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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How to find all the parameters of an ellipse from its general equation of conic?

I have an ellipse in the form $ax^2+bxy+cy^2+dx+ey+f=0$ and from this how would I find the length of the semi major and minor axis, the tilt, and the center of it? I made an ellipse fitting code to give me the values of (a,b,c,d,e,f) But I need to…
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Best fit of ellipse with given size to a set of points

A few months ago, I created this post in which I wanted to fit an ellipse with a fixed inclination and size to a set of points: Best fit of ellipse with given size and tilt to a set of points Now I would like to adapt this by including the fact that…
B Legu
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Intersection of two parabolas with perpendicular axis

Let there be two parabolas: $$y^2+2kx=k^2 \tag{1}$$ $$x^2+2ky=k^2 \tag{2}$$ What will be the point of intersection of these two curves? The general form of intersection of such two curves would lead to solving a quartic equation(a lengthy solution),…
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Where does $c^2=a^2-b^2$ come from for ellipsis?

$c^2=a^2-b^2$ is used when determining the foci of an ellipsis. However, it is unclear where this formula arises from. It is not at all intuitive for me. A previous answer I found on Stack Exchange was the following: Solution Using the diagram…
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Shortest distance of point $P$ on parabola from fixed point $Q$

If $P(a,b)$ be any point in the curve $y^2=6x$. Then find shortest distance of point $P(a,b)$ from point $\displaystyle Q(3,\frac{3}{2})$ and also find $2(a+b)$ Given point $P(a,b)$ in curve $y^2=6x.$ Then we have $b^2=6a\cdots \cdots (1)$ And…
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Prove that the tangent line at the vertex of a parabolic segment is parallel to the chord

Regarding the quadrature of the parabola: In a parabolic segment (the area enclosed by a parabola and a chord that intersects it), the vertex is defined as that point on the parabola which is "perpendicularly" furthest away from the chord. (That…
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Where does the light reflected inside the ellipse touch the orbit of the ellipse?

Here is the Ellipse Image I know the length of the Major axis and the Minor axis of the ellipse. I know the $x$ and $y$ coordinates of random points. We know the $x,y$ coordinates at the point where the tangent meets the orbit of the ellipse. At…
Amour Math
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Convert this ellipse equation, $2x^2 + 6xy + 5y^2 = 1$ into standard form.

I have tried this first I took $x^2 + y^2 + 2xy$ on side and on the other side $x^2 + 4y^2 + 4xy$ and I complete square on both and this becomes $(x+y)^2 + (x + 2y)^2 = 1$ but this two line are not perpendicular to each other.
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Ensuring tangency between two ellipses

we know that two tangent circles of centers $(x_{1},y_{1})$ and $(x_{2},y_{2})$, radii $r_{1}$ and $r_{2}$ will have to respect this formula : $$ (x_{1}-x_{2})^2+(y_{1}-y_{2})^2=(r_{1} \pm r_{2})^2 $$ Is there a similar formula for two tangent…
Charles
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Eccentric Angle of hyperbola

Lets say, a vertical hyperbola whose transverse axis is $y$ axis. Its parametric coordinates $(a\tan \theta, b\sec \theta)$. This $\theta$ represents the eccentric angle related with auxiliary circle. If any point of the hyperbola is located in the…
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Where can I find good resources explaining conic sections?

I'm looking for something that explains them simply or something that has a lot of examples. The online course I'm taking doesn't explain them in much detail and I haven't managed to find something that explains it better. Mainly parabolas and…
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Are conics completely defined by a single parameter - eccentricity?

Are all conics completely defined (up to rotation, translation, and dilation) by a single parameter, their eccentricity? I believe this to be true but am surprised that this fact is not more widely identified. This means, for examples, that all of…
SRobertJames
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Consider two circles S1 and S2 given by $x^4 + y^4 +2x^2y^2-10x^2+6y^2+9=0 $? How can I separate the circles?

I recently gave a test and had this question there . To be honest I was confused on seeing this question. I was unable to even deduce the approach. I am a student studying in class 11 so I don't have access to desmos during tests.
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Is there a shortcut to get the second directrix of an ellipse in polar form?

The general form for conics in polar coordinates indicate only one directrix depending on the type of equation. With ellipses, to my knowledge there are suppose to be two directrices. I've tried to do an equation of an ellipse in Geogebra, where…
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Locus of intersection of a pair of variable straight lines $x^2+4y^2+\alpha xy=0$ with ellipse $x^2+4y^2=4$

If a pair of variable straight lines $x^2+4y^2+\alpha xy=0$ (where α is a real parameter) cuts the ellipse $x^2+4y^2=4$ at two points A and B, then the locus of the point intersection of tangents at A and B is… ${x^2} + 4{y^2} + \alpha xy =…