GPT-3显示了培训的大规模语言模型（LMS）的卓越情调学习能力，培训数十亿规模数据。在这里，我们解决了GPT-3纸张报告的一些剩余问题，例如非英语LM，不同大小模型的性能，以及最近引入的迅速优化对上下文学习的效果。为实现这一目标，我们介绍了HyperClova，一个韩国VPT-3的韩国变体训练在一个以韩国为中心的560b标准的令牌。通过我们的韩国特定标记化，HyperClova与我们的培训配置增强，显示了韩国各种下游任务的最先进的上下游零射击和几秒钟学习表演。此外，我们展示了基于及时的学习的性能优势，并演示如何集成到迅速的工程管道中。然后，我们讨论了通过引入Hyperclova Studio，互动提示工程界面向ML的非专家提供AI原型设计能力来实现No Code AI范例的可能性。最后，我们展示了我们具有三个成功的内部应用程序的方法的潜力。

我们解决了基于标签数据集基准群集技术的可靠性。外部聚类验证中的标准方案是基于每个类形成一个单一的，明显分离的群集的假设，将类标签用作地面真实群集。但是，由于这种集群标签匹配（CLM）的假设经常破坏，因此缺乏对基准数据集CLM的理智检查对外部验证的有效性产生怀疑。尽管如此，评估CLM的程度还是具有挑战性的。例如，内部聚类验证措施可用于量化同一数据集中的CLM以评估其不同的聚类，但并非旨在比较不同数据集的聚类。在这项工作中，我们提出了一种原则性的方法来生成数据集中的内部度量，以使CLM在数据集中进行比较。我们首先确定了数据集内措施之间的四个公理，并补充了Ackerman和Ben-David的数据库内公理。然后，我们提出了概括内部措施以实现这些新公理的过程，并使用它们扩展了广泛使用的Calinski-Harabasz索引，以进行数据库CLM之间的评估。通过定量实验，我们（1）验证了概括过程的有效性和必要性，（2）表明，所提出的数据与calinski-Harabasz索引索引准确地评估了整个数据集的CLM。最后，我们证明了在进行外部验证之前评估基准数据集的CLM的重要性。

我们引入了统一的歧管近似值，具有两相优化（UMATO），这是一种降低尺寸（DR）技术，可改善UMAP，以更准确地捕获高维数据的全局结构。在Umato中，优化分为两个阶段，因此所得的嵌入可以可靠地描绘出全球结构，同时以足够的精度保留局部结构。在第一阶段，识别并预测集线器点以构建全局结构的骨骼布局。在第二阶段，剩余点添加到保存地方区域特征的嵌入中。通过定量实验，我们发现Umato（1）在保留全局结构方面优于广泛使用的DR技术，而（2）在代表局部结构方面产生了竞争精度。我们还验证了Umato在鲁棒性方面比各种初始化方法，时期数量和亚采样技术优选。

域适应（DA）最近在医学影像社区提出了强烈的兴趣。虽然已经提出了大量DA技术进行了用于图像分割，但大多数这些技术已经在私有数据集或小公共可用数据集上验证。此外，这些数据集主要解决了单级问题。为了解决这些限制，与第24届医学图像计算和计算机辅助干预（Miccai 2021）结合第24届国际会议组织交叉模态域适应（Crossmoda）挑战。 Crossmoda是无监督跨型号DA的第一个大型和多级基准。挑战的目标是分割参与前庭施瓦新瘤（VS）的后续和治疗规划的两个关键脑结构：VS和Cochleas。目前，使用对比度增强的T1（CET1）MRI进行VS患者的诊断和监测。然而，使用诸如高分辨率T2（HRT2）MRI的非对比度序列越来越感兴趣。因此，我们创建了一个无人监督的跨模型分段基准。训练集提供注释CET1（n = 105）和未配对的非注释的HRT2（n = 105）。目的是在测试集中提供的HRT2上自动对HRT2进行单侧VS和双侧耳蜗分割（n = 137）。共有16支球队提交了评估阶段的算法。顶级履行团队达成的表现水平非常高（最佳中位数骰子 - vs：88.4％; Cochleas：85.7％）并接近完全监督（中位数骰子 - vs：92.5％;耳蜗：87.7％）。所有顶级执行方法都使用图像到图像转换方法将源域图像转换为伪目标域图像。然后使用这些生成的图像和为源图像提供的手动注释进行培训分割网络。

Graph Neural Networks (GNNs) have shown satisfying performance on various graph learning tasks. To achieve better fitting capability, most GNNs are with a large number of parameters, which makes these GNNs computationally expensive. Therefore, it is difficult to deploy them onto edge devices with scarce computational resources, e.g., mobile phones and wearable smart devices. Knowledge Distillation (KD) is a common solution to compress GNNs, where a light-weighted model (i.e., the student model) is encouraged to mimic the behavior of a computationally expensive GNN (i.e., the teacher GNN model). Nevertheless, most existing GNN-based KD methods lack fairness consideration. As a consequence, the student model usually inherits and even exaggerates the bias from the teacher GNN. To handle such a problem, we take initial steps towards fair knowledge distillation for GNNs. Specifically, we first formulate a novel problem of fair knowledge distillation for GNN-based teacher-student frameworks. Then we propose a principled framework named RELIANT to mitigate the bias exhibited by the student model. Notably, the design of RELIANT is decoupled from any specific teacher and student model structures, and thus can be easily adapted to various GNN-based KD frameworks. We perform extensive experiments on multiple real-world datasets, which corroborates that RELIANT achieves less biased GNN knowledge distillation while maintaining high prediction utility.

Despite significant progress in object categorization, in recent years, a number of important challenges remain; mainly, the ability to learn from limited labeled data and to recognize object classes within large, potentially open, set of labels. Zero-shot learning is one way of addressing these challenges, but it has only been shown to work with limited sized class vocabularies and typically requires separation between supervised and unsupervised classes, allowing former to inform the latter but not vice versa. We propose the notion of vocabulary-informed learning to alleviate the above mentioned challenges and address problems of supervised, zero-shot, generalized zero-shot and open set recognition using a unified framework. Specifically, we propose a weighted maximum margin framework for semantic manifold-based recognition that incorporates distance constraints from (both supervised and unsupervised) vocabulary atoms. Distance constraints ensure that labeled samples are projected closer to their correct prototypes, in the embedding space, than to others. We illustrate that resulting model shows improvements in supervised, zero-shot, generalized zero-shot, and large open set recognition, with up to 310K class vocabulary on Animal with Attributes and ImageNet datasets.

Understanding the informative structures of scenes is essential for low-level vision tasks. Unfortunately, it is difficult to obtain a concrete visual definition of the informative structures because influences of visual features are task-specific. In this paper, we propose a single general neural network architecture for extracting task-specific structure guidance for scenes. To do this, we first analyze traditional spectral clustering methods, which computes a set of eigenvectors to model a segmented graph forming small compact structures on image domains. We then unfold the traditional graph-partitioning problem into a learnable network, named \textit{Scene Structure Guidance Network (SSGNet)}, to represent the task-specific informative structures. The SSGNet yields a set of coefficients of eigenvectors that produces explicit feature representations of image structures. In addition, our SSGNet is light-weight ($\sim$ 55K parameters), and can be used as a plug-and-play module for off-the-shelf architectures. We optimize the SSGNet without any supervision by proposing two novel training losses that enforce task-specific scene structure generation during training. Our main contribution is to show that such a simple network can achieve state-of-the-art results for several low-level vision applications including joint upsampling and image denoising. We also demonstrate that our SSGNet generalizes well on unseen datasets, compared to existing methods which use structural embedding frameworks. Our source codes are available at https://github.com/jsshin98/SSGNet.

Advances in computer vision and machine learning techniques have led to significant development in 2D and 3D human pose estimation from RGB cameras, LiDAR, and radars. However, human pose estimation from images is adversely affected by occlusion and lighting, which are common in many scenarios of interest. Radar and LiDAR technologies, on the other hand, need specialized hardware that is expensive and power-intensive. Furthermore, placing these sensors in non-public areas raises significant privacy concerns. To address these limitations, recent research has explored the use of WiFi antennas (1D sensors) for body segmentation and key-point body detection. This paper further expands on the use of the WiFi signal in combination with deep learning architectures, commonly used in computer vision, to estimate dense human pose correspondence. We developed a deep neural network that maps the phase and amplitude of WiFi signals to UV coordinates within 24 human regions. The results of the study reveal that our model can estimate the dense pose of multiple subjects, with comparable performance to image-based approaches, by utilizing WiFi signals as the only input. This paves the way for low-cost, broadly accessible, and privacy-preserving algorithms for human sensing.

With the increasing ability of large language models (LLMs), in-context learning (ICL) has become a new paradigm for natural language processing (NLP), where LLMs make predictions only based on contexts augmented with a few training examples. It has been a new trend exploring ICL to evaluate and extrapolate the ability of LLMs. In this paper, we aim to survey and summarize the progress, challenges, and future work in ICL. We first present a formal definition of ICL and clarify its correlation to related studies. Then, we organize and discuss advanced techniques of ICL, including training strategies, prompting strategies, and so on. Finally, we present the challenges of ICL and provide potential directions for further research. We hope our work can encourage more research on uncovering how ICL works and improving ICL in future work.

Designing better deep networks and better reinforcement learning (RL) algorithms are both important for deep RL. This work focuses on the former. Previous methods build the network with several modules like CNN, LSTM and Attention. Recent methods combine the Transformer with these modules for better performance. However, it requires tedious optimization skills to train a network composed of mixed modules, making these methods inconvenient to be used in practice. In this paper, we propose to design \emph{pure Transformer-based networks} for deep RL, aiming at providing off-the-shelf backbones for both the online and offline settings. Specifically, the Transformer in Transformer (TIT) backbone is proposed, which cascades two Transformers in a very natural way: the inner one is used to process a single observation, while the outer one is responsible for processing the observation history; combining both is expected to extract spatial-temporal representations for good decision-making. Experiments show that TIT can achieve satisfactory performance in different settings, consistently.