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Optimal algorithms for learning quantum phase states

Quantum Physics 2023-05-04 v2 Data Structures and Algorithms

Abstract

We analyze the complexity of learning nn-qubit quantum phase states. A degree-dd phase state is defined as a superposition of all 2n2^n basis vectors xx with amplitudes proportional to (1)f(x)(-1)^{f(x)}, where ff is a degree-dd Boolean polynomial over nn variables. We show that the sample complexity of learning an unknown degree-dd phase state is Θ(nd)\Theta(n^d) if we allow separable measurements and Θ(nd1)\Theta(n^{d-1}) if we allow entangled measurements. Our learning algorithm based on separable measurements has runtime poly(n)\textsf{poly}(n) (for constant dd) and is well-suited for near-term demonstrations as it requires only single-qubit measurements in the Pauli XX and ZZ bases. We show similar bounds on the sample complexity for learning generalized phase states with complex-valued amplitudes. We further consider learning phase states when ff has sparsity-ss, degree-dd in its F2\mathbb{F}_2 representation (with sample complexity O(2dsn)O(2^d sn)), ff has Fourier-degree-tt (with sample complexity O(22t)O(2^{2t})), and learning quadratic phase states with ε\varepsilon-global depolarizing noise (with sample complexity O(n1+ε)O(n^{1+\varepsilon})). These learning algorithms give us a procedure to learn the diagonal unitaries of the Clifford hierarchy and IQP~circuits.

Keywords

Cite

@article{arxiv.2208.07851,
  title  = {Optimal algorithms for learning quantum phase states},
  author = {Srinivasan Arunachalam and Sergey Bravyi and Arkopal Dutt and Theodore J. Yoder},
  journal= {arXiv preprint arXiv:2208.07851},
  year   = {2023}
}

Comments

39 pages, corrected proof on learning phase states with PGMs, accepted to TQC 2023

R2 v1 2026-06-25T01:44:46.258Z