Halving the cost of quantum multiplexed rotations

Abstract

We improve the number of T gates needed for a b-bit approximation of a multiplexed quantum gate with c controls applying n single-qubit arbitrary phase rotations from 4n b+O(cn b) to 2n b+O(cn b), and reduce the number of qubits needed by up to a factor of two. This generic quantum circuit primitive is found in many quantum algorithms, and our results roughly halve the cost of state-of-art electronic structure simulations based on qubitization of double-factorized or tensor-hypercontracted representations. We achieve this by extending recent ideas on stochastic compilation of quantum circuits to classical data and discuss space-time trade-offs and concentration of measure in its implementation.

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