Novel Learning of Bathymetry from Landsat 9 Imagery Using Machine Learning, Feature Extraction and Meta-Heuristic Optimization in a Shallow Turbid Lagoon

Novel Learning of Bathymetry from Landsat 9 Imagery Using Machine Learning, Feature Extraction and Meta-Heuristic Optimization in a Shallow Turbid Lagoon

Bathymetry data is indispensable for a variety of aquatic field studies and benthic resource inventories. Determining water depth can be accomplished through an echo sounding system or remote estimation utilizing space-borne and air-borne data across diverse environments, such as lakes, rivers, seas...

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Bibliographic Details
Published in:Geosciences (Basel) Vol. 14; no. 5; p. 130
Main Authors: Tran, Hang Thi Thuy, Nguyen, Quang Hao, Pham, Ty Huu, Ngo, Giang Thi Huong, Pham, Nho Tran Dinh, Pham, Tung Gia, Tran, Chau Thi Minh, Ha, Thang Nam
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-05-2024
Subjects:
Accuracy
Algorithms
Aquatic environment
Artificial intelligence
Bathymeters
Bathymetric maps
Bathymetry
Benthos
Datasets
Echo sounding
Echosounding
Environmental aspects
Feature extraction
Feature selection
Heuristic
Heuristic methods
Lagoons
Lakes
Landsat
Landsat satellites
Learning algorithms
Machine learning
Mapping
Mathematical optimization
metaheuristic
Morphology
Neural networks
Optical properties
Optimization
Particle swarm optimization
Problem solving
Ratios
Remote sensing
Rivers
Satellite imagery
Satellite imaging
Spatial discrimination
Spatial resolution
Support vector machines
Swamps
Technology application
Tourism
turbid
Water depth
Vietnam
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Summary:Bathymetry data is indispensable for a variety of aquatic field studies and benthic resource inventories. Determining water depth can be accomplished through an echo sounding system or remote estimation utilizing space-borne and air-borne data across diverse environments, such as lakes, rivers, seas, or lagoons. Despite being a common option for bathymetry mapping, the use of satellite imagery faces challenges due to the complex inherent optical properties of water bodies (e.g., turbid water), satellite spatial resolution limitations, and constraints in the performance of retrieval models. This study focuses on advancing the remote sensing based method by harnessing the non-linear learning capabilities of the machine learning (ML) model, employing advanced feature selection through a meta-heuristic algorithm, and using image extraction techniques (i.e., band ratio, gray scale morphological operation, and morphological multi-scale decomposition). Herein, we validate the predictive capabilities of six ML models: Random Forest (RF), Support Vector Machine (SVM), CatBoost (CB), Extreme Gradient Boost (XGB), Light Gradient Boosting Machine (LGBM), and KTBoost (KTB) models, both with and without the application of meta-heuristic optimization (i.e., Dragon Fly, Particle Swarm Optimization, and Grey Wolf Optimization), to accurately ascertain water depth. This is achieved using a diverse input dataset derived from multi-spectral Landsat 9 imagery captured on a cloud-free day (19 September 2023) in a shallow, turbid lagoon. Our findings indicate the superior performance of LGBM coupled with Particle Swamp Optimization (R2 = 0.908, RMSE = 0.31 m), affirming the consistency and reliability of the feature extraction and selection-based framework, while offering novel insights into the expansion of bathymetric mapping in complex aquatic environments.
ISSN:2076-3263
2076-3263
DOI:10.3390/geosciences14050130