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Main Authors: Ciancaglini, Nicolás, Cifuentes, Santiago, Bellomo, Guido, Figueira, Santiago, Bendersky, Ariel
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.00341
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author Ciancaglini, Nicolás
Cifuentes, Santiago
Bellomo, Guido
Figueira, Santiago
Bendersky, Ariel
author_facet Ciancaglini, Nicolás
Cifuentes, Santiago
Bellomo, Guido
Figueira, Santiago
Bendersky, Ariel
contents We introduce a hierarchical algorithm for identifying the largest Pauli coefficients of an unknown $n$-qubit quantum state. The algorithm traverses a prefix-based tree whose nodes represent partial sums of squared Pauli coefficients, always expanding branches with the largest estimated weight and discarding the rest. Node weights are estimated using Bell sampling on two copies of the state, or alternatively via SWAP tests on subsystems. We analyze the sample complexity of each node estimation and derive bounds on the total number of nodes expanded as a function of the desired number of coefficients and the state's purity. For states admitting a sparse representation in the Pauli basis, the algorithm achieves a good reconstruction of the dominant components without requiring full state tomography. We validate the method with numerical simulations on Pauli-singleton states and random stabilizer states, showing that the algorithm's performance is competitive with other methods for structured states. Our work addresses an open problem in Pauli sampling and provides a practical tool for the targeted characterization of structured quantum states.
format Preprint
id arxiv_https___arxiv_org_abs_2605_00341
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Measuring the largest coefficients of a quantum state
Ciancaglini, Nicolás
Cifuentes, Santiago
Bellomo, Guido
Figueira, Santiago
Bendersky, Ariel
Quantum Physics
We introduce a hierarchical algorithm for identifying the largest Pauli coefficients of an unknown $n$-qubit quantum state. The algorithm traverses a prefix-based tree whose nodes represent partial sums of squared Pauli coefficients, always expanding branches with the largest estimated weight and discarding the rest. Node weights are estimated using Bell sampling on two copies of the state, or alternatively via SWAP tests on subsystems. We analyze the sample complexity of each node estimation and derive bounds on the total number of nodes expanded as a function of the desired number of coefficients and the state's purity. For states admitting a sparse representation in the Pauli basis, the algorithm achieves a good reconstruction of the dominant components without requiring full state tomography. We validate the method with numerical simulations on Pauli-singleton states and random stabilizer states, showing that the algorithm's performance is competitive with other methods for structured states. Our work addresses an open problem in Pauli sampling and provides a practical tool for the targeted characterization of structured quantum states.
title Measuring the largest coefficients of a quantum state
topic Quantum Physics
url https://arxiv.org/abs/2605.00341