Journal ArticleDOI
A neural network modeling approach to circuit optimization and statistical design
TLDR
This paper presents a new approach to microwave circuit optimization and statistical design featuring neural network models at either device or circuit levels, which has the capability to handle high-dimensional and highly nonlinear problems.Abstract:
The trend of using accurate models such as physics-based FET models, coupled with the demand for yield optimization results in a computationally challenging task. This paper presents a new approach to microwave circuit optimization and statistical design featuring neural network models at either device or circuit levels. At the device level, the neural network represents a physics-oriented FET model yet without the need to solve device physics equations repeatedly during optimization. At the circuit level, the neural network speeds up optimization by replacing repeated circuit simulations. This method is faster than direct optimization of original device and circuit models. Compared to existing polynomial or table look-up models used in analysis and optimization, the proposed approach has the capability to handle high-dimensional and highly nonlinear problems. >read more
Citations
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Proceedings ArticleDOI
An Efficient Yield-Constrained Design Framework Using Global Surrogates for Microwave Filters
TL;DR: In this article , an efficient framework is designed to obtain the optimal design solutions with a high yield using the Polynomial chaos method, all objectives are modeled using the PCC method.
Proceedings ArticleDOI
Variability analysis of interconnects terminated by polynomial nonlinear loads
TL;DR: In this paper, a stochastic modeling method is presented for the analysis of variability effects induced by the manufacturing process on interconnect structures terminated by polynomial nonlinear loads.
Characteristic fluctuation of gate-all-around silicon nanowire MOSFETs induced by random discrete dopants from source/drain extensions
Wen Li Sung,Yiming Li +1 more
TL;DR: In this paper, the effect of random discrete dopants (RDDs) penetrating from the source/drain (S/D) extensions is explored for undoped gateall-around silicon nanowire MOSFETs.
An Early History of Optimization Technology for Automated Design of Microwave Circuits
TL;DR: In this article , the authors outline the early history of optimization technology for the design of microwave circuits, a personal journey filled with aspirations, academic contributions, and commercial innovations, which connects to today's multi-physics, system-level, and measurement-based optimization challenges exploiting confined and feature-based surrogates.
References
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Journal ArticleDOI
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TL;DR: In this paper, a new method for the solution of nonlinear periodic networks has been developed, where the network is decomposed into a minimum number of linear and nonlinear subnetworks.
Journal ArticleDOI
State of the art and present trends in nonlinear microwave CAD techniques
Vittorio Rizzoli,Andrea Neri +1 more
TL;DR: A survey of modern nonlinear CAD techniques as applied to the specific field of microwave circuits shows that the various subjects are not just separate items, but rather can be chained in a strictly logical sequence.
Journal ArticleDOI
Circuit optimization: the state of the art
John W. Bandler,S.H. Chen +1 more
TL;DR: A unified hierarchical treatment of circuit models forms the basis of the presentation, and the concepts of design centering, tolerance assignment, and postproduction tuning in relation to yield enhancement and cost reduction suitable for integrated circuits are discussed.
Journal ArticleDOI
Nonlinear circuit analysis using the method of harmonic balance—A review of the art. Part I. Introductory concepts
TL;DR: The harmonic balance method is a technique for the numerical solution of nonlinear analog circuits operating in a periodic, or quasi-periodic, steady-state regime as mentioned in this paper, which can be used to efficiently derive the continuous-wave response of numerous nonlinear microwave components including amplifiers, mixers, and oscillators.