Abstract
A method is presented for the signature analysis of pulses by reconstructing in the time domain the shape of the pulse prior to its passing through the measurement system. This deconvolution technique is first evaluated using an idealized system and analytical pulse models and is shown to provide improved results. An experimental situation is then treated; system-component models are developed for the digitizer, tape recorder, filter, transducer and mechanical structure. To accommodate both calibration results and manufacturer's data, and to provide stable mathematical models entails considerable effort: some 30 parameters must be identified to model this system—which is still a substantial approximation—albeit of very high order. Experimental pulses generated by a ball drop, spark discharge and a tearing crack are then deconvoluted ‘back through’ the system as modeled, using this technique. These results are compared and indicate (a) that consistent shapes may be expected from a given type of source and (b) that some sources can be identified with greater clarity using the deconvolution approach.
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References
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P.F. Packman was Professor, Mechanical Engineering and Materials Science Department, Vanderbilt University
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Houghton, J.R., Townsend, M.A. & Packman, P.F. The application of a time-domain deconvolution technique for identification of experimental acoustic-emission signals. Experimental Mechanics 18, 233–239 (1978). https://doi.org/10.1007/BF02328419
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DOI: https://doi.org/10.1007/BF02328419