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Recent Patents on Engineering

Editor-in-Chief

ISSN (Print): 1872-2121
ISSN (Online): 2212-4047

Research Article

Breast Cancer Segmentation Recognition Using Explored DCT-DWT based Compression

Author(s): Navnish Goel*, Akhilendra Yadav and Brij Mohan Singh

Volume 16, Issue 2, 2022

Published on: 30 December, 2020

Article ID: e180122189612 Pages: 10

DOI: 10.2174/1872212115666201230091919

Price: $65

Abstract

Background and Objective: Breast cancer is a leading cause of death worldwide, and its early detection is usually performed with low quality clinical images. Due to unpredictable structure of breast and characterization of cancer, disease in early stages is yet a difficult issue for specialists and analysts. The accurate identification of breast cancer is an important step in its early stage to avoid drastic death rate. With the advancement in the field of medical science, advancements have been created to a phase where the medicinal services industry demonstrates to give best outcomes most precisely.

Method: It is observed that the breast cancer images are analyzed after decompression during telecommunications. In this paper, first we aimed to compress malignant cancer images so that it could illuminate the motivation behind the telemedicine by applying preprocessing techniques and second identification, classifications of breast cancer disease depend on segmentation using discrete cosine transformation and discrete wavelet transformation.

Result: Segmentation addresses the problem to identify the characteristics of malignant cancer. The segmented image eliminates the false positives, to obtain a clear-segmented image. Segmentation methods are based on a structural approach to isolate the breast edge and a region approach to extract the malignant portion. The result of image quality index achieved the output based on fusion techniques.

Conclusion: Because of the unpredictable structure of the breast and low quality of clinical images, a precise discovery, position, and characterization of the disease in early stages are considered a difficult issue for specialists and analysts. The breast cancer could detect and segment if highly efficient image compression is achieved successfully. The conclusion procedure of disease infection is time taking and requires storage capacity limit in computer system. A large number of Magnetic Resonance Imaging techniques were assembled as required and an enormous assortment for each wiped out individual required huge space for capacity just as a wide transmission transfer speed for computer system framework and again additionally for transmission over the web. Our proposed method can be useful for accurate and automatic classification of malignant cells from medical images by the specialist, with a goal that genuine cases would create novel outcomes and improve endurance rates.

Keywords: Breast cancer, image denoising, discrete cosine transformation, discrete wavelet transformation, segmentation, fusion techniques.

Graphical Abstract

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