The 2006 IEEE International Behavioral Modeling and Simulation Conference is a ″workshop–like″ conference that focuses on behavioral modeling and simulation for analog electronic circuits and systems. As such, it addresses the development and application of behavioral languages and simulators, as well modeling practices and the automatic extraction of models. The Verilog–AMS and VHDL–AMS languages are of particular interest. The conference will held in conjunction with the Custom Integrated Circuits Conference at the Doubletree Hotel in San Jose in 2006. Please join us at the world′s premier mixed–signal behavioral modeling conference. <b>Keywords:</b> Mixed–Signal Topics<br>Topics focusing on contributions to the research, development and applications involving analog, digital and mixed–signal integrated circuits and systems. Representative areas include:<br>Behavioral model generation, optimization, or validation and qualification<br>Statistical behavioral modeling<br>Parasitic–aware techniques<br>Timing, power and noise modeling for deep–submicron design<br>Language–based analog synthesis<br>Analog and mixed–signal fault modeling and test emulation<br>Modeling methodologies and standards<br>Virtual prototyping and testing<br>System on chip modeling simulation methods<br>Mixed–signal and RF system simulation<br>Compilation techniques for simulation optimization<br>Distributed and parallel mixed–signal simulation<br>Case studies and practical experiences of behavioral modeling<br>Frequency domain modeling and simulation<br>Semiconductor Device Compact Modeling<br>Representative areas include:<br>Compact device modeling lanuages and compilers<br>Standard and new compact device models implemented in Verilog–A and VHDL–AMS<br>Compact device models for emerging technologies and topical issues (nano–devices, distributed thermal effect, leakaging issues, manufacturability, radiation effects, etc).<br>Mixed–Technology Topics<br>Topics focusing on contributions to the research, development and applications involving systems that are part or wholly non–electrical by nature. Representative areas include:<br>Mixed–technology modeling (electro–mechanical, thermal–electronic, etc.)<br>Thermal modeling<br>Optical modeling<br>Hydraulics modeling<br>Mechanical modeling<br>MEMS modeling<br>Biological and biochemical modeling<br>Mixed–level simulation (e.g., mixed finite–element/continuous–time)<br>Mixed–domain modeling (frequency–domain, time–domain)<br>Case studies in telecommunication, automotive electronics, etc.<br>Power electronic modeling<br>Full–system verification<br>Stress modeling<br>Failure effects modeling<br>Language and Tool Topics<br>Topics focusing on contributions to the research and development of hardware description languages (HDLs) and modeling and simulation tools and algorithms that enable the simulation of the previous two general tracks. Representative areas include:<br>VHDL–AMS, Verilog–A, Verilog A/MS<br>Language requirements, analysis and validation<br>Language design issues and language–theoretic foundations<br>Extensions to standard modeling languages for specialized applications (semiconductors, MEMS, RF, etc.)<br>GUIs for simplifying use of languages<br>Compilation techniques for simulation optimization<br>Distributed and parallel mixed–signal simulation<br>Frequency domain modeling and simulation<br>Automated model extraction and reduction<br>Formal description languages for electronic circuits and systems<br>Unified solutions for simulating mixed domains<br>Tools providing interoperability of models and languages<br>
Abbrevation
BMAS
City
San Jose
Country
United States
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