Exponential qubit reduction in optimization for financial transaction settlement

Exponential qubit reduction in optimization for financial transaction settlement

We extend the qubit-efficient encoding presented in (Tan et al. in Quantum 5:454, 2021) and apply it to instances of the financial transaction settlement problem constructed from data provided by a regulated financial exchange. Our methods are directly applicable to any QUBO problem with linear ineq...

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Bibliographic Details
Main Authors: HUBER, Elias X., TAN, Benjamin Y. L., GRIFFIN, Paul Robert, ANGELAKIS, Dimitris G.
Format: text
Language:English
Published: Institutional Knowledge at Singapore Management University 2024
Subjects:
Mixed binary optimization
NISQ
Quantum Computing
Quantum Finance
Quantum Optimization
Qubit reduction
QUBO
Finance and Financial Management
Software Engineering
Online Access:https://ink.library.smu.edu.sg/sis_research/9274
https://ink.library.smu.edu.sg/context/sis_research/article/10274/viewcontent/s40507_024_00262_w_pvoa.pdf
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Institution: Singapore Management University
Language: English
Description
Summary:We extend the qubit-efficient encoding presented in (Tan et al. in Quantum 5:454, 2021) and apply it to instances of the financial transaction settlement problem constructed from data provided by a regulated financial exchange. Our methods are directly applicable to any QUBO problem with linear inequality constraints. Our extension of previously proposed methods consists of a simplification in varying the number of qubits used to encode correlations as well as a new class of variational circuits which incorporate symmetries thereby reducing sampling overhead, improving numerical stability and recovering the expression of the cost objective as a Hermitian observable. We also propose optimality-preserving methods to reduce variance in real-world data and substitute continuous slack variables. We benchmark our methods against standard QAOA for problems consisting of 16 transactions and obtain competitive results. Our newly proposed variational ansatz performs best overall. We demonstrate tackling problems with 128 transactions on real quantum hardware, exceeding previous results bounded by NISQ hardware by almost two orders of magnitude.

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