Matrices and Homogeneous Coordinates

Concepts from algebraic geometry such as cones and fans are related to toric varieties and can be applied to determine the convex polytopes and homogeneous coordinate rings of multivariate polynomial systems. The homogeneous coordinates of a system in its projective vector space can be associated with the entries of the resultant matrix of the system under consideration. This paper presents some conditions for the homogeneous coordinates of a certain system of bivariate polynomials through the construction and implementation of the Sylvester-Bèzout hybrid resultant matrix formulation. This basis of the implementation of the Bèzout block applies a combinatorial approach on a set of linear inequalities, named 5-rule. The inequalities involved the set of exponent vectors of the monomials of the system and the entries of the matrix are determined from the coefficients of facets variable known as brackets. The approach can determine the homogeneous coordinates of the given system and the entries of the Bèzout block. Conditions for determining the homogeneous coordinates are also given and proven.

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A plane quartic curve with twelve undulations

Edinburgh Mathematical Notes ◽

10.1017/s0950184300000197 ◽

1945 ◽

Vol 35 ◽

pp. 10-13 ◽

Cited By ~ 3

Author(s):

W. L. Edge

Keyword(s):

Homogeneous Coordinates ◽

Quartic Curve ◽

Base Points ◽

Octahedral Group ◽

Quartic Form ◽

Image Position ◽

Quartic Curves ◽

Set Of Points

The pencil of quartic curveswhere x, y, z are homogeneous coordinates in a plane, was encountered by Ciani [Palermo Rendiconli, Vol. 13, 1899] in his search for plane quartic curves that were invariant under harmonic inversions. If x, y, z undergo any permutation the ternary quartic form on the left of (1) is not altered; nor is it altered if any, or all, of x, y, z be multiplied by −1. There thus arises an octahedral group G of ternary collineations for which every curve of the pencil is invariant.Since (1) may also be writtenthe four linesare, as Ciani pointed out, bitangents, at their intersections with the conic C whose equation is x2 + y2 + z2 = 0, to every quartic of the pencil. The 16 base points of the pencil are thus all accounted for—they consist of these eight contacts counted twice—and this set of points must of course be invariant under G. Indeed the 4! collineations of G are precisely those which give rise to the different permutations of the four lines (2), a collineation in a plane being determined when any four non-concurrent lines and the four lines which are to correspond to them are given. The quadrilateral formed by the lines (2) will be called q.

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Clustering Irregular Shapes Using High-Order Neurons

Neural Computation ◽

10.1162/089976600300014962 ◽

2000 ◽

Vol 12 (10) ◽

pp. 2331-2353 ◽

Cited By ~ 13

Author(s):

H. Lipson ◽

H. T. Siegelmann

Keyword(s):

Synaptic Weight ◽

Hebbian Learning ◽

Second Order ◽

High Order ◽

Maximum Correlation ◽

Overlapping Clusters ◽

Homogeneous Coordinates ◽

Irregular Shapes ◽

Data Clusters ◽

Iris Data

This article introduces a method for clustering irregularly shaped data arrangements using high-order neurons. Complex analytical shapes are modeled by replacing the classic synaptic weight of the neuron by high-order tensors in homogeneous coordinates. In the first- and second-order cases, this neuron corresponds to a classic neuron and to an ellipsoidal-metric neuron. We show how high-order shapes can be formulated to follow the maximum-correlation activation principle and permit simple local Hebbian learning. We also demonstrate decomposition of spatial arrangements of data clusters, including very close and partially overlapping clusters, which are difficult to distinguish using classic neurons. Superior results are obtained for the Iris data.

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Pseudo-Homogeneous Coordinates for Hughes Planes

Canadian Mathematical Bulletin ◽

10.4153/cmb-1996-040-9 ◽

1996 ◽

Vol 39 (3) ◽

pp. 330-345 ◽

Cited By ~ 1

Author(s):

Peter Maier ◽

Markus Stroppel

Keyword(s):

Projective Planes ◽

Baer Subplane ◽

Homogeneous Coordinates ◽

Desargues Configuration ◽

Coset Spaces ◽

Insight Into ◽

Hughes Plane

AbstractAmong the projective planes, the class of Hughes planes has received much interest, for several good reasons. However, the existing descriptions of these planes are somewhat unsatisfactory. We introduce pseudo-homogeneous coordinates which at the same time are easy to handle and give insight into the action of the group that is generated by all elations of the desarguesian Baer subplane of a Hughes plane. The information about the orbit decomposition is then used to give a description in terms of coset spaces of this group. Finally, we exhibit a non-closing Desargues configuration in terms of coordinates.

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XVIII.—The Invariant Theory of Forms in Six Variables relating to the Line Complex

Proceedings of the Royal Society of Edinburgh ◽

10.1017/s0370164600022008 ◽

1927 ◽

Vol 46 ◽

pp. 210-222 ◽

Cited By ~ 1

Author(s):

H. W. Turnbull

Keyword(s):

Invariant Theory ◽

Line Geometry ◽

Five Dimensions ◽

Ordinary Space ◽

Homogeneous Coordinates ◽

Plücker Coordinates ◽

Algebraic Theories ◽

Straight Line ◽

Image Position ◽

Theory Of Forms

It is well known that the Plücker coordinates of a straight line in ordinary space satisfy a quadratic identitywhich may also be considered as the equation of a point-quadric in five dimensions, if the six coordinates Pij are treated as six homogeneous coordinates of a point. Projective properties of line geometry may therefore be treated as projective properties of point geometry in five dimensions. This suggests that certain algebraic theories of quaternary forms (corresponding to the geometry of ordinary space) can best be treated as algebraic theories of senary forms: that is, forms in six homogeneous variables.

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On an Observation of M. Riesz

Canadian Mathematical Bulletin ◽

10.4153/cmb-1961-012-3 ◽

1961 ◽

Vol 4 (1) ◽

pp. 70-71

Author(s):

P. Scherk

Keyword(s):

Simple Proof ◽

Cross Ratio ◽

Homogeneous Coordinates ◽

Three Space

On a recent visit to Toronto, Professor Riesz made an interesting remark on the invariance of a certain cross-ratio, I wish to present a simple proof of his result.Let x = ( x1, x2, x3, x4), … denote homogeneous coordinates in real projective three-space; x(t), … are differentiable curves in that space.

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A Specialised Net of Quadrics Having Selfpolar Polyhedra, with Details of the Fivedimensional Example

Canadian Journal of Mathematics ◽

10.4153/cjm-1981-069-3 ◽

1981 ◽

Vol 33 (4) ◽

pp. 885-892

Author(s):

W. L. Edge

Keyword(s):

Projective Space ◽

Complex Number ◽

Roots Of Unity ◽

Parametric Form ◽

Normal Curve ◽

Homogeneous Coordinates ◽

Image Position ◽

Rational Normal Curve

If x0,x1, … xn are homogeneous coordinates in [n], projective space of n dimensions, the prime (to use the standard name for a hyperplane)osculates, as θ varies, the rational normal curve C whose parametric form is [2, p. 347]Take a set of n + 2 points on C for which θ = ηjζ where ζ is any complex number andso that the ηj, for 0 ≦ j < n + 2, are the (n + 2)th roots of unity. The n + 2 primes osculating C at these points bound an (n + 2)-hedron H which varies with η, and H is polar for all the quadrics(1.1)in the sense that the polar of any vertex, common to n of its n + 2 bounding primes, contains the opposite [n + 2] common to the residual pair.

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Homogeneous Coordinates and Transformations of the Plane

Springer Undergraduate Mathematics Series - Applied Geometry for Computer Graphics and CAD ◽

10.1007/1-84628-109-1_2 ◽

2005 ◽

pp. 19-40

Author(s):

Marsh Duncan

Keyword(s):

Homogeneous Coordinates

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Perspective Triads

The Mathematical Gazette ◽

10.1017/s0025557200027571 ◽

1953 ◽

Vol 37 (322) ◽

pp. 247-255

Author(s):

W.R. Andress ◽

W. Saddler ◽

W.W. Sawyer

Keyword(s):

Homogeneous Coordinates

1. Consider two triads of points, a, b, c, a', b', c' in a plane ; then, using homogeneous coordinates and regarding the points as specified by the corresponding vectors, we may write

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The cyclic boundary conditions and crystal vibrations

Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences ◽

10.1098/rspa.1993.0109 ◽

1993 ◽

Vol 442 (1915) ◽

pp. 373-395 ◽

Cited By ~ 2

Keyword(s):

Boundary Conditions ◽

Degrees Of Freedom ◽

Strain Tensor ◽

Three Dimensional ◽

Normal Modes ◽

Inertial Mass ◽

Mean Value ◽

Reference Configuration ◽

Large Crystal ◽

Homogeneous Coordinates

In considering the vibrational properties of a crystal, a rigorous finite transformation of the particle displacements from their reference configuration is introduced. This transformation shows that an arbitrary set of such displacements may be regarded as made up of a rotation, a translation, a homogeneous deformation of the reference configuration, and a set of inhomogeneous deformational orthogonal modes. For a three-dimensional crystal, there are 3 N – 12 such inhomogeneous modes, which, in the limit of a large crystal can be considered wave-like. In the usual treatment beginning with the cyclic boundary conditions, 3 N wave-like modes are assumed and rotational displacements, for example, must be ignored. The present treatment accounts satisfactorily for all degrees of freedom, including rotational. Because of the non-singular nature of the above transformation, the transformation of the above modes to the normal modes proves that some normal modes are admixtures of inhomogeneous and homogeneous modes and therefore cannot possibly satisfy the Born cyclic boundary conditions. The vibrational hamiltonian is shown to contain the elastic energy and the elastic–phonon interaction terms as well as the usual wave energies. In the limit of a large crystal, it is shown that, for all processes involving phonons, the homogeneous coordinates may be regarded as effectively static, in much the same way as, in a simple theory of the Earth–Sun motion, the Sun, because of its large inertial mass, is considered stationary and its position coordinates static. The above transformation enables the case of a crystal, free or confined in a container, to be satisfactorily discussed. It is proved that the quantum mean value of the tensor whose independent elements define the homogeneous coordinates is, in the limit of a large crystal, equal to the strain tensor of the container, when it is being used to deform the crystal by being itself homogeneously deformed. A rigorous quantum treatment of crystal elastic constants may then be developed. For practical use, the 3 N – 12 inhomogeneous modes may be assumed to obey the cyclic boundary conditions. Thus a satisfactory complete basic treatment of lattice dynamics may be given which accounts for all degrees of freedom including rotation.

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