Calc 2 Lecture NotesSection 9.6Page 1 of 9
Section 9.6: Conic Sections
Big idea: The conic sections are a group of graphs (the point, line, circle, parabola, ellipse, and hyperbola) that share some amazing properties:
- Any of the graphs can be obtained from an intersection of a double cone and a plane.
- The graph of any quadratic equation in two variables is one of the conic sections.
- The graphs can be specified as a locus of points with special distance relationships to one or two points or a line.
- The graphs have useful reflection properties for light and sound waves.
- The graphs are the trajectories of an object moving under the influence of a central force (like gravity or a Coulomb force).
Big skill: You should be able to graph a conic section given in standard form.
The conic sections obtained as the intersection of a plane with a double cone.
This picture is from:
Weisstein, Eric W. "Conic Section." From MathWorld--A Wolfram Web Resource.
Circles
A circle is the locus of all points that are a given fixed distance from a given fixed point.
Derivation of the equation of a circle:
Let (h, k) be the given point and r be the fixed distance
For any point (x, y) on the circle,
= r
Practice:
- Graph the equation .
Parabolas
A parabola is the locus of all points that are equidistant from a given fixed point (called the focus) and a line (called the directrix).
Derivation of the equation of a parabola:
Let (h, k) be the focus and y = d be the directrix.
For any point (x, y) on the parabola,
Theorem 6.1: Equation of a parabola and its relation to geometry
The parabola with vertex at the point (b, c), focus at (b, c + 1/(4a)), and directrix given by the line y = c – 1/(4a) is described by the equation y = a(x – b)2 + c.
Practice:
- Graph the equation , and state the focus and directrix.
Ellipses
Anellipse is the locus of all points the sum of whose distances from two given fixed points (called the foci) is a constant.
Derivation of the equation of an ellipse:
Let the foci be on a horizontal line and equidistant from a central point (x0, y0), and let the sum of the distances from a point on the ellipse to the foci be a constant k.
For any point (x, y) on the ellipse,
If we let and , then we get .
Theorem 6.3: Equation of an ellipse and its relation to geometry
The equation , where ab > 0 describes an ellipse with the following properties:
Center at
Foci at , or (if ba), where
Vertices at and
Practice:
- Graph the equation
Hyperbolas
A hyperbola is the locus of all points the difference of whose distances from two given fixed points (called the foci) is a constant.
Derivation of the equation of a hyperbola:
Let the foci be on a horizontal line and equidistant from a central point (x0, y0), and let the sum of the distances from a point on the ellipse to the foci be a constant k.
For any point (x, y) on the hyperbola,
If we let and , then we get .
Theorem 6.4: Equation of a hyperbola and its relation to geometry
The equation describes a hyperbola with the following properties:
Center at
Foci at , where
Vertices at
Asymptotes
Practice:
- Graph the equation .
Hyperbola: Fold point F (a focus) onto the points of the circle centered at C.