Multi-Focus Image Fusion via Distance-Weighted Regional Energy and Structure Tensor in NSCT Domain

Lv, Ming; Li, Liangliang; Jin, Qingxin; Jia, Zhenhong; Chen, Liangfu; Ma, Hongbing

doi:10.3390/s23136135

Cited by 3 publications

(2 citation statements)

References 48 publications

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“…To objectively evaluate the enhancement effects of the different methods in the ten aforementioned infrared scenes, five traditional image evaluation metrics were employed, such as average gradient (AG) [48] and edge intensity (EI) [49], which are based on image features; figure definition (FD), which quantifies the level of detail and distinctness present in the visual content of the image; and root mean square contrast (RMSC) [50], which quantifies the contrast level of the image. These metrics are widely used for evaluating the quality of an image.…”

Section: Objective Analysismentioning

confidence: 99%

Multi-Scale FPGA-Based Infrared Image Enhancement by Using RGF and CLAHE

Liu,

Zhou,

Wan

et al. 2023

Sensors

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Infrared sensors capture thermal radiation emitted by objects. They can operate in all weather conditions and are thus employed in fields such as military surveillance, autonomous driving, and medical diagnostics. However, infrared imagery poses challenges such as low contrast and indistinct textures due to the long wavelength of infrared radiation and susceptibility to interference. In addition, complex enhancement algorithms make real-time processing challenging. To address these problems and improve visual quality, in this paper, we propose a multi-scale FPGA-based method for real-time enhancement of infrared images by using rolling guidance filter (RGF) and contrast-limited adaptive histogram equalization (CLAHE). Specifically, the original image is first decomposed into various scales of detail layers and a base layer using RGF. Secondly, we fuse detail layers of diverse scales, then enhance the detail information by using gain coefficients and employ CLAHE to improve the contrast of the base layer. Thirdly, we fuse the detail layers and base layer to obtain the image with global details of the input image. Finally, the proposed algorithm is implemented on an FPGA using advanced high-level synthesis tools. Comprehensive testing of our proposed method on the AXU15EG board demonstrates its effectiveness in significantly improving image contrast and enhancing detail information. At the same time, real-time enhancement at a speed of 147 FPS is achieved for infrared images with a resolution of 640 × 480.

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Section: Objective Analysismentioning

confidence: 99%

Multi-Scale FPGA-Based Infrared Image Enhancement by Using RGF and CLAHE

Liu,

Zhou,

Wan

et al. 2023

Sensors

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“…These comparative algorithms include parameter-adaptive pulse coupled neural network and nonsubsampled shearlet transform (NSSTPA) [3], proportional maintenance of gradient and intensity (PMGI) [28], threelayer decomposition and sparse representation (TLDSR) [35], convolutional simultaneous sparse approximation (CSSA) [36], local extreme map guided multi-modal image fusion (LEGFF) [37], unified unsupervised image fusion network (U2Fusion) [38], distanceweighted regional energy and nonsubsampled shearlet transform (NSSTDW) [18], and zero-shot multi-focus image fusion (ZMFF) [2]. Qualitative and quantitative evaluations were used to evaluate the results of fusion; the quantitative evaluation indicators include the edge-based similarity measurement Q AB/F [39,40], the structural similarity based metric Q E [41], the feature mutual information metric Q FMI [42], the gradient based metric Q G [41], the nonlinear correlation information entropy Q NCIE [41], the phase-congruencybased metric Q P [41], the mutual information metric Q MI [39,40], the normalized mutual information Q N MI [41], the structural-similarity-based metric Q Y introduced by Yang et al Q Y [41,43] and the average gradient metric Q AG [44,45], peak signal-to-noise ratio Q PSNR [46], and mean square error Q MSE [47]. The algorithms with larger indicator values (except for metric Q MSE ) are better.…”

Section: Experimental Settingmentioning

confidence: 99%

Multi-Focus Image Fusion via PAPCNN and Fractal Dimension in NSST Domain

Lv,

Jia,

et al. 2023

Mathematics

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Multi-focus image fusion is a popular technique for generating a full-focus image, where all objects in the scene are clear. In order to achieve a clearer and fully focused fusion effect, in this paper, the multi-focus image fusion method based on the parameter-adaptive pulse-coupled neural network and fractal dimension in the nonsubsampled shearlet transform domain was developed. The parameter-adaptive pulse coupled neural network-based fusion rule was used to merge the low-frequency sub-bands, and the fractal dimension-based fusion rule via the multi-scale morphological gradient was used to merge the high-frequency sub-bands. The inverse nonsubsampled shearlet transform was used to reconstruct the fused coefficients, and the final fused multi-focus image was generated. We conducted comprehensive evaluations of our algorithm using the public Lytro dataset. The proposed method was compared with state-of-the-art fusion algorithms, including traditional and deep-learning-based approaches. The quantitative and qualitative evaluations demonstrated that our method outperformed other fusion algorithms, as evidenced by the metrics data such as QAB/F, QE, QFMI, QG, QNCIE, QP, QMI, QNMI, QY, QAG, QPSNR, and QMSE. These results highlight the clear advantages of our proposed technique in multi-focus image fusion, providing a significant contribution to the field.

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