1 function FV=Snake3D(I,FV,Options)
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2 % This function SNAKE implements the basic snake segmentation. A snake is an
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3 % active (moving) contour, in which the points are attracted by edges and
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4 % other boundaries. To keep the contour smooth, an membrame and thin plate
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5 % energy is used as regularization.
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7 % OV=Snake3D(I,FV,Options)
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10 % I : An Image of type double preferable ranged [0..1]
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11 % FV : Structure with triangulated mesh, with list of faces FV.faces N x 3
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12 % and list of vertices M x 3
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13 % Options : A struct with all snake options
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16 % OV : Structure with triangulated mesh of the final surface
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18 % options (general),
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19 % Option.Verbose : If true show important images, default false
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20 % Options.Gamma : Time step, default 1
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21 % Options.Iterations : Number of iterations, default 100
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23 % options (Image Edge Energy / Image force))
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24 % Options.Sigma1 : Sigma used to calculate image derivatives, default 2
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25 % Options.Wline : Attraction to lines, if negative to black lines otherwise white
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26 % lines , default 0.04
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27 % Options.Wedge : Attraction to edges, default 2.0
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28 % Options.Sigma2 : Sigma used to calculate the gradient of the edge energy
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29 % image (which gives the image force), default 2
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31 % options (Gradient Vector Flow)
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32 % Options.Mu : Trade of between real edge vectors, and noise vectors,
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33 % default 0.2. (Warning setting this to high >0.5 gives
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34 % an instable Vector Flow)
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35 % Options.GIterations : Number of GVF iterations, default 0
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36 % Options.Sigma3 : Sigma used to calculate the laplacian in GVF, default 1.0
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39 % Options.Alpha : Membrame energy (first order), default 0.2
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40 % Options.Beta : Thin plate energy (second order), default 0.2
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41 % Options.Delta : Baloon force, default 0.1
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42 % Options.Kappa : Weight of external image force, default 2
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43 % Options.Lambda : Weight which changes the direction of the image
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44 % potential force to the direction of the surface
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45 % normal, value default 0.8 (range [0..1])
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46 % (Keeps the surface from self intersecting)
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49 % - Michael Kass, Andrew Witkin and Demetri TerzoPoulos "Snakes : Active
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50 % Contour Models", 1987
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51 % - Christoph Lurig, Leif Kobbelt, Thomas Ertl, "Hierachical solutions
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52 % for the Deformable Surface Problem in Visualization"
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59 % Options.Verbose=1;
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62 % Options.Alpha=0.2;
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64 % Options.Kappa=0.5;
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65 % Options.Delta=0.1000;
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66 % Options.Gamma=0.1000;
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67 % Options.Iterations=20;
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70 % Options.Lambda=0.8;
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71 % FV.vertices(:,1)=FV.vertices(:,1)+35;
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72 % FV.vertices(:,2)=FV.vertices(:,2)+25;
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73 % FV.vertices(:,3)=FV.vertices(:,3)+20;
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74 % OV=Snake3D(I,FV,Options)
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76 % Function is written by D.Kroon University of Twente (July 2010)
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79 defaultoptions=struct('Verbose',false,'Wline',0.04,'Wedge',2,'Sigma1',2,'Sigma2',2,'Alpha',0.2,'Beta',0.2,'Delta',0.1,'Gamma',1,'Kappa',2,'Iterations',100,'GIterations',0,'Mu',0.2,'Sigma3',1,'Lambda',0.8);
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80 if(~exist('Options','var')),
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81 Options=defaultoptions;
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83 tags = fieldnames(defaultoptions);
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84 for i=1:length(tags)
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85 if(~isfield(Options,tags{i})), Options.(tags{i})=defaultoptions.(tags{i}); end
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87 if(length(tags)~=length(fieldnames(Options))),
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88 warning('snake:unknownoption','unknown options found');
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92 % Convert input to single if xintxx
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93 if(~strcmpi(class(I),'single')&&~strcmpi(class(I),'double'))
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97 % The surface faces must always be clockwise (because of the balloon force)
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98 FV=MakeContourClockwise3D(FV);
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100 % Transform the Image into an External Energy Image
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101 Eext = ExternalForceImage3D(I,Options.Wline, Options.Wedge,Options.Sigma1);
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103 % Make the external force (flow) field.
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104 Fx=ImageDerivatives3D(Eext,Options.Sigma2,'x');
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105 Fy=ImageDerivatives3D(Eext,Options.Sigma2,'y');
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106 Fz=ImageDerivatives3D(Eext,Options.Sigma2,'z');
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108 Fext(:,:,:,1)=-Fx*2*Options.Sigma2^2;
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109 Fext(:,:,:,2)=-Fy*2*Options.Sigma2^2;
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110 Fext(:,:,:,3)=-Fz*2*Options.Sigma2^2;
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112 % Do Gradient vector flow, optimalization
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113 Fext=GVFOptimizeImageForces3D(Fext, Options.Mu, Options.GIterations, Options.Sigma3);
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115 % Show the image, contour and force field
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116 if(Options.Verbose)
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117 drawnow; pause(0.1);
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118 h=figure; set(h,'render','opengl')
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119 subplot(2,3,1),imshow(squeeze(Eext(:,:,round(end/2))),[]);
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120 subplot(2,3,2),imshow(squeeze(Eext(:,round(end/2),:)),[]);
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121 subplot(2,3,3),imshow(squeeze(Eext(round(end/2),:,:)),[]);
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122 subplot(2,3,4),imshow(squeeze(Fext(:,:,round(end/2),:))+0.5);
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123 subplot(2,3,5),imshow(squeeze(Fext(:,round(end/2),:,:))+0.5);
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124 subplot(2,3,6),imshow(squeeze(Fext(round(end/2),:,:,:))+0.5);
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125 h=figure; set(h,'render','opengl'); hold on;
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126 %patch(i,'facecolor',[1 0 0],'facealpha',0.1);
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128 [ix,iy,iz]=ind2sub(size(Eext),ind);
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129 plot3(ix,iy,iz,'b.');
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131 h=patch(FV,'facecolor',[1 0 0],'facealpha',0.1);
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132 drawnow; pause(0.1);
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135 % Make the interal force matrix, which constrains the moving points to a
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137 S=SnakeInternalForceMatrix3D(FV,Options.Alpha,Options.Beta,Options.Gamma);
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138 for i=1:Options.Iterations
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139 FV=SnakeMoveIteration3D(S,FV,Fext,Options.Gamma,Options.Kappa,Options.Delta,Options.Lambda);
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141 % Show current contour
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142 if(Options.Verbose)
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145 h=patch(FV,'facecolor',[1 0 0],'facealpha',0.1);
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146 drawnow; %pause(0.1);
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