Electronics: Operational Amplifier and its Applications

Electronics: Operational Amplifier and its Applications, available at $44.99, has an average rating of 4.8, with 65 lectures, based on 22 reviews, and has 113 subscribers.

You will learn about Desired characteristics of amplifiers, Problems associated with signal amplifiers, Negative feedback theory, Opamp and its history, Opamp Jargons Internal architecture and equivalent circuit, Differential-mode and common-mode signals, Voltage transfer curve, Open and closed-loop parameters, Virtual ground Basics of feedback amplifiers, Voltage amplifiers, Transresistance amplifiers, Transconductance amplifiers, Current amplifiers DC Specifications – Open-loop gain, Input offset voltage, Input bias and offset currents, Input and output impedances, Supply voltage, Common-mode input range DC Specifications – Differential-mode input voltage range, Quiescent current, Output voltage swing or range, Output current AC Specifications – Bandwidth, Noise, Slew-rate, Full power bandwidth, Settling-time, Rise and fall times, Phase margin, PSRR, CMRR Understanding Datasheet Parameters – Anatomy of datasheet, Absolute maximum ratings, ESD ratings, Thermal information, Electrical characteristics, Graphs Linear applications of opamp such as Inverting and Non-inverting amplifier, Buffer, Differential and Instrumentation amplifier, Integrator Non-linear applications of opamp such as Comparator, Bistable, Monostable and Astable Multivibrators and other popular applications Pugh Matrix based step-by-step procedure for selecting an operational amplifier for any given application This course is ideal for individuals who are Engineering Students pursuing their Bachelor's and Master's Degree or Electronics Designers, Analog Design and Application Engineers or Industry Professionals working on Signal Conditioning Circuits or Researchers working on Control of Power Converters or All Power Electronics and Analog Design Enthusiasts It is particularly useful for Engineering Students pursuing their Bachelor's and Master's Degree or Electronics Designers, Analog Design and Application Engineers or Industry Professionals working on Signal Conditioning Circuits or Researchers working on Control of Power Converters or All Power Electronics and Analog Design Enthusiasts.

Enroll now: Electronics: Operational Amplifier and its Applications

Summary

Title: Electronics: Operational Amplifier and its Applications

Price: $44.99

Average Rating: 4.8

Number of Lectures: 65

Number of Published Lectures: 65

Number of Curriculum Items: 65

Number of Published Curriculum Objects: 65

Original Price: $19.99

Quality Status: approved

Status: Live

What You Will Learn

Desired characteristics of amplifiers, Problems associated with signal amplifiers, Negative feedback theory, Opamp and its history, Opamp Jargons
Internal architecture and equivalent circuit, Differential-mode and common-mode signals, Voltage transfer curve, Open and closed-loop parameters, Virtual ground
Basics of feedback amplifiers, Voltage amplifiers, Transresistance amplifiers, Transconductance amplifiers, Current amplifiers
DC Specifications – Open-loop gain, Input offset voltage, Input bias and offset currents, Input and output impedances, Supply voltage, Common-mode input range
DC Specifications – Differential-mode input voltage range, Quiescent current, Output voltage swing or range, Output current
AC Specifications – Bandwidth, Noise, Slew-rate, Full power bandwidth, Settling-time, Rise and fall times, Phase margin, PSRR, CMRR
Understanding Datasheet Parameters – Anatomy of datasheet, Absolute maximum ratings, ESD ratings, Thermal information, Electrical characteristics, Graphs
Linear applications of opamp such as Inverting and Non-inverting amplifier, Buffer, Differential and Instrumentation amplifier, Integrator
Non-linear applications of opamp such as Comparator, Bistable, Monostable and Astable Multivibrators and other popular applications
Pugh Matrix based step-by-step procedure for selecting an operational amplifier for any given application

Who Should Attend

Engineering Students pursuing their Bachelor's and Master's Degree
Electronics Designers, Analog Design and Application Engineers
Industry Professionals working on Signal Conditioning Circuits
Researchers working on Control of Power Converters
All Power Electronics and Analog Design Enthusiasts

Target Audiences

Engineering Students pursuing their Bachelor's and Master's Degree
Electronics Designers, Analog Design and Application Engineers
Industry Professionals working on Signal Conditioning Circuits
Researchers working on Control of Power Converters
All Power Electronics and Analog Design Enthusiasts

Hello There!

Welcome to my course titled “Electronics: Operational Amplifier and its Applications.“

This comprehensive Three and half-hour course optimizes learning by offering a detailed understanding of opamp circuits. By bridging theory and practical applications, students save time by gaining hands-on experience, directly applying concepts to real-world scenarios, and significantly accelerating their learning curve.

The detailed course curriculum is highlighted below:

Module 1: Introduction to Operational Amplifiers

This module discusses the negative feedback theory, historical context, and the birth of opamp by examining the limitations of traditional signal amplifiers. It delves into the internal architecture and provides an extensive overview of opamp functionality.

Module 2: Types of Operational Amplifiers

This module explores different types of feedback amplifiers such as voltage feedback-based opamps, transimpedance amplifiers, transconductance amplifiers, and current-feedback-based opamps.

Module 3: DC Specifications of Operational Amplifiers

This module delves into various DC specifications like open-loop gain, virtual ground, input offset voltage, input bias and offset currents, input and output impedance, supply voltage, common-mode voltage range, differential mode voltage range, quiescent current, output voltage swing, and output current.

Module 4: AC Specifications of Operational Amplifiers

This module covers bandwidth, noise, slew-rate, full power bandwidth, settling time, rise and fall times, phase margin, CMRR, and PSRR.

Module 5: Understanding Datasheet Parameters

This module discusses the anatomy of an opamp datasheet and how to interpret it effectively.

Module 6: Applications of Opamp

This module explores various linear and non-linear applications along with practical circuit examples.

Module 7: Opamp Selection Procedure for Any Applications

This module guides you through a step-by-step procedure to select an opamp based on specific applications.

Module 8: Conclusion

This module concludes our journey together along with many references.

Skill Enhancements:

In-depth Understanding:

Develop a profound knowledge of Opamp theory, characteristics, and their myriad applications.

Practical Application Proficiency:

Apply theoretical knowledge enhancing problem-solving abilities in real-world scenarios.

Critical Decision-Making and Design Skills:

Master the art of informed decision-making in Opamp selection and circuit design based on specific requirements and performance expectations.

Enroll in this transformative course to become proficient in Opamp circuits, empowering yourself with the skills essential for excelling in analog circuit design and analysis.

We look forward to your participation!

Course Curriculum

Chapter 1: Introduction

Lecture 1: Introduction

Chapter 2: Introduction to Operational Amplifiers

Lecture 1: Desired Characteristics of an Amplifier

Lecture 2: Signal Amplifiers and their Problems

Lecture 3: The Negative Feedback

Lecture 4: Operational Amplifier and its History

Lecture 5: Opamp Jargons

Lecture 6: Internal Architecture and Equivalent Circuit

Lecture 7: DM and CM Signals

Lecture 8: Voltage Transfer Curve

Lecture 9: Open and Closed-loop Parameters

Lecture 10: Opamp Specifications and their Importance

Chapter 3: Types of Operational Amplifiers

Lecture 1: Basics of Feedback Amplifiers

Lecture 2: Voltage Amplifier

Lecture 3: Transimpedance Amplifier

Lecture 4: Transconductance Amplifier

Lecture 5: Current Amplifier

Chapter 4: DC Specifications of Operational Amplifiers

Lecture 1: Open Loop Gain

Lecture 2: Virtual Ground or Nulling

Lecture 3: Input Offset Voltage and Drift

Lecture 4: Input Bias Currents and their Compensation

Lecture 5: Input Offset Currents

Lecture 6: Input Impedance

Lecture 7: Output Impedance

Lecture 8: Supply Voltage Range

Lecture 9: Common Mode Input Voltage Range

Lecture 10: Differential Mode Input Voltage Range

Lecture 11: Quiescent Current

Lecture 12: Output Voltage Range or Swing

Lecture 13: Output Current

Chapter 5: AC Specifications of Operational Amplifiers

Lecture 1: Bandwidth

Lecture 2: Noise

Lecture 3: Slew-rate

Lecture 4: Full Power Bandwidth

Lecture 5: Settling Time

Lecture 6: Rise and Fall Times

Lecture 7: Phase Margin

Lecture 8: Power Supply Rejection Ratio (PSRR)

Lecture 9: Common Mode Rejection Ratio (CMRR)

Chapter 6: Understanding Datasheet Parameters

Lecture 1: Anatomy of Datasheet

Lecture 2: The Front Page

Lecture 3: Absolute Maximum Ratings

Lecture 4: ESD Ratings

Lecture 5: Recommended Operating Conditions

Lecture 6: Thermal Information

Lecture 7: Electrical Characteristics

Lecture 8: Typical Graphs

Lecture 9: Detailed Description and Typical Applications

Lecture 10: Ordering Information and Guide

Lecture 11: Packaging Information and Mechanical Data

Chapter 7: Opamp Based Applications

Lecture 1: Inverting Amplifier: Theory

Lecture 2: Inverting Amplifier: Circuit Example

Lecture 3: Non-inverting Amplifier: Theory

Lecture 4: Non-inverting Amplifier: Circuit Example

Lecture 5: Voltage Follower or Buffer

Lecture 6: Differential Amplifier

Lecture 7: Instrumentation Amplifier

Lecture 8: Integrator

Lecture 9: Differentiator

Lecture 10: Opamp as a Comparator

Lecture 11: Multivibrators

Lecture 12: Other Non-Linear Applications

Chapter 8: Opamp Selection Procedure for Any Applications

Lecture 1: Which Opamp Best Suits Your Application?

Lecture 2: Pugh Matrix

Lecture 3: Design Example

Chapter 9: Conclusion and References

Lecture 1: Conclusion

Instructors

Siri Subrahmanyam Vadlamani
Power Electronic Professional | M Tech from IISc Bangalore

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4 stars: 4 votes
5 stars: 18 votes

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