A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling

Here we describe the design, performance and field tests of a lightweight (13.1 kg), low-cost (15.000 USD), and portable remotely operated vehicle (ROV) of dimensions 55 x 43 x 34 cm (L x H x W), with a new optical based positioning system. The ROV is designed for deployments and measurements of the...

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Published in:Cold Regions Science and Technology
Main Authors: Lund-Hansen, Lars Chresten, Juul, Thomas, Eskildsen, Tor Dam, Hawes, Ian, Sorrell, Brian, Melvad, Claus, Hancke, Kasper
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
ROV
Sea ice
Snow
Transmittance
NDI
Greenland
ARCTIC SEA-ICE
ANTARCTIC PACK ICE
LIGHT TRANSMISSION
ALGAL COMMUNITY
VARIABILITY
GROWTH
THICKNESS
REMOVAL
BIOMASS
Antarctic
Arctic
Kangerlussuaq
Antarc*
ice algae
Online Access:https://pure.au.dk/portal/da/publications/a-lowcost-remotely-operated-vehicle-rov-with-an-optical-positioning-system-for-underice-measurements-and-sampling(a282086b-cd85-4d7f-abc0-c0e18479d4db).html
https://doi.org/10.1016/j.coldregions.2018.03.017
id ftuniaarhuspubl:oai:pure.atira.dk:publications/a282086b-cd85-4d7f-abc0-c0e18479d4db
record_format openpolar
spelling ftuniaarhuspubl:oai:pure.atira.dk:publications/a282086b-cd85-4d7f-abc0-c0e18479d4db 2023-11-12T04:07:26+01:00 A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling Lund-Hansen, Lars Chresten Juul, Thomas Eskildsen, Tor Dam Hawes, Ian Sorrell, Brian Melvad, Claus Hancke, Kasper 2018-07 https://pure.au.dk/portal/da/publications/a-lowcost-remotely-operated-vehicle-rov-with-an-optical-positioning-system-for-underice-measurements-and-sampling(a282086b-cd85-4d7f-abc0-c0e18479d4db).html https://doi.org/10.1016/j.coldregions.2018.03.017 eng eng https://pure.au.dk/portal/da/publications/a-lowcost-remotely-operated-vehicle-rov-with-an-optical-positioning-system-for-underice-measurements-and-sampling(a282086b-cd85-4d7f-abc0-c0e18479d4db).html info:eu-repo/semantics/restrictedAccess Lund-Hansen , L C , Juul , T , Eskildsen , T D , Hawes , I , Sorrell , B , Melvad , C & Hancke , K 2018 , ' A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling ' , Cold Regions Science and Technology , vol. 151 , pp. 148-155 . https://doi.org/10.1016/j.coldregions.2018.03.017 ROV Sea ice Snow Transmittance NDI Greenland ARCTIC SEA-ICE ANTARCTIC PACK ICE LIGHT TRANSMISSION ALGAL COMMUNITY VARIABILITY GROWTH THICKNESS REMOVAL BIOMASS article 2018 ftuniaarhuspubl https://doi.org/10.1016/j.coldregions.2018.03.017 2023-10-25T22:59:31Z Here we describe the design, performance and field tests of a lightweight (13.1 kg), low-cost (15.000 USD), and portable remotely operated vehicle (ROV) of dimensions 55 x 43 x 34 cm (L x H x W), with a new optical based positioning system. The ROV is designed for deployments and measurements of the irradiance field at a short distance below sea ice bottom in landfast level sea ice at calm under ice conditions. It is equipped with two cameras (front and rear) for optical positioning based on reference poles with LED lights below the ice. A third upward camera is for guiding during deployment and positioning. The ROV is equipped with spacer poles to maintain a constant distance between ROV with onboard optical sensors and bottom of the ice. All pre-tests of housing, thrusters, optical positioning, and ROV maneuverability were carried out in freshwater basins prior to field trials and tests. These were conducted at Kangerlussuaq, West Greenland on landfast first-year 79-80 cm thick ice with a variable (1-12 cm) snow cover in March 2016. The ROV was easily deployed through a hole (75 x 50 cm) in the ice and easy to maneuver below the ice. Test of positioning system showed an average deviation of 28 +/- 5 cm between optically based position and actual position with an average offset from center line of 16 +/- 5 cm. The ROV was applied for measuring the under-ice irradiance field and results demonstrated a solid negative correlation between snow depth and PAR transmittance. We derived a Normalized Differences Index (NDI) for snow depths: NDIsnow (depth) = [E(610 nm) - E(490 nm)]/[E(610 nm) + E(490 nm)] with minimum attenuation at 490 nm and maximum at 610 nm. It is discussed that the correlations for both PAR transmittance and the NDI with snow depths are due to a combination of a constant distance between optical sensor and ice bottom, and accurate positioning. A test showed that the wakes of thrusters removed parts of the ice algae biomass, but the study demonstrates the applicability of this ROV design for ... Article in Journal/Newspaper Antarc* Antarctic Arctic Greenland ice algae Kangerlussuaq Sea ice Aarhus University: Research Antarctic Arctic Greenland Kangerlussuaq ENVELOPE(-55.633,-55.633,72.633,72.633) Cold Regions Science and Technology 151 148 155
institution Open Polar
collection Aarhus University: Research
op_collection_id ftuniaarhuspubl
language English
topic ROV
Sea ice
Snow
Transmittance
NDI
Greenland
ARCTIC SEA-ICE
ANTARCTIC PACK ICE
LIGHT TRANSMISSION
ALGAL COMMUNITY
VARIABILITY
GROWTH
THICKNESS
REMOVAL
BIOMASS
spellingShingle ROV
Sea ice
Snow
Transmittance
NDI
Greenland
ARCTIC SEA-ICE
ANTARCTIC PACK ICE
LIGHT TRANSMISSION
ALGAL COMMUNITY
VARIABILITY
GROWTH
THICKNESS
REMOVAL
BIOMASS
Lund-Hansen, Lars Chresten
Juul, Thomas
Eskildsen, Tor Dam
Hawes, Ian
Sorrell, Brian
Melvad, Claus
Hancke, Kasper
A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
topic_facet ROV
Sea ice
Snow
Transmittance
NDI
Greenland
ARCTIC SEA-ICE
ANTARCTIC PACK ICE
LIGHT TRANSMISSION
ALGAL COMMUNITY
VARIABILITY
GROWTH
THICKNESS
REMOVAL
BIOMASS
description Here we describe the design, performance and field tests of a lightweight (13.1 kg), low-cost (15.000 USD), and portable remotely operated vehicle (ROV) of dimensions 55 x 43 x 34 cm (L x H x W), with a new optical based positioning system. The ROV is designed for deployments and measurements of the irradiance field at a short distance below sea ice bottom in landfast level sea ice at calm under ice conditions. It is equipped with two cameras (front and rear) for optical positioning based on reference poles with LED lights below the ice. A third upward camera is for guiding during deployment and positioning. The ROV is equipped with spacer poles to maintain a constant distance between ROV with onboard optical sensors and bottom of the ice. All pre-tests of housing, thrusters, optical positioning, and ROV maneuverability were carried out in freshwater basins prior to field trials and tests. These were conducted at Kangerlussuaq, West Greenland on landfast first-year 79-80 cm thick ice with a variable (1-12 cm) snow cover in March 2016. The ROV was easily deployed through a hole (75 x 50 cm) in the ice and easy to maneuver below the ice. Test of positioning system showed an average deviation of 28 +/- 5 cm between optically based position and actual position with an average offset from center line of 16 +/- 5 cm. The ROV was applied for measuring the under-ice irradiance field and results demonstrated a solid negative correlation between snow depth and PAR transmittance. We derived a Normalized Differences Index (NDI) for snow depths: NDIsnow (depth) = [E(610 nm) - E(490 nm)]/[E(610 nm) + E(490 nm)] with minimum attenuation at 490 nm and maximum at 610 nm. It is discussed that the correlations for both PAR transmittance and the NDI with snow depths are due to a combination of a constant distance between optical sensor and ice bottom, and accurate positioning. A test showed that the wakes of thrusters removed parts of the ice algae biomass, but the study demonstrates the applicability of this ROV design for ...
format Article in Journal/Newspaper
author Lund-Hansen, Lars Chresten
Juul, Thomas
Eskildsen, Tor Dam
Hawes, Ian
Sorrell, Brian
Melvad, Claus
Hancke, Kasper
author_facet Lund-Hansen, Lars Chresten
Juul, Thomas
Eskildsen, Tor Dam
Hawes, Ian
Sorrell, Brian
Melvad, Claus
Hancke, Kasper
author_sort Lund-Hansen, Lars Chresten
title A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
title_short A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
title_full A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
title_fullStr A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
title_full_unstemmed A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling
title_sort low-cost remotely operated vehicle (rov) with an optical positioning system for under-ice measurements and sampling
publishDate 2018
url https://pure.au.dk/portal/da/publications/a-lowcost-remotely-operated-vehicle-rov-with-an-optical-positioning-system-for-underice-measurements-and-sampling(a282086b-cd85-4d7f-abc0-c0e18479d4db).html
https://doi.org/10.1016/j.coldregions.2018.03.017
long_lat ENVELOPE(-55.633,-55.633,72.633,72.633)
geographic Antarctic
Arctic
Greenland
Kangerlussuaq
geographic_facet Antarctic
Arctic
Greenland
Kangerlussuaq
genre Antarc*
Antarctic
Arctic
Greenland
ice algae
Kangerlussuaq
Sea ice
genre_facet Antarc*
Antarctic
Arctic
Greenland
ice algae
Kangerlussuaq
Sea ice
op_source Lund-Hansen , L C , Juul , T , Eskildsen , T D , Hawes , I , Sorrell , B , Melvad , C & Hancke , K 2018 , ' A low-cost remotely operated vehicle (ROV) with an optical positioning system for under-ice measurements and sampling ' , Cold Regions Science and Technology , vol. 151 , pp. 148-155 . https://doi.org/10.1016/j.coldregions.2018.03.017
op_relation https://pure.au.dk/portal/da/publications/a-lowcost-remotely-operated-vehicle-rov-with-an-optical-positioning-system-for-underice-measurements-and-sampling(a282086b-cd85-4d7f-abc0-c0e18479d4db).html
op_rights info:eu-repo/semantics/restrictedAccess
op_doi https://doi.org/10.1016/j.coldregions.2018.03.017
container_title Cold Regions Science and Technology
container_volume 151
container_start_page 148
op_container_end_page 155
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