Summarize the pertinent information obtained by applying the graphing strategy and sketch the graph of $$ f(x)= $$ In $$ \left(x^{2}+9\right) $$. Summarize the pertinent information obtained by analyzing $$ f^{\prime}(x) $$. Select the correct choice below and fill in the answer box(es) to complete your choice. (Type your answer in interval notation. Use a comma to separate answers as needed.) A. $$ f(x) $$ is increasing on $$ \square $$ and decreasing on $$ \square $$ B. $$ f(x) $$ is increasing on C. $$ f(x) $$ is decreasing on $$ f(x) $$ has a local Summarize the pertinent information obtained by analyzing $$ f^{\prime \prime}(x) $$. Select the correct choice below and fill in the answer box(es) to complete your choice. (Type your answer in interval notation. Use a comma to separate answers as needed.) A. $$ f(x) $$ is concave upward on $$ \square $$ and concave downward on B. $$ f(x) $$ is concave upward on $$ \square $$. C. $$ f(x) $$ is concave downward on $$ \square $$.

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To analyze the function $$ f(x) = \ln(x^2 + 9) $$, we will follow these steps: 1. **Find the first derivative $$ f'(x) $$** to determine where the function is increasing or decreasing. 2. **Find the second derivative $$ f''(x) $$** to analyze the concavity of the function. 3. **Summarize the findings** based on the analysis of $$ f'(x) $$ and $$ f''(x) $$. ### Step 1: Find the first derivative $$ f'(x) $$ Using the chain rule, we can differentiate $$ f(x) $$: $$ f'(x) = \frac{d}{dx} \ln(x^2 + 9) = \frac{1}{x^2 + 9} \cdot \frac{d}{dx}(x^2 + 9) = \frac{1}{x^2 + 9} \cdot 2x = \frac{2x}{x^2 + 9} $$ ### Step 2: Determine where $$ f'(x) = 0 $$ Setting the first derivative equal to zero to find critical points: $$ \frac{2x}{x^2 + 9} = 0 $$ This occurs when $$ 2x = 0 $$, or $$ x = 0 $$. ### Step 3: Analyze the sign of $$ f'(x) $$ - For $$ x < 0 $$: $$ f'(x) < 0 $$ (decreasing) - For $$ x > 0 $$: $$ f'(x) > 0 $$ (increasing) Thus, we conclude: - $$ f(x) $$ is increasing on $$ (0, \infty) $$ - $$ f(x) $$ is decreasing on $$ (-\infty, 0) $$ ### Step 4: Find the second derivative $$ f''(x) $$ Now we differentiate $$ f'(x) $$: Using the quotient rule: $$ f''(x) = \frac{(x^2 + 9)(2) - (2x)(2x)}{(x^2 + 9)^2} = \frac{2(x^2 + 9 - 2x^2)}{(x^2 + 9)^2} = \frac{2(9 - x^2)}{(x^2 + 9)^2} $$ ### Step 5: Determine where $$ f''(x) = 0 $$ Setting the second derivative equal to zero: $$ 2(9 - x^2) = 0 \implies 9 - x^2 = 0 \implies x^2 = 9 \implies x = 3 \text{ or } x = -3 $$ ### Step 6: Analyze the sign of $$ f''(x) $$ - For $$ x < -3 $$: $$ f''(x) > 0 $$ (concave upward) - For $$ -3 < x < 3 $$: $$ f''(x) < 0 $$ (concave downward) - For $$ x > 3 $$: $$ f''(x) > 0 $$ (concave upward) Thus, we conclude: - $$ f(x) $$ is concave upward on $$ (-\infty, -3) $$ and $$ (3, \infty) $$ - $$ f(x) $$ is concave downward on $$ (-3, 3) $$ ### Summary of Findings 1. **From $$ f'(x) $$**: - A. $$ f(x) $$ is increasing on $$ (0, \infty) $$ and decreasing on $$ (-\infty, 0) $$ 2. **From $$ f''(x) $$**: - A. $$ f(x) $$ is concave upward on $$ (-\infty, -3) $$ and $$ (3, \infty) $$ and concave downward on $$ (-3, 3) $$ ### Final Answers - **Increasing/Decreasing**: - A. $$ f(x) $$ is increasing on $$ (0, \infty) $$ and decreasing on $$ (-\infty, 0) $$ - **Concavity**: - A. $$ f(x) $$ is concave upward on $$ (-\infty, -3) $$ and $$ (3, \infty) $$ and concave downward on $$ (-3, 3) $$ - **Increasing/Decreasing**: - $$ f(x) $$ is increasing on $$ (0, \infty) $$ and decreasing on $$ (-\infty, 0) $$ - **Concavity**: - $$ f(x) $$ is concave upward on $$ (-\infty, -3) $$ and $$ (3, \infty) $$, and concave downward on $$ (-3, 3) $$

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