Your search keyword '"Huang, Xiaoyang"' showing total 433 results

1. Hydrodynamics as the effective field theory of strong-to-weak spontaneous symmetry breaking

Author

Huang, Xiaoyang, Qi, Marvin, Zhang, Jian-Hao, and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Quantum Physics

Abstract

Inspired by the hunt for new phases of matter in quantum mixed states, it has recently been proposed that the equivalence of microcanonical and canonical ensembles in statistical mechanics is a manifestation of strong-to-weak spontaneous symmetry breaking (SWSSB) in an underlying many-body quantum description. Here, we build an effective field theory for SWSSB of a global U(1) symmetry; the answer exactly reproduces the Schwinger-Keldysh effective field theory of diffusion for the conserved charge. We conclude that hydrodynamics can be understood as a theory of "superfluidity" for the broken strong symmetry: a non-vanishing susceptibility is a measurable order parameter for SWSSB, the diffusion mode is the Goldstone boson of the spontaneously broken continuous symmetry, and a generalization of Goldstone's Theorem implies that the diffusion mode is always long-lived. This perspective provides a transparent physical explanation for the unusual "reparameterization" symmetries which are a necessary ingredient of Schwinger-Keldysh effective field theories for "normal fluids".

Published

2024

2. Effective field theory for ersatz Fermi liquids

Author

Huang, Xiaoyang, Lucas, Andrew, Mehta, Umang, and Qi, Marvin

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We apply "hydrodynamic" effective field theory techniques to an ersatz Fermi liquid. Our effective theory, which captures the correlation functions of density operators at each angle on the Fermi surface, can only deviate from conventional Fermi liquid behavior if the effective theory is non-local. Neglecting non-local effects, the ersatz Fermi liquid's effective action is the Legendre transform of the effective action for Fermi liquids, based on the coadjoint orbit method, up to irrelevant corrections., Comment: 11 pages

Published

2024

3. Deep Rib Fracture Instance Segmentation and Classification from CT on the RibFrac Challenge

Author

Yang, Jiancheng, Shi, Rui, Jin, Liang, Huang, Xiaoyang, Kuang, Kaiming, Wei, Donglai, Gu, Shixuan, Liu, Jianying, Liu, Pengfei, Chai, Zhizhong, Xiao, Yongjie, Chen, Hao, Xu, Liming, Du, Bang, Yan, Xiangyi, Tang, Hao, Alessio, Adam, Holste, Gregory, Zhang, Jiapeng, Wang, Xiaoming, He, Jianye, Che, Lixuan, Pfister, Hanspeter, Li, Ming, and Ni, Bingbing

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition

Abstract

Rib fractures are a common and potentially severe injury that can be challenging and labor-intensive to detect in CT scans. While there have been efforts to address this field, the lack of large-scale annotated datasets and evaluation benchmarks has hindered the development and validation of deep learning algorithms. To address this issue, the RibFrac Challenge was introduced, providing a benchmark dataset of over 5,000 rib fractures from 660 CT scans, with voxel-level instance mask annotations and diagnosis labels for four clinical categories (buckle, nondisplaced, displaced, or segmental). The challenge includes two tracks: a detection (instance segmentation) track evaluated by an FROC-style metric and a classification track evaluated by an F1-style metric. During the MICCAI 2020 challenge period, 243 results were evaluated, and seven teams were invited to participate in the challenge summary. The analysis revealed that several top rib fracture detection solutions achieved performance comparable or even better than human experts. Nevertheless, the current rib fracture classification solutions are hardly clinically applicable, which can be an interesting area in the future. As an active benchmark and research resource, the data and online evaluation of the RibFrac Challenge are available at the challenge website. As an independent contribution, we have also extended our previous internal baseline by incorporating recent advancements in large-scale pretrained networks and point-based rib segmentation techniques. The resulting FracNet+ demonstrates competitive performance in rib fracture detection, which lays a foundation for further research and development in AI-assisted rib fracture detection and diagnosis., Comment: Challenge paper for MICCAI RibFrac Challenge (https://ribfrac.grand-challenge.org/)

Published

2024

4. Effective field theory of Berry Fermi liquid from the coadjoint orbit method

Author

Huang, Xiaoyang

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We construct an effective field theory for an interacting Fermi liquid with nonzero Berry curvature at zero temperature, called the Berry Fermi liquid. We start with the extended phase space formalism, incorporating physical time into the configuration space. This approach allows us to include the time dependence of the background gauge fields ``covariantly'' into the symplectic structure. Upon restricting to the physical hypersurface, the effective action that lives on the coadjoint orbit becomes the minus free energy on the extended phase space. We also derive the action perturbatively in external fields using the canonical variables. For applications, we compute both linear and nonlinear electrical responses using the Kubo formula, and identify contributions from the electric and magnetic dipole moments, which stem from interactions breaking parity and time-reversal symmetry. The anomalous Hall effect is confirmed using the kinetic theory., Comment: 16 + 5 pages

Published

2023

5. Generalized time-reversal symmetry and effective theories for nonequilibrium matter

Author

Huang, Xiaoyang, Farrell, Jack H., Friedman, Aaron J., Zane, Isabella, Glorioso, Paolo, and Lucas, Andrew

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Soft Condensed Matter, High Energy Physics - Theory

Abstract

The past decade has witnessed the development of systematic effective theories for dissipative thermal systems. Here, we describe an analogous effective theory framework that applies to the classical stochastic dynamics of nonequilibrium systems. We illustrate this approach using a range of examples, including nonreciprocal (predator-prey) dynamics, dissipative and driven rigid-body motion, and active chiral fluids and solids. Many of these systems exhibit a generalized time-reversal symmetry, which plays a crucial role within our formalism, and in many cases can be implemented within the Martin-Siggia-Rose path integral. This effective theory formalism yields generalizations of the fluctuation-dissipation theorem and second law of thermodynamics valid out of equilibrium. By stipulating a stationary distribution and a set of symmetries -- rather than postulating the stochastic equations of motion directly -- this formalism provides an alternative route to building phenomenological models of driven and active matter. We hope that this approach facilitates a systematic investigation of the universality classes of active matter, and provides a common language for nonequilibrium many-body physics from high energy to condensed matter., Comment: 74 pages, 6 figures

Published

2023

6. Shifting More Attention to Breast Lesion Segmentation in Ultrasound Videos

Author

Lin, Junhao, Dai, Qian, Zhu, Lei, Fu, Huazhu, Wang, Qiong, Li, Weibin, Rao, Wenhao, Huang, Xiaoyang, and Wang, Liansheng

Subjects

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

Abstract

Breast lesion segmentation in ultrasound (US) videos is essential for diagnosing and treating axillary lymph node metastasis. However, the lack of a well-established and large-scale ultrasound video dataset with high-quality annotations has posed a persistent challenge for the research community. To overcome this issue, we meticulously curated a US video breast lesion segmentation dataset comprising 572 videos and 34,300 annotated frames, covering a wide range of realistic clinical scenarios. Furthermore, we propose a novel frequency and localization feature aggregation network (FLA-Net) that learns temporal features from the frequency domain and predicts additional lesion location positions to assist with breast lesion segmentation. We also devise a localization-based contrastive loss to reduce the lesion location distance between neighboring video frames within the same video and enlarge the location distances between frames from different ultrasound videos. Our experiments on our annotated dataset and two public video polyp segmentation datasets demonstrate that our proposed FLA-Net achieves state-of-the-art performance in breast lesion segmentation in US videos and video polyp segmentation while significantly reducing time and space complexity. Our model and dataset are available at https://github.com/jhl-Det/FLA-Net., Comment: 10 pages

Published

2023

7. Disordered quantum critical fixed points from holography

Author

Huang, Xiaoyang, Sachdev, Subir, and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Using holographic duality, we present an analytically controlled theory of quantum critical points without quasiparticles, at finite disorder and finite charge density. These fixed points are obtained by perturbing a disorder-free quantum critical point with relevant disorder whose operator dimension is perturbatively close to Harris marginal. We analyze these fixed points both using field theoretic arguments, and by solving the bulk equations of motion in holography. We calculate the critical exponents of the IR theory, together with thermoelectric transport coefficients. Our predictions for the critical exponents of the disordered fixed point are consistent with previous work, both in holographic and nonholograpic models., Comment: 5+14 pages

Published

2023

8. A Chern-Simons theory for dipole symmetry

Author

Huang, Xiaoyang

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We present effective field theories for dipole symmetric topological matters that can be described by the Chern-Simons theory. Unlike most studies using higher-rank gauge theory, we develop a framework with both U(1) and dipole gauge fields. As a result, only the highest multipole symmetry can support the 't Hooft anomaly. We show that with appropriate point group symmetries, the dipolar Chern-Simons theory can exist in any dimension and, moreover, the bulk-edge correspondence can depend on the boundary. As two applications, we draw an analogy between the dipole anomaly and the torsional anomaly and generalize particle-vortex duality to dipole phase transitions. All of the above are in the flat spacetime limit, but our framework is able to systematically couple dipole symmetry to curved spacetime. Based on that, we give a proposal about anomalous dipole hydrodynamics. Moreover, we show that the fracton-elasticity duality arises naturally from a non-abelian Chern-Simons theory in 3D., Comment: 16 + 1 pages; typos corrected, references added

Published

2023

9. Frequency-Modulated Point Cloud Rendering with Easy Editing

Author

Zhang, Yi, Huang, Xiaoyang, Ni, Bingbing, Li, Teng, and Zhang, Wenjun

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

We develop an effective point cloud rendering pipeline for novel view synthesis, which enables high fidelity local detail reconstruction, real-time rendering and user-friendly editing. In the heart of our pipeline is an adaptive frequency modulation module called Adaptive Frequency Net (AFNet), which utilizes a hypernetwork to learn the local texture frequency encoding that is consecutively injected into adaptive frequency activation layers to modulate the implicit radiance signal. This mechanism improves the frequency expressive ability of the network with richer frequency basis support, only at a small computational budget. To further boost performance, a preprocessing module is also proposed for point cloud geometry optimization via point opacity estimation. In contrast to implicit rendering, our pipeline supports high-fidelity interactive editing based on point cloud manipulation. Extensive experimental results on NeRF-Synthetic, ScanNet, DTU and Tanks and Temples datasets demonstrate the superior performances achieved by our method in terms of PSNR, SSIM and LPIPS, in comparison to the state-of-the-art., Comment: Accepted by CVPR 2023

Published

2023

10. AudioEar: Single-View Ear Reconstruction for Personalized Spatial Audio

Author

Huang, Xiaoyang, Wang, Yanjun, Liu, Yang, Ni, Bingbing, Zhang, Wenjun, Liu, Jinxian, and Li, Teng

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Multimedia

Abstract

Spatial audio, which focuses on immersive 3D sound rendering, is widely applied in the acoustic industry. One of the key problems of current spatial audio rendering methods is the lack of personalization based on different anatomies of individuals, which is essential to produce accurate sound source positions. In this work, we address this problem from an interdisciplinary perspective. The rendering of spatial audio is strongly correlated with the 3D shape of human bodies, particularly ears. To this end, we propose to achieve personalized spatial audio by reconstructing 3D human ears with single-view images. First, to benchmark the ear reconstruction task, we introduce AudioEar3D, a high-quality 3D ear dataset consisting of 112 point cloud ear scans with RGB images. To self-supervisedly train a reconstruction model, we further collect a 2D ear dataset composed of 2,000 images, each one with manual annotation of occlusion and 55 landmarks, named AudioEar2D. To our knowledge, both datasets have the largest scale and best quality of their kinds for public use. Further, we propose AudioEarM, a reconstruction method guided by a depth estimation network that is trained on synthetic data, with two loss functions tailored for ear data. Lastly, to fill the gap between the vision and acoustics community, we develop a pipeline to integrate the reconstructed ear mesh with an off-the-shelf 3D human body and simulate a personalized Head-Related Transfer Function (HRTF), which is the core of spatial audio rendering. Code and data are publicly available at https://github.com/seanywang0408/AudioEar., Comment: Accepted by Thirty-Seventh AAAI Conference on Artificial Intelligence (AAAI 2023)

Published

2023

11. Goldstone bosons and fluctuating hydrodynamics with dipole and momentum conservation

Author

Glorioso, Paolo, Huang, Xiaoyang, Guo, Jinkang, Rodriguez-Nieva, Joaquin F., and Lucas, Andrew

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics

Abstract

We develop a Schwinger-Keldysh effective field theory describing the hydrodynamics of a fluid with conserved charge and dipole moments, together with conserved momentum. The resulting hydrodynamic modes are highly unusual, including sound waves with quadratic (magnon-like) dispersion relation and subdiffusive decay rate. Hydrodynamics itself is unstable below four spatial dimensions. We show that the momentum density is, at leading order, the Goldstone boson for a dipole symmetry which appears spontaneously broken at finite charge density. Unlike an ordinary fluid, the presence or absence of energy conservation qualitatively changes the decay rates of the hydrodynamic modes. This effective field theory naturally couples to curved spacetime and background gauge fields; in the flat spacetime limit, we reproduce the "mixed rank tensor fields" previously coupled to fracton matter., Comment: 20+10 pages. v2, v3, v4: minor edits

Published

2023

12. Boosting Point Clouds Rendering via Radiance Mapping

Author

Huang, Xiaoyang, Zhang, Yi, Ni, Bingbing, Li, Teng, Chen, Kai, and Zhang, Wenjun

Subjects

Computer Science - Computer Vision and Pattern Recognition

Abstract

Recent years we have witnessed rapid development in NeRF-based image rendering due to its high quality. However, point clouds rendering is somehow less explored. Compared to NeRF-based rendering which suffers from dense spatial sampling, point clouds rendering is naturally less computation intensive, which enables its deployment in mobile computing device. In this work, we focus on boosting the image quality of point clouds rendering with a compact model design. We first analyze the adaption of the volume rendering formulation on point clouds. Based on the analysis, we simplify the NeRF representation to a spatial mapping function which only requires single evaluation per pixel. Further, motivated by ray marching, we rectify the the noisy raw point clouds to the estimated intersection between rays and surfaces as queried coordinates, which could avoid \textit{spatial frequency collapse} and neighbor point disturbance. Composed of rasterization, spatial mapping and the refinement stages, our method achieves the state-of-the-art performance on point clouds rendering, outperforming prior works by notable margins, with a smaller model size. We obtain a PSNR of 31.74 on NeRF-Synthetic, 25.88 on ScanNet and 30.81 on DTU. Code and data are publicly available at https://github.com/seanywang0408/RadianceMapping., Comment: Accepted by Thirty-Seventh AAAI Conference on Artificial Intelligence (AAAI 2023)

Published

2022

13. Exploring cardiovascular risk and outcomes in primary care consulters for osteoarthritis using longitudinal electronic primary care data

Author

Huang, Xiaoyang, Yu, D., and Wilkie, R.

Subjects

RC925 Diseases of the musculoskeletal system

Abstract

For adults aged 45 and over in the United Kingdom (UK), osteoarthritis is a common reason for consultation with primary care. Cardiovascular disease (CVD) is a common comorbidity with osteoarthritis; two in five people with osteoarthritis also have CVD. In the UK, primary care is often the first point of contact for people in need of osteoarthritis management and CVD preventive services. This thesis aims to assess the prevalence of CVD risk factors, the level of CVD risk and outcomes in primary care consulters with osteoarthritis in comparison to those without osteoarthritis. To address this question, the thesis includes a series of retrospective cohort studies using CPRD GOLD, a large representative primary care EHR database, and linked data in the UK between 1992-2017. The consistently higher prevalence of modifiable cardiovascular risk factors (CVRFs), variables that are associated with a higher risk of CVD events, in the osteoarthritis population was revealed in chapter 2 and the socioeconomic inequality in these CVRFs was found in chapter 3. The thesis could then try to understand that if ruling out the impact of CVRFs, what is the excess risk of CVD due to osteoarthritis. The thesis then tried to use the established risk score (sex-specific Framingham risk score) to predict the CVD risk and to assess the following preventative treatments in the osteoarthritis and non-osteoarthritis populations in Chapter 4. If the score performs well, we could then estimate the risk difference (excess risk) based on the established risk score. Unfortunately, its overall prediction performance was not good, as found in chapter 5. We then applied the frailty Cox model (conditional Cox model) based on the matched cohorts, controlling demographical variables, period effect, and coding variation at the practice level, adjusting lifestyles, body measurements, clinical measurements, and treatments to estimate the excess risk of CVD due to osteoarthritis. As the finding in Chapter 6, there was a significant excess risk of CVD for osteoarthritis, and higher in men, the elder and the deprived population. Importantly, the excess risk was also observed in the youngest age group (35-44 years). There could be potential unmeasured confounders, but the findings consistently suggest that clinical effectiveness, cost-effectiveness, and acceptability of potential preventive care strategies under the current screening criteria should be further addressed in the osteoarthritis population in the UK.

Published

2023

14. Hydrodynamics with helical symmetry

Author

Farrell, Jack H., Huang, Xiaoyang, and Lucas, Andrew

Subjects

Condensed Matter - Statistical Mechanics, High Energy Physics - Theory

Abstract

We present the hydrodynamics of fluids in three spatial dimensions with helical symmetry, wherein only a linear combination of a rotation and translation is conserved in one of the three directions. The hydrodynamic degrees of freedom consist of scalar densities (e.g. energy or charge) along with two velocity fields transverse to the helical axis when the corresponding momenta are conserved. Nondissipative hydrodynamic coefficients reminiscent of chiral vortical coefficients arise. We write down microscopic Hamiltonian dynamical systems exhibiting helical symmetry, and we demonstrate using kinetic theory that these systems will generically exhibit the new helical phenomena that we predicted within hydrodynamics. We also confirm our findings using modern effective field theory techniques for hydrodynamics. We postulate regimes where pinned cholesteric liquid crystals may possess transport coefficients of a helical fluid, which appear to have been overlooked in previous literature., Comment: 24 pages, 1 figure

Published

2022

15. Representation-Agnostic Shape Fields

Author

Huang, Xiaoyang, Yang, Jiancheng, Wang, Yanjun, Chen, Ziyu, Li, Linguo, Li, Teng, Ni, Bingbing, and Zhang, Wenjun

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Artificial Intelligence

Abstract

3D shape analysis has been widely explored in the era of deep learning. Numerous models have been developed for various 3D data representation formats, e.g., MeshCNN for meshes, PointNet for point clouds and VoxNet for voxels. In this study, we present Representation-Agnostic Shape Fields (RASF), a generalizable and computation-efficient shape embedding module for 3D deep learning. RASF is implemented with a learnable 3D grid with multiple channels to store local geometry. Based on RASF, shape embeddings for various 3D shape representations (point clouds, meshes and voxels) are retrieved by coordinate indexing. While there are multiple ways to optimize the learnable parameters of RASF, we provide two effective schemes among all in this paper for RASF pre-training: shape reconstruction and normal estimation. Once trained, RASF becomes a plug-and-play performance booster with negligible cost. Extensive experiments on diverse 3D representation formats, networks and applications, validate the universal effectiveness of the proposed RASF. Code and pre-trained models are publicly available https://github.com/seanywang0408/RASF, Comment: The Tenth International Conference on Learning Representations (ICLR 2022). Code is available at https://github.com/seanywang0408/RASF

Published

2022

16. Eltrombopag plus diacerein vs eltrombopag in patients with ITP: a multicenter, randomized, open-label phase 2 trial

Author

Sun, Lu, Huang, Xiaoyang, Wang, Juan, Yuan, Chenglu, Zhao, Hongyu, Li, Daqi, Xu, Ruirong, Wang, Yan, Qin, Ping, Shi, Yan, Peng, Jun, Hou, Ming, and Hou, Yu

Published

2024

17. Turbine blade tip aerothermal characteristics considering the influences of cavity tip shaping

Author

Du, Kun, Wang, Xubo, Huang, Xiaoyang, Liu, Cunliang, and Sunden, Bengt

Published

2024

18. Bit depth enhancement method based on visual contrast perception features

Author

Fu, Zhizhong, Peng, Changmeng, Huang, Xiaoyang, Xia, Maohan, Xu, Jin, and Li, Xiaofeng

Published

2024

19. An effective potential Bifidobacterium animalis F1-7 delivery strategy: Supramolecular hydrogel - sodium alginate/tryptophan-Sulfobutylether-β-cyclodextrin (Alg/Trp-SBE-β-CD)

Author

Huang, Xiaoyang, Wang, Jing, Liu, Rui, Yang, Chunrong, Shao, Yanchun, Wang, Xiaohong, Yi, Huaxi, and Lu, Youyou

Published

2024

20. Hydrodynamic effective field theories with discrete rotational symmetry

Author

Huang, Xiaoyang and Lucas, Andrew

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics

Abstract

We develop a hydrodynamic effective field theory on the Schwinger-Keldysh contour for fluids with charge, energy, and momentum conservation, but only discrete rotational symmetry. The consequences of anisotropy on thermodynamics and first-order dissipative hydrodynamics are detailed in some simple examples in two spatial dimensions, but our construction extends to any spatial dimension and any rotation group (discrete or continuous). We find many possible terms in the equations of motion which are compatible with the existence of an entropy current, but not with the ability to couple the fluid to background gauge fields and vielbein., Comment: 20 + 6 pages

Published

2022

21. Study on the characteristics of microwave pyrolysis of pine wood catalyzed by bimetallic catalysts prepared with microwave-assisted hydrothermal char

Author

Sun, Zhenjie, Wei, Haixiao, Guo, Feiqiang, Dong, Kaiming, Huang, Xiaoyang, You, Xiaodong, and Wu, Songtao

Published

2024

22. Morality or competence is more important? The effect of evaluation dimensions on ERP responses to neutral faces depends on contextual valence and self-relevance

Author

Huang, Xiaoyang, Sun, Yuliu, Tao, Ruiwen, Yan, Kaikai, and Zhang, Entao

Published

2024

23. Social power modulates individuals’ neural responses to monetary and social rewards

Author

He, Yuying, Huang, Xiaoyang, and Zhang, Entao

Published

2024

24. Unveiling the spatially confined oxidation processes in reactive electrochemical membranes

Author

Kang, Yuyang, Gu, Zhenao, Ma, Baiwen, Zhang, Wei, Sun, Jingqiu, Huang, Xiaoyang, Hu, Chengzhi, Choi, Wonyong, and Qu, Jiuhui

Published

2023

25. Boosting selective hydrogenation of α,β-unsaturated aldehydes through constructing independent Pt and Fe active sites on support

Author

Liang, Yu, He, Jieting, An, Yurong, Zhang, Jiaxing, Park, Gyeong-Su, Zhao, Liang, Oh, Rena, Huang, Xiaoyang, Dong, Jinxiang, and Liu, Lei

Published

2024

26. Unveiling the Ce-Mn ion redox behavior at the interface of CeO2/YbMn2O5 for low-temperature CO oxidation

Author

Wang, Siyan, Zhang, Jiyu, Rao, Fei, Zhai, Liangyu, Zhu, Lujun, Shi, Xianjin, Huang, Yu, Jia, Yanmin, Oh, Rena, Huang, Xiaoyang, and Zhu, Gangqiang

Published

2024

27. Fingerprints of quantum criticality in locally resolved transport

Author

Huang, Xiaoyang and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Understanding electrical transport in strange metals, including the seeming universality of Planckian $T$-linear resistivity, remains a longstanding challenge in condensed matter physics. We propose that local imaging techniques, such as nitrogen vacancy center magnetometry, can locally identify signatures of quantum critical response which are invisible in measurements of a bulk electrical resistivity. As an illustrative example, we use a minimal holographic model for a strange metal in two spatial dimensions to predict how electrical current will flow in regimes dominated by quantum critical dynamics on the Planckian length scale. We describe the crossover between quantum critical transport and hydrodynamic transport (including Ohmic regimes), both in charge neutral and finite density systems. We compare our holographic predictions to experiments on charge neutral graphene, finding quantitative agreement with available data; we suggest further experiments which may determine the relevance of our framework to transport on Planckian scales in this material. More broadly, we propose that locally imaged transport be used to test the universality (or lack thereof) of microscopic dynamics in the diverse set of quantum materials exhibiting $T$-linear resistivity., Comment: 7+14 pages; 4+9 figures, 1+0 tables. v2: some new results. v3: more results added. v4: minor revisions

Published

2021

28. Deep reinforcement learning for quantum Hamiltonian engineering

Author

Peng, Pai, Huang, Xiaoyang, Yin, Chao, Joseph, Linta, Ramanathan, Chandrasekhar, and Cappellaro, Paola

Subjects

Quantum Physics, Physics - Atomic and Molecular Clusters, Physics - Computational Physics

Abstract

Engineering desired Hamiltonian in quantum many-body systems is essential for applications such as quantum simulation, computation and sensing. Conventional quantum Hamiltonian engineering sequences are designed using human intuition based on perturbation theory, which may not describe the optimal solution and is unable to accommodate complex experimental imperfections. Here we numerically search for Hamiltonian engineering sequences using deep reinforcement learning (DRL) techniques and experimentally demonstrate that they outperform celebrated sequences on a solid-state nuclear magnetic resonance quantum simulator. As an example, we aim at decoupling strongly-interacting spin-1/2 systems. We train DRL agents in the presence of different experimental imperfections and verify robustness of the output sequences both in simulations and experiments. Surprisingly, many of the learned sequences exhibit a common pattern that had not been discovered before, to our knowledge, but has an meaningful analytical description. We can thus restrict the searching space based on this control pattern, allowing to search for longer sequences, ultimately leading to sequences that are robust against dominant imperfections in our experiments. Our results not only demonstrate a general method for quantum Hamiltonian engineering, but also highlight the importance of combining black-box artificial intelligence with understanding of physical system in order to realize experimentally feasible applications., Comment: 20 pages, 10+6 figures, 1+2 tables

Published

2021

29. Attention-Aware Contrastive Learning for Predicting Peptide-HLA Binding Specificity

Author

Luo, Pengyu, Huang, Yuehan, Zhang, Xinyi, Shen, Lian, Lin, Yuan, Liu, Xiangrong, Huang, Xiaoyang, 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, Huang, De-Shuang, editor, Premaratne, Prashan, editor, Jin, Baohua, editor, Qu, Boyang, editor, Jo, Kang-Hyun, editor, and Hussain, Abir, editor

Published

2023

30. Preparation and synbiotic interaction mechanism of microcapsules of Bifidobacterium animalis F1–7 and human milk oligosaccharides (HMO)

Author

Huang, Xiaoyang, Liu, Rui, Wang, Jing, Bao, Yuexin, Yi, Huaxi, Wang, Xiaohong, and Lu, Youyou

Published

2024

31. Tandem reactions on phase separated MnO2 and C to enhance formaldehyde conversion to hydrogen

Author

Zhang, Peipei, Sun, Hanlei, Lu, Xiuyuan, Oh, Rena, Zhang, Nuowei, Akdim, Ouardia, Roldan, Alberto, Huang, Xiaoyang, and Chen, Binghui

Published

2024

32. Experimental Study on the Overall Cooling Effectiveness of Effusion-Cooling Ceramic Matrix Composite Platform

Author

Du, Kun, Chen, Qihao, Huang, Xiaoyang, Liang, Tingrui, and Liu, Cunliang

Published

2023

33. Zero-oxidation state precursor assisted fabrication of highly dispersed and stable Pt catalyst for chemoselective hydrogenation of α,β-unsaturated aldehydes

Author

Liang, Yu, Douthwaite, Mark, Huang, Xiaoyang, Zhao, Binbin, Tang, Qiong, Liu, Lei, and Dong, Jinxiang

Published

2023

34. Learning Black-Box Attackers with Transferable Priors and Query Feedback

Author

Yang, Jiancheng, Jiang, Yangzhou, Huang, Xiaoyang, Ni, Bingbing, and Zhao, Chenglong

Subjects

Computer Science - Cryptography and Security, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

This paper addresses the challenging black-box adversarial attack problem, where only classification confidence of a victim model is available. Inspired by consistency of visual saliency between different vision models, a surrogate model is expected to improve the attack performance via transferability. By combining transferability-based and query-based black-box attack, we propose a surprisingly simple baseline approach (named SimBA++) using the surrogate model, which significantly outperforms several state-of-the-art methods. Moreover, to efficiently utilize the query feedback, we update the surrogate model in a novel learning scheme, named High-Order Gradient Approximation (HOGA). By constructing a high-order gradient computation graph, we update the surrogate model to approximate the victim model in both forward and backward pass. The SimBA++ and HOGA result in Learnable Black-Box Attack (LeBA), which surpasses previous state of the art by considerable margins: the proposed LeBA significantly reduces queries, while keeping higher attack success rates close to 100% in extensive ImageNet experiments, including attacking vision benchmarks and defensive models. Code is open source at https://github.com/TrustworthyDL/LeBA., Comment: NeurIPS 2020. Code is available at https://github.com/TrustworthyDL/LeBA

Published

2020

35. Electron-phonon hydrodynamics

Author

Huang, Xiaoyang and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We develop the theory of hydrodynamics of an isotropic Fermi liquid of electrons coupled to isotropic acoustic phonons, assuming that umklapp processes may be neglected. At low temperatures, the fluid is approximately Galilean invariant; at high temperatures, the fluid is nearly relativistic; at intermediate temperatures, there are seven additional temperature regimes with unconventional thermodynamic properties and hydrodynamic transport coefficients in a three-dimensional system. We predict qualitative signatures of electron-phonon fluids in incoherent transport coefficients, shear and Hall viscosity, and plasmon dispersion relations. Our theory may be relevant for numerous quantum materials where strong electron-phonon scattering has been proposed to underlie a hydrodynamic regime, including $\mathrm{WTe}_2$, $\mathrm{WP}_2$, and $\mathrm{PtSn}_4$., Comment: 24+10 pages, 4 figures. v2: published version

Published

2020

36. Prethermal quasiconserved observables in Floquet quantum systems

Author

Yin, Chao, Peng, Pai, Huang, Xiaoyang, Ramanathan, Chandrasekhar, and Cappellaro, Paola

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

Prethermalization, by introducing emergent quasiconserved observables, plays a crucial role in protecting Floquet many-body phases over exponentially long time, while the ultimate fate of such quasiconserved operators can signal thermalization to infinite temperature. To elucidate the properties of prethermal quasiconservation in many-body Floquet systems, here we systematically analyze infinite temperature correlations between observables. We numerically show that the late-time behavior of the autocorrelations unambiguously distinguishes quasiconserved observables from non-conserved ones, allowing to single out a set of linearly-independent quasiconserved observables. By investigating two Floquet spin models, we identify two different mechanism underlying the quasi-conservation law. First, we numerically verify energy quasiconservation when the driving frequency is large, so that the system dynamics is approximately described by a static prethermal Hamiltonian. More interestingly, under moderate driving frequency, another quasiconserved observable can still persist if the Floquet driving contains a large global rotation. We show theoretically how to calculate this conserved observable and provide numerical verification. Having systematically identified all quasiconserved observables, we can finally investigate their behavior in the infinite-time limit and thermodynamic limit, using autocorrelations obtained from both numerical simulation and experiments in solid state nuclear magnetic resonance systems., Comment: 12 pages, 9 figures. arXiv admin note: substantial text overlap with arXiv:1912.05799

Published

2020

37. AlignShift: Bridging the Gap of Imaging Thickness in 3D Anisotropic Volumes

Author

Yang, Jiancheng, He, Yi, Huang, Xiaoyang, Xu, Jingwei, Ye, Xiaodan, Tao, Guangyu, and Ni, Bingbing

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

This paper addresses a fundamental challenge in 3D medical image processing: how to deal with imaging thickness. For anisotropic medical volumes, there is a significant performance gap between thin-slice (mostly 1mm) and thick-slice (mostly 5mm) volumes. Prior arts tend to use 3D approaches for the thin-slice and 2D approaches for the thick-slice, respectively. We aim at a unified approach for both thin- and thick-slice medical volumes. Inspired by recent advances in video analysis, we propose AlignShift, a novel parameter-free operator to convert theoretically any 2D pretrained network into thickness-aware 3D network. Remarkably, the converted networks behave like 3D for the thin-slice, nevertheless degenerate to 2D for the thick-slice adaptively. The unified thickness-aware representation learning is achieved by shifting and fusing aligned "virtual slices" as per the input imaging thickness. Extensive experiments on public large-scale DeepLesion benchmark, consisting of 32K lesions for universal lesion detection, validate the effectiveness of our method, which outperforms previous state of the art by considerable margins without whistles and bells. More importantly, to our knowledge, this is the first method that bridges the performance gap between thin- and thick-slice volumes by a unified framework. To improve research reproducibility, our code in PyTorch is open source at https://github.com/M3DV/AlignShift., Comment: MICCAI 2020 (early accepted). Camera ready version. Code is available at https://github.com/M3DV/AlignShift

Published

2020

38. Relational Learning between Multiple Pulmonary Nodules via Deep Set Attention Transformers

Author

Yang, Jiancheng, Deng, Haoran, Huang, Xiaoyang, Ni, Bingbing, and Xu, Yi

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

Diagnosis and treatment of multiple pulmonary nodules are clinically important but challenging. Prior studies on nodule characterization use solitary-nodule approaches on multiple nodular patients, which ignores the relations between nodules. In this study, we propose a multiple instance learning (MIL) approach and empirically prove the benefit to learn the relations between multiple nodules. By treating the multiple nodules from a same patient as a whole, critical relational information between solitary-nodule voxels is extracted. To our knowledge, it is the first study to learn the relations between multiple pulmonary nodules. Inspired by recent advances in natural language processing (NLP) domain, we introduce a self-attention transformer equipped with 3D CNN, named {NoduleSAT}, to replace typical pooling-based aggregation in multiple instance learning. Extensive experiments on lung nodule false positive reduction on LUNA16 database, and malignancy classification on LIDC-IDRI database, validate the effectiveness of the proposed method., Comment: 2020 IEEE 17th International Symposium on Biomedical Imaging (ISBI 2020)

Published

2020

39. Observation of Floquet prethermalization in dipolar spin chains

Author

Peng, Pai, Yin, Chao, Huang, Xiaoyang, Ramanathan, Chandrasekhar, and Cappellaro, Paola

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

Periodically driven Floquet quantum systems provide a promising platform to investigate novel physics out of equilibrium. Unfortunately, the drive generically heats up the system to a featureless infinite temperature state. For large driving frequency, the heat absorption rate is predicted to be exponentially small, giving rise to a long-lived prethermal regime which exhibits all the intriguing properties of Floquet systems. Here we experimentally observe Floquet prethermalization using nuclear magnetic resonance techniques. We first show the relaxation of a far-from-equilibrium initial state to a long-lived prethermal state, well described by the time-independent ''prethermal'' Hamiltonian. By measuring the autocorrelation of this prethermal Hamiltonian we can further experimentally confirm the predicted exponentially slow heating rate. More strikingly, we find that in the timescale when the effective Hamiltonian picture breaks down, the Floquet system still possesses other quasi-conservation laws. Our results demonstrate that it is possible to realize robust Floquet engineering, thus enabling the experimental observation of non-trivial Floquet phases of matter., Comment: 5+7 pages, 3+6 figures

Published

2019

40. Effectively synthesized functional Si-doped carbon dots with the applications in tyrosinase detection and lysosomal imaging

Author

Miao, Chenfang, Zhou, Xin, Huang, Xiaoyang, Huang, Jiyue, Chen, Yanping, Liu, Yuebin, Hu, Xiaomu, Zeng, Lingjun, Weng, Shaohuang, and Chen, Huixing

Published

2023

41. Peroxymonosulfate activation by Co@TiO2 for high-efficiency organic removals

Author

Zeng, Qingyi, Cao, Yuhan, Gao, Beibei, Huang, Xiaoyang, Zhang, Qingyan, Wang, Yumei, Cai, Tao, Zhang, Yuehua, Lv, Junwen, Xiong, Zhu, and Xue, Wenjing

Published

2023

42. Investigations of interaction between gold and palladium in alcohol oxidation reactions

Author

Huang, Xiaoyang

Subjects

547

Abstract

Synergistic interactions between Au and Pd in supported heterogeneous catalysts have long been attributed to the performance enhancements exhibited by AuPd bimetallic catalysts in the liquid phase oxidation of alcohols. However, conclusive experimental evidence for this synergy is somewhat limited and remains a subject of debate, which indirectly inhibits catalyst design. In this PhD thesis, a new explanation is provided for synergistic interactions between Au and Pd in supported AuPd bimetallic catalysts. The aqueous phase aerobic oxidation of 5-Hydroxymethylfurfural (HMF) was selected as a probe reaction for these studies, given the platform chemicals current significance within this field of research and the abundance of work documented on this reaction. It is proposed that the performance of either Au or Pd in AuPd bimetallic catalysts can be enhanced by facilitating the movement of electrons from one metallic component to the other, indicating that synergy is attributable to a redox co-operation between the two metals. This synergy is markedly enhanced when the two metals are not alloyed, which is demonstrated with spatially separated Au and Pd nanoparticles, noted as (Au + Pd)/C, and physical mixtures of the monometallic counterparts. This theory is evidenced through careful experimental design, utilizing both chemical and electrochemical measurements, e.g., cyclic voltammetry (CV), Short Circuit Current (SCC). Furthermore, it is also demonstrated that this phenomenon is independent of the reaction substrate; similar trends in catalytic performance were also observed for the aqueous phase aerobic oxidation of glycerol and ethanol. The catalysts used in this work were characterized by a number of different techniques, including: Scanning Transmission Electron Microscopy (STEM), Temperature Programmed Reduction (TPR), ultraviolet–visible spectroscopy (UV-vis), X-ray photoelectron spectroscopy (XPS), to further validate the proposed theory. It is considered that this discovery will provide a new approach to the design and synthesis of highly efficient bimetallic heterogeneous catalysts and contains potential applications in fuel cell research.

Published

2020

43. Aircraft engine nozzle guide vane surface temperature optimization

Author

Lou Decang, Wang Mengjun, Liang Jinhua, Zeng Jun, Huang Xiaoyang, and Chen Along

Subjects

Conjugate heat transfer, Sensitivity analysis, Duck-paw type film cooling hole, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

An optimization method based on the sensitivity of global and local geometric parameters is proposed to improve the cooling efficiency of E3 engine nozzle guide vane. For 29 geometric parameters that affect the vane maximum temperature in the cooling design, the sensitivity ranking of them is firstly obtained by the DOE method. Then the most influential parameters including the diameter or location of the film cooling hole are selected as the optimization variables to decrease the maximum surface temperature of the nozzle guide vane. On this basis, to further reduce the local temperature downstream the pressure side, a new duck-paw type film cooling hole is applied. The duck-paw type film cooling hole was produced with the adjoint method through identifying the sensitivity of the geometric boundary parameters of the film cooling holes. Compared to the cylindrical holes, the duck-paw shaped film cooling hole can greatly improve the cooling efficiency under the same conditions. The duck-paw type film cooling holes are applied to the last two rows of film cooling holes located on the pressure side of nozzle guide vane. Three-dimensional conjugate flow and heat transfer analysis results show that the maximum temperature of the optimized cooling structure vane is reduced by 39K, and the average temperature decreases by nearly 20K.

Published

2023

44. Reinventing 2D Convolutions for 3D Images

Author

Yang, Jiancheng, Huang, Xiaoyang, He, Yi, Xu, Jingwei, Yang, Canqian, Xu, Guozheng, and Ni, Bingbing

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning

Abstract

There have been considerable debates over 2D and 3D representation learning on 3D medical images. 2D approaches could benefit from large-scale 2D pretraining, whereas they are generally weak in capturing large 3D contexts. 3D approaches are natively strong in 3D contexts, however few publicly available 3D medical dataset is large and diverse enough for universal 3D pretraining. Even for hybrid (2D + 3D) approaches, the intrinsic disadvantages within the 2D / 3D parts still exist. In this study, we bridge the gap between 2D and 3D convolutions by reinventing the 2D convolutions. We propose ACS (axial-coronal-sagittal) convolutions to perform natively 3D representation learning, while utilizing the pretrained weights on 2D datasets. In ACS convolutions, 2D convolution kernels are split by channel into three parts, and convoluted separately on the three views (axial, coronal and sagittal) of 3D representations. Theoretically, ANY 2D CNN (ResNet, DenseNet, or DeepLab) is able to be converted into a 3D ACS CNN, with pretrained weight of a same parameter size. Extensive experiments on several medical benchmarks (including classification, segmentation and detection tasks) validate the consistent superiority of the pretrained ACS CNNs, over the 2D / 3D CNN counterparts with / without pretraining. Even without pretraining, the ACS convolution can be used as a plug-and-play replacement of standard 3D convolution, with smaller model size and less computation., Comment: IEEE Journal of Biomedical and Health Informatics (IEEE JBHI). Code is available at https://github.com/m3dv/ACSConv

Published

2019

45. Evaluating and Boosting Uncertainty Quantification in Classification

Author

Huang, Xiaoyang, Yang, Jiancheng, Li, Linguo, Deng, Haoran, Ni, Bingbing, and Xu, Yi

Subjects

Computer Science - Machine Learning, Computer Science - Artificial Intelligence

Abstract

Emergence of artificial intelligence techniques in biomedical applications urges the researchers to pay more attention on the uncertainty quantification (UQ) in machine-assisted medical decision making. For classification tasks, prior studies on UQ are difficult to compare with each other, due to the lack of a unified quantitative evaluation metric. Considering that well-performing UQ models ought to know when the classification models act incorrectly, we design a new evaluation metric, area under Confidence-Classification Characteristic curves (AUCCC), to quantitatively evaluate the performance of the UQ models. AUCCC is threshold-free, robust to perturbation, and insensitive to the classification performance. We evaluate several UQ methods (e.g., max softmax output) with AUCCC to validate its effectiveness. Furthermore, a simple scheme, named Uncertainty Distillation (UDist), is developed to boost the UQ performance, where a confidence model is distilling the confidence estimated by deep ensembles. The proposed method is easy to implement; it consistently outperforms strong baselines on natural and medical image datasets in our experiments.

Published

2019

46. Developing Pt-M/C catalyst (M=Pb, Cu) for efficient catalytic wet air oxidation of phenol wastewater under mild conditions

Author

Shan, Huici, Oh, Rena, Fan, Jianqiang, Zhang, Xiang, Zhang, Nuowei, Huang, Xiaoyang, Park, Gyeong-Su, Zheng, Quanxing, Lu, Hongliang, and Chen, Binghui

Published

2023

47. Shifting More Attention to Breast Lesion Segmentation in Ultrasound Videos

Author

Lin, Junhao, primary, Dai, Qian, additional, Zhu, Lei, additional, Fu, Huazhu, additional, Wang, Qiong, additional, Li, Weibin, additional, Rao, Wenhao, additional, Huang, Xiaoyang, additional, and Wang, Liansheng, additional

Published

2023

48. Influence of advisees’ facial feedback on subsequent advice-giving by advisors: Evidence from the behavioral and neurophysiological approach

Author

Yan, Kaikai, Tao, Ruiwen, Huang, Xiaoyang, and Zhang, Entao

Published

2023

49. LCRCA: image super-resolution using lightweight concatenated residual channel attention networks

Author

Peng, Changmeng, Shu, Pei, Huang, Xiaoyang, Fu, Zhizhong, and Li, Xiaofeng

Published

2022

50. Quantum estimation in an expanding spacetime

Author

Huang, Xiaoyang, Feng, Jun, Zhang, Yao-Zhong, and Fan, Heng

Subjects

High Energy Physics - Theory, General Relativity and Quantum Cosmology, Quantum Physics

Abstract

We investigate the quantum estimation on the Hubble parameter of an expanding de Sitter space by quantum metrological techniques. By exploring the dynamics of a freely falling Unruh-DeWitt detector, which interacts with a scalar field coupling to curvature, we calculate the Fisher information (FI) and quantum Fisher information (QFI) for the detector, which bound the highest precision of the estimation on Hubble parameter. In standard Bunch-Davies vacuum, we show that the maxima of FI/QFI are located for particular initial state of probe. Beside its dependence on the evolving time of detector and the energy spacing of atom $\omega$, we show that the maxima of FI/QFI can be significantly enhanced once a proper coupling of scalar field to curvature is chosen. For instance, we show numerically that the estimation in the scenario with minimally/nearly minimally coupling scalar field can always outperform that with conformally coupling scalar field, corresponding to a higher FI/QFI in estimation. Moreover, we find that for general $\alpha-$vacua of de Sitter space, a further improvement of estimation can be achieved, attributed to the squeezed nature of $\alpha-$vacua that heavily constrains the measurement uncertainty. Some implications of our results are also discussed., Comment: 14 pages, 8 figures, typos fixed, published version

Published

2018