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Explicit Quantum Circuits for Block Encodings of Certain Sparse Matrices

Daan Camps, Lin Lin, Roel Van Beeumen, Chao Yang

2024SIAM Journal on Matrix Analysis and Applications60 citationsDOIOpen Access PDF

Abstract

Many standard linear algebra problems can be solved on a quantum computer by using recently developed quantum linear algebra algorithms that make use of block encodings and quantum eigenvalue/singular value transformations. A block encoding embeds a properly scaled matrix of interest A in a larger unitary transformation U that can be decomposed into a product of simpler unitaries and implemented efficiently on a quantum computer. Although quantum algorithms can potentially achieve exponential speedup in solving linear algebra problems compared to the best classical algorithm, such a gain in efficiency ultimately hinges on our ability to construct an efficient quantum circuit for the block encoding of A, which is difficult in general, and not trivial even for well structured sparse matrices. In this paper, we give a few examples on how efficient quantum circuits can be explicitly constructed for some well structured sparse matrices and discuss a few strategies used in these constructions. We also provide implementations of these quantum circuits in MATLAB.

Topics & Concepts

Linear algebraQuantum algorithmQuantum phase estimation algorithmEigenvalues and eigenvectorsMathematicsQuantum computerAlgebra over a fieldQuantumAlgorithmSingular value decompositionQuantum circuitComputer scienceQuantum error correctionPure mathematicsQuantum mechanicsGeometryPhysicsQuantum Computing Algorithms and ArchitectureQuantum-Dot Cellular AutomataQuantum Information and Cryptography
Explicit Quantum Circuits for Block Encodings of Certain Sparse Matrices | Litcius