DOCSLIB.ORG

THE UNIVERSITY of HULL an Evaluation of the Performance Of

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
THE UNIVERSITY of HULL an Evaluation of the Performance Of THE UNIVERSITY OF HULL An Evaluation of the Performance of Multi-static Handheld Ground Penetrating Radar using Full Wave Inversion for Landmine Detection Being a Thesis submitted for the Degree of Doctor of Philosophy in the University of Hull by Suki Dauda Sule, MSc, B.Eng. (Hons) June 2018 Acknowledgments I would like to begin by thanking my first supervisor, Dr. Kevin Paulson for his support and guidance before and throughout my research. His enthusiasm, optimism and availability have been critical to the completion of this work despite the challenges. To my second supervisor Mr. Nick Riley whose persistent constructive criticism and suggestions always helped to point me in the right direction. My special gratitude goes to my sponsor, the Petroleum Technology Development Fund (PTDF) of Nigeria for providing me with an exceptional full scholarship, one of the best in the world, without which this research would not have been possible. I’m also grateful to the humanitarian demining research teams at the University of Manchester led by Professors Anthony Peyton and William Lionheart for their support. I thank the Computer Simulation Technology (CST) GmbH technical support for the CST STUDIO SUITE. I will not forget the administrative support of Jo Arnett and Glen Jack in processing my numerous requests, expense claims and other academic requisitions. To my colleagues, my laboratory mate and other PhD students in the Electronic Engineering Department for their moral support and encouragement. I’m very thankful to Pastor Isaac Aleshinloye and the Amazing Grace Chapel, Hull family for providing me with a place of spiritual support, friendship, opportunity for community service and a place to spend my time outside of academic study productively. I need to thank my parents, Mr. and Mrs. S. S. Sule for their immense support in many ways and encouragement throughout my studies generally and my postgraduate study at the University of Hull. Special thanks also go to my sisters Suninba and Saundiba, as well as Aisha and my brother Saminu, who have also provided the motivation for me to succeed. I won’t forget my extended family members, uncles, aunties and cousins who I can’t mention by name but who have all contributed to my achievements in one way or the other. Lastly, I want to appreciate my dear wife Ndepana for her encouragement and support and my wonderful daughter Sarah Azaria for arriving and inspiring me in the final stages of the project. I cannot conclude this acknowledgement without a declaration of gratitude and praise to God who I firmly believe in and who is the source of my life and my driving force. 2 Abstract This thesis presents an empirical study comparing the ability of multi-static and bi-static, handheld, ground penetrating radar (GPR) systems, using full wave inversion (FWI), to determine the properties of buried anti-personnel (AP) landmines. A major problem associated with humanitarian demining is the occurrence of many false positives during clearance operations. Therefore, a reduction of the false alarm rate (FAR) and/or increasing the probability of detection (POD) is a key research and technical objective. Sensor fusion has emerged as a technique that promises to significantly enhance landmine detection. This study considers a handheld, combined metal detector (MD) and GPR device, and quantifies the advantages of the use of antenna arrays. During demining operations with such systems, possible targets are detected using the MD and further categorised using the GPR, possibly excluding false positives. A system using FWI imaging techniques to estimate the subsurface parameters is considered in this work. A previous study of multi-static GPR FWI used simplistic, 2D far-field propagation models, despite the targets being 3D and within the near field. This novel study uses full 3D electromagnetic (EM) wave simulation of the antenna arrays and propagation through the air and ground. Full EM simulation allows the sensitivity of radio measurements to landmine characteristics to be determined. The number and configuration of antenna elements are very important and must be optimised, contrary to the 2D sensitivity studies in (Watson, Lionheart 2014, Watson 2016) which conclude that the degree (number of elements) of the multi-static system is not critical. A novel sensitivity analysis for tilted handheld GPR antennas is used to demonstrate the positive impact of tilted antenna orientation on detection performance. A time domain GPR and A-scan data, consistent with a commercial handheld system, the MINEHOUND, is used throughout the simulated experiments which are based on synthetic GPR measurements. Finally, this thesis introduces a novel method of optimising the FWI solution through feature extraction or estimation of the internal air void typically present in pressure activated mines, to distinguish mines from non-mine targets and reduce the incidence of false positives. 3 Table of Contents Acknowledgments ............................................................................................................. 2 Abstract ............................................................................................................................. 3 Table of Contents .............................................................................................................. 4 List of Figures and Tables .................................................................................................. 7 List of Acronyms .............................................................................................................. 10 Chapter 1 Introduction .............................................................................................. 12 1.1 The Humanitarian Demining Challenge ........................................................... 12 1.2 Landmine Detection Methods .......................................................................... 14 1.2.1 MD and GPR Sensor Fusion ....................................................................... 15 1.2.2 GPR Signal Processing ............................................................................... 18 1.3 Research Motivation and Background ............................................................. 20 1.4 Thesis Aim and Objectives ................................................................................ 23 1.5 Thesis Methodology ......................................................................................... 25 1.6 Thesis Contributions ......................................................................................... 26 1.7 Publications ...................................................................................................... 28 1.8 Thesis Structure ................................................................................................ 29 Chapter 2 Landmine Detection Using Handheld GPR ................................................ 31 2.1 Introduction ...................................................................................................... 31 2.2 Landmine Detection Methods .......................................................................... 31 2.2.1 Nonlinear Seismo-acoustic Technique ...................................................... 31 2.2.2 Gamma Rays .............................................................................................. 32 2.2.3 Passive Infrared (IR) Polarization .............................................................. 33 2.2.4 Active Thermal Sensing ............................................................................. 33 2.2.5 Nuclear Quadrupole Resonance ............................................................... 34 2.2.6 Ultra-wideband (UWB) Radar ................................................................... 35 2.2.7 Electromagnetic Induction (EMI) .............................................................. 35 2.2.8 Summary ................................................................................................... 36 2.3 Sensor Fusion.................................................................................................... 37 4 2.3.1 Types of Sensor Fusion .............................................................................. 37 2.3.2 Current Handheld MD and GPR Systems .................................................. 39 2.4 GPR System Overview ...................................................................................... 41 2.4.1 Physics of Operation ................................................................................. 43 2.4.2 Range and Path Loss ................................................................................. 44 2.4.3 System Loop Gain ...................................................................................... 45 2.4.4 Velocity of Propagation ............................................................................. 46 2.4.5 Depth and Plan Resolution ........................................................................ 47 2.4.6 Clutter........................................................................................................ 48 2.4.7 Antennas for GPR ...................................................................................... 48 2.4.8 System Operating Frequency and Domain ............................................... 49 2.4.9 Signal Processing ....................................................................................... 50 2.5 Conclusion .......................................................................................................
Load more

Recommended publications
  • Toward a Mine-Free World Executive Summary
    Landmine Monitor Report 2004: Toward a Mine-Free World Executive Summary Landmine Monitor Core Group Human Rights Watch Handicap International Kenya Coalition Against Landmines Mines Action Canada Norwegian People’s Aid Copyright © October 2004 by Human Rights Watch Landmine Monitor Report 2004—Executive Summary Embargoed until 18 November 2004 2 All rights reserved. Printed in the United States of America This report was printed on recycled paper using vegetable based ink. ISBN: 1-56432-327-7 Library of Congress Control Number: 2004112567 Cover photograph © Fred Clarke, International Committee of the Red Cross (ICRC), August 2002 Cover design by Rafael Jiménez For a copy of Landmine Monitor Report 2004, please contact: International Campaign to Ban Landmines www.icbl.org/lm Email: [email protected] Human Rights Watch 1630 Connecticut Avenue NW, Suite 500, Washington, DC 20009, USA Tel: +1 (202) 612-4321, Fax: +1 (202) 612-4333, Email: [email protected] www.hrw.org Handicap International rue de Spa 67, B-1000 Brussels, BELGIUM Tel: +32 (2) 286-50-59, Fax: +32 (2) 230-60-30, Email: [email protected] www.handicap-international.be Kenya Coalition Against Landmines PO Box 57217, 00200 Nairobi, KENYA Tel: +254 (20) 573-099 /572-388, Fax: + 254 (20) 573-099 Email: [email protected] www.k-cal.org Mines Action Canada 1 Nicolas Street, Suite 1502, Ottawa, Ont K1N 7B7, CANADA Tel: +1 (613) 241-3777, Fax: +1 (613) 244-3410, Email: [email protected] www.minesactioncanada.org Norwegian People’s Aid PO Box 8844, Youngstorget NO-0028, Oslo,
    [Show full text]
  • TM-43-0001-36 Ammunition Data Sheets for Land Mines
    TM 43-0001-36 TECHNICAL MANUAL ARMY AMMUNITION DATA SHEETS FOR LAND MINES (FSC 1345) DISTRIBUTION STATEMENT A: Approved for public release; distribution is unlimited. HEADQUARTERS, DEPARTMENT OF THE ARMY SEPTEMBER 1994 TM 43-0001-36 C2 CHANGE HEADQUARTERS DEPARTMENT OF THE ARMY NO. 2 Washington, DC., 15 September 1997 ARMY AMMUNITION DATA SHEETS (LAND MINES (FSC 1345)) DISTRIBUTION STATEMENT A: Approved for public release; distribution unlimited. TM 43-0001-36, dated 01 September 1994, is changed as follows: 1. Cross out information on inside cover. The information is changed and placed on page a. 2. Remove old pages and insert new pages as indicated below. Changed material is indicated by a vertical bar in the margin of the page. Added or revised illustrations are indicated by a vertical bar adjacent to the identification number. Remove pages Insert pages i and ii i and ii 3-7 and 3-8 3-7 and 3-8 3. File this change sheet in front of the publication for reference purposes. By Order of the Secretary of the Army: DENNIS J. REIMER General, United States Army Chief of Staff Official: JOEL B. HUDSON Administrative Assistant to the Secretary of the Army 03953 Distribution: To be distributed in accordance with IDN 340853, with requirements for TM 43-000-36. TM 43-0001-36 C1 CHANGE HEADQUARTERS DEPARTMENT OF THE ARMY NO. 1 Washington, DC, 30 June 1997 ARMY AMMUNITION DATA SHEETS (LAND MINES (FSC 1345)) TM 43-0001-36, dated 01 September 1994, is changed as follows: 1. Cross out information on inside cover.
    [Show full text]
  • Classification of Buried Objects Using Acoustic Waves
    Minoufiya University Faculty of Electronic Engineering Department of Electronics and Electrical Communications Engineering Classification of Buried Objects Using Acoustic Waves A Thesis Submitted for the Degree of M. Sc. in Electronic Engineering, Communications Engineering, Department of Electronics and Communications Engineering By Eng. Emad Abd Elhalim Elsayed Elshazly B. Sc. in Electronics and Electrical Communications Engineering, Faculty of Electronic Engineering, Minoufiya University, Menouf 2004 Supervisors Prof. Mohamed F. El-Kordy Prof. in Electronics and Electrical Communications Engineering Department, Faculty of Electronic Engineering, Minoufiya University Prof. Sayed M. El-Araby Chairman of Atomic Energy Authority Dr. Osama F. Zahran Lecturer in Electronics and Electrical Communications Engineering Department, Faculty of Electronic Engineering, Minoufiya University 2012 Minoufiya University Faculty of Electronic Engineering Department of Electronics and Electrical Communications Engineering Classification of Buried Objects Using Acoustic Waves A Thesis Submitted for the Degree of M. Sc. in Electronic Engineering, Communications Engineering, Department of Electronics and Communications Engineering By Eng. Emad Abd Elhalim Elsayed Elshazly B. Sc. in Electronics and Electrical Communications Engineering, Faculty of Electronic Engineering, Minoufiya University, Menouf, 2004 Supervisors Prof. Mohamed F. El-Kordy ( ) Department of Electronics and Electrical Communications Engineering, Faculty of Electronic Engineering, Minoufiya
    [Show full text]
  • Subcourse Edition
    IDENTIFYING AMMUNITION Subcourse MM 2598 Edition 7 United States Army Combined Arms Support Command Fort Lee, Virginia 23801-1809 4 Credit Hours CONTENTS INTRODUCTION IDENTIFICATION OF AMMUNITION (Tasks 093-400-1100 through 093-400-1109), 7 Understanding Means of Identification, 7 Size, 7 Shape and Physical Features, 7 Color Code, 7 Markings, 7 Packing, 8 Type, 8 Identifying Small Arms Ammunition, 8 Size of Small Arms, 9 Types of Small Arms Cartridges, 10 Identifying Artillery Ammunition, 13 Use, 13 Loading Method, 15 Additional Identifying Features, 17 Artillery Ammunition Packing, 19 Identifying Mortar Ammunition, 20 60mm Mortar Ammunition, 20 81mm Mortar Ammunition, 24 4.2-inch (107mm) Mortar Ammunition, 27 Mortar Ammunition Packing, 29 Identifying Rocket Ammunition, 30 Classification of Rocket Ammunition, 30 Types of Rockets, 31 Identifying Hand Grenades, 37 Fragmentation Hand Grenades, 40 Offensive Hand Grenades, 40 Chemical Hand Grenades, 40 Illuminating Hand Grenades, 41 Practice Hand Grenades, 41 Identifying Land Mines, 41 Antipersonnel (apers) Mines, 41 Antitank (at) Mines, 44 Practice Mines, 47 Chemical Land Mines, 47 Identifying Fuzes, 48 Grenades Fuzes, 48 Mine Fuzes, 48 Mortar and Artillery Fuzes, 50 Identifying Small Guided Missiles, 54 Antitank Guided Missiles (ATGM), 54 Air Defense Guided Missiles, 59 Identifying Demolition Materials, 61 Demolition Charges, 62 Priming and Initiating Materials, 66 Demolition Kits, 69 Identifying Pyrotechnics, 71 Illumination Pyrotechnics, 71 Signaling Pyrotechnics, 72 Simulator Pyrotechnics, 75 Review Exercises, 77 EXERCISE SOLUTIONS, 88 MM2598 INTRODUCTION In the preceding subcourse (MM2597), you learned how to interpret ammunition markings and color codes. Now suppose, for example, a using unit turns in ammunition that has been removed from its original containers and there are no markings or the markings have been obliterated.
    [Show full text]
  • Assessment of Lower Leg Injury from Land Mine Blast – Phase 1
    Defence Research and Recherche et développement Development Canada pour la défense Canada Assessment of Lower Leg Injury from Land Mine Blast – Phase 1 Test Results using a Frangible Surrogate Leg with Assorted Protective Footwear and Comparison with Cadaver Test Data D.M. Bergeron, G.G. Coley, R.W. Fall Defence R&D Canada – Suffield I.B. Anderson Canadian Forces Medical Group Technical Report DRDC Suffield TR 2006-051 February 2006 Assessment of Lower Leg Injury from Land Mine Blast – Phase 1 Test Results using a Frangible Surrogate Leg with Assorted Protective Footwear and Comparison with Cadaver Test Data D.M. Bergeron, G.G. Coley, R.W. Fall Defence R&D Canada – Suffield I.B. Anderson Canadian Forces Medical Group Defence R&D Canada – Suffield Technical Report DRDC Suffield TR 2006-051 February 2006 Author D.M. Bergeron Approved by Dr. Chris A. Weickert Director, Canadian Centre for Mine Action Technologies Approved for release by Dr. Paul D’Agostino Chair, Document Review Panel © Her Majesty the Queen as represented by the Minister of National Defence, 2006 © Sa majesté la reine, représentée par le ministre de la Défense nationale, 2006 Abstract In 1999, the Canadian Centre for Mine Action Technologies (CCMAT) sponsored a series of tests involving the detonation of 25 anti-personnel blast mines against a frangible leg model. The model was fitted with various footwear and additional protective equipment. The aim of these tests was to assess whether this model could be used for routine tests of protective footwear against mine blast. The report describes the frangible leg and compares it to its human counterpart.
    [Show full text]
  • Landmines Landmines
    LANDMINES TITLES OF RELATED INTEREST Landmines in El Salvador & Nicaragua The Civilian Victims (1986) Americas Watch Landmines in Cambodia The Coward's War (1991) Asia Watch & Physicians for Human Rights Hidden Death Landmines and Civilian Casualties in Iraqi Kurdistan (1992) Middle East Watch Hidden Enemies Landmines in Northern Somalia (1992) Physicians for Human Rights Landmines in Angola (1993) Africa Watch LANDMINES A Deadly Legacy The Arms Project of Human Rights Watch &&& Physicians for Human Rights Human Rights Watch New York !!! Washington !!! Los Angeles !!! London Copyright 8 October 1993 by Human Rights Watch and Physicians for Human Rights All rights reserved. Printed in the United States of America. Library of Congress Catalog Card Number: 93 80418 ISBN 1-56432-113-4 Cover photo shows a collection of antipersonnel and antitank landmines in Iraqi Kurdistan. Copyright 8 R. Maro; courtesy of Medico International (Germany). THE ARMS PROJECT OF HUMAN RIGHTS WATCH The Arms Project of Human Rights Watch was formed in 1992 with a grant from the Rockefeller Foundation for the purposes of monitoring and seeking to prevent arms transfers to governments or organizations that either grossly violate internationally recognized human rights or grossly violate the laws of war. It also seeks to promote freedom of information and expression about arms transfers worldwide. The Arms Project takes a special interest in weapons that are prominent in human rights abuse and the abuse of non-combatants. The director of the Arms Project is Kenneth Anderson and its Washington director is Stephen D. Goose. Barbara Baker and Cesar Bolaños are New York staff associates, and Kathleen Bleakley is the Washington staff associate.
    [Show full text]
  • Non-Signatories
    NON-SIGNATORIES AFGHANISTAN Key developments since May 2001: Afghanistan has experienced dramatic political, military, and humanitarian changes. The cabinet approved Afghanistan’s accession to the Mine Ban Treaty on 29 July 2002 and the following day the Minister of Foreign Affairs signed the instrument of accession on behalf of the Transitional Islamic State of Afghanistan. Mine action operations were virtually brought to a halt following 11 September 2001. The mine action infrastructure suffered greatly during the subsequent military conflict, as some warring factions looted offices, seized vehicles and equipment, and assaulted local staff. Four deminers and two mine detection dogs were killed in errant U.S. air strikes. Military operations created additional threats to the population, especially unexploded U.S. cluster bomblets and ammunition scattered from storage depots hit by air strikes, as well as newly laid mines and booby-traps by Northern Alliance, Taliban, and Al-Qaeda fighters. A funding shortfall for the mine action program in Afghanistan prior to 11 September 2001 had threatened to again curtail mine action operations. But since October 2001, about $64 million has been pledged to mine action in Afghanistan. By March 2002, mine clearance, mine survey, and mine risk education operations had returned to earlier levels, and have since expanded beyond 2001 levels. In 2001, mine action NGOs surveyed approximately 14.7 million square meters of mined areas and 80.8 million square meters of former battlefield area, and cleared nearly 15.6 million square meters of mined area and 81.2 million square meters of former battlefields. Nearly 730,000 civilians received mine risk education.
    [Show full text]
  • Military-Technical-Courier-1-2017.Pdf
    МИНИСТАРСТВО ОДБРАНЕ РЕПУБЛИКЕ СРБИЈЕ МЕДИЈА ЦЕНТАР „ОДБРАНА” Директор Стевица С. Карапанџин, пуковник УНИВЕРЗИТЕТ ОДБРАНЕ У БЕОГРАДУ Ректор Проф. др Младен Вуруна, генерал-мајор, http://orcid.org/0000-0002-3558-4312 Начелник одсека за издавачку делатност Драгана Марковић УРЕДНИК ВОЈНОТЕХНИЧКОГ ГЛАСНИКА мр Небојша Гаћеша, потпуковник e-mail: [email protected], tel.: 011/3349-497, 064/80-80-118, http://orcid.org/0000-0003-3217-6513 УРЕЂИВАЧКИ ОДБОР – генерал-мајор проф. др Бојан Зрнић, начелник Управе за одбрамбене технологије Сектора за материјалне ресурсе Министарства одбране Републике Србије, председник Уређивачког одбора, http://orcid.org/0000-0002-0961-993X, – доц. др Данко Јовановић, генерал-мајор у пензији, заменик председника уређивачког одбора, – др Стеван М. Бербер, The University of Auckland, Department of Electrical and Computer Engineering, Auckland, New Zealand, http://orcid.org/0000-0002-2432-3088, – научни сарадник др Обрад Чабаркапа, пуковник у пензији, http://orcid.org/0000-0002-3949-8227, – проф. др Владимир Чернов, Владимирский государственный университет, Владимир, Российская федерация (Vla- dimir State University, Vladimir, Russian federation), http://orcid.org/0000-0003-1830-2261, – пуковник ванр. проф. др Горан Дикић, проректор Универзитета одбране, Београд, http://orcid.org/0000-0002-0858-1415, – проф. др Александр Дорохов, Харьковский национальный экономический университет, Харьков, Украина (Kharkiv National University of Economics, Kharkiv, Ukraine), http://orcid.org/0000-0002-0737-8714, – проф. др Жељко Ђуровић, Електротехнички факултет Универзитета у Београду, http://orcid.org/0000-0002-6076-442X, – проф. др Леонид И. Гречихин, Минский государственный высший авиационный колледж, Минск, Республика Бела- русь; академик Академии строительства Украины (Minsk State Higher Aviation College, Minsk, Republic of Belarus; academician оf Academy of Construction of Ukraine), http://orcid.org/0000-0002-5358-9037, – др Јован Исаковић, Војнотехнички институт, Београд, – проф.
    [Show full text]
  • Mine Action: Lessons and Challenges
    Mine Action: Lessons and Challenges Mine Action: Lessons and Challenges Geneva International Centre for Humanitarian Demining 7bis, avenue de la Paix P.O. Box 1300 CH - 1211 Geneva 1 Switzerland Tel. (41 22) 906 16 60, Fax (41 22) 906 16 90 www.gichd.ch Mine Action: Lessons and Challenges i The Geneva International Centre for Humanitarian Demining (GICHD) supports the efforts of the international community in reducing the impact of mines and unexploded ordnance (UXO). The Centre provides operational assistance, is active in research and supports the implementation of the Anti-Personnel Mine Ban Convention. Geneva International Centre for Humanitarian Demining 7bis, avenue de la Paix P.O. Box 1300 CH-1211 Geneva 1 Switzerland Tel. (41 22) 906 16 60 Fax (41 22) 906 16 90 www.gichd.ch [email protected] Mine Action: Lessons and Challenges, GICHD, Geneva, November 2005. This project was managed by Eric Filippino, Head, Socio-Economic Section ([email protected]). ISBN 2-88487-025-3 © Geneva International Centre for Humanitarian Demining The views expressed in this publication are those of the Geneva International Centre for Humanitarian Demining. The designations employed and the presentation of the material in this publication do not imply the expression of any opinion whatsoever on the part of the Geneva International Centre for Humanitarian Demining concerning the legal status of any country, territory or area, or of its authorities or armed groups, or concerning the delimitation of its frontiers or boundaries. ii Contents Foreword 1 Introduction 3 Executive summary 5 The evolution of the five pillars of mine action 6 The coordination and management o mine action programmes 11 So, has mine action really made a difference? 13 Part I.
    [Show full text]
  • Mine/Countermine Operations
    FM 20-32 C2 Change 2 Headquarters Department of the Army Washington, DC, 22 August 2001 Mine/Countermine Operations 1. Change FM 20-32, 30 September 1992, as follows: Remove Old Pages Insert New Pages i through xviii i through xviii 1-5 through 1-8 1-5 through 1-8 2-9 and 2-10 2-9 and 2-10 2-21 and 2-22 2-21 and 2-22 2-45 and 2-46 2-45 and 2-46 3-1 through 3-8 3-1 through 3-8 3-13 and 3-14 3-13 and 3-14 3-17 through 3-33 3-17 through 3-28 4-1 through 4-4 4-1 through 4-4 4-7 and 4-8 4-7 and 4-8 4-11 and 4-12 4-11 and 4-12 4-15 4-15 5-3 and 5-4 5-3 and 5-4 5-7 and 5-8 5-7 and 5-8 6-9 and 6-10 6-9 and 6-10 6-25 and 6-26 6-25 and 6-26 6-35 through 6-38 6-35 through 6-38 7-13 and 7-14 7-13 and 7-14 8-5 and 8-6 8-5 and 8-6 8-9 through 8-12 8-9 through 8-12 8-17 and 8-18 8-17 and 8-18 8-21 through 8-30 8-21 through 8-30 9-1 and 9-2 9-1 and 9-2 9-7 9-7 10-1 through 10-4 10-1 through 10-4 10-11 and 10-12 10-11 and 10-12 10-25 through 10-34 10-25 through 10-34 10-37 and 10-38 10-37 and 10-38 11-1 and 11-2 11-1 and 11-2 11-5 and 11-6 11-5 and 11-6 11-13 and 11-14 11-13 and 11-14 11-17 and 11-18 11-17 and 11-18 12-1 and 12-2 12-1 and 12-2 12-9 through 12-12 12-9 through 12-12 Remove Old Pages Insert New Pages 12-15 and 12-16 12-15 and 12-16 13-1 through 13-6 13-1 through 13-6 13-15 and 13-16 13-15 and 13-16 13-21 and 13-22 13-21 and 13-22 13-29 through 13-33 13-29 through 13-33 A-11 and A-12 A-11 and A-12 A-29 and A-30 A-29 and A-30 A-33 and A-34 A-33 and A-34 B-1 through B-6 B-1 through B-5 C-1 and C-2 C-1 and C-2 D-5 and D-6 D-5 and D-6 D-15 and D-16 D-15 and D-16 E-1 and E-2 E-1 and E-2 F-3 and F-4 F-3 and F-4 F-9 and F-10 F-9 and F-10 F-17 and F-18 F-17 and F-18 Glossary-7 through Glossary-10 Glossary-7 through Glossary-10 References-1 and References-2 References-1 and References-2 Index-1 through Index-6 Index-1 through Index-6 DA Form 1355-1-R DA Form 1355-1-R 2.
    [Show full text]
  • Volume II-Final Report of the Lower Extremity Assessment
    Humanitarian Demining Technologies - Volume II-Final Report of the Lower Extremi... Page 1 of 1 Volume II-Final Report of the Lower Extremity Assessme (LEAP 99-2) Home Technologies AUGUST - 2000 Threats Participants: Process U.S. ARMY COMMUNICATIONS – ELECTRONICS COMMA Publications NIGHT VISION ELECTRONIC SENSORS DIRECTORATE U.S. ARMY INSTITUTE OF SURGICAL RESEARCH EXTRE TRAUMA STUDY BRANCH U.S. ARMY ABERDEEN TEST Contact Us U.S. ARMY SOLDIER SYSTEMS COMMAND Links Archive Report Cover (36 KB) Site Map Title Page (26 KB) Accessiblity LEAP 99-2 Report Volume 2 (1,146 KB) Appendix A-Detailed Medical Evaluations (79 Appendix B-Pretest Radiographs (825KB) Appendix C-Post test Radiographs (525 KB) Appendix D-Detailed Footwear Damage Ass Appendix D-Detailed Footwear Damage Ass Appendix D-Detailed Footwear Damage Ass Appendix D-Detailed Footwear Damage Ass Appendix D-Detailed Footwear Damage Ass Appendix E-Force Data (225 KB) http://www.humanitarian-demining.org/demining/pubs/protection/leap99-2/leap99_2_r... 6/16/2005 Robert M. Harris Mark S. Rountree Lanny V. Griffin Roman A. Hayda Terry Bice Stephen J. Mannion U.S. Army Institute of Surgical Research Extremity Trauma Study Branch Fort Sam Houston, Texas Abstract Research conducted by Department of Defense laboratories and facilities, collaborating with leading academic institutions, has demonstrated that currently available landmine protective footwear does not prevent severe injury. This footwear potentially reduces injury severity against some antipersonnel mines. Volume 2 of the Lower Extremity Assessment Program (LEAP 99-2) discusses the change of injury pattern in a cadaver model wearing mine protective footwear during an antipersonnel blast mine detonation.
    [Show full text]
  • Novel Radar Techniques for Humanitarian Demining
    DETERMINE: Novel Radar Techniques for Humanitarian Demining Federico Lombardi A dissertation submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy of University College London. Department of Electronic and Electrical Engineering University College London July 17, 2019 To my Wife, who always supported me, whatever path I took. To my Son, who will always support my wife, whatever path I may take. 3 I, Federico Lombardi, confirm that the work presented in this thesis is my own. Where information has been derived from other sources, I confirm that this has been indicated in the work. Federico Lombardi Abstract Today the plague of landmines represent one of the greatest curses of modern time, killing and maiming innocent people every day. It is not easy to provide a global esti- mate of the problem dimension, however, reported casualties describe that the majority of the victims are civilians, with almost a half represented by children. Among all the technologies that are currently employed for landmine clearance, Ground Penetrating Radar (GPR) is one of those expected to increase the efficiency of operation, even if its high-resolution imaging capability and the possibility of detecting also non-metallic landmines are unfortunately balanced by the high sensor false alarm rate. Most landmines may be considered as multiple layered dielectric cylinders that interact with each other to produce multiple reflections, which will be not the case for other common clutter objects. Considering that each scattering component has its own angular radiation pattern, the research has evaluated the improvements that multistatic configurations could bring to the collected information content.
    [Show full text]