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29 Sept 03Solar System - Dr. C.C. Lang1 Exploring the Solar System: all about spacecraft/spaceflight.

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Presentation on theme: "29 Sept 03Solar System - Dr. C.C. Lang1 Exploring the Solar System: all about spacecraft/spaceflight."— Presentation transcript:

1 29 Sept 03Solar System - Dr. C.C. Lang1 Exploring the Solar System: all about spacecraft/spaceflight

2 29 Sept 03Solar System - Dr. C.C. Lang2 Exploring the Solar System: all about spacecraft/spaceflight II.How do we get there? - launch & orbits - gravity assist - fuel/propulsion I.How can we explore the Solar System? - types of space missions III. Onboard Systems - everything but the kitchen sink…

3 29 Sept 03Solar System - Dr. C.C. Lang3 1. Flyby Missions usually the first phase of exploration (remember Mars & Mariner 4?) spacecraft following continuous orbit - around the Sun - escape trajectory (heading off into deep space)

4 29 Sept 03Solar System - Dr. C.C. Lang4 Famous Example: VOYAGER 2 - launch 1977 with VOYAGER 1 - flew by Jupiter in 1979 - Saturn in 1980/1981 - Uranus (V2) in 1986 - Neptune in 1989 - will continue to interstellar space - study of interplanetary space particles (Van Allen) - data expected until 2020 Clouds on Neptune Interplanetary Space & the Solar Wind

5 29 Sept 03Solar System - Dr. C.C. Lang5 Other Flyby examples: Underway: Stardust Comet return mission - launched in 1999 - interstellar dust collection - asteroid Annefrank flyby - Comet encounter (Jan 2004) - Earth/sample return (Jan 2006)

6 29 Sept 03Solar System - Dr. C.C. Lang6 Future flyby: Pluto-Kuiper Belt Mission - to be launched in January 2006 - swing by Jupiter (gravity assist*) - fly by Pluto & moon Charon in 2015 - then head into Kuiper Belt region (tons of solar system debris) - to study objects that are like Pluto

7 29 Sept 03Solar System - Dr. C.C. Lang7 2. Orbiter Spacecraft designed to travel to distant planet & enter into orbit around planet must carry substantial propulsion (fuel) capacity has to withstand: - staying in the ‘dark’ for periods of time - extreme thermal variations - staying out of touch with Earth for periods of time usually the second phase of exploration

8 29 Sept 03Solar System - Dr. C.C. Lang8 Famous Example: Galileo - why would a mission to Jupiter be called Galileo? - launched in 1989 aboard Atlantis Space Shuttle - entered into Jupiter’s orbit in 1995 - highly successful study of Jupiter & its moons Burned up in Jupiter’s atmosphere last week!

9 29 Sept 03Solar System - Dr. C.C. Lang9 3. Atmospheric Spacecraft - relatively short mission - collect data about the atmosphere of a planet or planet’s moon - usually piggy back on a bigger craft - needs no propulsion of its own - takes direct measurements of atmosphere - usually is destroyed; rest of spacecraft continues its mission Example: Galileo’s atmospheric probe

10 29 Sept 03Solar System - Dr. C.C. Lang10 Example: Galileo’s atmospheric probe - traveled with Galileo for nearly six years - took five months from release to contact with atmosphere - collected 1 hour’s data IN Jupiter’s atmosphere

11 29 Sept 03Solar System - Dr. C.C. Lang11 4. Lander Spacecraft - designed to reach surface of a planet/body - survive long enough to transmit data back to Earth - small, chemical experiments possible Many Successful Examples: - Mars Viking Landers - Venus Lander - Moon Landers (with humans!) Mars Viking Lander

12 29 Sept 03Solar System - Dr. C.C. Lang12 Example: NEAR Asteroid Rendevous Mission Near-Earth Asteroid Eros fly to a nearby asteroid: Eros – 1-2 AU orbit around Sun ~ twice size of NYC

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15 29 Sept 03Solar System - Dr. C.C. Lang15 5. Penetrator Spacecraft - designed to penetrate the surface of a planet/body - must survive the impact of many times the gravity on Earth - measure properties of impacted surface No Currently Successful Examples: - Deep Space 2 (lost with Mars Polar Lander) But more to come in future: - “Ice Pick” Mission to Jupiter’s Moon Europa - “Deep Impact” Mission to a Comet

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17 29 Sept 03Solar System - Dr. C.C. Lang17 6. Rover Spacecraft - electrically powered, mobile rovers - mainly designed for exploration of Mars’ surface - purposes: taking/analyzing samples with possibility of return - Pathfinder was test mission – now being heavily developed Mars Pathfinder Mars Exploration Rovers

18 29 Sept 03Solar System - Dr. C.C. Lang18 7. Observatory Spacecraft - in Earth orbit (or at Lagrange points) - NASA’s “Great Observatories”: - Hubble (visible) - Chandra (X-ray) - SIRTF (infrared) - Compton (gamma-rays) -Large, complex scientific instruments - up to 10-20 instruments on board - designed to last > 5-10 years SIRTF (near-IR)Chandra (X-ray) SOHO

19 29 Sept 03Solar System - Dr. C.C. Lang19 How do we get there? 1. First must leave the Earth’s surface - must ‘escape’ into orbit - gets an initial boost via rocket to go into Earth’s orbit – needs an acceleration of 5 miles/sec - during orbit, you sometimes need to adjust height of orbit by increasing/decreasing energy: - practically: firing onboard rocket thrusters - a speed of 19,000 miles/hr will keep craft in orbit around Earth using LEAST amount of fuel – saves big $$$ to be light

20 29 Sept 03Solar System - Dr. C.C. Lang20 How do we get there? 2. To get to an outer orbit: Mars - spacecraft already in orbit (around Sun) - need to adjust the orbit – boost via rocket – so that the spacecraft gets transferred from Earth’s orbit around Sun to Mars’ orbit around Sun - but you want spacecraft to intercept Mars on Mars’ orbit - matter of timing: small window every 26 months - to be captured by Mars – must decelerate - to LAND on Mars – must decelerate further & use braking mechanism using LEAST amount of fuel – saves big $$$ to be light

21 29 Sept 03Solar System - Dr. C.C. Lang21 How do we get there? 3. To get to an inner orbit: Venus - spacecraft already in orbit (around Sun) on Earth - need to adjust the orbit once off Earth to head inwards to Venus - instead of SLOWING down (you’d fall to Earth), you use reverse motion in your solar orbit, effectively slowing down to land on Venus’ orbit - but you want spacecraft to intercept Venus on Venus’ orbit - matter of timing: small window every 19 months using LEAST amount of fuel – saves big $$$ to be light

22 29 Sept 03Solar System - Dr. C.C. Lang22 How do we get there? 4. Gravity Assist - can use the law of gravity to help spacecraft propel themselves further out in the SS - Voyager: its trajectory was aimed at getting to Jupiter’s orbit just after Jupiter - Voyager was gravitationally attracted to Jupiter, and fell in towards Jupiter - Jupiter was “tugged on” by Voyager and its orbital energy decreased slightly -then Voyager had more energy than was needed to stay in orbit around Jupiter, and was propelled outward! - repeated at Saturn & Uranus using LEAST amount of fuel – saves big $$$ to be light

23 29 Sept 03Solar System - Dr. C.C. Lang23 At what speeds are these things traveling through space? The currently fastest spacecraft speeds are around 20 km per second (72,000 km per/hr) For example, Voyager 1 is now movingVoyager 1 outwards from the solar system at a speed of 16 km per second. At this rate, it would take 85,000 years to reach the nearest star -3,000 human generations! Even assuming that we could reach a speed of 1/10th of the velocity of light, it would still take a minimum of 40 years or so to reach our nearest star.

24 29 Sept 03Solar System - Dr. C.C. Lang24 How do we get there? 5. Concerns about energy sources - traditional energy boost: chemical thrusters - most of energy is provided on launch – very costly! especially for large, heavy, complex instruments - a few times per year spacecraft fires short bursts from its thrusters to make adjustments - mostly free falling in orbit, coasting to destination using LEAST amount of fuel – saves big $$$ to be light

25 29 Sept 03Solar System - Dr. C.C. Lang25 How do we get there? 5. The Future: Ion Propulsion - Xenon atoms are made of protons (+) and electrons (-) - bombard a gas with electrons (-) to change charge - creates a build up of IONS (+) - use magnetic field to direct charged particles - the IONS are accelerated out the back of craft - this pushes the craft in the opposite direction using LEAST amount of fuel – saves big $$$ to be light

26 29 Sept 03Solar System - Dr. C.C. Lang26 to operate the ion system, use SOLAR panels sometimes called solar-electric propulsion can push a spacecraft up to 10x that of chemical propulsion very gentle – best for slow accelerations

27 29 Sept 03Solar System - Dr. C.C. Lang27 HISTORY of ION PROPULSION first ion propulsion engine – built in 1960 over 50 years in design/development at NASA very new technology has been used successfully on test mission: Deep Space 1

28 29 Sept 03Solar System - Dr. C.C. Lang28 Europe’s Lunar Explorer: Smart 1 Probe - launched 27 September 2003 (Saturday) - 2-2.5 year mission - will study lunar geochemistry - search for ice at south Lunar pole - **testing/proving of ion propulsion drives!**

29 29 Sept 03Solar System - Dr. C.C. Lang29 1. data handling 2. flight control 3. telecommunications 4. electrical power 5. particle shields 6. temperature control 7. propulsion mechanism 8. mechanical devices (deployment) Onboard Systems on Most Spacecraft: Galileo

30 29 Sept 03Solar System - Dr. C.C. Lang30 Time & Money Considerations Planning for a new spacecraft - plans start about ~10 years before projected launch date - must make through numerous hurdles/reviews - very competitive: 1/10-25 average acceptance rate Costs! (circa 2000) – total NASA budget (2000) was $13 billion Basic Assumptions for design/development of small craft: - Cost of spacecraft and design: $50M - Cost of launch: $50M + $10M per AU + $10M per instrument - Cost of mission operations: $10M / month - Initial speed: 3 months per AU of distance For every additional instrument, add $100M and increase travel time by 25% (e.g., for four instruments, double the travel time) A probe, lander, or balloon counts as two additional instruments. If you are going to the outer Solar System (Jupiter or beyond), you must add plutonium batteries, which count as one instrument.


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