LTC1609CSW#TRPBF

LTC1609 16-Bit, 200ksps, Serial ADC with Multiple Input Ranges U FEATURES ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ ■ DESCRIPTIO The LTC ®1609 is a 200ksps, serial sampling 16-bit A/D converter that draws only 65mW (typical) from a single 5V supply. This easy-to-use device includes a sample-andhold, a precision reference, a switched capacitor successive approximation A/D and trimmed internal clock. Sample Rate: 200ksps Input Ranges Unipolar: 0V to 10V, 0V to 5V and 0V to 4V Bipolar: ±10V, ±5V and ±3.3V Guaranteed No Missing Codes Serial I/O Single 5V Supply Power Dissipation: 65mW Typ Power Down Mode: 50µW SNR: 87dB Typ Operates with Internal or External Reference 28-Pin SSOP and 20-Pin SO Packages Improved 2nd Source to ADS7809 and AD977A The input range is specified for bipolar inputs of ±10V, ±5V and ±3.3V and unipolar inputs of 0V to 10V, 0V to 5V and 0V to 4V. Maximum DC specs include ±2LSB INL and 16-bit no missing codes over temperature. It has a typical signal-to-noise ratio of 87dB. The ADC has a high speed serial interface. The serial output data can be clocked out using either the internal serial shift clock or be clocked out by an external shift clock. A separate convert start input (R/C) and a data ready signal (BUSY) ease connections to FIFOs, DSPs and microprocessors. U APPLICATIO S ■ ■ ■ ■ Industrial Process Control Multiplexed Data Acquisition Systems High Speed Data Acquisition for PCs Digital Signal Processing , LTC and LT are registered trademarks of Linear Technology Corporation. U TYPICAL APPLICATIO 200kHz, 16-Bit Serial Sampling ADC Configured for ±10V Inputs 200Ω 1 2 100Ω 3 33.2k 4 5 2.5V 6 + 2.2µF 2.5V 7 + 2.2µF 8 9 10 11 12 13 14 R1IN VDIG AGND1 VANA R2IN PWRD R3IN BUSY NC LTC1609 CAP CS NC REF NC NC R/C AGND2 NC NC TAG NC NC SB/BTC DATA EXT/INT DATACLK DGND SYNC 28 27 5V + 10µF 26 Nonaveraged 4096 Point FFT Plot 0.1µF 0 fSAMPLE = 200kHz fIN = 1kHz SINAD = 87.2dB THD = –100.1dB 25 –20 24 23 MAGNITUDE (dB) ANALOG INPUT – 10V TO 10V 22 21 20 19 SERIAL INTERFACE 18 17 –40 –60 –80 –100 –120 16 –130 0 15 25 50 75 100 FREQUENCY (kHz) 1609 TA01 1609 G06 1609fa 1 LTC1609 U W W W ABSOLUTE MAXIMUM RATINGS (Notes 1, 2) VANA .......................................................................... 7V VDIG to VANA ........................................................... 0.3V VDIG ........................................................................... 7V Ground Voltage Difference DGND, AGND1 and AGND2 .............................. ±0.3V Analog Inputs (Note 3) R1IN, R2IN, R3IN ................................................ ±25V CAP ............................ VANA + 0.3V to AGND2 – 0.3V REF .................................... Indefinite Short to AGND2 Momentary Short to VANA Digital Input Voltage (Note 4) ........ DGND – 0.3V to 10V Digital Output Voltage ........ DGND – 0.3V to VDIG + 0.3V Power Dissipation .............................................. 500mW Operating Ambient Temperature Range LTC1609AC/LTC1609C ............................ 0°C to 70°C LTC1609AI/LTC1609I ......................... – 40°C to 85°C Storage Temperature Range ................. – 65°C to 150°C Lead Temperature (Soldering, 10 sec).................. 300°C U W U PACKAGE/ORDER INFORMATION ORDER PART NUMBER TOP VIEW ORDER PART NUMBER R1IN 1 28 VDIG AGND1 2 27 VANA R2IN 3 26 PWRD R3IN 4 25 BUSY NC 5 24 CS R2IN 3 18 PWRD 23 NC R3IN 4 17 BUSY CAP 5 16 CS REF 6 15 R/C 6 CAP 7 REF 8 21 R/C AGND2 9 20 NC NC 11 19 TAG 18 NC SB/BTC 12 17 DATA EXT/INT 13 16 DATACLK DGND 14 R1IN 1 20 VDIG AGND1 2 19 VANA 22 NC NC NC 10 TOP VIEW LTC1609CG LTC1609IG LTC1609CSW LTC1609ISW LTC1609ACSW LTC1609AISW AGND2 7 14 TAG SB/BTC 8 13 DATA EXT/INT 9 12 DATACLK DGND 10 11 SYNC SW PACKAGE 20-LEAD PLASTIC SO 15 SYNC TJMAX = 125°C, θJA = 130°C/W G PACKAGE 28-LEAD PLASTIC SSOP TJMAX = 125°C, θJA = 95°C/W Consult LTC Marketing for parts specified with wider operating temperature ranges. U CONVERTER CHARACTERISTICS The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. With external reference (Notes 5, 6). PARAMETER CONDITIONS MIN LTC1609 TYP MAX MIN LTC1609A TYP MAX UNITS Resolution ● 16 16 Bits No Missing Codes ● 15 16 Bits Transition Noise Integral Linearity Error 0.9 (Note 7) Differential Linearity Error Bipolar Zero Error External Reference = 2.5V (Note 8), Bipolar Ranges ±3 ● ● ● 0.9 –2 3 ±10 –1 LSBRMS ±2 LSB 1.75 LSB ±10 mV 1609fa 2 LTC1609 U CONVERTER CHARACTERISTICS The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. With external reference (Notes 5, 6). PARAMETER CONDITIONS MIN LTC1609 TYP MAX MIN LTC1609A TYP MAX ±2 Bipolar Zero Error Drift Bipolar Ranges Unipolar Zero Error External Reference = 2.5V, Unipolar Ranges Unipolar Zero Error Drift Unipolar Ranges ±2 ±10 ● ±2 ±7 Full-Scale Error Drift Full-Scale Error External Reference = 2.5V (Notes 12, 13) Full-Scale Error Drift External Reference = 2.5V Power Supply Sensitivity VANA = VDIG = VDD VDD = 5V ±5% (Note 9) ppm/°C ±10 ±2 ppm/°C ±0.25 ±2 ±2 ±8 mV ppm/°C ±7 ±0.50 ● UNITS % ppm/°C ±8 LSB U U A ALOG I PUT The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 5) SYMBOL PARAMETER CONDITIONS MIN VIN Analog Input Range (Note 9) 4.75V ≤ VANA ≤ 5.25V, 4.75V ≤ VDIG ≤ 5.25V, CIN RIN LTC1609/LTC1609A TYP MAX UNITS ±10, 0V to 5V, etc. (See Tables 1a and 1b) V Analog Input Capacitance 10 pF Analog Input Impedance See Tables 1a and 1b kΩ W U DY A IC ACCURACY ● (Notes 5, 14) MIN LTC1609 TYP MAX MIN LTC1609A TYP MAX SYMBOL PARAMETER CONDITIONS S/(N + D) Signal-to-(Noise + Distortion) Ratio 1kHz Input Signal (Note 14) 10kHz Input Signal 20kHz, – 60dB Input Signal 87.5 87 30 THD Total Harmonic Distortion 1kHz Input Signal, First 5 Harmonics 10kHz Input Signal, First 5 Harmonics – 100 – 94 – 100 – 94 Peak Harmonic or Spurious Noise 1kHz Input Signal 10kHz Input Signal – 102 – 94 – 102 – 94 dB dB Full-Power Bandwidth (Note 15) 275 275 kHz 85 87.5 87 30 UNITS dB dB dB –96 dB dB –3dB Input Bandwidth 1 1 MHz Aperture Delay 40 40 ns Aperture Jitter Sufficient to Meet AC Specs Sufficient to Meet AC Specs Transient Response Full-Scale Step (Note 9) Overvoltage Recovery (Note 16) U U U INTERNAL REFERENCE CHARACTERISTICS 2 µs 2 150 150 ns The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 5) PARAMETER CONDITIONS VREF Output Voltage IOUT = 0 VREF Output Tempco IOUT = 0 MIN ● 2.470 Internal Reference Source Current External Reference Voltage for Specified Linearity (Notes 9, 10) External Reference Current Drain External Reference = 2.5V (Note 9) CAP Output Voltage IOUT = 0 LTC1609/LTC1609A TYP MAX 2.30 2.500 2.520 UNITS V ±5 ppm/°C 1 µA 2.50 ● 2.50 2.70 V 100 µA V 1609fa 3 LTC1609 U U DIGITAL I PUTS A D DIGITAL OUTPUTS The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 5) SYMBOL PARAMETER CONDITIONS MIN VIH High Level Input Voltage VDD = 5.25V ● VIL Low Level Input Voltage VDD = 4.75V ● IIN Digital Input Current VIN = 0V to VDD ● CIN Digital Input Capacitance VOH High Level Output Voltage VDD = 4.75V IO = –10µA VOL Low Level Output Voltage VDD = 4.75V IO = 160µA IO = – 200µA IO = 1.6mA ● LTC1609/LTC1609A TYP MAX UNITS 2.4 V 0.8 V ±10 µA 5 pF 4.5 V 4.0 V 0.05 0.10 ● V 0.4 V ISOURCE Output Source Current VOUT = 0V –10 mA ISINK Output Sink Current VOUT = VDD 10 mA WU TI I G CHARACTERISTICS The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 5) MIN LTC1609/LTC1609A TYP MAX SYMBOL PARAMETER CONDITIONS t1 Convert Pulse Width (Note 11) ● t2 R/C, CS to BUSY Delay CL = 25pF ● 80 ns t3 BUSY Low Time ● 3 µs t4 BUSY Delay After End of Conversion t5 Aperture Delay t6 Conversion Time ● t7 Acquisition Time ● t6 + t 7 Throughput Time ● t8 R/C Low to DATACLK Delay 260 ns t9 DATACLK Period 150 ns t10 DATA Valid Setup Time ● 15 ns t11 DATA Valid Hold Time ● 40 ns t12 External DATACLK Period ● 50 ns t13 External DATACLK High ● 20 ns t14 External DATACLK Low ● 20 ns t15 R/C, CS to External DATACLK Setup Time ● 15 t16 R/C to CS Setup Time ● 10 t17 External DATACLK to SYNC Delay ● 6 50 ns t18 External DATACLK to DATA Valid Delay ● 10 50 ns t19 CS to External DATACLK Rising Edge Delay ● 10 ns t20 Previous DATA Valid After CS, R/C Low (Note 9) ● 2.2 µs t21 BUSY to External DATACLK Setup Time (Note 9) ● 5 ns t22 BUSY Falling Edge to Final External DATACLK (Notes 10, 17) ● t23 TAG Valid Setup Time ● 0 ns t24 TAG Valid Hold Time ● 15 ns 40 UNITS ns 100 ns 5 ns 3 µs µs 2 5 t12 µs ns ns 1.2 µs 1609fa 4 LTC1609 U W POWER REQUIREMENTS The ● indicates specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C. (Note 5) SYMBOL PARAMETER CONDITIONS MIN LTC1609/LTC1609A TYP MAX UNITS VDD Positive Supply Voltage (Notes 9, 10) 4.75 5.25 V IDD Positive Supply Current PWRD = Low PDIS Power Dissipation PWRD = Low PWRD = High Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired. Note 2: All voltage values are with respect to ground with DGND, AGND1 and AGND2 wired together (unless otherwise noted). Note 3: When these pin voltages are taken below ground or above VANA = VDIG = VDD, they will be clamped by internal diodes. This product can handle input currents of greater than 100mA below ground or above VDD without latch-up. Note 4: When these pin voltages are taken below ground, they will be clamped by internal diodes. This product can handle input currents of 90mA below ground without latchup. These pins are not clamped to VDD. Note 5: VDD = 5V, fSAMPLE = 200kHz, tr = tf = 5ns unless otherwise specified. Note 6: Linearity, offset and full-scale specifications apply for a VIN input with respect to ground. Note 7: Integral nonlinearity is defined as the deviation of a code from a straight line passing through the actual end points of the transfer curve. The deviation is measured from the center of the quantization band. Note 8: Bipolar zero error is the offset voltage measured from – 0.5 LSB when the output code flickers between 0000 0000 0000 0000 and 1111 1111 1111 1111. Unipolar zero error is the offset voltage measured from 0.5LSB when the output codes flickers between 0000. . .0000 and 0000. . .0001. ● 13 20 mA 65 50 100 mW µW Note 9: Guaranteed by design, not subject to test. Note 10: Recommended operating conditions. Note 11: With CS low the falling R/C edge starts a conversion. If R/C returns high at a critical point during the conversion it can create small errors. For best results ensure that R/C returns high within 1.2µs after the start of the conversion. Note 12: As measured with fixed 1% resistors shown in Figures 3a and 3b. Adjustable to zero with external potentiometer. Note 13: Full-scale error is the worst-case of –FS or +FS untrimmed deviation from ideal first and last code transitions, divided by the transition voltage (not divided by the full-scale range) and includes the effect of offset error. For unipolar input ranges full-scale error is the deviation of the last code transition from ideal divided by the transiton voltage and includes the effect of offset error. Note 14: All specifications in dB are referred to a full-scale ±5V input. Note 15: Full-power bandwidth is defined as full-scale input frequency at which a signal-to-(noise + distortion) degrades to 60dB or 10 bits of accuracy. Note 16: Recovers to specified performance after (2 • FS) input overvoltage. Note 17: When data is shifted out during a conversion, with an external data clock, complete the process within 1.2µs from the start of the conversion (BUSY falling). This will help keep any external disturbances from causing an error in the conversion result. 1609fa 5 LTC1609 U W TYPICAL PERFOR A CE CHARACTERISTICS Change in CAP Voltage vs Load Current Supply Current vs Supply Voltage 0.05 fSAMPLE = 200kHz 0 CHANGE IN CAP VOLTAGE (V) 14.5 14.0 13.5 13.0 12.5 12.0 11.5 0.03 0.02 0.01 0 –0.01 –0.02 –0.03 –0.04 11.0 4.5 5.0 4.75 5.25 SUPPLY VOLTAGE (V) –0.05 –14 –12 –10 –8 –6 –4 –2 0 LOAD CURRENT (mA) 5.5 Typical INL Curve –20 –30 –40 –50 –60 –70 4 1 1.5 1.5 –20 1.0 1.0 0.5 0.5 0 –0.5 –0.5 –1.0 –1.0 –1.5 –1.5 –2.0 –2.0 32768 49152 65535 MAGNITUDE (dB) 0 16384 1M fSAMPLE = 200kHz fIN = 1kHz SINAD = 87.2dB THD = –100.1dB –40 –60 –80 –100 –120 –130 0 16384 CODE 32768 65535 49152 0 CODE 25 50 75 100 FREQUENCY (kHz) 1609 G04 1609 G05 SINAD vs Input Frequency 1609 G06 THD vs Input Frequency 95 –40 90 –50 85 –60 THD (dB) SINAD (dB) 100 1k 10k 100k RIPPLE FREQUENCY (Hz) Nonaveraged 4096 Point FFT Plot Typical DNL Curve 2.0 0 10 1609 G03 2.0 DNL (LSB) INL (LSB) 2 –10 1609 G02 1609 G01 0 fSAMPLE = 200kHz 0.04 POWER SUPPLY REJECTION (dB) 15.0 SUPPLY CURRENT (mA) Power Supply Rejection vs Ripple Frequency 80 75 –70 –80 70 –90 65 –100 60 –110 1 10 FREQUENCY (kHz) 100 1609 G07 1 10 FREQUENCY (kHz) 100 1609 G08 1609fa 6 LTC1609 U U U PIN FUNCTIONS (20-Pin SO/28-Pin SSOP) R1IN (Pin 1/Pin 1): Analog Input. See Table 1 and Figure␣ 1 for input range connections. low, 16 clock pulses are output during each conversion. The pin will stay low between conversions. AGND1 (Pin 2/Pin 2): Analog Ground. Tie to analog ground plane. DATA (Pin 13/Pin 17): Serial Data Output. The output data is synchronized to the DATACLK and the format is determined by SB/BTC. In the external shift clock mode, after 16 bits of data have been shifted out and CS is low and R/C is high, the level in the TAG pin will be outputted. This can be used to daisy-chain the serial data output from several LTC1609s. If EXT/INT is low, the output data is valid on both the rising and falling edge of the internal shift clock which is outputted on DATACLK. In between conversions, DATA will stay at the level of the TAG input when the conversion was started. R2IN (Pin 3/Pin 3): Analog Input. See Table 1 and Figure␣ 1 for input range connections. R3IN (Pin 4/Pin 4): Analog Input. See Table 1 and Figure␣ 1 for input range connections. NC (28-Pin SSOP Only—Pins 5, 8, 10, 11, 18, 20, 22, 23): No Connect. CAP (Pin 5/Pin 6): Reference Buffer Output. Bypass with 2.2µF tantalum capacitor. REF (Pin 6/Pin 7): 2.5V Reference Output. Bypass with 2.2µF tantalum capacitor. Can be driven with an external reference. AGND2 (Pin 7/Pin 9): Analog Ground. Tie to analog ground plane. SB/BTC (Pin 8/Pin 12): Select straight binary or two’s complement data output format. Tie pin high for straight binary or tie low for two’s complement format. EXT/INT (Pin 9/Pin 13): Select external or internal clock for shifting out the output data. Tie the pin high to synchronize the output data to the clock that is applied to the DATACLK pin. If the pin is tied low, a convert command will start transmitting the output data from the previous conversion synchronized to 16 clock pulses that are outputted on the DATACLK pin. TAG (Pin 14/Pin 19): Tag input is used in the external clock mode. If EXT/INT is high, digital inputs applied to TAG will be shifted out on DATA delayed 16 DATACLK pulses as long as CS is low and R/C is high. R/C (Pin 15/Pin 21): Read/Convert Input. With CS low, a falling edge on R/C puts the internal sample-and-hold into the hold state and starts a conversion. With CS low, a rising edge on R/C enables the serial output data. CS (Pin 16/Pin 24): Chip Select. Internally OR’d with R/C. With R/C low, a falling edge on CS will initiate a conversion. With R/C high, a falling edge on CS will enable the serial output data. DGND (Pin 10/Pin 14): Digital Ground. BUSY (Pin 17/Pin 25): Output Shows Converter Status. It is low when a conversion is in progress. Data valid on the rising edge of BUSY. CS or R/C must be high when BUSY rises or another conversion will start without time for signal acquisition. SYNC (Pin 11/Pin 15): Sync Output. If EXT/INT is high, either a rising edge on R/C with CS low or a falling edge on CS with R/C high will output a pulse on SYNC synchronized to the external clock applied on the DATACLK pin. PWRD (Pin 18/Pin 26): Power Down Input. If the pin is tied high, conversions are inhibited and power consumption is reduced (10µA typ). Results from the previous conversion are maintained in the output shift register. DATACLK (Pin 12/Pin 16): Either an input or an output depending on the level set on EXT/INT. The output data is synchronized to this clock. When EXT/INT is high an external shift clock is applied to this pin. If EXT/INT is taken VANA (Pin 19/Pin 27): 5V Analog Supply. Bypass to ground with a 0.1µF ceramic and a 10µF tantalum capacitor. VDIG (Pin 20/Pin 28): 5V Digital Supply. Connect directly to VANA. 1609fa 7 LTC1609 W FUNCTIONAL BLOCK DIAGRA U U R1IN R2IN CSAMPLE 20k 10k 20k VANA CSAMPLE 5k R3IN REF VDIG ZEROING SWITCHES 4k 2.5V REF + REF BUF COMP 16-BIT CAPACITIVE DAC – CAP (2.5V) DATA SUCCESSIVE APPROXIMATION REGISTER AGND1 DATACLK SERIAL INTERFACE AGND2 SYNC INTERNAL CLOCK DGND CONTROL LOGIC 1609 BD CS R/C PWRD SB/BTC BUSY EXT/INT TAG U W U U APPLICATIO S I FOR ATIO Conversion Details The LTC1609 uses a successive approximation algorithm and an internal sample-and-hold circuit to convert an analog signal to a 16-bit serial output. The ADC is complete with a precision reference and an internal clock. The control logic provides easy interface to microprocessors and DSPs. (Please refer to the Digital Interface section for timing information.) Conversion start is controlled by the CS and R/C inputs. At the start of conversion the successive approximation register (SAR) is reset. Once a conversion cycle has begun it cannot be restarted. During the conversion, the internal 16-bit capacitive DAC output is sequenced by the SAR from the most significant bit (MSB) to the least significant bit (LSB). Referring to Figure 1, VIN is connected through the resistor divider to the sample-and-hold capacitor during the acquire phase and the comparator offset is nulled by the autozero switches. In this acquire phase, a minimum delay of 2µs will provide enough time for the sample-and-hold capacitor to acquire the analog signal. During the convert phase, the autozero switches open, putting the comparator into the compare mode. The input switch switches CSAMPLE to ground, injecting the analog input charge onto the summing junction. This input charge is successively compared with the binary-weighted charges supplied by the capacitive DAC. Bit decisions are made by the high speed comparator. At SAMPLE RIN1 SAMPLE SI CSAMPLE – VIN RIN2 HOLD + CDAC COMPARATOR DAC VDAC S A R 16-BIT SHIFT REGISTER 1609 F01 Figure 1. LTC1609 Simplified Equivalent Circuit 1609fa 8 LTC1609 U W U U APPLICATIO S I FOR ATIO the end of a conversion, the DAC output balances the VIN input charge. The SAR contents (a 16-bit data word) that represents the VIN are loaded into the 16-bit output shift register. Driving the Analog Inputs The LTC1609 analog input ranges, along with the nominal input impedances, are shown in Tables 1a and 1b. The inputs are overvoltage protected to ±25V. The input impedance can get as low as 10kΩ, therefore, it should be driven with a low impedance source. Wideband noise coupling into the input can be minimized by placing a 1000pF capacitor at the input as shown in Figure 2. An NPO-type capacitor gives the lowest distortion. Place the capacitor as close to the device input pin as possible. If an amplifier is to be used to drive the input, care should be taken to select an amplifier with adequate accuracy, linearity and noise for the application. The following list is a summary of the op amps that are suitable for driving the LTC1609. More detailed information is available in the Linear Technology data books and LinearViewTM CD-ROM. 200Ω AIN1 R1IN 1000pF LTC1609 100Ω AIN2 R2IN 1000pF AIN3 R3IN 1000pF 1609 F02 Figure 2. Analog Input Filtering LT1007 - Low noise precision amplifier. 2.7mA supply current ±5V to ±15V supplies. Gain bandwidth product 8MHz. DC applications. LT1097 - Low cost, low power precision amplifier. 300µA supply current. ±5V to ±15V supplies. Gain bandwidth product 0.7MHz. DC applications. LT1227 - 140MHz video current feedback amplifier. 10mA supply current. ±5V to ±15V supplies. Low noise and low distortion. LT1360 - 37MHz voltage feedback amplifier. 3.8mA supply current. ±5V to ±15V supplies. Good AC/DC specs. LT1363 - 50MHz voltage feedback amplifier. 6.3mA supply current. Good AC/DC specs. LT1364/LT1365 - Dual and quad 50MHz voltage feedback amplifiers. 6.3mA supply current per amplifier. Good AC/DC specs. LT1468 - 90MHz, 22V/µs 16-bit accurate amplifier LT1469 - Dual LT1468 Offset and Gain Adjustments The LTC1609 is specified to operate with three unipolar and three bipolar input ranges. Pins R1IN, R2IN and R3IN are connected as shown in Tables 1a and 1b for the different input ranges. The tables also list the nominal input impedance for each range. Table 1c shows the output codes for the ideal input voltages of each of the six input ranges. The LTC1609 offset and full-scale errors have been trimmed at the factory with the external resistors shown in Figures 3a and 3b. This allows for external adjustment of offset and full scale in applications where absolute accuracy is important. The offset and gain adjustment circuits for the six input ranges are also shown in Figures 3a and 3b. To adjust the offset for a bipolar input range, apply an input voltage equal to – 0.5LSB where 1LSB = (+ FS – – FS)/ 65536 and change the offset resistor so the output code is changing between 1111 1111 1111 1111 and 0000 0000 0000 0000. The gain is trimmed by applying an input voltage of + FS – 1.5LSB and adjusting the gain trim resistor until the output code is changing between 0111 1111 1111 1110 and 0111 1111 1111 1111. In both cases the data is in two’s complement format (SB/BTC = LOW) To adjust the offset for a unipolar input range, apply an input voltage equal to + 0.5LSB where 1LSB = + FS/65536. Then adjust the offset trim resistor until the output code changes between 0000 0000 0000 0000 and 0000 0000 0000 0001. To adjust the gain, apply an input voltage equal to + FS – 1.5LSB and vary the gain trimming resistor until the output code is changing between 1111 1111 1111 1110 and 1111 1111 1111 1111. In the unipolar case, the data is in straight binary format (SB/BTC = HIGH). Figures 4a and 4b show the transfer characteristics of the LTC1609. LinearView is a trademark of Linear Technology Corporation. 1609fa 9 LTC1609 U W U U APPLICATIO S I FOR ATIO INPUT RANGE WITH TRIM (ADJUST OFFSET FIRST AT 0V, THEN ADJUST GAIN) WITHOUT TRIM LTC1609 LTC1609 R1IN R1IN 200Ω 200Ω AGND1 AGND1 100Ω 100Ω VIN 0V TO 10V R2IN R2IN OFFSET 50k TRIM R3IN 33.2k 33.2k VIN 5V + R3IN 2.2µF CAP + + CAP 5V 576k GAIN 50k TRIM REF 2.2µF 2.2µF + AGND2 AGND2 LTC1609 LTC1609 R1IN R1IN 200Ω 200Ω AGND1 AGND1 100Ω 100Ω 5V R2IN 0V TO 5V REF 2.2µF VIN 33.2k 33.2k R3IN VIN CAP + + + R2IN OFFSET 50k TRIM REF 2.2µF CAP 5V 576k GAIN TRIM 50k + 2.2µF 2.2µF REF 2.2µF AGND2 200Ω AGND2 LTC1609 200Ω R1IN VIN AGND1 AGND1 100Ω R2IN 0V TO 4V R2IN R3IN R3IN 33.2k 33.2k CAP + LTC1609 R1IN VIN 100Ω + R3IN + 5V OFFSET 50k TRIM REF 2.2µF 2.2µF 5V GAIN 50k TRIM 2.2µF CAP 576k + REF 2.2µF AGND2 AGND2 1609 F03a Figure 3a. Offset/Gain Circuits for Unipolar Input Ranges Table 1a. Analog Input Range Connections for Figure 3a ANALOG INPUT RANGE CONNECT R1IN VIA 200Ω TO CONNECT R2IN VIA 100Ω TO CONNECT R3IN TO INPUT IMPEDANCE 0V to 10V AGND VIN AGND 13.3kΩ 0V to 5V AGND AGND VIN 10kΩ 0V to 4V VIN AGND VIN 10.7kΩ 1609fa 10 LTC1609 U W U U APPLICATIO S I FOR ATIO INPUT RANGE WITH TRIM (ADJUST OFFSET FIRST AT 0V, THEN ADJUST GAIN) WITHOUT TRIM 200Ω VIN LTC1609 200Ω R1IN VIN AGND1 AGND1 R2IN ± 10V R2IN 100Ω 100Ω R3IN 33.2k CAP + + R3IN + 33.2k 2.2µF 5V OFFSET 50k TRIM REF CAP 5V 576k GAIN 50k TRIM + 2.2µF 2.2µF AGND2 LTC1609 LTC1609 R1IN R1IN 200Ω 200Ω AGND1 AGND1 33.2k 100Ω VIN R2IN OFFSET 50k TRIM + R2IN + R3IN 2.2µF CAP + 100Ω VIN 5V R3IN 33.2k CAP 5V 576k GAIN TRIM 50k REF + 2.2µF 2.2µF AGND2 LTC1609 200Ω 100Ω LTC1609 200Ω R1IN VIN R1IN VIN AGND1 AGND1 100Ω R2IN 33.2k R2IN + R3IN 33.2k CAP + + REF 2.2µF AGND2 ± 3.3V REF 2.2µF AGND2 ± 5V LTC1609 R1IN 5V OFFSET 50k TRIM REF 2.2µF 2.2µF R3IN 2.2µF CAP 5V GAIN 50k TRIM 576k + REF 2.2µF AGND2 AGND2 1609 F03b Figure 3b. Offset/Gain Circuits for Bipolar Input Ranges Table 1b. Analog Input Range Connections for Figure 3b ANALOG INPUT RANGE CONNECT R1IN VIA 200Ω TO CONNECT R2IN VIA 100Ω TO CONNECT R3IN TO INPUT IMPEDANCE ±10V VIN AGND CAP 22.9kΩ ±5V AGND VIN CAP 13.3kΩ ±3.3V VIN VIN CAP 10.7kΩ 1609fa 11 LTC1609 U W U U APPLICATIO S I FOR ATIO Table 1c. LTC1609 Output Codes for Ideal Input Voltages DESCRIPTION ANALOG INPUT Full-Scale Range ±10V ±5V ±3.34 0V to 10V 0V to 5V 0V to 4V Least Significant Bit 305µV 153µV 102µV 153µV 76µV 61µV +Full Scale (FS – 1LSB) 9.999695V 4.999847V Midscale 1LSB Below Midscale 0V 0V 0V – 305µV –153µV –102µV –10V – 5V – 3.340000V 9.999847V 4.999924V 3.999939V 5V 2.5V 2V 4.999847V 2.499924V 1.999939V 0V 0V 0V STRAIGHT BINARY (SB/BTC HIGH) 0111 1111 1111 1111 1111 1111 1111 1111 0000 0000 0000 0000 1000 0000 0000 0000 1111 1111 1111 1111 0111 1111 1111 1111 1000 0000 0000 0000 0000 0000 0000 0000 111...111 011...111 BIPOLAR ZERO 011...110 111...110 OUTPUT CODE OUTPUT CODE (TWO’S COMPLIMENT) – Full Scale 3.339898V TWO’S COMPLEMENT (SB/BTC LOW) 000...001 000...000 111...111 111...110 100...001 FSR = +FS – –FS 1LSB = FSR/65536 100...000 –FSR/2 100...001 100...000 011...111 011...110 000...001 1LSB = FS/65536 000...000 –1 0V 1 FSR/2 – 1LSB LSB LSB INPUT VOLTAGE (V) 0V FS – 1LSB INPUT VOLTAGE (V) 1609 F04b 1609 F04a The ideal ±FS value for the ±3.3V range is 3.340000V – 1LSB and – 3.340000V, respectively. The external 33.2k resistor that is connected between the CAP pin and the R2IN pin, slightly attenuates the input signal applied to R2IN. Without the 33.2k resistor the ±FS value would be 3.333333V – 1LSB and – 3.333333V (zero volt offset), respectively. DC Performance One way of measuring the transition noise associated with a high resolution ADC is to use a technique where a DC signal is applied to the input of the ADC and the resulting output codes are collected over a large number of conversions. For example in Figure 5 the distribution of output code is shown for a DC input that has been digitized 4096 times. The distribution is Gaussian and the RMS code transition is about 0.9LSB. Figure 4b. LTC1609 Unipolar Transfer Characteristics 2000 1500 COUNT Figure 4a. LTC1609 Bipolar Transfer Characteristics 1000 500 0 –3 –2 –1 0 CODE 1 2 3 1609 F05 Figure 5. Histogram for 4096 Conversions 1609fa 12 LTC1609 U W U U APPLICATIO S I FOR ATIO Dynamic Performance FFT (Fast Fourier Transform) test techniques are used to test the ADC’s frequency response, distortion and noise at the rated throughput. By applying a low distortion sine wave and analyzing the digital output using an FFT algorithm, the ADC’s spectral content can be examined for frequencies outside the fundamental. Figure 6 shows a typical LTC1609 FFT plot which yields a SINAD of 87.2dB and THD of – 100dB. Signal-to-Noise Ratio The Signal-to-Noise and Distortion Ratio (SINAD) is the ratio between the RMS amplitude of the fundamental input frequency to the RMS amplitude of all other frequency components at the A/D output. The output is band limited to frequencies from above DC and below half the sampling frequency. Figure 6 shows a typical SINAD of 87.2dB with a 200kHz sampling rate and a 1kHz input. 0 fSAMPLE = 200kHz fIN = 1kHz SINAD = 87.2dB THD = –100.1dB MAGNITUDE (dB) –20 where V1 is the RMS amplitude of the fundamental frequency and V2 through VN are the amplitudes of the second through Nth harmonics. Internal Voltage Reference The LTC1609 has an on-chip, temperature compensated, curvature corrected, bandgap reference, which is factory trimmed to 2.50V. The full-scale range of the ADC scales with VREF. The output of the reference is connected to the input of a unity-gain buffer through a 4k resistor (see Figure 7). The input to the buffer or the output of the reference is available at REF. The internal reference can be overdriven with an external reference if more accuracy is needed. The buffer output drives the internal DAC and is available at CAP. The CAP pin can be used to drive a steady DC load of less than 2mA. Driving an AC load is not recommended because it can cause the performance of the converter to degrade. For minimum code transition noise the REF pin and the CAP pin should each be decoupled with a capacitor to filter wideband noise from the reference and the buffer (2.2µF tantalum). –40 –60 –80 REF (2.5V) –100 2.2µF 4k 7 BANDGAP REFERENCE S + VANA –120 – –130 0 25 50 100 75 CAP (2.5V) FREQUENCY (kHz) 1609 F06 Figure 6. LTC1609 Nonaveraged 4096 Point FFT Plot S INTERNAL CAPACITOR DAC 1609 F07 Total Harmonic Distortion Total Harmonic Distortion (THD) is the ratio of the RMS sum of all harmonics of the input signal to the fundamental itself. The out-of-band harmonics alias into the frequency band between DC and half the sampling frequency. THD is expressed as: 2 2.2µF 6 2 2 Figure 7. Internal or External Reference Source 2 V + V3 + V4 ... + VN THD = 20 log 2 V1 1609fa 13 LTC1609 U W U U APPLICATIO S I FOR ATIO Power Shutdown the sample-and-hold into the hold mode bring CS and R/C low for no less than 40ns. Once initiated it cannot be restarted until the conversion is complete. Converter status is indicated by the BUSY output and this is low while the conversion is in progress. When the PWRD pin is tied high, power consumption drops to a typical value of 50µW from a specified maximum of 100mW. In the power shutdown mode, the result from the previous conversion is still available in the internal shift register, assuming the data had not been clocked out before going into power shutdown. The conversion result is clocked out serially on the DATA pin. It can be synchronized by using the internal data clock or by using an external clock provided by the user. Tying the EXT/INT pin high puts the LTC1609 in the external clock mode and the DATACLK pin is a digital input. Tying the EXT/INT pin low puts the part in the internal clock mode and the DATACLK pin becomes a digital output. The internal reference buffer and the reference are shut down, so the power-up recovery time will be dependent upon how fast the bypass capacitors on these pins can be charged. If the internal reference is used, the 4k resistor in series with the output and the external bypass capacitor, typically 2.2µF, will be the main time constant for the power-up recovery time. If an external reference is used, the reference buffer output will be able to ramp from 0V to 2.5V in 1ms, while charging a typical bypass capacitor of 2.2µF. The recovery time will be less if the bypass capacitor has not completely discharged. Internal Clock Mode With the EXT/INT pin tied low, the LTC1609 provides the data clock on the DATACLK pin. The timing diagram is shown in Figure 8. Typically, CS is tied low and the R/C pin is used to start a conversion. During the conversion a 16-bit word will be shifted out MSB-first on the DATA pin. This word represents the result from the previous conversion. The DATACLK pin outputs 16 clock pulses used to synchronize the data. The output data is valid on both the rising and falling edges of the clock. After the LSB bit has been clocked out, the DATA pin will take on the state of the TAG pin at the start of the conversion. The DATACLK pin goes low until the next conversion is requested. The data clock is derived from the internal conversion clock. To avoid errors from occurring during the current conversion, minimize the loading on the DATACLK pin and the DATA pin. For the best conversion results the external clock mode is recommended. DIGITAL INTERFACE Internal Conversion Clock The ADC has an internal clock that is trimmed to achieve a typical conversion time of 2.7µs. No external adjustments are required and, with the typical acquisition time of 1.5µs, throughput performance of 200ksps is assured. Timing and Control Conversion start and data read are controlled by two digital inputs: CS and R/C. To start a conversion and put t8 R/C t9 t1 DATACLK 1 B15 (MSB) t2 3 14 15 16 B13 B2 B1 B0 t11 t10 DATA 2 B14 t3 BUSY 1609 F08 Figure 8. Serial Data Timing Using Internal Clock (CS, EXT/INT and TAG Tied Low) 1609fa 14 LTC1609 U W U U APPLICATIO S I FOR ATIO External Clock Mode pulse on the SYNC pin will be generated on the rising edge of DATACLK #0. The SYNC output can be captured on the falling edge of DATACLK #0 or on the rising edge of DATACLK #1. After the rising edge of DATACLK #1, the SYNC output will go low and the MSB will be clocked out on the DATA pin. This bit can be latched on the falling edge of DATACLK #1 or on the rising edge of DATACLK #2. The LSB will be valid on the falling edge of DATACLK #16 or the rising edge of DATACLK #17. After the rising edge of DATACLK #17 the DATA pin will take on the value of the TAG pin that occurred at the rising edge of DATACLK #1. A minimum of 17 clock pulses are required if the data is captured on falling clock edges. With the EXT/INT pin tied high, the DATACLK pin becomes a digital input and the LTC1609 can accept an externally supplied data clock. There are several ways in which the conversion results can be clocked out. The data can be clocked out during or after a conversion with a continuous or discontinuous data clock. Figures 9 to 12 show the timing diagram for each of these methods. External Discontinuous Data Clock Data Read After the Conversion Figure 9 shows how the result from the current conversion can be read out after the conversion has been completed. The externally supplied data clock is running discontinuously. R/C is used to initiate a conversion with CS tied low. The conversion starts on the falling edge of R/C. R/C should be returned high within 1.2µs to prevent the transition from disturbing the conversion. After the conversion has been completed (BUSY returning high), a Using the highest frequency permitted for DATACLK (20MHz), shifting the data out after the conversion will not degrade the 200kHz throughput. This method minimizes the possible external disturbances that can occur while a conversion is in progress and will yield the best performance. t12 t14 t13 0 1 2 3 15 16 17 EXTERNAL DATACLK t1 R/C t2 t21 t3 BUSY t17 SYNC t12 DATA t23 TAG TAG0 t18 B15 (MSB) t24 TAG1 B14 B13 B1 B0 TAG0 TAG1 TAG2 TAG2 TAG3 TAG15 TAG16 TAG17 TAG18 TAG19 1606 F09 Figure 9. Conversion and Read Timing Using an External Discontinuous Data Clock (EXT/INT Tied High, CS Tied Low). Read Conversion Result After the Conversion 1609fa 15 LTC1609 U W U U APPLICATIO S I FOR ATIO External Data Clock Data Read After the Conversion Using the highest frequency permitted for DATACLK (20MHz), shifting the data out after the conversion will not degrade the 200kHz throughput. Figure 10 shows how the result from the current conversion can be read out after the conversion has been completed. The externally supplied data clock is running continuously. CS and R/C are first used together to initiate a conversion and then CS is used to read the result. The conversion starts on the falling edge of CS with R/C low. Both CS and R/C should be returned high within 1.2µs to prevent the transition from disturbing the conversion. After the conversion has been completed (BUSY returning high), a pulse on the SYNC pin will be generated after the first rising edge of DATACLK #1 that occurs after CS goes low (R/C high). The SYNC output can be captured on the falling edge of DATACLK #1 or on the rising edge of DATACLK #2. After the rising edge of DATACLK #2, the SYNC output will go low and the MSB will be clocked out on the DATA pin. This bit can be latched on the falling edge of DATACLK #2 or on the rising edge of DATACLK #3. The LSB will be valid on the falling edge of DATACLK #17 or the rising edge of DATACLK #18. After the rising edge of DATACLK #18 the DATA pin will take on the value of the TAG pin that occurred at the rising edge of DATACLK #2. External Discontinuous Data Clock Data Read During the Conversion Figure 11 shows how the result from the previous conversion can be read out during the current conversion. The externally supplied data clock is running discontinuously. R/C is used to initiate a conversion with CS tied low. The conversion starts on the falling edge of R/C. R/C should be returned high within 1.2µs to prevent the transition from disturbing the conversion. A pulse on the SYNC pin will be generated on rising edge of DATACLK #0. The SYNC output can be captured on the falling edge of DATACLK #0 or on the rising edge of DATACLK #1. After the rising edge of DATACLK #1, the SYNC output will go low and the MSB will be clocked out on the DATA pin. This bit can be latched on the falling edge of DATACLK #1 or on the rising edge of DATACLK #2. The LSB will be valid on the falling edge of DATACLK #16. Another clock pulse would be needed if the LSB is captured on a rising edge. A minimum of 17 clock pulses are required if the data is captured on falling clock edges. t12 t13 t14 0 1 2 3 4 17 18 EXTERNAL DATACLK t19 t15 t1 CS t16 t16 R/C t2 t3 BUSY t17 SYNC t12 DATA t23 TAG TAG0 t18 B15 (MSB) t24 TAG1 B14 B1 B0 TAG0 TAG2 TAG15 TAG16 TAG17 TAG1 TAG18 TAG19 1606 F10 Figure 10. Conversion and Read Timing with External Clock (EXT/INT Tied High). Read After Conversion 1609fa 16 LTC1609 U W U U APPLICATIO S I FOR ATIO t12 t13 t14 0 1 2 15 16 EXTERNAL DATACLK t15 t1 R/C t2 BUSY t3 t21 t22 t17 SYNC t18 DATA B15 (MSB) B14 B1 B0 1606 F11 Figure 11. Conversion and Read Timing Using a Discontinuous Data Clock (EXT/INT Tied High, CS Tied Low). Read Previous Conversion Result During the Conversion. For Best Performance, Complete Read in Less Than 1.2µs To minimize the possible external disturbances that can occur while a conversion is in progress, the data needs to be shifted out within 1.2µs from the start of the conversion. Using the maximum data clock frequency of 20MHz will ensure this condition is met. External Data Clock Data Read During the Conversion Figure 12 shows how the result from the previous conversion can be read out during the current conversion. The externally supplied data clock is running continuously. CS and R/C are used to initiate a conversion and read the data from the previous conversion. The conversion starts on the falling edge of CS after R/C is low. A pulse on the SYNC pin will be generated on the first rising edge of DATACLK #1 after R/C has returned high. The SYNC output can be captured on the falling edge of DATACLK #1 or on the rising edge of DATACLK #2. After the rising edge of DATACLK #2 the SYNC output will go low and the MSB will be clocked out on the DATA pin. This bit can be latched on the falling edge of DATACLK #2 or on the rising edge of DATACLK #3. The LSB will be valid on the falling edge of DATACLK #17 or the rising edge of DATACLK #18. After the rising edge of DATACLK #18 the DATA pin will take on the value of the TAG pin that occurred at the rising edge of DATACLK #2. To minimize the possible external disturbances that can occur while a conversion is in progress, the data needs to be shifted out within 1.2µs from the start of the conversion. Using the maximum data clock frequency of 20MHz will ensure this condition is met. Since there is no throughput penalty for clocking the data out after the conversion, clocking the data out during the conversion is not recommended. Use of the TAG Input The TAG input pin is used to daisy-chain multiple converters. This is useful for applications where hardware constraints may limit the number of lines needed to interface to a large number of converters. This mode of operation works only using the external clock method of shifting out the data. Figure 13 shows how this feature can be used. R/C, CS and the DATACLK are tied together on both LTC1609s. CS can be grounded if a discontinuous data clock is used. A falling edge on R/C will allow both LTC1609s to capture their respective analog input signals simultaneously. Once the conversion has been completed the external data clock DCLK is started. The MSB from device #1 will be valid after the rising edge of DCLK #1. Once the LSB from device #1 has been shifted out on the rising edge of DCLK #16, a null 1609fa 17 LTC1609 U W U U APPLICATIO S I FOR ATIO t12 0 t14 t13 1 2 3 4 16 17 18 t19 EXTERNAL DATACLK CS t16 t15 R/C t2 t3 BUSY t17 SYNC t12 DATA t23 TAG TAG0 t18 B15 (MSB) t24 TAG1 B14 B13 B1 B0 TAG0 TAG1 TAG2 TAG3 TAG15 TAG16 TAG17 TAG18 TAG19 1606 F12 Figure 12. Conversion and Read Timing Using an External Data Clock (EXT/INT Tied High). Read Previous Conversion Result During the Conversion. For Best Performance, Complete Read in Less Than 1.2µs DCLK IN R/C IN CS IN LTC1609 #2 TAG DATA LTC1609 #1 TAG DATA CS CS R/C R/C DCLK DCLK DATA OUT 1609 F13 Figure 13. Two LTC1609s Cascaded Together Using the TAG Input bit will be shifted out on the following clock pulse before the MSB from device #2 becomes available (Figure 14). The reason for this is the MSB from device #2 will not be valid soon enough to meet the minimum setup time of device #1’s TAG input. A minimum of 34 clock pulses are needed to shift out the results from both LTC1609s assuming the data is captured on the falling clock edge. Using the highest frequency permitted for DATACLK (20MHz), a 200kHz throughput can still be achieved. 1609fa 18 LTC1609 U W U U APPLICATIO S I FOR ATIO R/C BUSY 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 DCLK ••• DATA OUT B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 DEVICE DATA #1 B5 B4 B3 B2 B1 B0 NULL BIT B15 B14 B13 B12 B11 DEVICE DATA #2 B10 • • • 1609 F14 Figure 14. Data Output from Cascading Two (CS = Low, TAG (#2) = Low) LTC1609s Together Output Data Format The SB/BTC pin controls the format of the serial digital output word. With the pin tied high the format is straight binary. With the pin tied low the data format is two’s complement. See Table 1c. Board Layout, Power Supplies and Decoupling Wire wrap boards are not recommended for high resolution or high speed A/D converters. To obtain the best performance from the LTC1609, a printed circuit board is required. Layout for the printed circuit board should ensure the digital and analog signal lines are separated as much as possible. In particular, care should be taken not to run any digital track alongside an analog signal track or underneath the ADC. The analog input should be screened by AGND. Pay particular attention to the design of the analog and digital ground planes. Placing the bypass capacitor as close as possible to the VDIG and VANA pins, the REF pin and reference buffer output is very important. Low impedance common returns for these bypass capacitors are essential to low noise operation of the ADC, and the foil width for these tracks should be as wide as possible. Also, since any potential difference in grounds between the signal source and ADC appears as an error voltage in series with the input signal, attention should be paid to reducing the ground circuit impedance as much as possible. The digital output latches and the onboard sampling clock have been placed on the digital ground plane. The two ground planes are tied together at the power supply ground connection. A “postage stamp” (1.6in × 1.5in) evaluation board is available and allows fast in-situ evaluation of the LTC1609. See Figures 15a through 15d, inclusive. 1609fa 19 LTC1609 U W U U APPLICATIO S I FOR ATIO C6 2.2µF E14 GND C4 1000pF C2 1000pF C5 2.2µF C3 1000pF E8 5V E15 R4 E16 R5 E17 R6 C1 10µF R4 200Ω 1 2 R5 100Ω R6 33k 3 4 E1 R3IN 5 6 7 8 9 10 11 5V 12 JP1 13 14 JP2 R1IN VDIG AGND1 VANA R2IN PWRD R3IN BUSY NC LTC1609 CS CAP NC REF NC NC R/C AGND2 NC NC TAG NC NC SB/BTC DATA EXT/INT DATACLK DGND SYNC 28 C7 0.1µF 27 R1 10k 26 25 24 E3 BUSY R2 10k E13 PWRD E12 CS 23 22 21 E4 RC 20 R3 10k 19 E11 TAG 18 17 16 E6 DATACLK 15 E5 DATA E7 SYNC E10 GND E2 GND 1609 F15a Figure 15a. LTC1609 “Postage Stamp” Evaluation Circuit Schematic 1609fa 20 LTC1609 U W U U APPLICATIO S I FOR ATIO Figure 15b. LTC1609 “Postage Stamp” Evaluation Board Silkscreen (2× Actual Size) Figure 15c. LTC1609 “Postage Stamp” Evaluation Board Top Metal Layer (2× Actual Size) Figure 15d. LTC1609 “Postage Stamp” Evaluation Board Bottom Metal Layer (2× Actual Size) 1609fa 21 LTC1609 U W U U APPLICATIO S I FOR ATIO LTC1609 200Ω R1IN LTC1609 R1IN VIN 200Ω AGND1 33.2k 0V TO 10V 100Ω VIN AGND1 ±10V R2IN R2IN 100Ω LTC1662 CS/LD SCK SDI 5V CS/LD VOUTA GND SCK VCC SDI VOUTB REF OFFSET TRIM R3IN CAP GAIN TRIM 787k + + REF LTC1662 CS/LD SCK SDI 5V CS/LD VOUTA GND SCK VCC SDI VOUTB REF 33.2k OFFSET TRIM CAP GAIN TRIM 787k + 2.2µF 2.2µF R3IN + 2.2µF 2.2µF AGND2 0.1µF AGND2 0.1µF LTC1609 LTC1609 R1IN R1IN 200Ω 200Ω AGND1 0V TO 5V LTC1662 CS/LD VOUTA GND SCK VCC SDI VOUTB REF OFFSET TRIM VIN 100Ω VIN R3IN CAP GAIN TRIM 787k + + 2.2µF REF LTC1662 CS/LD SCK SDI 5V CS/LD VOUTA GND SCK VCC SDI VOUTB REF OFFSET TRIM R2IN + R3IN 2.2µF CAP GAIN TRIM 787k + 2.2µF AGND2 200Ω AGND2 0.1µF LTC1609 R1IN VIN AGND1 AGND1 100Ω ±3.3V 100Ω LTC1609 200Ω R1IN VIN R2IN LTC1662 CS/LD SCK SDI 5V CS/LD VOUTA GND SCK VCC SDI VOUTB REF OFFSET TRIM R2IN 33.2k 33.2k R3IN + GAIN TRIM 2.2µF CAP 787k + REF LTC1662 CS/LD SCK SDI 5V CS/LD VOUTA GND SCK VCC SDI VOUTB REF OFFSET TRIM + R3IN 2.2µF CAP GAIN TRIM 2.2µF 0.1µF REF 2.2µF 0.1µF 0V TO 4V AGND1 33.2k ±5V 100Ω 33.2k R2IN CS/LD SCK SDI 5V REF 787k + REF 2.2µF AGND2 0.1µF AGND2 1609 F16 OFFSET/GAIN CIRCUITS FOR UNIPOLAR INPUT RANGES OFFSET/GAIN CIRCUITS FOR BIPOLAR INPUT RANGES Figure 16. Digitally-Controlled Offset and Full-Scale Adjust Circuits Using the LTC1662 Dual 10-Bit VOUT DAC (Adjust Offset First at 0V, Then Adjust Gain) 1609fa 22 LTC1609 U PACKAGE DESCRIPTIO G Package 28-Lead Plastic SSOP (5.3mm) (Reference LTC DWG # 05-08-1640) 10.07 – 10.33* (.397 – .407) 28 27 26 25 24 23 22 21 20 19 18 17 16 15 7.65 – 7.90 (.301 – .311) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 5.20 – 5.38** (.205 – .212) 1.73 – 1.99 (.068 – .078) 0° – 8° .13 – .22 (.005 – .009) .55 – .95 (.022 – .037) NOTE: 1. CONTROLLING DIMENSION: MILLIMETERS MILLIMETERS 2. DIMENSIONS ARE IN (INCHES) .65 (.0256) BSC .25 – .38 (.010 – .015) .05 – .21 (.002 – .008) G28 SSOP 0501 3. DRAWING NOT TO SCALE *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED .152mm (.006") PER SIDE **DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED .254mm (.010") PER SIDE 1609fa Information furnished by Linear Technology Corporation is believed to be accurate and reliable. However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. 23 LTC1609 U PACKAGE DESCRIPTIO SW Package 20-Lead Plastic Small Outline (Wide .300 Inch) (Reference LTC DWG # 05-08-1620) 0.496 – 0.512* (12.598 – 13.005) 20 19 18 17 16 15 14 13 12 11 0.394 – 0.419 (10.007 – 10.643) NOTE 1 0.291 – 0.299** (7.391 – 7.595) 2 1 3 4 5 6 7 8 9 10 0.037 – 0.045 (0.940 – 1.143) 0.093 – 0.104 (2.362 – 2.642) 0.010 – 0.029 × 45° (0.254 – 0.737) 0° – 8° TYP 0.009 – 0.013 (0.229 – 0.330) NOTE 1 0.016 – 0.050 (0.406 – 1.270) 0.050 (1.270) BSC 0.004 – 0.012 (0.102 – 0.305) 0.014 – 0.019 (0.356 – 0.482) TYP S20 (WIDE) 1098 NOTE: 1. PIN 1 IDENT, NOTCH ON TOP AND CAVITIES ON THE BOTTOM OF PACKAGES ARE THE MANUFACTURING OPTIONS. THE PART MAY BE SUPPLIED WITH OR WITHOUT ANY OF THE OPTIONS *DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE RELATED PARTS PART NUMBER DESCRIPTION COMMENTS LTC1417 Low Power 400ksps 14-Bit ADC 20mW, Single 5V or ±5V, Serial I/O LTC1418 Low Power 200ksps 14-Bit ADC 15mW, Single 5V or ±5V, Serial/Parallel I/O LTC1595/LTC1596 16-Bit Mulitplying DACs Low Glitch, Serial I/O, SO-8/S16 Packages LTC1597 16-Bit Mulitplying DAC 4-Quadrant Resistors On-Chip, Low Glitch, Parallel I/O LTC1604 16-Bit 333ksps Sampling ADC ±2.5V Input, 90dB SINAD, 100dB THD, Parallel I/O LTC1605 Low Power 100ksps 16-Bit ADC Single 5V, ±10V Input LTC1605-1 Low Power 100ksps 16-Bit ADC Single 5V, 0V to 4V Input LTC1605-2 Low Power 100ksps 16-Bit ADC Single 5V, ±4V Input LTC1606 Low Power 250ksps 16-Bit ADC Single 5V, ±10V Input, Parallel I/O LTC1608 16-Bit 500ksps Sampling ADC ±2.5V Input, Pin Compatible with LTC1604 LTC1650 16-Bit ±5V Voltage Output DAC Low Glitch, 4µs Settling Time, Serial I/O LTC1655/LTC1655L 16-Bit Single 5V/3V Voltage Output DACs SO-8 Package, Micropower, Serial I/O 1609fa 24 Linear Technology Corporation LT/TP 0302 1.5K REV A • PRINTED IN THE USA 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com  LINEAR TECHNOLOGY CORPORATION 2000