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Your search keyword '"Jin, Shichao"' showing total 236 results
Start Over Author "Jin, Shichao" Publication Year Range Last 50 years
236 results on '"Jin, Shichao"'

1. StoManager1: An Enhanced, Automated, and High-throughput Tool to Measure Leaf Stomata and Guard Cell Metrics Using Empirical and Theoretical Algorithms

Author

Wang, Jiaxin, Renninger, Heidi J., Ma, Qin, and Jin, Shichao

Subjects
Quantitative Biology - Tissues and Organs
Abstract

Automated stomata detection and measuring are vital for understanding plant physiological performance and ecological functioning in global water and carbon cycles. Current methods are laborious, time-consuming, prone to bias, and limited in scale. We developed StoManager1, a high-throughput tool utilizing empirical and theoretical algorithms and convolutional neural networks to automatically detect, count, and measure over 30 stomatal and guard cell metrics, including stomata and guard cell area, length, width, and orientation, stomatal evenness, divergence, and aggregation index. These metrics, combined with leaf functional traits, explained 78% and 93% of productivity and intrinsic water use efficiency (iWUE) variances in hardwoods, making them significant factors in leaf physiology and tree growth. StoManager1 demonstrates exceptional precision and recall (mAP@0.5 over 0.993), effectively capturing diverse stomatal properties across various species. StoManager1facilitates the automation of measuring leaf stomata, enabling broader exploration of stomatal control in plant growth and adaptation to environmental stress and climate change. This has implications for global gross primary productivity (GPP) modeling and estimation, as integrating stomatal metrics can enhance comprehension and predictions of plant growth and resource usage worldwide. StoManager1's source code and an online demonstration are available on GitHub (https://github.com/JiaxinWang123/StoManager.git), along with a user-friendly Windows application on Zenodo (https://doi.org/10.5281/zenodo.7686022)., Comment: 15 pages, 6 figures, 3 tables

Published
2023
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3. Multibeam Satellite Communications with Energy Efficiency Optimization

Author

Qi, Chenhao, Yang, Yang, Ding, Rui, Jin, Shichao, and Liu, Dunge

Subjects
Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing
Abstract

Energy efficiency (EE) is an important aspect of satellite communications. Different with the existing algorithms that typically use the first-order Taylor lower bound approximation to convert non-convex EE maximization (EEM) problems into convex ones, in this letter a two-step quadratic transformation method is presented. In the first step, the fractional form of the achievable rate over the total power consumption is converted into a non-fractional form based on quadratic transformation. In the second step, the fractional form of the signal power over the interference-and-noise power is further converted into a non-fractional form, still based on quadratic transformation. After the two-step quadratic transformation, the original EEM problem is converted into an equivalent convex one. Then an alternating optimization algorithm is presented to solve it by iteratively performing two stages until a stop condition is satisfied. Simulation results show that the presented algorithm can fast converge and its performance is better than that of the sequential convex approximation algorithm and the multibeam interference mitigation algorithm.

Published
2022

12. Lidar Boosts 3D Ecological Observations and Modeling

Author

Guo, Qinghua, Su, Yanjun, Hu, Tianyu, Guan, Hongcan, Jin, Shichao, Zhang, Jing, Zhao, Xiaoxia, Xu, Kexin, Wei, Dengjie, Kelly, Maggi, and Coops, Nicholas C

Subjects
Laser radar, Vegetation mapping, Three-dimensional displays, Surface emitting lasers, Optical sensors, Ecosystems, Optical reflection, Correlation, Analytical models, Radar polarimetry, Clutter, Speckle, Synthetic aperture radar, Imaging
Abstract

The advent of lidar has revolutionized the way we observe and measure vegetation structure from the ground and from above and represents a major advance toward the quantification of 3D ecological observations. Developments in lidar hardware systems and data processing algorithms have greatly improved the accessibility and ease of use of lidar observations in ecological studies. A wide range of studies has been devoted to accurately measuring and modeling vegetation structural and functional attributes from lidar data across a range of spatial scales (from individual organs to global scales) and ecosystem types (e.g., forest, agricultural, grassland, and urban ecosystems).

Published
2021

18. Canopy and Terrain Interactions Affecting Snowpack Spatial Patterns in the Sierra Nevada of California

Author

Zheng, Zeshi, Ma, Qin, Jin, Shichao, Su, Yanjun, Guo, Qinghua, and Bales, Roger C

Subjects
Life on Land, Physical Geography and Environmental Geoscience, Civil Engineering, Environmental Engineering
Abstract

Airborne light detection and ranging is an emerging measurement tool for snowpack estimation, and data are now emerging to better assess multiscale snow depth patterns. We used airborne light detection and ranging measurements from four sites in the southern Sierra Nevada to determine how snow depth varies with canopy structure and the interactions between canopies and terrain. We processed the point clouds into snow depth rasters at 0.5×0.5-m2 resolution and performed statistical analysis on the processed snow depth data, terrain attributes, and vegetation attributes, including the individual tree bole locations, canopy crown area, and canopy height. We studied the snow depth at such a fine scale due in part to the spatial heterogeneity introduced by canopy interception and enhanced melting caused by tree trunks in forested areas. We found that the dominant direction of a tree well, the area around the tree bole that has shallower snowpack, is correlated with the local aspect of the terrain, and the gradient of the snow surface in a tree well is correlated with the tree's crown area. The regression-tree based XGBoost model was fitted with the topographic variables and canopy variables, and about 71% of snow depth variability can be explained by the model.

Published
2019

27. An updated Vegetation Map of China (1:1000000)

Author

Su, Yanjun, Guo, Qinghua, Hu, Tianyu, Guan, Hongcan, Jin, Shichao, An, Shazhou, Chen, Xuelin, Guo, Ke, Hao, Zhanqing, Hu, Yuanman, Huang, Yongmei, Jiang, Mingxi, Li, Jiaxiang, Li, Zhenji, Li, Xiankun, Li, Xiaowei, Liang, Cunzhu, Liu, Renlin, Liu, Qing, Ni, Hongwei, Peng, Shaolin, Shen, Zehao, Tang, Zhiyao, Tian, Xingjun, Wang, Xihua, Wang, Renqing, Xie, Zongqiang, Xie, Yingzhong, Xu, Xiaoniu, Yang, Xiaobo, Yang, Yongchuan, Yu, Lifei, Yue, Ming, Zhang, Feng, and Ma, Keping

Published
2020
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31. Design of a Low-Sidelobe Millimeter-Wave Microstrip Array Antenna

Author

Wang, Jing, primary, Jin, Shichao, additional, Liu, Dunge, additional, Yang, Yuqian, additional, Chen, Tianfu, additional, Fei, Chunjiao, additional, Mei, Chenyu, additional, Zhou, Bo, additional, Huang, Jun, additional, Liu, Lipeng, additional, Su, Jinhuai, additional, Wang, Chenyu, additional, and Sun, Jiaxing, additional

Published
2023
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36. Efficient classification using parallel and scalable compressed model and Its application on intrusion detection

Author

Chen, Tieming, Zhang, Xu, Jin, Shichao, and Kim, Okhee

Subjects
Computer Science - Learning, Computer Science - Cryptography and Security
Abstract

In order to achieve high efficiency of classification in intrusion detection, a compressed model is proposed in this paper which combines horizontal compression with vertical compression. OneR is utilized as horizontal com-pression for attribute reduction, and affinity propagation is employed as vertical compression to select small representative exemplars from large training data. As to be able to computationally compress the larger volume of training data with scalability, MapReduce based parallelization approach is then implemented and evaluated for each step of the model compression process abovementioned, on which common but efficient classification methods can be directly used. Experimental application study on two publicly available datasets of intrusion detection, KDD99 and CMDC2012, demonstrates that the classification using the compressed model proposed can effectively speed up the detection procedure at up to 184 times, most importantly at the cost of a minimal accuracy difference with less than 1% on average.

Published
2014
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50. Additional file 1 of Field-measured canopy height may not be as accurate and heritable as believed: evidence from advanced 3D sensing

Author

Zang, Jingrong, Jin, Shichao, Zhang, Songyin, Li, Qing, Mu, Yue, Li, Ziyu, Li, Shaochen, Wang, Xiao, Su, Yanjun, and Jiang, Dong

Abstract

Additional file 1: Fig. S1. Canopy height correlations between the field measurement and DAP estimates at different flight heights. (a), (b), (c), and (d) are the results of flight height at 10, 20, 30, and 40m, respectively. The solid line represents the fitted line, and the dashed line represents the 1:1 line. The color bar shows the kernel density value of the point distribution, and the green to yellow represents the increase in kernel density. Fig. S2. (a) RMSE, (b) RMSE%, (c) Bias, and (d) Bias% between field measured height (FM) and different height quantiles (Hmax and H99) derived from the different 3D point cloud, including TLS, BLS, GLS, and DAP. The green triangle, blue diamond, dark orange circle, and baby blue square represent TLS vs. FM, BLS vs. FM, GLS vs. FM, and DAP vs. FM, respectively. Fig. S3. Correlations of cross-comparisons between different 3D sensing data estimated canopy height (CH) at four CH subgroups. (a), (b), (c), (d), (e), and (f) are comparisons of TLS vs. BLS, BLS vs. DAP, DAP vs. TLS, TLS vs. GLS, BLS vs. GLS, and DAP vs. GLS, respectively. The green triangle, blue diamond, orange circle, and light blue square represent the CH1, CH2, CH3, and CH4 groups, respectively. The solid line represents the fitted line, and the dashed line represents the 1:1 reference. Fig. S4. Correlations of cross-comparisons between different 3D sensing data estimated canopy height (CH) at four leaf area index (LAI) groups. (a), (b), (c), (d), (e), and (f) are comparisons of TLS vs. BLS, BLS vs. DAP, DAP vs. TLS, TLS vs. GLS, BLS vs. GLS, and DAP vs. GLS, respectively. The green triangle, blue diamond, orange circle, and light blue square represent the LAI1, LAI2, LAI3, and LAI4 groups, respectively. The solid line represents the fitted line, and the dashed line represents the 1:1 reference line. Fig. S5. Correlations of cross-comparisons between different 3D sensing data estimated canopy height (CH) at four growth stages (GS) groups. (a), (b), (c), (d), (e), and (f) are comparisons of TLS vs. BLS, BLS vs. DAP, DAP vs. TLS, TLS vs. GLS, BLS vs. GLS, and DAP vs. GLS, respectively. The green triangle, blue diamond, orange circle, and light blue square represent the jointing, heading, flowering, and maturity stages, respectively. The solid line represents the fitted line, and the dashed line represents the 1:1 reference line. Fig. S6. Correlations between GLS predicted datasets (including the measured canopy height over 0.82m) and other datasets. (a), (b), (c), and (d) respectively represent GLS vs. FM, TLS vs. GLS, BLS vs. GLS, and DAP vs. GLS. The solid line represents the fitted line, and the dashed line represents the 1:1 line. The color bar shows the kernel density value of the point distribution, and the green to yellow represents the increase in kernel density. Table S1. The performance of canopy height measurement with TLS, BLS, GLS, and DAP systems. R2, r, and RMSE are the coefficient of determination, correlation coefficient, and root mean square error, respectively. – represents the performance metric that is not available.

Published
2023
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