Abstract
This article presents an efficient design of a pure sine wave inverter which results in an electronic design with reduced losses. The proposed design incorporates the generation of custom programmed pulse width modulation (CPPWM) waveforms; the gate drive signals that are customized for the harmonic elimination from the output voltage, maximizing the fundamental component and resulting in an efficient electronic circuit design as compared to the traditional techniques in terms of the switching losses and the filtering energy losses. The CPPWM signals are digitally programmed in a micro-controller. The inverter realization is followed by an intelligent compensator design for the regulation of output voltage amplitude. The proposed algorithm self-adjusts its parameters in response to the load current and voltage amplitude variations hence resulting in an improved performance. The simulation results of the control algorithm are presented. The experimental validation of the theoretically investigated controller is also presented by implementing a discrete time realization of the control algorithm using digital controller interfaced in real time with MATLAB®/Simulink®. The hardware results are elucidated. The feasibility of the proposed controller is theoretically and experimentally verified by its efficiency compared to the classical techniques, the available tunable parameters in the controller structure and the immense flexibility in the attainable closed loop dynamics.
Highlights
A switch-mode-dc-to-ac inverters are fundamental to motor drives and uninterruptible power supply circuits
We have designed a power efficient sine wave inverter for which we have addressed the problem of custom programmed pulse width modulation (PWM) (CPPWM) signals generation
A DC-to-AC inverter is driven by a CPPWM module that is interfaced with a PC unit in the Rapid Control Prototyping (RCP) Mode
Summary
A switch-mode-dc-to-ac inverters are fundamental to motor drives and uninterruptible power supply circuits. The digital modules that are used to generate PPWM waveforms are programmable they provide extra degrees of freedom that are not possible with conventional analog methods These programmable processors enable us to generate “customized” PWM waveforms that may optimize the performance indexes such as the current and the voltage selective harmonics elimination or minimization. We have designed a power efficient sine wave inverter for which we have addressed the problem of CPPWM signals generation These signals are optimized for the particular harmonic content minimization and the fundamental component maximization. The parameter adjustments capability is implemented by a multi-dimensional look-up-table (LUT) and an if--else conditional statement algorithm This compensation scheme is intuitive, easy to be programmed in the EEPROM for execution by the digital processors, provides flexibility in the control of system behavior and resulted in excellent system transient performance.
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