Related papers: Prediction of Vessel Arrival Time to Pilotage Area Using Multi-Data Fusion and Deep Learning

Prediction of Vessel Arrival Time to Pilotage Area Using Multi-Data Fusion and Deep Learning

URL: http://arxiv.org/abs/2403.09969v1
Date: Fri, 15 Mar 2024 02:25:04 GMT
Title: Prediction of Vessel Arrival Time to Pilotage Area Using Multi-Data Fusion and Deep Learning
Authors: Xiaocai Zhang, Xiuju Fu, Zhe Xiao, Haiyan Xu, Xiaoyang Wei, Jimmy Koh, Daichi Ogawa, Zheng Qin,
Abstract summary: This paper investigates the prediction of vessels' arrival time to the pilotage area using multi-data fusion and deep learning approaches. Tests on two real-world data sets from Singapore have been conducted and the following promising results have been obtained.
Score: 9.458664533786994
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: This paper investigates the prediction of vessels' arrival time to the pilotage area using multi-data fusion and deep learning approaches. Firstly, the vessel arrival contour is extracted based on Multivariate Kernel Density Estimation (MKDE) and clustering. Secondly, multiple data sources, including Automatic Identification System (AIS), pilotage booking information, and meteorological data, are fused before latent feature extraction. Thirdly, a Temporal Convolutional Network (TCN) framework that incorporates a residual mechanism is constructed to learn the hidden arrival patterns of the vessels. Extensive tests on two real-world data sets from Singapore have been conducted and the following promising results have been obtained: 1) fusion of pilotage booking information and meteorological data improves the prediction accuracy, with pilotage booking information having a more significant impact; 2) using discrete embedding for the meteorological data performs better than using continuous embedding; 3) the TCN outperforms the state-of-the-art baseline methods in regression tasks, exhibiting Mean Absolute Error (MAE) ranging from 4.58 min to 4.86 min; and 4) approximately 89.41% to 90.61% of the absolute prediction residuals fall within a time frame of 10 min.

Related papers

Data-driven Probabilistic Trajectory Learning with High Temporal Resolution in Terminal Airspace [9.688760969026305]
We propose a data-driven learning framework, that leverages the predictive and feature extraction capabilities of the mixture models and seq2seq-based neural networks. After training with this framework, the learned model can improve long-step prediction accuracy significantly. The accuracy and effectiveness of the approach are evaluated by comparing the predicted trajectories with the ground truth.
arXiv Detail & Related papers (2024-09-25T21:08:25Z)
Generative Data Assimilation of Sparse Weather Station Observations at Kilometer Scales [5.453657018459705]
We demonstrate the viability of score-based data assimilation in the context of realistically complex km-scale weather. By incorporating observations from 40 weather stations, 10% lower RMSEs on left-out stations are attained. It is a ripe time to explore extensions that combine increasingly ambitious regional state generators with an increasing set of in situ, ground-based, and satellite remote sensing data streams.
arXiv Detail & Related papers (2024-06-19T10:28:11Z)
M4Fog: A Global Multi-Regional, Multi-Modal, and Multi-Stage Dataset for Marine Fog Detection and Forecasting to Bridge Ocean and Atmosphere [34.63172821289592]
We present the most comprehensive marine fog detection and forecasting dataset to date, named M4Fog. The dataset comprises 68,000 "superFog data cubes" along four dimensions: elements, latitude, longitude and time, with a temporal resolution of half an hour and a spatial resolution of 1 kilometer. Considering practical applications, we have defined and explored three meaningful tracks with multi-metric evaluation systems.
arXiv Detail & Related papers (2024-06-19T08:11:07Z)
Observation-Guided Meteorological Field Downscaling at Station Scale: A Benchmark and a New Method [66.80344502790231]
We extend meteorological downscaling to arbitrary scattered station scales and establish a new benchmark and dataset. Inspired by data assimilation techniques, we integrate observational data into the downscaling process, providing multi-scale observational priors. Our proposed method outperforms other specially designed baseline models on multiple surface variables.
arXiv Detail & Related papers (2024-01-22T14:02:56Z)
Deep Learning for Day Forecasts from Sparse Observations [60.041805328514876]
Deep neural networks offer an alternative paradigm for modeling weather conditions. MetNet-3 learns from both dense and sparse data sensors and makes predictions up to 24 hours ahead for precipitation, wind, temperature and dew point. MetNet-3 has a high temporal and spatial resolution, respectively, up to 2 minutes and 1 km as well as a low operational latency.
arXiv Detail & Related papers (2023-06-06T07:07:54Z)
Pangu-Weather: A 3D High-Resolution Model for Fast and Accurate Global Weather Forecast [91.9372563527801]
We present Pangu-Weather, a deep learning based system for fast and accurate global weather forecast. For the first time, an AI-based method outperforms state-of-the-art numerical weather prediction (NWP) methods in terms of accuracy. Pangu-Weather supports a wide range of downstream forecast scenarios, including extreme weather forecast and large-member ensemble forecast in real-time.
arXiv Detail & Related papers (2022-11-03T17:19:43Z)
Inertial Hallucinations -- When Wearable Inertial Devices Start Seeing Things [82.15959827765325]
We propose a novel approach to multimodal sensor fusion for Ambient Assisted Living (AAL) We address two major shortcomings of standard multimodal approaches, limited area coverage and reduced reliability. Our new framework fuses the concept of modality hallucination with triplet learning to train a model with different modalities to handle missing sensors at inference time.
arXiv Detail & Related papers (2022-07-14T10:04:18Z)
Predicting Berth Stay for Tanker Terminals: A Systematic and Dynamic Approach [1.6694381776724387]
The proposed approach can predict berth stay with the accuracy up to 98.81% validated by historical baselines. The model may be potentially applied for short-term pilot-booking or scheduling optimizations within a reasonable time frame.
arXiv Detail & Related papers (2022-04-08T14:03:33Z)
A Graph Convolutional Network with Signal Phasing Information for Arterial Traffic Prediction [63.470149585093665]
arterial traffic prediction plays a crucial role in the development of modern intelligent transportation systems. Many existing studies on arterial traffic prediction only consider temporal measurements of flow and occupancy from loop sensors and neglect the rich spatial relationships between upstream and downstream detectors. We fill this gap by enhancing a deep learning approach, Diffusion Convolutional Recurrent Neural Network, with spatial information generated from signal timing plans at targeted intersections.
arXiv Detail & Related papers (2020-12-25T01:40:29Z)
FMA-ETA: Estimating Travel Time Entirely Based on FFN With Attention [88.33372574562824]
We propose a novel framework based on feed-forward network (FFN) for ETA, FFN with Multi-factor self-Attention (FMA-ETA) The novel Multi-factor self-attention mechanism is proposed to deal with different category features and aggregate the information purposefully. Experiments show FMA-ETA is competitive with state-of-the-art methods in terms of the prediction accuracy with significantly better inference speed.
arXiv Detail & Related papers (2020-06-07T08:10:47Z)
Mission-Aware Spatio-Temporal Deep Learning Model for UAS Instantaneous Density Prediction [3.59465210252619]
Number of daily sUAS operations in uncontrolled low altitude airspace is expected to reach into the millions in a few years. Deep learning-based UAS instantaneous density prediction model is presented.
arXiv Detail & Related papers (2020-03-22T02:40:28Z)

This list is automatically generated from the titles and abstracts of the papers in this site.