You are in:Home/Publications/Elsayed Badr; Sultan Almotairi; Mustafa Abdul Salam; Hagar Ahmed (2021) "New Sequential and Parallel Support Vector Machine with Grey Wolf Optimizer for Breast Cancer Diagnosis" Alexandria Engineering Journal, Available online 28 July 2021. [ISI indexed: Impact Factor 3.732]

Prof. Alsayed alsayed mitwali badr :: Publications:

Title:
Elsayed Badr; Sultan Almotairi; Mustafa Abdul Salam; Hagar Ahmed (2021) "New Sequential and Parallel Support Vector Machine with Grey Wolf Optimizer for Breast Cancer Diagnosis" Alexandria Engineering Journal, Available online 28 July 2021. [ISI indexed: Impact Factor 3.732]
Authors: Elsayed Badr; Sultan Almotairi; Mustafa Abdul Salam; Hagar Ahmed
Year: 2021
Keywords: Machine learning; Support vector machine; Grey Wolf optimizer; Scaling techniques; Breast cancer; Parallel processing
Journal: Alexandria Engineering Journal
Volume: Not Available
Issue: Not Available
Pages: Not Available
Publisher: ScienceDirect
Local/International: International
Paper Link:
Full paper Alsayed alsayed mitwali badr_1.pdf
Supplementary materials Not Available
Abstract:

Breast cancer is one of the most common types of cancer worldwide. Early detection of cancer increases the probability of recovery. This work has three contributions. The first contribution is improving the performance of support vector machine (SVM) using a recent grey wolf optimizer (GWO) for diagnosis breast cancer with efficient scaling techniques. The second contribution is proposing three efficient scaling techniques against the classical normalization technique. The last contribution is using a parallel technique which applies task distribution to improve the efficiency of GWO. The proposed sequential model is applied on two different datasets, Wisconsin diagnosis breast cancer (WDBC) dataset and Electronic Health Records (EHR). Experimental results of WDBC show that the proposed hybrid GWO-SVM model achieves 98.60% with normalization scaling. Also, using the proposed scaling techniques with the proposed GWO-SVM model gives a fast convergence and achieves accuracy rate by 99.30%. The parallel version of the proposed model achieves a speedup by 3.9 on four CPU cores. On the other hand, Experimental results of EHR show that the proposed hybrid GWO-SVM model achieves 93.26% with normalization scaling against 82.05 for SVM.

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