include 'COMMON.SBRIDGE'
include 'COMMON.MD'
include 'COMMON.SETUP'
+ include 'COMMON.CONTROL'
+ include 'COMMON.SHIELD'
character*1 t1,t2,t3
character*1 onelett(4) /"G","A","P","D"/
character*1 toronelet(-2:2) /"p","a","G","A","P"/
enddo
endif
#endif
+C read Czybyshev torsional parameters
+ read (itorkcc,*,end=121,err=121) nkcctyp
+ read (itorkcc,*,end=121,err=121) (itortyp_kcc(i),i=1,ntyp)
+ do i=-ntyp,-1
+ itortyp_kcc(i)=-itortyp_kcc(-i)
+ enddo
+ do i=1,nkcctyp
+ do j=1,nkcctyp
+C first we read the cos and sin gamma parameters
+ read (itorkcc,*,end=121,err=121)
+ & nterm_kcc(j,i),nterm_kcc_Tb(j,i)
+C read (itorkcc,*,end=121,err=121) nterm_kcc_Tb(j,i)
+ do k=1,nterm_kcc(j,i)
+ do l=1,nterm_kcc_Tb(j,i)
+ read (itorkcc,*,end=121,err=121)
+ & v1_chyb(l,k,j,i)
+ enddo
+ do l=1,nterm_kcc_Tb(j,i)
+ read (itorkcc,*,end=121,err=121)
+ & v2_chyb(l,k,j,i)
+ enddo
+ read (itorkcc,*,end=121,err=121)
+ & v1_kcc(k,j,i)
+ read (itorkcc,*,end=121,err=121)
+ & v2_kcc(k,j,i)
+ enddo
+ enddo
+ enddo
+C here will be the apropriate recalibrating for D-aminoacid
+C read (ithetkcc,*,end=121,err=121) nkcctyp
+ do i=1,nkcctyp
+ read (ithetkcc,*,end=121,err=121) nbend_kcc_Tb(i)
+ do j=1,nbend_kcc_Tb(i)
+ read (ithetkcc,*,end=121,err=121)
+ & v1bend_chyb(j,i)
+ enddo
+ enddo
C Read of Side-chain backbone correlation parameters
C Modified 11 May 2012 by Adasko
CCC
c B2(2,i) = b(4)
c B2(1,-i) =b(2)
c B2(2,-i) =-b(4)
- B1tilde(1,i) = b(3)
- B1tilde(2,i) =-b(5)
- B1tilde(1,-i) =-b(3)
- B1tilde(2,-i) =b(5)
+ B1tilde(1,i) = b(3,i)
+ B1tilde(2,i) =-b(5,i)
+C B1tilde(1,-i) =-b(3,i)
+C B1tilde(2,-i) =b(5,i)
b1tilde(1,i)=0.0d0
b1tilde(2,i)=0.0d0
- B2(1,i) = b(2)
- B2(2,i) = b(4)
- B2(1,-i) =b(2)
- B2(2,-i) =-b(4)
+ B2(1,i) = b(2,i)
+ B2(2,i) = b(4,i)
+C B2(1,-i) =b(2,i)
+C B2(2,-i) =-b(4,i)
c b2(1,i)=0.0d0
c b2(2,i)=0.0d0
C now we start reading lipid
do i=1,ntyp
read (isidep,*,end=1161,err=1161)(epslip(i,j),j=i,ntyp)
- print *,"WARNING!!"
- do j=1,ntyp
- epslip(i,j)=epslip(i,j)+0.05d0
- enddo
+C print *,"WARNING!!"
+C do j=1,ntyp
+C epslip(i,j)=epslip(i,j)+0.05d0
+C enddo
enddo
+ write(iout,*) epslip(1,1),"OK?"
C For the GB potential convert sigma'**2 into chi'
if (ipot.eq.4) then
do i=1,ntyp
C write (iout,'(3(a,f10.2))') 'v1ss:',v1ss,' v2ss:',v2ss,
C & ' v3ss:',v3ss
C endif
+C set the variables used for shielding effect
+C write (iout,*) "SHIELD MODE",shield_mode
+C if (shield_mode.gt.0) then
+C VSolvSphere the volume of solving sphere
+C print *,pi,"pi"
+C rpp(1,1) is the energy r0 for peptide group contact and will be used for it
+C there will be no distinction between proline peptide group and normal peptide
+C group in case of shielding parameters
+C VSolvSphere=4.0/3.0*pi*rpp(1,1)**3
+C VSolvSphere_div=VSolvSphere-4.0/3.0*pi*(rpp(1,1)/2.0)**3
+C write (iout,*) VSolvSphere,VSolvSphere_div
+C long axis of side chain
+C do i=1,ntyp
+C long_r_sidechain(i)=vbldsc0(1,i)
+C short_r_sidechain(i)=sigma0(i)
+C enddo
+C lets set the buffor value
+C buff_shield=1.0d0
+C endif
return
111 write (iout,*) "Error reading bending energy parameters."
goto 999
118 write (iout,*) "Error reading SCp interaction parameters."
goto 999
119 write (iout,*) "Error reading SCCOR parameters"
+ go to 999
+ 121 write (iout,*) "Error in Czybyshev parameters"
999 continue
#ifdef MPI
call MPI_Finalize(Ierror)
#else
call getenv(var,val)
#endif
-
+C set the variables used for shielding effect
+C if (shield_mode.gt.0) then
+C VSolvSphere the volume of solving sphere
+C print *,pi,"pi"
+C rpp(1,1) is the energy r0 for peptide group contact and will be used for it
+C there will be no distinction between proline peptide group and normal peptide
+C group in case of shielding parameters
+C VSolvSphere=4.0/3.0*pi*rpp(1,1)**3
+C VSolvSphere_div=VSolvSphere-4.0/3.0*pi*(rpp(1,1)/2.0)**3
+C long axis of side chain
+C do i=1,ntyp
+C long_r_sidechain(i)=vbldsc0(1,i)
+C short_r_sidechain(i)=sigma0(i)
+C enddo
+C lets set the buffor value
+C buff_shield=1.0d0
+C endif
return
end