Eigenstate-assisted realization of general quantum controlled unitaries with a fixed cost

Abstract

Controlled unitary gates are a basic element in many quantum algorithms. Converting a general unitary U with a known decomposition into its controlled version, controlled-U, can introduce a large overhead in terms of the depth of the circuit. We present a general method to take any unitary U into controlled-U using a fixed circuit with 4 CNOT gates and 2 Toffoli gates per qubit. For n-qubit unitaries and one control qubit, we require 2n+1 qubits and a circuit that can generate an eigenstate of U, for which there are many cost-effective known algorithms. The method also works for any black block implementation of U, achieving a constant-depth realization independent of its decomposition. We illustrate its use in the Hadamard test and discuss applications to variational and quantum machine-learning algorithms.