suppose that (f(x)=10 - 2e^{-x}). (a) list all critical numbers of (f). if there are no critical numbers, enter none. (b) use interval notation to indicate where (f(x)) is increasing. increasing: (c) list the (x) - coordinates of all local maxima of (f). if there are no local maxima, enter none. (x) values of local maxima = (d) find the (x) - coordinates of all local minima of (f). if there are no local minima, enter none. (x) values of local minima = (e) use interval notation to indicate where (f(x)) is concave down. concave down: (f) list the (x) values of all inflection points of (f). if there are no inflection points, enter none. (x) values of inflection points = (g) list the horizontal asymptotes of (f). if there are no horizontal asymptotes, enter none. horizontal asymptotes (y=) (h) use all of the preceding information to sketch a graph of (f). when youre finished, enter a 1 in the box below. graph complete:

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1. **Find the derivative of $y = f(x)=10 - 2e^{-x}$**: - Recall the derivative of $e^{-x}$ is $-e^{-x}$. Using the sum - rule and constant - multiple rule of differentiation, if $y = 10-2e^{-x}$, then $y^\prime=f^\prime(x)=2e^{-x}$. 2. **(A) Find critical numbers**: - Critical numbers occur where $f^\prime(x) = 0$ or $f^\prime(x)$ is undefined. - Set $f^\prime(x)=2e^{-x}=0$. Since $e^{-x}=\frac{1}{e^{x}}$ and $e^{x}>0$ for all real $x$, $2e^{-x}$ is never zero. Also, $f^\prime(x)$ is defined for all real $x$. - # Answer: NONE 3. **(B) Find where $f(x)$ is increasing**: - A function $y = f(x)$ is increasing when $f^\prime(x)>0$. - Since $f^\prime(x)=2e^{-x}=\frac{2}{e^{x}}>0$ for all real $x$ (because $e^{x}>0$ for all $x\in R$). - In interval notation, the interval of increase is $(-\infty,\infty)$. - # Answer: $(-\infty,\infty)$ 4. **(C) Find local maxima and minima**: - Since there are no critical numbers (where the derivative is zero or undefined), there are no local maxima or minima. - # Answer: NONE 5. **(D) Find local minima**: - As above, since there are no critical numbers, there are no local minima. - # Answer: NONE 6. **(E) Find where $f(x)$ is concave down**: - First, find the second - derivative of $y = f(x)$. - Since $f^\prime(x)=2e^{-x}$, then $f^{\prime\prime}(x)=- 2e^{-x}$. - A function $y = f(x)$ is concave down when $f^{\prime\prime}(x)<0$. - Set $f^{\prime\prime}(x)=-2e^{-x}<0$. Since $e^{-x}=\frac{1}{e^{x}}>0$ for all real $x$, $-2e^{-x}<0$ for all real $x$. - In interval notation, the interval where $f(x)$ is concave down is $(-\infty,\infty)$. - # Answer: $(-\infty,\infty)$ 7. **(F) Find inflection points**: - Inflection points occur where $f^{\prime\prime}(x)$ changes sign. Since $f^{\prime\prime}(x)=-2e^{-x}<0$ for all real $x$, $f^{\prime\prime}(x)$ never changes sign. - # Answer: NONE 8. **(G) Find horizontal asymptotes**: - Calculate $\lim_{x ightarrow\infty}f(x)=\lim_{x ightarrow\infty}(10 - 2e^{-x})$. - As $x ightarrow\infty$, $e^{-x}=\frac{1}{e^{x}} ightarrow0$. So, $\lim_{x ightarrow\infty}(10 - 2e^{-x}) = 10$. - Calculate $\lim_{x ightarrow-\infty}f(x)=\lim_{x ightarrow-\infty}(10 - 2e^{-x})$. As $x ightarrow-\infty$, $e^{-x} ightarrow\infty$, and $\lim_{x ightarrow-\infty}(10 - 2e^{-x})=-\infty$. - The horizontal asymptote is $y = 10$. - # Answer: $y = 10$ 9. **(H) Sketch the graph**: - The function $y = 10-2e^{-x}$ has a horizontal asymptote $y = 10$, is increasing on $(-\infty,\infty)$, is concave down on $(-\infty,\infty)$, and has no critical numbers, local maxima, local minima, or inflection points. When $x = 0$, $y=10 - 2=8$. The graph starts below the horizontal asymptote $y = 10$ (at $y = 8$ when $x = 0$) and increases towards $y = 10$ as $x ightarrow\infty$. So, the answers are: (A) NONE (B) $(-\infty,\infty)$ (C) NONE (D) NONE (E) $(-\infty,\infty)$ (F) NONE (G) $y = 10$ (H) (Sketch as described above)

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