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Main Authors: Shi, Chenyu, Leoni, Gabriele, Petrillo, Mauro, Gallardo, Antonio Puertas, Wang, Hao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.05465
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author Shi, Chenyu
Leoni, Gabriele
Petrillo, Mauro
Gallardo, Antonio Puertas
Wang, Hao
author_facet Shi, Chenyu
Leoni, Gabriele
Petrillo, Mauro
Gallardo, Antonio Puertas
Wang, Hao
contents Computing the similarity between two DNA sequences is of vital importance in bioscience, yet it can be computationally expensive on classical hardware. For example, the edit distance with move operations (EDM), a DNA similarity measure of interest in biology, is proven to be NP-Complete to compute exactly on classical hardware. Recently, applied quantum algorithms have been anticipated to offer potential advantages over classical approaches. In this paper, we propose a novel variational quantum kernel model served as a surrogate model for estimating similarity between DNA sequences defined by EDM. Since the EDM metric exhibits a pairwise permutation-insensitive property, we incorporate a permutation-invariant structure into the variational quantum kernel to approximate this symmetry. Furthermore, to encode the four nucleotide bases as quantum states, we introduce a theoretically motivated encoding scheme based on symmetric informationally complete positive operator-valued measure (SIC-POVM) states. This encoding ensures mutual equivalence among bases, as each pair of symbols is mapped to quantum states that are equidistant on the Bloch sphere. We experimentally show that, equipped with the permutation-invariant circuit design and mutual-equivalence encoding, the proposed quantum kernel model achieves strong performance in approximating the similarity defined by EDM. Compared with classical kernel learning methods, our quantum approach achieves significantly higher accuracy while using substantially fewer trainable parameters.
format Preprint
id arxiv_https___arxiv_org_abs_2503_05465
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Compare Similarities Between DNA Sequences Using Permutation-Invariant Quantum Kernel
Shi, Chenyu
Leoni, Gabriele
Petrillo, Mauro
Gallardo, Antonio Puertas
Wang, Hao
Quantum Physics
Computing the similarity between two DNA sequences is of vital importance in bioscience, yet it can be computationally expensive on classical hardware. For example, the edit distance with move operations (EDM), a DNA similarity measure of interest in biology, is proven to be NP-Complete to compute exactly on classical hardware. Recently, applied quantum algorithms have been anticipated to offer potential advantages over classical approaches. In this paper, we propose a novel variational quantum kernel model served as a surrogate model for estimating similarity between DNA sequences defined by EDM. Since the EDM metric exhibits a pairwise permutation-insensitive property, we incorporate a permutation-invariant structure into the variational quantum kernel to approximate this symmetry. Furthermore, to encode the four nucleotide bases as quantum states, we introduce a theoretically motivated encoding scheme based on symmetric informationally complete positive operator-valued measure (SIC-POVM) states. This encoding ensures mutual equivalence among bases, as each pair of symbols is mapped to quantum states that are equidistant on the Bloch sphere. We experimentally show that, equipped with the permutation-invariant circuit design and mutual-equivalence encoding, the proposed quantum kernel model achieves strong performance in approximating the similarity defined by EDM. Compared with classical kernel learning methods, our quantum approach achieves significantly higher accuracy while using substantially fewer trainable parameters.
title Compare Similarities Between DNA Sequences Using Permutation-Invariant Quantum Kernel
topic Quantum Physics
url https://arxiv.org/abs/2503.05465