Sodern is a French company based in Limeil-Brévannes, near Paris in Ile-de-France, specialized in space instrumentation, optics and neutron analyzers.

Sodern
IndustrySpace instrumentation, optics, defence and neutron
Founded1962
Headquarters,
Key people
Franck Poirrier, CEO
Number of employees
450+
ParentArianeGroup
Websitewww.sodern.com

Its shareholders are ArianeGroup (90%) and the French Alternative Energies and Atomic Energy Commission (10%).

Sodern develops and produces instruments for space exploration missions or scientific programmes; satellite equipment; neutron generators and neutron interrogation tools.

Since the 2000s, Sodern has participated in space exploration missions to Mars (NASA InSight, India Mars Orbiter, etc.), the moons of Jupiter (NASA Europa Clipper, ESA JUICE, etc.), Venus ( Japanese Mission "Planet C"), Ceres (NASA Dawn), the Moon, etc. It has developed high-tech scientific instruments including the heart of the PHARAO atomic clock, which should deviate by no more than one second every 300 million years, and will verify the effects predicted by the theory of general relativity.

Sodern is the world leader in the development and production of star trackers, instruments that allow satellites to position themselves in space, and neutron tubes.

Called a "key actor" of national defense by French minister Jean-Yves Le Drian, Sodern develops and produces the neutron sources for the French nuclear force, part of the payloads of the French military satellites dedicated to Earth observation, GPS-free positioning systems, etc.

Franck Poirrier, CEO of Sodern, is the representative of the space equipment manufacturers within COSPACE (French Ministerial Committee of Space Coordination).

History

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IPS visible on the side of the ASTRO-1 observatory

Sodern was created in 1962 in the Philips' Laboratory of Electronics and Applied Physics (LEP) to launch a first generation of external neutron sources.[1]

In the late sixties, Sodern began to diversify its activities towards optical and high-tech space sensors, for which it is today the global leader.[2] In the early 70s, on CNES demand, Sodern realized the first European Earth sensors, sensors dedicated to the attitude control of the experimental telecommunication satellite Symphonie (satellite).[3]

In 1975, the European Space Agency (ESA) subcontracted the manufacturing of multiple instruments for the Spacelab. Sodern achieved a high-precision scoring system dedicated to readjust the inertial and to high-performance attitude measurement. Sodern also delivered SED04 stars trackers for the Instrument Pointing System (IPS) of the Spacelab observatory.[4] These sensors had a precision of 0.75 seconds of arc, thus the precision needed to see "a golf ball from a 10 km [6.2-mile] distance".[2]

Meanwhile, in the mid-1990s, Sodern enhanced its optical instrumentation activity dedicated to Space.

Activity

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Although Sodern activity started in the neutron area, by designing neutron sources for the French deterrent force, it began to diversify into optical sensors and advanced spacecraft instrumentation in the late 1960s.

Spatial Instrumentation

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Nowadays, its activities cover several ranges of space instruments.

- Instruments for satellite attitude control: Earth[5] and Solar sensors and stars trackers,[6] equipping among others Spot,[7] Helios,[8] Eurostar satellites[9] and M51 missile.[10] The first Earth sensor was created in 1977 and boarded on Meteosat I.

- Instruments for Earth observation (cameras, optical and optronic instruments for Spot satellites, Helios, Envisat, etc.).

- Advanced optical instruments for the nuclear industry, the French deterrence force and scientific research, for example Astrium ATV videometers,[11] that can guide its automatic docking[12] to the International Space Station (ISS), and the Infrared Atmospheric Sounding Interferometer (IASI) instrument for MetOp.[13]

- Unique scientific instruments created on demand and integrated aboard satellites, space stations and space vehicles, such as PHARAO atomic clock[14] (developed from the work of the Nobel Laureate Claude Cohen-Tannoudji), critical liquids on DECLIC orbit study instruments,[15] some of the main components of the camera seeking for exoplanets aboard COROT satellite,[16] etc.

Stars Trackers

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As a Star trackers worldwide leader, Sodern takes in 75% of the global market with two other European leaders, Galileo (Italy) and Jena Optronik (Germany).[17]

SED16 sensor has been the first to be used to replace gyroscopes in satellites. It was launched for the first time in May 2002 aboard Spot 5.[18] It has since flown with numerous satellites, including the US communication satellite AMC 12 in February 2005.[19] SED26, his almost similar successor, was launched in April 2005 aboard the satellite Apstar VI. The U.S. probe Dawn, that was made to visit two asteroids Vesta and Ceres, locates itself thanks to SED16 sensors.[20] Those sensors are, within all Sodern's supplied equipment, those farthest from Earth in deep Space.

The SED26 sensor guides, among others, the European Automated Transfer Vehicle ATV,[21] the satellites Helios 2,[22] Orbview 3 and 4, Sorce (from the American manufacturer Orbital), and more than a dozen satellites of the Russian manufacturer ISS-Reshetnev.[23]

 
Hydra Star Tracker

June 15, 2005, Sodern announced the development and production of Hydra sensors,[24] more accurate, more compact and lighter than the SED. Development of the sensor was funded by the European Space Agency (ESA) and The French Space Agency (CNES), and resulted in a radiation-resistant sensor, about half as heavy as the SED (which were 3Kg weight), which consumes only one Watt while operating and which has a precision of one arc second on each of its three axes. Sodern has sold more than a hundred of Hydra sensors so far, first of which was launched on September 6, 2012, aboard the French satellite Spot 6.[25]

Optical Instrumentation

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In the late 60s, several projects in optical instrumentation have been materialized, such as the strips,[26] bands incorporating all the data exchanged during the operations of air traffic control, as well as the prototype of a mini-camera for the French hospital Val-de-Grâce, detecting gamma and beta rays, to facilitate complete removal of cancerous tumours.

During the 1980s, Sodern designed the focal plans and the optics for the Meris[27] instrument of the European Space Agency satellite Envisat, provided the cameras for the programs Iasi[28] (CNES) and CALIPSO[29] (CNES/NASA), and the dioptric objective of the Corot[30] instrument, which doesn't observe the Earth but looks into Space searching for exoplanets or studying the seismic activity of the stars.

By producing Spot1's camera in 1986 (DTA01),[31] Sodern began a long participation in Earth observation programs, providing cameras as much as optical and optronic instruments for the satellites ranges Spot, Helios, Envisat, etc.

Strip Filters

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Strip Filters

Optical instrumentation and space being often linked, Sodern has developed a new generation of multi-spectral filters, "strip filters".[32]

The acquisition on multiple spectral bands is enabled by the use of multiple elementary optical filters juxtaposed to each other. Regarding the technology developed by Sodern, this juxtaposition is obtained by assembly of strips, the strip being a sub-set containing all the functions of an elementary filter. The final component is called "assembled strip filter". The number of elementary filters and their characteristics (centring, width, rejection, sloping edges, etc.) depend on the type of the satellite (Earth observation in the visible, infrared, etc.).

Neutron

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In the 1980s, Sodern has developed its civil neutron activity and designed neutron generators (TN26[33] then GENIE36[34]) used by radioactive waste reprocessing plants for the measurement of transuranic elements. It's also used for in situ measurements in mining and oil logging, for the control of raw materials in metallurgy, for the detection of explosives and in neutron radiography.[35]

In the early 1990s, a first neutron-flanged tube for the oil logging (electrical logging) was designed at the request of Schlumberger, first of an ongoing collaboration.

 
Cement CNA

In the late 1990s, a new project of neutron analyzer was launched, the Continuous Neutron Analyzer (CNA) for the analysis of cements.[36] The principle of material analysis by neutron interrogation was then extended for a vast range of applications: coal, ores (copper, nickel, bauxite, iron), scrap and waste. In 2010, about 70 of those devices had been sold, mostly to cement makers.[37] These CNAs are marketed by another company, PANalytical.[38]

Based on the same principle of analysis, Sodern designed INES, a detector of explosives for luggage at airports. This detector was developed jointly with the French Commissariat à l'Energie Atomique (CEA). It has used a technology called FNA, for Fast Neutron Activation, different from its American competitor (Science Applications International Corp.) technology, which is called TNA, for Thermal Neutron Activation. Sodern FNA detector was based on the fact that explosives often contain a large amount of oxygen and nitrogen but little carbon. A pulsed generator of neutrons then enabled it to detect such elements. The detector was able to analyze 1200 bags per hour, for a detection rate of 99.8%.[39] It has not yet been commercialized.

THOR (military version) and ULIS (civilian version) emerged in the 1990s. They make the detection of explosive and hazardous materials (toxic chemicals products), as illegal ones, possible in abandoned luggage and parcels, from a distance.[40] Their small size allows them to be carried like a suitcase.

NIPPS (Neutron Induced Prompt Photometer System) allows the non-intrusive detection of illicit and dangerous substances.[41] It has been used by the Organisation for the Prohibition of Chemical Weapons(OPCW).[42]

Management

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The main shareholder (90%) has been the European company ArianeGroup, the remaining 10% being held by the French Atomic Energy Commission CEA.

In 2017, the company employed about 400 people, including around 60% of engineers.

References

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  1. ^ "Observatoire des armes nucléaires françaises (La recherche et la fabrication des armes nucléaires en France aujourd'hui-Cahier n°6/20)" (in French). May 2001. p. 22.
  2. ^ a b "New Scientist #1529". 9 October 1986. p. 49.
  3. ^ Seetman, Bill (2007). "Jane's Space Systems and Industry (2007-2008)". p. 84.
  4. ^ Jean-Pierre Krebs. "Capteurs d'attitude et dispositifs d'imagerie pour satellites" (PDF). Techniques de l’Ingénieur, traité Électronique (in French). p. 6. Archived from the original (PDF) on 2013-01-17.
  5. ^ Nicollet, L.; Pochard, M.; Sicre, J. (1995). "Noise analysis of dry lubricated ball bearings for a scanning Earth sensor mechanism". 6th European Space Mechanisms and Tribology Symposium. 374: 185. Bibcode:1995ESASP.374..185N.
  6. ^ "e2v and Sodern celebrate the sale of the 100th satellite attitude star tracker incorporating e2v image sensors". e2v. 25 October 2007.
  7. ^ "New Scientist #1584". 29 October 1987. p. 53.
  8. ^ Hugues Lanteri (15 May 2005). "Ariane 5 - Données relatives au Vol 193" (PDF). Astrium (in French). p. 16. Archived from the original (PDF) on 18 January 2014.
  9. ^ "EADS Space (Le Bourget 2005)". EADS (in French). 13 June 2005.
  10. ^ "Le missile M51". netmarine (in French). Archived from the original on July 26, 2013.{{cite news}}: CS1 maint: unfit URL (link)
  11. ^ "ATV : des rendez-vous sous l'œil d'un laser". bulletin-electronique (in French). 9 September 2002.
  12. ^ "Docking video". Astrium Vidéothèque (in French). 24 February 2011. Archived from the original on 18 January 2014.
  13. ^ "MetOp". eoPortalDirectory.
  14. ^ "Pharao Design Report" (Issue dedicated to the ACES mission SRR). cnes.fr. 15 May 2005.[permanent dead link]
  15. ^ "Séminaire de prospective scientifique spatiale du Cnes" (PDF). cnes.fr (in French). 6 July 2004. p. 146.
  16. ^ "COROTCAM, la caméra de COROT" (PDF). obspm.fr (in French).[permanent dead link]
  17. ^ "Europe Dominating Satellite Startracker Market". Spaceref. 16 November 2012.
  18. ^ Marc Pochard. "New In-flight Results of SED16 Autonomous Star Sensor" (PDF). ZARM - Centre of applied space technology and microgravity. Archived from the original (54th International Astronautical Congress) on 2014-01-17. Retrieved 2013-02-25.
  19. ^ "e2v and Sodern celebrate the sale of the 100th Satellite Attitude Star Tracker incorporating e2v image sensors". e2v. 25 October 2007.
  20. ^ C. Anthony Vanelli; Brett Smith; Edward Swenka; Steve Collins (6 February 2010). "Straight on 'Til Morning: Guidance and Control Flight Experience from the Dawn Spacecraft". Univelt. p. 3.
  21. ^ Daniel Deak (8 March 2008). "ATV Le nouveau ravitailleur de l'ISS". Obsat (in French).
  22. ^ Jacques van Oene (December 13, 2004). "EADS SPACE, with its subsidiaries, is strongly involved in flight 165". spacebanter.
  23. ^ "Sodern star trackers for ISS-Reshetnev's spacecraft". ISS-Reshetnev. 28 June 2011.
  24. ^ Blarre, L.; Perrimon, N.; Lacroix, A.; Majewski, L.; Anciant, E. (2006). New Sodern's APS Based Autonomous Multiple Heads Star Sensor (hydra): Three Heads are Better than One. 6th International ESA Conference on Guidance, Navigation and Control Systems. Bibcode:2006ESASP.606E..11B.
  25. ^ Piot, Damien; Oddos-Marcel, Lionel; Gelin, Benoit; Thieuw, Alain; Genty, Patrick; Martinez, Pierre-Emmanuel; Airey, Stephen (February 13, 2013). HYDRA Star Tracker On-Board SPOT-6. 36th Annual American Astronautical Society Guidance & Control Conference. American Astronautical Society.
  26. ^ "Vintage poster".
  27. ^ esa. "Envisat-1 Mission & System Summary" (PDF). p. 81.
  28. ^ Corlay, G.; Arnolfo, M-C.; Bret-Dibat, T. (March 2001). "Microbolometer in space: IASI and PICASSO-CENA". Acta Astronautica. 48 (5–12): 299–309. Bibcode:2001AcAau..48..299C. doi:10.1016/S0094-5765(01)00019-4.
  29. ^ "Radiométre Imageur Infra-Rouge Calipso". cnes (in French). 27 March 2007.
  30. ^ "Du cœur des étoiles aux planètes habitables" (PDF). cnes (in French).
  31. ^ Torbjörn Westin. "Interior Orientation of Spot Imagery" (SSC Satellitbild Kiruna, Sweden - ISPRS Commission I). isprs. p. 193.
  32. ^ Roland Le Goff; François Tanguy; Philippe Fuss; Pierre Etcheto. "Technological development of multispectral filter assemblies for micro bolometer" (PDF). congrex. Archived from the original (PDF) on 2013-06-05.
  33. ^ International Atomic Energy Agency. "Manual for troubleshooting and upgrading of neutron generators" (PDF). IAEA. p. 35.
  34. ^ Toubon, H.; Mehlman, G.; Gain, T.; Lyoussi, A.; Perot, B.; Raoul, A.C.; Huver, M. (2001). Innovative nuclear measurement techniques used to characterize waste produced by Cogema's new compaction facility (PDF). WM’01 Conference. Tucson. p. 4. NAID 10025445866.
  35. ^ Bach, P.; Jatteau, M.; Ma, J. L.; Lambermont, C. (February 1993). "Industrial analysis possibilities using long-life sealed-tube neutron generators". Journal of Radioanalytical and Nuclear Chemistry. 168 (2): 393–401. doi:10.1007/BF02040519. S2CID 96009834.
  36. ^ "Sodern CNA-Cement". Panalytical.
  37. ^ Fernandez, Anabelle (2010). "Analyse en ligne des matières premières : EADS Sodern scanne les matière premières au neutron" [Online raw material analysis: EADS Sodern scans raw materials with neutron]. Ciments, bétons, plâtres, chaux (in French) (901): 30–39. INIST 22565274.
  38. ^ "Sodern CNA cross-belt analyzers". Panalytical.
  39. ^ Bruno Desruelle (5 June 2009). "La photonique pour les applications de défense et de sécurité" (PDF). Journées de l'Optique (in French). p. 20. Archived from the original (dga) on 17 January 2014.
  40. ^ "Sodern: Non-invasive detection of illicit and dangerous substances". git-security.com. May 1, 2009.
  41. ^ Lech Starostin. "OPCW approved-Non Destructive Evaluation (NDE) techniques in verification activities". opcw. p. 20.