS8320 is less than 2.4MHz in this power supply range. (3) See the Typical Performance Curves for more information. (4) f CLK = 2.4MHz, CS = VCC for 216 clock cycles out of every 240. (5) See the Power Dissipation section for more information regarding lower sample rates. ® 3 ADS8320 ELECTROSTATIC DISCHARGE SENSITIVITY PIN CONFIGURATION Top View MSOP VREF 1 +In 2 8 +VCC 7 DCLOCK Electrostatic discharge can cause damage ranging from performance degradation to complete device failure. BurrBrown Corporation recommends that all integrated circuits be handled and stored using appropriate ESD protection methods. ADS8320 –In 3 6 DOUT GND 4 5 CS/SHDN ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet published specifications. PIN ASSIGNMENTS PIN NAME 1 VREF DESCRIPTION 2 +In Non Inverting Input. 3 –In Inverting Input. Connect to ground or to remote ground sense point. ABSOLUTE MAXIMUM RATINGS(1) Reference Input. 4 GND 5 CS/SHDN Chip Select when LOW, Shutdown Mode when HIGH. 6 DOUT The serial output data word is comprised of 16 bits of data. In operation the data is valid on the falling edge of DCLOCK. The second clock pulse after the falling edge of CS enables the serial output. After one null bit the data is valid for the next 16 edges. 7 DCLOCK Data Clock synchronizes the serial data transfer and determines conversion speed. 8 +VCC VCC ....................................................................................................... +6V Analog Input .............................................................. –0.3V to (VCC + 0.3V) Logic Input ............................................................................... –0.3V to 6V Case Temperature ......................................................................... +100°C Junction Temperature .................................................................... +150°C Storage Temperature ..................................................................... +125°C External Reference Voltage .............................................................. +5.5V Ground. NOTE: (1) Stresses above these ratings may permanently damage the device. Power Supply. PACKAGE/ORDERING INFORMATION PRODUCT MAXIMUM INTEGRAL LINEARITY ERROR (LSB) NO MISSING CODES ERROR (LSB) ADS8320E PACKAGE PACKAGE DRAWING NUMBER(1) SPECIFICATION TEMPERATURE RANGE 0.018% 14 MSOP 337 –40°C to +85°C " " " " " " ADS8320EB 0.012% 15 MSOP 337 –40°C to +85°C " " " " " " ORDERING NUMBER TRANSPORT MEDIA ADS8320E/250 ADS8320E/2K5 ADS8320EB/250 ADS8320EB/2K5 Tape and Reel Tape and Reel Tape and Reel Tape and Reel NOTES: (1) For detailed drawing and dimension table, please see end of data sheet, or Appendix C of Burr-Brown IC Data Book. (2) Models with a slash (/) are available only in Tape and Reel in the quantities indicated (e.g., /2K5 indicates 2500 devices per reel). Ordering 2500 pieces of “ADS8320EB/2K5” will get a single 2500-piece Tape and Reel. For detailed Tape and Reel mechanical information, refer to Appendix B of Burr-Brown IC Data Book. ® ADS8320 4 TYPICAL PERFORMANCE CURVES At TA = +25°C, VCC = +5V, VREF = +5V, fSAMPLE = 100kHz, fCLK = 24 • fSAMPLE, unless otherwise specified. INTEGRAL LINEARITY ERROR vs CODE (+25°C) DIFFERENTIAL LINEARITY ERROR vs CODE (+25°C) 3.0 1.0 Differential Linearity Error (LSB) Integral Linearity Error (LSB) 20 0.0 –1.0 –2.0 –3.0 –4.0 –5.0 –6.0 0000H 1.0 0.0 –1.0 –2.0 –3.0 0000H Hex Code 8000H Hex Code SUPPLY CURRENT vs TEMPERATURE POWER DOWN SUPPLY CURRENT vs TEMPERATURE 4000H 8000H C000H FFFFH 1200 4000H FFFFH 500 Supply Current (nA) 5V 800 2.7V 600 400 200 400 5V 300 200 100 0 0 –50 –25 0 25 50 75 100 –50 –25 0 Temperature (°C) 25 50 75 100 Temperature (°C) QUIESCENT CURRENT vs VCC MAXIMUM SAMPLE RATE vs VCC 1200 1000 1000 Sample Rate (kHz) Quiescent Current (µA) C000H 600 1000 Supply Current (µA) 2.0 800 600 100 10 400 200 1 1 2 3 4 5 1 VCC (V) 2 3 VCC (V) 4 5 ® 5 ADS8320 TYPICAL PERFORMANCE CURVES (CONT) At TA = +25°C, VCC = +2.7V, VREF = +2.5V, fSAMPLE = 100kHz, fCLK = 24 • fSAMPLE, unless otherwise specified. CHANGE IN OFFSET vs TEMPERATURE CHANGE IN OFFSET vs REFERENCE VOLTAGE 6 3 VCC = 5V 4 2 Delta from 25°C (LSB) Change in Offset (LSB) 5 3 2 1 0 –1 5V 1 2.7V 0 –1 –2 –2 –3 –3 1 2 3 Reference Voltage (V) 4 –50 5 CHANGE IN GAIN vs REFERENCE VOLTAGE –25 0 25 50 Temperature (°C) 75 100 CHANGE IN GAIN vs TEMPERATURE 5 6 VCC = 5V 4 Delta from 25°C (LSB) Change in Gain (LSB) 4 3 2 1 0 2 0 5V –2 –6 –2 1 2 3 Reference Voltage (V) 4 –50 5 –25 0 25 50 75 100 Temperature (°C) FREQUENCY SPECTRUM (8192 Point FFT, FIN = 10.120kHz, –0.3dB) 0 PEAK-TO-PEAK NOISE vs REFERENCE VOLTAGE 10 VCC = 5V 9 Peak-to-Peak Noise (LSB) –20 –40 Amplitude (dB) 2.7V –4 –1 –60 –80 –100 –120 8 7 6 5 4 3 2 1 –140 0 0 10 20 30 Frequency (kHz) 40 50 0.1 ® ADS8320 6 1 Reference Voltage (V) 10 TYPICAL PERFORMANCE CURVES (CONT) At TA = +25°C, VCC = +5V, VREF = +5V, fSAMPLE = 100kHz, fCLK = 24 • fSAMPLE, unless otherwise specified. SPURIOUS FREE DYNAMIC RANGE AND SIGNAL-TO-NOISE RATIO vs FREQUENCY TOTAL HARMONIC DISTORTION vs FREQUENCY 0 Signal-to-Noise Ratio 90 80 Spurious Free Dynamic Range 70 –10 Total Harmonic Distortion (dB) Spurious Free Dynamic Range and Signal-to-Noise Ratio (dB) 100 60 50 40 30 20 –20 –30 –40 –50 –60 –70 –80 10 –90 0 –100 1 10 50 100 1 10 Frequency (kHz) Frequency (kHz) SIGNAL-TO-(NOISE + DISTORTION) vs FREQUENCY SIGNAL-TO-(NOISE + DISTORTION) vs INPUT LEVEL 90 Signal-to-(Noise + Distortion) (dB) Signal-to-(Noise + Distortion) (dB) 100 90 80 70 60 50 40 30 20 10 1 10 Frequency (kHz) 50 80 70 60 50 40 30 20 –40 0 100 70 60 60 Reference Current (µA) 70 50 40 5V 30 20 –35 –30 –25 –20 –15 Input Level (dB) –10 –5 0 REFERENCE CURRENT vs TEMPERATURE REFERENCE CURRENT vs SAMPLE RATE Reference Current (µA) 100 2.7V 50 5V 40 30 2.7V 20 10 10 –50 0 0 20 40 60 Sample Rate (kHz) 80 100 –25 0 25 50 75 100 Temperature (°C) ® 7 ADS8320 THEORY OF OPERATION riod. 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 input capacitance (45pF) to a 16-bit settling level within 4.5 clock cycles. When the converter goes into the hold mode or while it is in the powerdown mode, the input impedance is greater than 1GΩ. The ADS8320 is a classic Successive Approximation Register (SAR) analog-to-digital (A/D) converter. The architecture is based on capacitive redistribution which inherently includes a sample/hold function. The converter is fabricated on a 0.6µ CMOS process. The architecture and process allow the ADS8320 to acquire and convert an analog signal at up to 100,000 conversions per second while consuming less than 4.5mW from +VCC. The ADS8320 requires an external reference, an external clock, and a single power source (VCC). The external reference can be any voltage between 500mV and VCC. The value of the reference voltage directly sets the range of the analog input. The reference input current depends on the conversion rate of the ADS8320. Care must be taken regarding the absolute analog input voltage. To maintain the linearity of the converter, the –In input should not drop below GND – 100mV or exceed GND + 1V. The +In input should always remain within the range of GND – 100mV to VCC + 100mV. Outside of these ranges, the converter’s linearity may not meet specifications. To minimize noise, low bandwidth input signals with lowpass filters should be used. REFERENCE INPUT The external clock can vary between 24kHz (1kHz throughput) and 2.4MHz (100kHz throughput). The duty cycle of the clock is essentially unimportant as long as the minimum high and low times are at least 200ns (VCC = 2.7V or greater). The minimum clock frequency is set by the leakage on the capacitors internal to the ADS8320. The analog input is provided to two input pins: +In and –In. 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 inputs are disconnected from any internal function. The external reference sets the analog input range. The ADS8320 will operate with a reference in the range of 500mV to VCC. There are several important implications of this. As the reference voltage is reduced, the analog voltage weight of each digital output code is reduced. This is often referred to as the Least Significant Bit (LSB) size and is equal to the reference voltage divided by 65,536. This means that any offset or gain error inherent in the A/D converter will appear to increase, in terms of LSB size, as the reference voltage is reduced. The digital result of the conversion is clocked out by the DCLOCK input and is provided serially, most significant bit first, on the DOUT pin. The digital data that is provided on the DOUT pin is for the conversion currently in progress—there is no pipeline delay. It is possible to continue to clock the ADS8320 after the conversion is complete and to obtain the serial data least significant bit first. See the digital timing section for more information. The noise inherent in the converter will also appear to increase with lower LSB size. With a +5V reference, the internal noise of the converter typically contributes only 1.5 LSB peak-to-peak of potential error to the output code. When the external reference is 500mV, the potential error contribution from the internal noise will be 10 times larger— 15 LSBs. The errors due to the internal noise are gaussian in nature and can be reduced by averaging consecutive conversion results. For more information regarding noise, consult the typical performance curve “Peak-to-Peak Noise vs Reference Voltage.” Note that the Effective Number of Bits (ENOB) figure is calculated based on the converter’s signal-to-(noise + distortion) ratio with a 1kHz, 0dB input signal. SINAD is related to ENOB as follows: ANALOG INPUT The +In and –In input pins allow for a differential input signal. Unlike some converters of this type, the –In input is not re-sampled later in the conversion cycle. When the converter goes into the hold mode, the voltage difference between +In and –In is captured on the internal capacitor array. The range of the –In input is limited to –0.1V to +1V (–0.1V to +0.5V when using a 2.7V supply). Because of this, the differential input can be used to reject only small signals that are common to both inputs. Thus, the –In input is best used to sense a remote signal ground that may move slightly with respect to the local ground potential. SINAD = 6.02 • ENOB + 1.76 With lower reference voltages, extra care should be taken to provide a clean layout including adequate bypassing, a clean power supply, a low-noise reference, and a low-noise input signal. Because the LSB size is lower, the converter will also be more sensitive to external sources of error such as nearby digital signals and electromagnetic interference. The input current on the analog inputs depends on a number of factors: sample rate, input voltage, source impedance, and power-down mode. Essentially, the current into the ADS8320 charges the internal capacitor array during the sample pe- ® ADS8320 8 NOISE converter will vary in output code due to the internal noise of the ADS8320. This is true for all 16-bit SAR-type A/D converters. Using a histogram to plot the output codes, the distribution should appear bell-shaped with the peak of the bell curve representing the nominal code for the input value. The ±1σ, ±2σ, and ±3σ distributions will represent the 68.3%, 95.5%, and 99.7%, respectively, of all codes. The transition noise can be calculated by dividing the number of codes measured by 6 and this will yield the ±3σ distribution or 99.7% of all codes. Statistically, up to 3 codes could fall outside the distribution when executing 1000 conversions. The ADS8320, with < 3 output codes for the ±3σ distribution, will yield a < ±0.5LSB transition noise. Remember, to achieve this low noise performance, the peak-to-peak noise of the input signal and reference must be < 50µV. The noise floor of the ADS8320 itself is extremely low, as can be seen from Figures 1 and 2, and is much lower than competing A/D converters. It was tested by applying a low noise DC input and a 5.0V reference to the ADS8320 and initiating 5000 conversions. The digital output of the A/D 2510 2490 AVERAGING 0 0 1 2 3 4 0 0 5 6 The noise of the A/D converter can be compensated by averaging the digital codes. By averaging conversion results, transition noise will be reduced by a factor of 1/√n, where n is the number of averages. For example, averaging 4 conversion results will reduce the transition noise by 1/2 to ±0.25 LSBs. Averaging should only be used for input signals with frequencies near DC. For AC signals, a digital filter can be used to low pass filter and decimate the output codes. This works in a similar manner to averaging; for every decimation by 2, the signalto-noise ratio will improve 3dB. Code FIGURE 1. Histogram of 5000 Conversions of a DC Input at the Code Transition. 4864 DIGITAL INTERFACE SIGNAL LEVELS The digital inputs of the ADS8320 can accommodate logic levels up to 5.5V regardless of the value of VCC. Thus, the ADS8320 can be powered at 3V and still accept inputs from logic powered at 5V. 0 0 72 1 2 3 4 64 0 5 6 The CMOS digital output (DOUT) will swing 0V to VCC. If VCC is 3V and this output is connected to a 5V CMOS logic input, then that IC may require more supply current than normal and may have a slightly longer propagation delay. Code FIGURE 2. Histogram of 5000 Conversions of a DC Input at the Code Center. ® 9 ADS8320 SERIAL INTERFACE DATA FORMAT The ADS8320 communicates with microprocessors and other digital systems via a synchronous 3-wire serial interface as shown in Figure 3 and Table I. The DCLOCK signal synchronizes the data transfer with each bit being transmitted on the falling edge of DCLOCK. Most receiving systems will capture the bitstream on the rising edge of DCLOCK. However, if the minimum hold time for DOUT is acceptable, the system can use the falling edge of DCLOCK to capture each bit. A falling CS signal initiates the conversion and data transfer. The first 4.5 to 5.0 clock periods of the conversion cycle are used to sample the input signal. After the fifth falling DCLOCK edge, DOUT is enabled and will output a LOW value for one clock period. For the next 16 DCLOCK periods, DOUT will output the conversion result, most significant bit first. After the least significant bit (B0) has been output, subsequent clocks will repeat the output data but in a least significant bit first format. The output data from the ADS8320 is in Straight Binary format as shown in Table II. This table represents the ideal output code for the given input voltage and does not include the effects of offset, gain error, or noise. DESCRIPTION DESCRIPTION MIN TYP MAX UNITS t SMPL Analog Input Sample Time 4.5 t CONV Conversion Time 5.0 Clk Cycles t CYC Throughput Rate 100 kHz t CSD CS Falling to DCLOCK LOW 0 ns t SUCS CS Falling to DCLOCK Rising 20 t hDO DCLOCK Falling to Current DOUT Not Valid 5 t dDO DCLOCK Falling to Next DOUT Valid t dis t en 16 CS Rising to DOUT Tri-State 70 100 ns DCLOCK Falling to DOUT Enabled 20 50 ns tf DOUT Fall Time 5 25 ns tr DOUT Rise Time 7 25 ns Full Scale Midscale 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 POWER DISSIPATION The architecture of the converter, the semiconductor fabrication process, and a careful design allow the ADS8320 to convert at up to a 100kHz rate while requiring very little power. Still, for the absolute lowest power dissipation, there are several things to keep in mind. The power dissipation of the ADS8320 scales directly with conversion rate. Therefore, the first step to achieving the lowest power dissipation is to find the lowest conversion rate that will satisfy the requirements of the system. In addition, the ADS8320 is in power down mode under two conditions: when the conversion is complete and whenever CS is HIGH (see Figure 3). Ideally, each conversion should occur as quickly as possible, preferably at a 2.4MHz clock rate. This way, the converter spends the longest possible time in the power-down mode. This is very important as the converter not only uses power on each DCLOCK transition (as is typical for digital CMOS components) but also uses some current for the analog circuitry, such as the comparator. The analog section dissipates power continuously, until the power down mode is entered. ns 50 VREF/65,536 DIGITAL OUTPUT STRAIGHT BINARY TABLE II. Ideal Input Voltages and Output Codes. ns 30 Least Significant Bit (LSB) Zero Clk Cycles 15 VREF Midscale – 1LSB After the most significant bit (B15) has been repeated, DOUT will tri-state. Subsequent clocks will have no effect on the converter. A new conversion is initiated only when CS has been taken HIGH and returned LOW. SYMBOL ANALOG VALUE Full Scale Range ns TABLE I. Timing Specifications (VCC = 2.7V and above, –40°C to +85°C. Complete Cycle CS/SHDN tSUCS Sample Power Down Conversion DCLOCK tCSD DOUT Use positive clock edge for data transfer Hi-Z 0 tSMPL B15 B14 B13 B12 B11 B10 B9 B8 (MSB) tCONV B7 B6 B5 B4 B3 B2 B1 B0 (LSB) NOTE: Minimum 22 clock cycles required for 16-bit conversion. Shown are 24 clock cycles. If CS remains LOW at the end of conversion, a new datastream with LSB-first is shifted out again. FIGURE 3. ADS8320 Basic Timing Diagrams. ® ADS8320 10 Hi-Z 1.4V 3kΩ DOUT VOH DOUT VOL Test Point tr 100pF CLOAD tf Voltage Waveforms for DOUT Rise and Fall Times, tr, tf Load Circuit for tdDO, tr, and tf Test Point DCLOCK VIL VCC DOUT tdDO VOH DOUT tdis Waveform 2, ten 3kΩ tdis Waveform 1 100pF CLOAD VOL thDO Load Circuit for tdis and ten Voltage Waveforms for DOUT Delay Times, tdDO VIH CS/SHDN DOUT Waveform 1(1) CS/SHDN DCLOCK 90% 1 4 5 tdis DOUT Waveform 2(2) VOL DOUT 10% B11 ten Voltage Waveforms for tdis Voltage Waveforms for ten NOTES: (1) Waveform 1 is for an output with internal conditions such that the output is HIGH unless disabled by the output control. (2) Waveform 2 is for an output with internal conditions such that the output is LOW unless disabled by the output control. FIGURE 4. Timing Diagrams and Test Circuits for the Parameters in Table I. ® 11 ADS8320 Figure 5 shows the current consumption of the ADS8320 versus sample rate. For this graph, the converter is clocked at 2.4MHz regardless of the sample rate—CS is HIGH for the remaining sample period. Figure 6 also shows current consumption versus sample rate. However, in this case, the DCLOCK period is 1/24th of the sample period—CS is HIGH for one DCLOCK cycle out of every 16. 1000 Supply Current (µA) TA = 25°C fCLK = 2.4MHz 100 VCC = 5.0V VREF = 5.0V VCC = 2.7V VREF = 2.5V There is an important distinction between the power-down mode that is entered after a conversion is complete and the full power-down mode which is enabled when CS is HIGH. CS LOW will shut down only the analog section. The digital section is completely shutdown only when CS is HIGH. Thus, if CS is left LOW at the end of a conversion and the converter is continually clocked, the power consumption will not be as low as when CS is HIGH. See Figure 7 for more information. Power dissipation can also be reduced by lowering the power supply voltage and the reference voltage. The ADS8320 will operate over a VCC range of 2.0V to 5.25V. However, at voltages below 2.7V, the converter will not run at a 100kHz sample rate. See the typical performance curves for more information regarding power supply voltage and maximum sample rate. 10 1 0.1 1 10 100 Sample Rate (kHz) FIGURE 5. Maintaining fCLK at the Highest Possible Rate Allows Supply Current to Drop Linearly with Sample Rate. Supply Current (µA) 1000 100 10 SHORT CYCLING Another way of saving power is to utilize the CS signal to short cycle the conversion. Because the ADS8320 places the latest data bit on the DOUT line as it is generated, the converter can easily be short cycled. This term means that the conversion can be terminated at any time. For example, if only 14 bits of the conversion result are needed, then the conversion can be terminated (by pulling CS HIGH) after the 14th bit has been clocked out. TA = 25°C VCC = 5.0V VREF = 5.0V fCLK = 24 • fSAMPLE 1 0.1 1 10 100 Sample Rate (kHz) This technique can be used to lower the power dissipation (or to increase the conversion rate) in those applications where an analog signal is being monitored until some condition becomes true. For example, if the signal is outside a predetermined range, the full 16-bit conversion result may not be needed. If so, the conversion can be terminated after the first n bits, where n might be as low as 3 or 4. This results in lower power dissipation in both the converter and the rest of the system, as they spend more time in the power-down mode. FIGURE 6. Scaling fCLK Reduces Supply Current Only Slightly with Sample Rate. 1000 TA = 25°C VCC = 5.0V VREF = 5.0V fCLK = 24 • fSAMPLE Supply Current (µA) 800 600 CS LOW (GND) 400 LAYOUT 200 For optimum performance, care should be taken with the physical layout of the ADS8320 circuitry. This will be particularly true if the reference voltage is low and/or the conversion rate is high. At a 100kHz conversion rate, the ADS8320 makes a bit decision every 416ns. That is, for each subsequent bit decision, the digital output must be updated with the results of the last bit decision, the capacitor array appropriately switched and charged, and the input to the comparator settled to a 16-bit level all within one clock cycle. 0.0 CS HIGH (VCC) 0.250 0.00 0.1 1 10 100 Sample Rate (kHz) FIGURE 7. Shutdown Current with CS HIGH is 50nA Typically, Regardless of the Clock. Shutdown Current with CS LOW Varies with Sample Rate. ® ADS8320 12 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. This particular source of error can be very difficult to track down if the glitch is almost synchronous to the converter’s DCLOCK signal—as the phase difference between the two changes with time and temperature, causing sporadic misoperation. Also, keep in mind that the ADS8320 offers no inherent rejection of noise or voltage variation in regards to the reference input. This 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 out as described in the previous paragraph, voltage variation due to the line frequency (50Hz or 60Hz), can be difficult to remove. The GND pin on the ADS8320 should be placed on a clean ground point. In many cases, this will be the “analog” ground. Avoid connecting the GND 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 will include an analog ground plane for the converter and associated analog circuitry. With this in mind, power to the ADS8320 should be clean and well bypassed. A 0.1µF ceramic bypass capacitor should be placed as close to the ADS8320 package as possible. In addition, a 1 to 10µF capacitor and a 5Ω or 10Ω series resistor may be used to lowpass filter a noisy supply. The reference should be similarly bypassed with a 0.1µF capacitor. Again, a series resistor and large capacitor can be used to lowpass filter the reference voltage. If the reference voltage originates from an op amp, be careful that the op amp can drive the bypass capacitor without oscillation (the series resistor can help in this case). Keep in mind that while the ADS8320 draws very little current from the reference on average, there are still instantaneous current demands placed on the external input and reference circuitry. APPLICATION CIRCUITS Figure 8 shows a basic data acquisition system. The ADS8320 input range is 0V to VCC, as the reference input is connected directly to the power supply. The 5Ω resistor and 1µF to 10µF capacitor filter the microcontroller “noise” on the supply, as well as any high-frequency noise from the supply itself. The exact values should be picked such that the filter provides adequate rejection of the noise. Burr-Brown’s OPA627 op amp provides optimum performance for buffering both the signal and reference inputs. For low cost, low voltage, single-supply applications, the OPA2350 or OPA2340 dual op amps are recommended. +2.7V to +5.25V 5Ω + 1µF to 10µF ADS8320 VREF VCC 0.1µF +In CS –In DOUT GND + 1µF to 10µF Microcontroller DCLOCK FIGURE 8. Basic Data Acquisition System. ® 13 ADS8320