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If you’ve ever cooked food with a parabolic oven in science class or seen the Death Star’s laser in Star Wars , you have an idea of what the focal point (or focus) of a parabola is. But how do you calculate the focus mathematically? We’ve provided the formulas and equations you need to find the focus of any parabola, and added several helpful sample problems that you might see on your next algebra exam! [1] X Research source
Things You Should Know
- Depending on the type of parabola, use the equation or to determine the parabola’s vertex coordinates. [2] X Research source
- Once you have the vertex coordinates, use the formula or to calculate the graph coordinates of the focus.
Steps
Section 1 of 4:
What terms (like “parabola”) should I know?
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Parabola: A parabola can be defined as the graph of a quadratic equation —that is, the curved line you’ll get if you plot the equation on graph paper. Or, if you want to be more technical, it’s a curved line in which all coordinate points along the line are equidistant from a specific focal point and a specific line called a directrix. [3] X Research source
- In practical terms, it’s often easier to recognize parabolas in three dimensions. For example, think of large parabolic satellite dishes, or the clear plastic parabolic microphones you see on the sidelines of football games. Both of these direct waves (radio, sound, etc.) toward a single point—the focal point (or focus). [4] X Research source
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Vertex: The vertex is the “turning point” of a parabola—the point along the curve at which it changes direction. So, in a classic “U”-shaped parabola, the vertex is at the very bottom of the “U” shape. You need to know the coordinates of the vertex in order to find the coordinates of the focus. [5] X Research source
- Although they’re coordinates, you’ll see the vertex coordinates represented by in parabola equations and formulas.
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Axis of symmetry: The axis of symmetry is a line that runs through the vertex point and divides the parabola exactly in half. The parabola is a mirror image of itself on either side of the axis of symmetry. [6] X Research source
- For our needs, it’s also important that the vertex is always exactly halfway between the focus and the directrix along the axis of symmetry. [7] X Research source
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Directrix: The directrix is a straight line that crosses the axis of symmetry and is perpendicular to it. The directrix is always outside of the parabola but closest to the vertex. For example, in a classic “U” parabola, adding the directrix line makes it look like you underlined the "U." [8] X Research source
- The distance between the vertex and the directrix (at the axis of symmetry) is always exactly the same as that between the vertex and the focus. [9] X Research source
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Focus: The focus is a point along the axis of symmetry, inside the parabola, that is equal in distance from the vertex as is the directrix. So, if the directrix is 2 units away from the vertex, the focus is also 2 units away (and, as a result, 4 units away from the directrix). [10] X Research source
- If you draw a straight line from the focus to any point along the curve of the parabola, and then draw a straight line from that point to intersect at a right angle with the directrix, you’ll find that both of those lines are always equal in length.
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Section 2 of 4:
Which equations/formulas do I use?
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or . You’ll use one of these “vertex form of a parabola” equations based on the type of parabola you’re dealing with. A “regular” parabola that opens upward or downward (like a right-side up or upside-down “U”) needs to be converted into the form of the first equation, while a “sideways” parabola that opens to the side (like a forwards or backwards “C”) must be converted to the second. [11] X Research source
- If you have a graph of the parabola, it’s easy to tell which equation to use. But what if you’re only given the parabola in equation form? Here’s the trick to use:
- If the component is squared in the parabola’s equation—for example —convert it into the form .
- If the component is squared (like in ), use .
- In both equations, represent the coordinates of the parabola’s vertex, and represents its slope. [12] X Research source
- If you have a graph of the parabola, it’s easy to tell which equation to use. But what if you’re only given the parabola in equation form? Here’s the trick to use:
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or . Once you have determined (or have been given) the coordinates of the parabola’s vertex, you’ll use one of these formulas to determine the coordinates of the focus. Here’s how to know which to use: [13] X Research source
- Use for a “regular” parabola in form .
- Use for a “sideways” parabola in form .
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Section 3 of 4:
Example Walk-Through: y=x^2
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Put the equation into the vertex form of a parabola. Because the portion of the equation is squared, the correct vertex form is , meaning this is a “regular” parabola (it opens either up or down). [14] X Research source
- →
- Also note that, because is positive, the parabola opens upward.
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Identify the vertex and the focus equation. In , both and equal zero .
- That means the focus equation is →
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Solve for to find the focus coordinates.
- in
- So, the focus equation is
- Therefore, the focus of is at
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Section 4 of 4:
More Examples
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Find the focus of the parabola . This is a “sideways” parabola because the component is squared, so use the vertex form and the focus equation .
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→
- Vertex ,
- → →
- Answer: The focus is located at .
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→
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Find the focus of the parabola . Here’s another “sideways” parabola because the y component is squared, so use the vertex form and the focus equation .
- Put
in
form:
- →
- Vertex ,
- →
- →
- Answer: The focus is located at .
- Put
in
form:
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Find the focus of the parabola . This one’s a “regular” parabola (the component is squared), so use and .
- Put
in the proper form:
- →
- Vertex ,
- →
- →
- Answer: The focus is located at
- Put
in the proper form:
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Find the focus of the parabola . It’s another “regular” parabola, which means you use and .
- Put
in the proper form:
- →
- Vertex ,
- →
- → →
- Answer: the focus is located at [15] X Research source
- Put
in the proper form:
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References
- ↑ https://study.com/learn/lesson/parabola-focus-directix-formula-examples.html
- ↑ https://study.com/learn/lesson/parabola-focus-directix-formula-examples.html
- ↑ https://www.mathsisfun.com/geometry/parabola.html
- ↑ https://study.com/learn/lesson/parabola-focus-directix-formula-examples.html
- ↑ https://www.mathsisfun.com/geometry/parabola.html
- ↑ https://www.purplemath.com/modules/parabola.htm
- ↑ https://study.com/learn/lesson/parabola-focus-directix-formula-examples.html
- ↑ https://www.mathsisfun.com/geometry/parabola.html
- ↑ https://www.cuemath.com/geometry/focus-of-parabola/
- ↑ https://www.purplemath.com/modules/parabola.htm
- ↑ https://www.purplemath.com/modules/parabola.htm
- ↑ https://www.cuemath.com/geometry/focus-of-parabola/
- ↑ https://www.purplemath.com/modules/parabola.htm
- ↑ https://www.cuemath.com/geometry/focus-of-parabola/
- ↑ https://www.cuemath.com/geometry/focus-of-parabola/
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