Abstract :
In this paper a recently introduced signal processing technique is exploited for the interpolation and regularization of multidimensional sampled signals with missing data, based on Principal Component Analysis (PCA). The non-iterative methodology proposed corresponds to the optimal solution to a regulated weighted least mean square minimization problem, based on estimates for the mean and covariance of signals corrupted by zero-mean noise. Additionally, is deduced an estimate for the mean square interpolation error, with upper and lower bounds also available. Some refinements are used to improve the solution proposed, namely: (i) mean substitution for covariance estimation, (ii) Tikhonov regularization and, (iii) dynamic principal components selection. The resulting method will be applied to bathymetric data, acquired at sea with the advanced robotic tools IRIS and the Infante AUV, in the passage between the islands of Faial and Pico, Azores. The results obtained pave the way to the use of the proposed framework in a number of sensor fusion problems, in the presence of missing data.
Keywords :
bathymetry; geophysical signal processing; interpolation; least mean squares methods; oceanographic techniques; principal component analysis; remotely operated vehicles; sensor fusion; underwater equipment; Azores; Faial; IRIS robotic tools; Infante AUV; Pico; Tikhonov regularization; bathymetric data fusion; covariance estimation; dynamic principal components selection; geophysical signal processing; interpolation; missing data; multidimensional sampled signals; principal component analysis; regulated weighted least mean square minimization; sea tests; sensor fusion; zero-mean noise; Contracts; Interpolation; Multidimensional signal processing; Multidimensional systems; Principal component analysis; Remotely operated vehicles; Robot sensing systems; Sensor fusion; Signal processing; Testing;
