How to solve equation with Fourier's method of separation of variables

Question

$\frac{\partial^2 u}{\partial t^2} - 4 \frac{\partial^2 u}{\partial x^2} = 0$

$0< x< 1,t> 0$

Boundary conditions $\frac{\partial u }{\partial x}(0,t)=0$, $\frac{\partial u }{\partial x}(1,t)=0$

Initial conditions $u(x,0)=0$, $\frac{\partial u }{\partial t}(x,0)=cos^2(\pi x)$

with solution $\frac{t}{2} + \frac{1}{8 \pi}cos(2 \pi x)sin(4 \pi t)$

I tried with: $X(x)T''(t)=4X''(x)T(t)=\lambda$

$X'' - \lambda X =0$

a) There is no solution for $\lambda = K^2$

b) For $\lambda =0$ , $X(x)=A+Bx$ , $X'(x)=B$

With the boundary conditions $0=B$ and there's a solution $X=A$

c) For $\lambda = -K^2$ , $X=A cos(Kx) + B sin (kx)$

$X'=-AKsin(Kx) + BK cos(Kx)$ , using the boundary conditions $B=0$ , $X_n=Acos(n \pi)x$ and $\lambda = - \pi^2 n^2$

Solving for $T(t)$ , $T''-4 \lambda T =0$

a) For $\lambda = 0$ , $T= C + Dt$

A solution $u(x,t)= A \cdot (C+Dt) = C+Dt$ , using the initial conditions, $C=0$ , $u'(x,t)=D = cos^2( \pi x)$ and $u(x,t)=cos^2 (\pi x)t$

b) for $\lambda = - \pi^2 n^2$

$T_n= A cos(2n \pi)t + B sin(2n \pi)t$

The solution $u_n(x,t)= A cos(n \pi x)cos(2n \pi)t + B cos(n \pi x)sin(2n \pi)t$

Applying Fourier series $u(x,t) = \sum_{n=1}^{n= \infty} a_n cos(n \pi x)cos(2n \pi)t + b_n cos(n \pi x)sin(2n \pi)t$

Using the initial conditions $u(x,t) =\sum_{n=1}^{n= \infty} a_n cos(n \pi x) $

$a_n = \frac{<0,cos(n \pi x)>}{<cos(n \pi x),cos(n \pi x)>} = 0$

$u'(x,t) = \sum_{n=1}^{n= \infty} -a_n cos(n \pi x)2n \pi sin(2n \pi)t + b_n cos(n \pi x)2n \pi cos(2n \pi)t$

$b_n = \frac{<cos^2 \pi x,cos(n \pi x)>}{<cos(n \pi x),cos(n \pi x)>} = 0$

The solution that I get is $u(x,t)=cos^2 (\pi x)t$

EDIT:

How can I find $A_n$ using using Fourier coefficient formula?. That's the only way I've been taught to find it. In this case $A_n =\ \frac {\int_{0}^{1}cos^2(\pi x)cos(n \pi x)}{\int_{0}^{1}cos(n \pi x)^2}$ $\int_{0}^{1}cos^2(\pi x)cos(n \pi x) = \int_{0}^{1}1/2 \cdot cos(n \pi x) + \ 1/2 \cdot \int_{0}^{1}cos(2 \pi x)cos(n \pi x).$

$\int_{0}^{1}1/2 \cdot cos(n \pi x) = 1/2 \cdot [_0^1 \frac {sin(n \pi x)}{n \pi} = 0 $

Using the product sum formula $\cos x \cos y=\frac{1}{2}[\cos(x-y)+\cos(x+y)]\\$ The second integral $\ 1/2 \cdot \int_{0}^{1}cos(2 \pi x)cos(n \pi x)= 1/2 \cdot \int_{0}^{1}cos(\pi x(2-n) )+ \int_{0}^{1}cos(\pi x(2+n) ) = \ 1/2 \cdot[_0^1 \frac {sin(\pi x (2-n)}{\pi(2-n)}=0+ \ 1/2 \cdot[_0^1 \frac {sin(\pi x (2+n)}{\pi(2+n)}=0 $

Answer 1

The separation of variables problem for $u(x,t)=X(x)T(t)$ is $$ \frac{T''}{T} = \lambda = 4\frac{X''}{X}, \\ X'(0)=X'(1)=0 \\ T(0)=0. $$ To normalize the soutions $X$, assume that $X(0)=1$. The solutions of $$ X''+\frac{\lambda}{4}X=0 \\ X(0)=1,\; X'(0)=0 $$ have the form $$ X(x)=\cos\frac{\sqrt{\lambda}}{2}x. $$ This works for $\lambda=0$ as well, to give the solution $X(x)=1$. $\lambda$ is an eigenvalue iff the above solution satisfies $X'(0)=0$, which results in the eigenvalue equation $$ \frac{\sqrt{\lambda}}{2}\sin\frac{\sqrt{\lambda}}{2}=0. $$ The valid eigenvalues are $$ \frac{\sqrt{\lambda}}{2}=n\pi,\;\;\; n=0,1,2,3,\cdots,\\ \lambda_n = 4n^2\pi^2,\;\; n=0,1,2,3,\cdots. $$ The corresponding eigenfunctions are $$ X_n(x) = \cos(n\pi x),\;\;\; n=0,1,2,3,\cdots. $$ Because $T(0)=0$, the solutions in $t$ are \begin{align} T_0(t) & = A_0 t \\ T_n(t) & = A_n\sin(2n\pi t), \; \; n \ge 1. \end{align} The general solution becomes $$ u(x,t)= A_0t+\sum_{n=1}^{\infty}A_n\sin(2n\pi t)\cos(n\pi x). $$ The coefficients $A_n$ are determined by the initial conditions $$ \cos^2(\pi x) = u_t(x,0)= A_0+\sum_{n=1}^{\infty}2n\pi A_n\cos(n\pi x) \\ \frac{1}{2}(\cos(2\pi x)+1) = A_0+\sum_{n=1}^{\infty}2\pi n A_n\cos(n\pi x). $$ From this you can see that all $A_n$ are $0$ except, $$ A_0=\frac{1}{2},\;\; A_2=\frac{1}{8\pi} $$ So, the solution is $$ u(x,t) = \frac{t}{2}+\frac{1}{8\pi}\sin(4\pi t)\cos(2\pi x). $$