Biological systems in nature have evolved for millions of years to adapt and survive the environment. Many features they developed can be inspirational and beneficial for solving technical problems in modern industries. This leads to a specific form of design-by-analogy called bio-inspired design (BID). Although BID as a design method has been proven beneficial, the gap between biology and engineering continuously hinders designers from effectively applying the method. Therefore, we explore the recent advance of artificial intelligence (AI) for a data-driven approach to bridge the gap. This paper proposes a generative design approach based on the generative pre-trained language model (PLM) to automatically retrieve and map biological analogy and generate BID in the form of natural language. The latest generative pre-trained transformer, namely GPT-3, is used as the base PLM. Three types of design concept generators are identified and fine-tuned from the PLM according to the looseness of the problem space representation. Machine evaluators are also fine-tuned to assess the mapping relevancy between the domains within the generated BID concepts. The approach is evaluated and then employed in a real-world project of designing light-weighted flying cars during its conceptual design phase The results show our approach can generate BID concepts with good performance.

With the ever-growing model size and the limited availability of labeled training data, transfer learning has become an increasingly popular approach in many science and engineering domains. For classification problems, this work delves into the mystery of transfer learning through an intriguing phenomenon termed neural collapse (NC), where the last-layer features and classifiers of learned deep networks satisfy: (i) the within-class variability of the features collapses to zero, and (ii) the between-class feature means are maximally and equally separated. Through the lens of NC, our findings for transfer learning are the following: (i) when pre-training models, preventing intra-class variability collapse (to a certain extent) better preserves the intrinsic structures of the input data, so that it leads to better model transferability; (ii) when fine-tuning models on downstream tasks, obtaining features with more NC on downstream data results in better test accuracy on the given task. The above results not only demystify many widely used heuristics in model pre-training (e.g., data augmentation, projection head, self-supervised learning), but also leads to more efficient and principled fine-tuning method on downstream tasks that we demonstrate through extensive experimental results.

Neural-symbolic computing aims at integrating robust neural learning and sound symbolic reasoning into a single framework, so as to leverage the complementary strengths of both of these, seemingly unrelated (maybe even contradictory) AI paradigms. The central challenge in neural-symbolic computing is to unify the formulation of neural learning and symbolic reasoning into a single framework with common semantics, that is, to seek a joint representation between a neural model and a logical theory that can support the basic grounding learned by the neural model and also stick to the semantics of the logical theory. In this paper, we propose differentiable fuzzy $\mathcal{ALC}$ (DF-$\mathcal{ALC}$) for this role, as a neural-symbolic representation language with the desired semantics. DF-$\mathcal{ALC}$ unifies the description logic $\mathcal{ALC}$ and neural models for symbol grounding; in particular, it infuses an $\mathcal{ALC}$ knowledge base into neural models through differentiable concept and role embeddings. We define a hierarchical loss to the constraint that the grounding learned by neural models must be semantically consistent with $\mathcal{ALC}$ knowledge bases. And we find that capturing the semantics in grounding solely by maximizing satisfiability cannot revise grounding rationally. We further define a rule-based loss for DF adapting to symbol grounding problems. The experiment results show that DF-$\mathcal{ALC}$ with rule-based loss can improve the performance of image object detectors in an unsupervised learning way, even in low-resource situations.

High-quality traffic flow generation is the core module in building simulators for autonomous driving. However, the majority of available simulators are incapable of replicating traffic patterns that accurately reflect the various features of real-world data while also simulating human-like reactive responses to the tested autopilot driving strategies. Taking one step forward to addressing such a problem, we propose Realistic Interactive TrAffic flow (RITA) as an integrated component of existing driving simulators to provide high-quality traffic flow for the evaluation and optimization of the tested driving strategies. RITA is developed with fidelity, diversity, and controllability in consideration, and consists of two core modules called RITABackend and RITAKit. RITABackend is built to support vehicle-wise control and provide traffic generation models from real-world datasets, while RITAKit is developed with easy-to-use interfaces for controllable traffic generation via RITABackend. We demonstrate RITA's capacity to create diversified and high-fidelity traffic simulations in several highly interactive highway scenarios. The experimental findings demonstrate that our produced RITA traffic flows meet all three design goals, hence enhancing the completeness of driving strategy evaluation. Moreover, we showcase the possibility for further improvement of baseline strategies through online fine-tuning with RITA traffic flows.

Large-scale pre-trained language models (PLMs) bring new opportunities to challenge problems, especially those that need high-level intelligence, such as the math word problem (MWPs). However, directly applying existing PLMs to MWPs can fail as the generation process lacks sufficient supervision and thus lacks fast adaptivity as humans. We notice that human reasoning has a dual reasoning framework that consists of an immediate reaction system (system 1) and a delicate reasoning system (system 2), where the entire reasoning is determined by their interaction. This inspires us to develop a cooperative reasoning-induced PLM for solving MWPs, called Cooperative Reasoning (CoRe), resulting in a human-like reasoning architecture with system 1 as the generator and system 2 as the verifier. In our approach, the generator is responsible for generating reasoning paths, and the verifiers are used to supervise the evaluation in order to obtain reliable feedback for the generator. We evaluate our CoRe framework on several mathematical reasoning datasets and achieve decent improvement over state-of-the-art methods, up to 9.8% increase over best baselines.

近年来，在应用预训练的语言模型（例如Bert）上，取得了巨大进展，以获取信息检索（IR）任务。在网页中通常使用的超链接已被利用用于设计预训练目标。例如，超链接的锚文本已用于模拟查询，从而构建了巨大的查询文档对以进行预训练。但是，作为跨越两个网页的桥梁，尚未完全探索超链接的潜力。在这项工作中，我们专注于建模通过超链接连接的两个文档之间的关系，并为临时检索设计一个新的预训练目标。具体而言，我们将文档之间的关系分为四组：无链接，单向链接，对称链接和最相关的对称链接。通过比较从相邻组采样的两个文档，该模型可以逐渐提高其捕获匹配信号的能力。我们提出了一个渐进的超链接预测（{php}）框架，以探索预训练中超链接的利用。对两个大规模临时检索数据集和六个提问数据集的实验结果证明了其优于现有的预训练方法。

如今，基础模型已成为人工智能中的基本基础设施之一，铺平了通往通用情报的方式。但是，现实提出了两个紧急挑战：现有的基础模型由英语社区主导；用户通常会获得有限的资源，因此不能总是使用基础模型。为了支持中文社区的发展，我们介绍了一个名为Fengshenbang的开源项目，该项目由认知计算与自然语言研究中心（CCNL）领导。我们的项目具有全面的功能，包括大型预培训模型，用户友好的API，基准，数据集等。我们将所有这些都包装在三个子项目中：风水次模型，风水框架和狂热基准。 Fengshenbang的开源路线图旨在重新评估中国预培训的大型大型模型的开源社区，促使整个中国大型模型社区的发展。我们还希望构建一个以用户为中心的开源生态系统，以允许个人访问所需的模型以匹配其计算资源。此外，我们邀请公司，大学和研究机构与我们合作建立大型开源模型的生态系统。我们希望这个项目将成为中国认知情报的基础。

3D多对象跟踪（MOT）确保在连续动态检测过程中保持一致性，有利于自动驾驶中随后的运动计划和导航任务。但是，基于摄像头的方法在闭塞情况下受到影响，准确跟踪基于激光雷达的方法的对象的不规则运动可能是具有挑战性的。某些融合方法效果很好，但不认为在遮挡下出现外观特征的不可信问题。同时，错误检测问题也显着影响跟踪。因此，我们根据组合的外观运动优化（Camo-Mot）提出了一种新颖的相机融合3D MOT框架，该框架使用相机和激光镜数据，并大大减少了由遮挡和错误检测引起的跟踪故障。对于遮挡问题，我们是第一个提出遮挡头来有效地选择最佳对象外观的人，从而减少了闭塞的影响。为了减少错误检测在跟踪中的影响，我们根据置信得分设计一个运动成本矩阵，从而提高了3D空间中的定位和对象预测准确性。由于现有的多目标跟踪方法仅考虑一个类别，因此我们还建议建立多类损失，以在多类别场景中实现多目标跟踪。在Kitti和Nuscenes跟踪基准测试上进行了一系列验证实验。我们提出的方法在KITTI测试数据集上的所有多模式MOT方法中实现了最先进的性能和最低的身份开关（IDS）值（CAR为23，行人为137）。并且我们提出的方法在Nuscenes测试数据集上以75.3％的AMOTA进行了所有算法中的最新性能。

伴随的药物给药会引起药物 - 药物相互作用（DDIS）。某些药物组合是有益的，但其他药物组合可能会引起以前未记录的负面影响。以前关于DDI预测的工作通常依赖于手工设计的领域知识，这是努力获得的。在这项工作中，我们提出了一个新型模型，即分子亚结构网络（MSAN），以有效预测药物对分子结构的潜在DDI。我们采用类似变压器的子结构提取模块，以获取与药物分子的各种子结构模式相关的固定代表媒介。然后，两种药物的子结构之间的相互作用强度将由基于相似性的相互作用模块捕获。在图形编码之前，我们还执行一个子结构删除增强，以减轻过度拟合。实际数据集的实验结果表明，我们提出的模型实现了最新的性能。我们还表明，通过案例研究，我们的模型的预测是高度解释的。

搜索会话中的上下文信息对于捕获用户的搜索意图很重要。已经提出了各种方法来对用户行为序列进行建模，以改善会话中的文档排名。通常，（搜索上下文，文档）对的训练样本在每个训练时期随机采样。实际上，了解用户的搜索意图和判断文档的相关性的困难从一个搜索上下文到另一个搜索上下文有很大差异。混合不同困难的训练样本可能会使模型的优化过程感到困惑。在这项工作中，我们为上下文感知文档排名提出了一个课程学习框架，其中排名模型以易于恐惧的方式学习搜索上下文和候选文档之间的匹配信号。这样一来，我们旨在将模型逐渐指向全球最佳。为了利用正面和负面示例，设计了两个课程。两个真实查询日志数据集的实验表明，我们提出的框架可以显着提高几种现有方法的性能，从而证明课程学习对上下文感知文档排名的有效性。