Robust Computing with Nano-Scale Devices
- Indbinding:
- Hardback
- Sideantal:
- 180
- Udgivet:
- 26. marts 2010
- Udgave:
- 2010
- Størrelse:
- 164x20x243 mm.
- Vægt:
- 436 g.
- 8-11 hverdage.
- 6. december 2024
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- 1 valgfrit digitalt ugeblad
- 20 timers lytning og læsning
- Adgang til 70.000+ titler
- Ingen binding
Abonnementet koster 75 kr./md.
Ingen binding og kan opsiges når som helst.
Beskrivelse af Robust Computing with Nano-Scale Devices
Although complementary metal-oxide semiconductor (CMOS) technology will continue dominating the digital electronic circuits for the next 10-15 years, a number of grand challenges have emerged as the transistor size scales down. The rising costs of semiconductor mask and fabrication pose economic barriers to lithography. The quantum effects and increasing leakage power begin setting physical limits on continuous CMOS feature size shrinking.
The research advances of innovative nano-scale devices have created great opportunities to surpass the barriers faced by CMOS technology, which include nanowires, carbon nanotube transistors, programmable molecular switches, resonant tunneling diodes, quantum dots, etc.
However, the success of many nanotechnologies relies on the self-assembly fabrication process to fabricate circuits. The stochastic self-assembly fabrication, unfortunately, has low reliability with defect densities several orders of magnitude higher than conventional CMOS technology.
Robust Nano-Computing focuses on various issues of robust nano-computing, defect-tolerance design for nano-technology at different design abstraction levels. It addresses both redundancy- and configuration-based methods as well as fault detecting techniques through the development of accurate computation models and tools. The contents present an insightful view of the ongoing researches on nano-electronic devices, circuits, architectures, and design methods, as well as provide promising directions for future research.
The research advances of innovative nano-scale devices have created great opportunities to surpass the barriers faced by CMOS technology, which include nanowires, carbon nanotube transistors, programmable molecular switches, resonant tunneling diodes, quantum dots, etc.
However, the success of many nanotechnologies relies on the self-assembly fabrication process to fabricate circuits. The stochastic self-assembly fabrication, unfortunately, has low reliability with defect densities several orders of magnitude higher than conventional CMOS technology.
Robust Nano-Computing focuses on various issues of robust nano-computing, defect-tolerance design for nano-technology at different design abstraction levels. It addresses both redundancy- and configuration-based methods as well as fault detecting techniques through the development of accurate computation models and tools. The contents present an insightful view of the ongoing researches on nano-electronic devices, circuits, architectures, and design methods, as well as provide promising directions for future research.
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Bogen Robust Computing with Nano-Scale Devices findes i følgende kategorier:
- Business og læring > Computer og IT
- Kunst og kultur > Arkitektur og design
- Sprog og lingvistik
- Teknologi, ingeniørvidenskab og landbrug > Teknologi: generelle emner > Nanoteknologi
- Teknologi, ingeniørvidenskab og landbrug > Elektronik og kommunikationsteknik > Elektronik teknik > Elektronik: kredse og komponenter
- Databehandling og informationsteknologi > Informatik > Dataarkitektur og logisk design
- Databehandling og informationsteknologi > Informatik > Kunstig intelligens
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