120 lines
3.9 KiB
Matlab
120 lines
3.9 KiB
Matlab
function [field_i mesh_i] = GetField_Interpolation(field, mesh, lines, varargin)
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% [field_i mesh_i] = GetField_Interpolation(field, mesh, lines, varargin)
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%
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% Get an interpolated field, e.g. read by ReadHDF5Dump
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%
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% homogen interpolation given by a 3x1 vector: e.g. [21,1,101]
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%
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% abitrary interpolation on a given mesh:
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% e.g.: mesh_interp{1} = linspace(0, 1,101) * 1e-3;
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% mesh_interp{2} = linspace(0,0.5, 51) * 1e-3;
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% mesh_interp{3} = linspace(0,0.2, 21) * 1e-3;
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%
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% example:
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% [field mesh] = ReadHDF5Dump('Et.h5');
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% %interpolate on a mesh with 21x21x101 lines
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% [field_i mesh_i] = GetField_Interpolation(field, mesh, [21 21 101]);
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% or
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% [field_i mesh_i] = GetField_Interpolation(field, mesh, mesh_interp);
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%
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% %or both steps in one with the same result:
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% [field_i mesh_i] = ReadHDF5Dump('Et.h5','Interpolation', [21 21 101]);
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%
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% openEMS matlab interface
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% -----------------------
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% author: Thorsten Liebig
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%
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% See also ReadHDF5Dump ReadHDF5FieldData ReadHDF5Mesh
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if ((~iscell(lines) && ~isnumeric(lines)) || numel(lines)~=3)
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error('openEMS:GetField_Interpolation: numLines for interpolation must be a vector...');
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end
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x = mesh.lines{1};
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y = mesh.lines{2};
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z = mesh.lines{3};
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if (isnumeric(lines))
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x_i = linspace(x(1),x(end),lines(1));
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y_i = linspace(y(1),y(end),lines(2));
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z_i = linspace(z(1),z(end),lines(3));
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else
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x_i = lines{1};
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y_i = lines{2};
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z_i = lines{3};
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end
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field_i = field;
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mesh_i = mesh;
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mesh_i.lines{1} = x_i;
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mesh_i.lines{2} = y_i;
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mesh_i.lines{3} = z_i;
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if (isfield(field,'TD'))
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field_i.TD = interpolate_fields(field.TD,x,y,z, x_i, y_i, z_i);
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field_i.TD.time = field.TD.time;
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field_i.TD.names= field.TD.names;
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end
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if (isfield(field,'FD'))
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field_i.FD = interpolate_fields(field.FD,x,y,z, x_i, y_i, z_i);
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field_i.FD.frequency = field.FD.frequency;
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field_i.FD.DataType = field.FD.DataType;
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end
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return
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function field_i = interpolate_fields(field, x,y,z, x_i, y_i, z_i)
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% matlab cannot handle 3D data to be 2D data, workaround for these cases
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if (numel(x)==1)
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[Y Z] = ndgrid(y,z);
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[Y_I Z_I] = ndgrid(y_i,z_i);
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for n=1:numel(field.values)
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field_i.values{n}(1,:,:,1) = interpn(Y,Z,squeeze(field.values{n}(1,:,:,1)),Y_I,Z_I);
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if (size(field.values{n},4)>1)
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field_i.values{n}(1,:,:,2) = interpn(Y,Z,squeeze(field.values{n}(1,:,:,2)),Y_I,Z_I);
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field_i.values{n}(1,:,:,3) = interpn(Y,Z,squeeze(field.values{n}(1,:,:,3)),Y_I,Z_I);
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end
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end
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return;
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end
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if (numel(y)==1)
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[X Z] = ndgrid(x,z);
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[X_I Z_I] = ndgrid(x_i,z_i);
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for n=1:numel(field.values)
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field_i.values{n}(:,1,:,1) = interpn(X,Z,squeeze(field.values{n}(:,1,:,1)),X_I,Z_I);
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if (size(field.values{n},4)>1)
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field_i.values{n}(:,1,:,2) = interpn(X,Z,squeeze(field.values{n}(:,1,:,2)),X_I,Z_I);
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field_i.values{n}(:,1,:,3) = interpn(X,Z,squeeze(field.values{n}(:,1,:,3)),X_I,Z_I);
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end
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end
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return;
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end
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if (numel(z)==1)
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[X Y] = ndgrid(x,y);
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[X_I Y_I] = ndgrid(x_i,y_i);
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for n=1:numel(field.values)
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field_i.values{n}(:,:,1,1) = interpn(X,Y,squeeze(field.values{n}(:,:,1,1)),X_I,Y_I);
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if (size(field.values{n},4)>1)
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field_i.values{n}(:,:,1,2) = interpn(X,Y,squeeze(field.values{n}(:,:,1,2)),X_I,Y_I);
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field_i.values{n}(:,:,1,3) = interpn(X,Y,squeeze(field.values{n}(:,:,1,3)),X_I,Y_I);
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end
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end
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return;
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end
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%real 3D case
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[X Y Z] = ndgrid(x,y,z);
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[X_I Y_I Z_I] = ndgrid(x_i,y_i,z_i);
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for n=1:numel(field.values)
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field_i.values{n}(:,:,:,1) = interpn(X,Y,Z,field.values{n}(:,:,:,1),X_I,Y_I,Z_I);
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if (size(field.values{n},4)>1)
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field_i.values{n}(:,:,:,2) = interpn(X,Y,Z,field.values{n}(:,:,:,2),X_I,Y_I,Z_I);
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field_i.values{n}(:,:,:,3) = interpn(X,Y,Z,field.values{n}(:,:,:,3),X_I,Y_I,Z_I);
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end
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end
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