Satellite flare

Satellite flare, also known as satellite glint, is a satellite pass visible to the naked eye as a brief, bright "flare". It is caused by the reflection toward the Earth below of sunlight incident on satellite surfaces such as solar panels and antennas (e.g., synthetic aperture radar). Streaks from satellite flare are a form of light pollution that can negatively affect ground-based astronomy, stargazing, and indigenous people.^[1][2][3][4]

• Top: a simulated animation of a typical Iridium flare
• Bottom: Both images show a flare of an Iridium satellite. Comet Holmes can be seen in the right image, slightly above the tree branch.

Many satellites flare with magnitudes bright enough to see with the unaided eye, i.e. brighter than magnitude +6.5.^[5][6] Smaller magnitude numbers are brighter, so negative magnitudes are brighter than positive magnitudes, i.e. the scale is reverse logarithmic (see apparent magnitude).

The Iridium constellation was one of the first anthropogenic sources of near-space light pollution to draw criticism. Larger satellite constellations, like OneWeb and Starlink, have received increased criticism.^[7][8][9] Scientific and policy analyses have raised questions about which regulatory bodies hold jurisdiction over human actions that obscure starlight in ways that affect astronomy,^[10][11][12] stargazers,^[13][14] and indigenous communities.^[4][3][15]

Controlled satellites

Flaring from reflection of the Sun

The time and place of the satellite's flare can be predicted only when the satellite is controlled, and its orientation in space is known. In this case it is possible to predict the exact time of the flare, its place in the sky, the brightness and duration.

Iridium flares

Double flare - Iridium 6 and its replacement, #51, both flare in a 21-second exposure.

First-generation Iridium satellite. Antennas can be seen in front, and solar panels in the back.

The first generation of the Iridium constellation launched a total of 95 telecommunication satellites in low Earth orbit which were known to cause Iridium flares, the brightest flares of all orbiting satellites, starting in 1997. From 2017 to 2019 they were replaced with a new generation that does not produce flares, with the first generation completely deorbited by 27 December 2019.^[16][17]

While the first-generation Iridium satellites were still controlled, their flares could be predicted.^[18] These Iridium communication satellites had three polished door-sized antennas, 120° apart and at 40° angles with the main bus. The forward antenna faced the direction the satellite is traveling. Occasionally, an antenna reflects sunlight directly down at Earth, creating a predictable and quickly moving illuminated spot on the surface below of about 10 km (6 mi) diameter. To an observer this looks like a bright flash, or flare in the sky, with a duration of a few seconds.

Ranging up to −9.5 magnitude, some of the flares were so bright that they could be seen in the daytime. This flashing caused some annoyance to astronomers, as the flares occasionally disturbed observations.^[19]

As the Iridium constellation consisted of 66 working satellites, Iridium flares were visible quite often (2 to 4 times per night). Flares of brightness −5 magnitude occurred 3 to 4 times per week, and −8 magnitude were visible 3 to 5 times per month for stationary observers.

Flares could also occur from solar panels, but they were not as bright (up to −3.5 magnitude). Such flares lasted about twice as long as those from the main mission antennas (MMA), because the so-called "mirror angle" for the solar panels was twice that for the MMAs. There were also rare cases of flares from MMAs and solar panels, or two MMAs (front and either right or left) of one satellite in a single pass.

The flares were bright enough to be seen at night in big cities where light pollution usually prevents most stellar observation. When not flaring, the satellites were often visible crossing the night sky at a typical magnitude of 6, similar to a dim star.

Mega-constellations

333 seconds-exposure containing 19 or more streaks due to Starlink satellites

Starlink Satellite Trails over Brazil alongside a shooting star - NASA's Astronomy Picture of the Day, 10 December 2019.^[20]

Planned low-orbit satellite constellations such as Starlink are a concern for astronomers, stargazers, and indigenous communities because of light pollution.^{[4][21][22][23]}

In February 2020, the Russian Academy of Sciences said it would send a letter to the United Nations complaining that Starlink's satellites will damage "30-40% of astronomical images."^[24][25][26]

Numerous satellite operators have criticized SpaceX for attempting to overwhelm the FCC with paperwork as a means to gain approval to launch 42,000 satellites,^[27] which has raised questions about which aspects of space law pertain to light pollution from satellites.^[4]

SpaceX and Elon Musk have asserted in meetings with the National Academy of Sciences^[28] and in FCC filings^[29] that "SpaceX is committed to reducing satellite brightness to allow enjoyment of the skies and not thwart scientific discovery"^[30] and that its objectives are (1) to "make the satellites generally invisible to the naked eye within a week of launch," and (2) to "minimize Starlink's impact on astronomy by darkening satellites so they do not saturate observatory detectors."^[30]

Other satellite flares

A COSMO-SkyMed flare

A MetOp-A flare

Many other controlled satellites also flare to magnitudes visible to the naked eye, i.e. larger than +6.5.^[5]

MetOp-B and C, however, can produce predictable flares up to −5 magnitude (MetOp-A in no longer controlled) .^{[31][32][33][34]} Four COSMO-SkyMed satellites can produce flares up to -3 magnitude, and lasting much longer than the Iridium flares.^[35] The Terrasar X and Tandem X also can produce predictable flares up to -3 magnitude.

The International Space Station (ISS) is known to cause bright ISS flares.^{[36][37][38][39]}

Composite image showing 27 minutes of Starlink satellite flares near the constellation Cassiopeia, 4/24/23.

Starlink satellites can flare repeatedly in an isolated area of the sky, typically directly above the sun (below the horizon) as they transit the highest latitude of their orbits. This phenomenon is most obvious when satellites are low over the horizon, and is due to the large number of Starlink satellites that are orbiting the Earth, predominantly at ~53° orbital inclination.^[40]

The flares from Starlink have been misidentified as UFOs by airline pilots^[41][42] due to their unusual repetitive nature, which is visually analogous to a car's headlights at night getting brighter (then dimmer) as it rounds a turn.

Uncontrolled satellites

When a satellite goes out of control, it becomes possible to predict only a trajectory of its pass, while it becomes virtually impossible to accurately predict any flaring. These non-operational satellites are also described as "tumbling". This category includes many rotating rocket bodies, some failed Iridium satellites, ALOS satellite (which can produce flashes up to −10 mag), etc. The most important and valuable information about tumbling satellites is the period of flashes. It can vary from 0.5 seconds (rapidly rotating objects) to a minute or more (slowly rotating objects). Other important characteristics are the amplitude of changes in brightness and period of repetition of these changes.^{[citation needed]}

Observation

Main article: List of satellite pass predictors

While satellites may be seen by chance, there are websites and mobile apps which provide location-specific information as to when and where in the sky a satellite flare may be seen (for controlled satellites), or trajectory of a tumbling satellite's pass (for uncontrolled satellites) in the sky.

Reflections from satellites and other human space objects are sometimes reported as unidentified flying objects (UFOs),^[43] and are often a result of repetitive observations in an isolated area of the sky over a short time period.

See also

• NanoSail-D
• Humanity Star

References

1. "SATCON1 Report". 25 August 2020. Archived from the original on 29 November 2020.
2. "Media advisory: Press Conference to Unveil Conclusions from Satellite Constellations 1 (SATCON1) Workshop" (Press release). 21 August 2020. Archived from the original on 29 November 2020.
3. Gallozzi, Stefano; Scardia, Marco; Maris, Michele (4 February 2020). "Concerns about ground based astronomical observations: A step to Safeguard the Astronomical Sky". arXiv:2001.10952 [astro-ph.IM].
4. Venkatesan, Aparna; Lowenthal, James; Prem, Parvathy; Vidaurri, Monica (2020). "The impact of satellite constellations on space as an ancestral global commons". Nature Astronomy. 4 (11): 1043–1048. Bibcode:2020NatAs...4.1043V. doi:10.1038/s41550-020-01238-3. S2CID 228975770.
5. Curtis, Heber Doust (1903) [1901-03-27]. "On the Limits of Unaided Vision". Lick Observatory Bulletin. 2 (38). University of California: 67–69. Bibcode:1903LicOB...2...67C. doi:10.5479/ADS/bib/1903LicOB.2.67C. PMID 17800603.
6. "Satellite and Flare Tracking". Retrieved 19 December 2020.
7. "IAU's statement on satellite constellations". International Astronomical Union. Retrieved 3 June 2019.
8. "Light pollution from satellites will get worse. But how much?". astronomy.com. 14 June 2019. Retrieved 7 November 2019.
9. "SpaceX Starlink satellite constellation astronomy light pollution". 29 May 2019. Archived from the original on 29 November 2020.
10. Bakos, Gaspar. "Light pollution from Satellites".
11. Montgomery, Marc (18 November 2020). "Astronomers vs tech giants in space". Archived from the original on 29 November 2020.
12. "SATCON1 Report". 25 August 2020.
13. "Why do mega constellations matter to the Dark Sky community" (Press release). 27 December 2019.
14. Lawler, Samantha (17 November 2020). "SpaceX's Starlink satellites are about to ruin stargazing for everyone".
15. Venkatesan, Aparna; Begay, David; Burgasser, Adam J.; Hawkins, Isabel; Kimura, Ka’iu; Maryboy, Nancy; Peticolas, Laura (6 December 2019). "Towards inclusive practices with indigenous knowledge". Nature Astronomy. 3 (12): 1035–1037. arXiv:2009.12425. Bibcode:2019NatAs...3.1035V. doi:10.1038/s41550-019-0953-2. S2CID 212942611.
16. "Catch the Iridium". Catch the Iridium. Retrieved 6 May 2020.
17. Carter, Jamie (14 November 2017). "Iridium flares to cease by end of 2018". BBC Sky at Night Magazine. Retrieved 26 May 2018.
18. Peat, Chris (15 May 2018). "The end of Iridium flares?". Heavens-Above. Munich. Retrieved 2 November 2018.
19. "Iridium Flare Satellite Tracker". Apollo Satellite Communications. Retrieved 6 November 2019.
20. Filter, Egon (10 December 2019). "NASA's Astronomy Picture of the Day showing Starlink Satellite Trails over Brazil". NASA.
21. Hall, Shannon (June 2019). "After SpaceX Starlink Launch, a Fear of Satellites That Outnumber All Visible Stars". The New York Times. Retrieved 3 June 2019.
22. "The unexpected brightness of new satellites could ruin the night sky". The Economist. 30 May 2019. Retrieved 3 June 2019.
23. "SpaceX's Starlink Could Change The Night Sky Forever, And Astronomers Are Not Happy". Forbes. Retrieved 3 June 2019.
24. "RAS will complain to the UN about Elon Musk over the Starlink satellite system". RIA Novosti. 27 February 2020.
25. Cole, Brendan (28 February 2020). "Light From Elon Musk's Starlink Satellites Ruins Space Photos, Says Russian Government Agency". Newsweek.
26. Tlis, Fatima (3 March 2020). "Russian Academy of Sciences Takes Aim at Musk's SpaceX Satellites". Polygraph Info.
27. Hebden, Kerry (18 October 2019). "Companies unite to reject SpaceX satellite plans".
28. "Decadal Survey on Astronomy and Astrophysics 2020 (Astro2020): Optical Interference from Satellite Constellations Meeting". National Academy of Science. 27 April 2020.
29. Wiltshire, William (30 April 2020). "Application for Fixed Satellite Service by Space Exploration Holdings, LLC SAT-MOD-20200417-00037 / SATMOD2020041700037 Space Exploration Holdings, LLC seeks to modify its Ku/Ka-band NGSO license to relocate satellites previously authorized to operate at altitudes from 1,110 km to 1,325 km down to altitudes ranging from 540 km to 570 km, and to make related changes".
30. Musk, Elon (27 April 2020). Starlink: NAS Decadal Panel. National Academy of Sciences.
31. "FPAS Reports - DB Query for Metop-A".
32. "FPAS Reports - DB Query for Metop-B".
33. Wesley (9 April 2014). "MetOp-A satellite flare".
34. "Video of Metop-A Flaring". 23 March 2012.
35. "FPAS Reports - DB Query for SkyMed 2".
36. "Watch International Space Station Flybys All Night Long". Sky & Telescope. 15 May 2019. Retrieved 6 May 2020.
37. Dickinson, David (14 May 2019). "The International Space Station Rides High Through the May Sky". Universe Today. Retrieved 6 May 2020.
38. Rao, Joe (11 July 2008). "Spot the Space Station". Space.com. Retrieved 6 May 2020.
39. "Spot The Station". spotthestation.nasa.gov. Retrieved 6 May 2020.
40. warnerjh (24 April 2023). "Starlink Satellites Flaring in Cassiopeia". CatchingTime. Retrieved 3 March 2024.
41. "Pilot Shares Videos Of Strange UFO Sightings In Skies Over The US". YouTube. 21 October 2022. Retrieved 21 October 2022.
42. "Why "Racetrack" UFOs are mostly Starlink Flares". Metabunk. 15 May 2019. Retrieved 23 October 2022.
43. "Is that a UFO?! There's probably an explanation - Human World". EarthSky | Updates on your cosmos and world. 15 December 2020. Retrieved 30 January 2022.

External links

• sourceforge.net/projects/previsat/ – PreviSat software which calculates satellite flares (Iridium, MetOp, SkyMed)
• www.heavens-above.com/IridiumFlares.aspx – schedule of upcoming Iridium flares
• iridiumflares.sourceforge.net – IridiumFlares prediction software (Java application)
• satobs.org/iridium.html – "Catch a Flaring Iridium" at Visual Satellite Observer
• www.fifthstarlabs.com – SkyGuide
• www.youtube.com/watch?v=ePBE7pHzAdA Iridium 25 flare near the Moon
• https://www.youtube.com/watch?v=FzaPT4ahyCs Starlink satellites repeatedly flaring low on horizon