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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Find the value of $\lambda$ that maximises the area of a triangle on a hyperbola.

Consider the hyperbola: $$ \frac{x^2}{4} - \frac{y^2}{36}=1$$ $l_1$ and $l_2$ are the asymptotes Consider a case where $P$ is located in the first quadrant. Through $P$, draw another line $CD$, where $C$ is on line $l_1$, D is on line $l_2$, and…
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Condition for two conics to intersect in four concyclic points

I am facing trouble with the following question What is the condition that the two conic sections $ax_1^2+2h_1xy+b_1y^2+2g_1x+2f_1y+c_1=0$ and $ax_2^2+2h_2xy+b_2y^2+2g_2x+2f_2y+c_2=0$ intersects each other in four concyclic points. I took the four…
Navin
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locus of the point of intersection of tangents drawn at the extremities of a normal chord of the parabola $y^2=-8x$

The locus of the point of intersection of tangents drawn at the extremities of a normal chord of the parabola $y^2=-8x$ is a curve having asymptote at $x$=...? Let one end of the normal chord be $(-2t^2,-4t)$,then the other parametric coordinate of…
Navin
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A proof related to ellipse.

A tangent is drawn to the ellipse $\frac{x^2}{a^2}+\frac{y^2}{b^2}=1$ to cut the ellipse $\frac{x^2}{c^2}+\frac{y^2}{d^2}=1$ at the points $P$ and $Q$. If tangents at $P$ and $Q$ to the ellipse $\frac{x^2}{c^2}+\frac{y^2}{d^2}=1$ intersect at right…
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Equation of an ellipse word problem

Good day, the problem is this : The distance of Jupiter from the sun ranges from 741 million km to 816 million km. Find the equation of its elliptical orbit where the sun is one of the foci. Assume again that the center is the origin and its major…
Codex
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Tangents to a parabola that go through the same point

The question is: The two lines tangent to f (x) = $x^2$ + 4x + 2 through the point (2, -12)have equations y = ax + b and y = cx + d, respectively. What is the value of a + b + c + d? What I did to solve it: f '(x) = 2x + 4. The point is (2 -12) so I…
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What is the name of this "ellipse"?

When I was in school, I learned what a circle was. Later, I learned what an ellipsis was. I also discovered that a circle is a particular case of ellipse (both foci at the same location). Now, I'm pretty sure mathematicians have already studied…
Stephan
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Another parabola turning point

I have come across another one I am unable to do- I believe I am able to solve it but it doesn't work with the y-intercept I got. Please tell me how to solve for the turning point: $$y=-x^2-2x+15$$ For the y-intercept I got (0,15) and it is a…
Kiwi
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Tangent; Parabola; Shifted; Normal; Shortes distance

I have a few questions on the topic of parabola. Here , they are : 1. What is the correct/easiest way to find the equation of (i)a tangent (ii) a normal to/of any shifted/rotated parabola.?I know the equations of standard ones ($ y^2 = 4ax $and…
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$3$ distinct normals to the given parabola

If $(h,k)$ be the point on the parabola $\displaystyle (x-1)^2+(y-1)^2 = \frac{(x+y+2)^2}{2}$ from where $3$ Distinct normal can be drawn to the parabola, Then $\min$ positive integer value of $h$ Here $(1,1)$ be the focus of the parabola and…
juantheron
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Let $P$ (with $x$ coordinate $p$) be any point on the hyperbola. A tangent from $P$ strikes the $x$ axis at $(q,0)$. Prove $pq=a^2$

The question is , Let $P$ (with $x$ coordinate $p$) be any point on the hyperbola $x^2/a^2-y^2/b^2 =1$. A tangent from $P$ strikes the $x$ axis at $(q,0)$. Prove $pq=a^2$ What I have tried: Say that the there is a point $(p,k)$ which lies on…
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Two tangents to the hyperbola $4x^2-y^2=36$ intersect at the point $(0,4)$. Find the coordinates for the points on the hyperbola for this to occur.

The question is two tangents to the hyperbola $4x^2-y^2=36$ intersect at the point $(0,4)$. Find the coordinates for the points on the hyperbola for this to occur. My attempt: Consider the line $y=mx+c$ as it passes through $(0,4)$ then $c=4$ -->…
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integer points on conics

The following lines are from Schinzels paper "integer points on conics" Let $ax^2 + bxy + cy^2 + dx + ey +f = 0$ be a non-degenerate conic over integers. Setting $X= \delta x+be-2cd$, $Y=\delta y+bd-2ae$, where $\delta=b^2-4ac$, we get $$aX^2…
paris
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What is the equation of this hyperbola?

What is the equation of the hyperbola that satisfies these conditions: Asymptotes $y=2x$ and $y=-2x$, centre $(0,0)$, and the point $(1,1)$ lies on the curve. This isn't a homework question; I study maths for the fun of it. The question is taken…
Blakes7
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How do I find the left end height of an ellipse tilted at the right end?

Let's say I have a large ellipse on a flat ground as shown in Figure 1 and 2 below. Angles DBC and ABD are right-angles and the longest radius with respect to the ground, BD is perpendicular to line ABC and the flat ground. The ellipse is in a…