2. A conic is the intersection of a plane and a right circular cone. The four basic
types of conics are parabolas, ellipses, circles, and hyperbolas. We've
already discussed parabolas and circles in previous sections, but here we'll
define them a new way. Study the figures below to see how a conic is
geometrically defined.

4. In the conics above, the plane does not pass through the vertex of the cone.
When the plane does intersect the vertex of the cone, the resulting conic is
called a degenerate conic. Degenerate conics include a point, a line, and two
intersecting lines.
The equation of every conic can be written in the following form:
Ax2
+ Bxy + Cy2
+ Dx + Ey + F = 0.
This is the algebraic definition of a conic. Conics can be classified according to
the coefficients of this equation.
The determinant of the equation is B2
- 4AC. Assuming a conic is not
degenerate, the following conditions hold true: If B2
-4AC > 0, the conic is a
hyperbola. If B2
-4AC < 0, the conic is a circle, or an ellipse. If B2
- 4AC = 0, the
conic is a parabola.
Another way to classify conics has to do with the product of A and C. Assuming
a conic is not degenerate, the following conditions hold true: if AC > 0, the conic
is an ellipse or a circle. If AC < 0, the conic is a hyperbola. If AC = 0, and A
and C are not both zero, the conic is a parabola. Finally, if A = C, the conic is a
circle.
In the following sections we'll study the other forms in which the equations for
certain conics can be written, and what each part of the equation means
graphically.

6. Analytic geometry is roughly the same as plane geometry except that in analytic
geometry, figures are studied in the context of the coordinate plane. Instead of
focusing on the congruence of shapes like plane geometry, analytic geometry
deals with the coordinates of shapes and formulas for their graphs in the
coordinate plane. Much of analytic geometry focuses on the conics. A conic is a
two-dimensional figure created by the intersection of a plane and a right circular
cone. All conics can be written in terms of the following equation:
Ax2
+ Bxy + Cy2
+ Dx + Ey + F = 0.
The four conics we'll explore in this text are parabolas, ellipses, circles, and
hyperbolas. The equations for each of these conics can be written in a standard
form, from which a lot about the given conic can be told without having to graph
it. We'll study the standard forms and graphs of these four conics, as well as the
polar equations for the conics, which are useful for certain applications.

7. Analytic geometry is roughly the same as plane geometry except that in analytic
geometry, figures are studied in the context of the coordinate plane. Instead of
focusing on the congruence of shapes like plane geometry, analytic geometry
deals with the coordinates of shapes and formulas for their graphs in the
coordinate plane. Much of analytic geometry focuses on the conics. A conic is a
two-dimensional figure created by the intersection of a plane and a right circular
cone. All conics can be written in terms of the following equation:
Ax2
+ Bxy + Cy2
+ Dx + Ey + F = 0.
The four conics we'll explore in this text are parabolas, ellipses, circles, and
hyperbolas. The equations for each of these conics can be written in a standard
form, from which a lot about the given conic can be told without having to graph
it. We'll study the standard forms and graphs of these four conics, as well as the
polar equations for the conics, which are useful for certain applications.