1.01 Key features of functions

State the coordinates of the vertex.

For this function, the vertex is the absolute minimum. Note the values on the x-axis change by 1, and the values on the y-axis change by 2.

It appears the vertex is halfway between x=-1 and x=0 and halfway between y=-8 and y=-10. Therefore, the vertex is at \left(-\dfrac{1}{2},-9\right).

Recall the axis of symmetry is a key feature of quadratic functions. The axis of symmetry is the line that passes through the middle of the parabola and the x-value of the vertex. So, the axis of symmetry for this parabola is x=-\dfrac{1}{2}.

State the positive and negative intervals.

The positive intervals are the domain values for which the parabola lies above the x-axis. We can see that this happens on the left side of the leftmost x-intercept and on the right side of the rightmost x-intercept. The function is negative between the intercepts.

The function is positive on the intervals \left(-\infty, -3.5\right)\cup\left(2.5,\infty\right).

The function is negative on the interval \left(-3.5,2.5\right).

Similar to increasing and decreasing intervals, the intercepts are not included in the interval since 0 is neither positive nor negative. That is why we used parentheses for the end values of the intervals.

State the domain and range in interval notation.

Remember that the domain of the function is the set of all possible input values, which are the x-values that correspond to points on the graph.

Similarly, the range of the function is the set of all possible output values, which are the y-values that correspond to points on the graph.

If we were to continue extending both ends of the function indefinitely, it would stretch upwards towards positive infinity on both sides. In addition, the ends would continue indefinitely toward the left and toward the right.

In part (b) we stated that the vertex is the point \left(-\dfrac{1}{2},-9\right), and we can see that it is the minimum point on the function.

So, the domain is "all real values" and the range is "all values greater than or equal to -9". In interval notation, this is:

• Domain: \left(-\infty, \infty\right)

• Range: \left[-9, \infty\right)

In set-builder notation, we would write the domain and range as follows:

• Domain: \left\{x\vert x\in\Reals\right\} or \left\{x\vert -\infty < x < \infty \right\}
• Range: \left\{y\vert y\geq -9\right\}

State the equation of the asymptote.

Notice how the function approaches the x-axis without ever reaching it:

This means that the x-axis is an asymptote for the function. The equation of the horizontal aymptote is y = 0.

Asmptotes are lines, so they should always be stated as an equation. The equation for horizontal asymptotes is always of the form y=c, and the equation for vertical asymptotes is always of the form x=c where c is any real number.

Identify the intercepts.

In part (a), we found there is a horizontal asymptote on the x-axis. This means there will be no x-intercepts, so we only need to identify the y-intercept.

The y-intercept of the function is at \left(0,1\right).

Recall from Algebra 1 that all the exponential functions of the form f\left(x\right)=b^x will have a y-intercept at \left(0,1\right). This is because f\left(0\right)=b^0=1. Later in this unit, we will begin transforming functions, so we will see exponential functions that do not have a y-intercept at \left(0,1\right).

Describe the end behavior of the function.

As the input values decrease indefinitely, the function output values continue to increase indefinitely. So as x \to -\infty, f\left(x\right)\to \infty.

As the input values increase indefinitely, the function output values approach the asymptote at y=0. So as x \to \infty, f\left(x\right)\to 0.

Determine the increasing and decreasing intervals.

To determine the increasing and decreasing intervals, we need to first find the x-values of the turning points. These values will be the endpoints of the increasing and decreasing intervals.

The turning points occur at x=-3.5,-1,1.5,4,6.

Tracing the graph from the smallest x-values toward the largest x-values, we can see that the graph switches between increasing and decreasing at each of the turning points.

Increasing intervals: \left(-\infty, -3.5\right)\cup \left(-1,1.5\right)\cup \left(4,6\right)

Decreasing intervals: \left(-3.5, -1\right)\cup \left(1.5,4\right)\cup \left(6,\infty\right)

Notice that we are not interested in the y-values when listing the increasing and decreasing intervals. If we used the y-values, some of them would be listed in multiple intervals which would make the notation confusing. By only using the domain values, the notation is clear and the x-values do not appear in multiple intervals.

State any absolute and relative maxima and minima.

We have already identified the x-values of the turning points in part (a). Now, we need to identify the corresponding y-values and classify each as an absolute maximum, an absolute minimum, a relative maximum, or a relative minimum.

The point with the largest y-value is \left(-3.5, 6\right). This is the absolute maximum.

The relative maxima are \left(1.5, 0.5\right) and \left(6,0\right).

The relative minima are \left(-1, -3\right) and \left(4, -4\right).

There is no absolute minimum since the end behavior of the function tends toward negative infinity.