Bayesian selector of adaptive bandwidth for multivariate gamma kernel estimator on [0,∞ ) d

This paper utilized the Improved Particle Swarm Optimization (IPSO) technique for adjusting the gains of PID and the bandwidth of zero-phase Butterworth Filter of an Iterative Learning Controller (ILC) for precision motion. Simulation results show that IPSO-ILC-PID controller without adaptive bandwidth filter tuning have the chance of producing high frequencies in the error signals when the filter bandwidth is fixed for every repetition. However the learnable and unlearnable error signals should be separated for bettering control process. Thus the adaptive bandwidth of a zero phase filter in ILC-PID controller with IPSO tuning is applied to one single motion axis of a CNC table machine. Simulation results show that the developed controller can cancel the errors efficiently as repetition goes. The frequency response of the error signals is analyzed by the empirical mode decomposition (EMD) and the Hilbert-Huang Transform (HHT) method. Errors are reduced and validated by ILC with adaptive bandwidth filtering design.

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An Upper Bound of the Bias of Nadaraya-Watson Kernel Regression under Lipschitz Assumptions

Stats ◽

10.3390/stats4010001 ◽

2020 ◽

Vol 4 (1) ◽

pp. 1-17

Author(s):

Samuele Tosatto ◽

Riad Akrour ◽

Jan Peters

Keyword(s):

Upper Bound ◽

Prediction Error ◽

Kernel Estimator ◽

Asymptotic Bias ◽

Surgical Robots ◽

Related Literature ◽

Asymptotic Nature ◽

Potential Applications ◽

Self Driving Cars ◽

Automated Decision Making

The Nadaraya-Watson kernel estimator is among the most popular nonparameteric regression technique thanks to its simplicity. Its asymptotic bias has been studied by Rosenblatt in 1969 and has been reported in several related literature. However, given its asymptotic nature, it gives no access to a hard bound. The increasing popularity of predictive tools for automated decision-making surges the need for hard (non-probabilistic) guarantees. To alleviate this issue, we propose an upper bound of the bias which holds for finite bandwidths using Lipschitz assumptions and mitigating some of the prerequisites of Rosenblatt’s analysis. Our bound has potential applications in fields like surgical robots or self-driving cars, where some hard guarantees on the prediction-error are needed.

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Bayesian selector of adaptive bandwidth for multivariate gamma kernel estimator on [0,∞ ) d

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An Upper Bound of the Bias of Nadaraya-Watson Kernel Regression under Lipschitz Assumptions

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