Urban and suburban vegetation phenology feature based on phenology camera: A case study of Platanus acerifolia in Nanjing City, China

doi:10.13287/j.1001-9332.202512.023

Abstract

Abstract: To address the limitations of satellite remote sensing in monitoring vegetation phenology across heterogeneous urban and suburban landscapes, with Platanus acerifolia as research object, we proposed a novel pixel-based method for extracting target vegetation within region of interest (ROI) based on images from phenology camera observation sites in urban and suburban Nanjing during the year of 2020. By calculating the green chromatic coordinate (GCC) index, we employed Klosterman curve fitting alongside the Gu phenological parameter extraction method to derive four key phenological phases, i.e., greenup, maturity, senescence, and dormancy, and analyzed urban and suburban phenology feature of P. acerifolia. We analyzed the impact of meteorological factors on phenological phase of urban and suburban P. acerifolia at the daily scale. The results showed that the pixel-based target vegetation extraction method within ROI proposed here significantly reduced interference from buildings and understory vegetation. The identified phenological phase showed strong consistency with satellite remote sensing results, being more robust and reasonable than traditional pixel-averaged ROI method. There was a significant difference of phenological phases of P. acerifolia between urban and suburban sites. In 2020, the greenup of urban P. acerifolia occurred 5.5 days earlier than that of suburban areas, while senescence was delayed by 9.1 days. Temperature and shortwave radiation were the main factors affecting the phenological changes of P. acerifolia in the urban and suburban areas, while the impact of precipitation was not significant. The pixel-based target vegetation extraction technique developed in this study could enhance the accuracy of urban landscape phenological observation and provide methodological support for research on the impact of urbanization on vegetation phenology.

Key words: urban phenology, phenology camera, pixel, meteorological factor, Platanus acerifolia

TIAN Haoxiang, CAO Chang, SHI Dongtou, XU Jiaping, XIAO Wei, ZONG Pengcheng. Urban and suburban vegetation phenology feature based on phenology camera: A case study of Platanus acerifolia in Nanjing City, China[J]. Chinese Journal of Applied Ecology, 2025, 36(12): 3799-3809.

References

[1] Migliavacca M, Sonnentag O, Keenan TF, et al. On the uncertainty of phenological responses to climate change, and implications for a terrestrial biosphere model. Biogeosciences, 2012, 9: 2063-2083
[2] Richardson AD, Keenan TF, Migliavacca M, et al. Climate change, phenology, and phenological control of vegetation feedbacks to the climate system. Agricultural and Forest Meteorology, 2013, 169: 156-173
[3] Dang CY, Shao ZF, Huang X, et al. Climate warming-induced phenology changes dominate vegetation productivity in Northern Hemisphere ecosystems. Ecological Indicators, 2023, 151: 110326
[4] Chamberlain CJ, Wolkovich EM. Variation across space, species and methods in models of spring phenology. Climate Change Ecology, 2023, 5: 100071
[5] Li LZ, Li XC, Asrar G, et al. Detection and attribution of long-term and fine-scale changes in spring phenology over urban areas: A case study in New York State. International Journal of Applied Earth Observation and Geoinformation, 2022, 110: 102815
[6] Walker JJ, De Beurs KM, Henebry GM. Land surface phenology along urban to rural gradients in the U.S. great plains. Remote Sensing of Environment, 2015, 165: 42-52
[7] Christmann T, Kowarik I, Bernard-Verdier M, et al. Phenology of grassland plants responds to urbanization. Urban Ecosystems, 2023, 26: 261-275
[8] Zheng QM, Seto KC, Zhou YY, et al. Nighttime light remote sensing for urban applications: Progress, challenges, and prospects. ISPRS Journal of Photogrammetry and Remote Sensing, 2023, 202: 125-141
[9] Meng L, Zhou YY, Román MO, et al. Artificial light at night: An underappreciated effect on phenology of deciduous woody plants. Proceedings of the National Academy of Sciences of the United States of America Nexus, 2022, 1: pgac046
[10] 阮文洁, 何云玲, 黄丽华. 滇中城市群植被物候时空变化及其对城市化的响应. 应用生态学报, 2023, 34(12): 3263-3270
[11] Hou HR, Su HB, Liu K, et al. Driving forces of UHI changes in China’s major cities from the perspective of land surface energy balance. Science of the Total Environment, 2022, 829: 154710
[12] 张聪聪, 孟丹, 李小娟. 京津冀地区植被物候时空变化及其对城市化的响应. 生态学报, 2023, 43(1): 249-262
[13] Granero-Belinchon C, Adeline K, Lemonsu A, et al. Phenological dynamics characterization of alignment trees with Sentinel-2 imagery: A vegetation indices time series reconstruction methodology adapted to urban areas. Remote Sensing, 2020, 12: 639
[14] Yang L, Zhao SQ. A stronger advance of urban spring vegetation phenology narrows vegetation productivity difference between urban settings and natural environments. Science of the Total Environment, 2023, 868: 161649
[15] 丁海勇, 卜亚勤, 徐路明. 长三角地区植被物候时空变化及其对城市化的响应. 安全与环境学报, 2021, 21(3): 1352-1360
[16] Moon M, Richardson AD, Friedl MA. Multiscale assessment of land surface phenology from harmonized Landsat 8 and Sentinel-2, PlanetScope, and PhenoCam imagery. Remote Sensing of Environment, 2021, 266: 112716
[17] Yin PY, Li XC, Mao JF, et al. A comprehensive analysis of the crop effect on the urban-rural differences in land surface phenology. Science of the Total Environment, 2023, 861: 160604
[18] Tang JW, Körner C, Muraoka H, et al. Emerging opportunities and challenges in phenology: A review. Ecosphere, 2016, 7: e01436
[19] 韩贵锋, 徐建华, 袁兴中. 城市化对长三角地区主要城市植被物候的影响. 应用生态学报, 2008, 19(8): 1803-1809
[20] Burke MWV, Rundquist BC. Scaling PhenoCam GCC, NDVI, and EVI2 with harmonized Landsat-Sentinel using Gaussian processes. Agricultural and Forest Meteorology, 2021, 300: 108316
[21] Tran KH, Zhang XY, Ketchpaw AR, et al. A novel algorithm for the generation of gap-free time series by fusing harmonized Landsat 8 and Sentinel-2 observations with PhenoCam time series for detecting land surface phenology. Remote Sensing of Environment, 2022, 282: 113275
[22] Filippa G, Cremonese E, Migliavacca M, et al. NDVI derived from near-infrared-enabled digital cameras: Applicability across different plant functional types. Agricultural and Forest Meteorology, 2018, 249: 275-285
[23] Brown TB, Hultine KR, Steltzer H, et al. Using phenocams to monitor our changing Earth: Toward a global PhenoCam network. Frontiers in Ecology and the Environment, 2016, 14: 84-93
[24] Richardson AD. Tracking seasonal rhythms of plants in diverse ecosystems with digital camera imagery. New Phytologist, 2019, 222: 1742-1750
[25] Richardson AD, Hufkens K, Li XL, et al. Testing Hopkins’ bioclimatic law with PhenoCam data. Applications in Plant Sciences, 2019, 7: e01228
[26] Richardson AD, Hufkens K, Milliman T, et al. Tracking vegetation phenology across diverse North American biomes using PhenoCam imagery. Scientific Data, 2018, 5: 180028
[27] Richardson AD, Hufkens K, Milliman T, et al. Intercomparison of phenological transition dates derived from the PhenoCam dataset V1.0 and MODIS satellite remote sensing. Scientific Reports, 2018, 8: 5679
[28] Klosterman ST, Hufkens K, Gray JM, et al. Evaluating remote sensing of deciduous forest phenology at multiple spatial scales using PhenoCam imagery. Biogeosciences, 2014, 11: 4305-4320
[29] Snyder KA, Richardson W, Browning DM, et al. Plant phenology of high-elevation meadows: Assessing spectral responses of grazed meadows. Rangeland Ecology and Management, 2023, 87: 69-82
[30] Julitta T, Cremonese E, Migliavacca M, et al. Using digital camera images to analyse snowmelt and phenology of a subalpine grassland. Agricultural and Forest Meteorology, 2014, 198-199: 116-125
[31] Zipper SC, Schatz J, Singh A, et al. Urban heat island impacts on plant phenology: Intra-urban variability and response to land cover. Environmental Research Letters, 2016, 11: 054023
[32] Kaddoura YO, Wilkinson B, Merrick T, et al. Georeferencing oblique PhenoCam imagery. ISPRS Journal of Photogrammetry and Remote Sensing, 2022, 190: 301-321
[33] Gillespie AR, Kahle AB, Walker RE. Color enhancement of highly correlated images. Ⅱ. Channel ratio and “chromaticity” transformation techniques. Remote Sensing of Environment, 1987, 22: 343-365
[34] Sonnentag O, Hufkens K, Teshera-Sterne C, et al. Digi-tal repeat photography for phenological research in forest ecosystems. Agricultural and Forest Meteorology, 2012, 152: 159-177
[35] Gu L, Post W, Baldocchi D, et al. Characterizing the seasonal dynamics of plant community photosynthesis across a range of vegetation types// Noormets A, ed. Phenology of Ecosystem Processes. New York: Springer, 2009: 35-58
[36] Chen Y, Lin MX, Lin T, et al. Spatial heterogeneity of vegetation phenology caused by urbanization in China based on remote sensing. Ecological Indicators, 2023, 153: 110448
[37] Yang L, Zhao SQ, Liu SG. Urban environments provide new perspectives for forecasting vegetation phenology responses under climate warming. Global Change Biology, 2023, 29: 4383-4396
[38] Wang X, Du PJ, Chen DM, et al. Characterizing urbanization-induced land surface phenology change from time-series remotely sensed images at fine spatio-temporal scale: A case study in Nanjing, China (2001-2018). Journal of Cleaner Production, 2020, 274: 122487
[39] Kim J, Sohn S, Wang ZS, et al. Nonuniform response of vegetation phenology to daytime and nighttime warming in urban areas. Communication Earth and Environment, 2024, 5: 308
[40] Meng L, Mao JF, Zhou YY, et al. Urban warming advances spring phenology but reduces the response of phenology to temperature in the conterminous United States. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117: 4228-4233
[41] Jia WX, Zhao SQ, Zhang XY, et al. Urbanization imprint on land surface phenology: The urban-rural gradient analysis for Chinese cities. Global Change Biology, 2021, 27: 2895-2904
[42] Dhami I, Arano KG, Warner TA, et al. Phenology of trees and urbanization: A comparative study between New York City and Ithaca, New York. Geocarto International, 2011, 26: 507-526
[43] 张晓东, 朱文博, 张静静, 等. 伏牛山森林植被物候及其对气候变化的响应. 地理学报, 2018, 73(1): 41-53
[44] Wu ZF, Fu YS, Crowther TW, et al. Poleward shifts in the maximum of spring phenological responsiveness of Ginkgo biloba to temperature in China. New Phytologist, 2023, 240: 1421-1432
[45] Kabano P, Lindley S, Harris A. Evidence of urban heat island impacts on the vegetation growing season length in a tropical city. Landscape and Urban Planning, 2021, 206: 103989
[46] Wang LQ, Boeck HJD, Chen LX, et al. Urban warming increases the temperature sensitivity of spring vegetation phenology at 292 cities across China. Science of the Total Environment, 2022, 834: 155154
[47] 孟丹, 刘芯蕊, 张聪聪. 北京市植物物候对热岛效应的响应. 生态学杂志, 2021, 40(3): 844-854
[48] Yin P, Li X, Pellikka P. Asymmetrical impact of daytime and nighttime warming on the interannual variation of urban spring vegetation phenology. Earth’s Future, 2024, 12: e2023EF004127
[49] Liu ZH, Zhou Y, Feng ZT. Response of vegetation phenology to urbanization in urban agglomeration areas: A dynamic urban-rural gradient perspective. Science of the Total Environment, 2023, 864: 161109
[50] Zhang YH, Yin PY, Li XC, et al. The divergent response of vegetation phenology to urbanization: A case study of Beijing City, China. Science of the Total Environment, 2022, 803: 150079
[51] 洪辛茜, 孙涛, 陈利顶. 城市化背景下植被物候动态变化及驱动因素. 应用生态学报, 2023, 34(9): 2436-2444
[52] Peng ZJ, Jiang DZ, Li WB, et al. Impacts of the scale effect on quantifying the response of spring vegetation phenology to urban intensity. Remote Sensing of Environment, 2024, 315: 114485