The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-1
\[ \newcommand{\dnorm}{\text{dnorm}} \newcommand{\pnorm}{\text{pnorm}} \newcommand{\recip}{\text{recip}} \]
Exercise 1 Which of the derivative rules should you use to find \[\partial_t e^{t^2}\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-1
Exercise 2 Which of the derivative rules should you use to find \[\partial_t e^{x^2}\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-2
Exercise 3 Which of the derivative rules should you use to find \[\partial_t e^t \sin(t)\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-3
Exercise 4 Which of the derivative rules should you use to find \[\partial_t e^t \sin(x)\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-4
Exercise 5 Which of the derivative rules should you use to find \[\partial_t \ln(t)\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-5
Exercise 6 Which of the derivative rules should you use to find \[\partial_t\, t\, e^{-t}\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-6
Exercise 7 Which of the derivative rules should you use to find \[\partial_x\ 37 x^5\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-7
Exercise 8 Which of the derivative rules should you use to find \[\partial_x\ 19\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-8
Exercise 9 Which of the derivative rules should you use to find \[\partial_x\ 15 x^2 - 3 x + 7 \ln(x)\ ?\]
The constant multiplier rule
The linear combination rule
The product rule
The chain rule
No rule needed, it is so basic.
question id: drill-Deriv-rules-9
Exercise 10 What is \(\partial_x\ 15 x^2 - 3 x + 7 \ln(x)\)?
\(15 x - 3 + 7/x\)
\(30 x - 3 + 7/x\)
\(30 x - 3x + 7/x\)
\(30 x - 3 - 7/x\)
question id: drill-Deriv-rules-10
Exercise 11 What is \(\partial_t e^k + \ln(e^2) - t\)?
question id: drill-Deriv-rules-11
Exercise 12 What is \(\partial_{x} \ln(x)/x^2\)? (Hint: You can write the function in a simpler way.)
question id: drill-Deriv-rules-12
Exercise 13 Which of these is \(\partial_t \left(ln(6)+t^4-e^t\right)\)?
\(\frac{1}{6}+4t^3-e^t\)
\(\frac{1}{6}+4t^3-e^{-t}\)
\(4t^3-e^{-t}\)
\(4t^3-e^t\)
question id: drill-Deriv-rules-12a
Exercise 14 Which of these is \(\partial_u(\frac{1}{u^6}-\pi^3+4u^3+e)\)?
\(-6u^{-7}-3\pi^2+4u^3\)
\(-6u^{-5}-3\pi^2+12u^2+\frac{1}{e}\)
\(-6u^{-7}+12u^2\)
\(-6u^{-5}+12u^2 +\frac{1}{e}\)
question id: drill-Deriv-rules-12b
Exercise 15 Which of these is \(\partial_v(\sqrt[4]{v^7}+e^7-4-\frac{3v^6}{v^2})=\)
\(\frac{7}{4}\frac{1}{v^4}+7e^6-\frac{18v^5}{2v}\)
\(\frac{7}{4}v^{\frac{3}{4}}-12v^3\)
\(\frac{4}{7}v^{\frac{-3}{7}}-\frac{18v^5}{2v}\)
\(\frac{7}{4}v^{\frac{3}{4}}+e^7-12v^3\)
question id: drill-Deriv-rules-12c
Exercise 16 What is \(\partial_{t} \left(4 \sin(2\pi t) - 5\right)\)?
question id: drill-Deriv-rules-13
Exercise 17 What is \(\partial_{t} \left(7 + 8 t^2 + 3 t^4\right)\)?
question id: drill-Deriv-rules-14
Exercise 18 The derivative \(\partial_x \text{dnorm}(x) = - x\, \text{dnorm}(x)\). What is \[\partial_x \text{dnorm}\left(\frac{x^2}{4}\right)\ ?\]
\(- \frac{x^3}{8} \text{dnorm}\left(\frac{x^2}{4}\right)\)
\(-\frac{x}{2} \text{dnorm}\left(\frac{x^2}{4}\right)\)
\(-\frac{x}{8} \text{dnorm}\left(\frac{x^2}{4}\right)\)
\(-\frac{x^2}{2} \text{dnorm}\left(\frac{x^2}{4}\right)\)
question id: drill-Deriv-rules-15
Exercise 19 What is \(\partial_{t} \left(6 t - 3 t^2 + 2 t^4\right)\)?
question id: drill-Deriv-rules-16
Exercise 20 What is \(\partial_t \ln(t^2 + 1)\)?
question id: drill-Deriv-rules-17
Exercise 21 For the function \[g(t) \equiv \sin\left(\frac{2 \pi}{P} (t - t_0)\right)\] is the interior function linear?
question id: drill-M08-1
Exercise 22 For the function \[g(P) \equiv \sin\left(\frac{2 \pi}{P} (t - t_0)\right)\] is the interior function linear?
question id: drill-M08-2
Exercise 23 For the function \[h(u) \equiv \ln(a^2 u - \sqrt{b})\] is the interior function linear?
question id: drill-M08-3
Exercise 24 For the function \(f(w) \equiv e^{kw}\), is the interior function linear?
question id: drill-M08-4
Exercise 25 Saying “the interior function is linear” is not an entirely complete statement. A full statement is “the interior function is linear in terms of the input \(x\)” or “in terms of the input \(u\)” or whatever name we choose to use for the input.
Is the expression \(V x + U\) linear in terms of \(U\)?
question id: drill-M08-5
Exercise 26 Saying “the interior function is linear” is not an entirely complete statement. A full statement is “the interior function is linear in terms of the input \(x\)” or “in terms of the input \(u\)” or whatever name we choose to use for the input.
Is the expression \(V x^2 + U\) linear in terms of \(U\)?
question id: drill-M08-6
Exercise 27 Saying “the interior function is linear” is not an entirely complete statement. A full statement is “the interior function is linear in terms of the input \(x\)” or “in terms of the input \(u\)” or whatever name we choose to use for the input.
Is the expression \(V x^2 + U\) linear in terms of \(X\)?
question id: drill-M08-7