Litcius/Paper detail

Multi-Step-Ahead Forecasting of Wave Conditions Based on a Physics-Based Machine Learning (PBML) Model for Marine Operations

Mengning Wu, Christos Stefanakos, Zhen Gao

2020Journal of Marine Science and Engineering40 citationsDOIOpen Access PDF

Abstract

Short-term wave forecasts are essential for the execution of marine operations. In this paper, an efficient and reliable physics-based machine learning (PBML) model is proposed to realize the multi-step-ahead forecasting of wave conditions (e.g., significant wave height Hs and peak wave period Tp). In the model, the primary variables in physics-based wave models (i.e., the wind forcing and initial wave boundary condition) are considered as inputs. Meanwhile, a machine learning algorithm (artificial neural network, ANN) is adopted to build an implicit relation between inputs and forecasted outputs of wave conditions. The computational cost of this data-driven model is obviously much lower than that of the differential-equation based physical model. A ten-year (from 2001 to 2010) dataset of every three hours at the North Sea center was used to assess the model performance in a small domain. The result reveals high reliability for one-day-ahead Hs forecasts, while that of Tp is slightly lower due to the weaker implicit relationships between the data. Overall, the PBML model can be conceived as an efficient tool for the multi-step-ahead forecasting of wave conditions, and thus has great potential for furthering assist decision-making during the execution of marine operations.

Topics & Concepts

Artificial neural networkForcing (mathematics)Significant wave heightMachine learningArtificial intelligenceTerm (time)Wave modelWind waveComputer scienceWave heightDomain (mathematical analysis)MeteorologyMathematicsPhysicsMathematical analysisThermodynamicsQuantum mechanicsHydrological Forecasting Using AIOcean Waves and Remote SensingOceanographic and Atmospheric Processes