Review 10.5-10.7 Conic Sections C E H P. General Form of a Conic Equation We usually see conic equations written in General, or Implicit Form: where A,

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Review Conic Sections C E H P

General Form of a Conic Equation We usually see conic equations written in General, or Implicit Form: where A, B, C, D, E and F are integers and A, B and C are NOT ALL equal to zero.

Please Note: A conic equation written in General Form doesn’t have to have all SIX terms! Several of the coefficients A, B, C, D, E and F can equal zero, as long as A, B and C don’t ALL equal zero. Linear! If A, B and C all equal zero, what kind of equation do you have? THINK......

So, it’s a conic equation if... the highest degree (power) of x and/or y is 2 (at least ONE has to be squared) the other terms are either linear, constant, or the product of x and y there are no variable terms with rational exponents (i.e. no radical expressions) or terms with negative exponents (i.e. no rational expressions)

What values form an Ellipse? The values of the coefficients in the conic equation determine the TYPE of conic. What values form a Hyperbola? What values form a Parabola?

Ellipses... NOTE: There is no Bxy term, and D, E & F may equal zero! where A & C have the SAME SIGN For example:

Ellipses... The General Form of the equations can be converted to Standard Form by completing the square and dividing so that the constant = 1. This is an ellipse since x & y are both squared, and both quadratic terms have the same sign! Center (-2, 0) Vert. Axis = √8 Hor. Axis = 2

Ellipses... In this example, x 2 and y 2 are both negative (still the same sign), you can see in the final step that when we divide by negative 4 all of the terms are positive. Vert. axis = 2/√3 Hor. axis = 2 center (-1, 1)

Ellipses…a special case! it is a... When A & C are the same value as well as the same sign, the ellipse is the same length in all directions … Circle! Center (- 2, 0) Radius = √5

Hyperbola... NOTE: There is no Bxy term, and D, E & F may equal zero! where A & C have DIFFERENT signs. For example:

Hyperbola... The General, or Implicit, Form of the equations can be converted to Graphing Form by completing the square and dividing so that the constant = 1. This is a hyperbola since x & y are both squared, and the quadratic terms have different signs! Center (2,-1) y-axis=3 x-axis=2

Hyperbola... In this example, the signs change, but since the quadratic terms still have different signs, it is still a hyperbola! Center (0,3) x-axis=2 y-axis=2

Parabola... A Parabola can be oriented 2 different ways: A parabola is vertical if the equation has an x squared term AND a linear y term; it may or may not have a linear x term & constant: A parabola is horizontal if the equation has a y squared term AND a linear x term; it may or may not have a linear y term & constant:

Parabola …Vertical The following equations all represent vertical parabolas in general form; they all have a squared x term and a linear y term:

Parabola …Vertical To write the equations in Standard Form, complete the square for the x-terms. There are 2 popular conventions for writing parabolas in Graphing Form, both are given below: Vertex (2,3)

Parabola …Vertical In this example, the signs must be changed at the end so that the y-term is positive, notice that the negative coefficient of the x squared term makes the parabola open downward. Vertex (-1,4)

Parabola …Horizontal The following equations all represent horizontal parabolas in general form, they all have a squared y term and a linear x term:

Parabola …Horizontal To write the equations in Standard Form, complete the square for the y-terms. There are 2 popular conventions for writing parabolas in Standard Form, both are given below: Vertex (1,-4)

Parabola …Horizontal In this example, the signs must be changed at the end so that the x-term is positive; notice that the negative coefficient of the y squared term makes the parabola open to the left. Vertex (3,0)

What About the term Bxy? None of the conic equations we have looked at so far included the term Bxy. This term leads to a hyperbolic graph: or, solved for y:

What About the term Bxy? You need to find the discriminant and use that to determine the conic section. The graph is a circle (A = C) or an ellipse (A ≠ C) If there is a Bxy term: The graph is a parabola The graph is a hyperbola

Summary... General Form of a Conic Equation: where A, B, C, D, E and F are integers and A, B and C are NOT ALL equal to zero. Identifying a Conic Equation:

Practice... Identify each of the following equations as a(n): (a) ellipse(b) circle(c) hyperbola (d) parabola(e) not a conic See if you can rewrite each equation into its Graphing Form!

Answers... (a) ellipse (b) circle (c) hyperbola (d) parabola (e) not a conic

Write the general from of the equation fo the translation of -6x x + 4y – 8 = 0 for T (-1, -2)

Identify the graph of each equation and then find θ Use this Formula: Ellipse

Identify the graph of each equation and then find θ Use this Formula: Hyperbola

Identify the graph of each equation and then find θ Use this Formula: Hyperbola

Solve this system of equations: Substitution: Step 1 Solve for a variable Step 2 Plug into other equation Not Factorable NO SOLUTION!!! Straight Line and a circle

Solve this system of equations: Substitution: Step 1 Solve for a variable Step 2 Plug into other equation Hyperbola And a straight line Step 3 Plug into step 1 to find the other variable Solution(s):

Solve this system of equations: ELIMINATION: Step 1 Make a new system Step 2 Combine to eliminate CRICLE And a ELLIPSE Step 3 Plug into first equation to find the other variable Solution(s):

Solve this system of equations: Elimination: Step 1 Re-write the system: Step 2 Combine to eliminate Hyperbola And a Ellipse Step 3 Plug into step 1 to find the other variable Solution(s):

Solve this system of equations: Substitution: Step 1 Solve for a variable Step 2 Plug into other equation circle And a straight line Step 3 Plug into step 1 to find the other variable Solution(s):