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- Code: Lid-driven cavity using pressure-free velocity form (2) ...}=\Pi^S(-\mathbf{v}\cdot\nabla\mathbf{v}+\nu\nabla^2\mathbf{v})+\mathbf{f}^S </math>, ... are solenoidal and irrotational projection operators satisfying <math>\Pi^S+\Pi^I=1</math> and12 KB (1,673 words) - 20:07, 15 March 2013
- PFV4 convection matrix ZZ_Sc{m,k}= eu.S(nn(m,:),xa(k),ya(k)); S=zeros(2,nedofs); Sx=zeros(2,nedofs); Sy=zeros(2,nedofs);6 KB (856 words) - 19:12, 15 March 2013
- PFV4 get pressure ZZ_Spcd{m,k} =eu.S(nn(m,:),xa(k),ya(k)); S=zeros(2,nvdf); Sx=zeros(2,nvdf); Sy=zeros(2,nvdf); G=zeros(2,npdf);11 KB (1,613 words) - 19:29, 15 March 2013
- PFV convection matrix 2 S=zeros(2,nd4); Sx=zeros(2,nd4); Sy=zeros(2,nd4); % Pre-allocate arrays S(:,mm+ND)=Jtd*ZS4424c{m,k}*Ti{m};7 KB (1,099 words) - 18:38, 4 July 2011
- PFV convection matrix ZZ_Sc{m,k}= eu.S(nn(m,:),xa(k),ya(k)); S=zeros(2,nedofs); Sx=zeros(2,nedofs); Sy=zeros(2,nedofs);6 KB (865 words) - 16:06, 15 March 2013
- PFV get pressure ZZ_Spcd{m,k} =eu.S(nn(m,:),xa(k),ya(k)); S=zeros(2,nvdf); Sx=zeros(2,nvdf); Sy=zeros(2,nvdf); G=zeros(2,npdf);11 KB (1,623 words) - 16:10, 15 March 2013
- PFV GMRES solver % Matlab's preconditioned gmres sparse solver. When Dirichlet5 KB (689 words) - 04:10, 29 June 2011
- PFV mesh regrade % if a<1 then grade towards the edge(s)1 KB (199 words) - 04:17, 29 June 2011
- PFV get pressure 2 S=zeros(2,nd4); Sx=zeros(2,nd4); Sy=zeros(2,nd4); G=zeros(2,np4); S(:,mm+ND) =Jtd*ZS4424pc{m,k}*Ti{m};19 KB (3,020 words) - 18:42, 4 July 2011
- Code: Thermal cavity using pressure-free velocity form ...}=\Pi^S(-\mathbf{v}\cdot\nabla\mathbf{v}+\nu\nabla^2\mathbf{v})+\mathbf{f}^S </math>, ... are solenoidal and irrotational projection operators satisfying <math>\Pi^S+\Pi^I=1</math> and14 KB (1,998 words) - 21:21, 15 March 2013
- PFV Tconvection matrix 2 TCm=zeros(nfT,nfT); S=zeros(2,nfV); g=zeros(1,nfT); G=zeros(2,nfT); S(:,mv+NDV)= Jtd*ZS4424tc{m,k}*Ti{m}; mv = mv+nV;7 KB (1,061 words) - 16:13, 7 July 2011
- PFV Buoyancy matrix 2 Bm=zeros(nfV,nfT); S=zeros(2,nfV); g=zeros(1,nfT); % Preallocate arrays S(:,mv+NDV)=Jtd*ZS4424b{m,k}*Ti{m}; mv = mv + nV;6 KB (874 words) - 16:20, 7 July 2011
- Code: 3D Lid-driven cavity using pressure-free velocity form ...}=\Pi^S(-\mathbf{v}\cdot\nabla\mathbf{v}+\nu\nabla^2\mathbf{v})+\mathbf{f}^S </math>, ... are solenoidal and irrotational projection operators satisfying <math>\Pi^S+\Pi^I=1</math> and24 KB (3,584 words) - 14:08, 10 August 2011
- PFV 3D diffusion matrix function G=GTL(ni,q,r,s) ...*(1+ni(:,2).*r).*(1+ni(:,3).*s), .125*ni(:,2).*(1+ni(:,1).*q).*(1+ni(:,3).*s), ...5 KB (815 words) - 12:17, 20 July 2011
- PFV 3D convection matrix Cm=zeros(ndfe,ndfe); S=zeros(3,ndfe); % Preallocate arrays S(:,mm3)= JtbD*Z3_V8c{m,k}*Ti{m};5 KB (765 words) - 12:20, 20 July 2011
- PFV V8cW 3D linear FE function S=V8cW(ni,q,r,s) % V = V8cW(ni,q,r,s)2 KB (263 words) - 14:12, 10 August 2011
- PFV V8xyzcW 3D linear FE derivatives function [Vx,Vy,Vz]=V8xyzcW(ni,q,r,s) % [Vx,Vy,Vz]=V8xyzcW(ni,q,r,s)4 KB (820 words) - 12:12, 20 July 2011
- SIMPLEM algorithm - SIMPLE-Modified * {{reference-paper|author=Acharya, S. and Moukalled, F.|year=1989|title=Improvements to Incompressible Flow Calc303 B (38 words) - 21:32, 28 December 2011
- Pointwise Pointwise's mesh generation employs the following algorithms. ** Steger's formulation for hex extrusion3 KB (441 words) - 18:16, 28 August 2018
- What is Open Source? ...elines and information related to an Open Source license. From an engineer's standpoint: "Open-source software ... is computer software that is ... prov ...at this [http://www.linkedin.com/groups/What-are-your-experiences-in-66032.S.258407217?view=&gid=66032&item=ANET%3AS%3A258407217&trk=NUS_RITM-title inte28 KB (4,443 words) - 05:05, 23 December 2017