Every conceptual framework requires several developmental stages such as prototyping, preproduction and production stages. This paper considers prototype developmental stage which entails design, modelling and simulation for the conceptual system to determine suitable parameters and specifications before the production task is initiation. The inability to represent the conceptual control system with mathematical equivalence would hamper on the system operational efficiency, stability, controllability and observability; would not be guaranteed. This paper focuses on the modelling and simulation of intelligent master controller for hybridized power pool deployment. This is achieved using state space mathematical model, MATLAB/Simulink and proteus software. The state space model provides the mathematical equation for the system stability, controllability and observability criteria from the system transfer function. The MATLAB/Simulink software provides response trends and the Proteus software provides the virtual implementation platform for concept validation with its code written in Arduino (IDE). The system was demonstrated through simulation and the virtual results showed that the system capability in fostering intelligent control commands in the hybridized power pool scenario. The system stability was determined using Root locus, Nyquist and Routh Hurwitz criteria. Subsequent research efforts are being made towards implementing the design optimizable on the hardware using the design specifications.
| Published in | American Journal of Electrical Power and Energy Systems (Volume 10, Issue 6) |
| DOI | 10.11648/j.epes.20211006.12 |
| Page(s) | 109-118 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Deployment, Hybridized Power Pool, Intelligent Master Controller, Modelling, Simulation
| [1] | Heussen, K., Saleem, A. & Lind, M. (2009). Control architecture of power systems: Modeling of purpose and function. IEEE Power and Energy Society General Meeting, PES ’09, 2009, 1–8. |
| [2] | Zhang, W., Zhu, Q., Mobayen, S., Yan, H., Qiu, J. & Narayan, P. (2020). U -Model and U -Control Methodology for Nonlinear Dynamic Systems. Complexity, 1–13. |
| [3] | Alexandridis, A. T. (2020). Modern Power System Dynamics, Stability and Control. Energies, 13 (15), 1–8. |
| [4] | Michaels, L., Pagerit, S., Rousseau, A., Sharer, P., Halbach, S., Vijayagopal, R., Kropinski, M., Matthews, G., Kao, M., Matthews, O., Steele, M., & Will, A. (2010). Model-based systems engineering and control system development via virtual hardware-in-the-loop simulation. SAE Technical Papers, October. https://doi.org/10.4271/2010-01-2325 |
| [5] | Mu, S., Wang, H., Hou, J., & Wang, T. (2019). Fast Electromagnetic Transient Simulation Model of Photovoltaic Power System. 2018 International Conference on Power System Technology, POWERCON 2018 - Proceedings, 201804270000731, 286–291. https://doi.org/10.1109/POWERCON.2018.8602037 |
| [6] | Jack, K. E., Affia, N. J., Onu, U. G., Okekenwa, Ezugwu, E. E. O. & Udofa, E. S. (2021). Real time energy monitoring and control model for peer-to-peer integrated hybrid supply system,” in 2021 IEEE PES/IAS PowerAfrica, PowerAfrica 2021, 1–5. |
| [7] | Ezugwu, E. O., Aniagu, C. E., Okozi,, S. O., Jack, K. E. & Uzoechi, L. O. (2021). Design and Evaluation of a Hybridized Energy System for Remote Palm Oil Mill and Community. International Journal Mechatronics, Electrical Computer Technology, 11 (40), 4983–4988. |
| [8] | Neumann, F. and Brown, T. (2020). The near-optimal feasible space of a renewable power system model. Electrical Power System Research., 190 (0), 106690. |
| [9] | Hu, M., Fu, C., Wang, J. S., Rao, H., & Liu, H. B. (2012). Real time digital simulation of the parallel multi-terminal HVDC transmission system. 2012 IEEE International Conference on Power System Technology, POWERCON 2012, 1–5. https://doi.org/10.1109/PowerCon.2012.6401417 |
| [10] | Dasu, B., Mangipudi, S. & Rayapudi, S. (2021) Small signal stability enhancement of a large scale power system using a bio-inspired whale optimization algorithm. Prot. Control Mod. Protection and Control of Modern Power System, 6 (35), 1–17. |
| [11] | Olubiwe M.& Uzoechi, L. O. (2014). Modelling of Three Phase Short Circuit and Measuring Parameters of a Turbo Generator for Improved Performance,” International Journal of Engineering Research Technology, 3 (4), 2264–2269. |
| [12] | Lin, J., Tong, X., Wang, X., & Wang, W. (2008). Parallel simulation for the transient stability of power system. 3rd International Conference on Deregulation and Restructuring and Power Technologies, DRPT 2008, April, 1325–1329. https://doi.org/10.1109/DRPT.2008.4523611 |
| [13] | Meng, H., & Song, X. (2012). The modeling and simulation of command and control system based on capability characteristics. Communications in Computer and Information Science, 327 CCIS (PART 2), 255–261. https://doi.org/10.1007/978-3-642-34396-4_31 |
| [14] | Naşcu, I., De Keyser, R., Naçcu, I., & Buzdugan, T. (2010). Modeling and simulation of a level control system. 2010 IEEE International Conference on Automation, Quality and Testing, Robotics, AQTR 2010 - Proceedings, 1, 181–186. https://doi.org/10.1109/AQTR.2010.55208 |
| [15] | Matej Krpan & Igor Kuzle (2018) Introducing low-order system frequency response modelling of a future power system with high penetration of wind power plants with frequency support capabilities. The Institution of Engineering and Technology (IET): Renewable Power Generation, 1-9. |
| [16] | Qing, K., Xi, X., Zanxiang, N., Lipei, H., & Kai, S. (2013). Design of grid-connected directly driven wave power generation system with optimal control of output power. 2013 15th European Conference on Power Electronics and Applications, EPE 2013. https://doi.org/10.1109/EPE.2013.6631811 |
| [17] | Dritsas, L., Kontouras, E., Vlahakis E., Kitsios, I, Halikias, G. & Tzes, A. (2020). Modelling issues and aggressive robust load frequency control of interconnected electric power systems. International Journal Control, 0 (0), 1–15. |
| [18] | Mora, E. & Steinke, F. (2021). On the minimal set of controllers and sensors for linear power flow. Electr. Power Syst. Res., 190 (0), 106647. |
| [19] | Yang-Wu, S., Xun, M., Ao, P., Yang-Guang, W., Ting, C., DIng, W., & Jian, Z. (2019). Load Frequency Control Strategy for Wind Power Grid-connected Power Systems Considering Wind Power Forecast. 2019 3rd IEEE Conference on Energy Internet and Energy System Integration: Ubiquitous Energy Network Connecting Everything, EI2 2019, 1124–1128. https://doi.org/10.1109/EI247390.2019.906208 |
APA Style
Kufre Esenowo Jack, Damian Obioma Dike, Matthew Olubiwe, Jude-Kennedy Chibuzo Obichere, Nkwachukwu Chukwuchekwa, et al. (2021). Modelling and Simulation of Intelligent Master Controller Model for Hybridized Power Pool Deployment. American Journal of Electrical Power and Energy Systems, 10(6), 109-118. https://doi.org/10.11648/j.epes.20211006.12
ACS Style
Kufre Esenowo Jack; Damian Obioma Dike; Matthew Olubiwe; Jude-Kennedy Chibuzo Obichere; Nkwachukwu Chukwuchekwa, et al. Modelling and Simulation of Intelligent Master Controller Model for Hybridized Power Pool Deployment. Am. J. Electr. Power Energy Syst. 2021, 10(6), 109-118. doi: 10.11648/j.epes.20211006.12
AMA Style
Kufre Esenowo Jack, Damian Obioma Dike, Matthew Olubiwe, Jude-Kennedy Chibuzo Obichere, Nkwachukwu Chukwuchekwa, et al. Modelling and Simulation of Intelligent Master Controller Model for Hybridized Power Pool Deployment. Am J Electr Power Energy Syst. 2021;10(6):109-118. doi: 10.11648/j.epes.20211006.12
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Download@article{10.11648/j.epes.20211006.12,
author = {Kufre Esenowo Jack and Damian Obioma Dike and Matthew Olubiwe and Jude-Kennedy Chibuzo Obichere and Nkwachukwu Chukwuchekwa and Lazarus Okechukwu Uzoechi},
title = {Modelling and Simulation of Intelligent Master Controller Model for Hybridized Power Pool Deployment},
journal = {American Journal of Electrical Power and Energy Systems},
volume = {10},
number = {6},
pages = {109-118},
doi = {10.11648/j.epes.20211006.12},
url = {https://doi.org/10.11648/j.epes.20211006.12},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.epes.20211006.12},
abstract = {Every conceptual framework requires several developmental stages such as prototyping, preproduction and production stages. This paper considers prototype developmental stage which entails design, modelling and simulation for the conceptual system to determine suitable parameters and specifications before the production task is initiation. The inability to represent the conceptual control system with mathematical equivalence would hamper on the system operational efficiency, stability, controllability and observability; would not be guaranteed. This paper focuses on the modelling and simulation of intelligent master controller for hybridized power pool deployment. This is achieved using state space mathematical model, MATLAB/Simulink and proteus software. The state space model provides the mathematical equation for the system stability, controllability and observability criteria from the system transfer function. The MATLAB/Simulink software provides response trends and the Proteus software provides the virtual implementation platform for concept validation with its code written in Arduino (IDE). The system was demonstrated through simulation and the virtual results showed that the system capability in fostering intelligent control commands in the hybridized power pool scenario. The system stability was determined using Root locus, Nyquist and Routh Hurwitz criteria. Subsequent research efforts are being made towards implementing the design optimizable on the hardware using the design specifications.},
year = {2021}
}
TY - JOUR T1 - Modelling and Simulation of Intelligent Master Controller Model for Hybridized Power Pool Deployment AU - Kufre Esenowo Jack AU - Damian Obioma Dike AU - Matthew Olubiwe AU - Jude-Kennedy Chibuzo Obichere AU - Nkwachukwu Chukwuchekwa AU - Lazarus Okechukwu Uzoechi Y1 - 2021/12/29 PY - 2021 N1 - https://doi.org/10.11648/j.epes.20211006.12 DO - 10.11648/j.epes.20211006.12 T2 - American Journal of Electrical Power and Energy Systems JF - American Journal of Electrical Power and Energy Systems JO - American Journal of Electrical Power and Energy Systems SP - 109 EP - 118 PB - Science Publishing Group SN - 2326-9200 UR - https://doi.org/10.11648/j.epes.20211006.12 AB - Every conceptual framework requires several developmental stages such as prototyping, preproduction and production stages. This paper considers prototype developmental stage which entails design, modelling and simulation for the conceptual system to determine suitable parameters and specifications before the production task is initiation. The inability to represent the conceptual control system with mathematical equivalence would hamper on the system operational efficiency, stability, controllability and observability; would not be guaranteed. This paper focuses on the modelling and simulation of intelligent master controller for hybridized power pool deployment. This is achieved using state space mathematical model, MATLAB/Simulink and proteus software. The state space model provides the mathematical equation for the system stability, controllability and observability criteria from the system transfer function. The MATLAB/Simulink software provides response trends and the Proteus software provides the virtual implementation platform for concept validation with its code written in Arduino (IDE). The system was demonstrated through simulation and the virtual results showed that the system capability in fostering intelligent control commands in the hybridized power pool scenario. The system stability was determined using Root locus, Nyquist and Routh Hurwitz criteria. Subsequent research efforts are being made towards implementing the design optimizable on the hardware using the design specifications. VL - 10 IS - 6 ER -
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