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MAXIMUM LIKELIHOOD JOINT ASSOCIATION, TRACKING, AND FUSION IN STRONG CLUTTER

MAXIMUM LIKELIHOOD JOINT ASSOCIATION, TRACKING, AND FUSION IN STRONG CLUTTER. Seminar Department of Electrical and Computer Engineering, University of Connecticut Storr, 6 Mar., 2009. Leonid Perlovsky Harvard University and the AF Research Lab. OUTLINE. Related research

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MAXIMUM LIKELIHOOD JOINT ASSOCIATION, TRACKING, AND FUSION IN STRONG CLUTTER

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  1. MAXIMUM LIKELIHOOD JOINT ASSOCIATION, TRACKING, AND FUSION IN STRONG CLUTTER Seminar Department of Electrical and Computer Engineering, University of Connecticut Storr, 6 Mar., 2009 Leonid Perlovsky Harvard University and the AF Research Lab

  2. OUTLINE • Related research • Combinatorial complexity and logic • Dynamic logic • Joint likelihood, math. formulation • Examples • Publications, recognition

  3. RELATED RESEARCH • > 50 publications by Perlovsky and co-authors on concurrent association, tracking, and fusion (+ > 200 other applications) • Perlovsky, L. I. (1991). Model Based Target Tracker with Fuzzy Logic. 25th Annual Asilomar Conference on Signals, Systems and Computers, Pacific Grove, CA. • Perlovsky, L.I., Schoendorf, W.H., Tye, D.M., Chang, W. (1995). Concurrent Classification and Tracking Using Maximum Likelihood Adaptive Neural System. Journal of Underwater Acoustics, 45(2), pp.399-414. • Many publications by Bar-Shalom, Streit, Luginbuhl, Willett, Avitzour, and co-authors • Similarity: algorithms related to EM • Differences: • Formulation of likelihood • Maximization procedures • Performance: linear complexity, Cramer-Rao Bound • Cramer-Rao Bound for joint association and tracking • Perlovsky, L.I. (1997). Cramer-Rao Bound for Tracking in Clutter and Tracking Multiple Objects. Pattern Recognition Letters, 18(3), pp.283-288.

  4. COMBINATORIAL COMPLEXITY 50 years of difficulties • Detect signal in noise and clutter at the farthest possible distance • SP, detection, exploitation, fusion, tracking, etc. in noise/clutter • Requires association (pixels<->objects) before detection • If 1 object, no noise: (1) detect pixels, (2) detect objects, (3) recognize targets • Joint detection-discrimination-classification… • Combinatorial Complexity (CC) • Need to evaluate large numbers of combinations (pixels<->objects) , operations: ~MN • A general problem (since the 1950s) • SP, detection, recognition, tracking, fusion, exploitation, situational awareness,… • Pattern recognition, neural networks, rule systems… • Combinations of 100 elements are 100100 • Larger than the number of particles in known Universe • Greater than all the elementary events in the Universe during its entire life • CC affects many SP algorithms • Our sensors under-utilize signals • Work much worse than Cramer-Rao Bound information-theoretic limit

  5. CC vs. LOGIC • CC is related to formal logic • Gödel proved that logic is “illogical,” “inconsistent” (1930s) • CC is Gödel's “incompleteness” in a finite system • Fuzzy logic • How to select degree of fuzziness? • The mind fits fuzziness for every process => CC • Logic pervades all algorithms and neural networks • Rule systems, fuzzy systems (degree of fuzziness), pattern recognition, neural networks (training uses logic) • Probabilistic association (Bar-Shalom) • Overcame logic in association • Where all logical steps overcome?

  6. DYNAMIC LOGICovercame logic limitations • CC is related to logic • CC is Gödel's “incompleteness” in a finite system • Logic pervaded all algorithms and neural networks in the past • rule systems, fuzzy systems (degree of fuzziness), pattern recognition, neural networks (training uses logical statements) • Dynamic Logic is a process-logic • “from vague to crisp” (statements, targets, decisions…) • Overcomes CC • Fast algorithms

  7. OUTLINE • Related research • Combinatorial complexity and logic • Dynamic logic • Joint likelihood, math. formulation • Examples • Publications, recognition

  8. JOINT LIKELIHOOD for tracks and clutter • Total likelihood • L = l ({x}) = l (x(n)) • no assumption of “independence” • Conditional likelihoods • l (x(n)) = r(m) l (x(n) | Mm(Sm,n)) • l (x(n) | Mm(Sm,n)) is a conditional likelihood for x(n) given m • {x(n)} are not independent, M(n) may depend on n’ • CC: L contains MN items: all associations of pixels and models (LOGIC)

  9. EXAMPLES OF MODELS • Linear track model • Mm(Sm,n) = Xm + Vm*t; Sm = (Xm, Vm, rm,Cm-1) • Gaussian conditional likelihoods • l (x(n) | Mm(Sm,n)) = (2p) -d/2 (detC)-1/2 exp{ -0.5 [ x(n) - Mm(Sm,n) ]T Cm-1[ x(n) - Mm(Sm,n) ] } • No “Gaussian” assumption • errors are Gaussian • mixture of any pdfs can be used • Uniform clutter model • rm, l (x(n) | Mm(Sm,n)) = 1/ volume(x)

  10. DYNAMIC LOGIC (DL) non-combinatorial solution • Start with a set of signals and unknown models • any parameter values Sm • associate models with signals (vague) • (1) f(m|n) = r(m) l (n|m) /r(m') l (n|m') • Improve parameter estimation • (2) Sm = Sm + a f(m|n) [ln l (n|m)/Mm]*[Mm/Sm] • Continue iterations (1)-(2). Theorem: DL is a convergingsystem - likelihood increases on each iteration

  11. OUTLINE • Related research • Combinatorial complexity and logic • Dynamic logic • Joint likelihood, math. formulation • Examples • Publications, recognition

  12. TRACKING AND DETECTION BELOW CLUTTER DL starts with uncertain knowledge and converges rapidly on exact solution y Performance achieves joint CRB for association and estimation

  13. TRACKING AND DETECTION BELOW CLUTTER 1 km (a) True Tracks (b) Range 0 Cross-Range 0 1 km detections c d 1 km Range 0 e f g h Multiple Hypothesis Testing“logical” complexity ~ 101800; DL complexity ~ 106; S/C ~ 18 dB improvement

  14. NUMBER OF TARGETS • Active models and one dormant model • Only r(m) is estimated for the dormant model • The dormant model is activated if r(m) > threshold • An active model is deactivated if r(m) < threshold • In this example threshold = 0.001 of the total signal • threshold = 0.001 x(n)

  15. LOCAL MAXIMA • Practically it is not a problem • Reasons • Vague initial states smooth local maxima • Activation and deactivation eliminates local convergences • In system applications, new data are coming all the time • local maxima come and go, real tracks persist

  16. JOINT FUSION, ASSOCIATION, TRACKING, AND NAVIGATION • 3 platforms-sensors • Targets cannot be detected or tracked with one sensor • All data are processed simultaneously • GPS is inadequate for triangulation - Relative platform positions have to be estimated jointly with target tracks • Multiple Hypothesis Testing “logical” complexity ~ 1017000

  17. Sensor 1 (of 3): Model Evolves to Locate Target Tracks in Image Data truth data Initial uncertain model Improved model after few iterations Few more iterations Models converged to the truth UNCLASSIFIED

  18. Sensor 2 (of 3): Model Evolves to Locate Target Tracks in Image Data UNCLASSIFIED

  19. Sensor 3 (of 3): Model Evolves to Locate Target Tracks in Image Data UNCLASSIFIED

  20. NAVIGATION, FUSION, TRACKING, AND DETECTIONthis is the basis for the previous 3 figures, all fused in x,y,z, coordinates

  21. OUTLINE • Related research • Combinatorial complexity and logic • Dynamic logic • Joint likelihood, math. formulation • Examples • Publications, recognition

  22. PUBLICATIONS • 300 publications OXFORD UNIVERSITY PRESS (2001; 3rd printing) Neurodynamics of High Cognitive Functions with Prof. Kozma, Springer, 2007 Sapient Systems with Prof. Mayorga, Springer, 2007

  23. RECOGNITION • 2007 Gabor Award - The top engineering award from International Neural Network Society (INNS) • Elected to the Board of Governors of INNS • 2007 John L. McLucas Award - The top scientific award from the US Air Force

  24. CONCLUSION • Dynamic Logic – an approachto improve algorithms and developing new ones • Being developed since late 1980s • Proven breakthrough in several areas • More can be done 24 16-Sep-05

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