Let g be a continuous function with g(2) = 5. The graph of the piecewise-linear function g', the derivative of g, is (1. 1) (7, 1) shown above for -3 s x S 7. (-1.0) (a) Find the r-coordinate of all points of inflection of the graph of y = g(x) for -3 < x < 7. Justify your answer. (4.-2) (b) Find the absolute maximum value of g on the interval -3 s r s 7. Justify your answer. (c) Find the average rate of change of g(x) on the interval -3 < x S7. Giraph of g'

Transcribed Image Text:

**Problem Statement:** Let \( g \) be a continuous function with \( g(2) = 5 \). The graph of the piecewise-linear function \( g' \), the derivative of \( g \), is shown above for \( -3 \leq x \leq 7 \). **(a)** Find the \( x \)-coordinate of all points of inflection of the graph of \( y = g(x) \) for \(-3 < x < 7\). Justify your answer. **(b)** Find the absolute maximum value of \( g \) on the interval \(-3 \leq x \leq 7\). Justify your answer. **(c)** Find the average rate of change of \( g(x) \) on the interval \(-3 \leq x \leq 7\). **(d)** Find the average rate of change of \( g'(x) \) on the interval \(-3 \leq x \leq 7\). Does the Mean Value Theorem applied on the interval \(-3 \leq x \leq 7\) guarantee a value of \( c \), for \(-3 < c < 7\), such that \( g'(c) \) is equal to this average rate of change? Why or why not? **Graphical Explanation:** The graph labeled "Graph of \( g' \)" is a piecewise-linear graph with key points at \((-3, -4)\), \((-1, 0)\), \( (1, 1)\), \( (4, -2)\), and \( (7, 1)\). The graph forms line segments connecting these points: - From \((-3, -4)\) to \((-1, 0)\) - From \((-1, 0)\) to \( (1, 1)\) - From \( (1, 1)\) to \( (4, -2)\) - From \( (4, -2)\) to \( (7, 1)\) The \( y \)-axis represents \( g'(x) \), and the \( x \)-axis represents values from \(-3\) to \(7\) in regular increments.