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Autores principales: Khanpour, Cameron, Turizo, Daniel, Talkington, Samuel
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2604.01211
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author Khanpour, Cameron
Turizo, Daniel
Talkington, Samuel
author_facet Khanpour, Cameron
Turizo, Daniel
Talkington, Samuel
contents We study the problem of controlling how a limited communication bandwidth budget is allocated across heterogeneously quantized sensor measurements. The performance criterion is the trace of the error covariance matrix of the linear minimum mean square error (LMMSE) state estimator, i.e., an $A$-optimal design criterion. Minimizing this criterion with a bit budget constraint yields a nonconvex optimization problem. We derive a formula that reduces each evaluation of the gradient to a single Cholesky factorization. This enables efficient optimization by both a projection-free Frank-Wolfe method (with a computable convergence certificate) and an interior point method with L-BFGS Hessian approximation over the problem's continuous relaxation. A largest remainder rounding procedure recovers integer bit allocations with a bound on the quality of the rounded solution. Numerical experiments in IEEE power grid test cases with up to 300 buses compare both solvers and demonstrate that the analytic gradient is the key computational enabler for both methods. Additionally, the heterogeneous bit allocation is compared to standard uniform bit allocation on the 500 bus IEEE power grid test case.
format Preprint
id arxiv_https___arxiv_org_abs_2604_01211
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Making Every Bit Count for $A$-Optimal State Estimation
Khanpour, Cameron
Turizo, Daniel
Talkington, Samuel
Systems and Control
We study the problem of controlling how a limited communication bandwidth budget is allocated across heterogeneously quantized sensor measurements. The performance criterion is the trace of the error covariance matrix of the linear minimum mean square error (LMMSE) state estimator, i.e., an $A$-optimal design criterion. Minimizing this criterion with a bit budget constraint yields a nonconvex optimization problem. We derive a formula that reduces each evaluation of the gradient to a single Cholesky factorization. This enables efficient optimization by both a projection-free Frank-Wolfe method (with a computable convergence certificate) and an interior point method with L-BFGS Hessian approximation over the problem's continuous relaxation. A largest remainder rounding procedure recovers integer bit allocations with a bound on the quality of the rounded solution. Numerical experiments in IEEE power grid test cases with up to 300 buses compare both solvers and demonstrate that the analytic gradient is the key computational enabler for both methods. Additionally, the heterogeneous bit allocation is compared to standard uniform bit allocation on the 500 bus IEEE power grid test case.
title Making Every Bit Count for $A$-Optimal State Estimation
topic Systems and Control
url https://arxiv.org/abs/2604.01211