Teku Sandhya Kumari

Work place: Vignan’s Institute of Engineering for Women, Department of Electronics and Communication Engineering, Visakhapatnam, Andhra Pradesh, India

E-mail: teku.sandhya@gmail.com

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Biography

Dr. T. Sandhya Kumari is an Associate Professor in the Department of ECE, Vignan’s Institute of Engineering for Women, Visakhapatnam. She did her B.E. degree from S.R.K.R. Engineering College, Bhimavaram, affiliated to Andhra University and M. Tech degree from JNT University, Kakinada. She pursued her Ph. D from JNT, University, Kakinada. She has around 20 research publications in SCI, Scopus, UGC Indexed Journals and in National Conferences. Her areas of interest are multi-sensor image fusion, Image Enhancement and Image Restoration.

Author Articles
Infrared and Visible Image Fusion (IVF) Using Latent Low-Rank Representation and Deep Feature Extraction Network

By Teku Sandhya Kumari Gundala Sujatha Boddeda Sravya Hari Jyothula

DOI: https://doi.org/10.5815/ijigsp.2024.03.03, Pub. Date: 8 Jun. 2024

The combination of visible and infrared images from different sensors can provide a more detailed and informative image. Visible images capture environmental details and texture, while infrared sensors can detect thermal radiation and create grayscale images that have high contrast. These images are useful for distinguishing between target and background in challenging conditions, such as at night or in inclement weather. When these two types of images are fused, they create high- contrast images with rich texture and target details. In this paper, an effective image fusion technique has been developed, which utilizes Latent Low Rank Representation (LatLRR) method that decomposes the source images into latent low rank and salient parts to capture common and unique information respectively. The proposed network design incorporates the dense network and VGG-19 architectures for deep feature extraction of latent low- rank and salient parts, that minimize distortion while maintaining crucial texture and details in the output. Weighted average fusion strategies are used to combine these latent low-rank and salient parts, and the resulting fused features are used for feature reconstruction to generate a fused low-rank and salient part. These parts are integrated to yield a fused image output. The proposed approach out performs existing state-of-the-art methods on both visual characteristics and objective evaluation metrics.

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