Asynchronous Ballistic Reversible Fluxon Logic

In a previous paper, we described a new abstract circuit model for reversible computation called asynchronous ballistic reversible computing (ABRC), in which localized information-bearing pulses propagate ballistically along signal paths between stateful abstract devices and elastically scatter off...

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Bibliographic Details
Published in:IEEE transactions on applied superconductivity 2019-08, Vol.29 (5), p.1-7
Main Authors: Frank, Michael P., Lewis, Rupert M., Missert, Nancy A., Wolak, Matthaus A., Henry, Michael D.
Format: Article
Language:English
Subjects:
Ballistic signaling
Binary data
Circuits
Computation
Computational modeling
Energy conservation
Energy efficiency
Integrated circuit interconnections
Integrated circuit modeling
Josephson junctions
MATHEMATICS AND COMPUTING
Polarity
Pulse propagation
reversible computing
Signal paths
single flux quanta
Solitary waves
Solitons
State variable
Superconducting logic circuits
Superconductivity
Transmission lines
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Summary:In a previous paper, we described a new abstract circuit model for reversible computation called asynchronous ballistic reversible computing (ABRC), in which localized information-bearing pulses propagate ballistically along signal paths between stateful abstract devices and elastically scatter off those devices serially, while updating the device state in a logically-reversible and deterministic fashion. The ABRC model has been shown to be capable of universal computation. In the research reported here, we begin exploring how the ABRC model might be realized in practice using single flux quantum solitons (fluxons) in superconducting Josephson junction (JJ) circuits. One natural family of realizations could utilize fluxon polarity to represent binary data in individual pulses propagating near-ballistically, along discrete or continuous long Josephson junctions or microstrip passive transmission lines, and utilize the flux charge (-1, 0, +1) of a JJ-containing superconducting loop with Φ 0
ISSN:1051-8223
1558-2515
DOI:10.1109/TASC.2019.2904962