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Transient Stability Constrained Optimal Power Flow Using Teaching Learning-Based Optimization

Transient Stability Constrained Optimal Power Flow Using Teaching Learning-Based Optimization

Aparajita Mukherjee, Sourav Paul, Provas Kumar Roy
Copyright: © 2014 |Volume: 3 |Issue: 4 |Pages: 17
ISSN: 2160-9500|EISSN: 2160-9543|EISBN13: 9781466654105|DOI: 10.4018/ijeoe.2014100104
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MLA

Mukherjee, Aparajita, et al. "Transient Stability Constrained Optimal Power Flow Using Teaching Learning-Based Optimization." IJEOE vol.3, no.4 2014: pp.55-71. http://doi.org/10.4018/ijeoe.2014100104

APA

Mukherjee, A., Paul, S., & Roy, P. K. (2014). Transient Stability Constrained Optimal Power Flow Using Teaching Learning-Based Optimization. International Journal of Energy Optimization and Engineering (IJEOE), 3(4), 55-71. http://doi.org/10.4018/ijeoe.2014100104

Chicago

Mukherjee, Aparajita, Sourav Paul, and Provas Kumar Roy. "Transient Stability Constrained Optimal Power Flow Using Teaching Learning-Based Optimization," International Journal of Energy Optimization and Engineering (IJEOE) 3, no.4: 55-71. http://doi.org/10.4018/ijeoe.2014100104

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Abstract

Transient stability constrained optimal power flow (TSC-OPF) is a non-linear optimization problem which is not easy to deal directly because of its huge dimension. In order to solve the TSC-OPF problem efficiently, a relatively new optimization technique named teaching learning based optimization (TLBO) is proposed in this paper. TLBO algorithm simulates the teaching–learning phenomenon of a classroom to solve multi-dimensional, linear and nonlinear problems with appreciable efficiency. Like other nature-inspired algorithms, TLBO is also a population-based method and uses a population of solutions to proceed to the global solution. The authors have explained in detail, the basic philosophy of this method. In this paper, the authors deal with the comparison of other optimization problems with TLBO in solving TSC-OPF problem. Case studies on IEEE 30-bus system WSCC 3-generator, 9-bus system and New England 10-generator, 39-bus system indicate that the proposed TLBO approach is much more computationally efficient than the other popular methods and is promising to solve TSC-OPF problem.

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