A TechnologyIndependent Model for Nanoscale Logic Devices

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A TechnologyIndependent Model for Nanoscale Logic Devices

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Candidate nanocomputing technologies operate in a wide variety of different physical domains. ... Field effect transistors, resonant tunneling diodes ... – PowerPoint PPT presentation

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Title: A TechnologyIndependent Model for Nanoscale Logic Devices

1
A Technology-Independent Model for Nanoscale
Logic Devices
Michael P. Frank, University of Florida, Depts.
of CISE and ECE,CSE Bldg., Box 116120,
Gainesville, FL 32611, mpf_at_cise.ufl.edu
Reconstructing Physical Quantities in
Computational Terms

Motivation / problem description
Candidate nanocomputing technologies operate in a
wide variety of different physical domains.
E.g., electronic, mechanical, optical, chemical.
Even just the all-electronic technologies differ
by
Conductivity class
Semiconductors, conductors, superconductors.
Operating principles
Field effect transistors, resonant tunneling
diodes/transistors, Josephson junctions, etc.
Confinement dimensions
Quantum dots, wires, wells.
Materials
Metals, silicon crystals, other semiconductors,
hybrid materials, carbon nanotubes, organic
molecules,
Information encoding
In position, voltage, current, phase, or spin
states.
Particles manipulated
Just electrons, or also holes, ions, dopants,
nuclei, charged molecules,
The long-term winner is still completely unclear
Yet, we would like a theoretical foundation for
future nanocomputer systems engineering and
architecture!
Proposed solution

(Some example implications)

Fundamental Physical Limits of Computing
A 100 watt computer expelling its waste heat into
a room-temperature environment can perform no
more than
A single-electron device where electrons may be
at most 1 volt above their ground state can
perform no more than
Any system whose internal computational degrees
of freedom are at a generalized temperature no
greater than room temperature can update its
logical bits at a frequency of no more than
Device Model Parameters
Tg Avg. generalized temperature for ops. in the
coding subsystem.
Elb Energy per amt. of coding-state info.
representing 1 logical bit.
tlbop Elapsed time for carrying out one logical
bit-operation (transition of a
logical bit-system).
td Avg. time btw. decoherence events per bit in
coding subsystem.
Plk Leakage power per stored logical bit.
St Rate of parasitic entopy generation per bit.
Minimum Entropy Generation per Bit-op

Hierarchical System Design/Optimization
Methodology
wherec Tg/T(overdrivefactor)
whereq td/ttr Tg/Td(quantumqualityfacto
r)
Conclusion The generalized temperature of the
computational degrees of freedom must be gtgt both
the prevailing decoherence thermal temps. in
order to permit ltlt kT energy dissipation per
rev-op.

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