Evaluating the expression \dfrac{1}{\left(x - 3\right)^2} at each value of x we get:

We can plot the points from the table of values and use this to help draw the curve.

We can confirm this by using the function definition: y = \dfrac{1}{\left(x - 3\right)^2} can never be equal to 0 as the numerator will never be equal to 0.

Here is a graph of the parent function y = \dfrac{1}{x^2} on the same coordinate plane:

Looking at the graph, and in particular the location of the vertical asymptote, we can see that the function has been translated 3 units to the right.

The y-intercept of a function occurs where x = 0. We can substitute this into the function to find the y-coordinate.

Similarly, the x-intercept(s) of a function occur where y = 0. In particular, for a rational function, this occurs at values of x which make the numerator equal to 0 (and not the denominator).

For the y-intercept, we have:

So the y-intercept occurs at \left(0, 4\right).

For the x-intercepts, we have:

The function is undefined at x = -1 (the value which makes the denominator 0). This is neither of the values we just solved for, and so we have x-intercepts at both \left(1, 0\right) and \left(4, 0\right).

It is important to consider values of x which make the denominator equal to 0, as the function cannot have an intercept if it is undefined at that value of x.

Note that the step of work "multiply both sides by x + 1" fails if x = -1. This is why we factored the numerator first, so that we could see that there was no corresponding factor of x + 1 in the numerator.

As part of determining the x-intercepts, we determined that the function is undefined at x = -1 and that this is not a zero of the numerator.

So the function has a single vertical asymptote, which is the line x = -1.

A rational function has a horizontal asymptote if the degree of the numerator is less than or equal to the degree of the denominator, and an oblique asymptote if the degree is exactly 1 larger.

In this case the function is y = \dfrac{x^2 - 5x + 4}{x + 1}, which has a numerator of degree 2 and a denominator of degree 1.

So the degree of the numerator is exactly 1 larger than the degree of the denominator, and therefore the function has an oblique asymptote.

For a rational function y = \dfrac{P\left(x\right)}{Q\left(x\right)}, we can determine the equation of a horizontal or oblique asymptote by using polynomial division or other techniques to rewrite the function in the formy = A\left(x\right) + \dfrac{B\left(x\right)}{Q\left(x\right)}where the degree of B\left(x\right) is smaller than the degree of Q\left(x\right). The equation of the asymptote will then be y = A\left(x\right).

We can use polynomial long division for the function y = \dfrac{x^2 - 5x + 4}{x + 1}:

This tells us that we can rewrite the function in the form y = x - 6 + \frac{10}{x + 1}So the equation of the oblique asymptote is y = x - 6.

The oblique or horizontal asymptote of a rational function is related to its end behavior.

For a function such as y = x - 6 + \dfrac{10}{x + 1}, as the value of x tends towards \pm \infty, the value of the rational part \dfrac{10}{x + 1} will become very small. So the overall function values will be very close to the line y = x - 6, which is why this is the equation of the oblique asymptote.

In parts (a) to (d) we determined the x- and y-intercepts, the equation of the vertical asymptote, and the equation of the oblique asymptote.

If we draw all of these key features to a coordinate plane, we should be able to make an approximate sketch of the function. We can also evaluate the function at a few extra points if needed.

Drawing the key features on a coordinate plane, we have:

We can sketch the top-right section of the graph using the intercepts. Since the bottom-left section doesn't contain any key features, we can just approximately draw it so that it approaches the asymptotes:

To identify the transformations involved, we will first aim to locate the horizontal and vertical asymptotes. This will directly tell us about any horizontal or vertical translations, and will also help to determine if there has been a reflection or stretch/compression.

Looking at the table of values, we can immediately see that the function is undefined at x = 1. So the vertical asymptote of the function is at x = 1, and this means there has been a translation of 1 unit to the right.

Looking at the function values on either side, we can see that they go above 1, but the rate of change is rapidly decreasing as the function values approach 2. So it seems likely that the horizontal asymptote will be the line y = 2, indicating a translation of 2 units upwards.

With this in mind, we can also see that all of the function values lie below the horizontal asymptote, and so there has been a reflection across the x-axis.

Finally, we can see that when x = 0, the function value is 1, which is 1 unit below the horizontal asymptote. Similarly, when x = 2 the function value is also 1. This is what we would expect for a reflection across the x-axis without a vertical stretch or compression.

To summarize, the transformations are:

• Reflection across the x-axis
• Vertical translation of 2 units upwards
• Horizontal translation of 1 unit to the right

We can use the points in the graph, as well as the asymptotes which we identified in part (a), to sketch a graph of the function.

We can also use this graph to confirm the transformations that we found in part (a). The function has been reflected across the x-axis, and has been translated both vertically by 2 units upwards and horizontally by 1 unit to the right.

We can use the graph to see which values of x and y correspond to points on the graph, and which ones do not.

Note that although the function approaches the two asymptotes, it never quite reaches those values.

We can see that all values of x except for the value of the vertical asymptote, x = 1, correspond to points on the graph. So the domain will be "all real values of x except for x = 1".

We can also see that the function takes all values below the horizontal asymptote, y = 2, but no values on or above it. So the range will be "all real values of y that are less than 2".

We can express the domain and range using interval notation as follows:

• Domain: \left(-\infty, 1\right) \cup \left(1, \infty\right)
• Range: \left(-\infty, 2\right)

As a rational function, the domain will be all real values of x except for those which make the denominator equal to 0. So we will set the denominator to be equal to 0 and solve for x.

So the domain of the function will be \left(-\infty, -4\right) \cup \left(-4, -3\right) \cup \left(-3, \infty\right).

If a factor in the denominator is not in the numerator, or is in the numerator but with a lower multiplicity, then there will be a vertical asymptote at the corresponding value of x.

If a factor is in the denominator and the numerator with the same or higher multiplicity, there will be a removable point of discontinuity instead.

So we also want to factor the numerator, then compare the factors.

We can see that the factor \left(x + 3\right) appears in both the numerator and denominator, while the factor \left(x + 4\right) only appears in the denominator.

As such, x = -3 will correspond to a removable point of discontinuity, while x = -4 will be the equation of a vertical asymptote.