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1. Possible way to achieve anomalous valley Hall effect by tunable intrinsic piezoelectric polarization in FeO$_2$SiGeN$_2$ monolayer

Author

Tian, Jianke, Li, Jia, Liu, Hengbo, Li, Yan, Liu, Ze, Li, Linyang, Li, Jun, Liu, Guodong, and Shi, Junjie

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Valley-related multiple Hall effect and piezoelectric response are novel transport characteristics in low-dimensional system, however few studies have reported their coexistence in a single system as well as their coupling relationships. By first-principles calculations, we propose a multifunctional Janus semiconductor, i.e. FeO$_2$SiGeN$_2$ monolayer with large valley polarization of about 120 meV and in-plane piezoelectric polarization with d11 of -0.714.03 pm/V. The magnetic anisotropy energy can be significantly regulated by electronic correlation strength and strain, which can be attributed to the change of competition relationship about Fe-3d-resolved magnetic anisotropy energy brought about by external regulatory means. Electronic correlation strength can induce phase transitions in Janus FeO$_2$SiGeN$_2$ monolayer from ferrovalley to quantum anomalous Hall phase, while the half-valley metallic state as the boundary of the phase transition can gererate 100% spin- and valley polarization. The related phase transition mechanism is analyzed based on the two-band strained kp model. The presence of piezoelectric strain coefficients d11 in valleytronic material makes the coupling between charge degrees of freedom and valley degrees of freedom possible, and the intrinsic electric field caused by the in-plane piezoelectric response provide the way to realize piezoelectric anomalous valley Hall effect. This work may pave a way to find a new member of materials with valley-related multiple Hall effect and stimulate further experimental works related to valleytronics and piezotronics.

Published
2024

2. Piezoelectric Manipulation and Engineering for Layertronics in Two-Dimensional Materials

Author

Tian, Jianke, Li, Jia, Liu, Hengbo, Li, Yan, Liu, Ze, Li, Linyang, Li, Jun, Liu, Guodong, and Shi, Junjie

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

The electronic transport characteristics of two-dimensional (2D) systems have widespread application prospects in the fabrication of multifunctional nanodevices. However, the current research for basic transport phenomena, such as anomalous valley Hall effect (AVHE) and piezoelectric response, is limited to discrete discussion. Here, we theoretically propose a valley-piezoelectricity coupling strategy beyond the existing paradigm to realize AVHE and layer Hall effect (LHE) in ferrovalley (FV) systems, and its essential principle can be extended to general valleytronic materials. Through first-principles calculations, we demonstrate that the large polarized electric field of 2.8*106 (1.67*107) V/m can be induced by 0.1% uniaxial strain in FV 2H-LaHF (1T-LaHF) monolayers. In addition, the microscopic mechanism of interlayer antiferromagnetic (AFM) state of 2H-LaHF bilayer is uncovered by the spin Hamiltonian and super-superexchange (SSE) interaction. Our findings pave the way for new explorations of valley Hall-related effect involving piezoelectricity.

Published
2024

3. Spin-layer coupling in altermagnets multilayer: a design principle for spintronics

Author

Tian, Jianke, Li, Jia, Liu, Hengbo, Li, Yan, Liu, Ze, Li, Linyang, Li, Jun, Liu, Guodong, and Shi, Junjie

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

The discovery of collinear symmetric-compensated altermagnets (AM) with intrinsic spin splitting provides a route towards energy-efficient and ultrafast device applications. Here, using first-principles calculations and symmetry analysis, we propose a series of AM Cr2SX (X=O, S, Se) monolayer and explore the spin splitting in Cr2SX multilayer. A general design principle for realizing the spin-layer coupling in odd/even-layer is mapped out based on the comprehensive analysis of spin group symmetry. The spin splitting behavior related with the MzUt, Mz and ML symmetries in AM multilayer can be significantly modulated by magnetic orders, crystal symmetry and external perpendicular gate field (Ez). Due to the spin-compensated bands of sublayers linked by overall Mz and interlayers ML symmetries, the Cr2S2 odd-layer exhibits the unique coexistence of spin splitting and spin degeneracy at high symmetric paths and X/Y valley, respectively. Furthermore, owing to the higher priority of overall ML symmetry compared to interlayers ML symmetry in AM even-layer, the spin-layer coupling of AM multilayer shows strong odd/even-layer dependence. Our work not only offer a new direction for manipulating spin splitting, but also greatly enrich the research on AM monolayer and multilayer.

Published
2024

4. TCDformer-based Momentum Transfer Model for Long-term Sports Prediction

Author

Liu, Hui, Gu, Jiacheng, Huang, Xiyuan, Shi, Junjie, Feng, Tongtong, and He, Ning

Subjects
Computer Science - Machine Learning, Statistics - Applications
Abstract

Accurate sports prediction is a crucial skill for professional coaches, which can assist in developing effective training strategies and scientific competition tactics. Traditional methods often use complex mathematical statistical techniques to boost predictability, but this often is limited by dataset scale and has difficulty handling long-term predictions with variable distributions, notably underperforming when predicting point-set-game multi-level matches. To deal with this challenge, this paper proposes TM2, a TCDformer-based Momentum Transfer Model for long-term sports prediction, which encompasses a momentum encoding module and a prediction module based on momentum transfer. TM2 initially encodes momentum in large-scale unstructured time series using the local linear scaling approximation (LLSA) module. Then it decomposes the reconstructed time series with momentum transfer into trend and seasonal components. The final prediction results are derived from the additive combination of a multilayer perceptron (MLP) for predicting trend components and wavelet attention mechanisms for seasonal components. Comprehensive experimental results show that on the 2023 Wimbledon men's tournament datasets, TM2 significantly surpasses existing sports prediction models in terms of performance, reducing MSE by 61.64% and MAE by 63.64%., Comment: Under reviewing

Published
2024

5. Eliminating Timing Anomalies in Scheduling Periodic Segmented Self-Suspending Tasks with Release Jitter

Author

Lin, Ching-Chi, Günzel, Mario, Shi, Junjie, Seidl, Tristan Taylan, Chen, Kuan-Hsun, and Chen, Jian-Jia

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Ensuring timing guarantees for every individual tasks is critical in real-time systems. Even for periodic tasks, providing timing guarantees for tasks with segmented self-suspending behavior is challenging due to timing anomalies, i.e., the reduction of execution or suspension time of some jobs increases the response time of another job. The release jitter of tasks can add further complexity to the situation, affecting the predictability and timing guarantees of real-time systems. The existing worst-case response time analyses for sporadic self-suspending tasks are only over-approximations and lead to overly pessimistic results. In this work, we address timing anomalies without compromising the worst-case response time (WCRT) analysis when scheduling periodic segmented self-suspending tasks with release jitter. We propose two treatments: segment release time enforcement and segment priority modification, and prove their effectiveness in eliminating timing anomalies. Our evaluation demonstrates that the proposed treatments achieve higher acceptance ratios in terms of schedulability compared to state-of-the-art scheduling algorithms. Additionally, we implement the segment-level fixed-priority scheduling mechanism on RTEMS and verify the validity of our segment priority modification treatment. This work expands our previous conference publication at the 29th IEEE Real-Time and Embedded Technology and Applications Symposium (RTAS 2023), which considers only periodic segmented self-suspending tasks without release jitter., Comment: This is an extension from a previous conference publication at the 29th IEEE Real-Time and Embedded Technology and Applications Symposium (RTAS 2023)

Published
2024

6. PASSION: Towards Effective Incomplete Multi-Modal Medical Image Segmentation with Imbalanced Missing Rates

Author

Shi, Junjie, Shang, Caozhi, Sun, Zhaobin, Yu, Li, Yang, Xin, and Yan, Zengqiang

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

Incomplete multi-modal image segmentation is a fundamental task in medical imaging to refine deployment efficiency when only partial modalities are available. However, the common practice that complete-modality data is visible during model training is far from realistic, as modalities can have imbalanced missing rates in clinical scenarios. In this paper, we, for the first time, formulate such a challenging setting and propose Preference-Aware Self-diStillatION (PASSION) for incomplete multi-modal medical image segmentation under imbalanced missing rates. Specifically, we first construct pixel-wise and semantic-wise self-distillation to balance the optimization objective of each modality. Then, we define relative preference to evaluate the dominance of each modality during training, based on which to design task-wise and gradient-wise regularization to balance the convergence rates of different modalities. Experimental results on two publicly available multi-modal datasets demonstrate the superiority of PASSION against existing approaches for modality balancing. More importantly, PASSION is validated to work as a plug-and-play module for consistent performance improvement across different backbones. Code is available at https://github.com/Jun-Jie-Shi/PASSION., Comment: Accepted by ACM MM 2024

Published
2024

7. Optimization the operation parameters of SDA desulfurization tower by flow coupling chemical reaction model

Author

Mei Dan, Shi Junjie, Zhu Yuzheng, Xu Xuemei, Xing Futang, and Shi Ling

Subjects
spray drying absorber tower, gas-liquid two-phase flow, droplet diameter, desulfurization efficiency, amount of scaling, Chemistry, QD1-999
Abstract

Spray Drying Absorber (SDA) has been widely used for large-scale desulfurization. However, it also has some limitations. For example, the liquid absorbent easily causes scaling, which impedes the contact between the serous fluid and the flue gas and reduces the chemical reaction rate and desulfurization efficiency. This paper establishes the mathematical and physical model of gas and liquid two-phase flow and droplet evaporation and heat transfer in rotary spray desulfurization tower. To study the accumulation and distribution of chemical reaction precipitates in the desulfurization tower and analyze the removal efficiency of sulfur dioxide (SO2) in different atomization diameters, this paper establishes a simulation model concerning the coupling of desulfurization reaction and flow field calculation based on the absorption and reaction mechanism of SO2. Baffle in different widths are set to optimize the internal flow field and balance the distribution of flue gas. By setting baffles of different widths to optimize the flow field in the tower and changing the distribution of flue gas, this model reduces the scaling while ensuring the desulfurization efficiency. The results of the simulation experiment have verified that the droplet with a diameter of 50 μm is the optimal option, which can effectively remove the scaling and ensure that the desulfurizing tower runs in high efficiency and stability. When the width of baffles is 2250 mm, the efficiency of desulfurization exceeds 95%, and the amount of scaling on the desulfurization tower main wall is controlled at the minimum level, which is the optimal option for production.

Published
2020
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8. FedMLP: Federated Multi-Label Medical Image Classification under Task Heterogeneity

Author

Sun, Zhaobin, Wu, Nannan, Shi, Junjie, Yu, Li, Yang, Xin, Cheng, Kwang-Ting, and Yan, Zengqiang

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Cross-silo federated learning (FL) enables decentralized organizations to collaboratively train models while preserving data privacy and has made significant progress in medical image classification. One common assumption is task homogeneity where each client has access to all classes during training. However, in clinical practice, given a multi-label classification task, constrained by the level of medical knowledge and the prevalence of diseases, each institution may diagnose only partial categories, resulting in task heterogeneity. How to pursue effective multi-label medical image classification under task heterogeneity is under-explored. In this paper, we first formulate such a realistic label missing setting in the multi-label FL domain and propose a two-stage method FedMLP to combat class missing from two aspects: pseudo label tagging and global knowledge learning. The former utilizes a warmed-up model to generate class prototypes and select samples with high confidence to supplement missing labels, while the latter uses a global model as a teacher for consistency regularization to prevent forgetting missing class knowledge. Experiments on two publicly-available medical datasets validate the superiority of FedMLP against the state-of-the-art both federated semi-supervised and noisy label learning approaches under task heterogeneity. Code is available at https://github.com/szbonaldo/FedMLP., Comment: Early accepted by MICCAI 2024

Published
2024

14. Preparation of ta-C Film by High-Power Impulse Magnetron Sputtering Technology and Its Performance Modification

Author

FENG Limin, SHI Jingwei, HE Zheqiu, LI Jianzhong, SHI Junjie

Subjects
high power impulse magnetron sputtering, ta-c film, c2h2, film properties, Materials of engineering and construction. Mechanics of materials, TA401-492, Technology
Abstract

The adhesion and friction performance of tetrahedral amorphous carbon film(ta-C film) deposited on the surface of hard alloy affect its application effect in cutting tools and wear-resistant components. In this work, ta-C thin film was prepared based on high power pulse magnetron sputtering technology(HiPIMS), and the modification of ta-C thin film was studied through adjusting C2H2 flow rate. The thickness of the film was observed by SEM, the structure of the film was studied through Raman and XPS, the hardness of the film was characterized through nanoindentation, the adhesion of the film was analyzed by nanoscratches, and the wear resistance of the film was tested through friction and wear tests. Results showed that the introduction of C2H2 gas could effectively improve the structure, hardness, adhesion and wear resistance of ta-C film. Changing the C2H2 flow rate could regulate the performance of ta-C film. As the C2H2 flow rate gradually increased, the various properties of the film showed a trend of first increasing and then decreasing. When the flow rate of C2H2 was 15 cm3/min, the various properties of the film reached excellent results. Specifically, the as-obtained ta-C film had the thickness of 655.9 nm, the hardness of 43.633 GPa and the adhesion force of 19.2 N. Besides, the content of sp3 bond was 70.19%, and the surface of ta-C film was uniform and dense with good performance.

Published
2024
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16. An exponentially shrinking problem

Author

Hussain, Mumtaz and Shi, Junjie

Subjects
Mathematics - Number Theory
Abstract

The Jarn\'ik-Besicovitch theorem is a fundamental result in metric number theory which gives the Hausdorff dimension for limsup sets. We investigate a related problem of estimating the Hausdorff dimension of a liminf set. Let $h>0, \tau\geq 1$, and for any $j\geq 1$ define the integer sequence $q_{j+1}=q_j^h$. We prove the Hausdorff dimension of the set $$\Lambda^\bftheta_d(\tau)=\left\{\xx\in[0, 1)^d: \|q_jx_i-\theta_i\|

Published
2023

17. Binaural Rendering of Ambisonic Signals by Neural Networks

Author

Zhu, Yin, Kong, Qiuqiang, Shi, Junjie, Liu, Shilei, Ye, Xuzhou, Wang, Ju-chiang, and Zhang, Junping

Subjects
Computer Science - Sound, Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Audio and Speech Processing
Abstract

Binaural rendering of ambisonic signals is of broad interest to virtual reality and immersive media. Conventional methods often require manually measured Head-Related Transfer Functions (HRTFs). To address this issue, we collect a paired ambisonic-binaural dataset and propose a deep learning framework in an end-to-end manner. Experimental results show that neural networks outperform the conventional method in objective metrics and achieve comparable subjective metrics. To validate the proposed framework, we experimentally explore different settings of the input features, model structures, output features, and loss functions. Our proposed system achieves an SDR of 7.32 and MOSs of 3.83, 3.58, 3.87, 3.58 in quality, timbre, localization, and immersion dimensions.

Published
2022

18. Neural Sound Field Decomposition with Super-resolution of Sound Direction

Author

Kong, Qiuqiang, Liu, Shilei, Shi, Junjie, Ye, Xuzhou, Cao, Yin, Zhu, Qiaoxi, Xu, Yong, and Wang, Yuxuan

Subjects
Computer Science - Sound, Electrical Engineering and Systems Science - Audio and Speech Processing
Abstract

Sound field decomposition predicts waveforms in arbitrary directions using signals from a limited number of microphones as inputs. Sound field decomposition is fundamental to downstream tasks, including source localization, source separation, and spatial audio reproduction. Conventional sound field decomposition methods such as Ambisonics have limited spatial decomposition resolution. This paper proposes a learning-based Neural Sound field Decomposition (NeSD) framework to allow sound field decomposition with fine spatial direction resolution, using recordings from microphone capsules of a few microphones at arbitrary positions. The inputs of a NeSD system include microphone signals, microphone positions, and queried directions. The outputs of a NeSD include the waveform and the presence probability of a queried position. We model the NeSD systems respectively with different neural networks, including fully connected, time delay, and recurrent neural networks. We show that the NeSD systems outperform conventional Ambisonics and DOANet methods in sound field decomposition and source localization on speech, music, and sound events datasets. Demos are available at https://www.youtube.com/watch?v=0GIr6doj3BQ., Comment: 12 pages

Published
2022

30. Renovation of EdgeCloudSim: An Efficient Discrete-Event Approach

Author

Freymann, Raphael, Shi, Junjie, Chen, Jian-Jia, and Chen, Kuan-Hsun

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Due to the growing popularity of the Internet of Things, edge computing concept has been widely studied to relieve the load on the original cloud and networks while improving the service quality for end-users. To simulate such a complex environment involving edge and cloud computing, EdgeCloudSim has been widely adopted. However, it suffers from certain efficiency and scalability issues due to the ignorance of the deficiency in the originally adopted data structures and maintenance strategies. Specifically, it generates all events at beginning of the simulation and stores unnecessary historical information, both result in unnecessarily high complexity for search operations. In this work, by fixing the mismatches on the concept of discrete-event simulation, we propose enhancement of EdgeCloudSim which improves not only the runtime efficiency of simulation, but also the flexibility and scalability. Through extensive experiments with statistical methods, we show that the enhancement does not affect the expressiveness of simulations while obtaining 2 orders of magnitude speedup, especially when the device count is large., Comment: 8 pages

Published
2021

41. Improving Semiconductor Device Modeling for Electronic Design Automation by Machine Learning Techniques

Author

Wang, Zeheng, Li, Liang, Leon, Ross C. C., Yang, Jinlin, Shi, Junjie, van der Laan, Timothy, and Usman, Muhammad

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

The semiconductors industry benefits greatly from the integration of Machine Learning (ML)-based techniques in Technology Computer-Aided Design (TCAD) methods. The performance of ML models however relies heavily on the quality and quantity of training datasets. They can be particularly difficult to obtain in the semiconductor industry due to the complexity and expense of the device fabrication. In this paper, we propose a self-augmentation strategy for improving ML-based device modeling using variational autoencoder-based techniques. These techniques require a small number of experimental data points and does not rely on TCAD tools. To demonstrate the effectiveness of our approach, we apply it to a deep neural network-based prediction task for the Ohmic resistance value in Gallium Nitride devices. A 70% reduction in mean absolute error when predicting experimental results is achieved. The inherent flexibility of our approach allows easy adaptation to various tasks, thus making it highly relevant to many applications of the semiconductor industry., Comment: Entirely rewrote and reorganized. Updated models

Published
2021
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42. Supporting Multiprocessor Resource Synchronization Protocols in RTEMS

Author

Shi, Junjie, Pham, Jan Duy Thien, Münch, Malte, Hafemeister, Jan Viktor, Chen, Jian-Jia, and Chen, Kuan-Hsun

Subjects
Computer Science - Operating Systems
Abstract

When considering recurrent tasks in real-time systems, concurrent accesses to shared resources, can cause race conditions or data corruptions. Such a problem has been extensively studied since the 1990s, and numerous resource synchronization protocols have been developed for both uni-processor and multiprocessor real-time systems, with the assumption that the implementation overheads are negligible. However, in practice, the implementation overheads may impact the performance of different protocols depending upon the practiced scenarios, e.g., resources are accessed locally or remotely, and tasks spin or suspend themselves when the requested resources are not available. In this paper, to show the applicability of different protocols in real-world systems, we detail the implementation of several state-of-the-art multiprocessor resource synchronization protocols in RTEMS. To study the impact of the implementation overheads, we deploy these implemented protocols on a real platform with synthetic task set. The measured results illustrate that the developed resource synchronization protocols in RTEMS are comparable to the existed protocol, i.e., MrsP., Comment: 6 pages, 5 figures, presented in 16th annual workshop on Operating Systems Platforms for Embedded Real-Time applications (OSPERT'22)

Published
2021

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