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Quantum State Preparation by Improved MPS Method

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arxiv 2508.12821 v1 pith:O5GCZGDL submitted 2025-08-18 quant-ph

Quantum State Preparation by Improved MPS Method

classification quant-ph
keywords methodpreparationstatecircuitdepthimprovedquantumachieving
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Efficient encoding of classical information plays a fundamental role in numerous practical quantum algorithms. However, the preparation of an arbitrary amplitude-encoded state has been proven to be time-consuming, and its deployment on current noisy devices can be challenging. In this work, we propose an improved Matrix Product State(MPS) method preparation protocol with an exponential reduction on the circuit depth, as well as topological adaptability. By refined utilization of the disentangling principle, we also reduce approximately 33% two-qubit gate count. To validate our method, we study various families of functions and distributions with provably bounded MPS rank. Numerical experiments show that our method significantly reduces circuit depth while achieving higher fidelity for states arising in financial and other applications.

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Cited by 1 Pith paper

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    quant-ph 2026-06 unverdicted novelty 6.0

    Introduces a parallelizable hybrid tensor network algorithm for time-evolving matrix product states that combines classical BUG integration with quantum methods without synchronization barriers.