asen 5050 spaceflight dynamics mission orbits, constellation design
DESCRIPTION
Announcements STK Lab 3 due Friday 12/5 STK Lab 4 due 12/12 Planetary ephemerides should be changed to DE421 instead of “Default” Final Exam on 12/12, due 12/18 Take-home, open book open notes Final project and exam due 12/18 Lecture 35: OrbitsTRANSCRIPT
ASEN 5050 SPACEFLIGHT DYNAMICS Mission Orbits, Constellation
Design
Prof. Jeffrey S. Parker University of Colorado Boulder Lecture 35:
Orbits Announcements STK Lab 3 due Friday 12/5 STK Lab 4 due
12/12
Planetary ephemerides should be changed to DE421 instead of Default
Final Exam on 12/12, due 12/18 Take-home, open book open notes
Final project and exam due 12/18 Lecture 35: Orbits Schedule from
here out 12/3: Mission Orbits, Constellation Design
12/5:Spacecraft Navigation 12/8:Final Review, part 1 12/10:Final
Review, part 2 12/12:Deep Impact Lecture 35: Orbits Final Project
Due 12/18.If you turn it in by 12/12, Ill forgive 5 pts of
deductions. Worth 20% of your grade, equivalent to 6-7 homework
assignments. Final Exam is worth 25%. Find an interesting problem
and investigate it anything related to spaceflight mechanics (maybe
even loosely, but check with me). Requirements: Introduction,
Background, Description of investigation, Methods, Results,
Conclusions, References. You will be graded on quality of work,
scope of the investigation, and quality of the presentation.The
project will be built as a webpage, so take advantage of web design
as much as you can and/or are interested and/or will help the
presentation. Lecture 35: Orbits Final Project Instructions for
delivery of the final project:
Build your webpage with every required file inside of a directory.
Name the directory LastName_FirstName i.e., Parker_Jeff/ there are
a lot of duplicate last names in this class! You can link to
external sites as needed. Name your main web page index.html i.e.,
the one that you want everyone to look at first Make every link in
the website a relative link, relative to the directory structure
within your named directory. We will move this directory around,
and the links have to work! Test your webpage!Change the location
of the page on your computer and make sure it still works! Zip
everything up into a single file and upload that to the D2L
dropbox. Lecture 35: Orbits Space News Japans Hayabusa 2 launched
last night! Lecture 35: Orbits Space News Japans Hayabusa 2
launched last night! Lecture 35: Orbits Space News Orions
Exploration Flight Test 1:Thurs 12/4 at 7:04 am Eastern Time (5:04
am Mountain!).Duration: 4.5 hours. Lecture 35: Orbits ASEN 5050
SPACEFLIGHT DYNAMICS Mission Orbits
Prof. Jeffrey S. Parker University of Colorado Boulder Lecture 35:
Orbits Satellite Populations
Molniya 28.5 51.5 Lecture 35: Orbits Satellite Populations
Lecture 35: Orbits Satellite Populations
Molniya, GNSS Lecture 35: Orbits Satellite Populations
Gabbard classes GEO GNSS GTO ISS Lecture 35: Orbits Satellite
Populations
Lecture 35: Orbits Frozen Orbits Molniya orbits are designed to
have a critical inclination, such that the argument of perigee does
not change over time. Example plots for NROSS frozen orbit
characteristics: Lecture 35: Orbits Repeat Groundtracks Exact
Repeat Groundtracks
A satellites ground track returns to exactly the same
latitude/longitude that it began. Should occur within ~50 days for
this classification The satellite never flies over much of the
Earth. Near-exact Repeat Groundtracks A satellites ground track
returns to a point very near its starting point. The drift provides
a dense coverage of the Earth. Lecture 35: Orbits Repeat
Groundtracks Example exact repeat groundtracks
Lecture 35: Orbits Repeat Groundtracks The nodal crossings occur in
a pattern
Lecture 35: Orbits Some Period Definitions
Lecture 35: Orbits General Perturbation Techniques
The secular change of the orbital elements due to J2 is given from
the Lagrange Planetary Equations as: Lecture 35: Orbits Nodal
Period Lecture 35: Orbits Exact Repeat Constraint
Lecture 35: Orbits Altitude/Inclination vs NERP/K
Lecture 35: Orbits Groundtrack Drift Lecture 35: Orbits TOPEX
Crosstrack Drift
Lecture 35: Orbits Altimetry Missions Consider Topex/Poseidon,
Jason, Jason-2, and the like. They perform remote sensing
operations of the ocean surface, including measuring the sea
surface height, sea surface smoothness, temperature, etc. Driving
requirements: The orbit must be very well known and well
determined. A meter error in height may make the ocean height
estimation off by a meter very significant! The orbit should pass
over a large portion of the oceans surface. The orbit should pass
over the same points within a reasonably short time period. The
fly-over period should not alias any effects that significantly
contribute to the motion of water in the ocean, such as tides.
Lecture 35: Orbits Altimetry Missions Parke et al. (1987) developed
the following requirements for the orbit of Topex/Poseidon: The
satellites altitude must be known to within 14 cm The orbit should
be compatible with that sort of OD requirement.I.e., it would not
work to orbit too close to the atmosphere or in an unstable
resonance with the gravity field. Minimize the spatial and temporal
aliases on surface geotrophic currents, geoid variations, etc.
Subsatellite groundtrack should repeat within 1 km. Tidal aliases
will not be aliased into semiannual, annual, or zero frequencies or
to frequencies close to these. The global grid of subsatellite
points must extend as far south as the southern limit of the Drake
Passage (62 deg S) The ascending and descending tracks must cross
at sufficiently large angles to resolve the 2D geostrophic current.
Lecture 35: Orbits Altimetry Missions Station Keeping
Atmospheric drag is one of the largest effects that drives the
ground track away from its reference, and therefore must be
compensated for using maneuvers. For a circular orbit and
neglecting the Earths rotation: The loss of energy over time due to
drag: Lecture 35: Orbits Altimetry Missions The loss of energy over
time due to drag:
Varies with time Lecture 35: Orbits Altimetry Missions The change
in energy over time: Integrate:
Integrate over one orbit period: Lecture 35: Orbits Altimetry
Missions The change in energy over time: Integrate:
If drag were estimated with 50% accuracy, then the orbit error for
the satellite will be < 1 cm for a satellite above 1100 km.
Recommendation: remain above 1100 km and preferably above 1300 km.
Lecture 35: Orbits Altimetry Missions Effects of Solar Radiation
Pressure.
Since solar panels are virtually always pointing toward the Sun,
there is always a force acting on the satellite, and it changes the
circular orbits semimajor axis: Lecture 35: Orbits Altimetry
Missions Circular orbits: Minimum: between 1200 1300 km
Lecture 35: Orbits Altimetry Missions Altitude Desirable to be as
high as possible for OD
Desirable to be 1200 1300 km for station keeping Good for link
budgets too Desirable to be below 1500 km for radiation Van Allen
Belts! Lecture 35: Orbits Altimetry Missions Polar Crossing Angle:
psi Lecture 35: Orbits Altimetry Missions Desirable > 40 deg
Lecture 35: Orbits Altimetry Missions Less Desirable Desirable >
40 deg
Lecture 35: Orbits Altimetry Missions Orbit Period Considerations
Tidal Aliasing
Want to avoid this: Lecture 35: Orbits Altimetry Missions Tidal
Aliasing, the frequencies, periods, and amplitudes of the most
significant tidal constituents: Lecture 35: Orbits Primary Lunar
Tide Lecture 35: Orbits Vertical displacement
If the Earths surface was in equilibrium with the potential from
the moon, the vertical displacement of the surface would be in the
shape of an ellipsoid elongated toward the moon. Lecture 35: Orbits
The Principal Tide: M2 The largest component of the tides is
associated with the potential due to the moon and with the
frequency of the motion of the Earth-moon system around its center
of mass. The time from high moon to high moon: 1 lunar day (1 + 1
day/ 27.5 days) = 24 hours minutes High tide separation is half of
this: 12 hours 25 minutes However, this component, like all of the
semi-diurnal (and diurnal) tides is not in equilibrium with the
potential. A phase difference between high moon and high tide has
been known for centuries. The high tide generally lags behind the
high moon. Lecture 35: Orbits Tidal friction If there were no
dissipation in the Earth systems, tides would lie directly under MP
: However, friction creates a delay in the tidal response. The
Earths surface reacts to the tidal potential due to MP with a lag.
The tides peak 30 minutes later. Lecture 35: Orbits Altimetry
Missions Tidal Aliasing, the frequencies, periods, and amplitudes
of the most significant tidal constituents: Lecture 35: Orbits
Altimetry Missions Tidal Aliasing, the frequencies, periods, and
amplitudes of the most significant tidal constituents: Lecture 35:
Orbits Altimetry Missions In each cycle, the altimeter samples the
phase of each tide. A sun-synchronous altimeter sampling the S2
constituent would find a frozen tide with an infinite aliasing
period. ERS-1, ERS-2, Envisat, and NPOESS all did this. Otherwise,
the change in phase of the tide during one repeat period T is: The
primary alias period: Lecture 35: Orbits Altimetry Missions For
Topex/Poseidons day repeat period orbit, the primary alias periods
are: Lecture 35: Orbits Each of these is different by at least
several days
Altimetry Missions For Topex/Poseidons day repeat period orbit, the
primary alias periods are: Each of these is different by at least
several days Lecture 35: Orbits Altimetry Missions If tidal
aliasing does occur and/or the tidal frequencies or their aliasing
frequencies overlap, there are ways to resolve the alias. Use
along-track data Use cross-over points Lecture 35: Orbits Altimetry
Missions Spatial vs. Temporal Resolution Lecture 35: Orbits
Altimetry Missions Tide Gauges and Ground Track Placement
Lecture 35: Orbits Altimetry Missions Lecture 35: Orbits
Topex/Poseidons Options
1335 km, deg inclination 1252 km, deg inclination 1255 km, deg
inclination 1173 km, deg Option 1 first choice, Option 3 as backup
if a frozen orbit is desired. Topex/Poseidon was placed in an exact
repeat groundtrack orbit with 127 revolutions per 10-day cycle.
Lecture 35: Orbits ASEN 5050 SPACEFLIGHT DYNAMICS Constellation
Design
Prof. Jeffrey S. Parker University of Colorado Boulder Lecture 35:
Orbits Constellation Designs
GPS: 6 circular orbits, 12-sidereal hour period, 55 deg inclination
4+ satellites per orbit, evenly spaced over 360 deg Galileo, a
Walker Delta 56 deg:27/3/1 3 orbital planes, 56 deg inclination 9+
satellites per orbit, evenly spaced over 360 deg Iridium, a
near-polar Walker Star 6 orbital planes, 86.4 deg inclination 11
satellites per orbit, evenly spaced over 180 deg Lecture 35: Orbits
Constellation Designs
A-train (Afternoon Sun-Synch, coordinated) BGAN Compass Navigation
system Disaster Monitoring Constellation Globalstar GLONASS Orbcomm
RapidEye Sirius Satellite Radio TDRSS XM Satellite Radio And
others! Lecture 35: Orbits A-Train Coordinated constellation of
French, American, Japanese, Canadian satellites Sun-Synch 98.14 deg
inclination 1:30 pm solar time equatorial crossing GCOM-W1
(SHIZUKU), JAXA Aqua (4 min behind), USA CloudSat (2.5 min behind),
USA and CSA CALIPSO (15 sec behind), CNES, USA Aura (15 min behind
Aqua) PARASOL (now retired) OCO-2 Lecture 35: Orbits Compass /
BeiDou-1 Chinese navigation system Geostationary orbits
The area that can be serviced is from longitude 70E to 140E and
from latitude 5N to 55N. Lecture 35: Orbits BeiDou-2 Chinese
navigation system Supersedes BeiDou-1
35 satellites, completed by 2020 5 in geostationary orbit 27 in MEO
3 in inclined geosynch orbit Plans for up to 75 or more satellites,
covering urban canyons Lecture 35: Orbits GPS 6 circular orbits,
12-sidereal hour period, 55 deg inclination
4+ satellites per orbit, evenly spaced over 360 deg Lecture 35:
Orbits Disaster Monitoring Constellation
International, coordinated, Sun-Synch orbit 10:15 am local time
Northward equator crossing Lecture 35: Orbits Globalstar LEO ~50
satellites Inclination: 52 deg 1400 km altitude
Communication, short latency 5 ms 1-way light time. Lecture 35:
Orbits Iridium 66 active satellites
LEO: 781 km altitude, inclination 86.4 deg 11 satellites in each of
6 orbital planes Iridium NEXT: 2nd generation communication system
66 more satellites, launched 10 at a time on Falcon 9 launches
Lecture 35: Orbits Orbcomm 29 satellites LEO: 775 km altitude
Telecommunication system
Lecture 35: Orbits RapidEye German geospatial information
provider.
5 satellites in the same orbital plane. Altitude 630 km
Sun-synchronous, 11:00 am ascending time, 97.8 deg inclination
Lecture 35: Orbits Sirius 3 satellites Highly elliptical,
geosychronous orbits (Tundra orbits) Each satellite spends 16 hours
over the continental US per orbit. XM Satellites: 2 geostationary
satellites. Lecture 35: Orbits TDRSS Tracking and Data Relay
Satellite System
A dozen GEO satellites some equatorial and some just off of the
equator. Navigation and communication, largely of NASAs assets.
Lecture 35: Orbits Announcements STK Lab 3 due Friday 12/5 STK Lab
4 due 12/12
Any issues with v9 versus v10? STK Lab 4 due 12/12 Final Exam on
12/12, due 12/18 Take-home, open book open notes Final project and
exam due 12/18 Lecture 35: Orbits