Design and comparison among concrete, steel and timber vertical members for large clear span buildings

Timber structure is undergoing a renaissance in building industry due to their ecologic and high strength-weight ratio benefits. Nevertheless, in large-clear span building case, the dimension of vertical timber member could be huge. Therefore, a mixed structure---wooden slab and beam system combined with columns of different material---could be an option for economic and technic sake

Quantitative Study on Walking Space Around Residential Rail Transit Stations in Beijing

Firstly, the key factors affecting the convenience and comfort of walking around Beijing residential rail transit stations were confirmed through questionnaire, the most significant factors respectively are the degree of walking detours and the street ground-floor commercial facilities, then quantitative researches were carried out on the two factors. 13 residential stations in Beijing were selected, and the coefficients of detours both under current situation and the scenario of open communities were calculated, moreover, the current situation was compared with other domestic and foreign cities. The distribution of street ground-floor commercial facilities around 13 stations was investigated, and the Huilongguan station was analyzed in details. The result shows that the degree of walking detours around residential stations in Beijing was relatively serious, and significant factors are, for instance, closed communities and road network. There are relatively continuous underlying commercial facilities over half of the sites, and the facilities around a few of stations were insufficient, the density of street ground-floor commercial facilities within 500 meters of Huilongguan station was 2.42 per 100 meters, which is far less than the walkable standard

Unsupervised Prototype Adapter for Vision-Language Models

Recently, large-scale pre-trained vision-language models (e.g. CLIP and ALIGN) have demonstrated remarkable effectiveness in acquiring transferable visual representations. To leverage the valuable knowledge encoded within these models for downstream tasks, several fine-tuning approaches, including prompt tuning methods and adapter-based methods, have been developed to adapt vision-language models effectively with supervision. However, these methods rely on the availability of annotated samples, which can be labor-intensive and time-consuming to acquire, thus limiting scalability. To address this issue, in this work, we design an unsupervised fine-tuning approach for vision-language models called Unsupervised Prototype Adapter (UP-Adapter). Specifically, for the unannotated target datasets, we leverage the text-image aligning capability of CLIP to automatically select the most confident samples for each class. Utilizing these selected samples, we generate class prototypes, which serve as the initialization for the learnable prototype model. After fine-tuning, the prototype model prediction is combined with the original CLIP's prediction by a residual connection to perform downstream recognition tasks. Our extensive experimental results on image recognition and domain generalization show that the proposed unsupervised method outperforms 8-shot CoOp, 8-shot Tip-Adapter, and also the state-of-the-art UPL method by large margins.Comment: Accepted by PRCV 202

Meta learning for few shot learning

Few-shot learning aims to scale visual recognition to open-ended growth of new classes with limited labelled examples, thus alleviating data and computation bottleneck of conventional deep learning. This thesis proposes a meta learning (a.k.a. learning to learn), paradigm to tackle the real-world few shot learning challenges. Firstly, we present a parameterized multi-metric based meta learning algorithm (RelationNet2). Existing metric learning algorithms are always based on training a global deep embedding and metric to support image similarity matching, but we propose a deep comparison network comprised of embedding and relation modules learning multiple non-linear distance metrics based on different levels of features simultaneously. Furthermore, images are represented as \todo{a} distribution rather than vectors via learning parameterized Gaussian noise regularization, reducing overfitting and enable the use of deeper embeddings. We next consider the fact that several recent competitors develop effective few-shot learners through strong conventional representations in combination with very simple classifiers, questioning whether “meta-learning” is necessary or highly effective features are sufficient. To defend meta-learning, we take an approach agnostic to the off-the-shelf features, and focus exclusively on meta-learning the final classifier layer. Specifically, we introduce MetaQDA, a Bayesian meta-learning extension of quadratic discriminant analysis classifier, that is complementary to advances in feature representations, leading to high accuracy and state-of-the-art uncertainty calibration performance in predictions. Finally, we investigate the extension of MetaQDA to more generalized real-world scenarios beyond the narrow standard few-shot benchmarks. Our model achieves both many-shot and few-shot classification accuracy in generalized few-shot learning. In terms of few-shot class-incremental learning, MetaQDA is inherently suitable to novel classes growing \todo{scenarios}. As for open-set recognition, we calculate the probability belonging to novel class by Bayes' Rule, maintaining high accuracy in both close-set recognition and open-set rejection. Overall, our contributions in few-shot meta-learning advance state of the art under both accuracy and calibration metrics, explore a series of increasingly realistic problem settings, to support more researchers and practitioners in future exploration

Rapid Determination of Saponins in the Honey-Fried Processing of Rhizoma Cimicifugae by Near Infrared Diffuse Reflectance Spectroscopy.

ObjectiveA model of Near Infrared Diffuse Reflectance Spectroscopy (NIR-DRS) was established for the first time to determine the content of Shengmaxinside I in the honey-fried processing of Rhizoma Cimicifugae.MethodsShengmaxinside I content was determined by high-performance liquid chromatography (HPLC), and the data of the honey-fried processing of Rhizoma Cimicifugae samples from different batches of different origins by NIR-DRS were collected by TQ Analyst 8.0. Partial Least Squares (PLS) analysis was used to establish a near-infrared quantitative model.ResultsThe determination coefficient R² was 0.9878. The Cross-Validation Root Mean Square Error (RMSECV) was 0.0193%, validating the model with a validation set. The Root Mean Square Error of Prediction (RMSEP) was 0.1064%. The ratio of the standard deviation for the validation samples to the standard error of prediction (RPD) was 5.5130.ConclusionThis method is convenient and efficient, and the experimentally established model has good prediction ability, and can be used for the rapid determination of Shengmaxinside I content in the honey-fried processing of Rhizoma Cimicifugae

Shallow Bayesian Meta Learning for Real-World Few-Shot Recognition

Current state-of-the-art few-shot learners focus on developing effective training procedures for feature representations, before using simple, e.g. nearest centroid, classifiers. In this paper we take an orthogonal approach that is agnostic to the features used, and focus exclusively on meta-learning the actual classifier layer. Specifically, we introduce MetaQDA, a Bayesian meta-learning generalisation of the classic quadratic discriminant analysis. This setup has several benefits of interest to practitioners: meta-learning is fast and memory efficient, without the need to fine-tune features. It is agnostic to the off-the-shelf features chosen, and thus will continue to benefit from advances in feature representations. Empirically, it leads to robust performance in cross-domain few-shot learning and, crucially for real-world applications, it leads to better uncertainty calibration in predictions