Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems

Mayank Shekhar Jha; Prasanna Date

doi:10.1109/QCE65121.2025.10341

Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems

Mayank Shekhar Jha
, Prasanna Date

Learning Systems

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

This paper presents a novel approach for solving finite-horizon linear optimal control based on block-Toeplitz least-squares problem, by recasting the latter as Quadratic Unconstrained Binary Optimization (QUBO) suitable for adiabatic quantum computing (AQC). Classical block-Toeplitz leastsquares problem, scales as Nm3 for horizon length N and control dimension m. We demonstrate that this Toeplitzstructured least-squares cost can be transformed into a QUBO formulation by introducing binary precision vectors that encode each continuous control parameter into finite number of bits. We establish the general case in mathematically rigorous manner wherein the total number of binary decision variables remain dependent on N. To respect current quantum annealer capabilities, we propose a basis-function parametrization that approximates the full control sequence with a small set of basis coefficients, reducing the total number of binary-variables and rendering the latter independent of N. Through simulation study, we show that, for large datasets, the QUBO pipeline, comprising of hardware-constant anneal step outperforms classical least square based solvers by several factors whilst demonstrating acceptable accuracy.

Original language	English
Title of host publication	Keynotes, Workshops, Posters, Panels, and Tutorials Program
Editors	Candace Culhane, Greg Byrd, Hausi Muller, Andrea Delgado, Stephan Eidenbenz
Publisher	Institute of Electrical and Electronics Engineers Inc.
Pages	308-313
Number of pages	6
ISBN (Electronic)	9798331557362
DOIs	https://doi.org/10.1109/QCE65121.2025.10341
State	Published - 2025
Event	6th IEEE International Conference on Quantum Computing and Engineering, QCE 2025 - Albuquerque, United States Duration: Aug 31 2025 → Sep 5 2025

Publication series

Name	Proceedings - IEEE Quantum Week 2025, QCE 2025
Volume	2

Conference

Conference	6th IEEE International Conference on Quantum Computing and Engineering, QCE 2025
Country/Territory	United States
City	Albuquerque
Period	08/31/25 → 09/5/25

Funding

The first author would like to thank the good Costa Brava beaches, sangria and Ludwig Göransson for the music in the movie Oppenheimer.

Keywords

adiabatic quantum computing
least squares
optimal control
quantum control

Access to Document

10.1109/QCE65121.2025.10341

Cite this

Jha, M. S., & Date, P. (2025). Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems. In C. Culhane, G. Byrd, H. Muller, A. Delgado, & S. Eidenbenz (Eds.), Keynotes, Workshops, Posters, Panels, and Tutorials Program (pp. 308-313). (Proceedings - IEEE Quantum Week 2025, QCE 2025; Vol. 2). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/QCE65121.2025.10341

Jha, Mayank Shekhar ; Date, Prasanna. / Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems. Keynotes, Workshops, Posters, Panels, and Tutorials Program. editor / Candace Culhane ; Greg Byrd ; Hausi Muller ; Andrea Delgado ; Stephan Eidenbenz. Institute of Electrical and Electronics Engineers Inc., 2025. pp. 308-313 (Proceedings - IEEE Quantum Week 2025, QCE 2025).

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title = "Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems",

abstract = "This paper presents a novel approach for solving finite-horizon linear optimal control based on block-Toeplitz least-squares problem, by recasting the latter as Quadratic Unconstrained Binary Optimization (QUBO) suitable for adiabatic quantum computing (AQC). Classical block-Toeplitz leastsquares problem, scales as Nm3 for horizon length N and control dimension m. We demonstrate that this Toeplitzstructured least-squares cost can be transformed into a QUBO formulation by introducing binary precision vectors that encode each continuous control parameter into finite number of bits. We establish the general case in mathematically rigorous manner wherein the total number of binary decision variables remain dependent on N. To respect current quantum annealer capabilities, we propose a basis-function parametrization that approximates the full control sequence with a small set of basis coefficients, reducing the total number of binary-variables and rendering the latter independent of N. Through simulation study, we show that, for large datasets, the QUBO pipeline, comprising of hardware-constant anneal step outperforms classical least square based solvers by several factors whilst demonstrating acceptable accuracy.",

keywords = "adiabatic quantum computing, least squares, optimal control, quantum control",

author = "Jha, \{Mayank Shekhar\} and Prasanna Date",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 6th IEEE International Conference on Quantum Computing and Engineering, QCE 2025 ; Conference date: 31-08-2025 Through 05-09-2025",

year = "2025",

doi = "10.1109/QCE65121.2025.10341",

language = "English",

series = "Proceedings - IEEE Quantum Week 2025, QCE 2025",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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Jha, MS & Date, P 2025, Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems. in C Culhane, G Byrd, H Muller, A Delgado & S Eidenbenz (eds), Keynotes, Workshops, Posters, Panels, and Tutorials Program. Proceedings - IEEE Quantum Week 2025, QCE 2025, vol. 2, Institute of Electrical and Electronics Engineers Inc., pp. 308-313, 6th IEEE International Conference on Quantum Computing and Engineering, QCE 2025, Albuquerque, United States, 08/31/25. https://doi.org/10.1109/QCE65121.2025.10341

Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems. / Jha, Mayank Shekhar; Date, Prasanna.
Keynotes, Workshops, Posters, Panels, and Tutorials Program. ed. / Candace Culhane; Greg Byrd; Hausi Muller; Andrea Delgado; Stephan Eidenbenz. Institute of Electrical and Electronics Engineers Inc., 2025. p. 308-313 (Proceedings - IEEE Quantum Week 2025, QCE 2025; Vol. 2).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Date, Prasanna

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N2 - This paper presents a novel approach for solving finite-horizon linear optimal control based on block-Toeplitz least-squares problem, by recasting the latter as Quadratic Unconstrained Binary Optimization (QUBO) suitable for adiabatic quantum computing (AQC). Classical block-Toeplitz leastsquares problem, scales as Nm3 for horizon length N and control dimension m. We demonstrate that this Toeplitzstructured least-squares cost can be transformed into a QUBO formulation by introducing binary precision vectors that encode each continuous control parameter into finite number of bits. We establish the general case in mathematically rigorous manner wherein the total number of binary decision variables remain dependent on N. To respect current quantum annealer capabilities, we propose a basis-function parametrization that approximates the full control sequence with a small set of basis coefficients, reducing the total number of binary-variables and rendering the latter independent of N. Through simulation study, we show that, for large datasets, the QUBO pipeline, comprising of hardware-constant anneal step outperforms classical least square based solvers by several factors whilst demonstrating acceptable accuracy.

AB - This paper presents a novel approach for solving finite-horizon linear optimal control based on block-Toeplitz least-squares problem, by recasting the latter as Quadratic Unconstrained Binary Optimization (QUBO) suitable for adiabatic quantum computing (AQC). Classical block-Toeplitz leastsquares problem, scales as Nm3 for horizon length N and control dimension m. We demonstrate that this Toeplitzstructured least-squares cost can be transformed into a QUBO formulation by introducing binary precision vectors that encode each continuous control parameter into finite number of bits. We establish the general case in mathematically rigorous manner wherein the total number of binary decision variables remain dependent on N. To respect current quantum annealer capabilities, we propose a basis-function parametrization that approximates the full control sequence with a small set of basis coefficients, reducing the total number of binary-variables and rendering the latter independent of N. Through simulation study, we show that, for large datasets, the QUBO pipeline, comprising of hardware-constant anneal step outperforms classical least square based solvers by several factors whilst demonstrating acceptable accuracy.

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KW - least squares

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A2 - Delgado, Andrea

A2 - Eidenbenz, Stephan

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 6th IEEE International Conference on Quantum Computing and Engineering, QCE 2025

Y2 - 31 August 2025 through 5 September 2025

ER -

Jha MS, Date P. Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems. In Culhane C, Byrd G, Muller H, Delgado A, Eidenbenz S, editors, Keynotes, Workshops, Posters, Panels, and Tutorials Program. Institute of Electrical and Electronics Engineers Inc. 2025. p. 308-313. (Proceedings - IEEE Quantum Week 2025, QCE 2025). doi: 10.1109/QCE65121.2025.10341

Adiabatic Quantum Linear Optimal Control for Discrete Time Dynamical Systems

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Keywords

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