Abstract
Solar energy is one of the immeasurable renewable energy in power generation for a green, clean and healthier environment. The silicon-layer solar panels absorb sun energy and converts it into electricity by off-grid inverter. Electricity is transferred either from this inverter or from transformer, consumed by consumption unit(s) available for residential or economic purposes. The artificial neural network is the foundation of artificial intelligence and solves many complex problems which are difficult by statistical methods or by humans. In view of this, the purpose of this work is to assess the performance of the Solar - Transformer - Consumption (STC) system. The system may be in complete breakdown situation due to failure of both solar power automation subsystem and transformer simultaneously or consumption unit; otherwise it works with fully or lesser efficiency. Statistically independent failures and repairs are considered. Using the elementary probabilities phenomenon incorporated with differential equations is employed to examine the system reliability, for repairable and non-repairable system, and to analyze its cost function. The accuracy and consistency of the system can be improved by feed forward- back propagation neural network (FFBPNN) approach. Its gradient descent learning mechanism can update the neural weights and hence the results up to the desired accuracy in each iteration, and aside the problem of vanishing gradient in other neural networks, that increasing the efficiency of the system in real time. MATLAB code for FFBP algorithm is built to improve the values of reliability and cost function by minimizing the error up to 0.0001 precision. Numerical illustrations are considered with their data tables and graphs, to demonstrate and analyze the results in the form of reliability and cost function, which may be helpful for system analyzers.
Highlights
In today's scenario, demand of electricity is more than its generation
A wellconnected set of neurons and learning mechanism describe the process of adjusting/ updating the weights to desired accuracy and minimize the errors in each iteration using feed forward back propagation neural network (FFBPNN) structure and gradient descent algorithm
Calculate the reliability and cost function using neural network, from output equations established in 29 - 37, and are written in the following manner: Reliability, R(t) = ∑ Oi, i = 2, 4, 5, 6, 7, 8, 9
Summary
In today's scenario, demand of electricity is more than its generation. As known, conventional resources such as fossil fuels, coal, nuclear, natural gases, etc. are decreasing day- by - day due to increase in their consumption in various activities of human beings. The network fails to train, reducing the error and optimize the results Keeping all these facts in mind, authors give the priority to neural network multilayered arrangement consists of three main layers: input, hidden and output. A wellconnected set of neurons and learning mechanism describe the process of adjusting/ updating the weights to desired accuracy and minimize the errors in each iteration using feed forward back propagation neural network (FFBPNN) structure and gradient descent algorithm. It was formerly proposed in 1970s for training the system and minimizing the errors appropriate for required precision. The system monitoring unit administers the power, voltage and current of the system
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