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| LT1028/LT1128 Ultra Low Noise Precision High Speed Op Amps FEATURES s DESCRIPTIO s s s s s s s Voltage Noise 1.1nV/Hz Max. at 1kHz 0.85nV/Hz Typ. at 1kHz 1.0nV/Hz Typ. at 10Hz 35nVP-P Typ., 0.1Hz to 10Hz Voltage and Current Noise 100% Tested Gain-Bandwidth Product LT1028: 50MHz Min. LT1128: 13MHz Min. Slew Rate LT1028: 11V/s Min. LT1128: 5V/s Min. Offset Voltage: 40V Max. Drift with Temperature: 0.8V/C Max. Voltage Gain: 7 Million Min. Available in 8-Pin SO Package The LT1028(gain of -1 stable)/LT1128(gain of +1 stable) achieve a new standard of excellence in noise performance with 0.85nV/Hz 1kHz noise, 1.0nV/Hz 10Hz noise. This ultra low noise is combined with excellent high speed specifications (gain-bandwidth product is 75MHz for LT1028, 20MHz for LT1128), distortion-free output, and true precision parameters (0.1V/C drift, 10V offset voltage, 30 million voltage gain). Although the LT1028/ LT1128 input stage operates at nearly 1mA of collector current to achieve low voltage noise, input bias current is only 25nA. The LT1028/LT1128's voltage noise is less than the noise of a 50 resistor. Therefore, even in very low source impedance transducer or audio amplifier applications, the LT1028/LT1128's contribution to total system noise will be negligible. APPLICATI s s s s s s s S Low Noise Frequency Synthesizers High Quality Audio Infrared Detectors Accelerometer and Gyro Amplifiers 350 Bridge Signal Conditioning Magnetic Search Coil Amplifiers Hydrophone Amplfiers Flux Gate Amplifier 10 VOLTAGE NOISE DENSITY (nV/Hz) DEMODULATOR SYNC OUTPUT TO DEMODULATOR 1k + LT1028 - SQUARE WAVE DRIVE 1kHz FLUX GATE TYPICAL SCHONSTEDT #203132 1 1/f CORNER = 3.5Hz 50 0.1 0.1 1028/1128 TA01 U Voltage Noise vs Frequency VS = 15V TA = 25C MAXIMUM 1/f CORNER = 14Hz TYPICAL 1 10 100 FREQUENCY (Hz) 1k 1028/1128 TA02 UO 1 LT1028/LT1128 ABSOLUTE AXI U RATI GS Operating Temperature Range LT1028/LT1128AM, M ..................... - 55C to 125C LT1028/LT1128AC, C ......................... - 40C to 85C Storage Temperature Range All Devices ........................................ - 65C to 150C Lead Temperature (Soldering, 10 sec.)................. 300C Supply Voltage -55C to 105C ................................................ 22V 105C to 125C ................................................ 16V Differential Input Current (Note 8) ...................... 25mA Input Voltage ............................ Equal to Supply Voltage Output Short Circuit Duration .......................... Indefinite PACKAGE/ORDER I FOR ATIO TOP VIEW VOS TRIM 8 VOS TRIM 1 - ORDER PART NUMBER 7 V+ 6 OUT 5 OVERCOMP -IN 2 + +IN 3 4 V- (CASE) LT1028AMH LT1028MH LT1028ACH LT1028CH H PACKAGE 8-LEAD TO-5 METAL CAN TOP VIEW VOS TRIM 1 -IN 2 +IN 3 V - 8 - + VOS TRIM 7 V+ OUT 6 4 5 OVERCOMP J8 PACKAGE 8-LEAD CERAMIC DIP N8 PACKAGE 8-LEAD PLASTIC DIP LT1028AMJ8 LT1028MJ8 LT1028ACJ8 LT1028CJ8 LT1028ACN8 LT1028CN8 LT1128AMJ8 LT1128MJ8 LT1128CJ8 LT1128ACN8 LT1128CN8 ELECTRICAL CHARACTERISTICS SYMBOL VOS VOS Time IOS IB en PARAMETER Input Offset Voltage Long Term Input Offset Voltage Stability Input Offset Current Input Bias Current Input Noise Voltage CONDITIONS (Note 1) (Note 2) VS = 15V, TA = 25C, unless otherwise noted. LT1028AM/AC LT1128AM/AC MIN TYP 10 0.3 12 25 35 MAX 40 VCM = 0V VCM = 0V 0.1Hz to 10Hz (Note 3) 2 U U W WW U W TOP VIEW VOS TRIM 1 -IN 2 +IN 3 V - ORDER PART NUMBER 8 7 6 5 VOS TRIM V+ OUT OVERCOMP - + LT1028CS8 LT1128CS8 S8 PART MARKING 1028 1128 ORDER PART NUMBER LT1028CS16 4 S8 PACKAGE 8-LEAD PLASTIC SOIC TOP VIEW NC 1 NC 2 TRIM 3 -IN 4 +IN 5 V- 6 NC 7 NC 8 - + 16 NC 15 NC 14 TRIM 13 V + 12 OUT 11 OVERCOMP 10 NC 9 S PACKAGE 16-LEAD PLASTIC SOL NC NOTE: THIS DEVICE IS NOT RECOMMENDED FOR NEW DESIGNS LT1028M/C LT1128M/C MIN TYP 20 0.3 18 30 35 MAX 80 UNITS V V/Mo nA nA nVP-P 50 90 75 100 180 90 LT1028/LT1128 ELECTRICAL CHARACTERISTICS SYMBOL PARAMETER Input Noise Voltage Density In Input Noise Current Density Input Resistance Common Mode Differential Mode Input Capacitance Input Voltage Range Common-Mode Rejection Ratio Power Supply Rejection Ratio Large-Signal Voltage Gain VS = 15V, TA = 25C, unless otherwise noted. LT1028AM/AC LT1128AM/AC LT1028M/C LT1128M/C MIN TYP 1.0 0.9 4.7 1.0 300 20 5 12.2 126 132 30.0 20.0 15.0 13.0 12.2 15.0 6.0 75 20 80 7.6 MAX 1.9 1.2 12.0 1.8 UNITS nV/Hz nV/Hz pA/Hz pA/Hz M k pF V dB dB V/V V/V V/V V V V/s V/s MHz MHz mA CONDITIONS fO = 10Hz (Note 4) fO = 1000Hz, 100% tested fO = 10Hz (Note 3 and 5) fO = 1000Hz, 100% tested MIN TYP 1.00 0.85 4.7 1.0 MAX 1.7 1.1 10.0 1.6 CMRR PSRR AVOL VOUT SR GBW ZO IS Maximum Output Voltage Swing Slew Rate Gain-Bandwidth Product Open-Loop Output Impedance Supply Current VCM = 11V VS = 4V to 18V RL 2k, VO = 12V RL 1k, VO = 10V RL 600, VO = 10V RL 2k RL 600 AVCL = -1 AVCL = -1 fO = 20kHz (Note 6) fO = 200kHz (Note 6) VO = 0, IO = 0 LT1028 LT1128 LT1028 LT1128 300 20 5 11.0 12.2 114 126 117 133 7.0 30.0 5.0 20.0 3.0 15.0 12.3 13.0 11.0 12.2 11.0 15.0 5.0 6.0 50 75 13 20 80 7.4 11.0 110 110 5.0 3.5 2.0 12.0 10.5 11.0 4.5 50 11 9.5 10.5 ELECTRICAL CHARACTERISTICS SYMBOL VOS VOS Temp IOS IB CMRR PSRR AVOL VOUT IS PARAMETER Input Offset Voltage Average Input Offset Drift Input Offset Current Input Bias Current Input Voltage Range Common-Mode Rejection Ratio Power Supply Rejection Ratio Large-Signal Voltage Gain Maximum Output Voltage Swing Supply Current CONDITIONS (Note 1) (Note7) VCM = 0V VCM = 0V VS = 15V, -55C TA 125C, unless otherwise noted. LT1028AM LT1128AM MIN q q q q q q q q q q LT1028M LT1128M MAX 120 0.8 MIN TYP 45 0.25 30 50 11.7 120 130 14.0 10.0 11.6 9.0 MAX 180 1.0 180 300 UNITS V V/C nA nA V dB dB V/V V/V V mA TYP 30 0.2 VCM = 10.3V VS = 4.5V to 16V RL 2k, VO = 10V RL 1k, VO = 10V RL 2k 25 40 10.3 11.7 106 122 110 130 3.0 14.0 2.0 10.0 10.3 11.6 8.7 90 150 10.3 100 104 2.0 1.5 10.3 11.5 13.0 3 LT1028/LT1128 ELECTRICAL CHARACTERISTICS SYMBOL VOS V OS Temp IOS IB CMRR PSRR AVOL VOUT IS PARAMETER Input Offset Voltage Average Input Offset Drift Input Offset Current Input Bias Current Input Voltage Range Common-Mode Rejection Ratio Power Supply Rejection Ratio Large-Signal Voltage Gain Maximum Output Voltage Swing Supply Current CONDITIONS (Note 1) (Note7) VCM = 0V VCM = 0V VS = 15V, 0C TA 70C, unless otherwise noted. LT1028AC LT1128AC MIN q q q q q q q q q q LT1028C LT1128C MAX 80 0.8 65 120 10.5 106 107 3.0 2.5 11.5 9.0 10.5 MIN TYP 30 0.2 22 40 12.0 124 132 25.0 18.0 12.7 10.5 8.2 MAX 125 1.0 130 240 UNITS V V/C nA nA V dB dB V/V V/V V V mA TYP 15 0.1 VCM = 10.5V VS = 4.5V to 18V RL 2k, VO = 10V RL 1k, VO = 10V RL 2k RL 600 (Note 9) 15 30 10.5 12.0 110 124 114 132 5.0 25.0 4.0 18.0 11.5 12.7 9.5 11.0 8.0 11.5 ELECTRICAL CHARACTERISTICS SYMBOL VOS V OS Temp IOS IB CMRR PSRR AVOL VOUT IS PARAMETER Input Offset Voltage Average Input Offset Drift Input Offset Current Input Bias Current Input Voltage Range Common-Mode Rejection Ratio Power Supply Rejection Ratio Large-Signal Voltage Gain Maximum Output Voltage Swing Supply Current CONDITIONS VS = 15V, - 40C TA 85C, unless otherwise noted. (Note 10) LT1028AC LT1128AC MIN q q LT1028C LT1128C MAX 95 0.8 80 140 10.4 102 106 2.5 2.0 11.0 11.0 MIN TYP 35 0.25 28 45 11.8 123 131 20.0 14.0 12.5 8.7 MAX 150 1.0 160 280 UNITS V V/C nA nA V dB dB V/V V/V V mA TYP 20 0.2 VCM = 0V VCM = 0V VCM = 10.5V VS = 4.5V to 18V RL 2k, VO = 10V RL 1k, VO = 10V RL 2k q q q q q q q q 20 35 10.4 11.8 108 123 112 131 4.0 20.0 3.0 14.0 11.0 12.5 8.5 12.5 The q denotes specifications which apply over the full operating temperature range. Note 1: Input Offset Voltage measurements are performed by automatic test equipment approximately 0.5 sec. after application of power. In addition, at TA = 25C, offset voltage is measured with the chip heated to approximately 55C to account for the chip temperature rise when the device is fully warmed up. Note 2: Long Term Input Offset Voltage Stability refers to the average trend line of Offset Voltage vs. Time over extended periods after the first 30 days of operation. Excluding the initial hour of operation, changes in VOS during the first 30 days are typically 2.5V. Note 3: This parameter is tested on a sample basis only. Note 4: 10Hz noise voltage density is sample tested on every lot with the exception of the S8 and S16 packages. Devices 100% tested at 10Hz are available on request. Note 5: Current noise is defined and measured with balanced source resistors. The resultant voltage noise (after subtracting the resistor noise on an RMS basis) is divided by the sum of the two source resistors to obtain current noise. Maximum 10Hz current noise can be inferred from 100% testing at 1kHz. Note 6: Gain-bandwidth product is not tested. It is guaranteed by design and by inference from the slew rate measurement. Note 7: This parameter is not 100% tested. Note 8: The inputs are protected by back-to-back diodes. Current-limiting resistors are not used in order to achieve low noise. If differential input voltage exceeds 1.8V, the input current should be limited to 25mA. Note 9: This parameter guaranteed by design, fully warmed up at TA = 70C. It includes chip temperature increase due to supply and load currents. Note 10: The LT1028/LT1128 are not tested and are not qualityassurance-sampled at -40C and at 85C. These specifications are guaranteed by design, correlation and/or inference from -55C, 0C, 25C, 70C and /or 125C tests. 4 LT1028/LT1128 TYPICAL PERFOR A CE CHARACTERISTICS 10Hz Voltage Noise Distribution 180 160 140 158 148 120 100 80 60 40 20 0 0.6 8 70 57 RMS VOLTAGE NOISE (V) NUMBER OF UNITS VS = 15V TA = 25C 500 UNITS MEASURED FROM 4 RUNS 28 74 3 2 2 2 12 3 21 1 1 0.8 1.0 1.2 1.4 1.6 1.8 2.0 VOLTAGE NOISE DENSITY (nV/Hz) LT1020/1120 * TPC01 Total Noise vs Matched Source Resistance 100 RS TOTAL NOISE DENSITY (nV/Hz) RS + TOTAL NOISE DENSITY (nV/Hz) - CURRENT NOISE DENSITY (pA/Hz) 10 AT 10Hz 1 2 RS NOISE ONLY VS = 15V TA = 25C 0.1 1 3 10 30 100 300 1k 3k MATCHED SOURCE RESISTANCE () 10k AT 1kHz LT1028/1128 * TPC04 0.1Hz to 10Hz Voltage Noise VS = 15V TA = 25C RMS VOLTAGE DENSITY (nV/Hz) 10nV 0 2 6 4 TIME (SEC) LT1028/1128 * TPC07 UW 2.2 8 10 Wideband Noise, DC to 20kHz 10 Wideband Voltage Noise (0.1Hz to Frequency Indicated) VS = 15V TA = 25C 1 0.1 VERTICAL SCALE = 0.5V/DIV HORIZONTAL SCALE = 0.5ms/DIV 0.01 100 1k 10k 100k BANDWIDTH (Hz) 1M 10M LT1028/1128 * TPC03 Total Noise vs Unmatched Source Resistance 100 RS Current Noise Spectrum 100 10 10 MAXIMUM 1/f CORNER = 800Hz TYPICAL AT 10Hz 1 AT 1kHz 1 1/f CORNER = 250Hz 2 RS NOISE ONLY VS = 15V TA = 25C 0.1 1 3 10 30 100 300 1k 3k 10k UNMATCHED SOURCE RESISTANCE () LT1028/1128 * TPC05 0.1 10 100 1k FREQUENCY (Hz) 10k LT1028/1128 * TPC06 0.01Hz to 1Hz Voltage Noise 2.0 VS = 15V TA = 25C Voltage Noise vs Temperature VS = 15V 1.6 1.2 AT 10Hz 0.8 AT 1kHz 10nV O.4 0 20 60 40 TIME (SEC) 80 100 0 -50 -25 50 25 0 75 TEMPERATURE (C) 100 125 LT1028/1128 * TPC07 LT1028/1128 * TPC09 5 LT1028/LT1128 TYPICAL PERFOR A CE CHARACTERISTICS 20 18 16 14 UNITS (%) Distribution of Input Offset Voltage VS = 15V TA = 25C 800 UNITS TESTED FROM FOUR RUNS 30 OFFSET VOLTAGE CHANGE (V) OFFSET VOLTAGE (V) 12 10 8 6 4 2 0 -50 -40 -30 -20 -10 0 10 20 30 40 50 OFFSET VOLTAGE (V) LT1028/1128 * TPC10 Warm-Up Drift 24 INPUT BIAS AND OFFSET CURRENTS (nA) CHANGE IN OFFSET VOLTAGE (V) 20 16 VS = 15V TA = 25C INPUT BIAS CURRENT (nA) METAL CAN (H) PACKAGE 12 8 4 0 0 1 2 3 4 TIME AFTER POWER ON (MINUTES) 5 DUAL-IN-LINE PACKAGE PLASTIC (N) OR CERDIP (J) LT1028/1128 * TPC13 Voltage Noise vs Supply Voltage 1.5 RMS VOLTAGE NOISE DENSITY (nV/Hz) 10 TA = 25C 1.25 8 VS = 15V SHORT-CIRCUIT CURRENT (mA) SINKING SOURCING SUPPLY CURRENT (mA) 1.0 AT 10Hz AT 1kHz 0.75 0.5 0 5 10 15 SUPPLY VOLTAGE (V) LT1028/1128 * TPC16 6 UW Offset Voltage Drift with Temperature of Representative Units 50 40 VS = 15V Long-Term Stability of Five Representative Units 10 8 6 4 2 0 -2 -4 -6 -8 VS = 15V TA = 25C t = 0 AFTER 1 DAY PRE-WARM UP 20 10 0 -10 -20 -30 -40 -50 -50 -25 50 25 0 75 TEMPERATURE (C) 100 125 -10 0 1 3 2 TIME (MONTHS) 4 5 LT1028/1128 * TPC11 LT1028/1128 * TPC12 Input Bias and Offset Currents Over Temperature 60 50 40 30 BIAS CURRENT 20 10 0 -50 -25 OFFSET CURRENT VS = 15V VCM = 0V 100 80 60 40 20 0 -20 -40 -60 Bias Current Over the CommonMode Range RCM = 20V 300M VS = 15V 65nA TA = 25C POSITIVE INPUT CURRENT (UNDERCANCELLED) DEVICE NEGATIVE INPUT CURRENT (OVERCANCELLED) DEVICE 10 5 -10 0 -5 COMMON-MODE INPUT VOLTAGE (V) 15 50 25 75 0 TEMPERATURE (C) 100 125 -80 -15 LT1028/1128 * TPC14 LT1028/1128 * TPC15 Supply Current vs Temperature 50 40 30 20 10 0 -10 -20 -30 -40 50 25 0 75 TEMPERATURE (C) 100 125 9 Output Short-Circuit Current vs Time -50C 25C 125C VS = 15V 7 6 5 4 3 2 1 VS = 5V 125C 25C -50C 20 0 -50 -25 -50 3 2 0 1 TIME FROM OUTPUT SHORT TO GROUND (MINUTES) LT1028/1128 * TPC18 LT1028/1128 * TPC17 LT1028/LT1128 TYPICAL PERFOR A CE CHARACTERISTICS Voltage Gain vs Frequency 160 140 120 VOLTAGE GAIN (dB) PHASE MARGIN (DEGREES) OVERSHOOT (%) LT1128 80 60 40 20 0 -20 0.01 0.1 1 LT1028 40 30 GAIN 20 10 0 VS = 15V TA = 25C CL = 10pF 100k 1M 10M FREQUENCY (Hz) 40 30 20 10 0 -10 100M 50 40 30 20 10 0 10 AV = -1, RS = 2k AV = -10 RS = 200 AV = -100 RS = 20 VS = 15V TA = 25C 10000 10 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) LT1028/1128 * TPC19 -10 10k LT1028/1128 * TPC20 Gain Error vs Frequency Closed-Loop Gain = 1000 1 TYPICAL PRECISION OP AMP 0.1 VOLTAGE GAIN (dB) GAIN ERROR (%) 70 60 LT1128 Gain Phase vs Frequency 70 60 80 70 LT1128 Capacitance Load Handling 30pF 2k PHASE MARGIN (DEGREES) PHASE LT1128 OVERSHOOT (%) 40 30 20 GAIN 10 40 30 20 10 VS = 15V TA = 25C CL = 10pF 100k 1M 10M FREQUENCY (Hz) 0 -10 100M 50 40 30 20 10 0 10 AV = -1, RS = 2k AV = -10 RS = 200 VS = 15V TA = 25C VO = 10mVP-P 10000 LT1028 0.01 0.001 0.1 GAIN ERROR = CLOSED-LOOP GAIN OPEN-LOOP GAIN 10 1 FREQUENCY (Hz) 100 LT1028/1128 * TPC22 0 -10 10k AV = -100, RS = 20 LT1028/1128 * TPC23 Voltage Gain vs Supply Voltage 100 100 Voltage Gain vs Load Resistance 30 PEAK-TO-PEAK OUTPUT VOLTAGE (V) VS = 15V Maximum Undistorted Output vs Frequency VS = 15V TA = 25C RL = 2k TA = 25C 25 20 15 LT1128 10 5 LT1028 VOLTAGE GAIN (V/V) VOLTAGE GAIN (V/V) RL = 2k TA = -55C 10 TA = 25C TA = 125C 10 RL = 600 ILMAX = 35mA AT -55C = 27mA AT 25C = 16mA AT 125C 1 0 5 10 15 SUPPLY VOLTAGE (V) 20 1 0.1 1 LOAD RESISTANCE (k) 10 10k LT1028/1128 * TPC25 LT1028/1128 * TPC26 + - 50 50 60 RS + 100 VOLTAGE GAIN (dB) - VS = 15V TA = 25C RL = 2k UW LT1028 Gain, Phase vs Frequency 70 PHASE 60 50 60 50 70 60 LT1028 Capacitance Load Handling 70 80 30pF 2k RS CL 100 1000 CAPACITIVE LOAD (pF) LT1028/1128 * TPC21 CL 100 1000 CAPACITIVE LOAD (pF) LT1028/1128 * TPC 24 100k 1M FREQUENCY (Hz) 10M LT1028/1128 * TPC27 7 LT1028/LT1128 TYPICAL PERFOR A CE CHARACTERISTICS LT1028 Large-Signal Transient Response 50mV 20mV/DIV 10V 5V/DIV SLEW RATE (V/s) -10V -50mV 1s/DIV AV = -1, RS = RF = 2k, C F = 15pF LT1128 Large-Signal Transient Response 50mV 10V SLEW RATE (V/s) 0V -10V -50mV 2s/DIV AV = -1, R S = RF = 2k, CF = 30pF Closed-Loop Output Impedance 100 IO = 1mA VS = 15V TA = 25C AV = +1000 1 LT1128 LT1028 10 100 OUTPUT IMPEDANCE () 10 100 SLEW RATE (V/s) SLEW RATE (V/s) 0.1 LT1128 AV = +5 LT1028 0.01 0.001 10 100 10k 1k FREQUENCY (Hz) 100k LT1028/1128 * TPC34 8 UW 1M LT1028 Small-Signal Transient Response 18 17 16 15 14 13 LT1028 Slew Rate, Gain-Bandwidth Product Over Temperature GAIN-BANDWIDTH PRODUCT (fO = 20kHz), (MHz) VS = 15V GBW FALL RISE 90 80 70 60 50 40 30 125 0.2s/DIV AV = -1, RS = RF = 2k CF = 15pF, C L = 80pF 12 -50 -25 50 25 75 0 TEMPERATURE (C) 100 LT1028/1128 * TPC30 LT1128 Small-Signal Transient Response 9 8 7 LT1128 Slew Rate, Gain-Bandwidth Product Over Temperature GAIN-BANDWIDTH PRODUCT (fO = 200kHz), (MHz) FALL RISE 6 5 4 3 2 10 GBW 20 30 0V 0.2s/DIV AV = +1, C L = 10pF 1 0 -50 -25 75 50 25 0 TEMPERATURE (C) 100 125 LT1028/1128 * TPC33 LT1128 Slew Rate, Gain-Bandwidth Product vs Over-Compensation Capacitor 1k LT1028 Slew Rate, Gain-Bandwidth Product vs Over-Compensation Capacitor 100 10k GBW SLEW RATE SLEW 10 GAIN AT 200kHz GBW 1k GAIN AT 20kHz 1 10 1 COC FROM PIN 5 TO PIN 6 VS = 15V TA = 25C 0.1 1 100 0.1 1 1 100 1000 10000 10 OVER-COMPENSATION CAPACITOR (pF) LT1028/1128 * TPC35 10 10 100 1000 10000 OVER-COMPENSATION CAPACITOR (pF) LT1028/1128 * TPC36 LT1028/LT1128 TYPICAL PERFOR A CE CHARACTERISTICS Common-Mode Limit Over Temperature V+ COMMON-MODE REJECTION RATIO (dB) POWER SUPPLY REJECTION RATIO (dB) -1 COMMON-MODE LIMIT (V) REFERRED TO POWER SUPPLY -2 -3 -4 VS = 5V VS = 15V 4 3 2 1 V- -50 -25 50 25 0 75 TEMPERATURE (C) 100 125 VS = 5V TO 15V LT1028/1128 * TPC37 LT1028 Total Harmonic Distortion vs Frequency and Load Resistance 0.1 0.1 TOTAL HARMONIC DISTORTION (%) AV = +1000 RL = 600 TOTAL HARMONIC DISTORTION (%) 0.01 NOISE VOLTAGE DENSITY (nV/Hz) AV = +1000 RL = 2k 0.01 AV = -1000 RL = 2k AV = +1000 RL = 600 VO = 20VP-P VS = 15V TA = 25C 10 FREQUENCY (kHz) 100 LT1028/1128 * TPC40 0.001 1 LT1128 Total Harmonic Distortion vs Frequency and Load Resistance 1.0 TOTAL HARMONIC DISTORTION (%) 0.1 AV = +1000 RL = 2k AV = +1000 RL = 600 TOTAL HARMONIC DISTORTION (%) 0.01 0.001 1.0 UW Common-Mode Rejection Ratio vs Frequency 140 120 100 LT1128 80 60 40 20 0 10 100 100k 10k 1k FREQUENCY (Hz) 1M 10M LT1028 VS = 15V TA = 25C Power Supply Rejection Ratio vs Frequency 160 140 120 100 80 60 40 20 0 0.1 1 10 100 1k 10k 100k 1M 10M FREQUENCY (Hz) LT1028/1128 * TPC39 VS = 15V TA = 25C NEGATIVE SUPPLY POSITIVE SUPPLY LT1028/1128 * TPC38 LT1028 Total Harmonic Distortion vs Closed-Loop Gain 10 VO = 20VP-P f = 1kHz VS = 15V TA = 25C RL = 10k NON-INVERTING GAIN High Frequency Voltage Noise vs Frequency 1.0 0.001 INVERTING GAIN MEASURED EXTRAPOLATED 10 100 1k 10k CLOSED LOOP GAIN 100k 0.0001 0.1 10k 100k FREQUENCY (Hz) 1M LT1028/1128 * TPC42 LT1028/1128 * TPC41 LT1128 Total Harmonic Distortion vs Closed-Loop Gain 0.1 VO = 20VP-P f = 1kHz VS = 15V TA = 25C RL = 10k NON-INVERTING GAIN 0.01 AV = -1000 RL = 2k AV = +1000 RL = 600 VO = 20VP-P VS = 15V TA = 25C 10 FREQUENCY (kHz) 100 LT1028/1128 * TPC43 0.001 INVERTING GAIN MEASURED EXTRAPOLATED 10 100 1k 10k CLOSED LOOP GAIN 100k 0.0001 LT1028/1128 * TPC44 9 LT1028/LT1128 APPLICATI S I FOR ATIO - OISE largest term, as in the example above, and the LT1028/ LT1128's voltage noise becomes negligible. As Req is further increased, current noise becomes important. At 1kHz, when Req is in excess of 20k, the current noise component is larger than the resistor noise. The total noise versus matched source resistance plot illustrates the above calculations. The plot also shows that current noise is more dominant at low frequencies, such as 10Hz. This is because resistor noise is flat with frequency, while the 1/f corner of current noise is typically at 250Hz. At 10Hz when Req > 1k, the current noise term will exceed the resistor noise. When the source resistance is unmatched, the total noise versus unmatched source resistance plot should be consulted. Note that total noise is lower at source resistances below 1k because the resistor noise contribution is less. When RS > 1k total noise is not improved, however. This is because bias current cancellation is used to reduce input bias current. The cancellation circuitry injects two correlated current noise components into the two inputs. With matched source resistors the injected current noise creates a common-mode voltage noise and gets rejected by the amplifier. With source resistance in one input only, the cancellation noise is added to the amplifier's inherent noise. In summary, the LT1028/LT1128 are the optimum amplifiers for noise performance, provided that the source resistance is kept low. The following table depicts which op amp manufactured by Linear Technology should be used to minimize noise, as the source resistance is increased beyond the LT1028/LT1128's level of usefulness. 1028/1128 AI01 Voltage Noise vs Current Noise The LT1028/LT1128's less than 1nV/Hz voltage noise is three times better than the lowest voltage noise heretofore available (on the LT1007/1037). A necessary condition for such low voltage noise is operating the input transistors at nearly 1mA of collector currents, because voltage noise is inversely proportional to the square root of the collector current. Current noise, however, is directly proportional to the square root of the collector current. Consequently, the LT1028/LT1128's current noise is significantly higher than on most monolithic op amps. Therefore, to realize truly low noise performance it is important to understand the interaction between voltage noise (en), current noise (In) and resistor noise (rn). Total Noise vs Source Resistance The total input referred noise of an op amp is given by et = [en2 + rn2 + (InReq)2]1/2 where Req is the total equivalent source resistance at the two inputs, and rn = 4kTReq = 0.13Req in nV/Hz at 25C As a numerical example, consider the total noise at 1kHz of the gain 1000 amplifier shown below. 100 100k - 100 LT1028 LT1128 + Req = 100 + 100 || 100k 200 rn = 0.13200 = 1.84nVHz en = 0.85nVHz In = 1.0pA/Hz et = [0.852 + 1.842 + (1.0 x 0.2) 2]1/2 = 2.04nV/Hz Output noise = 1000 et = 2.04V/Hz At very low source resistance (Req < 40) voltage noise dominates. As Req is increased resistor noise becomes the 10 UU W U UO Best Op Amp for Lowest Total Noise vs Source Resistance SOURCE RESISTANCE() (Note 1) 0 to 400 400 to 4k 4k to 40k 40k to 500k 500k to 5M >5M BEST OP AMP AT LOW FREQ(10Hz) WIDEBAND(1kHz) LT1028/LT1128 LT1007/1037 LT1001 LT1012 LT1012 or LT1055 LT1055 LT1028/LT1128 LT1028/LT1128 LT1007/1037 LT1001 LT1012 LT1055 Note 1: Source resistance is defined as matched or unmatched, e.g., RS = 1k means: 1k at each input, or 1k at one input and zero at the other. LT1028/LT1128 APPLICATI S I FOR ATIO - OISE Measuring the typical 35nV peak-to-peak noise performance of the LT1028/LT1128 requires special test precautions: (a) The device should be warmed up for at least five minutes. As the op amp warms up, its offset voltage changes typically 10V due to its chip temperature increasing 30C to 40C from the moment the power supplies are turned on. In the 10 second measurement interval these temperature-induced effects can easily exceed tens of nanovolts. (b) For similar reasons, the device must be well shielded from air current to eliminate the possibility of thermoelectric effects in excess of a few nanovolts, which would invalidate the measurements. (c) Sudden motion in the vicinity of the device can also "feedthrough" to increase the observed noise. A noise-voltage density test is recommended when measuring noise on a large number of units. A 10Hz noisevoltage density measurement will correlate well with a 0.1Hz to 10Hz peak-to-peak noise reading since both results are determined by the white noise and the location of the 1/f corner frequency. Noise Testing - Voltage Noise The LT1028/LT1128's RMS voltage noise density can be accurately measured using the Quan Tech Noise Analyzer, Model 5173 or an equivalent noise tester. Care should be taken, however, to subtract the noise of the source resistor used. Prefabricated test cards for the Model 5173 set the device under test in a closed-loop gain of 31 with a 60 source resistor and a 1.8k feedback resistor. The noise of this resistor combination is 0.1358 = 1.0nV/Hz. An LT1028/LT1128 with 0.85nV/Hz noise will read (0.852 + 1.02)1/2 = 1.31nV/Hz. For better resolution, the resistors should be replaced with a 10 source and 300 feedback resistor. Even a 10 resistor will show an apparent noise which is 8% to 10% too high. The 0.1Hz to 10Hz peak-to-peak noise of the LT1028/ LT1128 is measured in the test circuit shown. The frequency response of this noise tester indicates that the 0.1Hz corner is defined by only one zero. The test time to measure 0.1Hz to 10Hz noise should not exceed 10 seconds, as this time limit acts as an additional zero to eliminate noise contributions from the frequency band below 0.1Hz. 0.1Hz to 10Hz Noise Test Circuit 0.1F 100k GAIN (dB) - 100 2k * + LT1001 + 4.7F - 100k VOLTAGE GAIN = 50,000 * DEVICE UNDER TEST NOTE ALL CAPACITOR VALUES ARE FOR NONPOLARIZED CAPACITORS ONLY 24.3k 0.1F 2.2F UU 4.3k W U UO 0.1Hz to 10Hz Peak-to-Peak Noise Tester Frequency Response 100 90 80 22F 70 60 50 40 30 0.01 1028/1128 AI02 SCOPE x1 RIN = 1M 110k 0.1 1.0 10 FREQUENCY (Hz) 100 LT1028/1128 * AI03 11 LT1028/LT1128 APPLICATI S I FOR ATIO - OISE 10Hz voltage noise density is sample tested on every lot. Devices 100% tested at 10Hz are available on request for an additional charge. 10Hz current noise is not tested on every lot but it can be inferred from 100% testing at 1kHz. A look at the current noise spectrum plot will substantiate this statement. The only way 10Hz current noise can exceed the guaranteed limits is if its 1/f corner is higher than 800Hz and/or its white noise is high. If that is the case then the 1kHz test will fail. eno Noise Testing - Current Noise Current noise density (In) is defined by the following formula, and can be measured in the circuit shown: In = [eno - (31 x 18.4nV/Hz) ] 20k x 31 2 1.8k 10k 60 2 1/2 - LT1028 LT1128 10k + 1028/1128 AI04 NOISE FILTER LOSS (dB) If the Quan Tech Model 5173 is used, the noise reading is input-referred, therefore the result should not be divided by 31; the resistor noise should not be multiplied by 31. 100% Noise Testing The 1kHz voltage and current noise is 100% tested on the LT1028/LT1128 as part of automated testing; the approximate frequency response of the filters is shown. The limits on the automated testing are established by extensive correlation tests on units measured with the Quan Tech Model 5173. APPLICATI General S I FOR ATIO The LT1028/LT1128 series devices may be inserted directly into OP-07, OP-27, OP-37, LT1007 and LT1037 sockets with or without removal of external nulling components. In addition, the LT1028/LT1128 may be fitted to 5534 sockets with the removal of external compensation components. Offset Voltage Adjustment The input offset voltage of the LT1028/LT1128 and its drift with temperature, are permanently trimmed at wafer testing to a low level. However, if further adjustment of VOS is necessary, the use of a 1k nulling potentiometer will not degrade drift with temperature. Trimming to a value other 12 UU U W W U U UO Automated Tester Noise Filter 10 0 -10 -20 -30 -40 -50 100 CURRENT NOISE VOLTAGE NOISE 1k 10k 100k LT1028/1128 * AI05 FREQUENCY (Hz) UO 1k 15V 1 2 INPUT 3 - + 8 76 OUTPUT LT1028 LT1128 4 -15V 1028/1128 AI06 than zero creates a drift of (VOS/300)V/C, e.g., if VOS is adjusted to 300V, the change in drift will be 1V/C. The adjustment range with a 1k pot is approximately 1.1mV. Offset Voltage and Drift Thermocouple effects, caused by temperature gradients across dissimilar metals at the contacts to the input LT1028/LT1128 APPLICATI S I FOR ATIO U Frequency Response The LT1028's Gain, Phase vs Frequency plot indicates that the device is stable in closed-loop gains greater than +2 or -1 because phase margin is about 50 at an open-loop gain of 6dB. In the voltage follower configuration phase margin seems inadequate. This is indeed true when the output is shorted to the inverting input and the noninverting input is driven from a 50 source impedance. However, when feedback is through a parallel R-C network (provided CF < 68pF), the LT1028 will be stable because of interaction between the input resistance and capacitance and the feedback network. Larger source resistance at the noninverting input has a similar effect. The following voltage follower configurations are stable: 33pF 2k 1028/1128 AI08 terminals, can exceed the inherent drift of the amplifier unless proper care is exercised. Air currents should be minimized, package leads should be short, the two input leads should be close together and maintained at the same temperature. The circuit shown to measure offset voltage is also used as the burn-in configuration for the LT1028/LT1128. Test Circuit for Offset Voltage and Offset Voltage Drift with Temperature 10k* 15V 2 200* 3 10k* - + 7 6 VO LT1028 LT1128 4 -15V VO = 100VOS * RESISTORS MUST HAVE LOW THERMOELECTRIC POTENTIAL Unity-Gain Buffer Applications (LT1128 Only) When RF 100 and the input is driven with a fast, largesignal pulse (>1V), the output waveform will look as shown in the pulsed operation diagram. RF - OUTPUT 6V/s 1028/1128 AI07 + During the fast feedthrough-like portion of the output, the input protection diodes effectively short the output to the input and a current, limited only by the output short-circuit protection, will be drawn by the signal generator. With RF 500, the output is capable of handling the current requirements (IL 20mA at 10V) and the amplifier stays in its active mode and a smooth transition will occur. As with all operational amplifiers when RF > 2k, a pole will be created with RF and the amplifier's input capacitance, creating additional phase shift and reducing the phase margin. A small capacitor (20pF to 50pF) in parallel with RF will eliminate this problem. W U UO - LT1028 - 500 LT1028 + 50 + 50 1028/1128 AI09 Another configuration which requires unity-gain stability is shown below. When CF is large enough to effectively short the output to the input at 15MHz, oscillations can occur. The insertion of RS2 500 will prevent the LT1028 from oscillating. When RS1 500, the additional noise contribution due to the presence of RS2 will be minimal. When RS1 100, RS2 is not necessary, because RS1 represents a heavy load on the output through the CF short. When 100 < RS1 < 500, RS2 should match RS1 . For example, RS1 = RS2 = 300 will be stable. The noise increase due to RS2 is 40%. C1 R1 RS1 - LT1028 RS2 + 1028/1128 AI10 13 LT1028/LT1128 APPLICATI S I FOR ATIO If CF is only used to cut noise bandwidth, a similar effect can be achieved using the over-compensation terminal. The Gain, Phase plot also shows that phase margin is about 45 at gain of 10 (20dB). The following configura10pF 10k 1.1k - LT1028 + 50 1028/1128 AI11 TYPICAL APPLICATI Strain Gauge Signal Conditioner with Bridge Excitation 15V 3 5.0V 2 LT1021-5 + - 7 6 330 LT1128 4 -15V 350 BRIDGE REFERENCE OUTPUT 15V 3 301k* 7 6 1F - + LT1028 10k ZERO TRIM 2 4 -15V 15V 3 - + 7 6 330 *RN60C FILM RESISTORS LT1028 2 4 -15V THE LT1028's NOISE CONTRIBUTION IS NEGLIGIBLE COMPARED TO THE BRIDGE NOISE. 14 U tion has a high (70%) overshoot without the 10pF capacitor because of additional phase shift caused by the feedback resistor - input capacitance pole. The presence of the 10pF capacitor cancels this pole and reduces overshoot to 5%. Over-Compensation The LT1028/LT1128 are equipped with a frequency overcompensation terminal (pin 5). A capacitor connected between pin 5 and the output will reduce noise bandwidth. Details are shown on the Slew Rate, Gain-Bandwidth Product vs Over-Compensation Capacitor plot. An additional benefit is increased capacitive load handling capability. Low Noise Voltage Regulator 28V + 121 LT317A 10 28V 1k LT1021-10 2.3k PROVIDES PRE-REG AND CURRENT LIMITING 10 W UO U UO + LT1028 330 2N6387 - 0V TO 10V OUTPUT 30.1k* 1000pF 2k 20V OUTPUT 5k GAIN TRIM 49.9* 2k 1028/1128 TA04 1028/1128 TA05 LT1028/LT1128 TYPICAL APPLICATI Paralleling Amplifiers to Reduce Voltage Noise 10 + A1 LT1028 1.5k - 7.5 470 + A2 LT1028 1.5k - 7.5 470 + An LT1028 1.5k - 7.5 470 1.ASSUME VOLTAGE NOISE OF LT1028 AND 7.5 SOURCE RESISTOR = 0.9nV/Hz. 2.GAIN WITH n LT1028s IN PARALLEL = n x 200. 3.OUTPUT NOISE = n x 200 x 0.9nV/Hz. 0.9 4.INPUT REFERRED NOISE = OUTPUT NOISE = nV/ Hz. n x 200 n 5.NOISE CURRENT AT INPUT INCREASES n TIMES. 2V 6.IF n = 5, GAIN = 1000, BANDWIDTH = 1MHz, RMS NOISE, DC TO 1MHz = = 0.9 V. 5 Low Noise, Wide Bandwidth Instrumentation Amplifier + LT1028 -INPUT 300 820 68pF - 50 10 - LT1028 +INPUT 820 68pF 300 + 10k 100 1028/1128 TA09 GAIN = 1000, BANDWIDTH = 1MHz INPUT REFERRED NOISE = 1.5nV/Hz AT 1kHz WIDEBAND NOISE -DC to 1MHz = 3VRMS IF BW LIMITED TO DC TO 100kHz = 0.55VRMS UO Phono Preamplifier 787 15V 2 100pF 4.7k 0.1F 10k 0.33F 6 OUTPUT - + 7 LT1028 3 47k 4 -15V ALL RESISTORS METAL FILM - LT1028 OUTPUT + MAG PHONO INPUT 1028/1128 TA06 Tape Head Amplifier 0.1F 499 31.6k 10 2 - LT1028 6 OUTPUT TAPE HEAD INPUT 3 + 1028/1128 TA07 1028/1128 TA03 ALL RESISTORS METAL FILM Gyro Pick-Off Amplifier 10k GYRO TYPICAL- NORTHROP CORP. GR-F5AH7-5B SINE DRIVE - LT1028 OUTPUT * + LT1028 OUTPUT TO SYNC DEMODULATOR 1k + - 1028/1128 TA08 15 LT1028/LT1128 TYPICAL APPLICATI C1 0.047 20 R1 2k Super Low Distortion Variable Sine Wave Oscillator C2 0.047 20 2k R2 + LT1028 - 2.4k 5.6k 10pF 15F 22k 2N4338 560 100k LT1055 20k TRIM FOR LOWEST DISTORTION <0.0018% DISTORTION AND NOISE. MEASUREMENT LIMITED BY RESOLUTION OF HP339A DISTORTION ANALYZER 5V 10 + 1k 33 100F SYNCHRONOUS DEMODULATOR 10k* OPTICAL CHOPPER WHEEL IR RADIATION PHOTOELECTRIC PICK-OFF 267 1000F 3 5V 5V 2 6 8 4 -5V INFRA RED ASSOCIATES, INC. HgCdTe IR DETECTOR 13 AT 77K 10 10k 14 16 1/4 LTC1043 13 12 3 7 LT1028 2 10k* + 100F + 39 16 - 10k + UO Chopper-Stabilized Amplifier 15V 1N758 3 + - 1 7 LT1052 6 8 4 0.1 0.01 1VRMS OUTPUT 1.5kHz TO 15kHz 1 f= 2RC WHERE R1C1 = R2C2 4.7k 15V ( ) 2 0.1 LT1004-1.2V -15V 100k 1N758 15V 130 1 7 68 30k + MOUNT 1N4148s IN CLOSE PROXIMITY INPUT 3 + LT1028 8 OUTPUT 10k 4 -15V 10 2 - 10k 1028/1128 TA10 1028/1128 TA11 Low Noise Infrared Detector + - + - 4 -5V 7 6 8 1M 3 30pF 2 5V LM301A 1 + - 4 7 LT1012 1 -5V 6 8 DC OUT 1028/1128 TA12 LT1028/LT1128 SCHE ATIC DIAGRA NULL 8 R5 130 R6 130 NULL 1 R1 3k R2 3k 900A 900A Q5 3 1 Q8 3 NONINVERTING INPUT 3 4.5A Q1 Q7 4.5A 4.5A 4.5A Q2 INTERVING INPUT 2 0 1.8mA BIAS Q3 300A Q15 Q21 R7 80 R8 480 600A Q20 Q23 V- 4 C2 = 50pF for LT1028 C2 = 275pF for LT1128 5 OVERCOMP 1028/1128 TA13 W V+ 7 Q4 C1 257pF 500A Q17 Q16 Q18 R10 400 R11 400 Q19 R10 C2 500 Q26 Q6 1 Q11 Q9 R11 100 C3 250pF Q24 1.5A Q12 Q13 1.5A Q14 R12 240 C4 35pF Q27 Q25 OUTPUT 6 Q22 1.1mA 2.3mA 400A Q10 W 17 LT1028/LT1128 PACKAGE DESCRIPTIO U Dimensions in inches (millimeters) unless otherwise noted. J8 Package 8-Lead Ceramic DIP 0.290 - 0.320 (7.366 - 8.128) 0.200 (5.080) MAX 0.015 - 0.060 (0.381 - 1.524) 0.005 (0.127) MIN 0.405 (10.287) MAX 8 7 6 5 0.008 - 0.018 (0.203 - 0.460) 0.385 0.025 (9.779 0.635) 0.025 (0.635) RAD TYP 1 2 3 0.220 - 0.310 (5.588 - 7.874) 0 - 15 4 0.038 - 0.068 (0.965 - 1.727) 0.014 - 0.026 (0.360 - 0.660) 0.125 3.175 0.100 0.010 MIN (2.540 0.254) 0.055 (1.397) MAX TJMAX 165C JA 100C/W N8 Package 8-Lead Plastic DIP 0.300 - 0.320 (7.620 - 8.128) 0.045 - 0.065 (1.143 - 1.651) 0.130 0.005 (3.302 0.127) 0.400 (10.160) MAX 8 7 6 5 0.009 - 0.015 (0.229 - 0.381) 0.065 (1.651) TYP 0.125 (3.175) MIN 0.020 (0.508) MIN 0.250 0.010 (6.350 0.254) ( +0.025 0.325 -0.015 +0.635 8.255 -0.381 ) 0.045 0.015 (1.143 0.381) 0.100 0.010 (2.540 0.254) 1 2 3 4 0.018 0.003 (0.457 0.076) TJMAX 130C JA 130C/W S8 Package 8-Lead Plastic SOIC 0.010 - 0.020 x 45 (0.254 - 0.508) 0.008 - 0.010 (0.203 - 0.254) 0.016 - 0.050 0.406 - 1.270 0.053 - 0.069 (1.346 - 1.752) 0.004 - 0.010 (0.101 - 0.254) 0.228 - 0.244 (5.791 - 6.197) 8 0.189 - 0.197 (4.801 - 5.004) 7 6 5 0- 8 TYP 0.014 - 0.019 (0.355 - 0.483) 0.050 (1.270) BSC 0.150 - 0.157 (3.810 - 3.988) TJMAX 135C JA 140C/W 1 2 3 4 18 LT1028/LT1128 PACKAGE DESCRIPTIO 0.291 - 0.299 (7.391 - 7.595) 0.005 (0.127) RAD MIN 0.010 - 0.029 x 45 (0.254 - 0.737) 0.093 - 0.104 (2.362 - 2.642) 0 - 8 TYP 0.009 - 0.013 (0.229 - 0.330) SEE NOTE 0.016 - 0.050 (0.406 - 1.270) NOTE: 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. 45TYP 0.027 - 0.034 (0.686 - 0.864) 7 6 5 0.110 - 0.160 (2.794 - 4.064) INSULATING STANDOFF 1 0.027 - 0.045 (0.686 - 1.143) 8 2 3 4 0.200 - 0.230 (5.080 - 5.842) BSC SEATING PLANE NOTE: LEAD DIAMETER IS UNCONTROLLED BETWEEN THE REFERENCE PLANE AND SEATING PLANE. 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. U Dimensions in inches (millimeters) unless otherwise noted. S Package 16-Lead Plastic SOL 0.037 - 0.045 (0.940 - 1.143) 16 15 0.398 - 0.413 (10.109 - 10.490) 14 13 12 11 10 9 SEE NOTE 0.050 (1.270) TYP 0.004 - 0.012 (0.102 - 0.305) 0.394 - 0.419 (10.007 - 10.643)SOL16 0.014 - 0.019 (0.356 - 0.482) TYP 1 2 3 4 5 6 7 8 T JMAX 140C JA 130C/W H Package 8-Lead TO-5 Metal Can 0.335 - 0.370 (8.509 - 9.398) DIA 0.305 - 0.335 (7.747 - 8.509) 0.040 (1.016) MAX 0.050 (1.270) MAX GAUGE PLANE 0.165 - 0.185 (4.191 - 4.699) REFERENCE PLANE 0.500 - 0.750 (12.70 - 19.05) 0.010 - 0.045 (0.254 - 1.143) 0.016 - 0.021 (0.406 - 0.533) TYP TJMAX 175C JA JC 140C/W 40C/W 19 LT1028/LT1128 U.S. Area Sales Offices NORTHEAST REGION Linear Technology Corporation One Oxford Valley 2300 E. Lincoln Hwy.,Suite 306 Langhorne, PA 19047 Phone: (215) 757-8578 FAX: (215) 757-5631 SOUTHEAST REGION Linear Technology Corporation 17060 Dallas Parkway Suite 208 Dallas, TX 75248 Phone: (214) 733-3071 FAX: (214) 380-5138 CENTRAL REGION Linear Technology Corporation Chesapeake Square 229 Mitchell Court, Suite A-25 Addison, IL 60101 Phone: (708) 620-6910 FAX: (708) 620-6977 SOUTHWEST REGION Linear Technology Corporation 22141 Ventura Blvd. Suite 206 Woodland Hills, CA 91364 Phone: (818) 703-0835 FAX: (818) 703-0517 NORTHWEST REGION Linear Technology Corporation 782 Sycamore Dr. Milpitas, CA 95035 Phone: (408) 428-2050 FAX: (408) 432-6331 International Sales Offices FRANCE Linear Technology S.A.R.L. Immeuble "Le Quartz" 58 Chemin de la Justice 92290 Chatenay Mallabry France Phone: 33-1-46316161 FAX: 33-1-46314613 GERMANY Linear Techonolgy GMBH Untere Hauptstr. 9 D-8057 Eching Germany Phone: 49-89-3197410 FAX: 49-89-3194821 JAPAN Linear Technology KK 4F Ichihashi Building 1-8-4 Kudankita Chiyoda-Ku Tokyo, 102 Japan Phone: 81-3-3237-7891 FAX: 81-3-3237-8010 KOREA Linear Technology Korea Branch Namsong Building, #505 Itaewon-Dong 260-199 Yongsan-Ku, Seoul Korea Phone: 82-2-792-1617 FAX: 82-2-792-1619 SINGAPORE Linear Technology Pte. Ltd. 101 Boon Keng Road #02-15 Kallang Ind. Estates Singapore 1233 Phone: 65-293-5322 FAX: 65-292-0398 TAIWAN Linear Technology Corporation Rm. 801, No. 46, Sec. 2 Chung Shan N. Rd. Taipei, Taiwan, R.O.C. Phone: 886-2-521-7575 FAX: 886-2-562-2285 UNITED KINGDOM Linear Technology (UK) Ltd. The Coliseum, Riverside Way Camberley, Surrey GU15 3YL United Kingdom Phone: 44-276-677676 FAX: 44-276-64851 World Headquarters Linear Technology Corporation 1630 McCarthy Blvd. Milpitas, CA 95035-7487 Phone: (408) 432-1900 FAX: (408) 434-0507 07/10/92 20 Linear Technology Corporation 1630 McCarthy Blvd., Milpitas, CA 95035-7487 (408) 432-1900 q FAX: (408) 434-0507 q TELEX: 499-3977 LT/GP 0792 10K REV 0 (c) LINEAR TECHNOLOGY CORPORATION 1992 |
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