We present the design and simulation of systolic information processing hardware that is comprised of single domain, Co/Pt magnets (i.e., out-of-plane nanomagnet logic or oNML). The designed circuit can identify instances of a preprogrammed bit sequence in streaming data. The systolic architecture 1) exploits unique benefits of the oNML device architecture such as nonvolatility and inherently pipelined logic with no memory overhead for holding the bits in the pipeline and 2) mitigates less desirable features of oNML such as nearest neighbor dataflow and longer device switching times when compared to a CMOS transistor. The designed layout is verified and analyzed by micromagnetic simulations. We quantify how the performance and energy of oNML information processing hardware compares to CMOS equivalents and conclude that the initial oNML design (including the overhead of magnetic field generation) is about an order of magnitude more power efficient at essentially iso-performance.
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We present the design and simulation of systolic information processing hardware that is comprised of single domain, Co/Pt magnets (i.e., out-of-plane nanomagnet logic or oNML). The designed circuit can identify instances of a preprogrammed bit sequence in streaming data. The systolic architecture 1) exploits unique benefits of the oNML device architecture such as nonvolatility and inherently pipelined logic with no memory overhead for holding the bits in the pipeline and 2) mitigates less desir...
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