orbital mechanics 101, part ii
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Orbital Mechanics 101, Part II. Understand basic orbital mechanics and how orbits work Understand the different types of orbits used for different purposes Understand basic principles of Interplanetary Travel mechanics. Spheres of Influence. - PowerPoint PPT PresentationTRANSCRIPT
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Understand basic orbital mechanics and how orbits work
Understand the different types of orbits used for different purposes
Understand basic principles of Interplanetary Travel mechanics
Orbital Mechanics 101, Part II
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Spheres of InfluenceA body’s sphere of influence (SOI)
is the surrounding volume in which its gravity dominates a spacecraft. In theory, SOI is infinite. In practice, as a spacecraft gets
farther away, another body’s gravity dominates.
The size of a planet’s SOI depends on:The planet’s massHow close the planet is to the
Sun (Sun’s gravity overpowers that of closer planets)
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Low-Earth orbit – an orbit up to about 1,240 miles above the Earth Medium-Earth orbit – one with an altitude of about 12,400 miles High-Earth orbit – an orbit at an altitude of about 22,300 miles
Types of Orbits
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Maneuvering in SpaceOrbit Changes
Moving From One Orbit to AnotherUsing the Hohmann Transfer
Rendezvous in SpaceGravity Assist Velocity
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Simple Orbit Changes:Moving from one orbit to another
Moving from one orbit to another is a complex and orchestrated dance of speed and fuel consumption
When we maneuver in space, we need to factor fuel into the process.
Fuel is EVERYTHING in Space
First space rendezvous of two spacecraft (Gemini 6 and 7) in December 1965
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In 1925 a German engineer, Walter Hohmann, thought of a fuel-efficient way to transfer spacecraft between orbits—the Hohmann Transfer.
The Hohmann Transfer uses an elliptical transfer orbit tangent to the initial and final orbits.
Simple Orbit Changes:Moving from one orbit to another
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Simple Orbit Changes:Using the Hohmann TransferA spacecraft changes its energy by
increasing or decreasing its velocity — in essence firing rocket engines.
Adding or subtracting velocity changes the orbit’s energy
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First space rendezvous of two spacecraft (Gemini 6 and 7) in December 1965
Hohmann Transfer (Application to Rendezvous)
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Interplanetary Travel
Four bodies are involved:
Sun Departure Planet Target Planet Spacecraft
Analyzing the gravitational forces (Remember that Newton guy and his Law of Universal Gravitation) from all three central bodies on the spacecraft would amount to a “four-body” problem. Far to complicated, so….
Simplify (A process called “Patched Conic” Approximation) Break into familiar, manageable pieces. Consider as three two-body problems.
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“Patched Conic” Approximation
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Gravity-Assist TrajectoriesProcess using a
planet’s gravitational field and orbital velocity to “sling shot” a spacecraft, changing its velocity (in magnitude and direction) with respect to the Sun.
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Gravity-Assist TrajectoriesAs a spacecraft
enters a planet’s sphere of influence (SOI), it coasts on a hyperbolic trajectory around the planet.
Then, the planet pulls it in the direction of the planet’s motion, increasing (or decreasing) its velocity relative to the Sun.
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Gravity-Assist Trajectories
Generally, gravity-assisted trajectories consist of two types:
A gravity assist that changes the magnitude of a spacecraft’s velocity is called orbit pumping.
Using a planet’s gravity to change the direction of travel is called orbit cranking.
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Gravity-Assist TrajectoriesGravity Launch Game
http://www.sciencenetlinks.com/interactives/gravity.html
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Understand basic orbital mechanics and how orbits work
Understand the different types of orbits used for different purposes
Understand basic principles of Interplanetary Travel mechanics
Orbital Mechanics 101, Part II