Abstract
Grey wolf optimization (GWO) is a recent and popular swarm-based metaheuristic approach. It has been used in numerous fields such as numerical optimization, engineering problems, and machine learning. The different variants of GWO have been developed in the last 5 years for solving optimization problems in diverse fields. Like other metaheuristic algorithms, GWO also suffers from local optima and slow convergence problems, resulted in degraded performance. An adequate equilibrium among exploration and exploitation is a key factor to the success of meta-heuristic algorithms especially for optimization task. In this paper, a new variant of GWO, called inertia motivated GWO (IMGWO) is proposed. The aim of IMGWO is to establish better balance between exploration and exploitation. Traditionally, artificial neural network (ANN) with backpropagation (BP) depends on initial values and in turn, attains poor convergence. The metaheuristic approaches are better alternative instead of BP. The proposed IMGWO is used to train the ANN to prove its competency in terms of prediction. The proposed IMGWO-ANN is used for medical diagnosis task. Some benchmark medical datasets including heart disease, breast cancer, hepatitis, and parkinson's diseases are used for assessing the performance of IMGWO-ANN. The performance measures are described in terms of mean squared errors (MSEs), classification accuracies, sensitivities, specificities, the area under the curve (AUC), and receiver operating characteristic (ROC) curve. It is found that IMGWO outperforms than three popular metaheuristic approaches including GWO, genetic algorithm (GA), and particle swarm optimization (PSO). Results confirmed the potency of IMGWO as a viable learning technique for an ANN.
Highlights
The process of medical diagnosis becomes easier and faster if a decision support system assists the doctors because machines do not suffer from fatigue or boredom
Continuous efforts are put in this direction to improve the performance of the diagnosis process through machine learning methods like support vector machine (SVM) by Akay (2009) and Maglogiannis et al (2009)
The current study extends the work of Long et al (2018) by introducing a new equation for non-linear adjustment of the control parameter a⃗a
Summary
The process of medical diagnosis becomes easier and faster if a decision support system assists the doctors because machines do not suffer from fatigue or boredom. Blum and Socha (2005) applied ant colony optimization (ACO) algorithm to train a feedforward neural network, and improved classification results were obtained using benchmark medical datasets including breast cancer, diabetes, and heart disease. Long et al (2018) stated that a proper balance between exploration and exploitation is needed to achieve global optima solution in case of population-based stochastic methods They proposed a new non-linear control variable a⃗a and modification in the position updating equation inspired by PSO. Recent jjtth literature confirmed that SI, NIA, and EA have better exploration capabilities than single-solution-based metaheuristic algorithms to train ANN (Ojha et al, 2017). IMGWO used MSE as fitness function during the training of MLP and obtained a significant improvement in the results as compared to other contemporary metaheuristic methods (GA, PSO, and GWO)
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