Aurelle Tchagna Kouanou

Work place: Research Unity of Condensed Matter, Electronics and Signal Processing, Department of Physics, Faculty of Science, University of Dschang, P.O.Box 67 Dschang, Cameroon.

E-mail: tkaurelle@gmail.com

Website:

Research Interests: Data Structures and Algorithms, Medical Image Computing, Image Processing, Computational Learning Theory, Artificial Intelligence

Biography

Tchagna Kouanou Aurelle was born in 1990 in Dschang-Cameroon. He obtained a MS degree in Electronic in 2013 from University of Dschang, he graduated in Telecommunication engineering from the National Advanced School of Posts, Telecommunications and Information Communication Technologies (SUP’ PTIC) Yaounde-Cameroon in 2015. Actually, Mr Tchagna perform a PhD degree at University of Dschang where his main items of research include Biomedical image processing, Artificial Intelligence, Big Data, Deep Learning, Machine learning and Internet of Things.

Author Articles
A Machine Learning Algorithm for Biomedical Images Compression Using Orthogonal Transforms

By Aurelle Tchagna Kouanou Daniel Tchiotsop Rene Tchinda Christian Tchito Tchapga Adelaide Nicole Kengnou Telem Romanic Kengne

DOI: https://doi.org/10.5815/ijigsp.2018.11.05, Pub. Date: 8 Nov. 2018

Compression methods are increasingly used for medical images for efficient transmission and reduction of storage space. In this work, we proposed a compression scheme for colored biomedical image based on vector quantization and orthogonal transforms. The vector quantization relies on machine learning algorithm (K-Means and Splitting Method). Discrete Walsh Transform (DWaT) and Discrete Chebyshev Transform (DChT) are two orthogonal transforms considered. In a first step, the image is decomposed into sub-blocks, on each sub-block we applied the orthogonal transforms. Machine learning algorithm is used to calculate the centers of clusters and generates the codebook that is used for vector quantization on the transformed image. Huffman encoding is applied to the index resulting from the vector quantization. Parameters Such as Mean Square Error (MSE), Mean Average Error (MAE), PSNR (Peak Signal to Noise Ratio), compression ratio, compression and decompression time are analyzed. We observed that the proposed method achieves excellent performance in image quality with a reduction in storage space. Using the proposed method, we obtained a compression ratio greater than 99.50 percent. For some codebook size, we obtained a MSE and MAE equal to zero. A comparison between DWaT, DChT method and existing literature method is performed. The proposed method is really appropriate for biomedical images which cannot tolerate distortions of the reconstructed image because the slightest information on the image is important for diagnosis. 

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