trisurf-ng.git - Gitblit

			@@ -1,9 +1,20 @@
			/* vim: set ts=4 sts=4 sw=4 noet : */
			#include<stdlib.h>
			#include "general.h"
			#include "energy.h"
			#include "vertex.h"
			#include "bond.h"
			#include<math.h>
			#include<stdio.h>


			/** @brief Wrapper that calculates energy of every vertex in vesicle
			*
			* Function calculated energy of every vertex in vesicle. It can be used in
			* initialization procedure or in recalculation of the energy after non-MCsweep * operations. However, when random move of vertex or flip of random bond occur * call to this function is not necessary nor recommended.
			* @param *vesicle is a pointer to vesicle.
			* @returns TS_SUCCESS on success.
			*/
			ts_bool mean_curvature_and_energy(ts_vesicle *vesicle){

			ts_uint i;
			@@ -19,109 +30,219 @@
			return TS_SUCCESS;
			}

			/** @brief Calculate energy of a bond (in models where energy is bond related)
			*
			* This function is experimental and currently only used in polymeres calculation (PEGs or polymeres inside the vesicle).
			*
			* @param *bond is a pointer to a bond between two vertices in polymere
			* @param *poly is a pointer to polymere in which we calculate te energy of the bond
			* @returns TS_SUCCESS on successful calculation
			*/
			inline ts_bool bond_energy(ts_bond bond,ts_poly poly){
			//TODO: This value to be changed and implemented in data structure:
			ts_double d_relaxed=1.0;
			bond->energy=poly->k*pow(bond->bond_length-d_relaxed,2);
			return TS_SUCCESS;
			};

			/** @brief Calculation of the bending energy of the vertex.
			*
			* Main function that calculates energy of the vertex \f$i\f$. Function returns \f$\frac{1}{2}(c_1+c_2-c)^2 s\f$, where \f$(c_1+c_2)/2\f$ is mean curvature,
			* \f$c/2\f$ is spontaneous curvature and \f$s\f$ is area per vertex \f$i\f$.
			*
			* Nearest neighbors (NN) must be ordered in counterclockwise direction for this function to work.
			* Firstly NNs that form two neighboring triangles are found (\f$j_m\f$, \f$j_p\f$ and common \f$j\f$). Later, the scalar product of vectors \f$x_1=(\mathbf{i}-\mathbf{j_p})\cdot (\mathbf{i}-\mathbf{j_p})(\mathbf{i}-\mathbf{j_p})\f$, \f$x_2=(\mathbf{j}-\mathbf{j_p})\cdot (\mathbf{j}-\mathbf{j_p})\f$ and \f$x_3=(\mathbf{j}-\mathbf{j_p})\cdot (\mathbf{i}-\mathbf{j_p})\f$ are calculated. From these three vectors the \f$c_{tp}=\frac{1}{\tan(\varphi_p)}\f$ is calculated, where \f$\varphi_p\f$ is the inner angle at vertex \f$j_p\f$. The procedure is repeated for \f$j_m\f$ instead of \f$j_p\f$ resulting in \f$c_{tn}\f$.
			*
			\begin{tikzpicture}{
			\coordinate[label=below:$i$] (i) at (2,0);
			\coordinate[label=left:$j_m$] (jm) at (0,3.7);
			\coordinate[label=above:$j$] (j) at (2.5,6.4);
			\coordinate[label=right:$j_p$] (jp) at (4,2.7);

			\draw (i) -- (jm) -- (j) -- (jp) -- (i) -- (j);

			\begin{scope}
			\path[clip] (jm)--(i)--(j);
			\draw (jm) circle (0.8);
			\node[right] at (jm) {$\varphi_m$};
			\end{scope}

			\begin{scope}
			\path[clip] (jp)--(i)--(j);
			\draw (jp) circle (0.8);
			\node[left] at (jp) {$\varphi_p$};
			\end{scope}

			%%vertices
			\draw [fill=gray] (i) circle (0.1);
			\draw [fill=white] (j) circle (0.1);
			\draw [fill=white] (jp) circle (0.1);
			\draw [fill=white] (jm) circle (0.1);
			%\node[draw,circle,fill=white] at (i) {};
			\end{tikzpicture}

			* The curvature is then calculated as \f$\mathbf{h}=\frac{1}{2}\Sigma_{k=0}^{\mathrm{neigh\_no}} c_{tp}^{(k)}+c_{tm}^{(k)} (\mathbf{j_k}-\mathbf{i})\f$, where \f$c_{tp}^{(k)}+c_{tm}^k=2\sigma^{(k)}\f$ (length in dual lattice?) and the previous equation can be written as \f$\mathbf{h}=\Sigma_{k=0}^{\mathrm{neigh\_no}}\sigma^{(k)}\cdot(\mathbf{j}-\mathbf{i})\f$ (See Kroll, p. 384, eq 70).
			*
			* From the curvature the enery is calculated by equation \f$E=\frac{1}{2}\mathbf{h}\cdot\mathbf{h}\f$.
			* @param *vtx is a pointer to vertex at which we want to calculate the energy
			* @returns TS_SUCCESS on successful calculation.
			*/
			inline ts_bool energy_vertex(ts_vertex *vtx){
			// ts_vertex *vtx=&vlist->vertex[n]-1; // Caution! 0 Indexed value!
			// ts_triangle *tristar=vtx->tristar-1;
			ts_vertex_data *data=vtx->data;
			ts_uint jj;
			ts_uint jjp,jjm;
			ts_vertex j,jp, *jm;
			ts_triangle *jt;
			ts_double s=0,xh=0,yh=0,zh=0,txn=0,tyn=0,tzn=0;
			ts_double x1,x2,x3,ctp,ctm,tot,xlen;
			ts_double h,ht;
			for(jj=1; jj<=data->neigh_no;jj++){
			jjp=jj+1;
			if(jjp>data->neigh_no) jjp=1;
			jjm=jj-1;
			if(jjm<1) jjm=data->neigh_no;
			j=data->neigh[jj-1];
			jp=data->neigh[jjp-1];
			jm=data->neigh[jjm-1];
			// printf("tristar_no=%u, neigh_no=%u, jj=%u\n",data->tristar_no,data->neigh_no,jj);
			jt=data->tristar[jj-1];
			x1=vtx_distance_sq(vtx,jp); //shouldn't be zero!
			x2=vtx_distance_sq(j,jp); // shouldn't be zero!
			x3=(j->data->x-jp->data->x)*(data->x-jp->data->x)+
			(j->data->y-jp->data->y)*(data->y-jp->data->y)+
			(j->data->z-jp->data->z)*(data->z-jp->data->z);

			#ifdef TS_DOUBLE_DOUBLE
			ctp=x3/sqrt(x1x2-x3x3);
			#endif
			#ifdef TS_DOUBLE_FLOAT
			ctp=x3/sqrtf(x1x2-x3x3);
			#endif
			#ifdef TS_DOUBLE_LONGDOUBLE
			ctp=x3/sqrtl(x1x2-x3x3);
			#endif
			x1=vtx_distance_sq(vtx,jm);
			x2=vtx_distance_sq(j,jm);
			x3=(j->data->x-jm->data->x)*(data->x-jm->data->x)+
			(j->data->y-jm->data->y)*(data->y-jm->data->y)+
			(j->data->z-jm->data->z)*(data->z-jm->data->z);
			#ifdef TS_DOUBLE_DOUBLE
			ctm=x3/sqrt(x1x2-x3x3);
			#endif
			#ifdef TS_DOUBLE_FLOAT
			ctm=x3/sqrtf(x1x2-x3x3);
			#endif
			#ifdef TS_DOUBLE_LONGDOUBLE
			ctm=x3/sqrtl(x1x2-x3x3);
			#endif
			tot=ctp+ctm;
			tot=0.5*tot;
			xlen=vtx_distance_sq(j,vtx);
			#ifdef TS_DOUBLE_DOUBLE
			data->bond[jj-1]->data->bond_length=sqrt(xlen);
			#endif
			#ifdef TS_DOUBLE_FLOAT
			data->bond[jj-1]->data->bond_length=sqrtf(xlen);
			#endif
			#ifdef TS_DOUBLE_LONGDOUBLE
			data->bond[jj-1]->data->bond_length=sqrtl(xlen);
			#endif
			ts_uint jj, i, j;
			ts_double edge_vector_x[7]={0,0,0,0,0,0,0};
			ts_double edge_vector_y[7]={0,0,0,0,0,0,0};
			ts_double edge_vector_z[7]={0,0,0,0,0,0,0};
			ts_double edge_normal_x[7]={0,0,0,0,0,0,0};
			ts_double edge_normal_y[7]={0,0,0,0,0,0,0};
			ts_double edge_normal_z[7]={0,0,0,0,0,0,0};
			ts_double edge_binormal_x[7]={0,0,0,0,0,0,0};
			ts_double edge_binormal_y[7]={0,0,0,0,0,0,0};
			ts_double edge_binormal_z[7]={0,0,0,0,0,0,0};
			ts_double vertex_normal_x=0.0;
			ts_double vertex_normal_y=0.0;
			ts_double vertex_normal_z=0.0;
			// ts_triangle *triedge[2]={NULL,NULL};

			data->bond[jj-1]->data->bond_length_dual=tot*data->bond[jj-1]->data->bond_length;
			ts_uint nei,neip,neim;
			ts_vertex it, k, kp,km;
			ts_triangle lm=NULL, lp=NULL;
			ts_double sumnorm;

			s+=tot*xlen;
			xh+=tot*(j->data->x - data->x);
			yh+=tot*(j->data->y - data->y);
			zh+=tot*(j->data->z - data->z);
			txn+=jt->data->xnorm;
			tyn+=jt->data->ynorm;
			tzn+=jt->data->znorm;
			}

			h=xhxh+yhyh+zh*zh;
			ht=txnxh+tynyh + tzn*zh;
			s=s/4.0;
			#ifdef TS_DOUBLE_DOUBLE
			if(ht>=0.0) {
			data->curvature=sqrt(h);
			} else {
			data->curvature=-sqrt(h);
			}
			#endif
			#ifdef TS_DOUBLE_FLOAT
			if(ht>=0.0) {
			data->curvature=sqrtf(h);
			} else {
			data->curvature=-sqrtf(h);
			}
			#endif
			#ifdef TS_DOUBLE_LONGDOUBLE
			if(ht>=0.0) {
			data->curvature=sqrtl(h);
			} else {
			data->curvature=-sqrtl(h);
			}
			#endif
			// What is vtx->data->c?????????????? Here it is 0!
			// c is forced curvature energy for each vertex. Should be set to zero for
			// norman circumstances.
			data->energy=0.5s(data->curvature/s-data->c)*(data->curvature/s-data->c);
			// Here edge vector is calculated
			// fprintf(stderr, "Vertex has neighbours=%d\n", vtx->neigh_no);
			for(jj=0;jj<vtx->neigh_no;jj++){
			edge_vector_x[jj]=vtx->neigh[jj]->x-vtx->x;
			edge_vector_y[jj]=vtx->neigh[jj]->y-vtx->y;
			edge_vector_z[jj]=vtx->neigh[jj]->z-vtx->z;

			return TS_SUCCESS;

			it=vtx;
			k=vtx->neigh[jj];
			nei=0;
			for(i=0;i<it->neigh_no;i++){ // Finds the nn of it, that is k
			if(it->neigh[i]==k){
			nei=i;
			break;
			}
			}
			neip=nei+1; // I don't like it.. Smells like I must have it in correct order
			neim=nei-1;
			if(neip>=it->neigh_no) neip=0;
			if((ts_int)neim<0) neim=it->neigh_no-1; /* casting is essential... If not
			there the neim is never <0 !!! */
			// fprintf(stderr,"The numbers are: %u %u\n",neip, neim);
			km=it->neigh[neim]; // We located km and kp
			kp=it->neigh[neip];

			if(km==NULL \|\| kp==NULL){
			fatal("In bondflip, cannot determine km and kp!",999);
			}

			for(i=0;i<it->tristar_no;i++){
			for(j=0;j<k->tristar_no;j++){
			if((it->tristar[i] == k->tristar[j])){ //ce gre za skupen trikotnik
			if((it->tristar[i]->vertex[0] == km \|\| it->tristar[i]->vertex[1]
			== km \|\| it->tristar[i]->vertex[2]== km )){
			lm=it->tristar[i];
			// lmidx=i;
			}
			else
			{
			lp=it->tristar[i];
			// lpidx=i;
			}

			}
			}
			}
			if(lm==NULL \|\| lp==NULL) fatal("ts_flip_bond: Cannot find triangles lm and lp!",999);


			/*
			// We find lm and lp from k->tristar !
			cnt=0;
			for(i=0;i<vtx->tristar_no;i++){
			for(j=0;j<vtx->neigh[jj]->tristar_no;j++){
			if((vtx->tristar[i] == vtx->neigh[jj]->tristar[j])){ //ce gre za skupen trikotnik
			triedge[cnt]=vtx->tristar[i];
			cnt++;
			}
			}
			}
			if(cnt!=2) fatal("ts_energy_vertex: both triangles not found!", 133);
			*/

			sumnorm=sqrt( pow((lm->xnorm + lp->xnorm),2) + pow((lm->ynorm + lp->ynorm), 2) + pow((lm->znorm + lp->znorm), 2));

			edge_normal_x[jj]=(lm->xnorm+ lp->xnorm)/sumnorm;
			edge_normal_y[jj]=(lm->ynorm+ lp->ynorm)/sumnorm;
			edge_normal_z[jj]=(lm->znorm+ lp->znorm)/sumnorm;


			edge_binormal_x[jj]=(edge_normal_y[jj]edge_vector_z[jj])-(edge_normal_z[jj]edge_vector_y[jj]);
			edge_binormal_y[jj]=-(edge_normal_x[jj]edge_vector_z[jj])+(edge_normal_z[jj]edge_vector_x[jj]);
			edge_binormal_z[jj]=(edge_normal_x[jj]edge_vector_y[jj])-(edge_normal_y[jj]edge_vector_x[jj]);

			printf("(%f %f %f); (%f %f %f); (%f %f %f)\n", edge_vector_x[jj], edge_vector_y[jj], edge_vector_z[jj], edge_normal_x[jj], edge_normal_y[jj], edge_normal_z[jj], edge_binormal_x[jj], edge_binormal_y[jj], edge_binormal_z[jj]);

			}
			for(i=0; i<vtx->tristar_no; i++){
			vertex_normal_x=vertex_normal_x + vtx->tristar[i]->xnorm*vtx->tristar[i]->area;
			vertex_normal_y=vertex_normal_y + vtx->tristar[i]->ynorm*vtx->tristar[i]->area;
			vertex_normal_z=vertex_normal_z + vtx->tristar[i]->znorm*vtx->tristar[i]->area;
			}
			printf("(%f %f %f)\n", vertex_normal_x, vertex_normal_y, vertex_normal_z);
			vtx->energy=0.0;
			return TS_SUCCESS;
			}

			ts_bool sweep_attraction_bond_energy(ts_vesicle *vesicle){
			int i;
			for(i=0;i<vesicle->blist->n;i++){
			attraction_bond_energy(vesicle->blist->bond[i], vesicle->tape->w);
			}
			return TS_SUCCESS;
			}


			inline ts_bool attraction_bond_energy(ts_bond *bond, ts_double w){

			if(fabs(bond->vtx1->c)>1e-16 && fabs(bond->vtx2->c)>1e-16){
			bond->energy=-w;
			}
			else {
			bond->energy=0.0;
			}
			return TS_SUCCESS;
			}

			ts_double direct_force_energy(ts_vesicle vesicle, ts_vertex vtx, ts_vertex *vtx_old){
			if(fabs(vtx->c)<1e-15) return 0.0;
			// printf("was here");
			if(fabs(vesicle->tape->F)<1e-15) return 0.0;

			ts_double norml,ddp=0.0;
			ts_uint i;
			ts_double xnorm=0.0,ynorm=0.0,znorm=0.0;
			/find normal of the vertex as sum of all the normals of the triangles surrounding it. /
			for(i=0;i<vtx->tristar_no;i++){
			xnorm+=vtx->tristar[i]->xnorm;
			ynorm+=vtx->tristar[i]->ynorm;
			znorm+=vtx->tristar[i]->znorm;
			}
			/normalize/
			norml=sqrt(xnormxnorm+ynormynorm+znorm*znorm);
			xnorm/=norml;
			ynorm/=norml;
			znorm/=norml;
			/calculate ddp, perpendicular displacement/
			ddp=xnorm(vtx->x-vtx_old->x)+ynorm(vtx->y-vtx_old->y)+znorm*(vtx->z-vtx_old->z);
			/calculate dE/
			// printf("ddp=%e",ddp);
			return vesicle->tape->F*ddp;

			}

			void stretchenergy(ts_vesicle vesicle, ts_triangle triangle){
			triangle->energy=vesicle->tape->xkA0/2.0*pow((triangle->area/vesicle->tlist->a0-1.0),2);
			}