Hybrid Electric Vehicle Characterization Using Generalized Notion of Power
Keywords:
Electric machines, hybrid electric vehicles, internal combustion engines, magnetostatics, mathematical modelsAbstract
This paper presents a novel mathematical model based on the generalized notion of power (GNP) to accurately predict the performance characteristics of hybrid electric vehicles (HEVs). The uniqueness of this technique is the ability to represent both internal combustion engine and electrical propulsion machines in one system of state space equations. Thus, it allows proper characterization and control of the interaction of both systems by taking into account large and small load disturbances and the irreversibility of entropy generation by the internal combustion engine. The superiority of the proposed model is demonstrated by applying it to a prototype HEV configuration and by comparison to readily available benchmark data.
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N. Al-Aawar, A. Hanbali and A. Arkadan, “Characterization and design optimization of ALA rotor synchronous reluctance motor drives for traction applications,” 22nd Annual Review of Progress in Applied Computational Electromagnetics (ACES), pp. 249-256, Florida, USA, March 2006.
USA DOE Plug-in Hybrid Electric Vehicle R&D Plan, 2007.
S. Barmada, M. Raugi, and M. Tucci, “Analysis of power line communications channels on board a fully electric vehicle,” 26th Annual Review of Progress in Applied Computational Electromagnetics (ACES), pp. 441-446, Tampere, Finland, April 2010.
A. Roussea, P. Sharer, and F. Besnier, “Feasibility of reusable vehicle modeling: Application to hybrid vehicles,” SAE World Congress, Detroit, March 2004.
L. Boulon, A. Bouscayrol, D. Hissel, O. Page, and M.-C. Pera, “Inversion–based control of highly redundant military HEV,” IEEE Transactions on Vehicular Technology, vol. 62, no. 2, pp. 500-510, 2013.
N. Barcaro, N. Bianchi, and F. Magnussen, “PM motor for hybrid electric vehicle,” The Open Fuels and Energy Science Journal, pp. 135-141, 2009.
A. Arkadan, R. Heiden, and J. Defenbaugh, “Effects of forced power transfer on high speed generator-load system,” IEEE Transactions on Energy Conversion, vol. 11, no. 2, pp. 344-352, June 1996.
N. Al-Aawar, T. Hijazi, and A. Arkadan, “Particle swarm optimization of coupled electromechanical systems,” IEEE Transaction On Magnetics, vol. 47, no. 5, pp. 1314-1317, 2011.
P. Curto-Risso, “Theoretical and simulated models for irreversible Otto cycle,” IEEE Journal of Applied Physics, vol. 104, no. 9, pp. 094911- 094911-11, Nov. 2008.
J. Ginsberg, Advanced Engineering Dynamics, 2nd ed. Cambridge, UK: Cambridge University Press, ISBN: 9780521470216, 1995.
