Journal Article10.1109/TMTT.2003.809179
Artificial neural networks for RF and microwave design - from theory to practice
TL;DR: Fundamental concepts in this emerging area of neural-network computational modules are described at teaching RF/microwave engineers what neural networks are, why they are useful, when they can be used, and how to use them.
read more
Abstract: Neural-network computational modules have recently gained recognition as an unconventional and useful tool for RF and microwave modeling and design. Neural networks can be trained to learn the behavior of passive/active components/circuits. A trained neural network can be used for high-level design, providing fast and accurate answers to the task it has learned. Neural networks are attractive alternatives to conventional methods such as numerical modeling methods, which could be computationally expensive, or analytical methods which could be difficult to obtain for new devices, or empirical modeling solutions whose range and accuracy may be limited. This tutorial describes fundamental concepts in this emerging area aimed at teaching RF/microwave engineers what neural networks are, why they are useful, when they can be used, and how to use them. Neural-network structures and their training methods are described from the RF/microwave designer's perspective. Electromagnetics-based training for passive component models and physics-based training for active device models are illustrated. Circuit design and yield optimization using passive/active neural models are also presented. A multimedia slide presentation along with narrative audio clips is included in the electronic version of this paper. A hyperlink to the NeuroModeler demonstration software is provided to allow readers practice neural-network-based design concepts.
read more
Chat with Paper
AI Agents for this Paper
Find similar papers on Google Scholar, PubMed and Arxiv
Write a critical review of this paper
Analyze citations of this paper to find unaddressed research gaps
Citations
Artificial Neural Network Model of zero-bias Schottky Diode for Energy Harvesting
Branka Milosevic,Milos Radovanovic,Branka Jokanovic,Zlatica Marinkovic +3 more
- 01 Oct 2019
TL;DR: The S-parameters of SMS 7630 zerobias Schottky diode are modeled with artificial neural network (ANN), and results turned up to be satisfactory and useful, especially considering a limited number of different input powers for network training.
2
•Dissertation
Artificial Neural Networks for Microwave Detection
Ahmed Ashoor
- 23 May 2012
TL;DR: An approach of using Artificial Neural Networks to detect material change in a rectangular cavity based on the theory of the perturbation of cavity resonators where a change in the resonant frequencies of the cavity is directly proportional to the dielectric constant of the inserted objects.
2
ANN Modeling of Motional Resistance for Micro Disk Resonator
TL;DR: This article describesﻷ howﻴ�modeling providesﻢthe-theoretical-characterization-of-the-oreticalﻡ�characterizationﻰ�of�the-situational-economic-psychological-social-cognitive-behaviors of the proposed artificial neural networks.
2
Neural modeling of high-frequency forward transmission coefficient for HEMT and FinFET technologies
Zlatica Marinkovic,Giovanni Crupi,Dominique Schreurs +2 more
- 01 Dec 2011
TL;DR: The ability of artificial neural networks to model the forward transmission coefficient, which represents an important figure of merit for microwave transistors, is examined for two different on-wafer devices, namely GaAs HEMT and Si FinFET.
2
A Novel Modeling Methodology for Silicon-based RF Components
Tao Liu,Wenjun Zhang,Zhiping Yu +2 more
- 01 Oct 2006
TL;DR: In this paper, a wideband ANN-based modeling methodology for radiofrequency (RF) components is presented, which is applied to differential spiral inductors with various geometrical sizes.
2
References
Multilayer feedforward networks are universal approximators
TL;DR: It is rigorously established that standard multilayer feedforward networks with as few as one hidden layer using arbitrary squashing functions are capable of approximating any Borel measurable function from one finite dimensional space to another to any desired degree of accuracy, provided sufficiently many hidden units are available.
23.1K
•Dissertation
Constructive algorithms for structure learning in feedforward neural networks
Tin Yau Kwok
- 01 Jan 1996
TL;DR: This survey paper first describes the general issues in constructive algorithms, with special emphasis on the search strategy, then presents a taxonomy, based on the differences in the state transition mapping, the training algorithm, and the network architecture.
495
Constructive algorithms for structure learning in feedforward neural networks for regression problems
Tin-Yau Kwok,Dit-Yan Yeung +1 more
TL;DR: A survey of constructive algorithms for structure learning in feed-forward neural networks for regression problems can be found in this paper, where the authors formulate the whole problem as a state-space search, with special emphasis on the search strategy.
488
Knowledge-based neural models for microwave design
Fang Wang,Qi-Jun Zhang +1 more
TL;DR: A new microwave-oriented knowledge based neural network is proposed, in which microwave knowledge in the form of empirical functions or analytical approximations are incorporated into neural networks that enhances neural model accuracy especially for unseen data and reduces the need of large set of training data.
304
EM-ANN models for microstrip vias and interconnects in dataset circuits
P.M. Watson,K.C. Gupta +1 more
TL;DR: A novel approach for accurate and efficient modeling of monolithic microwave/millimeter wave integrated circuit (MMIC) components by using electromagnetically trained artificial neural network (EM-ANN) software modules is presented.
275