Surface Water and Ocean Topography

Surface Water and Ocean Topography
SWOT spacecraft model.png
SWOT satellite
NamesSWOT
Mission typeHydrology, Oceanography
OperatorNASA / CNES
COSPAR ID Edit this at Wikidata
Mission duration3 years (planned)
Spacecraft properties
Spacecraft typeSurface Water and Ocean Topography
BusSWOT
ManufacturerThales Alenia Space
Launch mass2000 kg
Start of mission
Launch date5 December 2022 (planned)
RocketFalcon 9
Launch siteVandenberg, SLC-4E
ContractorSpaceX
Orbital parameters
Reference systemGeocentric orbit
RegimeLow Earth orbit
Periapsis altitude857 km (533 mi)
Apoapsis altitude857 km (533 mi)
Inclination77.6°
Period112.42 minutes
 

The Surface Water and Ocean Topography (SWOT) mission is a future satellite altimeter jointly developed by NASA and CNES, the French space agency, in partnership with the Canadian Space Agency (CSA) and UK Space Agency (UKSA). The objectives of the mission are to make the first global survey of the Earth's surface water, to observe the fine details of the ocean surface topography, and to measure how terrestrial surface water bodies change over time. While past satellite missions like the Jason series altimeters (TOPEX/Poseidon, Jason-1, Jason-2, Jason-3) have provided variation in river and lake water surface elevations at select locations, SWOT will provide the first truly global observations of changing water levels, slopes, and inundation extents in rivers, lakes, and floodplains. In the world's oceans, SWOT will observe ocean circulation at unprecedented scales of 15–25 km (9.3–15.5 mi), approximately an order of magnitude finer than current satellites. Because it uses wide-swath altimetry technology, SWOT will almost completely observe the world's oceans and freshwater bodies with repeated high-resolution elevation measurements, allowing observations of variations.

Context

SWOT builds on a long-standing partnership between NASA and CNES to measure the surface of the ocean using radar altimetry. This partnership began with the TOPEX/Poseidon mission (launched in 1992), and continued with the Jason series. SWOT brings together the hydrology and oceanography communities, and will extend the precise, high-resolution surface topography observations into the coastal and estuarine regions.

Scientific objectives

The mission's science goals are to:

  • Provide sea surface heights and terrestrial water heights over a 120 km (75 mi) wide swath with a ±10 km (6.2 mi) gap at the nadir track.
  • Over the deep oceans, provide sea surface heights within each swath with a posting every 2 × 2 km (1.2 × 1.2 mi), and a precision not to exceed 2.7 cm (1.1 in) at 1 × 1 km (0.62 × 0.62 mi), or 1.35 cm (0.53 in) at 2 × 2 km (1.2 × 1.2 mi) when averaged over the area.
  • Over land, download the raw data for ground processing and produce a water mask able to resolve 100 m (330 ft) wide rivers and (250 m2 (2,700 sq ft)) lakes and reservoirs. Associated with this mask will be water level elevations with an accuracy of 10 cm (3.9 in) for water bodies whose non-vegetated surface area exceeds 1 km2 (0.39 sq mi). The slope accuracy is 1.7 cm (0.67 in)/km over a maximum 10 km (6.2 mi) of flow distance.
  • The satellite will overfly Earth from 78° S to 78° N, covering at least 86% of the globe.

SWOT is designed for a mission lifetime of three years.

Mission

SWOT is designed for the study and monitoring of inland waters and the oceans, such as:

Management of water sharing issues

The sharing of river water often causes friction between neighboring states, especially when there is no common technology for verification. SWOT will provide global information as input for systems monitoring transboundary river basins, including measurements of variations in reservoir water storage and estimates of river discharge.

More accurate weather and climate forecasting

SWOT will enable more accurate weather and climate forecasting, especially seasonally. The quality of weather and climate forecasting largely depends on numerical modeling that uses the state of the ocean surface and the hydrological conditions of catchment areas in their initial and boundary conditions.

Managing freshwater for urban, industrial and agricultural consumption

Accurate knowledge of sources of available water is a key factor in decision-making for organizations involved in the distribution of water for agricultural, urban and industrial needs. Data from SWOT will contribute at a global level by providing water supply services and distribution companies with information about major reservoirs and the largest rivers and catchment areas, thus enabling them to plan the management of water stocks further into the future.

Improved flood modeling

Flooding, whether from rivers overflowing their banks or in coastal regions, is among the most costly natural disasters. Altimetry data from the SWOT mission will make it possible to measure the 3-dimensional shape of flood waves, track floodwater levels, and improve measurements of local topographic details in floodplains. All of these will improve prediction capabilities for future floods.

Coastal ocean dynamics

Coastal ocean dynamics are important for many societal applications. They have smaller spatial and temporal scales than the dynamics of the open ocean and require finer-scale monitoring. SWOT will provide global, high-resolution observations in coastal regions for observing coastal currents and storm surges. While SWOT is not designed to monitor the fast temporal changes of the coastal processes, the swath coverage will allow us to characterize the spatial structure of their dynamics when they occur within the swath.

Reducing environmental risk and contributing to public policy-making

More generally, SWOT will help improve our knowledge of Earth's water cycle and ocean circulation, enhance our observation capacity by collecting unique data on water storage and fluxes and making them freely available, and help us better understand the physics that drives surface water and ocean dynamics. Water resources, natural risks (floods, climate change, hurricane forecasting, etc.), biodiversity, health (preventing the propagation of water-borne diseases), the agricultural sector, energy (including the management of electricity production and offshore gas and oil rigs), territorial development; all these areas and more stand to benefit from this new satellite mission.

Satellite characteristics

Diagram of SWOT data collection
Diagram of SWOT data collection

The primary instrument on SWOT is the Ka-band Radar Interferometer (KaRIn), which uses radar interferometry and synthetic-aperture radar (SAR) technology. Because SWOT operates at relatively short wavelengths (compared to the Ku-band Jason series) and at near-nadir incidence angles (<5°), it is designed to be uniquely appropriate for measuring water surface elevations and inundation extents. The satellite will fly two radar antennas at either end of a 10 m (33 ft) mast, allowing it to measure the elevation of the surface across a 120 km (75 mi) wide swath. The new radar system is smaller but similar to the one that flew on NASA's Shuttle Radar Topography Mission, which made high-resolution measurements of Earth's land surface in 2000. A conventional nadir altimeter will also be flown, and measure just beneath the satellite, as was done on the Topex/Poseidon, Jason series and SARAL missions.

Project status

SWOT is being developed by an international group of hydrologists and oceanographers to provide a better understanding of the world's oceans and its terrestrial surface waters. It will give scientists their first comprehensive view of Earth's freshwater bodies from space and much more detailed measurements of the ocean surface than ever before. As of summer 2019, the mission hardware is under active construction, algorithms to produce hydrology and oceanography data products are under final development, and calibration/validation methods and post-launch activities are being finalized. Launch on a SpaceX Falcon 9 launch vehicle is currently planned for 5 December 2022.

Mating

Mating of SWOT Payload on satellite platform made in Thales Alenia Space Cannes Center

The mating of the payload made by Jet Propulsion Laboratory (JPL) took place on 11 August 2021 at Thales Alenia Space Cannes Center, France.

See also


This page was last updated at 2022-08-27 05:03 UTC. Update now. View original page.

All our content comes from Wikipedia and under the Creative Commons Attribution-ShareAlike License.


Top

If mathematical, chemical, physical and other formulas are not displayed correctly on this page, please useFirefox or Safari