The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach

The long range detection of ice hazards such as multi-year ice, pressure ridges and icebergs will allow for more efficient planning of Arctic navigation routes and exploration in ice infested waters. An analysis of the electromagnetic scattering from a vertical discontinuity representing the transit...

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Bibliographic Details
Main Author: Ryan, Joseph P. (Joseph Patrick)
Format: Thesis
Language:English
Published: Memorial University of Newfoundland 1983
Subjects:
Arctic
Laplace
Ice Sheet
Iceberg*
Online Access:https://research.library.mun.ca/5300/
https://research.library.mun.ca/5300/1/Ryan_JosephPatrick.pdf
https://research.library.mun.ca/5300/2/Ryan_JosephPatrick.pdf
id ftmemorialuniv:oai:research.library.mun.ca:5300
record_format openpolar
spelling ftmemorialuniv:oai:research.library.mun.ca:5300 2023-10-01T03:54:18+02:00 The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach Ryan, Joseph P. (Joseph Patrick) 1983 application/pdf https://research.library.mun.ca/5300/ https://research.library.mun.ca/5300/1/Ryan_JosephPatrick.pdf https://research.library.mun.ca/5300/2/Ryan_JosephPatrick.pdf en eng Memorial University of Newfoundland https://research.library.mun.ca/5300/1/Ryan_JosephPatrick.pdf https://research.library.mun.ca/5300/2/Ryan_JosephPatrick.pdf Ryan, Joseph P. (Joseph Patrick) <https://research.library.mun.ca/view/creator_az/Ryan=3AJoseph_P=2E_=28Joseph_Patrick=29=3A=3A.html> (1983) The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach. Masters thesis, Memorial University of Newfoundland. thesis_license Thesis NonPeerReviewed 1983 ftmemorialuniv 2023-09-03T06:45:14Z The long range detection of ice hazards such as multi-year ice, pressure ridges and icebergs will allow for more efficient planning of Arctic navigation routes and exploration in ice infested waters. An analysis of the electromagnetic scattering from a vertical discontinuity representing the transition from sea water or first-year ice to a multi- year ice sheet has been carried out. The analysis is based on a method of Space/Field decomposition where two Heaviside functions are used to decompose a three dimensional space into three regions each having different electrical properties. Maxwell's equations are used to derive a partial differential field equation for the complete space. Making use of a field decomposition, this differential equation may be decomposed into three field equations, one for each region, and a boundary equation. A spherical Green's function is taken as the fundamental solution and the spatial Fourier transform is used to simplify the equations to a single integral equation. Selecting a vertical electric dipole as the source field the solution for the vertical component of the surface field is obtained by writing this resultant integral equation in an operator form and expanding the inverse operator in a Neumann series. Using the Laplace transform and stationary phase integration this series solution may be summed to provide expressions for both the backscattered field and the field propagated past the boundary separating the two media. The solution for the propagated field agrees with that of both Bremmer and Wait. The technique differs from that of previous investigators in that it is possible to obtain an expression for the backscattered field and thereby the radar cross-section of the vertical discontinuity. The results of this analysis indicate that radar operating in the High Frequency range (3 - 30 MHz) should provide a significant improvement over present methods for the detection of this type of hazard. Thesis Arctic Ice Sheet Iceberg* Memorial University of Newfoundland: Research Repository Arctic Laplace ENVELOPE(141.467,141.467,-66.782,-66.782)
institution Open Polar
collection Memorial University of Newfoundland: Research Repository
op_collection_id ftmemorialuniv
language English
description The long range detection of ice hazards such as multi-year ice, pressure ridges and icebergs will allow for more efficient planning of Arctic navigation routes and exploration in ice infested waters. An analysis of the electromagnetic scattering from a vertical discontinuity representing the transition from sea water or first-year ice to a multi- year ice sheet has been carried out. The analysis is based on a method of Space/Field decomposition where two Heaviside functions are used to decompose a three dimensional space into three regions each having different electrical properties. Maxwell's equations are used to derive a partial differential field equation for the complete space. Making use of a field decomposition, this differential equation may be decomposed into three field equations, one for each region, and a boundary equation. A spherical Green's function is taken as the fundamental solution and the spatial Fourier transform is used to simplify the equations to a single integral equation. Selecting a vertical electric dipole as the source field the solution for the vertical component of the surface field is obtained by writing this resultant integral equation in an operator form and expanding the inverse operator in a Neumann series. Using the Laplace transform and stationary phase integration this series solution may be summed to provide expressions for both the backscattered field and the field propagated past the boundary separating the two media. The solution for the propagated field agrees with that of both Bremmer and Wait. The technique differs from that of previous investigators in that it is possible to obtain an expression for the backscattered field and thereby the radar cross-section of the vertical discontinuity. The results of this analysis indicate that radar operating in the High Frequency range (3 - 30 MHz) should provide a significant improvement over present methods for the detection of this type of hazard.
format Thesis
author Ryan, Joseph P. (Joseph Patrick)
spellingShingle Ryan, Joseph P. (Joseph Patrick)
The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
author_facet Ryan, Joseph P. (Joseph Patrick)
author_sort Ryan, Joseph P. (Joseph Patrick)
title The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
title_short The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
title_full The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
title_fullStr The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
title_full_unstemmed The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
title_sort electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach
publisher Memorial University of Newfoundland
publishDate 1983
url https://research.library.mun.ca/5300/
https://research.library.mun.ca/5300/1/Ryan_JosephPatrick.pdf
https://research.library.mun.ca/5300/2/Ryan_JosephPatrick.pdf
long_lat ENVELOPE(141.467,141.467,-66.782,-66.782)
geographic Arctic
Laplace
geographic_facet Arctic
Laplace
genre Arctic
Ice Sheet
Iceberg*
genre_facet Arctic
Ice Sheet
Iceberg*
op_relation https://research.library.mun.ca/5300/1/Ryan_JosephPatrick.pdf
https://research.library.mun.ca/5300/2/Ryan_JosephPatrick.pdf
Ryan, Joseph P. (Joseph Patrick) <https://research.library.mun.ca/view/creator_az/Ryan=3AJoseph_P=2E_=28Joseph_Patrick=29=3A=3A.html> (1983) The electromagnetic scattering from a vertical discontinuity with application to ice hazard detection : an operator expansion approach. Masters thesis, Memorial University of Newfoundland.
op_rights thesis_license
_version_ 1778521788966240256

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