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姓名	李?lèi)?ài)農	性別	男
職務(wù)	數字山地與遙感應用中心主任	職稱(chēng)	研究員
通訊地址	成都市人民南路四段九號，中國科學(xué)院成都山地災害與環(huán)境研究所
郵政編碼	610041	電子郵件	ainongli@imde.ac.cn

簡(jiǎn)歷:

李?lèi)?ài)農，男（1974-），漢族，中共黨員，理學(xué)博士，研究員（二級），博士生導師，國家重點(diǎn)研發(fā)計劃項目首席科學(xué)家。數字山地與遙感應用中心主任、數字山地黨支部書(shū)記、王朗山地遙感四川省野外觀(guān)測研究站站長(cháng)；兼任中國科學(xué)院無(wú)人機應用與管控研究中心副主任、《遙感學(xué)報》副主編、國際數字地球學(xué)會(huì )中國國家委員會(huì )(CNISDE)數字山地專(zhuān)業(yè)委員會(huì )主任、全國科技創(chuàng )新領(lǐng)軍人才聯(lián)盟理事等。曾任所團委書(shū)記（2007-2010）、山區發(fā)展與數字山地黨支部書(shū)記（2015-2017）。

1997年畢業(yè)于西南交通大學(xué)攝影測量與遙感專(zhuān)業(yè)；2003年、2007年在中國科學(xué)院大學(xué)獲得碩士和博士學(xué)位；2005年、2008-2010年先后赴美國馬里蘭大學(xué)地理系從事訪(fǎng)問(wèn)學(xué)習與博士后研究。先后承擔國家重點(diǎn)研發(fā)計劃項目、國家自然科學(xué)基金重點(diǎn)項目、中科院戰略性先導科技專(zhuān)項、國際合作重點(diǎn)項目、環(huán)保部“生態(tài)十年”專(zhuān)項等科研任務(wù)20余項。在國內外主流學(xué)術(shù)期刊上發(fā)表論文238篇，其中SCI/TOP論文101/52篇，出版《山地遙感》、《山地土地利用/覆被遙感監測》、《Land cover change and its eco-environmental responses in Nepal》等專(zhuān)著(zhù)5部、《中國數字山地圖》等地圖作品2套；獲授權國家發(fā)明專(zhuān)利、軟件著(zhù)作權15項。

研究領(lǐng)域:
	山地定量遙感理論、方法及其綜合應用研究。

社會(huì )任職:

獲獎及榮譽(yù):

四川省學(xué)術(shù)和技術(shù)帶頭人（2021）,國家高層次人才計劃入選者（2018）、科技部中青年科技創(chuàng )新領(lǐng)軍人才（2016）、四川省引進(jìn)海外高層次人才（2012）、中科院人才計劃（A類(lèi)）入選者（2010）；獲中國科學(xué)院優(yōu)秀導師獎、愛(ài)思唯爾國際“擎天神”獎、國際環(huán)境信息協(xié)會(huì )“最佳論文”獎、全國青年地理科技獎、中國自然資源學(xué)會(huì )青年科技獎、中國測繪地理信息學(xué)會(huì )科學(xué)技術(shù)獎、四川省青年科技獎等獎項。

代表論著(zhù):

[1] 李?lèi)?ài)農, 邊金虎, 靳華安, 等. 山地遙感[M]. 北京: 科學(xué)出版社, 2016.

[2] 李?lèi)?ài)農, 雷光斌, 邊金虎, 等.山地土地利用/覆被遙感監測[M]. 北京:科學(xué)出版社, 2021.

[3] Li Ainong, Deng Wei, Zhao Wei. Land Cover Change and Its Eco-Environmental Response in Nepal[M]. Singapore, Springer-Nature, 2017.

[4] 鄧偉, 李?lèi)?ài)農(副主編), 南希, 陳昱, 廖克. 中國數字山地圖[M]. 北京: 中國地圖出版社, 2015.

[5] 鄧偉, 李?lèi)?ài)農(副主編). 南亞地理—資源與環(huán)境[M].成都:四川科技出版社,2017.

[6] 李?lèi)?ài)農^*, 邊金虎, 張正健, 等. 山地遙感主要研究進(jìn)展、發(fā)展機遇與挑戰[J]. 遙感學(xué)報, 2016, 20(5): 1199-1215.

[7] 李?lèi)?ài)農^*, 邊金虎, 張正健, 等. 若爾蓋高原區域碳收支參量多尺度遙感綜合觀(guān)測試驗：科學(xué)目標與試驗設計[J]. 遙感技術(shù)與應用, 2016, 31(3): 405-416.

[8] 李?lèi)?ài)農^*, 尹高飛, 靳華安, 等. 山地地表生態(tài)參量遙感反演的理論、方法與問(wèn)題[J]. 遙感技術(shù)與應用, 2016, 31(1): 1-11.

[9] 李?lèi)?ài)農^*, 邊金虎, 尹高飛, 等. 山地典型生態(tài)參量遙感反演建模及其時(shí)空表征能力研究[J]. 地球科學(xué)進(jìn)展, 2018, 33(2): 141-151.

[10] 李?lèi)?ài)農^*, 尹高飛, 張正健, 等. 基于站點(diǎn)的生物多樣性星空地一體化遙感監測[J]. 生物多樣性, 2018,26(08): 819-827.

[11] 李?lèi)?ài)農^*, 張正健, 雷光斌, 等. 四川蘆山“4·20”強烈地震核心區災損遙感快速調查與評估[J]. 自然災害學(xué)報, 2013, 22(6): 8-18.

[12] 李?lèi)?ài)農^*, 南希, 張正健, 等. 茂縣“6.24”特大高位遠程崩滑災害遙感回溯與應急調查[J]. 自然災害學(xué)報, 2018, 27(2):1-9.

[13] 李?lèi)?ài)農^*, 南希, 張正健, 等. 特大山地災害遙感應急響應調查方法與案例[J]. 中國減災, 2018,(19): 42-45.

[14] Hu, G. and Li, A.^*. SGOT: A Simplified Geometric-Optical Model for Crown Scene Components Modeling over Rugged Terrain [J]. Remote Sensing , 2022, 14(8): 1821.

[15] Naboureh, A., Li, A.^*, Ebrahimy, H., et al. Assessing the effects of irrigated agricultural expansions on Lake Urmia using multi-decadal Landsat imagery and a sample migration technique within Google Earth Engine [J]. International Journal of Applied Earth Observation and Geoinformation, 2021, 105: 102607.

[16] Jin, Y., Li, A.^*, Bian, J., et al. Spatiotemporal analysis of ecological vulnerability along Bangladesh-China-India-Myanmar economic corridor through a grid level prototype model [J]. Ecological Indicators, 2021, 120: 106933.

[17] Xie, X. and Li, A.^*. An Adjusted Two-Leaf Light Use Efficiency Model for Improving GPP Simulations Over Mountainous Areas [J]. Journal of Geophysical Research: Atmospheres, 2021, 125(13): e2019JD031702.

[18] Xie, X. and Li, A.^*. Development of a topographic-corrected temperature and greenness model (TG) for improving GPP estimation over mountainous areas [J]. Agricultural and Forest Meteorology, 2020, 295: 108193.

[19] Bian, J., Li, A.^*, Lei, G., et al. Global high-resolution mountain green cover index mapping based on Landsat images and Google Earth Engine [J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2020, 162: 63-76.

[20] Lei, G., Li, A.^*, Bian, J., et al. OIC-MCE: A Practical Land Cover Mapping Approach for Limited Samples Based on Multiple Classifier Ensemble and Iterative Classification [J]. Remote Sensing, 2020, 12(6): 987.

[21] Jin, H., Li, A.^*, Xu, W., et al. Evaluation of topographic effects on multiscale leaf area index estimation using remotely sensed observations from multiple sensors [J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2019, 154: 176-188.

[22] Jin, H., Li, A.^*, Yin, G., et al. A Multiscale Assimilation Approach to Improve Fine-Resolution Leaf Area Index Dynamics [J]. IEEE Transactions on Geoscience and Remote Sensing, 2019, 57(10): 8153-8168.

[23] Tan, J., Li, A.^*, Lei, G., et al. A novel and direct ecological risk assessment index for environmental degradation based on response curve approach and remotely sensed data [J]. Ecological Indicators, 2019, 98:783-793.

[24] Tan, J., Li, A.^*, Lei, G., et al. A SD-MaxEnt-CA model for simulating the landscape dynamic of natural ecosystem by considering socio-economic and natural impacts [J]. Ecological Modelling, 2019, 410: 108783.

[25] Li, A.^*, Deng, W., Zhao, W., et al. A geo-spatial database about the eco-environment and its key issues in South Asia [J]. Big Earth Data, 2018, 2(3): 298-319.

[26] Xie, X., Li, A.^*, Yin, G., et al. Derivation of temporally continuous leaf maximum carboxylation rate (Vcmax) from the sunlit leaf gross photosynthesis productivity through combining BEPS model with light response curve at tower flux sites [J]. Agricultural and Forest Meteorology, 2018, 259:82-94,

[27] Bian, J., Li, A.^*, Huang, C., et al. A self-adaptive approach for producing clear-sky composites from VIIRS surface reflectance datasets [J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2018, 144: 189-201.

[28] Zhao, W., Sánchez, N., Lu H. and Li, A.^*. A spatial downscaling approach for the SMAP passive surface soil moisture product using random forest regression [J]. Journal of Hydrology, 2018, 563: 1009-1024.

[29] Yin, G., Li, A.^*, Wu, S., et al. PLC: A simple and semi-physical topographic correction method for vegetation canopies based on path length correction [J]. Remote Sensing of Environment, 2018, 215:184-198.

[30] Bian, J., Li, A.^*, Zhang, Z., et al. Monitoring fractional green vegetation cover dynamics over a seasonally inundated alpine wetland using dense time series HJ-1 A/B constellation images and an adaptive endmember selection LSMM model [J]. Remote Sensing of Environment, 2017, 197: 98-114.

[31] Yin, G., LI, A.^*, Zhao, W., et al. Modeling Canopy Reflectance Over Sloping Terrain Based on Path Length Correction [J]. IEEE Transactions on Geoscience and Remote Sensing, 2017, 55(8): 4597 - 4609.

[32] Yin, G., Li, A.^*, Jin, H., et al. Derivation of temporally continuous LAI reference maps through combining the LAINet observation system with CACAO [J]. Agricultural and Forest Meteorology, 2017, 233(2017): 209-221.

[33] Zhao, W., Li, A.^*, Zhao, T. Potential of Estimating Surface Soil Moisture With the Triangle-Based Empirical Relationship Model [J]. IEEE Transactions on Geoscience & Remote Sensing, 2017, 55(11): 6494-6504.

[34] Zhao, W., Li, A.^*, Jin, H., et al. Performance Evaluation of the Triangle-Based Empirical Soil Moisture Relationship Models Based on Landsat-5 TM Data and In Situ Measurements [J]. IEEE Transactions on Geoscience and Remote Sensing, 2017, 55(5): 2632-2645.

[35] Tan, J., Li, A.^*, Lei, G., et al. Preliminary assessment of ecosystem risk based on IUCN criteria in a hierarchy of spatial domains: A case study in Southwestern China [J]. Biological Conservation, 2017, 215(2017): 152-161.

[36] Lei, G., Li, A.^*, Bian, J., et al. Land Cover Mapping in Southwestern China Using the HC-MMK Approach [J]. Remote Sensing, 2016, 8(4): 305.

[37] Wang, J., Li, A.^*, Bian, J. Simulation of the Grazing Effects on Grassland Aboveground Net Primary Production Using DNDC Model Combined with Time-Series Remote Sensing Data—A Case Study in Zoige Plateau, China [J]. Remote Sensing, 2016, 8(3): 168.

[38] Bian, J., Li, A.^*, Wang, Q., et al. Development of Dense Time Series 30-m Image Products from the Chinese HJ-1A/B Constellation: A Case Study in Zoige Plateau, China [J]. Remote Sensing, 2016, 7(12): 16647-16671.

[39] Jin, H., Li, A.^*, Wang, J., et al. Improvement of spatially and temporally continuous crop leaf area index by integration of CERES-Maize model and MODIS data [J]. European Journal of Agronomy, 2016, 78(2016): 1-12.

[40] Yin, G., Li, A.^*, Zeng, Y., et al. A cost-constrained sampling strategy in support of lai product validation in mountainous areas [J]. Remote Sensing, 2016, 8, 704.

[41] Li, A.^*, Wang, Q., Bian, J., et al. An Improved Physics-Based Model for Topographic Correction of Landsat TM Images [J]. Remote Sensing, 2015, 7(5): 6296-6319.

[42] Li, A.^*, Zhao, W., Deng, W. A Quantitative Inspection on Spatio-Temporal Variation of Remote Sensing-Based Estimates of Land Surface Evapotranspiration in South Asia [J]. Remote Sensing, 2015, 7(4): 4726-4752.

[43] Li, A.^*, Zhang, W., Lei, G., et al. Comparative Analysis on Two Schemes for Synthesizing the High Temporal Landsat-like NDVI Dataset Based on the STARFM Algorithm [J]. ISPRS International Journal of Geo-Information, 2015, 4(3): 1423-1441.

[44] Li, A.^*, Deng, W., Kong, B., et al. A study on wetland landscape pattern and its change process in Huang-Huai-Hai (3H) area, China [J]. Journal of Environmental Informatics, 2013, 21(1): 23-34.

[45] Li, A.^*, Liang, S., Wang, A., et al. Investgating the impacts of the North Atlantic Oscillation on global vegetation changes by a remotely sensed vegetation index. International Journal of Remote Sensing [J], 2012, 33(22): 7222-7239.

[46] Li, A.^*, Jiang, J., Bian, J., et al. Combining the matter element model with the associated function of probability transformation for multi-source remote sensing data classification in mountainous regions [J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2012, 67(1): 80-92.

[47] Li, A.^*, Bian, J., Lei, G., et al. Estimating the maximal light use efficiency for different vegetation through the CASA model combined with time-series remote sensing data and ground measurements [J]. Remote Sensing, 2012, 4(12): 3857-3876.

[48] Li, A., Huang, C., Sun, G., et al. Modeling the height of young forests regenerating from recent disturbances in Mississippi using Landsat and ICESat data [J]. Remote sensing of Environment, 2011, 115(8): 1837-1849.

[49] Li, A.^*, Deng, W., Liang, S., et al. Investigation on the patterns of global vegetation change using a satellite-sensed vegetation index [J]. Remote Sensing, 2010, 2(6): 1530-1548.

[50] Li, A.^*, Liang, S., Wang, A., et al. Estimating crop yield from multi-temporal satellite data using multivariate regression and neural network techniques [J]. Photogrammetric Engineering and Remote Sensing, 2007, 73(10): 1149-1157.

[51] Li, A.^*, Wang, A., Liang, S., et al. Eco-environmental vulnerability evaluation in mountainous region using remote sensing and GIS - A case study in the upper reaches of Minjiang River, China [J]. Ecological Modelling, 2006, 192(1-2): 175-187.

承擔科研項目情況:

國家重點(diǎn)研發(fā)計劃項目“山地生態(tài)系統全球變化關(guān)鍵參數立體觀(guān)測與高分辨率產(chǎn)品研制”（2021-2025）；

國家重大研發(fā)計劃項目課題“典型山地生態(tài)系統全球變化關(guān)鍵參數星-空-地立體觀(guān)測與時(shí)空尺度擴展”（2021-2025）；

國家自然科學(xué)基金重大項目“陸表智慧化定量遙感的理論與方法研究”專(zhuān)題“重難點(diǎn)地表覆蓋制圖”（2021-2025）；

中國科學(xué)院任務(wù)/戰略性先導科技專(zhuān)項（A類(lèi)）子課題“一帶一路重要經(jīng)濟廊道生態(tài)環(huán)境遙感監測與綜合評估”（2018-2022）；

中央級科學(xué)事業(yè)單位改善科研條件專(zhuān)項資金科研裝備項目“山地地表過(guò)程和生物多樣性天空地一體化監測平臺”（2022-2023）；

國家自然科學(xué)基金重點(diǎn)項目“山地典型生態(tài)參量遙感反演建模及其時(shí)空表征能力研究”（2017-2021）；

國家重點(diǎn)研發(fā)計劃項目專(zhuān)題“山地關(guān)鍵氣候變量天-空-地一體化協(xié)同觀(guān)測與應用示范”（2016-2021）；

中國科學(xué)院成都山地所“一三五”重點(diǎn)培育方向項目“南亞地緣合作關(guān)鍵資源環(huán)境變化過(guò)程與空間信息服務(wù)”（2017-2020）；

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研究隊伍