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Aerial Video Surveillance and Exploitation

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Title: Aerial Video Surveillance and Exploitation


1
Aerial Video Surveillance and Exploitation
  • Roland Miezianko
  • CIS 750 - Video Processing and Mining
  • Prof. Latecki

2
Agenda
  • Aerial Surveillance Comparisons
  • Technical Challenges and the Mission
  • Framework Ideas for Video Surveillance
  • Alignment and Change Detection
  • Mosaicing
  • Tracking Moving Objects
  • Geo-location
  • Enhanced Visualization
  • Image Mosaics

3
Types of Aerial Surveillance
  • Using film and framing cameras
  • Hi-resolution still images
  • Examined by human or machine
  • Video captures dynamic events
  • Used to detect and geo-locate moving objects in
    real-time
  • Follow detected motion
  • Constantly monitor a site

4
Technical Challenges, 1
  • Video cameras have lower resolution than framing
    cameras
  • Video uses telephoto lens to get high resolution
    to identify objects
  • Telephoto lens - Narrow field of view
  • Provides soda straw view of the scene 2

5
Technical Challenges, 2
  • Camera must scan the region of interest to get
    the full-picture
  • Objects of interest move in and out of the field
    of view
  • Difficulty in perceiving object relative locations

6
Technical Challenges, 3
  • Challenge in manually tracking an object due to
    cameras small field of view
  • Video contains much more data then film frames
    Storage is expensive

7
The Mission
  • The new aerial surveillance systems must provide
    a framework for spatio-temporal aerial video
    analysis

8
Video AnalysisFramework, 1
  • Frame-to-Frame alignment and decomposition of
    video frames into motion layers
  • Mosaicing static background layers to form
    panoramas as compact representations of the
    static scene

9
Video AnalysisFramework, 2
  • Detecting and tracking independently moving
    objects in the presents of background clutter
  • Geo-locating the video and tracked objects by
    registering it to controlled reference imagery
    digital terrain maps and models

10
Video AnalysisFramework, 3
  • Enhanced visualization of the video by
    re-projecting and merging it with reference
    imagery, terrain, and maps to provide a larger
    context

11
Alignment and Change Detection, 1
  • Displacement of pixels between video frames may
    occur due to the following
  • Motion of the video sensor
  • Independent motion of objects in the field of
    view
  • Motion of the source of illumination

12
Alignment and Change Detection, 2
  • Global motion estimation
  • Displacement of pixels due to the motion of the
    sensor is computed
  • Alignment of Video Frames
  • Pyramid-Processing
  • Lock into the motion of background scene
  • Warp images into common coordinate frame

13
Alignment and Change Detection, 3
  • Moving objects are detected by aligning video
    frames and detecting pixels with poor correlation
    across the temporal domain

14
MosAICING, 1
  • Images are accumulated into the mosaic as the
    camera pans
  • Construction of a 2D mosaic requires computation
    of alignment parameters that relate all of the
    images in the collection to a common world
    coordinate system

15
MosAICING, 2
  • Transformation parameters are used to warp the
    images into the mosaic coordinate system
  • Warped images are then combined to form a mosaic
  • To avoid seams, warped frames are merged in the
    Laplacian pyramid domain

16
MosAICING, example
17
MosAICING, example
18
Tracking Moving Objects, 1
  • Scene analysis includes operations that interpret
    the source video in terms of objects and
    activities in the scene
  • Moving objects are detected and tracked over the
    cluttered scene

19
Tracking Moving Objects, 2
  • State of each moving object is represented by
    its
  • Motion
  • Appearance
  • Shape
  • The state is updated at each instant of time
    using Expectation-Maximization (EM) algorithm

20
Tracking Moving Objects, example
21
Geo-location
  • Video Surveillance system must also determine the
    geodetic coordinates of objects within the
    cameras field of view
  • More precise geo-locations can be estimated by
    aligning video frames to calibrated reference
    images

22
Enhanced Visualization
  • Challenging aspect of aerial video surveillance
    is formatting video imagery for effective
    presentation to an operator
  • The soda straw view makes direct observation
    tedious and disorienting

23
Mosaic-Based Display
  • Display de-couples the observers display from
    the camera
  • Operator may scroll or zoom to examine one region
    of the mosaic even as the camera is updating
    another region of the mosaic

24
Elements of Mosaic Display
camera
Pyramid merge
warp
merge
ED
Estimate displacement
Update window
Operators display
Image accumulating memory
25
Camera Input
26
Mosaic Generation, 1
27
Mosaic Generation, 2
28
Psuedo codes of main algorithm 5
read(base_image) read(unregistered_image)
base_imageexpand(base_image) confirm three
pairs of matched points between base_image and
unregistered_imagecalculate initial matrix
MApply Levenberg-Marquardt minimization to
update MM inverse(M)Resample and apply
blending function to render the mosaics
29
Homogeneous Coordinates
Using homogeneous coordinates, we can describe
the class of 2D planar projective transformations
using matrix multiplication 4
30
Rigid Transformation
The same hierarchy of transformations exists in
3D. Rigid (Euclidean) transformation where R is a
3 3 orthonormal rotation matrix and t is a 3D
translation vector.
31
Viewing Matrix
The 34 viewing matrix
projects 3D points through the origin onto a 2D
projection plane a distance f along the z axis.
32
Combined Equations
The combined equations projecting a 3D world
coordinate p (x, y, z, w) onto a 2D screen
location u (x', y', w') can thus be written as
where P is a 3 4 camera matrix. This equation
is valid even if the camera calibration
parameters and/or the camera orientation are
unknown.
33
Local Image Registration, 1
  • How do we compute the transformations relating
    the various scene pieces so that we can paste
    them together?
  • We could manually identify four or more
    corresponding points between the two views
  • Manual approaches are too tedious to be useful

34
Local Image Registration, 2
  • This has the advantages of not requiring any
    easily identifiable feature points and of being
    statistically optimal, that is, giving the
    maximum likelihood estimate once we are in the
    vicinity of the true solution.

Rewrite our 2D transformations
35
Minimizes Intensity Errors
Technique minimizes the sum of the squared
intensity errors. Over all corresponding pairs of
pixels i inside both images I(x, y) and I(x,
y). Pixels that are mapped outside image
boundaries do not contribute.
36
Minimization
To perform the minimization, we use the
Levenberg-Marquardt iterative nonlinear
minimization algorithm. This algorithm requires
computation of the partial derivatives of ei with
respect to the unknown motion parameters m 0 ...
m 7 .
37
Complete Registration Algorithm Step 1 4
38
Complete Registration Algorithm Steps 2-4
39
Bryce Canyon Mosaic
40
Wall Frame, example
41
Conclusion
  • The techniques presented here automatically
    register video frames into 2D and partial 3D
    scene models.
  • Video mosaics and related techniques will enable
    an even more exciting range of interactive
    computer graphics, telepresence, and virtual
    reality applications.

42
References
1 Automatic Panoramic Image Construction
Yap-Peng Tan, Sanjeev R. Kulkarni and Peter J.
Ramadge Princeton University, Department of
Electrical Engineering
2 Chapter 2 by Rakesh Kumar Aerial Video
Survelliance and Exploitation
3 A Multiresolution Spline With Application to
Image Mosaics PETER J. BURT and EDWARD H.
ADELSON RCA David Sarnoff Research Center
43
References
4 Richard Szeliski. Video mosaics for virtual
environments. IEEE Computer Graphics and
Applications, 16(2)22--30, March 1996
5 Jingbin Wang, Boston University
CS580Advanced Graphics Project 1 Image Mosaics
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