Camera calibration - PowerPoint PPT Presentation

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Camera calibration

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Linear least square fitting. y. t. is linear, too. residual. prediction. Nonlinear least square fitting. Function minimization. It is very hard to solve in general. ... – PowerPoint PPT presentation

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Title: Camera calibration


1
Camera calibration
  • Digital Visual Effects, Spring 2006
  • Yung-Yu Chuang
  • 2005/4/19

with slides by Richard Szeliski, Steve Seitz, and
Marc Pollefyes
2
Announcements
  • Artifacts for assignment 1 voting
  • http//www.csie.ntu.edu.tw/cyy/vfx/assignments/p
    roj1/artifacts/index.html

3
Outline
  • Camera projection models
  • Camera calibration
  • Nonlinear least square methods
  • Bundle adjustment

4
Camera projection models
5
Pinhole camera
6
Pinhole camera model
origin
principal point
(optical center)
7
Pinhole camera model
8
Pinhole camera model
9
Principal point offset
intrinsic matrix
10
Intrinsic matrix
Is this form of K good enough?
  • non-square pixels (digital video)
  • skew
  • radial distortion

11
Radial distortion
12
Camera rotation and translation
extrinsic matrix
13
Two kinds of parameters
  • internal or intrinsic parameters such as focal
    length, optical center, aspect ratiowhat kind
    of camera?
  • external or extrinsic (pose) parameters including
    rotation and translationwhere is the camera?

14
Other projection models
15
Orthographic projection
  • Special case of perspective projection
  • Distance from the COP to the PP is infinite
  • Also called parallel projection (x, y, z) ?
    (x, y)

Image
World
16
Other types of projections
  • Scaled orthographic
  • Also called weak perspective
  • Affine projection
  • Also called paraperspective

17
Fun with perspective
18
Perspective cues
19
Perspective cues
20
Fun with perspective
Ames room
21
Forced perspective in LOTR
22
Camera calibration
23
Camera calibration
  • Estimate both intrinsic and extrinsic parameters
  • Mainly, two categories
  • Photometric calibration uses reference objects
    with known geometry
  • Self calibration only assumes static scene, e.g.
    structure from motion

24
Camera calibration approaches
  • linear regression (least squares)
  • nonlinear optinization
  • multiple planar patterns

25
Chromaglyphs (HP research)
26
Linear regression
27
Linear regression
  • Directly estimate 11 unknowns in the M matrix
    using known 3D points (Xi,Yi,Zi) and measured
    feature positions (ui,vi)

28
Linear regression
29
Linear regression
30
Linear regression
Solve for Projection Matrix M using least-square
techniques
31
Normal equation
  • Given an overdetermined system

the normal equation is that which minimizes the
sum of the square differences between left and
right sides
Why?
32
Normal equation
nxm, n equations, m variables
33
Normal equation
34
Normal equation
35
Linear regression
  • Advantages
  • All specifics of the camera summarized in one
    matrix
  • Can predict where any world point will map to in
    the image
  • Disadvantages
  • Doesnt tell us about particular parameters
  • Mixes up internal and external parameters
  • pose specific move the camera and everything
    breaks

36
Nonlinear optimization
  • Feature measurement equations
  • Likelihood of M given (ui,vi)

37
Optimal estimation
  • Log likelihood of M given (ui,vi)
  • How do we minimize C?
  • Non-linear regression (least squares), because ûi
    and vi are non-linear functions of M
  • We can use Levenberg-Marquardt method to minimize
    it

38
Multi-plane calibration

Images courtesy Jean-Yves Bouguet, Intel Corp.
  • Advantage
  • Only requires a plane
  • Dont have to know positions/orientations
  • Good code available online!
  • Intels OpenCV library http//www.intel.com/rese
    arch/mrl/research/opencv/
  • Matlab version by Jean-Yves Bouget
    http//www.vision.caltech.edu/bouguetj/calib_doc/i
    ndex.html
  • Zhengyou Zhangs web site http//research.micros
    oft.com/zhang/Calib/

39
Step 1 data acquisition
40
Step 2 specify corner order
41
Step 3 corner extraction
42
Step 3 corner extraction
43
Step 4 minimize projection error
44
Step 4 camera calibration
45
Step 4 camera calibration
46
Step 5 refinement
47
Nonlinear least square methods
48
Least square fitting
number of data points
number of parameters
49
Linear least square fitting
y
t
prediction
residual
50
Nonlinear least square fitting
51
Function minimization
Least square is related to function minimization.
  • It is very hard to solve in general. Here, we
    only consider a simpler problem of finding local
    minimum.

52
Function minimization
53
Quadratic functions
Approximate the function with a quadratic
function within a small neighborhood
54
Quadratic functions
A is positive definite. All eigenvalues are
positive. Fall all x, xTAxgt0.
negative definite
A is singular
A is indefinite
55
Function minimization
56
Descent methods
57
Descent direction
58
Steepest descent method
the decrease of F(x) per unit along h direction
?
hsd is a descent direction because hTsd F(x)-
F(x)2lt0
  • It has good performance in the initial stage of
    the iterative process. Converge very slow with a
    linear rate.

59
Steepest descent method
isocontour
gradient
60
Line search
61
Line search
62
Steepest descent method
63
Newtons method
?
?
?
?
  • It has good performance in the final stage of the
    iterative process, where x is close to x.

64
Hybrid method
  • This needs to calculate second-order derivative
    which might not be available.

65
Levenberg-Marquardt method
  • LM can be thought of as a combination of steepest
    descent and the Newton method. When the current
    solution is far from the correct one, the
    algorithm behaves like a steepest descent method
    slow, but guaranteed to converge. When the
    current solution is close to the correct
    solution, it becomes a Newtons method.

66
Nonlinear least square
67
Levenberg-Marquardt method
68
Levenberg-Marquardt method
  • µ0 ? Newtons method
  • µ?8 ? steepest descent method
  • Strategy for choosing µ
  • Start with some small µ
  • If F is not reduced, keep trying larger µ until
    it does
  • If F is reduced, accept it and reduce µ for the
    next iteration

69
Bundle adjustment
70
Bundle adjustment
  • Bundle adjustment (BA) is a technique for
    simultaneously refining the 3D structure and
    camera parameters
  • It is capable of obtaining an optimal
    reconstruction under certain assumptions on image
    error models. For zero-mean Gaussian image
    errors, BA is the maximum likelihood estimator.

71
Bundle adjustment
  • n 3D points are seen in m views
  • xij is the projection of the i-th point on image
    j
  • aj is the parameters for the j-th camera
  • bi is the parameters for the i-th point
  • BA attempts to minimize the projection error

predicted projection
Euclidean distance
72
Bundle adjustment
73
Bundle adjustment
  • 3 views and 4 points

74
Typical Jacobian
75
Block structure of normal equation
76
Bundle adjustment
77
Bundle adjustment
  • Multiplied by

78
Reference
  • Manolis Lourakis and Antonis Argyros, The Design
    and Implementation of a Generic Sparse Bundle
    Adjustment Software Package Based on the
    Levenberg-Marquardt Algorithm, FORTH-ICS/TR-320
    2004.
  • K. Madsen, H.B. Nielsen, O. Timgleff, Methods for
    Non-Linear Least Squares Problems, 2004.
  • Zhengyou Zhang, A Flexible New Techniques for
    Camera Calibration, MSR-TR-98-71, 1998.
  • Bill Triggs, Philip McLauchlan, Richard Hartley
    and Andrew Fitzgibbon, Bundle Adjustment - A
    Modern Symthesis, Proceedings of the
    International Workshop on Vision Algorithms
    Theory and Practice, pp298-372, 1999.
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