Improved Stabilizer Estimation via Bell Difference Sampling

Abstract

We study the complexity of learning quantum states in various models with respect to the stabilizer formalism and obtain the following results: - We prove that (n) T-gates are necessary for any Clifford+T circuit to prepare computationally pseudorandom quantum states, an exponential improvement over the previously known bound. This bound is asymptotically tight if linear-time quantum-secure pseudorandom functions exist. - Given an n-qubit pure quantum state | that has fidelity at least τ with some stabilizer state, we give an algorithm that outputs a succinct description of a stabilizer state that witnesses fidelity at least τ - . The algorithm uses O(n/(2τ4)) samples and (O(n/τ4)) / 2 time. In the regime of τ constant, this algorithm estimates stabilizer fidelity substantially faster than the na\"ive (O(n2))-time brute-force algorithm over all stabilizer states. - In the special case of τ > 2(π/8), we show that a modification of the above algorithm runs in polynomial time. - We exhibit a tolerant property testing algorithm for stabilizer states. The underlying algorithmic primitive in all of our results is Bell difference sampling. To prove our results, we establish and/or strengthen connections between Bell difference sampling, symplectic Fourier analysis, and graph theory.