The controlling of internal parametric variations in addition to the non-linearity of a large conversion system of wind energy (WECS) is prime challenges to make the most of the generated energy, with less power loss and secure the proficiency (η) integration conventional grid. An adjustable speed control structure of grid-connected conversion system of wind energy (WECS), with the help of a Permanent Magnet Type Synchronous Generator with intelligent controller minimizes the power loss. The control system incorporates a pair of controllers dedicated to the converters of both the generator and grid edge. The controller at the generator side has the main function is to optimize power that can be withdrawal from the wind by intelligently regulating the turbine’s rotational speed. Meanwhile, the grid edge converter effectively manages active and reactive power by manipulating the d & q-axis current components, respectively. This paper discusses about the improvement in performance of the system when using Neuro-Fuzzy system as compared to Neural Network and Management of energy deliver system via direct control method. The findings reveal that the training time for Artificial Neural Networks (ANNs) is substantial, leading to the Neural Network-Direct Power Contol (NN-DPC) approach being the slowest option among the alternatives. Additionally, the NF-DPC system is less time-consuming than the NN-DPC, with a recorded duration of 24 seconds compared to the NN-DPC’s observation of 8 min and 5 s. However, it is worth noting that the NF-DPC system is somewhat more time-intensive than Common-Direct Power Contol (C-DPC).

1. Farh HM, Eltamaly AM. Fuzzy logic control of wind energy conversion system. Journal of Renewable and Sustainable Energy 2013; 5(2): 023125. doi: 10.1063/1.4798739

2. Joselin Herbert GM, Iniyan S, Amutha D. A review of technical issues on the development of wind farms. Renewable and Sustainable Energy Reviews 2014; 32: 619–641. doi: 10.1016/j.rser.2014.01.055

3. Ackermann T, Söder L. Wind Power in Power System. Wiley; 2005. doi: 10.1002/0470012684

4. Bookman T. Wind energy’s promise, offshore. IEEE Technology and Society Magazine 2005; 24(2): 9–15. doi: 10.1109/mtas.2005.1442376

5. Das D, Pan J, Bala S. HVDC light for large offshore wind farm integration. In: Proceedings of 2012 IEEE Power Electronics and Machines in Wind Applications; 16–18 July 2012; Denver, CO, USA. doi: 10.1109/pemwa.2012.6316363

6. Flourentzou N, Agelidis VG, Demetriades GD. VSC-based HVDC power transmission systems: An overview. IEEE Transactions on Power Electronics 2009; 24(3): 592–602. doi: 10.1109/tpel.2008.2008441

7. Yaramasu V, Wu B, Sen PC, et al. High-power wind energy conversion systems: State-of-the-art and emerging technologies. Proceedings of the IEEE 2015; 103(5): 740–788. doi: 10.1109/jproc.2014.2378692

8. Wang L, Chai S, Yoo D, et al. PID and Predictive Control of Electrical Drives and Power Converters Using Matlab®/Simulink®. John Wiley & Sons Singapore Pte. Ltd; 2015. doi: 10.1002/9781118339459

9. Executive summary: World wind energy market update 2017. Available online: https://www.navigantresearch.com/research/energy-technologies/wind-energy-service (accessed on 15 November 2023).

10. Global Wind Energy Council (GWEC). Available online: https://www.gwec.net (accessed on 15 November 2023).

11. Global Wind Energy Council (GWEC). Indian wind energy: A brief outlook 2016. Available online: http://www.indianwindpower.com/pdf/GWEO_2016.pdf (accessed on 15 November 2023).

12. Wind GBI. Indian renewable energy development agency ltd.(IREDA). Available online: http://www.ireda.gov.in/forms/contentpage.aspx?lid=744 (accessed on 12 February 2018).

13. Hasanien HM. A set-membership affine projection algorithm-based adaptive-controlled SMES units for wind farms output power smoothing. IEEE Transactions on Sustainable Energy 2014; 5(4): 1226–1233. doi: 10.1109/tste.2014.2340471

14. Somayajula D, Crow ML. An ultracapacitor integrated power conditioner for intermittency smoothing and improving power quality of distribution grid. IEEE Transactions on Sustainable Energy 2014; 5(4): 1145–1155. doi: 10.1109/tste.2014.2334622

15. Boutoubat M, Mokrani L, Machmoum M. Control of a wind energy conversion system equipped by a DFIG for active power generation and power quality improvement. Renewable Energy 2013; 50: 378–386. doi: 10.1016/j.renene.2012.06.058

16. Zhan P, Lin W, Wen J, et al. Design of LCL filters for the back-to-back converter in a Doubly Fed Induction Generator. In: Proceedings of IEEE PES Innovative Smart Grid Technologies; 21–24 May 2012; Tianjin, China. doi: 10.1109/isgt-asia.2012.6303305

17. Zhou D, Blaabjerg F, Franke T, et al. Reduced cost of reactive power in doubly fed induction generator wind turbine system with optimized grid filter. IEEE Transactions on Power Electronics 2015; 30(10): 5581–5590. doi: 10.1109/tpel.2014.2374652

18. Huang M, Blaabjerg F, Yang Y, Wu W. Step by step design of a high order power filter for three-phase three-wire grid-connected inverter in renewable energy system. In: Proceedings of 2013 4th IEEE International Symposium on Power Electronics for Distributed Generation Systems (PEDG); 8–11 July 2013; Rogers, AR, USA. doi: 10.1109/pedg.2013.6785603

19. El Ouanjli N, Derouich A, El Ghzizal A, et al. A comparative study between FOC and DTC control of the Doubly Fed Induction Motor (DFIM). In: Proceedings of 2017 International Conference on Electrical and Information Technologies (ICEIT); 15–18 November 2017; Rabat, Morocco. doi: 10.1109/eitech.2017.8255302

20. El Ouanjli N, Derouich A, El Ghzizal A, et al. Direct torque control of doubly fed induction motor using three-level NPC inverter. Protection and Control of Modern Power Systems 2019; 4(1): 17. doi: 10.1186/s41601-019-0131-7

21. Taoussi M, Karim M, Hammoumi D, et al. Comparative study between backstepping adaptive and field-oriented control of the DFIG applied to wind turbines. In: Proceedings of 2017 International Conference on Advanced Technologies for Signal and Image Processing (ATSIP); 22–24 May 2017; Fez, Morocco. doi: 10.1109/atsip.2017.8075592

22. Chehaidia SE, Abderezzak A, Kherfane H, et al. An improved machine learning techniques fusion algorithm for controlsadvanced research turbine (Cart) power coefficient estimation. UPB Scientific Bulletin, Series C: Electrical Engineering 2020; 82(2): 279–292.

23. Amrane F, Chaiba A, Mekhilef S. High performances of Grid-connected DFIG based on direct power control with fixed switching frequency via MPPT strategy using MRAC and Neuro-Fuzzy control. Journal of Power Technologies 2016; 96: 27–39.

24. Baggu MM, Chowdhury BH, Kimball JW. Comparison of advanced control techniques for grid side converter of doubly-fed induction generator back-to-back converters to improve power quality performance during unbalanced voltage dips. IEEE Journal of Emerging and Selected Topics in Power Electronics 2015; 3(2): 516–524. doi: 10.1109/JESTPE.2014.2359205

25. Zhang Y, Jiao J, Xu D, et al. Model predictive direct power control of doubly fed induction generators under balanced and unbalanced network conditions. IEEE Transactions on Industry Applications 2020; 56(1): 771–786. doi: 10.1109/tia.2019.2947396

26. Sahri Y, Tamalouzt S, Belaid Lalouni S. Enhanced direct power control strategy of a DFIG-based wind energy conversion system operating under random conditions. Periodica Polytechnica Electrical Engineering 2021; 65(3): 196–206. doi: 10.3311/ppee.16656

27. Jaladi KK, Sandhu KS, Bommala P. Real-time simulator of DTC–FOC-based DFIG during voltage dip and LVRT. Journal of Control, Automation and Electrical Systems 2020; 31(2): 402–411. doi: 10.1007/s40313-019-00557-9

28. Abdullah MA, Yatim AHM, Tan CW. A study of maximum power point tracking algorithms for wind energy system. In: Proceedings of 2011 IEEE Conference on Clean Energy and Technology (CET); 27–29 June 2011; Kuala Lumpur. doi: 10.1109/cet.2011.6041484

29. Hussein MM, Orabi M, Ahmed ME, Sayed MA. Simple sensorless control technique of permanent magnet synchronous generator wind turbine. In: Proceedings of 2010 IEEE International Conference on Power and Energy; 29 November–1 December 2010; Kuala Lumpur, Malaysia. doi: 10.1109/pecon.2010.5697636

30. Mazouz F, Belkacem S, Colak I, et al. Adaptive direct power control for double fed induction generator used in wind turbine. International Journal of Electrical Power & Energy Systems 2020; 114: 105395. doi: 10.1016/j.ijepes.2019.105395

31. Moussa I, Bouallegue A, Khedher A (2015). 3 kw wind turbine emulator implementation on FPGA using MATLAB/Simulink. International Journal of Renewable Energy Research 2015; 5(4): 1154–1163.

32. Chen H, Sun S, Aliprantis DC, Zambreno J. Dynamic simulation of DFIG wind turbines on FPGA boards. In: Proceedings of 2010 Power and Energy Conference At Illinois (PECI); 12–13 February 2010; Urbana, IL, USA. doi: 10.1109/peci.2010.5437160

33. Eltamaly AM. Modelling of wind turbine driving permanent Magnet Generator with maximum power point tracking system. Journal of King Saud University-Engineering Sciences 2007; 19(2): 223–237. doi: 10.1016/S1018-3639(18)30949-8

34. Li H, Shi KL, McLaren PG. Neural-network-based sensorless maximum wind energy capture with compensated power coefficient. IEEE Transactions on Industry Applications 2005; 41(6): 1548–1556. doi: 10.1109/tia.2005.858282

35. Yang B, Yu T, Shu H, et al. Democratic joint operations algorithm for optimal power extraction of PMSG based wind energy conversion system. Energy Conversion and Management 2018; 159: 312–326. doi: 10.1016/j.enconman.2017.12.090

36. Qais MH, Hasanien HM, Alghuwainem S. A grey wolf optimizer for optimum parameters of multiple PI controllers of a grid-connected PMSG driven by variable speed wind turbine. IEEE Access 2018; 6: 44120–44128. doi: 10.1109/access.2018.2864303

37. Qais MH, Hasanien HM, Alghuwainem S. Whale optimization algorithm-based Sugeno fuzzy logic controller for fault ride-through improvement of grid-connected variable speed wind generators. Engineering Applications of Artificial Intelligence 2020; 87: 103328. doi: 10.1016/j.engappai.2019.103328

38. Amin MN, Soliman MA, Hasanien HM, Abdelaziz AY. Grasshopper optimization algorithm-based PI controller scheme for performance enhancement of a grid-connected wind generator. Journal of Control, Automation and Electrical Systems 2020; 31(2): 393–401. doi: 10.1007/s40313-020-00569-w

39. Qais MH, Hasanien HM, Alghuwainem S. Optimal transient search algorithm-based PI controllers for enhancing low voltage ride-through ability of grid-linked PMSG-based wind turbine. Electronics 2020; 9(11): 1807. doi: 10.3390/electronics9111807

40. Amin MN, Soliman MA, Hasanien HM, Abdelaziz AY. Hybrid CSA-GWO algorithm-based optimal control strategy for efficient operation of variable-speed wind generators. In: Eltamaly AM, Abdelaziz AY, Abo-Khalil AG (editors). Control and Operation of Grid-Connected Wind Energy Systems. Springer, Cham; 2021. pp. 227–245. doi: 10.1007/978-3-030-64336-2_9

41. Shutari H, Saad N, Nor NBM, et al. Towards enhancing the performance of grid-tied VSWT via adopting sine cosine algorithm-based optimal control scheme. IEEE Access 2021; 9: 139074–139088. doi: 10.1109/access.2021.3119019