Journal of VLSI Design Tools & Technology (JoVDTT)

In battery-powered technologies, also including (hybrid) electric vehicles and portable electronics, the battery management system (BMS) arises as a crucial network element. Many battery-operated industrial and commercial equipment use battery management systems (BMSs) to increase battery efficiency and enable non-destructive estimate of battery state. However, present BMSs are unable to control batteries adequately, which has an impact on the usability of products, due to the inaccurate parameter assessment of old battery cells and multi-cell batteries. This paper examines the BMS strategies already in use and suggests a new design process for a generalized dependable BMS. The proposed BMS's primary benefit over the current systems is because it offers battery protection and fault-tolerant functionality. The suggested BMS is made up of several smart battery modules (SBMs), each of which offers battery equalisation, monitoring, and protection to a line of battery cells. The findings of the laboratory testing and development of an evaluation SBM support the predictions made by theory.

Fisher, D., Lohner, A. and Mauracher, P., 1996. Battery management: Increase in the reliability of UPS. ETZ, VDE-Verlag, 117, pp. 18–22.

Noworolski, Z., Noworolski, J.M. and Bennett, C.A., 1991, March. A microcomputer-based UPS battery management system. In [Proceedings] APEC'91: Sixth Annual Applied Power Electronics Conference and Exhibition (pp. 475–479). IEEE.

Shimizu, K.I., Shirai, N. and Nihei, M., 1996. On-board battery management system with SOC indicator. JSAE Review, 4 (17), pp. 438–439.

Alzieu, J., Gagnol, P. and Smimite, H., 1995. Development of an on-board charge and discharge management system for electric-vehicle batteries. Journal of power sources, 53 (2), pp. 327–333.

Kutkut, N.H., Divan, D.M. and Novotny, D.W., 1995. Charge equalization for series connected battery strings. IEEE transactions on industry applications, 31 (3), pp. 562 568.

Kutkut, N.H., Wiegman, H.L., Divan, D.M. and Novotny, D.W., 1998. Charge equalization for an electric vehicle battery system. IEEE Transactions on Aerospace and Electronic Systems, 34 (1), pp. 235–246.

Kutkut, N.H., Wiegman, H.L., Divan, D.M. and Novotny, D.W., 1999. Design considerations for charge equalization of an electric vehicle battery system. IEEE Transactions on Industry Applications, 35 (1), pp. 28–35.

Bell, D., 2000. A battery management system (Doctoral dissertation, Master’s thesis, School Eng., Univ. Queensland, St. Lucia, Australia).

Retzlaff, W., 1992. On Board Battery Diagnostic and Charge Equalizing System (BADICHQ). Proc. of EVS-11.

Pattipati, B., Pattipati, K., Christopherson, J.P., Namburu, S.M., Prokhorov, D.V. and Qiao, L., 2008. Automotive battery management systems (pp. 581–586). IEEE.

Li, Y., Wei, X. and Sun, Z., 2009, April. Low power strategy design for battery management system. In 2009 International Conference on Measuring Technology and Mechatronics Automation (Vol. 2, pp. 636–639). IEEE.

Affanni, A., Bellini, A., Franceschini, G., Guglielmi, P. and Tassoni, C., 2005. Battery choice and management for new-generation electric vehicles. IEEE transactions on industrial electronics, 52 (5), pp. 1343–1349.

Zhu, Y., Hu, H., Xu, G. and Zhao, Z., 2009, February. Hardware-in-the-loop simulation of pure electric vehicle control system. In 2009 International Asia Conference on Informatics in Control, Automation and Robotics (pp. 254–258). IEEE.

Maharjan, L., Inoue, S., Akagi, H. and Asakura, J., 2009. State-of-charge (SOC)-balancing control of a battery energy storage system based on a cascade PWM converter. IEEE Transactions on Power Electronics, 24 (6), pp. 1628–1636.

H. Dai, X. Wei, and Z. Sun, “Model-based SOC estimation for high-power Li-ion battery packs used on FCHVs,” High Technol. Lett., vol. 13, no. 3, pp. 322–326, 2007.

Chengdongyi, H.L., Ant algorithms for power management system of wearable computer.

Bhangu, B.S., Bentley, P., Stone, D.A. and Bingham, C.M., 2005. Nonlinear observers for predicting state-of-charge and state-of-health of lead-acid batteries for hybrid-electric vehicles. IEEE transactions on vehicular technology, 54 (3), pp. 783–794.

Do, D.V., Forgez, C., Benkara, K.E.K. and Friedrich, G., 2009. Impedance observer for a Li-ion battery using Kalman filter. IEEE transactions on vehicular technology, 58 (8), pp. 3930–3937.

Goser, K., Schuhmacher, K., Hartung, M., Heesche, K., Hesse, B. and Kanstein, A., 1996, September. Neuro-fuzzy systems for engineering applications. In Proceedings of IEEE. AFRICON'96 (Vol. 2, pp. 759–764). IEEE.

Saha, B., Goebel, K., Poll, S. and Christophersen, J., 2008. Prognostics methods for battery health monitoring using a Bayesian framework. IEEE Transactions on instrumentation and measurement, 58 (2), pp. 291–296.

Gould, C.R., Bingham, C.M., Stone, D.A. and Bentley, P., 2009. New battery model and state-of-health determination through subspace parameter estimation and state-observer techniques. IEEE Transactions on Vehicular Technology, 58 (8), pp. 3905–3916.

Hussein, A.A.H. and Batarseh, I., 2011. A review of charging algorithms for nickel and lithium battery chargers. IEEE Transactions on Vehicular Technology, 60 (3), pp. 830–838.

Xiao, B., Shi, Y. and He, L., 2010, June. A universal state-of-charge algorithm for batteries. In Proceedings of the 47th Design Automation Conference (pp. 687–692).

Pattipati, B., Sankavaram, C. and Pattipati, K., 2011. System identification and estimation framework for pivotal automotive battery management system characteristics. IEEE Transactions on Systems, Man, and Cybernetics, Part C (Applications and Reviews), 41 (6), pp. 869–884.

Goser, K., Schuhmacher, K., Hartung, M., Heesche, K., Hesse, B. and Kanstein, A., 1996, September. Neuro-fuzzy systems for engineering applications. In Proceedings of IEEE. AFRICON'96 (Vol. 2, pp. 759–764). IEEE.

Pattipati, B., Sankavaram, C. and Pattipati, K., 2011. System identification and estimation framework for pivotal automotive battery management system characteristics. IEEE Transactions on Systems, Man, and Cybernetics, Part C (Applications and Reviews), 41 (6), pp. 869–884.

Do, D.V., Forgez, C., Benkara, K.E.K. and Friedrich, G., 2009. Impedance observer for a Li-ion battery using Kalman filter. IEEE transactions on vehicular technology, 58 (8), pp. 3930–3937.

Piller, S., Perrin, M. and Jossen, A., 2001. Methods for state-of-charge determination and their applications. Journal of power sources, 96 (1), pp. 113–120.

Andrews, J.M. and Johnes, R.H., 1996. A VRLA battery management system. In Proc. INTELEC (pp. 507–513).