Your search keyword '"Wang, Zihu"' showing total 3 results

1. RELICS: a REactor neutrino LIquid xenon Coherent elastic Scattering experiment

Author

Cai, Chang, Chen, Guocai, Chen, Jiangyu, Gao, Fei, Guo, Xiaoran, He, Tingyi, Jia, Chengjie, Jin, Gaojun, Jing, Yipin, Ju, Gaojun, Lei, Yang, Li, Jiayi, Li, Kaihang, Li, Meng, Li, Minhua, Li, Shengchao, Li, Siyin, Li, Tao, Lin, Qing, Liu, Jiajun, Liu, Minghao, Lv, Sheng, Luo, Guang, Ma, Jian, Shen, Chuanping, Song, Mingzhuo, Tong, Lijun, Wang, Xiaoyu, Wang, Wei, Wang, Zihu, Wei, Yuehuan, Weng, Liming, Xiao, Xiang, Xie, Lingfeng, Xu, Dacheng, Yang, Jijun, Yang, Litao, Yang, Long, Ye, Jingqiang, Yu, Jiachen, Yue, Qian, Yue, Yuyong, Zhang, Bingwei, Zhang, Shuhao, Zhao, Yifei, Cai, Chang, Chen, Guocai, Chen, Jiangyu, Gao, Fei, Guo, Xiaoran, He, Tingyi, Jia, Chengjie, Jin, Gaojun, Jing, Yipin, Ju, Gaojun, Lei, Yang, Li, Jiayi, Li, Kaihang, Li, Meng, Li, Minhua, Li, Shengchao, Li, Siyin, Li, Tao, Lin, Qing, Liu, Jiajun, Liu, Minghao, Lv, Sheng, Luo, Guang, Ma, Jian, Shen, Chuanping, Song, Mingzhuo, Tong, Lijun, Wang, Xiaoyu, Wang, Wei, Wang, Zihu, Wei, Yuehuan, Weng, Liming, Xiao, Xiang, Xie, Lingfeng, Xu, Dacheng, Yang, Jijun, Yang, Litao, Yang, Long, Ye, Jingqiang, Yu, Jiachen, Yue, Qian, Yue, Yuyong, Zhang, Bingwei, Zhang, Shuhao, and Zhao, Yifei

Abstract

Coherent elastic neutrino-nucleus scattering (CEvNS) provides a unique probe for neutrino properties Beyond the Standard Model (BSM) physics. REactor neutrino LIquid xenon Coherent Scattering experiment (RELICS), a proposed reactor neutrino program using liquid xenon time projection chamber (LXeTPC) technology, aims to investigate the CEvNS process of antineutrinos off xenon atomic nuclei. In this work, the design of the experiment is studied and optimized based on Monte Carlo (MC) simulations. To achieve a sufficiently low energy threshold for CEvNS detection, an ionization-only analysis channel will be adopted for RELICS. A high emission rate of delayed electrons after a big ionization signal is the major background, leading to an analysis threshold of 120 photo-electrons in the CEvNS search. The second largest background, nuclear recoils induced by cosmic-ray neutrons, is suppressed via a passive water shield. The physics potential of RELICS was explored with a 32 kg-yr exposure at a baseline of 25 m from a reactor core with a 3 GW thermal power. In an energy range of 120 to 240 PEs, we the expected 13673.5 CEvNS and 2133.7 background events.The sensitivity of RELICS to the weak mixing angle was investigated at a low momentum transfer. Our study has shown that RELICS can further improve the constraints on the non-standard neutrino interaction (NSI) compared to the best results. RELICS set out to develop a powerful surface-level detection technology for low-energy neutrinos from reactors.

Published

2024

2. PID Control-Based Self-Healing to Improve the Robustness of Large Language Models

Author

Chen, Zhuotong, Wang, Zihu, Yang, Yifan, Li, Qianxiao, Zhang, Zheng, Chen, Zhuotong, Wang, Zihu, Yang, Yifan, Li, Qianxiao, and Zhang, Zheng

Abstract

Despite the effectiveness of deep neural networks in numerous natural language processing applications, recent findings have exposed the vulnerability of these language models when minor perturbations are introduced. While appearing semantically indistinguishable to humans, these perturbations can significantly reduce the performance of well-trained language models, raising concerns about the reliability of deploying them in safe-critical situations. In this work, we construct a computationally efficient self-healing process to correct undesired model behavior during online inference when perturbations are applied to input data. This is formulated as a trajectory optimization problem in which the internal states of the neural network layers are automatically corrected using a PID (Proportional-Integral-Derivative) control mechanism. The P controller targets immediate state adjustments, while the I and D controllers consider past states and future dynamical trends, respectively. We leverage the geometrical properties of the training data to design effective linear PID controllers. This approach reduces the computational cost to that of using just the P controller, instead of the full PID control. Further, we introduce an analytical method for approximating the optimal control solutions, enhancing the real-time inference capabilities of this controlled system. Moreover, we conduct a theoretical error analysis of the analytic solution in a simplified setting. The proposed PID control-based self-healing is a low cost framework that improves the robustness of pre-trained large language models, whether standard or robustly trained, against a wide range of perturbations. A detailed implementation can be found in:https://github.com/zhuotongchen/PID-Control-Based-Self-Healing-to-Improve-the-Robustness-of-Large-Language-Models., Comment: Transactions on Machine Learning Research

Published

2024

3. Contrastive Learning with Consistent Representations

Author

Wang, Zihu, Wang, Yu, Hu, Hanbin, Li, Peng, Wang, Zihu, Wang, Yu, Hu, Hanbin, and Li, Peng

Abstract

Contrastive learning demonstrates great promise for representation learning. Data augmentations play a critical role in contrastive learning by providing informative views of the data without needing the labels. However, the performance of the existing works heavily relies on the quality of the employed data augmentation (DA) functions, which are typically hand picked from a restricted set of choices. While exploiting a diverse set of data augmentations is appealing, the intricacies of DAs and representation learning may lead to performance degradation. To address this challenge and allow for a systemic use of large numbers of data augmentations, this paper proposes Contrastive Learning with Consistent Representations (CoCor). At the core of CoCor is a new consistency measure, DA consistency, which dictates the mapping of augmented input data to the representation space such that these instances are mapped to optimal locations in a way consistent to the intensity of the DA applied. Furthermore, a data-driven approach is proposed to learn the optimal mapping locations as a function of DA while maintaining a desired monotonic property with respect to DA intensity. The proposed techniques give rise to a semi-supervised learning framework based on bi-level optimization, achieving new state-of-the-art results for image recognition.

Published

2023