By transferring knowledge from large, diverse, task-agnostic datasets, modern machine learning models can solve specific downstream tasks either zero-shot or with small task-specific datasets to a high level of performance. While this capability has been demonstrated in other fields such as computer vision, natural language processing or speech recognition, it remains to be shown in robotics, where the generalization capabilities of the models are particularly critical due to the difficulty of collecting real-world robotic data. We argue that one of the keys to the success of such general robotic models lies with open-ended task-agnostic training, combined with high-capacity architectures that can absorb all of the diverse, robotic data. In this paper, we present a model class, dubbed Robotics Transformer, that exhibits promising scalable model properties. We verify our conclusions in a study of different model classes and their ability to generalize as a function of the data size, model size, and data diversity based on a large-scale data collection on real robots performing real-world tasks. The project's website and videos can be found at robotics-transformer.github.io

最近的作品表明，如何将大语言模型（LLM）的推理能力应用于自然语言处理以外的领域，例如机器人的计划和互动。这些具体的问题要求代理商了解世界上许多语义方面：可用技能的曲目，这些技能如何影响世界以及对世界的变化如何映射回该语言。在体现环境中规划的LLMS不仅需要考虑要做什么技能，还需要考虑如何以及何时进行操作 - 答案随着时间的推移而变化，以响应代理商自己的选择。在这项工作中，我们调查了在这种体现的环境中使用的LLM在多大程度上可以推论通过自然语言提供的反馈来源，而无需任何其他培训。我们建议，通过利用环境反馈，LLM能够形成内部独白，使他们能够在机器人控制方案中进行更丰富的处理和计划。我们研究了各种反馈来源，例如成功检测，场景描述和人类互动。我们发现，闭环语言反馈显着改善了三个领域的高级指导完成，包括模拟和真实的桌面顶部重新排列任务以及现实世界中厨房环境中的长途移动操作任务。

大型语言模型可以编码有关世界的大量语义知识。这种知识对于旨在采取自然语言表达的高级，时间扩展的指示的机器人可能非常有用。但是，语言模型的一个重大弱点是，它们缺乏现实世界的经验，这使得很难利用它们在给定的体现中进行决策。例如，要求语言模型描述如何清洁溢出物可能会导致合理的叙述，但是它可能不适用于需要在特定环境中执行此任务的特定代理商（例如机器人）。我们建议通过预处理的技能来提供现实世界的基础，这些技能用于限制模型以提出可行且在上下文上适当的自然语言动作。机器人可以充当语​​言模型的“手和眼睛”，而语言模型可以提供有关任务的高级语义知识。我们展示了如何将低级技能与大语言模型结合在一起，以便语言模型提供有关执行复杂和时间扩展说明的过程的高级知识，而与这些技能相关的价值功能则提供了连接必要的基础了解特定的物理环境。我们在许多现实世界的机器人任务上评估了我们的方法，我们表明了对现实世界接地的需求，并且这种方法能够在移动操纵器上完成长远，抽象的自然语言指令。该项目的网站和视频可以在https://say-can.github.io/上找到。

通过模仿学习（IL）使用用户提供的演示，或者通过使用大量的自主收集的体验来学习机器人技能。方法具有互补的经验和缺点：RL可以达到高度的性能，但需要缺陷，但是需要缺乏要求，但是需要达到高水平的性能，但需要达到高度的性能这可能非常耗时和不安全; IL不要求Xploration，但只学习与所提供的示范一样好的技能。一种方法将两种方法的优势结合在一起？一系列的方法旨在解决这个问题，提出了整合IL和RL的元素的各种技术。然而，扩大了这种方法，这些方法复杂的机器人技能，整合了不同的离线数据，概括到现实世界的情景仍然存在重大挑战。在本文中，USAIM是测试先前IL + RL算法的可扩展性，并设计了一种系统的详细实验实验，这些实验结合了现有的组件，其具有效果有效和可扩展的方式。为此，我们展示了一系列关于了解每个设计决定的影响的一系列实验，以便开发可以利用示范和异构的先前数据在一系列现实世界和现实的模拟问题上获得最佳表现的批准方法。我们通过致电Wap-opt的完整方法将优势加权回归[1,2]和QT-opt [3]结合在一起，提供了一个UnifiedAgveach，用于集成机器人操作的演示和离线数据。请参阅HTTPS： //awopt.github.io有关更多详细信息。

强化学习可以培训有效执行复杂任务的政策。然而，对于长地平线任务，这些方法的性能与地平线脱落，通常需要推理和构成较低级别的技能。等级强化学习旨在通过为行动抽象提供一组低级技能来实现这一点。通过抽象空间状态，层次结构也可以进一步提高这一点。我们对适当的状态抽象应取决于可用的较低级别策略的功能。我们提出了价值函数空间：通过使用与每个较低级别的技能对应的值函数来产生这种表示的简单方法。这些价值函数捕获场景的可取性，从而形成了紧凑型摘要任务相关信息的表示，并强大地忽略了分散的人。迷宫解决和机器人操纵任务的实证评估表明，我们的方法提高了长地平的性能，并且能够比替代的无模型和基于模型的方法能够更好的零拍泛化。

Weakly-supervised object localization aims to indicate the category as well as the scope of an object in an image given only the image-level labels. Most of the existing works are based on Class Activation Mapping (CAM) and endeavor to enlarge the discriminative area inside the activation map to perceive the whole object, yet ignore the co-occurrence confounder of the object and context (e.g., fish and water), which makes the model inspection hard to distinguish object boundaries. Besides, the use of CAM also brings a dilemma problem that the classification and localization always suffer from a performance gap and can not reach their highest accuracy simultaneously. In this paper, we propose a casual knowledge distillation method, dubbed KD-CI-CAM, to address these two under-explored issues in one go. More specifically, we tackle the co-occurrence context confounder problem via causal intervention (CI), which explores the causalities among image features, contexts, and categories to eliminate the biased object-context entanglement in the class activation maps. Based on the de-biased object feature, we additionally propose a multi-teacher causal distillation framework to balance the absorption of classification knowledge and localization knowledge during model training. Extensive experiments on several benchmarks demonstrate the effectiveness of KD-CI-CAM in learning clear object boundaries from confounding contexts and addressing the dilemma problem between classification and localization performance.

An increasing number of public datasets have shown a marked clinical impact on assessing anatomical structures. However, each of the datasets is small, partially labeled, and rarely investigates severe tumor subjects. Moreover, current models are limited to segmenting specific organs/tumors, which can not be extended to novel domains and classes. To tackle these limitations, we introduce embedding learned from Contrastive Language-Image Pre-training (CLIP) to segmentation models, dubbed the CLIP-Driven Universal Model. The Universal Model can better segment 25 organs and 6 types of tumors by exploiting the semantic relationship between abdominal structures. The model is developed from an assembly of 14 datasets with 3,410 CT scans and evaluated on 6,162 external CT scans from 3 datasets. We rank first on the public leaderboard of the Medical Segmentation Decathlon (MSD) and achieve the state-of-the-art results on Beyond The Cranial Vault (BTCV). Compared with dataset-specific models, the Universal Model is computationally more efficient (6x faster), generalizes better to CT scans from varying sites, and shows stronger transfer learning performance on novel tasks. The design of CLIP embedding enables the Universal Model to be easily extended to new classes without catastrophically forgetting the previously learned classes.

In this work, we tackle two vital tasks in automated driving systems, i.e., driver intent prediction and risk object identification from egocentric images. Mainly, we investigate the question: what would be good road scene-level representations for these two tasks? We contend that a scene-level representation must capture higher-level semantic and geometric representations of traffic scenes around ego-vehicle while performing actions to their destinations. To this end, we introduce the representation of semantic regions, which are areas where ego-vehicles visit while taking an afforded action (e.g., left-turn at 4-way intersections). We propose to learn scene-level representations via a novel semantic region prediction task and an automatic semantic region labeling algorithm. Extensive evaluations are conducted on the HDD and nuScenes datasets, and the learned representations lead to state-of-the-art performance for driver intention prediction and risk object identification.

New architecture GPUs like A100 are now equipped with multi-instance GPU (MIG) technology, which allows the GPU to be partitioned into multiple small, isolated instances. This technology provides more flexibility for users to support both deep learning training and inference workloads, but efficiently utilizing it can still be challenging. The vision of this paper is to provide a more comprehensive and practical benchmark study for MIG in order to eliminate the need for tedious manual benchmarking and tuning efforts. To achieve this vision, the paper presents MIGPerf, an open-source tool that streamlines the benchmark study for MIG. Using MIGPerf, the authors conduct a series of experiments, including deep learning training and inference characterization on MIG, GPU sharing characterization, and framework compatibility with MIG. The results of these experiments provide new insights and guidance for users to effectively employ MIG, and lay the foundation for further research on the orchestration of hybrid training and inference workloads on MIGs. The code and results are released on https://github.com/MLSysOps/MIGProfiler. This work is still in progress and more results will be published soon.

There are multiple scales of abstraction from which we can describe the same image, depending on whether we are focusing on fine-grained details or a more global attribute of the image. In brain mapping, learning to automatically parse images to build representations of both small-scale features (e.g., the presence of cells or blood vessels) and global properties of an image (e.g., which brain region the image comes from) is a crucial and open challenge. However, most existing datasets and benchmarks for neuroanatomy consider only a single downstream task at a time. To bridge this gap, we introduce a new dataset, annotations, and multiple downstream tasks that provide diverse ways to readout information about brain structure and architecture from the same image. Our multi-task neuroimaging benchmark (MTNeuro) is built on volumetric, micrometer-resolution X-ray microtomography images spanning a large thalamocortical section of mouse brain, encompassing multiple cortical and subcortical regions. We generated a number of different prediction challenges and evaluated several supervised and self-supervised models for brain-region prediction and pixel-level semantic segmentation of microstructures. Our experiments not only highlight the rich heterogeneity of this dataset, but also provide insights into how self-supervised approaches can be used to learn representations that capture multiple attributes of a single image and perform well on a variety of downstream tasks. Datasets, code, and pre-trained baseline models are provided at: https://mtneuro.github.io/ .