Imaging Extended Reflectors in a Terminating Waveguide

Abstract: We consider the problem of imaging extended reflectors in terminating waveguides. We form the image by back-propagating the array response matrix projected on the waveguide's non evanescent modes. The projection is adequately defined for any array aperture size covering fully or partially the waveguide's vertical cross-section. We perform a resolution analysis of the imaging method and show that the resolution is determined by the central frequency while the image's signalto-noise ratio improves as the bandwid… Show more

“…The interpretation of these results is quite clear. For h " 1, the identification results are better ifh " 0.5 than ifh " 0.75 (figure 10), because the amount of reflected waves at the interface between the two half-waveguides is larger (at the limit whenh tends to 0, our waveguide tends to a terminating waveguide like in [22], which can be seen as an ideal situation). On the contrary, forh " 1, the Figure 7.…”

“…Note that in [3], our method was successfully tested in the presence of real data coming from an ultrasonic NDT experiment on a steel plate. We here mention several other works based on sampling-type methods in acoustic waveguides [15,20,21,22,5,6] and electromagnetic waveguides [7,19].…”

“…Let us now assume that there is a Dirichlet obstacle O to retrieve in the junction B. For all y P W , we introduce the total field up¨, yq which satisfies (22) and the scattered field u s p¨, yq which satisfies (23) with f "´Gp¨, yq| BO . For j " 0, .…”

“…We assume there exists an obstacle O within the waveguide W , more precisely O is a smooth and bounded open (not necessarily connected) domain such that O Ă W , with Ω " W zO a connected open domain. For some y P Ω, let us consider the problem: find up¨, yq P L2 loc pΩq such that WW Obstacles within the waveguide(22)…”

Imaging junctions of waveguides

“…The interpretation of these results is quite clear. For h " 1, the identification results are better ifh " 0.5 than ifh " 0.75 (figure 10), because the amount of reflected waves at the interface between the two half-waveguides is larger (at the limit whenh tends to 0, our waveguide tends to a terminating waveguide like in [22], which can be seen as an ideal situation). On the contrary, forh " 1, the Figure 7.…”

“…Note that in [3], our method was successfully tested in the presence of real data coming from an ultrasonic NDT experiment on a steel plate. We here mention several other works based on sampling-type methods in acoustic waveguides [15,20,21,22,5,6] and electromagnetic waveguides [7,19].…”

“…Let us now assume that there is a Dirichlet obstacle O to retrieve in the junction B. For all y P W , we introduce the total field up¨, yq which satisfies (22) and the scattered field u s p¨, yq which satisfies (23) with f "´Gp¨, yq| BO . For j " 0, .…”

“…We assume there exists an obstacle O within the waveguide W , more precisely O is a smooth and bounded open (not necessarily connected) domain such that O Ă W , with Ω " W zO a connected open domain. For some y P Ω, let us consider the problem: find up¨, yq P L2 loc pΩq such that WW Obstacles within the waveguide(22)…”

Imaging junctions of waveguides

“…The wave equation in such empty waveguides can be solved with separation of variables and the wave field is a superposition of propagating, evanescent and possibly radiating modes that do not interact with each other. A sample of the existing mathematical literature is [17,12,23,24,10,31,32] and examples of imaging with experimental validation are in [25,26].…”

A direct approach to imaging in a waveguide with perturbed geometry

Factorization method versus migration imaging in a waveguide