In the factored form y=a(x-x_1)(x-x_2) the values of x_1 and x_2 are the x-values of the x-intercepts. The y-value of the x-intercepts is y=0.

The x-intercepts are \left( 4,0 \right) and \left( -6,0 \right).

Notice that x+6 is the same as x-(-6).

The y-value of the y-intercept is the result when x=0. We can substitute x=0 into the factored form to find this value.

To find the y-value of the y-intercept:

The y-intercept is \left( 0,-48 \right).

The vertex lies on the axis of symmetry, so the x-coordinate of the vertex will be the average of 4 and -6. We can then substitute this value into the funtion to find the y-coordinate.

To find the x-coordinate:

The average of 4 and -6 is half way between them. We can calculate that \dfrac{4+(-6)}{2}=-1, so the x-coordinate of the vertex and the axis of symmetry is x=-1.

To find the y-coordinate:

The vertex is \left( -1,-50 \right).

The scale factor is 2 which is positive, so the graph will open up. We can draw the graph through any three points that we know are on it.

Any three points is enough to draw the graph, but knowing where the vertex is can make it easier since the vertex is on the axis of symmetry.

To make the graph match the information, we want to make sure that our choice of axis labels makes sense for the context, and the axis scales correctly describe the path of the cannon ball. Both axes will have meters as their units.

We can see that the path on the graph starts at a point on the vertical axis and ends at a point on the horizontal axis. So we can make the vertical axis represent height, with y=0 being sea level, and the horizontal axis represent distance, with x=0 being the edge of the cliff.

We can then add values onto the axes to show that the cannon ball starts at the edge of the cliff at \left(0,15\right), reaches it peak at \left(10,20\right), and then falls into the sea at \left(30,0\right).

Another way to show the scale of the axes is to label some key points. For example:

To match the graph in part (a), we can let x represent the horizontal distance from the cliff, and let y represent the height above sea level.

To find the factored equation that models the cannon ball, we need to know both x-intercepts and the scale factor.

We know that one of the x-intercepts is at x=30, and that the vertex is at x=10. Remember that the vertex lies on the axis of symmetry of a quadratic relation, so we can use this to find the other x-intercept.

We can find the scale factor by substituting any point into the equation (that isn't an x-intercept) and solving for the scale factor that makes the equation true.

Since both x-intercepts have the same y-value, they will be mirrored across the axis of symmetry. Since x=30 is 20 more units than x=10, the other x-intercept will be at 20 less units than x=10. So the other x-intercept is at x=-10.

If we let the scale factor of the equation be a, then our equation will be: y=a\left(x+10\right)\left(x-30\right)

We can find the scale factor by substituting in a point on the graph (let's use the y-intercept) and solving for a.

So the equation which models the path of the cannon ball is: y=-\frac{1}{20}\left(x+10\right)\left(x-30\right)

To find where the cannon ball landed, we'll find the point where y is 0 since the y-value represents height above sea level, and a height of 0 indicates sea level. We'll need to find the corresponding x-value.

Since the cannon ball is being fired away from the cliff in the positive x-direction, we know that x=-12 is a non-viable solution. So the second cannon ball lands in the sea 27 meters from the base of the cliff.

Since the model equation was in factored form, we could also have identified the x-intercepts directly from the equation.