Persistent Link:
http://hdl.handle.net/10150/606184
Title:
Approaches to Mitigate Disruption of Telemetry During Directed Energy Testing
Author:
Keidar, Michael; Kundrapu, Madhusudhan; Kim, Minkwan; Boyd, Iain D.; Jones, Charles H.; Mork, Brian
Affiliation:
The George Washington University; University of Michigan; Edwards Air Force Base
Issue Date:
2008-10
Rights:
Copyright © held by the author; distribution rights International Foundation for Telemetering
Collection Information:
Proceedings from the International Telemetering Conference are made available by the International Foundation for Telemetering and the University of Arizona Libraries. Visit http://www.telemetry.org/index.php/contact-us if you have questions about items in this collection.
Publisher:
International Foundation for Telemetering
Journal:
International Telemetering Conference Proceedings
Abstract:
Testing of directed-energy weapon systems requires continuous radio-wave telemetry in order to characterize in situ the effect of irradiation on a target. The telemetry in these cases might be disrupted due to plasma formation causing communication blackout. In this paper several mitigation approaches, namely electrostatic and electromagnetic, are considered. The electrostatic mitigation approach takes into account that an electron depleted sheath is formed around the negatively biased electrode. This creates a 'hole' in the electron density distribution allowing radio communication through the plasma. The electromagnetic approach is based on formation of the ExB layer in the plasma, consequent plasma acceleration, and resulting decrease in the plasma density. In order to assess these mitigation approaches, one needs to characterize the plasma which is created as a result of laser irradiation on different target materials and under various laser beam power levels. We developed a model of the plasma formation which is based on a kinetic description of the Knudsen layer and a hydrodynamic description of the collision-dominated plasma region which is coupled with analyses of the heat transfer in the target material. The overall model describes the absorption of the laser energy by the target and the resulting temperature rise in the surface. This temperature rise then induces ablation of the target material. Laser energy absorption by the plasma plume created above the surface is also considered. Analysis of the ablation rate of various targets subject to directed energy impact was performed. We considered a typical multilayer structure consisting of black paint, titanium, and aluminum layers. For instance, it was found that the aluminum layer has the highest ablation rate, while the black pain layer has the smallest rate for a given surface temperature.
Sponsors:
International Foundation for Telemetering
ISSN:
0884-5123; 0074-9079
Additional Links:
http://www.telemetry.org/

Full metadata record

DC FieldValue Language
dc.language.isoen_USen
dc.titleApproaches to Mitigate Disruption of Telemetry During Directed Energy Testingen_US
dc.contributor.authorKeidar, Michaelen
dc.contributor.authorKundrapu, Madhusudhanen
dc.contributor.authorKim, Minkwanen
dc.contributor.authorBoyd, Iain D.en
dc.contributor.authorJones, Charles H.en
dc.contributor.authorMork, Brianen
dc.contributor.departmentThe George Washington Universityen
dc.contributor.departmentUniversity of Michiganen
dc.contributor.departmentEdwards Air Force Baseen
dc.date.issued2008-10en
dc.rightsCopyright © held by the author; distribution rights International Foundation for Telemeteringen
dc.description.collectioninformationProceedings from the International Telemetering Conference are made available by the International Foundation for Telemetering and the University of Arizona Libraries. Visit http://www.telemetry.org/index.php/contact-us if you have questions about items in this collection.en
dc.publisherInternational Foundation for Telemeteringen
dc.description.abstractTesting of directed-energy weapon systems requires continuous radio-wave telemetry in order to characterize in situ the effect of irradiation on a target. The telemetry in these cases might be disrupted due to plasma formation causing communication blackout. In this paper several mitigation approaches, namely electrostatic and electromagnetic, are considered. The electrostatic mitigation approach takes into account that an electron depleted sheath is formed around the negatively biased electrode. This creates a 'hole' in the electron density distribution allowing radio communication through the plasma. The electromagnetic approach is based on formation of the ExB layer in the plasma, consequent plasma acceleration, and resulting decrease in the plasma density. In order to assess these mitigation approaches, one needs to characterize the plasma which is created as a result of laser irradiation on different target materials and under various laser beam power levels. We developed a model of the plasma formation which is based on a kinetic description of the Knudsen layer and a hydrodynamic description of the collision-dominated plasma region which is coupled with analyses of the heat transfer in the target material. The overall model describes the absorption of the laser energy by the target and the resulting temperature rise in the surface. This temperature rise then induces ablation of the target material. Laser energy absorption by the plasma plume created above the surface is also considered. Analysis of the ablation rate of various targets subject to directed energy impact was performed. We considered a typical multilayer structure consisting of black paint, titanium, and aluminum layers. For instance, it was found that the aluminum layer has the highest ablation rate, while the black pain layer has the smallest rate for a given surface temperature.en
dc.description.sponsorshipInternational Foundation for Telemeteringen
dc.identifier.issn0884-5123en
dc.identifier.issn0074-9079en
dc.identifier.urihttp://hdl.handle.net/10150/606184en
dc.identifier.journalInternational Telemetering Conference Proceedingsen
dc.typetexten
dc.typeProceedingsen
dc.relation.urlhttp://www.telemetry.org/en
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