Tuning of fractional complex‐order direct current motor controller using frequency domain analysis

Zheng, Min; Zhang, Guangfeng; Huang, Tao

doi:10.1002/mma.6653

Cited by 7 publications

(3 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The genesis of COPID controller is related to the CRONE controller (third generation) [47,48]. The complex order PID controller structure for the DC motor fractional order model in the current study is given as follows [14,20,49].…”

Section: Copid Controllermentioning

confidence: 99%

Complex Order PIa+jbDc+jd Controller Design for a Fractional Order DC Motor System

Shah¹,

Sekhar²,

Iswanto³

et al. 2021

Adv. sci. technol. eng. syst. j.

View full text Add to dashboard Cite

Fractional order controller DC motor Complex order controller Bode diagram Root locus Industry 4.0 implementation stipulates effective actuator control. In the present work, a complex order PI a+ jb D c+ jd (COPID) controller was designed for a fractional order model of a direct current (DC) motor system. For comparisons, the DC motor system model was also controlled using the conventional proportional integral (PI), proportional integral derivative (PID), proportional resonant (PR) and fractional order PID controllers (FOPID). Time domain results indicated that the PR controller performed exceedingly well for output signal responses, but fared poorly in case of control signal specifications. The PI controller responses suffered from high time domain characteristics for both control and output signals. The PID controller performed moderately in terms of time domain and peak overshoot metrics. The FOPID controller attained the best time domain characteristics, but was unable to effectively limit the control and output signal peak overshoots. It was only the COPID controller, that successfully minimised / eliminated peak overshoots in control and output signals (0.1 % and 0.0 % respectively). Moreover, the COPID controller was also successful in limiting the rise, peak and settling times. In addition, Bode diagram, root locus plot were obtained and system gain parameters were varied to confirm the robustness of the proposed COPID controller. Thus, COPID controller promises to be an effective solution towards accurate and robust actuator control in modern manufacturing.

show abstract

Section: Copid Controllermentioning

confidence: 99%

Complex Order PIa+jbDc+jd Controller Design for a Fractional Order DC Motor System

Shah¹,

Sekhar²,

Iswanto³

et al. 2021

Adv. sci. technol. eng. syst. j.

View full text Add to dashboard Cite

show abstract

“…While researchers have explored various techniques for LFC in microgrid power systems, recent efforts have focused on soft computing methods that have shown promise in enhancing load frequency control in complex energy systems. These methods include neural networks [3], fuzzy logic [4], adaptive neurofuzzy logic control [5], fractional order controller [6]- [9], complex order controller [10]- [13], Grey wolf optimization [14], differential evolution [15], particle swarm optimization [16], ant colony optimization [17], artificial bee colony [18], hybrid optimization [19], imperialist competitive algorithm [20], genetic algorithm [21], [22], teaching-learning based optimization [23]- [26], cohort intelligence optimization [27]- [31]. Researchers have investigated various aspects of complex and fractional order modeling and control in various systems [32]- [45].…”

Section: Introductionmentioning

confidence: 99%

Optimization of Load Frequency Control Gain Parameters for Stochastic Microgrid Power System

D.,

K.,

Shah

et al. 2023

Journal of Robotics and Control

View full text Add to dashboard Cite

Interconnected multi-area microgrids are vital for the future of sustainable and reliable power systems. Effective load frequency control (LFC) is indispensable for ensuring their stable operation. This paper introduces a PID-based LFC system tailored for a stochastic microgrid with diverse power sources, including solar, wind, diesel engine generators, and electrical batteries. The gain parameters of the proposed microgrid PID LFC controller are optimized using genetic algorithms (GA), teaching learning-based optimization (TLBO), and cohort intelligence algorithms. Integral time-multiplied absolute error (ITAE) and integral time-squared error (ITSE) serve as the cost functions for all optimization algorithms. The study evaluated the performance of these optimized microgrid PID LFC configurations under random step load disruptions. Our primary findings reveal that the cohort intelligence-optimized PID LFC controller excels in minimizing computation time (upto 76% and 94% lesser than GA and TLBO respectively) and exhibits superior robust response characteristics. Moreover, the cohort intelligence algorithm requires fewer iterations (upto 66% and 90% lesser than GA and TLBO respectively) and enhances power supply quality within the multi-power microgrid electrical framework, specifically in terms of effective load frequency control.

show abstract

“…In this direction, a systematic study of the generalized KdV-Burgers-Kuramoto equation using the symmetry method is presented in a previous study [23], a new (3 + 1)-dimensional KdV equation and MKdV equation with their corresponding fractional forms are presented in another study [24], and the modified Gardner type equation and its time fractional form is studied by Wang and Wazwaz [25]. Researchers are now investigating the use of complex order differ-integral operators in control theory and system modeling [26][27][28][29][30][31][32][33][34][35][36]. Although not exactly the same as this paper, there can be found studies in the literature aiming to provide frequency specifications.…”

mentioning

confidence: 99%

An examination of complex fractional order physical phenomena in IOPD controller design

Demiroğlu

Senol

Matušů

2023

Math Methods in App Sciences

View full text Add to dashboard Cite

This research focuses on the fractional complex order plant (FCOP). The significant contribution is the role of complex plant models in system stability and robustness and associated physical phenomena. A general transfer function is studied in the paper. Other plant models may be built with this structure since the FCOP is a general mathematical form covering integer order plant (IOP) and fractional order plant (FOP). Using the equations produced with the proposed technique and the recommended integer order proportional derivative (IOPD controller, physical changes in integer, fractional and complex coefficients, and orders are observed within this paper. Analysis of the plant controlled with an IOPD controller is done by applying an integrator to reveal the differences. The effects of the parameters are discussed together with the visuals, supported by simulations. The aim is to tune the controller parameters to achieve the phase and specifications as the researcher desired. It is observed that the integrator greatly takes part in reducing the steady‐state error. The IOP with the integrator showed the lowest steady‐state error, and also, the settling and overshoot time were enhanced. Increase in the phase margin also caused an increase in the phase crossover frequency. It is also observed that the fractional order affected the phase crossover frequency comparing with the IOP, and the complex order modification also had an effect comparing to the fractional order version. The complex order of the system is considered with its conjugate components in the imaginary part thus, the results are found separately for each case.

show abstract

Tuning of fractional complex‐order direct current motor controller using frequency domain analysis

Cited by 7 publications

References 30 publications

Complex Order PIa+jbDc+jd Controller Design for a Fractional Order DC Motor System

Complex Order PIa+jbDc+jd Controller Design for a Fractional Order DC Motor System

Optimization of Load Frequency Control Gain Parameters for Stochastic Microgrid Power System

An examination of complex fractional order physical phenomena in IOPD controller design

Contact Info

Product

Resources

About