This note covers the following topics: Ideal
Operational Amplifier, Op-amp types , Non-inverting Amplifier, The Integrator
Amplifier, The Differentiator Amplifier, Basic OPAMP Configurations and Simple
Mathematical Operations , Differentiation and Integration using OPAMP, Digital
Logic Families, Boolean Logic Operations using Digital ICs, Adder and Subtractor
Circuits, Flip-Flop Circuits, Master-slave JK Flip-flop, IC 555 multivibrator
circuits.
Author(s): National Institute of Science Education
and Research Bhubaneswar
The goal of this text, as its name implies, is to allow the reader to
become proficient in the analysis and design of circuits utilizing modern linear
ICs. It progresses from the fundamental circuit building blocks through to
analog/digital conversion systems. The text is intended for use in a second year
Operational Amplifiers course at the Associate level, or for a junior level
course at the Baccalaureate level.
This note discusses the following topics:Op Amp:
equivalent circuit, Op Amp circuits, Op Amp circuits (linear region), Op Amp
circuits: inverting amplifier , Non-inverting amplifier , Loading effects and Op
Amp buffer.
This note explains the following
topics: Common-mode and differential-mode voltages , Common-Mode Rejection Ratio
, Difference amplifier , Improved difference amplifier , Instrumentation
amplifier , Current-to-voltage conversion , Op Amp circuits (linear region) ,
Offset voltage , Effect of VOS.
This note discusses and compares the existing compensation methods for
operational amplifiers. It explores a method to stabilize the op amps without
sacrificing bandwidth to the same degree that commonly used methods do.
This note covers the
following topics related to operational amplifier: Properites and Modeling of
Feedback Systems, Linear System Response, Stability, Compensation, Nonlinear
Systems, Direct-Coupled Amplifiers, Operational-Amplifier Design Techniques,
Integrated-Circuit Operational Amplifiers, Basic and Advanced Applications.
Author(s): James K. Roberge and Kent
H. Lundberg, Massachusetts Institute of Technology
This note covers the following topics: Circuits and Analyses Using The
Ideal Operational Amplifier, Characteristics Of Practical Operational
Amplifiers, Frequency Dependent Properties, Bode Plots and Basic Practical
Circuitry, Voltage Detectors and Comparators, The Voltage Follower, Voltage and
Current References, The Non-inverting Amplifier, Inverting Amplifier,
Integrators, Practical Integrators, The Differential (balanced) Output Amplifier
and Dc Amplifiers.
This note covers
the following topics: Ideal Op-amp in an open loop configuration, Operational
Amplifier Circuits as Computational Devices, Summing Amplifier, Difference
Amplifier, Instrumentation Amplifier, Voltage to Current converter, The
Differentiator: Active High Pass Filter, Active Band Reject Filter, Diodes and
transistors in op-amp circuits.
Author(s): Prof.
David Cory, Prof. Ian Hutchinson and Prof. Manos Chaniotakis
This note explains the following topics: Inverting Amplifier,
Noninverting Amplifier, Single Op-Amp Bandpass Filter, 2nd Order Opamp Filters
and Low Power Op-Amp - Audio Amp.
The approach to electronics taken in this course note will be a mixture
of physical concepts and design principles. This note explains the following
topics: Direct Current Circuits, Alternating Current Circuits, Filter Circuits,
Diode Circuits, Transistor Circuits, Digital Circuits, Operational Amplifiers,
Data Acquisition and Process Control.