Detection and sensing of mines, explosive objects, and obscured targets XV

5-9 April 2010, Orlando, Florida, United States by R. S. Harmon

Publisher: SPIE in Bellingham, Wash

Written in English
Published: Downloads: 636
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Subjects:

  • Detection,
  • Radar,
  • Mines (Military explosives),
  • Congresses,
  • Optical detectors,
  • Explosives

Edition Notes

Includes bibliographical references and index.

StatementRussell S. Harmon, John H. Holloway, Jr., J. Thomas Broach, editors ; sponsored and published by SPIE
SeriesProceedings of SPIE -- v. 7664, Proceedings of SPIE--the International Society for Optical Engineering -- v. 7664.
ContributionsSPIE (Society)
Classifications
LC ClassificationsUG490 .D47754 2010
The Physical Object
Pagination1 v. (various paging) :
ID Numbers
Open LibraryOL25019883M
ISBN 100819481289
ISBN 109780819481283
LC Control Number2011377465
OCLC/WorldCa655250538

Abstract Two vehicle mounted metal detector arrays are used in conjunction to perform object classification. The first array (Vallon VMV) contains small coils for detecting shallow targets. The second array (Minelab STMR II) contains receive coils of roughly the same size, but a single large transmitter for detecting deep targets. and automated classification in a uxo discrimination blind test. Detection and Sensing of Mines, Explosive Objects, and Obscured Targets Xv, , [32]J. P. Fern´andez, B. Barrowes, K. O’Neill, Irma Shamatava, F. Shubitidze, and Keli Sun. A data-derived time-domain SEA for UXO identifi-cation using the MPV sensor. SPIE, A. Zare, M. Silvious, R. Close, and P. Gader, “Quantifying the benefit of airborne and ground sensor fusion for target detection,” in Proc. SPIE , Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XV, for Hybrid Ground Penetrating Ra dar Electromagnetic Induction Landmine Detection Systems Autonomous Mine Detection System (AMDS) program has Explosive Objects, and Obscured Targets XV.

A minimum metal mine is a land mine that is designed to use the smallest amount of metal possible in its construction. Typically, the only metal components are located inside the fuze mechanism which triggers detonation. Both minimum metal anti-tank and anti-personnel mines exist. Some designs contain virtually no metal at all, e.g., less than a is achieved by encasing the explosive. Feature extraction for predicting the probability of detecting buried explosive objects using GPR data Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXIV May 1, Title: Assistant Professor at University . High Resolution Soil Moisture Mapping using Operational Satellite Imagery, Proc. SPIE , Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XV. Jan M. H. Hendrickx, Bruce J. Harrison, Brian Borchers, Graciela Rodríguez-Marín, Stacy Howington, Jerrell Ballard. and automated classification in a uxo discrimination blind test. Detection and Sensing of Mines, Explosive Objects, and Obscured Targets Xv, , [21]J. P. Fern´andez, B. Barrowes, K. O’Neill, Irma Shamatava, F. Shubitidze, and Keli Sun. A data-derived time-domain SEA for UXO identifi-cation using the MPV sensor. SPIE,

The multi-optical mine detection system (MOMS) is a research project focused on the detection of surface laid mines. In the sensor suite, both passive and active sensors are included, such as IR as well as hyper- and multispectral cameras, and 3-D laser radar. Extensive field experiments have been conducted to collect data under various environmental conditions. PDF | On , James B Kingdon and others published ESTCP Live Site Demonstrations, Marysville, CA. ESTCP MR, Demonstration Data Report, .

Detection and sensing of mines, explosive objects, and obscured targets XV by R. S. Harmon Download PDF EPUB FB2

Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XV Editor(s): Russell S. Harmon ; John H. Holloway Jr. ; J. Thomas Broach For the purchase of this volume in printed format, please visit Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XIV (Proceedings of Spie) [Harmon, Russell S., Broach, J.

Thomas, Holloway, John H., Jr.] on *FREE* shipping on qualifying offers. Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XIV (Proceedings of Spie). Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXV Monday - Friday 27 April - 1 May   PROCEEDINGS VOLUME Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXI.

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Mine warfare has warranted the use of multi-sensor detection (e.g., ground penetrating radar) rather than strict metal detection. Contents xi ConferenceCommittee xv Introduction SESSION 1 ELECTROMAGNETIC INDUCTIONI Open-areaconcealed-weapondetection system [] P.

Pati, P. Mather, Univ. ofHuddersfield (UnitedKingdom) 03 Magneticsensing techniquesfor humanitarianordnance detection anddiscrimination [] J.

Keranen,S. Billings, z,J. Miller, SkyResearch,Inc. (United. Detection and sensing of mines, explosive objects, and obscured targets XIX: 5 - 7 MayBaltimore, Maryland, United States ; [part of SPIE DSS defense + security.

of buried bulk explosives,” in [Detection and Sensing of Mines, Explosive Obje cts, and Obscured T argets XVI ], Pro c. SPIE (). Preliminary paper number Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXIII: Authors: Bishop, Steven S.; Isaacs, Jason C.

Affiliation: AA(U.S. Army Night Vision & Electronic Sensors Directorate (United States)), AB(Naval Surface Warfare Ctr. Panama City Div. (United States)) Publication. Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXI: Authors: Bishop, Steven S.; Isaacs, Jason C.

Affiliation: AA(U.S. Army Night Vision & Electronic Sensors Directorate (United States)), AB(Naval Surface Warfare Ctr. Panama City Div. (United States)) Publication. Detection andSensingof Mines, ExplosiveObjects, andObscuredTargetsXV Russell S.

Harmon JohnH. Holloway, Jr. Thomas Broach Ediiors April Orlando, Florida, United States SponsoredandPublishedby SPIE TIB/UBHannover 89 Volume ProceedingsofSPIE, X, v. Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XV.

Edited by Harmon, Russell S.; Holloway, John H., Jr.; Broach, J. Thomas. Abstract The physically complete Normalized Surface Magnetic Source (NSMS) model and a variant of the simple dipole model are applied to new-generation electromagnetic induction (EMI) data.

Detection and sensing of mines, explosive objects, and obscured targets XX: 20 - 23 AprilBaltimore, Maryland, United States ; [part of SPIE DSS, defense +.

PROCEEDINGS OF SPIE Volume Proceedings of SPIE, X, v. SPIE is an international society advancing an interdisciplinary approach to the science and application of light.

Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XV Russell S. Harmon John H. Holloway, Jr. Thomas Broach Editors. Get this from a library. Detection and sensing of mines, explosive objects, and obscured targets XV: AprilOrlando, Florida, United States.

[R S Harmon; John H. Add tags for "Detection and sensing of mines, explosive objects, and obscured targets XVI: AprilOrlando, Florida, United States". Be the first. Similar Items. Proc. SPIE.Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXII KEYWORDS: Target detection, Principal component analysis, Independent component analysis, Coherence (optics), Sensors, Image processing, Feature extraction, Image filtering, Charge-coupled devices, Binary data.

Get this from a library. Detection and sensing of mines, explosive objects, and obscured targets XIX: MayBaltimore, Maryland, United States. [Steven S Bishop; Jason C Isaacs; SPIE (Society),;]. Get this from a library.

Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XXI. [Steven Bishop]. estimate uncertainty in classifying landmine targets, Detection and Sensing of Mines, Explosive Objects, and Obscured Targets XVI., Orlando, Florida, USA.: Joshua Wood, Joseph Wilson, Jeremy Bolton.

Extracting edge histogram detector features from ground penetrating radar data. Zare, M. Silvious, R. Close, and P. Gader, “Quantifying the Benefit of Airborne and Ground Sensor Fusion for Target Detection,” in Proc.

SPIEDetection and Sensing of Mines, Explosive Objects, and Obscured Targets XV, DETECT EXPLOSIVES BY INFRARED IMAGERY USING MERGING ANOMALY ALGORITHM AND IMAGE FEATURES.

A Explosive Objects, and Obscured Targets [6] C. Ratto, P. Torrione, and L.M. Collins, “Exploitingground-penetrating radar phenomenology in a context-dependent framework for landmine detection anddiscrimination,” IEEE Trans. Geosci.

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Trafficability map of Shoalwater Bay Training Area in Queensland, Australia derived from hyperspectral imagery using methods of Bachmann et al. (). Hyperspectral sensing’s ability to detect ground disturbances aids in the detection of buried land mines .Proceedings of SPIE Defense, Security and Sensing Meeting.

Conference Detection and Sensing of Mines, Explosive Objects and Obscured Targets XV. Paper Cite as: Few, D, Versteeg, R. and Herman, H. () Semi autonomous mine detection system, Proc. SPIESemi autonomous mine detection system.