The ability to jointly learn from multiple modalities, such as text, audio, and visual data, is a defining feature of intelligent systems. While there have been promising advances in designing neural networks to harness multimodal data, the enormous success of data augmentation currently remains limited to single-modality tasks like image classification. Indeed, it is particularly difficult to augment each modality while preserving the overall semantic structure of the data; for example, a caption may no longer be a good description of an image after standard augmentations have been applied, such as translation. Moreover, it is challenging to specify reasonable transformations that are not tailored to a particular modality. In this paper, we introduce LeMDA, Learning Multimodal Data Augmentation, an easy-to-use method that automatically learns to jointly augment multimodal data in feature space, with no constraints on the identities of the modalities or the relationship between modalities. We show that LeMDA can (1) profoundly improve the performance of multimodal deep learning architectures, (2) apply to combinations of modalities that have not been previously considered, and (3) achieve state-of-the-art results on a wide range of applications comprised of image, text, and tabular data.

The number of international benchmarking competitions is steadily increasing in various fields of machine learning (ML) research and practice. So far, however, little is known about the common practice as well as bottlenecks faced by the community in tackling the research questions posed. To shed light on the status quo of algorithm development in the specific field of biomedical imaging analysis, we designed an international survey that was issued to all participants of challenges conducted in conjunction with the IEEE ISBI 2021 and MICCAI 2021 conferences (80 competitions in total). The survey covered participants' expertise and working environments, their chosen strategies, as well as algorithm characteristics. A median of 72% challenge participants took part in the survey. According to our results, knowledge exchange was the primary incentive (70%) for participation, while the reception of prize money played only a minor role (16%). While a median of 80 working hours was spent on method development, a large portion of participants stated that they did not have enough time for method development (32%). 25% perceived the infrastructure to be a bottleneck. Overall, 94% of all solutions were deep learning-based. Of these, 84% were based on standard architectures. 43% of the respondents reported that the data samples (e.g., images) were too large to be processed at once. This was most commonly addressed by patch-based training (69%), downsampling (37%), and solving 3D analysis tasks as a series of 2D tasks. K-fold cross-validation on the training set was performed by only 37% of the participants and only 50% of the participants performed ensembling based on multiple identical models (61%) or heterogeneous models (39%). 48% of the respondents applied postprocessing steps.

Real-time monocular 3D reconstruction is a challenging problem that remains unsolved. Although recent end-to-end methods have demonstrated promising results, tiny structures and geometric boundaries are hardly captured due to their insufficient supervision neglecting spatial details and oversimplified feature fusion ignoring temporal cues. To address the problems, we propose an end-to-end 3D reconstruction network SST, which utilizes Sparse estimated points from visual SLAM system as additional Spatial guidance and fuses Temporal features via a novel cross-modal attention mechanism, achieving more detailed reconstruction results. We propose a Local Spatial-Temporal Fusion module to exploit more informative spatial-temporal cues from multi-view color information and sparse priors, as well a Global Spatial-Temporal Fusion module to refine the local TSDF volumes with the world-frame model from coarse to fine. Extensive experiments on ScanNet and 7-Scenes demonstrate that SST outperforms all state-of-the-art competitors, whilst keeping a high inference speed at 59 FPS, enabling real-world applications with real-time requirements.

Image-text retrieval in remote sensing aims to provide flexible information for data analysis and application. In recent years, state-of-the-art methods are dedicated to ``scale decoupling'' and ``semantic decoupling'' strategies to further enhance the capability of representation. However, these previous approaches focus on either the disentangling scale or semantics but ignore merging these two ideas in a union model, which extremely limits the performance of cross-modal retrieval models. To address these issues, we propose a novel Scale-Semantic Joint Decoupling Network (SSJDN) for remote sensing image-text retrieval. Specifically, we design the Bidirectional Scale Decoupling (BSD) module, which exploits Salience Feature Extraction (SFE) and Salience-Guided Suppression (SGS) units to adaptively extract potential features and suppress cumbersome features at other scales in a bidirectional pattern to yield different scale clues. Besides, we design the Label-supervised Semantic Decoupling (LSD) module by leveraging the category semantic labels as prior knowledge to supervise images and texts probing significant semantic-related information. Finally, we design a Semantic-guided Triple Loss (STL), which adaptively generates a constant to adjust the loss function to improve the probability of matching the same semantic image and text and shorten the convergence time of the retrieval model. Our proposed SSJDN outperforms state-of-the-art approaches in numerical experiments conducted on four benchmark remote sensing datasets.

Although existing semi-supervised learning models achieve remarkable success in learning with unannotated in-distribution data, they mostly fail to learn on unlabeled data sampled from novel semantic classes due to their closed-set assumption. In this work, we target a pragmatic but under-explored Generalized Novel Category Discovery (GNCD) setting. The GNCD setting aims to categorize unlabeled training data coming from known and novel classes by leveraging the information of partially labeled known classes. We propose a two-stage Contrastive Affinity Learning method with auxiliary visual Prompts, dubbed PromptCAL, to address this challenging problem. Our approach discovers reliable pairwise sample affinities to learn better semantic clustering of both known and novel classes for the class token and visual prompts. First, we propose a discriminative prompt regularization loss to reinforce semantic discriminativeness of prompt-adapted pre-trained vision transformer for refined affinity relationships. Besides, we propose a contrastive affinity learning stage to calibrate semantic representations based on our iterative semi-supervised affinity graph generation method for semantically-enhanced prompt supervision. Extensive experimental evaluation demonstrates that our PromptCAL method is more effective in discovering novel classes even with limited annotations and surpasses the current state-of-the-art on generic and fine-grained benchmarks (with nearly $11\%$ gain on CUB-200, and $9\%$ on ImageNet-100) on overall accuracy.

Recently, the dominant DETR-based approaches apply central-concept spatial prior to accelerate Transformer detector convergency. These methods gradually refine the reference points to the center of target objects and imbue object queries with the updated central reference information for spatially conditional attention. However, centralizing reference points may severely deteriorate queries' saliency and confuse detectors due to the indiscriminative spatial prior. To bridge the gap between the reference points of salient queries and Transformer detectors, we propose SAlient Point-based DETR (SAP-DETR) by treating object detection as a transformation from salient points to instance objects. In SAP-DETR, we explicitly initialize a query-specific reference point for each object query, gradually aggregate them into an instance object, and then predict the distance from each side of the bounding box to these points. By rapidly attending to query-specific reference region and other conditional extreme regions from the image features, SAP-DETR can effectively bridge the gap between the salient point and the query-based Transformer detector with a significant convergency speed. Our extensive experiments have demonstrated that SAP-DETR achieves 1.4 times convergency speed with competitive performance. Under the standard training scheme, SAP-DETR stably promotes the SOTA approaches by 1.0 AP. Based on ResNet-DC-101, SAP-DETR achieves 46.9 AP.

高光谱成像技术（HSI）在远程分布光谱波长上记录了视觉信息。代表性的高光谱图像采集程序通过编码的光圈快照光谱成像器（CASSI）进行了3D到2D的编码，并且需要用于3D信号重建的软件解码器。基于此编码程序，两个主要挑战妨碍了高保真重建的方式：（i）获得2D测量值，CASSI通过分散器触觉并将其挤压到同一空间区域，从。 （ii）物理编码的光圈（掩码）将通过选择性阻止像素的光曝光来导致掩盖数据丢失。为了应对这些挑战，我们提出了具有面膜感知的学习策略的空间光谱（S2-）变压器体系结构。首先，我们同时利用空间和光谱注意模型来沿两个维度划分2D测量中的混合信息。空间和光谱线索跨的一系列变压器结构是系统设计的，它考虑了两倍提示之间的信息相互依赖性。其次，蒙面的像素将引起更高的预测难度，应与未掩盖的像素不同。因此，我们通过推断出对蒙版意识预测的难度级别来适应归因于面具结构的损失惩罚。我们提出的方法不仅定量设置了新的最新方法，而且在结构化区域中产生了更好的感知质量。

语义本地化（SELO）是指使用语义信息（例如文本）在大规模遥感（RS）图像中获得最相关位置的任务。作为基于跨模式检索的新兴任务，Selo仅使用字幕级注释来实现语义级检索，这表明了其在统一下游任务方面的巨大潜力。尽管Selo已连续执行，但目前没有系统地探索并分析了这一紧急方向。在本文中，我们彻底研究了这一领域，并根据指标和测试数据提供了完整的基准，以推进SELO任务。首先，基于此任务的特征，我们提出了多个判别评估指标来量化SELO任务的性能。设计的显着面积比例，注意力转移距离和离散的注意距离可用于评估从像素级别和区域级别中产生的SELO图。接下来，为了为SELO任务提供标准评估数据，我们为多样化的，多语义的，多目标语义定位测试集（AIR-SLT）贡献。 AIR-SLT由22个大型RS图像和59个具有不同语义的测试用例组成，旨在为检索模型提供全面的评估。最后，我们详细分析了RS跨模式检索模型的SELO性能，探索不同变量对此任务的影响，并为SELO任务提供了完整的基准测试。我们还建立了一个新的范式来引用RS表达理解，并通过将其与检测和道路提取等任务相结合，证明了Selo在语义中的巨大优势。拟议的评估指标，语义本地化测试集和相应的脚本已在github.com/xiaoyuan1996/semanticlocalizationmetrics上访问。

大量的数据和创新算法使数据驱动的建模成为现代行业的流行技术。在各种数据驱动方法中，潜在变量模型（LVM）及其对应物占主要份额，并在许多工业建模领域中起着至关重要的作用。 LVM通常可以分为基于统计学习的经典LVM和基于神经网络的深层LVM（DLVM）。我们首先讨论经典LVM的定义，理论和应用，该定义和应用既是综合教程，又是对经典LVM的简短申请调查。然后，我们对当前主流DLVM进行了彻底的介绍，重点是其理论和模型体系结构，此后不久就提供了有关DLVM的工业应用的详细调查。上述两种类型的LVM具有明显的优势和缺点。具体而言，经典的LVM具有简洁的原理和良好的解释性，但是它们的模型能力无法解决复杂的任务。基于神经网络的DLVM具有足够的模型能力，可以在复杂的场景中实现令人满意的性能，但它以模型的解释性和效率为例。旨在结合美德并减轻这两种类型的LVM的缺点，并探索非神经网络的举止以建立深层模型，我们提出了一个新颖的概念，称为“轻量级Deep LVM（LDLVM）”。在提出了这个新想法之后，该文章首先阐述了LDLVM的动机和内涵，然后提供了两个新颖的LDLVM，并详尽地描述了其原理，建筑和优点。最后，讨论了前景和机会，包括重要的开放问题和可能的研究方向。

图神经网络（GNN）在图形分类和多样化的下游现实世界应用方面取得了巨大成功。尽管他们成功了，但现有的方法要么仅限于结构攻击，要么仅限于本地信息。这要求在图形分类上建立更一般的攻击框架，由于使用全球图表级信息生成本地节点级的对抗示例的复杂性，因此面临重大挑战。为了解决这个“全局到本地”问题，我们提出了一个通用框架CAMA，以通过层次样式操纵图形结构和节点特征来生成对抗性示例。具体而言，我们利用Graph类激活映射及其变体来产​​生与图形分类任务相对应的节点级的重要性。然后，通过算法的启发式设计，我们可以借助节点级别和子图级的重要性在不明显的扰动预算下执行功能和结构攻击。在六个现实世界基准上攻击四个最先进的图形分类模型的实验验证了我们框架的灵活性和有效性。