Difference between revisions of "Tutorial Week 10"

Latest revision as of 23:08, 30 December 2020

A undamped mass-spring system with mass 1 kg and spring constant 16 kg/s$^2$, is initially at rest. At $t=3$, a linearly increasing force is applied until the force reaches $F_0 = 10$ N at $t=8$. After that moment, the force remains constant at that level ($F_0$).
1. Write down the forcing function for this scenario in terms of Heaviside functions.
2. Write down the ODE for this mass-spring system subject to the given forcing function.
3. What is the transfer function ($H(s)$) and the impulse response ($h(t)$) for this ODE?
4. Use the impulse response and convolution to solve the ODE from part (b).
Consider the following differential equation:$$ y''+\omega^2 y=\frac{2}{\pi}\cos(t)$$ where $\omega=2.01$.
1. Find a particular solution $y_p(t)$ using the method of undetermined coefficients.
2. Now consider the equation $$ y''+\omega^2 y=\sum_{n=1}^{10}\frac{2}{n\pi}\cos(nt).$$ Use your solution in (a), and again the method of undetermined coefficients, to determine a particular solution $y_p(t)$.
3. Describe how the magnitude of the coefficients in your particular solution varies with n.

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 ## Describe how the magnitude of the coefficients in your particular solution varies with n.
-===Solutions===
+[[Tutorial Week 10 Solutions]]
-<ol>
-<li>
-<ol>
-<li>$f(t)= 2 u_3(t) (t-3) - 2u_8(t)(t-8)$ (2 marks -1 if there is a small error)</li>
-<li>$x''+16x=f(t)$ (1 mark)</li>
-<li>$H(s) = \frac{1}{s^2+16}$ (2 marks) $h(t)=\frac{1}{4} \sin(4t)$ (2 marks -1 if they did not include the coefficient)</li>
-<li>For $t<3$:
-::$x(t)=0\text{  (1 mark)}$.
-For $3<t<8$:
-::$x(t) = \int_0^t f(w)h(t-w) \ dw =\frac{1}{2} \int_3^t (w-3) \sin(4(t-w)) \ dw.\text{ (1 mark)}$
-For $t>8$:
-::$x(t) =\frac{1}{2} \int_3^8 (w-3)  \sin(4(t-w)) \ dw + \frac{1}{2} \int_8^t 5\sin(4(t-w)) \ dw.\text{  (2 marks)}$</li>
-</ol>
-<li>
-<ol>
-<li>$\displaystyle y_p=\frac{2}{\pi(\omega^2-1)}\cos (t)$ (1 mark)</li>
-<li>$y_p=\sum_{n=1}^{10}a_n \cos (nt)$ where $\displaystyle a_n=\frac{2}{n\pi (\omega^2-n^2)}$ (2 marks: 1 for the correct coefficient and 1 for writing the sum correctly)</li>
-<li> The magnitude of the coefficients decreases as the distance between $n$ and $\omega$ increases. (1 mark)</li>
-</ol>
-</li>