Yunfei Xu scite author profile

This paper presents a novel class of self-organizing sensing agents that adaptively learn an anisotropic, spatio-temporal Gaussian process using noisy measurements and move in order to improve the quality of the estimated covariance function. This approach is based on a class of anisotropic covariance functions of Gaussian processes introduced to model a broad range of spatio-temporal physical phenomena. The covariance function is assumed to be unknown a priori. Hence, it is estimated by the maximum a posteriori probability (MAP) estimator. The prediction of the field of interest is then obtained based on the MAP estimate of the covariance function. An optimal sampling strategy is proposed to minimize the information-theoretic cost function of the Fisher Information Matrix. Simulation results demonstrate the effectiveness and the adaptability of the proposed scheme.

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Recent advances in emerging techniques for non-destructive detection of seed viability: A review

Xia

et al. 2019

Artificial Intelligence in Agriculture

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Gaussian Process Regression for Sensor Networks Under Localization Uncertainty

Jadaliha

Choi

et al. 2013

IEEE Trans. Signal Process.

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In this paper, we formulate Gaussian process regression with observations under the localization uncertainty due to the resource-constrained sensor networks. In our formulation, effects of observations, measurement noise, localization uncertainty, and prior distributions are all correctly incorporated in the posterior predictive statistics. The analytically intractable posterior predictive statistics are proposed to be approximated by two techniques, viz., Monte Carlo sampling and Laplace's method. Such approximation techniques have been carefully tailored to our problems and their approximation error and complexity are analyzed. Simulation study demonstrates that the proposed approaches perform much better than approaches without considering the localization uncertainty properly. Finally, we have applied the proposed approaches on the experimentally collected real data from a dye concentration field over a section of a river and a temperature field of an outdoor swimming pool to provide proof of concept tests and evaluate the proposed schemes in real situations. In both simulation and experimental results, the proposed methods outperform the quick-and-dirty solutions often used in practice.

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Yunfei Xu

Mobile Sensor Network Navigation Using Gaussian Processes With Truncated Observations

Efficient Bayesian spatial prediction with mobile sensor networks using Gaussian Markov random fields

Adaptive Sampling for Learning Gaussian Processes Using Mobile Sensor Networks

Recent advances in emerging techniques for non-destructive detection of seed viability: A review

Gaussian Process Regression for Sensor Networks Under Localization Uncertainty

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