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Senani, Raj [Author]; Bhaskar, Data Ram [Author]; Singh, Vinod K. [Author]; Singh, Abdhesh Kumar [Author]

Gyrators, simulated inductors and related immittances

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  • Media type: E-Book
  • Title: Gyrators, simulated inductors and related immittances : realizations and applications
  • Contributor: Senani, Raj [Author]; Bhaskar, Data Ram [Author]; Singh, Vinod K. [Author]; Singh, Abdhesh Kumar [Author]
  • Published: Stevenage: Institution of Engineering and Technology, 2020
  • Published in: Materials, Circuits & Devices Series ; 48
  • Extent: 1 Online-Ressource (xxv, 549 Seiten); illustrations
  • Language: English
  • DOI: 10.1049/PBCS048E
  • ISBN: 9781785616716; 1785616714
  • Identifier:
  • Keywords: Gyrators ; bipolar integrated circuits ; CMOS integrated circuits ; current conveyors ; electric immittance ; electric impedance ; feedback amplifiers ; gyrators ; impedance convertors ; inductors ; operational amplifiers ; resistors ; Electronic books
  • Origination:
  • Footnote: Includes bibliographical references and index (pages 543-549)
  • Description: Intro -- Contents -- About the authors -- Preface -- Acknowledgement -- 1. Gyrators, integrated inductors and simulated inductors -- Abstract -- 1.1 Prologue -- 1.2 Basic one-port circuit elements -- 1.3 Basic two-port circuit elements -- 1.3.1 The transformer -- 1.3.2 The gyrator -- 1.3.3 The two-port impedance converters and inverters -- 1.4 The pathological elements -- 1.5 Multi-terminal gyrator -- 1.6 Multiport inverters/converters -- 1.7 Commercially available inductors and Coilcraft -- 1.8 Basic difficulties in micro-miniaturization of inductors

    1.9 Integrated inductors and transformers on the chip -- 1.10 Power gyrators -- 1.11 Use of ANSYS and COMSOL for the analysis of inductor designs -- 1.12 The need for simulated inductors -- 1.13 Concluding remarks -- References -- 2. Gyrators and simulated inductors using op-amps -- Abstract -- 2.1 Introduction -- 2.2 The gyrator -- 2.3 Op-amp gyrators and related circuits -- 2.3.1 NIC-based gyrator -- 2.3.2 VCCS-based gyrator -- 2.3.3 Generalized impedance converters (GIC)/gyrators -- 2.3.4 Two-op-amp resistively variable capacitance simulators -- 2.3.5 Two-op-amp lossless inductance simulator

    2.3.6 Tripathi-Patranabis lossless grounded inductor -- 2.3.7 Lossless GI using summer/subtractor circuits -- 2.3.8 Two modified forms of the GIC and their applications -- 2.4 Single-op-amp lossless inductance simulators -- 2.4.1 Orchard-Willson gyrator -- 2.4.2 Schmidt-Lee circuit -- 2.4.3 Ramsey gyrator -- 2.4.4 Horn-Moschytz circuit -- 2.5 Economic inductance simulators and resonators -- 2.5.1 Ford-Girling circuit -- 2.5.2 Prescott circuit -- 2.5.3 Berndt-Dutta Roy circuit -- 2.5.4 Caggiano circuit -- 2.5.5 Patranabis circuit

    2.5.6 The parallel/series RL inductors derived by Rao-Venkateswaran -- 2.5.7 Ahmed-Dutta Roy technique of deriving grounded-capacitor lossy GI -- 2.5.8 Senani-Tiwari circuit -- 2.5.9 Soliman-Awad tunable active inductor -- 2.5.10 Nagarajan-Dutta Roy-Choudhary circuit -- 2.5.11 Senani's single-resistance-tunable GIs -- 2.6 Lossless floating impedance simulators using four op-amps -- 2.6.1 Riordan's method of creating a lossless FI -- 2.6.2 GIC method of simulating FI -- 2.6.3 Tripathi-Patranabis FI -- 2.6.4 Mutator-simulated floating inductors

    2.7 The multi-port immittance converters/inverters and multi-port gyrators -- 2.8 Three-op-amp-based floating immittance simulators -- 2.8.1 Three-op-amp-single-capacitor FIs based on GIC-type networks -- 2.8.2 FI realizations using three op-amps along with a grounded capacitor -- 2.8.3 Senani's single-resistance-controllable lossless FI -- 2.8.4 Patranabis-Paul capacitance floatation circuit -- 2.9 Lossless FIs using only two op-amps -- 2.9.1 The-Yanagisawa circuit -- 2.9.2 Sudo-Teramoto circuit -- 2.10 Economic op-amp-based lossless/lossy FIs

    The operational transconductance amplifier based gyrators and impedance simulators -- Synthetic impedances using current conveyors and their variants -- Current feedback-op-amp-based synthetic impedances -- Applications of FTFN/OFA and OMAs in impedance synthesis -- Realization of voltage-controlled impedances -- Impedance synthesis using modern active building blocks -- Transistor-level realization of electronically controllable ground and floating resistors -- Bipolar and CMOS active inductors and transformers -- Recent developments and concluding remarks.

    This book provides coverage of the major gyrator circuits, simulated inductors and related synthetic impedances. It offers a review of research in this field to date, and includes a wide range and number of circuit examples, along with their relevant design equations, limitations, performance features, advantages and shortcomings