OMOTENASHI

OMOTENASHI
Names	Outstanding MOon exploration TEchnologies demonstrated by NAno Semi-Hard Impactor
Mission type	Technology demonstrator, Reconnaissance
Operator	JAXA
COSPAR ID	2022-156D
SATCAT no.	55904
Website	www.isas.jaxa.jp/home/omotenashi/index.html
Mission duration	1 day
Spacecraft properties
Spacecraft	OMOTENASHI
Spacecraft type	CubeSat
Bus	6U CubeSat
Manufacturer	JAXA
Launch mass	12.6 kg (28 lb)
Dimensions	10 cm × 20 cm × 30 cm
Power	30 watts
Start of mission
Launch date	16 November 2022, 06:47:44 UTC
Rocket	SLS Block 1
Launch site	Kennedy, LC-39B
Contractor	NASA
End of mission
Last contact	Working to restore communications
Orbital parameters
Reference system	Selenocentric orbit
Moon impactor
Spacecraft component	Orbiter and lander
Transponders
Band	X-band, S-band, P-band
Instruments
	Radiation monitor; Accelerometer

OMOTENASHI (Outstanding MOon exploration TEchnologies demonstrated by NAno Semi-Hard Impactor) was a small spacecraft and semi-hard lander of the 6U CubeSat format intended to demonstrate low-cost technology to land and explore the lunar surface. The CubeSat was to take measurements of the radiation environment near the Moon as well as on the lunar surface. Omotenashi is a Japanese word for "welcome" or "Hospitality".^[2]^[6]

OMOTENASHI was one of ten CubeSats launched with the Artemis 1 mission into a heliocentric orbit in cislunar space on the maiden flight of the Space Launch System (SLS), that took place on 16 November 2022.^[3]^[7]

After deployment from the Artemis I second stage, JAXA reported unstable communications with the spacecraft.^[8] On 21 November 2022, a Twitter message sent by JAXA reported that further attempts to communicate with the lander, which was scheduled to begin its landing sequences that day, had been ended.^[9]

Overview[edit]

The OMOTENASHI mission was to land the smallest lunar lander up to then on the lunar surface to demonstrate the feasibility of the hardware for distributed synergistic exploration system with multi-point exploration. Once on the lunar surface, the OMOTENASHI lander was planned to observe the radiation environment of the lunar surface. The OMOTENASHI orbiter and lander were designed by the Japan Aerospace Exploration Agency (JAXA). It was a 6U CubeSat measuring 10 cm × 20 cm × 30 cm, and had a mass of 14 kg (31 lb). The principal investigator was Tatsuaki Hashimoto from JAXA.^[10] The spacecraft featured two body-fixed solar panels and lithium ion batteries. After measuring the radiation environment as it approached the Moon, OMOTENASHI's lander module was planned to perform a semi-hard landing on the lunar surface.^[11]

Flight[edit]

JAXA announced that OMOTENASHI had successfully separated from the ICPS interstage around 90 minutes after launch. However, as of November 17, 2022, the spacecraft had yet to achieve Sun acquisition, and communication was unstable. JAXA continued operations to "stabilise attitude, secure power and establish communication,"^[12] but after failing to restore operations, they abandoned recovery attempts on November 22.^[9]^[13] Reports indicate that the loss was due to failure of the solar cells to point toward the Sun.^[14] The next time they would be facing towards the Sun was March 2023.^[15]^[16] The team is considering recovery operations if they are able to reestablish contact with the spacecraft.^[17]

Payload[edit]

The lander's scientific payload consisted of a radiation monitor and an accelerometer.^[2]

Propulsion and proposed landing[edit]

OMOTENASHI was to use a cold gas thruster to enter a lunar-impact orbit, and a solid rocket motor for the landing phase.^[5] The entry and landing phases would have been informed by the use of an X-band two-way Doppler radar.^[5] The orbiting module was planned to enter at a shallow flight-path angle of ≤7°, and to be ejected when the solid rocket burn begins the deceleration manoeuvre.^[5] The rocket would have been ignited with a laser.^[2]^[18] After the deceleration rocket burn that was planned to last 15–20 seconds,^[18] OMOTENASHI's lander would have ejected the retrorocket, experiencing a free-fall of about 100 m. Just before impact, the lander was planned to deploy a single airbag about 50 cm in diameter to minimize the impact,^[18]^[19] estimated to be at 20–30 m/s.^[2]^[5]

Spacecraft components ^[18]^[5]	Units/performance
Modules	* Orbiting module * Retro motor Module * Surface probe
Surface probe	0.7 kg ^[19] Battery: 30 Wh Consumption: 15 W
Orbiter	7 kg (including cold gas system)
Propulsion	* Solid motor: 6 kg (2500 m/s) - includes solid fuel * Cold gas jet: (N₂, 20 m/s)

References[edit]

^ "OMOTENASHI". JAXA. Retrieved 16 February 2023.
^ ^a ^b ^c ^d ^e ^f "OMOTENASHI" (PDF). JAXA. 29 October 2016. Retrieved 10 March 2021.
^ ^a ^b Roulette, Joey; Gorman, Steve (16 November 2022). "NASA's next-generation Artemis mission heads to moon on debut test flight". Reuters. Retrieved 16 November 2022.
^ "OMOTENASHI". 22 November 2022.
^ ^a ^b ^c ^d ^e ^f "Trajectory Design for the JAXA Moon Nano-Lander OMOTENASHI". Digital Commons. 2017. Retrieved 10 March 2021.
^ "Go To MOON! The World's Smallest Moon Lander: OMOTENASHI" (PDF). JAXA. 2017. Retrieved 12 March 2021.
^ Clark, Stephen (12 October 2021). "Adapter structure with 10 CubeSats installed on top of Artemis moon rocket". Spaceflight Now. Retrieved 22 October 2021.
^ "Status of the JAXA CubeSats OMOTENASHI and EQUULEUS onboard Artemis I". JAXA. 17 November 2022. Retrieved 21 November 2022.
^ ^a ^b "OMOTENASHI Project official JAXA Twitter message". JAXA. 21 November 2022. Retrieved 21 November 2022.
^ "International Partners Provide Science Satellites for America's Space Launch System Maiden Flight". NASA. 26 May 2016. Retrieved 10 March 2021. This article incorporates text from this source, which is in the public domain.
^ "International Partners To Launch CubeSats On Orion Exploration Mission-1". Colaorado Space News. 26 May 2016. Archived from the original on 16 April 2021. Retrieved 10 March 2021.
^ "Status of the JAXA CubeSats OMOTENASHI and EQUULEUS onboard NASA Artemis I". Japan Aerospace Exploration Agency. 17 November 2022. Retrieved 21 November 2022.
^ "JAXA Gives Up on Landing Omotenashi Probe on Moon Archived 28 November 2022 at the Wayback Machine", Nippon.com, Nov 22, 2022. Retrieved 28 November 2022.
^ "Editorial: Failure of OMOTENASHI Should Lead to New Lunar Landing Attempts", Japan Forward, 28 November 2022. Retrieved 28 November 2022.
^ "JAXA's Ultra Small Lander OMOTENASHI Fails to Receive Transmissions from Earth".^{[permanent dead link]}
^ "OMOTENASHI twitter Update". Twitter. 22 November 2022. Retrieved 6 February 2023.
^ "OMOTENASHI Twitter about future". Twitter (in Japanese). 22 November 2022. Retrieved 2 February 2023.
^ ^a ^b ^c ^d "OMOTENASHI" (PDF). JAXA. 2017. Retrieved 10 March 2021.
^ ^a ^b "OMOTENASHI - Mission Sequence". JAXA. 2017. Retrieved 12 March 2021.

External links[edit]

An OMOTENASHI page, in Japanese but it includes interesting images
NSSDCA page

[OMOTENASHI-1] "OMOTENASHI". JAXA. Retrieved 16 February 2023.

[Welcome2016-2] ^ ^a ^b ^c ^d ^e ^f "OMOTENASHI" (PDF). JAXA. 29 October 2016. Retrieved 10 March 2021.

[reuters_1-3] Roulette, Joey; Gorman, Steve (16 November 2022). "NASA's next-generation Artemis mission heads to moon on debut test flight". Reuters. Retrieved 16 November 2022.

[4] "OMOTENASHI". 22 November 2022.

[Hernando_2017-5] ^ ^a ^b ^c ^d ^e ^f "Trajectory Design for the JAXA Moon Nano-Lander OMOTENASHI". Digital Commons. 2017. Retrieved 10 March 2021.

[GoToMoon-6] "Go To MOON! The World's Smallest Moon Lander: OMOTENASHI" (PDF). JAXA. 2017. Retrieved 12 March 2021.

[7] Clark, Stephen (12 October 2021). "Adapter structure with 10 CubeSats installed on top of Artemis moon rocket". Spaceflight Now. Retrieved 22 October 2021.

[OMOTComm1-8] "Status of the JAXA CubeSats OMOTENASHI and EQUULEUS onboard Artemis I". JAXA. 17 November 2022. Retrieved 21 November 2022.

[OMOTComm2-9] "OMOTENASHI Project official JAXA Twitter message". JAXA. 21 November 2022. Retrieved 21 November 2022.

[OMOTENASHI_NEWS_2016-10] "International Partners Provide Science Satellites for America's Space Launch System Maiden Flight". NASA. 26 May 2016. Retrieved 10 March 2021. This article incorporates text from this source, which is in the public domain.

[Colorado-11] "International Partners To Launch CubeSats On Orion Exploration Mission-1". Colaorado Space News. 26 May 2016. Archived from the original on 16 April 2021. Retrieved 10 March 2021.

[JAXA_update-12] "Status of the JAXA CubeSats OMOTENASHI and EQUULEUS onboard NASA Artemis I". Japan Aerospace Exploration Agency. 17 November 2022. Retrieved 21 November 2022.

[nippon.com-13] "JAXA Gives Up on Landing Omotenashi Probe on Moon Archived 28 November 2022 at the Wayback Machine", Nippon.com, Nov 22, 2022. Retrieved 28 November 2022.

[14] "Editorial: Failure of OMOTENASHI Should Lead to New Lunar Landing Attempts", Japan Forward, 28 November 2022. Retrieved 28 November 2022.

[15] "JAXA's Ultra Small Lander OMOTENASHI Fails to Receive Transmissions from Earth".^{[permanent dead link]}

[16] "OMOTENASHI twitter Update". Twitter. 22 November 2022. Retrieved 6 February 2023.

[17] "OMOTENASHI Twitter about future". Twitter (in Japanese). 22 November 2022. Retrieved 2 February 2023.

[diagrams_2017-18] "OMOTENASHI" (PDF). JAXA. 2017. Retrieved 10 March 2021.

[Airbag-19] "OMOTENASHI - Mission Sequence". JAXA. 2017. Retrieved 12 March 2021.

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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	USA-337 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 Yunhai-3 01 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) Oceansat-3
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).