MINERVA (MIcro-Nano Experimental Robot Vehicle for Asteroid) are a series of rovers developed by the Japanese space agency JAXA for the purpose of exploring asteroid surfaces. The first MINERVA was part of the Hayabusa mission, and MINERVA-II are a series of three rovers for Hayabusa2 . On 12 November 2005, MINERVA rover was deployed from Hayabusa orbiter with aim to land on asteroid 25143 Itokawa. However, the landing failed as MINERVA missed the asteroid and ended up on heliocentric orbit. On 21 September 2018, first two MINERVA-II rovers successfully landed on asteroid 162173 Ryugu. [1] The third MINERVA-II rover malfunctioned before deployment from the Hayabusa2 orbiter, but it was released anyway on 2 October 2019 to perform gravitational measurements before impacting the asteroid a few days later.
Following the approval of the asteroid sample-return project MUSES-C, a rover was proposed to be mounted on the asteroid explorer, and development of MINERVA began in 1997. Completed in February 2003, MINERVA was Japan's first space rover, and the first asteroid rover in the world. [2]
On 9 May 2003, the MUSES-C spacecraft carrying MINERVA was launched from Kagoshima Space Center, and was named Hayabusa . Hayabusa arrived at its target, asteroid 25143 Itokawa, on 12 September 2005. After a two-month long observation phase, Hayabusa began descent rehearsals in preparation for its asteroid landings. On 12 November, MINERVA was separated from Hayabusa and headed for Itokawa, but the drop failed and thus MINERVA became the smallest artificial object in heliocentric orbit. [3] [4] Following separation MINERVA continued to communicate for 18 hours, transmitting data to its mothership. [4]
After Hayabusa's return to Earth, a successor project, Hayabusa2 , began, which also included a rover. [5] While MINERVA was treated as an optional addition in the first Hayabusa, MINERVA-II became part of the nominal payload for Hayabusa2. [6] Launched on 3 December 2014, Hayabusa2 arrived at asteroid 162173 Ryugu on 27 June 2018. MINERVA-II-1, composed of two identical rovers, was deployed from Hayabusa2 in 21 September. Both rovers reached Ryugu's surface, and became the first probes ever to travel the surface of an asteroid. JAXA announced that the rovers have been named HIBOU (previously Rover-1A) and OWL (previously Rover-1B), respectively.
The second rover deployment for MINERVA-II-2 happened 2 October 2019 16:38 UTC. [7] The rover, known as Rover-2 or MINERVA-II-2 failed before deployment, but was released from the Hayabusa2 orbiter anyway to perform gravitational measurements. It impacted the asteroid a few days after release on 8 October.
MINERVA consists of five components, including the rover's body.
These four components were inside the rover.
MINERVA itself is a hexadecagonal prism with a diameter of 12 cm and a height of 10 cm, with solar cells attached to each side. This allows the probe to secure power in any attitude as long as it was in a sunlit environment. [8] [9] For shock mitigation during landing and to protect the solar cells, 16 pins are protruding from MINERVA's surface. Six among them had thermometers inside them to directly measure the asteroid's ground temperature. [3] The pins also functioned as a means to increase friction during the hops. [8]
Power is supplied from the solar cells attached to every side of MINERVA. [3] Surplus power gets stored in an electric double-layer capacitor, and is used in situations that requires greater power than what gets generated by the solar cells, such as rotating the motor and when using the cameras. After the electric double-layer capacitor ceases function, communication will still be possible but the rover will be unable to make further hops or imaging, so an operation was considered to have a stationary MINERVA continuously measure the asteroid surface temperature of its final resting place.
Along with six built-in temperature sensors at the pins sticking out from the main body, MINERVA had three cameras and six photodiodes on board as external sensors. The three CCD cameras were identical; two of them faced the same direction and were adjacent with each other, enabling closeup stereographic imaging. This was intended for mainly shooting the asteroid surface. The remaining camera was placed on the opposite side of the two cameras, with the primary purpose of imaging the asteroid from above during the hops.
On MINERVA's topside and underside an antenna is located. As the rover's attitude shifts, the either side facing Hayabusa was to be used. The communication speed between MINERVA and OME-E was 9.6 kbps, with a maximum range of 20 km.
MINERVA has an on-board microcomputer. Its main CPU microprocessor is Hitachi's SH-3, clocked at 10 MHz, adopted for its low power consumption, performance efficiency and reliability. The computer's memory includes 2 MB RAM, 512 KB ROM, and 2 MB Flash ROM. [10] [11]
MINERVA-II-1 was developed by JAXA and the University of Aizu. It has a slim design compared to its predecessor, to increase the likelihood the surface with larger area would contact the asteroid surface. MINERVA-II-1 was enlarged from its predecessor as the rover's destination, asteroid Ryugu was more distant from the Sun than Itokawa, necessitating an increase in solar cell area. [12] Ryugu's greater size compared to Itokawa means rovers will face stronger gravity, thus larger DC motors are used for MINERVA-II-1. [13] By deploying two rovers simultaneously, a network of space probes can be achieved. [9] The maximum communication speed between the MINERVA-II-1 rovers and the mothership's OME-E is 32 kbps. The two rovers are nearly identical, the only difference being some internal sensors and the thermal characteristics. [14] Rover-1A uses a traditional multi-layer insulation, which covers the rover to prevent heat from entering, while Rover-1B is equipped with radiators to dissipate heat to the outside. [15]
Unlike the other three MINERVAs (one on Hayabusa, two on Hayabusa2) developed by JAXA/ISAS, MINERVA-II-2 was developed by a consortium of Japanese universities, and employs significantly different methods of mobility. MINERVA-II-2's primary goal is to verify navigation in an environment with extremely small gravitational acceleration. [16] The rover was realized as an 'outreach payload', aimed at the university community. [12] The responsibility of each universities are the following: [16]
MINERVA was deployed by Hayabusa during the third landing rehearsal. On 12 November 2005 6:07:38 UTC the command to deploy MINERVA was sent from Earth. [3] However, before the MINERVA deployment command, a command instructing Hayabusa to raise its altitude was accidentally sent. MINERVA was deployed on 6:24 UTC, but the distance to 25143 Itokawa was 200 m, and Hayabusa was ascending at approximately 15 cm/s away from the asteroid. An image taken by Hayabusa 212 s after MINERVA's deployment caught both MINERVA and OME-C, the rover's cover that was also deployed.
Of the images taken by MINERVA, only one was sent, which was a photograph of Hayabusa's solar panels. [3] After separating from Hayabusa communication with MINERVA lasted for 18 hours.
Hayabusa2 arrived at asteroid 162173 Ryugu on 27 July 2018. The spacecraft released MINERVA-II-1, a batch of 2 rovers, over the 'northern hemisphere' of Ryugu. The process was conducted fully autonomously, a countermeasure to prevent the recurrence of the error that doomed their predecessor. [15] The landing site of MINERVA-II-1 rovers was named Tritonis. [17] Of the two rovers, HIBOU (aka Rover-1A) took an image of Hayabusa2 soon after deployment. OWL (aka Rover-1B) succeeded in recording a video from Ryugu. [18] MINERVA-II-1 became the first probes to take an image, and move on an asteroid surface. After completing their missions, the two rovers will remain on the asteroid surface.
The MINERVA-II-2 rover, also called Rover-2, failed before deployment. It was however deployed 2 October 2019 on orbit around Ryugu to perform gravitational measurements. After release from Hayabusa2 it impacted the asteroid on 8 October.
A lander is a spacecraft that descends towards, then comes to rest on, the surface of an astronomical body. In contrast to an impact probe, which makes a hard landing that damages or destroys the probe upon reaching the surface, a lander makes a soft landing after which the probe remains functional.
Hayabusa was a robotic spacecraft developed by the Japan Aerospace Exploration Agency (JAXA) to return a sample of material from a small near-Earth asteroid named 25143 Itokawa to Earth for further analysis. Hayabusa, formerly known as MUSES-C for Mu Space Engineering Spacecraft C, was launched on 9 May 2003 and rendezvoused with Itokawa in mid-September 2005. After arriving at Itokawa, Hayabusa studied the asteroid's shape, spin, topography, color, composition, density, and history. In November 2005, it landed on the asteroid and collected samples in the form of tiny grains of asteroidal material, which were returned to Earth aboard the spacecraft on 13 June 2010.
25143 Itokawa (provisional designation 1998 SF36) is a sub-kilometer near-Earth object of the Apollo group and a potentially hazardous asteroid. It was discovered by the LINEAR program in 1998 and later named after Japanese rocket engineer Hideo Itokawa. The peanut-shaped S-type asteroid has a rotation period of 12.1 hours and measures approximately 330 meters (1,100 feet) in diameter. Due to its low density and high porosity, Itokawa is considered to be a rubble pile, consisting of numerous boulders of different sizes rather than of a single solid body.
The Japan Aerospace Exploration Agency (JAXA) is the Japanese national air and space agency. Through the merger of three previously independent organizations, JAXA was formed on 1 October 2003. JAXA is responsible for research, technology development and launch of satellites into orbit, and is involved in many more advanced missions such as asteroid exploration and possible human exploration of the Moon. Its motto is One JAXA and its corporate slogan is Explore to Realize.
Solar electric propulsion (SEP) refers to the combination of solar cells and electric thrusters to propel a spacecraft through outer space. This technology has been exploited in a variety of spacecraft designs by the European Space Agency (ESA), the JAXA, Indian Space Research Organisation (ISRO) and NASA. SEP has a significantly higher specific impulse than chemical rocket propulsion, thus requiring less propellant mass to be launched with a spacecraft. The technology has been evaluated for missions to Mars.
A sample-return mission is a spacecraft mission to collect and return samples from an extraterrestrial location to Earth for analysis. Sample-return missions may bring back merely atoms and molecules or a deposit of complex compounds such as loose material and rocks. These samples may be obtained in a number of ways, such as soil and rock excavation or a collector array used for capturing particles of solar wind or cometary debris. Nonetheless, concerns have been raised that the return of such samples to planet Earth may endanger Earth itself.
The following outline is provided as an overview of and topical guide to space exploration.
Hayabusa2 is an asteroid sample-return mission operated by the Japanese state space agency JAXA. It is a successor to the Hayabusa mission, which returned asteroid samples for the first time in June 2010. Hayabusa2 was launched on 3 December 2014 and rendezvoused in space with near-Earth asteroid 162173 Ryugu on 27 June 2018. It surveyed the asteroid for a year and a half and took samples. It left the asteroid in November 2019 and returned the samples to Earth on 5 December 2020 UTC. Its mission has now been extended through at least 2031, when it will rendezvous with the small, rapidly-rotating asteroid 1998 KY26.
162173 Ryugu, provisional designation 1999 JU3, is a near-Earth object and a potentially hazardous asteroid of the Apollo group. It measures approximately 900 metres (3,000 ft) in diameter and is a dark object of the rare spectral type Cb, with qualities of both a C-type asteroid and a B-type asteroid. In June 2018, the Japanese spacecraft Hayabusa2 arrived at the asteroid. After making measurements and taking samples, Hayabusa2 left Ryugu for Earth in November 2019 and returned the sample capsule to Earth on 5 December 2020. The samples showed the presence of organic compounds, such as uracil (one of the four components in RNA) and vitamin B3.
Hayabusa Mk2 was a proposed Japan Aerospace Exploration Agency (JAXA) space mission aimed at visiting a small primitive asteroid and returning a sample to Earth for laboratory analysis. It was intended to be the follow-on mission to JAXA's Hayabusa mission, as well as the Hayabusa2 mission. The latest proposal for Hayabusa Mk2 stated its target to be the dormant comet 4015 Wilson–Harrington, with a launch of the probe in 2018. From 2007 to 2010, it was also considered as a joint JAXA-ESA mission under the name Marco Polo. The in-situ investigation and sample analysis would allow scientists to improve our knowledge of the physical and chemical properties of a small Near-Earth Object (NEO) which is thought to have kept the original composition of the solar nebula in which planet formed. Thus, it would provide some constraints to the models of planet formation and some information on how life may have been brought to Earth. Information on the physical structure will help defining efficient mitigation strategies against a potential threatening object.
The (Japanese) Lunar Exploration Program (月探査計画) is a program of robotic and human missions to the Moon undertaken by the Japanese Aerospace Exploration Agency (JAXA) and its division, the Institute of Space and Astronautical Science (ISAS). It is also one of the three major enterprises of the JAXA Space Exploration Center (JSPEC). The main goal of the program is "to elucidate the origin and evolution of the Moon and utilize the Moon in the future".
PROCYON was an asteroid flyby space probe that was launched together with Hayabusa2 on 3 December 2014 13:22:04 (JST). It was developed by University of Tokyo and JAXA. It was a small, low cost spacecraft.
(98943) 2001 CC21 (or simply 2001 CC21) is a stony near-Earth asteroid of the Apollo group, with a diameter of about 500 metres (1,600 feet). It was discovered by the Lincoln Near-Earth Asteroid Research (LINEAR) survey at Socorro, New Mexico on 3 February 2001. It is an upcoming flyby target of JAXA's Hayabusa2 extended mission, which will approach less than 100 km (62 mi) from the asteroid in July 2026.
OKEANOS was a proposed mission concept to Trojan asteroids, which share Jupiter's orbit, using a hybrid solar sail for propulsion; the sail was planned to be covered with thin solar panels to power an ion engine. In situ analysis of the collected samples would have been performed by either direct contact or using a lander carrying a high-resolution mass spectrometer. A sample-return to Earth was an option under study.
The Planetary Material Sample Curation Facility (PMSCF), commonly known as the Extraterrestrial Sample Curation Center is the facility where Japan Aerospace Exploration Agency (JAXA) conducts the curation works of extraterrestrial materials retrieved by some sample-return missions. They work closely with Japan's Astromaterials Science Research Group. Its objectives include documentation, preservation, preparation, and distribution of samples. All samples collected are made available for international distribution upon request.
Stephan Ulamec is an Austrian geophysicist, born in Salzburg on January 27th, 1966, with more than 100 articles in peer-reviewed journals and several participations in space missions and payloads operated by diverse space agencies. He is working at the German Aerospace Center in Cologne. He is regularly giving lectures about his publications in aerospace engineering at the University of Applied Sciences: Fachhochschule FH-Aachen. Main aspects of his work are related to the exploration of small bodies in the solar system.