On the Computational Complexity of Geometrically Local QAC0 circuits

Abstract

The computational complexity of QAC0, which are constant-depth, polynomial-size quantum circuit families consisting of arbitrary single-qubit unitaries and n-qubit generalized Toffoli gates, has gained tremendous focus recently. In this work, we initiate the study of the computational complexity of geometrically local QAC0 circuits, where all the generalized Toffoli gates act on nearest neighbor qubits. We show that any QAC0 circuit can be exactly simulated by a two-dimensional geometrically local QAC0 circuit, i.e., a 2D-QAC0 circuit, with a quadratic size blow-up. This implies that QAC0 = 2D-QAC0. We further show that if there existed a QAC0 circuit that computes Parity with a bounded constant error, then for any > 0, there would exist a 2D-QAC0 circuit that exactly computes Parity, with a very "thin" width n. We further study the computational power of 1D-QAC0 circuits, i.e., one-dimensional QAC0 circuits, which are the "thinnest" 2D-QAC0 circuits. We prove a nearly logarithmic depth lower bound on 1D-QAC0 circuits to compute the Parity function, even if allowing an unlimited number of ancilla. Furthermore, if the inputs are encoded in contiguous qubits, we prove that it requires a nearly linear depth 1D-QAC0 circuit to compute the Parity function. This lower bound is almost tight. The results are proved via the combination of the restriction argument and the light-cone argument. These results may provide a new angle for studying the computational power of QAC0 circuits and for resolving the long-standing open problem of whether Parity is in QAC0.