Derivative-Free Direct Search Optimization Method for Enhancing Performance of Analytical Design Approach-Based Digital Controller for Switching Regulator

Although an analytical design approach-based digital controller—which is essentially a deadbeat controller—shows zero steady-state error and no intersampling oscillations, it takes a finite number of sampling periods to settle down to a steady-state value. This paper describes the application of a derivative-free Nelder–Mead (N–M) simplex method to the digital controller for retuning of its coefficients intelligently to ensure improved settling and rise times without disturbing the deadbeat controller characteristics (i.e., no ripples between the sampling periods and no steady-state error). A switching-mode buck regulator working at 1 MHz in continuous conduction mode (CCM) is considered as a plant. Numerical simulation results depict that the N–M algorithm-based optimized digital controller not only shows improved steady-state and transient performance but also guarantees rigorous robustness against model uncertainty and disturbance as compared to its traditional counterpart, as well as the other optimized digital controller fine-tuned through other derivative-free metaheuristic optimization techniques, such as the genetic algorithm (GA). A system generator-based hardware software co-simulation is also performed to validate the simulation results.

[1]  Konstantinos G Papadopoulos,et al.  Explicit analytical tuning rules for digital PID controllers via the magnitude optimum criterion. , 2017, ISA transactions.

[2]  Shantanu Das,et al.  Design and Realization of Stand-Alone Digital Fractional Order PID Controller for Buck Converter Fed DC Motor , 2016, Circuits Syst. Signal Process..

[3]  Slobodan Cuk,et al.  A general unified approach to modelling switching-converter power stages , 1976, 1970 IEEE Power Electronics Specialists Conference.

[4]  Yang Xu,et al.  Design of a single-input fuzzy PID controller based on genetic optimization scheme for DC-DC buck converter , 2015, 2015 International Symposium on Next-Generation Electronics (ISNE).

[5]  Pengfei Song,et al.  Robust Output Voltage Regulation for DC–DC Buck Converters Under Load Variations via Sampled-Data Sensorless Control , 2018, IEEE Access.

[6]  Lorenzo Ntogramatzidis,et al.  Direct Digital Design of PIDF Controllers with ComPlex Zeros for DC-DC Buck Converters , 2018, Energies.

[7]  Eduardo I. Silva,et al.  Optimal design of ripple-free deadbeat controllers based on an ITSE index , 2010, 18th Mediterranean Conference on Control and Automation, MED'10.

[8]  Bin Wu,et al.  New digital control method for power factor correction , 2006, IEEE Transactions on Industrial Electronics.

[9]  M. Veerachary,et al.  Deadbeat controller for double-boost DC-DC converter , 2014, International Conference for Convergence for Technology-2014.

[10]  Xiongfei Wang,et al.  Model-based control design of Series Resonant Converter based on the Discrete Time Domain Modelling Approach for DC Wind Turbine , 2018 .

[11]  Fred C. Lee,et al.  Unified Equivalent Circuit Model and Optimal Design of $V^{2}$ Controlled Buck Converters , 2016, IEEE Transactions on Power Electronics.

[12]  Maher Al-Greer,et al.  Real-Time Parameter Estimation of DC–DC Converters Using a Self-Tuned Kalman Filter , 2017, IEEE Transactions on Power Electronics.

[13]  Zheng-Guang Wu,et al.  Sampled-Data Control With Adjustable Switching Frequency for DC–DC Converters , 2019, IEEE Transactions on Industrial Electronics.

[14]  Rami A. Maher,et al.  Design and implementation of a discrete variable gain controller based on a numerical approach , 2017, 2017 14th International Multi-Conference on Systems, Signals & Devices (SSD).

[15]  Muhammad Usman Asad,et al.  Compensation of the nonlinearities present in the digital control loop , 2016, 2016 International Conference on Intelligent Systems Engineering (ICISE).

[16]  Frede Blaabjerg,et al.  Small-Signal Modeling and Comprehensive Analysis of Magnetically Coupled Impedance-Source Converters , 2016, IEEE Transactions on Power Electronics.

[17]  M. Ranjani,et al.  Optimal fuzzy controller parameters using PSO for speed control of Quasi-Z Source DC/DC converter fed drive , 2015, Appl. Soft Comput..

[18]  Jubaer Ahmed,et al.  An Enhanced Adaptive P&O MPPT for Fast and Efficient Tracking Under Varying Environmental Conditions , 2018, IEEE Transactions on Sustainable Energy.

[19]  P. B. de Moura Oliveira,et al.  Design of Digital PID Controllers using Particle Swarm Optimization: A Video Based Teaching Experiment , 2018 .

[20]  A. Monti,et al.  Design of a high performance deadbeat-type current controller for LCL-filtered grid-parallel inverters , 2015, 2015 IEEE 6th International Symposium on Power Electronics for Distributed Generation Systems (PEDG).

[21]  Cheng Siyuan,et al.  Tuning digital PID controllers for discrete-time system by Election Campaign Optimization algorithm , 2010, 2010 International Conference on Mechanic Automation and Control Engineering.

[22]  Jeffrey C. Lagarias,et al.  Convergence Properties of the Nelder-Mead Simplex Method in Low Dimensions , 1998, SIAM J. Optim..

[23]  Katsuhiko Ogata,et al.  Discrete-time control systems , 1987 .

[24]  Giuseppe Orlando,et al.  A unified observer for robust sensorless control of DC–DC converters , 2017 .

[25]  Jason Gu,et al.  Optimized Digital Controllers for Switching-Mode DC-DC Step-Down Converter , 2018 .