澳门·威尼斯人(Venetian)官方网站

       主要从事热辐射辐射传输建模及应用研究，长期从事热红外澳门·威斯尼斯网站建模和应用研究。将分形思想引入辐射传输建模，解决了宏观地表与微观结构特征同步模拟难题：模型用于国产多颗传感器仿真论证、被法国SPARSE系统采纳；揭示了陆表红外辐射时-空-角变化规律，发展了光学/红外协同的角度校正算法：被国家气候中心温度产品采纳，可降低60%以上的角度偏差；引入贝叶斯优化理论提升了热红外混合像元弱信息提取能力，实现了组分温度产品业务化生产：产品可显著降低蒸散发估算不确定性（15%）。发表SCI论文40余篇，第一及通讯作者论文19篇，高被引文章2篇；获得中科院院长“特别”奖，后续研究获得博士后创新人才支持计划、空天院“未来之星”、北京市科技新星等项目资助；担任中国澳门·威斯尼斯网站应用协会定量澳门·威斯尼斯网站专委会青年委员、中国气象服务协会人工智能委员会委员。 

工作经历：

2013.09 - 2018.07，中国科学院澳门·威斯尼斯网站与数字地球研究所，博士；

2019.01-2022.04，中国科学院空天信息创新研究院，特别研究助理；

2022.04-2023.03，中国科学院空天信息创新研究院，助理研究员；

2023.03-至今，中国科学院空天信息创新研究院，副研究员。

2024.09 – 2027.09，北京市科技新星项目，项目负责人；

2023.01 – 2025.12，空天院“未来之星”，项目负责人；

2023.01 - 2026.12，国家自然科学基金面上基金：考虑能量平衡过程的山区热红外辐射传输建模与组分温度反演，项目负责人

2020.01 - 2022.12，国家自然科学基金青年基金：离散森林场景组分温度模拟与热辐射方向性建模，项目负责人

2019.01 - 2020.12，博士后基金（一等）：基于贝叶斯模型平均方法的组分温度集成算法研究，项目负责人

2019.01 - 2020.12，博士后创新人才支持计划：复杂场景热辐射方向性建模及卫星尺度组分温度反演研究，项目负责人

2020-09 - 2023-12, 中国科学院仪器设备改造项目: 植被冠层观测传感器网络节点升级改造, 项目负责人。

2018年，中国科学院院长“特别”奖；

2018年，中国科学院“环保奖”；

2018年，北京市优秀毕业生；

2019年，博士后创新人才支持计划； 

2022年，中国科学院空天院“优秀职工”；

2023年，中国科学院空天院“未来之星”；

2024年，中国科学院空天院“优秀党员”。

文章

1.Bian, Z., Zhong, S., Roujean, J.L., Liu, X., Duan, S., Li, H., Cao, B., Li, R., Du, Y., Xiao, Q., & Liu, Q. (2024). An integrated method for angular and temporal reconstruction of land surface temperatures. Remote Sensing of Environment, 313, 114357

2.Fan, T., Wen, J., Jiao, Z., Bian, Z., Zhong, S., Zhu, W., Cao, B., Li, H., Du, Y., Xiao, Q., & Liu, Q. (2024). Modeling the Topographic Effect on Directional Anisotropies of Land Surface Temperature from Thermal Remote Sensing. Journal of Remote Sensing, 4, 0226

3.Zhong, S., Li, H., Bian, Z., Liu, Q., Du, Y., Cao, B., & Xiao, Q. (2024). A Consistency Analysis of Land Surface Temperatures Retrieved From Several Polar-Orbiting Satellite Observations. IEEE Transactions on Geoscience and Remote Sensing, 62, 1-16

4.Bian, Z., Fan, T., Roujean, J.L., Wang, D., Irvine, M., Wu, S., Cao, B., Li, H., Du, Y., Xiao, Q., & Liu, Q. (2024). An analytical urban temperature model with building heterogeneity using geometric optical theory. Remote Sensing of Environment, 301, 113948

5.Bian, Z., Roujean, J.L., Fan, T., Dong, Y., Hu, T., Cao, B., Li, H., Du, Y., Xiao, Q., & Liu, Q. (2023). An angular normalization method for temperature vegetation dryness index (TVDI) in monitoring agricultural drought. Remote Sensing of Environment, 284, 113330

6.Bian, Z., Qi, J., Gastellu-Etchegorry, J.-P., Roujean, J.-L., Cao, B., Li, H., Du, Y., Xiao, Q., & Liu, Q. (2022a). A GPU-Based Solution for Ray Tracing 3-D Radiative Transfer Model for Optical and Thermal Images. IEEE Geoscience Remote Sensing Letters, 19, 1-5

7.Bian, Z., Wu, S., Roujean, J.-L., Cao, B., Li, H., Yin, G., Du, Y., Xiao, Q., & Liu, Q. (2022b). A TIR forest reflectance and transmittance (FRT) model for directional temperatures with structural and thermal stratification. Remote Sensing of Environment, 268, 112749

8.Bian, Z., Roujean, J.-L., Cao, B., Du, Y., Li, H., Gamet, P., Fang, J., Xiao, Q., & Liu, Q. (2021). Modeling the directional anisotropy of fine-scale TIR emissions over tree and crop canopies based on UAV measurements. Remote Sensing of Environment, 252, 112150

9.Bian, Z., Cao, B., Li, H., Du, Y., Fan, W., Xiao, Q., & Liu, Q. (2020a). The Effects of Tree Trunks on the Directional Emissivity and Brightness Temperatures of a Leaf-Off Forest Using a Geometric Optical Model. IEEE Transactions on Geoscience and Remote Sensing, 1-17

10.Bian, Z., Roujean, J.L., Lagouarde, J.P., Cao, B., Li, H., Du, Y., Liu, Q., Xiao, Q., & Liu, Q. (2020c). A semi-empirical approach for modeling the vegetation thermal infrared directional anisotropy of canopies based on using vegetation indices. ISPRS Journal of Photogrammetry and Remote Sensing, 160, 136-148

11.Bian, Z., Li, H., Göttsche, F.M., Li, R., Du, Y., Ren, H., Cao, B., Xiao, Q., & Liu, Q. (2020b). Retrieving Soil and Vegetation Temperatures From Dual-Angle and Multipixel Satellite Observations. IEEE Journal of Selected Topics in Applied Earth Observations Remote Sensing, 13, 5536-5549

12.Bian, Z., Cao, B., Li, H., Du, Y., Lagouarde, J.-P., Xiao, Q., & Liu, Q. (2018b). An Analytical Four-component Directional Brightness Temperature Model for Crop and Forest Canopies. Remote Sensing of Environment, 209, 731-746

13.Bian, Z., Cao, B., Li, H., Du, Y., Huang, H., Xiao, Q., & Liu, Q. (2018a). Modeling the Distributions of Brightness Temperatures of a Cropland Study Area Using a Model that Combines Fast Radiosity and Energy Budget Methods. Remote Sensing, 10, 736

14.Bian, Z., Du, Y., Li, H., Cao, B., Huang, H., Xiao, Q., & Liu, Q. (2017b). Modeling the Temporal Variability of Thermal Emissions From Row-Planted Scenes Using a Radiosity and Energy Budget Method. IEEE Transactions on Geoscience and Remote Sensing, 55, 6010-6026

15.Bian, Z., Cao, B., Li, H., Du, Y., Song, L., Fan, W., Xiao, Q., & Liu, Q. (2017a). A Robust Inversion Algorithm for Surface Leaf and Soil Temperatures Using the Vegetation Clumping Index. Remote Sensing, 9, 780

16.Bian, Z., Xiao, Q., Cao, B., Du, Y., Li, H., Wang, H., Liu, Q., & Liu, Q. (2016). Retrieval of Leaf, Sunlit Soil, and Shaded Soil Component Temperatures Using Airborne Thermal Infrared Multiangle Observations. IEEE Transactions on Geoscience and Remote Sensing, 54, 4660-4671

17.Bian, Z., Lu, Y., Du, Y., Zhao, W., Cao, B., Hu, T., Li, R., Li, H., Xiao, Q., & Liu, Q. (2022a). Comparison between Physical and Empirical Methods for Simulating Surface Brightness Temperature Time Series. In, Remote Sensing

 

专利

1.一种三维复杂地表叶面积指数反演方法及系统，卞尊健;李嘉昕;范腾远;曹彪;历华;杜永明;肖青 柳钦火，ZL 2021 1 0796019.1

2.一种三维复杂地表澳门·威斯尼斯网站光学特征反演方法及系统，：卞尊健;范腾远;李嘉昕;曹彪;历华;杜永明;肖青 柳钦火，ZL 2021 1 0794684.7

3.基于辐射度的地表高分辨率光谱信息澳门·威斯尼斯网站反演方法，卞尊健;李嘉昕;范腾远;曹彪;历华;杜永明;肖青 柳钦火， ZL 2021 1 0107797.5

4.基于贝叶斯模型平均方法的地表组分温度多算法集成算法，卞尊健;历华;杜永明;曹彪，肖青 柳钦火, ZL 2020 1 1096827.9