词条 | Generalized conic |
释义 |
In mathematics, a generalized conic is a geometrical object defined by a property which is a generalization of some defining property of the classical conic. For example, in elementary geometry, an ellipse can be defined as the locus of a point which moves in a plane such that the sum of its distances from two fixed points – the foci – in the plane is a constant. The curve obtained when the set of two fixed points is replaced by an arbitrary, but fixed, finite set of points in the plane is called an n–ellipse and can be thought of as a generalized ellipse. Since an ellipse is the equidistant set of two circles, the equidistant set of two arbitrary sets of points in a plane can be viewed as a generalized conic. In rectangular Cartesian coordinates, the equation y = x2 represents a parabola. The generalized equation y = x r, for r ≠ 0 and r ≠ 1, can be treated as defining a generalized parabola. The idea of generalized conic has found applications in approximation theory and optimization theory.[1] Among the several possible ways in which the concept of a conic can be generalized, the most widely used approach is to define it as a generalization of the ellipse. The starting point for this approach is to look upon an ellipse as a curve satisfying the 'two-focus property': an ellipse is a curve that is the locus of points the sum of whose distances from two given points is constant. The two points are the foci of the ellipse. The curve obtained by replacing the set of two fixed points by an arbitrary, but fixed, finite set of points in the plane can be thought of as a generalized ellipse. Generalized conics with three foci are called trifocal ellipses. This can be further generalized to curves which are obtained as the loci of points which move such that the some of weighted arithmetic mean of the distances from a finite set of points is a constant. A still further generalization is possible by assuming that the weights attached to the distances can be of arbitrary sign, namely, plus or minus. Finally, the restriction that the set of fixed points, called the set of foci of the generalized conic, be finite may also be removed. The set may be assumed to be finite or infinite. In the infinite case, the weighted arithmetic mean has to be replaced by an appropriate integral. Generalized conics in this sense are also called polyellipses, egglipses, or, generalized ellipses. Since such curves were considered by the German mathematician Ehrenfried Walther von Tschirnhaus (1651 – 1708) they are also known as Tschirnhaus'sche Eikurve.[2] Also such generalizations have been discussed by Rene Descartes[3] and by James Clerk Maxwell.[3] Multifocal oval curvesRene Descartes (1596–1650), father of analytical geometry, in his La Geometrie published in 1637, set apart a section of about 15 pages to discuss what he had called bifocal ellipses. A bifocal oval was defined there as the locus of a point P which moves in a plane such that where A and B are fixed points in the plane and λ and c are constants which may be positive or negative. Descartes had introduced these ovals, which are now known as Cartesian ovals, to determine the surfaces of glass such that after refraction the rays meet at the same point. Descartes had also recognized these ovals as generalizations of central conics, because for certain values of λ these ovals reduce to the familiar central conics, namely, the circle, the ellipse or the hyperbola.[4]Multifocal ovals were rediscovered by James Clerk Maxwell (1831–1879) while he was still a school student. At the young age of 15, Maxwell wrote a scientific paper on these ovals with the title "Observations on circumscribed figures having a plurality of foci, and radii of various proportions" and got it presented by Professor J. D. Forbes in a meeting of the Royal Society of Edinburgh in 1846. Professor J. D. Forbes also published an account of the paper in the Proceedings of the Royal Society of Edinburgh.[3][5] In his paper, though Maxwell did not use the term "generalized conic", he was considering curves defined by conditions which were generalizations of the defining condition of an ellipse. DefinitionA multifocal oval is a curve which is defined as the locus of a point moving such that where A1, A2, . . . , An are fixed points in a plane and λ1, λ2, . . . , λn are fixed rational numbers and c is a constant. He gave simple pin-string-pencil methods for drawing such ovals. The method for drawing the oval defined by the equation illustrates the general approach adopted by Maxwell for drawing such curves. Fix two pins at the foci A and B. Take a string whose length is c + AB and tie one end of the string to the pin at A. A pencil is attached to the other end of the string and the string is passed round the pin at the focus B. The pencil is then moved guided by the bight of the string. The curve traced by the pencil is the locus of P. His ingenuity is more visible in his description of the method for drawing a trifocal oval defined by an equation of the form . Let three pins be fixed at the three foci A, B, C. Let one end of the string be fixed at the pin at C and let the string be passed around the other pins. Let the pencil be attached to the other end of the string. Let the pencil catch a bight in the string between A and C and then stretch to P. The pencil is moved such that the string is taut. The resulting figure would be a part of a trifocal ellipse. The positions of the string may have to adjusted to get the full oval. In the two years after his paper was presented to the Royal Society of Edinburgh, Maxwell systematically developed the geometrical and optical properties of these ovals.[5] Specialization and generalization of Maxwell's approachAs a special case of Maxwell's approach, consider the n-ellipse—the locus of a point which moves such that the following condition is satisfied: Dividing by n and replacing c/n by c, this defining condition can be stated as This suggests a simple interpretation: the generalised conic is a curve such that the average distance of every point P on the curve from the set {A1, A2, . . . , An} has the same constant value. This formulation of the concept of a generalized conic has been further generalised in several different ways.
The formulation of the definition of the generalized conic in the most general case when the cardinality of the focal set is infinite involves the notions of measurable sets and Lebesgue integration. All these have been employed by different authors and the resulting curves have been studied with special emphasis on applications. DefinitionLet be a metric and a measure on a compact set with . The unweighted generalized conic function associated with is where is a kernel function associated with . is the set of foci. The level sets are called generalized conics.[6] Generalized conics via polar equationsGiven a conic, by choosing a focus of the conic as the pole and the line through the pole drawn parallel to the directrix of the conic as the polar axis, the polar equation of the conic can be written in the following form: Here e is the eccentricity of the conic and d is the distance of the directrix from the pole. Tom M. Apostol and Mamikon A. Mnatsakanian in their study of curves drawn on the surfaces of right circular cones introduced a new class of curves which they called generalized conics.[10][11] These are curves whose polar equations are similar to the polar equations of ordinary conics and the ordinary conics appear as special cases of these generalized conics. DefinitionFor constants r0 ≥ 0, λ ≥ 0 and real k, a plane curve described by the polar equation is called a generalized conic.[11] The conic is called a generalized ellipse, parabola or hyperbola according as λ < 1, λ = 1, or λ > 1. Special cases
Let α be an angle such that sin α = 1/k. Consider a right circular cone with semi-vertical angle equal to α. Consider the intersection of this cone by a plane such that the intersection is a conic with eccentricity λ. Unwrap the cone to a plane. Then the curve in the plane to which the conic section of eccentricity λ is unwrapped is a generalized conic with polar equation as specified in the definition.
Consider an ordinary conic drawn on a plane. Wrap the plane to form a right circular cone so that the conic becomes a curve in three-dimensional space. The projection of the curve onto a plane perpendicular to the axis of the cone will be a generalized conic in the sense of Apostol and Mnatsakanian with k < 1. ExamplesGeneralized conics in curve approximationIn 1996, Ruibin Qu introduced a new notion of generalized conic as a tool for generating approximations to curves.[12] The starting point for this generalization is the result that the sequence of points defined by lie on a conic. In this approach, the generalized conic is now defined as below. DefinitionA generalized conic is such a curve that if the two points and are on it, then the points generated by the recursive relation for some and satisfying the relations are also on it. Generalized conics as equidistant setsDefinitionLet (X, d) be a metric space and let A be a nonempty subset of X. If x is a point in X, the distance of x from A is defined as d(x, A) = inf{ d(x, a): a in A}. If A and B are both nonempty subsets of X then the equidistant set determined by A and B is defined to be the set {x in X: d(x, A) = d(x, B)}. This equidistant set is denoted by { A = B }. The term generalized conic is used to denote a general equidistant set.[13] ExamplesClassical conics can be realized as equidistant sets. For example, if A is a singleton set and B is a straight line, then the equidistant set { A = B } is a parabola. If A and B are circles such that A is completely within B then the equidistant set { A = B } is an ellipse. On the other hand, if A lies completely outside B the equidistant set { A = B } is a hyperbola. References1. ^{{cite web|last1=Csaba Vincze|title=Convex Geometry|url=http://www.tankonyvtar.hu/hu/tartalom/tamop412A/2011_0025_mat_14/ch10.html|accessdate=11 November 2015}} 2. ^{{cite journal|last1=Gyula Sz.-Nagy|title=Tschirnhaus'sche Eiflachen und EiKurven|journal=Acta Mathematica Academiae Scientiarum Hungaricae|date=June 1950|volume=1|issue=2|pages=167–181}} 3. ^1 {{cite book|last1=James Clerk Maxwell|title=The Scientific Letters and Papers of James Clerk Maxwell: 1846–1862 (Paper on the description of oval curves)|date=1990|publisher=CUP Archive|isbn=9780521256254|pages=35–42|url=https://books.google.co.in/books?id=zfM8AAAAIAAJ&pg=PA35&lpg=PA35&redir_esc=y#v=onepage&q&f=false|accessdate=11 November 2015}} 4. ^1 {{cite book|last1=Ivor Grattan-Guinness|title=Landmark Writings in Western Mathematics 1640–1940|date=2005|publisher=Elsevier|isbn=9780080457444|page=13|url=https://books.google.co.in/books?id=UdGBy8iLpocC&pg=PA13&lpg=PA13&dq=bifocal+oval+descartes&source=bl&ots=RXiw2bRDxg&sig=QLu2ves0Ntn5JK8zbwV4ryBqCxY&hl=en&sa=X&ved=0ahUKEwjKga3dhN7JAhVMH44KHcIcBoQQ6AEINTAE#v=onepage&q=bifocal%20oval%20descartes&f=false|accessdate=15 December 2015}} 5. ^1 {{cite book|last1=P. M. Harman, Peter Michael Harman|title=The Natural Philosophy of James Clerk Maxwell|date=February 2001|publisher=Cambridge University Press|isbn=9780521005852|pages=11–15|url=https://books.google.co.in/books?id=v4xjVtszqssC&pg=PA15&lpg=PA15&dq=descartes+ovals&source=bl&ots=tK59mUWLZZ&sig=W8Sf8S8c61MH6YuKh_HVQFqh4Ps&hl=en&sa=X&ved=0ahUKEwi-mJWdgt7JAhUEt44KHQzCAvQQ6AEIYDAM#v=onepage&q=descartes%20ovals&f=false|accessdate=15 December 2015}} 6. ^1 2 3 {{cite journal|last1=Abris nagy|title=A short review on the theory of generalized conics|journal=Acta Mathematica Academiae Paedagogicae Nyíregyháziensis|date=2015|volume=31|pages=81–96|url=http://www.emis.de/journals/AMAPN/vol31_1/31_09.pdf|accessdate=17 December 2015}} 7. ^{{cite journal|last1=C. Gross and T.-K. Strempel|title=On generalizations of conics and on a generalization of the Fermat–Torricelli problem|journal=American Mathematical Monthly|date=1998|volume=105|issue=8|pages=732–743|doi=10.2307/2588990}} 8. ^{{cite journal|last1=Akos G. Horvath, Horst Martini|title=Conics in Normed Planes|journal=Extracta Mathematicae|date=2011|volume=26|issue=1|pages=29–43|url=http://www.eweb.unex.es/eweb/extracta/Vol-26-1/abstract_26J1Horv.pdf|accessdate=17 December 2015}} 9. ^{{cite web|last1=Abris Nagy|title=Generalized conics and geometric tomography|url=http://www.math.unideb.hu/irses/publ/nagy_abris_mwdg.pdf|accessdate=17 December 2015}} 10. ^{{cite journal|last1=Tom M. Apostol and Mamikon A. Mnatsakanian|title=Unwrapping Curves from Cylinders and Cones|journal=American Mathematical Monthly|date=May 2007|volume=114|pages=388–416|jstor=27642220|doi=10.1080/00029890.2007.11920429|url=http://mamikon.com/USArticles/RollingConesCylinders.pdf|accessdate=11 December 2015}} 11. ^1 2 {{cite book|last1=Tom M. Apostol and Mamikon A. Mnatsakanian|title=New Horizons in Geometry|date=2012|publisher=The Mathematical Association of America|isbn=9780883853542|page=197}} 12. ^{{cite journal|last1=Ruibin Qu|title=Generalized conic curves and their applications in curve approximation|journal=Approximation Theory and Its Applications|date=December 1997|volume=13|issue=4|pages=57–74}} 13. ^{{cite journal|last1=Mario Ponce, Patricio Santibánez|title=On equidistant sets and generalized conics: the old and the new|journal=The American Mathematical Monthly|date=January 2014|volume=121|issue=1|pages=18–32|url=https://www.researchgate.net/profile/Mario_Ponce2/publication/262963455_On_Equidistant_Sets_and_Generalized_Conics_The_Old_and_the_New/links/54b90ef90cf2c27adc491065.pdf|accessdate=10 November 2015|doi=10.4169/amer.math.monthly.121.01.018}} 14. ^{{cite web|last1=Csaba Vincze|title=Convex Geometry Chapter 10. Generalized Conics|url=http://www.tankonyvtar.hu/en/tartalom/tamop412A/2011_0025_mat_14/ch10.html|website=Digitalis Tankonyvtar|accessdate=17 December 2015}} Further reading
2 : Conic sections|Algebraic curves |
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