Soldier Power Operational Benefit Analysis
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Abstract
An operational benefit analysis of military small unit power (SUP) equipment is presented in detail. SUP equipment is designed to improve power generation, conservation, and overall power management strategies for dismounted military units. The operational benefit analysis examines four tactical scenarios and considers a naïve power management strategy and a SUP enabled power management strategy. The major findings and conclusions discussed in this paper include: specific conservation and generation strategies for select dismounted tactical scenarios; the importance of proper solar blanket employment; identification of a capability gap between 100W and 1000W in the power generation spectrum; the benefits of using conformal batteries; and the impact of inefficient PRC 154 battery swaps in the naïve case.
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Published
July 16, 2015
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Carrol, A., & Heiser, G. (2010). An Analysis of Power Consumption in a Smartphone. USENIX Annual Technical Conference.
Driscoll, P., Henderson, D., & Parnell, G. (2011). Decision Making in Systems Engineering and Management. New York: Wiley.
Emerson, M., Ahuja, A., & Beckwith, J. (2014). Maneuver-Fires Exercise Phase II. Maneuver Battle Laboratory, Fort Benning, Georgia.
Fredrickson, M., & Thaler, B. (2014). Lightweight and Affordable Universal Battery Chargers and Squad Power Managers.
Jha, A. (2012). Next-Generation Batteries and Fuel Cells for Commercial, Military, and Space Applications. Boca Raton, Florida: Taylor and Francis.
Keller, J. (2013). Demand for Small Size points to Lithium-Ion Batteries for the Military's Future. Business Source Premier.
Maneuver Fires Integration Exercise. (2014). MFIX Phase II Assessed Technologies.
PV Education. Solar Radiation on a Tilted Surface. Retrieved January, 2015, from http://www.pveducation.org/pvcdrom/properties-of-sunlight/solar-radiation-on-tilted-surface.
Rosen, J., & Walsh, J. (2011). The Nett Warrior System: A Case Study for the Acquisition of Soldier Systems. Acquisition Research Sponsored Report Series.
Shafran, S. (2014). Evaluation of Soldier Power Manager. APD Battery T&E Report.
Shukla, K. (2014). OECIF Program Review Soldier and Small Unit Operational Energy Program. U.S Army NATICK Soldier RD&E Center.
Smith, Christian. (2011). Nett Warrior C3Conflict Experiment: Measuring the Effect of Battlefield Awareness in Small Units. Naval Postgraduate School.
Ultra Electronics. (2012). Man Portable Fuel Cell Generator –Right Sizing Power Solutions.
U.S. Army, Program Executive Office Soldier, Soldier System Integration. (2014). Dismounted Baseline Version 1.0 for the Soldier System.
Warner, Chris. (2014). Deployable Renewable Energy Systems Power Critical Equipment on the Battlefield. ECN Magazine. Retrieved February, 2015, from http://www.ecnmag.com/articles/2014/07/deployable-renewable-energy-systems-power-critical-equipment-battlefield
How to Cite
Soldier Power Operational Benefit Analysis. (2015). Industrial and Systems Engineering Review, 3(2), 82-90. https://doi.org/10.37266/ISER.2015v3i2.pp82-90
How to Cite
Soldier Power Operational Benefit Analysis. (2015). Industrial and Systems Engineering Review, 3(2), 82-90. https://doi.org/10.37266/ISER.2015v3i2.pp82-90
