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Satellite internet constellation

A satellite internet constellation is a constellation of artificial satellites providing satellite internet service. In particular, the term has come to refer to a new generation of very large constellations (sometimes referred to as megaconstellations[1]) orbiting in low Earth orbit (LEO) to provide low-latency, high bandwidth (broadband) internet service.[2] As of 2020, 63 percent of rural households worldwide lack internet access due to the infrastructure requirements of underground cables and network towers. Satellite internet constellations offer a low-cost solution for expanding coverage.[3]

History

While more-limited satellite internet services have been available through geosynchronous commsats orbiting in geostationary orbit for years, these have been of quite limited bandwidth (not broadband), high-latency, and provided at such a relatively high price that demand for the services offered has been quite low.[4][5][6]

In the 1990s, several LEO satellite internet constellations were proposed and developed, including Celestri (63 satellites) and Teledesic (initially 840, later 288 satellites). These projects were abandoned after the bankruptcy of the Iridium and Globalstar satellite phone constellations in the early 2000s.

In the 2010s, interest in satellite internet constellations reemerged due to the dropping cost of launching to space and the increased demand for broadband internet access. Internet satellite constellations are planned by private companies like OneWeb (OneWeb constellation),[7][8] SpaceX (Starlink),[9][10] Amazon (Project Kuiper),[11][12] Samsung and Russia's Roscosmos (Sfera)[13][14] and China (Hongwan, 2018,[2] or national satellite internet project, 2021).[15] By late 2018, more than 18,000 new satellites had been proposed to be launched and placed in LEO orbits between 2019 and 2025.[2] This is more than ten times as many satellites as the sum of all active satellites in space as of March 2018. More recent proposals by 2020 could bring that number to over 100,000.[16]

A year after the start of fielding the first satellite internet constellation—Starlink which began launching in late 2019 and began beta test of the network in late 2020; OneWeb began satellite deployment in 1H2020—the competitive disruption to established satellite company business models began to be better understood. In early 2021, the three largest European satellite operators SES, Eutelsat, and Hispasat—which had until that time eschewed developing and fielding a broadband satellite internet constellation with private funds—informed the European Commission that they would be willing to invest in the development of such a project if the European Union were to invest government funds in the effort as well.[17] All three companies had formerly focused on the provision of communication services from GEO and MEO orbits, while the newer satellite internet providers have been fielding their constellations exclusively in LEO.[17]

In 2018, the Russian government established the Sfera (Sphere) constellation program, to consist of 162 satellites, providing broadband internet connectivity, message relay, video broadcast, and remote sensing services. In October 2022, a demonstrator satellite called Skif-D technology was launched.[18]

Design

Proposed systems vary greatly in the number of satellites, the types of orbits and the telecommunication architecture (in particular the presence or absence of inter-satellite links). System designs have been analyzed using statistical methods and simulations to estimate the total throughput.[19] Particularly challenging is the dynamic nature of the network, as LEO satellites typically pass over a given location in less than 10 minutes.[20]

Potential

For continental distances (greater than about 3,000 km[21]), LEO satellite internet networks are expected to be able to provide lower latency than optical fiber links.[22][21][23] This is expected to hold even without inter-satellite links, using only ground station relays.[24][25] The new networks are said to be able to "potentially compete with today's ISPs in many settings".[21]

Issues and criticism

Critics have objected against the increased light pollution for astronomy, the increased possibility satellite collisions resulting in space debris and, more generally, a lack of end-of-life cleanup for the increasing number of satellites that would become space debris.[26][27]

Astronomers have studied the potential effects increased satellite usage in Low Earth Orbit would have on Very Large Telescope that use ultra-wide imaging exposures, such as the 8.4-meter Simonyi Survey Telescope[28] used in the Legacy Survey of Space and Time project at the Vera C. Rubin Observatory. They found that 30 to 40% of exposures could be compromised during the first and last hours of the night.[29] A study found that twilight observations are particularly affected by SC and that the fraction of streaked images taken during twilight has increased from less than 0.5% in late 2019 to 18% in August 2021 due to SpaceX Starlink Satellites.[30] Astronomers have also voiced concern over the impact satellite internet constellations will have on radio astronomy.[31]

Additional research is needed to determine impact of (inter alia) light pollution on various locations, communities, indigenous peoples, and other forms of observation.

Mitigation in astronomy

A report from the SATCON1 workshop in 2020 concluded that the effects of large satellite constellations can severely affect some astronomical research efforts and lists six ways to mitigate harm to astronomy.[32][33] In 2022, the IAU announced the Centre for the Protection of the Dark and Quiet Sky from Satellite Constellation Interference to coordinate or aggregate measures to mitigate such detrimental effects.[34][35][36] The AAS is maintaining a living document that tracks recent progress in the field.[37]

Space governance

The growth of all tracked objects in space over time showing a recent increase of active satellites[38]

UN Guidelines and ISO standard 24113 on space debris mitigation "encourages" organizations to voluntarily:[27]

  • Limit debris released during normal operations
  • Minimize the potential for on-orbit break-ups
  • Post-mission disposal
  • Prevention of on-orbit collisions

A study suggests policies could help achieve the goal of debris mitigation and space sustainability.[27] A team of scientists outlined rationale for governance that regulates the current free externalization of true costs and risks, treating orbital space around the Earth as an "additional ecosystem" or a common "part of the human environment" which should be subject to the same concerns and regulations like e.g. oceans on Earth. The study concludes that it needs "new policies, rules and regulations at national and international level".[39][38]

As of 2022, global space activity is not sufficiently shaped by any international entity, and therefore "there is no common set of rules that govern global space activity and no mechanisms to ensure the proper disposal of hardware at the completion of space missions. Nor is there any coordinated effort to clean up the decades of space debris already accumulated in orbit."[40]

Federation of Cross-Orbit Satellite Networks

There exist many satellite operators at LEO, MEO, and GEO. Similar to the Internet, which is a network of networks, satellite networks of different operators can also form federated networks of satellite networks.[41]

Constellations

Operational

  • Globalstar — an operational constellation of 24 low Earth orbiting (LEO) satellites for satellite phone and low-speed data communications, covering most of the world's landmass. The launch of the second-generation constellation was completed on February 6, 2013
  • Iridium — an operational constellation of 66 cross-linked satellites in a polar orbit, used to provide satellite phone and low-speed data services over the entire surface of Earth. Iridium NEXT, a second-generation constellation of the communications satellites, was completed on January 11, 2019
  • Orbcomm — an operational constellation used to provide global asset monitoring and messaging services from its constellation of 29 LEO communications satellites orbiting at 775 km
  • Starlink — a satellite constellation development project to provide high-speed Internet underway by SpaceX to deploy nearly 12,000 satellites in multiple orbital shells by the mid-2020s
  • Lynk Global — a satellite-to-mobile-phone satellite constellation with the objective of coverage to traditional low-cost mobile devices
  • Viasat, Inc. — a current broadband satellite provider providing fixed, ground mobile, and airborne antennas
  • OneWeb constellation — 648-satellite network is planned for completion by late 2022
  • Project Kuiper — Amazon's constellation will consist of 3,236 satellites operating in three orbital shells
  • O3b mPOWER - provides coverage to most of the globe under a service launched in 2024. Satellites were built by Boeing.
  • China State Owned Constellation (Chinasat) — an operational satellite internet constellation owned by the government of China.[42][43]
  • AST SpaceMobile — a satellite-to-mobile-phone constellation to provide 5G services around the world to existing unmodified mobile phones[44]
  • G60/Qianfan — a megaconstellation project developed by Shanghai Spacecom Satellite Technology (SSST) to deploy 14,000 satellites by 2030. The first stage consists of 1,296 satellites to provide global coverage; 648 of these are to be launched by the end of 2025 to provide regional network coverage. The first launch was on August 6, 2024.[45], second batch of satellites were launched on 15 October 2024.

Planned

Defunct

  • Teledesic — a former (1990s) venture to accomplish broadband satellite internet services

See also

References

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