Your search keyword '"Fan, Yingchun"' showing total 6 results

1. MFISN: Modality Fuzzy Information Separation Network for Disease Classification

Author

Nan, Fengtao, Pu, Bin, Pan, Jiayi, Fan, Yingchun, Yang, Jiewen, Dong, Xingbo, Xu, Zhaozhao, Wang, Shuihua, Nan, Fengtao, Pu, Bin, Pan, Jiayi, Fan, Yingchun, Yang, Jiewen, Dong, Xingbo, Xu, Zhaozhao, and Wang, Shuihua

Abstract

Most of the previous machine learning-based models for multi-modal medical diagnosis, primarily designed for unimodal images, usually do not fully leverage the potential of multimodal medical images, leading to limited classification accuracy. These conventional methods typically focus only on the intermodality common information, neglecting the intra-modality specific information and assuming that the common information is more effective in disease diagnosis. Moreover, they do not adequately address the impact of fuzzy information between different medical imaging modalities on diagnostic results. To this end, we propose a Modality Fuzzy Information Separation Network for disease classification, which extracts both common and specific information from fuzzy information to construct a comprehensive representation of multi-modal medical images. Specifically, we extract modality invariant features as common information by explicitly modeling and maximizing loss constraints on mutual information. For specific information extraction, a constraint on feature space independence between specific and common information is imposed on each modality. Above two steps, we concatenate common information and specific information to construct a comprehensive multi-modal representation for separating fuzzy information. Finally, we purposely design a decoder network to reconstruct medical images from uni-modal specific information and common information to demonstrate the effectiveness of the modality fuzzy information separation network. We conducted a validation of the proposed method's performance in classifying cardiomegaly, pneumothorax, edema, and skin disease. The experimental results substantiate the effectiveness of our proposed approach. IEEE

Published

2024

2. Liquid CO2 phase transition fracturing technology and its application in enhancing gas drainage of coal mines

Author

Fan, Yingchun, primary, Qin, Botao, additional, Zhou, Qun, additional, Shi, Quanlin, additional, Ma, Dong, additional, and Wu, Jiahao, additional

Published

2020

3. Semantic SLAM With More Accurate Point Cloud Map in Dynamic Environments

Author

Fan, Yingchun, primary, Zhang, Qichi, additional, Liu, Shaofeng, additional, Tang, Yuliang, additional, Jing, Xin, additional, Yao, Jintao, additional, and Han, Hong, additional

Published

2020

4. Cross-Modal Retrieval via Similarity-Preserving Learning and Semantic Average Embedding

Author

Zhi, Tao, primary, Fan, Yingchun, additional, and Han, Hong, additional

Published

2020

5. Liquid CO2 phase transition fracturing technology and its application in enhancing gas drainage of coal mines.

Author

Fan, Yingchun, Qin, Botao, Zhou, Qun, Shi, Quanlin, Ma, Dong, and Wu, Jiahao

Subjects

*MINE drainage, *PHASE transitions, *COAL gas, *LIQUEFIED gases, *ROCK deformation, *COAL mining

Abstract

Liquid CO2 phase transition fracturing (LCO2-PTF) is an effective and economical technology used to improve the permeability of rock and coal. In this study, the working mechanisms of LCO2-PTF were analysed and relevant equipment was designed to develop and promote the application of this technology. It utilized phase transition equipment (PTE) consisting of a liquid gas container, control unit for the current and gas volume, heating tube, and other components. LCO2 blasting experiments were conducted in an airtight container to investigate the released energy, pressure, and other technical parameters. The application of LCO2-PTF for enhancing gas drainage in coal mines was then evaluated. The results of a blasting experiment showed a maximum energy of 947.12 kJ and revealed that the releasing pressure could be easily changed by varying the plate and heat tube. The releasing pressure remained unchanged within an initial distance and then decreased exponentially. The blasting products were gaseous CO2 and water vapor, with no sparks or flames. The surface temperature of the PTE ranged from 269.32 to 277.96 K. Application of LCO2-PTF in coal mines with low permeability showed gas drainage 3.38 times higher than that achieved with conventional technologies, with methane concentration increasing from 55 to 89%. The attenuation coefficient of gas emissions dropped by 94% and the gas permeability coefficient of the coal body increased more than 23 times after fracturing. The shockwave of the high-pressure gas promoted the development and extension of cracks. The influence radius of the pre-cracking coal seam was 8.1 m, which is 6.75 times that of the original coal seam. The experimental results and the engineering applications indicate that LCO2-PTF is a safe and effective technology to enhance gas drainage in coal mines. [ABSTRACT FROM AUTHOR]

Published

2020

6. EXPERIMENTAL STUDY OF EFFICIENT WIRELESS POWER TRANSFER SYSTEM INTEGRATING WITH HIGHLY SUB-WAVELENGTH METAMATERIALS

Author

Fan, Yingchun, primary, Li, Long, additional, Yu, Shixing, additional, Zhu, Cheng, additional, and Liang, Chang-Hong, additional

Published

2013