International Cometary Explorer


The International Cometary Explorer spacecraft, was launched August 12, 1978, into a heliocentric orbit. It was one of three spacecraft, along with the mother/daughter pair of ISEE-1 and ISEE-2, built for the International Sun-Earth Explorer program, a joint effort by NASA and ESRO/ESA to study the interaction between the Earth's magnetic field and the solar wind.
ISEE-3 was the first spacecraft to be placed in a halo orbit at the Earth-Sun Lagrangian point. Renamed ICE, it became the first spacecraft to visit a comet, passing through the plasma tail of comet Giacobini-Zinner within about of the nucleus on September 11, 1985.
NASA suspended routine contact with ISEE-3 in 1997, and made brief status checks in 1999 and 2008.
On May 29, 2014, two-way communication with the spacecraft was reestablished by the ISEE-3 Reboot Project, an unofficial group with support from the Skycorp company. On July 2, 2014, they fired the thrusters for the first time since 1987. However, later firings of the thrusters failed, apparently due to a lack of nitrogen pressurant in the fuel tanks. The project team initiated an alternative plan to use the spacecraft to "collect scientific data and send it back to Earth", but on September 16, 2014, contact with the probe was lost.

Original mission: International Sun/Earth Explorer 3 (ISEE-3)

ISEE-3 carries no cameras; instead, its instruments measure energetic particles, waves, plasmas, and fields.
ISEE-3 originally operated in a halo orbit about the Sun-Earth Lagrangian point, 235 Earth radii above the surface. It was the first artificial object placed at a so-called "libration point", entering orbit there on November 20, 1978, proving that such a suspension between gravitational fields was possible. It rotates at 19.76 rpm about an axis perpendicular to the ecliptic, to keep it oriented for its experiments, to generate solar power and to communicate with Earth.
The purposes of the mission were:
After completing its original mission, ISEE-3 was re-tasked to study the interaction between the solar wind and a cometary atmosphere. On June 10, 1982, the spacecraft performed a maneuver which removed it from its halo orbit around the point and placed it in a transfer orbit. This involved a series of passages between Earth and the Sun-Earth Lagrangian point, through the Earth's magnetotail. Fifteen propulsive maneuvers and five lunar gravity assists resulted in the spacecraft being ejected from the Earth-Moon system and into a heliocentric orbit. Its last and closest pass over the Moon, on December 22, 1983, was only above the lunar surface; following this pass, the spacecraft was re-designated as the International Cometary Explorer.

Giacobini-Zinner encounter

Its new orbit put it ahead of the Earth on a trajectory to intercept comet Giacobini-Zinner. On September 11, 1985, the craft passed through the comet's plasma tail.
ICE did a flyby of the comet nucleus at a distance of of the nucleus on September 11, 1985.

Halley encounter

ICE transited between the Sun and Comet Halley in late March 1986, when other spacecraft were near the comet on their early-March comet rendezvous missions. ICE flew through the tail; its minimum distance to the comet nucleus was. For comparison, Earth's minimum distance to Comet Halley in 1910 was.

Heliospheric mission

An update to the ICE mission was approved by NASA in 1991. It defines a heliospheric mission for ICE consisting of investigations of coronal mass ejections in coordination with ground-based observations, continued cosmic ray studies, and the Ulysses probe. By May 1995, ICE was being operated under a low duty cycle, with some data-analysis support from the Ulysses project.

End of mission

On May 5, 1997, NASA ended the ICE mission, leaving only a carrier signal operating. The ISEE-3/ICE downlink bit rate was nominally 2048 bits per second during the early part of the mission, and 1024 bit/s during the Giacobini-Zinner comet encounter. The bit rate then successively dropped to 512 bit/s, 256 bit/s, 128 bit/s and finally to 64 bit/s. Though still in space, NASA donated the craft to the Smithsonian Museum.
By January 1990, ICE was in a 355-day heliocentric orbit with an aphelion of 1.03 AU, a perihelion of 0.93 AU and an inclination of 0.1 degree.

Further contact

In 1999, NASA made brief contact with ICE to verify its carrier signal.
On September 18, 2008, NASA, with the help of KinetX, located ICE using the NASA Deep Space Network after discovering that it had not been powered off after the 1999 contact. A status check revealed that all but one of its 13 experiments were still functioning, and it still had enough propellant for of Δv.
It was determined to be possible to reactivate the spacecraft in 2014, when it again made a close approach to Earth, and scientists discussed reusing the probe to observe more comets in 2017 or 2018.

Reboot effort

Sometime after NASA's interest in the ICE waned, others realized that the spacecraft might be steered to pass close to another comet. A team of engineers, programmers, and scientists began to study the feasibility and challenges involved.
In April 2014, its members formally announced their intentions to "recapture" the spacecraft for use, calling the effort the ISEE-3 Reboot Project. A team webpage said, "We intend to contact the ISEE-3 spacecraft, command it to fire its engine and enter an orbit near Earth, and then resume its original mission... If we are successful we intend to facilitate the sharing and interpretation of all of the new data ISEE-3 sends back via crowd sourcing."
On May 15, the project reached its crowdfunding goal of US$125,000 on RocketHub, which was expected to cover the costs of writing the software to communicate with the probe, searching through the NASA archives for the information needed to control the spacecraft, and buying time on the dish antennas. The project then set a "stretch goal" of $150,000, which it also met with a final total of $159,502 raised.
The project members were working on deadline: if they got the spacecraft to change its orbit by late May or early June 2014, or in early July by using more fuel, it could use the Moon's gravity to get back into a useful halo orbit.

Replacing lost hardware

Earlier in 2014, officials with the Goddard Space Flight Center said the Deep Space Network equipment necessary to transmit signals to the spacecraft had been decommissioned in 1999, and was too expensive to replace. However, project members were able to find documentation for the original equipment and were able to simulate the complex modulator/demodulator electronics using modern software-defined radio techniques and open-source programs from the GNU Radio project. They obtained the needed hardware, an off-the-shelf SDR transceiver and power amplifier, and installed it on the 305-meter Arecibo dish antenna on May 19, 2014. Once they gained control of the spacecraft, the capture team planned to shift the primary ground station to the 21-meter dish located at Kentucky's Morehead State University Space Science Center. The 20-meter dish antenna in Bochum Observatory, Germany, would be a support station.
Although NASA was not funding the project, it made advisors available and gave approval to try to establish contact. On May 21, 2014, NASA announced that it had signed a Non-Reimbursable Space Act Agreement with the ISEE-3 Reboot Project. "This is the first time NASA has worked such an agreement for use of a spacecraft the agency is no longer using or ever planned to use again," officials said.

Contact reestablished

On May 29, 2014, the reboot team successfully commanded the probe to switch into Engineering Mode to begin to broadcast telemetry.
On June 26, project members using the Goldstone Deep Space Communications Complex DSS-24 antenna achieved synchronous communication and obtained the four ranging points needed to refine the spacecraft's orbital parameters.
The project team received approval from NASA to continue operations through at least July 16, and made plans to attempt the orbital maneuver in early July.
On July 2, the reboot project fired the thrusters for the first time since 1987. They spun up the spacecraft to its nominal roll rate, in preparation for the upcoming trajectory correction maneuver in mid-July.
On July 8, a longer sequence of thrusters firings failed, apparently due to loss of the nitrogen gas needed to pressurize the fuel tanks.
On July 24, the ISEE-3 Reboot Team announced that all attempts to change orbit using the ISEE-3 propulsion system had failed. Instead, the team said, the ISEE-3 Interplanetary Citizen Science Mission would gather data as the spacecraft flies by the Moon on August 10 and enters a heliocentric orbit similar to Earth's. The team began shutting down propulsion components to maximize the electrical power available for the science experiments.
On July 30, the team announced that it still planned to acquire data from as much of ISEE-3's 300-day orbit as possible. With five of the 13 instruments on the spacecraft still working, the science possibilities included listening for gamma-ray bursts, where observations from additional locations in the Solar System can be valuable. The team was also recruiting additional receiving sites around the globe to improve diurnal coverage, in order to upload additional commands while the spacecraft is close to Earth and later to receive data.
On August 10 at 18:16 UTC, the spacecraft passed about from the surface of the Moon. It will continue in its heliocentric orbit, and will return to the vicinity of Earth in 2031.

Contact lost

On September 25, 2014, the Reboot team announced that contact with the probe was lost on September 16. It is unknown whether contact can be reestablished because the probe's exact orbit is uncertain. The spacecraft's post-lunar flyby orbit takes it further from the Sun, causing electrical power available from its solar arrays to drop, and its battery failed in 1981. Reduced power could have caused the craft to enter a safe mode, from which it may be impossible to awaken without the precise orbital location information needed to point transmissions at the craft.

Spacecraft design

The ICE spacecraft is a barrel-like cylindrical shape covered by solar panels. Four long antennas protrude equidistant around the circumference of the spacecraft, spanning. It has a dry mass of and can generate nominal power of 173 watts.

Payload

ICE carries 13 scientific instruments to measure plasmas, energetic particles, waves, and fields., five were known to be functional. It does not carry a camera or imaging system. Its detectors measure high energy particles such as X- and gamma-rays, solar wind, plasma and cosmic particles. A data handling system gathers the scientific and engineering data from all systems in the spacecraft and formats them into a serial stream for transmission. The transmitter output power is five watts.

Scientific payload and experiments

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