Titlebook: Nano, Quantum and Molecular Computing; Implications to High Sandeep K. Shukla,R. Iris Bahar Book 2004 Springer Science+Business Media New Y

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Obtaining Quadrillion-Transistor Logic Systems Despite Imperfect Manufacture, Hardware Failure, and y drastically advance logic system manufacture. At some point in the future, possibly within 20 years, logic designers may have access to a billion times more switches than they do now. It is sometimes useful to allow larger milestones such as this to determine some of the directions of contemporary

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A Probabilistic-Based Design for Nanoscale Computation becomes a central research priority. It is expected that nanoarchitectures will confront devices and interconnections with high inherent defect rates, which motivates the search for new architectural paradigms. In this chapter, we exam probabilistic-based design methodologies for designing nanoscal

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Tools and Techniques for Evaluating Reliability Trade-Offs for Nano-ArchitecturesAccording to many experts, it is expected that nano-scale devices and interconnections will introduce unprecedented level of defects in the substrates and architectural designs need to accommodate the uncertainty inherent at such scales. This consideration motivates the search for new architectural

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Challenges in Reliable Quantum Computing There are several challenges in building a large-scale quantum computer - fabrication, verification, and architecture. The power of quantum computing comes from the ability to store a complex state in a single bit. This also what makes quantum systems difficult to build, verify, and design. Quantum

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Origins and Motivations for Design Rules in QCAe near-to-midterm. It will also explain a systems-level research component that complements work in physical science. One objective of the systems-level track is to compile a set of design rules to not only help system designers become more involved with the evolution of emergent, nano-scale devices

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Partitioning and Placement for Buildable QCA Circuitsrge configuration in chemical molecules. It has the potential to allow for circuits and systems with functional densities that are better than end of the roadmap for CMOS, but also imposes new constraints on system designers. In this article, we present the first partitioning and placement algorithm