c c c ################################################### c ## COPYRIGHT (C) 1991 by Jay William Ponder ## c ## All Rights Reserved ## c ################################################### c c ####################################################### c ## ## c ## subroutine eimptor -- improper torsion energy ## c ## ## c ####################################################### c c c "eimptor" calculates the improper torsion potential energy c c subroutine eimptor implicit none include 'sizes.i' include 'atoms.i' include 'bound.i' include 'energi.i' include 'group.i' include 'imptor.i' include 'torpot.i' include 'usage.i' integer i,ia,ib,ic,id real*8 e,rcb,fgrp real*8 xt,yt,zt real*8 xu,yu,zu real*8 xtu,ytu,ztu real*8 rt2,ru2,rtru real*8 v1,v2,v3 real*8 c1,c2,c3 real*8 s1,s2,s3 real*8 sine,cosine real*8 sine2,cosine2 real*8 sine3,cosine3 real*8 phi1,phi2,phi3 real*8 xia,yia,zia real*8 xib,yib,zib real*8 xic,yic,zic real*8 xid,yid,zid real*8 xba,yba,zba real*8 xcb,ycb,zcb real*8 xdc,ydc,zdc logical proceed c c c zero out improper torsional energy c eit = 0.0d0 c c calculate the improper torsional angle energy term c do i = 1, nitors ia = iitors(1,i) ib = iitors(2,i) ic = iitors(3,i) id = iitors(4,i) c c decide whether to compute the current interaction c proceed = .true. if (use_group) call groups (proceed,fgrp,ia,ib,ic,id,0,0) if (proceed) proceed = (use(ia) .or. use(ib) .or. & use(ic) .or. use(id)) c c compute the value of the torsional angle c if (proceed) then xia = x(ia) yia = y(ia) zia = z(ia) xib = x(ib) yib = y(ib) zib = z(ib) xic = x(ic) yic = y(ic) zic = z(ic) xid = x(id) yid = y(id) zid = z(id) xba = xib - xia yba = yib - yia zba = zib - zia xcb = xic - xib ycb = yic - yib zcb = zic - zib xdc = xid - xic ydc = yid - yic zdc = zid - zic if (use_polymer) then call image (xba,yba,zba) call image (xcb,ycb,zcb) call image (xdc,ydc,zdc) end if xt = yba*zcb - ycb*zba yt = zba*xcb - zcb*xba zt = xba*ycb - xcb*yba xu = ycb*zdc - ydc*zcb yu = zcb*xdc - zdc*xcb zu = xcb*ydc - xdc*ycb xtu = yt*zu - yu*zt ytu = zt*xu - zu*xt ztu = xt*yu - xu*yt rt2 = xt*xt + yt*yt + zt*zt ru2 = xu*xu + yu*yu + zu*zu rtru = sqrt(rt2 * ru2) if (rtru .ne. 0.0d0) then rcb = sqrt(xcb*xcb + ycb*ycb + zcb*zcb) cosine = (xt*xu + yt*yu + zt*zu) / rtru sine = (xcb*xtu + ycb*ytu + zcb*ztu) / (rcb*rtru) c c set the improper torsional parameters for this angle c v1 = itors1(1,i) c1 = itors1(3,i) s1 = itors1(4,i) v2 = itors2(1,i) c2 = itors2(3,i) s2 = itors2(4,i) v3 = itors3(1,i) c3 = itors3(3,i) s3 = itors3(4,i) c c compute the multiple angle trigonometry and the phase terms c cosine2 = cosine*cosine - sine*sine sine2 = 2.0d0 * cosine * sine cosine3 = cosine*cosine2 - sine*sine2 sine3 = cosine*sine2 + sine*cosine2 phi1 = 1.0d0 + (cosine*c1 + sine*s1) phi2 = 1.0d0 + (cosine2*c2 + sine2*s2) phi3 = 1.0d0 + (cosine3*c3 + sine3*s3) c c calculate the improper torsional energy for this angle c e = itorunit * (v1*phi1 + v2*phi2 + v3*phi3) c c scale the interaction based on its group membership c if (use_group) e = e * fgrp c c increment the total torsional angle energy c eit = eit + e end if end if end do return end