The function y = -0.03(x - 14)^2 + 6 models the mump of a red kangaroo where x is the horizontal distance in meters and y is the vertical distance in meters for the height of the jump. What is the kangaroo's maximum height? How long is the kangaroo's jump?

Sagot :

Answer:

Kangaroo's maximum height is 6 m and the kangaroo's jump is 28 m long

Step-by-step explanation:

Given :[tex]y = -0.03(x - 14)^2 + 6[/tex]

To Find : What is the kangaroo's maximum height? How long is the kangaroo's jump?

Solution:

[tex]y = -0.03(x - 14)^2 + 6[/tex]

x is the horizontal distance in meters

y is the vertical distance in meters for the height of the jump.

Substitute y = 0

[tex]0 = -0.03(x - 14)^2 + 6[/tex]

[tex]0.03(x - 14)^2 = 6[/tex]

[tex](x - 14)^2 = \frac{6}{0.03}[/tex]

[tex](x - 14)^2 =200[/tex]

[tex](x - 14) =\sqrt{200}[/tex]

[tex](x - 14) =14.142[/tex]

[tex]x =14.142+14[/tex]

[tex]x =28.142[/tex]

x≈ 28 m

Now the maximum height will be attained at mid point i.e. [tex]\frac{28}{2} =14[/tex]

Now substitute x= 14

[tex]y = -0.03(14 - 14)^2 + 6[/tex]

[tex]y = 6[/tex]

So, kangaroo's maximum height is 6 m and the kangaroo's jump is 28 m long

  • From the vertex of the quadratic equation, we find that: The kangaroos maximum height is of 6 meters.
  • From the roots of the equation, we find that: The kangaroo's jump is 28.14 meters long.

----------------------------

Vertex of a quadratic function:

Suppose we have a quadratic function in the following format:

[tex]f(x) = ax^{2} + bx + c[/tex]

It's vertex is the point [tex](x_{v}, y_{v})[/tex]

In which

[tex]x_{v} = -\frac{b}{2a}[/tex]

[tex]y_{v} = -\frac{\Delta}{4a}[/tex]

Where

[tex]\Delta = b^2-4ac[/tex]

If a<0, the vertex is a maximum point, that is, the maximum value happens at [tex]x_{v}[/tex], and it's value is [tex]y_{v}[/tex].

----------------------------

Solving a quadratic equation:

Given a second order polynomial expressed by the following equation:

[tex]ax^{2} + bx + c, a\neq0[/tex].

This polynomial has roots [tex]x_{1}, x_{2}[/tex] such that [tex]ax^{2} + bx + c = a(x - x_{1})*(x - x_{2})[/tex], given by the following formulas:

[tex]x_{1} = \frac{-b + \sqrt{\Delta}}{2*a}[/tex]

[tex]x_{2} = \frac{-b - \sqrt{\Delta}}{2*a}[/tex]

[tex]\Delta = b^{2} - 4ac[/tex]

----------------------------

The quadratic equation is:

[tex]y = -0.03(x - 14)^2 + 6[/tex]

Placing in standard form:

[tex]y = -0.03(x^2 - 28x + 196) + 6[/tex]

[tex]y = -0.03x^2 + 0.84x + 0.12[/tex]

Thus, it has coefficients [tex]a = -0.03, b = 0.84, c = 0.12[/tex]

----------------------------

The kangaroo's maximum height is the y-value of the vertex, thus:

[tex]\Delta = b^2 - 4ac = (0.84)^2 - 4(-0.03)(0.12) = 0.72[/tex]

[tex]y_{v} = -\frac{\Delta}{4a} = -\frac{0.72}{4(-0.03)} = 6[/tex]

The kangaroos maximum height is of 6 meters.

----------------------------

The length of the kangaroo's jump is the positive root. The roots are found at the values of x for which y = 0, thus, the solutions of the quadratic equation.

[tex]x_{1} = \frac{-0.84 + \sqrt{0.72}}{2(-0.03)} = -0.14[/tex]

[tex]x_{2} = \frac{-0.84 - \sqrt{0.72}}{2(-0.03)} = 28.14[/tex]

The kangaroo's jump is 28.14 meters long.

A similar question is given at https://brainly.com/question/16858635