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Parallel spatial photonic Ising machine using spatial multiplexing for accelerating combinatorial optimization.

Suguru Shimomura, Jun Tanida, Yusuke Ogura

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    A new parallel spatial photonic Ising machine (pSPIM) speeds up solving complex optimization problems. This optical computing approach uses spatial multiplexing for faster, more frequent optimal solutions in large-scale combinatorial problems.

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    Area of Science:

    • Physics
    • Computer Science
    • Optical Engineering

    Background:

    • Spatial photonic Ising machines (SPIMs) leverage optical processing and spatial parallelism for combinatorial optimization.
    • Iterative feedback in SPIMs limits processing speed despite optical computation of the Ising Hamiltonian.

    Purpose of the Study:

    • To propose and demonstrate a parallel spatial photonic Ising machine (pSPIM) for efficient combinatorial optimization.
    • To enhance the speed and efficiency of solving large-scale optimization problems using optical computing.

    Main Methods:

    • Utilizing spatial multiplexing with grating patterns to encode multiple Ising spin configurations.
    • Computing multiple Ising Hamiltonians simultaneously through phase distribution.
    • Demonstrating pSPIM on max-cut problems with 100 Ising spins.

    Main Results:

    • Optimal solutions for max-cut problems were obtained more frequently with increased processing units.
    • Parallel processing combined with a multicomponent model efficiently solves problems with rank-greater-than-one interaction matrices.
    • The pSPIM spin-update strategy proves effective for large-scale combinatorial optimization.

    Conclusions:

    • The pSPIM offers a significant advancement in solving large-scale combinatorial optimization problems.
    • Spatial multiplexing and parallel processing are key to overcoming the speed limitations of traditional SPIMs.
    • pSPIM provides an efficient optical computing approach for complex optimization tasks.