DistMesh - A Simple Mesh Generator for MATLAB
About DistMesh
DistMesh is a simple MATLAB and GNU Octave code for automatic generation of unstructured 2D triangular and 3D tetrahedral volume meshes.
This repository contains a slightly modified, consolidated, and refactored version of DistMesh, which also can be used from a graphical user interface (GUI) together with the FEATool Multiphysics Octave and MATLAB PDE and FEM Toolbox.
Note that a Julia implementation of this DistMesh version is also available in the DistMesh-Julia repository as well as QuadMesh - unstructured quadrilateral mesh generation based on distance functions.
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Description
The DistMesh algorithm was invented by Per-Olof Persson and Gilbert Strang in the Department of Mathematics at MIT. More detailed descriptions of the original DistMesh method and MATLAB mesh generation code can be found in the SIAM Review paper and other references linked below.
The simplicity of the DistMesh algorithm is due to using signed distance functions (level sets) to specify and describe domains, geometries, and regions to mesh. Distance functions specify the shortest distance from any point in space to the boundary of the domain, where the sign of the function is positive outside the region, negative inside, and zero on the boundary. This definition is used to identify if a point is located in or outside of the geometry. Moreover, the gradient of the distance function points in the direction of the boundary, allowing points outside to be efficiently moved back to the domain.
A simple example is the unit circle in two dimensions, which has the distance function d(r) = r-1, where r = sqrt(x^2+y^2) is the distance from the origin. For more complicated geometries the distance function can be computed by interpolation between values on a grid, which is a common representation for level set methods.
For the mesh generation procedure, DistMesh uses the Delaunay triangulation routine in MATLAB and Octave and tries to optimize the node locations by a force-based smoothing procedure. The topology is regularly updated by Delaunay. The boundary points are only allowed to move tangentially to the boundary by projections using the distance function. This iterative procedure typically results in very uniform and well-shaped high quality meshes.
Modifications
In addition to cleanup, refactoring, and consolidation, this DistMesh implementation has been modified in the following ways:
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CAD geometry and GUI support (with the FEATool Multiphysics Toolbox)
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2D and 3D cases merged and handled in one code base.
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Full support for mesh generation in both MATLAB and Octave.
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Support for constrained edges (and constraint functions).
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Delaunay function selection depending on MATLAB or Octave version (with constrained Delaunay triangulation if available).
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fd and fh can both be specified as function handles and as cell arrays of a function handle/string names with optional calling arguments.
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Alternative optimized edge pair computation.
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Optional number of re-tracing steps for grid points outside domain.
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Added statistics and timing output.
Usage
To use the this mesh generation code, simply download the stand alone distmesh source code and run it in MATLAB or Octave. The function syntax is as follows
[ P, T, STAT ] = DISTMESH( FD, FH, H0, BBOX, P_FIX, E_FIX, IT_MAX, FID, FIT )
where FD is a function handle to the geometry description that
should take evaluation coordinates and points as input. For example
fd = @(p) sqrt(sum(p.^2,2)) - 1; specifies the distance
function for a unit circle (both function handles, string function
names, and anonymous functions are supported). Similar to FD, FH
a function describing the desired relative mesh size distribution. For
example fh = @(p) ones(size(p,1),1); specifies a uniform
distribution where FH evaluates to 1 at all points. H0 is a
numeric scalar specifying the initial edge lengths, and BBOX is a
2 by 2 in 2D (or 2 by 3 in 3D) bounding box of the domain (enclosing
the zero contour/level set of FD). P_FIX optionally specifies a
number of points that should always be present (fixed) in the
resulting mesh. E_FIX can be sets of edge vertex indices to
constrain, or alternatively a cell array with function handle to call.
IT_MAX sets the maximum number of grid generation iterations
allowed (default 1000). Finally, FID specifies a file
identifies for output (default 1 = terminal output), FIT is an
optional % function to call every iteration to check for early
termination.
The DistMesh MATLAB function returns the grid point vertices in P, triangulated simplices in T, as well as an optional statistics struct STAT including timings and convergence information.
Input:
FD: Distance function d(x,y,(z))
FH: Scaled edge length function h(x,y,(z))
H0: Initial edge length
BBOX: Bounding box [xmin,ymin,(zmin); xmax,ymax,(zmax)]
P_FIX: Fixed node positions (N_P_FIX x 2/3)
E_FIX: Constrained edges (N_E_FIX x 2)
IT_MAX: Maximum number of iterations
FID: Output file id number (default 1 = terminal)
Output:
P: Grid vertex/node coordinates (N_P x 2/3)
T: Triangle indices (N_T x 3)
STAT: Mesh generation statistics (struct)
Examples
To automatically run the collection of basic mesh generation examples described below, type distmesh_demo into the MATLAB or Octave CLI command prompts from the directory where the distmesh files can be found.
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Example 1: Uniform mesh on unit circle
fd = @(p) sqrt(sum(p.^2,2)) - 1; fh = @(p) ones(size(p,1),1); [p,t] = distmesh( fd, fh, 0.2, [-1,-1;1,1] ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 2: Uniform mesh on ellipse
fd = @(p) p(:,1).^2/2^2 + p(:,2).^2/1^2 - 1; fh = @(p) ones(size(p,1),1); [p,t] = distmesh( fd, fh, 0.2, [-2,-1;2,1] ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 3: Uniform mesh on unit square
fd = @(p) -min(min(min(1+p(:,2),1-p(:,2)),1+p(:,1)),1-p(:,1)); fh = @(p) ones(size(p,1),1); [p,t] = distmesh( fd, fh, 0.2, [-1,-1;1,1], [-1,-1;-1,1;1,-1;1,1] ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 4: Uniform mesh on complex polygon
pv = [-0.4 -0.5;0.4 -0.2;0.4 -0.7;1.5 -0.4;0.9 0.1; 1.6 0.8;0.5 0.5;0.2 1;0.1 0.4;-0.7 0.7;-0.4 -0.5]; fd = { 'l_dpolygon', [], pv }; fh = @(p) ones(size(p,1),1); [p,t] = distmesh( fd, fh, 0.1, [-1,-1; 2,1], pv ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 5: Rectangle with circular hole, refined at circle boundary
drectangle = @(p,x1,x2,y1,y2) -min(min(min(-y1+p(:,2),y2-p(:,2)),-x1+p(:,1)),x2-p(:,1)); fd = @(p) max( drectangle(p,-1,1,-1,1), -(sqrt(sum(p.^2,2))-0.5) ); fh = @(p) 0.05 + 0.3*(sqrt(sum(p.^2,2))-0.5); [p,t] = distmesh( fd, fh, 0.05, [-1,-1;1,1], [-1,-1;-1,1;1,-1;1,1] ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 6: Square, with size function point and line sources
dcircle = @(p,xc,yc,r) sqrt((p(:,1)-xc).^2+(p(:,2)-yc).^2)-r; fd = @(p) -min(min(min(p(:,2),1-p(:,2)),p(:,1)),1-p(:,1)); dpolygon = @(p,v) feval('l_dpolygon',p,v); fh = @(p) min(min(0.01+0.3*abs(dcircle(p,0,0,0)), ... 0.025+0.3*abs(dpolygon(p,[0.3,0.7;0.7,0.5;0.3,0.7]))),0.15); [p,t] = distmesh( fd, fh, 0.01, [0,0;1,1], [0,0;1,0;0,1;1,1] ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 7: NACA0012 airfoil
hlead = 0.01; htrail = 0.04; hmax = 2; circx = 2; circr = 4; a = 0.12/0.2*[0.2969,-0.126,-0.3516,0.2843,-0.1036]; fd = @(p) max( dcircle(p,circx,0,circr), ... -((abs(p(:,2))-polyval([a(5:-1:2),0],p(:,1))).^2-a(1)^2*p(:,1)) ); fh = @(p) min(min(hlead+0.3*dcircle(p,0,0,0),htrail+0.3*dcircle(p,1,0,0)),hmax); fixx = 1 - htrail*cumsum(1.3.^(0:4)'); fixy = a(1)*sqrt(fixx) + polyval([a(5:-1:2),0],fixx); pfix = [[circx+[-1,1,0,0]*circr; 0,0,circr*[-1,1]]'; 0,0; 1,0; fixx,fixy; fixx,-fixy]; bbox = [circx-circr,-circr; circx+circr,circr]; h0 = min([hlead,htrail,hmax]); [p,t] = distmesh( fd, fh, h0, bbox, pfix ); patch( 'vertices', p, 'faces', t, 'facecolor', [.9, .9, .9] ) -
Example 8: Uniform mesh on unit sphere
fd = @(p) sqrt(sum(p.^2,2)) - 1; fh = @(p) ones(size(p,1),1); [p,t] = distmesh( fd, fh, 0.2, [-1,-1,-1;1,1,1] ); f = [t(:,[1:3]); t(:,[1,2,4]); t(:,[2,3,4]); t(:,[3,1,4])]; patch( 'vertices', p, 'faces', f, 'facecolor', [.9, .9, .9] ) -
Example 9: Uniform mesh on unit cube
fd = @(p) -min(min(min(min(min(p(:,3),1-p(:,3) ),p(:,2)),1-p(:,2)),p(:,1)),1-p(:,1)); fh = @(p) ones(size(p,1),1); pfix = [-1,-1,-1;-1,1,-1;1,-1,-1;1,1,-1; -1,-1,1;-1,1,1;1,-1,1;1,1,1]; [p,t] = distmesh( fd, fh, 0.2, [-1,-1,-1;1,1,1], pfix ); f = [t(:,[1:3]); t(:,[1,2,4]); t(:,[2,3,4]); t(:,[3,1,4])]; patch( 'vertices', p, 'faces', f, 'facecolor', [.9, .9, .9] ), view(3) -
Example 10: Uniform mesh on cylinder
fd = @(p) -min(min(p(:,3),4-p(:,3)),1-sqrt(sum(p(:,1:2).^2,2))); fh = @(p) ones(size(p,1),1); pfix = [-1,-1,-1;-1,1,-1;1,-1,-1;1,1,-1; -1,-1,1;-1,1,1;1,-1,1;1,1,1]; [p,t] = distmesh( fd, fh, 0.5, [-1,-1,0;1,1,4], [] ); f = [t(:,[1:3]); t(:,[1,2,4]); t(:,[2,3,4]); t(:,[3,1,4])]; patch( 'vertices', p, 'faces', f, 'facecolor', [.9, .9, .9] ), view(3)
References
[3] P.-O. Persson's DistMesh website
[4] FEATool Multiphysics grid generation documentation
Alternative Implementations
[5] libDistMesh: A Simple Mesh Generator in C++
[6] DistMesh-Julia - Julia Mesh Generation with DistMesh
[7] PyDistMesh - A Simple Mesh Generator in Python
[8] Mesh generator - Java implementation of DistMesh
[9] DistMesh - Wolfram Language Implementation
[10] J. Burkardt's DistMesh repository
[11] KOKO Mesh Generator
License
DistMesh is distributed for free under the GNU GPL; see the License and Copyright notice for more information.
Modifications made to the original DistMesh code are copyrighted by Precise Simulation Limited and licensed under the GNU GPL License.