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1. DaRePlane: Direction-aware Representations for Dynamic Scene Reconstruction

Author

Lou, Ange, Planche, Benjamin, Gao, Zhongpai, Li, Yamin, Luan, Tianyu, Ding, Hao, Zheng, Meng, Chen, Terrence, Wu, Ziyan, and Noble, Jack

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Numerous recent approaches to modeling and re-rendering dynamic scenes leverage plane-based explicit representations, addressing slow training times associated with models like neural radiance fields (NeRF) and Gaussian splatting (GS). However, merely decomposing 4D dynamic scenes into multiple 2D plane-based representations is insufficient for high-fidelity re-rendering of scenes with complex motions. In response, we present DaRePlane, a novel direction-aware representation approach that captures scene dynamics from six different directions. This learned representation undergoes an inverse dual-tree complex wavelet transformation (DTCWT) to recover plane-based information. Within NeRF pipelines, DaRePlane computes features for each space-time point by fusing vectors from these recovered planes, then passed to a tiny MLP for color regression. When applied to Gaussian splatting, DaRePlane computes the features of Gaussian points, followed by a tiny multi-head MLP for spatial-time deformation prediction. Notably, to address redundancy introduced by the six real and six imaginary direction-aware wavelet coefficients, we introduce a trainable masking approach, mitigating storage issues without significant performance decline. To demonstrate the generality and efficiency of DaRePlane, we test it on both regular and surgical dynamic scenes, for both NeRF and GS systems. Extensive experiments show that DaRePlane yields state-of-the-art performance in novel view synthesis for various complex dynamic scenes., Comment: arXiv admin note: substantial text overlap with arXiv:2403.02265

Published
2024

2. Theta and/or alpha? Neural oscillational substrates for dynamic inter-brain synchrony during mother-child cooperation

Author

Xu, Jiayang, Li, Yamin, Su, Ruxin, Wu, Saishuang, Wu, Chengcheng, Wang, Haiwa, Zhu, Qi, Fang, Yue, Jiang, Fan, Tong, Shanbao, Zhang, Yunting, and Guo, Xiaoli

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Mother-child interaction is a highly dynamic process neurally characterized by inter-brain synchrony (IBS) at {\theta} and/or {\alpha} rhythms. However, their establishment, dynamic changes, and roles in mother-child interactions remain unknown. Through dynamic analysis of dual-EEG from 40 mother-child dyads during turn-taking cooperation, we uncover that {\theta}-IBS and {\alpha}-IBS alternated with interactive behaviors, with EEG frequency-shift as a prerequisite for IBS transitions. When mothers attempt to track their children's attention and/or predict their intentions, they will adjust their EEG frequencies to align with their children's {\theta} oscillations, leading to a higher occurrence of the {\theta}-IBS state. Conversely, the {\alpha}-IBS state, accompanied by the EEG frequency-shift to the {\alpha} range, is more prominent during mother-led interactions. Further exploratory analysis reveals greater presence and stability of the {\theta}-IBS state during cooperative than non-cooperative conditions, particularly in dyads with stronger emotional attachments and more frequent interactions in their daily lives. Our findings shed light on the neural oscillational substrates underlying the IBS dynamics during mother-child interactions., Comment: 27 Pages,6 figures

Published
2024

3. Surgical Depth Anything: Depth Estimation for Surgical Scenes using Foundation Models

Author

Lou, Ange, Li, Yamin, Zhang, Yike, and Noble, Jack

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Monocular depth estimation is crucial for tracking and reconstruction algorithms, particularly in the context of surgical videos. However, the inherent challenges in directly obtaining ground truth depth maps during surgery render supervised learning approaches impractical. While many self-supervised methods based on Structure from Motion (SfM) have shown promising results, they rely heavily on high-quality camera motion and require optimization on a per-patient basis. These limitations can be mitigated by leveraging the current state-of-the-art foundational model for depth estimation, Depth Anything. However, when directly applied to surgical scenes, Depth Anything struggles with issues such as blurring, bleeding, and reflections, resulting in suboptimal performance. This paper presents a fine-tuning of the Depth Anything model specifically for the surgical domain, aiming to deliver more accurate pixel-wise depth maps tailored to the unique requirements and challenges of surgical environments. Our fine-tuning approach significantly improves the model's performance in surgical scenes, reducing errors related to blurring and reflections, and achieving a more reliable and precise depth estimation.

Published
2024

4. NeuroBOLT: Resting-state EEG-to-fMRI Synthesis with Multi-dimensional Feature Mapping

Author

Li, Yamin, Lou, Ange, Xu, Ziyuan, Zhang, Shengchao, Wang, Shiyu, Englot, Dario J., Kolouri, Soheil, Moyer, Daniel, Bayrak, Roza G., and Chang, Catie

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Functional magnetic resonance imaging (fMRI) is an indispensable tool in modern neuroscience, providing a non-invasive window into whole-brain dynamics at millimeter-scale spatial resolution. However, fMRI is constrained by issues such as high operation costs and immobility. With the rapid advancements in cross-modality synthesis and brain decoding, the use of deep neural networks has emerged as a promising solution for inferring whole-brain, high-resolution fMRI features directly from electroencephalography (EEG), a more widely accessible and portable neuroimaging modality. Nonetheless, the complex projection from neural activity to fMRI hemodynamic responses and the spatial ambiguity of EEG pose substantial challenges both in modeling and interpretability. Relatively few studies to date have developed approaches for EEG-fMRI translation, and although they have made significant strides, the inference of fMRI signals in a given study has been limited to a small set of brain areas and to a single condition (i.e., either resting-state or a specific task). The capability to predict fMRI signals in other brain areas, as well as to generalize across conditions, remain critical gaps in the field. To tackle these challenges, we introduce a novel and generalizable framework: NeuroBOLT, i.e., Neuro-to-BOLD Transformer, which leverages multi-dimensional representation learning from temporal, spatial, and spectral domains to translate raw EEG data to the corresponding fMRI activity signals across the brain. Our experiments demonstrate that NeuroBOLT effectively reconstructs resting-state fMRI signals from primary sensory, high-level cognitive areas, and deep subcortical brain regions, achieving state-of-the-art accuracy and significantly advancing the integration of these two modalities., Comment: This preprint has been accepted to NeurIPS 2024

Published
2024

5. Reconstructing physiological signals from fMRI across the adult lifespan

Author

Wang, Shiyu, Xu, Ziyuan, Li, Yamin, Mather, Mara, Bayrak, Roza G., and Chang, Catie

Subjects
Computer Science - Machine Learning, Electrical Engineering and Systems Science - Image and Video Processing, Electrical Engineering and Systems Science - Signal Processing
Abstract

Interactions between the brain and body are of fundamental importance for human behavior and health. Functional magnetic resonance imaging (fMRI) captures whole-brain activity noninvasively, and modeling how fMRI signals interact with physiological dynamics of the body can provide new insight into brain function and offer potential biomarkers of disease. However, physiological recordings are not always possible to acquire since they require extra equipment and setup, and even when they are, the recorded physiological signals may contain substantial artifacts. To overcome this limitation, machine learning models have been proposed to directly extract features of respiratory and cardiac activity from resting-state fMRI signals. To date, such work has been carried out only in healthy young adults and in a pediatric population, leaving open questions about the efficacy of these approaches on older adults. Here, we propose a novel framework that leverages Transformer-based architectures for reconstructing two key physiological signals - low-frequency respiratory volume (RV) and heart rate (HR) fluctuations - from fMRI data, and test these models on a dataset of individuals aged 36-89 years old. Our framework outperforms previously proposed approaches (attaining median correlations between predicted and measured signals of r ~ .698 for RV and r ~ .618 for HR), indicating the potential of leveraging attention mechanisms to model fMRI-physiological signal relationships. We also evaluate several model training and fine-tuning strategies, and find that incorporating young-adult data during training improves the performance when predicting physiological signals in the aging cohort. Overall, our approach successfully infers key physiological variables directly from fMRI data from individuals across a wide range of the adult lifespan.

Published
2024

6. Zero-Shot Surgical Tool Segmentation in Monocular Video Using Segment Anything Model 2

Author

Lou, Ange, Li, Yamin, Zhang, Yike, Labadie, Robert F., and Noble, Jack

Subjects
Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition
Abstract

The Segment Anything Model 2 (SAM 2) is the latest generation foundation model for image and video segmentation. Trained on the expansive Segment Anything Video (SA-V) dataset, which comprises 35.5 million masks across 50.9K videos, SAM 2 advances its predecessor's capabilities by supporting zero-shot segmentation through various prompts (e.g., points, boxes, and masks). Its robust zero-shot performance and efficient memory usage make SAM 2 particularly appealing for surgical tool segmentation in videos, especially given the scarcity of labeled data and the diversity of surgical procedures. In this study, we evaluate the zero-shot video segmentation performance of the SAM 2 model across different types of surgeries, including endoscopy and microscopy. We also assess its performance on videos featuring single and multiple tools of varying lengths to demonstrate SAM 2's applicability and effectiveness in the surgical domain. We found that: 1) SAM 2 demonstrates a strong capability for segmenting various surgical videos; 2) When new tools enter the scene, additional prompts are necessary to maintain segmentation accuracy; and 3) Specific challenges inherent to surgical videos can impact the robustness of SAM 2., Comment: The first work evaluates the performance of SAM 2 in surgical videos

Published
2024

7. DaReNeRF: Direction-aware Representation for Dynamic Scenes

Author

Lou, Ange, Planche, Benjamin, Gao, Zhongpai, Li, Yamin, Luan, Tianyu, Ding, Hao, Chen, Terrence, Noble, Jack, and Wu, Ziyan

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Graphics
Abstract

Addressing the intricate challenge of modeling and re-rendering dynamic scenes, most recent approaches have sought to simplify these complexities using plane-based explicit representations, overcoming the slow training time issues associated with methods like Neural Radiance Fields (NeRF) and implicit representations. However, the straightforward decomposition of 4D dynamic scenes into multiple 2D plane-based representations proves insufficient for re-rendering high-fidelity scenes with complex motions. In response, we present a novel direction-aware representation (DaRe) approach that captures scene dynamics from six different directions. This learned representation undergoes an inverse dual-tree complex wavelet transformation (DTCWT) to recover plane-based information. DaReNeRF computes features for each space-time point by fusing vectors from these recovered planes. Combining DaReNeRF with a tiny MLP for color regression and leveraging volume rendering in training yield state-of-the-art performance in novel view synthesis for complex dynamic scenes. Notably, to address redundancy introduced by the six real and six imaginary direction-aware wavelet coefficients, we introduce a trainable masking approach, mitigating storage issues without significant performance decline. Moreover, DaReNeRF maintains a 2x reduction in training time compared to prior art while delivering superior performance., Comment: Accepted at CVPR 2024. Paper + supplementary material

Published
2024

10. An Investigation of Active Noise Control Based on Wave-U-Net

Author

Li, Yamin, Feng, Guojin, Sun, Guohua, Zhen, Dong, Zhang, Hao, Gu, Fengshou, Ceccarelli, Marco, Series Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Agrawal, Sunil K., Advisory Editor, Liu, Tongtong, editor, Zhang, Fan, editor, Huang, Shiqing, editor, Wang, Jingjing, editor, and Gu, Fengshou, editor

Published
2024
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11. YOLO-TL: A Tiny Object Segmentation Framework for Low Quality Medical Images

Author

Li, Yamin, Duan, Yu, Duan, Liu, Xiang, Wen, Wu, Qifeng, Goos, Gerhard, Series 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, Yap, Moi Hoon, editor, Kendrick, Connah, editor, Behera, Ardhendu, editor, Cootes, Timothy, editor, and Zwiggelaar, Reyer, editor

Published
2024
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12. A Real-Time Active Noise Control System for Low Frequency Substation Noise Suppression

Author

Wang, Haohui, Li, Yamin, Hao, Ying, Gao, Jianzheng, Liang, Xiaoxia, Feng, Guojin, Zhen, Dong, IFToMM, Series Editor, Ceccarelli, Marco, Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Agrawal, Sunil K., Advisory Editor, Ball, Andrew D., editor, Ouyang, Huajiang, editor, Sinha, Jyoti K., editor, and Wang, Zuolu, editor

Published
2024
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44. Reliability and validity of the Chinese version of the family presence risk-benefit and self-confidence scales in Chinese nurses.

Author

Guo, Yan, Yang, Jiaxin, Peng, Juan, Liu, Yiting, Tian, Yusheng, Chen, Zengyu, and Li, Yamin

Abstract

Background: Controversy surrounding Family Presence during Resuscitation (FPDR) continues internationally. The attitudes of medical professionals toward FPDR are particularly important for its clinical implementation. Currently, there is a lack of validated tools to evaluate medical professionals’ perceptions of FPDR in China. The study aimed to: (1) Cross-culturally adapt and validate the Family Presence Risk-Benefit Scale (FPR-BS) and the Self-Confidence Scale (FPS-CS) for use in China; and (2) investigate the nurses’ perceptions of FPDR and explore the relationships between the nurses’ perceptual variables and demographic variables. Methods: The English version of the FPR-BS and FPS-CS underwent a rigorous process of translation, back-translation, proofreading, and cultural adaptation to create the Chinese versions. In the first stage, a sample of 200 nurses were recruited to evaluate the reliability and validity of the scales. In the second stage, a larger cohort 519 nurses were invited to assess their perceptions of FPDR and the relationships between these perceptual variables and demographic variables. Results: Exploratory factorial analysis identified a single dimension for both the FPR-BS and FPS-CS, explaining 43.84% and 48.43% of the variance, respectively. The Scale-level content validity index (S-CVI) of the FPR-BS and the FPS-CS was 0.98 and 0.97, respectively. Reliability assessments yielded Cronbach’s alpha coefficients of 0.933 for the FPR-BS and 0.930 for the FPS-CS. The split-half reliability coefficients were 0.832 for the FPR-BS and 0.835 for the FPS-CS, while the retest reliability coefficients were 0.742 and 0.927, respectively. The average scores obtained were 2.76 (SD = 0.52) for the FPR-BS and 3.43 (SD = 0.58) for the FPS-CS. Statistical analyses revealed that factors such as patient type, family members’ prior experience with resuscitation, and the number of times nurses invited family members during resuscitation significantly influenced perceptions of the benefits and risks associated with FPDR (P < 0.05). Furthermore, obtaining certification as an intensive care specialist was positively associated with nurses’ self-confidence in managing FPDR (P < 0.05). Conclusions: The FPR-BS and FPS-CS were validated as effective instruments for measuring nurses’ perceptions of PFDR, demonstrating acceptable levels of validity and reliability. While nurses reported fewer benefits and greater risks of FPDR, they exhibited increased self-confidence in managing family presence during resuscitation. [ABSTRACT FROM AUTHOR]

Published
2024
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45. Area–Time-Efficient High-Radix Modular Inversion Algorithm and Hardware Implementation for ECC over Prime Fields.

Author

Li, Yamin

Abstract

Elliptic curve cryptography (ECC) is widely used for secure communications, because it can provide the same level of security as RSA with a much smaller key size. In constrained environments, it is important to consider efficiency, in terms of execution time and hardware costs. Modular inversion is a key time-consuming calculation used in ECC. Its hardware implementation requires extensive hardware resources, such as lookup tables and registers. We investigate the state-of-the-art modular inversion algorithms, and evaluate the performance and cost of the algorithms and their hardware implementations. We then propose a high-radix modular inversion algorithm aimed at reducing the execution time and hardware costs. We present a detailed radix-8 hardware implementation based on 256-bit primes in Verilog HDL and compare its cost performance to other implementations. Our implementation on the Altera Cyclone V FPGA chip used 1227 ALMs (adaptive logic modules) and 1037 registers. The modular inversion calculation took 3.67 ms. The AT (area–time) factor was 8.30, outperforming the other implementations. We also present an implementation of ECC using the proposed radix-8 modular inversion algorithm. The implementation results also showed that our modular inversion algorithm was more efficient in area–time than the other algorithms. [ABSTRACT FROM AUTHOR]

Published
2024
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49. A Simple Synthesis of Tetraamino-[60]Fullerene Epoxides as Potential Antitumor Drug Candidates

Author

Lu, Yicheng, primary, Li, Jie, additional, Liu, Xiaolong, additional, He, Dan, additional, Yang, Libin, additional, Zhou, Wei, additional, Wang, Xie, additional, Chen, Shanshan, additional, Chen, Shiliang, additional, Liu, Yating, additional, Wang, Xin, additional, Li, Jiao, additional, Huo, Jiawei, additional, Liu, Yang, additional, Wang, Zehu, additional, Liu, Meihan, additional, Wang, Yijun, additional, Li, Yamin, additional, Zhao, Fuwen, additional, Li, Shumu, additional, Wei, Jinchao, additional, Liu, Jianan, additional, Li, Wei, additional, and Wang, Chunru, additional

Published
2024
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