Strictly Decentralized Adaptive Estimation of External Fields using Reproducing Kernels
Abstract
This paper describes an adaptive method in continuous time for the estimation of external fields by a team of agents. The agents each explore subdomains of a bounded subset of interest . Ideal adaptive estimates are derived for each agent from a distributed parameter system (DPS) that takes values in the scalar-valued reproducing kernel Hilbert space of functions over . Approximations of the evolution of the ideal local estimate of agent is constructed solely using observations made by agent on a fine time scale. Since the local estimates on the fine time scale are constructed independently for each agent, we say that the method is strictly decentralized. On a coarse time scale, the individual local estimates are fused via the expression that uses a partition of unity subordinate to the cover of . Realizable algorithms are obtained by constructing finite dimensional approximations of the DPS in terms of scattered bases defined by each agent from samples along their trajectories. Rates of convergence of the error in the finite dimensional approximations are derived in terms of the fill distance of the samples that define the scattered centers in each subdomain. The qualitative performance of the convergence rates for the decentralized estimation method is illustrated via numerical simulations.
Keywords
Cite
@article{arxiv.2103.12721,
title = {Strictly Decentralized Adaptive Estimation of External Fields using Reproducing Kernels},
author = {Jia Guo and Michael E. Kepler and Sai Tej Paruchuri and Haoran Wang and Andrew J. Kurdila and Daniel J. Stilwell},
journal= {arXiv preprint arXiv:2103.12721},
year = {2021}
}
Comments
10 pages, 3 figures