COSMO-SkyMed

COSMO-SkyMed Second Generation
Manufacturer	Thales Alenia Space
Country of origin	Italy
Operator	ASI
Applications	Earth observation radar
Website	http://www.cosmo-skymed.it/it/index.htm
Specifications
Bus	PRIMA
Launch mass	2,205 kg (4,861 lb)
Power	5 kW
Regime	Sun-synchronous orbit
Design life	7 years (planned)
Production
Status	Operational
On order	4
Built	2
Launched	2
Operational	1
Maiden launch	CSG-1; 18 December 2019, 08:54 UTC

COSMO-SkyMed
	A COSMO-SkyMed flare above the UK
Manufacturer	Thales Alenia Space
Country of origin	Italy
Operator	ASI
Applications	Earth observation radar
Website	http://www.cosmo-skymed.it/it/index.htm
Specifications
Bus	PRIMA
Launch mass	1,700 kg (3,700 lb)
Power	4 kW
Regime	Sun-synchronous orbit
Design life	5 years (planned)
Production
Status	Operational
On order	4
Built	4
Launched	4
Operational	4
Maiden launch	COSMO-1 ; 23 June 2007, 02:34:00 UTC
Last launch	COSMO-4; 5 November 2010, 02:20:03 UTC

Last updated July 30, 2023

COSMO-SkyMed (COnstellation of small Satellites for the Mediterranean basin Observation) is an Earth-observation satellite space-based radar system funded by the Italian Ministry of Research and Ministry of Defence and conducted by the Italian Space Agency (ASI), intended for both military and civilian use.^[3] The prime contractor for the spacecraft was Thales Alenia Space. COSMO SkyMed is a constellation of four dual use Intelligence, surveillance, target acquisition, and reconnaissance (ISR) Earth observation satellites with a synthetic-aperture radar (SAR) as main payload, the result of the intuition of Giorgio Perrotta in the early nineties. The synthetic-aperture radar was developed starting in the late nineties with the SAR 2000 program funded by ASI.

The space segment of the system includes four identical medium-sized 1,700 kg (3,700 lb) satellites called COSMO-SkyMed (or COSMO) 1, 2, 3, 4, equipped with synthetic-aperture radar (SAR) sensors with global coverage of the planet.^[4] Observations of an area of interest can be repeated several times a day in all-weather conditions. The imagery is applied to defense and security assurance in Italy and other countries, seismic hazard analysis, environmental disaster monitoring, and agricultural mapping.^[5]

COSMO-SkyMed first generation

The four satellites are in Sun-synchronous polar orbits with a 97.90° inclination at a nominal altitude of 619 km (385 mi) and an orbital period of 97.20 minutes. The local time ascending node at the equator is 06:00. The operating life of each satellite is estimated to be 5 years. Each satellite repeats the same ground track every 16 days. They cross the equator at approximately 06:00 and 18:00 local-time each day and can image any point twice each day. The satellites are phased in the same orbital plane, with COSMO-SkyMed's 1, 3, and 2 at 90° intervals followed by COSMO-SkyMed 4 at 67.5° after COSMO-SkyMed 2. The offset of satellite 4 allows a one-day interferometry mode for elevation information.^[6] The Sun-synchronous orbit (SSO) is used due to power (Electrical Power Subsystem) and revisit time requirements.

The satellites' main components are:

Two solar arrays for 3.8 kW at 42 V DC
Stabilization, navigation and Global Positioning System (GPS) systems
Synthetic-aperture radar (SAR) working in X-band
300 Gbit on-board memory and 310 Mbit/s data-link with ground segments

The radar antenna is a phased array that is 1.4 × 5.7 m (4 ft 7 in × 18 ft 8 in). The system is capable of both single- and dual-polarization collection. The center frequency is 9.6 GHz with a maximum radar bandwidth of 400 MHz.^[7]

List of launches

United Launch Alliance provided launch services for the satellites with their Delta II 7420-10C launch vehicles from Vandenberg Air Force Base.^[8] Satellite processing for the first two satellites was handled by the Astrotech Space Operations subsidiary of SPACEHAB.^[5] The first satellite COSMO-1 (COSPAR 2007-023A) was launched at 02:34:00 UTC on 8 June 2007.^[9] COSMO-2 (COSPAR 2007-059A) was launched at 02:31:42 UTC on 9 December 2007,^[10] the launch having been delayed from 6 December 2007 due to bad weather, and problems with the rocket's cork insulation. COSMO-3 (COSPAR 2008-054A) launched at 02:28 UTC on 25 October 2008. COSMO-4 (COSPAR 2010-060A) launched on 6 November 2010, at 02:20 UTC.^[11]

Flight No.	Date/Time (UTC)	Launch site	Launch vehicle	Payload	Outcome
1	8 June 2007, 02:34:00	VAFB, SLC-2W	Delta II 7420-10	COSMO-1	Success
2	9 December 2007, 02:31:42	VAFB, SLC-2W	Delta II 7420-10	COSMO-2	Success
3	25 October 2008, 02:28:25	VAFB, SLC-2W	Delta II 7420-10C	COSMO-3	Success
4	6 November 2010, 02:20:03	VAFB, SLC-2W	Delta II 7420-10C	COSMO-4	Success

Ground segment

The ground segment of the system is composed of:

Command Center:
- Italian Centro Controllo e Pianificazione Missione del Fucino
Tracking and data stations:
- Argentine Cordoba Station
- Sweden Kiruna Station
User Ground Segments:
- Italian Matera Civil User Ground Segment
- Italian Pratica di Mare Defence User Ground Segment
- France Defence User Ground Segment

The governments of Argentina and France are involved respectively in the civil and military segments of the system.

SAR capabilities

The COSMO-SkyMed satellites have three basic types of imaging modes:

Spotlight, a high-resolution mode collected over a small area by steering the radar beam slightly fore-to-aft during the collection period
Stripmap, a medium-resolution mode collected over long, continuous swaths in which the beam is pointed broadside to the satellite track
ScanSAR, a low-resolution mode that creates extra-wide swaths by collecting short segments at different ranges and then mosaicking them together

There are two Spotlight modes:

SPOTLIGHT1, which is a military-only mode, and
SPOTLIGHT2, which provides a resolution of 1 m (3 ft 3 in) over a 10 × 10 km (6.2 × 6.2 mi) area. Spotlight polarization is limited to either HH or VV

There are two Stripmap modes:

HIMAGE, which provides a resolution of between 3 and 5 m (9.8 and 16.4 ft) over a swath of 40 km (25 mi), and
PINGPONG, which collects dual-polarization data at 15 m (49 ft) resolution over a swath of 30 km (19 mi). The dual-polarization data can consist of any two polarizations (HH, VV, VH, HV), and it is non-coherent, as it is collected in "pulse groups" that alternate from one polarization to the other.

There are two ScanSAR modes:

WIDEREGION, which provides 30 m (98 ft) resolution data over a swath of 100 km (62 mi), and
HUGEREGION, which provides 100 m (330 ft) resolution data over a swath of 200 km (120 mi).

The system is sized to collect up to 450 images per satellite per day.^[12]

Overview of Damage Proxy Map from COSMO-SkyMed data
Detail of the Damage Proxy Map of Norcia, Italy
View of Norcia before October 2016 Central Italy earthquakes
View of Norcia after October 2016 Central Italy earthquakes

Commercialization

e-GEOS, S.p.A., a joint venture between European spaceflight services company Telespazio (80%) and the Italian Space Agency (ASI) (20%), has the exclusive worldwide commercial rights to sell COSMO-SkyMed data and products.^[13]^[12]

Flares

The COSMO-SkyMed satellites are lesser-known deliverers of satellite flares, sometimes approaching magnitude −3. Flares come mainly from SAR-panels of the satellites. Although overshadowed by the Iridium satellites, the flares are often long-lasting, with the satellites traversing much of the sky at brighter-than-average magnitudes.

COSMO-SkyMed second generation (CSG)

To replace the first COSMO-SkyMed constellation, the Italian Space Agency is developing the COSMO-SkyMed second generation constellation. The 2nd generation constellation has the same function of radar-based Earth observation with particular focus on the Mediterranean area as the 1st generation. Like the 1st generation, the 2nd generation also consists of 4 satellites, CSG-1, CSG-2, CSG-3 and CSG-4. The satellites are improved versions of the first generation satellites. Also the radar payload CSG-SAR (COSMO-SkyMed Second Generation Synthetic Aperture Radar) is an improved version of the first generation X-band SAR payload. Furthermore, the 2nd generation satellites will operate in the same orbit (indeed, in the same orbital plane) as the first generation satellites. The 2nd generation satellites slightly outweigh the first generation satellites at 2,205 kg (4,861 lb) of mass.^[14]

The contract for building two satellites was signed in September 2015. In December 2020, another two satellites were ordered. The satellites are built by Thales Alenia Space (the successor company of Alenia Spazio). They have a planned lifetime of 7 years. CSG-1 was launched on 18 December 2019 by Soyuz ST-A from Centre spatial Guyanais (CSG). CSG-2 was launched on 31 January 2022 by Falcon 9 Block 5 from Space Launch Complex 40 at Cape Canaveral Space Force Station,^[15] while the CSG-3 satellite is scheduled to be launched in 2024 on a Vega-C launch vehicle.^[16]

List of launches

Flight No.	Date/Time (UTC)	Launch site	Launch vehicle	Payload	Outcome	Notes
1	18 December 2019, 08:54:20	Kourou, ELS	Soyuz ST-A / Fregat-MT	CSG-1	Success	On 18 January 2021, COSMO-SkyMed Second Generation-1 (CSG-1) became operational with the first of four satellites.^[17]
2	31 January 2022, 23:11:14	CCSFS, SLC-40	Falcon 9 Block 5 ♺ B1052.3 ^[18]	CSG-2	Success	On 31 January 2022, SpaceX launched COSMO-SkyMed Second Generation FM2 mission to low Earth orbit from Space Launch Complex 40 (SLC-40) at Cape Canaveral Space Force Station in Florida.
3	2024	Kourou, ELV	Vega-C	CSG-3	Planned
4	2027 ?	Kourou, ELV	Vega-C	CSG-4	Planned

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References

↑ "COSMO-SkyMed (Constellation of 4 SAR Satellites)". eoportal.org. Retrieved 26 November 2020.
↑ "COSMO-SkyMed Second Generation (CSG) Constellation". eoportal.org. Retrieved 26 November 2020.
↑ "COSMO-SkyMed: Mission definition and main applications and products" (PDF). ESA.
↑ "COSMO-SkyMed". Telespazio. Archived from the original on 8 July 2007.
1 2 "SPACEHAB Subsidiary Signs New Contracts Totaling US$4.7 million". SPACEHAB.
↑ "COSMO-SkyMed Mission and Products Description 23/01/2019". e-geos.my.salesforce.com. Italian Space Agency. Retrieved 24 August 2020.
↑ "COSMO-SkyMed User Guide" (PDF). ASI. Archived from the original (PDF) on 29 August 2017. Retrieved 8 November 2012.
↑ "Boeing To Launch Fourth EO Satellite For Italy". SpaceDaily. 23 December 2008.
↑ "Worldwide launch schedule". Spaceflight Now. Archived from the original on 11 September 2013.
↑ NASA Spaceflight.com – Delta II launches with COSMO-SkyMed-2 Archived 8 December 2007 at the Wayback Machine
↑ "COSMO 1, 2, 3, 4". Gunter's Space Page. 7 July 2020. Retrieved 12 October 2021.
1 2 "eGEOS: COSMO-SkyMed Overview". eGEOS. Archived from the original on 22 July 2013. Retrieved 10 August 2011.(subscription required)
↑ "E-GEOS to Create Early Warning System for Caribbean Weather Emergencies". satellitetoday.com. 18 December 2018. Retrieved 23 August 2019.
↑ "CSG 1, 2, 3, 4 (COSMO-SkyMed 2nd Gen.)". Gunter's Space Page. 3 October 2021. Retrieved 12 October 2021.
↑ "Falcon 9 finally launches with Italian CSG-2 Earth observation satellite". NASASpaceflight. 31 January 2022. Retrieved 1 February 2022.
↑ "COSMO-SKYMED". Italian Space Agencydate. 3 October 2021. Retrieved 3 October 2021.
↑ "COSMO-SkyMed". Agenzia Spaziale Italiana. 12 October 2021. Retrieved 12 October 2021.
↑ "CSG-2 | Falcon 9 Block 5". 25 January 2022.

External links

COSMO-SkyMed Web Site
COSMO-SkyMed Products Archived 22 July 2013 at the Wayback Machine
INNOVA Consorzio per l'Informatica e la Telematica s.r.l. – Italian SME with specific know-how and expertise with COSMO-SkyMed's HDF5 format
Remote Monitoring of Migrants Vessels in the Mediterranean Sea (CeMiSS)

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[eoPortal-CSK-1] "COSMO-SkyMed (Constellation of 4 SAR Satellites)". eoportal.org. Retrieved 26 November 2020.

[eoPortal-CSG-2] "COSMO-SkyMed Second Generation (CSG) Constellation". eoportal.org. Retrieved 26 November 2020.

[3] "COSMO-SkyMed: Mission definition and main applications and products" (PDF). ESA.

[4] "COSMO-SkyMed". Telespazio. Archived from the original on 8 July 2007.

[SH-5] 1 2 "SPACEHAB Subsidiary Signs New Contracts Totaling US$4.7 million". SPACEHAB.

[6] "COSMO-SkyMed Mission and Products Description 23/01/2019". e-geos.my.salesforce.com. Italian Space Agency. Retrieved 24 August 2020.

[7] "COSMO-SkyMed User Guide" (PDF). ASI. Archived from the original (PDF) on 29 August 2017. Retrieved 8 November 2012.

[8] "Boeing To Launch Fourth EO Satellite For Italy". SpaceDaily. 23 December 2008.

[SFN-9] "Worldwide launch schedule". Spaceflight Now. Archived from the original on 11 September 2013.

[NSF-PL2-10] NASA Spaceflight.com – Delta II launches with COSMO-SkyMed-2 Archived 8 December 2007 at the Wayback Machine

[Gunter-11] "COSMO 1, 2, 3, 4". Gunter's Space Page. 7 July 2020. Retrieved 12 October 2021.

[e-geos-12] 1 2 "eGEOS: COSMO-SkyMed Overview". eGEOS. Archived from the original on 22 July 2013. Retrieved 10 August 2011.(subscription required)

[13] "E-GEOS to Create Early Warning System for Caribbean Weather Emergencies". satellitetoday.com. 18 December 2018. Retrieved 23 August 2019.

[14] "CSG 1, 2, 3, 4 (COSMO-SkyMed 2nd Gen.)". Gunter's Space Page. 3 October 2021. Retrieved 12 October 2021.

[15] "Falcon 9 finally launches with Italian CSG-2 Earth observation satellite". NASASpaceflight. 31 January 2022. Retrieved 1 February 2022.

[16] "COSMO-SKYMED". Italian Space Agencydate. 3 October 2021. Retrieved 3 October 2021.

[ASI-17] "COSMO-SkyMed". Agenzia Spaziale Italiana. 12 October 2021. Retrieved 12 October 2021.

[18] "CSG-2 | Falcon 9 Block 5". 25 January 2022.

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v t e ← 2009 · Orbital launches in 2010 · 2011 →
January	Compass-G1 Globus-1M No.12L
February	Progress M-04M STS-130 (Tranquility, Cupola) SDO Intelsat 16
March	Kosmos 2459, Kosmos 2460, Kosmos 2461 GOES 15 Yaogan 9A, Yaogan 9B, Yaogan 9C EchoStar XIV
April	Soyuz TMA-18 STS-131 (Leonardo MPLM) CryoSat-2 GSAT-4 Kosmos 2462 USA-212 SES-1 Kosmos 2463 Progress M-05M
May	STS-132 (Rassvet, ICC-VLD) Akatsuki, IKAROS (DCAM-1, DCAM-2), Shin'en, Waseda-SAT2, Hayato, Negai ☆'' Astra 3B, COMSATBw-2 USA-213
June	SERVIS-2 Compass-G3 Badr-5 Dragon Spacecraft Qualification Unit STSAT-2B Shijian XII Prisma, Picard, BPA-1 Soyuz TMA-19 TanDEM-X Ofek-9 Arabsat-5A, Chollian Progress M-06M
July	EchoStar XV Cartosat-2B, AlSat-2A, StudSat, AISSat-1, TIsat-1 Compass-IGSO1
August	Nilesat 201, RASCOM-QAF 1R Yaogan 10 USA-214 Tian Hui 1
September	Kosmos 2464, Kosmos 2465, Kosmos 2466 Chinasat-6A Gonets-M No.2, Kosmos 2467, Kosmos 2468 Progress M-07M Michibiki USA-215 Yaogan 11, Zheda Pixing 1B, Zheda Pixing 1C USA-216 Kosmos 2469
October	Chang'e 2 Shijian 6G, Shijian 6H Soyuz TMA-01M XM-5 Globalstar 73, Globalstar 74, Globalstar 75, Globalstar 76, Globalstar 77, Globalstar 79 Progress M-08M Eutelsat W3B, BSat 3B Compass-G4
November	Meridian 3 Fengyun 3B COSMO-4 SkyTerra-1 STPSat-2, USA-220 / FASTSAT ( NanoSail-D2 ), USA-221 / FalconSat-5, USA-222 / FASTRAC-1, USA-222 / FASTRAC-2, USA-218 / RAX , USA-219 / O/OREOS USA-223 / Orion 7 Chinasat 20A Intelsat 17, HYLAS-1
December	Glonass-M No.39, Glonass-M No.40, Glonass-M No.41 SpaceX COTS Demo Flight 1, Mayflower, SMDC-ONE 1, QbX-1, QbX-2, Perseus 000, Perseus 001, Perseus 002, Perseus 003 Soyuz TMA-20 Compass-IGSO2 GSAT-5P KA-SAT
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).

v t e ← 2018 · Orbital launches in 2019 · 2020 →
January	ChinaSat 2D Iridium NEXT × 10 RAPIS-1, ALE-1, Hodoyoshi-2, MicroDragon, AOBA-VELOX-IV , NEXUS , OrigamiSat-1 USA-290 / KH-11 17 Jilin-1 Hyperspectral-01, Jilin-1 Hyperspectral-02 Microsat-R
February	Dousti† GSAT-31, SaudiGeoSat-1 / HellasSat-4 EgyptSat A, Helios Wire 4 Nusantara Satu / PSN 6, Beresheet, S5 OneWeb x6
March	Crew Dragon Demo-1 ChinaSat-6C Soyuz MS-12 WGS-10 PRISMA Lingque 1B† "Two Thumbs Up" (R3D2) Tianlian II-01
April	EMISAT, Astrocast 0.2 , Bluewalker 1 , Flock-4a × 20, Lemur-2 × 4, M6P , Progress MS-11 O3b × 4 Arabsat-6A Cygnus NG-11 ( NepaliSat-1 , Raavana 1 , Seeker ) BeiDou-3 I1Q
May	SpaceX CRS-17 Harbinger / ICEYE X3 BeiDou-2 G8 RISAT-2B Yaogan 33† Starlink v0.9 (60 satellites) GLONASS-M 758 Yamal-601
June	Jilin-1 Gaofen-03A RADARSAT Constellation × 3 Eutelsat 7C BeiDou-3 I2Q STP-2, DSX, COSMIC-2 × 6, GPIM, StangSat , FalconSAT-7 , BRICSat-2 , LightSail-2 BlackSky Global 3, SpaceBEE 8 , SpaceBEE 9
July	Meteor-M 2-2, CarboNIX, ICEYE X4, ICEYE X5, Lemur-2 × 8 Kosmos 2535, Kosmos 2536, Kosmos 2537, Kosmos 2538 Falcon Eye 1† Spektr-RG Soyuz MS-13 Chandrayaan-2 Vikram Pragyan SpaceX CRS-18 Yaogan 30-05 x3 Meridian 8 Progress MS-12
August	Blagovest-14L EDRS-C / HYLAS-3 Amos-17 AEHF-5 Tianqi-2, Qian Sheng-1 01 / Xingshidai-5 Chinasat 18 "Look Ma, No Hands" BlackSky Global 4 BRO 1 Pearl White × 2 Soyuz MS-14 GPS IIIA-02 Nahid-1† Geo-IK-2 No.3 Taiji-1, Xiaoxiang 1-07
September	Ziyuan I-02D, Ice Pathfinder, Taurus 1 Zhuhai-1 x2 BeiDou-3 M23, M24 HTV-8 Yunhai-1 02 Soyuz MS-15 EKS-3
October	Gaofen 10R Eutelsat 5 West B, MEV-1 ICON "As The Crow Flies" Palisade TJS-4
November	Cygnus NG-12 (STPSat 4) Gaofen 7 BeiDou-3 I3Q Starlink V1.0-L1 (60 satellites) Jilin-1 Gaofen-02A BeiDou-3 M21, BeiDou-3 M22 Kosmos 2542, Kosmos 2543 Inmarsat-5 F5 Cartosat-3, Flock-4p × 12 Gaofen 12
December	SpaceX CRS-19 Unicorn-2B / NOOR-1A, Unicorn-2C / NOOR-1B Progress MS-13 Jilin-1 Gaofen-02B Kosmos 2544 / GLONASS-M 759 RISAT-2BR1, Lemur-2 × 4 BeiDou-3 M19, BeiDou-3 M20 JCSAT-18 / Kacific 1 CHEOPS, CSG-1, OPS-SAT CBERS-4A / Ziyuan I-04A, ETRSS-1, Tianqin-1 Starliner Boe-OFT Elektro-L No.3 Gonets-M × 3, BLITS-M Shijian 20
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).

v t e ← 2021 · Orbital launches in 2022 · 2023 →
January	Starlink G4-5 (49 satellites) ION-SCV 004 ( LabSat, STORK-1, STORK-2, SW1FT ), Capella 7, Capella 8, ICEYE X14, ICEYE X16, USA-320, USA-321, USA-322, USA-323, DEWA SAT-1 , Flock 4x × 44, Kepler × 4, Lemur-2 × 5, Nepal PQ-1 Lemur-2 Krywe, STORK-3 , TechEdSat-13 , Unicorn-1 , Unicorn-2 × 4 Shiyan 13 Starlink G4-6 (49 satellites) USA-324 / GSSAP-5, USA-325 / GSSAP-6 CSG-2
February	USA-326 Starlink G4-7 (49 satellites) Kosmos 2553 / Neitron №1 OneWeb L13 (34 satellites) EOS-04 / RISAT-1A Progress MS-19 Cygnus NG-17 ( KITSUNE ) Starlink G4-8 (46 satellites) Starlink G4-11 (50 satellites) Jilin-1 Gaofen-03D × 9, Jilin-1 Mofang-02A 01
March	GOES-18 / GOES-T Starlink G4-9 (47 satellites) Noor 2 Starlink G4-10 (48 satellites) SpaceBEE × 16, SpaceBEE NZ × 4 Yaogan 34-02 Soyuz MS-21 Starlink G4-12 (53 satellites) Meridian-M 10
April	ION-SCV 005 ( KSF2 × 4), EnMAP, Lynk Tower 01, MP42 / Tiger-3, ÑuSat × 5, SpaceBEE × 12 Gaofen 3-03 Kosmos 2554 / Lotos-S1 №5 Axiom Mission 1 ChinaSat 6D USA-327 / NOSS-3 9A, NOSS-3 9B Starlink G4-14 (53 satellites) SpaceX Crew-4 Kosmos 2555 / EO MKA №2 Starlink G4-16 (53 satellites) Jilin-1 Gaofen-03D × 4, Jilin-1 Gaofen-04A
May	SpaceBEE × 16, SpaceBEE NZ × 8, Unicorn-2F Jilin-1 Kuanfu-01C, Jilin-1 Gaofen-03D × 7 Starlink G4-17 (53 satellites) Tianzhou 4 Jilin-1 Mofang-01A† Starlink G4-13 (53 satellites) Starlink G4-15 (53 satellites) Starlink G4-18 (53 satellites) Kosmos 2556 / Bars-M 3L Boe OFT-2 ION-SCV 006 ( SBUDNIC ), SHERPA AC1, Vigoride-3, ICEYE × 5, ÑuSat × 4, Lemur-2 × 5, Platform 1 , PTD-3
June	Progress MS-20 Shenzhou 14 TROPICS 02†, TROPICS 04† Starlink G4-19 (53 satellites) CMS-02 or GSAT-24 Yaogan 35-02 (3 satellites) CAPSTONE
July	Kosmos 2557 / GLONASS-K 16L Starlink G4-21 (53 satellites) Starlink G3-1 (46 satellites) Tianlian II-03 SpaceX CRS-25 ( TUMnanoSAT ) Starlink G4-22 (53 satellites) Starlink G3-2 (46 satellites) Wentian Starlink G4-25 (53 satellites) Yaogan 35-03 (3 satellites)
August	Kosmos 2558 / Nivelir №3 USA-335 / RASR-4 USA-336 / SBIRS GEO-6 Chinese reusable experimental spacecraft Danuri EOS-02 / Microsat-2A†, AzaadiSAT† Starlink G4-26 (52 satellites) Jilin-1 Gaofen-03D × 10, Jilin-1 Hongwai-01A × 6 Starlink G3-3 (46 satellites) Yaogan 35-04 (3 satellites) Starlink G4-27 (53 satellites) Starlink G4-23 (54 satellites) Starlink G3-4 (46 satellites)
September	Yaogan 33-02 Starlink G4-20 (51 satellites) Yaogan 35-05 (3 satellites) Eutelsat Konnect VHTS Starlink G4-2 (34 satellites) ChinaSat 1E Starlink G4-34 (54 satellites) Soyuz MS-22 KH-11 19/NROL-91 Shiyan 14, Shiyan 15 Starlink G4-35 (52 satellites) Yaogan 36-01 (3 satellites) Shiyan 16A, Shiyan 16B, Shiyan 17
October	TechEdSat-15 SES-20, SES-21 SpaceX Crew-5 Starlink G4-29 (52 satellites) Galaxy 33, Galaxy 34 GLONASS-K 17L RAISE-3†, KOSEN-2 †, MAGNARO †, MITSUBA †, WASEDA-SAT-ZERO † Huanjing 2E Yaogan 36-02 (3 satellites) Hotbird 13F Starlink G4-36 (54 satellites) OneWeb L14 (36 satellites) Gonets-M × 3 Progress MS-21 Starlink G4-31 (53 satellites) Shiyan 20C Mengtian
November	LDPE-2, USA-339 / Shepherd Demonstration, USA-340 , USA-341 , USA-344 / USUVL Kosmos 2563 / EKS-6 Hotbird 13G MATS ChinaSat 19 Cygnus NG-18 ( SpaceTuna1 ) NOAA-21, LOFTID Tianzhou 5 Galaxy 31, Galaxy 32 Yaogan 34-03 Jilin-1 Gaofen-03D × 5 Artemis 1 ( ArgoMoon, BioSentinel, CuSP, EQUULEUS, LunaH-Map, Lunar IceCube, LunIR, Near-Earth Asteroid Scout, OMOTENASHI, Team Miles ) Eutelsat 10B EOS-06 / Oceansat-3, Astrocast × 4 SpaceX CRS-26 Yaogan 36-03 (3 satellites) Kosmos 2564 / GLONASS-M 761 Shenzhou 15 Kosmos 2565 / Lotos-S1 №6 (Kosmos 2566)
December	Gaofen 5-01A OneWeb L15 (40 satellites) Jilin-1 Gaofen-03D × 7, Jilin-1 Pingtai-01A 01 Hakuto-R Mission 1 ( Rashid ), Lunar Flashlight Shiyan 20A, Shiyan 20B Galaxy 35, Galaxy 36, MTG-I1 Yaogan 36-04 (3 satellites) Shiyan 21 SWOT O3b mPOWER 1, O3b mPOWER 2 Starlink G4-37 (54 satellites) Pléiades Neo 5†, Pléiades Neo 6† Gaofen 11-04 Starlink G5-1 (54 satellites) Shiyan 10-02 EROS-C3
Launches are separated by dots ( • ), payloads by commas ( , ), multiple names for the same satellite by slashes ( / ). Cubesats are smaller. Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).

COSMO-SkyMed

Contents

COSMO-SkyMed first generation

List of launches

Ground segment

SAR capabilities

Commercialization

Flares

COSMO-SkyMed second generation (CSG)

List of launches

See also

Related Research Articles

References

External links