CIVIL AIR PATROL CAP-STK Aerospace Program 2010!! Orbital
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CIVIL AIR PATROL CAP-STK Aerospace Program 2010!! Orbital Mechanics and other Space Operations Topics !! Colorado Springs Cadet Squadron Lt Col M. T. McNeely
ORBITAL MECHANICS Physical Laws Requirements for Injection Classifications of Orbit Six Orbital Elements Ground Tracks
Two ORBITAL MECHANICS men in history that were essential to formulating orbital mechanics: Kepler and Newton!! Kepler’s 3 Laws: – Law of Ellipses – Law of Equal areas – Law of Harmonics Newton’s 3 Laws: – Law of Inertia – Law of Momentum – Law of Action -Reaction
PHYSICAL LAWS Kepler’s 1st Law: Law of Ellipses The orbits of the planets are ellipses with the sun at one focus. Or, the orbits of satellites around the earth are ellipses with the earth at one focus .
PHYSICAL LAWS Is this orbit possible?
PHYSICAL LAWS Kepler’s 2nd Law: Law of Equal Areas The line joining the planet to the center of the sun sweeps out equal areas in equal times T4 T5 A5 T6 A6 A4 T3 A3 A2 T2 A1 T1
PHYSICAL LAWS Kepler’s 2nd Law: Law of Equal Areas Satellites travel at the same speed!!
PHYSICAL LAWS Kepler’s 2nd Law: Law of Equal Areas t2 t1 Area 1 Area 2 t0 t3 t1-t0 t3-t2 Area 1 Area 2 Satellites travel at varying speeds!!
PHYSICAL LAWS Kepler’s 3rd Law: Law of Harmonics The squares of the periods of two planets’ orbits are proportional to each other as the cubes of their semimajor axes: T12/T22 a13/a23 In English: Orbits with the same semimajor axis will have the same period
PHYSICAL LAWS Newton’s 1st Law: Law of Inertia Every body continues in a state of uniform motion unless it is compelled to change that state by a force imposed upon it
PHYSICAL LAWS Newton’s 2nd Law: Law of Momentum Change in momentum is proportional to and in the direction of the force applied Momentum equals mass x velocity Change in momentum gives: F ma F F
PHYSICAL LAWS Newton’s 3rd Law: Action - Reaction For every action, there is an equal and opposite reaction Hints at conservation of momentum
INJECTION REQUIREMENTS Speed If you want something to stay in an orbit, it has to be going very fast!
INJECTION REQUIREMENTS Speed 5m 8 km
INJECTION REQUIREMENTS Speed A satellite must be going 17,500 mph to stay in a low earth orbit 17,500 mi/hr 100 miles
INJECTION REQUIREMENTS Altitude Are you moving FASTER or SLOWER the higher your altitude?
INJECTION REQUIREMENTS Direction Since the earth rotates from west to east, you want to launch satellites to the east This give you a 915 mph speed boost by launching east (at the Kennedy Space Center’s location in Florida) What happens if you launch to the west? The south?
ORBITAL ELEMENTS Definition A set of mathematical parameters that enables us to accurately describe satellite motion
ORBITAL ELEMENTS Purpose Discriminate one satellite from other satellites Predict where a satellite will be in the future or has been in the past Determine amount and direction of maneuver or perturbation
ORBITAL ELEMENTS or The Six Keplerian Elements Size/Period Shape (Circular or Ellipse) Inclination Right Ascension Argument of Perigee True Anomaly
ORBIT CLASSIFICATION Size/Period Size is how big or small your satellite’s orbit is . Defined by semi-major axis There are basically 4 sizes of orbits satellites use: – Low Earth Orbit (LEO): approx 120 – 1200 miles above Earth – Medium Earth Orbit (MEO) or Semi-synchronous Orbit: approx 12,000 miles above Earth – Highly Elliptical Orbit (HEO): altitude varies greatly! From 100 miles to sometimes several hundred thousand miles – Geo-synchronous or Geo-stationary Orbit (GEO): approx 22,300 miles from Earth
ORBIT CLASSIFICATION Location of Orbits Equatorial – Prograde (towards the east) or Retrograde (towards the west) Polar – Over the Poles!! A very Important Point: ALL ORBITS OF SATELLITES MUST INTERSECT THE CENTER OF THE EARTH
ORBIT CLASSIFICATION Shape Orbit shapes are either circular or not circular: some sort of an Ellipse!! How elliptical an orbit, is called Eccentricity
ORBIT CLASSIFICATIONS Circular Orbits Characteristics – – Constant speed Nearly constant altitude Typical Missions – – – – Reconnaissance/Weather (DMSP) Manned Navigational (GPS) Geo-synchronous (Comm sats)
ORBIT CLASSIFICATIONS Elliptical Orbits Characteristics – – – Varying speed Varying altitude Asymmetric Ground Track Typical Missions – – – Deep space surveillance (Pioneer) Communications (Polar comm.) Ballistic Missiles
ORBIT CLASSIFICATIONS Eccentricity e 0.75 e .45 The closer your Eccentricity is to 1, the more elliptical your orbit is e 0 Why could you never have an Eccentricity of 1?
ORBITAL ELEMENTS Inclination Inclination is the tilt of your orbit At 0 degrees of inclination, you are orbiting the equator At 90 degrees of inclination, you are in a polar orbit Equatorial Plane Inclination: Is this angle, measured in degrees Inclination Orbital Plane
ORBITAL ELEMENTS Inclination Prograde: 0 i 90 Equatorial: i 0 or 180 Polar: i 90 Retrograde: 90 i ú 180
ORBITAL ELEMENTS Right Ascension Right Ascension is the swivel of your tilt, as measured from a fixed point in space, called the First Point of Aries i ne Li of s de No First Point of Aries ( ) Right Ascension of the Ascending Node
ORBITAL ELEMENTS Right Ascension Right Ascension will determine where your satellite will cross the Equator on the ascending pass It is measured in degrees Inclination ne Li of First Point of Aries ( ) s de No You will be able to much easily see what Right Ascension is when using STK!! Right Ascension is this angle, measured in degrees You will not have a Right Ascension if your Inclination is 0, why?
ORBITAL ELEMENTS Argument of Perigee Argument of Perigee is a measurement from a fixed point in space to where perigee occurs in the orbit It is measured in degrees Perigee Inclination ne Li Apogee of You will be able to much easily see what Argument of Perigee is when using STK!! s de No Argument of Perigee: Is this angle, measured in degrees
ORBITAL ELEMENTS True Anomaly True Anomaly is a measurement from a fixed point in space to the actual satellite location in the orbit True Anomaly: It is measured in degrees Is this angle, measured in degrees Direction of satellite motion You will be able to much easily see what True Anomaly is when using STK!! Fixed point in space
GROUND TRACKS!!
GROUND TRACKS Definition One way to define a satellite’s orbit is to determine its track across the ground It is as if you had a big pencil from the satellite to the ground. The track it traces is called the ground track
GROUND TRACKS Definition Sub point – Point on Earth’s surface defined by an imaginary line connecting the satellite and the Earth’s center Ground Track – Trace of sub points over time
GROUND TRACKS Factors Size/Period Eccentricity Inclination Argument of Perigee Injection Point
Ground Tracks Period - For a non-rotating Earth, the ground track of a satellite is a great circle - Since the Earth spins on its axis and the satellite orbits the Earth, the period of both affects the ground track
Ground Tracks Westward Regression - Earth rotates east under a satellite satellite appears to walk west - Earth rotates 360 degrees in 24 hours (15 degrees per hour)
Ground Tracks Eccentricity Highly eccentric orbit means satellite moves faster at perigee and slower at apogee ground track will be asymmetrical Satellite will ‘hang’ over earth at apogee and move faster than the earth at perigee
Ground Tracks Eccentricity Ground Track for Molnyia orbit eccentricity .7252
Ground Tracks Inclination Inclination of the orbit determines the maximum latitude the ground track will reach
Ground tracks Inclination 60 45N 30 0 30 60 Inclination 45 degrees Eccentricity 0 45S
Ground Tracks Argument of Perigee - Establishes the longitude of both perigee and apogee Direction of satellite motion perigee Argument of Perigee angle apogee ascending node line of nodes
Ground tracks Argument of Perigee Argument of Perigee 90 degrees (red) argument of perigee 270 degrees (white)
Ground tracks Injection Point Assuming no maneuvers after launch, launch sites will determine inclination more on this in launch considerations Injection point will determine where the ground track will start -
PERTURBATIONS Space is a vacuum Once a satellite is in orbit, in the vacuum of space, is there anything that will affect it? Yes – these things are called Perturbations .
PERTURBATIONS Definition – A disturbance in the regular motion of a celestial body Types – – – – – Gravitational Atmospheric Drag Third Body Effects Solar Wind/Radiation Effects Electro-magnetic
PERTURBATIONS Gravitational Earth’s asymmetrical mass causes a noncentral gravitational pull
PERTURBATIONS Gravitational Ellipticity of the Earth causes gravity wells and hills Stable points: 75E and 105W -- Himalayas and Rocky Mountains Unstable points: 165E and 5W -- Marshall Islands and Portugal Drives the requirement for station keeping
PERTURBATIONS Atmospheric Drag Friction caused by impact of satellite with particles in the Earth’s atmosphere Reduces satellite’s energy Changes the size (semi-major axis) and shape (eccentricity)
PERTURBATIONS Atmospheric Drag Perigee remains same, Apogee decreases
PERTURBATIONS Third Body Effects Gravitational pull of other massive bodies, i.e. Sun, moon Mainly noticeable in deep space orbits
PERTURBATIONS Solar Wind/Radiation Pressure Solar wind causes radiation pressure on the satellite Effects similar to atmospheric drag Effects are more pronounced on satellites with large surface areas
PERTURBATIONS Electro-Magnetic Interaction between the Earth’s magnetic field and the satellite’s electro-magnetic field results in magnetic drag
LAUNCH CONSIDERATIONS Launch Windows Azimuth Vs. Inclination
LAUNCH CONSIDERATIONS Launch Windows The period of time during which a satellite can be launched directly into a specific orbital plane from a specific launch site Window duration driven by safety, fuel requirements, desired injection points, etc. Window is centered around optimal launch time
LAUNCH CONSIDERATIONS Launch Windows Opportunities to launch DIRECTLY into orbital plane – – – 2 per day if latitude of launch site is less than orbit’s inclination 1 per day if latitude is equal to inclination None if latitude is greater than inclination
LAUNCH CONSIDERATIONS Azimuth Vs. Inclination Launching due east, or at an azimuth of 90 degrees will result in an orbital inclination equal to launch site latitude Any other azimuth results in a GREATER inclination Azimuth selected for initial velocity boost and to avoid populated areas Proper azimuth minimizes future plane change requirements
ORBITAL MANEUVERS Reasons Types Methods
ORBITAL MANEUVERS Reasons Maneuver to higher orbit – – Increase satellite Field-of-view (FOV) Counteract atmospheric effects Maneuver to lower orbit – – – Increase imaging resolution Satellite rendezvous De-orbit
ORBITAL MANEUVERS Types In-plane – – – Change in size/period Change in argument of perigee Change in true anomaly Out-of-Plane – – Change in inclination Change in RAAN
DE-ORBIT/DECAY De-Orbit is the controlled re-entry of a satellite to a specific location – Used for the recovery of payload Manned missions Decay is uncontrolled re-entry – – Potential impact anywhere along ground track Re-entry Assessment (by CMAS)
TYPES OF ORBITS Uses of Satellites Daily Uses of Satellites Big Picture Affects of Altitude
TYPES OF ORBITS Uses of Satellites Global Positioning System!!
TYPES OF ORBITS Uses of Satellites A Remote Sensing Satellite’s view of Earthquake Damage in Haiti
PLACING SATELLITES IN ORBIT OVERVIEW How Satellites are Launched Location Advantages of the Two Primary US Launch Site
PLACING SATELLITES IN ORBIT You need LIFT !! W m (g) Weight mass (acceleration of gravity)
PLACING SATELLITES IN ORBIT Boosters DELTA IV
PLACING SATELLITES IN ORBIT Boosters ATLAS V
PLACING SATELLITES IN ORBIT Boosters PEGASUS
PLACING SATELLITES IN ORBIT Boosters TAURUS
PLACING SATELLITES IN ORBIT Boosters The SHUTTLE BOOSTER
PLACING SATELLITES IN ORBIT Launch Locations – Cape Canaveral (Patrick AFB) Eastern Range) – Vandenberg AFB (Western Range)
PLACING SATELLITES IN ORBIT Launch Constraints
SATELLITE OPERATIONS ELEMENTS Ground Segment Space Segment Data Link Segment
SATELLITE OPERATIONS FUNCTIONS GPS Example
SATELLITE OPERATION ACCESS Field of View (FOV) Location of Ground station/Observer Satellite Orbital Position
ORBITAL MECHANICS Classroom Presentations using Powerpoint Demonstrate with STK Let’s Demo !! The world of Space Operations awaits you!!