Abstract
In this work, a design method of an ultra-wideband, low-noise amplifier (LNA) is put forward exploiting the performance limitations of a single high-quality discrete transistor. For this purpose, the compatible (noise F, input VSWR Vi, gain GT) triplets and their (ZS, ZL) terminations of the microwave transistor are used for the feasible design target space with the minimum noise Fmin(f), maximum gain GTmax(f), and a low constant input VSWR Vireq using the optimum noise impedance Zopt(f), and the maximum gain termination ZLmax(f) over the available bandwidth B. In the next stage, this multiobjective design process is reduced to the Darlington synthesis of the corresponding Zopt(f), ZLmax(f) terminations using the unit elements and short-circuited stubs in the T-, L-, Π-configurations. This synthesis is transformed to an optimization process with the determined feasible target space and optimization variables. Here, particle swarm intelligence is successfully implemented as a comparatively simple and efficient optimization tool in both verification of the design target space and the design process of the input and output matching circuits. Typical design examples are given with their challenging performances in the simple matching configurations realizable by the microstrip line technology. Furthermore, the performances of the synthesized amplifiers are compared using an analysis programme in MATLAB code and a microwave system simulator and verified to agree with each other and the design target space. © 2010 Wiley Periodicals, Inc. Int J RF and Microwave CAE, 2010.
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