From Wikipedia, the free encyclopedia
Interactive Scenario Builder (Builder ) is a
modeling and
simulation ,
three-dimensional
application developed by the Advanced Tactical Environmental Simulation Team (ATEST) at the
Naval Research Laboratory (NRL) that aids in understanding
radio frequency (RF) and
electro-optical /
infrared (EO/IR)
propagation .
[1]
[2]
[3]
[A 1]
[A 2]
[A 3]
[A 4]
[4]
[5]
[6]
[7]
[8]
Uses
Operational use
Developer information
Builder is developed by the:
[9]
Advanced Tactical Environmental Simulation Team (ATEST) (Code 5774)
Electronic Warfare Modeling & Simulation (EW M&S) Branch (Code 5770)
Tactical Electronic Warfare Division (TEWD) (Code 5700)
Systems Directorate (Code 5000)
Naval Research Laboratory (NRL)
Office of Naval Research (ONR)
A listing in the
Department of Defense (DoD) Modeling and Simulation Resource Registry (MSRR) states that "The primary objective of the Electronic Warfare Modeling and Simulation Branch is to develop and utilize tools for effectiveness evaluations of present, proposed, and future electronic warfare (EW) concepts, systems, and configurations for U.S. Naval Units."
[2] The EW M&S Branch used to be known as the Effectiveness of Navy Electronic Warfare Systems (ENEWS) Group (Code 5707) circa 2005. At that time, the Builder Team was under Code 5707.4.
[5] In an NRL "Solicitation, Offer and Award" document, the "Statement of Work" section states that "Code 5707 has historically developed simulations of naval EW systems,
anti-ship threats, and military communication systems to support the development,
fielding and testing of electronic and weapons systems."
[10]
See also
References
General references
Mathewson, B.A. (2021). Barrett, A. (ed.).
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Naval Postgraduate School . Archived from
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Chairman of the Joint Chiefs of Staff . 22 May 2020. p. H-4. Archived from
the original (PDF) on 2021-02-08. Retrieved 14 March 2021 .
Tune in to S. Strang from NRL's Advanced Tactical...
56th Annual AOC International Symposium & Convention . Washington, D.C.:
US Naval Research Laboratory . 28 October 2019. Archived from
the original on 2021-03-01. Retrieved 5 March 2021 .
"NRL Highlights New Model Enhancements" . Show Daily . National Training and Simulation Association.
I/ITSEC . 1 December 2016. Archived from
the original on 2021-02-27. Retrieved 27 February 2021 .
The Importance of Dirt in Radio-Frequency Testing and Spectrum Management (PDF) .
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the original (PDF) on 2021-03-14. Retrieved 14 March 2021 .
Zothner, T. (2 April 2015).
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the original on 2015-10-30. Retrieved 3 March 2021 .
Pywell, M. (September 2013).
Development and management of high-fidelity test technology for comprehensive performance evaluation of electronic warfare systems in multi-threat environments (PDF) (PhD thesis).
University of Central Lancashire . p. 75. Archived from
the original (PDF) on 2018-11-03. Retrieved 1 March 2021 .
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NASA
World Wind Forum . 19 October 2012. Archived from
the original on 2021-03-13. Retrieved 13 March 2021 .
Performing Electronic Attack in the U.S. & Canada for Tests, Training, and Exercises (PDF) .
Chairman of the Joint Chiefs of Staff . 20 March 2011. p. D-2. Archived from
the original (PDF) on 2020-10-25. Retrieved 14 March 2021 .
Burbank, J.L.; Kasch, W.; Ward, J. (2011). "RF Propagation Simulators". An introduction to network modeling and simulation for the practicing engineer . Hoboken, N.J.: John Wiley & Sons.
ISBN
978-1-118-06364-4 .
"TEW ~ EW Modeling/Simulation: Advanced Tactical & Environmental Simulation Section" .
US Naval Research Laboratory . Archived from
the original on 2010-02-14. Retrieved 14 February 2010 .
Andrusenko, J.; Burbank, J.; Ward, J. (1 December 2009).
"Modeling and Simulation for RF Propagation" (PDF) .
Applied Physics Laboratory . Archived from
the original (PDF) on 2021-03-01. Retrieved 1 March 2021 .
Ivanic, N.; Rivera, B.; Adamson, B. (October 2009).
"Mobile Ad Hoc Network emulation environment" . MILCOM 2009 - 2009 IEEE Military Communications Conference .
IEEE . pp. 1–6.
doi :
10.1109/MILCOM.2009.5379781 .
ISBN
978-1-4244-5238-5 .
S2CID
14810551 .
EW M&S from Engineering to Campaign .
AOC EW Modeling and Simulation Conference . Las Vegas, NV:
US Naval Research Laboratory . 29 July 2009. Retrieved 14 March 2021 .
Comparetto, G.; Marshall, J.; Mirhakkak, M.; Schult, N.; Schwartz, J.; Zhang, K.; DiOrio, D.; Thai, S. (November 2008). "Quantifying network performance of Mobile Ad-hoc Networks". MILCOM 2008 - 2008 IEEE Military Communications Conference .
IEEE . pp. 1–7.
doi :
10.1109/MILCOM.2008.4753312 .
ISBN
978-1-4244-2676-8 .
S2CID
19209139 .
Clarke, T.L. (September 2008).
"An Ontological Approach to Developing Information Operations Applications for Use on the Semantic Web" (PDF) .
Naval Postgraduate School .
Archived (PDF) from the original on 2021-03-01. Retrieved 1 March 2021 .
Defense Science and Technology Success Stories .
DoD Research and Engineering . 2007. pp. 118–119. Retrieved 1 March 2021 .
"Member News" . Naval Engineers Journal . 110 (1–3).
American Society of Naval Engineers : 10. 1998. Retrieved 1 March 2021 .
Further reading
Papers used as references
^
Murphy, R.M. (September 2005).
Analysis of High-Resolution COAMPS With Observed METOC Data to Demonstrate Atmospheric Impact on EM Propagation (PDF) (Master thesis).
Naval Postgraduate School .
CiteSeerX
10.1.1.670.379 .
Archived (PDF) from the original on 2021-02-26. Retrieved 28 August 2008 .
^
a
b
Heyer, J.; Schuette, L.C. (2004).
"Unattended Ground Sensor Network" . 2004 NRL Review .
US Naval Research Laboratory . Archived from
the original on 2007-07-13. Retrieved 29 May 2008 .
^
a
b
c
d
Schuette, L.C.; Solan, B.T. (2000).
"Electronic Warfare Simulation and Analysis" . NRL Review 2000 .
US Naval Research Laboratory : 193–195. Retrieved 27 May 2011 .
^
Darken, R.P.; Hill, T.A.; Solan, B.T.; Brookes, C.B. (1996).
"A Hybrid Virtual Environment Interface to Electronic Warfare Information" . Proceedings of the 1996 Modeling, Simulation, and Virtual Prototyping Conference .
CiteSeerX
10.1.1.12.4490 . Archived from
the original on 2021-02-26. Retrieved 29 May 2008 .
^ Holt, T.; Doyle, J.; Bucholtz, A.; Haack, T.; Jiang, Q.; Wang, S.; Strang, S.; Giampaolo, V.; Barrios, A.; Navarro, R.; Lynch, S.; Reinhardt, C. (31 October 2017).
Electromagnetic Spectrum Performance Products Ashore (EMSPPA) (PDF) .
Bridging the gap between the development and operational deployment of naval tactical decision aids . Den Helder, Netherlands:
NATO Science and Technology Organization. Archived from
the original (PDF) on 2021-03-03. Retrieved 3 March 2021 .
Other papers
Cadette, P.E.; Jones, W.L. (September 2019). "Modeling Propagation Loss in Site-Specific Non-Uniform Dielectric Urban Environments Using VTRPE". 2019 IEEE-APS Topical Conference on Antennas and Propagation in Wireless Communications (APWC) .
IEEE . pp. 113–117.
doi :
10.1109/APWC.2019.8870394 .
ISBN
978-1-7281-0566-6 .
S2CID
204820674 .
Cadette, P.; Jones, W.L. (September 2018). "Site Specific Urban Propagation Using the Variable Terrain Radiowave Parabolic Equation Model". 2018 IEEE-APS Topical Conference on Antennas and Propagation in Wireless Communications (APWC) .
IEEE . pp. 944–947.
doi :
10.1109/APWC.2018.8503786 .
ISBN
978-1-5386-6765-1 .
S2CID
53081238 .
Barbosa, J.G. (23 May 2015). Carapezza, E.M. (ed.). "Sea-air boundary meteorological sensor". Sensors, and Command, Control, Communications, and Intelligence (C3I) Technologies for Homeland Security, Defense, and Law Enforcement XIV . 9456 .
SPIE : 299–313.
Bibcode :
2015SPIE.9456E..1DB .
doi :
10.1117/12.2182677 .
S2CID
118497254 .
Abramson, M.; Will, I.; Mittu, R. (June 2011). "Hybrid tuning of an evolutionary algorithm for sensor allocation". 2011 IEEE Congress of Evolutionary Computation (CEC) .
IEEE . pp. 1672–1678.
doi :
10.1109/CEC.2011.5949816 .
ISBN
978-1-4244-7834-7 .
S2CID
8358729 .
Mittu, R.; Abramson, M.; Sjoberg, B.; Kowtha, V.; Will, I.; Ridder, J.; Murphy, J.; Naley, B. (August 2009).
"Optimization of ISR Platforms for Improved Collection in Maritime Environments" (PDF) . Defense Technical Information Center .
CiteSeerX
10.1.1.1022.8232 .
Archived (PDF) from the original on 2021-03-01. Retrieved 1 March 2021 .
Bleidorn, A. (March 2008).
"Modeling Atmospheric Effects on Wireless Networks" (PDF) .
Naval Postgraduate School .
Archived (PDF) from the original on 2021-03-01. Retrieved 1 March 2021 .
Sjoberg, B.; Szymanski, A.; Walters, J.; Durbin, J.; Malloy, D.; Will, I.; Phillippi, E.; Mamaril, C.; Lilley, K.; Dettmar, H.; Bowen, A.; Mistry, Z.; Ortiz, V. (2008).
"CREW Modeling of Effectiveness and Compatibility for Operational Test and Evaluation" (PDF) . 2008 NRL Review .
US Naval Research Laboratory : 229–231. Archived from
the original (PDF) on 2019-04-16. Retrieved 1 March 2021 .
Darken, R.P.; Hill, T.A.; Solan, B.T. (1996).
"A Hybrid Virtual Environment Interface to C3 I Information" (PDF) . 1996 NRL Review .
US Naval Research Laboratory : 181–182.
Archived (PDF) from the original on 2021-03-01. Retrieved 1 March 2021 .
Darken, R.P.; Darken, C.J. (10 April 1996). Bolas, M.T.; Fisher, S.S.; Merritt, J.O. (eds.). "VR + AI = intelligent environments: a synergistic approach to engineering design support". Stereoscopic Displays and Virtual Reality Systems III . 2653 .
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Bibcode :
1996SPIE.2653..292D .
doi :
10.1117/12.237450 .
S2CID
18452726 .
External links
This article incorporates
public domain material from the
United States Navy
ELF 3 Hz/100 Mm 30 Hz/10 Mm
SLF 30 Hz/10 Mm 300 Hz/1 Mm
ULF 300 Hz/1 Mm 3 kHz/100 km
VLF 3 kHz/100 km 30 kHz/10 km
LF 30 kHz/10 km 300 kHz/1 km
MF 300 kHz/1 km 3 MHz/100 m
HF 3 MHz/100 m 30 MHz/10 m
VHF 30 MHz/10 m 300 MHz/1 m
UHF 300 MHz/1 m 3 GHz/100 mm
SHF 3 GHz/100 mm 30 GHz/10 mm
EHF 30 GHz/10 mm 300 GHz/1 mm
THF 300 GHz/1 mm 3 THz/0.1 mm