7.03 Quadratic functions in vertex form

Find the vertex.

The function is given in vertex form y=a\left(x - h\right)^{2} + k where the vertex is the point \left(h,k\right).

In the equation m\left(x\right)=-\dfrac{1}{2}\left(x-2\right)^{2}+8 the x-coordinate of vertex is h=2 and the y-coordinate of vertex is k=8.

With h=2 and k=8, the ordered pair of the vertex is at \left(2, 8\right).

State the domain.

To find the domain of m\left(x\right), we want to find all possible x-values for which m\left(x\right) could be graphed.

We know that for a parabola, there are no restrictions on which x-values can be graphed as each side of the parabola continues infinitely in either x direction.

Domain: \{x \vert- \infty \lt x \lt \infty\}

State the range.

To find the range, we want to find all possible values of m\left(x\right). The vertex of a parabola affects the range of the function, as it will be the maximum or minimum value of m\left(x\right).

This parabola opens down, so the y-value of the vertex is the maximum value of the function. The parabola continues infinitely in the negative y direction.

Range: \{y \vert y \leq 8\}

Draw the graph of the function.

The scale factor is -\dfrac{1}{2} which is negative, so the graph will open down. We can draw the graph through any three points that we know are on it.

Technically we only need 3 points to graph a parabola, but finding more points can make our graph more precise.

Write the function p\left(x\right) in vertex form.

We can use the fact that a quadratic function has symmetry about its vertex to identify the location of the vertex from the table.

Looking at the values of p\left(x\right), we can see that it has a maximum value of 4 and falls off symmetrically on either side. So we know that the vertex is the point \left(-1, 4\right), so we can use that to set up the equation: p\left(x\right) = a\left(x + 1\right)^{2} + 4

We can now find the value of a by substituting any other pair of values from the table, such as \left(0, 3\right). Doing so, we get 3 = a\left(0 + 1\right)^{2} + 4which we can solve to get a=-1.

So the quadratic function shown in the table of values is p\left(x\right) = -\left(x + 1\right)^{2} + 4

Determine the value of p\left(x\right) when x=6.

We can substitute x = 6 into the equation that was created in part (a) in order to predict what p\left(x\right) will be equal to.

The equation found in part (a) is

This means that when x=6, p\left(x\right) is equal to -45.

Determine the x- and y-intercepts of the function.

Use the table of values to identify the x-intercepts when y=0 and the y-intercept when x=0.

The x-intercepts occur at \left(-3,0\right) and \left(1,0\right).

The y-intercept occurs at \left(0,3\right).

Describe the transformation from f\left(x\right) to g\left(x\right).

The function g\left(x\right) has the same shape and size as f\left(x\right), but has been shifted to the left. Comparing the vertices of the two parabolas, we can see that this is a translation of 6 units to the left.

We could confirm that g\left(x\right) is a horizontal shift left by evaluating f\left(x+6\right)=2\left(x+6\right)^{2}:

g\left(-8\right)=8 and f\left(-8+6\right)=2\left(-8+6\right)^{2}=2\left(-2\right)^{2}=2\left(4\right)=8

g\left(-6\right)=0 and f\left(-6+6\right)=2\left(-6+6\right)^{2}=2\left(0\right)^{2}=2\left(0\right)=0

g\left(-4\right)=8 and f\left(-4+6\right)=2\left(-4+6\right)^{2}=2\left(2\right)^{2}=2\left(4\right)=8

Write the equation of the function g\left(x\right) in vertex form.

Remember that vertex form for a quadratic is g\left(x\right) = a\left(x - h\right)^2 + k, where the vertex is at the point \left(h, k\right).

f\left(x\right) = 2x^{2} has been translated 6 units to the left to produce g\left(x\right), and we can see that its vertex is at \left(-6, 0\right). So g\left(x\right) has can be written as g\left(x\right) = 2\left(x + 6\right)^{2}.

Describe the transformations of the graph of f\left(x\right) resulting in the function h\left(x\right)=-2\left(x+6\right)^{2} +3.

Since f\left(x\right) opens upward and has a vertex at \left(0,0\right), the vertex form of h\left(x\right) gives information about its vertex and direction of its opening.

The function h\left(x\right) will open downward and be a reflection of f\left(x\right) across the x-axis, since the value of a became negative.

The vertex of h\left(x\right) is \left(-6, 3\right). The vertex became a maximum value and shifted the graph up 3 units and to the left 6 units.

Sketch the graph of h\left(x\right).

Use the description of the transformations of g\left(x\right) from part (c) and graph of g\left(x\right) to sketch h\left(x\right).

Start by reflecting g\left(x\right) across the x-axis using points from its graph.

Perform a vertical shift 3 units up.

The graph of h\left(x\right) follows:

Rewrite the equation in vertex form by completing the square.

We'll follow the standard complete the square method and stop working once our equation is in vertex form, y = a\left(x - h\right)^{2} + k.

We've completed the square and the equation is now in vertex form.

We must add and subtract \left(\dfrac{b}{2}\right)^{2} to the RHS of the equation so that the value of the equation does not change.

Determine the vertex of the quadratic function and if it is a minimum or maximum.

Use the vertex form of the quadratic function from part (a) to determine its vertex and whether it is a minimum or maximum value.

The quadratic function in vertex form is y=\left(x-2\right)^{2} +2, meaning the vertex is located at the point \left(2,2\right).

Since the value of a is 1, we know that the graph opens upward and the vertex is a minimum value.

Sketch the graph of the parabola.

We can find key points of our parabola to sketch it. In part (a) we found the x-value of the vertex, and in part (b) we found the vertex form of our equation which shows us the y-value of our vertex. We can also use the vertex form to consider the x- and y-intercepts.

The y-value of the vertex is 2 since the vertex form of the equation is y=\left(x-2\right)^{2} + 2. This means that the vertex is located at \left(2,2\right). We know the scale factor a is 1, so the parabola opens upward. Since the vertex is above the x-axis and opens up, the graph will not cross the x-axis and there are no x-intercepts.

Find the y-intercept:

Therefore the y-intercept is \left(0, 6\right).

We can use the vertex and y-intercept to sketch the parabola, remembering there is an axis of symmetry at the vertex.