Background In the power system, the identification of the health status of the transmission tower is a daily task that must be performed. In addition, bolt loosening is a common damage mode affecting the main material...
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Background In the power system, the identification of the health status of the transmission tower is a daily task that must be performed. In addition, bolt loosening is a common damage mode affecting the main materials of transmission towers. When bolt loosening occurs, it weakens the bearing capacity of the transmission tower. If not detected and addressed in a timely manner, serious adverse events, such as tower collapse, may occur which will endanger the normal operation of the power *** Based on this, in order to ensure the normal operation of the transmission tower and improve the identification effect of bolt loosening, the GP-bpneuralnetworkalgorithm was applied to the detection process. The feasibility of this algorithm was evaluated through the quantitative analysis of different damage *** The results are as follows: 1) except for the average accuracy rate of substructure 7, which is 89.74%, the identification accuracy of other substructures is more than 90%, indicating that the ga-bp neural network algorithm is effective in identifying the single-damage degree of the tower bolt loosening in the main material;2) the identification accuracy of double-damage substructure is also more than 90%, indicating that the ga-bpalgorithm is effective in identifying the double-damage degree of the tower bolt loosening in the main *** In summary, it can be concluded that both the single- and double-damage degree conditions exhibit a relatively considerable recognition accuracy. In addition, the recognition effect of the algorithm under the double-damage degree condition is better than that of the single-damage degree condition. Therefore, it can be applied in practical projects involving double-damage degree conditions to improve the recognition effect of bolt-loosening faults and provide reliable technical support for the safe operation of transmission equipment.
The Genetic algorithm-Extreme Learning Machine (ga-ELM) neuralnetworkalgorithm is proposed to model the relevant characteristics of gaN pseudomorphic high electron mobility transistor (P-HEMT) large signal. This alg...
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The Genetic algorithm-Extreme Learning Machine (ga-ELM) neuralnetworkalgorithm is proposed to model the relevant characteristics of gaN pseudomorphic high electron mobility transistor (P-HEMT) large signal. This algorithm solves the over-fitting problem of the Back Propagation (bp) neuralnetworkalgorithm in the prediction data. It has the characteristics of fast calculation speed, so it can greatly save calculation processing time. It can also randomly generate the connection weights of the input layer, the hidden layer and the threshold of the hidden layer neurons, avoiding errors in parameter selection. In order to verify the superiority of the algorithm, the modeling effects of the bpneuralnetworkalgorithm model, the Genetic algorithm-Back Propagation (ga-bp) neuralnetworkalgorithm model and the ga-ELM neuralnetworkalgorithm model are compared in this paper. The results show that the proposed ga-ELM neuralnetworkalgorithm model has the highest accuracy.
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