math104-f21:hw13
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math104-f21:hw13 [2021/11/29 12:21] pzhou |
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| ====== HW 13 ====== | ====== HW 13 ====== | ||
| - | Due Monday (Nov 29) 6pm. | + | Due Monday (Nov 29) 9pm. 8-O problem 6 contains a typo, and it is updated now. |
| 1. In class we have seen that a function $f(x)$ may be differentiable everywhere, but the derivative function $f' | 1. In class we have seen that a function $f(x)$ may be differentiable everywhere, but the derivative function $f' | ||
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| 3. Ross Ex 29.3 | 3. Ross Ex 29.3 | ||
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| 4. Ross Ex 29.5 | 4. Ross Ex 29.5 | ||
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| 5. Ross Ex 30.1 | 5. Ross Ex 30.1 | ||
| - | 6. Prove that $\lim_{x \to 0^+} x^{-n} e^{-1/x} = 0$. Hint: let $u = 1/x$, and turn the problem into a $u \to \infty$ limit calculation, | + | 6. Prove that $\lim_{x \to 0^+} x^{-n} e^{-1/x} = 0$. Hint: let $u = 1/x$, and turn the problem into a $u \to \infty$ limit calculation, |
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| + | ====== Solution ====== | ||
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| + | 1. Assume that $\lim_{x \to 0} f'(x) = 1$. Prove that $f' | ||
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| + | By mean value theorem for interval $[0, | ||
| + | $$ \frac{f(\delta)-f(0)}{\delta - 0} = f' | ||
| + | some $x_\delta \in (0, \delta)$. Thus as $\delta \to 0$, $x_\delta \to 0$, hence | ||
| + | $$ \lim_{\delta \to 0}\frac{f(\delta)-f(0)}{\delta - 0} = \lim_{\delta \to 0} f' | ||
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| + | 2. If $f: [0,1] \to \R$ is a differentiable function such that $f' | ||
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| + | It may not be true. Let $g(x)= e^{-1/x}$ for $x \in (0,1]$ and $g(0)=0$. Then $g' | ||
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| + | 3. Ross Ex 29.3 | ||
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| + | {{math104-f21: | ||
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| + | Consider the interval $[0,2]$, the slope of the segment $\frac{f(2)-f(0)}{2-0} = 1/2$, hence there is an $x_1 \in (0,2)$, such that $f' | ||
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| + | Consider the interval $[1,2]$, by mean value theorem, there is a $x_2 \in (1,2)$, such that $f' | ||
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| + | By the intermediate value theorem, since $1/7 \in (0,1/2)$, there is an $x_3 \in (x_1, x_2)$ or $(x_2, | ||
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| + | 4. Ross Ex 29.5 | ||
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| + | {{math104-f21: | ||
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| + | We can prove that $f' | ||
| + | $$ \lim_{h\to 0} \left| \frac{ f(x+h) - f(x)}{h} \right| \leq \lim_{h\to 0} h = 0. $$ | ||
| + | Thus, for any $x_1, x_2 \in \R$, we may apply the mean value theorem to get | ||
| + | $$ f(x_1) - f(x_2) = (x_1 - x_2) f' | ||
| + | for some $x_3 \in (x_1, x_2)$. | ||
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| + | 5. Ross Ex 30.1 | ||
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| + | {{math104-f21: | ||
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| + | (a) Taking derivatives once both upstairs and downstairs, we get | ||
| + | $$ \lim_{x\to 0} \frac{2 e^{2x}+\sin(x)}{1} = 2 $$ | ||
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| + | (b) Taking derivatives twice both upstairs and downstairs, we get | ||
| + | $$ \lim_{x\to 0} \frac{\cos(x)}{2} = 1/2 $$ | ||
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| + | (c ) Taking derivatives 3 times both upstairs and downstairs, we get | ||
| + | $$ \lim_{x \to \infty} \frac{6}{8 e^{2x}} = 0 $$ | ||
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| + | (d) Taking derivative once, we get | ||
| + | $$ \lim_{x \to 0} \frac{1/ | ||
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| + | 6. Prove that $\lim_{x \to 0^+} x^{-n} e^{-1/x} = 0$. | ||
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| + | Let $u = 1/x$, then we are computing | ||
| + | $$ \lim_{u\to \infty} u^n / e^{u} $$ | ||
| + | We may apply L' | ||
| + | $$ \lim_{u\to \infty} u^n / e^{u} = \lim_{u\to \infty} n! e^{-u} = 0. $$ | ||
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math104-f21/hw13.1638217270.txt.gz · Last modified: 2021/11/29 12:21 by pzhou
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