SECOR (Sequential Collation of Ranges)[1] was a series of small United States Armed Forces satellites launched in the 1960s for geodesy measurements that precisely determined the locations of points on the Earth's surface, particularly of isolated islands in the Pacific Ocean. This data allowed for improved global mapping and precise positioning of ground stations for other satellites.[2]

Any SECOR satellite could be linked to four mobile ground stations: three were placed in accurately determined known locations, and a fourth one was placed in an unknown location. By measuring a satellite's distance from the three known stations, its position in space was determined. Then, the distance between the unknown ground station and the previously determined satellite's position was used to compute the unknown ground station's coordinates. This process was repeated many times, to enhance the accuracy of the measurement. Once the unknown station's position was accurately determined, it became a known station. Then one of the four stations was moved to a new unknown point, and the process began again.

SECOR was a predecessor to navigational satellite systems such as Timation and Navstar-GPS (Global Positioning System).

Satellites

Fifteen dedicated SECOR satellites were made, and eight SECOR transponders flew as a subsystem of other satellites.

Two versions of SECOR satellites were built, Type I and Type II. They had several differences, but they also shared many features. Therefore, a detailed description is provided for Type I, and a differences-only summary for Type II.

Type I

An engineer from Ling-Tempco-Vought makes final adjustments to a SECOR Satellite
An engineer from Ling-Temco-Vought makes final adjustments to a SECOR satellite.

Description

The Type 1 SECOR satellites were spherical, 50.8 cm (20.0 in) in diameter, in construction similar to Vanguard III and the early SOLRAD/Galactic Radiation and Background (GRAB) spacecraft. The satellites massed 16.8 kg (37 lb) in average, with most of it being batteries and voltage regulators. Their surface was made of polished aluminium covered with a thin layer of silicon monoxide to help with thermal regulation. There were nine collapsible antennas, eight around the equator for distance measurement and one atop the sphere for telemetry and command. A hollow cone connected the upper stage of the launch vehicle to the base of the satellite. Expected lifespan was one year.

Electrical power

Six sets of 160 solar cells were mounted on aluminium plates around the surface, providing 17 volts. Within the sphere, a vertically aligned cylinder housed the batteries and voltage regulators. A stable voltage was essential for accurate transponder operation, and, in addition to the voltage regulators, each battery cell in the battery was matched to within 0.03 volts in their discharge curves.

Transponder

The transponder was placed on a framework within the remaining space.

Telemetry

Each satellite was equipped to transmit data such as battery charge, voltages, temperature of equipment inside the satellite, etc. Later satellites had more telemetry channels.

Passive attitude control

On the inner side of the skin, a magnetic rod was placed. It aligned itself with Earth's magnetic field, thus keeping the satellite in a constant orientation. Also inside the skin, many despin coils were placed. These devices were used to stop undesired rotation induced by launch vehicle separation, and by passing near the magnetic poles of Earth. The despin coils were simply large wire coils that were electrically shorted. Rotational movement within Earth's magnetic field induced current on the coils. The current in the coils generated a magnetic field of its own that opposed Earth's, thus slowing the satellite's rotation. As the coils were shorted, the electric current was converted to heat and dissipated to space. The initial braking took several days because of the weak magnetic field at the typical SECOR orbital altitudes.

Type II

SECOR-1 satellite

These later satellites were made in the shape of a rectangular prism, measuring 25.3 × 29.8 × 34.9 cm (10.0 × 11.7 × 13.7 in). They were almost fully covered in solar cells, and the antennas were made of flexible steel tape. They were much more compact, and thus worked better as secondary payloads. They were designed to avoid removing covers and panels during satellite pre-launch checks. Their antennas were perforated, to diminish antenna shadow over the solar panels.

Non-dedicated

SECOR transponders were also attached to a number of satellites. While the specific implementation was done on a case-by-case basis, the general idea was to place a transponder either outside/inside of a host satellite, sharing power, antennas, and telemetry with other experiments.

Ground stations

The ground stations were transportable. They consisted of three shelters, one for radio equipment, one for data handling, and one for storage. Generators and air conditioning for the electronic equipment were included.

Lighter weight, solid-state electronics equipment was eventually developed to replace the initial units.

Radio equipment

The equipment was designed for all-weather operation.

  • Send Transponder on/off command
  • Receive Satellite Battery Voltage
  • Receive Satellite temperatures (shell, battery and amplifier)

Data handling

The data was recorded on magnetic tape and processed by a computer.

Storage

  • Fuel and other consumables

System operation

  • Determine the distance between the satellite and the stations several times.
  • Compute the position of the satellite relative to the three known stations by trilateration.
  • Compute the possible positions of the unknown ground station that could yield the measured distance.
  • Repeat the cycle, narrowing down the set of possible positions with each satellite pass until the accuracy is deemed acceptable.

First, the distances between each station and a satellite were obtained and recorded. The distances between the known positions and this satellite were used to determine the satellite's location in space, and then, the previously measured distance from the fourth station and the calculated satellite position were used to calculate the coordinates of the fourth station with respect to the three known stations.[3]

The accuracy of the position calculations was enhanced by the great amount of data obtained in each satellite pass. At about 70 measurements per second, and considering the time the satellite was visible from the ground station, a typical satellite pass yielded approximately 48,000 measurements. Because depending on the exact angle between the satellite and a ground station, the precision could have variation, data was collected during several passes. This allowed data from the best passes to be selected, while still conserving a great amount of redundancy.

Once enough measurements had been made to ensure the unknown position was precisely established, one of the stations was moved to a different place and became the new unknown position. In this way, former measurements helped establish new positions.[2]

Launch history

Sources differ in details such as names and launch dates. When there are inconsistencies, sources are provided for both.

Name Launch date International Designator Launch vehicle Launched from Satellite type Notes
Transit 3B[4] 22 February 1961, 03:45 GMT 1961-007A Thor-Ablestar Cape Canaveral Air Force Station Shared [2] Launch failure,[2] satellites failed to separate and were placed in a low orbit. Decayed 37 days after launch.[4]
DISCOVERER 33 [2] 23 October 1961 1961-F10 Thor-Agena B Vandenberg AFB Shared Launch failure
DISCOVERER 34 [2] 5 November 1961 1961-029A Thor-Agena B Vandenberg AFB Shared Partial success
DISCOVERER 36 [2] 12 December 1961 1961-034A Thor-Agena B Vandenberg AFB Shared Partial success
COMPOSITE I [2] 24 January 1962 1962-F02 Thor Ablestar Cape Canaveral Air Force Station Type I Launch failure, the second stage failed to add enough velocity.
ANNA 1A [2] 10 May 1962 1962-F04 Thor Ablestar Cape Canaveral Air Force Station Shared Launch failure.
ANNA 1B [2] 31 October 1962 1962-060A Thor Ablestar Cape Canaveral Air Force Station Shared Partial success
SECOR-1 (EGRS-1),[5] SECOR-1B,[6] 11 January 1964 1964-001C Thor Augmented Delta-Agena D Vandenberg AFB Type II Success.
SECOR 3 (EGRS-3),[7] 9 March 1965 1965-016E Thor Augmented Delta-Agena D Vandenberg AFB Type II Success.
SECOR 2 (EGRS-2),[8] 9 March 1965 [9] 1965-017B Thor Augmented Delta-Agena D Vandenberg AFB Type II Success, decayed 25 February 1968.
SECOR 4 (EGRS-4),[10] 3 April 1965 1965-027B Atlas-Agena D Vandenberg AFB Type II Transponder failure. U.S. Army / U.S. Air Force
EGRS V [2] 10 August 1965 1965-063A Scout B Wallops Flight Facility Type I Partial success
Explorer 29 (GEOS A)[2] 6 November 1965 1965-089A Thor-Delta E Vandenberg AFB Shared Success.
SECOR 6 (EGRS-6),[11] 9 June 1966 1966-051B Atlas-Agena D Vandenberg AFB Type II Success. U.S. Army / U.S. Air Force
SECOR 7 (EGRS-7),[12] 19 August 1966 1966-077B Atlas-Agena D Vandenberg AFB Type II Partial success
SECOR 8 (EGRS-8),[13] 5 October 1966 1966-089B Atlas-Agena D Vandenberg AFB Type II Transponder failure. U.S. Air Force
SECOR 9 (EGRS-9),[14] 29 June 1967 1967-065A Thor-Burner Vandenberg AFB Type II Success. U.S. Army / U.S. Navy
Explorer 36 (GEOS B) [2] 11 January 1968 1968-002A Thor-Delta E1 Vandenberg AFB Shared Success.
SECOR 10 (EGRS-10),[15] 18 May 1968 1968-F04 Thorad SLV2G-Agena D Vandenberg AFB Type II Launch failure.
SECOR 11 (EGRS-11),[15]> 16 August 1968 1968-F07 Atlas SLV3-Burner 2 Vandenberg AFB Type II Launch failure.
SECOR 12 (EGRS 12) [15] 16 August 1968 1968-F07 Atlas SLV3-Burner-2 Vandenberg AFB Type II Launch failure.
SECOR 13 (EGRS 13) [16] 14 April 1969 1969-037B Thor-Agena Vandenberg AFB Type II Success.
TOPO I [2] 8 April 1970 1970-025B Thorad SLV2G-Agena D Vandenberg AFB Type II Success.

Notes

EGRS (Engineer Geodetic Research Satellite) was the U.S. Army Corps of Engineers acronym for the SECOR satellites.

References

  1. Seeber, Günter (22 August 2008). Satellite Geodesy. Walter de Gruyter. ISBN 9783110200089.
  2. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Nichols, Robert H. (June 1974). "Geodetic SECOR satellite" (PDF). DTIC (Defense Technical Information Center). Archived (PDF) from the original on 15 March 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  3. Brinker, Russell C. (29 June 2013). The Surveying Handbook. Springer. ISBN 9781475711882.
  4. 1 2 "Display: Transit 3B 1961-007A". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  5. "Display: Secor-1 1964-001C". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  6. "SECOR 1B". N2YO.com. Retrieved 11 March 2019.
  7. "Display: SECOR 3 1965-016E". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  8. "Display: SECOR 2 1965-017B". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  9. Ford, Dominic. "SECOR 2 - In-The-Sky.org". in-the-sky.org. Retrieved 11 March 2019.
  10. "Display: SECOR 2 1965-027B". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  11. "Display: SECOR 6 1966-051B". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  12. "Display: SECOR 7 1966-077B". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  13. "Display: SECOR 8 1966-089B". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  14. "Display: SECOR 9 1967-065A". NASA. 28 October 2021. Retrieved 13 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
  15. 1 2 3 "SECOR 1, 2, 3, 4, 6, 7, 8, 9, 10, 11, 12, 13 (EGRS 1, 2, 3, 4, 6, 7, 8, 9, 10, 11, 12, 13)". Gunter's Space Page. 23 December 2017. Retrieved 13 November 2021.
  16. "Display: SECOR-13 1969-037B". NASA. 28 October 2021. Retrieved 12 November 2021. Public Domain This article incorporates text from this source, which is in the public domain.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.