Collapse of the Hierarchy of Constant-Depth Exact Quantum Circuits

Abstract

We study the quantum complexity class QNC0f of quantum operations implementable exactly by constant-depth polynomial-size quantum circuits with unbounded fan-out gates (called QNC0f circuits). Our main result is that the quantum OR operation is in QNC0f, which is an affirmative answer to the question of Hoyer and Spalek. In sharp contrast to the strict hierarchy of the classical complexity classes: NC0 ⊂neq AC0 ⊂neq TC0, our result with Hoyer and Spalek's one implies the collapse of the hierarchy of the corresponding quantum ones: QNC0f = QAC0f = QTC0f. Then, we show that there exists a constant-depth subquadratic-size quantum circuit for the quantum threshold operation. This implies the size difference between the QNC0f and QTC0f circuits for implementing the same quantum operation. Lastly, we show that, if the quantum Fourier transform modulo a prime is in QNC0f, there exists a polynomial-time exact classical algorithm for a discrete logarithm problem using a QNC0f oracle. This implies that, under a plausible assumption, there exists a classically hard problem that is solvable exactly by a QNC0f circuit with gates for the quantum Fourier transform.