Linear-Size QAC0 Channels: Learning, Testing and Hardness
Abstract
Shallow quantum circuits have attracted increasing attention in recent years, due to the fact that current noisy quantum hardware can only perform faithful quantum computation for a short amount of time. The constant-depth quantum circuits QAC0, a quantum counterpart of AC0 circuits, are the polynomial-size and constant-depth quantum circuits composed of only single-qubit unitaries and polynomial-size generalized Toffoli gates. The computational power of QAC0 has been extensively investigated in recent years. In this paper, we are concerned with QLC0 circuits, which are linear-size QAC0 circuits, a quantum counterpart of LC0. * We show that depth-d QAC0 circuits working on n input qubits and a ancilla qubits have approximate degree at most O((n+a)1-2-d), improving the O((n+a)1-3-d) degree upper bound of previous works. Consequently, this directly implies that to compute the parity function, QAC0 circuits need at least O(n1+2-d) circuit size. * We present the first agnostic learning algorithm for QLC0 channels using subexponential running time and queries. Moreover, we also establish exponential lower bounds on the query complexity of learning QAC0 channels under both the spectral norm distance of the Choi matrix and the diamond norm distance. * We present a tolerant testing algorithm which determines whether an unknown quantum channel is a QLC0 channel. This tolerant testing algorithm is based on our agnostic learning algorithm. Our approach leverages low-degree approximations of QAC0 circuits and Pauli analysis as key technical tools. Collectively, these results advance our understanding of agnostic learning for shallow quantum circuits.
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