事实证明，知识蒸馏是使用教师模型的预测来改善学生模型的一项有效技术。但是，最近的工作表明，在数据中的亚组中，平均效率的提高并不统一，尤其是在稀有亚组和类别上的准确性通常可能以准确性为代价。为了在可能遵循长尾分配的课程中保持强劲的表现，我们开发了蒸馏技术，这些技术是为了改善学生最差的级别表现而定制的。具体来说，我们为教师和学生介绍了不同组合的强大优化目标，并进一步允许在整体准确性和强大的最差目标之间进行任何权衡训练。我们从经验上表明，与其他基线方法相比，我们强大的蒸馏技术不仅可以实现更好的最差级别性能，而且还可以改善整体性能和最差的级别性能之间的权衡。从理论上讲，我们提供有关在目标培训健壮学生时使一名好老师的见解。

Real-world classification problems typically exhibit an imbalanced or long-tailed label distribution, wherein many labels are associated with only a few samples. This poses a challenge for generalisation on such labels, and also makes naïve learning biased towards dominant labels. In this paper, we present two simple modifications of standard softmax cross-entropy training to cope with these challenges. Our techniques revisit the classic idea of logit adjustment based on the label frequencies, either applied post-hoc to a trained model, or enforced in the loss during training. Such adjustment encourages a large relative margin between logits of rare versus dominant labels. These techniques unify and generalise several recent proposals in the literature, while possessing firmer statistical grounding and empirical performance. A reference implementation of our methods is available at: https://github.com/google-research/google-research/tree/master/logit_adjustment.Recently, long-tail learning has received renewed interest in the context of neural networks. Two active strands of work involve post-hoc normalisation of the classification weights [

与计算机视觉合并的基于无人机的遥感系统（UAV）遥感系统具有协助建筑物建设和灾难管理的潜力，例如地震期间的损害评估。可以通过检查来评估建筑物到地震的脆弱性，该检查考虑到相关组件的预期损害进展以及组件对结构系统性能的贡献。这些检查中的大多数是手动进行的，导致高利用人力，时间和成本。本文提出了一种通过基于无人机的图像数据收集和用于后处理的软件库来自动化这些检查的方法，该方法有助于估算地震结构参数。这里考虑的关键参数是相邻建筑物，建筑计划形状，建筑计划区域，屋顶上的对象和屋顶布局之间的距离。通过使用距离测量传感器以及通过Google Earth获得的数据进行的现场测量，可以验证所提出的方法在估计上述参数估算上述参数方面的准确性。可以从https://uvrsabi.github.io/访问其他详细信息和代码。

RDMA超过融合以太网（ROCE），由于其与常规以太网的织物的兼容性，对数据中心网络具有重要的吸引力。但是，RDMA协议仅在（几乎）无损网络上有效，这强调了拥塞控制对ROCE网络的重要作用。不幸的是，基于优先流量控制（PFC）的本地ROCE拥塞控制方案遭受了许多缺点，例如不公平，线路阻滞和僵局。因此，近年来，已经提出许多计划为ROCE网络提供额外的拥塞控制，以最大程度地减少PFC缺点。但是，这些方案是针对一般数据中心环境提出的。与使用商品硬件构建并运行通用工作负载的一般数据中心相反，高性能分布式培训平台部署高端加速器和网络组件，并专门使用集体（全能，全能，全能）运行培训工作负载）通信库进行通信。此外，这些平台通常具有一个私人网络，将其通信流量与其他数据中心流量分开。可扩展的拓扑意识集体算法固有地设计旨在避免造成的模式并最佳地平衡流量。这些独特的功能需要重新审视先前提出的通用数据中心环境的拥塞控制方案。在本文中，我们彻底分析了在分布式培训平台上运行时的一些SOTA ROCE拥塞控制方案与PFC。我们的结果表明，先前提出的ROCE拥塞控制计划对培训工作负载的端到端表现几乎没有影响，这激发了根据分布式培训平台和分布式培训平台和特征的设计优化但低空的拥塞控制计划的必要性工作负载。

数据增强是自然语言处理（NLP）模型的鲁棒性评估的重要组成部分，以及增强他们培训的数据的多样性。在本文中，我们呈现NL-Cogmenter，这是一种新的参与式Python的自然语言增强框架，它支持创建两个转换（对数据的修改）和过滤器（根据特定功能的数据拆分）。我们描述了框架和初始的117个变换和23个过滤器，用于各种自然语言任务。我们通过使用其几个转换来分析流行自然语言模型的鲁棒性来证明NL-Upmenter的功效。基础架构，Datacards和稳健性分析结果在NL-Augmenter存储库上公开可用（\ url {https://github.com/gem-benchmark/nl-augmenter}）。

基于实用的缺点风险（UBSR）是一种风险指标，越来越受到金融应用中的流行，由于它享有的某些理想的属性。我们考虑在递归设置中估算UBSR的问题，其中来自潜在损耗分布的样本是一次性的。我们将UBSR估计问题作为根发现问题，并提出了基于随机近似的估计方案。我们在样本数量的估计误差中获得了非渐近界。我们还考虑在随机变量的参数化类中的UBSR优化问题。我们提出了一种用于UBSR优化的随机梯度下降算法，并导出其收敛性的非渐近界。

We present a theoretically grounded approach to train deep neural networks, including recurrent networks, subject to class-dependent label noise. We propose two procedures for loss correction that are agnostic to both application domain and network architecture. They simply amount to at most a matrix inversion and multiplication, provided that we know the probability of each class being corrupted into another. We further show how one can estimate these probabilities, adapting a recent technique for noise estimation to the multi-class setting, and thus providing an end-to-end framework. Extensive experiments on MNIST, IMDB, CIFAR-10, CIFAR-100 and a large scale dataset of clothing images employing a diversity of architectures -stacking dense, convolutional, pooling, dropout, batch normalization, word embedding, LSTM and residual layers -demonstrate the noise robustness of our proposals. Incidentally, we also prove that, when ReLU is the only non-linearity, the loss curvature is immune to class-dependent label noise.

Deep learning techniques with neural networks have been used effectively in computational fluid dynamics (CFD) to obtain solutions to nonlinear differential equations. This paper presents a physics-informed neural network (PINN) approach to solve the Blasius function. This method eliminates the process of changing the non-linear differential equation to an initial value problem. Also, it tackles the convergence issue arising in the conventional series solution. It is seen that this method produces results that are at par with the numerical and conventional methods. The solution is extended to the negative axis to show that PINNs capture the singularity of the function at $\eta=-5.69$

The generalisation performance of a convolutional neural networks (CNN) is majorly predisposed by the quantity, quality, and diversity of the training images. All the training data needs to be annotated in-hand before, in many real-world applications data is easy to acquire but expensive and time-consuming to label. The goal of the Active learning for the task is to draw most informative samples from the unlabeled pool which can used for training after annotation. With total different objective, self-supervised learning which have been gaining meteoric popularity by closing the gap in performance with supervised methods on large computer vision benchmarks. self-supervised learning (SSL) these days have shown to produce low-level representations that are invariant to distortions of the input sample and can encode invariance to artificially created distortions, e.g. rotation, solarization, cropping etc. self-supervised learning (SSL) approaches rely on simpler and more scalable frameworks for learning. In this paper, we unify these two families of approaches from the angle of active learning using self-supervised learning mainfold and propose Deep Active Learning using BarlowTwins(DALBT), an active learning method for all the datasets using combination of classifier trained along with self-supervised loss framework of Barlow Twins to a setting where the model can encode the invariance of artificially created distortions, e.g. rotation, solarization, cropping etc.

Generative AI has matured to a point where large-scale models can generate text that seems indistinguishable from human-written text and remarkably photorealistic images. Automatically measuring how close the distribution of generated data is to the target real data distribution is a key step in diagnosing existing models and developing better models. We present MAUVE, a family of comparison measures between pairs of distributions such as those encountered in the generative modeling of text or images. These scores are statistical summaries of divergence frontiers capturing two types of errors in generative modeling. We explore four approaches to statistically estimate these scores: vector quantization, non-parametric estimation, classifier-based estimation, and parametric Gaussian approximations. We provide statistical bounds for the vector quantization approach. Empirically, we find that the proposed scores paired with a range of $f$-divergences and statistical estimation methods can quantify the gaps between the distributions of human-written text and those of modern neural language models by correlating with human judgments and identifying known properties of the generated texts. We conclude the paper by demonstrating its applications to other AI domains and discussing practical recommendations.