PyObject *wrap_calc_fit_R(PyObject *self,PyObject *args) { PyObject *cs1, *cs2, *mass; if(!PyArg_ParseTuple(args,"OOO",&cs1, &cs2, &mass)) return NULL; int natoms1 = PySequence_Length(cs1); int natoms2 = PySequence_Length(cs2); if( natoms1 != natoms2 ) { Error("Cannot fit coordinate sets with different lengths"); } rvec x1[natoms1]; rvec x2[natoms1]; real m[natoms1]; PyObject2rvec( cs1, x1, natoms1); PyObject2rvec( cs2, x2, natoms2); PyObject2real_array(mass, m, natoms1); center(x1, natoms1); center(x2, natoms1); matrix R; clear_mat(R); calc_fit_R(natoms1,m,x1,x2,R); PyObject *ret = matrix2PyObject(R); return ret; }
void do_fit_ndim(int ndim, int natoms, real *w_rls, rvec *xp, rvec *x) { int i, j, m, r, c; matrix R; rvec x_old; /* Calculate the rotation matrix R */ calc_fit_R(ndim, natoms, w_rls, xp, x, R); /*rotate X*/ for (j = 0; j < natoms; j++) { for (m = 0; m < DIM; m++) { x_old[m] = x[j][m]; } for (r = 0; r < DIM; r++) { x[j][r] = 0; for (c = 0; c < DIM; c++) { x[j][r] += R[r][c]*x_old[c]; } } } }
real calc_orires_dev(const gmx_multisim_t *ms, int nfa,const t_iatom forceatoms[],const t_iparams ip[], const t_mdatoms *md,const rvec x[],const t_pbc *pbc, t_fcdata *fcd,history_t *hist) { int fa,d,i,j,type,ex,nref; real edt,edt1,invn,pfac,r2,invr,corrfac,weight,wsv2,sw,dev; tensor *S,R,TMP; rvec5 *Dinsl,*Dins,*Dtav,*rhs; real *mref,***T; double mtot; rvec *xref,*xtmp,com,r_unrot,r; t_oriresdata *od; bool bTAV; const real two_thr=2.0/3.0; od = &(fcd->orires); if (od->nr == 0) { /* This means that this is not the master node */ gmx_fatal(FARGS,"Orientation restraints are only supported on the master node, use less processors"); } bTAV = (od->edt != 0); edt = od->edt; edt1 = od->edt1; S = od->S; Dinsl= od->Dinsl; Dins = od->Dins; Dtav = od->Dtav; T = od->TMP; rhs = od->tmp; nref = od->nref; mref = od->mref; xref = od->xref; xtmp = od->xtmp; if (bTAV) { od->exp_min_t_tau = hist->orire_initf*edt; /* Correction factor to correct for the lack of history * at short times. */ corrfac = 1.0/(1.0 - od->exp_min_t_tau); } else { corrfac = 1.0; } if (ms) { invn = 1.0/ms->nsim; } else { invn = 1.0; } clear_rvec(com); mtot = 0; j=0; for(i=0; i<md->nr; i++) { if (md->cORF[i] == 0) { copy_rvec(x[i],xtmp[j]); mref[j] = md->massT[i]; for(d=0; d<DIM; d++) { com[d] += mref[j]*xref[j][d]; } mtot += mref[j]; j++; } } svmul(1.0/mtot,com,com); for(j=0; j<nref; j++) { rvec_dec(xtmp[j],com); } /* Calculate the rotation matrix to rotate x to the reference orientation */ calc_fit_R(DIM,nref,mref,xref,xtmp,R); copy_mat(R,od->R); d = 0; for(fa=0; fa<nfa; fa+=3) { type = forceatoms[fa]; if (pbc) { pbc_dx_aiuc(pbc,x[forceatoms[fa+1]],x[forceatoms[fa+2]],r_unrot); } else { rvec_sub(x[forceatoms[fa+1]],x[forceatoms[fa+2]],r_unrot); } mvmul(R,r_unrot,r); r2 = norm2(r); invr = invsqrt(r2); /* Calculate the prefactor for the D tensor, this includes the factor 3! */ pfac = ip[type].orires.c*invr*invr*3; for(i=0; i<ip[type].orires.power; i++) { pfac *= invr; } Dinsl[d][0] = pfac*(2*r[0]*r[0] + r[1]*r[1] - r2); Dinsl[d][1] = pfac*(2*r[0]*r[1]); Dinsl[d][2] = pfac*(2*r[0]*r[2]); Dinsl[d][3] = pfac*(2*r[1]*r[1] + r[0]*r[0] - r2); Dinsl[d][4] = pfac*(2*r[1]*r[2]); if (ms) { for(i=0; i<5; i++) { Dins[d][i] = Dinsl[d][i]*invn; } } d++; } if (ms) { gmx_sum_sim(5*od->nr,Dins[0],ms); } /* Calculate the order tensor S for each experiment via optimization */ for(ex=0; ex<od->nex; ex++) { for(i=0; i<5; i++) { rhs[ex][i] = 0; for(j=0; j<=i; j++) { T[ex][i][j] = 0; } } } d = 0; for(fa=0; fa<nfa; fa+=3) { if (bTAV) { /* Here we update Dtav in t_fcdata using the data in history_t. * Thus the results stay correct when this routine * is called multiple times. */ for(i=0; i<5; i++) { Dtav[d][i] = edt*hist->orire_Dtav[d*5+i] + edt1*Dins[d][i]; } } type = forceatoms[fa]; ex = ip[type].orires.ex; weight = ip[type].orires.kfac; /* Calculate the vector rhs and half the matrix T for the 5 equations */ for(i=0; i<5; i++) { rhs[ex][i] += Dtav[d][i]*ip[type].orires.obs*weight; for(j=0; j<=i; j++) { T[ex][i][j] += Dtav[d][i]*Dtav[d][j]*weight; } } d++; } /* Now we have all the data we can calculate S */ for(ex=0; ex<od->nex; ex++) { /* Correct corrfac and copy one half of T to the other half */ for(i=0; i<5; i++) { rhs[ex][i] *= corrfac; T[ex][i][i] *= sqr(corrfac); for(j=0; j<i; j++) { T[ex][i][j] *= sqr(corrfac); T[ex][j][i] = T[ex][i][j]; } } m_inv_gen(T[ex],5,T[ex]); /* Calculate the orientation tensor S for this experiment */ S[ex][0][0] = 0; S[ex][0][1] = 0; S[ex][0][2] = 0; S[ex][1][1] = 0; S[ex][1][2] = 0; for(i=0; i<5; i++) { S[ex][0][0] += 1.5*T[ex][0][i]*rhs[ex][i]; S[ex][0][1] += 1.5*T[ex][1][i]*rhs[ex][i]; S[ex][0][2] += 1.5*T[ex][2][i]*rhs[ex][i]; S[ex][1][1] += 1.5*T[ex][3][i]*rhs[ex][i]; S[ex][1][2] += 1.5*T[ex][4][i]*rhs[ex][i]; } S[ex][1][0] = S[ex][0][1]; S[ex][2][0] = S[ex][0][2]; S[ex][2][1] = S[ex][1][2]; S[ex][2][2] = -S[ex][0][0] - S[ex][1][1]; } wsv2 = 0; sw = 0; d = 0; for(fa=0; fa<nfa; fa+=3) { type = forceatoms[fa]; ex = ip[type].orires.ex; od->otav[d] = two_thr* corrfac*(S[ex][0][0]*Dtav[d][0] + S[ex][0][1]*Dtav[d][1] + S[ex][0][2]*Dtav[d][2] + S[ex][1][1]*Dtav[d][3] + S[ex][1][2]*Dtav[d][4]); if (bTAV) { od->oins[d] = two_thr*(S[ex][0][0]*Dins[d][0] + S[ex][0][1]*Dins[d][1] + S[ex][0][2]*Dins[d][2] + S[ex][1][1]*Dins[d][3] + S[ex][1][2]*Dins[d][4]); } if (ms) { /* When ensemble averaging is used recalculate the local orientation * for output to the energy file. */ od->oinsl[d] = two_thr* (S[ex][0][0]*Dinsl[d][0] + S[ex][0][1]*Dinsl[d][1] + S[ex][0][2]*Dinsl[d][2] + S[ex][1][1]*Dinsl[d][3] + S[ex][1][2]*Dinsl[d][4]); } dev = od->otav[d] - ip[type].orires.obs; wsv2 += ip[type].orires.kfac*sqr(dev); sw += ip[type].orires.kfac; d++; } od->rmsdev = sqrt(wsv2/sw); /* Rotate the S matrices back, so we get the correct grad(tr(S D)) */ for(ex=0; ex<od->nex; ex++) { tmmul(R,S[ex],TMP); mmul(TMP,R,S[ex]); } return od->rmsdev; /* Approx. 120*nfa/3 flops */ }
static void get_refx(output_env_t oenv, const char *trxfn, int nfitdim, int skip, int gnx, int *index, gmx_bool bMW, t_topology *top, int ePBC, rvec *x_ref) { int natoms, nfr_all, nfr, i, j, a, r, c, min_fr; t_trxstatus *status; real *ti, min_t; double tot_mass, msd, *srmsd, min_srmsd, srmsd_tot; rvec *x, **xi; real xf; matrix box, R; real *w_rls; gmx_rmpbc_t gpbc = NULL; nfr_all = 0; nfr = 0; snew(ti, 100); snew(xi, 100); natoms = read_first_x(oenv, &status, trxfn, &ti[nfr], &x, box); snew(w_rls, gnx); tot_mass = 0; for (a = 0; a < gnx; a++) { if (index[a] >= natoms) { gmx_fatal(FARGS, "Atom index (%d) is larger than the number of atoms in the trajecory (%d)", index[a]+1, natoms); } w_rls[a] = (bMW ? top->atoms.atom[index[a]].m : 1.0); tot_mass += w_rls[a]; } gpbc = gmx_rmpbc_init(&top->idef, ePBC, natoms); do { if (nfr_all % skip == 0) { gmx_rmpbc(gpbc, natoms, box, x); snew(xi[nfr], gnx); for (i = 0; i < gnx; i++) { copy_rvec(x[index[i]], xi[nfr][i]); } reset_x(gnx, NULL, gnx, NULL, xi[nfr], w_rls); nfr++; if (nfr % 100 == 0) { srenew(ti, nfr+100); srenew(xi, nfr+100); } } nfr_all++; } while (read_next_x(oenv, status, &ti[nfr], x, box)); close_trj(status); sfree(x); gmx_rmpbc_done(gpbc); snew(srmsd, nfr); for (i = 0; i < nfr; i++) { printf("\rProcessing frame %d of %d", i, nfr); for (j = i+1; j < nfr; j++) { calc_fit_R(nfitdim, gnx, w_rls, xi[i], xi[j], R); msd = 0; for (a = 0; a < gnx; a++) { for (r = 0; r < DIM; r++) { xf = 0; for (c = 0; c < DIM; c++) { xf += R[r][c]*xi[j][a][c]; } msd += w_rls[a]*sqr(xi[i][a][r] - xf); } } msd /= tot_mass; srmsd[i] += sqrt(msd); srmsd[j] += sqrt(msd); } sfree(xi[i]); } printf("\n"); sfree(w_rls); min_srmsd = GMX_REAL_MAX; min_fr = -1; min_t = -1; srmsd_tot = 0; for (i = 0; i < nfr; i++) { srmsd[i] /= (nfr - 1); if (srmsd[i] < min_srmsd) { min_srmsd = srmsd[i]; min_fr = i; min_t = ti[i]; } srmsd_tot += srmsd[i]; } sfree(srmsd); printf("Average RMSD between all structures: %.3f\n", srmsd_tot/nfr); printf("Structure with lowest RMSD to all others: time %g, av. RMSD %.3f\n", min_t, min_srmsd); for (a = 0; a < gnx; a++) { copy_rvec(xi[min_fr][a], x_ref[index[a]]); } sfree(xi); }
int gmx_rotmat(int argc, char *argv[]) { const char *desc[] = { "[THISMODULE] plots the rotation matrix required for least squares fitting", "a conformation onto the reference conformation provided with", "[TT]-s[tt]. Translation is removed before fitting.", "The output are the three vectors that give the new directions", "of the x, y and z directions of the reference conformation,", "for example: (zx,zy,zz) is the orientation of the reference", "z-axis in the trajectory frame.", "[PAR]", "This tool is useful for, for instance,", "determining the orientation of a molecule", "at an interface, possibly on a trajectory produced with", "[TT]gmx trjconv -fit rotxy+transxy[tt] to remove the rotation", "in the [IT]x-y[it] plane.", "[PAR]", "Option [TT]-ref[tt] determines a reference structure for fitting,", "instead of using the structure from [TT]-s[tt]. The structure with", "the lowest sum of RMSD's to all other structures is used.", "Since the computational cost of this procedure grows with", "the square of the number of frames, the [TT]-skip[tt] option", "can be useful. A full fit or only a fit in the [IT]x-y[it] plane can", "be performed.", "[PAR]", "Option [TT]-fitxy[tt] fits in the [IT]x-y[it] plane before determining", "the rotation matrix." }; const char *reffit[] = { NULL, "none", "xyz", "xy", NULL }; static int skip = 1; static gmx_bool bFitXY = FALSE, bMW = TRUE; t_pargs pa[] = { { "-ref", FALSE, etENUM, {reffit}, "Determine the optimal reference structure" }, { "-skip", FALSE, etINT, {&skip}, "Use every nr-th frame for [TT]-ref[tt]" }, { "-fitxy", FALSE, etBOOL, {&bFitXY}, "Fit the x/y rotation before determining the rotation" }, { "-mw", FALSE, etBOOL, {&bMW}, "Use mass weighted fitting" } }; FILE *out; t_trxstatus *status; t_topology top; int ePBC; rvec *x_ref, *x; matrix box, R; real t; int natoms, i; char *grpname, title[256]; int gnx; gmx_rmpbc_t gpbc = NULL; atom_id *index; output_env_t oenv; real *w_rls; const char *leg[] = { "xx", "xy", "xz", "yx", "yy", "yz", "zx", "zy", "zz" }; #define NLEG asize(leg) t_filenm fnm[] = { { efTRX, "-f", NULL, ffREAD }, { efTPS, NULL, NULL, ffREAD }, { efNDX, NULL, NULL, ffOPTRD }, { efXVG, NULL, "rotmat", ffWRITE } }; #define NFILE asize(fnm) if (!parse_common_args(&argc, argv, PCA_CAN_TIME | PCA_CAN_VIEW | PCA_BE_NICE, NFILE, fnm, asize(pa), pa, asize(desc), desc, 0, NULL, &oenv)) { return 0; } read_tps_conf(ftp2fn(efTPS, NFILE, fnm), title, &top, &ePBC, &x_ref, NULL, box, bMW); gpbc = gmx_rmpbc_init(&top.idef, ePBC, top.atoms.nr); gmx_rmpbc(gpbc, top.atoms.nr, box, x_ref); get_index(&top.atoms, ftp2fn_null(efNDX, NFILE, fnm), 1, &gnx, &index, &grpname); if (reffit[0][0] != 'n') { get_refx(oenv, ftp2fn(efTRX, NFILE, fnm), reffit[0][2] == 'z' ? 3 : 2, skip, gnx, index, bMW, &top, ePBC, x_ref); } natoms = read_first_x(oenv, &status, ftp2fn(efTRX, NFILE, fnm), &t, &x, box); snew(w_rls, natoms); for (i = 0; i < gnx; i++) { if (index[i] >= natoms) { gmx_fatal(FARGS, "Atom index (%d) is larger than the number of atoms in the trajecory (%d)", index[i]+1, natoms); } w_rls[index[i]] = (bMW ? top.atoms.atom[index[i]].m : 1.0); } if (reffit[0][0] == 'n') { reset_x(gnx, index, natoms, NULL, x_ref, w_rls); } out = xvgropen(ftp2fn(efXVG, NFILE, fnm), "Fit matrix", "Time (ps)", "", oenv); xvgr_legend(out, NLEG, leg, oenv); do { gmx_rmpbc(gpbc, natoms, box, x); reset_x(gnx, index, natoms, NULL, x, w_rls); if (bFitXY) { do_fit_ndim(2, natoms, w_rls, x_ref, x); } calc_fit_R(DIM, natoms, w_rls, x_ref, x, R); fprintf(out, "%7g %7.4f %7.4f %7.4f %7.4f %7.4f %7.4f %7.4f %7.4f %7.4f\n", t, R[XX][XX], R[XX][YY], R[XX][ZZ], R[YY][XX], R[YY][YY], R[YY][ZZ], R[ZZ][XX], R[ZZ][YY], R[ZZ][ZZ]); } while (read_next_x(oenv, status, &t, x, box)); gmx_rmpbc_done(gpbc); close_trj(status); gmx_ffclose(out); do_view(oenv, ftp2fn(efXVG, NFILE, fnm), "-nxy"); return 0; }
int gmx_helixorient(int argc, char *argv[]) { const char *desc[] = { "[THISMODULE] calculates the coordinates and direction of the average", "axis inside an alpha helix, and the direction/vectors of both the", "C[GRK]alpha[grk] and (optionally) a sidechain atom relative to the axis.[PAR]", "As input, you need to specify an index group with C[GRK]alpha[grk] atoms", "corresponding to an [GRK]alpha[grk]-helix of continuous residues. Sidechain", "directions require a second index group of the same size, containing", "the heavy atom in each residue that should represent the sidechain.[PAR]", "[BB]Note[bb] that this program does not do any fitting of structures.[PAR]", "We need four C[GRK]alpha[grk] coordinates to define the local direction of the helix", "axis.[PAR]", "The tilt/rotation is calculated from Euler rotations, where we define", "the helix axis as the local [IT]x[it]-axis, the residues/C[GRK]alpha[grk] vector as [IT]y[it], and the", "[IT]z[it]-axis from their cross product. We use the Euler Y-Z-X rotation, meaning", "we first tilt the helix axis (1) around and (2) orthogonal to the residues", "vector, and finally apply the (3) rotation around it. For debugging or other", "purposes, we also write out the actual Euler rotation angles as [TT]theta[1-3].xvg[tt]" }; t_topology *top = NULL; real t; rvec *x = NULL; matrix box; t_trxstatus *status; int natoms; real theta1, theta2, theta3; int i, j, teller = 0; int iCA, iSC; int *ind_CA; int *ind_SC; char *gn_CA; char *gn_SC; rvec v1, v2; rvec *x_CA, *x_SC; rvec *r12; rvec *r23; rvec *r34; rvec *diff13; rvec *diff24; rvec *helixaxis; rvec *residuehelixaxis; rvec *residueorigin; rvec *residuevector; rvec *sidechainvector; rvec *residuehelixaxis_t0; rvec *residuevector_t0; rvec *axis3_t0; rvec *residuehelixaxis_tlast; rvec *residuevector_tlast; rvec *axis3_tlast; rvec refaxes[3], newaxes[3]; rvec unitaxes[3]; rvec rot_refaxes[3], rot_newaxes[3]; real tilt, rotation; rvec *axis3; real *twist, *residuetwist; real *radius, *residueradius; real *rise, *residuerise; real *residuebending; real tmp; real weight[3]; t_pbc pbc; matrix A; FILE *fpaxis, *fpcenter, *fptilt, *fprotation; FILE *fpradius, *fprise, *fptwist; FILE *fptheta1, *fptheta2, *fptheta3; FILE *fpbending; int ePBC; gmx_output_env_t *oenv; gmx_rmpbc_t gpbc = NULL; static gmx_bool bSC = FALSE; static gmx_bool bIncremental = FALSE; static t_pargs pa[] = { { "-sidechain", FALSE, etBOOL, {&bSC}, "Calculate sidechain directions relative to helix axis too." }, { "-incremental", FALSE, etBOOL, {&bIncremental}, "Calculate incremental rather than total rotation/tilt." }, }; #define NPA asize(pa) t_filenm fnm[] = { { efTPR, NULL, NULL, ffREAD }, { efTRX, "-f", NULL, ffREAD }, { efNDX, NULL, NULL, ffOPTRD }, { efDAT, "-oaxis", "helixaxis", ffWRITE }, { efDAT, "-ocenter", "center", ffWRITE }, { efXVG, "-orise", "rise", ffWRITE }, { efXVG, "-oradius", "radius", ffWRITE }, { efXVG, "-otwist", "twist", ffWRITE }, { efXVG, "-obending", "bending", ffWRITE }, { efXVG, "-otilt", "tilt", ffWRITE }, { efXVG, "-orot", "rotation", ffWRITE } }; #define NFILE asize(fnm) if (!parse_common_args(&argc, argv, PCA_CAN_TIME, NFILE, fnm, NPA, pa, asize(desc), desc, 0, NULL, &oenv)) { return 0; } top = read_top(ftp2fn(efTPR, NFILE, fnm), &ePBC); for (i = 0; i < 3; i++) { weight[i] = 1.0; } /* read index files */ printf("Select a group of Calpha atoms corresponding to a single continuous helix:\n"); get_index(&(top->atoms), ftp2fn_null(efNDX, NFILE, fnm), 1, &iCA, &ind_CA, &gn_CA); snew(x_CA, iCA); snew(x_SC, iCA); /* sic! */ snew(r12, iCA-3); snew(r23, iCA-3); snew(r34, iCA-3); snew(diff13, iCA-3); snew(diff24, iCA-3); snew(helixaxis, iCA-3); snew(twist, iCA); snew(residuetwist, iCA); snew(radius, iCA); snew(residueradius, iCA); snew(rise, iCA); snew(residuerise, iCA); snew(residueorigin, iCA); snew(residuehelixaxis, iCA); snew(residuevector, iCA); snew(sidechainvector, iCA); snew(residuebending, iCA); snew(residuehelixaxis_t0, iCA); snew(residuevector_t0, iCA); snew(axis3_t0, iCA); snew(residuehelixaxis_tlast, iCA); snew(residuevector_tlast, iCA); snew(axis3_tlast, iCA); snew(axis3, iCA); if (bSC) { printf("Select a group of atoms defining the sidechain direction (1/residue):\n"); get_index(&(top->atoms), ftp2fn_null(efNDX, NFILE, fnm), 1, &iSC, &ind_SC, &gn_SC); if (iSC != iCA) { gmx_fatal(FARGS, "Number of sidechain atoms (%d) != number of CA atoms (%d)", iSC, iCA); } } natoms = read_first_x(oenv, &status, ftp2fn(efTRX, NFILE, fnm), &t, &x, box); fpaxis = gmx_ffopen(opt2fn("-oaxis", NFILE, fnm), "w"); fpcenter = gmx_ffopen(opt2fn("-ocenter", NFILE, fnm), "w"); fprise = gmx_ffopen(opt2fn("-orise", NFILE, fnm), "w"); fpradius = gmx_ffopen(opt2fn("-oradius", NFILE, fnm), "w"); fptwist = gmx_ffopen(opt2fn("-otwist", NFILE, fnm), "w"); fpbending = gmx_ffopen(opt2fn("-obending", NFILE, fnm), "w"); fptheta1 = gmx_ffopen("theta1.xvg", "w"); fptheta2 = gmx_ffopen("theta2.xvg", "w"); fptheta3 = gmx_ffopen("theta3.xvg", "w"); if (bIncremental) { fptilt = xvgropen(opt2fn("-otilt", NFILE, fnm), "Incremental local helix tilt", "Time(ps)", "Tilt (degrees)", oenv); fprotation = xvgropen(opt2fn("-orot", NFILE, fnm), "Incremental local helix rotation", "Time(ps)", "Rotation (degrees)", oenv); } else { fptilt = xvgropen(opt2fn("-otilt", NFILE, fnm), "Cumulative local helix tilt", "Time(ps)", "Tilt (degrees)", oenv); fprotation = xvgropen(opt2fn("-orot", NFILE, fnm), "Cumulative local helix rotation", "Time(ps)", "Rotation (degrees)", oenv); } clear_rvecs(3, unitaxes); unitaxes[0][0] = 1; unitaxes[1][1] = 1; unitaxes[2][2] = 1; gpbc = gmx_rmpbc_init(&top->idef, ePBC, natoms); do { /* initialisation for correct distance calculations */ set_pbc(&pbc, ePBC, box); /* make molecules whole again */ gmx_rmpbc(gpbc, natoms, box, x); /* copy coords to our smaller arrays */ for (i = 0; i < iCA; i++) { copy_rvec(x[ind_CA[i]], x_CA[i]); if (bSC) { copy_rvec(x[ind_SC[i]], x_SC[i]); } } for (i = 0; i < iCA-3; i++) { rvec_sub(x_CA[i+1], x_CA[i], r12[i]); rvec_sub(x_CA[i+2], x_CA[i+1], r23[i]); rvec_sub(x_CA[i+3], x_CA[i+2], r34[i]); rvec_sub(r12[i], r23[i], diff13[i]); rvec_sub(r23[i], r34[i], diff24[i]); /* calculate helix axis */ cprod(diff13[i], diff24[i], helixaxis[i]); svmul(1.0/norm(helixaxis[i]), helixaxis[i], helixaxis[i]); tmp = cos_angle(diff13[i], diff24[i]); twist[i] = 180.0/M_PI * std::acos( tmp ); radius[i] = std::sqrt( norm(diff13[i])*norm(diff24[i]) ) / (2.0* (1.0-tmp) ); rise[i] = std::abs(iprod(r23[i], helixaxis[i])); svmul(radius[i]/norm(diff13[i]), diff13[i], v1); svmul(radius[i]/norm(diff24[i]), diff24[i], v2); rvec_sub(x_CA[i+1], v1, residueorigin[i+1]); rvec_sub(x_CA[i+2], v2, residueorigin[i+2]); } residueradius[0] = residuetwist[0] = residuerise[0] = 0; residueradius[1] = radius[0]; residuetwist[1] = twist[0]; residuerise[1] = rise[0]; residuebending[0] = residuebending[1] = 0; for (i = 2; i < iCA-2; i++) { residueradius[i] = 0.5*(radius[i-2]+radius[i-1]); residuetwist[i] = 0.5*(twist[i-2]+twist[i-1]); residuerise[i] = 0.5*(rise[i-2]+rise[i-1]); residuebending[i] = 180.0/M_PI*std::acos( cos_angle(helixaxis[i-2], helixaxis[i-1]) ); } residueradius[iCA-2] = radius[iCA-4]; residuetwist[iCA-2] = twist[iCA-4]; residuerise[iCA-2] = rise[iCA-4]; residueradius[iCA-1] = residuetwist[iCA-1] = residuerise[iCA-1] = 0; residuebending[iCA-2] = residuebending[iCA-1] = 0; clear_rvec(residueorigin[0]); clear_rvec(residueorigin[iCA-1]); /* average helix axes to define them on the residues. * Just extrapolate second first/list atom. */ copy_rvec(helixaxis[0], residuehelixaxis[0]); copy_rvec(helixaxis[0], residuehelixaxis[1]); for (i = 2; i < iCA-2; i++) { rvec_add(helixaxis[i-2], helixaxis[i-1], residuehelixaxis[i]); svmul(0.5, residuehelixaxis[i], residuehelixaxis[i]); } copy_rvec(helixaxis[iCA-4], residuehelixaxis[iCA-2]); copy_rvec(helixaxis[iCA-4], residuehelixaxis[iCA-1]); /* Normalize the axis */ for (i = 0; i < iCA; i++) { svmul(1.0/norm(residuehelixaxis[i]), residuehelixaxis[i], residuehelixaxis[i]); } /* calculate vector from origin to residue CA */ fprintf(fpaxis, "%15.12g ", t); fprintf(fpcenter, "%15.12g ", t); fprintf(fprise, "%15.12g ", t); fprintf(fpradius, "%15.12g ", t); fprintf(fptwist, "%15.12g ", t); fprintf(fpbending, "%15.12g ", t); for (i = 0; i < iCA; i++) { if (i == 0 || i == iCA-1) { fprintf(fpaxis, "%15.12g %15.12g %15.12g ", 0.0, 0.0, 0.0); fprintf(fpcenter, "%15.12g %15.12g %15.12g ", 0.0, 0.0, 0.0); fprintf(fprise, "%15.12g ", 0.0); fprintf(fpradius, "%15.12g ", 0.0); fprintf(fptwist, "%15.12g ", 0.0); fprintf(fpbending, "%15.12g ", 0.0); } else { rvec_sub( bSC ? x_SC[i] : x_CA[i], residueorigin[i], residuevector[i]); svmul(1.0/norm(residuevector[i]), residuevector[i], residuevector[i]); cprod(residuehelixaxis[i], residuevector[i], axis3[i]); fprintf(fpaxis, "%15.12g %15.12g %15.12g ", residuehelixaxis[i][0], residuehelixaxis[i][1], residuehelixaxis[i][2]); fprintf(fpcenter, "%15.12g %15.12g %15.12g ", residueorigin[i][0], residueorigin[i][1], residueorigin[i][2]); fprintf(fprise, "%15.12g ", residuerise[i]); fprintf(fpradius, "%15.12g ", residueradius[i]); fprintf(fptwist, "%15.12g ", residuetwist[i]); fprintf(fpbending, "%15.12g ", residuebending[i]); } } fprintf(fprise, "\n"); fprintf(fpradius, "\n"); fprintf(fpaxis, "\n"); fprintf(fpcenter, "\n"); fprintf(fptwist, "\n"); fprintf(fpbending, "\n"); if (teller == 0) { for (i = 0; i < iCA; i++) { copy_rvec(residuehelixaxis[i], residuehelixaxis_t0[i]); copy_rvec(residuevector[i], residuevector_t0[i]); copy_rvec(axis3[i], axis3_t0[i]); } } else { fprintf(fptilt, "%15.12g ", t); fprintf(fprotation, "%15.12g ", t); fprintf(fptheta1, "%15.12g ", t); fprintf(fptheta2, "%15.12g ", t); fprintf(fptheta3, "%15.12g ", t); for (i = 0; i < iCA; i++) { if (i == 0 || i == iCA-1) { tilt = rotation = 0; } else { if (!bIncremental) { /* Total rotation & tilt */ copy_rvec(residuehelixaxis_t0[i], refaxes[0]); copy_rvec(residuevector_t0[i], refaxes[1]); copy_rvec(axis3_t0[i], refaxes[2]); } else { /* Rotation/tilt since last step */ copy_rvec(residuehelixaxis_tlast[i], refaxes[0]); copy_rvec(residuevector_tlast[i], refaxes[1]); copy_rvec(axis3_tlast[i], refaxes[2]); } copy_rvec(residuehelixaxis[i], newaxes[0]); copy_rvec(residuevector[i], newaxes[1]); copy_rvec(axis3[i], newaxes[2]); /* rotate reference frame onto unit axes */ calc_fit_R(3, 3, weight, unitaxes, refaxes, A); for (j = 0; j < 3; j++) { mvmul(A, refaxes[j], rot_refaxes[j]); mvmul(A, newaxes[j], rot_newaxes[j]); } /* Determine local rotation matrix A */ calc_fit_R(3, 3, weight, rot_newaxes, rot_refaxes, A); /* Calculate euler angles, from rotation order y-z-x, where * x is helixaxis, y residuevector, and z axis3. * * A contains rotation column vectors. */ theta1 = 180.0/M_PI*std::atan2(A[0][2], A[0][0]); theta2 = 180.0/M_PI*std::asin(-A[0][1]); theta3 = 180.0/M_PI*std::atan2(A[2][1], A[1][1]); tilt = std::sqrt(theta1*theta1+theta2*theta2); rotation = theta3; fprintf(fptheta1, "%15.12g ", theta1); fprintf(fptheta2, "%15.12g ", theta2); fprintf(fptheta3, "%15.12g ", theta3); } fprintf(fptilt, "%15.12g ", tilt); fprintf(fprotation, "%15.12g ", rotation); } fprintf(fptilt, "\n"); fprintf(fprotation, "\n"); fprintf(fptheta1, "\n"); fprintf(fptheta2, "\n"); fprintf(fptheta3, "\n"); } for (i = 0; i < iCA; i++) { copy_rvec(residuehelixaxis[i], residuehelixaxis_tlast[i]); copy_rvec(residuevector[i], residuevector_tlast[i]); copy_rvec(axis3[i], axis3_tlast[i]); } teller++; } while (read_next_x(oenv, status, &t, x, box)); gmx_rmpbc_done(gpbc); gmx_ffclose(fpaxis); gmx_ffclose(fpcenter); xvgrclose(fptilt); xvgrclose(fprotation); gmx_ffclose(fprise); gmx_ffclose(fpradius); gmx_ffclose(fptwist); gmx_ffclose(fpbending); gmx_ffclose(fptheta1); gmx_ffclose(fptheta2); gmx_ffclose(fptheta3); close_trj(status); return 0; }
real calc_orires_dev(t_commrec *mcr, int nfa,t_iatom forceatoms[],t_iparams ip[], t_mdatoms *md,rvec x[],t_fcdata *fcd) { int fa,d,i,j,type,ex,nref; real edt,edt1,invn,pfac,r2,invr,corrfac,weight,wsv2,sw,dev; tensor *S,R,TMP; rvec5 *Dinsl,*Dins,*Dtav,*rhs; real *mref,***T; rvec *xref,*xtmp,com,r_unrot,r; t_oriresdata *od; bool bTAV; static real two_thr=2.0/3.0; od = &(fcd->orires); bTAV = (fabs(od->edt)>GMX_REAL_MIN); edt = od->edt; edt1 = od->edt1; S = od->S; Dinsl= od->Dinsl; Dins = od->Dins; Dtav = od->Dtav; T = od->TMP; rhs = od->tmp; nref = od->nref; mref = od->mref; xref = od->xref; xtmp = od->xtmp; od->exp_min_t_tau *= edt; if (mcr) invn = 1.0/mcr->nnodes; else invn = 1.0; j=0; for(i=0; i<md->nr; i++) if (md->cORF[i] == 0) { copy_rvec(x[i],xtmp[j]); for(d=0; d<DIM; d++) com[d] += mref[j]*xref[j][d]; j++; } svmul(od->invmref,com,com); for(j=0; j<nref; j++) rvec_dec(xtmp[j],com); /* Calculate the rotation matrix to rotate x to the reference orientation */ calc_fit_R(nref,mref,xref,xtmp,R); copy_mat(R,od->R); d = 0; for(fa=0; fa<nfa; fa+=3) { type = forceatoms[fa]; rvec_sub(x[forceatoms[fa+1]],x[forceatoms[fa+2]],r_unrot); mvmul(R,r_unrot,r); r2 = norm2(r); invr = invsqrt(r2); /* Calculate the prefactor for the D tensor, this includes the factor 3! */ pfac = ip[type].orires.c*invr*invr*3; for(i=0; i<ip[type].orires.pow; i++) pfac *= invr; Dinsl[d][0] = pfac*(2*r[0]*r[0] + r[1]*r[1] - r2); Dinsl[d][1] = pfac*(2*r[0]*r[1]); Dinsl[d][2] = pfac*(2*r[0]*r[2]); Dinsl[d][3] = pfac*(2*r[1]*r[1] + r[0]*r[0] - r2); Dinsl[d][4] = pfac*(2*r[1]*r[2]); if (mcr) for(i=0; i<5; i++) Dins[d][i] = Dinsl[d][i]*invn; d++; } if (mcr) gmx_sum(5*od->nr,Dins[0],mcr); /* Correction factor to correct for the lack of history for short times */ corrfac = 1.0/(1.0-od->exp_min_t_tau); /* Calculate the order tensor S for each experiment via optimization */ for(ex=0; ex<od->nex; ex++) for(i=0; i<5; i++) { rhs[ex][i] = 0; for(j=0; j<=i; j++) T[ex][i][j] = 0; } d = 0; for(fa=0; fa<nfa; fa+=3) { if (bTAV) for(i=0; i<5; i++) Dtav[d][i] = edt*Dtav[d][i] + edt1*Dins[d][i]; type = forceatoms[fa]; ex = ip[type].orires.ex; weight = ip[type].orires.kfac; /* Calculate the vector rhs and half the matrix T for the 5 equations */ for(i=0; i<5; i++) { rhs[ex][i] += Dtav[d][i]*ip[type].orires.obs*weight; for(j=0; j<=i; j++) T[ex][i][j] += Dtav[d][i]*Dtav[d][j]*weight; } d++; } /* Now we have all the data we can calculate S */ for(ex=0; ex<od->nex; ex++) { /* Correct corrfac and copy one half of T to the other half */ for(i=0; i<5; i++) { rhs[ex][i] *= corrfac; T[ex][i][i] *= sqr(corrfac); for(j=0; j<i; j++) { T[ex][i][j] *= sqr(corrfac); T[ex][j][i] = T[ex][i][j]; } } m_inv_gen(T[ex],5,T[ex]); /* Calculate the orientation tensor S for this experiment */ S[ex][0][0] = 0; S[ex][0][1] = 0; S[ex][0][2] = 0; S[ex][1][1] = 0; S[ex][1][2] = 0; for(i=0; i<5; i++) { S[ex][0][0] += 1.5*T[ex][0][i]*rhs[ex][i]; S[ex][0][1] += 1.5*T[ex][1][i]*rhs[ex][i]; S[ex][0][2] += 1.5*T[ex][2][i]*rhs[ex][i]; S[ex][1][1] += 1.5*T[ex][3][i]*rhs[ex][i]; S[ex][1][2] += 1.5*T[ex][4][i]*rhs[ex][i]; } S[ex][1][0] = S[ex][0][1]; S[ex][2][0] = S[ex][0][2]; S[ex][2][1] = S[ex][1][2]; S[ex][2][2] = -S[ex][0][0] - S[ex][1][1]; } wsv2 = 0; sw = 0; d = 0; for(fa=0; fa<nfa; fa+=3) { type = forceatoms[fa]; ex = ip[type].orires.ex; od->otav[d] = two_thr* corrfac*(S[ex][0][0]*Dtav[d][0] + S[ex][0][1]*Dtav[d][1] + S[ex][0][2]*Dtav[d][2] + S[ex][1][1]*Dtav[d][3] + S[ex][1][2]*Dtav[d][4]); if (bTAV) od->oins[d] = two_thr*(S[ex][0][0]*Dins[d][0] + S[ex][0][1]*Dins[d][1] + S[ex][0][2]*Dins[d][2] + S[ex][1][1]*Dins[d][3] + S[ex][1][2]*Dins[d][4]); if (mcr) /* When ensemble averaging is used recalculate the local orientation * for output to the energy file. */ od->oinsl[d] = two_thr* (S[ex][0][0]*Dinsl[d][0] + S[ex][0][1]*Dinsl[d][1] + S[ex][0][2]*Dinsl[d][2] + S[ex][1][1]*Dinsl[d][3] + S[ex][1][2]*Dinsl[d][4]); dev = od->otav[d] - ip[type].orires.obs; wsv2 += ip[type].orires.kfac*sqr(dev); sw += ip[type].orires.kfac; d++; } od->rmsdev = sqrt(wsv2/sw); /* Rotate the S matrices back, so we get the correct grad(tr(S D)) */ for(ex=0; ex<od->nex; ex++) { tmmul(R,S[ex],TMP); mmul(TMP,R,S[ex]); } return od->rmsdev; /* Approx. 120*nfa/3 flops */ }