practice exercises
21 - 44. determining limits analytically determine the following limits.
21. a. $lim_{x
ightarrow2^{+}}\frac{1}{x - 2}$ b. $lim_{x
ightarrow2^{-}}\frac{1}{x - 2}$ c. $lim_{x
ightarrow2}\frac{1}{x - 2}$
22. a. $lim_{x
ightarrow3^{+}}\frac{2}{(x - 3)^{3}}$ b. $lim_{x
ightarrow3^{-}}\frac{2}{(x - 3)^{3}}$ c. $lim_{x
ightarrow3}\frac{2}{(x - 3)^{3}}$
23. a. $lim_{x
ightarrow4^{+}}\frac{x - 5}{(x - 4)^{2}}$ b. $lim_{x
ightarrow4^{-}}\frac{x - 5}{(x - 4)^{2}}$ c. $lim_{x
ightarrow4}\frac{x - 5}{(x - 4)^{2}}$
24. a. $lim_{x
ightarrow1^{+}}\frac{x}{|x - 1|}$ b. $lim_{x
ightarrow1^{-}}\frac{x}{|x - 1|}$ c. $lim_{x
ightarrow1}\frac{x}{|x - 1|}$
25. a. $lim_{z
ightarrow3^{+}}\frac{(z - 1)(z - 2)}{(z - 3)}$ b. $lim_{z
ightarrow3^{-}}\frac{(z - 1)(z - 2)}{(z - 3)}$
c. $lim_{z
ightarrow3}\frac{(z - 1)(z - 2)}{(z - 3)}$

Question

practice exercises
21 - 44. determining limits analytically determine the following limits.
21. a. $lim_{x
ightarrow2^{+}}\frac{1}{x - 2}$ b. $lim_{x
ightarrow2^{-}}\frac{1}{x - 2}$ c. $lim_{x
ightarrow2}\frac{1}{x - 2}$
22. a. $lim_{x
ightarrow3^{+}}\frac{2}{(x - 3)^{3}}$ b. $lim_{x
ightarrow3^{-}}\frac{2}{(x - 3)^{3}}$ c. $lim_{x
ightarrow3}\frac{2}{(x - 3)^{3}}$
23. a. $lim_{x
ightarrow4^{+}}\frac{x - 5}{(x - 4)^{2}}$ b. $lim_{x
ightarrow4^{-}}\frac{x - 5}{(x - 4)^{2}}$ c. $lim_{x
ightarrow4}\frac{x - 5}{(x - 4)^{2}}$
24. a. $lim_{x
ightarrow1^{+}}\frac{x}{|x - 1|}$ b. $lim_{x
ightarrow1^{-}}\frac{x}{|x - 1|}$ c. $lim_{x
ightarrow1}\frac{x}{|x - 1|}$
25. a. $lim_{z
ightarrow3^{+}}\frac{(z - 1)(z - 2)}{(z - 3)}$ b. $lim_{z
ightarrow3^{-}}\frac{(z - 1)(z - 2)}{(z - 3)}$
 c. $lim_{z
ightarrow3}\frac{(z - 1)(z - 2)}{(z - 3)}$

Accepted Answer

### 21.
#### a.
# Explanation:
## Step1: Analyze right - hand limit
As $x\to2^{+}$, $x - 2\to0^{+}$. Let $t=x - 2$, when $x\to2^{+}$, $t\to0^{+}$, and $\lim_{x\to2^{+}}\frac{1}{x - 2}=\lim_{t\to0^{+}}\frac{1}{t}=+\infty$.
# Answer:
$+\infty$

#### b.
# Explanation:
## Step1: Analyze left - hand limit
As $x\to2^{-}$, $x - 2\to0^{-}$. Let $t=x - 2$, when $x\to2^{-}$, $t\to0^{-}$, and $\lim_{x\to2^{-}}\frac{1}{x - 2}=\lim_{t\to0^{-}}\frac{1}{t}=-\infty$.
# Answer:
$-\infty$

#### c.
# Explanation:
## Step1: Check one - sided limits
Since $\lim_{x\to2^{+}}\frac{1}{x - 2}=+\infty$ and $\lim_{x\to2^{-}}\frac{1}{x - 2}=-\infty$, the two - sided limit does not exist.
# Answer:
Does not exist

### 22.
#### a.
# Explanation:
## Step1: Analyze right - hand limit
As $x\to3^{+}$, $x - 3\to0^{+}$. Let $t=x - 3$, then $\lim_{x\to3^{+}}\frac{2}{(x - 3)^{3}}=\lim_{t\to0^{+}}\frac{2}{t^{3}}=+\infty$.
# Answer:
$+\infty$

#### b.
# Explanation:
## Step1: Analyze left - hand limit
As $x\to3^{-}$, $x - 3\to0^{-}$. Let $t=x - 3$, then $\lim_{x\to3^{-}}\frac{2}{(x - 3)^{3}}=\lim_{t\to0^{-}}\frac{2}{t^{3}}=-\infty$.
# Answer:
$-\infty$

#### c.
# Explanation:
## Step1: Check one - sided limits
Since $\lim_{x\to3^{+}}\frac{2}{(x - 3)^{3}}=+\infty$ and $\lim_{x\to3^{-}}\frac{2}{(x - 3)^{3}}=-\infty$, the two - sided limit does not exist.
# Answer:
Does not exist

### 23.
#### a.
# Explanation:
## Step1: Analyze right - hand limit
As $x\to4^{+}$, $(x - 4)^{2}\to0^{+}$ and $x-5=-1$ (constant near $x = 4$). So $\lim_{x\to4^{+}}\frac{x - 5}{(x - 4)^{2}}=\lim_{x\to4^{+}}\frac{-1}{(x - 4)^{2}}=-\infty$.
# Answer:
$-\infty$

#### b.
# Explanation:
## Step1: Analyze left - hand limit
As $x\to4^{-}$, $(x - 4)^{2}\to0^{+}$ and $x - 5=-1$ (constant near $x = 4$). So $\lim_{x\to4^{-}}\frac{x - 5}{(x - 4)^{2}}=\lim_{x\to4^{-}}\frac{-1}{(x - 4)^{2}}=-\infty$.
# Answer:
$-\infty$

#### c.
# Explanation:
## Step1: Use one - sided limits
Since $\lim_{x\to4^{+}}\frac{x - 5}{(x - 4)^{2}}=-\infty$ and $\lim_{x\to4^{-}}\frac{x - 5}{(x - 4)^{2}}=-\infty$, $\lim_{x\to4}\frac{x - 5}{(x - 4)^{2}}=-\infty$.
# Answer:
$-\infty$

### 24.
#### a.
# Explanation:
## Step1: Analyze right - hand limit
As $x\to1^{+}$, $|x - 1|=x - 1$. So $\lim_{x\to1^{+}}\frac{x}{|x - 1|}=\lim_{x\to1^{+}}\frac{x}{x - 1}=+\infty$.
# Answer:
$+\infty$

#### b.
# Explanation:
## Step1: Analyze left - hand limit
As $x\to1^{-}$, $|x - 1|=-(x - 1)$. So $\lim_{x\to1^{-}}\frac{x}{|x - 1|}=\lim_{x\to1^{-}}\frac{x}{-(x - 1)}=-\infty$.
# Answer:
$-\infty$

#### c.
# Explanation:
## Step1: Check one - sided limits
Since $\lim_{x\to1^{+}}\frac{x}{|x - 1|}=+\infty$ and $\lim_{x\to1^{-}}\frac{x}{|x - 1|}=-\infty$, the two - sided limit does not exist.
# Answer:
Does not exist

### 25.
#### a.
# Explanation:
## Step1: Analyze right - hand limit
As $z\to3^{+}$, $z - 3\to0^{+}$ and $(z - 1)(z - 2)\to2$. So $\lim_{z\to3^{+}}\frac{(z - 1)(z - 2)}{z - 3}=+\infty$.
# Answer:
$+\infty$

#### b.
# Explanation:
## Step1: Analyze left - hand limit
As $z\to3^{-}$, $z - 3\to0^{-}$ and $(z - 1)(z - 2)\to2$. So $\lim_{z\to3^{-}}\frac{(z - 1)(z - 2)}{z - 3}=-\infty$.
# Answer:
$-\infty$

#### c.
# Explanation:
## Step1: Check one - sided limits
Since $\lim_{z\to3^{+}}\frac{(z - 1)(z - 2)}{z - 3}=+\infty$ and $\lim_{z\to3^{-}}\frac{(z - 1)(z - 2)}{z - 3}=-\infty$, the two - sided limit does not exist.
# Answer:
Does not exist

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QUESTION IMAGE

Question

Explanation:

21.

a.

Step1: Analyze right - hand limit

Step1: Analyze left - hand limit

Step1: Check one - sided limits

Answer:

b.