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| title | chunk | source | category | tags | date_saved | instance |
|---|---|---|---|---|---|---|
| Space Safety Programme | 1/2 | https://en.wikipedia.org/wiki/Space_Safety_Programme | reference | science, encyclopedia | 2026-05-05T13:22:57.133102+00:00 | kb-cron |
The Space Safety Programme (S2P), formerly the Space Situational Awareness (SSA) programme, is an initiative by the European Space Agency (ESA) to monitor hazards from space, determine their risk, make this data available to the appropriate authorities, and where possible, mitigate the threat. The programme focuses on 3 areas: space weather forecasting and nowcasting, asteroid impact prediction and prevention, and space debris mitigation. S2P is being implemented as an optional ESA programme with financial participation by 14 Member States.
== History ==
The programme started in 2009 and its mandate was extended until 2019. The second phase of the programme received €46.5 million for the 2013–2016 period. The original SSA Programme was designed to support Europe's independent space access and utilization through the timely and accurate information delivery regarding the space environment, particularly hazards to both in-orbit and ground infrastructure. In 2019 it evolved into the present Space Safety Programme (S2P) with an expanded focus, also including missions and activities to mitigate and prevent dangers from space. At the ESA ministerial council in 2025, member states committed to a budget of €955 million for S2P over the following three years, increasing the budget by 30%. These funds were even higher than what the programme requested and covered all plans outlined in the proposal published before the council. In 2025, IAU approved the naming of 10 asteroids after people and places connected with ESA's planetary defense projects.
== Structure == The programme is split into three "Cornerstones" managing major missions and six "COSMIC" areas managing small missions and other aspects of the programme:
=== Space Weather Cornerstone === S2P's space weather projects are monitoring the activity of the Sun, the solar wind, and Earth's magnetosphere, ionosphere, and thermosphere, that can affect spaceborne and ground-based infrastructure or endanger human life or health. This data is processed and made available freely via the Space Weather Service Network. The upcoming deep-space mission Vigil, designed to observe the Sun from the Sun-Earth Lagrange point L5, will contribute to this monitoring system, allowing for timely warnings.
=== Planetary Defence Cornerstone === Planetary Defence at ESA focuses on detecting natural objects, such as asteroids and comets, which can potentially impact Earth, gathering observations from telescopes around the world and plotting their path through the sky to calculate the impact risk. Another area of the Cornerstone's activity is coordinating the response to a possible impactor with the international community through groups such as the International Asteroid Warning Network (IAWN) and the Space Mission Planning Advisory Group (SMPAG). The European asteroid observation network is coordinated by the S2P's Near-Earth Object Coordination Centre (NEOCC). In October 2024, ESA launched the Hera mission, a follow-up to NASA's DART mission which performed the first kinetic impact test of Planetary Defence on 26 September 2022. Hera will rendezvous with the impacted Didymos binary asteroid system in 2026 to study the crater formed, the dust plume released, and more. S2P is working on another asteroid exploration mission, the Hera-derived Ramses and developing the asteroid-detecting space telescope named NEOMIR that will be placed in the Sun–Earth Lagrange point L1.
=== ADRIOS Cornerstone === The Active Debris Removal & In-Orbit Servicing (ADRIOS) Cornerstone supports development of technologies for space debris removal and on-orbit servicing of satellites for sustainable use of space. The ADRIOS Cornerstone is developing the CApTure Payload Bay (CAT) and RISE missions. Space debris projects at ESA are tracking active and inactive satellites and space debris to better understand the debris environment, providing data, analysis, and advice to spacecraft engineers to perform collision avoidance manoeuvres, as well as developing a system of automated collision avoidance. The space debris office also works with the international community on norms and standards for the sustainable future of space. Clean Space projects aim for systematically considering the entire life-cycle of space activities, from the early stages of conceptual design to the mission's end of life and beyond, to removal of space debris. ESA Clean Space includes EcoDesign (embedding environmental sustainability within space mission design), management of end-of-life, developing technologies to prevent the creation of future debris, in-orbit servicing/active debris removal, removing spacecraft from orbit, and demonstrating in-orbit servicing of spacecraft.
=== COSMIC areas === The "COSMIC" areas aim to develop and support:
Space weather services Space weather sensors Asteroid impact prediction Technologies for increased space traffic Clean and zero space debris future Competitiveness Earth-orbiting space weather missions like SWING, SAWA, Aurora, and SWORD will form the Distributed Space Weather Sensor System (D3S) complementing the deep-space observations by Vigil. ESA is also supporting development of new terrestrial solar monitoring stations, e.g. the Radio Observations of the Solar Indicative Emissions (ROSIE) station in Białków, Poland. ESA is building the Flyeye network of automated ground-based telescopes to scan the sky every night for Near Earth Object (NEO) detection. The first telescope, built on Sicily, had its first light in 2025. The Draco mission will study the process of satellite breakup during uncontrolled atmospheric reentry. The first mission to remove a piece of space debris from orbit will be the ESA-commissioned ClearSpace-1. ESA is also testing laser-based technologies for precise tracking, and possibly also remote deflection, of space debris at Izaña-1 and Izaña-2 laser-ranging stations at Teide Observatory on Tenerife. The laser deflection system, named OMLET (Orbit Maintenance via Laser MomEntum Transfer), is expected to become operational in 2031.
== Space missions ==