PHOTODIODE WITH ON-CHIP AMPLIFIER
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1 PHOTODIODE WITH ON-CHIP AMPLIFIER FEATURES BANDWIDTH: khz PHOTODIODE SIZE:.9 x.9 inch (2.29 x 2.29mm) FEEDBACK RESISTOR HIGH RESPONSIVITY: A/W (6nm) LOW DARK ERRORS: 2mV WIDE SUPPLY RANGE: ±2.2 to ±18V LOW QUIESCENT CURRENT: 4µA TRANSPARENT 8-PIN DIP AND -PIN SIP HERMETIC 8-PIN CERAMIC DIP APPLICATIONS MEDICAL INSTRUMENTATION LABORATORY INSTRUMENTATION POSITION AND PROXIMITY SENSORS PHOTOGRAPHIC ANALYZERS SMOKE DETECTORS DESCRIPTION The is an opto-electronic integrated circuit containing a photodiode and transimpedance amplifier on a single dielectrically isolated chip. The transimpedance amplifier consists of a precision FETinput op amp and an on-chip metal film resistor. The.9 x.9 inch photodiode is operated at zero bias for excellent linearity and low dark current. The integrated combination of photodiode and transimpedance amplifier on a single chip eliminates the problems commonly encountered in discrete designs such as leakage current errors, noise pick-up and gain peaking due to stray capacitance. The operates over a wide supply range (±2.2 to ±18V) and supply current is only 4µA. It is packaged in a transparent plastic 8-pin DIP or -pin SIP, specified for the C to +7 C temperature range as well as a hermetic ceramic 8-pin DIP with a glass window, specified for the 4 C to +8 C temperature range. SPECTRAL RESPONSIVITY 2 (Pin available on DIP only) (1) 8 (2) 1 (3) 3 (SIP) DIP 4 (4) () Voltage Output (V/µW)..3 Ultraviolet Blue Using Internal Resistor Green Yellow Infrared Wavelength (nm) Red..3 Photodiode Responsivity (A/W) International Airport Industrial Park Mailing Address: PO Box 114 Tucson, AZ 8734 Street Address: 673 S. Tucson Blvd. Tucson, AZ 876 Tel: (2) Twx: Cable: BBRCORP Telex: FAX: (2) Immediate Product Info: (8) Burr-Brown Corporation PDS-12D Printed in U.S.A. January, 199
2 SPECIFICATIONS ELECTRICAL T A = +2 C, V S = ±1V, = 6nm, internal feedback resistor, unless otherwise noted. P, W, G PARAMETER CONDITIONS MIN TYP MAX UNITS RESPONSIVITY Photodiode Current 6nm A/W Voltage Output 6nm V/µW vs Temperature 1 ppm/ C Unit-to-Unit Variation 6nm ± % Nonlinearity (1) FS Output = 1V.1 % of FS Photodiode Area (.9 x.9in).8 in 2 (2.29 x 2.29mm).2 mm 2 DARK ERRORS, RTO (2) Offset Voltage, Output: P, W Packages ±. ±2 mv G Package ±. ±3 mv vs Temperature ±1 µv/ C vs Power Supply V S = ±2.2V to ±18V 1 1 µv/v Voltage Noise Measured BW = Hz to 1kHz 1 mvrms RESISTOR Internal Resistance 1 MΩ Tolerance: P, G Packages ±. ±2 % W Package ±. % vs Temperature ppm/ C FREQUENCY RESPONSE Bandwidth, Large or Small-Signal, 3dB khz Rise Time, 1% to 9% 1 µs Settling Time, 1% FS to Dark 1 µs % FS to Dark 2 µs.1% FS to Dark 4 µs Overload Recovery Time (to 1%) 1% Overdrive, V S = ±1V 44 µs 1% Overdrive, V S = ±V 1 µs 1% Overdrive, V S = ±2.2V 24 µs OUTPUT Voltage Output R L = 1kΩ () 1.2 () 1 V R L = kω () 2 () 1. V Capacitive Load, Stable Operation 1 nf Short-Circuit Current ±18 ma POWER SUPPLY Specified Operating Voltage ±1 V Operating Voltage Range ±2.2 ±18 V Quiescent Current = ±4 ± µa TEMPERATURE RANGE Specification; P, W Packages +7 C G Package 4 +8 C Operating, P, W Packages +7 C G Package +12 C Storage P, W Packages 2 +8 C G Package +12 C Thermal Resistance, θ JA 1 C/W NOTES: (1) Deviation in percent of full scale from best-fit straight line. (2) Referred to Output. Includes all error sources. 2
3 SPECIFICATIONS (CONT) ELECTRICAL Op Amp Section of (1) T A = +2 C, V S = ±1V, unless otherwise noted. Op Amp PARAMETER CONDITIONS MIN TYP MAX UNITS INPUT Offset Voltage ±. mv vs Temperature ± µv/ C vs Power Supply V S = ±2.2V to ±18V 1 µv/v Input Bias Current 1 pa vs Temperature doubles every 1 C NOISE Input Voltage Noise Voltage Noise Density, f = 1Hz 3 nv/ Hz f = 1Hz 2 nv/ Hz f = 1kHz 1 nv/ Hz Current Noise Density, f = 1kHz.8 fa/ Hz INPUT VOLTAGE RANGE Common-Mode Input Range ±14.4 V Common-Mode Rejection 16 db INPUT IMPEDANCE Differential Ω pf Common-Mode Ω pf OPEN-LOOP GAIN Open-Loop Voltage Gain 12 db FREQUENCY RESPONSE Gain-Bandwidth Product 16 MHz Slew Rate 6 V/µs Settling Time % 4 µs.1% µs OUTPUT Voltage Output R L = 1kΩ () 1.2 () 1 V R L = kω () 2 () 1. V Short-Circuit Current ±18 ma POWER SUPPLY Specified Operating Voltage ±1 V Operating Voltage Range ±2.2 ±18 V Quiescent Current I O = ±4 ± µa NOTE: (1) Op amp specifications provided for information and comparison only. PHOTODIODE SPECIFICATIONS T A = +2 C, unless otherwise noted. Photodiode of PARAMETER CONDITIONS MIN TYP MAX UNITS Photodiode Area (.9 x.9in).8 in 2 (2.29 x 2.29mm).2 mm 2 Current Responsivity 6nm A/W Dark Current V D = V (1) fa vs Temperature doubles every 1 C Capacitance V D = V (1) 6 pf NOTE: (1) Voltage Across Photodiode. The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user s own risk. Prices and specifications are subject to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant any BURR-BROWN product for use in life support devices and/or systems. 3
4 DICE INFORMATION 4 3 Photodiode Area.9 x.9 inch 2.29 x 2.29 mm B 8A PAD FUNCTION 1 2 In 3 4 Feedback Output 6 NC 7 NC 8A, 8B Common NC: No Connection. Pads 8A and 8B must both be connected to common. Substrate Bias: The substrate is electrically connected to internal circuitry. Do not make electrical connection to the substrate. MECHANICAL INFORMATION MILS (.1") MILLIMETERS Die Size 14 x 12 ± 3.91 x 3. ±3 Die Thickness 2 ±3 ±.8 Min. Pad Size 4 x 4 x Backing None DIE TOPOGRAPHY PIN CONFIGURATIONS Top View In Feedback (1) Common NC NC NOTE: (1) Photodiode location. Top View Common (1) Feedback 4 Output ABSOLUTE MAXIMUM RATINGS Output Supply Voltage... ±18V Input Voltage Range (Common Pin)... ±V S Output Short-Circuit (to ground)... Continuous Operating Temperature: P, W... 2 C to +8 C G... C to +12 C Storage Temperature: P, W... 2 C to +8 C G... C to +12 C Junction Temperature: P, W C G C Lead Temperature (soldering, 1s) C (Vapor-Phase Soldering Not Recommended on Plastic Packages) PACKAGE INFORMATION PACKAGE DRAWING MODEL PACKAGE NUMBER (1) DIP SIP ELECTROSTATIC DISCHARGE SENSITIVITY This integrated circuit can be damaged by ESD. Burr-Brown recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. MOISTURE SENSITIVITY AND SOLDERING Clear plastic does not contain the structural-enhancing fillers used in black plastic molding compound. As a result, clear plastic is more sensitive to environmental stress than black plastic. This can cause difficulties if devices have been stored in high humidity prior to soldering. The rapid heating during soldering can stress wire bonds and cause failures. Prior to soldering, it is recommended that plastic devices be baked-out at 8 C for 24 hours. The fire-retardant fillers used in black plastic are not compatible with clear molding compound. The plastic packages cannot meet flammability test, UL-94. P 8-Pin Plastic DIP 6-1 W -Pin Plastic SIP 321 G 8-Pin Ceramic DIP NOTE: (1) For detailed drawing and dimension table, please see end of data sheet, or Appendix D of Burr-Brown IC Data Book. 4
5 TYPICAL PERFORMANCE CURVES At T A = +2 C, V S = ±1V, = 6nm, unless otherwise noted. Normalized Current or Voltage Output NORMALIZED SPECTRAL RESPONSIVITY 6nm (A/W) Wavelength (nm) (8A/W) Output Voltage (V) VOLTAGE RESPONSIVITY vs RADIANT POWER = = 1kΩ k Radiant Power (µw) = 6nm 1 VOLTAGE RESPONSIVITY vs IRRADIANCE 1 VOLTAGE OUTPUT RESPONSIVITY vs FREQUENCY R = 6nm F = 3.3MΩ Output Voltage (V) 1.1 = = 1kΩ = 6nm Responsivity (V/µW) 1.1 = 33kΩ C EXT = = Irradiance (W/m 2 ).1 1 1k 1k 1k 1M 1M Frequency (Hz) 1. RESPONSE vs INCIDENT ANGLE RESPONSE vs INCIDENT ANGLE Relative Response.8.6 SIP Package θ X θ X Plastic DIP Package θ Y θ Y θ Y θ X.8.6 Relative Output θ Ceramic X DIP Package θ Y θ X and θ Y 2. ±2 ±4 ±6 ±8 Incident Angle ( ) Angle of Incidence
6 TYPICAL PERFORMANCE CURVES (CONT) At T A = +2 C, V S = ±1V, = 6nm, unless otherwise noted. Quiescent Current (ma).6..3 QUIESCENT CURRENT vs TEMPERATURE V S = ±1V V S = ±2.2V Dice Noise Voltage (Vrms) OUTPUT NOISE VOLTAGE vs MEASUREMENT BANDWIDTH Dotted lines indicate noise measured beyond the signal bandwidth. = = 1kΩ Temperature ( C) k 1k 1k 1M Frequency (Hz) SMALL-SIGNAL RESPONSE LARGE-SIGNAL RESPONSE 2mV/div 2V/div 1µs/div 1µs/div Noise Effective Power (W) NOISE EFFECTIVE POWER vs MEASUREMENT BANDWIDTH Dotted lines indicate noise measured beyond the signal bandwidth. = 6nm = 1kΩ = Units (%) DISTRIBUTION OF RESPONSIVITY = 6nm Distribution Totals 1% Laboratory Test Data Responsivity (A/W) k 1k 1k 1M Frequency (Hz) 6
7 APPLICATIONS INFORMATION Figure 1 shows the basic connections required to operate the. Applications with high-impedance power supplies may require decoupling capacitors located close to the device pins as shown. Output is zero volts with no light and increases with increasing illumination. I D is proportional to light intensity (radiant power). I D (V) (Pin available on DIP only) µf µf +1V 1V FIGURE 1. Basic Circuit Connections. Photodiode current, I D, is proportional to the radiant power or flux (in watts) falling on the photodiode. At a wavelength of 6nm (visible red) the photodiode Responsivity, R I, is approximately A/W. Responsivity at other wavelengths is shown in the typical performance curve Responsivity vs Wavelength. The typical performance curve Output Voltage vs Radiant Power shows the response throughout a wide range of radiant power. The response curve Output Voltage vs Irradiance is based on the photodiode area of.23 x 1 6 m 2. The s voltage output is the product of the photodiode current times the feedback resistor, (I D ). The internal feedback resistor is laser trimmed to ±2%. Using this resistor, the output voltage responsivity, R V, is approximately V/µW at 6nm wavelength. An external resistor can be connected to set a different voltage responsivity. Best dynamic performance is achieved by connecting R EXT in series (for > ), or in parallel (for < ), with the internal resistor as shown in Figure 2. Placing the external resistor in parallel with the internal resistor requires the DIP package. These connections take advantage of on-chip capacitive guarding of the internal resistor, which improves dynamic performance. For values of less than, an external capacitor, C EXT, should be connected in parallel with (see Figure 2). This capacitor eliminates gain peaking and prevents instability. The value of C EXT can be read from the table in Figure 2. LIGHT SOURCE POSITIONING The is 1% tested with a light source that uniformly illuminates the full area of the integrated circuit, including the op amp. Although all IC amplifiers are light-sensitive to I D = I D some degree, the op amp circuitry is designed to minimize this effect. Sensitive junctions are shielded with metal, and differential stages are cross-coupled. Furthermore, the photodiode area is very large relative to the op amp input circuitry making these effects negligible. If your light source is focused to a small area, be sure that it is properly aimed to fall on the photodiode. If a narrowly focused light source were to miss the photodiode area and fall only on the op amp circuitry, the would not perform properly. The large (.9 x.9 inch) photodiode area allows easy positioning of narrowly focused light sources. The photodiode area is easily visible it appears very dark compared to the surrounding active circuitry. The incident angle of the light source also affects the apparent sensitivity in uniform irradiance. For small incident angles, the loss in sensitivity is simply due to the smaller effective light gathering area of the photodiode (proportional to the cosine of the angle). At a greater incident angle, light is diffused by the side of the package. These effects are shown in the typical performance curve Response vs Incident Angle. For > For < = R EXT EQUIVALENT C EXT 1MΩ (1) 1MΩ (1) (1) 33kΩ 2pF 1kΩ (2) NOTES: (1) No C EXT required. (2) Not recommended due to possible op amp instability. FIGURE 2. Using External Feedback Resistor. C EXT R EXT 4 = R EXT + R EXT = I D = I D Circuit Requires DIP Package 7
8 DARK ERRORS The dark errors in the specification table include all sources. The dominant error source is the input offset voltage of the op amp. Photodiode dark current and input bias current of the op amp are in the 2pA range and contribute virtually no offset error at room temperature. Dark current and input bias current double for each 1 C above 2 C. At 7 C, the error current can be approximately 1pA. This would produce a 1mV offset with. The is useful with feedback resistors of 1MΩ or greater at room temperature. The dark output voltage can be trimmed to zero with the optional circuit shown in Figure 3. When used with very large feedback resistors, tiny leakage currents on the circuit board can degrade the performance of the. Careful circuit board design and clean assembly procedures will help achieve best performance. A guard ring on the circuit board can help minimize leakage to the critical non-inverting input (pin 2). This guard ring should encircle pin 2 and connect to Common, pin 8. 1µA 1/2 REF2 1Ω 1Ω 1µA 1/2 REF2 Ω FIGURE 3. Dark Error (Offset) Adjustment Circuit. LINEARITY PERFORMANCE Current output of the photodiode is very linear with radiant power throughout a wide range. Nonlinearity remains below approximately.1% up to 1µA photodiode current. The photodiode can produce output currents of 1mA or greater with high radiant power, but nonlinearity increases to several percent in this region. This very linear performance at high radiant power assumes that the full photodiode area is uniformly illuminated. If the light source is focused to a small area of the photodiode, nonlinearity will occur at lower radiant power. DYNAMIC RESPONSE Using the internal resistor, the dynamic response of the photodiode/op amp combination can be modeled as a.1µf Adjust dark output for V. Trim Range: ±7mV simple R/C circuit with a 3dB cutoff frequency of khz. This yields a rise time of approximately 1µs (1% to 9%). Dynamic response is not limited by op amp slew rate. This is demonstrated by the dynamic response oscilloscope photographs showing virtually identical large-signal and small-signal response. Dynamic response will vary with feedback resistor value as shown in the typical performance curve Voltage Output Responsivity vs Frequency. Rise time (1% to 9%) will vary according to the 3dB bandwidth produced by a given feedback resistor value t R where: t R is the rise time (1% to 9%) f C is the 3dB bandwidth. 3 f C (1) NOISE PERFORMANCE Noise performance of the is determined by the op amp characteristics in conjunction with the feedback components and photodiode capacitance. The typical performance curve Output Noise Voltage vs Measurement Bandwidth shows how the noise varies with and measured bandwidth (1Hz to the indicated frequency). The signal bandwidth of the is indicated on the curves. Noise can be reduced by filtering the output with a cutoff frequency equal to the signal bandwidth. Output noise increases in proportion to the square-root of the feedback resistance, while responsivity increases linearly with feedback resistance. So best signal-to-noise ratio is achieved with large feedback resistance. This comes with the trade-off of decreased bandwidth. The noise performance of a photodetector is sometimes characterized by Noise Effective Power (NEP). This is the radiant power which would produce an output signal equal to the noise level. NEP has the units of radiant power (watts). The typical performance curve Noise Effective Power vs Measurement Bandwidth shows how NEP varies with and measurement bandwidth. Gain Adjustment +%; % kω 1kΩ FIGURE 4. Responsivity (Gain) Adjustment Circuit. 8
9 = R 1 + R 2 I D R 2 R 1 19kΩ + = I D FIGURE. T Feedback Network. R 2 1kΩ Advantages: High gain with low resistor values. Less sensitive to circuit board leakage. Disadvantage: Higher offset and noise than by using high value for. V (1) Z V Z 3.3V kω (pesudo-ground) µf NOTE: (1) Zener diode or other shunt regulator. FIGURE 7. Single Power Supply Operation. C 2 µf R 2 A 1 I D +1V 1V R 1 1kΩ R 3 1kΩ 2 4 R 1 C 1 µf I O ma I O = I D 1 + FIGURE 6. Current Output Circuit. R 1 8 Other application circuits can be seen in the OPT29 data sheet. See AB-61 for details. Circuit requires DIP package. 2dB/decade R f 1 3dB = 2πR 2 R 3 C 2 = 16Hz FIGURE 8. DC Restoration Rejects Unwanted Steady-State Background Light. 9
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Quad High-Speed Precision Difet OPERATIONAL AMPLIFIER FEATURES WIDE BANDWIDTH:.MHz HIGH SLEW RATE: V/µs LOW OFFSET: ±µv max LOW BIAS CURRENT: ±pa max LOW SETTLING:.µs to.% STANDARD QUAD PINOUT APPLICATIONS
High-Voltage, Internally Powered ISOLATION AMPLIFIER
ISO17 High-Voltage, Internally Powered ISOLATION AMPLIFIER FEATURES SIGNAL AND POWER IN ONE TRIPLE-WIDE PACKAGE 8Vpk TEST VOLTAGE 5Vrms CONTINUOUS AC BARRIER RATING WIDE INPUT SIGNAL RANGE: 1V to 1V WIDE
Dual FET-Input, Low Distortion OPERATIONAL AMPLIFIER
www.burr-brown.com/databook/.html Dual FET-Input, Low Distortion OPERATIONAL AMPLIFIER FEATURES LOW DISTORTION:.3% at khz LOW NOISE: nv/ Hz HIGH SLEW RATE: 25V/µs WIDE GAIN-BANDWIDTH: MHz UNITY-GAIN STABLE
Voltage-to-Frequency and Frequency-to-Voltage CONVERTER
Voltage-to-Frequency and Frequency-to-Voltage CONVERTER FEATURES OPERATION UP TO 00kHz EXCELLENT LINEARITY ±0.0% max at 0kHz FS ±0.0% max at 00kHz FS V/F OR F/V CONVERSION MONOTONIC VOLTAGE OR CURRENT
Precision INSTRUMENTATION AMPLIFIER
Precision INSTRUMENTATION AMPLIFIER FEATURES LOW OFFSET VOLTAGE: 5µV max LOW DRIFT:.5µV/ C max LOW INPUT BIAS CURRENT: na max HIGH COMMON-MODE REJECTION: 5dB min INPUT OVER-VOLTAGE PROTECTION: ±V WIDE
Voltage-to-Frequency and Frequency-to-Voltage CONVERTER
Voltage-to-Frequency and Frequency-to-Voltage CONVERTER FEATURES OPERATION UP TO 500kHz EXCELLENT LINEARITY ±0.0% max at 0kHz FS ±0.05% max at 00kHz FS V/F OR F/V CONVERSION MONOTONIC VOLTAGE OR CURRENT
Dual FET-Input, Low Distortion OPERATIONAL AMPLIFIER
Dual FET-Input, Low Distortion OPERATIONAL AMPLIFIER FEATURES LOW DISTORTION:.3% at khz LOW NOISE: nv/ Hz HIGH SLEW RATE: 2V/µs WIDE GAIN-BANDWIDTH: 2MHz UNITY-GAIN STABLE WIDE SUPPLY RANGE: V S = ±4.
Low-Cost, Internally Powered ISOLATION AMPLIFIER
Low-Cost, Internally Powered ISOLATION AMPLIFIER FEATURES SIGNAL AND POWER IN ONE DOUBLE-WIDE (.6") SIDE-BRAZED PACKAGE 56Vpk TEST VOLTAGE 15Vrms CONTINUOUS AC BARRIER RATING WIDE INPUT SIGNAL RANGE: V
+10V Precision VOLTAGE REFERENCE
+1V Precision VOLTAGE REFEREE FEATURES OUTPUT VOLTAGE: +1V ±.% max EXCELLENT TEMPERATURE STABILITY: 8.ppm/ C max ( C to +8 C) LOW NOISE: µvp-p typ (.1Hz to 1Hz) EXCELLENT LINE REGULATION:.1%/V max EXCELLENT
Precision VOLTAGE REFERENCE
Precision VOLTAGE REFEREE FEATURES 10V ±0.00PUT VERY LOW DRIFT:.ppm/ C max EXCELLENT STABILITY: ppm/1000hr typ EXCELLENT LINE REGULATION: 1ppm/V max EXCELLENT LOAD REGULATION: 10ppm/mA max LOW NOISE: µvp-p
CMOS 12-Bit Serial Input Multiplying DIGITAL-TO-ANALOG CONVERTER
CMOS 12-Bit Serial Input Multiplying DIGITAL-TO-ANALOG CONVERTER FEATURES 12-BICCURACY IN 8-PIN MINI-DIP AND 8-PIN SOIC FAST 3-WIRE SERIAL INTERFACE LOW INL AND DNL: ±1/2 LSB max GAIN ACCURACY TO ±1LSB
CMOS 12-Bit Multiplying DIGITAL-TO-ANALOG CONVERTER Microprocessor Compatible
CMOS 12-Bit Multiplying DIGITAL-TO-ANALOG CONVERTER Microprocessor Compatible FEATURES FOUR-QUADRANT MULTIPLICATION LOW GAIN TC: 2ppm/ C typ MONOTONICITY GUARANTEED OVER TEMPERATURE SINGLE 5V TO 15V SUPPLY
Serial Input 18-Bit Monolithic Audio DIGITAL-TO-ANALOG CONVERTER
Serial Input 8-Bit Monolithic Audio DIGITAL-TO-ANALOG CONVERTER FEATURES 8-BIT MONOLITHIC AUDIO D/A CONVERTER LOW MAX THD + N: 92dB Without External Adjust 00% PIN COMPATIBLE WITH INDUSTRY STD 6-BIT PCM56P
Precision High-Speed Difet OPERATIONAL AMPLIFIERS
Precision High-Speed Difet OPERATIONAL AMPLIFIERS FEATURES VERY LOW NOISE: 4.nV/ Hz at khz FAST SETTLING TIME: ns to.% 4ns to.% LOW V OS : µv max LOW DRIFT:.8µV/ C max LOW I B : pa max : Unity-Gain Stable
Low Power INSTRUMENTATION AMPLIFIER
INA2 ABRIDGED DATA SHEET For Complete Data Sheet Call Fax Line -800-8- Request Document Number 2 Low Power INSTRUMENTATION AMPLIFIER FEATURES LOW QUIESCENT CURRENT: 0µA max INTERNAL GAINS:,, 0, 00 LOW
INA126. MicroPOWER INSTRUMENTATION AMPLIFIER Single and Dual Versions IN ) G V IN G = 5 +
INA6 INA6 INA6 INA6 INA6 INA6 INA6 SBOS06A JANUARY 996 REVISED AUGUST 005 MicroPOWER INSTRUMENTATION AMPLIFIER Single and Dual Versions FEATURES LOW QUIESCENT CURRENT: 75µA/chan. WIDE SUPPLY RANGE: ±.35V
SINGLE-SUPPLY, RAIL-TO-RAIL OPERATIONAL AMPLIFIERS
OPA OPA OPA OPA OPA OPA OPA SINGLE-SUPPLY, RAIL-TO-RAIL OPERATIONAL AMPLIFIERS MicroAmplifier Series FEATURES RAIL-TO-RAIL INPUT RAIL-TO-RAIL OUTPUT (within mv) MicroSIZE PACKAGES WIDE BANDWIDTH:.MHz HIGH
High-Speed Programmable Gain INSTRUMENTATION AMPLIFIER
High-Speed Programmable Gain INSTRUMENTATION AMPLIFIER FEATURES DIGITALLY PROGRAMMABLE GAINS: : G=, 2,, 8V/V : G=, 2,, V/V TRUE INSTRUMENTATION AMP INPUT FAST SETTLING: 3.µs to 0.0% FET INPUT: I B = 0pA
SGM MHz, 48μA, Rail-to-Rail I/O CMOS Operational Amplifier
PRODUCT DESCRIPTION The is a low cost, single rail-to-rail input and output voltage feedback amplifier. It has a wide input common mode voltage range and output voltage swing, and takes the minimum operating
SAMPLE/HOLD AMPLIFIER
SAMPLE/HOLD AMPLIFIER FEATURES FAST (µs max) ACQUISITION TIME (1-bit) APERTURE JITTER: 00ps POWER DISSIPATION: 300mW COMPATIBLE WITH HIGH RESOLUTION A/D CONVERTERS ADC7, PCM75, AND ADC71 DESCRIPTION The
Low-Cost, High-Voltage, Internally Powered OUTPUT ISOLATION AMPLIFIER
Low-Cost, High-Voltage, Internally Powered OUTPUT ISOLATION AMPLIFIER FEATURES SELF-CONTAINED ISOLATED SIGNAL AND OUTPUT POWER SMALL PACKAGE SIZE: Double-Wide (.6") Sidebraze DIP CONTINUOUS AC BARRIER
SGM8621/2/3/4 3MHz, Rail-to-Rail I/O CMOS Operational Amplifiers
SGM8621/2/3/4 3MHz, Rail-to-Rail I/O PRODUCT DESCRIPTION The SGM8621 (single), SGM8622 (dual), SGM8623 (single with shutdown) and SGM8624 (quad) are low noise, low voltage, and low power operational amplifiers,
High Common-Mode Voltage Difference Amplifier AD629
a FEATURES Improved Replacement for: INAP and INAKU V Common-Mode Voltage Range Input Protection to: V Common Mode V Differential Wide Power Supply Range (. V to V) V Output Swing on V Supply ma Max Power
Dual, Current Feedback Low Power Op Amp AD812
a FEATURES Two Video Amplifiers in One -Lead SOIC Package Optimized for Driving Cables in Video Systems Excellent Video Specifications (R L = ): Gain Flatness. db to MHz.% Differential Gain Error. Differential
Monolithic SAMPLE/HOLD AMPLIFIER
SHC9 SHC9A Monolithic SAMPLE/HOLD AMPLIFIER FEATURES -BIT THROUGHPUT ACCURACY LESS THAN µs ACQUISITION TIME WIDEBAND NOISE LESS THAN µvrms RELIABLE MONOLITHIC CONSTRUCTION Ω INPUT RESISTANCE TTL-CMOS-COMPATIBLE
Quad Picoampere Input Current Bipolar Op Amp AD704
a FEATURES High DC Precision 75 V Max Offset Voltage V/ C Max Offset Voltage Drift 5 pa Max Input Bias Current.2 pa/ C Typical I B Drift Low Noise.5 V p-p Typical Noise,. Hz to Hz Low Power 6 A Max Supply
QUAD 12-BIT DIGITAL-TO-ANALOG CONVERTER (12-bit port interface)
QUAD -BIT DIGITAL-TO-ANALOG CONVERTER (-bit port interface) FEATURES COMPLETE WITH REFERENCE AND OUTPUT AMPLIFIERS -BIT PORT INTERFACE ANALOG OUTPUT RANGE: ±1V DESCRIPTION is a complete quad -bit digital-to-analog
Low Cost Instrumentation Amplifier AD622
a FEATURES Easy to Use Low Cost Solution Higher Performance than Two or Three Op Amp Design Unity Gain with No External Resistor Optional Gains with One External Resistor (Gain Range 2 to ) Wide Power
Single Supply, Rail to Rail Low Power FET-Input Op Amp AD820
a FEATURES True Single Supply Operation Output Swings Rail-to-Rail Input Voltage Range Extends Below Ground Single Supply Capability from + V to + V Dual Supply Capability from. V to 8 V Excellent Load
SGM8631/2/3 6MHz, Rail-to-Rail I/O CMOS Operational Amplifiers
/2/3 6MHz, Rail-to-Rail I/O PRODUCT DESCRIPTION The (single), SGM8632 (dual) and SGM8633 (single with shutdown) are low noise, low voltage, and low power operational amplifiers that can be designed into
Precision LOGARITHMIC AND LOG RATIO AMPLIFIER
LOG Precision LOGARITHMIC AND LOG RATIO AMPLIFIER FEATURES ACCURACY.3% FSO max Total Error Over 5 Decades LINEARITY.% max Log Conformity Over 5 Decades EASY TO USE Pin-selectable Gains Internal Laser-trimmed
SGM8631/2/3/4 470μA, 6MHz, Rail-to-Rail I/O CMOS Operational Amplifiers
PRODUCT DESCRIPTION The SGM863 (single), SGM863 (dual), SGM8633 (single with shutdown) and SGM8634 (quad) are low noise, low voltage, and low power operational amplifiers, that can be designed into a wide
OBSOLETE. Parameter AD9621 AD9622 AD9623 AD9624 Units
a FEATURES MHz Small Signal Bandwidth MHz Large Signal BW ( V p-p) High Slew Rate: V/ s Low Distortion: db @ MHz Fast Settling: ns to.%. nv/ Hz Spectral Noise Density V Supply Operation Wideband Voltage
Dual 16-Bit DIGITAL-TO-ANALOG CONVERTER
Dual - DIGITAL-TO-ANALOG CONVERTER FEATURES COMPLETE DUAL V OUT DAC DOUBLE-BUFFERED INPUT REGISTER HIGH-SPEED DATA INPUT: Serial or Parallel HIGH ACCURACY: ±0.003% Linearity Error 14-BIT MONOTONICITY OVER
High Precision OPERATIONAL AMPLIFIERS
OPA OPA OPA OPA OPA OPA OPA OPA OPA OPA OPA High Precision OPERATIONAL AMPLIFIERS SBOS09A MARCH 999 REVISED APRIL 00 FEATURES ULTRA LOW OFFSET VOLTAGE: 0µV ULTRA LOW DRIFT: ±0.µV/ C HIGH OPEN-LOOP GAIN:
150 μv Maximum Offset Voltage Op Amp OP07D
5 μv Maximum Offset Voltage Op Amp OP7D FEATURES Low offset voltage: 5 µv max Input offset drift:.5 µv/ C max Low noise:.25 μv p-p High gain CMRR and PSRR: 5 db min Low supply current:. ma Wide supply
200 ma Output Current High-Speed Amplifier AD8010
a FEATURES 2 ma of Output Current 9 Load SFDR 54 dbc @ MHz Differential Gain Error.4%, f = 4.43 MHz Differential Phase Error.6, f = 4.43 MHz Maintains Video Specifications Driving Eight Parallel 75 Loads.2%
16-Bit ANALOG-TO-DIGITAL CONVERTER
16-Bit ANALOG-TO-DIGITAL CONVERTER FEATURES 16-BIT RESOLUTION LINEARITY ERROR: ±0.003% max (KG, BG) NO MISSING CODES GUARANTEED FROM 25 C TO 85 C 17µs CONVERSION TIME (16-Bit) SERIAL AND PARALLEL OUTPUTS
Improved Second Source to the EL2020 ADEL2020
Improved Second Source to the EL ADEL FEATURES Ideal for Video Applications.% Differential Gain. Differential Phase. db Bandwidth to 5 MHz (G = +) High Speed 9 MHz Bandwidth ( db) 5 V/ s Slew Rate ns Settling
High Accuracy 8-Pin Instrumentation Amplifier AMP02
a FEATURES Low Offset Voltage: 100 V max Low Drift: 2 V/ C max Wide Gain Range 1 to 10,000 High Common-Mode Rejection: 115 db min High Bandwidth (G = 1000): 200 khz typ Gain Equation Accuracy: 0.5% max
Very Low Distortion, Precision Difference Amplifier AD8274
Very Low Distortion, Precision Difference Amplifier AD8274 FEATURES Very low distortion.2% THD + N (2 khz).% THD + N ( khz) Drives Ω loads Excellent gain accuracy.3% maximum gain error 2 ppm/ C maximum
Serial Input 18-Bit Monolithic Audio DIGITAL-TO-ANALOG CONVERTER
Serial Input 8-Bit Monolithic Audio DIGITAL-TO-ANALOG CONVERTER FEATURES 8-BIT MONOLITHIC AUDIO D/A CONVERTER LOW MAX THD + N: 92dB Without External Adjust 00% PIN COMPATIBLE WITH INDUSTRY STD 6-BIT PCM56P
Single Supply, Rail to Rail Low Power FET-Input Op Amp AD820
a FEATURES True Single Supply Operation Output Swings Rail-to-Rail Input Voltage Range Extends Below Ground Single Supply Capability from V to V Dual Supply Capability from. V to 8 V Excellent Load Drive
FEATURES TYPICAL APPLICATIO. LT1194 Video Difference Amplifier DESCRIPTIO APPLICATIO S
FEATURES Differential or Single-Ended Gain Block: ± (db) db Bandwidth: MHz Slew Rate: /µs Low Cost Output Current: ±ma Settling Time: ns to.% CMRR at MHz: db Differential Gain Error:.% Differential Phase
High Precision, Low Noise OPERATIONAL AMPLIFIERS
For most current data sheet and other product information, visit www.burr-brown.com OPA47 OPA7 OPA47 OPA7 OPA7 OPA7 OPA7 OPA7 OPA47 OPA OPA OPA4 High Precision, Low Noise OPERATIONAL AMPLIFIERS FEATURES
LF353 Wide Bandwidth Dual JFET Input Operational Amplifier
LF353 Wide Bandwidth Dual JFET Input Operational Amplifier General Description These devices are low cost, high speed, dual JFET input operational amplifiers with an internally trimmed input offset voltage
Very Low Distortion, Dual-Channel, High Precision Difference Amplifier AD8274 FUNCTIONAL BLOCK DIAGRAM +V S FEATURES APPLICATIONS GENERAL DESCRIPTION
Very Low Distortion, Dual-Channel, High Precision Difference Amplifier AD8273 FEATURES ±4 V HBM ESD Very low distortion.25% THD + N (2 khz).15% THD + N (1 khz) Drives 6 Ω loads Two gain settings Gain of
Quad Picoampere Input Current Bipolar Op Amp AD704
a FEATURES High DC Precision 75 V max Offset Voltage V/ C max Offset Voltage Drift 5 pa max Input Bias Current.2 pa/ C typical I B Drift Low Noise.5 V p-p typical Noise,. Hz to Hz Low Power 6 A max Supply
Precision Dual Difet OPERATIONAL AMPLIFIER
OP Precision Dual Difet OPERTIONL MPLIFIER FETURES VERY LOW NOISE: nv/ Hz at khz LOW V OS : µv max LOW DRIFT: µv/ C max LOW I B : p max FST SETTLING TIME: µs to.% UNITY-GIN STBLE PPLICTIONS DT CQUISITION
HA-2600, HA Features. 12MHz, High Input Impedance Operational Amplifiers. Applications. Pinouts. Ordering Information
HA26, HA26 September 998 File Number 292.3 2MHz, High Input Impedance Operational Amplifiers HA26/26 are internally compensated bipolar operational amplifiers that feature very high input impedance (MΩ,
Wideband, High Output Current, Fast Settling Op Amp AD842
a FEATURES AC PERFORMAE Gain Bandwidth Product: 8 MHz (Gain = 2) Fast Settling: ns to.1% for a V Step Slew Rate: 375 V/ s Stable at Gains of 2 or Greater Full Power Bandwidth: 6. MHz for V p-p DC PERFORMAE
FET-Input, Low Power INSTRUMENTATION AMPLIFIER
FET-Input, Low Power INSTRUMENTATION AMPLIFIER FEATURES LOW BIAS CURRENT: ±4pA LOW QUIESCENT CURRENT: ±45µA LOW INPUT OFFSET VOLTAGE: ±µv LOW INPUT OFFSET DRIFT: ±µv/ C LOW INPUT NOISE: nv/ Hz at f = khz
Quad Picoampere Input Current Bipolar Op Amp AD704
a FEATURES High DC Precision 75 V Max Offset Voltage V/ C Max Offset Voltage Drift 5 pa Max Input Bias Current.2 pa/ C Typical I B Drift Low Noise.5 V p-p Typical Noise,. Hz to Hz Low Power 6 A Max Supply
SON3130 FEATURES PRODUCT DESCRIPTION PIN CONFIGURATION (TOP VIEW) APPLICATIONS
PRODUCT DESCRIPTION The SON313 is designed for heart rate output with SON133(heart rate sensor) offering low cost. It has a wide input common mode voltage range and output voltage swing, and takes the
HA-2520, HA-2522, HA-2525
HA-, HA-, HA- Data Sheet September 99 File Number 9. MHz, High Slew Rate, Uncompensated, High Input Impedance, Operational Amplifiers HA-// comprise a series of operational amplifiers delivering an unsurpassed
Low Cost, General Purpose High Speed JFET Amplifier AD825
a FEATURES High Speed 41 MHz, 3 db Bandwidth 125 V/ s Slew Rate 8 ns Settling Time Input Bias Current of 2 pa and Noise Current of 1 fa/ Hz Input Voltage Noise of 12 nv/ Hz Fully Specified Power Supplies:
Voltage-to-Frequency and Frequency-to-Voltage Converter ADVFC32
a FEATURES High Linearity 0.01% max at 10 khz FS 0.05% max at 100 khz FS 0.2% max at 500 khz FS Output TTL/CMOS Compatible V/F or F/V Conversion 6 Decade Dynamic Range Voltage or Current Input Reliable
Microprocessor-Compatible ANALOG-TO-DIGITAL CONVERTER
Microprocessor-Compatible ANALOG-TO-DIGITAL CONVERTER FEATURES COMPLETE 12-BIT A/D CONVERTER WITH REFERENCE, CLOCK, AND 8-, 12-, OR 16-BIT MICROPROCESSOR BUS INTERFACE IMPROVED PERFORMANCE SECOND SOURCE
SGM321/SGM358/SGM324 1MHz, 60μA, Rail-to-Rail I/O CMOS Operational Amplifiers
/SGM358/SGM324 1MHz, 60μA, Rail-to-Rail I/O CMOS Operational Amplifiers GENERAL DESCRIPTION The (single), SGM358 (dual) and SGM324 (quad) are low cost, rail-to-rail input and output voltage feedback amplifiers.
CLC440 High Speed, Low Power, Voltage Feedback Op Amp
CLC440 High Speed, Low Power, Voltage Feedback Op Amp General Description The CLC440 is a wideband, low power, voltage feedback op amp that offers 750MHz unity-gain bandwidth, 1500V/µs slew rate, and 90mA
Single-Supply 42 V System Difference Amplifier AD8205
Single-Supply 42 V System Difference Amplifier FEATURES Ideal for current shunt applications High common-mode voltage range 2 V to +65 V operating 5 V to +68 V survival Gain = 50 Wide operating temperature
Ultralow Input Bias Current Operational Amplifier AD549
Ultralow Input Bias Current Operational Amplifier AD59 FEATURES Ultralow input bias current 60 fa maximum (AD59L) 250 fa maximum (AD59J) Input bias current guaranteed over the common-mode voltage range
SGM8551XN Single-Supply, Single Rail-to-Rail I/O Precision Operational Amplifier
PRODUCT DESCRIPTION The SGM8551XN is a single rail-to-rail input and output precision operational amplifier which has low input offset voltage, and bias current. It is guaranteed to operate from 2.5V to
LF442 Dual Low Power JFET Input Operational Amplifier
LF442 Dual Low Power JFET Input Operational Amplifier General Description The LF442 dual low power operational amplifiers provide many of the same AC characteristics as the industry standard LM1458 while
Distributed by: www.jameco.com 1-800-831-4242 The content and copyrights of the attached material are the property of its owner. LM148/LM248/LM348 Quad 741 Op Amps General Description The LM148 series