Real-Time Management of Vessel Carbon Dioxide Emissions Based on Automatic Identification System Database Using Deep Learning

In this study, we propose an effective method using deep learning to strengthen real-time vessel carbon dioxide emission management. We propose a method to predict real-time carbon dioxide emissions of the vessel in three steps: (1) convert the trajectory data of the fixed time interval into a spatial–temporal sequence, (2) apply a long short-term memory (LSTM) model to predict the future trajectory and vessel status data of the vessel, and (3) predict the carbon dioxide emissions. Automatic identification system (AIS) database of a liquefied natural gas (LNG) vessel were selected as the sample and we reconstructed the trajectory data with a fixed time interval using cubic spline interpolation. Applying the interpolated AIS data, the carbon dioxide emissions of the vessel were calculated based on the International Towing Tank Conference (ITTC) recommended procedures. The experimental results are twofold. First, it reveals that vessel emissions are currently underestimated. This study clearly indicates that the actual carbon dioxide emissions are higher than those reported. The finding offers insight into how to accurately measure the emissions of vessels, and hence, better execute a greenhouse gases (GHGs) reduction strategy. Second, the LSTM model has a better trajectory prediction performance than the recurrent neural network (RNN) model. The errors of the trajectory endpoint and carbon dioxide emissions were small, which shows that the LSTM model is suitable for spatial–temporal data prediction with excellent performance. Therefore, this study offers insights to strengthen the real-time management and control of vessel greenhouse gas emissions and handle those in a more efficient way.

[1]  Enna Hirata,et al.  Spatial Analysis of an Emission Inventory from Liquefied Natural Gas Fleet Based on Automatic Identification System Database , 2021, Sustainability.

[2]  S. Fassois,et al.  Evaluation of Different Deep-Learning Models for the Prediction of a Ship’s Propulsion Power , 2021, Journal of Marine Science and Engineering.

[3]  J. Falzarano Ship Resistance and Propulsion: Practical Estimation of Ship Propulsive Power , 2018, AIAA Journal.

[4]  Henrik Ljunggren,et al.  Using Deep Learning for Classifying Ship Trajectories , 2018, 2018 21st International Conference on Information Fusion (FUSION).

[5]  Chan Le Van,et al.  Vessel Trajectory Prediction using Sequence-to-Sequence Models over Spatial Grid , 2018, DEBS.

[6]  Bo Quan,et al.  基于LSTM的船舶航迹预测模型 (Prediction Model of Ship Trajectory Based on LSTM) , 2018, 计算机科学.

[7]  Stephen R. Turnock,et al.  Ship Resistance and Propulsion: Practical Estimation of Ship Propulsive Power , 2017 .

[8]  Pengfei Chen,et al.  Ship Emission Inventories in Estuary of the Yangtze River Using Terrestrial AIS Data , 2016 .

[9]  Ian D. Williams,et al.  An AIS-based approach to calculate atmospheric emissions from the UK fishing fleet , 2015 .

[10]  Salaheddine Hamdoune,et al.  Estimating Carbon Dioxide and Particulate Matter Emissions from Ships using Automatic Identification System Data , 2014 .

[11]  Morten Winther,et al.  Emission inventories for ships in the arctic based on satellite sampled AIS data , 2013 .

[12]  Shan Liang,et al.  Track prediction of vessel in controlled waterway based on improved Kalman filter: Track prediction of vessel in controlled waterway based on improved Kalman filter , 2013 .

[13]  Wang De-jun,et al.  Track prediction of vessel in controlled waterway based on improved Kalman filter , 2012 .

[14]  Göran Falkman,et al.  Anomaly detection in sea traffic - A comparison of the Gaussian Mixture Model and the Kernel Density Estimator , 2009, 2009 12th International Conference on Information Fusion.

[15]  Jürgen Schmidhuber,et al.  Long Short-Term Memory , 1997, Neural Computation.