Real-time frequency and harmonic evaluation using artificial neural networks

Abstract: With increasing harmonic pollution in the power system, real-time monitoring and analysis of harmonic variations have become important. Because of limitations associated with conventional algorithms, particularly under supply-frequency drift and transient situations, a new approach based on non-linear leastsquares parameter estimation has been proposed as an alternative solution for high-accuracy evaluation. However, the computational demand of the algorithm is very high and it is more appropriate to use Hopfi… Show more

“…However, computational complexities such as matrix inversion involved in KF make it less appealing for real-time hardware implementation. The recursive nature of ANN based techniques proposed in the literature [8][9][10][11], results in a much slower response time (e.g. 35 ms [11]).…”

“…However, the computational complexity of these methods is much more than that of the FFT whilst the time taken for harmonic extraction is similar. The use of ANNs for real-time harmonic monitoring has been the focus of many researchers [8][9][10][11]. ANNs provide simple and straightforward techniques for selectively tracking individual harmonic components.…”

Fast non-recursive extraction of individual harmonics using artificial neural networks

“…However, computational complexities such as matrix inversion involved in KF make it less appealing for real-time hardware implementation. The recursive nature of ANN based techniques proposed in the literature [8][9][10][11], results in a much slower response time (e.g. 35 ms [11]).…”

“…However, the computational complexity of these methods is much more than that of the FFT whilst the time taken for harmonic extraction is similar. The use of ANNs for real-time harmonic monitoring has been the focus of many researchers [8][9][10][11]. ANNs provide simple and straightforward techniques for selectively tracking individual harmonic components.…”

Fast non-recursive extraction of individual harmonics using artificial neural networks

“…The schemes presented in Reference [17] makes it possible to perform any real-world task described by a certain Boolean function via an SLP or a dynamic neuron. For a few years, ANN techniques have been widely explored for signal decomposition in electrical systems and are very promising in the field, as discussed in References [18][19][20][21][22][23]. Indeed, the learning capacities of the ANNs allow an online adaptation to every changing parameter of the electrical system, e.g., nonlinear and time-varying loads.…”

“…In this Subsection, the mathematical formulation of adaptive linear neural network (ADALINE) [18][19][20][21][22][23] is outlined as follows. Consider an arbitrary signalY (t) with Fourier series expansion as…”

“…The proportional-integral (PI) controllers are implemented in daxis and q-axis based on the decoupled state-space equations of the T-type active power filter. The load side dynamics are incorporated in the feed-forward control loop by using two groups of synchronous frame adaptive linear neural networks (SADALINEs) [13][14][15][16][17][18][19][20][21][22][23] in d-axis and q-axis, respectively, for fast estimation of the fundamental components of nonlinear load currents. Besides, a separate proportional-integral (PI) controller is adopted in the outer voltage loop for balancing the active power flow of the voltage source inverter.…”

A new scheme for power factor correction and active filtering for six-pulse converters loads

Data inheritance–based updating method and its application in transient frequency prediction for a power system