Eight-point algorithm explained

The eight-point algorithm is an algorithm used in computer vision to estimate the essential matrix or the fundamental matrix related to a stereo camera pair from a set of corresponding image points. It was introduced by Christopher Longuet-Higgins in 1981 for the case of the essential matrix. In theory, this algorithm can be used also for the fundamental matrix, but in practice the normalized eight-point algorithm, described by Richard Hartley in 1997, is better suited for this case.

The algorithm's name derives from the fact that it estimates the essential matrix or the fundamental matrix from a set of eight (or more) corresponding image points. However, variations of the algorithm can be used for fewer than eight points.

Coplanarity constraint

One may express the epipolar geometry of two cameras and a point in space with an algebraic equation. Observe that, no matter where the point

is in space, the vectors

\overline{O_LP}

\overline{O_RP}

and

\overline{O_RO_L}

belong to the same plane. Call

X_L

the coordinates of point

in the left eye's reference frame and call

X_R

the coordinates of

in the right eye's reference frame and call

R,T

the rotation and translation between the two reference frames s.t.

X_R=R(X_L-T)

is the relationship between the coordinates of

in the two reference frames. The following equation always holds because the vector generated from

T\wedgeX_L

is orthogonal to both

and

X_L

	T
X
	L

T\wedgeX_L-T^TT\wedgeX_L=

	T
(X
	L-T)

T\wedgeX_L=0

Because

I=R^TR

, we get

	T
(X
	L-T)

R^TRT\wedgeX_L=0

Replacing

	TR
(X
	L-T)

with

	T
X
	R

, we get

	T
X
	R

RT\wedgeX_L=

	T
X
	R

RSX_L=

	T
X
	R

EX_L=0

Observe that

T\wedge

may be thought of as a matrix; Longuet-Higgins used the symbol

to denote it. The product

RT\wedge=RS

is often called essential matrix and denoted with

The vectors

\overline{O_Lp_L},\overline{O_Rp_R}

are parallel to the vectors

\overline{O_LP},\overline{O_RP}

and therefore the coplanarity constraint holds if we substitute these vectors. If we call

y,y'

the coordinates of the projections of

onto the left and right image planes, then the coplanarity constraint may be written as

y'^TEy=0

Basic algorithm

The basic eight-point algorithm is here described for the case of estimating the essential matrix

. It consists of three steps. First, it formulates a homogeneous linear equation, where the solution is directly related to

, and then solves the equation, taking into account that it may not have an exact solution. Finally, the internal constraints of the resulting matrix are managed. The first step is described in Longuet-Higgins' paper, the second and third steps are standard approaches in estimation theory.

The constraint defined by the essential matrix

(y')^TEy=0

for corresponding image points represented in normalized image coordinates

y,y'

. The problem which the algorithm solves is to determine

for a set of matching image points. In practice, the image coordinates of the image points are affected by noise and the solution may also be over-determined which means that it may not be possible to find

which satisfies the above constraint exactly for all points. This issue is addressed in the second step of the algorithm.

With

y=\begin{pmatrix}y₁\ y₂\ 1\end{pmatrix}

and

y'=\begin{pmatrix}y'₁\ y'₂\ 1\end{pmatrix}

and

E=\begin{pmatrix}e₁₁&e₁₂&e₁₃\ e₂₁&e₂₂&e₂₃\ e₃₁&e₃₂&e₃₃\end{pmatrix}

the constraint can also be rewritten as

y'₁y₁e₁₁+y'₁y₂e₁₂+y'₁e₁₃+y'₂y₁e₂₁+y'₂y₂e₂₂+y'₂e₂₃+y₁e₃₁+y₂e₃₂+e₃₃=0

e ⋅ \tilde{y

} = 0

where

\tilde{y

} = \begin y'_1 y_1 \\ y'_1 y_2 \\ y'_1 \\ y'_2 y_1 \\ y'_2 y_2 \\ y'_2 \\ y_1 \\ y_2 \\ 1 \end and

e=\begin{pmatrix}e₁₁\ e₁₂\ e₁₃\ e₂₁\ e₂₂\ e₂₃\ e₃₁\ e₃₂\ e₃₃\end{pmatrix}

that is,

represents the essential matrix in the form of a 9-dimensional vector and this vector must be orthogonal to the vector

\tilde{y

} which can be seen as a vector representation of the

3 x 3

matrix

y'y^T

Each pair of corresponding image points produces a vector

\tilde{y

} . Given a set of 3D points

P_k

this corresponds to a set of vectors

\tilde{y

}_ and all of them must satisfy

e ⋅ \tilde{y

}_ = 0

for the vector

. Given sufficiently many (at least eight) linearly independent vectors

\tilde{y

}_ it is possible to determine

in a straightforward way. Collect all vectors

\tilde{y

}_ as the columns of a matrix

and it must then be the case that

e^TY=0

This means that

is the solution to a homogeneous linear equation.

Step 2: Solving the equation

A standard approach to solving this equation implies that

is a right singular vector of

corresponding to a singular value that equals zero. Provided that at least eight linearly independent vectors

\tilde{y

}_ are used to construct

it follows that this singular vector is unique (disregarding scalar multiplication) and, consequently,

and then

can be determined.

In the case that more than eight corresponding points are used to construct

it is possible that it does not have any singular value equal to zero. This case occurs in practice when the image coordinates are affected by various types of noise. A common approach to deal with this situation is to describe it as a total least squares problem; find

which minimizes

\|e^TY\|

when

\|e\|=1

. The solution is to choose

as the left singular vector corresponding to the smallest singular value of

. A reordering of this

back into a

3 x 3

matrix gives the result of this step, here referred to as

E_\rm

Step 3: Enforcing the internal constraint

Another consequence of dealing with noisy image coordinates is that the resulting matrix may not satisfy the internal constraint of the essential matrix, that is, two of its singular values are equal and nonzero and the other is zero. Depending on the application, smaller or larger deviations from the internal constraint may or may not be a problem. If it is critical that the estimated matrix satisfies the internal constraints, this can be accomplished by finding the matrix

of rank 2 which minimizes

\|E'-E_\rm\|

where

E_\rm

is the resulting matrix from Step 2 and the Frobenius matrix norm is used. The solution to the problem is given by first computing a singular value decomposition of

E_\rm

E_\rm=USV^T

where

U,V

are orthogonal matrices and

is a diagonal matrix which contains the singular values of

E_\rm

. In the ideal case, one of the diagonal elements of

should be zero, or at least small compared to the other two which should be equal. In any case, set

S'=\begin{pmatrix}s₁&0&0\ 0&s₂&0\ 0&0&0\end{pmatrix},

where

s_1,s₂

are the largest and second largest singular values in

respectively. Finally,

is given by

E'=US'V^T

The matrix

is the resulting estimate of the essential matrix provided by the algorithm.

Normalized algorithm

The basic eight-point algorithm can in principle be used also for estimating the fundamental matrix

. The defining constraint for

(y')^TFy=0

where

y,y'

are the homogeneous representations of corresponding image coordinates (not necessary normalized). This means that it is possible to form a matrix

in a similar way as for the essential matrix and solve the equation

f^TY=0

for

which is a reshaped version of

. By following the procedure outlined above, it is then possible to determine

from a set of eight matching points. In practice, however, the resulting fundamental matrix may not be useful for determining epipolar constraints.

Difficulty

The problem is that the resulting

often is ill-conditioned. In theory,

should have one singular value equal to zero and the rest are non-zero. In practice, however, some of the non-zero singular values can become small relative to the larger ones. If more than eight corresponding points are used to construct

, where the coordinates are only approximately correct, there may not be a well-defined singular value which can be identified as approximately zero. Consequently, the solution of the homogeneous linear system of equations may not be sufficiently accurate to be useful.

Cause

Hartley addressed this estimation problem in his 1997 article. His analysis of the problem shows that the problem is caused by the poor distribution of the homogeneous image coordinates in their space,

R³

. A typical homogeneous representation of the 2D image coordinate

(y₁,y₂)

y=\begin{pmatrix}y₁\ y₂\ 1\end{pmatrix}

where both

y₁,y₂

lie in the range 0 to 1000–2000 for a modern digital camera. This means that the first two coordinates in

vary over a much larger range than the third coordinate. Furthermore, if the image points which are used to construct

lie in a relatively small region of the image, for example at

(700,700)\pm(100,100)

, again the vector

points in more or less the same direction for all points. As a consequence,

will have one large singular value and the remaining are small.

Solution

As a solution to this problem, Hartley proposed that the coordinate system of each of the two images should be transformed, independently, into a new coordinate system according to the following principle.

The origin of the new coordinate system should be centered (have its origin) at the centroid (center of gravity) of the image points. This is accomplished by a translation of the original origin to the new one.
After the translation the coordinates are uniformly scaled so that the mean of distances from the origin to the points equals

\sqrt{2}

This principle results, normally, in a distinct coordinate transformation for each of the two images. As a result, new homogeneous image coordinates

\bary,\bary'

are given by

\bary=Ty

\bary'=T'y'

where

T,T'

are the transformations (translation and scaling) from the old to the new normalized image coordinates. This normalization is only dependent on the image points which are used in a single image and is, in general, distinct from normalized image coordinates produced by a normalized camera.

The epipolar constraint based on the fundamental matrix can now be rewritten as

0=(\bary')^T((T')^T)^-1FT^-1\bary=(\bary')^T\barF\bary

where

\barF=((T')^T)^-1FT^-1

. This means that it is possible to use the normalized homogeneous image coordinates

\bary,\bary'

to estimate the transformed fundamental matrix

\barF

using the basic eight-point algorithm described above.

The purpose of the normalization transformations is that the matrix

\barY

, constructed from the normalized image coordinates, in general, has a better condition number than

has. This means that the solution

\barf

is more well-defined as a solution of the homogeneous equation

\barY\barf

than

is relative to

. Once

\barf

has been determined and reshaped into

\barF

the latter can be de-normalized to give

according to

F=(T')^T\barFT

In general, this estimate of the fundamental matrix is a better one than would have been obtained by estimating from the un-normalized coordinates.

Using fewer than eight points

Each point pair contributes with one constraining equation on the element in

. Since

has five degrees of freedom it should therefore be sufficient with only five point pairs to determine

. David Nister proposed an efficient solution to estimate the essential matrix from set of five paired points, known as the five-point algorithm.^[1] Hartley et. al. later proposed a modified and more stable five-point algorithm based on Nister's algorithm.^[2]

Notes and References

10.1109/TPAMI.2004.17 . Nister . David . 2004 . An efficient solution to the five-point relative pose problem . IEEE Transactions on Pattern Analysis and Machine Intelligence. 26 . 6 . 756–770 . 18579936 . 886598 .
Book: Li, Hongdong . 10.1109/ICPR.2006.579 . 18th International Conference on Pattern Recognition (ICPR'06) . Five-Point Motion Estimation Made Easy . 2006 . https://ieeexplore.ieee.org/document/1698971 . 630–633 . 0-7695-2521-0 . 7745676 .

Eight-point algorithm explained

Coplanarity constraint

Basic algorithm

Step 2: Solving the equation

Step 3: Enforcing the internal constraint

Normalized algorithm

Difficulty

Cause

Solution

Using fewer than eight points

See also

Further reading

Notes and References