深度映射记录场景中的视点和对象之间的距离,这在许多真实应用程序中起着关键作用。然而,消费者级RGB-D相机捕获的深度图遭受了低空间分辨率。引导深度地图超分辨率(DSR)是解决此问题的流行方法,该方法试图从输入的低分辨率(LR)深度及其耦合的HR RGB图像中恢复高分辨率(HR)深度映射和作为指引。引导DSR最具挑战性的问题是如何正确选择一致的结构并传播它们,并正确处理不一致的结构。在本文中,我们提出了一种用于引导DSR的新型关注的分层多模态融合(AHMF)网络。具体地,为了有效地提取和组合来自LR深度和HR引导的相关信息,我们提出了一种基于多模态注意力的融合(MMAF)策略,包括分层卷积层,包括特征增强块,以选择有价值的功能和特征重新校准块来统一不同外观特征的方式的相似性度量。此外,我们提出了一个双向分层特征协作(BHFC)模块,以完全利用多尺度特征之间的低级空间信息和高级结构信息。实验结果表明,在重建精度,运行速度和记忆效率方面,我们的方法优于最先进的方法。
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引导过滤器是计算机视觉和计算机图形中的基本工具,旨在将结构信息从引导图像传输到目标图像。大多数现有方法构造来自指导本身的滤波器内核,而不考虑指导和目标之间的相互依赖性。然而,由于两种图像中通常存在显着不同的边沿,只需将引导的所有结构信息传送到目标即将导致各种伪像。要应对这个问题,我们提出了一个名为Deep Enterponal引导图像过滤的有效框架,其过滤过程可以完全集成两个图像中包含的互补信息。具体地,我们提出了一种注意力内核学习模块,分别从引导和目标生成双组滤波器内核,然后通过在两个图像之间建模像素方向依赖性来自适应地组合它们。同时,我们提出了一种多尺度引导图像滤波模块,以粗略的方式通过所构造的内核逐渐产生滤波结果。相应地,引入了多尺度融合策略以重用中间导点在粗略的过程中。广泛的实验表明,所提出的框架在广泛的引导图像滤波应用中,诸如引导超分辨率,横向模态恢复,纹理拆除和语义分割的最先进的方法。
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引导深度超分辨率(GDSR)是多模态图像处理中的必要主题,其在同一场景的HR RGB图像的帮助下重建与次优条件的低分辨率的高分辨率(HR)深度映射。为了解决解释工作机制的挑战,提取过度转移的跨模型特征和RGB纹理,我们提出了一种新颖的离散余弦变换网络(DCTNet)来缓解三个方面的问题。首先,离散余弦变换(DCT)模块通过使用DCT来解决来自GDSR的图像域的频道明智的优化问题来重建多通道HR深度特征。其次,我们介绍了一个半耦合特征提取模块,使用共享卷积核,以提取公共功能和私有内核,以提取特定的模态特征。第三,我们采用了边缘注意机制,以突出导致导游的轮廓。广泛的定量和定性评估表明了我们的DCTNET的有效性,这优于以前的最先进方法,具有相对较少的参数。代码将公开。
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深度完成旨在预测从深度传感器(例如Lidars)中捕获的极稀疏图的密集像素深度。它在各种应用中起着至关重要的作用,例如自动驾驶,3D重建,增强现实和机器人导航。基于深度学习的解决方案已经证明了这项任务的最新成功。在本文中,我们首次提供了全面的文献综述,可帮助读者更好地掌握研究趋势并清楚地了解当前的进步。我们通过通过对现有方法进行分类的新型分类法提出建议,研究网络体系结构,损失功能,基准数据集和学习策略的设计方面的相关研究。此外,我们在包括室内和室外数据集(包括室内和室外数据集)上进行了三个广泛使用基准测试的模型性能进行定量比较。最后,我们讨论了先前作品的挑战,并为读者提供一些有关未来研究方向的见解。
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Depth map super-resolution (DSR) has been a fundamental task for 3D computer vision. While arbitrary scale DSR is a more realistic setting in this scenario, previous approaches predominantly suffer from the issue of inefficient real-numbered scale upsampling. To explicitly address this issue, we propose a novel continuous depth representation for DSR. The heart of this representation is our proposed Geometric Spatial Aggregator (GSA), which exploits a distance field modulated by arbitrarily upsampled target gridding, through which the geometric information is explicitly introduced into feature aggregation and target generation. Furthermore, bricking with GSA, we present a transformer-style backbone named GeoDSR, which possesses a principled way to construct the functional mapping between local coordinates and the high-resolution output results, empowering our model with the advantage of arbitrary shape transformation ready to help diverse zooming demand. Extensive experimental results on standard depth map benchmarks, e.g., NYU v2, have demonstrated that the proposed framework achieves significant restoration gain in arbitrary scale depth map super-resolution compared with the prior art. Our codes are available at https://github.com/nana01219/GeoDSR.
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This paper explores the problem of reconstructing high-resolution light field (LF) images from hybrid lenses, including a high-resolution camera surrounded by multiple low-resolution cameras. The performance of existing methods is still limited, as they produce either blurry results on plain textured areas or distortions around depth discontinuous boundaries. To tackle this challenge, we propose a novel end-to-end learning-based approach, which can comprehensively utilize the specific characteristics of the input from two complementary and parallel perspectives. Specifically, one module regresses a spatially consistent intermediate estimation by learning a deep multidimensional and cross-domain feature representation, while the other module warps another intermediate estimation, which maintains the high-frequency textures, by propagating the information of the high-resolution view. We finally leverage the advantages of the two intermediate estimations adaptively via the learned attention maps, leading to the final high-resolution LF image with satisfactory results on both plain textured areas and depth discontinuous boundaries. Besides, to promote the effectiveness of our method trained with simulated hybrid data on real hybrid data captured by a hybrid LF imaging system, we carefully design the network architecture and the training strategy. Extensive experiments on both real and simulated hybrid data demonstrate the significant superiority of our approach over state-of-the-art ones. To the best of our knowledge, this is the first end-to-end deep learning method for LF reconstruction from a real hybrid input. We believe our framework could potentially decrease the cost of high-resolution LF data acquisition and benefit LF data storage and transmission.
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卷积神经网络(CNN)不仅被广泛普及,而且在包括图像分类,恢复和生成在内的许多应用中都取得了明显的结果。尽管卷积的重量共享特性使它们在各种任务中被广泛采用,但其内容不足的特征也可以视为主要缺点。为了解决这个问题,在本文中,我们提出了一个新型操作,称为Pixel自适应核(PAKA)。 Paka通过从可学习的功能中乘以空间变化的注意力来提供对滤波器重量的方向性。所提出的方法会沿通道和空间方向分别渗入像素自适应的注意图,以使用较少的参数来解决分解模型。我们的方法可以以端到端的方式训练,并且适用于任何基于CNN的模型。此外,我们建议使用PAKA改进的信息聚合模块,称为层次PAKA模块(HPM)。与常规信息聚合模块相比,我们通过在语义细分方面提出最先进的性能来证明HPM的优势。我们通过其他消融研究来验证提出的方法,并可视化PAKA的效果,从而为卷积的权重提供了方向性。我们还通过将其应用于多模式任务,尤其是颜色引导的深度图超分辨率来显示该方法的普遍性。
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Convolutional Neural Network (CNN)-based image super-resolution (SR) has exhibited impressive success on known degraded low-resolution (LR) images. However, this type of approach is hard to hold its performance in practical scenarios when the degradation process is unknown. Despite existing blind SR methods proposed to solve this problem using blur kernel estimation, the perceptual quality and reconstruction accuracy are still unsatisfactory. In this paper, we analyze the degradation of a high-resolution (HR) image from image intrinsic components according to a degradation-based formulation model. We propose a components decomposition and co-optimization network (CDCN) for blind SR. Firstly, CDCN decomposes the input LR image into structure and detail components in feature space. Then, the mutual collaboration block (MCB) is presented to exploit the relationship between both two components. In this way, the detail component can provide informative features to enrich the structural context and the structure component can carry structural context for better detail revealing via a mutual complementary manner. After that, we present a degradation-driven learning strategy to jointly supervise the HR image detail and structure restoration process. Finally, a multi-scale fusion module followed by an upsampling layer is designed to fuse the structure and detail features and perform SR reconstruction. Empowered by such degradation-based components decomposition, collaboration, and mutual optimization, we can bridge the correlation between component learning and degradation modelling for blind SR, thereby producing SR results with more accurate textures. Extensive experiments on both synthetic SR datasets and real-world images show that the proposed method achieves the state-of-the-art performance compared to existing methods.
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Face Restoration (FR) aims to restore High-Quality (HQ) faces from Low-Quality (LQ) input images, which is a domain-specific image restoration problem in the low-level computer vision area. The early face restoration methods mainly use statistic priors and degradation models, which are difficult to meet the requirements of real-world applications in practice. In recent years, face restoration has witnessed great progress after stepping into the deep learning era. However, there are few works to study deep learning-based face restoration methods systematically. Thus, this paper comprehensively surveys recent advances in deep learning techniques for face restoration. Specifically, we first summarize different problem formulations and analyze the characteristic of the face image. Second, we discuss the challenges of face restoration. Concerning these challenges, we present a comprehensive review of existing FR methods, including prior based methods and deep learning-based methods. Then, we explore developed techniques in the task of FR covering network architectures, loss functions, and benchmark datasets. We also conduct a systematic benchmark evaluation on representative methods. Finally, we discuss future directions, including network designs, metrics, benchmark datasets, applications,etc. We also provide an open-source repository for all the discussed methods, which is available at https://github.com/TaoWangzj/Awesome-Face-Restoration.
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Informative features play a crucial role in the single image super-resolution task. Channel attention has been demonstrated to be effective for preserving information-rich features in each layer. However, channel attention treats each convolution layer as a separate process that misses the correlation among different layers. To address this problem, we propose a new holistic attention network (HAN), which consists of a layer attention module (LAM) and a channel-spatial attention module (CSAM), to model the holistic interdependencies among layers, channels, and positions. Specifically, the proposed LAM adaptively emphasizes hierarchical features by considering correlations among layers. Meanwhile, CSAM learns the confidence at all the positions of each channel to selectively capture more informative features. Extensive experiments demonstrate that the proposed HAN performs favorably against the state-ofthe-art single image super-resolution approaches.
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Existing convolutional neural networks (CNN) based image super-resolution (SR) methods have achieved impressive performance on bicubic kernel, which is not valid to handle unknown degradations in real-world applications. Recent blind SR methods suggest to reconstruct SR images relying on blur kernel estimation. However, their results still remain visible artifacts and detail distortion due to the estimation errors. To alleviate these problems, in this paper, we propose an effective and kernel-free network, namely DSSR, which enables recurrent detail-structure alternative optimization without blur kernel prior incorporation for blind SR. Specifically, in our DSSR, a detail-structure modulation module (DSMM) is built to exploit the interaction and collaboration of image details and structures. The DSMM consists of two components: a detail restoration unit (DRU) and a structure modulation unit (SMU). The former aims at regressing the intermediate HR detail reconstruction from LR structural contexts, and the latter performs structural contexts modulation conditioned on the learned detail maps at both HR and LR spaces. Besides, we use the output of DSMM as the hidden state and design our DSSR architecture from a recurrent convolutional neural network (RCNN) view. In this way, the network can alternatively optimize the image details and structural contexts, achieving co-optimization across time. Moreover, equipped with the recurrent connection, our DSSR allows low- and high-level feature representations complementary by observing previous HR details and contexts at every unrolling time. Extensive experiments on synthetic datasets and real-world images demonstrate that our method achieves the state-of-the-art against existing methods. The source code can be found at https://github.com/Arcananana/DSSR.
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本文通过控制功能级别的RGB图像和深度图之间的消息,介绍了RGB-D显着对象检测的新型深神经网络框架,并探索有关RGB和深度特征的远程语义上下文和几何信息推断出明显的对象。为了实现这一目标,我们通过图神经网络和可变形的卷积制定动态消息传播(DMP)模块,以动态学习上下文信息,并自动预测消息传播控制的过滤权重和亲和力矩阵。我们将该模块进一步嵌入基于暹罗的网络中,分别处理RGB图像和深度图,并设计多级特征融合(MFF)模块,以探索精制的RGB和深度特征之间的跨级信息。与六个基准数据集上用于RGB-D显着对象检测的17种最先进的方法相比,实验结果表明,我们的方法在定量和视觉上都优于其他所有方法。
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RGB-thermal显着对象检测(RGB-T SOD)旨在定位对齐可见的和热红外图像对的共同突出对象,并准确地分割所有属于这些对象的像素。由于对热图像的照明条件不敏感,它在诸如夜间和复杂背景之类的具有挑战性的场景中很有希望。因此,RGB-T SOD的关键问题是使两种方式的功能相互补充并互相调整,因为不可避免的是,由于极端光条件和诸如极端光条件和诸如极端光明条件和热跨界。在本文中,我们提出了一个针对RGB-T SOD的新型镜子互补变压器网络(MCNET)。具体而言,我们将基于变压器的特征提取模块引入RGB和热图像的有效提取分层特征。然后,通过基于注意力的特征相互作用和基于串行的多尺度扩张卷积(SDC)特征融合模块,提出的模型实现了低级特征的互补相互作用以及深度特征的语义融合。最后,基于镜子互补结构,即使是一种模态也可以准确地提取两种方式的显着区域也是无效的。为了证明在现实世界中具有挑战性的场景下提出的模型的鲁棒性,我们基于自动驾驶域中使用的大型公共语义分段RGB-T数据集建立了一种新颖的RGB-T SOD数据集VT723。基准和VT723数据集上的昂贵实验表明,所提出的方法优于最先进的方法,包括基于CNN的方法和基于变压器的方法。该代码和数据集将在稍后在https://github.com/jxr326/swinmcnet上发布。
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图像超分辨率(SR)是重要的图像处理方法之一,可改善计算机视野领域的图像分辨率。在过去的二十年中,在超级分辨率领域取得了重大进展,尤其是通过使用深度学习方法。这项调查是为了在深度学习的角度进行详细的调查,对单像超分辨率的最新进展进行详细的调查,同时还将告知图像超分辨率的初始经典方法。该调查将图像SR方法分类为四个类别,即经典方法,基于学习的方法,无监督学习的方法和特定领域的SR方法。我们还介绍了SR的问题,以提供有关图像质量指标,可用参考数据集和SR挑战的直觉。使用参考数据集评估基于深度学习的方法。一些审查的最先进的图像SR方法包括增强的深SR网络(EDSR),周期循环gan(Cincgan),多尺度残留网络(MSRN),Meta残留密度网络(META-RDN) ,反复反射网络(RBPN),二阶注意网络(SAN),SR反馈网络(SRFBN)和基于小波的残留注意网络(WRAN)。最后,这项调查以研究人员将解决SR的未来方向和趋势和开放问题的未来方向和趋势。
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面部超分辨率(FSR),也称为面部幻觉,其旨在增强低分辨率(LR)面部图像以产生高分辨率(HR)面部图像的分辨率,是特定于域的图像超分辨率问题。最近,FSR获得了相当大的关注,并目睹了深度学习技术的发展炫目。迄今为止,有很少有基于深入学习的FSR的研究摘要。在本次调查中,我们以系统的方式对基于深度学习的FSR方法进行了全面审查。首先,我们总结了FSR的问题制定,并引入了流行的评估度量和损失功能。其次,我们详细说明了FSR中使用的面部特征和流行数据集。第三,我们根据面部特征的利用大致分类了现有方法。在每个类别中,我们从设计原则的一般描述开始,然后概述代表方法,然后讨论其中的利弊。第四,我们评估了一些最先进的方法的表现。第五,联合FSR和其他任务以及与FSR相关的申请大致介绍。最后,我们设想了这一领域进一步的技术进步的前景。在\ URL {https://github.com/junjun-jiang/face-hallucination-benchmark}上有一个策划的文件和资源的策划文件和资源清单
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Camouflaged object detection (COD) aims to detect/segment camouflaged objects embedded in the environment, which has attracted increasing attention over the past decades. Although several COD methods have been developed, they still suffer from unsatisfactory performance due to the intrinsic similarities between the foreground objects and background surroundings. In this paper, we propose a novel Feature Aggregation and Propagation Network (FAP-Net) for camouflaged object detection. Specifically, we propose a Boundary Guidance Module (BGM) to explicitly model the boundary characteristic, which can provide boundary-enhanced features to boost the COD performance. To capture the scale variations of the camouflaged objects, we propose a Multi-scale Feature Aggregation Module (MFAM) to characterize the multi-scale information from each layer and obtain the aggregated feature representations. Furthermore, we propose a Cross-level Fusion and Propagation Module (CFPM). In the CFPM, the feature fusion part can effectively integrate the features from adjacent layers to exploit the cross-level correlations, and the feature propagation part can transmit valuable context information from the encoder to the decoder network via a gate unit. Finally, we formulate a unified and end-to-end trainable framework where cross-level features can be effectively fused and propagated for capturing rich context information. Extensive experiments on three benchmark camouflaged datasets demonstrate that our FAP-Net outperforms other state-of-the-art COD models. Moreover, our model can be extended to the polyp segmentation task, and the comparison results further validate the effectiveness of the proposed model in segmenting polyps. The source code and results will be released at https://github.com/taozh2017/FAPNet.
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A very deep convolutional neural network (CNN) has recently achieved great success for image super-resolution (SR) and offered hierarchical features as well. However, most deep CNN based SR models do not make full use of the hierarchical features from the original low-resolution (LR) images, thereby achieving relatively-low performance. In this paper, we propose a novel residual dense network (RDN) to address this problem in image SR. We fully exploit the hierarchical features from all the convolutional layers. Specifically, we propose residual dense block (RDB) to extract abundant local features via dense connected convolutional layers. RDB further allows direct connections from the state of preceding RDB to all the layers of current RDB, leading to a contiguous memory (CM) mechanism. Local feature fusion in RDB is then used to adaptively learn more effective features from preceding and current local features and stabilizes the training of wider network. After fully obtaining dense local features, we use global feature fusion to jointly and adaptively learn global hierarchical features in a holistic way. Experiments on benchmark datasets with different degradation models show that our RDN achieves favorable performance against state-of-the-art methods.
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随着深度学习的发展,单图像超分辨率(SISR)取得了重大突破。最近,已经提出了基于全局特征交互的SISR网络性能的方法。但是,需要动态地忽略对上下文的响应的神经元的功能。为了解决这个问题,我们提出了一个轻巧的交叉障碍性推理网络(CFIN),这是一个由卷积神经网络(CNN)和变压器组成的混合网络。具体而言,一种新型的交叉磁场导向变压器(CFGT)旨在通过使用调制卷积内核与局部代表性语义信息结合来自适应修改网络权重。此外,提出了基于CNN的跨尺度信息聚合模块(CIAM),以使模型更好地专注于潜在的实用信息并提高变压器阶段的效率。广泛的实验表明,我们提出的CFIN是一种轻巧有效的SISR模型,可以在计算成本和模型性能之间达到良好的平衡。
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卷积神经网络在过去十年中允许在单个图像超分辨率(SISR)中的显着进展。在SISR最近的进展中,关注机制对于高性能SR模型至关重要。但是,注意机制仍然不清楚为什么它在SISR中的工作原理。在这项工作中,我们试图量化和可视化SISR中的注意力机制,并表明并非所有关注模块都同样有益。然后,我们提出了关注网络(A $ ^ 2 $ n)的注意力,以获得更高效和准确的SISR。具体来说,$ ^ 2 $ n包括非关注分支和耦合注意力分支。提出了一种动态注意力模块,为这两个分支产生权重,以动态地抑制不需要的注意力调整,其中权重根据输入特征自适应地改变。这允许注意模块专门从事惩罚的有益实例,从而大大提高了注意力网络的能力,即几个参数开销。实验结果表明,我们的最终模型A $ ^ 2 $ n可以实现与类似尺寸的最先进网络相比的卓越的权衡性能。代码可以在https://github.com/haoyuc/a2n获得。
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高动态范围(HDR)成像是一种允许广泛的动态曝光范围的技术,这在图像处理,计算机图形和计算机视觉中很重要。近年来,使用深度学习(DL),HDR成像有重大进展。本研究对深层HDR成像方法的最新发展进行了综合和富有洞察力的调查和分析。在分层和结构上,将现有的深层HDR成像方法基于(1)输入曝光的数量/域,(2)学习任务数,(3)新传感器数据,(4)新的学习策略,(5)应用程序。重要的是,我们对关于其潜在和挑战的每个类别提供建设性的讨论。此外,我们审查了深度HDR成像的一些关键方面,例如数据集和评估指标。最后,我们突出了一些打开的问题,并指出了未来的研究方向。
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