74 research outputs found

    Transmission Map and Atmospheric Light Guided Iterative Updater Network for Single Image Dehazing

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    Hazy images obscure content visibility and hinder several subsequent computer vision tasks. For dehazing in a wide variety of hazy conditions, an end-to-end deep network jointly estimating the dehazed image along with suitable transmission map and atmospheric light for guidance could prove effective. To this end, we propose an Iterative Prior Updated Dehazing Network (IPUDN) based on a novel iterative update framework. We present a novel convolutional architecture to estimate channel-wise atmospheric light, which along with an estimated transmission map are used as priors for the dehazing network. Use of channel-wise atmospheric light allows our network to handle color casts in hazy images. In our IPUDN, the transmission map and atmospheric light estimates are updated iteratively using corresponding novel updater networks. The iterative mechanism is leveraged to gradually modify the estimates toward those appropriately representing the hazy condition. These updates occur jointly with the iterative estimation of the dehazed image using a convolutional neural network with LSTM driven recurrence, which introduces inter-iteration dependencies. Our approach is qualitatively and quantitatively found effective for synthetic and real-world hazy images depicting varied hazy conditions, and it outperforms the state-of-the-art. Thorough analyses of IPUDN through additional experiments and detailed ablation studies are also presented.Comment: First two authors contributed equally. This work has been submitted to the IEEE for possible publication. Copyright may be transferred without notice, after which this version may no longer be accessible. Project Website: https://aupendu.github.io/iterative-dehaz

    Enhanced DCP filter for Real-World Hazy Scenes

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    Haze is an atmospheric phenomenon that considerably degrades the visibility of out- door scenes. This happens due to atmosphere particles that absorb and disperse the sunshine. This paper introduces a unique single image visibility restoration algorithm that enhances visibility of such corrupted pictures. A unique edge-preserving decomposition-based technique is prepared to estimate transmission map for a haze image. Therefore, haze removal algorithmic rule has been taken from Koschmiedars law that includes a quick replacement-variation approach to dehaze and denoise at the same time. The proposed technique Enhanced DCP Filter (EDCPF) initially estimates a transmission map employing a windows adaptive technique that supported the dark channel. Restoration of foggy images is an important issue for the de-weathering in computer vision. A new method has been introduced for estimating the optical transmission in hazy scenes. Based on this estimation, the scattered light is eliminated to increase scene visibility and recover haze-free scenes

    Scattering Removal for Finger-Vein Image Restoration

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    Finger-vein recognition has received increased attention recently. However, the finger-vein images are always captured in poor quality. This certainly makes finger-vein feature representation unreliable, and further impairs the accuracy of finger-vein recognition. In this paper, we first give an analysis of the intrinsic factors causing finger-vein image degradation, and then propose a simple but effective image restoration method based on scattering removal. To give a proper description of finger-vein image degradation, a biological optical model (BOM) specific to finger-vein imaging is proposed according to the principle of light propagation in biological tissues. Based on BOM, the light scattering component is sensibly estimated and properly removed for finger-vein image restoration. Finally, experimental results demonstrate that the proposed method is powerful in enhancing the finger-vein image contrast and in improving the finger-vein image matching accuracy

    Non-aligned supervision for Real Image Dehazing

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    Removing haze from real-world images is challenging due to unpredictable weather conditions, resulting in misaligned hazy and clear image pairs. In this paper, we propose a non-aligned supervision framework that consists of three networks - dehazing, airlight, and transmission. In particular, we explore a non-alignment setting by utilizing a clear reference image that is not aligned with the hazy input image to supervise the dehazing network through a multi-scale reference loss that compares the features of the two images. Our setting makes it easier to collect hazy/clear image pairs in real-world environments, even under conditions of misalignment and shift views. To demonstrate this, we have created a new hazy dataset called "Phone-Hazy", which was captured using mobile phones in both rural and urban areas. Additionally, we present a mean and variance self-attention network to model the infinite airlight using dark channel prior as position guidance, and employ a channel attention network to estimate the three-channel transmission. Experimental results show that our framework outperforms current state-of-the-art methods in the real-world image dehazing. Phone-Hazy and code will be available at https://github.com/hello2377/NSDNet

    Contrast enhancement and exposure correction using a structure-aware distribution fitting

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    Realce de contraste e correção de exposição são úteis em aplicações domésticas e técnicas, no segundo caso como uma etapa de pré-processamento para outras técnicas ou para ajudar a observação humana. Frequentemente, uma transformação localmente adaptativa é mais adequada para a tarefa do que uma transformação global. Por exemplo, objetos e regiões podem ter níveis de iluminação muito diferentes, fenômenos físicos podem comprometer o contraste em algumas regiões mas não em outras, ou pode ser desejável ter alta visibilidade de detalhes em todas as partes da imagem. Para esses casos, métodos de realce de imagem locais são preferíveis. Embora existam muitos métodos de realce de contraste e correção de exposição disponíveis na literatura, não há uma solução definitiva que forneça um resultado satisfatório em todas as situações, e novos métodos surgem a cada ano. Em especial, os métodos tradicionais baseados em equalização adaptativa de histograma sofrem dos efeitos checkerboard e staircase e de excesso de realce. Esta dissertação propõe um método para realce de contraste e correção de exposição em imagens chamado Structure-Aware Distribution Stretching (SADS). O método ajusta regionalmente à imagem um modelo paramétrico de distribuição de probabilidade, respeitando a estrutura da imagem e as bordas entre as regiões. Isso é feito usando versões regionais das expressões clássicas de estimativa dos parâmetros da distribuição, que são obtidas substituindo a mé- dia amostral presente nas expressões originais por um filtro de suavização que preserva as bordas. Após ajustar a distribuição, a função de distribuição acumulada (CDF) do modelo ajustado e a inversa da CDF da distribuição desejada são aplicadas. Uma heurística ciente de estrutura que detecta regiões suaves é proposta e usada para atenuar as transformações em regiões planas. SADS foi comparado a outros métodos da literatura usando métricas objetivas de avaliação de qualidade de imagem (IQA) sem referência e com referência completa nas tarefas de realce de contraste e correção de exposição simultâneos e na tarefa de defogging/dehazing. Os experimentos indicam um desempenho geral superior do SADS em relação aos métodos comparados para os conjuntos de imagens usados, de acordo com as métricas IQA adotadas.Contrast enhancement and exposure correction are useful in domestic and technical applications, the latter as a preprocessing step for other techniques or for aiding human observation. Often, a locally adaptive transformation is more suitable for the task than a global transformation. For example, objects and regions may have very different levels of illumination, physical phenomena may compromise the contrast at some regions but not at others, or it may be desired to have high visibility of details in all parts of the image. For such cases, local image enhancement methods are preferable. Although there are many contrast enhancement and exposure correction methods available in the literature, there is no definitive solution that provides a satisfactory result in all situations, and new methods emerge each year. In special, traditional adaptive histogram equalization-based methods suffer from checkerboard and staircase effects and from over enhancement. This dissertation proposes a method for contrast enhancement and exposure correction in images named Structure-Aware Distribution Stretching (SADS). The method fits a parametric model of probability distribution to the image regionally while respecting the image structure and edges between regions. This is done using regional versions of the classical expressions for estimating the parameters of the distribution, which are obtained by replacing the sample mean present in the original expressions by an edge-preserving smoothing filter. After fitting the distribution, the cumulative distribution function (CDF) of the adjusted model and the inverse of the CDF of the desired distribution are applied. A structure-aware heuristic to indicate smooth regions is proposed and used to attenuate the transformations in flat regions. SADS was compared with other methods from the literature using objective no-reference and full-reference image quality assessment (IQA) metrics in the tasks of simultaneous contrast enhancement and exposure correction and in the task of defogging/dehazing. The experiments indicate a superior overall performance of SADS with respect to the compared methods for the image sets used, according to the IQA metrics adopted

    Visibility recovery on images acquired in attenuating media. Application to underwater, fog, and mammographic imaging

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    136 p.When acquired in attenuating media, digital images of ten suffer from a particularly complex degradation that reduces their visual quality, hindering their suitability for further computational applications, or simply decreasing the visual pleasan tness for the user. In these cases, mathematical image processing reveals it self as an ideal tool to recover some of the information lost during the degradation process. In this dissertation,we deal with three of such practical scenarios in which this problematic is specially relevant, namely, underwater image enhancement, fogremoval and mammographic image processing. In the case of digital mammograms,X-ray beams traverse human tissue, and electronic detectorscapture them as they reach the other side. However, the superposition on a bidimensional image of three-dimensional structures produces low contraste dimages in which structures of interest suffer from a diminished visibility, obstructing diagnosis tasks. Regarding fog removal, the loss of contrast is produced by the atmospheric conditions, and white colour takes over the scene uniformly as distance increases, also reducing visibility.For underwater images, there is an added difficulty, since colour is not lost uniformly; instead, red colours decay the fastest, and green and blue colours typically dominate the acquired images. To address all these challenges,in this dissertation we develop new methodologies that rely on: a)physical models of the observed degradation, and b) the calculus of variations.Equipped with this powerful machinery, we design novel theoreticaland computational tools, including image-dependent functional energies that capture the particularities of each degradation model. These energie sare composed of different integral terms that are simultaneous lyminimized by means of efficient numerical schemes, producing a clean,visually-pleasant and use ful output image, with better contrast and increased visibility. In every considered application, we provide comprehensive qualitative (visual) and quantitative experimental results to validateour methods, confirming that the developed techniques out perform other existing approaches in the literature

    impact of dehazing on underwater marker detection for augmented reality

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    Underwater augmented reality is a very challenging task and amongst several issues, one of the most crucial aspects involves real-time tracking. Particles present in water combined with the uneven absorption of light decrease the visibility in the underwater environment. Dehazing methods are used in many areas to improve the quality of digital image data that is degraded by the influence of the environment. This paper describes the visibility conditions affecting underwater scenes and shows existing dehazing techniques that successfully improve the quality of underwater images. Four underwater dehazing methods are selected for evaluation of their capability of improving the success of square marker detection in underwater videos. Two reviewed methods represent approaches of image restoration: Multi-Scale Fusion, and Bright Channel Prior. Another two methods evaluated, the Automatic Color Enhancement and the Screened Poisson Equation, are methods of image enhancement. The evaluation uses diverse test data set to evaluate different environmental conditions. Results of the evaluation show an increased number of successful marker detections in videos pre-processed by dehazing algorithms and evaluate the performance of each compared method. The Screened Poisson method performs slightly better to other methods across various tested environments, while Bright Channel Prior and Automatic Color Enhancement shows similarly positive results

    Mapping and Deep Analysis of Image Dehazing: Coherent Taxonomy, Datasets, Open Challenges, Motivations, and Recommendations

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    Our study aims to review and analyze the most relevant studies in the image dehazing field. Many aspects have been deemed necessary to provide a broad understanding of various studies that have been examined through surveying the existing literature. These aspects are as follows: datasets that have been used in the literature, challenges that other researchers have faced, motivations, and recommendations for diminishing the obstacles in the reported literature. A systematic protocol is employed to search all relevant articles on image dehazing, with variations in keywords, in addition to searching for evaluation and benchmark studies. The search process is established on three online databases, namely, IEEE Xplore, Web of Science (WOS), and ScienceDirect (SD), from 2008 to 2021. These indices are selected because they are sufficient in terms of coverage. Along with definition of the inclusion and exclusion criteria, we include 152 articles to the final set. A total of 55 out of 152 articles focused on various studies that conducted image dehazing, and 13 out 152 studies covered most of the review papers based on scenarios and general overviews. Finally, most of the included articles centered on the development of image dehazing algorithms based on real-time scenario (84/152) articles. Image dehazing removes unwanted visual effects and is often considered an image enhancement technique, which requires a fully automated algorithm to work under real-time outdoor applications, a reliable evaluation method, and datasets based on different weather conditions. Many relevant studies have been conducted to meet these critical requirements. We conducted objective image quality assessment experimental comparison of various image dehazing algorithms. In conclusions unlike other review papers, our study distinctly reflects different observations on image dehazing areas. We believe that the result of this study can serve as a useful guideline for practitioners who are looking for a comprehensive view on image dehazing
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