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Improved Strong Simulation of Universal Quantum Circuits

Quantum Physics 2022-06-08 v4

Abstract

We find a scaling reduction in the stabilizer rank of the twelve-qubit tensored TT gate magic state. This lowers its asymptotic bound to 20.463t2^{\sim 0.463 t} for multi-Pauli measurements on tt magic states, improving over the best previously found bound of 20.468t2^{\sim 0.468 t}. We numerically demonstrate this reduction. This constructively produces the most efficient strong simulation algorithm of the Clifford+TT gateset to relative or multiplicative error. We then examine the cost of Pauli measurement in terms of its Gauss sum rank, which is a slight generalization of the stabilizer rank and is a lower bound on its asymptotic scaling. We demonstrate that this lower bound appears to be tight at low tt-counts, which suggests that the stabilizer rank found at the twelve-qubit state can be lowered further to 20.449t2^{\sim 0.449 t} and we prove and numerically show that this is the case for single-Pauli measurements. Our construction directly shows how the reduction at 1212 qubits is iteratively based on the reduction obtained at 66, 33, 22, and 11 qubits. This explains why novel reductions are found at tensor factors for these number of qubit primitives, an explanation lacking previously in the literature. Furthermore, in the process we observe an interesting relationship between the T gate magic state's stabilizer rank and decompositions that are Clifford-isomorphic to a computational sub-basis tensored with single-qubit states that produce minimal unique stabilizer state inner products -- the same relationship that allowed for finding minimal numbers of unique Gauss sums in the odd-dimensional qudit Wigner formulation of Pauli measurements.

Keywords

Cite

@article{arxiv.2012.11739,
  title  = {Improved Strong Simulation of Universal Quantum Circuits},
  author = {Lucas Kocia},
  journal= {arXiv preprint arXiv:2012.11739},
  year   = {2022}
}
R2 v1 2026-06-23T21:10:33.040Z