EKT 314/4 WEEK 5 : CHAPTER 3 SIGNAL CONDITIONING ELECTRONIC INSTRUMENTATION.

Slides:

Advertisements

Similar presentations

Introduction Goal: Understand the design of op-amp based ICs (comparators, oscillators, integrators, differentiators, instrumentation amplifiers) for applications.

Advertisements

Operational Amplifiers

Operational Amplifiers 1. Copyright  2004 by Oxford University Press, Inc. Microelectronic Circuits - Fifth Edition Sedra/Smith2 Figure 2.1 Circuit symbol.

Chapter 7 Operational-Amplifier and its Applications

CHAPTER 3: SPECIAL PURPOSE OP-AMP CIRCUITS

Describe and analyze the operation of several types of comparator circuits. Describe and analyze the operation of several types of summing amplifiers.

Ref:080114HKNOperational Amplifier1 Lecture 1 Op-Amp Introduction of Operation Amplifier (Op- Amp) Analysis of ideal Op-Amp applications Comparison of.

* Operational Amplifiers * Op-Amp Circuits * Op-Amp Analysis

Operational Amplifier

Department of Information Engineering357 Operation amplifier The tail, large impedance gives high CMRR Mirror as active load. High gain Follower as buffer.

Announcements Tuesday’s Lecture next week is cancelled –October 18 th Assignment 4 is active, due in my mailbox by 5pm Friday (October 14 th ) Mid-term.

Operational Amplifiers

1 ECE 3336 Introduction to Circuits & Electronics MORE on Operational Amplifiers Spring 2015, TUE&TH 5:30-7:00 pm Dr. Wanda Wosik Set #14.

© 2012 Pearson Education. Upper Saddle River, NJ, All rights reserved. Electronic Devices, 9th edition Thomas L. Floyd Electronic Devices Ninth.

Introduction to Op Amps

Operational Amplifiers

The Ideal Op-amp (Operational amplifier) + – v+v+ v–v– V OUT + – + – V IN V OUT V IN [μV] V OUT [V] +15V –15V V OUT =A(v + –v – ) A~10 5 saturation.

Announcements Assignment 3 due now, or by tomorrow 5pm in my mailbox Assignment 4 posted, due next week –Thursday in class, or Friday 5pm in my mailbox.

Content Op-amp Application Introduction Inverting Amplifier

Chapter 8 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Characteristics of Op-Amp &

Electronic Devices Ninth Edition Floyd Chapter 13.

Integrator Op Amp Amplifier

Operational Amplifiers David Lomax Azeem Meruani Gautam Jadhav.

Introduction to Op Amp Circuits ELEC 121. April 2004ELEC 121 Op Amps2 Basic Op-Amp The op-amp is a differential amplifier with a very high open loop gain.

Analogue Electronics II EMT 212/4

EKT314/4 Electronic Instrumentation

EKT314/4 Electronic Instrumentation

A Differentiator Circuit.  All of the diagrams use a uA741 op amp. ◦ You are to construct your circuits using an LM 356 op amp.  There is a statement.

Chapter 8 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

electronics fundamentals

Chapter 19 Electronics Fundamentals Circuits, Devices and Applications - Floyd © Copyright 2007 Prentice-Hall Chapter 19.

CHAPTER 11 Op-Amp Applications. Objectives Describe and Analyze: Audio mixers Integrators Differentiators Peak detectors Comparators Other applications.

Operational Amplifier

Microprocessor Interface

Lecture 1 Op-Amp Introduction of Operation Amplifier (Op- Amp) Analysis of ideal Op-Amp applications Comparison of ideal and non-ideal Op-Amp Non-ideal.

Electronic Troubleshooting Chapter 8 Operational Amplifiers.

EE445:Industrial Electronics. Outline Introduction Some application Comparators Integrators & Differentiators Summing Amplifier Digital-to-Analog (D/A)

10/11/2015 Operational Amplifier Characterization Chapter 3.

Module 4 Operational Amplifier

1 Fundamentals of Microelectronics  CH1 Why Microelectronics?  CH2 Basic Physics of Semiconductors  CH3 Diode Circuits  CH4 Physics of Bipolar Transistors.

ELECTRONIC INSTRUMENTATION & PLC DKT Signal Conditioning Circuits.

UNIT – III : OP-AMPS AND APPLICATIONS

Fundamentals of Electric Circuits Chapter 5 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Operational Amplifiers The operational amplifier, also know as an op amp, is essentially a voltage amplifier with an extremely high voltage gain. One of.

Operational Amplifiers Op Amps – a useful building block K. El-Ayat 11.

Applications of OP-AMP. Introduction Operational amplifier using IC's is inexpensive, versatile and easy to use. For this reason they are used not only.

CommunicationElectronics Principles & Applications Chapter 5 Frequency Modulation Circuits.

3/19/2016 Subject Name: LINEAR IC’s AND APPLICATIONS Subject Code:10EC46 Prepared By: Kumutha A Department: Electronics and Communication Date:

Analogue Electronics Higher Physics Unit 2 Electricity And Electronics Introduction to Op-Amps.

1 Chapter 8 Operational Amplifier as A Black Box  8.1 General Considerations  8.2 Op-Amp-Based Circuits  8.3 Nonlinear Functions  8.4 Op-Amp Nonidealities.

OPERATIONAL AMPLIFIERS + - Presented by D.Satishkumar Asst. Professor, Electrical & Electronics Engineering

EE101-Lecture 8 Operational Amplifier Basics of amplifiers EE101 Fall 2012 Lect 8- Kang1 Noninverting amplifier & Inverting amplifier.

CHAPTER 20 OPERATIONAL AMPLIFIERS (OP-AMPS). Introduction to operational amplifiers Symbol and Terminals.

NON LINEAR IC APPLICATION USING OP AMP NAME:- ROLL NO. ROHAN V. KHRISTI 14ELEE310 AFJAL A. RATHOD 14ELEE311 NIKUNJ K. PARMAR 14ELEE312 SUB :- ANALOG ELECTRONIC.

1 - By Sandip B. kheni( ) Bhavin V. Mangukiya( )

An operational amplifier (Op-Amp) is a differential amplifier that amplifies the difference of voltages applied to its two input terminals (differential.

Module 2 Operational Amplifier Basics

EKT 314/4 WEEK 7 : CHAPTER 3 SIGNAL CONDITIONING ELECTRONIC INSTRUMENTATION.

 The differentiator or differentiating amplifier is as shown in figure.  This circuit will perform the mathematical operation of differentiation.

7/20/2016 Subject Name: LINEAR IC’s AND APPLICATIONS Subject Code:10EC46 Prepared By: Aparna.P Department: Electronics and Communication Date:

EKT 314/4 WEEK 6 : CHAPTER 3 SIGNAL CONDITIONING EKT 314 Electronic instrumentation.

BME 311: BIOMEDICAL INSTRUMENTATION I Lecturer: Ali Işın

Mrs V.S.KharoteChavan,E&Tc,PC poly

SIGNAL CONDITIONING Signal conditioning is stage of instrumentation system used for modifying the transduced signal into a usable format for the final.

Electronic Devices Ninth Edition Floyd Chapter 13.

Analogue Electronics Circuit II EKT 214/4

OSCILLATOR & Operational Amplifier

Chapter 4 – Operational Amplifiers – Part 2

Presentation transcript:

EKT 314/4 WEEK 5 : CHAPTER 3 SIGNAL CONDITIONING ELECTRONIC INSTRUMENTATION

Chapter 3 Problem Statement Don’t know why signal conditioning needed. Don’t know where should the signal conditioning part to be located. Don’t know what actually the content of signal conditioning part. Don’t know what the function of signal conditioning parts.

Chapter 3 Objectives To understand why signal conditioning is important To know where exactly signal conditioning circuit exist To implement amplifier, modulator and filter circuit in system To suit each circuit to system implementation

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

Introduction

SCC Function 1. Perform Linear Task/Process 2. Perform Non-Linear Task/Process

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

SCC Function 1. Perform Linear Task/Process › Amplification › Attenuation › Integration › Differentiation › Addition › Substraction 2. Perform Non-Linear Task/Process

SCC Function 1. Perform Linear Task/Process 2. Perform Non-Linear Task/Process › Modulation › Demodulation › Sampling › Filtering › Clipping & Clamping › Squaring & Linearizing › Multiplication

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

Preliminary Requirement Passive Transducer Require excitation Require amplification Active Transducer Require amplification

Signal Excitation Only needed by passive transducer since they cannot generate their own voltage or current Excitation come from external source External source can be ac or dc

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

SC System Type 1. DC Signal Conditioning System 2. AC Signal Conditioning System

SC System Type 1. DC Signal Conditioning System Generally used for common resistance transducers (e.g. potentiometer and straing gauges) 2. AC Signal Conditioning System Used for variable reactance transducers For systems where signal have to be transmitted via long cables to connect the transducers to signal conditioning equipment.

DC Signal Conditioning System

AC Signal Conditioning System

Signal Conditioning (SC) System Type DC SC SystemAC SC System

Chapter 3 Content Introduction Signal Conditioning Circuit (SCC) Function Preliminary Requirement Signal Conditioning (SC) System Type Amplifier Modulator Filter

Amplifier Two types Operational Amplifier (OpAmp) Instrumentation Amplifier

Amplifier Normal Amplifier Block Diagram OPAMPs Non-Inverting / Inverting Integrator / Differentiator Sum/Scale/Average Substractor Comparator Instrumentation Amplifier

Amplifier: Block Diagram Input Stage Dual input balanced output differential amplifer Double-ended high gain amplifier Gain = 60 Intermediate Stage Single-ended differential amplifier Dual input unbalanced output differential amplifier Gain = 30 Level Shifter Level translator circuit To bring dc output voltage to ground potential Output Stage Push-pull complementary amplifier Gain = 5 to 10

OPAMPs V o = AV id = A(V + - V - ) A – Large signal voltage gain V id – differential input voltage V + - noninverting terminal voltage V - - inverting terminal voltage

OpAmp Operation Non-Inverting Inverting Integrator Differentiator Summing Amplifier Scaling Amplifer Averaging Amplifier Substractor Comparator

Non-Inverting Amplifier Key: Input signal is applied to the non-inverting input terminal.

Inverting Amplifier Key: The input signal is applied to the inverting terminal.

OpAmp as Integrator

Key: Use C F instead of R F

Practical Integrator Circuit At low freq and dc signal, C F acts like an open circuit Close loop gain = open loop gain Produce too much output offset voltage.

Practical Integrator Circuit At zero freq (DC) and without negative feedback, the circuit treats the input offsets as a valid input signal charges the capacitor. This drive the output into +ve or –ve saturation.

Practical Integrator Circuit Insert R F in parallel with C F Resistor, R F used must be at least 10 times the input resistance, R 1

Integrator Application To use constant input voltage to produce a ramp voltage Analog Computer A/D Conversion Signal Wave Shaping

OpAmp as Differentiator

Key: Input resistor replaced by capacitor

Practical Differentiator Circuit This differentiator has tendency to undesirably oscillate The gain R F /X C1 increases at a rate of 20dB/decade with increases in frequency  become unstable

Practical Differentiator Circuit As the freq increases, input impedance X C decreases, making the circuit more susceptible to high frequency noise. This noise is superimposed after amplification, on the differential output signal.

Practical Differentiator Circuit Introduce R 1 and C F 0.01R F < R 1 < 0.1R F so close loop gain reduced to between -10 to -100.

Practical Differentiator Circuit Consideration: 1. f a is the highest freq range to be differentiated f a = 1/(2  R F C 1 )

Practical Differentiator Circuit Consideration: 2. f b is the gain limiting frequency at which the gain begins to decrease at a rate of 20db/decade. f b = 1/(2  R 1 C 1 ) R 1 C 1 =R F C F f b =20f a

Differentiator Application Detection of the leading and trailing edges of rectangular pulse Wave shaping circuit to detect high frequency components in an input signal. Rate of change detector in FM modulators. Triggering the time base generator in an oscilloscope.

OpAmp as Summing Key: Depends on relation of R a, R b, R c, R F, circuit can be summing, scaling or average amplifier.

Sum, Scale, Average Amplifier FunctionCondition 1SumR a =R b =R c =R F 2ScaleR a ≠R b ≠ R c 3AverageR a =R b =R c

OpAmp as Substractor Key: All R value are same.

OpAmp as Comparator Key: Opamp used without feedback. Amplifier goes either to saturation limit +V cc or – V EE One terminal considered as reference terminal. When V + > V -, V o  When V + < V -, V o 

OpAmp as Comparator If V - = GND, slight V + ++ result in V o = +V sat = +V CC If V - = GND, V + goes slightly below 0, V o = -V sat = -V EE Diodes used to protect opamp from damage due to excessive V in.

OpAmp as Comparator If V in feed to V + then it is called non-inverting comparator. If V in fed to V - then it is called inverting comparator.

Comparator Application Discriminator Voltage level detector Oscillator Digital interfacing Schmitt trigger

Amplifier Normal Amplifier Instrumentation Amplifier Important Features Difference with Normal Opamp

EKT 314/4 WEEK 5 : CHAPTER 3 END ELECTRONIC INSTRUMENTATION