自动编码是表示学习的一种流行方法。常规的自动编码器采用对称编码编码程序和简单的欧几里得潜在空间，以无监督的方式检测隐藏的低维结构。这项工作介绍了一个图表自动编码器，其中具有不对称编码编码过程，该过程可以包含其他半监督信息，例如类标签。除了增强使用复杂的拓扑结构和几何结构处理数据的能力外，这些模型还可以成功区分附近的数据，但仅与少量监督相交并与歧管相交。此外，该模型仅需要较低的复杂性编码器，例如局部线性投影。我们讨论了此类网络的理论近似能力，基本上取决于数据歧管的固有维度，而不是观测值的维度。我们对合成和现实世界数据的数值实验验证了所提出的模型可以有效地通过附近的多类，但分离不同类别，重叠的歧管和具有非平凡拓扑的歧管的数据。

基于非线性吸引力 - 抑制力的方法（包括T-SNE，UMAP，FORCEATLAS2，grounvis等）主导了维度降低的现代方法。本文的目的是证明所有此类方法，通过设计，都带有一个沿途自动计算的附加功能，即与这些力相关的向量场。我们展示了该向量领域如何提供其他高质量信息，并根据莫尔斯理论的思想提出了一般的完善策略。这些想法的效率是使用T-SNE在合成和现实生活数据集上专门说明的。

超参数优化构成了典型的现代机器学习工作流程的很大一部分。这是由于这样一个事实，即机器学习方法和相应的预处理步骤通常只有在正确调整超参数时就会产生最佳性能。但是在许多应用中，我们不仅有兴趣仅仅为了预测精度而优化ML管道；确定最佳配置时，必须考虑其他指标或约束，从而导致多目标优化问题。由于缺乏知识和用于多目标超参数优化的知识和容易获得的软件实现，因此通常在实践中被忽略。在这项工作中，我们向读者介绍了多个客观超参数优化的基础知识，并激励其在应用ML中的实用性。此外，我们从进化算法和贝叶斯优化的领域提供了现有优化策略的广泛调查。我们说明了MOO在几个特定ML应用中的实用性，考虑了诸如操作条件，预测时间，稀疏，公平，可解释性和鲁棒性之类的目标。

机器学习方法利用多参数生物标志物，特别是基于神经影像动物，具有改善痴呆早期诊断的巨大潜力，并预测哪些个体存在发展痴呆的风险。对于机器学习领域的基准算法和痴呆症中的神经影像症，并评估他们在临床实践中使用的潜力和临床试验，七年的大挑战已经在过去十年中组织：Miriad，Alzheimer的疾病大数据梦，Caddementia，机器学习挑战，MCI神经影像动物，蝌蚪和预测分析竞争。基于两个挑战评估框架，我们分析了这些大挑战如何互相补充研究问题，数据集，验证方法，结果和影响。七个大挑战解决了与（临床前）痴呆症（临床）痴呆症的筛查，诊断，预测和监测有关的问题。临床问题，任务和性能指标几乎没有重叠。然而，这具有提供对广泛问题的洞察力的优势，它也会限制对挑战的结果的验证。通常，获胜算法执行严格的数据预处理并组合了广泛的输入特征。尽管最先进的表演，但临床上没有挑战评估的大部分方法。为了增加影响，未来的挑战可以更加关注统计分析，对其与高于阿尔茨海默病的临床问题，以及使用超越阿尔茨海默病神经影像疾病的临床问题，以及超越阿尔茨海默病的临床问题。鉴于过去十年中汲取的潜力和经验教训，我们在未来十年及其超越的机器学习和神经影像中的大挑战前景兴奋。

迄今为止，迄今为止，众所周知，对广泛的互补临床相关任务进行了全面比较了医学图像登记方法。这限制了采用研究进展，以防止竞争方法的公平基准。在过去五年内已经探讨了许多新的学习方法，但优化，建筑或度量战略的问题非常适合仍然是开放的。 Learn2reg涵盖了广泛的解剖学：脑，腹部和胸部，方式：超声波，CT，MRI，群体：患者内部和患者内部和监督水平。我们为3D注册的培训和验证建立了较低的入境障碍，这帮助我们从20多个独特的团队中汇编了65多个单独的方法提交的结果。我们的互补度量集，包括稳健性，准确性，合理性和速度，使得能够独特地位了解当前的医学图像登记现状。进一步分析监督问题的转移性，偏见和重要性，主要是基于深度学习的方法的优越性，并将新的研究方向开放到利用GPU加速的常规优化的混合方法。

背景：12个引线ECG是心血管疾病的核心诊断工具。在这里，我们描述并分析了一个集成的深度神经网络架构，从12个引导eCG分类了24个心脏异常。方法：我们提出了挤压和激发reset，以自动学习来自12个引主ECG的深度特征，以识别24个心脏病。在最终完全连接的层中，随着年龄和性别特征增强了深度特征。使用约束网格搜索设置每个类的输出阈值。为了确定为什么该模型的预测不正确，两个专家诊所人员独立地解释了一组关于左轴偏差的一次无序的ECG。结果：采用定制加权精度度量，我们达到了0.684的5倍交叉验证得分，灵敏度和特异性分别为0.758和0.969。我们在完整的测试数据中得分0.520，并在官方挑战排名中排名第21中。在一系列被错误分类的心电图中，两个临床医生和训练标签之间的协议差（临床医生1：Kappa = -0.057，临床医生2：Kappa = -0.159）。相比之下，临床医生之间的协议非常高（Kappa = 0.92）。讨论：与在相同数据上培训的模型相比，所提出的预测模型很好地对验证和隐藏的测试数据进行了良好。我们还发现培训标签的相当不一致，这可能会阻碍更准确的模型的开发。

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/ .

The purpose of this work was to tackle practical issues which arise when using a tendon-driven robotic manipulator with a long, passive, flexible proximal section in medical applications. A separable robot which overcomes difficulties in actuation and sterilization is introduced, in which the body containing the electronics is reusable and the remainder is disposable. A control input which resolves the redundancy in the kinematics and a physical interpretation of this redundancy are provided. The effect of a static change in the proximal section angle on bending angle error was explored under four testing conditions for a sinusoidal input. Bending angle error increased for increasing proximal section angle for all testing conditions with an average error reduction of 41.48% for retension, 4.28% for hysteresis, and 52.35% for re-tension + hysteresis compensation relative to the baseline case. Two major sources of error in tracking the bending angle were identified: time delay from hysteresis and DC offset from the proximal section angle. Examination of these error sources revealed that the simple hysteresis compensation was most effective for removing time delay and re-tension compensation for removing DC offset, which was the primary source of increasing error. The re-tension compensation was also tested for dynamic changes in the proximal section and reduced error in the final configuration of the tip by 89.14% relative to the baseline case.

Compliance in actuation has been exploited to generate highly dynamic maneuvers such as throwing that take advantage of the potential energy stored in joint springs. However, the energy storage and release could not be well-timed yet. On the contrary, for multi-link systems, the natural system dynamics might even work against the actual goal. With the introduction of variable stiffness actuators, this problem has been partially addressed. With a suitable optimal control strategy, the approximate decoupling of the motor from the link can be achieved to maximize the energy transfer into the distal link prior to launch. However, such continuous stiffness variation is complex and typically leads to oscillatory swing-up motions instead of clear launch sequences. To circumvent this issue, we investigate decoupling for speed maximization with a dedicated novel actuator concept denoted Bi-Stiffness Actuation. With this, it is possible to fully decouple the link from the joint mechanism by a switch-and-hold clutch and simultaneously keep the elastic energy stored. We show that with this novel paradigm, it is not only possible to reach the same optimal performance as with power-equivalent variable stiffness actuation, but even directly control the energy transfer timing. This is a major step forward compared to previous optimal control approaches, which rely on optimizing the full time-series control input.

The previous fine-grained datasets mainly focus on classification and are often captured in a controlled setup, with the camera focusing on the objects. We introduce the first Fine-Grained Vehicle Detection (FGVD) dataset in the wild, captured from a moving camera mounted on a car. It contains 5502 scene images with 210 unique fine-grained labels of multiple vehicle types organized in a three-level hierarchy. While previous classification datasets also include makes for different kinds of cars, the FGVD dataset introduces new class labels for categorizing two-wheelers, autorickshaws, and trucks. The FGVD dataset is challenging as it has vehicles in complex traffic scenarios with intra-class and inter-class variations in types, scale, pose, occlusion, and lighting conditions. The current object detectors like yolov5 and faster RCNN perform poorly on our dataset due to a lack of hierarchical modeling. Along with providing baseline results for existing object detectors on FGVD Dataset, we also present the results of a combination of an existing detector and the recent Hierarchical Residual Network (HRN) classifier for the FGVD task. Finally, we show that FGVD vehicle images are the most challenging to classify among the fine-grained datasets.