Questions tagged [conic-sections]

For questions about circles, ellipses, hyperbolas, and parabolas. These curves are the result of intersecting a cone with a plane.

A conic section is a smooth planar curve that is the result of intersecting a cone with a plane. There are commonly four conic sections: circles, ellipses, parabolas, and hyperbolas.

We can construct these conic sections analytically. The solutions to the equation $x^2+y^2=z^2$ give us a cone in three-dimensional space. An plane in three-dimensional space that goes through a point $p=(x_0,y_0,z_0)$ and has normal vector $\langle a,b,c \rangle$ is given by the equation

$$a(x-x_0)+b(y-y_0)+c(z-z_0)=0\,.$$

Finding the common solutions to the equation of the cone and equation of the plane for various choices of $p$ and normal vector will—after a change in coordinates to write them as planar curves—lead you to the (potentially) familiar equations

  • Circle: $x^2+y^2 = r^2$
  • Ellipse: $ax^2 + b y^2 = r^2$, where $a,b>0$
  • Parabola: $ax^2 +by = r^2$, where $a\neq 0$
  • Hyperbola: $ax^2 - by^2 = r^2$, where $a,b>0$

There are also geometric constructions of the conic sections. For example, a circle is the set of all points that are a fixed distance from a given points. An ellipse is the set of all points .... The construction of Dandelin spheres (see Wikipedia) unifies the analytic and geometric constructions of conic sections.

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Finding standard equation of parabola with only one vertext coordinate?

I can't seem to figure this problem out, there doesn't seem to be enough information. Find the standard equation of the parabola that has a vertical axis that has $x$-intercepts $-5$ and $3$ and has a lowest point with a $y$-coordinate of $-7$. I…
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Range of angle made by focal chord of a parabola at the vertex.

How to determine the range of angle which a focal chord of a parabola (considering a standard parabola $ y^2 =4ax $) subtend at the vertex. My attempt:Take $ t_1$ and $ t_2$ two points on the para bola. We have the relation $ t_1 t_2 =-1$. How to…
Pratyush
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Deriving the quadratic equation

Is there an elegant way to derive the quadratic equation from the definition of a parabola? In other words, how can it be proven that the set of all points an equal distance away from a focus and a diretrix forms a curve that can be represented by…
margalo
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Prove: If the five points of a conic are rational, then it contains infinitely many rational points.

Sketch a proof: If the five points of a conic are rational, then it contains infinitely many rational points. In class, we learned about Pascal's Theorem for a hexagon inscribed in a conic. The hexagon may be inscribed in a conic iff the three…
user380668
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Overlapping ellipses centered at origin:

Imagine there are two unrotated ellipses in 2d with different major and minor axes (that is to say different ellipses, but also consider case where ellipses have proportional major and minor axes, so same ellipses just that one is bigger than the…
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Equation for x-axis 3D paraboloid

I've been playing around with plenty of variants of paraboloid equations. However I couldn't come up with the equation for a x-axis parallel 3D paraboloid of revolution. For a 2D parabola the equation $$ (y-y_p)^2 = 4p(x-x_p)$$ is derived…
Daniyal
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Focus of ellipse

If we are given an ellipse with centre (3,4) touches the x axis at (0,0) and if slope of major axis is 1 . Then we have to find the focus of the ellipse . I tried to rotate the ellipse . But i am not able to proceed . Can anybody help me in…
Koolman
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Showing that $\textbf{a} \cos \omega t + \textbf{b} \cos \omega t$ traces out an ellipse where $\textbf{a}$ and $\textbf{b}$ are arbitrary vectors.

As in the title, if $\textbf{a}$ and $\textbf{b}$ are vectors in the $x-y$ plane, then the parametrised form (with parameter $t$) $\textbf{a} \cos \omega t + \textbf{b} \cos \omega t$ traces out an ellipse. I wrote $\textbf{a} = a_x \textbf{i} + a_y…
user110503
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approximate an ellipse using straight lines of equal length - with closure

I'd like to construct (i.e. graph using a computer program) an ellipse from straight lines of equal length. With closure - i.e. without any gaps in the perimeter. I know that straight lines of equal length will not result in the best approximation…
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An ellipse meets a hyperbola that the tangent lines at the points of intersection are perpendicular to each other . Show that $a^2-b^2=c^2+d^2$

Question: $\frac{x^2}{a^2} + \frac{y^2}{b^2}=1 $ meets $\frac{x^2}{c^2} - \frac{y^2}{d^2}=1$ in such a way that the tangent lines at the points of intersection are perpendicular to each other. Show that $a^2-b^2=c^2+d^2$ I've been stuck on a…
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Complex Numbers, Square, Conics

On the Argand diagram, $P$ represents the complex number $z$, and $R$ the number $\frac{1}{z}$ A square $PQRS$ is drawn in the plane with $PR$ as a diagonal If $P$ lies on the circle $|z| = 2$, (I) Prove that $Q$ will lie on the ellipse whose…
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Calculate the Y value of an arc of an ellipse given X

Before I say anything else, let me just state, that I am only in high school and going in Precalculus this upcoming school year, which is probably why I am having this issue in the first place. And if any more information is needed, just let me…
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Finding a point on a ellipse so that it has the shortest distance between this point and another given point

Possible Duplicate: Calculating Distance of a Point from an Ellipse Border Given a point $A = (x_1, y_1)$ and a $2$D ellipse, how could we find a point $B = (x_2, y_2)$ on the ellipse so that it has the shortest distance between point $A$ and…
Jin
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Find the length of the chord joining the points in which the straight line $\frac{x}{a} + \frac{y}{b}= 1$ meets the circle $x^2+y^2=r^2$

Question: Find the length of the chord joining the points in which the straight line $\frac{x}{a} + \frac{y}{b}= 1$ meets the circle $x^2+y^2=r^2$ My initial thoughts were rearranging the straight line equation into the form of $y=mx+c$ which…
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Given the width and height of an ellipse find n number of points around the ellipse?

I am looking to find $n$ number of points around an ellipse. They don't necessarily have to be equidistant. Similar to what this forum is asking: I found several answers that are similar but I am having a hard time expressing it in code.