Nonlinear image processing with α-tension field: A geometric approach

Seyyed Mehdi Kazemi Torbaghan; Yaser Jouybari Moghaddam; Amin Jajarmi

doi:10.36922/IJOCTA025110050

An International Journal of Optimization and Control: Theories & Applications ›› 2025, Vol. 15 ›› Issue (4) :578 -593. DOI: 10.36922/IJOCTA025110050

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Nonlinear image processing with α-tension field: A geometric approach

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Abstract

In this paper, we apply an α-tension field from differential geometry to classical image processing tasks of denoising with edge preservation and multiphase feature enhancement. The main contribution of this work is that it is the first systematic investigation of the α-tension field for image processing. Contrary to traditional operators, such as the Laplacian, which are susceptible to noise amplification or are ineffective for complex structures, the α-tension field relies on a nonlinear adaptive mechanism depending on the magnitudes of local gradients. It allows effective denoising and retains edges and fine details by utilizing higher-order gradient information. The field of α-tension provides more sensitive and adaptive models than linear models, such as total variation regularization, anisotropic diffusion, etc. The study exemplifies its advantages over previous methods in preserving structural integrity and minimizing artifacts. It also considers numerical implementation issues and provides guidelines for real-time and large-scale processing. This framework adds up to the known need for faster image-processing tools while links connections to differential geometry.

Keywords

Image processing / α−tension field / Harmonic maps / Riemannian geometry

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Seyyed Mehdi Kazemi Torbaghan, Yaser Jouybari Moghaddam, Amin Jajarmi. Nonlinear image processing with α-tension field: A geometric approach. An International Journal of Optimization and Control: Theories & Applications, 2025, 15(4): 578-593 DOI:10.36922/IJOCTA025110050

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The authors declare that they have no conflict of interest regarding the publication of this article.

References

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[1]	Kazemi Torbaghan SM, Salehi K, Babayi S. Existence and stability of α-harmonic maps. J Math. 2022; 2022(1):1906905.

[2]	Sacks J, Uhlenbeck K. The existence of minimal immersions of 2-spheres. Ann Math. 1981; 113(1):1-24.

[3]	Shahnavaz A, Kazemi Torbaghan SM, Kouhestani N. Sacks-Uhlenbeck α-harmonic maps from Finsler manifolds. J Finsler Geom Appl. 2024; 5(2):70-86.

[4]	Lamm T, Malchiodi A, Micallef M. A gap theorem for α-harmonic maps between two-spheres. Anal PDE. 2021; 14(3):881-889.

[5]	Li J, Zhu X. Energy identity and necklessness for a sequence of Sacks-Uhlenbeck maps to a sphere. Ann Inst Henri Poincaré (C) Anal Non Lineaire. 2019; 36(1):103-118.

[6]	Shahnavaz A, Kouhestani N, Kazemi Torbaghan SM. The Morse index of Sacks-Uhlenbeck α-harmonic maps for Riemannian manifolds. J Math. 2024; 2024(1):2692876.

[7]	Perelman G. Finite extinction time for the solutions to the Ricci flow on certain three-manifolds. arXiv Preprint Math/0307245; 2003.

[8]	https://www.kaggle.com/datasets/zhangweiled/lidcidri

[9]	Kazemi Torbaghan SM, Jouybari Y. Generalized harmonic maps and applications in image processing. J Finsler Geom Appl. 2025; 6(1):23-35.

[10]	Birkfellner W. Applied Medical Image Processing: A Basic Course. CRC Press; 2024.

[11]	Wei W, Zhou B, Polap D, Wozniak M. A regional adaptive variational PDE model for computed tomography image reconstruction. Pattern Recogn. 2019;92:64-81.

[12]	Canty MJ. Image Analysis, Classification and Change Detection in Remote Sensing: With Algorithms for Python. CRC Press; 2019.

[13]	Oprea J. Differential Geometry and its Applications. American Mathematical Society; 2024.

[14]	Tian C, Chen Y. Image segmentation and denoising algorithm based on partial differential equations. IEEE Sens J. 2019; 20(20):11935-11942.

[15]	Kimmel R. Numerical Geometry of Images: Theory, Algorithms, and Applications. Springer Science & Business Media; 2012.

[16]	Sapiro G. Geometric Partial Differential Equations and Image Analysis. Cambridge University Press; 2006.

[17]	Heijmans HJ. Mathematical morphology: a modern approach in image processing based on algebra and geometry. SIAM Rev., 1995; 37(1):1-36.

[18]	Chaudhari DJ, Malathi K. Detection and prediction of rice leaf disease using a hybrid CNN-SVM model. Opt Mem Neural Netw., 2023; 32(1):39-57.

[19]	Kuijper A. Geometrical PDEs based on second-order derivatives of gauge coordinates in image processing. Image Vis Comput. 2009; 27(8):1023-1034.

[20]	Varanasi S, Malathi K. Self-improved COOT optimization-based LSTM for patient waiting time prediction. Multimedia Tools Appl. 2023; 83(13): 39315-39333.

[21]	Babu VD, Malathi K. Three-stage multi-objective feature selection with distributed ensemble machine and deep learning for processing of complex and large datasets. Measure Sens. 2023;28: 100820.

[22]	Kumar MR, Malathi K. An innovative method in classifying and predicting the accuracy of intrusion detection on cybercrime by comparing decision tree with support vector machine. In: 2022 International Conference on Business Analytics for Technology and Security (ICBATS), Dubai; 2022.

[23]	Duits R, Citti G, Fuster A, Schultz T. Differential geometry and orientation analysis in image processing. J Math Imaging Vis. 2018;60:763-765.

[24]	Rambabu V, Malathi K, Mahaveerakannan R. An innovative method to predict the accuracy of phishing websites by comparing logistic regression algorithm with support vector machine algorithm. In: 6th International Conference on Electronics, Communication and Aerospace Technology, Coimbatore; 2022.

[25]	Kumar A, Bhushan S, Mustafa MS, Aldallal R, Aljohani HM, Almulhim F A. Novel imputation methods under stratified simple random sampling. Alexandria Eng J. 2024;95:236-246.