Journal of Bionic Engineering ›› 2023, Vol. 20 ›› Issue (2): 797-818.doi: 10.1007/s42235-022-00297-8

• • 上一篇    下一篇

Boosting Whale Optimizer with Quasi-Oppositional Learning and Gaussian Barebone for Feature Selection and COVID-19 Image Segmentation

Jie Xing1; Hanli Zhao1; Huiling Chen1; Ruoxi Deng1; Lei Xiao1   

  1. Key Laboratory of Intelligent Informatics for Safety & Emergency of Zhejiang Province, Wenzhou University, Wenzhou 325035, China
  • 出版日期:2023-03-10 发布日期:2023-03-15
  • 通讯作者: Hanli Zhao; Huiling Chen; Lei Xiao; Jie Xing; Ruoxi Deng E-mail:hanlizhao@wzu.edu.cn; chenhuiling.jlu@gmail.com; xiaolei@wzu.edu.cn; xingjie095@163.com; ruoxii.deng@gmail.com
  • 作者简介:Jie Xing1; Hanli Zhao1; Huiling Chen1; Ruoxi Deng1; Lei Xiao1

Boosting Whale Optimizer with Quasi-Oppositional Learning and Gaussian Barebone for Feature Selection and COVID-19 Image Segmentation

Jie Xing1; Hanli Zhao1; Huiling Chen1; Ruoxi Deng1; Lei Xiao1   

  1. Key Laboratory of Intelligent Informatics for Safety & Emergency of Zhejiang Province, Wenzhou University, Wenzhou 325035, China
  • Online:2023-03-10 Published:2023-03-15
  • About author:Jie Xing1; Hanli Zhao1; Huiling Chen1; Ruoxi Deng1; Lei Xiao1

摘要: Whale optimization algorithm (WOA) tends to fall into the local optimum and fails to converge quickly in solving complex problems. To address the shortcomings, an improved WOA (QGBWOA) is proposed in this work. First, quasi-opposition-based learning is introduced to enhance the ability of WOA to search for optimal solutions. Second, a Gaussian barebone mechanism is embedded to promote diversity and expand the scope of the solution space in WOA. To verify the advantages of QGBWOA, comparison experiments between QGBWOA and its comparison peers were carried out on CEC 2014 with dimensions 10, 30, 50, and 100 and on CEC 2020 test with dimension 30. Furthermore, the performance results were tested using Wilcoxon signed-rank (WS), Friedman test, and post hoc statistical tests for statistical analysis. Convergence accuracy and speed are remarkably improved, as shown by experimental results. Finally, feature selection and multi-threshold image segmentation applications are demonstrated to validate the ability of QGBWOA to solve complex real-world problems. QGBWOA proves its superiority over compared algorithms in feature selection and multi-threshold image segmentation by performing several evaluation metrics.

关键词: Whale optimization algorithm , · Quasi-opposition-based learning , · Gaussian barebone , · Image segmentation , · Feature selection , · Bionic algorithm

Abstract: Whale optimization algorithm (WOA) tends to fall into the local optimum and fails to converge quickly in solving complex problems. To address the shortcomings, an improved WOA (QGBWOA) is proposed in this work. First, quasi-opposition-based learning is introduced to enhance the ability of WOA to search for optimal solutions. Second, a Gaussian barebone mechanism is embedded to promote diversity and expand the scope of the solution space in WOA. To verify the advantages of QGBWOA, comparison experiments between QGBWOA and its comparison peers were carried out on CEC 2014 with dimensions 10, 30, 50, and 100 and on CEC 2020 test with dimension 30. Furthermore, the performance results were tested using Wilcoxon signed-rank (WS), Friedman test, and post hoc statistical tests for statistical analysis. Convergence accuracy and speed are remarkably improved, as shown by experimental results. Finally, feature selection and multi-threshold image segmentation applications are demonstrated to validate the ability of QGBWOA to solve complex real-world problems. QGBWOA proves its superiority over compared algorithms in feature selection and multi-threshold image segmentation by performing several evaluation metrics.

Key words: Whale optimization algorithm , · Quasi-opposition-based learning , · Gaussian barebone , · Image segmentation , · Feature selection , · Bionic algorithm