Advancements in Ocean Mapping and Nautical Cartography
1
Center for Coastal and Ocean Mapping and NOAA-UNH Joint Hydrographic Center, University of New Hampshire, Durham, NH 03824, USA
2
Danish Hydrographic Office, Danish Geodata Agency, 9400 Nørresundby, Denmark
3
Department of Geodesy and Geomatics Engineering, University of New Brunswick, Fredericton, NB E3B5A3, Canada
4
School of Ocean Science and Engineering, University of Southern Mississippi, Stennis Space Center, Hattiesburg, MS 39406, USA
5
Department of Computer Science, Aalborg University, Selma Lagerlöfs Vej 300, 9220 Aalborg East, Denmark
*
Author to whom correspondence should be addressed.
Geomatics 2024, 4(4), 433-436; https://doi.org/10.3390/geomatics4040023
Submission received: 1 November 2024
/
Accepted: 26 November 2024
/
Published: 28 November 2024
(This article belongs to the Special Issue Advances in Ocean Mapping and Nautical Cartography)
1. Introduction
Ocean mapping and nautical cartography are foundational to understanding and managing marine environments. These fields support a wide range of applications—from safe navigation and resource management to ecosystem conservation and assessment of the impacts of climate change [1]. The ocean remains largely uncharted at a high resolution, and new technologies are crucial to bridge this knowledge gap [2]. This Special Issue of Geomatics brings together nine studies, each tackling unique challenges facing ocean mapping. The articles highlight a wide-ranging spectrum of innovations, from automated data processing and high-resolution mapping systems to ecosystem-based planning and machine learning applications for habitat classification. Together, they showcase how diverse, interdisciplinary approaches are essential to advancing oceanography and marine spatial planning, facilitating sustainable development, and contributing to safer and more informed approaches to ocean use.
The collected works underscore the diversity of current research into ocean mapping and cartography, with methodologies ranging from traditional sonar-based mapping to advanced, machine learning-driven analyses of marine habitats. By exploring different technological and methodological advancements, this Special Issue emphasizes the importance of both preserving historical data and embracing new tools and approaches to meet the evolving demands of marine science and resource management [3]. This Editorial review provides an overview of these articles, highlighting their collective contribution to the field and their implications for the future of ocean mapping.
2. Data Collection and Review
2.1. A New Approach to Wide-Area Deep-Ocean Mapping
In response to the challenges of mapping deep-sea areas from the ocean surface, Ryu et al. [4] present a cutting-edge system that employs autonomous surface vessels to deploy a distributed array of sonar sensors. This design overcomes the limitations of sonar-based underwater mapping by achieving a high resolution at significant depths without the need to deploy costly and logistically complex underwater vessels. The sparse-array approach allows for the precise tracking of sonar positions relative to each other, compensating for oceanic conditions, and thereby advancing bathymetric mapping from the surface to unprecedented depths.
2.2. Open-Source Tools for Sonar Acceptance Testing
In the field of sonar data acquisition, testing and troubleshooting are critical for ensuring data accuracy. Younkin and Umfress [5] showcase the usefulness of Kluster, an open-source Python-based software, which streamlines sonar data processing and visualization, particularly for the Kongsberg EM712 system. By offering a user-friendly interface that supports common sonar tests, Kluster enables field professionals and scientists alike to easily evaluate and verify sonar system data, making it a valuable asset for marine data collection operations.
2.3. Automating Hydrographic Data Review for Nautical Cartography
Hydrographic data reviews involve a meticulous process that includes human error risks and substantial time investments. Masetti et al. [6] address these issues by introducing automated review tools that incorporate NOAA’s hydrographic specifications, providing a standardized and efficient solution for hydrographic offices. These tools—named QC Tools and CA Tools—accelerate the data review process and improve reproducibility, serving as a model for conducting automated data reviews across the hydrographic community. This development marks a significant step forward in processing efficiency and data quality, improving navigation safety.
3. Bathymetric Modeling: Data Fusion and Interpolation
3.1. Automating Historical Data Compilation with Shom’s Téthys Workflow
The French Hydrographic Service, Shom, has compiled over 300 years of data into an automated workflow known as Téthys. Le Deunf et al. [7] detail how this workflow integrates historical data from multiple sources, enhancing the accuracy of nautical charts by consolidating bathymetric data. The project emphasizes the importance of data fusion and ensures that modern digital models leverage centuries of seafloor data for current applications, demonstrating the importance of historical continuity in hydrographic sciences.
3.2. Multigrid/Multiresolution Interpolation to Reduce Data Artifacts
Traditional interpolation techniques often create artifacts such as over-smoothing in regions with a high data density. Rodriguez-Perez and Sanchez-Carnero [8] tackle this with a new multigrid interpolation approach that dynamically adapts to the data density, ensuring detail preservation in data-dense regions and achieving a smoother surface where data are sparse. This methodology allows for the creation of accurate digital elevation models (DEMs), improving seafloor mapping accuracy and providing realistic error estimations for applications like hazard mapping and habitat analysis.
3.3. Denmark’s Digital Bathymetric Model
In a comprehensive mapping of Danish waters, Masetti et al. [9] compile a 50 m resolution bathymetric model using datasets spanning decades. This model serves multiple purposes, from environmental management to infrastructure development, highlighting the value of accessible, high-resolution bathymetric models in marine policy and planning. This digital bathymetric model (DBM) also offers web access through the Danish Geodata Agency, illustrating how data transparency and accessibility are integral to effective spatial planning. Notably, the insights and methodologies presented in this work provided a foundational basis for the authors’ subsequent article detailing the release of an enhanced version the model, further refining its applications in marine and spatial planning [10].
3.4. Mapping the Kerguelen Plateau’s Tectonic and Bathymetric Structures
In an exploration of one of the world’s most remote plateaus, Lemenkova [11] integrates satellite and marine geophysical datasets to map the complex structures within the Kerguelen Plateau. This study sheds light on the plateau’s tectonic history and heterogeneous seafloor composition, enriching our scientific understanding of marine geology. By overlaying magnetic, gravitational, and topographic data, this study exemplifies how advanced cartographic techniques can elucidate the geological development of underwater landforms.
4. Spatial Planning and Machine Learning for Habitat Classification
4.1. Smart Marine Ecosystem-Based Planning (SMEP) for Greece
Recognizing the importance of data-driven marine governance, Contarinis et al. [12] introduce the SMEP framework, a spatial planning approach tailored to Greek marine ecosystems. The model emphasizes the importance of iterative planning cycles and continuous environmental monitoring to ensure sustainable development. SMEP brings together ecological data and human activity metrics, fostering a comprehensive planning process that reflects Greece’s unique coastal environment. This approach aims to serve as a model for responsive, ecosystem-focused governance in high-activity marine zones worldwide.
4.2. Coastal Benthic Substrate Classification Using Machine Learning
Machine learning holds significant potential in marine habitat mapping, as shown by Labbé-Morissette et al. [13] in their comparative study of the application of supervised and unsupervised models to classify benthic substrates. By employing multibeam echosounder data from the St. Lawrence Estuary, this study not only advances ecological monitoring methods but also provides essential tools for resource management and conservation in coastal habitats. The findings reveal that supervised and unsupervised learning models both offer advantages, with Gaussian mixture models excelling in terms of their efficiency and classification accuracy.
5. Conclusions
This Special Issue of Geomatics presents an array of research on ocean mapping and nautical cartography with compelling results, reflecting the significant progress made in this field within recent years. The studies herein demonstrate that innovations in data processing, automation, high-resolution mapping, and ecological planning are not only advancing scientific understanding but are also improving the practical applications of such strategies across the maritime and environmental sectors. By addressing longstanding challenges such as data accuracy, coverage limitations, and the integration of historical datasets, these advancements are paving the way for a more comprehensive, accessible, and sustainable approach to marine spatial planning [14,15,16].
Future research into ocean mapping will likely continue to combine traditional data sources with emerging technologies like machine learning and satellite geophysics [17,18]. This convergence of technologies is essential in handling the immense and varied data required to map, monitor, and protect ocean ecosystems effectively. As the demand for accurate, high-resolution seafloor data grows, particularly in the context of climate change and resource management, the approaches presented in this Special Issue will serve as models for future research, policy-making, and applied marine sciences. Ultimately, the strides made in this Special Issue exemplify the need for a forward-thinking approach to oceanography, in which data-driven interdisciplinary efforts enhance our capacity to safeguard and sustainably manage the world’s oceans.
Conflicts of Interest
The authors declare no conflicts of interest.
References
- Winther, J.-G.; Dai, M.; Rist, T.; Hoel, A.H.; Li, Y.; Trice, A.; Morrissey, K.; Juinio-Meñez, M.A.; Fernandes, L.; Unger, S.; et al. Integrated ocean management for a sustainable ocean economy. Nat. Ecol. Evol. 2020, 4, 1451–1458. [Google Scholar] [CrossRef] [PubMed]
- Mayer, L.; Jakobsson, M.; Allen, G.; Dorschel, B.; Falconer, R.; Ferrini, V.; Lamarche, G.; Snaith, H.; Weatherall, P. The Nippon Foundation—GEBCO Seabed 2030 Project: The Quest to See the World’s Oceans Completely Mapped by 2030. Geosciences 2018, 8, 63. [Google Scholar] [CrossRef]
- Mayer, L. Uncrewed surface systems facilitating a new era of global ocean exploration. Int. Hydrogr. Rev. 2023, 29, 42–55. [Google Scholar] [CrossRef]
- Ryu, P.; Brown, D.; Arsenault, K.; Cho, B.; March, A.; Ali, W.H.; Charous, A.; Lermusiaux, P.F.J. A Wide-Area Deep Ocean Floor Mapping System: Design and Sea Tests. Geomatics 2023, 3, 290–311. [Google Scholar] [CrossRef]
- Younkin, E.; Umfress, S.H. Performing a Sonar Acceptance Test of the Kongsberg EM712 Using Open-Source Software: A Case Study of Kluster. Geomatics 2022, 2, 540–553. [Google Scholar] [CrossRef]
- Masetti, G.; Faulkes, T.; Wilson, M.; Wallace, J. Effective Automated Procedures for Hydrographic Data Review. Geomatics 2022, 2, 338–354. [Google Scholar] [CrossRef]
- Le Deunf, J.; Schmitt, T.; Keramoal, Y.; Jarno, R.; Fally, M. Automating the Management of 300 Years of Ocean Mapping Effort in Order to Improve the Production of Nautical Cartography and Bathymetric Products: Shom’s Téthys Workflow. Geomatics 2023, 3, 239–249. [Google Scholar] [CrossRef]
- Rodriguez-Perez, D.; Sanchez-Carnero, N. Multigrid/Multiresolution Interpolation: Reducing Oversmoothing and Other Sampling Effects. Geomatics 2022, 2, 236–253. [Google Scholar] [CrossRef]
- Masetti, G.; Andersen, O.; Andreasen, N.R.; Christiansen, P.S.; Cole, M.A.; Harris, J.P.; Langdahl, K.; Schwenger, L.M.; Sonne, I.B. Denmark’s Depth Model: Compilation of Bathymetric Data within the Danish Waters. Geomatics 2022, 2, 486–498. [Google Scholar] [CrossRef]
- Masetti, G.; Granding, P.S.; Langdahl, K.; Schwenger, L.M.; Kristmar, K.V. Denmark’s Depth Model version 2.0—Improved compilation of bathymetric data within the Danish waters. Int. Hydrogr. Rev. 2024, 30, 50–63. [Google Scholar] [CrossRef]
- Lemenkova, P. Seafloor and Ocean Crust Structure of the Kerguelen Plateau from Marine Geophysical and Satellite Altimetry Datasets. Geomatics 2023, 3, 393–426. [Google Scholar] [CrossRef]
- Contarinis, S.; Nakos, B.; Pallikaris, A. Introducing Smart Marine Ecosystem-Based Planning (SMEP)—How SMEP Can Drive Marine Spatial Planning Strategy and Its Implementation in Greece. Geomatics 2022, 2, 197–220. [Google Scholar] [CrossRef]
- Labbé-Morissette, G.; Leclercq, T.; Charron-Morneau, P.; Gonthier, D.; Doiron, D.; Chouaer, M.-A.; Munang, D.N. Classification of Coastal Benthic Substrates Using Supervised and Unsupervised Machine Learning Models on North Shore of the St. Lawrence Maritime Estuary (Canada). Geomatics 2024, 4, 237–252. [Google Scholar] [CrossRef]
- Lecours, V.; Oxton, A.; Khor, D.; Tiplea, J. High-Resolution Ensemble Modelling of Coral Distributions in the Northern Gulf of Mexico Based on Geomorphometry: Coral Diversity and Benthic Habitat Fragmentation From Oil and Gas Infrastructure to Inform Spatial Planning. Aquat. Conserv. Mar. Freshw. Ecosyst. 2024, 34, e4234. [Google Scholar] [CrossRef]
- Sowers, D.C.; Mayer, L.A.; Masetti, G.; Cordes, E.; Gasbarro, R.; Lobecker, E.; Cantwell, K.; Candio, S.; Hoy, S.; Malik, M.; et al. Mapping and Geomorphic Characterization of the Vast Cold-Water Coral Mounds of the Blake Plateau. Geomatics 2024, 4, 17–47. [Google Scholar] [CrossRef]
- Church, I.W. Multibeam Sonar Ray-Tracing Uncertainty Evaluation from a Hydrodynamic Model in a Highly Stratified Estuary. Mar. Geod. 2020, 43, 359–375. [Google Scholar] [CrossRef]
- Elmore, P.; Calder, B.; Petry, F.; Masetti, G.; Yager, R. Aggregation Methods Using Bathymetry Sources of Differing Subjective Reliabilities for Navigation Mapping. Mar. Geod. 2023, 46, 99–128. [Google Scholar] [CrossRef]
- Parrish, C.E.; Magruder, L.; Herzfeld, U.; Thomas, N.; Markel, J.; Jasinski, M.; Imahori, G.; Herrmann, J.; Trantow, T.; Borsa, A.; et al. ICESat-2 Bathymetry: Advances in Methods and Science. In Proceedings of the OCEANS 2022, Hampton Roads, VA, USA, 17–20 October 2022; pp. 1–6. [Google Scholar]
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Masetti, G.; Church, I.; Hiroji, A.; Andersen, O. Advancements in Ocean Mapping and Nautical Cartography. Geomatics 2024, 4, 433-436. https://doi.org/10.3390/geomatics4040023
AMA Style
Masetti G, Church I, Hiroji A, Andersen O. Advancements in Ocean Mapping and Nautical Cartography. Geomatics. 2024; 4(4):433-436. https://doi.org/10.3390/geomatics4040023
Chicago/Turabian StyleMasetti, Giuseppe, Ian Church, Anand Hiroji, and Ove Andersen. 2024. "Advancements in Ocean Mapping and Nautical Cartography" Geomatics 4, no. 4: 433-436. https://doi.org/10.3390/geomatics4040023
APA StyleMasetti, G., Church, I., Hiroji, A., & Andersen, O. (2024). Advancements in Ocean Mapping and Nautical Cartography. Geomatics, 4(4), 433-436. https://doi.org/10.3390/geomatics4040023
