Efficient Learning of Quantum States Prepared With Few Non-Clifford Gates

Abstract

We give a pair of algorithms that efficiently learn a quantum state prepared by Clifford gates and O( n) non-Clifford gates. Specifically, for an n-qubit state | prepared with at most t non-Clifford gates, our algorithms use poly(n,2t,1/) time and copies of | to learn | to trace distance at most . The first algorithm for this task is more efficient, but requires entangled measurements across two copies of |. The second algorithm uses only single-copy measurements at the cost of polynomial factors in runtime and sample complexity. Our algorithms more generally learn any state with sufficiently large stabilizer dimension, where a quantum state has stabilizer dimension k if it is stabilized by an abelian group of 2k Pauli operators. We also develop an efficient property testing algorithm for stabilizer dimension, which may be of independent interest.