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Artech House USA
Nonlinear Design: FETs and HEMTs

Nonlinear Design: FETs and HEMTs

By (author): Peter H. Ladbrooke
Copyright: 2021
Pages: 400
ISBN: 9781630818685

Hardback $144.00 Qty:
Digital download and online $112.00 Qty:

Despite its continuing popularity, the so-called standard circuit model of compound semiconductor field-effect transistors (FETs) and high electron mobility transistors (HEMTs) is shown to have a limitation for nonlinear analysis and design: it is valid only in the static limit. When the voltages and currents are time-varying, as they must be for these devices to have any practical use, the model progressively fails for higher specification circuits.

 

This book shows how to reform the standard model to render it fully compliant with the way FETs and HEMTs actually function, thus rendering it valid dynamically. Proof-of-principle is demonstrated for several practical circuits, including a frequency doubler and amplifiers with demanding performance criteria. Methods for extracting both the reformulated model and the standard model are described, including a scheme for re-constructing from S-parameters the bias-dependent dynamic (or RF) I(V) characteristics along which devices work in real-world applications, and as needed for the design of nonlinear circuits using harmonic-balance and time-domain simulators.

 

The book includes a historical review of how variations on the standard model theme evolved, leading up to one of the most widely used—the Angelov (or Chalmers) model.

Introduction; Summary of approaches and needs; Practical behavior of FETs; The standard model: deriving the elements; The capacitance puzzle in the standard model; Dynamic I(V) measurements

  • Peter H. Ladbrooke

    has spent a professional lifetime on the physics and application of compound semiconductor FETs, following work on non-uniformities in Gunn and Schottky devices for which he was awarded a Ph.D. by Cambridge University.

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