Multiplier-cum-divider circuits : principles, design, and applications /: principles, design, and applications. (2021)
- Record Type:
- Book
- Title:
- Multiplier-cum-divider circuits : principles, design, and applications /: principles, design, and applications. (2021)
- Main Title:
- Multiplier-cum-divider circuits : principles, design, and applications
- Further Information:
- Note: K.C. Selvam.
- Authors:
- Selvam, K. C
- Contents:
- Chapter 1: Introduction 1.1: Characteristics 1.2: Specifications 1.3: Errors 1.4: Individual Error 1.5: Offset nulling 1.6: MCD types; Chapter 2: Basic Components of MCDs 2.1: Inverting amplifier 2.2: Non-inverting amplifier 2.3: Integrator 2.4: Analog switches 2.5: Analog multiplexer 2.6: Astable multivibrator; Chapter 3: Non – Linear Op-amp Circuits 3.1: Voltage comparator 3.2: Schmitt trigger 3.3: Half wave rectifier 3.4: Full wave rectifier 3.5: Peak detector 3.6: Sample and hold circuit 3.7: Log amplifier 3.8: Anti log amplifier; Chapter 4: Conventional MCDs 4.1 Log-antilog MCD – type I 4.2 Log-antilog MCD – type II 4.3 MCD using FETs 4.4 MCD using MOSFETs 4.5 MCDs using multipliers and dividers; Chapter 5: Saw tooth wave referenced time division MCD with multiplexers 5.1 Saw tooth wave generators 5.2 Double multiplexing – averaging MCD 5.3 Time division single slope peak detecting MCD 5.4 Time division multiply – divide MCD 5.5 Time division divide – multiply MCD; Chapter 6: Triangular wave referenced MCD with multiplexers 6.1 Triangular wave generators 6.2 Time division MCD 6.3 Time division divide – multiply MCD 6.4 Time division multiply – divide MCD; Chapter 7: Peak responding MCD with multiplexers 7.1 Double Single slope MCD 7.2 Double dual slope MCD with FBC 7.3 Double dual slope MCD with Flip-Flop 7.4 Pulse width integrated MCD 7.5 Peak detecting MCD using voltage tunable astable multivibrator; Chapter 8: Saw tooth wave referenced MCD with analog switches 8.1Chapter 1: Introduction 1.1: Characteristics 1.2: Specifications 1.3: Errors 1.4: Individual Error 1.5: Offset nulling 1.6: MCD types; Chapter 2: Basic Components of MCDs 2.1: Inverting amplifier 2.2: Non-inverting amplifier 2.3: Integrator 2.4: Analog switches 2.5: Analog multiplexer 2.6: Astable multivibrator; Chapter 3: Non – Linear Op-amp Circuits 3.1: Voltage comparator 3.2: Schmitt trigger 3.3: Half wave rectifier 3.4: Full wave rectifier 3.5: Peak detector 3.6: Sample and hold circuit 3.7: Log amplifier 3.8: Anti log amplifier; Chapter 4: Conventional MCDs 4.1 Log-antilog MCD – type I 4.2 Log-antilog MCD – type II 4.3 MCD using FETs 4.4 MCD using MOSFETs 4.5 MCDs using multipliers and dividers; Chapter 5: Saw tooth wave referenced time division MCD with multiplexers 5.1 Saw tooth wave generators 5.2 Double multiplexing – averaging MCD 5.3 Time division single slope peak detecting MCD 5.4 Time division multiply – divide MCD 5.5 Time division divide – multiply MCD; Chapter 6: Triangular wave referenced MCD with multiplexers 6.1 Triangular wave generators 6.2 Time division MCD 6.3 Time division divide – multiply MCD 6.4 Time division multiply – divide MCD; Chapter 7: Peak responding MCD with multiplexers 7.1 Double Single slope MCD 7.2 Double dual slope MCD with FBC 7.3 Double dual slope MCD with Flip-Flop 7.4 Pulse width integrated MCD 7.5 Peak detecting MCD using voltage tunable astable multivibrator; Chapter 8: Saw tooth wave referenced MCD with analog switches 8.1 Saw tooth generators 8.2 Double switching – averaging MCD 8.3 Time division single slope peak detecting MCD 8.4 Time division multiply – divide MCD 8.5 Time division divide – multiply MCD; Chapter 9: Triangular wave referenced MCD with analog switches 9.1 Time division MCD 9.2 Divide – multiply MCD 9.3 Multiply – divide MCD; Chapter 10: Peak responding MCD with analog switches 10.1 Double Single slope MCD 10.2 Double dual slope MCD with FBC 10.3 Double dual slope MCD with Flip-Flop 10.4 Pulse width integrated MCD 10.5 Peak detecting MCD using voltage tunable astable multivibrator; Chapter 11: Time division MCD with no reference 11.1 Time division MCD with no reference – type I – Multiplexing 11.2 Time division MCD with no reference – type II – Multiplexing 11.3 Time division MCD with no reference – type I – Switching 11.4 Time division MCD with no reference – type II - Switching; Chapter 12: Pulse Position Responding MCDs 12.1 Pulse position peak detecting MCD – multiplexing 12.2 Pulse position peak detecting MCD – switching 12.3 Pulse position peak sampling MCD – multiplexing 12.4 Pulse position peak sampling MCD – switching; Chapter 13: Applications of MCD 13.1: Balanced modulator 13.2: Amplitude modulator 13.3: Frequency doubler 13.4: Phase angle detector 13.5: RMS detector 13.6: Rectifier 13.7: Inductance measurement 13.8: Capacitance measurement 13.9: Automatic gain control - type I 13.10: Automatic gain control – type II; Chapter 14: Circuit Simulation 14.1: Simulation of time division multiply – divide MCD 14.2: Simulation of time division divide – multiply MCD 14.3: Simulation of time division MCD no reference – type I 14.4: Simulation of time division MCD no reference – type II; AFC Trainer Kit; … (more)
- Edition:
- 1st
- Publisher Details:
- Boca Raton : CRC Press
- Publication Date:
- 2021
- Extent:
- 1 online resource, illustrations (black and white)
- Subjects:
- 621.3815
Electronic circuits
Operational amplifiers - Languages:
- English
- ISBNs:
- 9781000407037
9781000407020
9781003168515 - Related ISBNs:
- 9780367754464
- Notes:
- Note: Description based on CIP data; resource not viewed.
- Access Rights:
- Legal Deposit; Only available on premises controlled by the deposit library and to one user at any one time; The Legal Deposit Libraries (Non-Print Works) Regulations (UK).
- Access Usage:
- Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force.
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD.DS.624389
- Ingest File:
- 05_032.xml