ICIT Mapping maerl habitats using autonomous sensors Malcolm Thomson International Centre for Island Technology (ICIT) Heriot Watt University Old Academy.

Slides:

Advertisements

Similar presentations

Yakama Nation Pacific Lamprey Recovery Project Core Data And Monitoring Framework.

Advertisements

Tasks and selected results of the project „Ecosystem approach to marine spatial planning – Polish marine areas and the Natura 2000 network” Department.

A Methodology for Simultaneous Retrieval of Ice and Liquid Water Cloud Properties O. Sourdeval 1, L. C.-Labonnote 2, A. J. Baran 3, G. Brogniez 2 1 – Institute.

The effect of plant coverage on macro- invertebrate density and diversity in the intertidal zone Sarah Park, Bailey Shuttleworth Cucinelli, James Holobow,

Mapping Benthic Habitats in the Fal Estuary A Geophysical Investigation by Group 9 Background Information The Fal estuary was sampled because it contains.

Adapting Ocean Surveys to the Observed Fields Characteristics Maria-João Rendas I3S, CNRS-UNSA.

UNEP Coral Reef Unit Division of Environmental Conventions c/o UNEP-World Conservation Monitoring Centre Monitoring of coral reefs.

Coral Reef Habitat Monitoring Ecosystem based management requires multifaceted monitoring Habitat = benthos + water column Coral reef ecosystems ≈ 0 –

Spatial Abundance of Permeable Sediment on the Eastern US Continental Shelf Patricia L. Wiberg 1 and Chris Jenkins 2 1 Environmental Sciences, University.

Coral Reefs. General description Global distribution.

Characterization of Mesophotic Coral Reefs Using the Seabed AUV Roy A. Armstrong 1 and Hanumant Singh 2 1 Bio-optical Oceanography Laboratory, Deapartment.

Intra- and inter-habitat variation in macroalgae and coral diversity in the Bahamas Biosciences, University of Exeter, Exeter Abstract Macroalgae and coral.

Spatial and Temporal Variation of Epiphytic Growth on Zostera marina Tara Seely* and Mike Kennish** *Department of Earth and Planetary Science, Washington.

1 Quantifying Opinion about a Logistic Regression using Interactive Graphics Paul Garthwaite The Open University Joint work with Shafeeqah Al-Awadhi.

Sonar Chapter 9. History Sound Navigation And Ranging (SONAR) developed during WW II –Sound pulses emitted reflected off metal objects with characteristic.

Nice, 17/18 December 2001 Autonomous mapping of natural fields using Random Closed Set Models Stefan Rolfes, Maria Joao Rendas

1 Malcolm Thomson International Centre for Island Technology Heriot Watt University(Orkney Campus) Old Academy Stromness Orkney Scotland, UK SUMARE Workshop:

Timed. Transects Statistics indicate that overall species Richness varies only as a function of method and that there is no difference between sites.

21 / 06 / 2000Segmentation of Sea-bed Images.1 Josepha UNIA Ecole Centrale de Lyon.

International Centre for Island Technology Heriot-Watt University (Orkney Campus) Old Academy Stromness Orkney Scotland The distribution of maerl around.

Predicting the distribution of maerl By Malcolm Thomson International Centre for Island Technology Heriot-Watt University (Orkney Campus) Old Academy Stromness.

The Global Digital Elevation Model (GTOPO30) of Great Basin Location: latitude 38  15’ to 42  N, longitude 118  30’ to 115  30’ W Grid size: 925 m.

Measuring abiotic components  Objectives  To make an exhaustive list of abiotic factors  To discuss the ways they are measured  To critically appraise.

The Biosphere Sub topic (a) Investigating an Ecosystem NameTeacher.

SFCC Walkover Habitat Survey Training Course July 2015.

Comparing manual and computer assisted benthic cover estimations from underwater imagery for offshore wind-farms assessment Aleksej Šaškov 1 *, Thomas.

Nicole Hill*, E Lawrence, J Dambacher, A Williams, N Barrett, J Hulls, B Barker, S Nichol, V Lucieer, F Althaus, J Kool and K R Hayes Designing long-term.

Non-destructive Biodiversity Monitoring of Marine Protected Areas A flying array using High Definition Video Prof Martin J Attrill Director, Plymouth University.

Acoustic Ground Discrimination Systems (AGDS) Fast mapping of sublittoral habitats without limitations due to turbidity based on the Procedural Guideline.

Using spectral data to discriminate land cover types.

Mapping the Impacts of Marine Debris Left in the Wake of Hurricane Katrina 61 st Interdepartmental Hurricane Conference 7 March, 2007 Brendan M. Bray NOAA.

Saco Bay Scallop Stock Enhancement Project A Collaboration: Northwest Atlantic Marine Alliance Local fishermen University of New England Maine Sea Grant.

Forward-Scan Sonar Tomographic Reconstruction PHD Filter Multiple Target Tracking Bayesian Multiple Target Tracking in Forward Scan Sonar.

Ecology An introduction to the study of the relationships between living things and their environments.

Summary Euphausiids (krill) are important food items of fish, seabirds and whales: consequently, it is important to understand their seasonal cycles. The.

GIS mapping and analysis of queen conch (Strombus gigas) stock abundance surveys in Puerto Rico Anthony R. Marshak and Richard S. Appeldoorn Department.

Kelley Bostrom University of Connecticut NASA OCRT Meeting May 12, 2010.

BOT / GEOG / GEOL 4111 / Field data collection Visiting and characterizing representative sites Used for classification (training data), information.

Wave Exposure and its Effects on the Diversity of a Shoreline Anne Haley, Lauren Jonah, Riki Krentz, Jessica Hingley & Caroline Méthé.

The Subtidal1 Life on the Continental Shelf. The Subtidal2 The Continental Shelf.

Remote Sensing Theory & Background III GEOG370 Instructor: Yang Shao.

Ecological Techniques Quadrats, Transects and Measuring Abiotic Factors.

Geophysical Practical - Habitat Mapping - Falmouth Harbour, UK – 3 rd July Group 8 Aims: To survey the seabed of Falmouth Harbour in a position.

Thresholding Foundation:. Thresholding In A: light objects in dark background To extract the objects: –Select a T that separates the objects from the.

1 Northwest National Marine Renewable Energy Center 031, ,TID Far-field Effects of Tidal Energy Extraction in Puget Sound Brian Polagye PhD Candidate.

OMSAP Public Meeting September 1999 Nearfield Hard-bottom Benthic Communities Barbara Hecker Hecker Environmental September 23, 1999.

Use a survey design Yes11 No3 Skipped4 Random designs for choosing transects –Random drift, towed gear, ROV Stratified to spread out sampling Habitat basis.

Unit 3 Investigative Biology. SQA Success Criteria  Explain the difference between random sampling, systematic sampling and stratified sampling.

ALEXANDRU – VLAD LAZAR 1, GHEORGHE – VIOREL UNGUREANU 1,2, ALEXANDRU – DAN IONESCU 1, ANDREI – DANIEL BALAHURA 1*, ROBERT LAZAR 1, ALEXANDRU MAGHER 1 1.

Objective Two classic theories attempt to explain how natural communities assemble: Gleason’s Individualistic model and Clements’ Organismic model. To.

Introduction Coral reefs are a vital marine resource for Cook Islanders, yielding a variety of foods, supporting sustainable tourism and providing coastal.

High-Resolution Determination of Coral Reefs using Fluorescence Imagery Laser Line Scanner (FILLS)

Forest ecological applications of ALS ALS provide 3D information where each point has height (and intensity) value Even with low pulse density data, say,

The distribution of ostebund aggregations (Porifera) in relation to oceanographic processes in the Faroe-Shetland Channel. Joshua Davison1, Nils Piechaud1,

Winter Flounder Spawning Areas in New Haven Harbor

Introduction to Spatial Statistical Analysis

Use of PSA data in biological studies

Developments in Seabed Mapping

Charlotte Levy1 & Eloise Brown2

DIGITAL SIGNAL PROCESSING

Geophysics Benthic Habitat Mapping in the Mouth of the Helford Estuary

Management Zones Starr Holtz SOIL 4213 April 26, 2006.

“grabcut”- Interactive Foreground Extraction using Iterated Graph Cuts

Questions Do fish species differ in relative abundance as a function of zone (shallow, deep) This should be in the context of a specific set of predictions.

Grouping/Segmentation

Predicting the distribution of maerl

Segmentation of Sea-bed Images.

Mosaic artifacts reduction in SIPS Backscatter

Presentation transcript:

ICIT Mapping maerl habitats using autonomous sensors Malcolm Thomson International Centre for Island Technology (ICIT) Heriot Watt University Old Academy Stromness Orkney UK KW16 3AW

ICIT Maerl habitats Under ambient light

ICIT Under artificial light

ICIT 50 meters “patches” of living and dead maerl are natural features of maerl beds Taking a step back...

ICIT Environmental requirements Moderate tidal currents, ms -1 Light - occurs in depths generally less than 30 m Shelter from wave exposure –sheltered bays and sounds Orkney Islands - numerous shallow tidal channels where maerl is abundant

ICIT Why is maerl interesting? Commercial value –soil conditioner –water filtration and purification –food additive –cosmetics –bone surgery Conservation value –provides a substrate for other flora and fauna –high species richness –high productivity –nursery area –recognised under EU Habitats Directive (92/43/EEC)

ICIT Why map maerl? Extraction –need to know production rate in order to calculate sustainable extraction rate –to calculate production rate need, inter alia: area of living maerl on the seabed –locate extraction site in areas of predominantly dead material Conservation –delineate boundaries of maerl bed –status of a maerl bed, e.g. is it actively growing or a relict (dead) bed how much living maerl occurs at a site –bed dynamics how it interacts with local environmental conditions, e.g. tidal currents, depth, wave exposure

ICIT Traditional maerl survey Side scan sonar –RoxAnn survey –not able to measure living or dead deposits directly Grab samples Video –diver –towed sled –difficult to manually estimate areas –time consuming data analysis

ICIT SUMARE: aims of maerl application Prove the use of autonomous sensors in mapping the occurrence of maerl in Wyre Sound, Orkney –estimate the area of seabed covered by living and dead maerl at different sites –capture variation in the small-scale distribution of maerl between different sites Applications in the sustainable extraction of maerl as a commercial resource, and in long-term conservation of maerl as an important marine habitat.

ICIT Survey area - Wyre Sound ~ 5 x 1 km Depth m Water currents up to 1.5 ms -1 1 km

ICIT Large bank of dead maerl visible from air

ICIT Existing knowledge for Wyre Sound Site specific data from the MNCR conducted by the Joint Nature Conservation Committee (JNCC) No indication of the distribution of maerl over large areas Initial assumptions that living maerl occurred in large patches with distinct boundaries (proved to be false - required modification of contouring method)

ICIT Methods Video survey using ROV Phantom –image segmentation –contour following

ICIT Image segmentation Aim to develop an algorithm which would automatically distinguish maerl features and segment video footage accordingly Based on segmentation, possible to estimate the area coverage of different maerl features which appear in the video footage. –living maerl –dead maerl –sand & macroalgae

ICIT Image segmentation (cont.) Maerl features distinguished using their greyscale characteristics Image is split into different segments using a segmentation algorithm - each segment has significantly different greyscale attributes

ICIT Segmentation according to greyscale in a unit of 12 x 12 pixels

ICIT Image segmentation (cont.) Manual analysis of segmented images –assign labels to different segments living maerl dead maerl The area of each label can then be quantified for a given piece of footage Dead maerl mixture Living maerl

ICIT Total area / m2= Transect length / m= 44.4 % area Living maerl= 64.6 Dead maerl= 21.2 Mix= 14.2 Macroalgae= -

ICIT Total area / m2= Transect length / m= 44.8 % area Living maerl= 34.7 Dead maerl= 45.8 Mix= 19.5 Macroalgae= -

ICIT Total area / m2= Transect length / m= 61.5 % area Living maerl= 34.4 Dead maerl= 65.6 Mix= - Macroalgae= -

ICIT Image segmentation (cont.) Rough segmentation occurs in real time, while ROV is collecting video footage Post-processing involves labelling of segments –Adjustment of segmentation –labelling may vary between sites or depending on local conditions of depth, light availability produces area estimates for living/dead maerl at different sites Ground-truthing –requires manual check of mosaic to confirm segmentation –diver survey for set area (not performed) Sources of error –other features may be captured in segmentation living maerl - macroalgae dead maerl - sand

ICIT Image segmentation (cont.) Presentation of data –graphs, used to show how the % of different features varies along the length of a transect –maps, used to show how the % of single features varies between different sites

ICIT Image segmentation (cont.)

ICIT Image segmentation (cont.)

ICIT Image segmentation (cont.)

ICIT Image segmentation (cont.)

ICIT Image segmentation (cont.) Image segmentation allows “patch” characteristics to be examined –patch perimeter –patch width –patch intensity Link patch characteristics with environmental variables –tidal current strength –depth –wave exposure

ICIT Patch intensity

ICIT Rousay Wyre boolean area Patch area

ICIT Patch perimeter

ICIT Contour following Original idea was to follow boundaries around patches of living or dead maerl –abandoned, patches too small!! Contouring capability proved for a different marine habitat –seagrass bed - Villefranche sur Mer Contouring for maerl - still possible in a different context –mapping contours between regions of different statistical properties, e.g. intensity, area, perimeter of living patches of maerl –tested in theory

ICIT Conclusions Expanded knowledge of the 2D distribution of maerl on the seabed –first attempt to directly measure areas of living and dead maerl Data assimilation –extraction of maerl located areas of predominantly dead maerl where extraction should occur information on the amount of living maerl in the area - useful in calculation of extraction rate –maerl conservation significant occurrence of living maerl - actively growing site information on site boundaries statistical information on the distribution of maerl including small-scale patch characteristics, e.g. intensity, area, perimeter, to link to environmental variables