## Wave Equation on Square Domain: PDE Modeler App

This example shows how to solve a wave equation for transverse vibrations of a membrane on a square. The membrane is fixed at the left and right sides, and is free at the upper and lower sides. This example uses the PDE Modeler app. For a programmatic workflow, see Wave Equation on Square Domain.

A wave equation is a hyperbolic PDE:

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

To solve this problem in the PDE Modeler app, follow these steps:

Open the PDE Modeler app by using the

`pdeModeler`

command.Display grid lines by selecting

**Options**>**Grid**.Align new shapes to the grid lines by selecting

**Options**>**Snap**.Draw a square with the corners at (-1,-1), (-1,1), (1,1), and (1,-1). To do this, first click the button. Then click one of the corners using the right mouse button and drag to draw a square. The right mouse button constrains the shape you draw to be a square rather than a rectangle.

You also can use the

`pderect`

function:pderect([-1 1 -1 1])

Check that the application mode is set to

**Generic Scalar**.Specify the boundary conditions. To do this, switch to boundary mode by clicking the button or selecting

**Boundary**>**Boundary Mode**. Select the left and right boundaries. Then select**Boundary**>**Specify Boundary Conditions**and specify the Dirichlet boundary condition*u*= 0. This boundary condition is the default one (`h = 1`

,`r = 0`

), so you do not need to change it.For the bottom and top boundaries, set the Neumann boundary condition ∂

*u*/∂*n*= 0. To do this, set`g = 0`

,`q = 0`

.Specify the coefficients by selecting

**PDE**>**PDE Specification**or clicking the button on the toolbar. Select the**Hyperbolic**type of PDE, and specify`c = 1`

,`a = 0`

,`f = 0`

, and`d = 1`

.Initialize the mesh by selecting

**Mesh**>**Initialize Mesh**. Refine the mesh by selecting**Mesh**>**Refine Mesh**.Set the solution times. To do this, select

**Solve**>**Parameters**. Create linearly spaced time vector from 0 to 5 seconds by setting the solution time to`linspace(0,5,31)`

.In the same dialog box, specify initial conditions for the wave equation. For a well-behaved solution, the initial values must match the boundary conditions. If the initial time is

*t*= 0, then the following initial values that satisfy the boundary conditions:`atan(cos(pi/2*x))`

for`u(0)`

and`3*sin(pi*x).*exp(sin(pi/2*y))`

for ∂*u*/∂*t*,The inverse tangent function and exponential function introduce more modes into the solution.

Solve the PDE by selecting

**Solve**>**Solve PDE**or clicking the button on the toolbar. The app solves the heat equation at times from 0 to 5 seconds and displays the result at the end of the time span.Visualize the solution as a 3-D static and animated plots. To do this:

Select

**Plot**>**Parameters**.In the resulting dialog box, select the

**Color**and**Height (3-D plot)**options.To visualize the dynamic behavior of the wave, select

**Animation**in the same dialog box. If the animation progress is too slow, select the**Plot in x-y grid**option. An*x*-*y*grid can speed up the animation process significantly.