Examples of directrix in the following topics:
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- Recall that hyperbolas and non-circular ellipses have two
foci and two associated directrices, while parabolas have one focus and one
directrix.
- In the next figure, each type of conic section is graphed with a focus and directrix.
- The orange lines denote the distance between the focus and points on the conic section, as well as the distance between the same points and the directrix.
- In other words, the distance between a point on a conic section and its focus is less than the distance between that point and the nearest directrix.
- This indicates that the distance between a point on a conic section the nearest directrix is less than the distance between that point and the focus.
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- Previously, we learned how a parabola is defined by the focus (a fixed point) and the directrix (a fixed line).
- We can define any conic in the polar coordinate system in terms of a fixed point, the focus $P(r,θ)$ at the pole, and a line, the directrix, which is perpendicular to the polar axis.
- With this definition, we may now define a conic in terms of the directrix: $x=±p$, the eccentricity $e$, and the angle $\theta$.
- For a conic with a focus at the origin, if the directrix is $x=±p$, where $p$ is a positive real number, and the eccentricity is a positive real number $e$, the conic has a polar equation:
- Any conic may be determined by three characteristics: a single focus, a fixed line called the directrix, and the ratio of the distances of each to a point on the graph.
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- For example, each type has at least one focus and directrix.
- A directrix is a line used to construct and define a conic section.
- As with the focus, a parabola has one
directrix, while ellipses and hyperbolas have two.
- The point halfway between the focus and the directrix is called the vertex of the parabola.
- The vertex lies at the midpoint between the directrix and the focus.
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- One of the most useful definitions, in that it involves only the plane, is that a conic consists of those points whose distances to some point—called a focus—and some line—called a directrix—are in a fixed ratio, called the eccentricity.
- In the focus-directrix definition of a conic, the circle is a limiting case with eccentricity 0.
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- There are a number of other geometric definitions possible, one of the most useful being that a conic consists of those points whose distances to some other point (called a focus) and some other line (called a directrix) are in a fixed ratio, called the eccentricity.
- In the focus-directrix definition of a conic, the circle is a limiting case with eccentricity 0.
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- All parabolas have a directrix.
- The directrix is a straight line on the opposite side of the parabolic curve from the focus.
- The parabolic curve itself is the set of all points that are equidistant (equal distances) from both the directrix line and the focus.
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- The eccentricity e equals the ratio of the distances from a point P on the hyperbola to one focus and its corresponding directrix line (shown in green).
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- It also shows how the sum of the distances from any point on the ellipse to the two foci is a constant, and how the eccentricity is determined by relating one of the foci to a line $D$ called the directrix.
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- The set of all points such that the ratio of the distance to a single focal point divided by the distance to a line (the directrix) is greater than one
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- In the focus-directrix definition of a conic, the circle is a limiting case of the ellipse with an eccentricity of $0$.