• ISSN 1008-505X
  • CN 11-3996/S

融合多源遥感指数与随机森林模型的雄安新区千年秀林土壤碳氮含量反演及动态监测

Inversion and spatiotemporal monitoring of soil carbon and nitrogen content in the Millennium Forest of Xiong’an New Area using multi-source remote sensing indices and random forest

  • 摘要:
    目的 研究可及时、快捷、准确地动态监测雄安新区千年秀林9号地块一区土壤有机碳(SOC)和土壤全氮(STN)含量的方法,明确其时空分布特征,为林区土壤可持续管理提供数据支持,保障千年秀林长期稳定发展。
    方法 2020年9月,在雄安新区千年秀林9号地块一区采集0—30 cm土层土壤样品95个,分析其SOC和STN含量。收集该区域2018—2023年6期Landsat 8 OLI影像(均获取于9月或10月),提取并计算各波段光谱反射率和遥感指数,将其与SOC和STN实测值进行关联性分析;利用特征筛选方法选取建模因子,以降低模型复杂性。基于随机森林算法分别构建SOC和STN含量预测模型,包括波段模型、波段+单遥感指数模型和波段+多遥感指数模型3类。对于SOC预测模型,选择Band 4和Band 6建立波段模型;红度指数(RI)参与单遥感指数模型构建,RI、土壤盐分指数2 (SI2)和土壤盐分指数3 (SI3)用于多遥感指数模型构建。对于STN预测模型,选择Band 4和Band 3构建波段模型;SI3参与单遥感指数模型构建,而多遥感指数模型结合RI、土壤盐分指数1 (SI1)和SI3。采用决定系数(R2)、相对分析误差(RPD)、平均绝对误差(MAE)及均方根误差(RMSE)等指标综合评估模型精度,并选取最优模型预测SOC和STN的时空分布特征。
    结果 SOC最优预测模型为SOC-Band 4+Band 6+RI+SI2+SI3 (R2=0.778,RPD=1.933,MAE=0.719,RMSE=0.829)和STN最优预测模型为SIN-Band 4+Band 3+SI3 (R2=0.679,RPD=1.742,MAE=0.047,RMSE=0.054)。2018—2023年,研究区SOC含量整体呈波动性升高趋势,2022年有所降低,年均值在7.274~8.334 g/kg之间波动;整个林区SOC含量在边缘区域相对稳定,而内部区域变化较为显著;生态基础林和近自然林西部SOC含量始终高于其他林区。STN含量整体变化趋势与SOC基本一致,年均值变化范围为0.676~0.772 g/kg。
    结论 在随机森林波段模型基础上引入遥感指数因子,可有效提高SOC和STN含量预测模型的精度。预测结果显示,研究区土壤有机质和全氮含量呈波动性升高趋势,其中2022年有所降低。5种景观功能林中,生态基础林和近自然林的SOC和STN含量始终高于其他林区。

     

    Abstract:
    Objectives To develop a timely, efficient, and accurate method for dynamically monitoring soil organic carbon (SOC) and soil total nitrogen (STN) in Area 1 of Plot 9 of the Millennium Forest in Xiong’an New Area, to characterize their spatiotemporal distribution patterns, support sustainable soil management, and ensure the long-term stable development of the Millennium Forest.
    Methods A total of 95 soil samples were collected in Area 1 of Plot 9 within the Millennium Forest, Xiong’an New Area, and their SOC and STN contents were determined. Six Landsat 8 OLI images acquired during September or October from 2018 to 2023 were collected for the study area. Spectral reflectance values and remote sensing indices were extracted and calculated, and their relationships with measured SOC and STN contents were analyzed. Feature selection methods were employed to identify optimal predictors and reduce model complexity. Based on the Random Forest (RF) algorithm, three types of prediction models were developed for SOC and STN, including band-based models, band + single remote sensing index models, and band + multiple remote sensing index models. For SOC prediction, Band 4 and Band 6 were selected to construct the band-based model. The Redness Index (RI) was incorporated into the band + single-index model, whereas RI, Soil Salinity Index 2 (SI2), and Soil Salinity Index 3 (SI3) were included in the band + multiple-index model. For STN prediction, Band 4 and Band 3 were selected for the band-based model. SI3 was used in the band + single-index model, while RI, Soil Salinity Index 1 (SI1), and SI3 were incorporated into the band + multiple-index model. Model performance was comprehensively evaluated using the coefficient of determination (R2), relative percent deviation (RPD), mean absolute error (MAE), and root mean square error (RMSE). The optimal models were subsequently applied to predict the spatiotemporal distributions of SOC and STN.
    Results The SOC-Band 4+Band 6+RI+SI2+SI3 model achieved the highest prediction accuracy for SOC, with R2=0.778, RPD=1.933, MAE=0.719, RMSE=0.829. For STN, the STN-Band 4+Band 3+SI3 model performed best, with R2=0.679, RPD=1.742, MAE=0.047, RMSE=0.054. From 2018 to 2023, the SOC content in the study area showed an overall fluctuating upward trend, with a slight decrease in 2022. The annual average SOC content ranged from 7.274 to 8.334 g/kg. Spatially, SOC content remained relatively stable in peripheral areas but showed considerable variation within the forest interior. The ecological basic forest and the western part of the near-natural forest consistently exhibited higher SOC contents than the other forest types. The overall changing trend of STN content was basically consistent with that of SOC content, and its annual average changing range is 0.676−0.772 g/kg.
    Conclusions Incorporating remote sensing indices into RF band-based models improved the prediction accuracy of both SOC and STN. The predicted results indicated that SOC and STN contents generally increased over time with interannual fluctuations, although both decreased in 2022. Among the five landscape forest types, the ecological basic forest and the western part of the near-natural forest consistently maintained higher SOC and STN contents than the other forest types.

     

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