NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios

Bernd Eberle; Wesley T. Kinerk; Michael Koerber; Johan Öhgren; Gunnar Ritt; Cristiane N. Santos; Bastian Schwarz; Ove Steinvall; Sean M. Tipper; Marijke Vandewal; Christopher L. Westgate

doi:10.1117/12.2533744

NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios

Bernd Eberle, Wesley T. Kinerk, Michael Koerber, Johan Öhgren, Gunnar Ritt, Cristiane N. Santos, Bastian Schwarz, Ove Steinvall, Sean M. Tipper, Marijke Vandewal, Christopher L. Westgate

Laser & Optronics Lab

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

In October 2018, NATO SET-249 performed a common trial at WTD 52, Oberjettenberg, Germany, to study laser dazzle effects in an airborne scenario. The facility is equipped with a cable car and is ideal for slanted path experiments from the base station to the cable car where the sensors were mounted. NATO SET-249's background is laser threat evaluation and the evaluation of the impact of laser eye dazzle on the visual performance of humans. This work gives an overview on the various measurements performed here: 1. Assessment of dazzle effects originating from light scattering at an aircraft canopy by comparing the images of two cameras: one outside and one inside the canopy. The general findings showed that the canopy, which had been used previously on an aircraft, substantially affected the dazzle pattern in the camera within the canopy as compared to the camera outside. 2. Sensor dazzling: Laser dazzling of complementary metal-oxide-semiconductor (CMOS) cameras in the visible domain and, in addition, laser dazzling of a camera equipped with a fisheye lens, which is commonly present in micro-unmanned aerial vehicles, is demonstrated. The dazzled area in the camera field of view (FoV) grows with increasing laser irradiance, and dazzling is effective at irradiance levels around a few μW/cm². 3. An overview on realistic handheld laser engagement scenarios to test the capabilities of a DSTL-developed Laser Event Recorder (LER) is provided. This technology is able to detect continuous wave (CW) and pulsed lasers, and extract their wavelengths, irradiances, Pulse Repetition Frequency (PRF) and directionality. Applications for this LER include collecting information on aircraft laser exposure events, giving information to assess if engagements are eye safe. 4. Measurements performed on various Fraunhofer IOSB developed sensor systems hardened against laser dazzle: The hardening measure of these systems is based either on the use of spatial light modulators or on the implementation of the principle of complementary wavelength bands. The field trial offered the possibility to generate data of the hardened systems under real life conditions.

Original language	English
Title of host publication	Technologies for Optical Countermeasures XVI
Editors	David H. Titterton, Robert J. Grasso, Mark A. Richardson
Publisher	Society of Photo-Optical Instrumentation Engineers
ISBN (Electronic)	9781510630253
DOIs	https://doi.org/10.1117/12.2533744
Publication status	Published - 2019
Event	Technologies for Optical Countermeasures XVI 2019 - Strasbourg, France Duration: 10 Sept 2019 → 11 Sept 2019

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	11161
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Technologies for Optical Countermeasures XVI 2019
Country/Territory	France
City	Strasbourg
Period	10/09/19 → 11/09/19

Keywords

Canopy Scattering
Laser Event Recorder
Laser dazzle
Micro-UAS Dazzling
Sensor Hardening

Access to Document

10.1117/12.2533744

Cite this

Eberle, B., Kinerk, W. T., Koerber, M., Öhgren, J., Ritt, G., Santos, C. N., Schwarz, B., Steinvall, O., Tipper, S. M., Vandewal, M., & Westgate, C. L. (2019). NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios. In D. H. Titterton, R. J. Grasso, & M. A. Richardson (Eds.), Technologies for Optical Countermeasures XVI Article 111610C (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11161). Society of Photo-Optical Instrumentation Engineers. https://doi.org/10.1117/12.2533744

Eberle, Bernd ; Kinerk, Wesley T. ; Koerber, Michael et al. / NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios. Technologies for Optical Countermeasures XVI. editor / David H. Titterton ; Robert J. Grasso ; Mark A. Richardson. Society of Photo-Optical Instrumentation Engineers, 2019. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{bcce6d477d4f4e98871bd885a1951df0,

title = "NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios",

abstract = "In October 2018, NATO SET-249 performed a common trial at WTD 52, Oberjettenberg, Germany, to study laser dazzle effects in an airborne scenario. The facility is equipped with a cable car and is ideal for slanted path experiments from the base station to the cable car where the sensors were mounted. NATO SET-249's background is laser threat evaluation and the evaluation of the impact of laser eye dazzle on the visual performance of humans. This work gives an overview on the various measurements performed here: 1. Assessment of dazzle effects originating from light scattering at an aircraft canopy by comparing the images of two cameras: one outside and one inside the canopy. The general findings showed that the canopy, which had been used previously on an aircraft, substantially affected the dazzle pattern in the camera within the canopy as compared to the camera outside. 2. Sensor dazzling: Laser dazzling of complementary metal-oxide-semiconductor (CMOS) cameras in the visible domain and, in addition, laser dazzling of a camera equipped with a fisheye lens, which is commonly present in micro-unmanned aerial vehicles, is demonstrated. The dazzled area in the camera field of view (FoV) grows with increasing laser irradiance, and dazzling is effective at irradiance levels around a few μW/cm2. 3. An overview on realistic handheld laser engagement scenarios to test the capabilities of a DSTL-developed Laser Event Recorder (LER) is provided. This technology is able to detect continuous wave (CW) and pulsed lasers, and extract their wavelengths, irradiances, Pulse Repetition Frequency (PRF) and directionality. Applications for this LER include collecting information on aircraft laser exposure events, giving information to assess if engagements are eye safe. 4. Measurements performed on various Fraunhofer IOSB developed sensor systems hardened against laser dazzle: The hardening measure of these systems is based either on the use of spatial light modulators or on the implementation of the principle of complementary wavelength bands. The field trial offered the possibility to generate data of the hardened systems under real life conditions.",

keywords = "Canopy Scattering, Laser Event Recorder, Laser dazzle, Micro-UAS Dazzling, Sensor Hardening",

author = "Bernd Eberle and Kinerk, \{Wesley T.\} and Michael Koerber and Johan {\"O}hgren and Gunnar Ritt and Santos, \{Cristiane N.\} and Bastian Schwarz and Ove Steinvall and Tipper, \{Sean M.\} and Marijke Vandewal and Westgate, \{Christopher L.\}",

note = "Publisher Copyright: {\textcopyright} 2019 SPIE.; Technologies for Optical Countermeasures XVI 2019 ; Conference date: 10-09-2019 Through 11-09-2019",

year = "2019",

doi = "10.1117/12.2533744",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "Society of Photo-Optical Instrumentation Engineers",

editor = "Titterton, \{David H.\} and Grasso, \{Robert J.\} and Richardson, \{Mark A.\}",

booktitle = "Technologies for Optical Countermeasures XVI",

}

Eberle, B, Kinerk, WT, Koerber, M, Öhgren, J, Ritt, G, Santos, CN, Schwarz, B, Steinvall, O, Tipper, SM, Vandewal, M & Westgate, CL 2019, NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios. in DH Titterton, RJ Grasso & MA Richardson (eds), Technologies for Optical Countermeasures XVI., 111610C, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11161, Society of Photo-Optical Instrumentation Engineers, Technologies for Optical Countermeasures XVI 2019, Strasbourg, France, 10/09/19. https://doi.org/10.1117/12.2533744

NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios. / Eberle, Bernd; Kinerk, Wesley T.; Koerber, Michael et al.
Technologies for Optical Countermeasures XVI. ed. / David H. Titterton; Robert J. Grasso; Mark A. Richardson. Society of Photo-Optical Instrumentation Engineers, 2019. 111610C (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11161).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios

AU - Eberle, Bernd

AU - Kinerk, Wesley T.

AU - Koerber, Michael

AU - Öhgren, Johan

AU - Ritt, Gunnar

AU - Santos, Cristiane N.

AU - Schwarz, Bastian

AU - Steinvall, Ove

AU - Tipper, Sean M.

AU - Vandewal, Marijke

AU - Westgate, Christopher L.

PY - 2019

Y1 - 2019

N2 - In October 2018, NATO SET-249 performed a common trial at WTD 52, Oberjettenberg, Germany, to study laser dazzle effects in an airborne scenario. The facility is equipped with a cable car and is ideal for slanted path experiments from the base station to the cable car where the sensors were mounted. NATO SET-249's background is laser threat evaluation and the evaluation of the impact of laser eye dazzle on the visual performance of humans. This work gives an overview on the various measurements performed here: 1. Assessment of dazzle effects originating from light scattering at an aircraft canopy by comparing the images of two cameras: one outside and one inside the canopy. The general findings showed that the canopy, which had been used previously on an aircraft, substantially affected the dazzle pattern in the camera within the canopy as compared to the camera outside. 2. Sensor dazzling: Laser dazzling of complementary metal-oxide-semiconductor (CMOS) cameras in the visible domain and, in addition, laser dazzling of a camera equipped with a fisheye lens, which is commonly present in micro-unmanned aerial vehicles, is demonstrated. The dazzled area in the camera field of view (FoV) grows with increasing laser irradiance, and dazzling is effective at irradiance levels around a few μW/cm2. 3. An overview on realistic handheld laser engagement scenarios to test the capabilities of a DSTL-developed Laser Event Recorder (LER) is provided. This technology is able to detect continuous wave (CW) and pulsed lasers, and extract their wavelengths, irradiances, Pulse Repetition Frequency (PRF) and directionality. Applications for this LER include collecting information on aircraft laser exposure events, giving information to assess if engagements are eye safe. 4. Measurements performed on various Fraunhofer IOSB developed sensor systems hardened against laser dazzle: The hardening measure of these systems is based either on the use of spatial light modulators or on the implementation of the principle of complementary wavelength bands. The field trial offered the possibility to generate data of the hardened systems under real life conditions.

AB - In October 2018, NATO SET-249 performed a common trial at WTD 52, Oberjettenberg, Germany, to study laser dazzle effects in an airborne scenario. The facility is equipped with a cable car and is ideal for slanted path experiments from the base station to the cable car where the sensors were mounted. NATO SET-249's background is laser threat evaluation and the evaluation of the impact of laser eye dazzle on the visual performance of humans. This work gives an overview on the various measurements performed here: 1. Assessment of dazzle effects originating from light scattering at an aircraft canopy by comparing the images of two cameras: one outside and one inside the canopy. The general findings showed that the canopy, which had been used previously on an aircraft, substantially affected the dazzle pattern in the camera within the canopy as compared to the camera outside. 2. Sensor dazzling: Laser dazzling of complementary metal-oxide-semiconductor (CMOS) cameras in the visible domain and, in addition, laser dazzling of a camera equipped with a fisheye lens, which is commonly present in micro-unmanned aerial vehicles, is demonstrated. The dazzled area in the camera field of view (FoV) grows with increasing laser irradiance, and dazzling is effective at irradiance levels around a few μW/cm2. 3. An overview on realistic handheld laser engagement scenarios to test the capabilities of a DSTL-developed Laser Event Recorder (LER) is provided. This technology is able to detect continuous wave (CW) and pulsed lasers, and extract their wavelengths, irradiances, Pulse Repetition Frequency (PRF) and directionality. Applications for this LER include collecting information on aircraft laser exposure events, giving information to assess if engagements are eye safe. 4. Measurements performed on various Fraunhofer IOSB developed sensor systems hardened against laser dazzle: The hardening measure of these systems is based either on the use of spatial light modulators or on the implementation of the principle of complementary wavelength bands. The field trial offered the possibility to generate data of the hardened systems under real life conditions.

KW - Canopy Scattering

KW - Laser Event Recorder

KW - Laser dazzle

KW - Micro-UAS Dazzling

KW - Sensor Hardening

UR - https://www.scopus.com/pages/publications/85077185014

U2 - 10.1117/12.2533744

DO - 10.1117/12.2533744

M3 - Conference contribution

AN - SCOPUS:85077185014

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Technologies for Optical Countermeasures XVI

A2 - Titterton, David H.

A2 - Grasso, Robert J.

A2 - Richardson, Mark A.

PB - Society of Photo-Optical Instrumentation Engineers

T2 - Technologies for Optical Countermeasures XVI 2019

Y2 - 10 September 2019 through 11 September 2019

ER -

Eberle B, Kinerk WT, Koerber M, Öhgren J, Ritt G, Santos CN et al. NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios. In Titterton DH, Grasso RJ, Richardson MA, editors, Technologies for Optical Countermeasures XVI. Society of Photo-Optical Instrumentation Engineers. 2019. 111610C. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2533744

NATO SET-249 joint measurement campaign on laser dazzle effects in airborne scenarios

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