Defence Research and Development Canada Reference Document DRDC-RDDC-2020-D100 September 2020 CAN UNCLASSIFIED CAN UNCLASSIFIED Virtual Trip Report SPIE Defense+ Commercial Sensing Digital Forum 2020 Helen Moise Corry Byrne DRDC – Suffield Research Centre The body of this CAN UNCLASSIFIED document does not contain the required security banners according to DND security standards. However, it must be treated as CAN UNCLASSIFIED and protected appropriately based on the terms and conditions specified on the covering page.
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Defence Research and Development Canada Reference Document
DRDC-RDDC-2020-D100
September 2020
CAN UNCLASSIFIED
CAN UNCLASSIFIED
Virtual Trip Report
SPIE Defense+ Commercial Sensing Digital Forum 2020
Helen Moise Corry Byrne DRDC – Suffield Research Centre
The body of this CAN UNCLASSIFIED document does not contain the required security banners according to DND security standards. However, it must be treated as CAN UNCLASSIFIED and protected appropriately based on the terms and conditions specified on the covering page.
This document was reviewed for Controlled Goods by Defence Research and Development Canada (DRDC) using the Schedule to the Defence Production Act.
Disclaimer: This publication was prepared by Defence Research and Development Canada an agency of the Department of National Defence. The information contained in this publication has been derived and determined through best practice and adherence to the highest standards of responsible conduct of scientific research. This information is intended for the use of the Department of National Defence, the Canadian Armed Forces (“Canada”) and Public Safety partners and, as permitted, may be shared with academia, industry, Canada’s allies, and the public (“Third Parties”). Any use by, or any reliance on or decisions made based on this publication by Third Parties, are done at their own risk and responsibility. Canada does not assume any liability for any damages or losses which may arise from any use of, or reliance on, the publication.
Endorsement statement: This publication has been published by the Editorial Office of Defence Research and Development Canada, an agency of the Department of National Defence of Canada. Inquiries can be sent to: [email protected].
DRDC-RDDC-2020-D100 i
Abstract
This Reference Document provides a brief summary and report on five select presentations within the
CBRNE stream that were seen during the Chemical, Biological, Radiological, Nuclear and Explosives
(CBRNE) Sensing XXI online conference session under the umbrella of the SPIE Defense + Commercial
Sensing Digital Forum 2020, which may be of great interest and relevance within CBRNE research at the
Counter Terrorism and Technology Centre (CTTC) at Defense Research and Development Canada’s
Suffield Research Centre. Future research work in these areas are also included. The following
presentations are presented in this report (ordered as per date viewed online):
Chemical sensing via a low SWaP wearable spectrometer. Author(s): Richard P. Kingsborough, Alexandra T. Wrobel, Devon Beck, Lauren Cantley, Shane Tysk,
Roderick Kunz, MIT Lincoln Lab. (United States).
Developing a novel network of CBRNE sensors in response to existing capability gaps in current
technologies.
Author(s): Lukasz Szklarski, Patryk Maik, Weronika M. Walczyk, ITTI Sp. z o.o. (Poland).
Rapid detection of infrared backscatter for standoff detection of trace explosives.
Author(s): Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, U.S. Naval Research
Lab. (United States); Yohan Yoon, American Society for Engineering Education (United States); Tyler J.
Huffman, National Research Council (United States); Viet Nguyen, R. Andrew McGill, U.S. Naval
Research Lab. (United States).
Design and operation of a human color vision inspired sensor for proximate standoff detection
(conference presentation). Author(s): Kevin J. Major, Jasbinder S. Sanghera, L. Brandon Shaw, Kenneth J. Ewing, U.S. Naval
Research Lab. (United States).
Infrared spectroscopic method for uranium isotopic analysis.
Author(s): K. Alicia Strange Fessler, Savannah River National Lab. (United States); Steven M. Serkiz,
Clemson Univ. (United States); Patrick E. O'Rourke, Nicholas DeRoller, Savannah River National Lab.
(United States); Darrell Simmons, Leigh R. Martin, Oak Ridge National Lab. (United States).
ii DRDC-RDDC-2020-D100
Résumé
Ce document de référence fournit un bref résumé et un rapport sur cinq présentations portant sur les
armes chimiques, biologiques, radiologiques, nucléaires et explosives (CBRNE) qui ont été données dans
le cadre de la conférence Chemical, Biological, Radiological, Nuclear and Explosives (CBRNE) Sensing
XXI, organisée dans le cadre du SPIE Defense + Commercial Sensing Digital Forum 2020, qui peut
s’avérer d’un grand intérêt et d’une grande pertinence pour la recherche CBRNE au Centre de technologie
antiterroriste (CTA) à Centre de recherches de Suffield de Recherche et développement pour la défense
Canada. De futurs travaux de recherche dans ces domaines sont également inclus. Les présentations
suivantes sont indiquées dans le présent rapport (en ordre selon la date de consultation en ligne):
Chemical sensing via a low SWaP wearable spectrometer (La détection chimique au moyen d’un
spectromètre portable à faible SWaP). Auteurs: Richard P. Kingsborough, Alexandra T. Wrobel, Devon Beck, Lauren Cantley, Shane Tysk,
Roderick Kunz, MIT Lincoln Lab. (États-Unis).
Developing a novel network of CBRNE sensors in response to existing capability gaps in current
technologies (Mise sur pied d’un nouveau réseau de capteurs CBRNE pour pallier les lacunes
existantes des technologies actuelles).
Auteurs: Lukasz Szklarski, Patryk Maik, Weronika M. Walczyk, ITTI Sp. z o.o. (Pologne).
Rapid detection of infrared backscatter for standoff detection of trace explosives (Détection rapide
de la rétrodiffusion infrarouge pour la détection de traces d'explosifs).
Auteurs: Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, U.S. Naval Research
Lab. (États-Unis); Yohan Yoon, American Society for Engineering Education (États-Unis); Tyler J.
Huffman, National Research Council (États-Unis); Viet Nguyen, R. Andrew McGill, U.S. Naval
Research Lab. (États-Unis).
Design and operation of a human color vision inspired sensor for proximate standoff detection
(conference presentation) (Conception et exploitation d'un capteur inspiré de la vision des couleurs
humaines pour la détection de l'impasse [présentation de la conférence]). Auteurs: Kevin J. Major, Jasbinder S. Sanghera, L. Brandon Shaw, Kenneth J. Ewing, U.S. Naval
Research Lab. (États-Unis).
Infrared spectroscopic method for uranium isotopic analysis (Méthode spectroscopique infrarouge
pour l'analyse isotopique de l'uranium).
Auteurs: K. Alicia Strange Fessler, Savannah River National Lab. (États-Unis); Steven M. Serkiz,
Clemson Univ. (États-Unis); Patrick E. O'Rourke, Nicholas DeRoller, Savannah River National Lab.
(États-Unis); Darrell Simmons, Leigh R. Martin, Oak Ridge National Lab. (États-Unis).
[3] Michael J. Kangas, Raychelle M. Burks, Jordyn Atwater, Rachel M. Lukowicz, Pat Williams, and
Andrea E. Holmes. Colorimetric sensor arrays for the detection and identification of chemical
weapons and explosives. Critical Reviews in Analytical Chemistry. 2017. 47(2), 138–153.
doi: 10.1080/10408347.2016.1233805.
[4] Łukasz Szklarski, Patryk Maik, and Weronika Walczyk. Developing a novel network of CBRNe
sensors in response to existing capability gaps in current technologies. SPIE Digital Library.
Proceedings Volume 11416 Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE)
Sensing XXI. 2020. doi: 10.1117/12.2558044.
[5] Christopher A. Kendziora, Christopher J. Breshike, Yohan Yoon, Robert Furstenberg, Tyler
Huffman, and R. Andrew McGill. A system for rapid standoff detection of trace explosives by active
infrared backscatter hyperspectral imaging. SPIE Digital Library. Proceedings Volume 11392,
Algorithms, Technologies, and Applications for Multispectral and Hyperspectral Imagery XXVI.
2020. doi: 10.1117/12.2558220.
[6] Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, Yohan Yoon, Tyler
Huffman, Viet Nguyen, and R. Andrew McGill. Rapid detection of infrared backscatter for standoff
detection of trace explosives. SPIE Digital Library. Proceedings Volume 11416 Chemical, Biological,
Radiological, Nuclear, and Explosives (CBRNE) Sensing XXI. 2020.
doi: 10.1117/12.2558485.
[7] Institute of Medicine, Committee on R&D Needs for Improving Civilian Medical Response to Chemical and Biological Terrorism Incidents. Washington (DC): National Academies Press. February 12, 1999. Chapter 4, 43–64.
[8] Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, Viet Nguyen, Andrew
Kusterbeck, and R. Andrew McGill. Infrared backscatter imaging spectroscopy of trace analytes at
standoff. Journal of Applied Physics. 2019. 125(10), 104901. doi: 10.1063/1.5079622.
[9] Kevin J. Major, Jasbinder S. Sanghera, L. Brandon Shaw, and Kenneth J. Ewing. Design and
operation of a human color vision inspired sensor for proximate standoff detection. SPIE Digital
Library. Proceedings Volume 11416 Chemical, Biological, Radiological, Nuclear, and Explosives
List of Symbols/Abbreviations/Acronyms/Initialisms
BTDS
CBE
CBRNE
CIE-IR
CTTC
DA
DMMP
DND
DRDC
EU-SENSE
FTIR
HPIR
IAEA
IBIS
IR
ITV
LED
LIDAR
MATLAB
MCT
NDA
OSL
PETN
RMS
QCL
RDX
SAIR
SoS
SWaP
TIC
TIMS
TL
UAV
Bio-inspired Threat Detection System
Chemical, biological, explosive
Chemical, biological, radiological, nuclear and explosives
Infrared chromatography chart
Counter Terrorism and Technology Centre
Destructive analysis
Dimethyl methylphosphonate
Department of National Defence
Defence Research and Development Canada
European Sensor System for CBRN Applications
Fourier transform infrared
High Performance Infrared
International Atomic Energy Agency
Infrared backscatter imaging spectroscopy
Infrared
International target value
Light emitting diodes
Light Detection and Ranging
Matrix Laboratory
Mercury-cadmium-telluride
Non-destructive analysis
Optically stimulated luminescence
Pentaerythritol tetranitrate
Root mean square
Quantum cascade laser
Cyclotrimethylenetrinitramine
Standard Army Insect Repellant
System of Systems
Low size, weight and power, wearable, colorimetric chemical sensor
Toxic industrial chemicals
Thermal ionization mass spectrometry
Thermoluminescence
Unmanned arial vehicle
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Virtual Trip Report: SPIE Defense+ Commercial Sensing Digital Forum 2020
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Moise, H.; Byrne, C.
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September 2020
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This document provides a brief summary and report on five select presentations within the CBRNE stream that were seen during the Chemical, Biological, Radiological, Nuclear and Explosives (CBRNE) Sensing XXI online conference session under the umbrella of the SPIE Defense + Commercial Sensing Digital Forum 2020, which may be of great interest and relevance within CBRNE research at the Counter Terrorism and Technology Centre (CTTC) at Defense Research and Development Canada’s Suffield Research Centre. Future research work in these areas are also included. The following presentations are presented in this report (ordered as per date viewed online):
Chemical sensing via a low SWaP wearable spectrometer. Author(s): Richard P. Kingsborough, Alexandra T. Wrobel, Devon Beck, Lauren Cantley, Shane Tysk, Roderick Kunz, MIT Lincoln Lab. (United States).
Developing a novel network of CBRNe sensors in response to existing capability gaps in current technologies. Author(s): Lukasz Szklarski, Patryk Maik, Weronika M. Walczyk, ITTI Sp. z o.o. (Poland).
Rapid detection of infrared backscatter for standoff detection of trace explosives. Author(s): Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, U.S. Naval Research Lab. (United States); Yohan Yoon, American Society for Engineering Education (United States); Tyler J. Huffman, National Research Council (United States); Viet Nguyen, R. Andrew McGill, U.S. Naval Research Lab. (United States).
Design and operation of a human color vision inspired sensor for proximate standoff detection (conference presentation). Author(s): Kevin J. Major, Jasbinder S. Sanghera, L. Brandon Shaw, Kenneth J. Ewing, U.S. Naval Research Lab. (United States).
Infrared spectroscopic method for uranium isotopic analysis. Author(s): K. Alicia Strange Fessler, Savannah River National Lab. (United States); Steven M. Serkiz, Clemson Univ. (United States); Patrick E. O'Rourke, Nicholas DeRoller, Savannah River National Lab. (United States); Darrell Simmons, Leigh R. Martin, Oak Ridge National Lab. (United States).
Ce document de référence fournit un bref résumé et un rapport sur cinq présentations portant sur les armes chimiques, biologiques, radiologiques, nucléaires et explosives (CBRNE) qui ont été données dans le cadre de la conférence Chemical, Biological, Radiological, Nuclear and Explosives (CBRNE) Sensing XXI, organisée dans le cadre du SPIE Defense + Commercial Sensing Digital Forum 2020, qui peut s’avérer d’un grand intérêt et d’une grande pertinence pour la recherche CBRNE au Centre de technologie antiterroriste (CTA) à Centre de recherches de Suffield de Recherche et développement pour la défense Canada. De futurs travaux de recherche dans ces domaines sont également inclus. Les présentations suivantes sont indiquées dans le présent rapport (en ordre selon la date de consultation en ligne)
Chemical sensing via a low SWaP wearable spectrometer (La détection chimique au moyen d’un spectromètre portable à faible SWaP). Auteurs: Richard P. Kingsborough, Alexandra T. Wrobel, Devon Beck, Lauren Cantley, Shane Tysk, Roderick Kunz, MIT Lincoln Lab. (États-Unis).
Developing a novel network of CBRNE sensors in response to existing capability gaps in current technologies (Mise sur pied d’un nouveau réseau de capteurs CBRNE pour pallier les lacunes existantes des technologies actuelles). Auteurs: Lukasz Szklarski, Patryk Maik, Weronika M. Walczyk, ITTI Sp. z o.o. (Pologne).
Rapid detection of infrared backscatter for standoff detection of trace explosives (Détection rapide de la rétrodiffusion infrarouge pour la détection de traces d'explosifs). Auteurs: Christopher J. Breshike, Christopher A. Kendziora, Robert Furstenberg, U.S. Naval
Research Lab. (États-Unis); Yohan Yoon, American Society for Engineering Education (États-Unis); Tyler J. Huffman, National Research Council (États-Unis); Viet Nguyen, R. Andrew McGill, U.S. Naval Research Lab. (États-Unis).
Design and operation of a human color vision inspired sensor for proximate standoff detection (conference presentation) (Conception et exploitation d'un capteur inspiré de la vision des couleurs humaines pour la détection de l'impasse [présentation de la conférence]). Auteurs: Kevin J. Major, Jasbinder S. Sanghera, L. Brandon Shaw, Kenneth J. Ewing, U.S. Naval Research Lab. (États-Unis).
Infrared spectroscopic method for uranium isotopic analysis (Méthode spectroscopique infrarouge pour l'analyse isotopique de l'uranium). Auteurs: K. Alicia Strange Fessler, Savannah River National Lab. (États-Unis); Steven M. Serkiz, Clemson Univ. (États-Unis); Patrick E. O'Rourke, Nicholas DeRoller, Savannah River National Lab. (États-Unis); Darrell Simmons, Leigh R. Martin, Oak Ridge National Lab. (États-Unis).