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32组--常用运放性能参数

2023-08-21 来源:好走旅游网
1. UA741

电源电压 (-3~-18)~(+3~+15) 输入失调电压 2mV 输入失调电流 2nA 开环电压增益 106DB 输入电阻 1M 输出电阻 75 BGP :1MHZ 摆率:0.5V/us Kcmr:90Db 功耗:50Mw 输入范围:-13~+13V

2. LF356

           

HIGH SPEED J-FET OP-AMPs : up to 20MHz,50V/us

OFFSET VOLTAGE ADJUSTMENT DOES NOT DEGRADE DRIFT OR COMMON-MODE REJECTION AS IN MOST OF MONOLITHIC AMPLIFIERS

INTERNAL COMPENSATION AND LARGE DIFFERENTIAL INPUT VOLTAGE CAPABILITY(UP TO VCC+) CMR,SVR :80---100Db

±VOPP Output Voltage Swing (RL = 10kW,RL = 2kW)= ±12 Input Offset Voltage Drift (RS = 50W) - (note 2) 5 uV/oC Ri Input Resistance (Tamb = 25oC) =1012 欧姆 Ci Input Capacitance (Tamb = 25oC) =3 pF Unity-gain bandwidth (25C )= 0.4~ 0.6 MHz ri Input resistance (25C )= 7 ~31 M CMRR Common V RS (25C) =94~ 110Db 可调零

3. OP07

4. OP37

5. AD811

               

High Speed:140 MHz Bandwidth (3 dB, G = +1);120 MHz Bandwidth (3 dB, G = +2); 5 MHz Bandwidth (0.1 dB, G = +2) 2500 V/us Slew Rate(15V)

25 ns Settling Time to 0.1% (For a 2 V Step);65 ns Settling Time to 0.01% (For a 10 V Step)

Excellent Video Performance (RL =150 V) 0.01% Differential Gain, 0.01° Differential Phase Voltage Noise of 1.9 nVHz

Low Distortion: THD = –74 dB @ 10 MHz

Excellent DC Precision:3 mV max Input Offset Voltage Specified for 5 V and 15 V Operation

Common-Mode Input Voltage . . . . . . . . . . . . . . . . . . . . . ±VS Differential Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . .±6 V OUTPUT CHARACTERISTICS

Voltage Swing, Useful Operating Range5 ±5 V ±2.9 V ±15 V ±12 V

Output Current = 100 mA

 +-2.3 V Output Swing into a 75 V Load (VS = 5 V)

      

Short-Circuit Current = 150 mA

Output Resistance (Open Loop @ 5 MHz)= 9 9 W INPUT CHARACTERISTICS +Input Resistance : 1.5 MW –Input Resistance : 14 W

Input Capacitance +Input = 7.5 pF Common-Mode Voltage Range =±13 V

6.AD844

60 MHz, 2000 V/ms Monolithic Op Amp

           

Wide Bandwidth: 60 MHz at Gain of –1, 33 MHz at Gain of –10 Very High Output Slew Rate: Up to 2000 V/ms 20 MHz Full Power Bandwidth, 20 V pk-pk, RL = 500 V Fast Settling: 100 ns to 0.1% (10 V Step) Differential Gain Error: 0.03% at 4.4 MHz Differential Phase Error: 0.158 at 4.4 MHz High Output Drive: 650 mA into 50 Load Low Offset Voltage: 150 mV max (B Grade)

Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6 V Voltage Swing ´ Bandwidth Product . . . . . . . . . . . 350 V-MHz |VH–VIN| . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .£ 6.3 V |VL–VIN| . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .£ 6.3 V

 Low Quiescent Current: 6.5 Ma

1. The AD844 is a versatile, low cost component providing an excellent combination of ac and dc performance. It may be used as an alternative to the EL2020 and CLC400/1.

2. It is essentially free from slew rate limitations. Rise and fall times are essentially independent of output level.

3. The AD844 can be operated from 4.5 V to 18 V power supplies and is capable of driving loads down to 50 , as well as driving very large capacitive loads using an external network.

4. The offset voltage and input bias currents of the AD844 are laser trimmed to minimize dc errors; VOS drift is typically 1 V/C and bias current drift is typically 9 nA/C.

5. The AD844 exhibits excellent differential gain and differential phase characteristics, making it suitable for a variety of video applications with bandwidths up to 60 MHz.

6. The AD844 combines low distortion, low noise and low drift with wide bandwidth, making it outstanding as an input amplifier for flash A/D converters.

7.AD8048/AD8047

250 MHz, General Purpose Voltage Feedback Op Amps

  

Wide Bandwidth AD8047, G = +1 AD8048, G = Small Signal 250 MHz 260 MHz Large Signal (2 V p-p) 130 MHz 160 MHz

         

5.8 mA Typical Supply Current Low Distortion, (SFDR) Low Noise :

–66 dBc typ @ 5 MHz –54 dBc typ @ 20 MHz

5.2 nV/Hz (AD8047), 3.8 nV/Hz (AD8048) Noise Drives 50 pF Capacitive Load High Speed

Slew Rate 750 V/s (AD8047), 1000 V/s (AD8048) Settling 30 ns to 0.01%, 2 V Step

 3 V to 6 V Supply Operation

8. AD8037

Low Distortion, Wide Bandwidth Voltage Feedback Clamp Amps

Superb Clamping Characteristics 3 mV Clamp Error

1.5 ns Overdrive Recovery

Minimized Nonlinear Clamping Region 240 MHz Clamp Input Bandwidth 3.9 V Clamp Input Range Wide Bandwidth AD8036 AD8037 Small Signal 240 MHz 270 MHz

Large Signal (4 V p-p) 195 MHz 190 MHz Good DC Characteristics 2 mV Offset 10 mV/8C Drift

Ultralow Distortion, Low Noise –72 dBc typ @ 20 MHz 4.5 nV/Hz Input Voltage Noise High Speed

Slew Rate 1500 V/ms

Settling 10 ns to 0.1%, 16 ns to 0.01% 63 V to 65 V Supply Operation

9.LM6132

Low Power 10 MHz Rail-to-Rail I/O Operational Amplifiers

(For 5V Supply, Typ Unless Noted) n Rail-to-Rail input CMVR −0.25V to 5.25V n Rail-to-Rail output swing 0.01V to 4.99V n High gain-bandwidth, 10 MHz at 20 kHz

n Slew rate 12 V/µs

n Low supply current 360 µA/Amp n Wide supply range 2.7V to over 24V n CMRR 100 dB

n Gain 100 dB with RL = 10k n PSRR 82 dB

GBW Gain-Bandwidth Product at supply=5v f = 20 kHz 10 MHz

LM6132 can drive capacitive loads as large as 500 pF at unity gain and not oscillate.

10.LM6171

High Speed Low Power Low Distortion Voltage Feedback Amplifier

n Easy-To-Use Voltage Feedback Topology n Very High Slew Rate: 3600V/µs

n Wide Unity-Gain-Bandwidth Product: 100 MHz n −3 dB Frequency @ AV = +2: 62 MHz n Low Supply Current: 2.5 mA n High CMRR: 110 dB

n High Open Loop Gain: 90 dB

n Specified for ±15V and ±5V Operation RIN Input Resistance Common Mode 40 M欧

Differential Mode 4.9M欧

RO Open Loop 14 欧

The LM6171 is a high speed, unity-gain stable voltage feedback amplifier. It consumes only 2.5 mA supply current

while providing a gain-bandwidth product of 100 MHz and a slew rate of 3600V/µs. It also has other great features such as low differential gain and phase and high output current. The LM6171 is a good choice in high speed circuits. The LM6171 is a true voltage feedback amplifier. Unlike current feedback amplifiers (CFAs) with a low inverting input impedance and a high non-inverting input impedance, both inputs of voltage feedback amplifiers (VFAs) have high impedance nodes. The low impedance inverting input in CFAs will couple with feedback capacitor and cause oscillation.

As a result, CFAs cannot be used in traditional op amp circuits such as photodiode amplifiers, I-to-V converters and integrators.

11.LM6172

12.THS3001, THS3002

420-MHz HIGH-SPEED CURRENT-FEEDBACK AMPLIFIERS

_ High Speed

– 420 MHz Bandwidth (G = 1, –3 dB) – 6500 V/s Slew Rate – 40-ns Settling Time (0.1%)

_ High Output Drive, IO = 100 mA _ Excellent Video Performance

– 115 MHz Bandwidth (0.1 dB, G = 2) – 0.01% Differential Gain – 0.02Differential Phase

_ Low 3-mV (max) Input Offset Voltage _ Very Low Distortion

– THD = –96 dBc at f = 1 MHz – THD = –80 dBc at f = 10 MHz

_ Wide Range of Power Supplies

– VCC = 4.5 V to 16 V

_ Evaluation Module Available

The THS300x is a high-speed current-feedback operational amplifier, ideal for communication, imaging, and high-quality video applications. This device offers a very fast 6500-V/s slew rate, a 420-MHz bandwidth, and 40-ns settling time for large-signal applications requiring excellent transient response. In addition, the THS300x operates with a very low distortion of –96 dBc, making it well suited for applications such as wireless communication basestations or ultrafast ADC or DAC buffers.

13.MAX4305

740MHz, Low-Noise, Low-DistortionOp Amps in SOT23-5

SUPPLY(-5V————+5V)

闭环输出阻抗 1欧姆@10MHz,RL=100 9欧姆@10MHz,RL=100K © Low 2.1nV/Hz Voltage Noise Density © Ultra-High 740MHz -3dB Bandwidth (MAX4304, AVCL = 2V/V)

© 100MHz 0.1dB Gain Flatness (MAX4104/4105) © 1400V/µs Slew Rate (MAX4105/4305)

© -88dBc SFDR (5MHz, RL = 100) (MAX4104/4304) © High Output Current Drive: ±70mA

© Low Differential Gain/Phase Error: 0.01%/0.01° (MAX4104/4304)

© Low ±1mV Input Offset Voltage

The MAX4105 is compensated for a minimum gain of +5V/V and delivers a 410MHz bandwidth and a 1400V/sec slew rate. The MAX4305 has +10V/V minimum gain compensation and delivers a 340MHz bandwidth and a 1400V/µs slew rate. Low voltage noise density of 2.1nV/Hz and -88dBc spurious-free dynamic range make these devices ideal for low-noise/low-distortion video and telecommunications applications. These op amps also feature a wide output voltage swing of ±3.7V and ±70mA output current drive capability.

14. OPA4354(pay attention to supply can not beyond 5v)

voltage-feedback 250MHz, Rail-to-Rail I/O, CMOS OPERATIONAL AMPLIFIERS

_ UNITY-GAIN BANDWIDTH: 250MHz

_ WIDE BANDWIDTH: 100MHz GBW _ HIGH SLEW RATE: 150V/s _ LOW NOISE: 6.5nV/󰀀Hz _ RAIL-TO-RAIL I/O

_ HIGH OUTPUT CURRENT: >

100mA

_ EXCELLENT VIDEO

PERFORMANCE:

Diff Gain: 0.02%, Diff Phase: 0.09_

0.1dB Gain Flatness: 40MHz

_ LOW INPUT BIAS CURRENT:

3pA

_ QUIESCENT CURRENT: 4.9mA _ THERMAL SHUTDOWN

_ SUPPLY RANGE: 2.5V to 5.5V

15.INA155

Single-Supply, Rail-to-Rail Output, CMOS INSTRUMENTATION AMPLIFIER 低输出阻抗

l RAIL-TO-RAIL OUTPUT SWING: Within 10mV l LOW OFFSET VOLTAGE: 200V l LOW OFFSET DRIFT: 5V/C

l INTERNAL FIXED GAIN = 10V/V OR 50V/V l SPECIFIED TEMPERATURE RANGE: –55C to +125C

l LOW INPUT BIAS CURRENT: 0.2pA l WIDE BANDWIDTH: 550kHz in G = 10 l HIGH SLEW RATE: 6.5V/s

16.MAX414

Quad 28Mhz,low noise low voltage precision op amp

Cmrr 105-120db psrr 90-94db 可调零 可可驱动nF级容性负载

17.INA322

microPower, Single-Supply, CMOS INSTRUMENTATION AMPLIFIER

The power supply should be capacitively decoupled with 0.1F capacitors as close to the INA322 as possible for noisy or high-impedance applications. The output is referred to the reference terminal, which must be at least 1.2V below the positive supply rail. 18.OPA2277

High Precision OPERATIONAL AMPLIFIERS

l ULTRA LOW OFFSET VOLTAGE: 10V l ULTRA LOW DRIFT: 0.1V/C l HIGH OPEN-LOOP GAIN: 134dB

l HIGH COMMON-MODE REJECTION: 140dB l HIGH POWER SUPPLY REJECTION: 130dB l LOW BIAS CURRENT: 1nA max l WIDE SUPPLY RANGE: 2V to 18V l LOW QUIESCENT CURRENT: 800A/amp 19.INA129

Precision, Low Power INSTRUMENTATION AMPLIFIERS

l LOW OFFSET VOLTAGE: 50V max l LOW DRIFT: 0.5V/C max

l LOW INPUT BIAS CURRENT: 5nA max l HIGH CMR: 120dB min l INPUTS PROTECTED TO 40V l WIDE SUPPLY RANGE: 2.25 to 18V LOW QUIESCENT CURRENT: 700A

SLOW RATE 4V/us

Their versatile 3-op amp design and small size make them ideal for a wide range of applications. Current-feedback input circuitry provides wide bandwidth even at high gain (200kHz at G = 100). A single external resistor sets any gain from 1 to 10,000. INA128 provides an industry standard gain equation; INA129’s gain equation is compatible with the AD620.

20.INA157

High-Speed, Precision DIFFERENCE AMPLIFIER

l LOW OFFSET VOLTAGE: 500V max l LOW OFFSET DRIFT: 2V/C l LOW GAIN ERROR: 0.05% max l WIDE BANDWIDTH: 3MHz l HIGH SLEW RATE: 14V/s

l FAST SETTLING TIME: 3s to 0.01% l WIDE SUPPLY RANGE: 4V to 18V l LOW QUIESCENT CURRENT: 2.4mA

输入阻抗只有几十K 可驱动500PF容性负载

Offset Adjustment

21.LME49720

Dual High Performance, High Fidelity Audio Operational Amplifier

Common-Mode Rejection –10VRL = 600Ω 0.00003% (typ)

■ Input Noise Density 2.7nV/√Hz (typ) ■ Slew Rate ±20V/μs (typ)

■ Gain Bandwidth Product 55MHz (typ) ■ Open Loop Gain (RL = 600Ω) 140dB (typ) ■ Input Bias Current 10nA (typ) ■ Input Offset Voltage 0.1mV (typ) ■ DC Gain Linearity Error 0.000009%

Features

■ Easily drives 600Ω loads

■ Optimized for superior audio signal fidelity ■ Output short circuit protection

■ PSRR and CMRR exceed 120dB (typ)

The LME49720 combines extremely low voltage noise density (2.7nV/√Hz) with vanishingly low THD+N (0.00003%) to easily satisfy the most demanding audio applications. To ensure that the most

challenging loads are driven without compromise, the LME49720 has a high slew rate of ±20V/μs and an output current capability of ±26mA. Further, dynamic range is maximized by an output stage that drives 2kΩ loads to within 1V of either power supply voltage and to within 1.4V when driving 600Ω loads. The LME49720's outstanding CMRR (120dB), PSRR (120dB), and VOS (0.1mV) give the amplifier excellent operational amplifier DC performance.

The LME49720 has a wide supply range of ±2.5V to ±17V.Over this supply range the LME49720’s input circuitry maintains excellent common-mode and power supply rejection, as well as maintaining its low input bias current. The LME49720 is unity gain stable. This Audio Operational Amplifier achieves outstanding AC performance while driving complex loads with values as high as 100pF.

22.INA143

High-Speed, Precision, G = 10 or G = 0.1DIFFERENCE AMPLIFIERS

l G = 10V/V or G = 0.1V/V l LOW OFFSET VOLTAGE:

250V max, 3V/C max

l LOW GAIN ERROR: 0.01% l HIGH SLEW RATE: 5V/s

l FAST SETTLING TIME: 9s to 0.01% l LOW QUIESCENT CURRENT: 950A l WIDE SUPPLY RANGE: 2.25V to 18V

23.OPA637

Precision High-Speed Difet® OPERATIONAL AMPLIFIERS

l VERY LOW NOISE: 4.5nV/Hz at 10kHz

l FAST SETTLING TIME: OPA627—550ns to 0.01% OPA637—450ns to 0.01% l LOW VOS: 100V max l LOW DRIFT: 0.8V/C max l LOW IB: 5pA max

l OPA627: Unity-Gain Stable l OPA637: Stable in Gain 5

24.INA410 SINGLE

25.

指标解释:

1.DISTRIBUTION

2. The input bias currents are junction leakage currents which approximately double for every 10oC increase in the junction temperature Tamb. Due to limited production test time, the input bias current measured is correlated to junction

temperature.In a normal operation the junction temperature rises above the ambient temperature as a result of internal power dissipation ,Ptot-Tamb =Tamb+Rth(j-a) x Ptot where Rth(j-a)is the thermal resistance from junction to ambient. Use of a heatsink is recommended f input currents are to be kept to a minimum.3 Supply voltage rejection is measured for both supply magnitudes increasing or decreasing simultaneously, in accordance with common practise.

4. Settling time is defined here, for a unity gain inverter connection using

2kresistors for the LF155, LF156 series. It is the time required for the error voltage (the voltage at the inverting input pin on the amplifier) to settle to within 0.01% of its final value from the time a 10V step input is applied to the inverter. For the LF157 series AV = -5, the feedback resistor from output to input is 2kand the output step is 10V. 应用技巧:

1.There are many things to consider when designing PC boards for high speed op amps. Without proper caution, it is very easy and frustrating to have excessive ringing, oscillation and other degraded AC performance in high speed circuits. As a rule, the signal traces should be short and wide to provide low inductance and low impedance paths. Any unused board space needs to be grounded to reduce stray signal pickup. Critical components should also be grounded at a common point to eliminate voltage drop. Sockets add capacitance to the board and can affect frequency performance.It is better to solder the amplifier directly into the PCboard without using any socket. jack

2.COMPONENTS SELECTION AND FEEDBACK RESISTOR

It is important in high speed applications to keep all component leads short because wires are inductive at high frequency. For discrete components, choose carbon composition-type resistors and mica-type capacitors. Surface mount components are preferred over discrete components for minimum

inductive effect. Large values of feedback resistors can couple with parasitic capacitance and cause undesirable effects such as ringing or oscillation in high speed amplifiers. For LM6171, a feedback resistor of 510gives optimal performance.

3.The combination of an amplifier’s input capacitance with the gain setting resistors adds a pole that can cause peaking or

oscillation. To solve this problem, a feedback capacitor with a value CF > (RG x CIN)/RF can be used to cancel that pole. For LM6171, a feedback capacitor of 2 pF is recommended. Figure 1illustrates the compensation circuit.

4.Driving Capacitive Loads

Amplifiers driving capacitive loads can oscillate or have ringing at the output. To eliminate oscillation or reduce ringing,an isolation resistor can be placed as shown below in Figure5. The combination of the isolation resistor and the load capacitor forms a pole to increase stablility by adding more phase margin to the overall system. The desired performance depends on the value of the isolation resistor; the bigger the isolation resistor, the more damped the pulse response becomes. For LM6171, a 50isolation resistor is

recommended for initial evaluation. Figure 6 shows the LM6171 driving a 200 pF load with the 50isolation resistor.

5.A common error for the first-time CFB user is the creation of a unity gain buffer amplifier by

shorting the output directly to the inverting input. A CFB amplifier in this configuration will oscillate and is not recommended. The THS300x, like all CFB amplifiers, must have a feedback resistor for stable operation. Additionally, placing capacitors directly from the output to the inverting input is not recommended. This is because, at high frequencies, a capacitor has a very low impedance. This results in an unstable amplifier and should not be considered when using a current-feedback amplifier. Because of this, integrators and simple low-pass filters, which are easily implemented on a VFB amplifier, have to be designed slightly differently. If filtering is required, simply place an RC-filter at the noninverting terminal of the operational-amplifier (see Figure Figure 57. Single-Pole Low-Pass Filter)

If a multiple-pole filter is required, the use of a Sallen-Key filter can work very well with CFB amplifiers. This is because the filtering elements are not in the negative feedback loop and stability is not compromised. Because of their high slew-rates and high bandwidths, CFB amplifiers can create very accurate signals and help minimize distortion. An example is shown in Figure 58.

Figure 58. 2-Pole Low-Pass Sallen-Key Filter

There are two simple ways to create an integrator with a CFB amplifier. The first, shown in Figure 59, adds a resistor in series with the capacitor. This is acceptable because at high frequencies, the resistor is dominant and the feedback impedance never drops below the resistor value. The second, shown in Figure 60, uses positive feedback to create the integration. Caution is advised because oscillations can occur due to the positive feedback.

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