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TOPIC: Deep Impact


L

Posts: 131433
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RE: Deep Impact transmission
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Change of transmission times for Deep Impact feed 14 June 2005
The transmission times for the "ESA Preview of Deep Impact" Exchange have been changed as follows:
14 June 2005
08:00-08:15 GMT Transmission
18:30-18:45 GMT Replay
18 June 2005
10:30-10:45 GMT Replay

EUTELSAT HOT BIRD at 13° East (DVB/MPEG-2), Horizontal, F=12,476 MHz (MCPC, Europe by Satellite), SR=27,500 MS/sec, FEC=3/4

The European Top in Brussels this week might lead to more changes of transmission times, at short notice. Please consult the EbS Website before your downlinks:
http://europa.eu.int/comm/ebs/schedule.cfm

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L

Posts: 131433
Date:
RE: Deep Impact
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The Hubble Space Telescope will be watching when the University of Maryland's Deep Impact space probe crashes into the comet.
The best view is expected to be had by the Deep Impact probe itself, but officials at the Space Telescope Science Institute, which coordinates Hubble's use, say they are ready for anything.
"We will be here and we'll be working," - Cheryl Gundy, spokeswoman for the Space Telescope Science Institute.
Hubble was also trained on the collision of comet Shoemaker Levy and Jupiter in 1994 and "had those great results. We're hoping well see something similar," Gundy said.
While the Shoemaker Levy collision was the first collision of two solar system bodies ever observed, if all goes well, the Deep Impact mission will mark the first time a spacecraft has struck a comet.
As Deep Impact nears the end of its six-month journey, the Hubble is also observing the comet to help guide mission officials, Gundy said.
Observations by Hubble and the Spitzer space telescopes in 2004 helped paint a clearer picture of the comet, showing it to be about 8.7 miles by 2.5 miles, with a matte black colour.
"The important point everyone has to realize is the uncertainty is so large we don't know what to expect. It is possible that the change will be so small you can't see it with anything less than a four-meter telescope. It could be much more than that, it could be that you could see the change with binoculars. You just have to be aware of the uncertainty " - professor Michael A'Hearn, University of Maryland.

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L

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RE: Deep Impact focusing problem
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Shortly after Deep Impact was launched Jan. 12, engineers found a focusing problem in the spacecraft's main camera-telescope, the High Resolution Instrument.
The problem has been traced to a mirror used when the HRI was tested at Ball, the space agency said. While flat at room temperatures, the mirror unexpectedly developed a slight curvature during testing at ultra-cold temperatures. Ball engineers didn't detect the curvature at the time.
"It was a mirror used in the test setup, not part of the instrument itself. Because of the curvature in the test mirror, we set the focus (on the HRI) slightly incorrectly." - Harold Reitsema, director of program development at Ball.


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RE: Blurry Vision Fix
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NASA’s Deep Impact mission team hope to fix the spacecraft’s blurry vision by using a mathematical process, called deconvolution, on the images it captures after they have been transmitted to Earth.
The announcement was made at a press briefing at NASA headquarters in Washington, during which the Deep Impact team discussed the impact the mission is expected to produce on July 4th.
It was discovered in March the Flyby spacecraft's High Resolution Instrument (HRI) was not focusing properly. The team will use deconvolution, to remedy the situation. Deconvolution is widely used in image processing and involves the reversal of the distortion created by the faulty lens of a camera or other optical devices, like a telescope or microscope.
"The process is a purely mathematical manipulation that works extremely well. Even if you have a perfect telescope, which is limited by diffraction, you can use deconvolution to improve the resolution. The process is sometimes time consuming, so the biggest effect on the science is a delay while you do all the processing to get the quality that you expected” - Don Yoemans, a co-investigator for the Jet Propulsion Laboratory (JPL).


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L

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RE: Deep Impact
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A worldwide network of observers, both professional and amateur, is part of the Deep Impact project. Within the global network of space and Earth telescopes for this unprecedented astronomical event, Europe plays a significant role.
Two ESA spacecraft, ESA’s Rosetta comet-chaser and its XMM-Newton space observatory, together with the NASA/ESA Hubble Space Telescope, will monitor the comet before impact, and then watch the impact and its aftermath.
ESO’s Very Large Telescope (VLT) facilities in Chile will observe the event in a big observation campaign.
ESA’s optical ground station at Tenerife, Spain, will also look at the impact.



Rosetta is in the most privileged position in space to watch this unique event, and will be able to monitor the comet continuously over an extended period.
Rosetta is likely to be one of the key observatories of this event because of its set of powerful remote-sensing instruments.
The Deep Impact experiment will be the first opportunity in time to study the crust and the interior of a comet.
As the material inside the comet’s nucleus is pristine, it will reveal new information on the early phases of the Solar System.
It will also provide scientists with new insight on the physics of craters formation, and thereby give a better understanding on the crater record on comets and other bodies in the Solar System.

The scientific outcome of the experiment depends crucially on pre-impact and follow-up observations. Before the impact, it is necessary to find out as much about the comet as possible, such as size, albedo (reflectivity) and rotation period.
It is essential to have a good set of observations before the impact to unambiguously distinguish the effects of the impact from the natural activity of the comet.

Due to the currently limited understanding of the structure of these dirty ‘snowballs,’ it is not known what the effect of the impact will be. Some scientists predict the ejection of a plume and the creation of a football stadium sized crater. Others think that the comet could simply swallow the impactor with hardly any visible effect, or that it may eventually break up.
To prepare for the Deep Impact event, two teams of astronomers have already used ESO’s telescopes over several months to do pre-impact monitoring, taking images and spectra of the comet both in the visible and mid-infrared wavebands.
These teams make observations typically once per month, using either the 3.6m or the 3.5m New Technology Telescope (NTT) telescopes at La Silla.



ESO’s telescopes will also be used in the post-impact observations. As soon as the comet is visible after the impact from Chile, all major ESO telescopes – the four Unit Telescopes of the Very Large Telescope Array at Paranal, as well as the 3.6m, 3.5m NTT and the 2.2m ESO/MPG telescopes at La Silla – will be observing Tempel 1, in very close collaboration with ESA and the space mission’s scientific team.


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RE: Comet 9P/Tempel 1
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This is a false-colour composite image of Comet 9P/Tempel 1 taken with EMMI on the New Technology Telescope (NTT) at La Silla, during the night of May 4 - 5, 2005, and shows the comet, 100 million kilometres away from Earth.
The coma extends more than 30 thousand kilometres from the comet nucleus, which is a 5 km diameter snowball hidden in the central bright core of the coma.


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North is up, East is left; the field of view is 2.5 arcmin. The exposure time is 30s in the V filter (associated to the Blue channel), 45s in R (green) and 30s in I (red).
As the images in the various filters were obtained one after the other, and as the comet is moving in front of the background objects, the two stars visible in this image appear as sequences of coloured dots.
The comet itself appears only very softly coloured, as its dust reflects almost uniformly the light from the Sun.




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RE: Deep Impact
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Fifty-nine days before going head-to-head with comet Tempel 1, NASA's
Deep Impact spacecraft successfully executed the second trajectory correction manoeuvre of the mission.
The burn further refined the spacecraft's trajectory, or flight path, and also moved forward the expected time of the July 4th comet encounter so that the impact would be visible by ground- and space-based observatories.
The 95-second burn - the longest remaining firing of the spacecraft's motors prior to comet encounter -- was executed on May 4.
It changed Deep Impact's speed by 18.2 kilometres per hour.



"Spacecraft performance has been excellent, and this burn was no different. It was a textbook manoeuvre that placed us right on the money." - Rick Grammier, Deep Impact project manager at NASA's Jet Propulsion Laboratory, Pasadena, US.
Right on the money is where Deep Impact has to be to place a 1-meter-long (39-inch) impactor spacecraft in the path of a comet about as big as the island of Manhattan that is bearing down on it at 37,100 kilometres per hour. At the same time, from a very comet-intimate distance of 500 kilometres, a flyby spacecraft will be monitoring the event. This all occurs i at 9:52 GMT (July 3,10:52 p.m. Pacific time) -- at a distance of 133.6-million kilometres from Earth.
"With this manoeuvre our friends working the Hubble Space Telescope are assured a ringside seat. Their observations, along with space telescopes Chandra and Spitzer and numerous ground-based observatories, will provide us with the most scientific bang for our buck with Deep Impact." - Dr. Michael A'Hearn Deep Impact Principal Investigator.
Deep Impact is comprised of two parts, a "flyby" spacecraft and a smaller "impactor." The impactor will be released into the comet's path before a planned high-speed collision on July 4.
The crater produced by the impact could range in size from the width of a large house up to the size of a football stadium, and from 2 to 14 stories deep.
Ice and dust debris will be ejected from the crater, revealing the material beneath.
The Deep Impact spacecraft has four data collectors to observe the effects of the collision. A camera and infrared spectrometer, which comprise the High Resolution Instrument, are carried on the flyby spacecraft, along with a Medium Resolution Instrument. A duplicate of the Medium Resolution Instrument on the impactor will record the vehicle's final moments before it is run over by comet Tempel 1 at a speed of about 37,100 kilometres per hour.



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The Faint comet Tempel 1 sports a fuzzy blue-tinted tail, just right of centre in this lovely field of stars.


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Recorded on May 3rd slowly sweeping through the constellation Virgo, periodic comet Tempel 1 orbits the Sun once every 5.5 years. Also caught in the sky view are two galaxies at the upper left - NGC 4762 and NGC 4754 - both members of the large Virgo Cluster of galaxies. Classified as a lenticular galaxy, NGC 4762 presents an edge-on disk as a narrow gash of light while NGC 4754 is a football-shaped elliptical galaxy.
Similar in apparent size, the galaxies and comet make for an intriguing visual comparison, but Tempel 1 is only about 3 light-minutes from planet Earth.
The two Virgo cluster galaxies are 50 million light-years away.
NASA's Deep Impact spacecraft is scheduled to encounter Tempel 1 on July 4th, launching a probe to impact the comet's nucleus.


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The Deep Impact mission team closed the Commission Phase of flight with the completion of the impactor projectile's checkout activities. During that phase, the team verified the basic health of all subsystems and tested the operation of the science instruments.
The mission now moves to Cruise Phase.
The Deep Impact spacecraft successfully photographed
Comet Tempel 1, from a distance of 39.7 million miles.

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The high-resolution telescope on Deep Impact, NASA's spacecraft that will smash into Comet Tempel 1 on July 4, has been found to have blurry vision.
The high resolution telescope wasn't fully focused after a `bake-out`, a procedure that heats up the instrument to remove moisture.
Test images revealed the problem.
"A special team has been formed to investigate the performance and to evaluate activities to bring the telescope the rest of the way to focus." - nasa

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