Abstract
Transmission towers are tall structures used to support overhead power lines. They play an important role in the electrical grids. There are several types of transmission towers in which lattice towers are the most common type. Designing steel lattice transmission towers is a challenging task for structural engineers due to a large number of members. Therefore, discovering effective ways to design lattice towers has attracted the interest of researchers. This paper presents a method that integrates Differential Evolution (DE), a powerful optimization algorithm, and a machine learning classification model to minimize the weight of steel lattice towers. A classification model based on the Adaptive Boosting algorithm is developed in order to eliminate unpromising candidates during the optimization process. A feature handling technique is also introduced to improve the model quality. An illustrated example of a 160-bar tower is conducted to demonstrate the efficiency of the proposed method. The results show that the application of the Adaptive Boosting model saves about 38% of the structural analyses. As a result, the proposed method is 1.5 times faster than the original DE algorithm. In comparison with other algorithms, the proposed method obtains the same optimal weight with the least number of structural analyses.
Highlights
Electricity is an essential part of modern life
I n this paper, a method that combines the Differential Evolution algorithm and the Adaptive Boosting classification technique to minimize the weight of steel lattice towers is proposed
The original Differential Evolution with four basic operators is employed with the aim of exploring the design space and collecting training data
Summary
Electricity is an essential part of modern life. Electricity is a big part of daily life in homes and plays an important role in industrial production. The electrical grid consists of two components which are the electric power transmission and the electric power distribution. The transmission network carries electricity from power plants to substations, while the distribution network delivers electricity from substations to customers. Due to the increasing demand for energy as well as the exploitation of new energy sources such as wind power, solar power, the transmission network is constantly being upgraded and expanded.
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