phd-scripts/Unpublished/XFEM/AbaqusUEL/2D_Test2.for

      subroutine uel(rhs,amatrx,svars,energy,ndofel,nrhs,nsvars,props,         
     1 nprops,coords,mcrd,nnode,u,du,v,a,jtype,time,dtime,kstep,kinc,
     2 jelem,params,ndload,jdltyp,adlmag,predef,npredf,lflags,
     3 mlvarx,ddlmag,mdload,pnewdt,jprops,njprop,period)
c
      include 'aba_param.inc'
c
      dimension rhs(mlvarx,*),amatrx(ndofel,ndofel),svars(nsvars),
     1 energy(8),props(*),coords(mcrd,nnode),dndg(4),dndh(4),
     2 u(ndofel),du(mlvarx,*),v(ndofel),a(ndofel),time(2),
     3 params(3),jdltyp(mdload,*),adlmag(mdload,*),
     4 ddlmag(mdload,*),predef(2,npredf,nnode),lflags(*),jprops(*)
c
      dimension gx(4),hx(4),gwei(4),dN(4),phix(8),phiy(8)
c
      parameter(zero=0.d0,one=1.d0)
C     MATERIAL PROPERTY DEFINITION
		thick = 1.
		rho   = 1.
		spec  = 1.
		conduc = 1.
C     INITIALIZATION  (NRHS=1)                                                        
		do k1=1,ndofel                      
			rhs(k1,nrhs)=zero
			do k2=1,ndofel
				amatrx(k2,k1)=zero
			enddo                                      
		enddo                                      
		if (lflags(1).eq.33) then
			gpos=1./sqrt(3.)
			gx(1)=-gpos
			gx(2)=gpos
			gx(3)=gpos
			gx(4)=-gpos
			hx(1)=-gpos
			hx(2)=-gpos
			hx(3)=gpos
			hx(4)=gpos
			do i=1,4
				gwei(i)=1.
			enddo
c     		assemble amatrx and rhs
			do k=1,4
c     		loop through gauss pts
				g=gx(k)
				h=hx(k)
c       		shape functions
				dN(1) = (one - g)*(one - h)/4.
				dN(2) = (one + g)*(one - h)/4.
				dN(3) = (one + g)*(one + h)/4.
				dN(4) = (one - g)*(one + h)/4.
c       		derivative d(Ni)/d(g)
				dNdg(1) = -(one - h)/4.
				dNdg(2) =  (one - h)/4.
				dNdg(3) =  (one + h)/4.
				dNdg(4) = -(one + h)/4.
c       		derivative d(Ni)/d(h)
				dNdh(1) = -(one - g)/4.
				dNdh(2) = -(one + g)/4.
				dNdh(3) =  (one + g)/4.
				dNdh(4) =  (one - g)/4.
c				derivative dx/dg,dx/dh,dy/dg,dy/dh
				dxdg=zero
				dxdh=zero
				dydg=zero
				dydh=zero
				do i=1,4
					dxdg=dxdg+coords(1,i)*dNdg(i)
					dxdh=dxdh+coords(1,i)*dNdh(i)
					dydg=dydg+coords(2,i)*dNdg(i)
					dydh=dydh+coords(2,i)*dNdh(i)	
				enddo
c     			calculation of jacobian
				ajacob=(dxdg*dydh-dxdh*dydg)
c				derivative dn/dx,dn/dy					
				do i=1,4
					phix(i)=(dNdg(i)*dydh-dNdh(i)*dydg)/ajacob
					phiy(i)=(dNdh(i)*dxdg-dNdg(i)*dxdh)/ajacob
     			enddo
				dtdx=zero
				dtdy=zero
				t =zero
				told=zero
				do i=1,4
					dtdx=u(i)*phix(i)+dtdx
					dtdy=u(i)*phiy(i)+dtdy
					t=u(i)*dn(i)+t
					told=(u(i)-du(i,nrhs))*dn(i)+told
				end do
				cond=1.
				dcdt=zero
				dtdt=(t-told)/dtime
				we=gwei(k)*ajacob
				do ki=1,4
c       		loop over nodes
					rhs(ki,nrhs) = rhs(ki,nrhs) - 
     1                 	we*(dN(ki)*rho*spec*dtdt + 
     2                 	cond*(phix(ki)*dtdx + phiy(ki)*dtdy))
					do kj=1,4
						amatrx(ki,kj)= amatrx(ki,kj) + 
     1					we*(dn(ki)*dn(kj)*rho*spec/dtime +
     1                 	cond*(phix(ki)*phix(kj) + phiy(ki)*phiy(kj)))            		
					end do
				end do
			enddo
		end if
      return
      end
Add scripts and inp files. 2024-05-13 19:50:21 +00:00			`subroutine uel(rhs,amatrx,svars,energy,ndofel,nrhs,nsvars,props,`
			`1 nprops,coords,mcrd,nnode,u,du,v,a,jtype,time,dtime,kstep,kinc,`
			`2 jelem,params,ndload,jdltyp,adlmag,predef,npredf,lflags,`
			`3 mlvarx,ddlmag,mdload,pnewdt,jprops,njprop,period)`
			`c`
			`include 'aba_param.inc'`
			`c`
			`dimension rhs(mlvarx,*),amatrx(ndofel,ndofel),svars(nsvars),`
			`1 energy(8),props(*),coords(mcrd,nnode),dndg(4),dndh(4),`
			`2 u(ndofel),du(mlvarx,*),v(ndofel),a(ndofel),time(2),`
			`3 params(3),jdltyp(mdload,),adlmag(mdload,),`
			`4 ddlmag(mdload,),predef(2,npredf,nnode),lflags(),jprops(*)`
			`c`
			`dimension gx(4),hx(4),gwei(4),dN(4),phix(8),phiy(8)`
			`c`
			`parameter(zero=0.d0,one=1.d0)`
			`C MATERIAL PROPERTY DEFINITION`
			`thick = 1.`
			`rho = 1.`
			`spec = 1.`
			`conduc = 1.`
			`C INITIALIZATION (NRHS=1)`
			`do k1=1,ndofel`
			`rhs(k1,nrhs)=zero`
			`do k2=1,ndofel`
			`amatrx(k2,k1)=zero`
			`enddo`
			`enddo`
			`if (lflags(1).eq.33) then`
			`gpos=1./sqrt(3.)`
			`gx(1)=-gpos`
			`gx(2)=gpos`
			`gx(3)=gpos`
			`gx(4)=-gpos`
			`hx(1)=-gpos`
			`hx(2)=-gpos`
			`hx(3)=gpos`
			`hx(4)=gpos`
			`do i=1,4`
			`gwei(i)=1.`
			`enddo`
			`c assemble amatrx and rhs`
			`do k=1,4`
			`c loop through gauss pts`
			`g=gx(k)`
			`h=hx(k)`
			`c shape functions`
			`dN(1) = (one - g)*(one - h)/4.`
			`dN(2) = (one + g)*(one - h)/4.`
			`dN(3) = (one + g)*(one + h)/4.`
			`dN(4) = (one - g)*(one + h)/4.`
			`c derivative d(Ni)/d(g)`
			`dNdg(1) = -(one - h)/4.`
			`dNdg(2) = (one - h)/4.`
			`dNdg(3) = (one + h)/4.`
			`dNdg(4) = -(one + h)/4.`
			`c derivative d(Ni)/d(h)`
			`dNdh(1) = -(one - g)/4.`
			`dNdh(2) = -(one + g)/4.`
			`dNdh(3) = (one + g)/4.`
			`dNdh(4) = (one - g)/4.`
			`c derivative dx/dg,dx/dh,dy/dg,dy/dh`
			`dxdg=zero`
			`dxdh=zero`
			`dydg=zero`
			`dydh=zero`
			`do i=1,4`
			`dxdg=dxdg+coords(1,i)*dNdg(i)`
			`dxdh=dxdh+coords(1,i)*dNdh(i)`
			`dydg=dydg+coords(2,i)*dNdg(i)`
			`dydh=dydh+coords(2,i)*dNdh(i)`
			`enddo`
			`c calculation of jacobian`
			`ajacob=(dxdgdydh-dxdhdydg)`
			`c derivative dn/dx,dn/dy`
			`do i=1,4`
			`phix(i)=(dNdg(i)dydh-dNdh(i)dydg)/ajacob`
			`phiy(i)=(dNdh(i)dxdg-dNdg(i)dxdh)/ajacob`
			`enddo`
			`dtdx=zero`
			`dtdy=zero`
			`t =zero`
			`told=zero`
			`do i=1,4`
			`dtdx=u(i)*phix(i)+dtdx`
			`dtdy=u(i)*phiy(i)+dtdy`
			`t=u(i)*dn(i)+t`
			`told=(u(i)-du(i,nrhs))*dn(i)+told`
			`end do`
			`cond=1.`
			`dcdt=zero`
			`dtdt=(t-told)/dtime`
			`we=gwei(k)*ajacob`
			`do ki=1,4`
			`c loop over nodes`
			`rhs(ki,nrhs) = rhs(ki,nrhs) -`
			`1 we(dN(ki)rhospecdtdt +`
			`2 cond(phix(ki)dtdx + phiy(ki)*dtdy))`
			`do kj=1,4`
			`amatrx(ki,kj)= amatrx(ki,kj) +`
			`1 we(dn(ki)dn(kj)rhospec/dtime +`
			`1 cond(phix(ki)phix(kj) + phiy(ki)*phiy(kj)))`
			`end do`
			`end do`
			`enddo`
			`end if`
			`return`
			`end`