Quantum State Learning Implies Circuit Lower Bounds

Abstract

We establish connections between state tomography, pseudorandomness, quantum state synthesis, and circuit lower bounds. In particular, let C be a family of non-uniform quantum circuits of polynomial size and suppose that there exists an algorithm that, given copies of | , distinguishes whether | is produced by C or is Haar random, promised one of these is the case. For arbitrary fixed constant c, we show that if the algorithm uses at most O(2nc) time and 2n0.99 samples then stateBQE ⊂ stateC. Here stateBQE := stateBQTIME[2O(n)] and stateC are state synthesis complexity classes as introduced by Rosenthal and Yuen (ITCS 2022), which capture problems with classical inputs but quantum output. Note that efficient tomography implies a similarly efficient distinguishing algorithm against Haar random states, even for nearly exponential-time algorithms. Because every state produced by a polynomial-size circuit can be learned with 2O(n) samples and time, or O(nω(1)) samples and 2O(nω(1)) time, we show that even slightly non-trivial quantum state tomography algorithms would lead to new statements about quantum state synthesis. Finally, a slight modification of our proof shows that distinguishing algorithms for quantum states can imply circuit lower bounds for decision problems as well. This help sheds light on why time-efficient tomography algorithms for non-uniform quantum circuit classes has only had limited and partial progress. Our work parallels results by Arunachalam et al. (FOCS 2021) that revealed a similar connection between quantum learning of Boolean functions and circuit lower bounds for classical circuit classes, but modified for the purposes of state tomography and state synthesis.

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