Investigation into the bistatic evolution of the acoustic scattering from a cylindrical shell using time-frequency analysis

The time and frequency analyses of the acoustic scattering by an elastic cylindrical shell in bistatic method show that the arrival times of the echoes and the resonance frequencies of the elastic waves propagating in and around the cylindrical shell are a function of the bistatic angle, β, between...

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Veröffentlicht in:	Journal of sound and vibration 2018-01, Vol.412, p.148-165
Hauptverfasser:	Agounad, Said, Aassif, El Houcein, Khandouch, Younes, Maze, Gérard, Décultot, Dominique
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Sprache:	eng
Schlagworte:	Acoustic scattering Beamforming Bi-static method Circumferential waves Configurations Cylindrical shells Echoes Elastic scattering Elastic waves Emitters Evolution Frequency domains Graphical representations Group velocity Material characterization Noise Physical properties Physics Seismology Sound Time-frequency analysis Transducers Wave dispersion Wave propagation Waveform analysis
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creator	Agounad, Said Aassif, El Houcein Khandouch, Younes Maze, Gérard Décultot, Dominique
description	The time and frequency analyses of the acoustic scattering by an elastic cylindrical shell in bistatic method show that the arrival times of the echoes and the resonance frequencies of the elastic waves propagating in and around the cylindrical shell are a function of the bistatic angle, β, between the emitter and receiver transducers. The aim of this work is to explain the observed results in time and frequency domains using time-frequency analysis and graphical interpretations. The performance of four widely used time-frequency representations, the Smoothed Pseudo Wigner-Ville (SPWV), the Spectrogram (SP), the reassignment SPWV, and the reassignment SP, are studied. The investigation into the evolution of the time-frequency plane as a function of the bistatic angle β shows that there are the waves propagating in counter-clockwise direction (labeled wave+) and the waves which propagate in clockwise direction (labeled waves−). In this paper the A, S0, and A1 circumferential waves are investigated. The graphical interpretations are used to explain the formation mechanism of these waves and the acoustic scattering in monostatic and bistatic configurations. The delay between the echoes of the waves+ and those of the waves− is expressed in the case of the circumnavigating wave (Scholte-Stoneley wave). This study shows that the observed waves at β=0° and β=180° are the result of the constructive interferences between the waves+ and the waves−. A comparative study of the physical properties (group velocity dispersion and cut-off frequency) of the waves+, the waves− and the waves observed in monostatic configuration is conducted. Furthermore, it is shown that the ability of the time-frequency representation to highlight the waves+ and the waves− is very useful, for example, for the detection and the localization of defaults, the classification purposes, etc. •Reveal the elastic waves propagating in clockwise and counter-clockwise directions.•Study the formation mechanism of surface waves around a cylindrical shell.•Compare the acoustic scattering in monostatic versus that in bistatic.•Highlight the performance of time-frequency methods to study the acoustic scattering.•Compare the properties of the surface waves in monostatic versus those in bistatic.
doi_str_mv	10.1016/j.jsv.2017.09.036
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The aim of this work is to explain the observed results in time and frequency domains using time-frequency analysis and graphical interpretations. The performance of four widely used time-frequency representations, the Smoothed Pseudo Wigner-Ville (SPWV), the Spectrogram (SP), the reassignment SPWV, and the reassignment SP, are studied. The investigation into the evolution of the time-frequency plane as a function of the bistatic angle β shows that there are the waves propagating in counter-clockwise direction (labeled wave+) and the waves which propagate in clockwise direction (labeled waves−). In this paper the A, S0, and A1 circumferential waves are investigated. The graphical interpretations are used to explain the formation mechanism of these waves and the acoustic scattering in monostatic and bistatic configurations. The delay between the echoes of the waves+ and those of the waves− is expressed in the case of the circumnavigating wave (Scholte-Stoneley wave). This study shows that the observed waves at β=0° and β=180° are the result of the constructive interferences between the waves+ and the waves−. A comparative study of the physical properties (group velocity dispersion and cut-off frequency) of the waves+, the waves− and the waves observed in monostatic configuration is conducted. Furthermore, it is shown that the ability of the time-frequency representation to highlight the waves+ and the waves− is very useful, for example, for the detection and the localization of defaults, the classification purposes, etc. •Reveal the elastic waves propagating in clockwise and counter-clockwise directions.•Study the formation mechanism of surface waves around a cylindrical shell.•Compare the acoustic scattering in monostatic versus that in bistatic.•Highlight the performance of time-frequency methods to study the acoustic scattering.•Compare the properties of the surface waves in monostatic versus those in bistatic.</description><identifier>ISSN: 0022-460X</identifier><identifier>EISSN: 1095-8568</identifier><identifier>DOI: 10.1016/j.jsv.2017.09.036</identifier><language>eng</language><publisher>Amsterdam: Elsevier Ltd</publisher><subject>Acoustic scattering ; Beamforming ; Bi-static method ; Circumferential waves ; Configurations ; Cylindrical shells ; Echoes ; Elastic scattering ; Elastic waves ; Emitters ; Evolution ; Frequency domains ; Graphical representations ; Group velocity ; Material characterization ; Noise ; Physical properties ; Physics ; Seismology ; Sound ; Time-frequency analysis ; Transducers ; Wave dispersion ; Wave propagation ; Waveform analysis</subject><ispartof>Journal of sound and vibration, 2018-01, Vol.412, p.148-165</ispartof><rights>2017 Elsevier Ltd</rights><rights>Copyright Elsevier Science Ltd. 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The aim of this work is to explain the observed results in time and frequency domains using time-frequency analysis and graphical interpretations. The performance of four widely used time-frequency representations, the Smoothed Pseudo Wigner-Ville (SPWV), the Spectrogram (SP), the reassignment SPWV, and the reassignment SP, are studied. The investigation into the evolution of the time-frequency plane as a function of the bistatic angle β shows that there are the waves propagating in counter-clockwise direction (labeled wave+) and the waves which propagate in clockwise direction (labeled waves−). In this paper the A, S0, and A1 circumferential waves are investigated. The graphical interpretations are used to explain the formation mechanism of these waves and the acoustic scattering in monostatic and bistatic configurations. The delay between the echoes of the waves+ and those of the waves− is expressed in the case of the circumnavigating wave (Scholte-Stoneley wave). This study shows that the observed waves at β=0° and β=180° are the result of the constructive interferences between the waves+ and the waves−. A comparative study of the physical properties (group velocity dispersion and cut-off frequency) of the waves+, the waves− and the waves observed in monostatic configuration is conducted. Furthermore, it is shown that the ability of the time-frequency representation to highlight the waves+ and the waves− is very useful, for example, for the detection and the localization of defaults, the classification purposes, etc. •Reveal the elastic waves propagating in clockwise and counter-clockwise directions.•Study the formation mechanism of surface waves around a cylindrical shell.•Compare the acoustic scattering in monostatic versus that in bistatic.•Highlight the performance of time-frequency methods to study the acoustic scattering.•Compare the properties of the surface waves in monostatic versus those in bistatic.</description><subject>Acoustic scattering</subject><subject>Beamforming</subject><subject>Bi-static method</subject><subject>Circumferential waves</subject><subject>Configurations</subject><subject>Cylindrical shells</subject><subject>Echoes</subject><subject>Elastic scattering</subject><subject>Elastic waves</subject><subject>Emitters</subject><subject>Evolution</subject><subject>Frequency domains</subject><subject>Graphical representations</subject><subject>Group velocity</subject><subject>Material characterization</subject><subject>Noise</subject><subject>Physical properties</subject><subject>Physics</subject><subject>Seismology</subject><subject>Sound</subject><subject>Time-frequency analysis</subject><subject>Transducers</subject><subject>Wave dispersion</subject><subject>Wave propagation</subject><subject>Waveform analysis</subject><issn>0022-460X</issn><issn>1095-8568</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp9kUFr3DAQhUVoodu0P6A3QU492B3JXq9MTyE0TWAhlwZ6E7I8ysp4rVQjG5b--cjZ0mNOgvnee8zoMfZFQClANN-GcqCllCB2JbQlVM0F2whot4XaNuod2wBIWdQN_P7APhINANDWVb1hf--nBSn5J5N8mLifUuDpgLzzlPLIclzCOL-y4F6JsWGmlZA1KWH00xN3MRy54fY0-qmP3pqR0wHHkc-04uSPWLiIf2ac7ImbyYwn8vSJvXdmJPz8771kj7c_ft3cFfuHn_c31_vCVq1KRYfCbbdyJ1sp677vlDW2NT00SiFipzonlW0616uqQyVF08jMhAODlRTKVpfs6zn3YEb9HP3RxJMOxuu7671eZyBauRoXkbVXZ-1zDHldSnoIc8wLk86pAqpdDVVWibPKxkAU0f2PFaDXPvSgcx967UNDq3Mf2fP97MF86uIxarI-_wf2PqJNug_-DfcLmbaVtQ</recordid><startdate>20180106</startdate><enddate>20180106</enddate><creator>Agounad, Said</creator><creator>Aassif, El Houcein</creator><creator>Khandouch, Younes</creator><creator>Maze, Gérard</creator><creator>Décultot, Dominique</creator><general>Elsevier Ltd</general><general>Elsevier Science Ltd</general><general>Elsevier</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>FR3</scope><scope>KR7</scope><scope>1XC</scope></search><sort><creationdate>20180106</creationdate><title>Investigation into the bistatic evolution of the acoustic scattering from a cylindrical shell using time-frequency analysis</title><author>Agounad, Said ; 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Furthermore, it is shown that the ability of the time-frequency representation to highlight the waves+ and the waves− is very useful, for example, for the detection and the localization of defaults, the classification purposes, etc. •Reveal the elastic waves propagating in clockwise and counter-clockwise directions.•Study the formation mechanism of surface waves around a cylindrical shell.•Compare the acoustic scattering in monostatic versus that in bistatic.•Highlight the performance of time-frequency methods to study the acoustic scattering.•Compare the properties of the surface waves in monostatic versus those in bistatic.</abstract><cop>Amsterdam</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.jsv.2017.09.036</doi><tpages>18</tpages></addata></record>
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subjects	Acoustic scattering Beamforming Bi-static method Circumferential waves Configurations Cylindrical shells Echoes Elastic scattering Elastic waves Emitters Evolution Frequency domains Graphical representations Group velocity Material characterization Noise Physical properties Physics Seismology Sound Time-frequency analysis Transducers Wave dispersion Wave propagation Waveform analysis
title	Investigation into the bistatic evolution of the acoustic scattering from a cylindrical shell using time-frequency analysis
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