2018
DOI: 10.1016/j.wavemoti.2018.02.007
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Signal-to-Noise Ratio analysis for time-reversal based imaging techniques in bounded domains

Abstract: We consider the problem of localizing small material defects in rectangular bounded domains. The scalar acoustic equation is used to model wave propagation in this context. Our data is the scattered field collected at one or more receivers and due to impulsive excitations at one or more source positions. To localize the defect we use an imaging method that consists in back-propagating the recorded field in the domain of interest. The back-propagation is performed numerically using a model for the Green's funct… Show more

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Cited by 6 publications
(3 citation statements)
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References 38 publications
(62 reference statements)
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“…The plots indicate an almost linear relation with respect to the receivers' number with deviations that occurred because of ghost superposition or cancellation. For the case of axial motion, the case of the left plot in Figure 7a, the factor of the linear evolution with the number of receivers is that of two as it was expected [36], while in the case of transverse and rotational motion depicted in the plot of Figure 7b, the corresponding coefficient is smaller.…”
Section: One-dimensional Beamsupporting
confidence: 54%
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“…The plots indicate an almost linear relation with respect to the receivers' number with deviations that occurred because of ghost superposition or cancellation. For the case of axial motion, the case of the left plot in Figure 7a, the factor of the linear evolution with the number of receivers is that of two as it was expected [36], while in the case of transverse and rotational motion depicted in the plot of Figure 7b, the corresponding coefficient is smaller.…”
Section: One-dimensional Beamsupporting
confidence: 54%
“…Following previous work [33,36], our choice here is to assumef of zero values components or units when it corresponds to some u r component. Evolutionf (t) = u(t * ) is the reversed in time component of vector u, actually being the solution of the forward problem of Equation (18).…”
Section: The Time Reversal or Backward Stepmentioning
confidence: 99%
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