### Author Topic: TT1--Problem 1  (Read 8454 times)

#### Victor Ivrii ##### TT1--Problem 1
« on: February 13, 2013, 10:36:58 PM »
Find integrating factor and solve
\begin{equation*}
x\,dx +y (1+x^2+y^2)\,dy=0.
\end{equation*}

#### Matthew Cristoferi-Paolucci

• Jr. Member
•  • Posts: 10
• Karma: 8 ##### Re: TT1--Problem 1
« Reply #1 on: February 13, 2013, 10:44:30 PM »
heres my solution

#### Marcia Bianchi

• Newbie
• • Posts: 4
• Karma: 3 ##### Re: TT1--Problem 1
« Reply #2 on: February 13, 2013, 10:46:08 PM »
solution

#### Marcia Bianchi

• Newbie
• • Posts: 4
• Karma: 3 ##### Re: TT1--Problem 1
« Reply #3 on: February 13, 2013, 10:49:07 PM »

#### Jeong Yeon Yook

• Full Member
•   • Posts: 20
• Karma: 8 ##### Re: TT1--Problem 1
« Reply #4 on: February 13, 2013, 10:57:16 PM »
better formatted solution

#### Alexander Jankowski

• Full Member
•   • Posts: 23
• Karma: 19 ##### Re: TT1--Problem 1
« Reply #5 on: February 13, 2013, 11:08:34 PM »
I am late, but at some point, someone is going to want a coded solution that isn't rotated by 90Â° CCW.

Let $M(x,y) = x$ and let $N(x,y) = y + x^2y + y^3$. Then,

\begin{align*}
M_y(x,y) = 0, & N_x(x,y) = 2xy.
\end{align*}

So the equation is not exact, and we need an integrating factor $\mu(x,y) = \mu(y)$ to make it exact.

\begin{equation*}
\frac{d\mu(y)}{dy} = \frac{N_x - M_y}{M} \mu(y) = \frac{2xy}{x} \mu(y) = y\mu(y) \Longrightarrow \frac{d\mu(y)}{\mu(y)} = 2ydy \Longrightarrow \mu(y) = e^{y^2}
\end{equation*}

Now, we require a function $\psi(x,y)$ that satisfies $\psi_x = \mu M$ and $\psi_y = \mu N$.

\begin{equation*}
\psi_x(x,y) = xe^{y^2} \Longrightarrow \psi(x,y) = \frac{1}{2}x^2e^{y^2} + h(y)
\end{equation*}

We differentiate the result to get

\begin{equation*}
\psi_y(x,y) = x^2xe^{y^2} + h'(y) = e^{y^2}(y + x^2y + y^3) \Longleftrightarrow h'(y) = e^{y^2}(y^3 + y) \Longrightarrow h(y) = \int{(e^{y^2}(y^3 + y))}dy.
\end{equation*}

Let $u = y^2$ so that $du = 2ydy$. Then,

\begin{equation*}
h(y) = \int{(y^3e^{y^2})}dy + \int{(ye^{y^2})}dy = \frac{1}{2}\int{(ue^u)}du + \frac{1}{2}\int{e^u}du = \frac{1}{2}ue^u - \frac{1}{2}\int{e^u}du + \frac{1}{2}e^u = \frac{1}{2}ue^u - \frac{1}{2}e^u + \frac{1}{2}e^u = \frac{1}{2}y^2e^{y^2}.
\end{equation*}

Therefore, the solution is implicitly given by

\begin{equation*}
C = \frac{1}{2}e^{y^2}(x^2 + y^2).
\end{equation*}
« Last Edit: February 14, 2013, 12:02:27 AM by Alexander Jankowski »

#### Victor Ivrii ##### Re: TT1--Problem 1
« Reply #6 on: February 14, 2013, 04:55:35 AM »
I decided to be generous and awarded karma to all 4. Marcia definitely realized that her first scan (actually snapshot) was almost completely useless and reposted with double resolution; honestly, even her 2nd snapshot is inferior. Matthew positioned paper in the best possible way, and Yook used grayscale (better than colour; however black and white would be even better but it requires more knowledge--see my avatar for b/w) and a monster-resolution picture (but because it was grayscale file size was not much larger!)

Alexander' post is far superior (orientation is not that important, major advantage it is typed and could be easily edited and recycled so in the most strict approach (the first gets all) Matthew and Alexander would get their karma.