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Journals >Journal of Infrared and Millimeter Waves >Volume 39 >Issue 6 >Page 810 > Article

Journal of Infrared and Millimeter Waves
Vol. 39, Issue 6, 810 (2020)

Fusion method for infrared and other-type images based on the multi-scale Gaussian filtering and morphological transform

Zhi-Jian LI^1、2, Feng-Bao YANG^1、*, Yu-Bin GAO³, Lin-Na JI¹, and Peng HU¹

Author Affiliations

¹School of Information and Communication Engineering， North University of China， Taiyuan030051， China

²North University of China， Shuozhou， Shuozhou036000， China

³Department of Mathematics， North University of China， Taiyuan030051， China

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DOI: 10.11972/j.issn.1001-9014.2020.06.021 Cite this Article

Zhi-Jian LI, Feng-Bao YANG, Yu-Bin GAO, Lin-Na JI, Peng HU. Fusion method for infrared and other-type images based on the multi-scale Gaussian filtering and morphological transform[J]. Journal of Infrared and Millimeter Waves, 2020, 39(6): 810 Copy Citation Text

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Abstract

To ensure the fusion quality and efficiency simultaneously， a novel image fusion method based on multi-scale Gaussian filtering and morphological transform is proposed. The multi-scale Gaussian filtering is designed to decompose the source images into a series of detail images and approximation images. The multi-scale top- and bottom-hat decompositions are used respectively to fully extract the bright and dark details of different scales in each approximation image. The multi-scale morphological inner- and outer-boundary decompositions are constructed to fully extract boundary information in each detail image. Experimental results demonstrate that the proposed method is comparable to or even better in comparison with typical multi-scale decomposition-based fusion methods. Additionally， the method operates much faster than some advanced multi-scale decomposition-based methods like NSCT and NSST.

Keywords

image fusion morphological transform multi-scale decomposition multi-scale Gaussian filtering

f^{(0)} \to \{y^{(1)}, f^{(2)}\} \to \dots \to \{y^{(1)}, y^{(2)}, \dots, y^{(j)}, f^{(j + 1)}\} \to \dots

(1)

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\{\begin{matrix} f^{(0)} = f \in V_{0} \\ f^{(j + 1)} = ψ_{j}^{↑} (f^{(j)}) \in V_{j + 1}, \\ y^{(j)} = f^{(j)} - ψ_{j}^{↓} (f^{(j + 1)}) \in Y_{j} \end{matrix} j \geq 0

(2)

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f = f^{(0)}, f^{(j)} = ψ_{j}^{↓} (f^{(j + 1)}) + y^{(j)}, j \geq 0

(3)

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\{\begin{matrix} f^{(0)} = f \in V_{0} \\ f^{(j + 1)} = G_{j} * f^{(j)} \in V_{j + 1}, \\ y^{(j)} = f^{(j)} - f^{(j + 1)} \in Y_{j} \end{matrix} j \geq 0

(4)

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G_{j} = (1 / 2 π σ_{j}^{2}) ∙ e x p [- (x^{2} + y^{2}) / 2 σ_{j}^{2}]

(5)

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f = f^{(0)}

(6)

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\{\begin{matrix} f^{(0)} = f \in V_{0} \\ f^{(j + 1)} = C l o s e_{b_{j}} (f^{(j)}) \in V_{j + 1}, \\ y^{(j)} = f^{(j + 1)} - f^{(j)} \in Y_{j} \end{matrix} j \geq 0

(7)

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f = f^{(0)}, f^{(j)} = f^{(j + 1)} - y^{(j)}, j \geq 0

(8)

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f \to \{y^{(1)}, y^{(2)}, \dots, y^{(k)}, \dots, y^{(K)}, f^{(K + 1)}\}

(9)

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f^{(K + 1)} \to \{\begin{matrix} \{y_{t}^{(1)}, y_{t}^{(2)}, \dots, y_{t}^{(l)}, \dots, y_{t}^{(M)}, f_{t}^{(M + 1)}\} \\ \{y_{b}^{(1)}, y_{b}^{(2)}, \dots, y_{b}^{(l)}, \dots, y_{b}^{(M)}, f_{b}^{(M + 1)}\} \end{matrix}

(10)

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y^{(k)} \to \{\begin{matrix} \{y_{i}^{(k, 1)}, y_{i}^{(k, 2)}, \dots, y_{i}^{(k, l)}, \dots, y_{i}^{(k, N_{k})}, f_{i}^{(k, N_{k} + 1)}\} \\ \{y_{o}^{(k, 1)}, y_{o}^{(k, 2)}, \dots, y_{o}^{(k, l)}, \dots, y_{o}^{(k, N_{k})}, f_{o}^{(k, N_{k} + 1)}\} \end{matrix}

(11)

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\{\begin{matrix} y_{t}^{(l)} (n | F) = m a x \{|y_{t}^{(l)} (n | A)|, |y_{t}^{(l)} (n | B)|\} \\ f_{t}^{(M + 1)} (n | F) = α_{t} f_{t}^{(M + 1)} (n | A) + β_{t} f_{t}^{(M + 1)} (n | B) \end{matrix}

(12)

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\{\begin{matrix} y_{b}^{(l)} (n | F) = m a x {|y_{b}^{(l)} (n | A)|, |y_{b}^{(l)} (n | B)|} \\ f_{b}^{(M + 1)} (n | F) = α_{b} f_{b}^{(M + 1)} (n | A) + β_{b} f_{b}^{(M + 1)} (n | B) \end{matrix}

(13)

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y_{i}^{(k, l)} (n | F) = \{\begin{matrix} y_{i}^{(k, l)} (n | A) i f |y_{i}^{(k, l)} (n | A)| > |y_{i}^{(k, l)} (n | B)| \\ y_{i}^{(k, l)} (n | B) o t h e r w i s e \end{matrix}

(14)

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f^{(K + 1)} (∙ | F) = (γ_{M + 1} f_{t}^{(M + 1)} (∙ | F) + \sum_{l = 0}^{M} γ_{l} y_{t}^{(l)} (∙ | F)) / 2 + (κ_{M + 1} f_{b}^{(M + 1)} (∙ | F) - \sum_{l = 0}^{M} κ_{l} y_{b}^{(l)} (∙ | F)) / 2

(15)

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y^{(k)} (∙ | F) = (f_{i}^{(k, N_{k} + 1)} (∙ | F) + \sum_{l = 1}^{N_{k}} y_{i}^{(k, l)} (∙ | F)) / 2 + (f_{o}^{(k, N_{k} + 1)} (∙ | F) - \sum_{l = 1}^{N_{k}} y_{o}^{(k, l)} (∙ | F)) / 2

(16)

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f (∙ | F) = f^{(0)} (∙ | F) = f^{(K + 1)} (∙ | F) + \sum_{k = 1}^{K} y^{(k)} (∙ | F)

(17)

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Zhi-Jian LI, Feng-Bao YANG, Yu-Bin GAO, Lin-Na JI, Peng HU. Fusion method for infrared and other-type images based on the multi-scale Gaussian filtering and morphological transform[J]. Journal of Infrared and Millimeter Waves, 2020, 39(6): 810

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