Title :
Trellis-based deconvolution of ultrasonic echoes
Author :
Gut, Richard ; Kreier, P. ; Moschytz, George S.
Author_Institution :
Signal & Inf. Process. Lab., Swiss Federal Inst. of Technol., Zurich, Switzerland
fDate :
30 Apr-3 May 1995
Abstract :
A novel deconvolution algorithm is proposed for ultrasonic (US) echoes from layered materials. The basic idea is to model the reflectivity functions as well-defined sparse sequences and to perform a maximum-likelihood (ML) sequence estimation over the set of these sequences. A tree-based sequence estimation exhibits an exponentially growing complexity, but can in this case be converted into a trellis-based estimation with a linearly growing complexity. Deconvolution results of measured US-signals are given to confirm the theory. They demonstrate that the a priori knowledge introduced by the reduction of the solution space improves the deconvolution considerably
Keywords :
computational complexity; deconvolution; estimation theory; maximum likelihood estimation; ultrasonic materials testing; ultrasonic reflection; MLSE; US signals; deconvolution algorithm; layered materials; linearly growing complexity; maximum-likelihood sequence estimation; reflectivity functions; sparse sequences; tree-based sequence estimation; trellis-based deconvolution; ultrasonic echoes; AWGN; Acoustic pulses; Acoustic reflection; Additive noise; Convolution; Deconvolution; Equations; Linear systems; Maximum likelihood estimation; Thumb;
Conference_Titel :
Circuits and Systems, 1995. ISCAS '95., 1995 IEEE International Symposium on
Conference_Location :
Seattle, WA
Print_ISBN :
0-7803-2570-2
DOI :
10.1109/ISCAS.1995.520405
