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SPOT Historical

The SPOT Historical archive holdings maintained and preserved by the USGS/Earth Resources Observation and Science (EROS) Center were received from the SPOT IMAGE Corporation in 1999. The French space agency, Centre National d'Etudes Spatiales (CNES), owns and operates the SPOT satellite system and worldwide commercial operations are anchored  by private companies (i.e., SPOT IMAGE Corp. of the United States and other distributors around the world).

The SPOT satellites carry two High Resolution Visible (HRV) sensors. The HRVs consist of multi­ linear array detectors that operate in a cross-track direction. Operating independently of each other, the two HRVs acquire imagery in either multi-spectral and/or panchromatic modes at any viewing angle within plus or minus 27 degrees. This off-nadir viewing also enables the acquisition of stereoscopic imagery.

The USGS SPOT Historical archive provides North American coverage between 87 degrees north latitude and 10 degrees north latitude acquired between 1986 and 1998. Each nominal scene covers a -60- by 60-km area. The USGS/EROS SPOT archive includes the following data volume: ~ 514,500 PAN scenes and ~ 281,700 Multi-spectral scenes. 

The acquisition years range from June 1986 to December 1998. 

SPOT satellites maintain a near-polar, near-circular, Sun-synchronous orbit with a mean altitude of 832 km at 45 degrees north latitude at an inclination of 98.7 degrees, and a mean revolution period equaling 101.4 minutes. The SPOT satellites orbit the same nadir ground track every 26 days with a nominal cycle of 369 revolutions. Crossing  the equator from north to south at 10:30 a.m.mean local solar time, the satellites' reference tracks are 108.6 km apart. The reference tracks draw closer at higher latitudes. Each HRV sensor views a 60-km area, and together they view a 117-km  area with 3-km overlap.

Characteristics of SPOT HRV Instruments Multispectral Mode (XS) Panchromatic Mode
Instrument Field of View 4.13 degrees 4.13 degrees
Ground Sampling Interval (Nadir Viewing) 20 m by 20 m 10 m by 10 m
Pixels Per Line 3000 6000
Ground Swath Width (Nadir Viewing) 60 km 60 km
 
The SPOT data were transmitted in direct recording mode to two ground receiving stations in North America (Prince Albert and Gatineau). For more information on SPOT's network of operation, see the SPOT IMAGE Homepage; Toulouse, France: http://www.spotimage.Fr/

Each SPOT satellite data-collection pass lasts approximately 10 minutes with a constant viewing configuration. Each pass yields two data segments with each segment containing approximately 75 scenes. This typically represents use of either one HRV set to dual mode or use of both HRVs in single mode. The size of individual scenes varies (i.e., a vertically viewed scene has a 60- by 60-km scene size while an obliquely viewed scene at maximum has a 60- by 81-km scene size). Grid Reference System (GRS) identification.
 

Spatial Resolution
Mode Band Resolution
Multispectral (XS) 1 (Green) 2 (Red) 3 (Near Infrared) 20 meters 20 meters 20 meters
Panchromatic Not Applicable 10 meters

 

Temporal Coverage
Satellite Launch Date Decommission Date
SPOT 1 SPOT 2 SPOT 3 02/22/1986 01/22/1990 09/26/1993 12/31/1990 07/29/2009 11/14/1997

 

Spectral Range of SPOT Sensor Mode
Mode Band Micrometers
Multispectral (XS) 1 (Green) 2 (Red) 3 (Near Infrared) 0.50 - 0.59 micrometers 0.61 - 0.68 micrometers 0.79 - 0.89 micrometers
Panchromatic Not Applicable  

SPOT Products

All SPOT Historical scenes were initially processed to Level 1 GST at EROS using the National Land Archive Production System (NLAPS) and are made accessible to authorized users through EarthExplorer. The SPOT L1T Product Generation is a two step process which utilizes in-house software – Land Analysis System (LAS) to perform an automated image-to-image registration.
•First Step – Generate a L1Gst product
•Second Step – Generate the L1T product using the L1Gst product as input.
•Image-to-image correlation with the LANDSAT GLS 2000 as the reference.
•Double resampling occurs when starting with the L1Gst but does account for the SPOT ephemeris.

Coverage Maps

Coverage Maps indicating the availability of SPOT Historical products are available for download.

USGS/EROS provides data to authorized users that comply with the USGS/SPOT agreement. These data are available at no cost to the user as direct data downloads. No hard media options exist for this data collection. All SPOT historical data (1986 to 1998) are available through EarthExplorer (earthexplorer.usgs.gov).

Procedures for Obtaining Additional Data
To obtain additional information outside of EarthExplorer regarding technical details, ancillary products, and pricing schedules, contact a SPOT data distributor. Information on SPOT data distributor is available through the SPOT IMAGE Homepage at the following site: Toulouse, France at: http://www.spotimage.Fr/

Copyright Information
Permission has been granted to EROS by SPOT Image Corporation to provide SPOT products to approved Federal Users [Copyright CNES/SPOT Image Corporation, 1995].

Grid Reference System (GRS)
The SPOT Grid Reference System (GRS) is used to identify the geographic location of SPOT images. The grid is made up of nodes located at the intersection of columns (K) and rows (J). When data strips are split into scenes, the SPOT GRS links each scene with two K,J designators representing a GRS node. Once the K,J designators have been identified for a new scene, the designators are added to that scene's characteristics file.

The GRS indicates the nominal location of scenes that can be acquired within SPOT's twin­ vertical viewing configuration. In the case of oblique viewing, the scene centers do not normally coincide with the GRS nodes as defined by the surveying conditions of twin-vertical viewing. Therefore, any SPOT scene acquired in the oblique viewing mode is identified by the K,J designators of the node closest to the scene center.

The GRS divides the Earth into five zones forming a symmetrical pattern on either side of the Equator. This division is dictated by the satellite's orbital characteristics and, more specifically, by the convergence of the ground tracks at high latitudes.

•    The intermediate zone extends from 51.5 degrees north latitude to 51.5 degrees south latitude.
•    The north and south zones extend from 51.5 degrees to 71.7 degrees north or south latitudes, respectively.
•    The north and south polar zones extend from 71.7 degrees to the pole north or south latitudes, respectively.

In the north, intermediate, and south zones, the K columns are parallel to satellite ground tracks while the J rows are parallel to latitude lines. The pattern of nodes within the three zones is defined in terms of satellite viewing conditions corresponding to the twin-vertical viewing configuration. This pattern indicates the nominal location of scene centers yielded by the viewing configuration. With oblique viewing, scene centers are always located on the J row, but scene centers may not coincide in longitude with GRS nodes.

The K columns are derived directly from the SPOT reference tracks. Each track number (N) corresponds to two K columns:
K = 2N-1 associated with HRV-1 and located west of track N (odd number) K = 2N associated with HRV-2 and located east of track N (even number)

The distance between these two columns (i.e., between K=2N-1 and K=2N) is constant at about 58 km and is a direct result of the twin-vertical viewing configuration.

Since the GRS nodes are located on either side of the reference tracks, the scene centers obtained in vertical viewing do not coincide with the GRS nodes.

The J rows correspond to latitude lines (i.e., all GRS nodes at the same latitude share the same J designator). The interval between the rows has been calculated to ensure that minimum endlap occurs between two successive scenes. The scenes of a given data strip are segmented in such a way that the scene centers are located on two adjacent rows (J and J+1).

In the two polar zones, the GRS node pattern is independent of satellite orbital and viewing characteristics. The pattern is obtained through hexagonal dissection using quasi-equilateral triangles, where the triangle measures approximately 26 km to a side.

Data Use and Citation Policies

For information on how to cite USGS data plus guidance on usage restrictions,
please see our Data Citations and Use page at https://lta.cr.usgs.gov/citation.

Any use of trade, firm, or product names is for descriptive purposes only and
does not imply endorsement by the U.S. Government.

Contact Information for User Assistance

U.S. Geological Survey (USGS)
Earth Resources Observation and Science (EROS) Center
47914 252nd Street
Sioux Falls, SD 57198-0001

Phone Number: 605-594-6151
Toll Free: 800-252-4547
Fax: 605-594-6589

Email: custserv@usgs.gov
Web: https://earthexplorer.usgs.gov/

Business Hours: Monday thru Friday, 8:00 a.m. to 4:00 p.m., Central Time