Artificial Neural Network-Based Experimental Investigations for Sliding Mode Control of an Induction Motor in Power Steering Applications

Parimalasundar, E.; Senthilkumar, R.; Kumar, B. Hemanth; Janardhan, K.; Singh, Arvind R.; Bajaj, Mohit; Bereznychenko, Viktoriia

doi:10.1155/2023/9381915

Cited by 11 publications

(3 citation statements)

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“…In addition, since the characteristics in Figs. 19,20,21 are almost non-variable, it can be confirmed that the PFC system is able to maintain the CCM operation despite the occurrence of variations in the input inductor when using the suggested predictive technique.…”

Section: Robustness To Parameter Variationsmentioning

confidence: 71%

“…Steady-state waveforms without PFC Figures 20,21 show the experimental steady-state waveforms without PFC system for constant-load and AC input voltage of 115Vrms. The AC input voltage in Fig.…”

Section: Hardware Results and Discussionmentioning

confidence: 99%

“…These control methods were employed to control the output voltage of the AC-DC rectifier, including sliding mode control (SMC) 6,14,15 , fuzzy logic 16,17 , fractional control 18 , and artificial intelligent control 19 . Sliding Mode Control, known for its simplicity and model-free implementation, requires high control efforts, potentially leading to excessive switching, increased losses, and component stress [20][21][22] . Advanced sliding regulators have been developed to mitigate these issues, but they often involve complex design and implementation processes.…”

mentioning

confidence: 99%

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A dSPACE-based implementation of ANFIS and predictive current control for a single phase boost power factor corrector

Babes,

Latrèche,

Bouafassa

et al. 2024

Sci Rep

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This paper presents an innovative control scheme designed to significantly enhance the power factor of AC/DC boost rectifiers by integrating an adaptive neuro-fuzzy inference system (ANFIS) with predictive current control. The innovative control strategy addresses key challenges in power quality and energy efficiency, demonstrating exceptional performance under diverse operating conditions. Through rigorous simulation, the proposed system achieves precise input current shaping, resulting in a remarkably low total harmonic distortion (THD) of 3.5%, which is well below the IEEE-519 standard threshold of 5%. Moreover, the power factor reaches an outstanding 0.990, indicating highly efficient energy utilization and near-unity power factor operation. To validate the theoretical findings, a 500 W laboratory prototype was implemented using the dSPACE ds1104 digital controller. Steady-state analysis reveals sinusoidal input currents with minimal THD and a power factor approaching unity, thereby enhancing grid stability and energy efficiency. Transient response tests further demonstrate the system’s robustness against load and voltage fluctuations, maintaining output voltage stability within an 18 V overshoot and a 20 V undershoot during load changes, and achieving rapid response times as low as 0.2 s. Comparative evaluations against conventional methods underscore the superiority of the proposed control strategy in terms of both performance and implementation simplicity. By harnessing the strengths of ANFIS-based voltage regulation and predictive current control, this scheme offers a robust solution to power quality issues in AC/DC boost rectifiers, promising substantial energy savings and improved grid stability. The results affirm the potential of the proposed system to set new benchmarks in power factor correction technology.

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Section: Robustness To Parameter Variationsmentioning

confidence: 71%

Section: Hardware Results and Discussionmentioning

confidence: 99%