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Main Authors: Giscard, Pierre-Louis, Faizy, Omid, Bonhomme, Christian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.04598
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author Giscard, Pierre-Louis
Faizy, Omid
Bonhomme, Christian
author_facet Giscard, Pierre-Louis
Faizy, Omid
Bonhomme, Christian
contents We present novel, exotic types of frame changes for the calculation of quantum evolution operators. We detail in particular the biframe, in which a physical system's evolution is seen in an equal mixture of two different standard frames at once. We prove that, in the biframe, convergence of all series expansions of the solution is quadratically faster than in `conventional' frames. That is, if in laboratory frame or after a standard frame change the error at order $n$ of some perturbative series expansion of the evolution operator is on the order of $ε^n$, $0<ε<1$, for a computational cost $C(n)$ then it is on the order of $ε^{2n+1}$ in the biframe for the same computational cost. We demonstrate that biframe is one of an infinite family of novel frames, some of which lead to higher accelerations but require more computations to set up initially, leading to a trade-off between acceleration and computational burden.
format Preprint
id arxiv_https___arxiv_org_abs_2510_04598
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Novel frame changes for quantum physics
Giscard, Pierre-Louis
Faizy, Omid
Bonhomme, Christian
Quantum Physics
Mathematical Physics
We present novel, exotic types of frame changes for the calculation of quantum evolution operators. We detail in particular the biframe, in which a physical system's evolution is seen in an equal mixture of two different standard frames at once. We prove that, in the biframe, convergence of all series expansions of the solution is quadratically faster than in `conventional' frames. That is, if in laboratory frame or after a standard frame change the error at order $n$ of some perturbative series expansion of the evolution operator is on the order of $ε^n$, $0<ε<1$, for a computational cost $C(n)$ then it is on the order of $ε^{2n+1}$ in the biframe for the same computational cost. We demonstrate that biframe is one of an infinite family of novel frames, some of which lead to higher accelerations but require more computations to set up initially, leading to a trade-off between acceleration and computational burden.
title Novel frame changes for quantum physics
topic Quantum Physics
Mathematical Physics
url https://arxiv.org/abs/2510.04598