Abstract

Grid-connected converters are an important class of power electronic systems. Many power and energy applications require grid-connected converters. To control grid-connected converters, precise information of the grid voltage frequency and phase are required. Gradient estimators can be very useful in this regard. They are suitable to estimate the frequency and phase of the grid voltage signal. Various gradient estimators are already available in the literature e.g. regression-based techniques. However, most of them are designed by using the instantaneous estimation error as the cost-function. This amplifies the effect of noise in the estimated parameters. To overcome this issue, an integral cost-function is considered in this paper. The integral cost-function tries to minimize the estimation error over the integration window leading to reduce the effect of noise in the estimated frequency and phase. Moreover, the cost-function uses tunable forgetting factor to give more importance to recent data. The proposed gradient estimator assumes the grid frequency to be constant. However, in practice the frequency is variable with known nominal value. To overcome this problem, a frequency estimation block is coupled with the gradient estimator. The frequency estimation block uses the idea of phase-based frequency estimation. Comparative numerical simulation and experimental studies are performed to demonstrate the suitability of the proposed technique over three other advanced techniques from the literature.

Highlights

  • Renewable energy sources (RES) are playing a very important role in decarbonization of the existing electric power grid

  • Frequency and instantaneous phase can not be directly measured rather to be estimated from the grid voltage signal

  • Numerical simulation studies are performed in Matlab/Simulink

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Summary

INTRODUCTION

Renewable energy sources (RES) are playing a very important role in decarbonization of the existing electric power grid. Frequency and instantaneous phase can not be directly measured rather to be estimated from the grid voltage signal. Regression-based technique [15]–[17] generally use a parameterized linear model of the grid voltage signal Using this model, least-squares type algorithms are used for parameter estimation purpose. In noisy environment, minimizing the instantaneous error can be problematic as this will amplify the effect of noise To overcome this issue, integral of the estimation error cost-function is more suitable. A frequency adaptive gradient estimator will be developed by considering the integral of the estimation error as the cost-function to minimize the effect of the noise.

PROPOSED APPROACH A single-phase grid voltage signal can be written as:
RESULTS AND DISCUSSIONS
CONCLUSION AND FUTURE WORKS

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