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3.3 Quadratic Functions

3.3 Quadratic Functions. Objectives: Define three forms for quadratic functions. Find the vertex and intercepts of a quadratic function and sketch its graph. Convert one form of a quadratic function to another. Parabolas. vertex.

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3.3 Quadratic Functions

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  1. 3.3 Quadratic Functions Objectives: Define three forms for quadratic functions. Find the vertex and intercepts of a quadratic function and sketch its graph. Convert one form of a quadratic function to another.

  2. Parabolas vertex The graph of a quadratic function is called a parabola and it always: Opens upward or downward Has a vertex which is a maximum or minimum Has exactly 1y-intercept Has either 0, 1, or 2 x-intercepts Is symmetric through its vertex x-intercepts y-intercept Line of Symmetry

  3. The Three Forms of a Quadratic Function • Transformation Form (Vertex Form): f(x) = a(x – h)2 + k • Polynomial Form (Standard Form): f(x) = ax2 + bx + c • x-Intercept Form (Factored Form): f(x) = a(x – s)(x – t)

  4. Graphing from the Three Quadratic Forms

  5. Example #1Transformation Form f(x) = a(x – h)2 + k • Find the vertex and the x- and y-intercepts for the following function. Then graph the function. Vertex: (h, k) x-Intercept: Let f(x) = 0 y-Intercept: Let x = 0 Vertex: (2, 5) x-intercept: y-intercept: The graph opens down because a is negative.

  6. Example #2Polynomial Form f(x) = ax2 + bx + c • Find the vertex and the x- and y-intercepts for the following function. Then graph the function. • The vertex can be found from polynomial form using: The graph opens up because a is positive.

  7. Example #2Polynomial Form f(x) = ax2 + bx + c • Find the vertex and the x- and y-intercepts for the following function. Then graph the function. • x-Intercept: Let f(x) = 0 • y-Intercept: c 5

  8. Example #3x-Intercept Form f(x) = a(x – s)(x – t) • Find the vertex and the x- and y-intercepts for the following function. Then graph the function. Vertex: Graph opens down because a is negative.

  9. Example #3x-Intercept Form f(x) = a(x – s)(x – t) • Find the vertex and the x- and y-intercepts for the following function. Then graph the function. x-Intercept: s & t y-Intercept: ast

  10. Example #4Changing to Polynomial and x-Intercept Form • Write the following functions in polynomial and x-intercept form, if possible. Polynomial: x-intercept: Since the discriminant is negative there are no x-intercepts so the function cannon be written into x-intercept form.

  11. Example #4Changing to Polynomial and x-Intercept Form • Write the following functions in polynomial and x-intercept form, if possible. Polynomial: Already in polynomial form. x-intercept:

  12. Example #4Changing to Polynomial and x-Intercept Form • Write the following functions in polynomial and x-intercept form, if possible. Polynomial: x-intercept: Already in x-intercept form.

  13. Example #5Changing to Transformation Form • Write the following functions in transformation form: To write into transformation form we must use completing the square. First factor out the a term. Then complete the square and add this value to the inside of the parentheses. Because of the -5 out front we are subtracting 9/5 so we must add 9/5 to the outside to keep it balanced.

  14. Example #5Changing to Transformation Form • Write the following functions in transformation form:

  15. Example #6Maximum Area for a Fixed Perimeter • Find the dimensions of a rectangular parking lot that can be enclosed with 2400 feet of fence and that has the largest possible area. The largest area would occur if the parking lot were a square with 600 ft on each side and an area of 360,000 square feet.

  16. Example #6Maximum Area for a Fixed Perimeter • Find the dimensions of a rectangular parking lot that can be enclosed with 2400 feet of fence and that has the largest possible area. Let x = length & y = width Perimeter = x + x + y + y = 2x + 2y Area = xy This is a parabola opening downward so the maximum area should occur at its vertex.

  17. Example #7Maximizing Profit • The owner of a concession stand sells 150 lunches per day at a price of $3 each. The cost to the owner is $2.25 per lunch. Each $0.25 price increase decreases sales by 30 lunches per day. What price should be charged to maximize profit? x = number of $0.25 price increases The profit on each lunch is then 0.25x +0.75 The number of lunches sold per day is 150 – 30x Total Profit: P(x) = (0.25x + 0.75)(150 – 30x) $3 – $2.25 = $0.75 per lunch

  18. Example #7Maximizing Profit • The owner of a concession stand sells 150 lunches per day at a price of $3 each. The cost to the owner is $2.25 per lunch. Each $0.25 price increase decreases sales by 30 lunches per day. What price should be charged to maximize profit? The maximum profit occurs with just one price increase with each lunch priced at $3.25.

  19. Example #8Number Problems • Find two numbers whose difference is 7 and whose product is a minimum. Even though is problem is looking for a minimum, the function is still a parabola so the vertex will be the lowest point. The two numbers are 3.5 and −3.5.

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