To analyze how a function behaves, the derivative acts as an important tool. It helps us determine where a function is increasing or decreasing.
For the function \( f(x) = \frac{x}{x+1} \), we calculate its derivative to gain insights into its nature. The derivative is found using the quotient rule. This result is \( f'(x) = \frac{1}{(x+1)^2} \).
This derivative tells us how the function's rate of change behaves. Notice that \( \frac{1}{(x+1)^2} \) is always positive when defined, indicating an increasing function. However, we also need to consider points where the derivative might not be defined.

The intervals on which a function increases or decreases can be determined through the sign of its derivative. Here, \( f'(x) = \frac{1}{(x+1)^2} \) is strictly positive and never zero in its domain where it is defined, which suggests the function is increasing in these regions.
Next, identify where the derivative is not defined due to division by zero. In this case, \( x = -1 \) makes \( (x+1)^2 = 0 \). Hence, the function is not defined here, splitting the number line into \( (\infty, -1) \) and \( (-1, \infty) \). In both intervals, the derivative is positive, implying the function increases to the left and right of \( x = -1 \).

Discontinuities in a function occur where the function is not defined or lacks a limit. For \( f(x) = \frac{x}{x+1} \), the point \( x = -1 \) causes the denominator to become zero, leading to a discontinuity.
At this point, the function does not exist, and so, cannot be continued smoothly. This type of discontinuity is classified as a vertical asymptote, meaning as you approach \( x = -1 \) from either side, the function approaches infinity or drops to negative infinity. This break in the graph must be noted, as it separates the intervals where increases or decreases occur.

When sketching \( f(x) = \frac{x}{x+1} \), the key is to reflect on the derivative and detected discontinuities. The graph shows increasing behavior, consistent before and after \( x = -1 \).
However, due to the vertical asymptote at \( x = -1 \), the graph shows a significant break here. Before this point, the function rises from negative infinity towards \( x = -1 \), and post \( x = -1 \), it rises from negative infinity again.
A function that appears to drop and then rise sharply can be misleading without awareness of the vertical asymptote. Including this feature in your graph ensures a comprehensive understanding of \( f(x) \).