Saved in:
Bibliographic Details
Main Authors: Mayer, Philipp Nikolas, Yun, Ho
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.25146
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916043396481024
author Mayer, Philipp Nikolas
Yun, Ho
author_facet Mayer, Philipp Nikolas
Yun, Ho
contents This paper introduces the Quantum Covariance Embedding, which embeds Positive Operator-Valued Measures into a tensor product of a Reproducing Kernel Hilbert Space and the quantum state space via a tensorized Bochner integral. This construction induces the Quantum Maximum Discrepancy that metrizes the space of quantum measurements. Applying this framework to Quantum State Tomography, we reformulate density estimation as a tensorized kernel regression, enabling optimal inference without the basis-dependent sparsity constraints that restrict existing methods. We develop a unified geometric design theory for quantum Gram superoperators, establishing that Unitary Designs are strictly E-optimal experimental designs and thus statistically superior to Pauli observables. For general structure-free estimation, we derive the exact minimax lower bound and prove that our tensorized estimators achieve this optimal rate. Furthermore, we introduce the QUAntum Regression with Kernels (QUARK) estimator to accommodate the spectral geometry of physical implementations, deriving central limit theorem and concentration inequalities. To facilitate practical estimation, we establish the exactness of trace-preserving projections and demonstrate efficient estimation under mutually unbiased bases via the fast Walsh-Hadamard transform.
format Preprint
id arxiv_https___arxiv_org_abs_2605_25146
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Kernel Embedding for Operator-Valued Measures and Its Application to Quantum Tomography
Mayer, Philipp Nikolas
Yun, Ho
Statistics Theory
Quantum Physics
81P50, 46E22 (Primary) 47N50, 62G05 (Secondary)
This paper introduces the Quantum Covariance Embedding, which embeds Positive Operator-Valued Measures into a tensor product of a Reproducing Kernel Hilbert Space and the quantum state space via a tensorized Bochner integral. This construction induces the Quantum Maximum Discrepancy that metrizes the space of quantum measurements. Applying this framework to Quantum State Tomography, we reformulate density estimation as a tensorized kernel regression, enabling optimal inference without the basis-dependent sparsity constraints that restrict existing methods. We develop a unified geometric design theory for quantum Gram superoperators, establishing that Unitary Designs are strictly E-optimal experimental designs and thus statistically superior to Pauli observables. For general structure-free estimation, we derive the exact minimax lower bound and prove that our tensorized estimators achieve this optimal rate. Furthermore, we introduce the QUAntum Regression with Kernels (QUARK) estimator to accommodate the spectral geometry of physical implementations, deriving central limit theorem and concentration inequalities. To facilitate practical estimation, we establish the exactness of trace-preserving projections and demonstrate efficient estimation under mutually unbiased bases via the fast Walsh-Hadamard transform.
title Kernel Embedding for Operator-Valued Measures and Its Application to Quantum Tomography
topic Statistics Theory
Quantum Physics
81P50, 46E22 (Primary) 47N50, 62G05 (Secondary)
url https://arxiv.org/abs/2605.25146