Microelectrofluidic Systems: Modeling and Simulation

Tianhao Zhang, Krishnendu Chakrabarty, Richard B. Fair

May 17, 2002 by CRC Press
Reference - 288 Pages - 114 B/W Illustrations
ISBN 9780849312762 - CAT# 1276
Series: Nano- and Microscience, Engineering, Technology and Medicine


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  • Offers the first complete treatment of design automation for reconfiguarable microfluidic systems
  • Presents methodologies and tools for top-down MEF system designs that reduce design time and costs while allowing high-volume production
  • Uses an integrated design environment based on SystemC
  • Includes case studies that illustrate the techniques in real-world applications
  • Provides a performance comparison between continuous-flow and droplet-based MEF systems
  • Summary

    Composite systems that integrate microelectromechanical and microelectrofluidic (MEF) components with electronics are emerging as the next generation of system-on-a-chip (SOC) designs. However, there remains a pressing need for a structured methodology for MEFS design automation, including modeling techniques and simulation and optimization tools.

    Integrating top-down and bottom-up design philosophies, Microelectrofluidic Systems presents the first comprehensive design strategy for MEFS. This strategy supports hierarchical modeling and simulation from the component level to the system level. It leads to multi-objective optimization tools valuable in all phases of the design process, from conceptualization to final manufacturing. The authors begin by defining the basic variables and elements needed to describe MEFS behavior, then model that behavior across three layers of abstraction: the low-level component, high-level reconfigurable architecture, and bio/chemical application layers. They have developed a hierarchical integrated design environment with SystemC and present its architecture and associated functional packages.

    Microelectrofluidic Systems is visionary in its leverage of electronic design principles for microsystem design and heralds a new era of automated SOC design. The strategy it presents holds the potential for significant reductions in design time and life-cycle maintenance costs, and its techniques and tools for robust design and application flexibility can lead to the high-volume production needed for the inevitably growing product market.

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