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Laser based tracking of mutually occluding dynamic objects

University of Aveiro 2010 Department of Mechanical Engineering. Laser based tracking of mutually occluding dynamic objects. Jorge Almeida. 10 September 2010. Overview. Overview. Objectives Motivation Laser Algorithm Experiments Results Conclusions. Objectives. Objectives.

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Laser based tracking of mutually occluding dynamic objects

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  1. University of Aveiro 2010 Department of Mechanical Engineering Laser based tracking of mutually occluding dynamic objects Jorge Almeida 10 September 2010

  2. Overview Overview • Objectives • Motivation • Laser • Algorithm • Experiments • Results • Conclusions

  3. Objectives Objectives • Develop an algorithm capable of following multiple targets • Overcoming temporary occlusions • Obtain position and velocity of targets • Laser rangefinder

  4. Introduction Motivation • Obtain a dynamic perception of the vicinity • Indoors • Building security • Optimization of motion paths • Outdoors • Driver assistance systems • Advanced path planning

  5. Laser Laser • 2D Laser rangefinder • Hokuyo UTM-30LX • 30 m max range • 40Hz scan frequency • 0.25° angular resolution • 270° field of view • Direct measurement of distance to targets

  6. Laser –Scan Typical scan Laser

  7. Laser –Scan Typical scan Wall Laser Columns

  8. Laser –Scan Typical scan Laser Pedestrians

  9. Algorithm Tracking algorithm • Two main phases • Object reconstruction • Preprocessing • Segmentation • Data reduction • Object association • Motion prediction

  10. Object creation –Preprocessing Preprocessing • Remove noise • Moving average filter • Applied to the data in polar coordinates (r, θ) • The filter is limited in order not to compromise the responsiveness • Obtain the Cartesian coordinates (x, y)

  11. Object creation –Segmentation Segmentation • Clustering of measurements belonging to the same object • Several steps • Occluded points detection • Clustering of visible and occluded points • Euclidian distance betweenconsecutive points

  12. Object creation –Data reduction Data reduction • Simplify the data handling • Conversion from groups of points to lines • This representation is enough for all intended purposes • Iterative End-Point Fit (IEPF)

  13. Data association Data association • Search zones • Shaped as ellipses • New objects are added to thetracking list • Not associated objects are removed from the list • Association aided by • Motion prediction • Heuristic rules

  14. Data association Data association • Search zones • Shaped as ellipses • New objects are added to thetracking list • Not associated objects are removed from the list • Association aided by • Motion prediction • Heuristic rules

  15. Data association – Search zone Search zone • Centered at the object predicted position • Aligned with the velocityvector • Variable axes lengths • Object size • Occlusion time • Prediction errors

  16. Data association – Motion prediction Motion prediction • Adaptive linear Kalman filters • Two filters per object • Constant velocity motion models • Process noise covariance is coupled with the prediction error

  17. Data association – Heuristic rules Heuristic rules • Increase performance • Single associations • Exclusion zones • ezA • Prevents the tracking of objects’ fragments • ezB • Avoids wrong associations

  18. Experiments Experiments • Robustness to occlusion in real world scenario • Outdoors people pathway • Global performance test • Tracking of nearby moving objects • Person moving close to a wall • Security applications

  19. Results– Real world scenario Real world scenario • Long duration trial (~17 min) in a very crowded environment • Ground-truth obtained with a video camera • Performance evaluation • Percentage tracking time • Percentage of targets with tracking faults • Loss of a target • Id switch • Fake tracks creation

  20. Results– Real world scenario Real world scenario

  21. Results– Real world scenario Real world scenario • Two distinct target types, single target (A) and multiple target (B) • Good results • Type B targets present worst results • Long occlusions • Most common fault was target lost

  22. Results – Close proxumity objects Close proximity objects

  23. Conclusions Conclusions • An algorithm capable of tracking multiple targets using laser data was developed. • The algorithm was shown robust and effective even under extensive occlusion. • The Kalman filter was an effective tool in the prediction of objects motion.

  24. Demonstration

  25. University of Aveiro 2010 Department of Mechanical Engineering Laser based tracking of mutually occluding dynamic objects Jorge Almeida 10 September 2010

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