Title :
Recursive multiscale estimation of space-time random fields
Author :
Ho, T.T. ; Fieguth, Paul W. ; Willski, A.S.
Author_Institution :
Lab. for Inf. & Decision Syst., MIT, Cambridge, MA, USA
Abstract :
We recently developed a multiscale recursive estimation procedure for the estimation of large-scale dynamic systems. The procedure propagates multiscale models for the estimation errors more efficiently than the Kalman filter´s propagation of the error covariances, with a resulting computational complexity of 𝒪(N) and 𝒪(N3/2), where N is the number of variables estimated, for 1-D and 2-D dynamic systems, respectively. To further reduce the computational cost, we introduce in this paper a new class of reduced-order spatially-interpolated multiscale models, and demonstrate their use in remote.
Keywords :
computational complexity; image processing; recursive estimation; space-time adaptive processing; computational complexity; estimation errors; large-scale dynamic systems; multiscale models; recursive multiscale estimation; reduced-order spatially-interpolated multiscale models; space-time random fields; Computational efficiency; Decorrelation; Design engineering; Estimation error; Kalman filters; Laboratories; Large-scale systems; Recursive estimation; Space technology; Systems engineering and theory;
Conference_Titel :
Image Processing, 1999. ICIP 99. Proceedings. 1999 International Conference on
Conference_Location :
Kobe
Print_ISBN :
0-7803-5467-2
DOI :
10.1109/ICIP.1999.823021
