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Main Authors: Sarkar, Anindita, Chaki, Paranjoy, Ghosh, Priya, Sen, Ujjwal
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.24484
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author Sarkar, Anindita
Chaki, Paranjoy
Ghosh, Priya
Sen, Ujjwal
author_facet Sarkar, Anindita
Chaki, Paranjoy
Ghosh, Priya
Sen, Ujjwal
contents We propose a general framework to compare the values of a physical quantity pertaining to two - or more - physical setups, in the finite-precision scenario. Such a situation requires us to compare between two "patches" on the real line instead of two numbers. Identification of extent of the patches is typically done via standard deviation, as obtained within usual quantum metrological considerations, but can not be always applied, especially for asymmetric error distributions. The extent can however be universally determined by utilizing the concept of percentiles of the probability distribution of the corresponding estimator. As an application, we introduce the concept of finite-precision cooling in a generic quantum system. We use this approach in the working of a three-qubit quantum refrigerator governed by Markovian dynamics, and demonstrate the occurrence of cooling within finite precision for both transient and steady-state regimes, across strong- and weak-coupling limits of the inter-qubit interaction.
format Preprint
id arxiv_https___arxiv_org_abs_2510_24484
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Comparing physical quantities with finite-precision: beyond standard metrology and an illustration for cooling in quantum processes
Sarkar, Anindita
Chaki, Paranjoy
Ghosh, Priya
Sen, Ujjwal
Quantum Physics
We propose a general framework to compare the values of a physical quantity pertaining to two - or more - physical setups, in the finite-precision scenario. Such a situation requires us to compare between two "patches" on the real line instead of two numbers. Identification of extent of the patches is typically done via standard deviation, as obtained within usual quantum metrological considerations, but can not be always applied, especially for asymmetric error distributions. The extent can however be universally determined by utilizing the concept of percentiles of the probability distribution of the corresponding estimator. As an application, we introduce the concept of finite-precision cooling in a generic quantum system. We use this approach in the working of a three-qubit quantum refrigerator governed by Markovian dynamics, and demonstrate the occurrence of cooling within finite precision for both transient and steady-state regimes, across strong- and weak-coupling limits of the inter-qubit interaction.
title Comparing physical quantities with finite-precision: beyond standard metrology and an illustration for cooling in quantum processes
topic Quantum Physics
url https://arxiv.org/abs/2510.24484