Abstracts

1. INTRODUCTION

Fitting an ellipsoid to an arbitrary set of points is a problem of fundamental importance in many wide fields of applied science ranging from astronomy, geodesy, digital image processing and robotics to metrology etc. Ellipsoids, though a bit simple in representing 3D shapes in general, are the only bounded and centric quadrics that can provide information of center and orientation of an object. Fitting ellipsoid has been discussed widely and some excellent work has been done in literature. However, most of these fitting techniques are algebraic fitting, but not orthogonal fitting. Various "least- squares" fitting approaches have been formulated over the years Zhang (1997Zhang, Z. Parameter estimation techniques: a tutorial with application to conic fitting, Image and Vision Computing 15,59-76, 1997.), but they all fall into two categories; (1) algebraic methods, which are extensively used due to their linear nature, simplicity and computationally efficiency, and (2) geometric methods that solve a nonlinear problemRay and Srivastava (2008Ray, A., Srivastava D.C. Non-linear least squares ellipse fitting using the genetic algorithm with applications to strain analysis, Journal of Structural Geology 30 1593-1602. 2008.).

We could not find enough studies with numerical examples in the literature. Turner et al (1999Turner, D.A., Anderson I. J., Mason J.C., Cox, M.G. An algorithm for fitting an ellipsoid to data, http://citeseerx.ist.psu.edu/viewdoc/summary? doi=10.1.1.36.2773, 1999.
http://citeseerx.ist.psu.edu/viewdoc/sum... ) gave a numerical application, but the application's data are not given Turner et al (1999Turner, D.A., Anderson I. J., Mason J.C., Cox, M.G. An algorithm for fitting an ellipsoid to data, http://citeseerx.ist.psu.edu/viewdoc/summary? doi=10.1.1.36.2773, 1999.
http://citeseerx.ist.psu.edu/viewdoc/sum... ). No other comparable orthogonal fitting ellipsoid application could be found in literature. Against this background, the purpose of the study is to give an orthogonal fitting ellipsoid with numerical examples. In this article, we demonstrate that the geometric fitting approach, provides a more robust alternative than algebraic fitting approach-although it is computationally more intensive.

The paper has eight parts. First, the basic ellipsoid will introduce some mathematical equationsto explainthe concepts. Then, it reviews the extended literature relevant to ellipsoid fitting. And we discussed in this research which estimators is used. Next, comes the part which deals with algebraic fitting, orthogonal fitting and numerical example. You will find ellipsoid fitting application based on both l₁-norm and l₂-norm methods. The paper concludes with a discussion of theoretical and managerial implications and directions for further research.

1.1 Ellipsoid

An ellipsoid is a closed quadric surface that is analogue of an ellipse. Ellipsoid has three different axes (a_x>a_y>b) in Figure 1. Mathematical literature often uses "ellipsoid" in place of "Triaxial ellipsoid or General ellipsoid". Scientific literature (particularly geodesy) often uses "ellipsoid" in place of "biaxial ellipsoid, rotational ellipsoid or ellipsoid revolution". Older literature uses 'spheroid' in place of rotational ellipsoid. The standard equation of an ellipsoid centered at the origin of a cartesian coordinate system and aligned with the axes is shown with this formula:

Figure 1:
Ellipsoid

Although ellipsoid equation is quite simple and smooth, computations are quite difficult on the ellipsoid. The main reason for this difficulty is the lack of symmetry. Generally, an ellipsoid is defined with 9 parameters. These parameters are; 3 coordinates of center (X_o,Y_o,Z_o), 3 semi-axes (a_x, a_y, b) and 3 rotational angles ((, (, () which represent rotations around x-,y- and z- axes respectively in Figure 2. These angles control the orientation of the ellipsoid.

R₁,R₂,R₃ are plane rotation matrices

R-rotation matrix is obtained from R₁,R₂,R₃ by multiplying the reverse order

Figure 2:
Shifted - oriented ellipsoid

2. FITTING ELLIPSOID

For the solution of the fitting problem, the linear or linearized relationship, written between the given data points and unknown parameters (one equation per data points), consists of equations, including unknown parameters.

Here, A is design matrix, (x is unknown parameters, l is measurements vector or data points,

For this minimization problem to have a unique solution the necessary conditions is to be n>= 9

and the data points lie in general position (e.g., not all data points should lie is an elliptic plane). Throughout this paper, we assume that these conditions are satisfied.

u=9 : number of unknown parameter

n: number of given data point (or measurements)

f=n-u :degree of freedom

-If f = 0 there is only one (exact) solution, algebraic solution

-If f<0 there is no solution. The solutioncan be found with based on the extra constraint

-If f> 0 is most commonly encountered situation. The given data points (or measurements), which are much greater than the required number cause discrepancy, and in this case, the solution is not unique. There is an over determined system. Because n > u, in other words the number of equations is greater than the number of unknowns.

The system of linear equations (4) must be solved. Therefore, this system must be consistent with the rang of design matrix, and design matrix extended with constant terms, must be equal, so that rang(A) =rang(A:l); whereas, the system of (4) is inconsistent, because (x unknown parameters that provide (4), can not be calculated. In this case, rang(A) ≤ u. The extended matrix with l measurements rang(A:l) is generally more than rang(A) . There is no solution of inconsistent equations, and only the approximate solution of the system can be derived. The equation system with approximate solution is calculated by adding ( residuals (or corrections) at the right side of (4).

Depending on the choice of ( residuals vector, infinite solutions can be obtained. The unique solution can be derived only according to an estimator (objective function). For example, the LS always give an unique solution Bektas and Sisman (2010Bektas, S., Sisman, Y. The comparison of L1 and L2-norm minimization methods, International Journal of the Physical Sciences, 5(11), 1721 - 1727, 2010). Here, the question of which estimation method to use comes to mind?

3. WHICH ESTIMATOR SHOULD BE USED?

It is hoped that the residuals will be small. The more suitable estimation method is one that creates smaller residuals. It is seen that usually the objective functions are formed based on the minimization of corrections or a function of corrections. There are numerous estimators, some of these are l₁-norm, l₂-norm,l_p-norm, Fair, Huber, Cauchy, German-McClure, Welsch and Tukey. Two estimator methods come to the forefront.The most used estimators are shown below:

(i) [((] = min. ( l₂-norm) Least Squares Method (LSM)

(ii) [I(I] = min. ( l₁-norm) Least Absolute Values Method (LAVM).

3.1. The Comparison of l₁ and l₂-Norm Methods

The solution of the l₂-norm method is always unique, and this solution is easily calculated. The l₂-norm method is widely used in parameters estimation. The l₂-norm method has indisputable superiority in parameter estimation.

The disadvantages of the l₂-norm method are that is affected by outlying (gross errors) and it distributes to the sensitivity measurements. In this case, ellipsoid fitting is a very nice application.

With least-squares techniques, even one or two outliers in a large set can wreak havoc! Outlying data give an effect so strong in the minimization that the parameters thus estimated by those outlying data are distorted. Numerous studies have been conducted, which clearly show that least-squares estimators are vulnerable to the violation of these assumptions. Sometimes, even when the data contains only one bad measurement, l₂-norm method estimates may be completely perturbed Zhang (1997Zhang, Z. Parameter estimation techniques: a tutorial with application to conic fitting, Image and Vision Computing 15,59-76, 1997.).

The solution of the l₁-norm method is not always unique, and there may be several solutions. Also, the solution of the l₁-norm method is not generally obtained directly, but iteratively calculations are made. Therefore, the solution is not easily calculated like in the l₂-norm method. Notwithstanding, when the computational tools, computer capacity and speed are considered, the difficulty of calculations are eliminated. The advantages of the l₁-norm method are non-sensitivity against measurements, including gross errors, and the solution is not or is little affected by these measurements.

The author of this study proposed and used the l₂-norm method in the solution of parameter estimation (optimization problems, adjustment calculus), after the measurement group cleaned up gross and systematic errors using the l₁-norm method. For further information see Bektas and Sisman (2010Bektas, S., Sisman, Y. The comparison of L1 and L2-norm minimization methods, International Journal of the Physical Sciences, 5(11), 1721 - 1727, 2010).

4. ALGEBRAIC ELLIPSOID FITTING METHODS

The general equation of an ellipsoid is given as

(6) contains ten parameters. In fact, nine of those ten parameters are independent. For example, if all the coefficients in this equation multiply by (-1/K'), we get a new equation which contains nine unknown parameters, and its constant term will be equal to "-1".

In this algorithm, we need to check whether a fitted shape is an ellipsoid. In theory, the conditions that ensure a quadratic surface to be an ellipsoid have been well investigated and explicitly stated in analytic geometry textbooks. An ellipsoid can be degenerated into other kinds of elliptic quadrics, such as an elliptic paraboloid. Therefore, a proper constraint must be added. Li and Griffiths gave the following definitions Li and Griffiths (2004Li, Q., Griffiths J.G. Least Squares Ellipsoid Specific Fitting, Geometric Modelling and Processing, 2004.).

However 4j-i2> 0 is just a sufficient condition to guarantee that an equation of second degree in three variables represent an ellipsoid, but it is not necessary. In this paper, we assume that these conditions are satisfied.

The algebraic method is a linear problem. It is solving the problem directly and easily. The fitting ellipsoid to a given the data set ((x,y,z)_i , i=1,2,...,n), is obtained by the solution in the LS sense of in the following:

Where

(_nxu = Design matrix

v_u = [ A B C D E F G H I ]^Tunknown conic parameters

l_n = [1 1 1...1]^T unit vector : right side vector

ith row of the nx9 matrix (

It is solved easily in the LS sense as below

or it is solved easily by MATLAB as below

If there are differences in weights or correlations between given data points, P weight matrix is added in the solution, and then

P=K_ll^-1K_ll:nxn variance-covariance matrix of data points

Residual (or correction) vector is computed as below

LS optimization give us ||(|| =min.

Algebraic methods all have indisputable advantages of solving linear LS problems. The methods for this are well known and fast. However, it is intuitively unclear what it is we are minimizing geometrically in (7) is often referred to as the "algebraic distance" to be minimized Ray and Srivastava (2008Ray, A., Srivastava D.C. Non-linear least squares ellipse fitting using the genetic algorithm with applications to strain analysis, Journal of Structural Geology 30 1593-1602. 2008.). A geometric interpretation given by Bookstein (1979Bookstein, F. L. "Fitting conic sections to scattered data", Computer Graphics and Image Processing 9,56-71, 1979.) clearly demonstrates that algebraic methods neglect points far from the center.

5. FITTING OF ELLIPSOID USING ORTHOGONAL DISTANCES

To overcome the problems with the algebraic distances, it is natural to replace them by the orthogonal distances which are invariant to transformations in Euclidean space and which do not exhibit the high curvature bias. An ellipsoid of best fit in the LS sense to the given data points can be found by minimizing the sum of the squares of the geometric distances from the data to the ellipsoid. The geometric distance is defined to be the distance between a data point and its closest point on the ellipsoid.

Determining best fit ellipsoid is a nonlinear least squares problem which in principle can be solved by using the Levenberg-Marquardt (LM)algorithm. Generally, non-linear least squares is a complicated issue. It is very difficult to develop methods which can find the global minimizer with certainty in this situation. When a local minimizer has been discovered, we do not know whether it is a global minimizer or one of the local minimizer Zisserman (2013Zisserman, A. C25 Optimization, 8 Lectures, Hilary Term 2013,2 Tutorial Sheets,Lectures 3-6 (BK), 2013.).

There are a variety of nonlinear optimization techniques. Such as Newton, Gauss-Newton, Gradient Descent, Levenberg-Marquardt approximation etc. However, these fitting techniques involve a highly nonlinear optimization procedure, which often stops at a local minimum and cannot guarantee an optimal solution Li and Griffiths (2004Li, Q., Griffiths J.G. Least Squares Ellipsoid Specific Fitting, Geometric Modelling and Processing, 2004.).

Away from the minimum, in regions of negative curvature, the Gauss-Newton approximation is not very good. In such regions, a simple steepest-descent step is probably the best plan. The Levenberg-Marquardt method is a mechanism for varying between steepest-descent and Gauss-Newton steps depending on how good the H_GN approximation is locally.

The Levenberg-Marquardt method uses the modified Hessian

H(x,λ) = H_GN +λ.I ( I : identity matrix )

• When λ is small, H approximates the Gauss-Newton Hessian.

• When λ is large, H is close to the identity, causing steepest-descent steps to be taken.

This algorithm does not require explicit line searches. More iterations than Gauss-Newton, but, no line search required, and more frequently converge suppose that we have a unknowns parameter set

v= [ A B C D E F G H I ]^T are unknown conic parameters. The general conic equation for an ellipsoid is given as (8)

We will reach the solution by establishing relationships between variations in the conical coefficients and the orthogonal distances.

The initial parameters were derived from the algebraic fitting ellipsoid.

: Projection coordinates (onto ellipsoid) of given P_i data points

ith row of the nx10 matrix J (jakobien matrix)

ith row of the right side vector h_nx1

We obtained the below linearized equation

The fitted orthogonal ellipsoid is obtained by the solution in the LS sense with the L-M algorithm.

5.1 The Levenberg-Marquardt Algorithm

1-Solve algebraic methods and find initial values for v

set λ=1 (say)

2- Compute J-jacobien matrix and h_i orthogonal distances from all given data points

minh= hTh

3- Solve ( JTJ + λ I ) dv= JTh

v=v+dv , new conic parameter

Find again h_i orthogonal distances from all given data points

newh= hTh

4- ifnewh<minh % yes there is improvement, reduce λ

minh=newh; λ=λ/2

goto 3

else % no improvement, increase λ

λ=2*λ

goto 3

end

5.2. Finding Orthogonal Distances from the Ellipsoid

In this paper, we present techniques for ellipsoid fitting which are based on minimizing the sum of the squares of the geometric distances between the data and the ellipsoid. The most time-consuming part is the computation of the orthogonal distances between each point and the ellipsoid. Our aim to find the orthogonal distances from a shifted-oriented ellipsoid see Figure 2. For detailed information on this subject refer to Bektas (2014)Bektas, S. "Orthogonal Distance From An Ellipsoid, Boletim de Ciencias Geodesicas, Vol. 20, No. 4 ISSN 1982-2170 , http://dx.doi.org/10.1590/S1982-217020140004000400053, 2014
https://doi.org/10.1590/S1982-2170201400... .

6. NUMERICAL EXAMPLE

For numerical applications 12 triplets (x,y,z) cartesian coordinates were produced.

Here data points coordinates,

x: [ 7 7 9 9 11 11 8 8 10 10 12 12 ]

y: [22 19 23 19 24 20 21 17 22 18 23 19 ]

z: [31 28 31 27 29 26 32 29 32 28 31 28 ]

This problem is also solved by Least Absolute Values Method( l₁-norm) and the following results were obtained.

The conical coefficients in the Least Squares Method is,

v=[-0.0006 -0.0008 -0.0010 0.0005 -0.0005 0.0003 0.0092 0.0050 0.0278]

The conical coefficients in the Least Absolute Values Method is,

v=[ -0.0071 -0.0084 -0.0096 0.0047 -0.0040 0.0023 0.0880 0.0061 0.0271]

We show both the algebraic and orthogonal fitting results are as shown in Table 1.

*RSS: The residual sum of squares of the orthogonal distances

7. DISCUSSION

Orthogonal least-squares has a much sounder basis, but is usually difficult to implement. Why are algebraic distances usually not satisfactory? The big advantage of use of algebraic distances is the gain in computational efficiency, because closed-form solutions can usually be obtained. In general, however, the results are not satisfactory.The function to minimize is usually not invariant under Euclidean transformations. For example, the function with normalization K' = -1 in (6) is not invariant with respect to translations. This is a feature we dislike, because we usually do not know in practice where the best coordinate system to represent the data is. A point may contribute differently to the parameter estimation depending on its position on the conic. If a priori all points are corrupted by the same amount of noise, it is desirable for them to contribute the same way Zhang (1997Zhang, Z. Parameter estimation techniques: a tutorial with application to conic fitting, Image and Vision Computing 15,59-76, 1997.). More importantly, algebraic methods have an inherent curvature bias - data corrupted by the same amount of noise will misfit unequally at different curvatures Ray and Srivastava (2008Ray, A., Srivastava D.C. Non-linear least squares ellipse fitting using the genetic algorithm with applications to strain analysis, Journal of Structural Geology 30 1593-1602. 2008.). Our experience tells us that if the coordinates of given points consists of a large number this will cause bad condition. Therefore, before fitting, you must shift the given coordinates to the center of gravity, after fitting operation the coordinates of ellipsoid's center must be shifted back to the previous position.

8. CONCLUSION

In this paper, we studied on the orthogonal fitting ellipsoid. The problem offitting ellipsoid is encounteredfrequently intheimage processing, face recognition, computer games, geodesy-determiningmore realistic Earth ellipsoid etc. The paper has presented a new method of orthogonal fitting ellipsoid. The new method relies on solving an over determined system of nonlinear equations with the use of the L-M method. In conclusion, the presented method may be considered as fast, accurate and reliable and may be successfully used in other areas. The presented orthogonal fitting algorithm can be applied easily to biaxial ellipsoid, sphere and also other surfaces such as paraboloid, hyperboloid,etc.

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