Abstract :
Summary form only given. Modeling and optimization of microwave and high-frequency/high-speed microelectronic devices and systems are important for achieving next generation information technology and communication systems. Increasing circuit size and design complexity, coupled with stringent design specifications and shorter design cycles, demand tools that are faster, more accurate and automated than possible today. Electromagnetic (EM)/physics-based design accuracies will be needed not only at the component level, but also at the circuit and system levels. Models with EM/physics-oriented accuracy but without the computational expense of direct EM/physics simulations are necessary. Recent applications of neural networks and space mapping for microwave design lead to new modeling and Computer-aided Design (CAD) with potential advantages in both speed and accuracy. Applications are being made in modeling and design of microstrip and CPW circuits, multilayer interconnects, embedded passives, printed antennas, LTCC circuits, semiconductor devices, measurement standards, filters, amplifiers, mixers and so on. New CAD methods for optimization, statistical design, global modeling, and computational electromagnetics exploiting computational intelligence concepts are being developed. Advanced microwave CAD methodologies such as knowledge-aided design, knowledge-based neural networks, and space mapping are being developed. This leads to new opportunities combining equivalent circuit/empirical models, EM/physics simulation, behavioral modeling, neural network and space mapping optimization algorithms for fast and accurate design of high-frequency components and systems. This presentation provides an overview of the state of the art in these emerging directions. The presentations highlight implementable methodologies for automated modeling and design of RF/microwave components, circuits and systems. The presentation covers fundamental concepts and methodologies, industrial a- plications, and future trends in R&D.
Keywords :
circuit CAD; circuit optimisation; computational electromagnetics; equivalent circuits; microwave circuits; neural nets; CAD methods; CPW circuits; EM-physics-oriented accuracy; R&D; RF component design; amplifiers; behavioral modeling; circuit design complexity; circuit size; communication systems; computational electromagnetics; computational intelligence; computer-aided design; direct EM-physics simulations; electromagnetic-physics-based design; embedded passives; equivalent circuit-empirical models; high-frequency components; high-frequency microelectronic devices; high-speed microelectronic devices; knowledge-aided design; knowledge-based neural networks; measurement standards; microstrip circuit design; microwave CAD methodology; microwave component design; microwave design; mixers; multilayer interconnects; next generation information technology; optimization techniques; printed antennas; semiconductor devices; space mapping optimization algorithms; statistical design; Computational modeling; Integrated circuit modeling; Microwave amplifiers; Microwave circuits; Microwave communication; Microwave filters; Solid modeling;
