/Final-Parameters_sm_fsn_fss_fsv/pulvinus-images.cpp - Annoter - Dandelion pappus morphing - Forge du Centre Blaise Pascal

root / Final-Parameters_sm_fsn_fss_fsv / pulvinus-images.cpp @ 21

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+include "getARGV.idp"
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+//include "bib_meca2d.cpp"
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+//usage :
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+//Freefem++ pulvinus.edp [-fE fEvalue] [-Nit Nit] [-geometry g]
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+//arguments:
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+//-fE fEvalue:
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+//-Nit Nit: number of iterations
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+//-geometry g: differnet geometries
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+//1:
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+//2:
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+//3:
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+func real lineD(real xA, real xB, real yA, real yB)
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+{        return (yB-yA)/(xB-xA);
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+func real lineC(real xA, real xB, real yA, real yB)
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+{        return (yA*xB-yB*xA)/(xB-xA);
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+//real PI=3.14159265;
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+func real angleToVertical(real Mx, real My, real Nx, real Ny)
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+{ /*  Computes the sinus of angle between the MN vector and Oy   */
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+        return asin((Nx-Mx)/sqrt((Mx-Nx)^2+(My-Ny)^2))*180/pi;
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+/*************************************************************
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+ *                  PARAMETERS
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+ * **********************************************************/
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+// reading script arguments
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+for (int i=0;i<ARGV.n;++i)
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+{ cout << ARGV[i] << " ";}
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+cout<<endl;
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+verbosity = getARGV("-vv", 0);
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+int vdebug = getARGV("-d", 1);
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+// swelling ability of each region is a parameter
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+real sm = -getARGV("-sm", 0.540061);// mesophyl swelling property
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+real fsn = getARGV("-fsn", 0.954482);// nectary     sn/sm
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+real fss = getARGV("-fss", 1.21648);// side        ss/sm
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+real fsv = getARGV("-fsv", 0.509563);// vasculature sv/sm
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+int Nit = getARGV("-Nit", 1);
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+string geom = getARGV("-geometry", "1");
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+string output = getARGV("-out", ".");
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+cout<<"----------------------------------------------"<< endl;
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+cout<<"   sm="<<sm<< endl;
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+// ---------------- geometrical parameters
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+// (lengths are measured in micrometers)
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+real units=200;
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+// pulvinus dimensions
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+real lx=491.0/units;       //sd =34.4
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+real ly= 240.0/units;      //sd=36.0
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+// nectary height
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+real hnect = 38.8/units;   //sd=9.6
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+real R=363.0/units;    //sd=49.4
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+// side dimensions
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+real hside=91.4/units;     //12.6
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+real lside=47.6/units/2;     //6.6
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+// vasculature dimensions
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+real vthickness=34.3/units;//5.5
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+real cwidth=74.8/units;    //15.2
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+real cwidthdry=44.2/units; //8.4
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+// vasculature displacement (from vascular bundle distance)
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+real vd=(cwidth-cwidthdry)/2;
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+real vposition=lx/2-vthickness-hnect/ly*(lx/2-cwidth/2-vthickness); //cout<<"vposition="<<vposition<<endl;
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+// mesh parameters
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+int nvertex=50; cout << "nvertex="<<nvertex<<endl;
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+real pinned=lx/nvertex/2;
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+// ---------------- Material properties
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+real nu = 0.29;    // Poisson's ratio
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+// Young modulus
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+real Ev;   // vasculature Young modulus
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+real fEm; // mesophyl Em/Ev
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+real fEn;  // nectary  En/Ev
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+real fEs;  // side     Es/Ev
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+// measured values for the density
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+//Region,Mean_tissue_density,SD_tissue_density
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+real dm=0.668060839; //sd=0.04091249
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+real dn=1.01896008; //sd=0.015464575
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+real ds=0.918032482; //sd=0.075097509
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+real dv=0.882171532; //sd=0.066651037
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+real nEd=1.0;
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+// Young modulus
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+Ev=1;   // vasculature Young modulus
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+fEm=(dm/dv)^nEd; // mesophyl Em/Ev
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+fEn=(dn/dv)^nEd;  // nectary  En/Ev
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+fEs=(ds/dv)^nEd;  // side     Es/Ev
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+// hydrophobicity as swelling ability
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+/*************************************************************
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+ *                  GEOMETRY and MESH
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+ * **********************************************************/
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+string geomfilename="geometry"+geom+".cpp";
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+cout<<"including "<<geomfilename<<endl;
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+include "geometry1.cpp";
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+// -------------------- define the finite element space
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+fespace Vh(Th,[P2,P2]);  // vector on the mesh (displacement vector)
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+Vh [u1,u2], [v1,v2];
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+fespace Sh(Th, P2);   // scalar on the mesh, P2 elements
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+fespace Sh0(Th,P0);   // scalar on the mesh, P0 elements
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+fespace Sh1(Th,P1);   // scalar on the mesh, P1 elements
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+Sh0 strain, stress;
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+// bounding box for the plot (use the same for all images so that they can be superposed)
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+func bb=[[-lx/2*1.5,-ly*1],[lx/2*1.5,ly*.1]];
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+real coef=1;
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+cout << "Coefficent of amplification:"<<coef<<endl;
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+//plot(Th, fill=1, ps=output+"/original_geometry.png", bb=bb); -------------------------------
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+// macro to redefine variables on the displaced mesh
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+macro redefineVariable(vvv)
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+{        real[int] temp(vvv[].n);
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+        temp=vvv[]; vvv=0; vvv[]=temp;
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+        vvv=vvv;
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+}//
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+real sqrt2=sqrt(2.);
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+macro epsilon(u1,u2)  [dx(u1),dy(u2),(dy(u1)+dx(u2))/sqrt2] // EOM
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+//the sqrt2 is because we want: epsilon(u1,u2)'* epsilon(v1,v2) $==  \epsilon(\bm{u}): \epsilon(\bm{v})$
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+macro div(u1,u2) ( dx(u1)+dy(u2) ) // EOM
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+/*************************************************************
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+ *                  MECHANICS
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+ * **********************************************************/
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+// definition of integer functions for the structural domains
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+func vasculature=int(vasculatureBool(x,y));
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+func nectary=int(nectaryBool(x,y));
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+func side=int(sideBool(x,y));
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+func mesophyl=int(mesophylBool(x,y));
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+func geometry = 1*vasculature + 3*nectary + 2*side + 4*mesophyl;
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+// definition of FE variables for the structural domains
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+Sh0 vasculatureh=vasculature;
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+//plot(vasculatureh,wait=1,value=true,fill=1, ps=output+"/vasculature-original.png", bb=bb);
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+Sh0 nectaryh=nectary;
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+//plot(nectaryh,wait=1,value=true,fill=1, ps=output+"/nectary-original.png", bb=bb);
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+Sh0 sideh=side;
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+//plot(sideh,wait=1,value=true,fill=1, ps=output+"/side-original.png", bb=bb);
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+Sh0 mesophylh=mesophyl;
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+//plot(mesophylh,wait=1,value=true,fill=1, ps=output+"/mesophyl-original.png", bb=bb);
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+Sh0 geometryh=geometry;
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+string fname=output+"/geometry-original.png";
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+plot(geometryh,fill=1, ps=fname, bb=bb);
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+// spatial dependence of Young modulus
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+func E=Ev*(vasculature + fEn*nectary + fEs*side + fEm*mesophyl);
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+Sh0 Eh=E;
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+// spatial dependence of the swelling property
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+func s=sm*(fsv*vasculature + fsn*nectary + fss*side + mesophyl);
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+Sh0 sh=s;
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+func mu=E/(2*(1+nu));
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+func lambda=E*nu/((1+nu)*(1-2*nu));
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+func K=lambda+2*mu/3;
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+/*************************************************************
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+ *                  SOLVING THE FEM
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+ * **********************************************************/
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+solve Lame([u1,u2],[v1,v2])=
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+  int2d(Th)(
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+            lambda*div(u1,u2)*div(v1,v2)
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+            + 2.*mu*( epsilon(u1,u2)'*epsilon(v1,v2) )
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+  - int2d(Th) ( K*sh*div(v1,v2))
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+  + on(32,u1=vd,u2=0)
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+  + on(33,u1=-vd,u2=0)
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+stress=2*K*(strain-s);
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+Sh0 e11=dx(u1)+1.;
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+Sh0 e12=1/2.*(dx(u2) + dy(u1));
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+Sh0 e22=dy(u2)+1.;
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+strain=e11+e22 ;
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+Sh0 Det=e11*e22-e12*e12;
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+Sh0 l1=abs(strain+sqrt(strain*strain-4*Det))/2.;
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+Sh0 l2=abs(strain-sqrt(strain*strain-4*Det))/2.;
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+Sh0 lmax=(l1-l2+abs(l1-l2))/2.+l2;
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+Sh0 lmin=(l1-l2-abs(l1-l2))/2.+l2;
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+Sh0 strainanisotropy=lmin/lmax;
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+/*************************************************************
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+ *                  VISUALISATION
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+ * **********************************************************/
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+real voltotal0=int2d(Th)(1);
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+real volvasculature0=int2d(Th)(vasculatureh);
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+real volnectary0=int2d(Th)(nectaryh);
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+real volmesophyl0=int2d(Th)(mesophylh);
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+real volside0=int2d(Th)(sideh);
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+cout<<"Original volume="<<voltotal0<<endl;
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+cout<<"Original vasculature volume="<<volvasculature0<<endl;
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+// compute mean strain per region
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+real straintotal=int2d(Th)(strain)/voltotal0;
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+real strainvasculature=int2d(Th)(strain*vasculatureh)/volvasculature0;
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+real strainnectary=int2d(Th)(strain*nectaryh)/volnectary0;
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+real strainside=int2d(Th)(strain*sideh)/volside0;
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+real strainmesophyl=int2d(Th)(strain*mesophylh)/volmesophyl0;
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+// compute mean strain anisotropy per region
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+real satotal=int2d(Th)(strainanisotropy)/voltotal0;
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+real savasculature=int2d(Th)(strainanisotropy*vasculatureh)/volvasculature0;
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+real sanectary=int2d(Th)(strainanisotropy*nectaryh)/volnectary0;
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+real saside=int2d(Th)(strainanisotropy*sideh)/volside0;
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+real samesophyl=int2d(Th)(strainanisotropy*mesophylh)/volmesophyl0;
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+// =====================================================================
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+mesh Th0=Th;
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+Th=movemesh(Th,[x+u1*coef,y+u2*coef]);
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+cout<<"Mean strain and strain anisotropy per region :"<<endl;
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+cout<<"Mesophyll:"<<strainmesophyl<<"   "<<samesophyl<<endl;
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+cout<<"Nectary:"<<strainnectary<<"   "<<sanectary<<endl;
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+cout<<"Side:"<<strainside<<"   "<<saside<<endl;
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+cout<<"Vasculature:"<<strainvasculature<<"   "<<savasculature<<endl;
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+cout<<"Total:"<<straintotal<<"   "<<satotal<<endl;
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+plot(Th, Th0, wait=1, ps=output+"/geometry-deformed-superposed_sm"+string(sm)+"_fsn"+string(fsn)+"_fss"+string(fss)+"_fsv"+string(fsv)+".png",bb=bb);
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+plot(Th, wait=1, ps=output+"/geometry-deformed_sm"+string(sm)+"_fsn"+string(fsn)+"_fss"+string(fss)+"_fsv"+string(fsv)+".png",bb=bb);
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+redefineVariable(strain);
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+redefineVariable(stress);
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+plot(strain, fill=1,wait=1,value=true, ps="strain.png",bb=bb);
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+plot(stress, fill=1,wait=1,value=true, ps="stress.png",bb=bb);
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+redefineVariable(geometryh);
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+plot(geometryh, fill=1, ps=output+"/geometry-deformed_sm"+string(sm)+".png",bb=bb);
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+redefineVariable(vasculatureh);
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+redefineVariable(nectaryh);
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+redefineVariable(sideh);
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+redefineVariable(mesophylh);
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+// compute structure volumes
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+real voltotal=int2d(Th)(1);
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+real volvasculature=int2d(Th)(vasculatureh);
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+real volnectary=int2d(Th)(nectaryh);
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+real volside=int2d(Th)(sideh);
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+real volmesophyl=int2d(Th)(mesophylh);
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+cout<<"Deformed total volume="<<voltotal<<endl;
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+cout<<"Deformed vasculature volume="<<volvasculature<<endl;
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+/*************************************************************
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+ *         LOOKING FOR ANGLE AND NECKHEIGHT
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+ * **********************************************************/
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+// displaced upper corner
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+real Nx=lx/2+u1(lx/2.,0), Ny=u2(lx/2.,0);
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+// compute tangentangle
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+real height=ly/nvertex/100;
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+real Mx=lx/2+u1(lx/2.,-height), My=-height+u2(lx/2.,-height);
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+real tangentangle=angleToVertical(Mx, My, Nx, Ny);
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+cout<<"Tangent angle="<<tangentangle<<endl;
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+// compute sideangle
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+height=hside;
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+Mx=lx/2+u1(lx/2.,-height); My=-height+u2(lx/2.,-height);
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+real sideangle=angleToVertical(Mx, My, Nx, Ny);
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+cout<<"Side angle="<<sideangle<<endl;
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+real am=volmesophyl0/volmesophyl;
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+real an=volnectary0/volnectary;
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+real as=volside0/volside;
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+real av=volvasculature0/volvasculature;
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+// compute deformed lengths
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+real cwidthdrysimu=cwidth+u1(cwidth/2,-ly)-u1(-cwidth/2,-ly);
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+/*************************************************************
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+ *         Writing results
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+ * **********************************************************/
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+cout<<"sm;fsn;fss;fsv;tangentangle;sideangle;am;an;as;av;sam;san;sas;sav;cwidthdry"<<endl;
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+ofstream textfile(output+"/results.csv", append);
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+textfile<<sm<<";"<<fsn<<";"<<fss<<";"<<fsv
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+<<";"<<tangentangle/38<<";"<<sideangle/38
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+<<";"<<am<<";"<<an<<";"<<as<<";"<<av
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+<<";"<<samesophyl<<";"<<sanectary<<";"<<saside<<";"<<savasculature<<";"<<cwidthdrysimu/cwidthdry
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+<<endl;
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+cout<<sm<<";"<<fsn<<";"<<fss<<";"<<fsv
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+<<";"<<tangentangle/38<<";"<<sideangle/38
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+<<";"<<am<<";"<<an<<";"<<as<<";"<<av
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+<<";"<<samesophyl<<";"<<sanectary<<";"<<saside<<";"<<savasculature<<";"<<cwidthdrysimu/cwidthdry
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+<<endl;
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Laboratoire RDP » Biophysics Team » Dandelion pappus morphing

root / Final-Parameters_sm_fsn_fss_fsv / pulvinus-images.cpp @ 21