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Main Authors: Jeon, Hyeongjun, Lee, Kyungmin, Lee, Dongkyu, Kim, Bongsang, Kim, Taehyun
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.06935
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author Jeon, Hyeongjun
Lee, Kyungmin
Lee, Dongkyu
Kim, Bongsang
Kim, Taehyun
author_facet Jeon, Hyeongjun
Lee, Kyungmin
Lee, Dongkyu
Kim, Bongsang
Kim, Taehyun
contents Matrix product state (MPS) offers a framework for encoding classical data into quantum states, enabling the efficient utilization of quantum resources for data representation and processing. This research paper investigates techniques to enhance the efficiency and accuracy of MPS representations specifically designed for encoding classical data. Based on the observations that MPS truncation error depends on the pattern of the classical data, we devised an algorithm that finds optimal qubit mapping for given classical data, thereby improving the efficiency and fidelity of the MPS representation. Furthermore, we evaluate the impact of the optimized MPS in the context of quantum classifiers, demonstrating their enhanced performance compared to the conventional mapping. This improvement confirms the efficacy of the proposed techniques for encoding classical data into quantum states. MPS representation combined with optimal qubit mapping can pave a new way for more efficient and accurate quantum data representation and processing.
format Preprint
id arxiv_https___arxiv_org_abs_2406_06935
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal Qubit Mapping Search for Encoding Classical Data into Matrix Product State Representation with Minimal Loss
Jeon, Hyeongjun
Lee, Kyungmin
Lee, Dongkyu
Kim, Bongsang
Kim, Taehyun
Quantum Physics
Matrix product state (MPS) offers a framework for encoding classical data into quantum states, enabling the efficient utilization of quantum resources for data representation and processing. This research paper investigates techniques to enhance the efficiency and accuracy of MPS representations specifically designed for encoding classical data. Based on the observations that MPS truncation error depends on the pattern of the classical data, we devised an algorithm that finds optimal qubit mapping for given classical data, thereby improving the efficiency and fidelity of the MPS representation. Furthermore, we evaluate the impact of the optimized MPS in the context of quantum classifiers, demonstrating their enhanced performance compared to the conventional mapping. This improvement confirms the efficacy of the proposed techniques for encoding classical data into quantum states. MPS representation combined with optimal qubit mapping can pave a new way for more efficient and accurate quantum data representation and processing.
title Optimal Qubit Mapping Search for Encoding Classical Data into Matrix Product State Representation with Minimal Loss
topic Quantum Physics
url https://arxiv.org/abs/2406.06935