Improving net ecosystem CO2 flux prediction using memory-based interpretable machine learning

Siyan Liu, Dawei Lu, D. Ricciuto, A. Walker
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Abstract

Terrestrial ecosystems play a central role in the global carbon cycle and affect climate change. However, our predictive understanding of these systems is still limited due to their complexity and uncertainty about how key drivers and their legacy effects influence carbon fluxes. Here, we propose an interpretable Long Short-Term Memory (iLSTM) network for predicting net ecosystem CO2 exchange (NEE) and interpreting the influence on the NEE prediction from environmental drivers and their memory effects. We consider five drivers and apply the method to three forest sites in the United States. Besides performing the prediction in each site, we also conduct transfer learning by using the iLSTM model trained in one site to predict at other sites. Results show that the iLSTM model produces good NEE predictions for all three sites and, more importantly, it provides reasonable interpretations on the input driver's importance as well as their temporal importance on the NEE prediction. Additionally, the iLSTM model demonstrates good across-site transferability in terms of both prediction accuracy and interpretability. The transferability can improve the NEE prediction in unobserved forest sites, and the interpretability advances our predictive understanding and guides process-based model development.
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利用基于记忆的可解释机器学习改进净生态系统二氧化碳通量预测
陆地生态系统在全球碳循环和影响气候变化中发挥着核心作用。然而,由于这些系统的复杂性和关键驱动因素及其遗留效应如何影响碳通量的不确定性,我们对这些系统的预测性理解仍然有限。在此,我们提出了一个可解释的长短期记忆(iLSTM)网络来预测净生态系统二氧化碳交换(NEE),并解释环境驱动因素及其记忆效应对净生态系统二氧化碳交换预测的影响。我们考虑了五个驱动因素,并将该方法应用于美国的三个森林地点。除了在每个站点进行预测外,我们还使用在一个站点训练的iLSTM模型进行迁移学习,以预测其他站点。结果表明,iLSTM模型对所有三个站点都能产生良好的NEE预测,更重要的是,它对输入驱动因素的重要性及其对NEE预测的时间重要性提供了合理的解释。此外,iLSTM模型在预测精度和可解释性方面具有良好的跨站点可移植性。可转移性可以提高对未观测样地的新能源经济预测能力,可解释性可以提高我们对新能源经济预测的认识,并指导基于过程的模型开发。
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