TY - GEN
T1 - Improving net ecosystem CO2flux prediction using memory-based interpretable machine learning
AU - Liu, Siyan
AU - Lu, Dan
AU - Ricciuto, Daniel
AU - Walker, Anthony
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - 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.
AB - 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.
KW - Inter-pretable machine learning
KW - Long Short-Term Memory networks
KW - driver importance
KW - memory effects
KW - net ecosystem CO2 exchange
UR - http://www.scopus.com/inward/record.url?scp=85148440906&partnerID=8YFLogxK
U2 - 10.1109/ICDMW58026.2022.00145
DO - 10.1109/ICDMW58026.2022.00145
M3 - Conference contribution
AN - SCOPUS:85148440906
T3 - IEEE International Conference on Data Mining Workshops, ICDMW
SP - 1111
EP - 1119
BT - Proceedings - 22nd IEEE International Conference on Data Mining Workshops, ICDMW 2022
A2 - Candan, K. Selcuk
A2 - Dinh, Thang N.
A2 - Thai, My T.
A2 - Washio, Takashi
PB - IEEE Computer Society
T2 - 22nd IEEE International Conference on Data Mining Workshops, ICDMW 2022
Y2 - 28 November 2022 through 1 December 2022
ER -