EQUULEUS
| Names | EQUilibriUm Lunar-Earth point 6U Spacecraft |
|---|---|
| Mission type | Technology, science |
| Mission duration | Cruise: 6 months (planned) [1] Science: 6 months (planned) |
| Spacecraft properties | |
| Spacecraft | EQUULEUS |
| Spacecraft type | CubeSat |
| Bus | 6U CubeSat |
| Manufacturer | JAXA / University of Tokyo |
| Launch mass | 14 kg (31 lb) |
| Dimensions | 10 cm × 20 cm × 30 cm (3.9 in × 7.9 in × 11.8 in) |
| Power | 15 watts |
| Start of mission | |
| Launch date | May 2022 (planned) |
| Rocket | SLS Block 1 |
| Launch site | Kennedy, LC-39B |
| Contractor | NASA |
| Orbital parameters | |
| Reference system | Selenocentric orbit |
| Flyby of Moon | |
| Transponders | |
| Band | X-band and Ka-band[1] |
| TWTA power | 13 W [1] |
| Instruments | |
| Plasmaspheric Helium ion Observation by Enhanced New Imager in eXtreme ultraviolet (PHOENIX) DEtection camera for Lunar impact PHenomena IN 6U Spacecraft (DELPHIUS)) Cis-Lunar Object Detector within Thermal Insulation (CLOTH) | |
EQUULEUS (EQUilibriUm Lunar-Earth point 6U Spacecraft) is a nanosatellite of the 6U CubeSat format that will measure the distribution of plasma that surrounds the Earth (plasmasphere) to help scientists understand the radiation environment in that region. It will also demonstrate low-thrust trajectory control techniques, such as multiple lunar flybys, within the Earth-Moon region using water steam as propellant.[2][1] The spacecraft was designed and developed jointly by the Japan Aerospace Exploration Agency (JAXA) and the University of Tokyo.[2][3]
EQUULEUS will be one of ten CubeSats to be carried with the Artemis 1 mission into a heliocentric orbit in cislunar space on the maiden flight of the Space Launch System, scheduled to launch in 2022.[4]
Overview[]
Mapping the plasmasphere around Earth may provide important insight for protecting both humans and electronics from radiation damage during long space journeys. It will also demonstrate low-thrust trajectory control techniques, such as multiple lunar flybys, within the Earth-Moon Lagrange points (EML).[1][5][6] The mission will demonstrate that departing from EML can transfer to various orbits, such as Earth orbits, Moon orbits, and interplanetary orbits, with a tiny amount of orbital control.[5] EQUULEUS features 2 deployable solar panels, and lithium batteries.
The mission will be monitored from the Japanese deep space antenna (64-meter antenna and 34-meter antenna) with support from the DSN (Deep Space Network) of Jet Propulsion Laboratory (JPL).[1] The principal investigator is Professor Hashimoto at the Japan Aerospace Exploration Agency (JAXA).[5] The mission is named after the 'little horse' constellation Equuleus.[7]
Propulsion[]
| Water thrusters | Unit/performance |
|---|---|
| Propellant | Water |
| Thrust | 2 - 4 mN |
| Specific impulse | >70 seconds |
| Stored pressure | < 100 kPa |
| Power | 12 – 15 watts |
| Water mass | 1.2 kg |
| Total Delta-V | 70 m/s |
The propulsion system, called AQUARIUS, employs 8 water thrusters also used for attitude control (orientation) and momentum management.[8] The spacecraft will carry 1.5 kg of water,[8][9] and the complete propulsion system will occupy about 2.5 units out of the 6 units total spacecraft volume. The waste heat from the communication components is reused to assist in the heating of water vapor, which is heated to 100 °C (212 °F) at the pre-heater.[8] The AQUARIUS' water thrusters produce a total of 4.0 mN, a specific impulse (Isp) of 70 seconds, and consumes about 20 watts power.[8] Before its flight on EQUULEUS, AQUARIUS will be first tested on the 2019 AQT-D CubeSat.
Scientific payload[]
PHOENIX[]
EQUULEUS' scientific payload features a small UV imager named PHOENIX (Plasmaspheric Helium ion Observation by Enhanced New Imager in eXtreme ultraviolet) that will operate in the high-energy extreme ultraviolet wavelengths. It consists of an entrance mirror of 60 mm diameter, and a photon counting device. The reflectivity of the mirror is optimized for the emission line of helium ion (30.4 nm wavelength), which is the relevant component of the plasmasphere of Earth.[10] The plasmasphere is where various phenomena are caused by the electromagnetic disturbances by the solar wind. By flying far from the Earth, the PHOENIX telescope will provide a global image of the plasmasphere of Earth and contribute to its spatial and temporal evolution.[10]
DELPHINUS[]
DELPHINUS (DEtection camera for Lunar impact PHenomena IN 6U Spacecraft), or DLP, for short is a camera connected to the PHOENIX telescope to observe lunar impact flashes and near-Earth asteroids (NEO), as well as potential 'mini-moons' while positioned at the Earth-Moon Lagrangian point L2 (L2) halo orbit.[11] Theoretically, NEOs approaching Earth can be briefly caught within gravity of Earth well, and although in terms of orbital mechanics the object's movements is still centered around the Sun, to an observer on Earth it will move as if it is a moon of the planet.[11] One example of such an object is 2006 RH120, which orbited Earth between 2006 and 2007. If a mini-moon or NEO that can be rendezvoused by EQUULEUS is identified, the CubeSat will attempt a flyby.[11] This payload occupies about 0.5 units out of the total 6 units volume.[1] The results will contribute to the risk evaluation for future infrastructure or human activity on the lunar surface.[1]
CLOTH[]
The instrument named CLOTH (Cis-Lunar Object Detector within Thermal Insulation) will detect and evaluate the meteoroid impact flux in the cislunar space by using dust detectors mounted on the exterior of the spacecraft. The goal of this instrument is to determine the size and spatial distribution of dust solid objects in the cislunar space.[1] CLOTH utilizes the spacecraft's multi-layer insulation (MLI) as a detector, thus realizing a dust counter suitable for mass-constrained CubeSats.[12] It will be the first instrument to measure the dust environment of the Earth–Moon L2 Lagrange point, and aims to uncover the dust's origin, as well as conducting risk assessment of the L2 point dust particles in anticipation of a future crewed mission.[12] CLOTH will decipher L2 point dust (likely originating from mini-moons) from sporadic dust by differences in their impact velocity.[12]
See also[]
- The 10 CubeSats flying in the Artemis 1 mission
- Near-Earth Asteroid Scout by NASA is a solar sail spacecraft that will encounter a near-Earth asteroid
- BioSentinel is an astrobiology mission
- LunIR by Lockheed Martin Space
- Lunar IceCube, by the Morehead State University
- CubeSat for Solar Particles (CuSP)
- Lunar Polar Hydrogen Mapper (LunaH-Map), designed by the Arizona State University
- EQUULEUS, submitted by JAXA and the University of Tokyo
- OMOTENASHI, submitted by JAXA, is a lunar lander
- ArgoMoon, designed by Argotec and coordinated by Italian Space Agency (ASI)
- Team Miles, by Fluid and Reason LLC, Tampa, Florida
- The 3 CubeSat missions removed from Artemis 1
- Lunar Flashlight will map exposed water ice on the Moon
- Cislunar Explorers, Cornell University, Ithaca, New York
- Earth Escape Explorer (CU-E3), University of Colorado Boulder
- CubeSat and microsatellite projects of ISSL
- Hodoyoshi 3
- Hodoyoshi 4
- PROCYON
- TRICOM-1R
- Nano-JASMINE
- ISSL Mars mission
References[]
- ^ a b c d e f g h i "EQUULEUS: Mission to Earth - Moon Lagrange Point by a 6U Deep Space CubeSat". Utah State University, Small Satellite Conference. 2017. Retrieved 12 March 2021.
- ^ a b "Space Launch System Highlights" (PDF). NASA. May 2016. Retrieved 12 March 2021.
This article incorporates text from this source, which is in the public domain.
- ^ Gunter Dirk Krebs (18 May 2020). "EQUULEUS". Gunter's Space Page. 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.
- ^ a b c "EQUULEUS - Technology Demonstration". Intelligent Space Systems Laboratory. University of Tokyo. 2017. Retrieved 12 March 2021.
- ^ "International Partners Provide Science Satellites for America's Space Launch System Maiden Flight". NASA. 26 May 2016. Retrieved 12 March 2021. This article incorporates text from this source, which is in the public domain.
- ^ Lester Haines (27 May 2016). "NASA firms up Space Launch System nanosat manifest". The Register. Retrieved 12 March 2021.
- ^ a b c d "Development of the Water Resistojet Propulsion System for Deep Space Exploration by the CubeSat: EQUULEUS". Small Satellite Conference. University of Tokyo. 2017. Retrieved 12 March 2021.
- ^ Hiroyuki Koizumi (2017). "Development of the Water ResistojetPropulsion System for Deep Space Exploration by the CubeSat EQUULEUS". Small Satellite Conference. University of Tokyo. Retrieved 12 March 2021.
- ^ a b "Plasmaspheric Helium ion Observation by Enhanced New Imager in eXtreme ultraviolet". EQUULEUS mission home page Intelligent Space Systems Laboratory. University of Tokyo. 2017. Retrieved 12 March 2021.
- ^ a b c "DELPHINUS". Intelligent Space Systems Laboratory. Archived from the original on 1 December 2017. Retrieved 26 November 2017.
- ^ a b c Yano, Hajime; Hirai, Takayuki; Arai, Kazuyoshi (5 January 2017). "EQUULEUS搭載地球・月軌道間微粒子検出機能断熱材(CLOTH)の開発" (PDF) (in Japanese). JAXA. Retrieved 27 April 2017.[permanent dead link]
This article incorporates text from this source, which is in the - CubeSats
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