Parabola: Difference between revisions

Revision as of 01:59, 10 December 2007

Synthetically, a parabola is the locus of points in a plane that are equidistant from a given line (the directrix) and a given point (the focus). Alternatively, a parabola is a conic section obtained as the intersection of a right circular cone with a plane parallel to a generator of the cone.

Let $d$ be a line and $F$ a point. In the special case when $F$ is a point of $D$ , the "parabola" with directrix $D$ and focus $F$ is the line through $F$ that is perpendicular to $D$ . In the language of conic sections, this corresponds to the case when the plane contains a generator of the cone.

To avoid this degenerate case, assume that $F$ does not lie in $D$ , let $\Pi$ be the unique plane containing $F$ and $D$ and let $P$ be the parabola with focus $F$ and directrix $d$ . The line $s$ through $F$ and perpendicular to $D$ is called the axis of the the parabola $P$ and is the unique line of symmetry of $P$ . The unique point $V$ of $s$ that is equidistant from $F$ and $D$ lies on $P$ and is known as the vertex of the parabola, and the distance $FV$ (half the distance from $F$ to $D$ ) is called the focal distance of the parabola.

Now let $P'$ be any other parabola in $\Pi$ be with the same focal distance as $P$ . Let $F'$ be its focus and $D'$ its directrix. Then there is a unique, orientation-preserving rigid motion of $\Pi$ taking $F$ to $F'$ and $D$ to $D'$ and therefore, the parabola $P$ to the parabola $P'$ . In other words, any two parabolas with the same focal distance are congruent.

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 Synthetically, a parabola is the locus of points in a plane that are equidistant from a given line (the ''directrix'') and a given point (the ''focus'').  Alternatively, a parabola is a [[conic section]] obtained as the intersection of a right circular cone with a plane parallel to a generator of the cone.
-Let <math>d</math> be a line and <math>F</math> a point.  In the degenerate when <math>F</math> is a point of <math>d</math>, the "parabola" with directrix <math>d</math> and focus <math>F</math> is the line through <math>F</math> that is perpendicular to <math>d</math>.  In the language of conic sections, this corresponds to the case when the plane contains a generator of the cone.
+Let <math>d</math> be a line and <math>F</math> a point.  In the special case when <math>F</math> is a point of <math>D</math>, the "parabola" with directrix <math>D</math> and focus <math>F</math> is the line through <math>F</math> that is perpendicular to <math>D</math>.  In the language of conic sections, this corresponds to the case when the plane contains a generator of the cone.
-To avoid the degenerate case, assume that <math>F</math> does not lie in <math>d</math>, let <math>\Pi</math> be the unique plane containing <math>F</math> and <math>d</math> and let <math>P</math> be the parabola with focus <math>F</math> and directrix <math>d</math>.  The line <math>s</math> through <math>F</math> and perpendicular to <math>d</math> is called the ''axis'' of the the parabola <math>P</math> and is the unique line of symmetry of <math>P</math>.  The unique point <math>V</math> of <math>s</math> that is equidistant from <math>F</math> and <math>d</math> lies on <math>P</math> and is known as the ''vertex'' of the parabola, and the distance <math>FV</math> is called the ''focal distance'' of the parabola.
+To avoid this degenerate case, assume that <math>F</math> does not lie in <math>D</math>, let <math>\Pi</math> be the unique plane containing <math>F</math> and <math>D</math> and let <math>P</math> be the parabola with focus <math>F</math> and directrix <math>d</math>.  The line <math>s</math> through <math>F</math> and perpendicular to <math>D</math> is called the ''axis'' of the the parabola <math>P</math> and is the unique line of symmetry of <math>P</math>.  The unique point <math>V</math> of <math>s</math> that is equidistant from <math>F</math> and <math>D</math> lies on <math>P</math> and is known as the ''vertex'' of the parabola, and the distance <math>FV</math> (half the distance from <math>F</math> to <math>D</math>) is called the ''focal distance'' of the parabola.
-Now let <math>F'</math> be a point in <math>\Pi</math> and <math>d'</math> a line in <math>\Pi</math> such that the distance from <math>F'</math> to <math>d'</math> equals the distance from <math>F</math> to <math>d</math>.  Then there is a unique, orientation-preserving rigid motion of <math>\Pi</math> taking <math>F</math> to <math>F'</math> and <math>d</math> to <math>d'</math> and therefore, the parabola <math>P</math> to the parabola with focus <math>F'</math> and directrix <math>d'</math>.  In other words, any two parabolas with the same focal distance are congruent.
+Now let <math>P'</math> be any other parabola in <math>\Pi</math> be with the same focal distance as <math>P</math>.  Let <math>F'</math> be its focus and <math>D'</math> its directrix.  Then there is a unique, orientation-preserving [[rigid motion]] of <math>\Pi</math> taking <math>F</math> to <math>F'</math> and <math>D</math> to <math>D'</math> and therefore, the parabola <math>P</math> to the parabola <math>P'</math>.  In other words, any two parabolas with the same focal distance are congruent.

Parabola: Difference between revisions

Revision as of 01:59, 10 December 2007

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