2.3 The Limit Laws - Calculus Volume 1 | OpenStax (2024)

1. The limit of x as x approaches a is a: $\underset{x\to 2}{\text{lim}}x=2.$
2. The limit of a constant is that constant: $\underset{x\to 2}{\text{lim}}5=5.$

Let’s apply the limit laws one step at a time to be sure we understand how they work. We need to keep in mind the requirement that, at each application of a limit law, the new limits must exist for the limit law to be applied.

$\begin{array}{ccccc}\underset{x\to \mathrm{-3}}{\text{lim}}\left(4x+2\right)\hfill & =\underset{x\to \mathrm{-3}}{\text{lim}}4x+\underset{x\to \mathrm{-3}}{\text{lim}}2\hfill & & & \text{Apply the sum law.}\hfill \\ & =4·\underset{x\to \mathrm{-3}}{\text{lim}}x+\underset{x\to \mathrm{-3}}{\text{lim}}2\hfill & & & \text{Apply the constant multiple law.}\hfill \\ & =4·\left(\mathrm{-3}\right)+2=\mathrm{-10}.\hfill & & & \text{Apply the basic limit results and simplify.}\hfill \end{array}$

To find this limit, we need to apply the limit laws several times. Again, we need to keep in mind that as we rewrite the limit in terms of other limits, each new limit must exist for the limit law to be applied.

$\begin{array}{}\\ \\ \underset{x\to 2}{\text{lim}}\frac{2x^2-3x+1}{x^3+4}\hfill & =\frac{\underset{x\to 2}{\text{lim}}\left(2x^2-3x+1\right)}{\underset{x\to 2}{\text{lim}}\left(x^3+4\right)}\hfill & & & \text{Apply the quotient law, making sure that.}{\left(2\right)}^3+4\ne 0\hfill \\ & =\frac{2·\underset{x\to 2}{\text{lim}}{x}^2-3·\underset{x\to 2}{\text{lim}}x+\underset{x\to 2}{\text{lim}}1}{\underset{x\to 2}{\text{lim}}{x}^3+\underset{x\to 2}{\text{lim}}4}\hfill & & & \text{Apply the sum law and constant multiple law.}\hfill \\ & =\frac{2·{\left(\underset{x\to 2}{\text{lim}}x\right)}^2-3·\underset{x\to 2}{\text{lim}}x+\underset{x\to 2}{\text{lim}}1}{{\left(\underset{x\to 2}{\text{lim}}x\right)}^3+\underset{x\to 2}{\text{lim}}4}\hfill & & & \text{Apply the power law.}\hfill \\ & =\frac{2\left(4\right)-3\left(2\right)+1}{{\left(2\right)}^3+4}=\frac{1}{4}.\hfill & & & \text{Apply the basic limit laws and simplify.}\hfill \end{array}$

Since 3 is in the domain of the rational function $f\left(x\right)=\frac{2x^2-3x+1}{5x+4},$ we can calculate the limit by substituting 3 for x into the function. Thus,

$$\underset{x\to 3}{\text{lim}}\frac{2x^2-3x+1}{5x+4}=\frac{10}{19}.$$

Step 1. The function $f\left(x\right)=\frac{x^2-3x}{2x^2-5x-3}$ is undefined for $x=3.$ In fact, if we substitute 3 into the function we get $0\text{/}0,$ which is undefined. Factoring and canceling is a good strategy:

$$\underset{x\to 3}{\text{lim}}\frac{x^2-3x}{2x^2-5x-3}=\underset{x\to 3}{\text{lim}}\frac{x\left(x-3\right)}{\left(x-3\right)\left(2x+1\right)}$$

Step 2. For all $x\ne 3,\frac{x^2-3x}{2x^2-5x-3}=\frac{x}{2x+1}.$ Therefore,

$$\underset{x\to 3}{\text{lim}}\frac{x\left(x-3\right)}{\left(x-3\right)\left(2x+1\right)}=\underset{x\to 3}{\text{lim}}\frac{x}{2x+1}.$$

Step 3. Evaluate using the limit laws:

$$\underset{x\to 3}{\text{lim}}\frac{x}{2x+1}=\frac{3}{7}.$$

Step 1. $\frac{\sqrt{x+2}-1}{x+1}$ has the form $0\text{/}0$ at −1. Let’s begin by multiplying by $\sqrt{x+2}+1,$ the conjugate of $\sqrt{x+2}-1,$ on the numerator and denominator:

$$\underset{x\to \mathrm{-1}}{\text{lim}}\frac{\sqrt{x+2}-1}{x+1}=\underset{x\to \mathrm{-1}}{\text{lim}}\frac{\sqrt{x+2}-1}{x+1}·\frac{\sqrt{x+2}+1}{\sqrt{x+2}+1}.$$

Step 2. We then multiply out the numerator. We don’t multiply out the denominator because we are hoping that the $\left(x+1\right)$ in the denominator cancels out in the end:

$$=\underset{x\to \mathrm{-1}}{\text{lim}}\frac{x+1}{\left(x+1\right)\left(\sqrt{x+2}+1\right)}.$$

Step 3. Then we cancel:

$$=\underset{x\to \mathrm{-1}}{\text{lim}}\frac{1}{\sqrt{x+2}+1}.$$

Step 4. Last, we apply the limit laws:

$$\underset{x\to \mathrm{-1}}{\text{lim}}\frac{1}{\sqrt{x+2}+1}=\frac{1}{2}.$$

Step 1. $\frac{\frac{1}{x+1}-\frac{1}{2}}{x-1}$ has the form $0\text{/}0$ at 1. We simplify the algebraic fraction by multiplying by $2\left(x+1\right)\text{/}2\left(x+1\right):$

$$\underset{x\to 1}{\text{lim}}\frac{\frac{1}{x+1}-\frac{1}{2}}{x-1}=\underset{x\to 1}{\text{lim}}\frac{\frac{1}{x+1}-\frac{1}{2}}{x-1}·\frac{2\left(x+1\right)}{2\left(x+1\right)}.$$

Step 2. Next, we multiply through the numerators. Do not multiply the denominators because we want to be able to cancel the factor $\left(x-1\right)\text{:}$

$$=\underset{x\to 1}{\text{lim}}\frac{2-\left(x+1\right)}{2\left(x-1\right)\left(x+1\right)}.$$

Step 3. Then, we simplify the numerator:

$$=\underset{x\to 1}{\text{lim}}\frac{-x+1}{2\left(x-1\right)\left(x+1\right)}.$$

Step 4. Now we factor out −1 from the numerator:

$$=\underset{x\to 1}{\text{lim}}\frac{-\left(x-1\right)}{2\left(x-1\right)\left(x+1\right)}.$$

Step 5. Then, we cancel the common factors of $\left(x-1\right)\text{:}$

$$=\underset{x\to 1}{\text{lim}}\frac{\mathrm{-1}}{2\left(x+1\right)}.$$

Step 6. Last, we evaluate using the limit laws:

$$\underset{x\to 1}{\text{lim}}\frac{\mathrm{-1}}{2(x+1)}=-\frac{1}{4}.$$

Both $1\text{/}x$ and $5\text{/}x\left(x-5\right)$ fail to have a limit at zero. Since neither of the two functions has a limit at zero, we cannot apply the sum law for limits; we must use a different strategy. In this case, we find the limit by performing addition and then applying one of our previous strategies. Observe that

$$\begin{array}{cc}\hfill \frac{1}{x}+\frac{5}{x\left(x-5\right)}& =\frac{x-5+5}{x\left(x-5\right)}\hfill \\ & =\frac{x}{x\left(x-5\right)}.\hfill \end{array}$$

Thus,

$$\begin{array}{cc}\hfill \underset{x\to 0}{\text{lim}}\left(\frac{1}{x}+\frac{5}{x\left(x-5\right)}\right)& =\underset{x\to 0}{\text{lim}}\frac{x}{x\left(x-5\right)}\hfill \\ & =\underset{x\to 0}{\text{lim}}\frac{1}{x-5}\hfill \\ & =-\frac{1}{5}.\hfill \end{array}$$

Figure 2.25 illustrates the function $f\left(x\right)=\sqrt{x-3}$ and aids in our understanding of these limits.

Figure 2.25 The graph shows the function $f\left(x\right)=\sqrt{x-3}.$

1. The function $f\left(x\right)=\sqrt{x-3}$ is defined over the interval $\left[3,\text{+}\infty \right).$ Since this function is not defined to the left of 3, we cannot apply the limit laws to compute $\underset{x\to 3^{-}}{\text{lim}}\sqrt{x-3}.$ In fact, since $f\left(x\right)=\sqrt{x-3}$ is undefined to the left of 3, $\underset{x\to 3^{-}}{\text{lim}}\sqrt{x-3}$ does not exist.
2. Since $f\left(x\right)=\sqrt{x-3}$ is defined to the right of 3, the limit laws do apply to $\underset{x\to 3^{+}}{\text{lim}}\sqrt{x-3}.$ By applying these limit laws we obtain $\underset{x\to 3^{+}}{\text{lim}}\sqrt{x-3}=0.$

Figure 2.26 illustrates the function $f\left(x\right)$ and aids in our understanding of these limits.

Figure 2.26 This graph shows a function $f\left(x\right).$

1. Since $f\left(x\right)=4x-3$ for all x in $\left(\text{−}\infty ,2\right),$ replace $f\left(x\right)$ in the limit with $4x-3$ and apply the limit laws:
   

   $$\underset{x\to 2^{-}}{\text{lim}}f\left(x\right)=\underset{x\to 2^{-}}{\text{lim}}\left(4x-3\right)=5.$$

2. Since $f\left(x\right)={\left(x-3\right)}^2$ for all x in $\left(2,\text{+}\infty \right),$ replace $f\left(x\right)$ in the limit with ${\left(x-3\right)}^2$ and apply the limit laws:
   

   $$\underset{x\to 2^{+}}{\text{lim}}f\left(x\right)=\underset{x\to 2^{+}}{\text{lim}}{\left(x-3\right)}^2=1.$$

3. Since $\underset{x\to 2^{-}}{\text{lim}}f\left(x\right)=5$ and $\underset{x\to 2^{+}}{\text{lim}}f\left(x\right)=1,$ we conclude that $\underset{x\to 2}{\text{lim}}f\left(x\right)$ does not exist.