1. Satellite Conjunction Analysis
Dr. Salvatore Alfano

2. Overview Introduction Review of assumptions Maximum probabilityQ
Introduction
Review of assumptions
Maximum probability
SOCRATES demo
Collision Avoidance Maneuver Planning
Upcoming Improvements

3. Introduction Q
Many operators are aware of the possibility of a collision between their satellite and another object
December 1991
COSMOS 1934 & COSMOS 926 debris
980 km mean altitude, 83° inclination
July 1996
CERISE & ARIANE 1 (third stage)
700 km polar orbit
January 2005
CZ-4 launch vehicle (third stage) & DMSP Rocket Body
885 km altitude above south polar region

4. Debris producing eventsQ
Deliberate debris generation
Chinese ASAT Test (Jan 2007)
Generated 2,300+ cataloged pieces
USA 193 intercept (Feb 2008)
Generated 130+ reported pieces
Within 5KM of SPOT 5, QUICKBIRD 2, IRIDIUM 46, IRIDIUM 86, OFEQ 7, LANDSAT 5, SAR-LUPE 3, & ISS
Other 2007 events
SL-12 Rocket Body Explosion (Feb)
BREEZE-M Rocket Body Explosion (Feb)
More info at

5. Review of linear assumptionsQ
All calculation data taken at TCA
Rel velocity ^ to rel distance
Combined positional uncertainties
Constant covariance – rapid encounter
Zero-mean Gaussian
Physical objects modeled
as spheres
Attitude info not required
(or known?)
Linear relative motion
Straight collision tube (permits simple projection & reduction)

6. Reorient Q
Rotate so that relative velocity is into screen

7. Uncertainty ellipses Mean Miss Distance VectorQ B A
Mean Miss
Distance Vector
Apply individual uncertainties
Relative velocity vector is now into page

8. Combine uncertaintiesQ
Combine
uncertainties
& center at B B A
In effect, I have
transferred all the
uncertainty to Object B
Choice is arbitray
I could have just as easily
done this by centering on A

9. Define collision region sizeQ
By definition
B could be
anywhere B B B B A B B B
Map out all possibilities
of B touching A
This defines locus
of contact (footprint)

10. Now ready to compute probabilityQ
Combined
covariance
ellipse B A
Combined object
footprint
Mean Miss
Distance Vector

11. Gaussian probability densityQ
Overlay
probability
density
contours + +
Integrate over combined object’s
footprint to get probability of collision

12. Review Find the minimum miss distance vectorQ
Review
Find the minimum miss distance vector
This is the point of closest approach
Rotate so that relative velocity is into screen
Combine the individual uncertainty (ellipses) and center them at B
This defines the probability density
Combine the object sizes and center them at A
Use the miss distance, size, and density from two ellipses to compute probability

13. Putting it all togetherQ
Relative motion creates path (collision tube) through combined uncertainty ellipsoid
Rotate ellipsoid & Project to reduce to 2D
Define footprint
Integrate over tube’s footprint
using projected probability density

14. Doing the right thing improperly
Desired outcome
Grill some burgers at pool party
Chosen Approach
Could lead to unintended consequence

15. Doing the right thing improperly
Desired outcome
Conjunction Probability
Chosen Approach
May not give decision maker sufficient information

16. Maximum Probability & DilutionQ
Mathematically both
are correct, but with
different association
STK
AdvCAT
also
computes
these
Low Risk
Poor Data
Quality

17. Another benefit of max probabilityQ
For TLEs covariance not given
Choose this one

18. SOCRATES Q
Satellite Orbital Conjunction Reports Assessing Threatening Encounters in Space
Center for Space Standards & Innovation (CSSI) offers SOCRATES conjunction advisory service starting May 2004
Each day, CSSI runs all payloads (active and inactive) against all objects on orbit (as of 2008 April 10)
2,864 payloads vs. 11,406 objects ( Conjunctions within 5KM)
Provides daily, searchable reports via CelesTrak
Reports are freely provided
No registration -- no solicitation
Associated orbital data freely available

19. SOCRATES DemonstrationQ
Easy to find from CelesTrak home page
Click on link for SOCRATES
Provides basic information along with:
Top 10 Conjunctions by Maximum Probability
Top 10 Conjunctions by Minimum Range
Search Capability
No subscription or sign-up required
No solicitation of user information

20. CELESTRAK Homepage DemoQ
Click Here

21. Demonstration -Introduction -Methodology -Tech papers -EnhancementsQ
-Introduction
-Methodology
-Tech papers
-Enhancements
-Resources
-Service Provider

22. Demonstration ANALYZE IRIDIUM VS. COSMOS (APR 20 REPORT) ACCURACYQ
IRIDIUM VS. COSMOS (APR 20 REPORT)
ASSUMES
SAME SIGMA
FOR ALL AXES
ACCURACY
(SIGMA)
REQUIRED
5 KM
ANALYZE

23. Analysis Button DemonstrationQ
TLEs provided
Cut & paste
as you wish
STK
Button
Sequence
Can obtain
STK/CAT
trial license

24. Automated STK/CAT Scenario BuilderQ
SOCRATES Button Sequence
Launch STK
Build Scenario
Pick viewing time(s)
Enter, TCA, Exit

25. STK/CAT Alteration (if desired)Q
Replace TLEs with better Pos/Vel Data
Change Covariance
Change Physical Object Size

26. SOCRATES-GEO Extend SOCRATES system on CelesTrak
Limit to GEO conjunctions (for now)
Replace TLEs, where possible
Owner/operator ephemeris (including maneuvers)
Public owner/operator data
11-parameter data
Keplerian/Cartesian state vectors
Enhanced TLEs for non-cooperative objects (debris)

27. SOCRATES-GEO Implementation
New SOCRATES-GEO system on CelesTrak
Looks for all objects which pass within 250 km of GEO
Uses improved data sources, when available
Generates standard reports, including orbital data
Allows user-defined notification criteria
Automatically sends notification
Web access via secure system
Privacy protected – CSSI acts as trusted data broker

28. SOCRATES-GEO Process Flow
Data sources
Owner ephemeris
Public orbital data
TLE data
Convert to standard format
Generate ephemerides
Produce enhanced TLEs
Select GEO data
Data preparation
Run SOCRATES-GEO
Generate/Upload reports
Send notifications

29. Test Case: Intelsat Owner ephemerides Public orbital data
IS-6B
IS-3R
IS-11
43.25° W
43.00° W
42.75° W km
Owner ephemerides
Public orbital data
Supplemental TLEs
AFSPC TLEs
Test Case: Intelsat

30. SOCRATES-GEO Collaborative effort addresses current limitations
Improves orbital accuracy through cooperation
Reduces search volumes
Reduces false-alarm rate
Provides more than public catalog
Already operating – subscription required
Need orbital data in your format
Need definition of data format, coordinate & time systems

31. Collision Avoidance Maneuver Planning
Run initial warning tool (SOCRATES)
Build STK/AdvCAT Scenario
Perform Parametric D-V Analysis
One-on-one with simplified orbital dynamics
We use a MATLAB program that interfaces with STK
Test proposed D-V – Feed into STK Scenario for
One-on-all conjunction analysis
Mission impact
Recovery to nominal orbit

32. MATLAB & STK Connect Single-Axis Parametric Analysis
Auto read
from STK or XLS
(user can modify)
Topography
created
Velocity
Normal
Co-Normal
User input
Press button

33. MATLAB with STK CONNECT Double-Axes Parametric Analysis
Choose
maneuver
time (-2500s)
Topography
created
V - N
N - C
C - V
User input
Press button

34. Test candidate maneuver
Feed maneuver back into STK scenario
Determine
Mission Impact
Temporarily degraded capability?
Maneuver to return to nominal orbit?
How long to task sensors and recover ephemeris?
Fuel usage
Shortened lifespan?
Recovery to nominal orbit?
Reschedule routine station-keeping (saves fuel)
Future conjunctions
Did I increase the possibility of a future conjunction with a different satellite?

35. Addressing nonlinear motionQ
Treat each small
segment as linear
Must reintroduce
3rd dimension along
each length of tube

36. Upcoming ImprovementsQ
Test for linearity
Assessing nonlinear motion
Adjoining right cylinders
Gap elimination
Handling non-spherical shapes

37. Eliminating gaps & overlapsQ
Re-introduce long axis into linear method
Use ERF method (pixelation) for 3D gaps/overlap
Piece-wise integration of bundled, rectangular
parallelepipeds (elongated voxels)

38. All data rotated to align new z axis with axis12r
Eliminating gaps & overlaps Q
All data rotated to align new z axis with axis12r
axis12r = [0 0 1]
axis13r
axis12r & axis23r are unit vectors
axis13r = axis12r + axis23r
Compound miter ┴ to axis13r

39. Eliminating gaps & overlapsQ
Object cross section (axis into screen)
Compute 2D probability of each pixel
Compute 1D probability of each parallelepiped’s Mahalanobis length based on dz

40. Bundles easily address complex shapesQ
Just light up different pixels
Concave, Spiral
Hollow, Convex
In theory, satellite could fly thru

41. Where can I get shapes? From image files Iridium silhouetteQ
From image files
Iridium silhouette
from STK Area Tool
Oriented along
relative velocity
vector

42. Combined object footprintQ
Raster sweep for combined object footprint
No need to alter integrand
Only compute red pixels
Footprint can be dynamic (tumbling)

43. Raster sweep example Q

44. MATLAB image merging toolQ

45. Chan’s approach to complex objectsQ
Model components as spheres, cylinders, cones +
circular, rectangular, & triangular plates . . .
Approximate individual probabilities
Sum all the pieces
Account for sun angle for proper solar panel orientation
relative velocity orientation, offsets, eclipsing/exclusions
Determine approximate equivalent cross sectional areas

46. Our approach – just let STK do itQ
Inherently accounts for proper solar panel orientation
relative velocity orientation, offsets, eclipsing/exclusions

47. Elimination of linear assumptionsQ
Physical Objects Modeled as Spheres
Attitude information not required (not known?)
Linear Relative Motion
Straight collision tube (permits simple projection & reduction)
Positional Uncertainties
Zero-mean Gaussian
Uncorrelated (permits simple summing for combination)
Constant (over encounter time)
All Calculation Data Taken at Time of Closest Approach
Precise shape &
orientation with time
Adjoining Right Cylinders
Bundled
Parallelepipeds
Cov Propagation required
Gaps (faster) or no gaps (slower) in abutting cylinders
New linearity tests (coarse & fine)

48. Uses many different STK featuresQ
AdvCAT
Determine TCA
Test for linearity
Compute appropriate probability
HPOP or ODTK for 6x6 covariance propagation
Vector Geometry Tool for proper viewing alignment
Area Tool for image extraction

49. Wrap up Assumptions Maximum probability & dilution SOCRATES demoQ
Assumptions
Maximum probability & dilution
SOCRATES demo
Collision Avoidance Maneuver Planning
Upcoming Improvements

50. Q
Need help? Just call
I would love to change the world, but they won't give me the source code - Unknown