Cartesian coordinates

\begin {align*} u\left ( 0,y,t\right ) & =0\\ u\left ( L,y,t\right ) & =0 \end {align*}

And boundary conditions on \(y\)\begin {align*} u\left ( x,0,t\right ) & =0\\ u\left ( x,H,t\right ) & =0 \end {align*}

Initial conditions\begin {align*} u\left ( x,y,0\right ) & =f\left ( x,y\right ) \\ \frac {\partial u}{\partial t}\left ( x,y,0\right ) & =g\left ( x,y\right ) \end {align*}

Mathematica ✗

ClearAll["Global`*"]; 
pde = D[u[x, y, t], {t, 2}] == c^2*Laplacian[u[x, y, t], {x, y}]; 
ic = {Derivative[0, 0, 1][u][x, y, 0] == g[x, y], u[x, y, 0] == f[x, y]}; 
bc = {u[0, y, t] == 0, u[0, H, t] == 0, u[x, 0, t] == 0, u[x, L, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, bc, ic}, u[x, y, t], {x, y, t},Assumptions -> {H > 0, L > 0, c > 0}], 60*10]];

Failed

Maple ✓

restart; 
pde := diff(u(x, y, t), t$2) = c^2*VectorCalculus:-Laplacian(u(x,y,t),[x,y]); 
bc  := u(0,y,t)=0, 
       u(L,y,t)=0, 
       u(x, 0, t) = 0, 
       u(x, H, t) = 0; 
ic  := u(x, y, 0) = f(x,y),(D[3](u))(x, y, 0) = g(x,y); 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde,bc,ic],u(x,y,t))assuming L>0,H>0),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=1}^{\infty }\sum _{n=1}^{\infty }\frac {4 \left (H L \left (\left (\int _{0}^{H}\left (\right ) \sin \left (\frac {\pi m y}{H}\right )d y \right )_{\mathit {AllSolutions}}\right ) \sin \left (\frac {\pi \sqrt {H^{2} n^{2}+L^{2} m^{2}}\, c t}{H L}\right )+\pi \sqrt {H^{2} n^{2}+L^{2} m^{2}}\, c \left (\left (\int _{0}^{H}\left (\right ) \sin \left (\frac {\pi m y}{H}\right )d y \right )_{\mathit {AllSolutions}}\right ) \cos \left (\frac {\pi \sqrt {H^{2} n^{2}+L^{2} m^{2}}\, c t}{H L}\right )\right ) \sin \left (\frac {\pi m y}{H}\right ) \sin \left (\frac {\pi n x}{L}\right )}{\sqrt {H^{2} n^{2}+L^{2} m^{2}}\, \pi H L c}\]

Assuming \(u=X\left ( x\right ) Y\left ( y\right ) T\left ( t\right ) \) and substituting into the PDE gives\begin {align*} \frac {1}{c^{2}}T^{\prime \prime }XY & =X^{\prime \prime }YT+Y^{\prime \prime }XT\\ \frac {1}{c^{2}}\frac {T^{\prime \prime }}{T} & =\frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y} \end {align*}

Therefore\begin {align*} \frac {1}{c^{2}}\frac {T^{\prime \prime }}{T} & =-\lambda \\ \frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y} & =-\lambda \end {align*}

The time ODE becomes\[ T^{\prime \prime }+c^{2}\lambda T=0 \] And the space ODE is\[ \frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y}=-\lambda \] Separating this again gives\[ \frac {X^{\prime \prime }}{X}=-\lambda -\frac {Y^{\prime \prime }}{Y}\] Let the second separation variable be \(\mu \). This gives two new ODE’s to solve\begin {align*} \frac {X^{\prime \prime }}{X} & =-\mu \\ -\lambda -\frac {Y^{\prime \prime }}{Y} & =-\mu \end {align*}

Or\begin {align*} X^{\prime \prime }+\mu X & =0\\ Y^{\prime \prime }+Y\left ( \lambda -\mu \right ) & =0 \end {align*}

Solving for \(X\left ( x\right ) \) ODE ﬁrst, and knowing that only \(\mu >0\) will give non trivial solutions (from the nature of the boundary conditions), gives the solution as\[ X\left ( x\right ) =A\cos \left ( \sqrt {\mu }x\right ) +B\sin \left ( \sqrt {\mu }x\right ) \] Applying B.C. at \(x=0\) results in\[ 0=A \] Therefore \(X\left ( x\right ) =B\sin \left ( \sqrt {\mu }x\right ) \). Applying the B.C. at \(x=L\) gives\[ 0=B\sin \left ( \sqrt {\mu }L\right ) \] For non trivial solution\begin {align*} \sqrt {\mu }L & =n\pi \\ \mu & =\left ( \frac {n\pi }{L}\right ) ^{2}\qquad n=1,2,3,\cdots \end {align*}

Therefore the \(X_{n}\left ( x\right ) \) eigenfunctions are\[ X_{n}\left ( x\right ) =B_{n}\sin \left ( \frac {n\pi }{L}x\right ) \qquad n=1,2,3,\cdots \] Now, solving the \(Y\left ( y\right ) \) ODE above\[ Y^{\prime \prime }+Y\left ( \lambda -\left ( \frac {n\pi }{L}\right ) ^{2}\right ) =0 \] The solution is\[ Y_{n}\left ( y\right ) =A\cos \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) +B\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) \] Applying ﬁrst B.C. gives \[ 0=A \] Hence\[ Y_{n}\left ( y\right ) =B\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) \] Applying the second B.C. gives\[ 0=B\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}H\right ) \] For non trivial solution\begin {align*} \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}H & =m\pi \qquad m=1,2,3,\cdots \\ \lambda _{nm}-\left ( \frac {n\pi }{L}\right ) ^{2} & =\left ( \frac {m\pi }{H}\right ) ^{2}\\ \lambda _{nm} & =\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}\qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \end {align*}

Hence the \(Y_{nm}\left ( y\right ) \) solution is\[ Y_{nm}=B_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \] The time ode \(T\left ( t\right ) \) is now solved\begin {align*} T_{nm}^{\prime \prime }+c^{2}\lambda _{nm}T_{nm} & =0\\ T_{nm}\left ( t\right ) & =A_{nm}\cos \left ( c\sqrt {\lambda _{nm}}t\right ) +B_{nm}\sin \left ( c\sqrt {\lambda _{nm}}t\right ) \end {align*}

Combining all solutions, and merging all constants into two results in\begin {align} u_{nm}\left ( x,y,t\right ) & =X_{n}\left ( x\right ) Y_{nm}\left ( y\right ) T_{nm}\left ( t\right ) \nonumber \\ u\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }X_{m}\left ( x\right ) Y_{mn}\left ( y\right ) T_{mn}\left ( t\right ) \nonumber \\ & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\lambda _{nm}}t\right ) \nonumber \\ & +\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }B_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\lambda _{nm}}t\right ) \tag {1} \end {align}

Initial conditions are now used to ﬁnd \(A_{nm},B_{nm}\). At \(t=0\)\begin {align*} u\left ( x,y,0\right ) & =f\left ( x,y\right ) \\ \frac {\partial u}{\partial t}\left ( x,y,0\right ) & =g\left ( x,y\right ) \end {align*}

Applying ﬁrst initial condition to (1) gives\[ f\left ( x,y\right ) =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \] Applying 2D orthogonality gives\begin {align*} \int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy & =A_{nm}\left ( \frac {L}{2}\right ) \left ( \frac {H}{2}\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy \end {align*}

Taking time derivative of (1) gives\begin {align*} \frac {\partial u}{\partial t}\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }-c\sqrt {\lambda _{nm}}A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\lambda _{nm}}t\right ) \\ & +\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }c\sqrt {\lambda _{nm}}B_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\lambda _{nm}}t\right ) \end {align*}

At \(t=0\) the above becomes\[ g\left ( x,y\right ) =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }c\sqrt {\lambda _{nm}}B_{nm}\sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \] Applying 2D orthogonality gives\begin {align*} \int _{0}^{L}\int _{0}^{H}g\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy & =B_{nm}\left ( \frac {L}{2}\right ) \left ( \frac {H}{2}\right ) \\ B_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}g\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy \end {align*}

Summary of solution\begin {align*} u\left ( x,y,t\right ) =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( \frac {n\pi }{L}x\right ) & +\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }B_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( \frac {n\pi }{L}x\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy\\ B_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}g\left ( x,y\right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy\\ \lambda _{nm} & =\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2} \end {align*}

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5.2.1.2 [395] Rectangular membrane. Fixed on all edges, zero velocity. Speciﬁc example

\begin {align*} u\left ( 0,y,t\right ) & =0\\ u\left ( L,y,t\right ) & =0 \end {align*}

And boundary conditions on \(y\)\begin {align*} u\left ( x,0,t\right ) & =0\\ u\left ( x,H,t\right ) & =0 \end {align*}

Initial conditions\begin {align*} u\left ( x,y,0\right ) & =f\left ( x,y\right ) \\ \frac {\partial u}{\partial t}\left ( x,y,0\right ) & =g\left ( x,y\right ) \end {align*}

Mathematica ✗

ClearAll["Global`*"]; 
L=1;H=2;c=1/10; 
f[x_,y_]:=x*Cos[y]; 
g[x_,y_]:=0; 
pde = D[u[x, y, t], {t, 2}] == c^2*Laplacian[u[x, y, t], {x, y}]; 
ic = {Derivative[0, 0, 1][u][x, y, 0] == g[x, y], u[x, y, 0] == f[x, y]}; 
bc = {u[0, y, t] == 0, u[0, H, t] == 0, u[x, 0, t] == 0, u[x, L, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, bc, ic}, u[x, y, t], {x, y, t}], 60*10]];

Failed

Maple ✓

restart; 
L:=1; 
H:=2; 
c:=1/10; 
f:=(x,y)->x*cos(y); 
g:=(x,y)->0; 
pde := diff(u(x, y, t), t$2) = c^2*VectorCalculus:-Laplacian(u(x,y,t),[x,y]); 
bc  := u(0,y,t)=0, 
       u(L,y,t)=0, 
       u(x, 0, t) = 0, 
       u(x, H, t) = 0; 
ic  := u(x, y, 0) = f(x,y),(D[3](u))(x, y, 0) = g(x,y); 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde,bc,ic],u(x,y,t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=1}^{\infty }\sum _{n=1}^{\infty }\frac {4 \left (-\left (-1\right )^{n}+\cos \left (2\right ) \left (-1\right )^{m +n}\right ) m \cos \left (\frac {\pi \sqrt {m^{2}+4 n^{2}}\, t}{20}\right ) \sin \left (\pi n x \right ) \sin \left (\frac {\pi m y}{2}\right )}{\left (\pi ^{2} m^{2}-4\right ) n}\]

The basic solution for this type of PDE was already given in problem 5.2.1.1 on page 1490 as

\begin {align*} u\left ( x,y,t\right ) =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( \frac {n\pi }{L}x\right ) & +\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }B_{nm}\sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( \frac {n\pi }{L}x\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy\\ B_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}g\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy\\ \lambda _{nm} & =\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}\qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \end {align*}

In this problem \begin {align*} L & =1\\ H & =2\\ c & =\frac {1}{10}\\ f\left ( x,y\right ) & =x\cos y\\ g\left ( x,y\right ) & =0 \end {align*}

\begin {align*} u\left ( x,y,t\right ) =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {m\pi }{2}y\right ) \cos \left ( \frac {1}{10}\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( n\pi x\right ) & +\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }B_{nm}\sin \left ( \frac {m\pi }{2}y\right ) \sin \left ( \frac {1}{10}\sqrt {\lambda _{nm}}t\right ) \right ) \sin \left ( n\pi x\right ) \\ A_{nm} & =2\int _{0}^{1}\int _{0}^{2}x\cos y\sin \left ( n\pi x\right ) \sin \left ( \frac {m\pi }{2}y\right ) \ dxdy\\ B_{nm} & =0\\ \lambda _{nm} & =\left ( \frac {m\pi }{2}\right ) ^{2}+\left ( n\pi \right ) ^{2}\qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \end {align*}

But \begin {align*} A_{nm} & =2\int _{0}^{1}\int _{0}^{2}x\cos y\sin \left ( n\pi x\right ) \sin \left ( \frac {m\pi }{2}y\right ) \ dxdy\\ & =\frac {4\left ( -1\right ) ^{n}m\left ( -1+\left ( -1\right ) ^{m}\cos \left ( 2\right ) \right ) }{n\left ( m^{2}\pi ^{2}-4\right ) } \end {align*}

\begin {align*} u\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }\frac {4\left ( -1\right ) ^{n}m\left ( -1+\left ( -1\right ) ^{m}\cos \left ( 2\right ) \right ) }{n\left ( m^{2}\pi ^{2}-4\right ) }\sin \left ( \frac {m\pi }{2}y\right ) \cos \left ( \frac {1}{10}\sqrt {\left ( \frac {m\pi }{2}\right ) ^{2}+\left ( n\pi \right ) ^{2}}t\right ) \right ) \sin \left ( n\pi x\right ) \\ & =\sum _{n=1}^{\infty }\left ( \sum _{m=1}^{\infty }\frac {4\left ( -1\right ) ^{n}m\left ( -1+\left ( -1\right ) ^{m}\cos \left ( 2\right ) \right ) }{n\left ( m^{2}\pi ^{2}-4\right ) }\cos \left ( \pi \frac {\sqrt {m^{2}+4n^{2}}}{20}t\right ) \sin \left ( \frac {m\pi }{2}y\right ) \right ) \sin \left ( n\pi x\right ) \end {align*}

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5.2.1.3 [396] All 4 edges ﬁxed, zero initial velocity, Speciﬁc example

Solve \[ u_{tt} = c^2 \nabla ^2 u(x,y) \] With boundary conditions \begin {align*} u(x,0,t) &=0 \\ u(0,y,t) &= 0 \\ u(L,y,t) &=0 \\ u(x,H,t) &= 0 \end {align*}

With initial conditions \begin {align*} u(x,y,0) &=3 f_1(x) f_2(y) \\ u_t(x,y,0) &= 0 \end {align*}

And \[ f_{1}\left ( x\right ) =\left \{ \begin {array} [c]{ccc}x & & 0<x<\frac {L}{2}\\ L-x & & \frac {L}{2}<x<L \end {array} \right . \] Where \[ f_{2}\left ( y\right ) =\left \{ \begin {array} [c]{ccc}y & & 0<y<\frac {H}{2}\\ H-y & & \frac {H}{2}<y<H \end {array} \right . \] And \(L=2,H=3\) and \(c=\frac {1}{3}\).

Mathematica ✓

ClearAll["Global`*"]; 
L=2; 
H=3; 
c=1/3; 
f1[x_] :=Piecewise[{{x, x < L/2}, {L - x, x > L/2}}]; 
f2[y_] := Piecewise[{{y, y < H/2}, {H - y, y > H/2}}]; 
pde =  D[u[x, y, t], {t, 2}] == c^2 * Laplacian[u[x, y, t], {x, y}]; 
ic  = {u[x, y, 0] == 3*f1[x]*f2[y], Derivative[0, 0, 1][u][x, y, 0] == 0}; 
bc  = {u[x, 0, t] == 0, u[0, y, t] == 0, u[L, y, t] == 0, u[x, H, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, ic, bc}, u[x, y, t], {x, y, t}], 60*10]]; 
sol =  sol /. {K[1] -> n, K[2] -> m};

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {n=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}\frac {288 \cos \left (\frac {1}{18} \pi t \sqrt {9 n^2+4 K[3]^2}\right ) \sin \left (\frac {n \pi }{2}\right ) \sin \left (\frac {n \pi x}{2}\right ) \sin \left (\frac {1}{2} \pi K[3]\right ) \sin \left (\frac {1}{3} \pi y K[3]\right )}{n^2 \pi ^4 K[3]^2} & (n|K[3])\in \mathbb {Z}\land n\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✓

restart; 
L   := 2; 
H   := 3; 
c   := 1/3; 
f1  := x-> piecewise(x < L/2,x, x > L/2,L - x); 
f2  := y-> piecewise(y < H/2,y, y > H/2,H - y); 
pde := diff(u(x, y, t), t$2) = c^2* VectorCalculus:-Laplacian(u(x, y, t), 'cartesian'[x, y]); 
ic  := u(x,y,0)=3*f1(x)*f2(y),D[3](u)(x,y,0)=0; 
bc  := u(x,0,t)=0,u(0,y,t)=0,u(L,y,t)=0,u(x,H,t)=0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde, ic,bc], u(x, y, t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=1}^{\infty }\sum _{n=1}^{\infty }\frac {288 \cos \left (\frac {\pi \sqrt {4 m^{2}+9 n^{2}}\, t}{18}\right ) \sin \left (\frac {\pi m}{2}\right ) \sin \left (\frac {\pi n}{2}\right ) \sin \left (\frac {\pi m y}{3}\right ) \sin \left (\frac {\pi n x}{2}\right )}{\pi ^{4} m^{2} n^{2}}\]

The basic solution for this type of PDE was already given in problem 5.2.1.8 on page 1531 as\begin {align*} u\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy \end {align*}

In this problem \begin {align*} L & =2\\ H & =3\\ c & =\frac {1}{3}\\ f\left ( x,y\right ) & =3f_{1}\left ( x\right ) f_{2}\left ( y\right ) \end {align*}

And\[ f_{1}\left ( x\right ) =\left \{ \begin {array} [c]{ccc}x & & 0<x<\frac {L}{2}\\ L-x & & \frac {L}{2}<x<L \end {array} \right . \] And\[ f_{2}\left ( y\right ) =\left \{ \begin {array} [c]{ccc}y & & 0<y<\frac {H}{2}\\ H-y & & \frac {H}{2}<y<H \end {array} \right . \] This is animation of the above solution using these speciﬁc values for for \(40\) seconds. (Animation will only show in the HTML version)

The following shows selected modes. For example, for \(n=1,m=1\) the solution becomes\[ u\left ( x,y,t\right ) =A_{1,1}\sin \left ( \frac {\pi }{L}x\right ) \sin \left ( \frac {\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {\pi }{H}\right ) ^{2}+\left ( \frac {1\pi }{L}\right ) ^{2}}t\right ) \] And for \(n=1,m=5\) then the solution becomes\[ u\left ( x,y,t\right ) =A_{1,5}\sin \left ( \frac {\pi }{L}x\right ) \sin \left ( \frac {5\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {5\pi }{H}\right ) ^{2}+\left ( \frac {\pi }{L}\right ) ^{2}}t\right ) \] And so on.


\(n\)	\(m\)	animation

\(1\)	\(1\)

\(1\)	\(3\)

\(1\)	\(5\)

\(3\)	\(1\)

\(3\)	\(5\)

\(5\)	\(1\)

\(5\)	\(3\)

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5.2.1.4 [397] All 4 edges ﬁxed, zero initial velocity, Speciﬁc example, delta in center

Solve \[ u_{tt} = c^2 \nabla ^2 u(x,y) \] With boundary conditions \begin {align*} u(x,0,t) &=0 \\ u(0,y,t) &= 0 \\ u(L,y,t) &=0 \\ u(x,H,t) &= 0 \end {align*}

With initial conditions \begin {align*} u(x,y,0) &=f(x,y) \\ u_t(x,y,0) &= 0 \end {align*}

And \begin {align*} L & =20\\ H & =30\\ c & =\frac {1}{3}\\ f\left ( x,y\right ) & =f_{1}\left ( x\right ) f_{2}\left ( y\right ) \end {align*}

Where \(f\left ( x,y\right ) \) is an approximation of delta in the middle of the membrane \[ f_{1}\left ( x\right ) =\left \{ \begin {array} [c]{ccc}1 & & \frac {45}{100}L<x<\frac {55}{100}L\\ 0 & & \text {otherwise}\end {array} \right . \] And\[ f_{2}\left ( y\right ) =\left \{ \begin {array} [c]{ccc}1 & & \frac {45}{100}H<y<\frac {55}{100}H\\ 0 & & \text {otherwise}\end {array} \right . \]

Mathematica ✓

ClearAll["Global`*"]; 
L  = 20; 
H  = 30; 
c  = 1/3; 
f1[x] := Piecewise[{{1,45/100*L <= x<= 55/100*L},{0,True}}]; 
f2[y] := Piecewise[{{1,45/100*H<= y<= 55/100*H},{0,True}}]; 
pde =  D[u[x, y, t], {t, 2}] == c^2 * Laplacian[u[x, y, t], {x, y}]; 
ic  = {u[x, y, 0] == f1[x]*f2[y], Derivative[0, 0, 1][u][x, y, 0] == 0}; 
bc  = {u[x, 0, t] == 0, u[0, y, t] == 0, u[L, y, t] == 0, u[x, H, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, ic, bc}, u[x, y, t], {x, y, t}], 60*10]]; 
sol =  sol /. {K[1] -> n, K[2] -> m};

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {n=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}\frac {4 \left (\cos \left (\frac {9 n \pi }{20}\right )-\cos \left (\frac {11 n \pi }{20}\right )\right ) \left (\cos \left (\frac {9}{20} \pi K[3]\right )-\cos \left (\frac {11}{20} \pi K[3]\right )\right ) \cos \left (\frac {1}{180} \pi t \sqrt {9 n^2+4 K[3]^2}\right ) \sin \left (\frac {n \pi x}{20}\right ) \sin \left (\frac {1}{30} \pi y K[3]\right )}{n \pi ^2 K[3]} & (n|K[3])\in \mathbb {Z}\land n\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✓

restart; 
L   := 20; 
H   := 30; 
c   := 1/3; 
f1  := x-> piecewise(x>45/100*L and x< 55/100*L,1, true,0); 
f2  := y-> piecewise(y>45/100*H and y< 55/100*H,1, true,0); 
pde := diff(u(x, y, t), t$2) = c^2* VectorCalculus:-Laplacian(u(x, y, t), 'cartesian'[x, y]); 
ic  := u(x,y,0)=f1(x)*f2(y),D[3](u)(x,y,0)=0; 
bc  := u(x,0,t)=0,u(0,y,t)=0,u(L,y,t)=0,u(x,H,t)=0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde, ic,bc], u(x, y, t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=1}^{\infty }\sum _{n=1}^{\infty }\frac {16 \left (-2 \cos \left (\frac {\pi n}{5}\right )+2 \cos \left (\frac {\pi n}{10}\right )-1\right ) \left (-2 \cos \left (\frac {\pi n}{10}\right )+2 \cos \left (\frac {\pi n}{20}\right )-1\right ) \left (2 \cos \left (\frac {\pi n}{10}\right )+2 \cos \left (\frac {\pi n}{20}\right )+1\right ) \left (\cos \left (\frac {9 \pi m}{20}\right )-\cos \left (\frac {11 \pi m}{20}\right )\right ) \cos \left (\frac {\pi n}{20}\right ) \cos \left (\frac {\pi \sqrt {4 m^{2}+9 n^{2}}\, t}{180}\right ) \left (\sin ^{2}\left (\frac {\pi n}{20}\right )\right ) \sin \left (\frac {\pi m y}{30}\right ) \sin \left (\frac {\pi n x}{20}\right )}{\pi ^{2} m n}\]

In this problem \begin {align*} L & =20\\ H & =30\\ c & =\frac {1}{3}\\ f\left ( x,y\right ) & =f_{1}\left ( x\right ) f_{2}\left ( y\right ) \end {align*}

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5.2.1.5 [398] All 4 edges ﬁxed

Solve \[ \frac {\partial ^2 u}{\partial t^2} = \frac {\partial ^2 u}{\partial x^2}+ \frac {\partial ^2 u}{\partial y^2} \] With boundary conditions \begin {align*} u(x,0,t) &=0 \\ u(0,y,t) &= 0 \\ u(1,y,t) &=0 \\ u(x,2,t) &= 0 \end {align*}

With initial conditions \begin {align*} u(x,y,0) &=\frac {1}{10} (x-x^2)(2 y-y^2) \\ \frac {\partial u}{\partial t}(x,y,0) &= 0 \end {align*}

Mathematica ✓

ClearAll["Global`*"]; 
pde =  D[u[x, y, t], {t, 2}] == Laplacian[u[x, y, t], {x, y}]; 
ic  = {u[x, y, 0] == (1/10)*(x - x^2)*(2*y - y^2), Derivative[0, 0, 1][u][x, y, 0] == 0}; 
bc  = {u[x, 0, t] == 0, u[0, y, t] == 0, u[1, y, t] == 0, u[x, 2, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, ic, bc}, u[x, y, t], {x, y, t}], 60*10]]; 
sol =  sol /. {K[1] -> n, K[2] -> m}; 
sol =  Assuming[Element[{n, m}, Integers], FullSimplify[sol]];

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {n=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}\frac {32 \left (-1+(-1)^n\right ) \left (-1+(-1)^{K[3]}\right ) \cos \left (\frac {1}{2} \pi t \sqrt {4 n^2+K[3]^2}\right ) \sin (n \pi x) \sin \left (\frac {1}{2} \pi y K[3]\right )}{5 n^3 \pi ^6 K[3]^3} & K[3]\in \mathbb {Z}\land n\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✓

restart; 
pde := diff(u(x, y, t), t$2) =  VectorCalculus:-Laplacian(u(x, y, t), 'cartesian'[x, y]); 
ic  := u(x,y,0)=(1/10)*(x-x^2)*(2*y-y^2),(D[3](u))(x,y,0)=0; 
bc  := u(x,0,t)=0,u(0,y,t)=0,u(1,y,t)=0,u(x,2,t)=0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde, ic,bc], u(x, y, t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=1}^{\infty }\sum _{n=1}^{\infty }-\frac {32 \left (\left (-1\right )^{m}+\left (-1\right )^{n}-\left (-1\right )^{m +n}-1\right ) \cos \left (\frac {\pi \sqrt {m^{2}+4 n^{2}}\, t}{2}\right ) \sin \left (\pi n x \right ) \sin \left (\frac {\pi m y}{2}\right )}{5 \pi ^{6} m^{3} n^{3}}\]

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5.2.1.6 [399] All edges ﬁxed (Haberman 8.5.5 (a)

This is problem 8.5.5 part(a) from Richard Haberman applied partial diﬀerential equations 5th edition.

Solve the initial value problem for membrane with time-dependent forcing and ﬁxed boundaries \(u=0\). \[ u_{tt} = c^2 \nabla ^2 u + Q(x,y,t) \] If the memberane is rectangle \((0<x<L,0<y<H)\). With initial conditions \begin {align*} u(x,y,0) &=f(x,y) \\ \frac {\partial u}{\partial t}(x,y,0) &= 0 \end {align*}

Mathematica ✓

ClearAll["Global`*"]; 
pde =  D[u[x, y, t], {t, 2}] == c^2*Laplacian[u[x, y, t], {x, y}] + Q[x, y, t]; 
ic  = {u[x, y, 0] == f[x, y], Derivative[0, 0, 1][u][x, y, 0] == 0}; 
bc  = {u[0, y, t] == 0, u[L, y, t] == 0, u[x, 0, t] == 0, u[x, H, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, ic, bc}, u[x, y, t], {x, y, t}, Assumptions -> {L > 0, H > 0, t > 0, c > 0}], 60*10]];

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {K[1]=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}2 \sqrt {\frac {1}{H}} \sqrt {\frac {1}{L}} \left (\int _0^t \frac {2 \left (\int _0^L\int _0^HQ(x,y,K[4]) \sin \left (\frac {\pi x K[1]}{L}\right ) \sin \left (\frac {\pi y K[3]}{H}\right )dydx\right ) \sin \left (c \pi \sqrt {\frac {K[1]^2}{L^2}+\frac {K[3]^2}{H^2}} (t-K[4])\right )}{c \pi \sqrt {\frac {H K[1]^2}{L}+\frac {L K[3]^2}{H}}} \, dK[4]+\frac {2 \cos \left (c \pi t \sqrt {\frac {K[1]^2}{L^2}+\frac {K[3]^2}{H^2}}\right ) \int _0^L\int _0^Hf(x,y) \sin \left (\frac {\pi x K[1]}{L}\right ) \sin \left (\frac {\pi y K[3]}{H}\right )dydx}{\sqrt {H L}}\right ) \sin \left (\frac {\pi x K[1]}{L}\right ) \sin \left (\frac {\pi y K[3]}{H}\right ) & (K[1]|K[3])\in \mathbb {Z}\land K[1]\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✗

restart; 
interface(showassumed=0); 
pde := diff(u(x,y,t),t$2)=c^2*(diff(u(x,y,t),x$2)+diff(u(x,y,t),y$2))+Q(x,y,t); 
bc  := u(0,y,t)=0,u(L,y,t)=0,u(x,0,t)=0,u(x,H,t)=0; 
ic  := u(x,y,0)=f(x,y), eval( diff(u(x,y,t),t),t=0)=0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde,bc,ic],u(x,y,t)) assuming L>0,H>0,c>0,t>0),output='realtime'));

sol=()

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5.2.1.7 [400] 2 edgs ﬁxed, 2 free, zero initial velocity

Taken from Maple PDE help pages. This wave PDE inside square with free to move on left edge and right edge, and top and bottom edges are ﬁxed. It has zero initial velocity, but given a non-zero initial position. Where \(0<x<\pi \) and \(0<y<\pi \) and \(t>0\).

Solve \[ u_{tt} = \frac {1}{4} \left ( \frac {\partial ^2 u}{\partial x^2}+ \frac {\partial ^2 u}{\partial y^2} \right ) \] With boundary conditions \begin {align*} \frac {\partial u}{\partial x}u(0,y,t) &= 0 \\ \frac {\partial u}{\partial x}u(\pi ,y,t) &= 0 \\ u(x,0,t) &= 0\\ u(x,\pi ,0) &=0 \end {align*}

With initial conditions \begin {align*} \frac {\partial u}{\partial t}(x,y,0) &=0 \\ u(x,0) &= x y (\pi -y) \end {align*}

Mathematica ✓

ClearAll["Global`*"]; 
pde =  D[u[x, y, t], {t, 2}] == (1*(D[u[x, y, t], {x, 2}] + D[u[x, y, t], {y, 2}]))/4; 
ic  = {Derivative[0, 0, 1][u][x, y, 0] == 0, u[x, y, 0] == x*y*(Pi - y)}; 
bc  = {Derivative[1, 0, 0][u][0, y, t] == 0, Derivative[1, 0, 0][u][Pi, y, t] == 0, u[x, 0, t] == 0, u[x, Pi, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, bc, ic}, u[x, y, t], {x, y, t}], 60*10]];

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {K[3]=1}{\overset {\infty }{\sum }}-\frac {2 \left (-1+(-1)^{K[3]}\right ) \cos \left (\frac {1}{2} t K[3]\right ) \sin (y K[3])}{K[3]^3}+\underset {K[1]=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}-\frac {8 \left (-1+(-1)^{K[1]}\right ) \left (-1+(-1)^{K[3]}\right ) \cos (x K[1]) \cos \left (\frac {1}{2} t \sqrt {K[1]^2+K[3]^2}\right ) \sin (y K[3])}{\pi ^2 K[1]^2 K[3]^3} & (K[1]|K[3])\in \mathbb {Z}\land K[1]\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✓

restart; 
pde := diff(u(x, y, t), t, t) = (1/4)*(diff(u(x, y, t), x, x))+(1/4)*(diff(u(x, y, t), y, y)); 
bc  := (D[1](u))(0, y, t) = 0, 
       (D[1](u))(Pi, y, t) = 0, 
       u(x, 0, t) = 0, 
       u(x, Pi, t) = 0; 
ic  := u(x, y, 0) = x*y*(Pi-y),(D[3](u))(x, y, 0) = 0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde,bc,ic],u(x,y,t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = -2 \left (\sum _{n=1}^{\infty }\frac {\left (\left (-1\right )^{n}-1\right ) \cos \left (\frac {n t}{2}\right ) \sin \left (n y \right )}{n^{3}}\right )+\left (\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }\frac {8 \left (\left (-1\right )^{m}+\left (-1\right )^{n}-\left (-1\right )^{m +n}-1\right ) \cos \left (m x \right ) \cos \left (\frac {\sqrt {m^{2}+n^{2}}\, t}{2}\right ) \sin \left (n y \right )}{\pi ^{2} m^{2} n^{3}}\right )\]

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5.2.1.8 [401] All 4 edges ﬁxed, zero initial velocity, general solution

Solve \[ u_{tt} = c^2 \nabla ^2 u(x,y) \] With boundary conditions \begin {align*} u(x,0,t) &=0 \\ u(0,y,t) &= 0 \\ u(L,y,t) &=0 \\ u(x,H,t) &= 0 \end {align*}

With initial conditions \begin {align*} u(x,y,0) &=f(x,y) \\ u_t(x,y,0) &= 0 \end {align*}

Mathematica ✓

ClearAll["Global`*"]; 
pde =  D[u[x, y, t], {t, 2}] == c^2 * Laplacian[u[x, y, t], {x, y}]; 
ic  = {u[x, y, 0] == f[x,y], Derivative[0, 0, 1][u][x, y, 0] == 0}; 
bc  = {u[x, 0, t] == 0, u[0, y, t] == 0, u[L, y, t] == 0, u[x, H, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, ic, bc}, u[x, y, t], {x, y, t}], 60*10]]; 
sol =  sol /. {K[1] -> n, K[2] -> m};

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {n=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}\frac {4 \cos \left (\pi t \sqrt {c^2 \left (\frac {n^2}{L^2}+\frac {K[3]^2}{H^2}\right )}\right ) \left (\int _0^L\int _0^Hf(x,y) \sin \left (\frac {n \pi x}{L}\right ) \sin \left (\frac {\pi y K[3]}{H}\right )dydx\right ) \sin \left (\frac {n \pi x}{L}\right ) \sin \left (\frac {\pi y K[3]}{H}\right )}{H L} & (n|K[3])\in \mathbb {Z}\land n\geq 1\land K[3]\geq 1\land c^2 H^2 L^2 \left (H^2 n^2+L^2 K[3]^2\right )>0 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✗

restart; 
pde := diff(u(x, y, t), t$2) = c^2* VectorCalculus:-Laplacian(u(x, y, t), 'cartesian'[x, y]); 
ic  := u(x,y,0)=f(x,y),D[3](u)(x,y,0)=0; 
bc  := u(x,0,t)=0,u(0,y,t)=0,u(L,y,t)=0,u(x,H,t)=0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde, ic,bc], u(x, y, t))),output='realtime')); 
sol := subs(n1=m,sol);

time expired

Solve for \(u\left ( r,\theta ,t\right ) \)\[ u_{tt}=c^{2}\nabla ^{2}u\left ( x,y\right ) \] With boundary conditions such that all edges are ﬁxed, and initial conditions \(u\left ( x,y,0\right ) =f\left ( x,y\right ) \) and initial velocity \(g\left ( x,y\right ) =0.\)

Let \(u=X\left ( x\right ) Y\left ( y\right ) T\left ( t\right ) \). Substituting into the above PDE gives\begin {align*} \frac {1}{c^{2}}T^{\prime \prime }XY & =X^{\prime \prime }YT+Y^{\prime \prime }XT\\ \frac {1}{c^{2}}\frac {T^{\prime \prime }}{T} & =\frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y} \end {align*}

Hence\begin {align*} \frac {1}{c^{2}}\frac {T^{\prime \prime }}{T} & =-\lambda \\ \frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y} & =-\lambda \end {align*}

The time ODE becomes\[ T^{\prime \prime }+c^{2}\lambda T=0 \] And the space ODE is\begin {align*} \frac {X^{\prime \prime }}{X}+\frac {Y^{\prime \prime }}{Y} & =-\lambda \\ \frac {X^{\prime \prime }}{X} & =-\lambda -\frac {Y^{\prime \prime }}{Y} \end {align*}

Using a new separation variable \(\mu \) gives the following two ODE’s\begin {align*} \frac {X^{\prime \prime }}{X} & =-\mu \\ -\lambda -\frac {Y^{\prime \prime }}{Y} & =-\mu \end {align*}

Or\begin {align*} X^{\prime \prime }+\mu X & =0\\ X\left ( 0\right ) & =0\\ X\left ( L\right ) & =0 \end {align*}

And\begin {align*} Y^{\prime \prime }+Y\left ( \lambda -\mu \right ) & =0\\ Y\left ( 0\right ) & =0\\ Y\left ( H\right ) & =0 \end {align*}

Solving ﬁrst for the \(X\left ( x\right ) \) ODE, and knowing that \(\mu \) must be positive only here from the nature of the boundary conditions gives\[ X=A\cos \left ( \sqrt {\mu }x\right ) +B\sin \left ( \sqrt {\mu }x\right ) \] Applying B.C. at \(x=0\)\[ 0=A \] Hence solution becomes \(X\left ( x\right ) =B\sin \left ( \sqrt {\mu }x\right ) \). Applying the B.C. at \(x=L\) gives\[ 0=B\sin \left ( \sqrt {\mu }L\right ) \] Non trivial solution requires that\begin {align*} \sqrt {\mu }L & =n\pi \qquad n=1,2,3,\cdots \\ \mu _{n} & =\left ( \frac {n\pi }{L}\right ) ^{2} \end {align*}

Therefore the eigenfunctions \(X_{n}\left ( x\right ) \) are\[ X_{n}\left ( x\right ) =\sin \left ( \frac {n\pi }{L}x\right ) \qquad n=1,2,3,\cdots \] Solving the \(Y\left ( y\right ) \) ODE\[ Y_{n}^{\prime \prime }+\left ( \lambda -\left ( \frac {n\pi }{L}\right ) ^{2}\right ) Y_{n}=0\qquad n=1,2,3,\cdots \] The nature of the boundary conditions on \(Y\left ( y\right ) \) suggests that \(\left ( \lambda -\left ( \frac {n\pi }{L}\right ) ^{2}\right ) \) must be positive (if \(\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}=0\) or \(\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}<0\), trivial solutions result).

Hence the solution for \(Y_{n}\left ( y\right ) \) becomes\[ Y_{n}\left ( y\right ) =A\cos \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) +B\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) \] Applying ﬁrst B.C. \(Y\left ( 0\right ) =0\) gives\[ 0=A \] The solution becomes\[ Y_{n}\left ( y\right ) =B_{n}\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}y\right ) \] Applying second B.C. \(Y\left ( H\right ) =0\) gives\[ 0=B\sin \left ( \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}H\right ) \] Non trivial solution requires that\begin {align*} \sqrt {\lambda -\left ( \frac {n\pi }{L}\right ) ^{2}}H & =m\pi \qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \\ \lambda _{nm}-\left ( \frac {n\pi }{L}\right ) ^{2} & =\left ( \frac {m\pi }{H}\right ) ^{2}\\ \lambda _{nm} & =\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2} \end {align*}

Hence the \(Y_{nm}\left ( y\right ) \) eigenfunctions are\[ Y_{nm}\left ( y\right ) =\sin \left ( \frac {m\pi }{H}y\right ) \qquad n=1,2,3,\cdots ,m=1,2,3,\cdots \] Now the time \(T\left ( t\right ) \) ode is solved, and since \(\lambda _{nm}\) is positive, then \begin {align*} T_{nm}^{\prime \prime }+c^{2}\lambda _{nm}T_{nm} & =0\\ T_{nm}\left ( t\right ) & =A_{nm}\cos \left ( c\sqrt {\lambda _{nm}}t\right ) +B_{nm}\sin \left ( c\sqrt {\lambda _{nm}}t\right ) \\ & =A_{nm}\cos \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) +B_{nm}\sin \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \end {align*}

\begin {align} u_{nm}\left ( x,y,t\right ) & =X_{n}\left ( x\right ) Y_{nm}\left ( y\right ) T_{nm}\left ( t\right ) \nonumber \\ u\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }X_{n}\left ( x\right ) Y_{nm}\left ( y\right ) T_{nm}\left ( t\right ) \nonumber \\ & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) +\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }B_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \tag {1} \end {align}

\begin {align*} u\left ( x,y,0\right ) & =f\left ( x,y\right ) \\ \frac {\partial u}{\partial t}\left ( x,y,0\right ) & =0 \end {align*}

Applying ﬁrst initial condition to (1) gives\[ f\left ( x,y\right ) =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \] Applying 2D orthogonality gives\begin {align*} \int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy & =A_{nm}\left ( \frac {L}{2}\right ) \left ( \frac {H}{2}\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy \end {align*}

Taking time derivative of (1) gives\begin {align*} \frac {\partial u}{\partial t}\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }-c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \sin \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \\ & +\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}B_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \end {align*}

AT \(t=0\) the above becomes\[ \int _{0}^{H}g\left ( x,y\right ) =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}B_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \] Applying 2D orthogonality gives\[ \int _{0}^{L}\int _{0}^{H}g\left ( x,y\right ) \sin \left ( \left ( \frac {n\pi }{L}\right ) x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy=B_{nm}\left ( \frac {L}{2}\right ) \left ( \frac {H}{2}\right ) \] But the initial velocity \(g\left ( x,y\right ) =0\). Hence \(B_{nm}=0\) for all \(n,m\).

Summary of solution\begin {align*} u\left ( x,y,t\right ) & =\sum _{n=1}^{\infty }\sum _{m=1}^{\infty }A_{nm}\sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \cos \left ( c\sqrt {\left ( \frac {m\pi }{H}\right ) ^{2}+\left ( \frac {n\pi }{L}\right ) ^{2}}t\right ) \\ A_{nm} & =\frac {4}{LH}\int _{0}^{L}\int _{0}^{H}f\left ( x,y\right ) \sin \left ( \frac {n\pi }{L}x\right ) \sin \left ( \frac {m\pi }{H}y\right ) \ dxdy \end {align*}

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5.2.1.9 [402] With damping

Taken from Maple PDE help pages. This wave PDE inside square with damping present.

Membrane is free to move on the right edge and also on top edge. But ﬁxed at left edge and bottom edge.

It has zero initial position, but given a non-zero initial velocity. Where \(0<x<1\) and \(0<y<1\) and \(t>0\). Solve \[ u_{tt} + \frac {1}{10} u_t = \frac {1}{4} \nabla ^2 u(x,y) \] With boundary conditions \begin {align*} u(0,y,t) &=0\\ \frac {\partial u}{\partial x}u(1,y,t) &= 0 \\ u(x,0,t) &=0 \\ \frac {\partial u}{\partial y}u(x,1,t) &= 0 \end {align*}

With initial conditions \begin {align*} u(x,y,0) &=0 \\ \frac {\partial u}{\partial t}(x,y,0) &= x(1- \frac {1}{2} x) (1- \frac {1}{2} y) y \end {align*}

Mathematica ✓

ClearAll["Global`*"]; 
pde =  D[u[x, y, t], {t, 2}] == (1*(D[u[x, y, t], {x, 2}] + D[u[x, y, t], {y, 2}]))/4 - (1*D[u[x, y, t], t])/10; 
ic  = {u[x, y, 0] == 0, Derivative[0, 0, 1][u][x, y, 0] == x*(1 - (1/2)*x)*(1 - (1/2)*y)*y}; 
bc  = {u[0, y, t] == 0, Derivative[1, 0, 0][u][1, y, t] == 0, u[x, 0, t] == 0, Derivative[0, 1, 0][u][x, 1, t] == 0}; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[{pde, bc, ic}, u[x, y, t], {x, y, t}], 60*10]];

\[\left \{\left \{u(x,y,t)\to \begin {array}{cc} \{ & \begin {array}{cc} \underset {K[1]=1}{\overset {\infty }{\sum }}\underset {K[3]=1}{\overset {\infty }{\sum }}\frac {5120 e^{-t/20} \sin \left (\frac {1}{2} \pi x (2 K[1]-1)\right ) \sin \left (\frac {1}{2} \pi y (2 K[3]-1)\right ) \sin \left (\frac {1}{20} t \sqrt {50 \pi ^2 \left (2 K[1]^2-2 K[1]+2 K[3]^2-2 K[3]+1\right )-1}\right )}{\pi ^6 (2 K[1]-1)^3 (2 K[3]-1)^3 \sqrt {50 \pi ^2 \left (2 K[1]^2-2 K[1]+2 K[3]^2-2 K[3]+1\right )-1}} & (K[1]|K[3])\in \mathbb {Z}\land K[1]\geq 1\land K[3]\geq 1 \\ \text {Indeterminate} & \text {True} \\\end {array} \\\end {array}\right \}\right \}\]

Maple ✓

restart; 
pde := diff(u(x, y, t), t$2) = 1/4*(diff(u(x, y, t), x$2)+diff(u(x, y, t), y$2))-(1/10)*(diff(u(x, y, t), t)); 
bc  := u(0, y, t) = 0, 
      (D[1](u))(1, y, t) = 0, 
      u(x, 0, t) = 0, 
      (D[2](u))(x, 1, t) = 0; 
ic  := u(x, y, 0) = 0, (D[3](u))(x, y, 0) = x*(1-(1/2)*x)*(1-(1/2)*y)*y; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve([pde, ic,bc], u(x, y, t))),output='realtime')); 
sol := subs(n1=m,sol);

\[u \left (x , y , t\right ) = \sum _{m=0}^{\infty }\sum _{n=0}^{\infty }\frac {5120 \,{\mathrm e}^{-\frac {t}{20}} \sin \left (\frac {\sqrt {-1+\left (100 m^{2}+100 n^{2}+100 m +100 n +50\right ) \pi ^{2}}\, t}{20}\right ) \sin \left (\frac {\left (2 n +1\right ) \pi x}{2}\right ) \sin \left (\frac {\left (2 m +1\right ) \pi y}{2}\right )}{\sqrt {-1+\left (100 m^{2}+100 n^{2}+100 m +100 n +50\right ) \pi ^{2}}\, \pi ^{6} \left (2 m +1\right )^{3} \left (2 n +1\right )^{3}}\]

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5.2.1.10 [403] On the whole plane

Solve for \(u(x,y)\) \[ u_{xx} -2 \sin x u_{x y} -\cos ^2 x u_{y y} -\cos x u_y=0 \]

Mathematica ✓

ClearAll["Global`*"]; 
ode = D[u[x, y], {x, 2}] - 2*Sin[x]*D[u[x, y], x, y] - Cos[x]^2*D[u[x, y], {y, 2}] - Cos[x]*D[u[x, y], y] == 0; 
sol =  AbsoluteTiming[TimeConstrained[DSolve[ode, u[x, y], {x, y}], 60*10]];

\[\{\{u(x,y)\to c_1(x-\cos (x)+y)+c_2(-x-\cos (x)+y)\}\}\]

Maple ✗

restart; 
interface(showassumed=0); 
ode := diff(u(x, y), x$2) - 2*sin(x)*diff(u(x, y),x,y)-cos(x)^2*diff(u(x, y), y$2) - cos(x)*diff(u(x, y), y) = 0; 
cpu_time := timelimit(60*10,CodeTools[Usage](assign('sol',pdsolve(ode, u(x, y))),output='realtime'));

sol=()

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5.2.1 Cartesian coordinates

5.2.1.1 [394] Rectangular membrane. Fixed on all edges, General solution

5.2.1.2 [395] Rectangular membrane. Fixed on all edges, zero velocity. Speciﬁc example

5.2.1.3 [396] All 4 edges ﬁxed, zero initial velocity, Speciﬁc example

5.2.1.4 [397] All 4 edges ﬁxed, zero initial velocity, Speciﬁc example, delta in center

5.2.1.5 [398] All 4 edges ﬁxed

5.2.1.6 [399] All edges ﬁxed (Haberman 8.5.5 (a)

5.2.1.7 [400] 2 edgs ﬁxed, 2 free, zero initial velocity

5.2.1.8 [401] All 4 edges ﬁxed, zero initial velocity, general solution

5.2.1.9 [402] With damping

5.2.1.10 [403] On the whole plane