Boeing Orbital Flight Test

Boeing Orbital Flight Test
	The maiden Atlas V N22 launch
Names	Boe-OFT
Mission type	Flight test
Operator	Boeing Defense, Space & Security
COSPAR ID	2019-094A
SATCAT no.	44900
Mission duration	8 days (planned); 2 days, 1 hour, 22 minutes (achieved)
Spacecraft properties
Spacecraft	Boeing Starliner Calypso
Spacecraft type	Boeing Starliner
Manufacturer	Boeing Defense, Space & Security
Launch mass	13,000 kg (29,000 lb)
Start of mission
Launch date	20 December 2019, 11:36:43 UTC (6:36:43 am EST)
Rocket	Atlas V N22; AV-080
Launch site	Cape Canaveral, SLC-41
Contractor	United Launch Alliance
End of mission
Landing date	22 December 2019, 12:58:53 UTC
Landing site	White Sands Space Harbor
Orbital parameters
Reference system	Geocentric orbit
Regime	Low Earth orbit
Perigee altitude	187 km (116 mi)
Apogee altitude	222 km (138 mi)
Inclination	51.63°
Period	90.00 minutes
	; Boeing Starliner Orbital Flight Test mission patch Commercial Crew Development ← Boe-PAT Dragon In-Flight Abort Test → Boeing Starliner flights ← Boe-PAT Boeing OFT-2 →

Last updated February 01, 2025

The Boeing Starliner Orbital Flight Test (also known as Boe-OFT) was the first orbital mission of the CST-100 Starliner spacecraft, conducted by Boeing as part of NASA's Commercial Crew Program. The mission was planned to be an eight-day test flight of the spacecraft, involving a rendezvous and docking with the International Space Station (ISS), and a landing in the western United States. The mission was launched on December 20, 2019 at 11:36:43 UTC or 06:36:43 AM EST; however an issue with the spacecraft's Mission Elapsed Time (MET) clock occurred 31 minutes into flight. This anomaly caused the spacecraft to burn into an incorrect orbit, preventing a rendezvous with the International Space Station (ISS). The mission was reduced to just two days, with the spacecraft successfully landing at White Sands Space Harbor on December 22, 2019.

Payload

Instead of carrying astronauts, the flight carried an Anthropomorphic Test Device (ATD) wearing Boeing's custom flight suit. The ATD is named Rosie (aka "Rosie the Rocketeer"^[5]), as a homage to all the women who helped contribute to the Starliner Program.^[6] The capsule was weighted similarly to missions with astronauts onboard and carried approximately 270 kg (600 lb) of supplies and equipment including a plush toy of Snoopy and holiday presents for the Expedition 61 crew members. Due to the inability to dock with the ISS, this cargo was never delivered.

Mission

The first Atlas V N22,^[a] designated AV-080, launched the CST-100 Starliner spacecraft on an uncrewed test flight to the International Space Station. The capsule was intended to dock with the space station, then return to Earth to land in the Western United States after an orbital shakedown cruise ahead of Boeing Crewed Flight Test.^{[ citation needed ]}

OFT is the first flight of an Atlas V without a payload fairing and its first flight with a dual-engine Centaur upper stage. The dual-engine Centaur utilizes two RL-10 and is required for Starliner flights in order to provide a launch trajectory that allows for a safe abort at any point in the mission.^[7]

The mission launched successfully on December 20, 2019 at 11:36:43 UTC, but thirty-one minutes after launch the mission elapsed timer (MET) clock made an error. During a later press conference, it was revealed that MET was offset by 11 hours. When it became obvious that the maneuver did not happen, NASA and Boeing tried sending commands to get Starliner back on track, but the position of the spacecraft switching communications between two TDRS satellites delayed the orbital insertion burn. This delay resulted in an abnormal orbit and excessive fuel use. The decision was made to scratch the ISS rendezvous/docking since the spacecraft burned too much fuel to reach orbit even after Mission control center fixed the MET clock issue. NASA and Boeing officials placed the spacecraft in a different orbit and the entire flight plan had to be redone and the mission was reduced from eight days to three flight days.^{[ citation needed ]}

By 11:40 UTC, the Starliner was in a "stable orbit", though orbital insertion was not nominal.^[8] It was later confirmed that Starliner had placed itself into a 187 km × 222 km (116 mi × 138 mi) orbit.^[9]

By 13:55 UTC, mission control center had realized that docking with the ISS was precluded.^[10] Despite not being able to dock and the MET anomaly, Jim Bridenstine stated during a press conference that "A lot of things went right. And this is in fact why we test".

On December 22, 2019, Starliner was cleared to reenter the Earth's atmosphere. After deorbiting, Starliner reentered the Earth's atmosphere, before successfully deploying all sets of parachutes. Starliner deployed airbags and successfully touched-down at White Sands Space Harbor at 12:58:53 UTC. Though the ISS rendezvous that was planned for the OFT did not happen, Jim Chilton, vice president for Boeing's space and launch division, estimated that Starliner has achieved over 60% of the flight objectives, and this could reach over 85% once all the data from the spacecraft is retrieved and analyzed.^[11]

The spacecraft will later be reused on mission Boeing Starliner-1. Its commander, Sunita Williams, informally dubbed the spacecraft "Calypso" after the famed oceanographic research ship and its eponymous John Denver song.^[1]

Anomalies

An issue with the spacecraft's Mission Elapsed Time (MET) clock occurred 31 minutes into flight. Due to intermittent space-to-ground communication issues flight controllers could not correct the issue.^[12] This anomaly caused the spacecraft's Orbital Maneuvering Thrusters (OMT) to burn into an incorrect orbit causing too much propellant to be burned. This precluded a rendezvous and docking with the ISS.^[13] The mission was reduced to just three days, with the spacecraft successfully landing at White Sands Space Harbor on December 22, 2019.^[11]

After the mission, it was revealed that another critical software bug was found in flight, which could have resulted in the service module bumping back into Starliner after separation. The bug was fixed two hours before the capsule re-entered. Had the bug not been discovered and fixed, it may have damaged Starliner and prevented a safe landing.^[14] Additionally, it was determined that had the first anomaly not occurred, the second would not have been detected.^[15]

Investigation

On February 7, 2020, NASA shared their preliminary findings about the Boeing OFT mission and discovered software problems with the Mission Elapsed Time (MET), which incorrectly polled time from the Atlas V booster nearly 11 hours prior to launch. Another software issue occurred within the Service Module (SM) Disposal Sequence, which incorrectly translated the SM disposal sequence into the SM Integrated Propulsion Controller (IPC). This could have made the service module crash into the capsule after separation, potentially leading to a catastrophic failure of the capsule. In addition, an Intermittent Space-to-Ground (S/G) forward link issue, which impeded the Flight Control team's ability to command and control the vehicle, was found. The current investigation was expected to last until end of February 2020, in addition a full-scale safety review was planned that would likely take months.^[12]^[16]

On March 6, 2020, NASA gave an update on the anomalies.^[17] They announced 61 corrective actions that addressed the MET and service module disposal software issues.^[17]^[18] The mission was declared a "high visibility close call" as there were two times where the spacecraft could have been lost. NASA found factors internally that led to the anomalies such as the oversight over software.^[19]

On July 7, 2020, NASA and Boeing announced the completion of the Space-to-Ground communication issue, marking the completion of the OFT review.^[20] The number of corrective actions was increased to 80 from the March 2020 update.^[21] 21 recommendations focused on a need for more testing and simulations; including the necessity to do full end to end tests prior to flights instead of testing in chunks as done in the OFT.^[22] 10 recommendations were made to cover software requirements such that they have proper coverage to catch errors during testing. 35 of the recommendations surrounded improvements over process and operations such as including more reviews and use of experts. 7 recommendations covered software updates that addresses the three main anomalies that occurred during the flight. The final 7 included "Knowledge Capture" and Boeing organizational changes to enable better safety reporting. They also included hardware changes to filter out radio interference and others to address the communication issue.^[20]^[23]

Internally within NASA the investigation found that the lack of oversight over Starliner software was from NASA's focus of resources on other high risk parts of the flight.^[22] In addition, NASA may have had less oversight due to Boeing's traditional systems development style compared to SpaceX; NASA had increased their oversight of SpaceX due to their different working practices.^[23] NASA made 6 recommendations internally to prevent similar occurrences in the future. This included the need for NASA to review and approve the contractors' "hazard verification tests plans" before the test.^[20]

Notes

1 2 N22 designates that the Atlas V has no payload fairing, two solid rocker boosters, and two Centaur second-stage engines.

Related Research Articles

Human spaceflight programs have been conducted, started, or planned by multiple countries and companies. Until the 21st century, human spaceflight programs were sponsored exclusively by governments, through either the military or civilian space agencies. With the launch of the privately funded SpaceShipOne in 2004, a new category of human spaceflight programs – commercial human spaceflight – arrived. By the end of 2022, three countries and one private company (SpaceX) had successfully launched humans to Earth orbit, and two private companies had launched humans on a suborbital trajectory.

Dream Chaser is an American reusable lifting-body spaceplane developed by Sierra Space. Originally intended as a crewed vehicle, the Dream Chaser Space System is set to be produced after the Dream Chaser Cargo System cargo variant is operational. The crewed variant is planned to carry up to seven people and cargo to and from low Earth orbit. Sierra plans to manufacture a fleet of the spaceplane.

Sunita Lyn "Suni" Williams is an American astronaut, retired U.S. Navy officer, and one of the most experienced spacewalkers with nine spacewalks and a total time of 62 hours and 6 minutes. Williams was assigned to the International Space Station as a member of Expedition 14 and Expedition 15. In 2012, she served as a flight engineer on Expedition 32 and then commander of Expedition 33. In 2024, she returned to the ISS on the Boeing Crew Flight Test, the first crewed mission of the Boeing Starliner; her return to Earth has been delayed until March 2025 at the earliest. As such, from August 2024 until March 2025, Williams and fellow astronaut Butch Wilmore are pivoting ahead to undertake various scientific experiments and maintenance tasks aboard the International Space Station.

Barry Eugene "Butch" Wilmore is an American NASA astronaut and United States Navy test pilot. He has had three spaceflights, the first of which was an 11-day Space Shuttle mission in November 2009, to the International Space Station. Wilmore was designated as pilot with five other crew members on Space Shuttle Atlantis for the mission STS-129. He served as part of Expedition 41 to the International Space Station, and in 2024 returned to the ISS on the Boeing Crew Flight Test, the first crewed mission of the Boeing Starliner. As of December 2024, he is in space and is set to return to Earth no earlier than late March of 2025 on a new SpaceX Dragon capsule.

The NASA Docking System is NASA's implementation of the International Docking System Standard (IDSS), an international spacecraft docking standard promulgated by the International Space Station Multilateral Coordination Board. NDS is a spacecraft docking and berthing mechanism used on the International Space Station (ISS) and the Boeing Starliner and planned to be used on the Orion spacecraft. The international Low Impact Docking System (iLIDS) was the precursor to the NDS. NDS Block 1 was designed, built, and tested by The Boeing Company in Huntsville Alabama. Design qualification testing took place through January 2017.

The Boeing Starliner is a spacecraft designed to transport crew to and from the International Space Station (ISS) and other low-Earth-orbit destinations. Developed by Boeing under NASA's Commercial Crew Program (CCP), it consists of a reusable crew capsule and an expendable service module.

Development of the Commercial Crew Program (CCDev) began in the second round of the program, which was rescoped from a smaller technology development program for human spaceflight to a competitive development program that would produce the spacecraft to be used to provide crew transportation services to and from the International Space Station (ISS). To implement the program, NASA awarded a series of competitive fixed-price contracts to private vendors starting in 2011. Operational contracts to fly astronauts were awarded in September 2014 to SpaceX and Boeing, and NASA expected each company to complete development and achieve crew rating in 2017. Each company performed an uncrewed orbital test flight in 2019.

The retirement of NASA's Space Shuttle fleet took place from March to July 2011. Discovery was the first of the three active Space Shuttles to be retired, completing its final mission on March 9, 2011; Endeavour did so on June 1. The final shuttle mission was completed with the landing of Atlantis on July 21, 2011, closing the 30-year Space Shuttle program.

Soyuz TMA-08M, identified as Soyuz 34 or 34S by NASA, was a 2013 flight to the International Space Station. It transported three members of the Expedition 35 crew to the International Space Station. TMA-08M was the 117th flight of a Soyuz spacecraft, the first flight launching in 1967.

<span class="mw-page-title-main">SpaceX Dragon 2</span> 2020s class of partially reusable spacecraft

Dragon 2 is a class of partially reusable spacecraft developed, manufactured, and operated by American space company SpaceX for flights to the International Space Station (ISS) and private spaceflight missions. The spacecraft, which consists of a reusable space capsule and an expendable trunk module, has two variants: the 4-person Crew Dragon and Cargo Dragon, a replacement for the Dragon 1 cargo capsule. The spacecraft launches atop a Falcon 9 Block 5 rocket, and the capsule returns to Earth through splashdown.

Crew Dragon Demo-1 was the first orbital test of the Dragon 2 spacecraft. The mission launched on 2 March 2019 at 07:49:03 UTC, and arrived at the International Space Station on 3 March 2019, a little over 24 hours after the launch. The mission ended with a splashdown on 8 March 2019 at 13:45:08 UTC.

Boeing Crew Flight Test (Boe-CFT) was the first crewed mission of the Boeing Starliner capsule. Launched on 5 June 2024, the mission flew a crew of two NASA astronauts, Barry E. Wilmore and Sunita Williams, from Cape Canaveral Space Force Station to the International Space Station. The mission was meant to last eight days, ending on 14 June with a landing in the American Southwest. However, Starliner's thrusters malfunctioned as it approached the ISS. After more than two months of investigation, NASA decided it was too risky to return Wilmore and Williams to Earth aboard Starliner. Instead, the Boeing spacecraft returned uncrewed on 7 September 2024, and the astronauts will ride down on the SpaceX Crew-9 spacecraft in March 2025.

Boeing Starliner-1, also called Post Certification Mission-1 (PCM-1), is the name of the first operational crewed mission of the Boeing Starliner to the International Space Station (ISS) as part of the Commercial Crew Program. It was originally planned as the first Starliner mission following the Starliner Crewed flight test (CFT). The CFT was not a complete success, and as of November 2024, the launch date and name for the next Starliner mission is not known.

The Boeing Orbital Flight Test-2 was a repeat of Boeing's unsuccessful first Orbital Flight Test (Boe-OFT) of its Starliner spacecraft. The uncrewed mission was part of NASA's Commercial Crew Program. OFT-2, using Starliner Spacecraft 2, launched 19 May 2022 and lasted 6 days. Starliner successfully docked with the International Space Station (ISS) on 21 May 2022. It stayed at the ISS for 4 days before undocking and landing in the White Sands Missile Range on 25 May 2022.

Boeing Starliner Calypso is a space capsule manufactured by Boeing and used in NASA's Commercial Crew Program. On 20 December 2019, Calypso launched on the Boeing Orbital Flight Test mission, an uncrewed test flight of Starliner to the International Space Station. The spacecraft was scheduled to dock to the ISS and then return to Earth following a week in space, although due to several software issues the spacecraft was unable to rendezvous with the station and landed after two days in space, resulting in Boeing needing to schedule a second Orbital Flight Test. It flew with two astronauts for Starliner Crewed Flight Test on its second mission in June 2024.

The Commercial Crew Program (CCP) provides commercially operated crew transportation service to and from the International Space Station (ISS) under contract to NASA, conducting crew rotations between the expeditions of the International Space Station program. American space manufacturer SpaceX began providing service in 2020, using the Crew Dragon spacecraft, and NASA plans to add Boeing when its Boeing Starliner spacecraft becomes operational no earlier than 2025. NASA has contracted for six operational missions from Boeing and fourteen from SpaceX, ensuring sufficient support for ISS through 2030.

SpaceX Crew-2 was the second operational flight of a Crew Dragon spacecraft, and the third overall crewed orbital flight of the Commercial Crew Program. The mission was launched on 23 April 2021 at 09:49:02 UTC, and docked to the International Space Station on 24 April at 09:08 UTC.

Boeing Starliner Spacecraft 2 is the first of two active Boeing CST-100 Starliner spacecraft developed and built under NASA's Commercial Crew Program. The spacecraft was originally scheduled to make its maiden flight on Boe-CFT, the first crewed flight test of the Starliner spacecraft, although following the partial failure of the other CST-100 on Boe-OFT which required a repeat uncrewed test (Boe-OFT-2) of the spacecraft to be scheduled, Spacecraft 2 was reassigned to Boe-OFT-2 and also scheduled to fly Starliner-1 after being reassigned from CFT mission.

SpaceX Crew-8 was the eighth crewed operational NASA Commercial Crew flight and the 13th overall crewed orbital flight of a Crew Dragon spacecraft. The mission launched on 4 March 2024.

References

1 2 Williams, Sunita [@Astro_Suni] (December 22, 2019). "A couple of the awesome people who brought Calypso home! Thank you Steve and Kayva!" (Tweet). Archived from the original on June 6, 2021 – via Twitter. This article incorporates text from this source, which is in the public domain.
↑ Clark, Stephen (December 3, 2019). "Launch of first Starliner orbital test flight slips to December 19". Spaceflight Now. Archived from the original on May 24, 2024. Retrieved December 3, 2019.
↑ Clark, Stephen (December 18, 2019). "Live coverage: Overnight countdown underway for Friday's Starliner launch". Spaceflight Now. Archived from the original on August 7, 2024. Retrieved January 18, 2021.
↑ Burghardt, Thomas (July 7, 2020). "NASA and Boeing Complete Starliner Orbital Flight Test Investigation". NASASpaceflight.com . Archived from the original on August 5, 2024. Retrieved August 10, 2020.
↑ Joy, Rachael (November 21, 2019). "Remember Rosie the Riveter? Meet Rosie the Rocketeer". Florida Today . Archived from the original on May 2, 2024.
↑ Gohd, Chelsea (December 16, 2019). "Rosie, a Bandana-Clad Test Dummy, Will Be the First to Fly on Boeing's Starliner". Space.com . Archived from the original on May 23, 2024.
↑ Gebhardt, Chris (November 21, 2019). "Starliner arrives at launch pad in major pre-flight milestone". NASASpaceflight.com . Archived from the original on August 6, 2024. Retrieved December 17, 2019.
↑ Gebhardt, Chris (December 19, 2019). "Boeing, ULA launches of Starliner, suffers orbital insertion issue". NASASpaceflight.com . Archived from the original on August 6, 2024.
↑ Bassa, Cees [@cgbassa] (December 20, 2019). "There's a second set of orbital elements released now, 187 x 222 km, with epoch at 13:20 UTC" (Tweet). Archived from the original on December 20, 2019. Retrieved December 21, 2019– via Twitter.
↑ Bridenstine, Jim [@JimBridenstine] (December 20, 2019). "Because #Starliner believed it was in an orbital insertion burn (or that the burn was complete), the dead bands were reduced and the spacecraft burned more fuel than anticipated to maintain precise control. This precluded @Space_Station rendezvous" (Tweet). Archived from the original on December 20, 2019. Retrieved December 20, 2019– via Twitter. This article incorporates text from this source, which is in the public domain .
1 2 Foust, Jeff (December 22, 2019). "Starliner lands in New Mexico". SpaceNews . Archived from the original on September 5, 2024. Retrieved July 7, 2020.
1 2 Wattles, Jackie (February 7, 2020). "Boeing's Starliner spacecraft, built to carry astronauts, faces new safety concerns". CNN . Archived from the original on May 2, 2024.
↑ Foust, Jeff (December 20, 2019). "Starliner anomaly to prevent ISS docking". SpaceNews . Archived from the original on September 5, 2024. Retrieved July 7, 2020.
↑ Berger, Eric (February 6, 2020). "Starliner faced "catastrophic" failure before software bug found". Ars Technica . Archived from the original on August 6, 2024. Retrieved July 7, 2020.
↑ Gebhardt, Chris (February 7, 2020). "Boeing and NASA admit multiple anomalies on Starliner mission". NASASpaceflight.com . Archived from the original on July 26, 2024. Retrieved July 7, 2020.
↑ Berger, Eric (February 7, 2020). "Boeing's Starliner problems may be worse than we thought". Ars Technica . Archived from the original on June 30, 2024.
1 2 Lewis, Marie (March 6, 2020). "NASA Update on Orbital Flight Test Independent Review Team – Commercial Crew Program". blogs.nasa.gov. NASA. Archived from the original on August 6, 2024. Retrieved July 8, 2020. This article incorporates text from this source, which is in the public domain .
↑ Sheetz, Michael (March 6, 2020). "NASA investigation finds 61 corrective actions for Boeing after failed Starliner spacecraft mission". CNBC . Archived from the original on May 2, 2024. Retrieved July 8, 2020.
↑ Berger, Eric (March 6, 2020). "NASA declares Starliner mishap a "high visibility close call"". Ars Technica . Archived from the original on August 6, 2024. Retrieved July 8, 2020.
1 2 3 Sempsrott, Danielle (July 7, 2020). "NASA and Boeing Complete Orbital Flight Test Reviews" (Press release). NASA. Archived from the original on July 7, 2020. Retrieved July 8, 2020. This article incorporates text from this source, which is in the public domain .
↑ Sheetz, Michael (July 7, 2020). "NASA and Boeing aim to redo Starliner spacecraft test later this year after investigating failures". CNBC . Archived from the original on June 22, 2024. Retrieved July 8, 2020.
1 2 Berger, Eric (July 7, 2020). "Independent reviewers offer 80 suggestions to make Starliner safer". Ars Technica . Archived from the original on January 16, 2024. Retrieved July 8, 2020.
1 2 Burghardt, Thomas (July 8, 2020). "NASA and Boeing Complete Starliner Orbital Flight Test Investigation". NASASpaceflight.com . Archived from the original on August 5, 2024. Retrieved July 8, 2020.

External links

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.

[N22-4] 1 2 N22 designates that the Atlas V has no payload fairing, two solid rocker boosters, and two Centaur second-stage engines.

[Astro_Suni_tweet-1] 1 2 Williams, Sunita [@Astro_Suni] (December 22, 2019). "A couple of the awesome people who brought Calypso home! Thank you Steve and Kayva!" (Tweet). Archived from the original on June 6, 2021 – via Twitter. This article incorporates text from this source, which is in the public domain.

[sfn-20191203-2] Clark, Stephen (December 3, 2019). "Launch of first Starliner orbital test flight slips to December 19". Spaceflight Now. Archived from the original on May 24, 2024. Retrieved December 3, 2019.

[SFN20191218-3] Clark, Stephen (December 18, 2019). "Live coverage: Overnight countdown underway for Friday's Starliner launch". Spaceflight Now. Archived from the original on August 7, 2024. Retrieved January 18, 2021.

[nsf20200707-5] Burghardt, Thomas (July 7, 2020). "NASA and Boeing Complete Starliner Orbital Flight Test Investigation". NASASpaceflight.com . Archived from the original on August 5, 2024. Retrieved August 10, 2020.

[FloridaToday-20191121-6] Joy, Rachael (November 21, 2019). "Remember Rosie the Riveter? Meet Rosie the Rocketeer". Florida Today . Archived from the original on May 2, 2024.

[Space-20191216-7] Gohd, Chelsea (December 16, 2019). "Rosie, a Bandana-Clad Test Dummy, Will Be the First to Fly on Boeing's Starliner". Space.com . Archived from the original on May 23, 2024.

[nsf-20191121-8] Gebhardt, Chris (November 21, 2019). "Starliner arrives at launch pad in major pre-flight milestone". NASASpaceflight.com . Archived from the original on August 6, 2024. Retrieved December 17, 2019.

[nsf-20191219-9] Gebhardt, Chris (December 19, 2019). "Boeing, ULA launches of Starliner, suffers orbital insertion issue". NASASpaceflight.com . Archived from the original on August 6, 2024.

[cgbassa-20191220-10] Bassa, Cees [@cgbassa] (December 20, 2019). "There's a second set of orbital elements released now, 187 x 222 km, with epoch at 13:20 UTC" (Tweet). Archived from the original on December 20, 2019. Retrieved December 21, 2019– via Twitter.

[birdenstine-20191220-11] Bridenstine, Jim [@JimBridenstine] (December 20, 2019). "Because #Starliner believed it was in an orbital insertion burn (or that the burn was complete), the dead bands were reduced and the spacecraft burned more fuel than anticipated to maintain precise control. This precluded @Space_Station rendezvous" (Tweet). Archived from the original on December 20, 2019. Retrieved December 20, 2019– via Twitter. This article incorporates text from this source, which is in the public domain .

[Foust_2019-12] 1 2 Foust, Jeff (December 22, 2019). "Starliner lands in New Mexico". SpaceNews . Archived from the original on September 5, 2024. Retrieved July 7, 2020.

[Wattles_2020-13] 1 2 Wattles, Jackie (February 7, 2020). "Boeing's Starliner spacecraft, built to carry astronauts, faces new safety concerns". CNN . Archived from the original on May 2, 2024.

[sn-20191220-14] Foust, Jeff (December 20, 2019). "Starliner anomaly to prevent ISS docking". SpaceNews . Archived from the original on September 5, 2024. Retrieved July 7, 2020.

[ars-20200206-15] Berger, Eric (February 6, 2020). "Starliner faced "catastrophic" failure before software bug found". Ars Technica . Archived from the original on August 6, 2024. Retrieved July 7, 2020.

[nsf-20200207-16] Gebhardt, Chris (February 7, 2020). "Boeing and NASA admit multiple anomalies on Starliner mission". NASASpaceflight.com . Archived from the original on July 26, 2024. Retrieved July 7, 2020.

[ars-20200207-17] Berger, Eric (February 7, 2020). "Boeing's Starliner problems may be worse than we thought". Ars Technica . Archived from the original on June 30, 2024.

[Lewis_2020-18] 1 2 Lewis, Marie (March 6, 2020). "NASA Update on Orbital Flight Test Independent Review Team – Commercial Crew Program". blogs.nasa.gov. NASA. Archived from the original on August 6, 2024. Retrieved July 8, 2020. This article incorporates text from this source, which is in the public domain .

[cnbc-20200306-19] Sheetz, Michael (March 6, 2020). "NASA investigation finds 61 corrective actions for Boeing after failed Starliner spacecraft mission". CNBC . Archived from the original on May 2, 2024. Retrieved July 8, 2020.

[ars-20200306-20] Berger, Eric (March 6, 2020). "NASA declares Starliner mishap a "high visibility close call"". Ars Technica . Archived from the original on August 6, 2024. Retrieved July 8, 2020.

[nasa-20200707-21] 1 2 3 Sempsrott, Danielle (July 7, 2020). "NASA and Boeing Complete Orbital Flight Test Reviews" (Press release). NASA. Archived from the original on July 7, 2020. Retrieved July 8, 2020. This article incorporates text from this source, which is in the public domain .

[cnbc-20200707-22] Sheetz, Michael (July 7, 2020). "NASA and Boeing aim to redo Starliner spacecraft test later this year after investigating failures". CNBC . Archived from the original on June 22, 2024. Retrieved July 8, 2020.

[Berger_2020-23] 1 2 Berger, Eric (July 7, 2020). "Independent reviewers offer 80 suggestions to make Starliner safer". Ars Technica . Archived from the original on January 16, 2024. Retrieved July 8, 2020.

[Burghardt_2020-24] 1 2 Burghardt, Thomas (July 8, 2020). "NASA and Boeing Complete Starliner Orbital Flight Test Investigation". NASASpaceflight.com . Archived from the original on August 5, 2024. Retrieved July 8, 2020.

[1]

[2]

[3]

[a]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]

[19]

[20]

[21]

[22]

[23]

v t e Boeing Starliner
Commercial Crew Program List of spaceflights to the ISS crewed uncrewed
Missions	Pad Abort Test Orbital Flight Test Orbital Flight Test 2 Crew Flight Test Starliner-1
Spacecraft	Spacecraft 1 (retired) Spacecraft 2 Spacecraft 3 "Calypso"
Hardware	Atlas V RS-88
Bold indicates current missions Italics indicates future missions Category

v t e Uncrewed spaceflights to the International Space Station
See also: {{ Crewed ISS flights }} {{ ISS expeditions }}
2000–2004	2000 2R / Zvezda 1P 2P 3P 2001 4P 5P SO1 / Pirs 6P 2002 7P 8P 9P 2003 10P 11P 12P 2004 13P 14P 15P 16P
2005–2009	2005 17P 18P 19P 20P 2006 21P 22P 23P 2007 24P 25P 26P 27P 2008 28P ATV-1 29P 30P 31P 2009 32P 33P 34P HTV-1 35P MIM2 / Poisk
2010–2014	2010 36P 37P 38P 39P 40P 2011 HTV-2 41P ATV-2 42P 43P 44P† 45P 2012 46P ATV-3 47P SpX-D HTV-3 48P SpX-1 49P 2013 50P SpX-2 51P ATV-4 52P HTV-4 Orb-D1 53P 2014 Orb-1 54P 55P SpX-3 Orb-2 56P ATV-5 SpX-4 Orb-3† 57P
2015–2019	2015 SpX-5 58P SpX-6 59P† SpX-7† 60P HTV-5 61P OA-4 62P 2016 OA-6 63P SpX-8 64P SpX-9 OA-5 65P† HTV-6 2017 SpX-10 66P OA-7 SpX-11 67P SpX-12 68P OA-8E SpX-13 2018 69P SpX-14 OA-9E SpX-15 70P HTV-7 71P NG-10 SpX-16 2019 SpX-DM1 72P NG-11 SpX-17 SpX-18 73P 60S HTV-8 NG-12 SpX-19 74P Boe-OFT†
2020–2024	2020 NG-13 SpX-20 75P HTV-9 76P NG-14 SpX-21 2021 77P NG-15 SpX-22 78P Nauka NG-16 SpX-23 79P M-UM / Prichal SpX-24 2022 80P NG-17 Boe-OFT 2 81P SpX-25 82P NG-18 SpX-26 2023 83P SpX-27 84P SpX-28 NG-19 85P SpX-29 86P 2024 NG-20 87P SpX-30 88P NG-21 89P SpX-31 90P
Future	2025 91P SpX-32 NG-22 SSC Demo-1 92P NG-23 93P HTV-X1 94P NG-24 SpX-33 SpX-34 SpX-35 2025 95P 96P 97P 98P NG-25 2030 US Deorbit Vehicle
Spacecraft	Roscomos Progress ESA ATV (past) JAXA HTV NASA CRS SpaceX Dragon 1 (past) SpaceX Dragon 2 Northrop Grumman Cygnus Sierra Nevada Dream Chaser
Ongoing spaceflights in underline Future spaceflights in italics † - mission failed to reach ISS

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) Kosmos 2543 / 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 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, HARP , HuskySat-1 ) 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 ( / ). Crewed flights are underlined. Launch failures are marked with the † sign. Payloads deployed from other spacecraft are (enclosed in parentheses).