4. use the graph to find the following. write ±∞ or does not exist where appropriate.\na) $lim_{x\rightarrow3…

4. use the graph to find the following. write ±∞ or does not exist where appropriate.\na) $lim_{x\rightarrow3^{+}}f(x)=$\nb) $lim_{x\rightarrow3^{-}}f(x)=$\nc) $lim_{x\rightarrow3}f(x)=$\nd) $lim_{x\rightarrow - 2^{-}}f(x)=$\ne) $lim_{x\rightarrow4^{+}}f(x)=$\nf) $lim_{x\rightarrow - 2}f(x)=$\ng) $f(3.2)=$\nh) $f(-3)=$\ni) $f(-1.3)=$
Answer
Explanation:
Step1: Analyze right - hand limit as x approaches 3
As x approaches 3 from the right ($x\to3^{+}$), we look at the part of the graph for $x > 3$. The function approaches - 4. So, $\lim_{x\to3^{+}}f(x)=-4$.
Step2: Analyze left - hand limit as x approaches 3
As x approaches 3 from the left ($x\to3^{-}$), we look at the part of the graph for $x < 3$. The function approaches 2. So, $\lim_{x\to3^{-}}f(x)=2$.
Step3: Analyze overall limit as x approaches 3
Since $\lim_{x\to3^{+}}f(x)\neq\lim_{x\to3^{-}}f(x)$, $\lim_{x\to3}f(x)$ does not exist.
Step4: Analyze left - hand limit as x approaches - 2
As x approaches - 2 from the left ($x\to - 2^{-}$), the function approaches - 2. So, $\lim_{x\to - 2^{-}}f(x)=-2$.
Step5: Analyze right - hand limit as x approaches 4
As x approaches 4 from the right ($x\to4^{+}$), the function approaches $-\infty$. So, $\lim_{x\to4^{+}}f(x)=-\infty$.
Step6: Analyze overall limit as x approaches - 2
Since the function is continuous at $x=-2$, $\lim_{x\to - 2}f(x)=-2$.
Step7: Analyze derivative at x = 3.2
At $x = 3.2$, the function has a sharp corner, so the derivative $f^{\prime}(3.2)$ does not exist.
Step8: Analyze derivative at x=-3
At $x=-3$, the function is a horizontal line, so the slope (derivative) $f^{\prime}(-3)=0$.
Step9: Analyze derivative at x=-1.3
At $x=-1.3$, the function is a straight - line segment with a slope of 1, so $f^{\prime}(-1.3)=1$.
Answer:
a. $\lim_{x\to3^{+}}f(x)=-4$ b. $\lim_{x\to3^{-}}f(x)=2$ c. $\lim_{x\to3}f(x)$ does not exist d. $\lim_{x\to - 2^{-}}f(x)=-2$ e. $\lim_{x\to4^{+}}f(x)=-\infty$ f. $\lim_{x\to - 2}f(x)=-2$ g. $f^{\prime}(3.2)$ does not exist h. $f^{\prime}(-3)=0$ i. $f^{\prime}(-1.3)=1$