Efficient Computation Using Spatial-Photonic Ising Machines: Utilizing Low-Rank and Circulant Matrix Constraints

We explore the potential of spatial-photonic Ising machines (SPIMs) to address computationally intensive Ising problems that employ low-rank and circulant coupling matrices. Our results indicate that the performance of SPIMs is critically affected by the rank and precision of the coupling matrices....

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Hauptverfasser:	Wang, Richard Zhipeng, Cummins, James S, Syed, Marvin, Stroev, Nikita, Pastras, George, Sakellariou, Jason, Tsintzos, Symeon, Askitopoulos, Alexis, Veraldi, Daniele, Strinati, Marcello Calvanese, Gentilini, Silvia, Pierangeli, Davide, Conti, Claudio, Berloff, Natalia G
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Schlagworte:	Computer Science - Emerging Technologies Computer Science - Learning Physics - Computational Physics Physics - Disordered Systems and Neural Networks Physics - Optics
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creator	Wang, Richard Zhipeng Cummins, James S Syed, Marvin Stroev, Nikita Pastras, George Sakellariou, Jason Tsintzos, Symeon Askitopoulos, Alexis Veraldi, Daniele Strinati, Marcello Calvanese Gentilini, Silvia Pierangeli, Davide Conti, Claudio Berloff, Natalia G
description	We explore the potential of spatial-photonic Ising machines (SPIMs) to address computationally intensive Ising problems that employ low-rank and circulant coupling matrices. Our results indicate that the performance of SPIMs is critically affected by the rank and precision of the coupling matrices. By developing and assessing advanced decomposition techniques, we expand the range of problems SPIMs can solve, overcoming the limitations of traditional Mattis-type matrices. Our approach accommodates a diverse array of coupling matrices, including those with inherently low ranks, applicable to complex NP-complete problems. We explore the practical benefits of low-rank approximation in optimization tasks, particularly in financial optimization, to demonstrate the real-world applications of SPIMs. Finally, we evaluate the computational limitations imposed by SPIM hardware precision and suggest strategies to optimize the performance of these systems within these constraints.
doi_str_mv	10.48550/arxiv.2406.01400
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title	Efficient Computation Using Spatial-Photonic Ising Machines: Utilizing Low-Rank and Circulant Matrix Constraints
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