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1. SurgicalGS: Dynamic 3D Gaussian Splatting for Accurate Robotic-Assisted Surgical Scene Reconstruction

Author

Chen, Jialei, Zhang, Xin, Islam, Mobarakol, Vasconcelos, Francisco, Stoyanov, Danail, Elson, Daniel S., and Huang, Baoru

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Accurate 3D reconstruction of dynamic surgical scenes from endoscopic video is essential for robotic-assisted surgery. While recent 3D Gaussian Splatting methods have shown promise in achieving high-quality reconstructions with fast rendering speeds, their use of inverse depth loss functions compresses depth variations. This can lead to a loss of fine geometric details, limiting their ability to capture precise 3D geometry and effectiveness in intraoperative application. To address these challenges, we present SurgicalGS, a dynamic 3D Gaussian Splatting framework specifically designed for surgical scene reconstruction with improved geometric accuracy. Our approach first initialises a Gaussian point cloud using depth priors, employing binary motion masks to identify pixels with significant depth variations and fusing point clouds from depth maps across frames for initialisation. We use the Flexible Deformation Model to represent dynamic scene and introduce a normalised depth regularisation loss along with an unsupervised depth smoothness constraint to ensure more accurate geometric reconstruction. Extensive experiments on two real surgical datasets demonstrate that SurgicalGS achieves state-of-the-art reconstruction quality, especially in terms of accurate geometry, advancing the usability of 3D Gaussian Splatting in robotic-assisted surgery., Comment: 7 pages

Published
2024

3. Generalizable Semantic Vision Query Generation for Zero-shot Panoptic and Semantic Segmentation

Author

Chen, Jialei, Deguchi, Daisuke, Zhang, Chenkai, and Murase, Hiroshi

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Zero-shot Panoptic Segmentation (ZPS) aims to recognize foreground instances and background stuff without images containing unseen categories in training. Due to the visual data sparsity and the difficulty of generalizing from seen to unseen categories, this task remains challenging. To better generalize to unseen classes, we propose Conditional tOken aligNment and Cycle trAnsiTion (CONCAT), to produce generalizable semantic vision queries. First, a feature extractor is trained by CON to link the vision and semantics for providing target queries. Formally, CON is proposed to align the semantic queries with the CLIP visual CLS token extracted from complete and masked images. To address the lack of unseen categories, a generator is required. However, one of the gaps in synthesizing pseudo vision queries, ie, vision queries for unseen categories, is describing fine-grained visual details through semantic embeddings. Therefore, we approach CAT to train the generator in semantic-vision and vision-semantic manners. In semantic-vision, visual query contrast is proposed to model the high granularity of vision by pulling the pseudo vision queries with the corresponding targets containing segments while pushing those without segments away. To ensure the generated queries retain semantic information, in vision-semantic, the pseudo vision queries are mapped back to semantic and supervised by real semantic embeddings. Experiments on ZPS achieve a 5.2% hPQ increase surpassing SOTA. We also examine inductive ZPS and open-vocabulary semantic segmentation and obtain comparative results while being 2 times faster in testing.

Published
2024

4. CLIP Is Also a Good Teacher: A New Learning Framework for Inductive Zero-shot Semantic Segmentation

Author

Chen, Jialei, Deguchi, Daisuke, Zhang, Chenkai, Zheng, Xu, and Murase, Hiroshi

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Generalized Zero-shot Semantic Segmentation aims to segment both seen and unseen categories only under the supervision of the seen ones. To tackle this, existing methods adopt the large-scale Vision Language Models (VLMs) which obtain outstanding zero-shot performance. However, as the VLMs are designed for classification tasks, directly adapting the VLMs may lead to sub-optimal performance. Consequently, we propose CLIP-ZSS (Zero-shot Semantic Segmentation), a simple but effective training framework that enables any image encoder designed for closed-set segmentation applied in zero-shot and open-vocabulary tasks in testing without combining with VLMs or inserting new modules. CLIP-ZSS consists of two key modules: Global Learning Module (GLM) and Pixel Learning Module (PLM). GLM is proposed to probe the knowledge from the CLIP visual encoder by pulling the CLS token and the dense features from the image encoder of the same image and pushing others apart. Moreover, to enhance the ability to discriminate unseen categories, PLM consisting of pseudo labels and weight generation is designed. To generate semantically discriminated pseudo labels, a multi-scale K-Means with mask fusion working on the dense tokens is proposed. In pseudo weight generation, a synthesizer generating pseudo semantic features for the unannotated area is introduced. Experiments on three benchmarks show large performance gains compared with SOTA methods.

Published
2023

5. Deep Generative Imputation Model for Missing Not At Random Data

Author

Chen, Jialei, Xu, Yuanbo, Wang, Pengyang, and Yang, Yongjian

Subjects
Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

Data analysis usually suffers from the Missing Not At Random (MNAR) problem, where the cause of the value missing is not fully observed. Compared to the naive Missing Completely At Random (MCAR) problem, it is more in line with the realistic scenario whereas more complex and challenging. Existing statistical methods model the MNAR mechanism by different decomposition of the joint distribution of the complete data and the missing mask. But we empirically find that directly incorporating these statistical methods into deep generative models is sub-optimal. Specifically, it would neglect the confidence of the reconstructed mask during the MNAR imputation process, which leads to insufficient information extraction and less-guaranteed imputation quality. In this paper, we revisit the MNAR problem from a novel perspective that the complete data and missing mask are two modalities of incomplete data on an equal footing. Along with this line, we put forward a generative-model-specific joint probability decomposition method, conjunction model, to represent the distributions of two modalities in parallel and extract sufficient information from both complete data and missing mask. Taking a step further, we exploit a deep generative imputation model, namely GNR, to process the real-world missing mechanism in the latent space and concurrently impute the incomplete data and reconstruct the missing mask. The experimental results show that our GNR surpasses state-of-the-art MNAR baselines with significant margins (averagely improved from 9.9% to 18.8% in RMSE) and always gives a better mask reconstruction accuracy which makes the imputation more principle.

Published
2023
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6. Project Florida: Federated Learning Made Easy

Author

Diaz, Daniel Madrigal, Manoel, Andre, Chen, Jialei, Singal, Nalin, and Sim, Robert

Subjects
Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Software Engineering
Abstract

We present Project Florida, a system architecture and software development kit (SDK) enabling deployment of large-scale Federated Learning (FL) solutions across a heterogeneous device ecosystem. Federated learning is an approach to machine learning based on a strong data sovereignty principle, i.e., that privacy and security of data is best enabled by storing it at its origin, whether on end-user devices or in segregated cloud storage silos. Federated learning enables model training across devices and silos while the training data remains within its security boundary, by distributing a model snapshot to a client running inside the boundary, running client code to update the model, and then aggregating updated snapshots across many clients in a central orchestrator. Deploying a FL solution requires implementation of complex privacy and security mechanisms as well as scalable orchestration infrastructure. Scale and performance is a paramount concern, as the model training process benefits from full participation of many client devices, which may have a wide variety of performance characteristics. Project Florida aims to simplify the task of deploying cross-device FL solutions by providing cloud-hosted infrastructure and accompanying task management interfaces, as well as a multi-platform SDK supporting most major programming languages including C++, Java, and Python, enabling FL training across a wide range of operating system (OS) and hardware specifications. The architecture decouples service management from the FL workflow, enabling a cloud service provider to deliver FL-as-a-service (FLaaS) to ML engineers and application developers. We present an overview of Florida, including a description of the architecture, sample code, and illustrative experiments demonstrating system capabilities.

Published
2023

8. Hopf PBW-deformations of a new type quantum group

Author

Xu, Yongjun and Chen, Jialei

Subjects
Mathematics - Quantum Algebra, Mathematics - Representation Theory, 17B37, 16G20, 18M05
Abstract

In this paper, we mainly focus on a new type quantum group $U_{q}(\mathfrak{sl}^{*}_2)$ and its Hopf PBW-deformations $U_{q}(\mathfrak{sl}^{*}_2,\kappa)$ in which $U_{q}(\mathfrak{sl}^{*}_2,0) = U_{q}(\mathfrak{sl}^{*}_2)$ and the classical Drinfeld-Jimbo quantum group $U_{q}(\mathfrak{sl}_2)$ is included. The category of finite dimensional $U_{q}(\mathfrak{sl}^{*}_2)$-modules is proved to be non-semisimple. We establish a uniform block decomposition of the category $U_{q}(\mathfrak{sl}^{*}_2,\kappa){\mbox -}{\rm \bf mod}_{\rm wt}$ of finite dimensional weight modules for each $U_{q}(\mathfrak{sl}^{*}_2,\kappa)$, and reduce the investigation on $U_{q}(\mathfrak{sl}^{*}_2,\kappa){\mbox -}{\rm \bf mod}_{\rm wt}$ to its principle block(s). We introduce the notion of primitive object in $U_{q}(\mathfrak{sl}^{*}_2,\kappa){\mbox -}{\rm \bf mod}_{\rm wt}$ which affords a new and elementary way to verify the semisimplicity of the category of finite dimensional $U_{q}(\mathfrak{sl}_2)$-modules. As the core of this present paper, a tensor equivalence between the principal block(s) of $U_{q}(\mathfrak{sl}^{*}_2,\kappa){\mbox -}{\rm \bf mod}_{\rm wt}$ and the category of finite dimensional representations of (deformed) preprojective algebras of Dynkin type $\A$ is obtained., Comment: 33pages

Published
2023

9. Federated Multilingual Models for Medical Transcript Analysis

Author

Manoel, Andre, Garcia, Mirian Hipolito, Baumel, Tal, Su, Shize, Chen, Jialei, Miller, Dan, Karmon, Danny, Sim, Robert, and Dimitriadis, Dimitrios

Subjects
Computer Science - Computation and Language, Computer Science - Machine Learning
Abstract

Federated Learning (FL) is a novel machine learning approach that allows the model trainer to access more data samples, by training the model across multiple decentralized data sources, while data access constraints are in place. Such trained models can achieve significantly higher performance beyond what can be done when trained on a single data source. As part of FL's promises, none of the training data is ever transmitted to any central location, ensuring that sensitive data remains local and private. These characteristics make FL perfectly suited for large-scale applications in healthcare, where a variety of compliance constraints restrict how data may be handled, processed, and stored. Despite the apparent benefits of federated learning, the heterogeneity in the local data distributions pose significant challenges, and such challenges are even more pronounced in the case of multilingual data providers. In this paper we present a federated learning system for training a large-scale multi-lingual model suitable for fine-tuning on downstream tasks such as medical entity tagging. Our work represents one of the first such production-scale systems, capable of training across multiple highly heterogeneous data providers, and achieving levels of accuracy that could not be otherwise achieved by using central training with public data. Finally, we show that the global model performance can be further improved by a training step performed locally.

Published
2022

11. Evolution and legacy of East Asian aurochs

Author

Hou, Jiawen, Guan, Xiwen, Xia, Xiaoting, Lyu, Yang, Liu, Xin, Mazei, Yuri, Xie, Ping, Chang, Fengqin, Zhang, Xiaonan, Chen, Jialei, Li, Xinyi, Zhang, Fengwei, Jin, Liangliang, Luo, Xiaoyu, Sinding, Mikkel-Holger S., Sun, Xin, Achilli, Alessandro, Migliore, Nicola Rambaldi, Zhang, Dongju, Lenstra, Johannes A., Han, Jianlin, Fu, Qiaomei, Liu, Xinyi, Zhang, Xiaoming, Chen, Ningbo, Lei, Chuzhao, and Zhang, Hucai

Published
2024
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15. Uncertainty-Aware Deep Co-training for Semi-supervised Medical Image Segmentation

Author

Zheng, Xu, Fu, Chong, Xie, Haoyu, Chen, Jialei, Wang, Xingwei, and Sham, Chiu-Wing

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Semi-supervised learning has made significant strides in the medical domain since it alleviates the heavy burden of collecting abundant pixel-wise annotated data for semantic segmentation tasks. Existing semi-supervised approaches enhance the ability to extract features from unlabeled data with prior knowledge obtained from limited labeled data. However, due to the scarcity of labeled data, the features extracted by the models are limited in supervised learning, and the quality of predictions for unlabeled data also cannot be guaranteed. Both will impede consistency training. To this end, we proposed a novel uncertainty-aware scheme to make models learn regions purposefully. Specifically, we employ Monte Carlo Sampling as an estimation method to attain an uncertainty map, which can serve as a weight for losses to force the models to focus on the valuable region according to the characteristics of supervised learning and unsupervised learning. Simultaneously, in the backward process, we joint unsupervised and supervised losses to accelerate the convergence of the network via enhancing the gradient flow between different tasks. Quantitatively, we conduct extensive experiments on three challenging medical datasets. Experimental results show desirable improvements to state-of-the-art counterparts.

Published
2021

21. Global genetic diversity, introgression, and evolutionary adaptation of indicine cattle revealed by whole genome sequencing

Author

Chen, Ningbo, Xia, Xiaoting, Hanif, Quratulain, Zhang, Fengwei, Dang, Ruihua, Huang, Bizhi, Lyu, Yang, Luo, Xiaoyu, Zhang, Hucai, Yan, Huixuan, Wang, Shikang, Wang, Fuwen, Chen, Jialei, Guan, Xiwen, Liu, Yangkai, Li, Shuang, Jin, Liangliang, Wang, Pengfei, Sun, Luyang, Zhang, Jicai, Liu, Jianyong, Qu, Kaixing, Cao, Yanhong, Sun, Junli, Liao, Yuying, Xiao, Zhengzhong, Cai, Ming, Mu, Lan, Siddiki, Amam Zonaed, Asif, Muhammad, Mansoor, Shahid, Babar, Masroor Ellahi, Hussain, Tanveer, Silva, Gamamada Liyanage Lalanie Pradeepa, Gorkhali, Neena Amatya, Terefe, Endashaw, Belay, Gurja, Tijjani, Abdulfatai, Zegeye, Tsadkan, Gebre, Mebrate Genet, Ma, Yun, Wang, Yu, Huang, Yongzhen, Lan, Xianyong, Chen, Hong, Migliore, Nicola Rambaldi, Colombo, Giulia, Semino, Ornella, Achilli, Alessandro, Sinding, Mikkel-Holger S., Lenstra, Johannes A., Cheng, Haijian, Lu, Wenfa, Hanotte, Olivier, Han, Jianlin, Jiang, Yu, and Lei, Chuzhao

Published
2023
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29. APIK: Active Physics-Informed Kriging Model with Partial Differential Equations

Author

Chen, Jialei, Chen, Zhehui, Zhang, Chuck, and Wu, C. F. Jeff

Subjects
Statistics - Methodology, Computer Science - Machine Learning
Abstract

Kriging (or Gaussian process regression) is a popular machine learning method for its flexibility and closed-form prediction expressions. However, one of the key challenges in applying kriging to engineering systems is that the available measurement data is scarce due to the measurement limitations and high sensing costs. On the other hand, physical knowledge of the engineering system is often available and represented in the form of partial differential equations (PDEs). We present in this work a PDE Informed Kriging model (PIK), which introduces PDE information via a set of PDE points and conducts posterior prediction similar to the standard kriging method. The proposed PIK model can incorporate physical knowledge from both linear and nonlinear PDEs. To further improve learning performance, we propose an Active PIK framework (APIK) that designs PDE points to leverage the PDE information based on the PIK model and measurement data. The selected PDE points not only explore the whole input space but also exploit the locations where the PDE information is critical in reducing predictive uncertainty. Finally, an expectation-maximization algorithm is developed for parameter estimation. We demonstrate the effectiveness of APIK in two synthetic examples, a shock wave case study, and a laser heating case study.

Published
2020

30. Scientific Reading Comprehension with Sentences Selection and Ranking

Author

Chen, Jialei, Wang, Weihua, Shao, Shuai, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Liu, Fei, editor, Duan, Nan, editor, Xu, Qingting, editor, and Hong, Yu, editor

Published
2023
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33. A calibration-free method for biosensing in cell manufacturing

Author

Chen, Jialei, Liu, Zhaonan, Wang, Kan, Jiang, Chen, Zhang, Chuck, and Wang, Ben

Subjects
Quantitative Biology - Quantitative Methods, Statistics - Methodology
Abstract

Chimeric antigen receptor T cell therapy has demonstrated innovative therapeutic effectiveness in fighting cancers; however, it is extremely expensive due to the intrinsic patient-to-patient variability in cell manufacturing. We propose in this work a novel calibration-free statistical framework to effectively recover critical quality attributes under the patient-to-patient variability. Specifically, we model this variability via a patient-specific calibration parameter, and use readings from multiple biosensors to construct a patient-invariance statistic, thereby alleviating the effect of the calibration parameter. A carefully formulated optimization problem and an algorithmic framework are presented to find the best patient-invariance statistic and the model parameters. Using the patient-invariance statistic, we can recover the critical quality attribute of interest, free from the calibration parameter. We demonstrate improvements of the proposed calibration-free method in different simulation experiments. In the cell manufacturing case study, our method not only effectively recovers viable cell concentration for monitoring, but also reveals insights for the cell manufacturing process.

Published
2020
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34. Adaptive design for Gaussian process regression under censoring

Author

Chen, Jialei, Mak, Simon, Joseph, V. Roshan, and Zhang, Chuck

Subjects
Statistics - Methodology
Abstract

A key objective in engineering problems is to predict an unknown experimental surface over an input domain. In complex physical experiments, this may be hampered by response censoring, which results in a significant loss of information. For such problems, experimental design is paramount for maximizing predictive power using a small number of expensive experimental runs. To tackle this, we propose a novel adaptive design method, called the integrated censored mean-squared error (ICMSE) method. The ICMSE method first estimates the posterior probability of a new observation being censored, then adaptively chooses design points that minimize predictive uncertainty under censoring. Adopting a Gaussian process regression model with product correlation function, the proposed ICMSE criterion is easy to evaluate, which allows for efficient design optimization. We demonstrate the effectiveness of the ICMSE design in two real-world applications on surgical planning and wafer manufacturing.

Published
2019

35. Function-on-function kriging, with applications to 3D printing of aortic tissues

Author

Chen, Jialei, Mak, Simon, Joseph, V. Roshan, and Zhang, Chuck

Subjects
Statistics - Methodology
Abstract

3D-printed medical prototypes, which use synthetic metamaterials to mimic biological tissue, are becoming increasingly important in urgent surgical applications. However, the mimicking of tissue mechanical properties via 3D-printed metamaterial can be difficult and time-consuming, due to the functional nature of both inputs (metamaterial structure) and outputs (mechanical response curve). To deal with this, we propose a novel function-on-function kriging model for efficient emulation and tissue-mimicking optimization. For functional inputs, a key novelty of our model is the spectral-distance (SpeD) correlation function, which captures important spectral differences between two functional inputs. Dependencies for functional outputs are then modeled via a co-kriging framework. We further adopt shrinkage priors on both the input spectra and the output co-kriging covariance matrix, which allows the emulator to learn and incorporate important physics (e.g., dominant input frequencies, output curve properties). Finally, we demonstrate the effectiveness of the proposed SpeD emulator in a real-world study on mimicking human aortic tissue, and show that it can provide quicker and more accurate tissue-mimicking performance compared to existing methods in the medical literature.

Published
2019
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37. Learning the Treatment Effects on FTIR Signals Subject to Multiple Sources of Uncertainties

Author

Tian, Hongzhen, Wang, Andi, Chen, Jialei, Jiang, Xuzhou, Shi, Jianjun, Zhang, Chuck, Mei, Yajun, and Wang, Ben

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Fourier-transform infrared spectroscopy (FTIR) is a versatile technique for characterizing the chemical composition of the various uncertainties, including baseline shift and multiplicative error. This study aims at analyzing the effect of certain treatment on the FTIR responses subject to these uncertainties. A two-step method is proposed to quantify the treatment effect on the FTIR signals. First, an optimization problem is solved to calculate the template signal by aligning the pre-treatment FTIR signals. Second, the effect of treatment is decomposed as the pattern of modification $\mathbf{g}$ that describes the overall treatment effect on the spectra and a vector of effect $\boldsymbol{\delta}$ that describes the degree of modification. $\mathbf g$ and $\boldsymbol{\delta}$ are solved by another optimization problem. They have explicit engineering interpretations and provide useful information on how the treatment effect change the surface chemical components. The effectiveness of the proposed method is first validated in a simulation. In a real case study, it's used to investigate how the plasma exposure applied at various heights affects the FTIR signal which indicates the change of the chemical composition on the composite material. The vector of effects indicates the range of effective plasma height, and the pattern of modification matches existing engineering knowledge well., Comment: \{copyright} 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works

Published
2019

38. Active Image Synthesis for Efficient Labeling

Author

Chen, Jialei, Xie, Yujia, Wang, Kan, Zhang, Chuck, Vannan, Mani A., Wang, Ben, and Qian, Zhen

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

The great success achieved by deep neural networks attracts increasing attention from the manufacturing and healthcare communities. However, the limited availability of data and high costs of data collection are the major challenges for the applications in those fields. We propose in this work AISEL, an active image synthesis method for efficient labeling to improve the performance of the small-data learning tasks. Specifically, a complementary AISEL dataset is generated, with labels actively acquired via a physics-based method to incorporate underlining physical knowledge at hand. An important component of our AISEL method is the bidirectional generative invertible network (GIN), which can extract interpretable features from the training images and generate physically meaningful virtual images. Our AISEL method then efficiently samples virtual images not only further exploits the uncertain regions, but also explores the entire image space. We then discuss the interpretability of GIN both theoretically and experimentally, demonstrating clear visual improvements over the benchmarks. Finally, we demonstrate the effectiveness of our AISEL framework on aortic stenosis application, in which our method lower the labeling cost by $90\%$ while achieving a $15\%$ improvement in prediction accuracy.

Published
2019
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43. Study on the Internet of Things Discipline in Civil Aviation

Author

Chen, Jialei, Zhang, Huan, Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Prates, Raquel Oliveira, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Sun, Xingming, editor, Zhang, Xiaorui, editor, Xia, Zhihua, editor, and Bertino, Elisa, editor

Published
2022
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44. Grothendieck Rings of 2$n^2$ dimensional Hopf Algebras $H_{2n^2}$

Author

Chen, Jialei, Yang, Shilin, and Wang, Dingguo

Subjects
Mathematics - Rings and Algebras, Mathematics - Representation Theory, 16G10, 16D70, 16T99
Abstract

In this paper, we construct the Grothendieck ring of a class of 2$n^2$-dimension semisimple Hopf Algebras $H_{2n^2}$, which can be viewed as a generalization of the 8-dimension Kac-Paljutkin Hopf algebra $K_8$. All irreducible $H_{2n^2}$-modules are classified. Furthermore, we describe the Grothendieck ring $r(H_{2n^2})$ by generators and relations explicitly., Comment: 18 pages

Published
2018
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45. On $4n$-dimensional neither pointed nor semisimple Hopf algebras and the associated weak Hopf algebras

Author

Chen, Jialei, Yang, Shilin, Wang, Dingguo, and Xu, Yongjun

Subjects
Mathematics - Rings and Algebras, Mathematics - Representation Theory, 16G10, 16D70, 16T99
Abstract

For a class of neither pointed nor semisimple Hopf algebras $H_{4n}$ of dimension $4n$, it is shown that they are quasi-triangular, which universal $R$-matrices are described. The corresponding weak Hopf algebras $\mathfrak{w}H_{4n}$ and their representations are constructed. Finally, their duality and their Green rings are established by generators and relations explicitly. It turns out that the Green rings of the associated weak Hopf algebras are not commutative even if the Green rings of $H_{4n}$ are commutative., Comment: 18 pages

Published
2018

46. Generative Invertible Networks (GIN): Pathophysiology-Interpretable Feature Mapping and Virtual Patient Generation

Author

Chen, Jialei, Xie, Yujia, Wang, Kan, Wang, Zih Huei, Lahoti, Geet, Zhang, Chuck, Vannan, Mani A, Wang, Ben, and Qian, Zhen

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Machine learning methods play increasingly important roles in pre-procedural planning for complex surgeries and interventions. Very often, however, researchers find the historical records of emerging surgical techniques, such as the transcatheter aortic valve replacement (TAVR), are highly scarce in quantity. In this paper, we address this challenge by proposing novel generative invertible networks (GIN) to select features and generate high-quality virtual patients that may potentially serve as an additional data source for machine learning. Combining a convolutional neural network (CNN) and generative adversarial networks (GAN), GIN discovers the pathophysiologic meaning of the feature space. Moreover, a test of predicting the surgical outcome directly using the selected features results in a high accuracy of 81.55%, which suggests little pathophysiologic information has been lost while conducting the feature selection. This demonstrates GIN can generate virtual patients not only visually authentic but also pathophysiologically interpretable.

Published
2018
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