Probabilistic duration of power estimation for Nickel- metal- hydride (NiMH) battery under constant load using Kalman filter on chip

IEEE-International Conference on Advances in Engineering, Science and Management, ICAESM-2012

Volumn , Issue , 2012, Pages 641-646

  Kumar, Anirudh ^a   Roychaudhury, Joydeb ^a   Mandal, Soumen ^a  

^a CSIR CENTRAL MECHANICAL ENGINEERING RESEARCH INSTITUTE   (India)

Author keywords

Kalman filter; Microcontroller; Recovery effect in battery; State estimation; State of charge (SOC); State space model; Surface resistance

Indexed keywords

BATTERY FAILURES; BATTERY POWER; BATTERY POWERED; BATTERY STATE OF CHARGE; CONSTANT LOADS; CRITICAL LOAD; CURRENT CONSUMPTION; ENERGY-AWARE SYSTEMS; INTERNAL PARAMETERS; MATLAB /SIMULINK; ON CHIPS; POWER ESTIMATIONS; POWER OUTAGE; PROBABILISTIC DURATION; RECOVERY EFFECTS; SAFETY CRITICAL SYSTEMS; SENSOR PREDICTION; SINGLE-CHIP MICROCONTROLLERS; SPECIFIC TASKS; STATE ESTIMATORS; STATE OF CHARGE; STATE PREDICTION; STATE SPACE MODEL; SYSTEM FAILURES; WARNING SIGNALS; WEIGHTED AVERAGES;

COMPUTER SIMULATION; CONTROLLERS; ESTIMATION; FORECASTING; KALMAN FILTERS; LEAD ACID BATTERIES; MICROCONTROLLERS; PROGRAMMABLE LOGIC CONTROLLERS; RISK PERCEPTION; SAFETY ENGINEERING; SOFTWARE TESTING; STATE ESTIMATION; STATE SPACE METHODS; SURFACE RESISTANCE; UNCERTAINTY ANALYSIS;

OUTAGES;

EID: 84863945826     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: None     Document Type: Conference Paper

References (9)

1. "Total battery production statistics in 2010 (Calender year), " Battery Association of Japan, 2011.
2. S. Yasuoka, Y.Magari, TMurata, T Tanaka, J.I shida, H. Nakamura, T Nohma, M. Kihara, Y. Baba, H. Teraoka, "Development of high capacity nickel-metal hydride batteries using super lattice hydrogen- absorbing alloys, " Journal of Power Sources, Vol. 156, pp. 662-666, 2006.
3. B. S. Bhangu, P. Bentley, D. A. Stone, and C. M. Bingham, "Nonlinear observers for predicting state-of-charge and state-of-health If lead-acid batteries for hybrid-electric vehicles, " IEEE Trans. Veh. Technol., vol. 54, pp.783-794, May.2005.
4. M. Doyle, T. F. Fuller, and J. Newman, "Modeling of galvanostatic charge and discharge of the Iithium/polymerlinsertion cell, " Journal of the Electrochemical Society, vol. 140, no. 6, pp. 1526-1533, 1993.
5. S. C. Hageman, "Simple PSpice models let you simulate common battery types, " Electronic Design News, vol. 38, pp. 117 - 129, 1993.
6. D. Rakhmatov and S. Vrudhula, "An analytical high-level battery model for use in energy management of portable electronic systems, " in Proceedings of the International Conference on Computer Aided Design (ICCAD'01), pp. 488-493, 2001.
7. J. Manwell and J. McGowan, "Lead acid battery storage model for hybrid energy systems, " Solar Energy, vol. 50, pp. 399-405, 1993.
8. V. H. Johnson, A. A. Pesaran, and T Sack, "Temperature-dependent battery models for high-power lithium-ion batteries, " presented at the Proc. EVS 17, Montreal, PQ, Canada, 2000.
9. M.R. Jongerden and B.R. Haverkort, "Battery Modeling " University of Twente, Centre for Telematics and Information Technology, Technical Report TR-CTIT-08-01, 2008.