Abstract
In this paper, fractional order internal model control technique is formulated for non-ideal dc–dc buck and boost converter. The fractional order internal model control approach integrates the concept of Commande Robuste d’Ordre Non Entier principle for tuning a fractional order filter with internal model control scheme. The final controller can be expressed as a series combination of proportional integral derivative controller and a fractional order low pass filter. To assess the robustness of the proposed fractional order internal model control scheme, both the servo response and regulatory response of the dc–dc converters are investigated in the presence of disturbances. The efficacy of fractional order internal model control technique is demonstrated via comparison with 2 degrees of freedom internal model control scheme. Furthermore, an experimental validation of fractional order internal model control is conducted on laboratory setup, and a dSPACE 1104 microcontroller is used for hardware implementation. The simulation results and the hardware validation are a testimony to the effectiveness of fractional order internal model control technique.
Highlights
Over the past years, switched mode power supplies have been used in a plethora of commercial and industrial applications such as dc motor drives, computers, electric vehicles, batteries and so on
A fractional order (FO)-Internal model control (IMC) technique is formulated, such that the final controller is obtained as a series combination of proportional integral derivative (PID) controller and FO filter
The non-ideal models of both buck and boost converters are derived via the consideration of all the parasitic elements such as forward voltage of diode, equivalent resistances of inductance and capacitance and resistance of semiconductor devices, while they are working in ON mode
Summary
Over the past years, switched mode power supplies have been used in a plethora of commercial and industrial applications such as dc motor drives, computers, electric vehicles, batteries and so on. The existing techniques can be categorized into proportional integral derivative (PID) control, adaptive control, sliding mode control, model predictive control, soft computing approaches and so on. Internal model control (IMC) is another such control approach based on Youla parameterization, which is widely used due to its simple structure and intuitive design In ideal conditions, it is characterized by dual stability, perfect control and zero-steady state error.. A FO controller is endowed with properties of disturbance rejection and robustness, which offers a motivation for consideration of its application to the voltage regulation of buck and boost converters. In this paper, FO-IMC technique is applied to the non-ideal model of buck and boost converters. The non-ideal models of buck and boost converters are formulated and the FO-IMC technique is discussed. The experimental results are presented, and the conclusions are drawn
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