TerraSAR-X

TerraSAR-X
Spacecraft properties

Mission type	Radar imaging
Operator	DLR
COSPAR ID	2007-026A
SATCAT №	31698

Manufacturer	EADS Astrium
Launch mass	1,230 kg (2,710 lb)

Start of mission
Launch date	15 June 2007, 02:14 (2007-06-15UTC02:14Z) UTC
Rocket	Dnepr
Launch site	Baikonur 109/95
Contractor	ISC Kosmotras

Orbital parameters
Reference system	Geocentric
Regime	Low Earth
Semi-major axis	6,886.39 kilometres (4,279.00 mi)^[1]
Eccentricity	0.0001445^[1]
Perigee	514 kilometres (319 mi)^[1]
Apogee	516 kilometres (321 mi)^[1]
Inclination	97.44 degrees^[1]
Period	94.79 minutes^[1]
Epoch	25 January 2015, 02:35:23 UTC^[1]

TerraSAR-X, a radar Earth observation satellite, is a joint venture being carried out under a public-private-partnership between the German Aerospace Center (DLR) and EADS Astrium. The exclusive commercial exploitation rights are held by the geo-information service provider Astrium. TerraSAR-X was launched on June 15, 2007 and has been in operational service since January 2008. With its twin satellite TanDEM-X, launched June 21, 2010, TerraSAR-X acquires the data basis for the WorldDEM, the worldwide and homogeneous DEM available from 2014.

Satellite and mission

Radar image

With its phased array synthetic aperture radar (SAR) antenna (X-band wavelength 31 mm, frequency 9.6 GHz), TerraSAR-X acquires new high-quality radar images of the entire planet whilst circling Earth in a polar orbit at 514 km altitude. The orbit is selected such that the satellite flies in a sun-synchronous dusk-dawn orbit, which means that it moves along the day-night boundary of the Earth and always presents the same face to the sun, ensuring an optimum energy supply via the solar cells. TerraSAR-X is designed to carry out its task for five years, independent of weather conditions and illumination, and reliably provides radar images with a resolution of up to 1m.

Features of TerraSAR-X:

resolution of up to 1 m,
excellent radiometric accuracy,
geometric accuracy unrivalled by any other commercial spaceborne sensor,
quick site access time of 2.5 days max. (2 days at 95% probability) to any point on Earth,
unique agility (rapid switches between imaging modes and polarisations)

TerraSAR-X imaging modes

TerraSAR-X acquires radar data in the following three main imaging modes:

SpotLight: up to 1 m resolution, scene size 10 km (width) × 5 km (length);
StripMap: up to 3 m resolution, scene size 30 km (width) × 50 km (length);
ScanSAR: up to 16 m resolution, scene size 100 km (width) × 150 km (length);^[2]

Wikimedia Commons has media related to TerraSAR-X.

In addition, the unique design of TerraSAR-X's SAR antenna allows a variety of polarimetric combinations: single or dual polarization and even full polarimetric data takes, are possible.

Depending on the desired application, one of four different product types (processing levels) can be selected

Single Look Slant Range Complex (SSC)
Multi Look Ground Range Detected (MGD)
Geocoded Ellipsoid Corrected (GEC)
Enhanced Ellipsoid Corrected (EEC)

TanDEM-X and WorldDEM Akida

TanDEM-X (TerraSAR-X add-on for Digital Elevation Measurements) is a second, very similar spacecraft launched successfully on June 21, 2010 from Baikonur Cosmodrome in Kazakhstan. Since October 2010, TerraSAR-X and TanDEM-X fly in a close formation at distances of only a few hundred metres and record data synchronously.^[3] This unique twin satellite constellation will allow the generation of WorldDEM, the global digital elevation models (DEMs). With an unprecedented accuracy, coverage and quality – WorldDEM is a consistent DEM of the Earth’s land surface is envisaged to be acquired and generated within three years after launch. Available from 2014, WorldDEM is to feature a vertical accuracy of 2m (relative) and 10m (absolute), within a horizontal raster of approximately 12x12 square meters, slightly varying depending on the geographic latitude.^[4]

Advantages of radar

Radar stood originally for Radio Detection and Ranging and contains traditionally:

Range finding (EDM) by means of the time a reflected signal needs to return;
Direction measurement over the adjustment of the antenna, and recently;
also different analysis such as SAR, polarization, Interferometry etc.

Satellite radar entered use more than fifteen years after optical camera systems did. The resolution (detail sharpness) is in principle lower, but radar can gather information at any time of the day or night and independent of cloud cover. This contributes significantly to the reliability of the system, a much-desired property.

Early radar satellite techniques were e.g. the Altimetrie (leveling over the sea), NASA's SEASAT (launched in 1978), regulation of waves/wind or soil data. Satellites like GRACE can measure for instance the speed of other satellites to mm/s exactly, and the slow deformation of volcanoes. The military has used radar since the late 1930s and radar satellites at least since 1978.^[5]

Innovations with TerraSAR X

TerraSAR X will exhibit some technical-industrial novelties. One of these innovations is a kind of zoom shot, with the resolution and scanning field vice versa changeable in a 1:10 relationship, either a larger area to grasp or a small area with the highest possible resolution.

Furthermore, the antenna can be aligned by electronics within an angle range so that the point of view is adjustable. Earlier radar satellites could radiate the antenna only in one direction.

Scanning and trajectory

With the adjustable angle radar sensor - along with other course refinements (precession by the earth flattening) - any place on earth can be observed preferentially within 1–3 days.

For a specific point on the Earth's equator, TerraSAR X has a revisit cycle of 11 days. The revisit time decreases towards the poles, e.g. northern Europe has a revisit time of typically 3–4 days.

Ground segment

The ground operating mechanism and controls for the TerraSAR X is developed by the DLR in Oberpfaffenhofen. It consists of Mission Operating Equipment, the Payload Ground Segment and the Instrument Operation and Calibration Segment. At the base of the ground segment lies the German Space Operation Center (GSOC), the German Remote Sensing Datum Center (DFD) as well as Institutes for Methodology of Remote Sensing (MF) and the Institute for High-Frequency Engineering and Radar Systems (HR) which are all part of the DLR.

Applications

Applications of the high-resolution TerraSAR-X radar imagery include:

Topographic Mapping: 2D and 3D, in scales down to 1:25,000, map updates
Surface Movement: Based on timeseries acquired by TerraSAR-X over the same area surface displacements caused by subsurface mining, oil-/gas extraction, infrastructure construction, excavations, or underground engineering can be visualised.^[6]
Change Detection: for the monitoring of large-scale construction projects, infrastructure networks, monitoring and documentation of changes and developments
Land Cover and Land Use Mapping: accurate and up-to-date land cover / land use informations, also from places, where it is difficult to get informations with using other technologies because of permanent cloud cover
Defence and Security Applications: Applications include effective mission planning, the quick assessment of natural or manmade disasters or border control through detection of paths (changes), fences and moving objects
Rapid Emergency Response: due to its rapid revisit time TerraSAR-X is a reliable source of information in case of natural or man-made disasters (e.g. earth quakes, floods, military conflicts etc.) providing reliable information for disaster management and response allowing the recognition and assessment of damages to populated areas and traffic infrastructure, the identification of focus areas, and an efficient coordination of rescue actions.^[7]^[8]
Environmental applications: e.g. forest monitoring, flood monitoring,^[9] water quality applications
Further applications currently under evaluation: Traffic Monitoring, Maritime applications, vegetation monitoring

Scientific use of TerraSAR-X data

The scientific use of the TerraSAR-X data will be coordinated through the TerraSAR-X Science Service System by the DLR.^[10] The new-quality data records, as provided by TerraSAR-X, will offer a vast amount of new research incentives, for instance in ecology, geology, hydrology and oceanography. The smallest movements of the Earth's surface (plate tectonics, volcanism, earthquake) are further scientific fields of application.

Commercial use of TerraSAR-X data

In order to ensure the commercial success of the mission, EADS Astrium founded its 100% subsidiary Infoterra in 2001; the company being responsible for establishing a commercial market for TerraSAR-X data as well as TerraSAR-X-based geo-information products and services.

References

1 2 3 4 5 6 7 "TERRA SAR X Satellite details 2007-026A NORAD 31698". N2YO. 25 January 2015. Retrieved 25 January 2015.
↑ StripMap & ScanSAR: acquisition length extendable to up to 1,650 km.
↑ DLR - Blogs - The satellites have 'eye contact'
↑ GIM International: Weber, Marco; Koudogbo, Fifamè,January 2009, TerraSAR-X 1m Spaceborne Radar - Use, Features, Products and TanDEM-X.
↑ (Jensen, J. R. 2007. Remote Sensing of the Environment: An Earth Resource Perspective)
↑ GeoBerichte 14, Landesamt für Bergbau, Energie und Geologie in Niedersachsen:Schrage, Thomas;Jacob, Philipp , June 2009, Flächenverbrauch und Bodenversigelung in Niedersachsen.
↑ GIM International: Balz, Timo; Scheuchl, Bernd;Li, Deren, October 2008, The Sichuan Earthquake(1)-Satellite Imagery for Rapid Response.
↑ GIM International: Shao, Yun; Scheuchl, Bernd, November 2008, The Sichuan Earthquake (2)- Spaceborne SAR in Earthquake Response.
↑ GIM International: Koudogbo, Fifamè; Müller, Marc; Scheuchl, Bernd, December 2008, The Sichuan Earthquake (3)- Satellite-based Global Flood Response.
↑ TerraSAR-X Science Service System

External links

Astrium Geo
TerraSAR-X at DLR website.
TerraSAR-X for risk management.
TanDEM-X at DLR website.
TanDEM-X Science Home at DLR website
Terrasar-x at Astrium website

Orbital meteorological and remote sensing systems

Concepts

Current projects

Earth Observing System (EOS)	GPM TRMM Landsat 7 QuikSCAT Terra ACRIMSAT NMP/EO-1 Jason-1 OSTM/Jason-2 Jason-3 Meteor 3M-1/Sage III GRACE Aqua SORCE Aura CloudSat CALIPSO NPOESS Megha-Tropiques SARAL IRS ESSP Aquarius Landsat 8 SMAP

A-train satellites	Aqua Aura CALIPSO CloudSat GCOM-W1 (Shizuku) OCO-2

Copernicus programme	Sentinel-1 Sentinel-2 Sentinel-3 Sentinel-4 Sentinel-5 Precursor Sentinel-5

Geostationary meteorological satellites	Elektro-L Fengyun-2 GOES INSAT Meteosat Himawari-8

Other satellites	CBERS COSMO-SkyMed DMSP DMC EROS Fengyun-3 FORMOSAT-2 GOSAT (Ibuki) Landsat MetOp Meteor POES RADARSAT-2 SMOS SPOT TerraSAR-X THEOS

Former projects

Completed	ADEOS (Midori) ADEOS II (Midori 2) COSMIC (FORMOSAT-3) Envisat ERS FORMOSAT-1 Geosat GMS (Himawari) ICESat IKONOS JERS-1 (Fuyo-1) Nimbus PARASOL QuickBird RADARSAT-1 Seasat SeaWiFS TIROS TOPEX/Poseidon UARS Vanguard

Failed	OCO Glory

Cancelled	NMP/EO-3

← 2006 · Orbital launches in 2007 · 2008 →

Cartosat-2 · SRE-1 · Lapan-TUBsat · Pehuensat-1 \| Progress M-59 \| NSS-8 \| Beidou-1D \| THEMIS A · THEMIS B · THEMIS C · THEMIS D · THEMIS E \| IGS Radar 2 · IGS Optical 3V \| ASTRO · NEXTSat · MidSTAR-1 · FalconSAT-3 · STPSat-1 · CFESat \| Skynet 5A · INSAT-4B \| DemoFlight 2 \| Soyuz TMA-10 \| Anik F3 \| Hai Yang 1B \| Compass-M1 \| EgyptSat 1 · Saudisat-3 · SaudiComsat-3 · SaudiComsat-4 · SaudiComsat-5 · SaudiComsat-6 · SaudiComsat-7 · CP-3 · CP-4 · CAPE-1 · Libertad 1 · AeroCube 2 · CSTB-1 · MAST \| AGILE · AAM \| NFIRE \| AIM \| Astra 1L · Galaxy 17 \| Progress M-60 \| NigComSat-1 \| Yaogan 2 · Zheda PiXing 1 \| Globalstar 65 · Globalstar 69 · Globalstar 71 · Globalstar 72 \| Sinosat-3 \| Kosmos 2427 \| COSMO-1 \| STS-117 (ITS S3/4) \| Ofek-7 \| TerraSAR-X \| USA-194 \| Genesis II \| Kosmos 2428 \| SAR-Lupe 2 \| zhongxing 6B \| DirecTV-10 \| Progress M-61 \| Phoenix \| STS-118 (ITS S5 · SpaceHab LSM) \| Spaceway-3 · BSAT-3a \| INSAT-4CR \| JCSAT-11 \| Kosmos 2429 \| Kaguya (Okina · Ouna) \| Foton-M No.3 · YES2 \| WorldView-1 \| CBERS-2B \| Dawn \| Intelsat 11 · Optus D2 \| Soyuz TMA-11 \| USA-195 \| USA-196 \| Globalstar 66 · Globalstar 67 · Globalstar 78 · Globalstar 70 \| Kosmos 2430 \| STS-120 (Harmony) \| Chang'e 1 \| Kosmos 2431 · Kosmos 2432 · Kosmos 2433 \| SAR-Lupe 3 · Rubin-7 \| USA-197 \| Yaogan 3 \| Skynet 5B · Star One C1 \| Sirius 4 \| Globus-1M No.11L \| COSMO-2 \| USA-198 \| Radarsat-2 \| USA-199 \| Horizons-2 · Rascom-QAF 1 \| Progress M-62 \| Kosmos 2434 · Kosmos 2435 · Kosmos 2436

Payloads are separated by bullets ( · ), launches by pipes ( \| ). Manned flights are indicated in bold text. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in brackets.

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