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LT1457CN8

LT1457CN8

LT1457CN8

Analog Devices, Inc.

2 Channels 7pA 82 dB Instrumentational OP Amps DIP

SOT-23

LT1457CN8 Datasheet PDF

non-compliant

Technical Specifications

Parameter NameValue
TypeParameter
Package / Case DIP
Number of Pins 8
Max Operating Temperature70°C
Min Operating Temperature 0°C
Number of Elements 2
Number of Channels 2
Number of Circuits 2
Max Supply Voltage40V
Min Supply Voltage9V
Operating Supply Current 1.8mA
Slew Rate4 V/μs
Common Mode Rejection Ratio 82 dB
Current - Input Bias 7pA
Input Offset Voltage (Vos) 150μV
Gain Bandwidth Product1.7MHz
Voltage Gain 109.54dB
Power Supply Rejection Ratio (PSRR) 86dB
Max Dual Supply Voltage20V
Nominal Gain Bandwidth Product 1MHz
RoHS StatusRoHS Compliant
Lead Free Contains Lead
In-Stock:3806 items

LT1457CN8 Product Details

LT1457CN8 Overview


The linear amplifier is packaged in a DIP case. The buffer op amp includes 8 pins. Regarding input offset voltage, op amp rates 150μV. This op amp can operate from a supply current at 1.8mA. Voltage gain should remain at 109.54dB. There are 2 circuits on this op amp. The op amp ic has 2 channels on it. The temperature should not be lower than 0°C for operational amplifier ics to operate. Use op amps only at temperatures no higher than 70°C. This linear amplifier has a total of 2 elements. With regard to the supply voltage, this electrical component is capable of working from under 40V. It is advised to keep the op amp's supply voltage higher than 9V. You should conduct this electronic component under the dual supply voltage of 20V.

LT1457CN8 Features


109.54dB voltage gain


LT1457CN8 Applications


There are a lot of Analog Devices, Inc.
LT1457CN8 Instrumentational OP Amps applications.


  • Inverse/same-phase proportional circuit
  • Addition operation circuits
  • Subtraction operation circuits
  • single/dual op amp sum and difference circuits
  • Integrator circuits
  • Differentiator circuits
  • Logarithmic operation circuits
  • Exponential operation circuits
  • Multiplication circuits
  • Division circuits

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