Approximation does not help in quantum unitary time-reversal
Abstract
Access to the time-reverse of an unknown quantum unitary process is widely assumed in quantum learning, metrology, and many-body physics. The fundamental task of unitary time-reversal dictates implementing to within diamond-norm error using black-box queries to the -dimensional unitary . Although the query complexity of this task has been extensively studied, existing lower bounds either hold only for the exact case (i.e., ) or are suboptimal in . This raises a central question: does approximation help reduce the query complexity of unitary time-reversal? We settle this question in the negative by establishing a robust and tight lower bound with explicit dependence on the error . This implies that unitary time-reversal retains optimal exponential hardness (in the number of qubits) even when constant error is allowed. Our bound applies to adaptive and coherent algorithms with unbounded ancillas and holds even when is an average-case distance error.
Cite
@article{arxiv.2507.05736,
title = {Approximation does not help in quantum unitary time-reversal},
author = {Kean Chen and Nengkun Yu and Zhicheng Zhang},
journal= {arXiv preprint arXiv:2507.05736},
year = {2026}
}
Comments
39 pages; v2: minor revision; v3: removed the result on hardness of unitary controlization due to an error; v4: changed title and revised Introduction section