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| LTC1418 Low Power, 14-Bit, 200ksps ADC with Serial and Parallel I/O FEATURES s s s s s s s s s s s s DESCRIPTION The LTC (R)1418 is a low power, 200ksps, 14-bit A/D converter. Data output is selectable for 14-bit parallel or serial format. This versatile device can operate from a single 5V or 5V supply. An onboard high performance sample-and-hold, a precision reference and internal timing minimize external circuitry requirements. The low 15mW power dissipation is made even more attractive with two user selectable power shutdown modes. The LTC1418 converts 0V to 4.096V unipolar inputs from a single 5V supply and 2.048V bipolar inputs from 5V supplies. DC specs include 1.25LSB INL, 1LSB DNL and no missing codes over temperature. Outstanding AC performance includes 82dB S/(N + D) and 94dB THD at the Nyquist input frequency of 100kHz. The flexible output format allows either parallel or serial I/O. The SPI/MICROWIRETM compatible serial I/O port can operate as either master or slave and can support clock frequencies from DC to 10MHz. A separate convert start input and a data ready signal (BUSY) allow easy control of conversion start and data transfer. , LTC and LT are registered trademarks of Linear Technology Corporation. MICROWIRE is a trademark of National Semiconductor Corporation. Single Supply 5V or 5V Operation Sample Rate: 200ksps 1.25LSB INL and 1LSB DNL Max Power Dissipation: 15mW (Typ) Parallel or Serial Data Output No Missing Codes Over Temperature Power Shutdown: Nap and Sleep External or Internal Reference Differential High Impedance Analog Input Input Range: 0V to 4.096V or 2.048V 81.5dB S/(N + D) and - 94dB THD at Nyquist 28-Pin Narrow PDIP and SSOP Packages APPLICATIONS s s s s s s Remote Data Acquisition Battery Operated Systems Digital Signal Processing Isolated Data Acquisition Systems Audio and Telecom Processing Medical Instrumentation TYPICAL APPLICATION Low Power, 200kHz, 14-Bit Sampling A/D Converter 5V 10F VDD LTC1418 AIN+ S/H AIN- 4.096V REFCOMP 10F BUFFER 14-BIT ADC 14 SELECTABLE SERIAL/ PARALLEL PORT D5 D4 (EXTCLKIN) D3 (SCLK) D2 (CLKOUT) D1 (DOUT) D0 (EXT/INT) BUSY CS RD CONVST SHDN SER/PAR D13 1.0 0.5 INL (LSBs) -0.5 8k VREF 1F AGND VSS (0V OR - 5V) DGND 1418 TA02 1418 TA01 2.5V REFERENCE TIMING AND LOGIC -1.0 0 4096 8192 OUTPUT CODE 12288 16384 U 0 U U Typical INL Curve 1 LTC1418 ABSOLUTE MAXIMUM RATINGS (Notes 1, 2) PACKAGE/ORDER INFORMATION TOP VIEW AIN+ AIN - VREF REFCOMP AGND D13 (MSB) D12 D11 D10 1 2 3 4 5 6 7 8 9 28 VDD 27 VSS 26 BUSY 25 CS 24 CONVST 23 RD 22 SHDN 21 SER/PAR 20 D0 (EXT/INT) 19 D1 (DOUT) 18 D2 (CLKOUT) 17 D3 (SCLK) 16 D4 (EXTCLKIN) 15 D5 N PACKAGE 28-LEAD NARROW PDIP Supply Voltage (VDD) ................................................. 6V Negative Supply Voltage (VSS) Bipolar Operation Only ........................... - 6V to GND Total Supply Voltage (VDD to VSS) Bipolar Operation Only ....................................... 12V Analog Input Voltage (Note 3) Unipolar Operation .................. - 0.3V to (VDD + 0.3V) Bipolar Operation........... (VSS - 0.3V) to (VDD + 0.3V) Digital Input Voltage (Note 4) Unipolar Operation ................................- 0.3V to 10V Bipolar Operation.........................(VSS - 0.3V) to 10V Digital Output Voltage Unipolar Operation .................. - 0.3V to (VDD + 0.3V) Bipolar Operation........... (VSS - 0.3V) to (VDD + 0.3V) Power Dissipation.............................................. 500mW Operation Temperature Range LTC1418C................................................ 0C to 70C LTC1418I............................................ - 40C to 85C Storage Temperature Range ................. - 65C to 150C Lead Temperature (Soldering, 10 sec).................. 300C ORDER PART NUMBER LTC1418ACG LTC1418ACN LTC1418AIG LTC1418AIN LTC1418CG LTC1418CN LTC1418IG LTC1418IN D9 10 D8 11 D7 12 D6 13 DGND 14 G PACKAGE 28-LEAD PLASTIC SSOP TJMAX = 110C, JA = 95C/ W (G) TJMAX = 110C, JA = 100C/ W (N) Consult factory for Military grade parts. CO VERTER CHARACTERISTICS PARAMETER Resolution (No Missing Codes) Integral Linearity Error Differential Linearity Error Offset Error Full-Scale Error Full-Scale Tempco (Note 8) Internal Reference External Reference = 2.5V (Note 7) CONDITIONS With internal reference (Notes 5, 6) unless otherwise noted. MIN q q q q LTC1418 TYP MAX 0.8 0.7 5 10 5 2 1.5 20 60 30 MIN 14 LTC1418A TYP MAX 0.5 0.35 2 20 5 10 20 1 1.25 1 10 60 15 45 UNITS Bits LSB LSB LSB LSB LSB ppm/C ppm/C ppm/C 13 IOUT(REF) = 0, Internal Reference, Commercial IOUT(REF) = 0, Internal Reference, Industrial IOUT(REF) = 0, External Reference q 15 5 A ALOG I PUT SYMBOL PARAMETER VIN IIN CIN tACQ (Note 5) CONDITIONS 4.75V VDD 5.25V (Unipolar) 4.75V VDD 5.25V, - 5.25V VSS - 4.75V (Bipolar) CS = High Between Conversions (Sample Mode) During Conversions (Hold Mode) Commercial Industrial q q q q q MIN TYP 0 to 4.096 2.048 MAX UNITS V V Analog Input Range (Note 9) Analog Input Leakage Current Analog Input Capacitance Sample-and-Hold Acquisition Time 1 25 5 300 300 1000 1000 2 U W U U WW W U U U A pF pF ns ns LTC1418 DY A IC ACCURACY SYMBOL PARAMETER S/(N + D) Signal-to-Noise Plus Distortion Ratio THD SFDR IMD Total Harmonic Distortion Spurious Free Dynamic Range Intermodulation Distortion Full Power Bandwidth Full Linear Bandwidth I TER AL REFERE CE CHARACTERISTICS PARAMETER VREF Output Voltage VREF Output Tempco VREF Line Regulation VREF Output Resistance CONDITIONS IOUT = 0 IOUT = 0, Commercial IOUT = 0, Industrial 4.75V VDD 5.25V - 5.25V VSS - 4.75V 0.1mA IOUT 0.1mA DIGITAL I PUTS AND OUTPUTS SYMBOL PARAMETER VIH VIL IIN CIN VOH VOL IOZ COZ ISOURCE ISINK High Level Input Voltage Low Level Input Voltage Digital Input Current Digital Input Capacitance High Level Output Voltage Low Level Output Voltage Hi-Z Output Leakage D13 to D0 Hi-Z Output Capacitance D13 to D0 Output Source Current Output Sink Current CONDITIONS VDD = 5.25V VDD = 4.75V POWER REQUIRE E TS SYMBOL PARAMETER VDD VSS IDD Positive Supply Voltage (Notes 10, 11) Negative Supply Voltage (Note 10) Positive Supply Current ISS Negative Supply Current Nap Mode Sleep Mode PDIS Power Dissipation UW U U U WU U (Note 5) CONDITIONS 97.5kHz Input Signal 100kHz Input Signal, First 5 Harmonics 100kHz Input Signal fIN1 = 97.7kHz, fIN2 = 104.2kHz S/(N + D) 77dB q q q MIN 79 86 TYP 81.5 - 94 95 - 90 5 0.5 MAX - 86 UNITS dB dB dB dB MHz MHz U (Note 5) MIN 2.480 q TYP 2.500 10 20 0.05 0.05 8 MAX 2.520 45 UNITS V ppm/C ppm/C LSB/ V LSB/ V k (Note 5) MIN q q q TYP MAX 0.8 10 UNITS V V A pF V V 2.4 VIN = 0V to VDD VDD = 4.75V, IO = - 10A VDD = 4.75V, IO = - 200A VDD = 4.75V, IO = 160A VDD = 4.75V, IO = 1.6mA VOUT = 0V to VDD, CS High CS High (Note 9) VOUT = 0V VOUT = VDD 1.4 4.74 q q q q 4.0 0.05 0.10 0.4 10 15 - 10 10 V V A pF mA mA (Note 5) CONDITIONS Bipolar Only (VSS = 0V for Unipolar) Unipolar, RD High (Note 5) Bipolar, RD High (Note 5) SHDN = 0V, CS = 0V (Note 12) SHDN = 0V, CS = 5V (Note 12) Bipolar, RD High (Note 5) SHDN = 0V, CS = 0V (Note 12) SHDN = 0V, CS = 5V (Note 12) Unipolar Bipolar q q MIN 4.75 - 4.75 TYP MAX 5.25 - 5.25 UNITS V V mA mA A A mA A A mW mW Nap Mode Sleep Mode 3.0 3.9 570 2 1.4 0.1 0.1 15.0 26.5 4.3 4.5 q 1.8 q q 21.5 31.5 3 LTC1418 TI I G CHARACTERISTICS SYMBOL fSAMPLE(MAX) tCONV tACQ tACQ + tCONV t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 PARAMETER Maximum Sampling Frequency Conversion Time Acquisition Time Acquisition Plus Conversion Time CS to RD Setup Time CS to CONVST Setup Time CS to SHDN Setup Time to Ensure Nap Mode SHDN to CONVST Wake-Up Time from Nap Mode CONVST Low Time CONVST to BUSY Delay Data Ready Before BUSY q t11 t12 t13 t14 t15 fSCLK fEXTCLKIN tdEXTCLKIN tH SCLK tL SCLK tH EXTCLKIN tL EXTCLKIN The q denotes specifications which apply over the full operating temperature range; all other limits and typicals TA = 25C. 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 and AGND wired together (unless otherwise noted). Note 3: When these pin voltages are taken below VSS or above VDD, they will be clamped by internal diodes. This product can handle input currents greater than 100mA below VSS or above VCC without latchup. Note 4: When these pin voltages are taken below VSS they will be clamped by internal diodes. This product can handle input currents greater than 100mA below VSS without latchup. These pins are not clamped to VDD. Note 5: VDD = 5V, VSS = 0V or - 5V, fSAMPLE = 200kHz, tr = tf = 5ns unless otherwise specified. Note 6: Linearity, offset and full-scale specifications apply for a singleended input with AIN- grounded. 4 UW (Note 5) CONDITIONS q q q q MIN 200 TYP 3.4 0.3 3.7 MAX 4 1 5 UNITS kHz s s s ns ns ns (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) (Note 10) (Notes 10, 11) CL = 25pF q q q 0 40 40 500 40 35 20 15 500 -5 15 30 40 40 55 20 25 30 35 70 ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns q q Delay Between Conversions Wait Time RD After BUSY Data Access Time After RD (Note 10) CL = 25pF q q q CL = 100pF q 20 8 Bus Relinquish Time Commercial Industrial RD Low Time CONVST High Time Delay Time, SCLK to DOUT Valid Time from Previous Data Remain Valid After SCLK Shift Clock Frequency External Conversion Clock Frequency Delay Time, CONVST to External Conversion Clock Input SCLK High Time SCLK Low Time EXTCLKIN High Time EXTCLKIN Low Time CL = 25pF (Note 9) CL = 25pF (Note 9) (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) (Notes 9, 10) 10 20 q q q q q t10 40 35 15 0 0.03 25 12.5 4.5 533 70 ns ns MHz MHz s ns ns 250 250 ns ns Note 7: Integral nonlinearity is defined as the deviation of a code from a straight line passing through the actual endpoints of the transfer curve. The deviation is measured from the center of the quantization band. Note 8: Bipolar offset is the offset voltage measured from - 0.5LSB when the output code flickers between 0000 0000 0000 00 and 1111 1111 1111 11. Note 9: Guaranteed by design, not subject to test. Note 10: Recommended operating conditions. Note 11: The falling edge of CONVST starts a conversion. If CONVST returns high at a critical point during the conversion, it can create small errors. For best performance ensure that CONVST returns high either within 2.1s after the conversion starts or after BUSY rises. Note 12: Pins 16 (D4/EXTCLKIN), 17 (D3/SCLK) and 20 (DO/EXT/INT) at 0V or 5V. See Power Shutdown. LTC1418 TYPICAL PERFORMANCE CHARACTERISTICS Typical INL Curve 1.0 SIGNAL/(NOISE + DISTORTION) (dB) 0.5 DNL ERROR (LSBs) INL (LSBs) 0 -0.5 -1.0 0 4096 8192 OUTPUT CODE 1418 TA02 12288 Signal-to-Noise Ratio vs Input Frequency AMPLITUDE (dB BELOW THE FUNDAMENTAL) 90 80 SIGNAL-TO -NOISE RATIO (dB) SPURIOUS-FREE DYNAMIC RANGE (dB) 70 60 50 40 30 20 10 0 1k 10k 100k INPUT FREQUENCY (Hz) 1M 1418 G02 Nonaveraged, 4096 Point FFT, Input Frequency = 10kHz 0 -20 AMPLITUDE (dB) fSAMPLE = 200kHz fIN = 9.9609375kHz SFDR = 99.32 SINAD = 82.4 AMPLITUDE (dB) -40 -60 -80 -40 -60 -80 AMPLITUDE (dB) -100 -120 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 F02a UW Differential Nonlinearity vs Output Code 1.0 90 80 70 60 50 40 30 20 10 0 S/(N + D) vs Input Frequency and Amplitude VIN = 0dB VIN = -20dB 0.5 0 - 0.5 VIN = -60dB -1.0 16384 0 4096 12288 8192 OUTPUT CODE 16384 1418 G06 1k 100k 10k INPUT FREQUENCY (Hz) 1M 1418 G01 Distortion vs Input Frequency 0 -20 -40 -60 -80 -100 -120 3RD THD 2ND 0 -20 -40 -60 -80 -100 Spurious-Free Dynamic Range vs Input Frequency 1k 10k 100k INPUT FREQUENCY (Hz) 1M 1418 G03 -120 10k 100k INPUT FREQUENCY (Hz) 1M 1418 G04 Nonaveraged, 4096 Point FFT, Input Frequency = 100kHz 0 -20 fSAMPLE = 200kHz fIN = 97.509765kHz SFDR = 94.29 SINAD = 81.4 0 - 20 - 40 - 60 - 80 Intermodulation Distortion Plot fSAMPLE = 200kHz fIN1 = 97.65625kHz fIN2 = 104.248046kHz -100 -120 -100 -120 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 F02b 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 G05 5 LTC1418 TYPICAL PERFORMANCE CHARACTERISTICS Power Supply Feedthrough vs Ripple Frequency 0 90 CHANGE IN OFFSET VOLTAGE (LSB) 80 COMMON MODE REJECTION (dB) -20 DISTORTION (dB) -40 -60 -80 VSS VDD DGND -100 -120 1k 10k 100k 1M FREQUENCY (Hz) VDD Supply Current vs Temperature (Unipolar Mode) 5 VDD SUPPLY CURRENT (mA) VDD SUPPLY CURRENT (mA) VSS SUPPLY CURRENT (mA) 4 3 2 1 0 -75 -50 -25 0 25 50 75 100 125 150 TEMPERATURE (C) 1418 G11 VDD Supply Current vs Sampling Frequency (Unipolar Mode) 5 5 VDD SUPPLY CURRENT (mA) VDD SUPPLY CURRENT (mA) VSS SUPPLY CURRENT (mA) 4 3 2 1 0 0 100 150 200 250 50 SAMPLING FREQUENCY (kHz) 300 6 UW 1418 G08 Input Common Mode Rejection vs Input Frequency 10 9 8 7 6 5 4 3 2 1 0 1 10 100 1k 10k 100k INPUT FREQUENCY (Hz) 1M Input Offset Voltage Shift vs Source Resistance 70 60 50 40 30 20 10 10M 0 10 100 100k 1k 10k INPUT SOURCE RESISTANCE () 1M 1418 G10 1418 G09 VDD Supply Current vs Temperature (Bipolar Mode) 5 2.0 1.8 VSS Supply Current vs Temperature (Bipolar Mode) 4 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 3 2 1 0 -75 -50 -25 0 25 50 75 100 125 150 TEMPERATURE (C) 1418 G12 0 -75 -50 -25 0 25 50 75 100 125 150 TEMPERATURE (C) 1418 G13 VDD Supply Current vs Sampling Frequency (Bipolar Mode) 2.0 1.8 4 1.6 1.4 1.2 1.0 0.8 0.6 0.4 0.2 0 0 50 150 200 250 100 SAMPLING FREQUENCY (kHz) 300 0 VSS Supply Current vs Sampling Frequency (Bipolar Mode) 3 2 1 0 50 150 200 250 100 SAMPLING FREQUENCY (kHz) 300 1418 G14 1418 G15 1418 G16 LTC1418 PIN FUNCTIONS AIN+ (Pin 1): Positive Analog Input. AIN- (Pin 2): Negative Analog Input. VREF (Pin 3): 2.50V Reference Output. Bypass to AGND with 1F. REFCOMP (Pin 4): 4.096V Reference Bypass Pin. Bypass to AGND with 10F tantalum in parallel with 0.1F ceramic. AGND (Pin 5): Analog Ground. D13 to D6 (Pins 6 to 13): Three-State Data Outputs (Parallel). D13 is the most significant bit. DGND (Pin 14): Digital Ground for Internal Logic. Tie to AGND. D5 (Pin 15): Three-State Data Output (Parallel). D4 (EXTCLKIN) (Pin 16): Three-State Data Output (Parallel). Conversion clock input (serial) when Pin 20 (EXT/INT) is tied high. D3 (SCLK) (Pin 17): Three-State Data Output (Parallel). Data clock input (serial). D2 (CLKOUT) (Pin 18): Three-State Data Output (Parallel). Conversion clock output (serial). D1 (DOUT) (Pin 19): Three-State Data Output (Parallel). Serial data output (serial). D0 (EXT/INT) (Pin 20): Three-State Data Output (Parallel). Conversion clock selector (serial). An input low enables the internal conversion clock. An input high indicates an external conversion clock will be assigned to Pin 16 (EXTCLKIN). SER/PAR (Pin 21): Data Output Mode. SHDN (Pin 22): Power Shutdown Input. Low selects shutdown. Shutdown mode selected by CS. CS = 0 for nap mode and CS = 1 for sleep mode. RD (Pin 23): Read Input. This enables the output drivers when CS is low. CONVST (Pin 24): Conversion Start Signal. This active low signal starts a conversion on its falling edge. CS (Pin 25): Chip Select. This input must be low for the ADC to recognize the CONVST and RD inputs. CS also sets the shutdown mode when SHDN goes low. CS and SHDN low select the quick wake-up nap mode. CS high and SHDN low select sleep mode. BUSY (Pin 26): The BUSY Output Shows the Converter Status. It is low when a conversion is in progress. VSS (Pin 27): Negative Supply, - 5V for Bipolar Operation. Bypass to AGND with 10F tantalum in parallel with 0.1F ceramic. Analog ground for unipolar operation. VDD (Pin 28): 5V Positive Supply. Bypass to AGND with 10F tantalum in parallel with 0.1F ceramic. TEST CIRCUITS Load Circuits for Access Timing 5V 1k DBN 1k DGND A) HI-Z TO VOH AND VOL TO VOH CL DBN CL DGND B) HI-Z TO VOL AND VOH TO VOL 1418 TC01 U U U Load Circuits for Output Float Delay 5V 1k DBN 1k 30pF DBN 30pF A) VOH TO HI-Z B) VOL TO HI-Z 1418 TC02 7 LTC1418 FUNCTIONAL BLOCK DIAGRA CSAMPLE AIN+ CSAMPLE AIN- VREF 2.5V 8k 2.5V REF ZEROING SWITCHES VDD: 5V VSS: 0V FOR UNIPOLAR MODE - 5V FOR BIPOLAR MODE REF AMP 14-BIT CAPACITIVE DAC REFCOMP AGND DGND 4.096V SUCCESSIVE APPROXIMATION REGISTER INTERNAL CLOCK 14 SHIFT REGISTER * * * D13 D0 D3/(SCLK) MUX CONTROL LOGIC D1/(DOUT) 1418 BD D4 (EXTCLKIN) D0 (EXT/INT) SHDN CONVST RD CS SER/PAR D2/(CLKOUT) BUSY NOTE: PIN NAMES IN PARENTHESES REFER TO SERIAL MODE APPLICATIONS INFORMATION CONVERSION DETAILS The LTC1418 uses a successive approximation algorithm and an internal sample-and-hold circuit to convert an analog signal to a 14-bit parallel or 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 Digital Interface section for the data format). Conversion start is controlled by the CS and CONVST inputs. At the start of the conversion the successive approximation register (SAR) is reset. Once a conversion cycle has begun it cannot be restarted. During the conversion, the internal differential 14-bit capacitive DAC output is sequenced by the SAR from the most significant bit (MSB) to the least significant bit (LSB). AIN+ SAMPLE CSAMPLE+ HOLD SAMPLE CSAMPLE HOLD CDAC+ - 8 W + COMP U W U U U U - ZEROING SWITCHES HOLD HOLD AIN - + VDAC+ CDAC- COMP - VDAC- 14 SAR OUTPUT LATCH D13 D0 1418 F01 Figure 1. Simplified Block Diagram LTC1418 APPLICATIONS INFORMATION Referring to Figure 1, the AIN+ and AIN- inputs are connected to the sample-and-hold capacitors (CSAMPLE) during the acquire phase and the comparator offset is nulled by the zeroing switches. In this acquire phase, a minimum delay of 1s will provide enough time for the sample-andhold capacitors to acquire the analog signal. During the convert phase the comparator zeroing switches open, putting the comparator into compare mode. The input switches the CSAMPLE capacitors to ground, transferring the differential analog input charge onto the summing junction. This input charge is successively compared with the binary weighted charges supplied by the differential capacitive DAC. Bit decisions are made by the high speed comparator. At the end of a conversion, the differential DAC output balances the AIN+ and AIN- input charges. The SAR contents (a 14-bit data word) which represent the difference of AIN+ and AIN- are loaded into the 14-bit output latches. DYNAMIC PERFORMANCE The LTC1418 has excellent high speed sampling capability. 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 2 shows a typical LTC1418 FFT plot. Signal-to-Noise Ratio The signal-to-noise plus distortion ratio [S/(N + D)] 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 2a shows a typical spectral content with a 200kHz sampling rate and a 10kHz input. The dynamic performance is excellent for input frequencies up to and beyond the Nyquist limit of 100kHz. Effective Number of Bits The effective number of bits (ENOBs) is a measurement of the resolution of an ADC and is directly related to the S/(N + D) by the equation: N = [S/(N + D) - 1.76]/6.02 where N is the effective number of bits of resolution and S/(N + D) is expressed in dB. At the maximum sampling rate of 200kHz the LTC1418 maintains near ideal ENOBs up to the Nyquist input frequency of 100kHz (refer to Figure 3). 0 -20 fSAMPLE = 200kHz fIN = 9.9609375kHz SFDR = 99.32 SINAD = 82.4 AMPLITUDE (dB) AMPLITUDE (dB) U W U U -40 -60 -80 -100 -120 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 F02a Figure 2a. LTC1418 Nonaveraged, 4096 Point FFT, Input Frequency = 10kHz 0 -20 -40 -60 -80 fSAMPLE = 200kHz fIN = 97.509765kHz SFDR = 94.29 SINAD = 81.4 -100 -120 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 F02b Figure 2b. LTC1418 Nonaveraged, 4096 Point FFT, Input Frequency = 97.5kHz 9 LTC1418 APPLICATIONS INFORMATION 14 13 12 11 EFECTIVE BITS 10 9 8 7 6 5 4 3 2 1k 10k 100k INPUT FREQUENCY (Hz) 1M 1418 F03 Figure 3. Effective Bits and Signal/(Noise + Distortion) vs Input Frequency 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: AMPLITUDE (dB) V22 + V32 + V42 + ...Vn2 V1 where V1 is the RMS amplitude of the fundamental frequency and V2 through Vn are the amplitudes of the second through nth harmonics. THD vs Input Frequency is THD = 20Log 0 -20 -40 -60 -80 -100 -120 3RD THD 2ND AMPLITUDE (dB BELOW THE FUNDAMENTAL) 1k 10k 100k INPUT FREQUENCY (Hz) 1M 1418 G03 Figure 4. Distortion vs Input Frequency 10 U W U U shown in Figure 4. The LTC1418 has good distortion performance up to the Nyquist frequency and beyond. Intermodulation Distortion If the ADC input signal consists of more than one spectral component, the ADC transfer function nonlinearity can produce intermodulation distortion (IMD) in addition to THD. IMD is the change in one sinusoidal input caused by the presence of another sinusoidal input at a different frequency. If two pure sine waves of frequencies fa and fb are applied to the ADC input, nonlinearities in the ADC transfer function can create distortion products at the sum and difference frequencies of mfa nfb, where m and n = 0, 1, 2, 3, etc. For example, the 2nd order IMD terms include (fa + fb). If the two input sine waves are equal in magnitude, the value (in decibels) of the 2nd order IMD products can be expressed by the following formula: IMD fa + fb = 20Log 0 - 20 - 40 - 60 - 80 fSAMPLE = 200kHz fIN1 = 97.65625kHz fIN2 = 104.248046kHz ( ) Amplitude at fa + fb Amplitude at fa ( ) -100 -120 0 10 20 30 40 50 60 70 80 90 100 FREQUENCY (kHz) 1418 G05 Figure 5. Intermodulation Distortion Plot Peak Harmonic or Spurious Noise The peak harmonic or spurious noise is the largest spectral component excluding the input signal and DC. This value is expressed in decibels relative to the RMS value of a full-scale input signal. LTC1418 APPLICATIONS INFORMATION Full-Power and Full-Linear Bandwidth The full-power bandwidth is that input frequency at which the amplitude of the reconstructed fundamental is reduced by 3dB for a full-scale input signal. The full-linear bandwidth is the input frequency at which the S/(N + D) has dropped to 77dB (12.5 effective bits). The LTC1418 has been designed to optimize input bandwidth, allowing the ADC to undersample input signals with frequencies above the converter's Nyquist Frequency. The noise floor stays very low at high frequencies; S/(N + D) becomes dominated by distortion at frequencies far beyond Nyquist. DRIVING THE ANALOG INPUT The differential analog inputs of the LTC1418 are easy to drive. The inputs may be driven differentially or as a singleended input (i.e., the AIN- input is grounded). The AIN+ and A IN- inputs are sampled at the same instant. Any unwanted signal that is common mode to both inputs will be reduced by the common mode rejection of the sampleand-hold circuit. The inputs draw only one small current spike while charging the sample-and-hold capacitors at the end of conversion. During conversion, the analog inputs draw only a small leakage current. If the source impedance of the driving circuit is low then the LTC1418 inputs can be driven directly. As source impedance increases so will acquisition time (see Figure 6). For minimum acquisition time, with high source impedance, a buffer amplifier must be used. The only requirement is that the amplifier driving the analog input(s) must settle after the small current spike before the next conversion starts -- 1s for full throughput rate. Choosing an Input Amplifier Choosing an input amplifier is easy if a few requirements are taken into consideration. First, choose an amplifier that has a low output impedance (<100) at the closed-loop bandwidth frequency. For example, if an amplifier is used in a gain of 1 and has a closed-loop bandwidth of 10MHz, then the output impedance at 10MHz must be less than 100. The second requirement is that the closed-loop bandwidth must be greater than 5MHz to ensure adequate small-signal settling for full throughput rate. If slower op amps are used, more settling time can be provided by increasing the time between conversions. The best choice for an op amp to drive the LTC1418 will depend on the application. Generally, applications fall into two categories: AC applications where dynamic specifications are most critical and time domain applications where DC accuracy and settling time are most critical. The following list is a summary of the op amps that are suitable for driving the LTC1418. More detailed information is available in the Linear Technology Databooks and on the LinearViewTM CD-ROM. LT (R)1354: 12MHz, 400V/s Op Amp. 1.25mA maximum supply current. Good AC and DC specifications. Suitable for dual supply application. LT1357: 25MHz, 600V/s Op Amp. 2.5mA maximum supply current. Good AC and DC specifications. Suitable for dual supply application. LT1366/LT1367: Dual/Quad Precision Rail-to-Rail Input and Output Op Amps. 375A supply current per amplifier. 1.8V to 15V supplies. Low input offset voltage: 150V. Good for low power and single supply applications with sampling rates of 20ksps and under. LT1498/LT1499: 10MHz, 6V/s, Dual/Quad Rail-to-Rail Input and Output Op Amps. 1.7mA supply current per 100 ACQUISITION TIME (s) U W U U 10 1 0.1 1 10 100 1k 10k SOURCE RESISTANCE () 100k 1418 F06 Figure 6. tACQ vs Source Resistance LinearView is a trademark of Linear Technology Corporation. 11 LTC1418 APPLICATIONS INFORMATION amplifier. 2.2V to 15V supplies. Good AC performance, input noise voltage = 12nV/Hz (typ). LT1630/LT1631: 30MHz, 10V/s, Dual/Quad Rail-to-Rail Input and Output Precision Op Amps. 3.5mA supply current per amplifier. 2.7V to 15V supplies. Best AC performance, input noise voltage = 6nV/Hz (typ), THD = - 86dB at 100kHz. Input Filtering The noise and the distortion of the input amplifier and other circuitry must be considered since they will add to the LTC1418 noise and distortion. The small-signal bandwidth of the sample-and-hold circuit is 5MHz. Any noise or distortion products that are present at the analog inputs will be summed over this entire bandwidth. Noisy input circuitry should be filtered prior to the analog inputs to minimize noise. A simple 1-pole RC filter is sufficient for many applications. For example, Figure 7 shows a 2000pF capacitor from + AIN to ground and a 100 source resistor to limit the input bandwidth to 800kHz. The 2000pF capacitor also acts as a charge reservoir for the input sample-and-hold and isolates the ADC input from sampling glitch sensitive circuitry. High quality capacitors and resistors should be used since these components can add distortion. NPO and silver mica type dielectric capacitors have excellent linearity. Carbon surface mount resistors can also generate distortion from self heating and from damage that may occur during soldering. Metal film surface mount resistors are much less susceptible to both problems. 100 ANALOG INPUT 2000pF 1 2 3 4 10F 5 AIN+ AIN- VREF LTC1418 REFCOMP AGND 1418 F07 Figure 7. RC Input Filter Figure 8. Using the LT1460 as an External Reference 12 U W U U Input Range The 2.048V and 0V to 4.096V input ranges of the LTC1418 are optimized for low noise and low distortion. Most op amps also perform well over these ranges, allowing direct coupling to the analog inputs and eliminating the need for special translation circuitry. Some applications may require other input ranges. The LTC1418 differential inputs and reference circuitry can accommodate other input ranges often with little or no additional circuitry. The following sections describe the reference and input circuitry and how they affect the input range. INTERNAL REFERENCE The LTC1418 has an on-chip, temperature compensated, curvature corrected, bandgap reference which is factory trimmed to 2.500V. It is internally connected to a reference amplifier and is available at Pin 3. A 8k resistor is in series with the output so that it can be easily overdriven in applications where an external reference is required, see Figure 8. The reference amplifier compensation pin (REFCOMP, Pin 4) must be connected to a capacitor to ground. The reference is stable with capacitors of 1F or greater. For the best noise performance, a 10F in parallel with a 0.1F ceramic is recommended. The VREF pin can be driven with a DAC or other means to provide input span adjustment. The reference should be kept in the range of 2.25V to 2.75V for specified linearity. 5V 1 5V VIN VOUT LT1460 10F ANALOG INPUT 2 3 4 0.1F 5 VDD AIN+ AIN- VREF LTC1418 REFCOMP AGND 1418 F08 LTC1418 APPLICATIONS INFORMATION UNIPOLAR / BIPOLAR OPERATION AND ADJUSTMENT Figure 9a shows the ideal input/output characteristics for the LTC1418. The code transitions occur midway between successive integer LSB values (i.e., 0.5LSB, 1.5LSB, 2.5LSB, ... FS - 1.5LSB). The output code is natural binary with 1LSB = FS/16384 = 4.096V/16384 = 250V. Figure 9b shows the input/output transfer characteristics for the bipolar mode in two's complement format. Unipolar Offset and Full-Scale Error Adjustment In applications where absolute accuracy is important, offset and full-scale errors can be adjusted to zero. Offset error must be adjusted before full-scale error. Figures 10a and 10b show the extra components required for fullscale error adjustment. Zero offset is achieved by adjusting the offset applied to the AIN- input. For zero offset error apply 125V (i.e., 0.5LSB) at the input and adjust the offset at the AIN- input until the output code flickers between 0000 0000 0000 00 and 0000 0000 0000 01. For full-scale adjustment, an input voltage of 4.095625V (FS - 1.5LSBs) is applied to AIN+ and R2 is adjusted until the output code flickers between 1111 1111 1111 10 and 1111 1111 1111 11. Bipolar Offset and Full-Scale Error Adjustment Bipolar offset and full-scale errors are adjusted in a similar fashion to the unipolar case. Again, bipolar offset error must be adjusted before full-scale error. Bipolar offset 111...111 111...110 111...101 OUTPUT CODE 1LSB = FS = 4.096V 16384 16384 111...100 000...011 000...010 000...001 000...000 0V UNIPOLAR ZERO 1 LSB INPUT VOLTAGE (V) FS - 1LSB 1418 F9a Figure 9a. LTC1418 Unipolar Transfer Characteristics 011...111 011...110 BIPOLAR ZERO OUTPUT CODE 000...001 000...000 111...111 111...110 100...001 100...000 -FS/2 FS = 4.096V 1LSB = FS/16384 -1 0V 1 LSB LSB INPUT VOLTAGE (V) FS/2 - 1LSB 1418 F9b Figure 9b. LTC1418 Bipolar Transfer Characteristics U W U U R8 100 ANALOG INPUT R1 50k R7 48k 1 AIN+ AIN- VREF 5V VDD R3 24k R5 R2 47k 50k R4 100 2 3 LTC1418 R6 24k 10F 0.1F 4 5 REFCOMP AGND V SS 1418 F10a Figure 10a. Offset and Full-Scale Adjust Circuit If - 5V Is Not Available -5V ANALOG INPUT R1 50k R3 24k R5 R2 47k 50k R6 24k 10F 0.1F R4 100 1 2 3 4 5 AIN+ AIN- VREF LTC1418 5V VDD REFCOMP AGND V SS * 1418 F10b *ONLY NEEDED IF VSS GOES ABOVE GROUND 1N5817 -5V Figure 10b. Offset and Full-Scale Adjust Circuit If - 5V Is Available 13 LTC1418 APPLICATIONS INFORMATION error adjustment is achieved by adjusting the offset applied to the AIN- input. For zero offset error apply - 125V (i.e., - 0.5LSB) at AIN+ and adjust the offset at the AIN- input until the output code flickers between 0000 0000 0000 00 and 1111 1111 1111 11. For full-scale adjustment, an input voltage of 2.047625V (FS - 1.5LSBs) is applied to AIN+ and R2 is adjusted until the output code flickers between 0111 1111 1111 10 and 0111 1111 1111 11. BOARD LAYOUT AND GROUNDING Wire wrap boards are not recommended for high resolution or high speed A/D converters. To obtain the best performance from the LTC1418, a printed circuit board with ground plane is required. The ground plane under the ADC area should be as free of breaks and holes as possible, such that a low impedance path between all ADC grounds and all ADC decoupling capacitors is provided. It is critical to prevent digital noise from being coupled to the analog input, reference or analog power supply lines. Layout should ensure that 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. An analog ground plane separate from the logic system ground should be established under and around the ADC. Pin 5 (AGND) and Pin 14 (DGND) and all other analog grounds should be connected to this single analog ground plane. The REFCOMP bypass capacitor and the VDD bypass capacitor should also be connected to this analog ground plane. No other digital grounds should be connected to this analog ground plane. Low impedance analog and digital power supply common returns are essential to low noise operation of the ADC and the foil width for these tracks should be as wide as possible. In applications where the ADC data outputs and control signals are connected to a continuously active microprocessor bus, it is possible to get errors in the conversion results. These errors are due to feedthrough from the microprocessor to the successive approximation comparator. The problem can be eliminated by forcing the microprocessor into a wait state during conversion or by using three-state buffers to isolate the ADC data bus. The traces connecting the pins and bypass capacitors must be kept short and should be made as wide as possible. The LTC1418 has differential inputs to minimize noise coupling. Common mode noise on the AIN+ and AIN- leads will be rejected by the input CMRR. The AIN- input can be used as a ground sense for the AIN+ input; the LTC1418 will hold and convert the difference voltage between AIN+ and AIN-. The leads to AIN+ (Pin 1) and AIN- (Pin 2) should be kept as short as possible. In applications where this is not possible, the AIN+ and AIN- traces should be run side by side to equalize coupling. SUPPLY BYPASSING High quality, low series resistance ceramic, 10F bypass capacitors should be used at the VDD and REFCOMP pins. Surface mount ceramic capacitors such as Murata GRM235Y5V106Z016 provide excellent bypassing in a small board space. Alternatively 10F tantalum capacitors in parallel with 0.1F ceramic capacitors can be used. 1 AIN+ AIN- VREF 3 1F REFCOMP 4 10F 2 ANALOG INPUT CIRCUITRY + - ANALOG GROUND PLANE 1418 F11 Figure 11. Power Supply Grounding Practice 14 U W U U LTC1418 AGND 5 VSS 27 10F VDD 28 10F DGND 14 DIGITAL SYSTEM VCC VCC VLOGIC -VIN VIN VOUT D[00:13] D00 D0 D00 D01 D02 D03 D04 D05 D6 D7 R8 R9 D09 D10 D11 D12 D13 R10 R11 R12 R13 D8 D9 D10 D11 D12 D13 D06 D07 D08 D09 D10 D11 D12 D13 D00 D12 D11 D10 16 Q3 Q4 D5 8 9 D6 D7 Q5 Q6 Q7 VLOGIC 14 VCC U7G HC14 GND 7 R23 100k 13 12 U7F HC14 74HC244 74HC244 R20 19k U8E 4 JP7 20 5 U7C HC14 6 1 19 B04 EN1 EN2 DGND EXTCLKIN 12 74HC244 13 U8F 7 B03 SCLK 14 1 9 B01 74HC244 U8B 16 B02 DOUT CLKOUT 74HC244 U8C 6 74HC244 U8D 8 B00 EXT/INT 74HC244 17 U8H 18 U8A 2 J8-5 J8-4 74HC244 15 U8G 5 J8-3 J8-1 J8-2 J8-6 HEADER 6-PIN R21 1k C6 15pF 9 11 U7E HC14 U7D HC14 8 10 15 14 13 12 D09 D08 D07 D06 D01 D02 D03 D04 D4 D05 D06 D07 D08 D09 D13 D10 D11 D12 D13 D13 RDY LED J6-13 J6-14 17 J6-11 J6-12 J6-9 J6-10 J6-7 J6-8 J6-5 J6-6 J6-3 J6-4 J6-1 J6-2 J6-15 J6-16 J6-17 J6-18 D00 D01 D02 D03 D04 D05 D06 D07 D08 D09 D10 D11 D12 D13 D13 RDY DGND DGND HEADER 18-PIN 1418 F12a U2 3 2 3 R0, 1k R1 D1 D2 D3 D4 D5 R2 R3 R4 R5 R6 R7 4 TAB GND C12 0.1F C14 0.1F LT1121-5 +VIN J3 7V TO 15V U1 LT1175-5 VSS 1 R14 20 0.125W J1 -7V TO -15V C7 0.1F C15 0.1F VIN VOUT GND TABGND 2 4 C2 22F 10V C10 10F 10V GND 1 B[00:13] 11 B00 B01 V+ B02 B03 B04 B05 B13 U4 LTC1418 D7 U6 74HC574 1 11 B12 2 3 4 5 6 7 D3 D2 Q2 D1 Q1 D0 18 Q0 19 B11 B10 B09 B08 B07 B06 0E Q7 1 2 3 4 25 24 23 22 U7B 28 26 27 5 14 DGND VSS VCC DUAL JP6 C9 10F 16V C5 10F 16V SINGLE DATA READY VLOGIC VLOGIC SUPPLY SELECT R22 1M D0 AGND 20 B00 D1 VSS 19 B01 D2 BUSY 18 B02 D3 VDD 17 B03 D4 16 B04 HC14 4 21 SER/PAR D5 SHDN 15 B05 D6 RD 13 B06 D7 CONVST 12 B07 D8 CS 11 B08 D9 REFCOMP 10 B09 D10 VREF 9 B10 D11 C13 10F 16V -AIN 8 B11 D12 +AIN 7 B12 D13 6 B13 9 12 D6 Q6 D13 8 13 D5 Q5 7 14 D05 D4 Q4 6 15 D04 D3 Q3 5 16 D03 D2 D08 Q2 4 17 D02 D1 D07 Q1 3 18 D01 D0 Q0 D06 2 19 D00 JP3 R15 51 VOUT 0E D05 VCC C4 0.1F D04 AGND DGND J4 JP2 A+ C11 1000pF C3 VSS 0.1F R18 10k JP4 A- R16 51 APPLICATIONS INFORMATION C8 1F 16V JP1 J7 CLK 1 U7A 2 3 R19 51 HC14 VLOGIC JP5C SHDN JP5B CS JP5A SER/PAR NOTES: UNLESS OTHERWISE SPECIFIED 1. ALL RESISTOR VALUES IN OHMS, 1/10W, 5% 2. ALL CAPACITOR VALUES IN F, 25V, 20% AND IN pF, 50V, 10% U LTC1418 J5 Figure 12a. Suggested Evaluation Circuit Schematic W R17 10k U3 LT1363 27 - 6 3+ 8 1 4 V- U U J2 U5 74HC574 + D01 D02 D03 D15 SS12 1 + D14 SS12 + C1 22F 10V 15 LTC1418 APPLICATIONS INFORMATION U W U U 1418 F12b Figure 12b. Suggested Evaluation Circuit Board-- Component Side Top Silkscreen 1418 F12c Figure 12c. Suggested Evaluation Circuit Board--Top Layer 16 LTC1418 APPLICATIONS INFORMATION Figure 12d. Suggested Evaluation Circuit Board--Solder Side Layout Bypass capacitors must be located as close to the pins as possible. The traces connecting the pins and the bypass capacitors must be kept short and should be made as wide as possible. Example Layout Figures 12a, 12b, 12c and 12d show the schematic and layout of a suggested evaluation board. The layout demonstrates the proper use of decoupling capacitors and ground plane with a 2-layer printed circuit board. DIGITAL INTERFACE The LTC1418 can operate in serial or parallel mode. In parallel mode the ADC is designed to interface with microprocessors as a memory mapped device. The CS and RD control inputs are common to all peripheral memory interfacing. In serial mode only four digital interface lines are required, SCLK, CONVST, EXTCLKIN and DOUT. SCLK, the serial data shift clock can be an external input or supplied by the LTC1418 internal clock. U W U U 1418 F12d Internal Clock The ADC has an internal clock. In parallel output mode the internal clock is always used as the conversion clock. In serial output mode either the internal clock or an external clock may be used as the conversion clock (see Figure 20). The internal clock is factory trimmed to achieve a typical conversion time of 3.4s and a maximum conversion time over the full operating temperature range of 4s. No external adjustments are required, and with the guaranteed maximum acquisition time of 1s, throughput performance of 200ksps is assured. Power Shutdown The LTC1418 provides two power shutdown modes, nap and sleep, to save power during inactive periods. The nap mode reduces the power by 80% and leaves only the digital logic and reference powered up. The wake-up time from nap to active is 500ns (see Figure 13a). In sleep mode all bias currents are shut down and only leakage current remains-- about 2A. Wake-up time from sleep 17 LTC1418 APPLICATIONS INFORMATION mode is much slower since the reference circuit must power up and settle to 0.005% for full 14-bit accuracy. Sleep mode wake-up time is dependent on the value of the capacitor connected to the REFCOMP (Pin 4). The wake-up time is 30ms with the recommended 10F capacitor. Shutdown is controlled by Pin 22 (SHDN); the ADC is in shutdown when it is low. The shutdown mode is selected with Pin 25 (CS); low selects nap (see Figure 13b), high selects sleep. SHDN t4 CONVST 1418 F13a Figure 13a. SHDN to CONVST Wake-Up Timing CS t3 SHDN 1418 F13b Figure 13b. CS to SHDN Timing Conversion Control Conversion start is controlled by the CS and CONVST inputs. A falling edge of CONVST pin will start a conversion after the ADC has been selected (i.e., CS is low, see Figure 14). Once initiated, it cannot be restarted until the conversion is complete. Converter status is indicated by the BUSY output. BUSY is low during a conversion. Data Output The data format is controlled by the SER/PAR input pin; logic low selects parallel output format. In parallel mode the 14-bit data output word D0 to D13 is updated at the end of each conversion on Pins 6 to 13 and Pins 15 to 20. A logic high applied to SER/PAR selects the serial formatted data output and Pins 16 to 20 assume their serial function, Pins 6 to 13 and 15 are in the Hi-Z state. In either parallel 18 U W U U CS t2 CONVST t1 RD 1418 F14 Figure 14. CS to CONVST Set-Up Timing or serial data formats, outputs will be active only when CS and RD are low. Any other combination of CS and RD will three-state the output. In unipolar mode (VSS = 0V) the data will be in straight binary format (corresponding to the unipolar input range). In bipolar mode (VSS = - 5V), the data will be in two's complement format (corresponding to the bipolar input range). Parallel Output Mode Parallel mode is selected with a logic 0 applied to the SER/PAR pin. Figures 15 through 19 show different modes of parallel output operation. In modes 1a and 1b (Figures 15 and 16) CS and RD are both tied low. The falling edge of CONVST starts the conversion. The data outputs are always enabled and data can be latched with the BUSY rising edge. Mode 1a shows operation with a narrow logic low CONVST pulse. Mode 1b shows a narrow logic high CONVST pulse. In mode 2 (Figure 17) CS is tied low. The falling edge of CONVST signal again starts the conversion. Data outputs are in three-state until read by the MPU with the RD signal. Mode 2 can be used for operation with a shared databus. In slow memory and ROM modes (Figures 18 and 19), CS is tied low and CONVST and RD are tied together. The MPU starts the conversion and reads the output with the RD signal. Conversions are started by the MPU or DSP (no external sample clock). In slow memory mode the processor takes RD (= CONVST) low and starts the conversion. BUSY goes low forcing the processor into a wait state. The previous conversion result appears on the data outputs. When the conversion is complete, the new conversion results appear on the data LTC1418 APPLICATIONS INFORMATION CS = RD = 0 tCONV (SAMPLE N) t5 CONVST t6 BUSY t7 DATA DATA (N - 1) DB13 TO DB0 DATA N DB13 TO DB0 DATA (N + 1) DB13 TO DB0 1418 F15 Figure 15. Mode 1a. CONVST Starts a Conversion. Data Outputs Always Enabled (CONVST = ) CS = RD = 0 CONVST t13 tCONV t5 t6 t8 t6 BUSY t7 DATA DATA (N - 1) DB13 TO DB0 DATA N DB13 TO DB0 DATA (N + 1) DB13 TO DB0 1418 F16 Figure 16. Mode 1b. CONVST Starts a Conversion. Data Outputs Always Enabled (CONVST = CS = 0 (SAMPLE N) tCONV t5 CONVST t6 BUSY t9 RD t 10 DATA DATA N DB13 TO DB0 1418 F17 Figure 17. Mode 2. CONVST Starts a Conversion. Data is Read by RD U W U U t8 ) t12 t8 t12 t11 19 LTC1418 APPLICATIONS INFORMATION CS = 0 (SAMPLE N) RD = CONVST t6 BUSY t10 DATA DATA (N - 1) DB13 TO DB0 t7 DATA N DB13 TO DB0 DATA N DB13 TO DB0 DATA (N + 1) DB13 TO DB0 1418 F18 tCONV Figure 18. Slow Memory Mode Timing CS = 0 (SAMPLE N) RD = CONVST t6 BUSY t10 DATA DATA (N - 1) DB13 TO DB0 DATA N DB13 TO DB0 1418 F19 tCONV t11 Figure 19. ROM Mode Timing outputs; BUSY goes high releasing the processor and the processor takes RD (= CONVST) back high and reads the new conversion data. In ROM mode, the processor takes RD (= CONVST) low, starting a conversion and reading the previous conversion result. After the conversion is complete, the processor can read the new result and initiate another conversion. Serial Output Mode Serial output mode is selected when the SER/PAR input pin is high. In this mode, Pins 16 to 20, D0 (EXT/INT), D1 (DOUT), D2 (CLKOUT), D3 (SCLK) and D4 (EXTCLKIN) assume their serial functions as shown in Figure 20. (During this discussion these pins will be referred to by their serial function names: EXT/INT, DOUT, CLKOUT, SCLK and EXTCLKIN.) As in parallel mode, conversions are started by a falling CONVST edge with CS low. After a conversion is completed and the output shift register has been updated, BUSY will go high and valid data will be available on DOUT (Pin 19). This data can be clocked out 20 U W U U t8 t11 t8 either before the next conversion starts or it can be clocked out during the next conversion. To enable the serial data output buffer and shift clock, CS and RD must be low. Figure 20 shows a function block diagram of the LTC1418 in serial mode. There are two pieces to this circuitry: the conversion clock selection circuit (EXT/INT, EXTCLKIN and CLKOUT) and the serial port (SCLK, DOUT, CS and RD). Conversion Clock Selection (Serial Mode) In Figure 20, the conversion clock controls the internal ADC operation. The conversion clock can be either internal or external. By connecting EXT/INT low, the internal clock is selected. This clock generates 16 clock cycles which feed into the SAR for each conversion. To select an external conversion clock, tie EXT/INT high and apply an external conversion clock to EXTCLKIN (Pin 16). (When an external shift clock (SCLK) is used during a conversion, the SCLK should be used as the external conversion clock to avoid the noise generated by the LTC1418 APPLICATIONS INFORMATION *** CLOCK INPUT SHIFT REGISTER 17 23 SCLK* RD CS DATA IN 14 DATA OUT SAR 16 CONVERSION CLOCK CYCLES THREE STATE BUFFER 18 EOC Figure 20. Functional Block Diagram for Serial Mode (SER/PAR = High) asynchronous clocks. To maintain accuracy the external conversion clock frequency must be between 30kHz and 4.5MHz.) The SAR sends an end of conversion signal, EOC, that gates the external conversion clock so that only 16 clock cycles can go into the SAR, even if the external clock, EXTCLKIN, contains more than 16 cycles. When CS and RD are low, these 16 cycles of conversion clock (whether internally or externally generated) will appear on CLKOUT during each conversion and then CLKOUT will remain low until the next conversion. If desired, CLKOUT can be used as a master clock to drive the serial port. Because CLKOUT is running during the conversion, it is important to avoid excessive loading that can cause large supply transients and create noise. For the best performance, limit CLKOUT loading to 20pF. Serial Port The serial port in Figure 20 is made up of a 16-bit shift register and a three-state output buffer that are controlled by three inputs: SCLK, RD and CS. The serial port has one output, DOUT, that provides the serial output data. U W U U 25 THREE STATE BUFFER 19 DOUT* CLKOUT* *** 16 20 EXTCLKIN* EXT/INT* INTERNAL CLOCK 26 *PINS 16 TO 20 ARE LABELED WITH THEIR SERIAL FUNCTIONS BUSY 1418 F20 The SCLK is used to clock the shift register. Data may be clocked out with the internal conversion clock operating as a master by connecting CLKOUT (Pin 18) to SCLK (Pin 17) or with an external data clock applied to D3 (SCLK). The minimum number of SCLK cycles required to transfer a data word is 14. Normally, SCLK contains 16 clock cycles for a word length of 16 bits; 14 bits with MSB first, followed by two trailing zeros. A logic high on RD disables SCLK and three-states DOUT. In case of using a continuous SCLK, RD can be controlled to limit the number of shift clocks to the desired number (i.e., 16 cycles) and to three-state DOUT after the data transfer. A logic high on CS three-states the DOUT output buffer. It also inhibits conversion when it is tied high. In power shutdown mode (SHDN = low), a high CS selects sleep mode while a low CS selects nap mode. For normal serial port operation, CS can be grounded. DOUT outputs the serial data; 14 bits, MSB first, on the falling edge of each SCLK (see Figures 21 and 22). If 16 SCLKs are provided, the 14 data bits will be followed by 21 LTC1418 APPLICATIONS INFORMATION two zeros. The MSB (D13) will be valid on the first rising and the first falling edge of the SCLK. D12 will be valid on the second rising and the second falling edge as will all the remaining bits. The data may be captured on either edge. The largest hold time margin is achieved if data is captured on the rising edge of SCLK. BUSY gives the end of conversion indication. When the LTC1418 is configured as a master serial device, BUSY can be used as a framing pulse and to three-state the SCLK VIL t14 t15 DOUT 1418 F21 CONVST 24 CONVST (SAMPLE N) CS = EXT/INT = 0 CONVST t13 t6 BUSY (= RD) t10 1 CLKOUT (= SCLK) t7 DOUT Hi-Z D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 FILL ZEROS D13 Hi-Z D13 D12 DATA N t11 CLKOUT (= SCLK) 1418 F22b t5 2 3 4 5 6 VIL t14 t15 DOUT D13 Figure 22. Internal Conversion Clock Selected. Data Transferred During Conversion Using the ADC Clock Output as a Master Shift Clock (SCLK Driven from CLKOUT) 22 U W U U VOH VOL Figure 21. SCLK to DOUT Delay BUSY RD SCLK 26 23 17 BUSY (= RD) P OR DSP (CONFIGURED AS SLAVE) OR SHIFT REGISTER LTC1418 CLKOUT DOUT EXT/INT CS 25 18 19 20 CLKOUT ( = SCLK) DOUT 1418 F22a (SAMPLE N + 1) t8 HOLD SAMPLE HOLD 7 8 9 10 11 12 13 14 15 16 1 2 3 D11 DATA (N - 1) tCONV D12 CAPTURE ON RISING CLOCK CAPTURE ON FALLING CLOCK D11 VOH VOL LTC1418 APPLICATIONS INFORMATION serial port after transferring the serial output data by tying it to the RD pin. Figures 22 to 25 show several serial modes of operation, demonstrating the flexibility of the LTC1418 serial port. Serial Data Output During a Conversion Using Internal Conversion Clock for Conversion and Data Transfer. Figure 22 shows data from the previous conversion being clocked out during the conversion with the LTC1418 internal clock providing both the conversion clock and the SCLK. The internal clock has been optimized for the fastest conversion time, consequently this mode can provide the best overall speed performance. To select an internal conversion clock, tie EXT/INT (Pin 20) low. The internal clock appears on CLKOUT (Pin 18) which can be tied to SCLK (Pin 17) to supply the SCLK. Using External Clock for Conversion and Data Transfer. In Figure 23, data from the previous conversion is output during the conversion with an external clock providing both the conversion clock and the shift clock. To select an external conversion clock, tie EXT/INT high and apply the CONVST 24 CONVST EXTCLKIN LTC1418 SCLK DOUT EXT/INT CS 25 (SAMPLE N) CS = 0, EXT/INT = 5 CONVST t5 t6 BUSY (= RD) tdEXTCLKIN 1 EXTCLKIN (= SCLK) t10 DOUT Hi-Z D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 FILL ZEROS t7 D13 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 HOLD EXTCLKIN (= SCLK) tLEXTCLKIN VIL t14 t15 tHEXTCLKIN DOUT D13 Figure 23. External Conversion Clock Selected. Data Transferred During Conversion Using the External Clock (External Clock Drives Both EXTCLKIN and SCLK) U W U U BUSY RD 26 23 BUSY (= RD) 16 EXTCLKIN ( = SCLK) P OR DSP 17 19 20 5V DOUT 1418 F23a (SAMPLE N + 1) t13 t8 SAMPLE HOLD 1 2 3 Hi-Z D13 D12 DATA N D11 DATA (N - 1) tCONV t11 1418 F23b D12 CAPTURE ON RISING CLOCK CAPTURE ON FALLING CLOCK D11 VOH VOL 23 LTC1418 APPLICATIONS INFORMATION clock to EXTCLKIN. The same clock is also applied to SCLK to provide a data shift clock. To maintain accuracy the conversion clock frequency must be between 30kHz and 4.5MHz. It is not recommended to clock data with an external clock during a conversion that is running on an internal clock because the asynchronous clocks may create noise. Serial Data Output After a Conversion Using Internal Conversion Clock and External Data Clock. In this mode, data is output after the end of each conversion but before the next conversion is started (Figure 24). The internal clock is used as the conversion clock and an external clock is used for the SCLK. This mode is useful in applications where the processor acts as a master serial device. This mode is SPI and MICROWIRE compatible. It CONVST 24 CONVST LTC1418 DOUT EXT/INT CS 25 19 20 CS = EXT/INT = 0 CONVST t5 t6 BUSY HOLD t9 RD 1 SCLK t10 DOUT (SAMPLE N) tCONV DATA N Hi-Z D13 12 11 10 9 8 7 2 3 4 5 6 7 Figure 24. Internal Conversion Clock Selected. Data Transferred After Conversion Using an External SCLK. BUSY Indicates End of Conversion 24 U W U U BUSY RD SCLK 26 23 17 INT C0 SCK P OR DSP MISO 1418 F24a t13 t8 SAMPLE 8 9 10 11 12 13 14 15 16 t11 6 5 4 3 2 1 0 FILL ZEROS Hi-Z 1418 F24b SCLK VIL t LSCLK t HSCLK t14 t15 DOUT D13 D12 CAPTURE ON RISING CLOCK CAPTURE ON FALLING CLOCK D11 VOH VOL LTC1418 APPLICATIONS INFORMATION also allows operation when the SCLK frequency is very low (less than 30kHz). To select the internal conversion clock tie EXT/INT low. The external SCLK is applied to SCLK. RD can be used to gate the external SCLK, such that data will clock only after RD goes low and to three-state DOUT after data transfer. If more than 16 SCLKs are provided, more zeros will be filled in after the data word indefinitely. Using External Conversion Clock and External Data Clock. In Figure 25, data is also output after each conversion is completed and before the next conversion is started. An external clock is used for the conversion clock and either another or the same external clock is used for the SCLK. This mode is identical to Figure 24 except that an external clock is used for the conversion. This mode CONVST 24 CONVST EXTCLKIN BUSY RD LTC1418 SCLK DOUT EXT/INT CS 25 CS = 0, EXT/INT = 5 EXTCLKIN tdEXTCLKIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 t5 CONVST t6 BUSY HOLD t9 RD 1 SCLK t10 DOUT (SAMPLE N) tCONV DATA N Hi-Z D13 12 11 10 9 8 7 2 3 4 5 6 7 Figure 25. External Conversion Clock Selected. Data Transferred After Conversion Using an External SCLK. BUSY Indicates End of Conversion U W U U 16 26 23 CLKOUT INT C0 P OR DSP 17 19 20 5V SCK MISO 1418 F25a 1 2 3 4 t7 t13 t8 SAMPLE 8 9 10 11 12 13 14 15 16 t11 6 5 4 3 2 1 0 FILL ZEROS Hi-Z 1418 F25b SCLK VIL t LSCLK t HSCLK t14 t15 DOUT D13 D12 CAPTURE ON RISING CLOCK CAPTURE ON FALLING CLOCK D11 VOH VOL 25 LTC1418 APPLICATIONS INFORMATION allows the user to synchronize the A/D conversion to an external clock either to have precise control of the internal bit test timing or to provide a precise conversion time. As in Figure 24, this mode works when the SCLK frequency is very low (less than 30kHz). However, the external conversion clock must be between 30kHz and 4.5MHz to maintain accuracy. If more than 16 SCLKs are provided, more zeros will be filled in after the data word indefinitely. To select the external conversion clock tie EXT/INT high. The external SCLK is applied to SCLK. RD can be used to gate the external SCLK such that data will clock only after RD goes low. PACKAGE DESCRIPTION Dimensions in inches (millimeters) unless otherwise noted. G Package 28-Lead Plastic SSOP (0.209) (LTC DWG # 05-08-1640) 0.205 - 0.212** (5.20 - 5.38) 0.005 - 0.009 (0.13 - 0.22) 0.022 - 0.037 (0.55 - 0.95) *DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE **DIMENSIONS DO NOT INCLUDE INTERLEAD FLASH. INTERLEAD FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE 26 U U W U U 0.397 - 0.407* (10.07 - 10.33) 28 27 26 25 24 23 22 21 20 19 18 17 16 15 0.301 - 0.311 (7.65 - 7.90) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 0.068 - 0.078 (1.73 - 1.99) 0 - 8 0.0256 (0.65) BSC 0.010 - 0.015 (0.25 - 0.38) 0.002 - 0.008 (0.05 - 0.21) G28 SSOP 0694 LTC1418 PACKAGE DESCRIPTION U Dimensions in inches (millimeters) unless otherwise noted. N Package 28-Lead PDIP (Narrow 0.300) (LTC DWG # 05-08-1510) 1.370* (34.789) MAX 28 27 26 25 24 23 22 21 20 19 18 17 16 15 0.255 0.015* (6.477 0.381) 1 0.300 - 0.325 (7.620 - 8.255) 0.130 0.005 (3.302 0.127) 0.020 (0.508) MIN 0.009 - 0.015 (0.229 - 0.381) 2 3 4 5 6 7 8 9 10 11 12 13 14 0.045 - 0.065 (1.143 - 1.651) 0.065 (1.651) TYP 0.005 (0.127) MIN 0.100 0.010 (2.540 0.254) 0.018 0.003 (0.457 0.076) N28 1197 ( +0.035 0.325 -0.015 8.255 +0.889 -0.381 ) 0.125 (3.175) MIN *THESE DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSIONS. MOLD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.010 INCH (0.254mm) 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. 27 LTC1418 TYPICAL APPLICATION Single 5V Supply, 200kHz, 14-Bit Sampling A/D Converter LTC1418 DIFFERENTIAL 1 + VDD ANALOG INPUT 2 AIN (0V TO 4.096V) AIN- VSS 3 VREF BUSY 4 REFCOMP CS 5 10F AGND CONVST 6 D13(MSB) RD 7 D12 SHDN 8 D11 SER/PAR 9 D10 (EXT/INT)D0 10 D9 (DOUT)D1 11 D8 (CLKOUT)D2 14-BIT 12 PARALLEL D7 (SCLK)D3 BUS 13 D6 (EXTCLKIN )D4 14 DGND D5 5V 28 27 26 25 24 23 22 21 20 19 18 17 16 15 *REQUIRED ONLY IF VSS CAN BECOME POSITIVE WITH RESPECT TO GROUND P CONTROL LINES 1N5817* 10F VREF OUTPUT 2.5V 1F RELATED PARTS PART NUMBER ADCs LTC1274/LTC1277 LTC1412 LTC1415 LTC1416 LTC1419 LTC1604 LTC1605 DACs LTC1595 LTC1596 Reference LT1019-2.5 Precision Bandgap Reference 0.05% Max, 5ppm/C Max 16-Bit CMOS Multiplying DAC in SO-8 16-Bit CMOS Multiplying DAC 1LSB Max INL/DNL, 1nV * sec Glitch, DAC8043 Upgrade 1LSB Max INL/DNL, DAC8143/AD7543 Upgrade Low Power, 12-Bit, 100ksps ADCs 12-Bit, 3Msps Sampling ADC Single 5V, 12-Bit, 1.25Msps ADC Low Power, 14-Bit, 400ksps ADC Low Power, 14-Bit, 800ksps ADC 16-Bit, 333ksps Sampling ADC Single 5V, 16-Bit, 100ksps ADC 10mW Power Dissipation, Parallel/Byte Interface Best Dynamic Performance, SINAD = 72dB at Nyquist 55mW Power Dissipation, 72dB SINAD 70mW Power Dissipation, 80.5dB SINAD True 14-Bit Linearity, 81.5dB SINAD, 150mW Dissipation 2.5V Input, SINAD = 90dB, THD = 100dB Low Power, 10V Inputs, Parallel/Byte Interface DESCRIPTION COMMENTS 28 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7417 (408)432-1900 q FAX: (408) 434-0507 q www.linear-tech.com U 1418 TA03 1418f LT/TP 0798 4K * PRINTED IN USA (c) LINEAR TECHNOLOGY CORPORATION 1998 |
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