|About the Mission | About the Spacecraft and Impactor|
|About the Comet | About Comets in General | About the Encounter|
- Why do scientists want to impact a comet?
- Who came up with the idea to impact a comet?
- Who is working on Deep Impact?
- Will the Hubble Space Telescope (HST) be involved in this project?
- Will any ground-based telescopes be observing the impact?
- Will I be able to see the impact?
- How will the data get from the spacecraft to the scientists?
- When are launch and impact?
- What tasks exist between 2000 and 2005, before the launch?
- Will we see the collision in full-motion video?
- How precisely known will the time of the impact be, and how soon will you know it?
- How do you get all the data from the spacecraft back to Earth?
- Why does a mission have a "launch period" and what does that mean?
- Are you using explosives to make the crater in Comet Tempel 1?
Scientists expect significant changes in the material that makes up the comet as you go deeper into the comet, just as the material of the Earth changes significantly the deeper you go underground. Only an impact mission can study the interior of a comet below the evolved surface layer. Other missions, such as ESA's Rosetta Mission, are being planned that will land on a comet and scratch the surface. But the Deep Impact Mission is the only one that will excavate a large enough hole to see the interior composition of the comet. Take a look at our science Objectives.
The idea of impacting a comet has been around for a long time and has been seriously discussed as the ending scenario for orbiter missions. The idea dates back at least 30 years to the book 2001 written by Arthur C. Clarke. Mission teams from a variety of other missions have studied the concept, including the team of the Comet Rendezvous Asteroid Flyby (CRAF) mission that was subsequently cancelled by NASA in the mid 1990's and the team of the Giotto mission (which was flown by ESA to comet Halley). The Deep Impact project was first proposed in a somewhat different form and rejected in 1996. In 1998 the team re-proposed the idea with a number of changes and on the basis of this proposal was one of two Discovery missions ultimately selected in July 1999.
Project members are affiliated with numerous organizations. The science team includes members from The University of Maryland and other universities, NASA/JPL (the Jet Propulsion Laboratory), and Ball Aerospace & Technologies Corp. (BATC). You can learn more about the science team and their specific roles on the Deep Impact mission here. In addition to the scientists, there are many other people working on the mission. To learn more about the different mission roles, take a look here.
Yes. The HST will be imaging the encounter before, during and after the impact. It will be joined by several large and small ground-based telescopes at various locations around the world.
The most spectacular images will come from the flyby spacecraft. But many ground-based telescopes will be collecting data in the optical and other wavelengths to complement the data from the flyby spacecraft. Details about the observing opportunities can be found here.
We hope so! Unfortunately, one side of the earth will be facing away from the comet at the time of impact so that side won't be able to see it directly. However, we plan on broadcasting the event on television and on the internet so that everyone all over the world can see the impact. Details about observing the comet can be found here.
The data gathered by the spacecraft is transmitted to the ground via X-band communication. The data will go through NASA's Deep Space Network to JPL and then to Cornell University and the University of Maryland. They then get distributed to the science team for analysis.
Launch was 12 January 2005. The impact is planned for 05:52 4 July 2005 UT. Take a look at the mission timeline to see where we are in the schedule. To find out when the impact will occur in local time, see our page of Questions About the Encounter.
The flight systems will be built between March 2001 and October 2003. It is then delivered to Cape Canaveral at the end of 2004 for launch at the beginning of 2005. Meanwhile, the science team will continue observations of the comet to better understand the environment that the spacecraft will encounter. Studies of cratering processes, both lab simulations and computer models, will continue. And the details of the observing sequence -- when to take images, when to take spectra, and when to send data back -- for the mission will be designed. Be sure to watch our timeline to see where we are in the mission.
We will not be able to observe the impact in "full motion video" (ie., at a rate of 30 frames/sec) because of data rate limitations both in the imaging cameras and in the data link from the spacecraft to Earth. The cameras are designed to make accurate scientific measurements, not primarily to produce video. As such, the imaging detectors are read out relatively slowly in order to keep the noise levels low, and the data are encoded to 14 bits to make the most accurate measurements possible. At their full frame format (1024x1024 pixels), the cameras will output only one frame every 1.7s. At impact and for the following few seconds, we plan to use subframe imaging modes (64x64 pixels in the Medium Resolution Instrument and 256x256 pixels in the High Resolution Instrument). With these formats, the cameras can produce frames at rates of about 20/sec for the MRI and 5/s for the HRI. So we will be able to reconstruct the impact itself with pretty good time resolution. Even if the cameras could produce frames at 30/sec, the data link to Earth at the range of the comet at impact would not allow the data to be returned to Earth fast enough to support full-motion video in real time. The maximum data rate that we expect to use given the spacecraft telecommunications system capabilities and the receiving capabilities of the Deep Space Network stations on Earth is about 300,000 bits/s, which is about 200 times slower than needed for full-motion digital video. The data link could support full-motion video only at ranges less than about 10 million km.
Our targeted impact time is 05:52 4 July 2005 UT plus or minus 3 minutes. In late June, 2005, we should know within 1 minute. Two or three days from the impact (July 2/3, 2005) we will know within 30 seconds. Five minutes away from impact we will know within 2.7 seconds. The web site will be updated with the time of impact as the event gets closer.
Both the flyby and the impactor spacecraft will gather images and other data as they observe the comet - but what good is that if we don't get it back to Earth? That's why the huge white antennas of NASA's Deep Space Network (DSN) are so important. They are positioned about 120 degrees apart around the world in: Spain, Australia and in California, USA. From there, they communicate with and listen to all our spacecraft. Not only will these antennas receive data, but they will send it on for distribution to our scientists and engineers at Jet Propulsion Laboratory, University of Maryland and Cornell University. In addition to collecting data, these dish-like structures serve as the communication path between the Deep Impact team on Earth giving instructions, and the spacecraft replying back to the team. It's through this two-way communication that the team can confirm the health of the spacecraft and give any changes needed in its flight. The DSN will be even more important in the 24 hours that the impactor aims at and hits the comet. So much data will be coming down for the 14 minutes of primary science that the team will actually time the collision to make sure they have overlapping coverage from 70-meter dishes in two locations in the world. This makes the DSN a truly important partner to the Deep Impact project. The next time you think of spacecraft in space - remember the Deep Space Network (deepspace.jpl.nasa.gov/dsn/).
The launch period is the number of days during which a mission can launch and still reach its target. The launch period is determined by several factors such as the current position of the planetary body they need to reach combined with the power of the launch vehicle. The launch period can be a number of days or weeks depending on the mission. Deep Impact had a launch period of 21 days beginning 12 January 2005. A spacecraft can be ready, installed in its launch vehicle, and on the launch pad and certain circumstances can put it on hold. Some of the factors are:
- Bad weather
- High winds
- A launch vehicle of the same type has problems on another mission
- The Deep Space Network antenna assigned for initial acquisition of the spacecraft has a problem and is not rated "green" and ready to track.
- A possible problem with the spacecraft or launch vehicle during last testing
- A violation of the surrounding secured air, land or ocean space
- A breakdown in the communication system for the launch team
For many systems needed during launch, there are additional backup systems but they are very careful to assure the success of a launch as much as possible before they proceed with the countdown.
There is no bomb nor explosives on our spacecraft. When the impactor hits the comet, it forms the crater simply from the transfer of kinetic energy. For example, 2 cars traveling very slowly only get crunched a little when they hit, but two cars traveling very fast can get demolished upon impact. Same thing with Deep Impact's impactor and the comet, they are both traveling very fast (faster than cars, faster than bullets) so the crunch they make is enough to carve out a good-sized crater on the comet without using explosives.