121 lines
5.9 KiB
Markdown
121 lines
5.9 KiB
Markdown
# Variation of parameters
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>[Professors definition/derivations during lecture](prof-variation-of-parameters.html) <- I found this to be too big brain for me. Here is a simplified definition:
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## Variation of parameters is a method to solve:
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## $$ay''+by'+cy=f(t)$$
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#voparam
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First, find the homogenous solution:
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$y_{h}=c_{1}y_{1}(t)+c_{2}y_{2}(t)$
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Now we need the particular solution, let $y_{p}$ be in the following form:
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$y_{p}(t)=v_{1}(t)y_{1}(t)+v_{2}(t)y_{2}(t)$ <- btw $y_{1}$ and $y_{2}$ are often called a fundamental pair. They are obtained from your homogenous solution.
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Impose the following:
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1) $v_{1}'y_{1}+v_{2}'y_{2}=0$
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Compute the derivatives and simplify:
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$y_{p}'=v_{1}y_{1}'+v_{2}y_{2}'$
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$y_{p}''=v_{1}'y_{1}'+v_{1}y_{1}''+v_{2}'y_{2}'+v_{2}y_{2}''$
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Now we plug those into the second order equation and simplify:
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2) $v_{1}'y_{1}'+v_{2}'y_{2}'=\frac{f(t)}{a}$
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We now have a system of two equations (1 and 2). Now we can solve for $v_{1}$ and $v_{2}$:
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Using Cramer's rule, we can solve for the system of equations and obtain the solutions:
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$v_{1}'=-\frac{{f(t)y_{2}(t)}}{aW[y_{1},y_{2}]}$; $v_{2}'=\frac{{f(t)y_{1}(t)}}{aW[y_{1},y_{2}]}$ <- integrate both sizes to get $v_{1}$ and $v_{2}$. When integrating, you don't need to add a generic constant.
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also, $W[y_1,y_{2}]$ is the Wrońskian, and it equals to: $\det \begin{pmatrix}y_{1}&y_{2}\\ y_{1}' &y_{2}'\end{pmatrix}=y_{1}y_{2}'-y_{2}y_{1}'$
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Finally, the general solution is:
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$$y(t)=y_{h}+y_{p}\qquad \text{where}\qquad y_{p}(t)=v_{1}(t)y_{1}(t)+v_{2}(t)y_{2}(t)$$
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## What you need to remember
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#remember
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So, what do you need to commit to memory? I believe memorizing these three is a good tradeoff between memory allocated and speed for when you're solving a #voparam problem:
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1) $y_{p}(t)=v_{1}(t)y_{1}(t)+v_{2}(t)y_{2}(t)$
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2) $v_{1}'=-\frac{{f(t)y_{2}(t)}}{aW[y_{1},y_{2}]}$
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3) $v_{2}'=\frac{{f(t)y_{1}(t)}}{aW[y_{1},y_{2}]}$
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Alternatively, you could memorize the system of equations and solve for $v_{1}'$ and $v_{2}'$. Ie:
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1) $y_{p}(t)=v_{1}(t)y_{1}(t)+v_{2}(t)y_{2}(t)$
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2) $v_{1}'y_{1}+v_{2}'y_{2}=0$
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3) $v_{1}'y_{1}'+v_{2}'y_{2}'=\frac{f(t)}{a}$
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This is what the prof likes. I love you Dr. Minev, but this I personally disagree with. I think I'll stick with the formulas.
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---
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#ex #second_order #IVP #voparam #mouc
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Solve the IVP:
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$$y''+4y=2\tan(2t)-e^t \qquad y(0)=0 \qquad y'(0)=\frac{4}{5}$$
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Can we use undetermined coefficients? Yes and no. We can use it on the $e^t$ term. However, guessing and checking $y_{p}$ for the $2\tan(2t)$ term might take a really, really long time.
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First, find general solution to homogenous counterpart:
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$y''+4y=0$ -> $r^2+4=0$ -> $r_{1,2}=\pm 2i$
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$y_{h}(t)=c_{1}\cos(2t)+c_{2}\sin(2t)$ Done. Easy peasy.
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For $-e^t$ lets use method of undetermined coefficients:
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$y''+4y=-e^t$
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$y_{p_{1}}(t)=Ae^{t}$
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$5Ae^t=-e^t$
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$A=-\frac{1}{5}$
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$y_{p_{1}}(t)=-\frac{1}{5}e^t$
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Now for $2\tan(2t)$, we cannot realistically use method of undetermined coefficients.
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Let's use variation of parameters instead:
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$y''+4y=2\tan(2t)$
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$y_{p_{2}}(t)=v_{1}(t)y_{1}(t)+v_{2}(t)y_{2}(t)$
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where $y_{1}=\cos(2t)$, $y_{2}=\sin(2t)$
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recall:
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$v_{1}'=-\frac{f(t)y_{2}}{aW[y_{1},y_{2}]}$
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$v_{2}'=\frac{f(t)y_{1}}{aW[y_{1},y_{2}]}$
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plugging in:
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$v_{1}'=-\frac{2\tan(2t)\sin(2t)}{(1)(\cos2t(2)\cos2t-\sin2t(-2)\sin2t}=-\frac{2\tan(2t)\sin(2t)}{2\cos^22t+2\sin^22t}=-\tan(2t)\sin(2t)$
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$v_{2}'=\frac{2\tan(2t)\cos(2t)}{2}=\sin(2t)$ <- isn't it nice how we can reuse our computation for the denominator? :D
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Now we integrate.
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$v_{2}=-\frac{1}{2}\cos(2t)$ <- Don't add a constant of integration, we want one solution only.
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$v_{1}=-\int \frac{\sin^2(2t)}{\cos(2t)} \, dt$
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$v_{1}=-\int \frac{{1-\cos^2(2t)}}{\cos(2t)} \, dt$
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$v_1=-\int sec(2t) \, dt+\int \cos(2t) \, dt$
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$v_{1}(t)=-\frac{1}{2}\ln\mid sec(2t)+\tan(2t)\mid+\frac{1}{2}\sin(2t)$
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$y_{p_{2}}(t)=v_{1}(t)\cos(2t)+v_{2}(t)\sin(2t)$
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> ^Now you can start to see how guessing $y_{p_{2}}$ would take a really, really long time.
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$y(t)=y_{h}(t)+y_{p_{1}}(t)+y_{p_{2}}(t)$
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=$c_{1}\cos(2t)+c_{2}\sin(2t)+v_{1}(t)\cos(2t)+v_{2}(t)\sin(2t)-\frac{1}{5}e^t$
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is the general answer.
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IVP solution:
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$y(0)=0=c_{1}-y_{p}(0)=c_{1}-\frac{1}{5} \implies c_{1}=\frac{1}{5}$
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$y'(0)=\frac{4}{5}=2c_{2}+v_{1}'(0)+2v_{2}(0)-\frac{1}{5} \implies c_{2}=1$
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$$y(t)=\frac{1}{5}\cos(2t)+\sin(2t)-\frac{1}{5}e^t+v_{1}(t)\cos(2t)+v_{2}(t)\sin(2t)$$
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#end of lecture 9 #start of lecture 10
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#ex #second_order #voparam #mouc
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Find the general solution for:
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$$y''-2y'+y=e^t\ln(t)+2\cos(t)$$
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Find homogenous solution first:
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$r^2-2r+1=0$
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$r_{1,2}=1$ (repeated root)
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$y_{h}(t)=c_{1}e^t+c_{2}te^t$
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2) $y_{p}(t)=?$
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$y''-2y'+y=2\cos (t)$
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let's use method of undetermined coefficients:
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$y_{p_{1}}=A\cos(t)+B\sin(t)$ is our guess
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$y_{p_{1}}'=-A\sin t+B\cos t$
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$y_{p_{1}}''=-A\cos t-B\sin t$
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$-A\cos t-B\sin t+2A\sin t-2B\cos t+A\cos t+B\sin t=2\cos t$
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$-2B\cos t+2A\sin(t)=2\cos t(t)$
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$\implies A=0,\ B=-1$
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$y_{p_{1}}=-\sin(t)$
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$y''-2y'+y=e^t\ln(t)$ cant use undetermined coefficients, use variation of parameters
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$y_{p}''(t)=v_{1}y_{1}+v_{2}y_{2}$
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$=v_{1}e^t+v_{2}te^t$
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Compute $v_{1}$ and $v_{2}$. This time let's do it using the linear system for practice:
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eq1) $e^tv_{1}'+te^tv_{2}'=0$
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eq2) $e^tv_{1}'+(te^t+e^t){v_{2}'}=e^t{\ln t}$
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subtract eq1 from eq2: $v_{2}'=\ln(t)$
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$v_{2}(t)=\int \ln(t) \, dt$
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integrate by parts
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$=t\ln(t)-\int t\frac{1}{t} \, dt$
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$=t\ln(t)-t$ no constant of integration.
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compute $v_{1}$ now:
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$v_{1}'=-tv_{2}'$
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$=-t\ln t$
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integrate to get $v_1$:
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$v_{1}=-\int t\ln t \, dt$
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integrate by parts (btw integration by parts will be the most important integration technique in this course):
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$v_{1}=-\frac{1}{2}(t^2\ln t)-\int t^2\frac{1}{t} \, dt$
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$=-\frac{1}{2}\left( t^2\ln t-\frac{t^2}{2} \right)=-\frac{1}{2}t^2\ln t+\frac{1}{4}t^2$
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$y_{p}''(t)=(\frac{1}{2}t^2\ln t+\frac{1}{4}t^2)e^t+(t\ln t-t)te^t$
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$y_{p}(t)=-\sin(t)+\frac{1}{2}t^2\ln(t)e^t-\frac{3}{4}t^2e^t$
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general solution is produced by adding the homogenous eq with $y_{p}(t)$
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general solution:
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$$y(t)=c_{1}e^t+c_{2}te^t-\sin(t)+\frac{1}{2}t^2\ln(t)e^t-\frac{3}{4}t^2e^t$$
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We are done. |