Abstract
With a gradually rising global average sea level, it is of great significance to predict changes in the sea level. However, sea level variations often exhibit both linear and nonlinear characteristics, complicating the prediction of sea level changes with a single model. The seasonal autoregressive integrated moving average (SARIMA) model can fully consider the linear characteristics of time series, but its nonlinear prediction ability is poor; the long short-term memory (LSTM) model can compensate for this shortcoming. To predict complex sea level changes, we propose a strategy to combine the SARIMA and LSTM models to increase the sea level prediction accuracy. In our method, sea level anomaly (SLA) time series are decomposed into the trend and seasonal term and random term; then, the SARIMA model is used to predict the trend and seasonal term of sea level variations, whereas the random term is predicted by LSTM. Sea surface height data from 1993 to 2018 are used in an experiment. Compared with other models, the performance of the SARIMA+LSTM model is superior in predicting sea level changes with a minimum root mean square error of 1.155 cm and a maximum determination coefficient ( R 2) of 0.89 during the testing period. Furthermore, the predicted results are in close agreement with the SLA data, which indicates that the SARIMA+LSTM model could be successfully used for the estimation of sea level variability.
Highlights
S EA level rise is slowly threatening human survival and impairing economic development, as this phenomenon has significant impacts on the social economy, natural environment, and ecosystem of coastal areas
The current study aims to demonstrate the applicability and capability of the seasonal autoregressive integrated moving average (SARIMA)+long short-term memory (LSTM) model to predict the sea level variations in China Sea and its vicinity
sea level anomaly (SLA) time series are decomposed into a trend and seasonal term and a random term; the SARIMA model is used to predict the trend and seasonal term of the sea level variations, whereas the random term is predicted by LSTM
Summary
S EA level rise is slowly threatening human survival and impairing economic development, as this phenomenon has significant impacts on the social economy, natural environment, and ecosystem of coastal areas. The Fifth Assessment Report of the Intergovernmental Panel on Climate Change (IPCC AR5) stated that the global mean sea level has risen by 0.19 m, estimated from a linear trend based on tide gauge records over the period 1901–2010 as well as satellite data since 1993. Different from coastal tide gauges and ship measurements, satellite altimetry provides measurements of sea level change on a near-global scale [8]. Many experts and scholars have calculated the global sea level rise rate and predicted the sea surface height by using satellite altimetry data [10]. The SARIMA and LSTM models have not been widely used to estimate sea level variations based on the satellite altimetry data. The current study aims to demonstrate the applicability and capability of the SARIMA+LSTM model to predict the sea level variations in China Sea and its vicinity. The MSS_CNES_CLS15 model utilized in this study is provided by CNES and is recognized as a highly precise global mean sea surface model
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
