evaluate the given limits using the graph of the function ( f(x) = \frac{1}{(x + 2)^2} ) shown above. enter inf for ( infty ), -inf for ( -infty ), or dne if the limit does not exist, but is neither ( infty ) nor ( -infty ). if you are having a hard time seeing the picture clearly, click on the picture. it will expand to a larger picture on its own page so that you can inspect it more clearly. a) ( lim_{x o -2} f(x) = square ) b) ( lim_{x o -2^+} f(x) = square ) c) ( lim_{x o -2} f(x) = square )

Question

evaluate the given limits using the graph of the function ( f(x) = \frac{1}{(x + 2)^2} ) shown above. enter inf for ( infty ), -inf for ( -infty ), or dne if the limit does not exist, but is neither ( infty ) nor ( -infty ). if you are having a hard time seeing the picture clearly, click on the picture. it will expand to a larger picture on its own page so that you can inspect it more clearly. a) ( lim_{x 	o -2} f(x) = square ) b) ( lim_{x 	o -2^+} f(x) = square ) c) ( lim_{x 	o -2} f(x) = square )

Accepted Answer

### Part (a): $\lim_{x \to -2} f(x)$
# Explanation:
## Step1: Analyze the graph near $ x = -2 $
The function $ f(x)=\frac{1}{(x + 2)^2} $ has a vertical asymptote at $ x=-2 $ (since the denominator is zero there and the numerator is non - zero). From the graph, as $ x $ approaches $ -2 $ from both the left and the right, the function values increase without bound.
## Step2: Determine the limit
For a limit as $ x \to a $ to exist, the left - hand limit and the right - hand limit must be equal. Here, as $ x $ approaches $ -2 $ (both sides), $ f(x) $ goes to $ \infty $. So $ \lim_{x \to -2}f(x)=\text{INF} $

### Part (b): $\lim_{x \to -2^{-}} f(x)$ (Left - hand limit as $ x $ approaches $ -2 $)
# Explanation:
## Step1: Analyze the left - hand side of $ x=-2 $
As $ x $ approaches $ -2 $ from the left (values of $ x $ less than $ -2 $, like $ x=-2 - h $ where $ h\to0^{+} $), we substitute into $ f(x)=\frac{1}{(x + 2)^2} $. Let $ x=-2 - h $, then $ f(x)=\frac{1}{(-h)^2}=\frac{1}{h^2} $. As $ h\to0^{+} $, $ \frac{1}{h^2}\to\infty $. From the graph, as we move towards $ x = - 2 $ from the left, the function values shoot up to infinity.
## Step2: Determine the left - hand limit
So $ \lim_{x \to -2^{-}}f(x)=\text{INF} $

### Part (c): $\lim_{x \to -2^{+}} f(x)$ (Right - hand limit as $ x $ approaches $ -2 $)
# Explanation:
## Step1: Analyze the right - hand side of $ x=-2 $
As $ x $ approaches $ -2 $ from the right (values of $ x $ greater than $ -2 $, like $ x=-2 + h $ where $ h\to0^{+} $), we substitute into $ f(x)=\frac{1}{(x + 2)^2} $. Let $ x=-2+h $, then $ f(x)=\frac{1}{h^2} $. As $ h\to0^{+} $, $ \frac{1}{h^2}\to\infty $. From the graph, as we move towards $ x=-2 $ from the right, the function values shoot up to infinity.
## Step2: Determine the right - hand limit
So $ \lim_{x \to -2^{+}}f(x)=\text{INF} $

# Answers:
a) $\text{INF}$

b) $\text{INF}$

c) $\text{INF}$

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QUESTION IMAGE

Question

Explanation:

Part (a): $\lim_{x \to -2} f(x)$

Step1: Analyze the graph near \( x = -2 \)

Step2: Determine the limit

Part (b): $\lim_{x \to -2^{-}} f(x)$ (Left - hand limit as \( x \) approaches \( -2 \))

Step1: Analyze the left - hand side of \( x=-2 \)

Step2: Determine the left - hand limit

Part (c): $\lim_{x \to -2^{+}} f(x)$ (Right - hand limit as \( x \) approaches \( -2 \))

Step1: Analyze the right - hand side of \( x=-2 \)

Step2: Determine the right - hand limit

Answer: