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Muon Tomography Algorithms for Nuclear Threat Detection

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Presentation on theme: "Muon Tomography Algorithms for Nuclear Threat Detection"— Presentation transcript:

1 Muon Tomography Algorithms for Nuclear Threat Detection
R. Hoch, D. Mitra, M. Hohlmann, K. Gnanvo

2 Tomography Imaging by sections Used in many applications
Image different sides of a volume Use reconstruction algorithms to combine 2D images into 3D Used in many applications Medical Biological Oceanography Cargo Inspections?

3 Muons Cosmic Ray Muons More massive cousin of electron
Produced by cosmic ray decay Sea level rate 1 per cm^2/min Highly penetrating, but affected by Coulomb force

4 Muon Tomography Previous work imaged large structures using radiography Not enough muon loss to image smaller containers Use multiple coulomb scattering as main criteria

5 Muon Tomography Concept

6 Reconstruction Algorithms
Point of Closest Approach (POCA) Geometry based Estimate where muon scattered Expectation Maximization (EM) Developed at Los Alamos National Laboratory More physics based Uses more information than POCA Estimate what type of material is in a given sub-volume

7 Simulations Geant4 - simulates the passage of particles through matter
CRY – generates cosmic ray shower distributions

8 POCA Concept Incoming ray 3D POCA Emerging ray

9 40cmx40cmx20cm Blocks (Al, Fe, Pb, W, U)
POCA Result 40cmx40cmx20cm Blocks (Al, Fe, Pb, W, U) Unit: mm Θ (degrees) U W Z Pb Fe Al X Y

10 POCA Discussion Pro’s Con’s Fast and efficient
Can be updated continuously Accurate for simple scenario’s Con’s Doesn’t use all available information Unscattered tracks are useless Performance decreases for complex scenarios

11 Expectation Maximization
Explained in 1977 paper by Dempster, Laird and Rubin Finds maximum likelihood estimates of parameters in probabilistic models using “hidden” data Iteratively alternates between an Expectation (E) and Maximization (M) steps E-Step computes an expectation of the log likelihood with respect to the current estimate of the distribution for the “hidden” data M-Step computes the parameters which maximize the expected log likelihood found on the E step

12 Basic Physics Scattering Angle Scattering function
Distribution ~ Gaussian Non-deterministic (Rossi)

13 EM Concept L T Voxels following POCA track

14 Algorithm gather data: (ΔΘx, Δθy, Δx, Δy, pr^2)
estimate LT for all muon-tracks initialize λ (small non-zero number) for each iteration k=1 to I for each muon-track i=1 to M Compute Cij - E-Step for each voxel j=1 to N M-Step return λ

15 Scenario 1 Geometry 5 40cmx40xcmx20cm Boxes

16 10 minutes exposure 10cmx10cmx10cm voxels
Scenario 1 Results 10 minutes exposure 10cmx10cmx10cm voxels Axis in mm Λ (mrad^2/cm) Z X Y

17 Scenario 1 Results Accuracy Test 48000 total voxels, 32 Uranium
Threshhold: 1000 True Positives: 25 False Negatives: 7 True Positive Rate: 78.1% False Positives: 119 False Positive Rate: %

18 Simulated Truck Red Boxes are Uranium Blue are Lower Z Materials
Scenario 2 Geometry Simulated Truck Red Boxes are Uranium Blue are Lower Z Materials

19 10 minutes exposure 5cmx5cmx5cm voxels
Scenario 2 Results 10 minutes exposure 5cmx5cmx5cm voxels Axis in mm Λ (mrad^2/cm) Z X Y

20 Scenario 2 Results Accuracy Test 9704448 total voxels, 106 Uranium
Threshhold: 1000 True Positives: 90 False Negatives: 16 True Positive Rate: 85% False Positives: 62 False Positive Rate: %

21 Median Method Rare large scattering events cause the average correction value to be too big Instead, use median as opposed to average Significant computational and storage issues Use binning to get an approximate median

22 Aproximate Median Cij = -357,000 Cij = -45,000 Cij = 25,000
Bin Size = 100,000 5 10 20 18 9 11 15 21 23 7 -400,000- -300,000 -200,000 -100,000 100,000 200,000 300,000 400,000+ 5 15 35 53 62 73 88 109 132 139 Total Tracks = 139 Median Track at 70 Track 70 in Bin 6 Take Average of Bin 6 (Total Value of Cij's / 11)

23 Scenario 1 Results 10 minutes exposure 5cmx5cmx5cm voxels Axis in mm
Λ (mrad^2/cm) Z X Y

24 Scenario 1 Results Accuracy Test 48000 total voxels, 32 Uranium
Threshhold: 500 True Positives: 26 False Negatives: 6 True Positive Rate: 81.1% False Positives: 31 False Positive Rate: %

25 Scenario 2 Results 10 minutes exposure 5cmx5cmx5cm voxels Axis in mm
Λ (mrad^2/cm) Z X Y

26 Scenario 2 Results Accuracy Test 9704448 total voxels, 106 Uranium
Threshhold: 500 True Positives: 97 False Negatives: 9 True Positive Rate: 91.5% False Positives: 5 False Positive Rate: %

27 Future Work Improvement of absolute lambda values Real-time EM
Analysis of complex scenarios

28 Thanks!

29 Timing Scenario 1: Average Method: 316s
Approximate Median Method: 1533s Median Method: ~12hrs Scenario 2: Average Method: 1573s Approximate Median Method: 7953s Median Method: +30hrs

30 Why Muon Tomography? Other ways to detect: Muon Tomography advantages:
Gamma ray detectors (passive and active) X-Rays Manual search Muon Tomography advantages: Natural source of radiation Less expensive and less dangerous Decreased chance of human error More probing i.e. tougher to shield against Can detect non-radioactive materials Potentially quicker searches


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