A multi-method approach for benthic habitat mapping of shallow coastal areas with high-resolution multibeam data

Micallef, Aaron; Bas, Tim Le; Huvenne, Veerle A.I.; Blondel, Philippe; Hühnerbach, Veit; Deidun, Alan

doi:10.1016/j.csr.2012.03.008

Cited by 145 publications

(114 citation statements)

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“…The more general term "multi-scale" is used in this paper to refer to both types of analysis as well as geomorphometric analysis using data of different resolutions. (Lundblad et al, 2006;Lanier et al, 2007;Micallef et al, 2012a;Dolan and Lucieer, 2014) Aspect (Galparsoro et al, 2009), northness/northerness and eastness/easterness (Monk et al, 2011) Mean curvature (Dolan et al, 2008); profile curvature (Guinan et al, 2009); plan/planimetric curvature (Ross et al, 2015); Bathymetric Position Index (BPI) (Monk et al, 2010;Pirtle et al, 2015) Rugosity (Dunn and Halpin, 2009); vector ruggedness measure (VRM) (Tempera et al, 2012); relative relief (Elvenes, 2013); fractal dimension (Wilson et al, 2007) Commonly used terrain attribute and software (algorithm reference)…”

Section: General Geomorphometry (Terrain Attributes)mentioning

confidence: 99%

A review of marine geomorphometry, the quantitative study of the seafloor

Lecours

Dolan

Micallef

et al. 2016

Hydrol. Earth Syst. Sci.

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Abstract. Geomorphometry, the science of quantitative terrain characterization, has traditionally focused on the investigation of terrestrial landscapes. However, the dramatic increase in the availability of digital bathymetric data and the increasing ease by which geomorphometry can be investigated using geographic information systems (GISs) and spatial analysis software has prompted interest in employing geomorphometric techniques to investigate the marine environment. Over the last decade or so, a multitude of geomorphometric techniques (e.g. terrain attributes, feature extraction, automated classification) have been applied to characterize seabed terrain from the coastal zone to the deep sea. Geomorphometric techniques are, however, not as varied, nor as extensively applied, in marine as they are in terrestrial environments. This is at least partly due to difficulties associated with capturing, classifying, and validating terrain characteristics underwater. There is, nevertheless, much common ground between terrestrial and marine geomorphometry applications and it is important that, in developing marine geomorphometry, we learn from experiences in terrestrial studies. However, not all terrestrial solutions can be adopted by marine geomorphometric studies since the dynamic, fourdimensional (4-D) nature of the marine environment causes its own issues throughout the geomorphometry workflow. For instance, issues with underwater positioning, variations in sound velocity in the water column affecting acousticbased mapping, and our inability to directly observe and measure depth and morphological features on the seafloor are all issues specific to the application of geomorphometry in the marine environment. Such issues fuel the need for a dedicated scientific effort in marine geomorphometry.This review aims to highlight the relatively recent growth of marine geomorphometry as a distinct discipline, and offers the first comprehensive overview of marine geomorphometry to date. We address all the five main steps of geomorphometry, from data collection to the application of terrain attributes and features. We focus on how these steps are relevant to marine geomorphometry and also highlight differences and similarities from terrestrial geomorphometry. We conclude with recommendations and reflections on the future of marine geomorphometry. To ensure that geomorphometry is used and developed to its full potential, there is a need to increase awareness of (1) marine geomorphometry amongst scientists already engaged in terrestrial geomorphometry, and of (2) geomorphometry as a science amongst marine scientists with a wide range of backgrounds and experiences.

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Section: General Geomorphometry (Terrain Attributes)mentioning

confidence: 99%

A review of marine geomorphometry, the quantitative study of the seafloor

Lecours

Dolan

Micallef

et al. 2016

Hydrol. Earth Syst. Sci.

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178

120

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“…Acoustic habitat mapping has become a major tool for evaluating the status of coastal ecosystems. This technique is also commonly used in marine spatial planning, resource assessment and offshore engineering (Micallef et al, 2012). Traditional sampling methods can only provide a snapshot that covers a fraction of the seafloor area (Harper et al, 2010), while acoustic mapping technologies are capable of efficiently capturing images across large areas of the seabed (Huang et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Conventionally, MBES data sets of seabed geological features have been manually interpreted by experts or using simplified substrate classification methods developed for single beam echosounder. Recently developed quantitative computational techniques can transform spatially complex bathymetric and backscatter data of large areas into simple, easily visualized maps that provide the end users with abundant information (Micallef et al, 2012). Driven by the advances in objective classification algorithms, a variety of automated methods have been developed and tested (Brown et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Acoustic mapping and classification of benthic habitat using unsupervised learning in artificial reef water

Tang

Xia

et al. 2017

Estuarine, Coastal and Shelf Science

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a b s t r a c tArtificial reefs (ARs) are effective means to maintain fishery resources and to restore ecological environment in coastal waters. ARs have been widely constructed along the Chinese coast. However, understanding of benthic habitats in the vicinity of ARs is limited, hindering effective fisheries and aquacultural management. Multibeam echosounder (MBES) is an advanced acoustic instrument capable of efficiently generating large-scale maps of benthic environments at fine resolutions. The objective of this study is to develop a technical approach to characterize, classify, and map shallow coastal areas with ARs using an MBES. An automated classification method is designed and tested to process bathymetric and backscatter data from MBES and transform the variables into simple, easily visualized maps. To reduce the redundancy in acoustic variables, a principal component analysis (PCA) is used to condense the highly collinear dataset. An acoustic benthic map of bottom sediments is classified using an iterative self-organizing data analysis technique (ISODATA). The approach is tested with MBES surveys in a 1.15 km 2 fish farm with a high density of ARs off the Yantai coast in northern China. Using this method, 3 basic benthic habitats (sandy bottom, muddy sediments, and ARs) are distinguished. The results of the classification are validated using sediment samples and underwater surveys. Our study shows that the use of MBES is an effective method for acoustic mapping and classification of ARs.

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“…Moreover, underwater imaging is an important tool to understand geological and biological processes taking place on the seafloor, providing scientists with high levels of detail and the ease of interpretation. Underwater 3D mapping has normally been carried out by acoustic multibeam sensors or side scan sonar (Paul et al, 2011;Micallef et al, 2012;Montefalcone et al, 2013;Campos et al, 2014). However, the information provided by acoustic devices is normally gathered in the form of elevation maps, which are useful for providing a rough approximation of the global shape of the area, but are inadequate for detecting more complex structures, (Campos et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

PILOT APPLICATION OF 3D UNDERWATER IMAGING TECHNIQUES FOR MAPPING POSIDONIA OCEANICA (L.) DELILE MEADOWS

Rende

Irving

Lagudi

et al. 2015

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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ABSTRACT:Seagrass communities are considered one of the most productive and complex marine ecosystems. Seagrasses belong to a small group of 66 species that can form extensive meadows in all coastal areas of our planet. Posidonia oceanica beds are the most characteristic ecosystem of the Mediterranean Sea, and should be constantly monitored, preserved and maintained, as specified by EU Habitats Directive for priority habitats. Underwater 3D imaging by means of still or video cameras can allow a detailed analysis of the temporal evolution of these meadows, but also of the seafloor morphology and integrity. Video-photographic devices and open source software for acquiring and managing 3D optical data rapidly became more and more effective and economically viable, making underwater 3D mapping an easier task to carry out. 3D reconstruction of the underwater scene can be obtained with photogrammetric techniques that require just one or more digital cameras, also in stereo configuration. In this work we present the preliminary results of a pilot 3D mapping project applied to the P. oceanica meadow in the Marine Protected Area of Capo Rizzuto (KR, Calabria Region-Italy).

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A multi-method approach for benthic habitat mapping of shallow coastal areas with high-resolution multibeam data

Cited by 145 publications

References 50 publications

A review of marine geomorphometry, the quantitative study of the seafloor

A review of marine geomorphometry, the quantitative study of the seafloor

Acoustic mapping and classification of benthic habitat using unsupervised learning in artificial reef water

PILOT APPLICATION OF 3D UNDERWATER IMAGING TECHNIQUES FOR MAPPING POSIDONIA OCEANICA (L.) DELILE MEADOWS

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