The Balearic Islands Coastal Observing and Forecasting System (SOCIB) allows consulting the currently
deployed platforms, their performed trajectory, and the latest information transmitted by them
(by clicking on the icon over the map).
The Lagrangian platforms available at SOCIB include surface drifters (
SVP
and SVP-B,
Global Drifter Program - NOAA), and profiling floats (Argo
observational program). Surface drifters perform trajectories and provide information on surface currents.
In addition, they measure sea surface temperature and atmospheric pressure. Profiling floats provide vertical profiles
up to 2,000 meters, offering a quantitative description of water masses down to this depth, allowing the
identification of patterns of climate variability in the ocean on different time scales.
Dapp is a web based client application, developed by the SOCIB Data Center,
intended to display and download deployments data from SOCIB. Dapp provides additional features such as:
Browse and display any deployments made by SOCIB
Create customized maps with several deployments and WMS map layers
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
The drifters were designed and built at Hereon to follow the upper surface flow (upper ~ 50 cm). These Hereon drifter consist of a 20 cm x 7.5 cm long tube, with a floatation ring. Furthermore, a drogue of 35 cm in both length and diameter is attached, via a flexible cord, in a distance of 20 cm to the tube. When deployed about 5 cm. The instrument acquires and reports the GPS position via a global satellite network in near real time.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
The SVP Barometer (SVPB) drifter has the same capabilities of the SVP Drifter but it also carries a barometer to measure Sea Level Pressure (Centurioni et al. 2016; Horányi et al. 2016; Maximenko et al. 2013; Niiler 2001). The air pressure sensor can either be a High Precision Barometer (HPB) by Honeywell, stable over the two years long nominal lifespan of the drifters and with an accuracy of ±0.4hPa, or an Integrated Pressure Transducer (IPT), also by Honeywell that has similar specifications and accuracy.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Novel CARTHE drifter (low-cost, compact, practical, and eco-friendly) representative of the upper 0.60m (including Stokes drift), with minimal wave-rectification issues, with wind-induced slip velocity < 0.5% of the neutral wind speed at 10m.
Near real-time data accuracy and recommendations: Temperature and pressure data from the profiling floats have an accuracy of ± 0.002 °C and ± 2.4 dbar, respectively. The data delivered in real-time may be affected by sensor drift. For many floats, this drift is small, and the accuracy of uncorrected salinities is within ± .01 psu. At a later stage, salinity data are corrected by expert examination, comparing historical floats with newly deployed instruments and ship-based data. Corrections are made both for identified sensor drift and for a thermal lag error, which can result when the float ascends through a region of strong temperature gradients. For this reason and following the Argo community recommendation, real-time data should not be used for science studies sensitive to small pressure and salinity bias (e.g. calculations of global ocean heat content or mixed layer depth). Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Drifter ODi006 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi004 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi009 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi010 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Drifter ODi009 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi007 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi010 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi004 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi011 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi008 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi003 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi006 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
Drifter ODi005 to test IBI system in the frame of MEDESS MED Project. Drifter measurements will be used for model testing as well as for dispersion studies in the WM Sea.
The IRIDIUM Drifter (iDrifter) is a Lagrangian drifting buoy designed (patent pending) by the Marine Technologies, Operational Oceanograhy and Sustainability (TMOOS) department of IMEDEA in collaboration with SOCIB under the ETD Technology Development Division. This design reduces energy consumption and minimizes the size and weight of standard drifters (SVP and CODE) in order to minimize the threat for maritime traffic, increasing also its operational capabilities.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
The IRIDIUM Drifter (iDrifter) is a Lagrangian drifting buoy designed (patent pending) by the Marine Technologies, Operational Oceanograhy and Sustainability (TMOOS) department of IMEDEA in collaboration with SOCIB under the ETD Technology Development Division. This design reduces energy consumption and minimizes the size and weight of standard drifters (SVP and CODE) in order to minimize the threat for maritime traffic, increasing also its operational capabilities.
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
Original data are collected, processed and published by Coriolis. This dataset is only a subset of the one at Coriolis, and follows the SOCIB data convention. Please, find the full-original dataset through: "Argo (2022). Argo float data and metadata from Global Data Assembly Centre (Argo GDAC). SEANOE. https://doi.org/10.17882/42182".
This application is still under development.
This data output should not be used for navigational purposes.
It's been released for limited public use with appropiate caution.
For near real-time data only limited quality controls are performed.
Timely delivery of data and products is not guaranteed.
