[meteorite-list] Dawn Journal - May 3, 2011
From: Sterling K. Webb <sterling_k_webb_at_meteoritecentral.com>
Date: Wed, 4 May 2011 19:34:21 -0500 Message-ID: <2E41C0C810EA40E79445AD77AA021316_at_ATARIENGINE2> On July 16, DAWN will enter a circum-Vestan orbit at an altitude of 9,600 miles above Vesta. Its altitude will be lowered progressively once the orbit has been tweaked to the precise parameters needed. Vesta is not a "sphere," so orbiting its center of gravity causes your distance from its surface to vary like you were on a roller coaster. Give it plenty of room; don't want to clip the asteroid, ya know... It's a long way to the nearest body shop. Sterling K. Webb ------------------------------------------------------------------------------- ----- Original Message ----- From: "Stuart McDaniel" <actionshooting at carolina.rr.com> To: "Ron Baalke" <baalke at zagami.jpl.nasa.gov>; "Meteorite Mailing List" <meteorite-list at meteoritecentral.com> Sent: Wednesday, May 04, 2011 6:11 PM Subject: Re: [meteorite-list] Dawn Journal - May 3, 2011 > So how is the craft only 9,00 miles in altitude?? > > > > Stuart McDaniel > Lawndale, NC > Secr., > Cleve. Co. Astronomical Society > IMCA #9052 > Member - KCA, KBCA, CDUSA > -----Original Message----- > From: Ron Baalke > Sent: Wednesday, May 04, 2011 1:59 PM > To: Meteorite Mailing List > Subject: [meteorite-list] Dawn Journal - May 3, 2011 > > > http://dawn.jpl.nasa.gov/mission/journal_05_03_11.asp > > Dawn Journal > Dr. Marc Rayman > May 3, 2011 > > Dear Dawntalizingly Close Readers, > > Dawn is on the threshold of a new world. After more than three and a > half years of interplanetary travel covering in excess of 2.6 billion > kilometers (1.6 billion miles), we are closing in on our first > destination. Dawn is starting its approach to Vesta. > > The interplanetary cruise phase of the mission ends today and the > 15-month Vesta phase begins. The first three months are the "approach > phase," during which the spacecraft maneuvers to its first science > orbit. Many of the activities during approach were discussed in detail > in March and April last year, and now we are about to see those plans > put into action. > > The beginning of the phase is marked by the first images of the alien > world Dawn has been pursuing since it left Earth. Vesta will appear as > little more than a smudge, a small fuzzy blob in the science camera's > first pictures. But navigators will analyze > where it shows up against the background stars to help pin down the > location of the spacecraft relative to its target. To imagine how this > works, suppose that distant trees are visible through a window in your > house. If someone gave you a photo that had been taken through that > window, you could determine where the photographer (Dawn) had been > standing by lining up the edge of the window (Vesta) with the pattern > of > the background trees (stars). Because navigators know the exact > position > of each star, they can calculate where Dawn and Vesta are relative to > each other. This process will be repeated as the craft closes in on > Vesta, which ultimately will provide a window to the dawn of the solar > system. > > Even though the mysterious orb is still too far away to reveal new > features, it will be exciting to receive these first images. For most > of > the two centuries that Vesta has been studied, it has been little more > than a pinpoint of light. Interrupting thrusting once a week this > month > to glimpse its protoplanetary destination, Dawn will watch it grow > from > about five pixels across to 12. By June, the images should be > comparable > to the tantalizing views obtained by the Hubble Space Telescope. As > the > approach phase continues and the distance diminishes, the focus will > grow still sharper and new details will appear in each subsequent set > of > pictures. During the approach phase, images will be released in > periodic > batches, with priority viewing for residents of Earth. The flow will > be > more frequent thereafter. > > The visible and infrared mapping spectrometer (VIR) > will join the camera in spying Vesta on > May 10 and again later in the approach phase. At the end of June, Dawn > will watch Vesta for a full Vestian day of 5 hours, 20 minutes. When > the > camera searches for moons on July 9 and 10, it will also enjoy another > full pirouette. By the third and final time the spacecraft observes > Vesta throughout a complete rotation on its axis, during a set of > observations from July 23 to 25, Dawn will be in orbit. > > On July 16, when the ship is at an altitude of around 15,500 > kilometers > (9,600 miles) and propelling itself with its ion propulsion system in > the same way it has been for more than 900 days of interplanetary > travel, Vesta will gently take hold. For the first time since > September > 27, 2007, when Dawn rode atop the second and third stages > of the Delta rocket for a short time in Earth orbit, it will be bound > to a planetary body. > > The precise time and distance at which Vesta gains control of its > visitor depend not only on subtleties of the thrusting until then but > also on the strength of the giant asteroid's gravity. Among the many > characteristics of Vesta yet to be known well is its mass. Astronomers > have estimated it by detecting the tiny changes Vesta induces in the > orbits of other asteroids and even of Mars, but those measurements > yield > only approximate values. One of Dawn's objectives is to determine > Vesta's mass and to map its gravitational field. > > The approach phase concludes when Dawn is ready to commence its survey > orbit in the second week of August. We will consider the timing of the > beginning of this next phase in a subsequent log. > > While the start of the approach phase is defined by the beginning of > the > navigation imaging, other changes are being made today as well, both > in > procedures used by the operations team and in the configuration of the > spacecraft. Let's consider just one subsystem: attitude control. > (To achieve a certain mystique about their work, > engineers use the term "attitude" to describe the orientation of the > probe in the weightless conditions of spaceflight; the system also > happens to have a very enthusiastic attitude about its work.) Since > August Dawn has controlled its attitude with > its reaction control system, the small thrusters > that operate with hydrazine propellant. (When the craft is using the > ion > propulsion system, which is most of the time, the ion thruster helps > control the attitude.) > > At the beginning of the approach phase, the ship returns to using > reaction wheels, gyroscope-like devices which, when electrically spun > faster or slower, rotate (or stop the rotation of) the spacecraft. > During Vesta operations, Dawn will turn much more frequently, as it > points its sensors at the alien world it is exploring, aims its main > antenna to Earth frequently to transmit its precious findings, and > follows a complex flight profile to > travel from one science orbit to another. The reaction wheels will be > used until Dawn has departed from Vesta in July 2012, providing more > accurate control of the attitude while conserving hydrazine. > > To enable the explorer to point its camera and VIR even more > delicately, > the ship's gyroscopes are powered on. Not to be confused with the > reaction wheels, these devices help determine exactly what the > attitude > is so that the system can command the wheels to achieve the desired > attitude. The gyroscopes are not needed for most of Dawn's activities > during the interplanetary cruise phase of its mission, so they have > been > off for most of the mission so far. > > The gyroscopes serve another purpose at Vesta, which we discussed in > more detail in January. The probe usually relies on star trackers for > sensing its attitude. Each tracker takes pictures of the stars. Its > internal computer processes the images, finding familiar patterns of > stars to determine where it is pointed, just as you might use some of > the constellations visible from your planet to orient yourself at > night. > When some component (such as the main antenna or an ion thruster) > needs > to be oriented in such a way that the star trackers happen to point at > Vesta, the gyroscopes will take over so the spacecraft doesn't lose > track of its attitude. There will be much to discover about the > enigmatic 530-kilometer-diameter (330-mile) rocky world, but its > ability > to block starlight is not in doubt. > > While the science camera and VIR will be turned on and off as needed > during the Vesta phase, the gamma-ray and neutron detector (GRaND) > is being activated today and will remain on > until the departure next year. Most of that time, the majority of the > signals it detects will be from space radiation known as cosmic rays. > But the closer it gets to Vesta, the more gamma rays and neutrons it > will receive from the surface, gradually allowing scientists to > formulate a census of the atomic constituents. GRaND's greatest > ability > to sense the faint radiation will be in the low altitude mapping > orbit. > > The instruments were tested during a planned coast period in March, > and each was in excellent condition. Dawn had > another scheduled hiatus in thrusting from April 11 to 19, but this > one > was not intended for calibrations or tests. Rather, controllers had > planned this for an upgrade to the software in the craft's main > computer. > > When version 9.0 of the software was installed last year, > it was intended to be used at Vesta. By > coincidence, the day after they rebooted the computer to start running > with 9.0, the operations team began thinking about adding a new > capability to the software. The motivation was the development of > excessive friction in reaction wheel no. 4. > While Dawn performs perfectly well with > the other three wheels, the unavailability of one wheel meant that > there > was no longer a spare. Since then, three tests of wheel no. 4 have > shown > that it cannot be restored as a backup prior to Vesta and probably not > for the rest of the mission. Therefore, to regain the robot's > resilience > to the loss of almost any component, work began immediately at Orbital > Sciences Corporation and JPL on new software that would allow safe and > stable attitude control with only two wheels. (Of course, the > spacecraft > can function with all wheels powered off, relying on the reaction > control system, but ever-cautious engineers wanted the two-wheel > option > to reduce the hydrazine expenditure for complex Vesta and Ceres > operations.) > > The installation of software on our probe flying in deep space is a > delicate task. To begin running with the new version, the computer has > to be rebooted. That same computer constantly performs such essential > functions as maintaining a steady attitude and acceptable > temperatures. > Controllers followed the same intricate procedures they used > successfully to load new software in November 2007, April 2009, and > June 2010. Preparing the spacecraft, radioing the > new software to it, rebooting the computer, and commanding the craft > back to its normal flight configuration all went exactly according to > plan. Although more than a week was allocated, it only took three > days. > > Dawn is now running what the team officially designates OBC flight > software version 10.0, but what the more zany team members refer to as > 10.0 or "ten oh." It may be surprising that even with the complex and > rigorous work to overcome myriad challenges of operating the first > explorer from Earth to take up residence in the main asteroid belt, > normally dispassionate engineers can display such frivolity. > > Now with new software, the spacecraft is beginning the approach phase. > Its journey has been long, but the reward is almost in view. Since > leaving Earth in September 2007, Dawn has made about one and three > quarters circuits around the sun as it spirals outward. > Earth itself (along with your > correspondent and some readers) has completed more than three and a > half > orbits in that time. But on May 14, Vesta will finish its first > revolution around the sun since Dawn has been in flight; the mission > will then have been under way for exactly one Vestian year. > > We have seen before that objects travel more > slowly in more distant orbits, where the force of gravity holding them > is weaker. Dawn has been climbing the solar system hill, traveling > farther and farther from the sun at the bottom. It began its journey > on > Earth, partway up the hill. Now far above Mars, the probe is closing > in > on Vesta. As the adventurer and the mysterious world each race around > the sun at nearly 21 kilometers per second (47,000 mph), Dawn is > gradually closing in for its rendezvous. Two months ago, the > spacecraft's course was bringing it toward Vesta at 0.7 kilometers per > second (1,600 mph). Today, having > completed more thrusting to bring its orbit into a closer and closer > match with Vesta's, the craft is approaching at about 0.37 kilometers > per second (830 mph). The speed will continue to diminish as Dawn > gradually reshapes its flight path to be exactly the same as Vesta's. > Soon, they will travel together around the sun. > > Meanwhile, the distance between them continues to shrink. Since the > middle of March, Vesta has outshone everything in Dawn's sky save the > sun. By the middle of April, a sharp-eyed passenger would notice that > Vesta is more than a pinpoint of light like the myriad stars and > distant > planets; it would appear as a tiny disk, hinting of the exciting > adventure ahead. (The passenger also might notice that his luggage was > left back on Earth, more than 320 million kilometers or 200 million > miles away.) Now, with Dawn's interplanetary cruise ending and the > approach beginning, Vesta is coming into its sights, as the ship > prepares to sail into port after an extraordinarily long journey > across > the lonely emptiness of the vast interplanetary seas. > > Dawn is 1.2 million kilometers (760,000 miles) from Vesta, or 3.2 > times > the average distance between Earth and the moon. It is also 1.90 AU > (284 > million kilometers or 177 million miles) from Earth, or 715 times as > far > as the moon and 1.89 times as far as the sun today. Radio signals, > traveling at the universal limit of the speed of light, take 32 > minutes > to make the round trip. > ______________________________________________ > Visit the Archives at > http://www.meteoritecentral.com/mailing-list-archives.html > Meteorite-list mailing list > Meteorite-list at meteoritecentral.com > http://six.pairlist.net/mailman/listinfo/meteorite-list > > ______________________________________________ > Visit the Archives at > http://www.meteoritecentral.com/mailing-list-archives.html > Meteorite-list mailing list > Meteorite-list at meteoritecentral.com > http://six.pairlist.net/mailman/listinfo/meteorite-list Received on Wed 04 May 2011 08:34:21 PM PDT |
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