Lower T-count with faster algorithms
Abstract
Among the cost metrics characterizing a quantum circuit, the -count stands out as one of the most crucial as its minimization is particularly important in various areas of quantum computation such as fault-tolerant quantum computing and quantum circuit simulation. In this work, we contribute to the -count reduction problem by proposing efficient -count optimizers with low execution times. In particular, we greatly improve the complexity of TODD, an algorithm currently providing the best -count reduction on various quantum circuits. We also propose some modifications to the algorithm which are leading to a significantly lower number of gates. In addition, we propose another algorithm which has an even lower complexity and that achieves a better or equal -count than the state of the art on most quantum circuits evaluated. We also prove that the number of gates in the circuit obtained after executing our algorithms on a Hadamard-free circuit composed of qubits is upper bounded by , which improves on the worst-case -count of existing optimization algorithms. From this we derive an upper bound of for the number of gates in a Clifford circuit where is the number of internal Hadamard gates in the circuit, i.e. the number of Hadamard gates lying between the first and the last gate of the circuit.
Cite
@article{arxiv.2407.08695,
title = {Lower T-count with faster algorithms},
author = {Vivien Vandaele},
journal= {arXiv preprint arXiv:2407.08695},
year = {2025}
}