include 'COMMON.INTERACT'
include 'COMMON.SBRIDGE'
include 'COMMON.CHAIN'
+ include 'COMMON.SHIELD'
+ include 'COMMON.CONTROL'
double precision fact(6)
cd write(iout, '(a,i2)')'Calling etotal ipot=',ipot
cd print *,'nnt=',nnt,' nct=',nct
C
C Calculate electrostatic (H-bonding) energy of the main chain.
C
- 106 call eelec(ees,evdw1,eel_loc,eello_turn3,eello_turn4)
+ 106 continue
+ if (shield_mode.eq.1) then
+ call set_shield_fac
+ else if (shield_mode.eq.2) then
+ call set_shield_fac2
+ endif
+ call eelec(ees,evdw1,eel_loc,eello_turn3,eello_turn4)
C write(iout,*) 'po eelec'
C Calculate excluded-volume interaction energy between peptide groups
call Eliptransfer(eliptran)
endif
+ if (TUBElog.eq.1) then
+ print *,"just before call"
+ call calctube(Etube)
+ print *,"just after call",etube
+ elseif (TUBElog.eq.2) then
+ call calctube2(Etube)
+ elseif (TUBElog.eq.3) then
+ call calcnano(Etube)
+ else
+ Etube=0.0d0
+ endif
+
C
C 12/1/95 Multi-body terms
C
call multibody_eello(ecorr,ecorr5,ecorr6,eturn6,n_corr,n_corr1)
c write (*,*) 'n_corr=',n_corr,' n_corr1=',n_corr1
c print *,ecorr,ecorr5,ecorr6,eturn6
+ else
+ ecorr=0.0d0
+ ecorr5=0.0d0
+ ecorr6=0.0d0
+ eturn6=0.0d0
endif
if (wcorr4.eq.0.0d0 .and. wcorr.gt.0.0d0) then
call multibody_hb(ecorr,ecorr5,ecorr6,n_corr,n_corr1)
endif
c write (iout,*) "ft(6)",fact(6)," evdw",evdw," evdw_t",evdw_t
#ifdef SPLITELE
+ if (shield_mode.gt.0) then
+ etot=fact(1)*wsc*(evdw+fact(6)*evdw_t)+fact(1)*wscp*evdw2
+ & +welec*fact(1)*ees
+ & +fact(1)*wvdwpp*evdw1
+ & +wang*ebe+wtor*fact(1)*etors+wscloc*escloc
+ & +wstrain*ehpb+wcorr*fact(3)*ecorr+wcorr5*fact(4)*ecorr5
+ & +wcorr6*fact(5)*ecorr6+wturn4*fact(3)*eello_turn4
+ & +wturn3*fact(2)*eello_turn3+wturn6*fact(5)*eturn6
+ & +wel_loc*fact(2)*eel_loc+edihcnstr+wtor_d*fact(2)*etors_d
+ & +wbond*estr+wsccor*fact(1)*esccor+ethetacnstr
+ & +wliptran*eliptran+wtube*Etube
+ else
etot=wsc*(evdw+fact(6)*evdw_t)+wscp*evdw2+welec*fact(1)*ees
& +wvdwpp*evdw1
& +wang*ebe+wtor*fact(1)*etors+wscloc*escloc
& +wturn3*fact(2)*eello_turn3+wturn6*fact(5)*eturn6
& +wel_loc*fact(2)*eel_loc+edihcnstr+wtor_d*fact(2)*etors_d
& +wbond*estr+wsccor*fact(1)*esccor+ethetacnstr
- & +wliptran*eliptran
+ & +wliptran*eliptran+wtube*Etube
+ endif
#else
+ if (shield_mode.gt.0) then
+ etot=fact(1)wsc*(evdw+fact(6)*evdw_t)+fact(1)*wscp*evdw2
+ & +welec*fact(1)*(ees+evdw1)
+ & +wang*ebe+wtor*fact(1)*etors+wscloc*escloc
+ & +wstrain*ehpb+wcorr*fact(3)*ecorr+wcorr5*fact(4)*ecorr5
+ & +wcorr6*fact(5)*ecorr6+wturn4*fact(3)*eello_turn4
+ & +wturn3*fact(2)*eello_turn3+wturn6*fact(5)*eturn6
+ & +wel_loc*fact(2)*eel_loc+edihcnstr+wtor_d*fact(2)*etors_d
+ & +wbond*estr+wsccor*fact(1)*esccor+ethetacnstr
+ & +wliptran*eliptran+wtube*Etube
+ else
etot=wsc*(evdw+fact(6)*evdw_t)+wscp*evdw2
& +welec*fact(1)*(ees+evdw1)
& +wang*ebe+wtor*fact(1)*etors+wscloc*escloc
& +wturn3*fact(2)*eello_turn3+wturn6*fact(5)*eturn6
& +wel_loc*fact(2)*eel_loc+edihcnstr+wtor_d*fact(2)*etors_d
& +wbond*estr+wsccor*fact(1)*esccor+ethetacnstr
- & +wliptran*eliptran
+ & +wliptran*eliptran+wtube*Etube
+ endif
#endif
energia(0)=etot
energia(1)=evdw
energia(21)=evdw_t
energia(24)=ethetacnstr
energia(22)=eliptran
+ energia(25)=Etube
c detecting NaNQ
#ifdef ISNAN
#ifdef AIX
#ifdef MPL
c endif
#endif
+#define DEBUG
+#ifdef DEBUG
+ call enerprint(energia,fact)
+#endif
+#undef DEBUG
if (calc_grad) then
C
C Sum up the components of the Cartesian gradient.
#ifdef SPLITELE
do i=1,nct
do j=1,3
+ if (shield_mode.eq.0) then
gradc(j,i,icg)=wsc*gvdwc(j,i)+wscp*gvdwc_scp(j,i)+
& welec*fact(1)*gelc(j,i)+wvdwpp*gvdwpp(j,i)+
& wbond*gradb(j,i)+
& wturn6*fact(5)*gcorr6_turn(j,i)+
& wsccor*fact(2)*gsccorc(j,i)
& +wliptran*gliptranc(j,i)
+ & +welec*gshieldc(j,i)
+ & +welec*gshieldc_loc(j,i)
+ & +wcorr*gshieldc_ec(j,i)
+ & +wcorr*gshieldc_loc_ec(j,i)
+ & +wturn3*gshieldc_t3(j,i)
+ & +wturn3*gshieldc_loc_t3(j,i)
+ & +wturn4*gshieldc_t4(j,i)
+ & +wturn4*gshieldc_loc_t4(j,i)
+ & +wel_loc*gshieldc_ll(j,i)
+ & +wel_loc*gshieldc_loc_ll(j,i)
+ & +wtube*gg_tube(j,i)
+
+
gradx(j,i,icg)=wsc*gvdwx(j,i)+wscp*gradx_scp(j,i)+
& wbond*gradbx(j,i)+
& wstrain*ghpbx(j,i)+wcorr*gradxorr(j,i)+
& wsccor*fact(2)*gsccorx(j,i)
& +wliptran*gliptranx(j,i)
+ & +welec*gshieldx(j,i)
+ & +wcorr*gshieldx_ec(j,i)
+ & +wturn3*gshieldx_t3(j,i)
+ & +wturn4*gshieldx_t4(j,i)
+ & +wel_loc*gshieldx_ll(j,i)
+ & +wtube*gg_tube_SC(j,i)
+
+ else
+ gradc(j,i,icg)=fact(1)*wsc*gvdwc(j,i)
+ & +fact(1)*wscp*gvdwc_scp(j,i)+
+ & welec*fact(1)*gelc(j,i)+fact(1)*wvdwpp*gvdwpp(j,i)+
+ & wbond*gradb(j,i)+
+ & wstrain*ghpbc(j,i)+
+ & wcorr*fact(3)*gradcorr(j,i)+
+ & wel_loc*fact(2)*gel_loc(j,i)+
+ & wturn3*fact(2)*gcorr3_turn(j,i)+
+ & wturn4*fact(3)*gcorr4_turn(j,i)+
+ & wcorr5*fact(4)*gradcorr5(j,i)+
+ & wcorr6*fact(5)*gradcorr6(j,i)+
+ & wturn6*fact(5)*gcorr6_turn(j,i)+
+ & wsccor*fact(2)*gsccorc(j,i)
+ & +wliptran*gliptranc(j,i)
+ & +welec*gshieldc(j,i)
+ & +welec*gshieldc_loc(j,i)
+ & +wcorr*gshieldc_ec(j,i)
+ & +wcorr*gshieldc_loc_ec(j,i)
+ & +wturn3*gshieldc_t3(j,i)
+ & +wturn3*gshieldc_loc_t3(j,i)
+ & +wturn4*gshieldc_t4(j,i)
+ & +wturn4*gshieldc_loc_t4(j,i)
+ & +wel_loc*gshieldc_ll(j,i)
+ & +wel_loc*gshieldc_loc_ll(j,i)
+ & +wtube*gg_tube(j,i)
+
+
+ gradx(j,i,icg)=fact(1)*wsc*gvdwx(j,i)
+ & +fact(1)*wscp*gradx_scp(j,i)+
+ & wbond*gradbx(j,i)+
+ & wstrain*ghpbx(j,i)+wcorr*gradxorr(j,i)+
+ & wsccor*fact(2)*gsccorx(j,i)
+ & +wliptran*gliptranx(j,i)
+ & +welec*gshieldx(j,i)
+ & +wcorr*gshieldx_ec(j,i)
+ & +wturn3*gshieldx_t3(j,i)
+ & +wturn4*gshieldx_t4(j,i)
+ & +wel_loc*gshieldx_ll(j,i)
+ & +wtube*gg_tube_SC(j,i)
+
+
+ endif
enddo
#else
do i=1,nct
do j=1,3
+ if (shield_mode.eq.0) then
gradc(j,i,icg)=wsc*gvdwc(j,i)+wscp*gvdwc_scp(j,i)+
& welec*fact(1)*gelc(j,i)+wstrain*ghpbc(j,i)+
& wbond*gradb(j,i)+
& wturn6*fact(5)*gcorr6_turn(j,i)+
& wsccor*fact(2)*gsccorc(j,i)
& +wliptran*gliptranc(j,i)
+ & +welec*gshieldc(j,i)
+ & +welec*gshieldc_loc(j,i)
+ & +wcorr*gshieldc_ec(j,i)
+ & +wcorr*gshieldc_loc_ec(j,i)
+ & +wturn3*gshieldc_t3(j,i)
+ & +wturn3*gshieldc_loc_t3(j,i)
+ & +wturn4*gshieldc_t4(j,i)
+ & +wturn4*gshieldc_loc_t4(j,i)
+ & +wel_loc*gshieldc_ll(j,i)
+ & +wel_loc*gshieldc_loc_ll(j,i)
+ & +wtube*gg_tube(j,i)
+
gradx(j,i,icg)=wsc*gvdwx(j,i)+wscp*gradx_scp(j,i)+
& wbond*gradbx(j,i)+
& wstrain*ghpbx(j,i)+wcorr*gradxorr(j,i)+
& wsccor*fact(1)*gsccorx(j,i)
& +wliptran*gliptranx(j,i)
+ & +welec*gshieldx(j,i)
+ & +wcorr*gshieldx_ec(j,i)
+ & +wturn3*gshieldx_t3(j,i)
+ & +wturn4*gshieldx_t4(j,i)
+ & +wel_loc*gshieldx_ll(j,i)
+ & +wtube*gg_tube_sc(j,i)
+
+
+ else
+ gradc(j,i,icg)=fact(1)*wsc*gvdwc(j,i)+
+ & fact(1)*wscp*gvdwc_scp(j,i)+
+ & welec*fact(1)*gelc(j,i)+wstrain*ghpbc(j,i)+
+ & wbond*gradb(j,i)+
+ & wcorr*fact(3)*gradcorr(j,i)+
+ & wel_loc*fact(2)*gel_loc(j,i)+
+ & wturn3*fact(2)*gcorr3_turn(j,i)+
+ & wturn4*fact(3)*gcorr4_turn(j,i)+
+ & wcorr5*fact(4)*gradcorr5(j,i)+
+ & wcorr6*fact(5)*gradcorr6(j,i)+
+ & wturn6*fact(5)*gcorr6_turn(j,i)+
+ & wsccor*fact(2)*gsccorc(j,i)
+ & +wliptran*gliptranc(j,i)
+ & +welec*gshieldc(j,i)
+ & +welec*gshieldc_loc(j,i)
+ & +wcorr*gshieldc_ec(j,i)
+ & +wcorr*gshieldc_loc_ec(j,i)
+ & +wturn3*gshieldc_t3(j,i)
+ & +wturn3*gshieldc_loc_t3(j,i)
+ & +wturn4*gshieldc_t4(j,i)
+ & +wturn4*gshieldc_loc_t4(j,i)
+ & +wel_loc*gshieldc_ll(j,i)
+ & +wel_loc*gshieldc_loc_ll(j,i)
+ & +wtube*gg_tube(j,i)
+
+ gradx(j,i,icg)=fact(1)*wsc*gvdwx(j,i)+
+ & fact(1)*wscp*gradx_scp(j,i)+
+ & wbond*gradbx(j,i)+
+ & wstrain*ghpbx(j,i)+wcorr*gradxorr(j,i)+
+ & wsccor*fact(1)*gsccorx(j,i)
+ & +wliptran*gliptranx(j,i)
+ & +welec*gshieldx(j,i)
+ & +wcorr*gshieldx_ec(j,i)
+ & +wturn3*gshieldx_t3(j,i)
+ & +wturn4*gshieldx_t4(j,i)
+ & +wel_loc*gshieldx_ll(j,i)
+ & +wtube*gg_tube_sc(j,i)
+
+
+ endif
enddo
#endif
enddo
estr=energia(18)
ethetacnstr=energia(24)
eliptran=energia(22)
+ Etube=energia(25)
#ifdef SPLITELE
write (iout,10) evdw,wsc,evdw2,wscp,ees,welec*fact(1),evdw1,
& wvdwpp,
& eel_loc,wel_loc*fact(2),eello_turn3,wturn3*fact(2),
& eello_turn4,wturn4*fact(3),eello_turn6,wturn6*fact(5),
& esccor,wsccor*fact(1),edihcnstr,ethetacnstr,ebr*nss,
- & eliptran,wliptran,etot
+ & eliptran,wliptran,etube,wtube ,etot
10 format (/'Virtual-chain energies:'//
& 'EVDW= ',1pE16.6,' WEIGHT=',1pD16.6,' (SC-SC)'/
& 'EVDW2= ',1pE16.6,' WEIGHT=',1pD16.6,' (SC-p)'/
& 'ETHETC= ',1pE16.6,' (valence angle constraints)'/
& 'ESS= ',1pE16.6,' (disulfide-bridge intrinsic energy)'/
& 'ELT=',1pE16.6, ' WEIGHT=',1pD16.6,' (Lipid transfer energy)'/
+ & 'ETUBE=',1pE16.6, ' WEIGHT=',1pD16.6,' (Lipid transfer energy)'/
& 'ETOT= ',1pE16.6,' (total)')
#else
write (iout,10) evdw,wsc,evdw2,wscp,ees,welec*fact(1),estr,wbond,
& ecorr6,wcorr6*fact(5),eel_loc,wel_loc*fact(2),
& eello_turn3,wturn3*fact(2),eello_turn4,wturn4*fact(3),
& eello_turn6,wturn6*fact(5),esccor*fact(1),wsccor,
- & edihcnstr,ethetacnstr,ebr*nss,eliptran,wliptran,etot
+ & edihcnstr,ethetacnstr,ebr*nss,eliptran,wliptran,etube,wtube,etot
10 format (/'Virtual-chain energies:'//
& 'EVDW= ',1pE16.6,' WEIGHT=',1pD16.6,' (SC-SC)'/
& 'EVDW2= ',1pE16.6,' WEIGHT=',1pD16.6,' (SC-p)'/
include 'COMMON.SBRIDGE'
logical lprn
common /srutu/icall
- integer icant
+ integer icant,xshift,yshift,zshift
external icant
do i=1,210
do j=1,2
& +aa_aq(itypi,itypj)*(2.0d0-sslipi-sslipj)/2.0d0
bb=bb_lip(itypi,itypj)*(sslipi+sslipj)/2.0d0
& +bb_aq(itypi,itypj)*(2.0d0-sslipi-sslipj)/2.0d0
+C if (aa.ne.aa_aq(itypi,itypj)) then
+
+C write(iout,*) "tu,", i,j,aa_aq(itypi,itypj)-aa,
+C & bb_aq(itypi,itypj)-bb,
+C & sslipi,sslipj
+C endif
+
C write(iout,*),aa,aa_lip(itypi,itypj),aa_aq(itypi,itypj)
C checking the distance
dist_init=(xj-xi)**2+(yj-yi)**2+(zj-zi)**2
c if (lprn) then
sigm=dabs(aa/bb)**(1.0D0/6.0D0)
epsi=bb**2/aa
+C#define DEBUG
#ifdef DEBUG
write (iout,'(2(a3,i3,2x),17(0pf7.3))')
& restyp(itypi),i,restyp(itypj),j,
& evdwij
write (iout,*) "partial sum", evdw, evdw_t
#endif
+C#undef DEBUG
c endif
if (calc_grad) then
C Calculate gradient components.
include 'COMMON.TORSION'
include 'COMMON.VECTORS'
include 'COMMON.FFIELD'
+ include 'COMMON.SHIELD'
dimension ggg(3),gggp(3),gggm(3),erij(3),dcosb(3),dcosg(3),
& erder(3,3),uryg(3,3),urzg(3,3),vryg(3,3),vrzg(3,3)
double precision acipa(2,2),agg(3,4),aggi(3,4),aggi1(3,4),
gcorr_loc(i)=0.0d0
enddo
do i=iatel_s,iatel_e
- if (i.eq.1) then
+C if (i.eq.1) then
if (itype(i).eq.ntyp1.or. itype(i+1).eq.ntyp1
- & .or. itype(i+2).eq.ntyp1) cycle
- else
- if (itype(i).eq.ntyp1 .or. itype(i+1).eq.ntyp1
- & .or. itype(i+2).eq.ntyp1
- & .or. itype(i-1).eq.ntyp1
+C & .or. itype(i+2).eq.ntyp1) cycle
+C else
+C if (itype(i).eq.ntyp1 .or. itype(i+1).eq.ntyp1
+C & .or. itype(i+2).eq.ntyp1
+C & .or. itype(i-1).eq.ntyp1
&) cycle
- endif
+C endif
if (itel(i).eq.0) goto 1215
dxi=dc(1,i)
dyi=dc(2,i)
if (ymedi.lt.0) ymedi=ymedi+boxysize
zmedi=mod(zmedi,boxzsize)
if (zmedi.lt.0) zmedi=zmedi+boxzsize
+ zmedi2=mod(zmedi,boxzsize)
+ if (zmedi2.lt.0) zmedi2=zmedi2+boxzsize
+ if ((zmedi2.gt.bordlipbot)
+ &.and.(zmedi2.lt.bordliptop)) then
+C the energy transfer exist
+ if (zmedi2.lt.buflipbot) then
+C what fraction I am in
+ fracinbuf=1.0d0-
+ & ((zmedi2-bordlipbot)/lipbufthick)
+C lipbufthick is thickenes of lipid buffore
+ sslipi=sscalelip(fracinbuf)
+ ssgradlipi=-sscagradlip(fracinbuf)/lipbufthick
+ elseif (zmedi2.gt.bufliptop) then
+ fracinbuf=1.0d0-((bordliptop-zmedi2)/lipbufthick)
+ sslipi=sscalelip(fracinbuf)
+ ssgradlipi=sscagradlip(fracinbuf)/lipbufthick
+ else
+ sslipi=1.0d0
+ ssgradlipi=0.0d0
+ endif
+ else
+ sslipi=0.0d0
+ ssgradlipi=0.0d0
+ endif
+
num_conti=0
C write (iout,*) 'i',i,' ielstart',ielstart(i),' ielend',ielend(i)
do j=ielstart(i),ielend(i)
- if (j.eq.1) then
- if (itype(j).eq.ntyp1 .or. itype(j+1).eq.ntyp1
- & .or.itype(j+2).eq.ntyp1
- &) cycle
- else
+ if (j.lt.1) cycle
+C if (itype(j).eq.ntyp1 .or. itype(j+1).eq.ntyp1
+C & .or.itype(j+2).eq.ntyp1
+C &) cycle
+C else
if (itype(j).eq.ntyp1 .or. itype(j+1).eq.ntyp1
- & .or.itype(j+2).eq.ntyp1
- & .or.itype(j-1).eq.ntyp1
+C & .or.itype(j+2).eq.ntyp1
+C & .or.itype(j-1).eq.ntyp1
&) cycle
- endif
+C endif
C
C) cycle
if (itel(j).eq.0) goto 1216
if (yj.lt.0) yj=yj+boxysize
zj=mod(zj,boxzsize)
if (zj.lt.0) zj=zj+boxzsize
+ if ((zj.gt.bordlipbot)
+ &.and.(zj.lt.bordliptop)) then
+C the energy transfer exist
+ if (zj.lt.buflipbot) then
+C what fraction I am in
+ fracinbuf=1.0d0-
+ & ((zj-bordlipbot)/lipbufthick)
+C lipbufthick is thickenes of lipid buffore
+ sslipj=sscalelip(fracinbuf)
+ ssgradlipj=-sscagradlip(fracinbuf)/lipbufthick
+ elseif (zj.gt.bufliptop) then
+ fracinbuf=1.0d0-((bordliptop-zj)/lipbufthick)
+ sslipj=sscalelip(fracinbuf)
+ ssgradlipj=sscagradlip(fracinbuf)/lipbufthick
+ else
+ sslipj=1.0d0
+ ssgradlipj=0.0
+ endif
+ else
+ sslipj=0.0d0
+ ssgradlipj=0.0
+ endif
dist_init=(xj-xmedi)**2+(yj-ymedi)**2+(zj-zmedi)**2
xj_safe=xj
yj_safe=yj
c write (iout,*) "i",i,iteli," j",j,itelj," eesij",eesij
C 12/26/95 - for the evaluation of multi-body H-bonding interactions
ees0ij=4.0D0+fac*fac-3.0D0*(cosb*cosb+cosg*cosg)
+ if (shield_mode.gt.0) then
+C#define DEBUG
+#ifdef DEBUG
+ write(iout,*) "ees_compon",i,j,el1,el2,
+ & fac_shield(i),fac_shield(j)
+#endif
+C#undef DEBUG
+C fac_shield(i)=0.4
+C fac_shield(j)=0.6
+ el1=el1*fac_shield(i)**2*fac_shield(j)**2
+ el2=el2*fac_shield(i)**2*fac_shield(j)**2
+ eesij=(el1+el2)
ees=ees+eesij
+ else
+ fac_shield(i)=1.0
+ fac_shield(j)=1.0
+ eesij=(el1+el2)
+ ees=ees+eesij
+ &*((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
+ endif
evdw1=evdw1+evdwij*sss
+ &*((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
c write (iout,'(a6,2i5,0pf7.3,2i5,2e11.3)')
c &'evdw1',i,j,evdwij
c &,iteli,itelj,aaa,evdw1
C
#ifdef SPLITELE
facvdw=-6*rrmij*(ev1+evdwij)*sss
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
facel=-3*rrmij*(el1+eesij)
+ &*((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
fac1=fac
erij(1)=xj*rmij
erij(2)=yj*rmij
ggg(1)=facel*xj
ggg(2)=facel*yj
ggg(3)=facel*zj
+ if ((fac_shield(i).gt.0).and.(fac_shield(j).gt.0).and.
+ & (shield_mode.gt.0)) then
+C print *,i,j
+ do ilist=1,ishield_list(i)
+ iresshield=shield_list(ilist,i)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,i)*eesij/fac_shield(i)
+ & *2.0
+ gshieldx(k,iresshield)=gshieldx(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,i)*eesij/fac_shield(i)*2.0
+ gshieldc(k,iresshield-1)=gshieldc(k,iresshield-1)+rlocshield
+C gshieldc_loc(k,iresshield)=gshieldc_loc(k,iresshield)
+C & +grad_shield_loc(k,ilist,i)*eesij/fac_shield(i)
+C if (iresshield.gt.i) then
+C do ishi=i+1,iresshield-1
+C gshieldc(k,ishi)=gshieldc(k,ishi)+rlocshield
+C & +grad_shield_loc(k,ilist,i)*eesij/fac_shield(i)
+C
+C enddo
+C else
+C do ishi=iresshield,i
+C gshieldc(k,ishi)=gshieldc(k,ishi)-rlocshield
+C & -grad_shield_loc(k,ilist,i)*eesij/fac_shield(i)
+C
+C enddo
+C endif
+ enddo
+ enddo
+ do ilist=1,ishield_list(j)
+ iresshield=shield_list(ilist,j)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,j)*eesij/fac_shield(j)
+ & *2.0
+ gshieldx(k,iresshield)=gshieldx(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,j)*eesij/fac_shield(j)*2.0
+ gshieldc(k,iresshield-1)=gshieldc(k,iresshield-1)+rlocshield
+ enddo
+ enddo
+
+ do k=1,3
+ gshieldc(k,i)=gshieldc(k,i)+
+ & grad_shield(k,i)*eesij/fac_shield(i)*2.0
+ gshieldc(k,j)=gshieldc(k,j)+
+ & grad_shield(k,j)*eesij/fac_shield(j)*2.0
+ gshieldc(k,i-1)=gshieldc(k,i-1)+
+ & grad_shield(k,i)*eesij/fac_shield(i)*2.0
+ gshieldc(k,j-1)=gshieldc(k,j-1)+
+ & grad_shield(k,j)*eesij/fac_shield(j)*2.0
+
+ enddo
+ endif
+
do k=1,3
ghalf=0.5D0*ggg(k)
gelc(k,i)=gelc(k,i)+ghalf
C ggg(3)=facvdw*zj
if (sss.gt.0.0) then
ggg(1)=facvdw*xj+sssgrad*rmij*evdwij*xj
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
ggg(2)=facvdw*yj+sssgrad*rmij*evdwij*yj
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
ggg(3)=facvdw*zj+sssgrad*rmij*evdwij*zj
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
else
ggg(1)=0.0
ggg(2)=0.0
gvdwpp(k,i)=gvdwpp(k,i)+ghalf
gvdwpp(k,j)=gvdwpp(k,j)+ghalf
enddo
+ gvdwpp(3,j)=gvdwpp(3,j)+
+ & sss*ssgradlipj*evdwij/2.0d0*lipscale**2
+ gvdwpp(3,i)=gvdwpp(3,i)+
+ & sss*ssgradlipi*evdwij/2.0d0*lipscale**2
+
*
* Loop over residues i+1 thru j-1.
*
enddo
#else
facvdw=(ev1+evdwij)*sss
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
facel=el1+eesij
fac1=fac
fac=-3*rrmij*(facvdw+facvdw+facel)
cd & (dcosg(k),k=1,3)
do k=1,3
ggg(k)=ecosb*dcosb(k)+ecosg*dcosg(k)
+ & *fac_shield(i)**2*fac_shield(j)**2
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
enddo
do k=1,3
ghalf=0.5D0*ggg(k)
gelc(k,i)=gelc(k,i)+ghalf
& +(ecosa*(dc_norm(k,j)-cosa*dc_norm(k,i))
& + ecosb*(erij(k)-cosb*dc_norm(k,i)))*vbld_inv(i+1)
+ & *fac_shield(i)**2*fac_shield(j)**2
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
+
gelc(k,j)=gelc(k,j)+ghalf
& +(ecosa*(dc_norm(k,i)-cosa*dc_norm(k,j))
& + ecosg*(erij(k)-cosg*dc_norm(k,j)))*vbld_inv(j+1)
+ & *fac_shield(i)**2*fac_shield(j)**2
+ & *((sslipi+sslipj)/2.0d0*lipscale**2+1.0d0)
+
enddo
do k=i+1,j-1
do l=1,3
C Contribution to the local-electrostatic energy coming from the i-j pair
eel_loc_ij=a22*muij(1)+a23*muij(2)+a32*muij(3)
& +a33*muij(4)
-c write (iout,*) 'i',i,' j',j,' eel_loc_ij',eel_loc_ij
-C write (iout,'(a6,2i5,0pf7.3)')
-C & 'eelloc',i,j,eel_loc_ij
+ if (shield_mode.eq.0) then
+ fac_shield(i)=1.0
+ fac_shield(j)=1.0
+C else
+C fac_shield(i)=0.4
+C fac_shield(j)=0.6
+ endif
+ eel_loc_ij=eel_loc_ij
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+C write (iout,'(a3,i4,a3,i4,a8,4f8.3)')
+C & 'i',i,' j',j,' eel_loc_ij',eel_loc_ij,sslipi,
+C & sslipj,lipscale
+C write (iout,'(a6,2i5,0pf7.3,2f7.3)')
+C & 'eelloc',i,j,eel_loc_ij,a22*muij(1),a23*muij(2)
C write(iout,*) 'muije=',i,j,muij(1),muij(2),muij(3),muij(4)
c write (iout,*) a22,muij(1),a23,muij(2),a32,muij(3)
+C eel_loc=eel_loc+eel_loc_ij
+ if ((fac_shield(i).gt.0).and.(fac_shield(j).gt.0).and.
+ & (shield_mode.gt.0)) then
+C print *,i,j
+
+ do ilist=1,ishield_list(i)
+ iresshield=shield_list(ilist,i)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,i)*eel_loc_ij
+ & /fac_shield(i)
+C & *2.0
+ gshieldx_ll(k,iresshield)=gshieldx_ll(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,i)*eel_loc_ij/fac_shield(i)
+ gshieldc_ll(k,iresshield-1)=gshieldc_ll(k,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(j)
+ iresshield=shield_list(ilist,j)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,j)*eel_loc_ij
+ & /fac_shield(j)
+C & *2.0
+ gshieldx_ll(k,iresshield)=gshieldx_ll(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,j)*eel_loc_ij/fac_shield(j)
+ gshieldc_ll(k,iresshield-1)=gshieldc_ll(k,iresshield-1)
+ & +rlocshield
+
+ enddo
+ enddo
+ do k=1,3
+ gshieldc_ll(k,i)=gshieldc_ll(k,i)+
+ & grad_shield(k,i)*eel_loc_ij/fac_shield(i)
+ gshieldc_ll(k,j)=gshieldc_ll(k,j)+
+ & grad_shield(k,j)*eel_loc_ij/fac_shield(j)
+ gshieldc_ll(k,i-1)=gshieldc_ll(k,i-1)+
+ & grad_shield(k,i)*eel_loc_ij/fac_shield(i)
+ gshieldc_ll(k,j-1)=gshieldc_ll(k,j-1)+
+ & grad_shield(k,j)*eel_loc_ij/fac_shield(j)
+ enddo
+ endif
eel_loc=eel_loc+eel_loc_ij
+
C Partial derivatives in virtual-bond dihedral angles gamma
if (calc_grad) then
if (i.gt.1)
& gel_loc_loc(i-1)=gel_loc_loc(i-1)+
- & a22*muder(1,i)*mu(1,j)+a23*muder(1,i)*mu(2,j)
- & +a32*muder(2,i)*mu(1,j)+a33*muder(2,i)*mu(2,j)
+ & (a22*muder(1,i)*mu(1,j)+a23*muder(1,i)*mu(2,j)
+ & +a32*muder(2,i)*mu(1,j)+a33*muder(2,i)*mu(2,j))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
gel_loc_loc(j-1)=gel_loc_loc(j-1)+
- & a22*mu(1,i)*muder(1,j)+a23*mu(1,i)*muder(2,j)
- & +a32*mu(2,i)*muder(1,j)+a33*mu(2,i)*muder(2,j)
+ & (a22*mu(1,i)*muder(1,j)+a23*mu(1,i)*muder(2,j)
+ & +a32*mu(2,i)*muder(1,j)+a33*mu(2,i)*muder(2,j))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
cd call checkint3(i,j,mu1,mu2,a22,a23,a32,a33,acipa,eel_loc_ij)
cd write(iout,*) 'agg ',agg
cd write(iout,*) 'aggi ',aggi
C Derivatives of eello in DC(i+1) thru DC(j-1) or DC(nres-2)
do l=1,3
- ggg(l)=agg(l,1)*muij(1)+
- & agg(l,2)*muij(2)+agg(l,3)*muij(3)+agg(l,4)*muij(4)
+ ggg(l)=(agg(l,1)*muij(1)+
+ & agg(l,2)*muij(2)+agg(l,3)*muij(3)+agg(l,4)*muij(4))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
enddo
do k=i+2,j2
do l=1,3
enddo
C Remaining derivatives of eello
do l=1,3
- gel_loc(l,i)=gel_loc(l,i)+aggi(l,1)*muij(1)+
- & aggi(l,2)*muij(2)+aggi(l,3)*muij(3)+aggi(l,4)*muij(4)
- gel_loc(l,i+1)=gel_loc(l,i+1)+aggi1(l,1)*muij(1)+
- & aggi1(l,2)*muij(2)+aggi1(l,3)*muij(3)+aggi1(l,4)*muij(4)
- gel_loc(l,j)=gel_loc(l,j)+aggj(l,1)*muij(1)+
- & aggj(l,2)*muij(2)+aggj(l,3)*muij(3)+aggj(l,4)*muij(4)
- gel_loc(l,j1)=gel_loc(l,j1)+aggj1(l,1)*muij(1)+
- & aggj1(l,2)*muij(2)+aggj1(l,3)*muij(3)+aggj1(l,4)*muij(4)
+ gel_loc(l,i)=gel_loc(l,i)+(aggi(l,1)*muij(1)+
+ & aggi(l,2)*muij(2)+aggi(l,3)*muij(3)+aggi(l,4)*muij(4))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
+ gel_loc(l,i+1)=gel_loc(l,i+1)+(aggi1(l,1)*muij(1)+
+ & aggi1(l,2)*muij(2)+aggi1(l,3)*muij(3)+aggi1(l,4)*muij(4))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
+ gel_loc(l,j)=gel_loc(l,j)+(aggj(l,1)*muij(1)+
+ & aggj(l,2)*muij(2)+aggj(l,3)*muij(3)+aggj(l,4)*muij(4))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
+ gel_loc(l,j1)=gel_loc(l,j1)+(aggj1(l,1)*muij(1)+
+ & aggj1(l,2)*muij(2)+aggj1(l,3)*muij(3)+aggj1(l,4)*muij(4))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
enddo
endif
ENDIF
ees0pij=dsqrt(4.0D0+cosa4+wij*wij-3.0D0*cosbg1*cosbg1)
ees0mij=dsqrt(4.0D0-cosa4+wij*wij-3.0D0*cosbg2*cosbg2)
c ees0mij=0.0D0
+ if (shield_mode.eq.0) then
+ fac_shield(i)=1.0d0
+ fac_shield(j)=1.0d0
+ else
+ ees0plist(num_conti,i)=j
+C fac_shield(i)=0.4d0
+C fac_shield(j)=0.6d0
+ endif
ees0p(num_conti,i)=0.5D0*fac3*(ees0pij+ees0mij)
+ & *fac_shield(i)*fac_shield(j)
+
ees0m(num_conti,i)=0.5D0*fac3*(ees0pij-ees0mij)
+ & *fac_shield(i)*fac_shield(j)
+
C Diagnostics. Comment out or remove after debugging!
c ees0p(num_conti,i)=0.5D0*fac3*ees0pij
c ees0m(num_conti,i)=0.5D0*fac3*ees0mij
gacontp_hb1(k,num_conti,i)=ghalfp
& +(ecosap*(dc_norm(k,j)-cosa*dc_norm(k,i))
& + ecosbp*(erij(k)-cosb*dc_norm(k,i)))*vbld_inv(i+1)
+ & *fac_shield(i)*fac_shield(j)
+
gacontp_hb2(k,num_conti,i)=ghalfp
& +(ecosap*(dc_norm(k,i)-cosa*dc_norm(k,j))
& + ecosgp*(erij(k)-cosg*dc_norm(k,j)))*vbld_inv(j+1)
+ & *fac_shield(i)*fac_shield(j)
+
gacontp_hb3(k,num_conti,i)=gggp(k)
+ & *fac_shield(i)*fac_shield(j)
+
gacontm_hb1(k,num_conti,i)=ghalfm
& +(ecosam*(dc_norm(k,j)-cosa*dc_norm(k,i))
& + ecosbm*(erij(k)-cosb*dc_norm(k,i)))*vbld_inv(i+1)
+ & *fac_shield(i)*fac_shield(j)
+
gacontm_hb2(k,num_conti,i)=ghalfm
& +(ecosam*(dc_norm(k,i)-cosa*dc_norm(k,j))
& + ecosgm*(erij(k)-cosg*dc_norm(k,j)))*vbld_inv(j+1)
+ & *fac_shield(i)*fac_shield(j)
+
gacontm_hb3(k,num_conti,i)=gggm(k)
+ & *fac_shield(i)*fac_shield(j)
+
enddo
endif
C Diagnostics. Comment out or remove after debugging!
include 'COMMON.TORSION'
include 'COMMON.VECTORS'
include 'COMMON.FFIELD'
+ include 'COMMON.SHIELD'
+ include 'COMMON.CONTROL'
dimension ggg(3)
double precision auxmat(2,2),auxmat1(2,2),auxmat2(2,2),pizda(2,2),
& e1t(2,2),e2t(2,2),e3t(2,2),e1tder(2,2),e2tder(2,2),e3tder(2,2),
double precision agg(3,4),aggi(3,4),aggi1(3,4),
& aggj(3,4),aggj1(3,4),a_temp(2,2)
common /locel/ a_temp,agg,aggi,aggi1,aggj,aggj1,j1,j2
+ zj=(c(3,j)+c(3,j+1))/2.0d0
+C xj=mod(xj,boxxsize)
+C if (xj.lt.0) xj=xj+boxxsize
+C yj=mod(yj,boxysize)
+C if (yj.lt.0) yj=yj+boxysize
+ zj=mod(zj,boxzsize)
+ if (zj.lt.0) zj=zj+boxzsize
+C if ((zj.lt.0).or.(xj.lt.0).or.(yj.lt.0)) write (*,*) "CHUJ"
+ if ((zj.gt.bordlipbot)
+ &.and.(zj.lt.bordliptop)) then
+C the energy transfer exist
+ if (zj.lt.buflipbot) then
+C what fraction I am in
+ fracinbuf=1.0d0-
+ & ((zj-bordlipbot)/lipbufthick)
+C lipbufthick is thickenes of lipid buffore
+ sslipj=sscalelip(fracinbuf)
+ ssgradlipj=-sscagradlip(fracinbuf)/lipbufthick
+ elseif (zj.gt.bufliptop) then
+ fracinbuf=1.0d0-((bordliptop-zj)/lipbufthick)
+ sslipj=sscalelip(fracinbuf)
+ ssgradlipj=sscagradlip(fracinbuf)/lipbufthick
+ else
+ sslipj=1.0d0
+ ssgradlipj=0.0
+ endif
+ else
+ sslipj=0.0d0
+ ssgradlipj=0.0
+ endif
+
if (j.eq.i+2) then
+ if (itype(i).eq.ntyp1 .or. itype(i+1).eq.ntyp1
+C changes suggested by Ana to avoid out of bounds
+C & .or.((i+5).gt.nres)
+C & .or.((i-1).le.0)
+C end of changes suggested by Ana
+ & .or. itype(i+2).eq.ntyp1
+ & .or. itype(i+3).eq.ntyp1
+C & .or. itype(i+5).eq.ntyp1
+C & .or. itype(i).eq.ntyp1
+C & .or. itype(i-1).eq.ntyp1
+ & ) goto 179
+
CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
C
C Third-order contributions
call matmat2(EUg(1,1,i+1),EUg(1,1,i+2),auxmat(1,1))
call transpose2(auxmat(1,1),auxmat1(1,1))
call matmat2(a_temp(1,1),auxmat1(1,1),pizda(1,1))
+ if (shield_mode.eq.0) then
+ fac_shield(i)=1.0
+ fac_shield(j)=1.0
+C else
+C fac_shield(i)=0.4
+C fac_shield(j)=0.6
+ endif
+
eello_turn3=eello_turn3+0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
+ eello_t3=0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+ write (iout,'(a3,i4,a3,i4,a8,4f8.3)')
+ & 'i',i,' j',j,' eturn3',eello_t3,sslipi,
+ & sslipj,lipscale
cd write (2,*) 'i,',i,' j',j,'eello_turn3',
cd & 0.5d0*(pizda(1,1)+pizda(2,2)),
cd & ' eello_turn3_num',4*eello_turn3_num
if (calc_grad) then
+C Derivatives in shield mode
+ if ((fac_shield(i).gt.0).and.(fac_shield(j).gt.0).and.
+ & (shield_mode.gt.0)) then
+C print *,i,j
+
+ do ilist=1,ishield_list(i)
+ iresshield=shield_list(ilist,i)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,i)*eello_t3/fac_shield(i)
+C & *2.0
+ gshieldx_t3(k,iresshield)=gshieldx_t3(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,i)*eello_t3/fac_shield(i)
+ gshieldc_t3(k,iresshield-1)=gshieldc_t3(k,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(j)
+ iresshield=shield_list(ilist,j)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,j)*eello_t3/fac_shield(j)
+C & *2.0
+ gshieldx_t3(k,iresshield)=gshieldx_t3(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,j)*eello_t3/fac_shield(j)
+ gshieldc_t3(k,iresshield-1)=gshieldc_t3(k,iresshield-1)
+ & +rlocshield
+
+ enddo
+ enddo
+
+ do k=1,3
+ gshieldc_t3(k,i)=gshieldc_t3(k,i)+
+ & grad_shield(k,i)*eello_t3/fac_shield(i)
+ gshieldc_t3(k,j)=gshieldc_t3(k,j)+
+ & grad_shield(k,j)*eello_t3/fac_shield(j)
+ gshieldc_t3(k,i-1)=gshieldc_t3(k,i-1)+
+ & grad_shield(k,i)*eello_t3/fac_shield(i)
+ gshieldc_t3(k,j-1)=gshieldc_t3(k,j-1)+
+ & grad_shield(k,j)*eello_t3/fac_shield(j)
+ enddo
+ endif
+
C Derivatives in gamma(i)
call matmat2(EUgder(1,1,i+1),EUg(1,1,i+2),auxmat2(1,1))
call transpose2(auxmat2(1,1),pizda(1,1))
call matmat2(a_temp(1,1),pizda(1,1),pizda(1,1))
gel_loc_turn3(i)=gel_loc_turn3(i)+0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
C Derivatives in gamma(i+1)
call matmat2(EUg(1,1,i+1),EUgder(1,1,i+2),auxmat2(1,1))
call transpose2(auxmat2(1,1),pizda(1,1))
call matmat2(a_temp(1,1),pizda(1,1),pizda(1,1))
gel_loc_turn3(i+1)=gel_loc_turn3(i+1)
& +0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
C Cartesian derivatives
do l=1,3
a_temp(1,1)=aggi(l,1)
call matmat2(a_temp(1,1),auxmat1(1,1),pizda(1,1))
gcorr3_turn(l,i)=gcorr3_turn(l,i)
& +0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggi1(l,1)
a_temp(1,2)=aggi1(l,2)
a_temp(2,1)=aggi1(l,3)
call matmat2(a_temp(1,1),auxmat1(1,1),pizda(1,1))
gcorr3_turn(l,i+1)=gcorr3_turn(l,i+1)
& +0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggj(l,1)
a_temp(1,2)=aggj(l,2)
a_temp(2,1)=aggj(l,3)
call matmat2(a_temp(1,1),auxmat1(1,1),pizda(1,1))
gcorr3_turn(l,j)=gcorr3_turn(l,j)
& +0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggj1(l,1)
a_temp(1,2)=aggj1(l,2)
a_temp(2,1)=aggj1(l,3)
call matmat2(a_temp(1,1),auxmat1(1,1),pizda(1,1))
gcorr3_turn(l,j1)=gcorr3_turn(l,j1)
& +0.5d0*(pizda(1,1)+pizda(2,2))
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
enddo
endif
+ 179 continue
else if (j.eq.i+3 .and. itype(i+2).ne.ntyp1) then
if (itype(i).eq.ntyp1 .or. itype(i+1).eq.ntyp1
C changes suggested by Ana to avoid out of bounds
- & .or.((i+5).gt.nres)
- & .or.((i-1).le.0)
+C & .or.((i+5).gt.nres)
+C & .or.((i-1).le.0)
C end of changes suggested by Ana
& .or. itype(i+3).eq.ntyp1
& .or. itype(i+4).eq.ntyp1
- & .or. itype(i+5).eq.ntyp1
+C & .or. itype(i+5).eq.ntyp1
& .or. itype(i).eq.ntyp1
- & .or. itype(i-1).eq.ntyp1) goto 178
+C & .or. itype(i-1).eq.ntyp1
+ & ) goto 178
CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
C
C Fourth-order contributions
call matmat2(ae3(1,1),e2t(1,1),ae3e2(1,1))
call matmat2(ae3e2(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
+ if (shield_mode.eq.0) then
+ fac_shield(i)=1.0
+ fac_shield(j)=1.0
+C else
+C fac_shield(i)=0.4
+C fac_shield(j)=0.6
+ endif
+
eello_turn4=eello_turn4-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
+ eello_t4=-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+
cd write (2,*) 'i,',i,' j',j,'eello_turn4',-(s1+s2+s3),
cd & ' eello_turn4_num',8*eello_turn4_num
C Derivatives in gamma(i)
if (calc_grad) then
+ if ((fac_shield(i).gt.0).and.(fac_shield(j).gt.0).and.
+ & (shield_mode.gt.0)) then
+C print *,i,j
+
+ do ilist=1,ishield_list(i)
+ iresshield=shield_list(ilist,i)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,i)*eello_t4/fac_shield(i)
+C & *2.0
+ gshieldx_t4(k,iresshield)=gshieldx_t4(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,i)*eello_t4/fac_shield(i)
+ gshieldc_t4(k,iresshield-1)=gshieldc_t4(k,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(j)
+ iresshield=shield_list(ilist,j)
+ do k=1,3
+ rlocshield=grad_shield_side(k,ilist,j)*eello_t4/fac_shield(j)
+C & *2.0
+ gshieldx_t4(k,iresshield)=gshieldx_t4(k,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(k,ilist,j)*eello_t4/fac_shield(j)
+ gshieldc_t4(k,iresshield-1)=gshieldc_t4(k,iresshield-1)
+ & +rlocshield
+
+ enddo
+ enddo
+
+ do k=1,3
+ gshieldc_t4(k,i)=gshieldc_t4(k,i)+
+ & grad_shield(k,i)*eello_t4/fac_shield(i)
+ gshieldc_t4(k,j)=gshieldc_t4(k,j)+
+ & grad_shield(k,j)*eello_t4/fac_shield(j)
+ gshieldc_t4(k,i-1)=gshieldc_t4(k,i-1)+
+ & grad_shield(k,i)*eello_t4/fac_shield(i)
+ gshieldc_t4(k,j-1)=gshieldc_t4(k,j-1)+
+ & grad_shield(k,j)*eello_t4/fac_shield(j)
+ enddo
+ endif
call transpose2(EUgder(1,1,i+1),e1tder(1,1))
call matmat2(e1tder(1,1),a_temp(1,1),auxmat(1,1))
call matvec2(auxmat(1,1),Ub2(1,i+3),auxvec(1))
call matmat2(ae3e2(1,1),e1tder(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gel_loc_turn4(i)=gel_loc_turn4(i)-(s1+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
C Derivatives in gamma(i+1)
call transpose2(EUgder(1,1,i+2),e2tder(1,1))
call matvec2(ae3(1,1),Ub2der(1,i+2),auxvec(1))
call matmat2(auxmat(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gel_loc_turn4(i+1)=gel_loc_turn4(i+1)-(s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
C Derivatives in gamma(i+2)
call transpose2(EUgder(1,1,i+3),e3tder(1,1))
call matvec2(e1a(1,1),Ub2der(1,i+3),auxvec(1))
call matmat2(auxmat(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gel_loc_turn4(i+2)=gel_loc_turn4(i+2)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
C Cartesian derivatives
+
C Derivatives of this turn contributions in DC(i+2)
if (j.lt.nres-1) then
do l=1,3
s3=0.5d0*(pizda(1,1)+pizda(2,2))
ggg(l)=-(s1+s2+s3)
gcorr4_turn(l,i+2)=gcorr4_turn(l,i+2)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
enddo
endif
C Remaining derivatives of this turn contribution
call matmat2(ae3e2(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gcorr4_turn(l,i)=gcorr4_turn(l,i)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggi1(l,1)
a_temp(1,2)=aggi1(l,2)
a_temp(2,1)=aggi1(l,3)
call matmat2(ae3e2(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gcorr4_turn(l,i+1)=gcorr4_turn(l,i+1)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggj(l,1)
a_temp(1,2)=aggj(l,2)
a_temp(2,1)=aggj(l,3)
call matmat2(ae3e2(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gcorr4_turn(l,j)=gcorr4_turn(l,j)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
a_temp(1,1)=aggj1(l,1)
a_temp(1,2)=aggj1(l,2)
a_temp(2,1)=aggj1(l,3)
call matmat2(ae3e2(1,1),e1t(1,1),pizda(1,1))
s3=0.5d0*(pizda(1,1)+pizda(2,2))
gcorr4_turn(l,j1)=gcorr4_turn(l,j1)-(s1+s2+s3)
+ & *fac_shield(i)*fac_shield(j)
+ &*((sslipi+sslipj)/2.0d0*lipscale+1.0d0)
+
enddo
+ gshieldc_t4(3,i)=gshieldc_t4(3,i)+
+ & ssgradlipi*eello_t4/4.0d0*lipscale
+ gshieldc_t4(3,j)=gshieldc_t4(3,j)+
+ & ssgradlipj*eello_t4/4.0d0*lipscale
+ gshieldc_t4(3,i-1)=gshieldc_t4(3,i-1)+
+ & ssgradlipi*eello_t4/4.0d0*lipscale
+ gshieldc_t4(3,j-1)=gshieldc_t4(3,j-1)+
+ & ssgradlipj*eello_t4/4.0d0*lipscale
endif
178 continue
endif
C else
if (itype(i-1).eq.ntyp1 .or. itype(i).eq.ntyp1) then
diff = vbld(i)-vbldpDUM
+C write(iout,*) i,diff
else
diff = vbld(i)-vbldp0
c write (iout,*) i,vbld(i),vbldp0,diff,AKP*diff*diff
C Set lprn=.true. for debugging
lprn=.false.
eturn6=0.0d0
+ ecorr6=0.0d0
#ifdef MPL
n_corr=0
n_corr1=0
cd write (iout,*) '******eturn6: i,j,i+1,j1',i,j,i+1,j1
eturn6=eturn6+eello_turn6(i,jj,kk)
cd write (2,*) 'multibody_eello:eturn6',eturn6
+ else if ((wturn6.eq.0.0d0).and.(wcorr6.eq.0.0d0)) then
+ eturn6=0.0d0
+ ecorr6=0.0d0
endif
+
ENDIF
1111 continue
else if (j1.eq.j) then
enddo ! kk
enddo ! jj
enddo ! i
+ write (iout,*) "eturn6",eturn6,ecorr6
return
end
c------------------------------------------------------------------------------
include 'COMMON.DERIV'
include 'COMMON.INTERACT'
include 'COMMON.CONTACTS'
+ include 'COMMON.CONTROL'
+ include 'COMMON.SHIELD'
double precision gx(3),gx1(3)
logical lprn
lprn=.false.
c & i,j,' fcont:',eij,' eij',' eesij',ees0pij,ees0mij,' and ',k,l
c & ,' fcont ',ekl,' eeskl',ees0pkl,ees0mkl,' ees=',ees
C Calculate the multi-body contribution to energy.
- ecorr=ecorr+ekont*ees
+C ecorr=ecorr+ekont*ees
if (calc_grad) then
C Calculate multi-body contributions to the gradient.
do ll=1,3
& ekont*(coeffp*ees0pij*gacontp_hb3(ll,kk,k)+
& coeffm*ees0mij*gacontm_hb3(ll,kk,k))
enddo
- enddo
+ enddo
+ if (shield_mode.gt.0) then
+ j=ees0plist(jj,i)
+ l=ees0plist(kk,k)
+C print *,i,j,fac_shield(i),fac_shield(j),
+C &fac_shield(k),fac_shield(l)
+ if ((fac_shield(i).gt.0).and.(fac_shield(j).gt.0).and.
+ & (fac_shield(k).gt.0).and.(fac_shield(l).gt.0)) then
+ do ilist=1,ishield_list(i)
+ iresshield=shield_list(ilist,i)
+ do m=1,3
+ rlocshield=grad_shield_side(m,ilist,i)*ehbcorr/fac_shield(i)
+C & *2.0
+ gshieldx_ec(m,iresshield)=gshieldx_ec(m,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(m,ilist,i)*ehbcorr/fac_shield(i)
+ gshieldc_ec(m,iresshield-1)=gshieldc_ec(m,iresshield-1)
+ &+rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(j)
+ iresshield=shield_list(ilist,j)
+ do m=1,3
+ rlocshield=grad_shield_side(m,ilist,j)*ehbcorr/fac_shield(j)
+C & *2.0
+ gshieldx_ec(m,iresshield)=gshieldx_ec(m,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(m,ilist,j)*ehbcorr/fac_shield(j)
+ gshieldc_ec(m,iresshield-1)=gshieldc_ec(m,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(k)
+ iresshield=shield_list(ilist,k)
+ do m=1,3
+ rlocshield=grad_shield_side(m,ilist,k)*ehbcorr/fac_shield(k)
+C & *2.0
+ gshieldx_ec(m,iresshield)=gshieldx_ec(m,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(m,ilist,k)*ehbcorr/fac_shield(k)
+ gshieldc_ec(m,iresshield-1)=gshieldc_ec(m,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+ do ilist=1,ishield_list(l)
+ iresshield=shield_list(ilist,l)
+ do m=1,3
+ rlocshield=grad_shield_side(m,ilist,l)*ehbcorr/fac_shield(l)
+C & *2.0
+ gshieldx_ec(m,iresshield)=gshieldx_ec(m,iresshield)+
+ & rlocshield
+ & +grad_shield_loc(m,ilist,l)*ehbcorr/fac_shield(l)
+ gshieldc_ec(m,iresshield-1)=gshieldc_ec(m,iresshield-1)
+ & +rlocshield
+ enddo
+ enddo
+C print *,gshieldx(m,iresshield)
+ do m=1,3
+ gshieldc_ec(m,i)=gshieldc_ec(m,i)+
+ & grad_shield(m,i)*ehbcorr/fac_shield(i)
+ gshieldc_ec(m,j)=gshieldc_ec(m,j)+
+ & grad_shield(m,j)*ehbcorr/fac_shield(j)
+ gshieldc_ec(m,i-1)=gshieldc_ec(m,i-1)+
+ & grad_shield(m,i)*ehbcorr/fac_shield(i)
+ gshieldc_ec(m,j-1)=gshieldc_ec(m,j-1)+
+ & grad_shield(m,j)*ehbcorr/fac_shield(j)
+
+ gshieldc_ec(m,k)=gshieldc_ec(m,k)+
+ & grad_shield(m,k)*ehbcorr/fac_shield(k)
+ gshieldc_ec(m,l)=gshieldc_ec(m,l)+
+ & grad_shield(m,l)*ehbcorr/fac_shield(l)
+ gshieldc_ec(m,k-1)=gshieldc_ec(m,k-1)+
+ & grad_shield(m,k)*ehbcorr/fac_shield(k)
+ gshieldc_ec(m,l-1)=gshieldc_ec(m,l-1)+
+ & grad_shield(m,l)*ehbcorr/fac_shield(l)
+
+ enddo
+ endif
+ endif
endif
ehbcorr=ekont*ees
return
end
C-----------------------------------------------------------------------
+ subroutine set_shield_fac
+ implicit real*8 (a-h,o-z)
+ include 'DIMENSIONS'
+ include 'COMMON.CHAIN'
+ include 'COMMON.DERIV'
+ include 'COMMON.IOUNITS'
+ include 'COMMON.SHIELD'
+ include 'COMMON.INTERACT'
+C this is the squar root 77 devided by 81 the epislion in lipid (in protein)
+ double precision div77_81/0.974996043d0/,
+ &div4_81/0.2222222222d0/,sh_frac_dist_grad(3)
+
+C the vector between center of side_chain and peptide group
+ double precision pep_side(3),long,side_calf(3),
+ &pept_group(3),costhet_grad(3),cosphi_grad_long(3),
+ &cosphi_grad_loc(3),pep_side_norm(3),side_calf_norm(3)
+C the line belowe needs to be changed for FGPROC>1
+ do i=1,nres-1
+ if ((itype(i).eq.ntyp1).and.itype(i+1).eq.ntyp1) cycle
+ ishield_list(i)=0
+Cif there two consequtive dummy atoms there is no peptide group between them
+C the line below has to be changed for FGPROC>1
+ VolumeTotal=0.0
+ do k=1,nres
+ if ((itype(k).eq.ntyp1).or.(itype(k).eq.10)) cycle
+ dist_pep_side=0.0
+ dist_side_calf=0.0
+ do j=1,3
+C first lets set vector conecting the ithe side-chain with kth side-chain
+ pep_side(j)=c(j,k+nres)-(c(j,i)+c(j,i+1))/2.0d0
+C pep_side(j)=2.0d0
+C and vector conecting the side-chain with its proper calfa
+ side_calf(j)=c(j,k+nres)-c(j,k)
+C side_calf(j)=2.0d0
+ pept_group(j)=c(j,i)-c(j,i+1)
+C lets have their lenght
+ dist_pep_side=pep_side(j)**2+dist_pep_side
+ dist_side_calf=dist_side_calf+side_calf(j)**2
+ dist_pept_group=dist_pept_group+pept_group(j)**2
+ enddo
+ dist_pep_side=dsqrt(dist_pep_side)
+ dist_pept_group=dsqrt(dist_pept_group)
+ dist_side_calf=dsqrt(dist_side_calf)
+ do j=1,3
+ pep_side_norm(j)=pep_side(j)/dist_pep_side
+ side_calf_norm(j)=dist_side_calf
+ enddo
+C now sscale fraction
+ sh_frac_dist=-(dist_pep_side-rpp(1,1)-buff_shield)/buff_shield
+C print *,buff_shield,"buff"
+C now sscale
+ if (sh_frac_dist.le.0.0) cycle
+C If we reach here it means that this side chain reaches the shielding sphere
+C Lets add him to the list for gradient
+ ishield_list(i)=ishield_list(i)+1
+C ishield_list is a list of non 0 side-chain that contribute to factor gradient
+C this list is essential otherwise problem would be O3
+ shield_list(ishield_list(i),i)=k
+C Lets have the sscale value
+ if (sh_frac_dist.gt.1.0) then
+ scale_fac_dist=1.0d0
+ do j=1,3
+ sh_frac_dist_grad(j)=0.0d0
+ enddo
+ else
+ scale_fac_dist=-sh_frac_dist*sh_frac_dist
+ & *(2.0*sh_frac_dist-3.0d0)
+ fac_help_scale=6.0*(sh_frac_dist-sh_frac_dist**2)
+ & /dist_pep_side/buff_shield*0.5
+C remember for the final gradient multiply sh_frac_dist_grad(j)
+C for side_chain by factor -2 !
+ do j=1,3
+ sh_frac_dist_grad(j)=fac_help_scale*pep_side(j)
+C print *,"jestem",scale_fac_dist,fac_help_scale,
+C & sh_frac_dist_grad(j)
+ enddo
+ endif
+C if ((i.eq.3).and.(k.eq.2)) then
+C print *,i,sh_frac_dist,dist_pep,fac_help_scale,scale_fac_dist
+C & ,"TU"
+C endif
+
+C this is what is now we have the distance scaling now volume...
+ short=short_r_sidechain(itype(k))
+ long=long_r_sidechain(itype(k))
+ costhet=1.0d0/dsqrt(1.0+short**2/dist_pep_side**2)
+C now costhet_grad
+C costhet=0.0d0
+ costhet_fac=costhet**3*short**2*(-0.5)/dist_pep_side**4
+C costhet_fac=0.0d0
+ do j=1,3
+ costhet_grad(j)=costhet_fac*pep_side(j)
+ enddo
+C remember for the final gradient multiply costhet_grad(j)
+C for side_chain by factor -2 !
+C fac alfa is angle between CB_k,CA_k, CA_i,CA_i+1
+C pep_side0pept_group is vector multiplication
+ pep_side0pept_group=0.0
+ do j=1,3
+ pep_side0pept_group=pep_side0pept_group+pep_side(j)*side_calf(j)
+ enddo
+ cosalfa=(pep_side0pept_group/
+ & (dist_pep_side*dist_side_calf))
+ fac_alfa_sin=1.0-cosalfa**2
+ fac_alfa_sin=dsqrt(fac_alfa_sin)
+ rkprim=fac_alfa_sin*(long-short)+short
+C now costhet_grad
+ cosphi=1.0d0/dsqrt(1.0+rkprim**2/dist_pep_side**2)
+ cosphi_fac=cosphi**3*rkprim**2*(-0.5)/dist_pep_side**4
+
+ do j=1,3
+ cosphi_grad_long(j)=cosphi_fac*pep_side(j)
+ &+cosphi**3*0.5/dist_pep_side**2*(-rkprim)
+ &*(long-short)/fac_alfa_sin*cosalfa/
+ &((dist_pep_side*dist_side_calf))*
+ &((side_calf(j))-cosalfa*
+ &((pep_side(j)/dist_pep_side)*dist_side_calf))
+
+ cosphi_grad_loc(j)=cosphi**3*0.5/dist_pep_side**2*(-rkprim)
+ &*(long-short)/fac_alfa_sin*cosalfa
+ &/((dist_pep_side*dist_side_calf))*
+ &(pep_side(j)-
+ &cosalfa*side_calf(j)/dist_side_calf*dist_pep_side)
+ enddo
+
+ VofOverlap=VSolvSphere/2.0d0*(1.0-costhet)*(1.0-cosphi)
+ & /VSolvSphere_div
+ & *wshield
+C now the gradient...
+C grad_shield is gradient of Calfa for peptide groups
+C write(iout,*) "shield_compon",i,k,VSolvSphere,scale_fac_dist,
+C & costhet,cosphi
+C write(iout,*) "cosphi_compon",i,k,pep_side0pept_group,
+C & dist_pep_side,dist_side_calf,c(1,k+nres),c(1,k),itype(k)
+ do j=1,3
+ grad_shield(j,i)=grad_shield(j,i)
+C gradient po skalowaniu
+ & +(sh_frac_dist_grad(j)
+C gradient po costhet
+ &-scale_fac_dist*costhet_grad(j)/(1.0-costhet)
+ &-scale_fac_dist*(cosphi_grad_long(j))
+ &/(1.0-cosphi) )*div77_81
+ &*VofOverlap
+C grad_shield_side is Cbeta sidechain gradient
+ grad_shield_side(j,ishield_list(i),i)=
+ & (sh_frac_dist_grad(j)*-2.0d0
+ & +scale_fac_dist*costhet_grad(j)*2.0d0/(1.0-costhet)
+ & +scale_fac_dist*(cosphi_grad_long(j))
+ & *2.0d0/(1.0-cosphi))
+ & *div77_81*VofOverlap
+
+ grad_shield_loc(j,ishield_list(i),i)=
+ & scale_fac_dist*cosphi_grad_loc(j)
+ & *2.0d0/(1.0-cosphi)
+ & *div77_81*VofOverlap
+ enddo
+ VolumeTotal=VolumeTotal+VofOverlap*scale_fac_dist
+ enddo
+ fac_shield(i)=VolumeTotal*div77_81+div4_81
+C write(2,*) "TOTAL VOLUME",i,VolumeTotal,fac_shield(i)
+ enddo
+ return
+ end
+C--------------------------------------------------------------------------
+C first for shielding is setting of function of side-chains
+ subroutine set_shield_fac2
+ implicit real*8 (a-h,o-z)
+ include 'DIMENSIONS'
+ include 'COMMON.CHAIN'
+ include 'COMMON.DERIV'
+ include 'COMMON.IOUNITS'
+ include 'COMMON.SHIELD'
+ include 'COMMON.INTERACT'
+C this is the squar root 77 devided by 81 the epislion in lipid (in protein)
+ double precision div77_81/0.974996043d0/,
+ &div4_81/0.2222222222d0/,sh_frac_dist_grad(3)
+
+C the vector between center of side_chain and peptide group
+ double precision pep_side(3),long,side_calf(3),
+ &pept_group(3),costhet_grad(3),cosphi_grad_long(3),
+ &cosphi_grad_loc(3),pep_side_norm(3),side_calf_norm(3)
+C the line belowe needs to be changed for FGPROC>1
+ do i=1,nres-1
+ if ((itype(i).eq.ntyp1).and.itype(i+1).eq.ntyp1) cycle
+ ishield_list(i)=0
+Cif there two consequtive dummy atoms there is no peptide group between them
+C the line below has to be changed for FGPROC>1
+ VolumeTotal=0.0
+ do k=1,nres
+ if ((itype(k).eq.ntyp1).or.(itype(k).eq.10)) cycle
+ dist_pep_side=0.0
+ dist_side_calf=0.0
+ do j=1,3
+C first lets set vector conecting the ithe side-chain with kth side-chain
+ pep_side(j)=c(j,k+nres)-(c(j,i)+c(j,i+1))/2.0d0
+C pep_side(j)=2.0d0
+C and vector conecting the side-chain with its proper calfa
+ side_calf(j)=c(j,k+nres)-c(j,k)
+C side_calf(j)=2.0d0
+ pept_group(j)=c(j,i)-c(j,i+1)
+C lets have their lenght
+ dist_pep_side=pep_side(j)**2+dist_pep_side
+ dist_side_calf=dist_side_calf+side_calf(j)**2
+ dist_pept_group=dist_pept_group+pept_group(j)**2
+ enddo
+ dist_pep_side=dsqrt(dist_pep_side)
+ dist_pept_group=dsqrt(dist_pept_group)
+ dist_side_calf=dsqrt(dist_side_calf)
+ do j=1,3
+ pep_side_norm(j)=pep_side(j)/dist_pep_side
+ side_calf_norm(j)=dist_side_calf
+ enddo
+C now sscale fraction
+ sh_frac_dist=-(dist_pep_side-rpp(1,1)-buff_shield)/buff_shield
+C print *,buff_shield,"buff"
+C now sscale
+ if (sh_frac_dist.le.0.0) cycle
+C If we reach here it means that this side chain reaches the shielding sphere
+C Lets add him to the list for gradient
+ ishield_list(i)=ishield_list(i)+1
+C ishield_list is a list of non 0 side-chain that contribute to factor gradient
+C this list is essential otherwise problem would be O3
+ shield_list(ishield_list(i),i)=k
+C Lets have the sscale value
+ if (sh_frac_dist.gt.1.0) then
+ scale_fac_dist=1.0d0
+ do j=1,3
+ sh_frac_dist_grad(j)=0.0d0
+ enddo
+ else
+ scale_fac_dist=-sh_frac_dist*sh_frac_dist
+ & *(2.0d0*sh_frac_dist-3.0d0)
+ fac_help_scale=6.0d0*(sh_frac_dist-sh_frac_dist**2)
+ & /dist_pep_side/buff_shield*0.5d0
+C remember for the final gradient multiply sh_frac_dist_grad(j)
+C for side_chain by factor -2 !
+ do j=1,3
+ sh_frac_dist_grad(j)=fac_help_scale*pep_side(j)
+C sh_frac_dist_grad(j)=0.0d0
+C scale_fac_dist=1.0d0
+C print *,"jestem",scale_fac_dist,fac_help_scale,
+C & sh_frac_dist_grad(j)
+ enddo
+ endif
+C this is what is now we have the distance scaling now volume...
+ short=short_r_sidechain(itype(k))
+ long=long_r_sidechain(itype(k))
+ costhet=1.0d0/dsqrt(1.0d0+short**2/dist_pep_side**2)
+ sinthet=short/dist_pep_side*costhet
+C now costhet_grad
+C costhet=0.6d0
+C sinthet=0.8
+ costhet_fac=costhet**3*short**2*(-0.5d0)/dist_pep_side**4
+C sinthet_fac=costhet**2*0.5d0*(short**3/dist_pep_side**4*costhet
+C & -short/dist_pep_side**2/costhet)
+C costhet_fac=0.0d0
+ do j=1,3
+ costhet_grad(j)=costhet_fac*pep_side(j)
+ enddo
+C remember for the final gradient multiply costhet_grad(j)
+C for side_chain by factor -2 !
+C fac alfa is angle between CB_k,CA_k, CA_i,CA_i+1
+C pep_side0pept_group is vector multiplication
+ pep_side0pept_group=0.0d0
+ do j=1,3
+ pep_side0pept_group=pep_side0pept_group+pep_side(j)*side_calf(j)
+ enddo
+ cosalfa=(pep_side0pept_group/
+ & (dist_pep_side*dist_side_calf))
+ fac_alfa_sin=1.0d0-cosalfa**2
+ fac_alfa_sin=dsqrt(fac_alfa_sin)
+ rkprim=fac_alfa_sin*(long-short)+short
+C rkprim=short
+
+C now costhet_grad
+ cosphi=1.0d0/dsqrt(1.0d0+rkprim**2/dist_pep_side**2)
+C cosphi=0.6
+ cosphi_fac=cosphi**3*rkprim**2*(-0.5d0)/dist_pep_side**4
+ sinphi=rkprim/dist_pep_side/dsqrt(1.0d0+rkprim**2/
+ & dist_pep_side**2)
+C sinphi=0.8
+ do j=1,3
+ cosphi_grad_long(j)=cosphi_fac*pep_side(j)
+ &+cosphi**3*0.5d0/dist_pep_side**2*(-rkprim)
+ &*(long-short)/fac_alfa_sin*cosalfa/
+ &((dist_pep_side*dist_side_calf))*
+ &((side_calf(j))-cosalfa*
+ &((pep_side(j)/dist_pep_side)*dist_side_calf))
+C cosphi_grad_long(j)=0.0d0
+ cosphi_grad_loc(j)=cosphi**3*0.5d0/dist_pep_side**2*(-rkprim)
+ &*(long-short)/fac_alfa_sin*cosalfa
+ &/((dist_pep_side*dist_side_calf))*
+ &(pep_side(j)-
+ &cosalfa*side_calf(j)/dist_side_calf*dist_pep_side)
+C cosphi_grad_loc(j)=0.0d0
+ enddo
+C print *,sinphi,sinthet
+ VofOverlap=VSolvSphere/2.0d0*(1.0d0-dsqrt(1.0d0-sinphi*sinthet))
+ & /VSolvSphere_div
+C & *wshield
+C now the gradient...
+ do j=1,3
+ grad_shield(j,i)=grad_shield(j,i)
+C gradient po skalowaniu
+ & +(sh_frac_dist_grad(j)*VofOverlap
+C gradient po costhet
+ & +scale_fac_dist*VSolvSphere/VSolvSphere_div/4.0d0*
+ &(1.0d0/(-dsqrt(1.0d0-sinphi*sinthet))*(
+ & sinphi/sinthet*costhet*costhet_grad(j)
+ & +sinthet/sinphi*cosphi*cosphi_grad_long(j)))
+ & )*wshield
+C grad_shield_side is Cbeta sidechain gradient
+ grad_shield_side(j,ishield_list(i),i)=
+ & (sh_frac_dist_grad(j)*-2.0d0
+ & *VofOverlap
+ & -scale_fac_dist*VSolvSphere/VSolvSphere_div/2.0d0*
+ &(1.0d0/(-dsqrt(1.0d0-sinphi*sinthet))*(
+ & sinphi/sinthet*costhet*costhet_grad(j)
+ & +sinthet/sinphi*cosphi*cosphi_grad_long(j)))
+ & )*wshield
+
+ grad_shield_loc(j,ishield_list(i),i)=
+ & scale_fac_dist*VSolvSphere/VSolvSphere_div/2.0d0*
+ &(1.0d0/(dsqrt(1.0d0-sinphi*sinthet))*(
+ & sinthet/sinphi*cosphi*cosphi_grad_loc(j)
+ & ))
+ & *wshield
+ enddo
+ VolumeTotal=VolumeTotal+VofOverlap*scale_fac_dist
+ enddo
+ fac_shield(i)=VolumeTotal*wshield+(1.0d0-wshield)
+C write(2,*) "TOTAL VOLUME",i,VolumeTotal,fac_shield(i)
+C write(2,*) "TU",rpp(1,1),short,long,buff_shield
+ enddo
+ return
+ end
+
+C-----------------------------------------------------------------------
+C-----------------------------------------------------------
+C This subroutine is to mimic the histone like structure but as well can be
+C utilizet to nanostructures (infinit) small modification has to be used to
+C make it finite (z gradient at the ends has to be changes as well as the x,y
+C gradient has to be modified at the ends
+C The energy function is Kihara potential
+C E=4esp*((sigma/(r-r0))^12 - (sigma/(r-r0))^6)
+C 4eps is depth of well sigma is r_minimum r is distance from center of tube
+C and r0 is the excluded size of nanotube (can be set to 0 if we want just a
+C simple Kihara potential
+ subroutine calctube(Etube)
+ implicit real*8 (a-h,o-z)
+ include 'DIMENSIONS'
+ include 'COMMON.GEO'
+ include 'COMMON.VAR'
+ include 'COMMON.LOCAL'
+ include 'COMMON.CHAIN'
+ include 'COMMON.DERIV'
+ include 'COMMON.INTERACT'
+ include 'COMMON.IOUNITS'
+ include 'COMMON.CALC'
+ include 'COMMON.CONTROL'
+ include 'COMMON.SPLITELE'
+ include 'COMMON.SBRIDGE'
+ double precision tub_r,vectube(3),enetube(maxres*2)
+ Etube=0.0d0
+ do i=itube_start,itube_end
+ enetube(i)=0.0d0
+ enetube(i+nres)=0.0d0
+ enddo
+C first we calculate the distance from tube center
+C first sugare-phosphate group for NARES this would be peptide group
+C for UNRES
+ do i=itube_start,itube_end
+C lets ommit dummy atoms for now
+ if ((itype(i).eq.ntyp1).or.(itype(i+1).eq.ntyp1)) cycle
+C now calculate distance from center of tube and direction vectors
+ xmin=boxxsize
+ ymin=boxysize
+ do j=-1,1
+ vectube(1)=mod((c(1,i)+c(1,i+1))/2.0d0,boxxsize)
+ vectube(1)=vectube(1)+boxxsize*j
+ vectube(2)=mod((c(2,i)+c(2,i+1))/2.0d0,boxysize)
+ vectube(2)=vectube(2)+boxysize*j
+
+ xminact=abs(vectube(1)-tubecenter(1))
+ yminact=abs(vectube(2)-tubecenter(2))
+ if (xmin.gt.xminact) then
+ xmin=xminact
+ xtemp=vectube(1)
+ endif
+ if (ymin.gt.yminact) then
+ ymin=yminact
+ ytemp=vectube(2)
+ endif
+ enddo
+ vectube(1)=xtemp
+ vectube(2)=ytemp
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+
+C print *,"x",(c(1,i)+c(1,i+1))/2.0d0,tubecenter(1)
+C print *,"y",(c(2,i)+c(2,i+1))/2.0d0,tubecenter(2)
+
+C as the tube is infinity we do not calculate the Z-vector use of Z
+C as chosen axis
+ vectube(3)=0.0d0
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ enetube(i)=pep_aa_tube/rdiff6**2.0d0+pep_bb_tube/rdiff6
+C write(iout,*) "TU13",i,rdiff6,enetube(i)
+C print *,rdiff,rdiff6,pep_aa_tube
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=(-12.0d0*pep_aa_tube/rdiff6-
+ & 6.0d0*pep_bb_tube)/rdiff6/rdiff
+C write(iout,'(a5,i4,f12.1,3f12.5)') "TU13",i,rdiff6,enetube(i),
+C &rdiff,fac
+
+C now direction of gg_tube vector
+ do j=1,3
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac/2.0d0
+ gg_tube(j,i)=gg_tube(j,i)+vectube(j)*fac/2.0d0
+ enddo
+ enddo
+C basically thats all code now we split for side-chains (REMEMBER to sum up at the END)
+C print *,gg_tube(1,0),"TU"
+
+
+ do i=itube_start,itube_end
+C Lets not jump over memory as we use many times iti
+ iti=itype(i)
+C lets ommit dummy atoms for now
+ if ((iti.eq.ntyp1)
+C in UNRES uncomment the line below as GLY has no side-chain...
+C .or.(iti.eq.10)
+ & ) cycle
+ xmin=boxxsize
+ ymin=boxysize
+ do j=-1,1
+ vectube(1)=mod((c(1,i+nres)),boxxsize)
+ vectube(1)=vectube(1)+boxxsize*j
+ vectube(2)=mod((c(2,i+nres)),boxysize)
+ vectube(2)=vectube(2)+boxysize*j
+
+ xminact=abs(vectube(1)-tubecenter(1))
+ yminact=abs(vectube(2)-tubecenter(2))
+ if (xmin.gt.xminact) then
+ xmin=xminact
+ xtemp=vectube(1)
+ endif
+ if (ymin.gt.yminact) then
+ ymin=yminact
+ ytemp=vectube(2)
+ endif
+ enddo
+ vectube(1)=xtemp
+ vectube(2)=ytemp
+C write(iout,*), "tututu", vectube(1),tubecenter(1),vectube(2),
+C & tubecenter(2)
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+
+C as the tube is infinity we do not calculate the Z-vector use of Z
+C as chosen axis
+ vectube(3)=0.0d0
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ sc_aa_tube=sc_aa_tube_par(iti)
+ sc_bb_tube=sc_bb_tube_par(iti)
+ enetube(i+nres)=sc_aa_tube/rdiff6**2.0d0+sc_bb_tube/rdiff6
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=-12.0d0*sc_aa_tube/rdiff6**2.0d0/rdiff-
+ & 6.0d0*sc_bb_tube/rdiff6/rdiff
+C now direction of gg_tube vector
+ do j=1,3
+ gg_tube_SC(j,i)=gg_tube_SC(j,i)+vectube(j)*fac
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac
+ enddo
+ enddo
+ do i=itube_start,itube_end
+ Etube=Etube+enetube(i)+enetube(i+nres)
+ enddo
+C print *,"ETUBE", etube
+ return
+ end
+C TO DO 1) add to total energy
+C 2) add to gradient summation
+C 3) add reading parameters (AND of course oppening of PARAM file)
+C 4) add reading the center of tube
+C 5) add COMMONs
+C 6) add to zerograd
+
+C-----------------------------------------------------------------------
+C-----------------------------------------------------------
+C This subroutine is to mimic the histone like structure but as well can be
+C utilizet to nanostructures (infinit) small modification has to be used to
+C make it finite (z gradient at the ends has to be changes as well as the x,y
+C gradient has to be modified at the ends
+C The energy function is Kihara potential
+C E=4esp*((sigma/(r-r0))^12 - (sigma/(r-r0))^6)
+C 4eps is depth of well sigma is r_minimum r is distance from center of tube
+C and r0 is the excluded size of nanotube (can be set to 0 if we want just a
+C simple Kihara potential
+ subroutine calctube2(Etube)
+ implicit real*8 (a-h,o-z)
+ include 'DIMENSIONS'
+ include 'COMMON.GEO'
+ include 'COMMON.VAR'
+ include 'COMMON.LOCAL'
+ include 'COMMON.CHAIN'
+ include 'COMMON.DERIV'
+ include 'COMMON.INTERACT'
+ include 'COMMON.IOUNITS'
+ include 'COMMON.CALC'
+ include 'COMMON.CONTROL'
+ include 'COMMON.SPLITELE'
+ include 'COMMON.SBRIDGE'
+ double precision tub_r,vectube(3),enetube(maxres*2)
+ Etube=0.0d0
+ do i=itube_start,itube_end
+ enetube(i)=0.0d0
+ enetube(i+nres)=0.0d0
+ enddo
+C first we calculate the distance from tube center
+C first sugare-phosphate group for NARES this would be peptide group
+C for UNRES
+ do i=itube_start,itube_end
+C lets ommit dummy atoms for now
+
+ if ((itype(i).eq.ntyp1).or.(itype(i+1).eq.ntyp1)) cycle
+C now calculate distance from center of tube and direction vectors
+C vectube(1)=mod((c(1,i)+c(1,i+1))/2.0d0,boxxsize)
+C if (vectube(1).lt.0) vectube(1)=vectube(1)+boxxsize
+C vectube(2)=mod((c(2,i)+c(2,i+1))/2.0d0,boxysize)
+C if (vectube(2).lt.0) vectube(2)=vectube(2)+boxysize
+ xmin=boxxsize
+ ymin=boxysize
+ do j=-1,1
+ vectube(1)=mod((c(1,i)+c(1,i+1))/2.0d0,boxxsize)
+ vectube(1)=vectube(1)+boxxsize*j
+ vectube(2)=mod((c(2,i)+c(2,i+1))/2.0d0,boxysize)
+ vectube(2)=vectube(2)+boxysize*j
+
+ xminact=abs(vectube(1)-tubecenter(1))
+ yminact=abs(vectube(2)-tubecenter(2))
+ if (xmin.gt.xminact) then
+ xmin=xminact
+ xtemp=vectube(1)
+ endif
+ if (ymin.gt.yminact) then
+ ymin=yminact
+ ytemp=vectube(2)
+ endif
+ enddo
+ vectube(1)=xtemp
+ vectube(2)=ytemp
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+
+C print *,"x",(c(1,i)+c(1,i+1))/2.0d0,tubecenter(1)
+C print *,"y",(c(2,i)+c(2,i+1))/2.0d0,tubecenter(2)
+
+C as the tube is infinity we do not calculate the Z-vector use of Z
+C as chosen axis
+ vectube(3)=0.0d0
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C THIS FRAGMENT MAKES TUBE FINITE
+ positi=mod((c(3,i)+c(3,i+1))/2.0d0,boxzsize)
+ if (positi.le.0) positi=positi+boxzsize
+C print *,mod(c(3,i+nres),boxzsize),bordlipbot,bordliptop
+c for each residue check if it is in lipid or lipid water border area
+C respos=mod(c(3,i+nres),boxzsize)
+ print *,positi,bordtubebot,buftubebot,bordtubetop
+ if ((positi.gt.bordtubebot)
+ & .and.(positi.lt.bordtubetop)) then
+C the energy transfer exist
+ if (positi.lt.buftubebot) then
+ fracinbuf=1.0d0-
+ & ((positi-bordtubebot)/tubebufthick)
+C lipbufthick is thickenes of lipid buffore
+ sstube=sscalelip(fracinbuf)
+ ssgradtube=-sscagradlip(fracinbuf)/tubebufthick
+ print *,ssgradtube, sstube,tubetranene(itype(i))
+ enetube(i)=enetube(i)+sstube*tubetranenepep
+C gg_tube_SC(3,i)=gg_tube_SC(3,i)
+C &+ssgradtube*tubetranene(itype(i))
+C gg_tube(3,i-1)= gg_tube(3,i-1)
+C &+ssgradtube*tubetranene(itype(i))
+C print *,"doing sccale for lower part"
+ elseif (positi.gt.buftubetop) then
+ fracinbuf=1.0d0-
+ &((bordtubetop-positi)/tubebufthick)
+ sstube=sscalelip(fracinbuf)
+ ssgradtube=sscagradlip(fracinbuf)/tubebufthick
+ enetube(i)=enetube(i)+sstube*tubetranenepep
+C gg_tube_SC(3,i)=gg_tube_SC(3,i)
+C &+ssgradtube*tubetranene(itype(i))
+C gg_tube(3,i-1)= gg_tube(3,i-1)
+C &+ssgradtube*tubetranene(itype(i))
+C print *, "doing sscalefor top part",sslip,fracinbuf
+ else
+ sstube=1.0d0
+ ssgradtube=0.0d0
+ enetube(i)=enetube(i)+sstube*tubetranenepep
+C print *,"I am in true lipid"
+ endif
+ else
+C sstube=0.0d0
+C ssgradtube=0.0d0
+ cycle
+ endif ! if in lipid or buffor
+
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ enetube(i)=enetube(i)+sstube*
+ &(pep_aa_tube/rdiff6**2.0d0+pep_bb_tube/rdiff6)
+C write(iout,*) "TU13",i,rdiff6,enetube(i)
+C print *,rdiff,rdiff6,pep_aa_tube
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=(-12.0d0*pep_aa_tube/rdiff6-
+ & 6.0d0*pep_bb_tube)/rdiff6/rdiff*sstube
+C write(iout,'(a5,i4,f12.1,3f12.5)') "TU13",i,rdiff6,enetube(i),
+C &rdiff,fac
+
+C now direction of gg_tube vector
+ do j=1,3
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac/2.0d0
+ gg_tube(j,i)=gg_tube(j,i)+vectube(j)*fac/2.0d0
+ enddo
+ gg_tube(3,i)=gg_tube(3,i)
+ &+ssgradtube*enetube(i)/sstube/2.0d0
+ gg_tube(3,i-1)= gg_tube(3,i-1)
+ &+ssgradtube*enetube(i)/sstube/2.0d0
+
+ enddo
+C basically thats all code now we split for side-chains (REMEMBER to sum up at the END)
+C print *,gg_tube(1,0),"TU"
+ do i=itube_start,itube_end
+C Lets not jump over memory as we use many times iti
+ iti=itype(i)
+C lets ommit dummy atoms for now
+ if ((iti.eq.ntyp1)
+C in UNRES uncomment the line below as GLY has no side-chain...
+ & .or.(iti.eq.10)
+ & ) cycle
+ vectube(1)=c(1,i+nres)
+ vectube(1)=mod(vectube(1),boxxsize)
+ if (vectube(1).lt.0) vectube(1)=vectube(1)+boxxsize
+ vectube(2)=c(2,i+nres)
+ vectube(2)=mod(vectube(2),boxysize)
+ if (vectube(2).lt.0) vectube(2)=vectube(2)+boxysize
+
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+C THIS FRAGMENT MAKES TUBE FINITE
+ positi=(mod(c(3,i+nres),boxzsize))
+ if (positi.le.0) positi=positi+boxzsize
+C print *,mod(c(3,i+nres),boxzsize),bordlipbot,bordliptop
+c for each residue check if it is in lipid or lipid water border area
+C respos=mod(c(3,i+nres),boxzsize)
+ print *,positi,bordtubebot,buftubebot,bordtubetop
+ if ((positi.gt.bordtubebot)
+ & .and.(positi.lt.bordtubetop)) then
+C the energy transfer exist
+ if (positi.lt.buftubebot) then
+ fracinbuf=1.0d0-
+ & ((positi-bordtubebot)/tubebufthick)
+C lipbufthick is thickenes of lipid buffore
+ sstube=sscalelip(fracinbuf)
+ ssgradtube=-sscagradlip(fracinbuf)/tubebufthick
+ print *,ssgradtube, sstube,tubetranene(itype(i))
+ enetube(i+nres)=enetube(i+nres)+sstube*tubetranene(itype(i))
+C gg_tube_SC(3,i)=gg_tube_SC(3,i)
+C &+ssgradtube*tubetranene(itype(i))
+C gg_tube(3,i-1)= gg_tube(3,i-1)
+C &+ssgradtube*tubetranene(itype(i))
+C print *,"doing sccale for lower part"
+ elseif (positi.gt.buftubetop) then
+ fracinbuf=1.0d0-
+ &((bordtubetop-positi)/tubebufthick)
+ sstube=sscalelip(fracinbuf)
+ ssgradtube=sscagradlip(fracinbuf)/tubebufthick
+ enetube(i+nres)=enetube(i+nres)+sstube*tubetranene(itype(i))
+C gg_tube_SC(3,i)=gg_tube_SC(3,i)
+C &+ssgradtube*tubetranene(itype(i))
+C gg_tube(3,i-1)= gg_tube(3,i-1)
+C &+ssgradtube*tubetranene(itype(i))
+C print *, "doing sscalefor top part",sslip,fracinbuf
+ else
+ sstube=1.0d0
+ ssgradtube=0.0d0
+ enetube(i+nres)=enetube(i+nres)+sstube*tubetranene(itype(i))
+C print *,"I am in true lipid"
+ endif
+ else
+C sstube=0.0d0
+C ssgradtube=0.0d0
+ cycle
+ endif ! if in lipid or buffor
+CEND OF FINITE FRAGMENT
+C as the tube is infinity we do not calculate the Z-vector use of Z
+C as chosen axis
+ vectube(3)=0.0d0
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ sc_aa_tube=sc_aa_tube_par(iti)
+ sc_bb_tube=sc_bb_tube_par(iti)
+ enetube(i+nres)=(sc_aa_tube/rdiff6**2.0d0+sc_bb_tube/rdiff6)
+ & *sstube+enetube(i+nres)
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=(-12.0d0*sc_aa_tube/rdiff6**2.0d0/rdiff-
+ & 6.0d0*sc_bb_tube/rdiff6/rdiff)*sstube
+C now direction of gg_tube vector
+ do j=1,3
+ gg_tube_SC(j,i)=gg_tube_SC(j,i)+vectube(j)*fac
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac
+ enddo
+ gg_tube_SC(3,i)=gg_tube_SC(3,i)
+ &+ssgradtube*enetube(i+nres)/sstube
+ gg_tube(3,i-1)= gg_tube(3,i-1)
+ &+ssgradtube*enetube(i+nres)/sstube
+
+ enddo
+ do i=itube_start,itube_end
+ Etube=Etube+enetube(i)+enetube(i+nres)
+ enddo
+C print *,"ETUBE", etube
+ return
+ end
+C TO DO 1) add to total energy
+C 2) add to gradient summation
+C 3) add reading parameters (AND of course oppening of PARAM file)
+C 4) add reading the center of tube
+C 5) add COMMONs
+C 6) add to zerograd
+
+
+C#-------------------------------------------------------------------------------
+C This subroutine is to mimic the histone like structure but as well can be
+C utilizet to nanostructures (infinit) small modification has to be used to
+C make it finite (z gradient at the ends has to be changes as well as the x,y
+C gradient has to be modified at the ends
+C The energy function is Kihara potential
+C E=4esp*((sigma/(r-r0))^12 - (sigma/(r-r0))^6)
+C 4eps is depth of well sigma is r_minimum r is distance from center of tube
+C and r0 is the excluded size of nanotube (can be set to 0 if we want just a
+C simple Kihara potential
+ subroutine calcnano(Etube)
+ implicit real*8 (a-h,o-z)
+ include 'DIMENSIONS'
+ include 'COMMON.GEO'
+ include 'COMMON.VAR'
+ include 'COMMON.LOCAL'
+ include 'COMMON.CHAIN'
+ include 'COMMON.DERIV'
+ include 'COMMON.INTERACT'
+ include 'COMMON.IOUNITS'
+ include 'COMMON.CALC'
+ include 'COMMON.CONTROL'
+ include 'COMMON.SPLITELE'
+ include 'COMMON.SBRIDGE'
+ double precision tub_r,vectube(3),enetube(maxres*2),
+ & enecavtube(maxres*2)
+ Etube=0.0d0
+ do i=itube_start,itube_end
+ enetube(i)=0.0d0
+ enetube(i+nres)=0.0d0
+ enddo
+C first we calculate the distance from tube center
+C first sugare-phosphate group for NARES this would be peptide group
+C for UNRES
+ do i=itube_start,itube_end
+C lets ommit dummy atoms for now
+ if ((itype(i).eq.ntyp1).or.(itype(i+1).eq.ntyp1)) cycle
+C now calculate distance from center of tube and direction vectors
+ xmin=boxxsize
+ ymin=boxysize
+ zmin=boxzsize
+
+ do j=-1,1
+ vectube(1)=mod((c(1,i)+c(1,i+1))/2.0d0,boxxsize)
+ vectube(1)=vectube(1)+boxxsize*j
+ vectube(2)=mod((c(2,i)+c(2,i+1))/2.0d0,boxysize)
+ vectube(2)=vectube(2)+boxysize*j
+ vectube(3)=mod((c(3,i)+c(3,i+1))/2.0d0,boxzsize)
+ vectube(3)=vectube(3)+boxzsize*j
+
+
+ xminact=abs(vectube(1)-tubecenter(1))
+ yminact=abs(vectube(2)-tubecenter(2))
+ zminact=abs(vectube(3)-tubecenter(3))
+
+ if (xmin.gt.xminact) then
+ xmin=xminact
+ xtemp=vectube(1)
+ endif
+ if (ymin.gt.yminact) then
+ ymin=yminact
+ ytemp=vectube(2)
+ endif
+ if (zmin.gt.zminact) then
+ zmin=zminact
+ ztemp=vectube(3)
+ endif
+ enddo
+ vectube(1)=xtemp
+ vectube(2)=ytemp
+ vectube(3)=ztemp
+
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+ vectube(3)=vectube(3)-tubecenter(3)
+
+C print *,"x",(c(1,i)+c(1,i+1))/2.0d0,tubecenter(1)
+C print *,"y",(c(2,i)+c(2,i+1))/2.0d0,tubecenter(2)
+C as the tube is infinity we do not calculate the Z-vector use of Z
+C as chosen axis
+C vectube(3)=0.0d0
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+ vectube(3)=vectube(3)/tub_r
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ enetube(i)=pep_aa_tube/rdiff6**2.0d0+pep_bb_tube/rdiff6
+C write(iout,*) "TU13",i,rdiff6,enetube(i)
+C print *,rdiff,rdiff6,pep_aa_tube
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=(-12.0d0*pep_aa_tube/rdiff6-
+ & 6.0d0*pep_bb_tube)/rdiff6/rdiff
+C write(iout,'(a5,i4,f12.1,3f12.5)') "TU13",i,rdiff6,enetube(i),
+C &rdiff,fac
+ if (acavtubpep.eq.0.0d0) then
+C go to 667
+ enecavtube(i)=0.0
+ faccav=0.0
+ else
+ denominator=(1.0+dcavtubpep*rdiff6*rdiff6)
+ enecavtube(i)=
+ & (bcavtubpep*rdiff+acavtubpep*sqrt(rdiff)+ccavtubpep)
+ & /denominator
+ enecavtube(i)=0.0
+ faccav=((bcavtubpep*1.0d0+acavtubpep/2.0d0/sqrt(rdiff))
+ & *denominator-(bcavtubpep*rdiff+acavtubpep*sqrt(rdiff)
+ & +ccavtubpep)*rdiff6**2.0d0/rdiff*dcavtubpep*12.0d0)
+ & /denominator**2.0d0
+C faccav=0.0
+C fac=fac+faccav
+C 667 continue
+ endif
+C print *,"TUT",i,iti,rdiff,rdiff6,acavtubpep,denominator,
+C & enecavtube(i),faccav
+C print *,"licz=",
+C & (bcavtub(iti)*rdiff+acavtub(iti)*sqrt(rdiff)+ccavtub(iti))
+CX print *,"finene=",enetube(i+nres)+enecavtube(i)
+
+C now direction of gg_tube vector
+ do j=1,3
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac/2.0d0
+ gg_tube(j,i)=gg_tube(j,i)+vectube(j)*fac/2.0d0
+ enddo
+ enddo
+
+ do i=itube_start,itube_end
+ enecavtube(i)=0.0
+C Lets not jump over memory as we use many times iti
+ iti=itype(i)
+C lets ommit dummy atoms for now
+ if ((iti.eq.ntyp1)
+C in UNRES uncomment the line below as GLY has no side-chain...
+C .or.(iti.eq.10)
+ & ) cycle
+ xmin=boxxsize
+ ymin=boxysize
+ zmin=boxzsize
+ do j=-1,1
+ vectube(1)=mod((c(1,i+nres)),boxxsize)
+ vectube(1)=vectube(1)+boxxsize*j
+ vectube(2)=mod((c(2,i+nres)),boxysize)
+ vectube(2)=vectube(2)+boxysize*j
+ vectube(3)=mod((c(3,i+nres)),boxzsize)
+ vectube(3)=vectube(3)+boxzsize*j
+
+
+ xminact=abs(vectube(1)-tubecenter(1))
+ yminact=abs(vectube(2)-tubecenter(2))
+ zminact=abs(vectube(3)-tubecenter(3))
+
+ if (xmin.gt.xminact) then
+ xmin=xminact
+ xtemp=vectube(1)
+ endif
+ if (ymin.gt.yminact) then
+ ymin=yminact
+ ytemp=vectube(2)
+ endif
+ if (zmin.gt.zminact) then
+ zmin=zminact
+ ztemp=vectube(3)
+ endif
+ enddo
+ vectube(1)=xtemp
+ vectube(2)=ytemp
+ vectube(3)=ztemp
+
+C write(iout,*), "tututu", vectube(1),tubecenter(1),vectube(2),
+C & tubecenter(2)
+ vectube(1)=vectube(1)-tubecenter(1)
+ vectube(2)=vectube(2)-tubecenter(2)
+ vectube(3)=vectube(3)-tubecenter(3)
+C now calculte the distance
+ tub_r=dsqrt(vectube(1)**2+vectube(2)**2+vectube(3)**2)
+C now normalize vector
+ vectube(1)=vectube(1)/tub_r
+ vectube(2)=vectube(2)/tub_r
+ vectube(3)=vectube(3)/tub_r
+
+C calculte rdiffrence between r and r0
+ rdiff=tub_r-tubeR0
+C and its 6 power
+ rdiff6=rdiff**6.0d0
+C for vectorization reasons we will sumup at the end to avoid depenence of previous
+ sc_aa_tube=sc_aa_tube_par(iti)
+ sc_bb_tube=sc_bb_tube_par(iti)
+ enetube(i+nres)=sc_aa_tube/rdiff6**2.0d0+sc_bb_tube/rdiff6
+C enetube(i+nres)=0.0d0
+C pep_aa_tube and pep_bb_tube are precomputed values A=4eps*sigma^12 B=4eps*sigma^6
+C now we calculate gradient
+ fac=-12.0d0*sc_aa_tube/rdiff6**2.0d0/rdiff-
+ & 6.0d0*sc_bb_tube/rdiff6/rdiff
+C fac=0.0
+C now direction of gg_tube vector
+C Now cavity term E=a(x+bsqrt(x)+c)/(1+dx^12)
+ if (acavtub(iti).eq.0.0d0) then
+C go to 667
+ enecavtube(i+nres)=0.0
+ faccav=0.0
+ else
+ denominator=(1.0+dcavtub(iti)*rdiff6*rdiff6)
+ enecavtube(i+nres)=
+ & (bcavtub(iti)*rdiff+acavtub(iti)*sqrt(rdiff)+ccavtub(iti))
+ & /denominator
+C enecavtube(i)=0.0
+ faccav=((bcavtub(iti)*1.0d0+acavtub(iti)/2.0d0/sqrt(rdiff))
+ & *denominator-(bcavtub(iti)*rdiff+acavtub(iti)*sqrt(rdiff)
+ & +ccavtub(iti))*rdiff6**2.0d0/rdiff*dcavtub(iti)*12.0d0)
+ & /denominator**2.0d0
+C faccav=0.0
+ fac=fac+faccav
+C 667 continue
+ endif
+C print *,"TUT",i,iti,rdiff,rdiff6,acavtub(iti),denominator,
+C & enecavtube(i),faccav
+C print *,"licz=",
+C & (bcavtub(iti)*rdiff+acavtub(iti)*sqrt(rdiff)+ccavtub(iti))
+C print *,"finene=",enetube(i+nres)+enecavtube(i)
+ do j=1,3
+ gg_tube_SC(j,i)=gg_tube_SC(j,i)+vectube(j)*fac
+ gg_tube(j,i-1)=gg_tube(j,i-1)+vectube(j)*fac
+ enddo
+ enddo
+C Now cavity term E=a(x+bsqrt(x)+c)/(1+dx^12)
+C do i=itube_start,itube_end
+C enecav(i)=0.0
+C iti=itype(i)
+C if (acavtub(iti).eq.0.0) cycle
+
+
+
+ do i=itube_start,itube_end
+ Etube=Etube+enetube(i)+enetube(i+nres)+enecavtube(i)
+ & +enecavtube(i+nres)
+ enddo
+C print *,"ETUBE", etube
+ return
+ end
+C TO DO 1) add to total energy
+C 2) add to gradient summation
+C 3) add reading parameters (AND of course oppening of PARAM file)
+C 4) add reading the center of tube
+C 5) add COMMONs
+C 6) add to zerograd