Entropy computing, a paradigm for optimization in open photonic systems

Lac Nguyen; Mohammad Ali Miri; R. Joseph Rupert; Wesley Dyk; Sam Wu; Nick Vrahoretis; Irwin Huang; Milan Begliarbekov; Nicholas Chancellor; Uchenna Chukwu; Pranav Mahamuni; Cesar Martinez-Delgado; David Haycraft; Carrie Spear; Joel Russell Huffman; Yong Meng Sua; Yu Ping Huang

doi:10.1038/s42005-025-02324-6

Entropy computing, a paradigm for optimization in open photonic systems

Lac Nguyen
, Mohammad Ali Miri
, R. Joseph Rupert
, Wesley Dyk
, Sam Wu
, Nick Vrahoretis
, Irwin Huang
, Milan Begliarbekov
, Nicholas Chancellor
, Uchenna Chukwu
, Pranav Mahamuni
, Cesar Martinez-Delgado
, David Haycraft
, Carrie Spear
, Joel Russell Huffman
, Yong Meng Sua
, Yu Ping Huang

Department of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Finding better solutions to combinatorial optimization problems could have a large positive impact on many real-world application areas, such as logistics. For this reason, significant efforts have been made to design novel optimization paradigms. Here we show an early instance of such paradigm in an optical setting, the entropy computing paradigm. Specifically, we experimentally demonstrate the feasibility of entropy computing by building a hybrid photonic-electronic computer that uses optical measurement and feedback to solve non-convex optimization problems. The system functions by using temporal photonic modes to create qudits in order to encode probability amplitudes in the time-frequency degree of freedom of a photon. This scheme, when coupled with with electronic interconnects, allows us to encode an arbitrary Hamiltonian into the system and solve non-convex continuous variables and combinatorial optimization problems. We show that the proposed entropy computing paradigm can act as a scalable and versatile platform for tackling a large range of NP-hard optimization problems.

Original language	English
Article number	411
Journal	Communications Physics
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s42005-025-02324-6
State	Published - Dec 2025

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Nguyen, L., Miri, M. A., Rupert, R. J., Dyk, W., Wu, S., Vrahoretis, N., Huang, I., Begliarbekov, M., Chancellor, N., Chukwu, U., Mahamuni, P., Martinez-Delgado, C., Haycraft, D., Spear, C., Huffman, J. R., Sua, Y. M., & Huang, Y. P. (2025). Entropy computing, a paradigm for optimization in open photonic systems. Communications Physics, 8(1), Article 411. https://doi.org/10.1038/s42005-025-02324-6

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title = "Entropy computing, a paradigm for optimization in open photonic systems",

abstract = "Finding better solutions to combinatorial optimization problems could have a large positive impact on many real-world application areas, such as logistics. For this reason, significant efforts have been made to design novel optimization paradigms. Here we show an early instance of such paradigm in an optical setting, the entropy computing paradigm. Specifically, we experimentally demonstrate the feasibility of entropy computing by building a hybrid photonic-electronic computer that uses optical measurement and feedback to solve non-convex optimization problems. The system functions by using temporal photonic modes to create qudits in order to encode probability amplitudes in the time-frequency degree of freedom of a photon. This scheme, when coupled with with electronic interconnects, allows us to encode an arbitrary Hamiltonian into the system and solve non-convex continuous variables and combinatorial optimization problems. We show that the proposed entropy computing paradigm can act as a scalable and versatile platform for tackling a large range of NP-hard optimization problems.",

author = "Lac Nguyen and Miri, \{Mohammad Ali\} and Rupert, \{R. Joseph\} and Wesley Dyk and Sam Wu and Nick Vrahoretis and Irwin Huang and Milan Begliarbekov and Nicholas Chancellor and Uchenna Chukwu and Pranav Mahamuni and Cesar Martinez-Delgado and David Haycraft and Carrie Spear and Huffman, \{Joel Russell\} and Sua, \{Yong Meng\} and Huang, \{Yu Ping\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

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doi = "10.1038/s42005-025-02324-6",

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Nguyen, L, Miri, MA, Rupert, RJ, Dyk, W, Wu, S, Vrahoretis, N, Huang, I, Begliarbekov, M, Chancellor, N, Chukwu, U, Mahamuni, P, Martinez-Delgado, C, Haycraft, D, Spear, C, Huffman, JR, Sua, YM & Huang, YP 2025, 'Entropy computing, a paradigm for optimization in open photonic systems', Communications Physics, vol. 8, no. 1, 411. https://doi.org/10.1038/s42005-025-02324-6

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AU - Nguyen, Lac

AU - Miri, Mohammad Ali

AU - Rupert, R. Joseph

AU - Dyk, Wesley

AU - Wu, Sam

AU - Vrahoretis, Nick

AU - Huang, Irwin

AU - Begliarbekov, Milan

AU - Chancellor, Nicholas

AU - Chukwu, Uchenna

AU - Mahamuni, Pranav

AU - Martinez-Delgado, Cesar

AU - Haycraft, David

AU - Spear, Carrie

AU - Huffman, Joel Russell

AU - Sua, Yong Meng

AU - Huang, Yu Ping

PY - 2025/12

Y1 - 2025/12

N2 - Finding better solutions to combinatorial optimization problems could have a large positive impact on many real-world application areas, such as logistics. For this reason, significant efforts have been made to design novel optimization paradigms. Here we show an early instance of such paradigm in an optical setting, the entropy computing paradigm. Specifically, we experimentally demonstrate the feasibility of entropy computing by building a hybrid photonic-electronic computer that uses optical measurement and feedback to solve non-convex optimization problems. The system functions by using temporal photonic modes to create qudits in order to encode probability amplitudes in the time-frequency degree of freedom of a photon. This scheme, when coupled with with electronic interconnects, allows us to encode an arbitrary Hamiltonian into the system and solve non-convex continuous variables and combinatorial optimization problems. We show that the proposed entropy computing paradigm can act as a scalable and versatile platform for tackling a large range of NP-hard optimization problems.

AB - Finding better solutions to combinatorial optimization problems could have a large positive impact on many real-world application areas, such as logistics. For this reason, significant efforts have been made to design novel optimization paradigms. Here we show an early instance of such paradigm in an optical setting, the entropy computing paradigm. Specifically, we experimentally demonstrate the feasibility of entropy computing by building a hybrid photonic-electronic computer that uses optical measurement and feedback to solve non-convex optimization problems. The system functions by using temporal photonic modes to create qudits in order to encode probability amplitudes in the time-frequency degree of freedom of a photon. This scheme, when coupled with with electronic interconnects, allows us to encode an arbitrary Hamiltonian into the system and solve non-convex continuous variables and combinatorial optimization problems. We show that the proposed entropy computing paradigm can act as a scalable and versatile platform for tackling a large range of NP-hard optimization problems.

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Entropy computing, a paradigm for optimization in open photonic systems

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