要素熱伝導行列を数値積分により求める 関数は、以下のようになる。
/* 要素熱伝導行列:三次元 */
void WH_ThermalFem3D__Linear__K_cnd_arrayInJn
(WH_Fem__Shape3DType shapeType,
WH_Fem__Element3DType elementType,
int nNodes,
double whV_x_arrayIn[/* nNodes */][3],
double whT_lambda[3][3],
double OUT__K_cnd_arrayInJn[/* nNodes * nNodes */])
/*
入力引数:
shapeType は要素形状のタイプ
elementType は要素のタイプ
nNodes は整数で、要素節点数
whV_x_arrayIn はベクトルの節点配列で、位置(節点座標)
whT_lambda はテンソルで、熱伝導率テンソル
出力引数:
OUT__K_cnd_arrayInJn はスカラーの配列(節点、節点)で、
要素熱伝導行列
*/
{
int order;
int nPoints;
int Ip;
int In, Jn;
switch (elementType) {
case WH_FEM__ELEMENT3D__TETRA4N:
order = 1;
break;
case WH_FEM__ELEMENT3D__TETRA10N:
case WH_FEM__ELEMENT3D__HEXA8N:
order = 2;
break;
case WH_FEM__ELEMENT3D__HEXA20N:
case WH_FEM__ELEMENT3D__HEXA27N:
order = 3;
break;
default:
assert(0);
break;
}
for (In = 0; In < nNodes; In++) {
for (Jn = 0; Jn < nNodes; Jn++) {
OUT__K_cnd_arrayInJn[In * nNodes + Jn] = 0.0;
}
}
WH_Fem__NumInt__Gauss3D__nPoints
(shapeType, order,
&nPoints);
for (Ip = 0; Ip < nPoints; Ip++) {
double whV_xi_Ip[3];
double w_Ip;
double whP_N_whV_xi_arrayIn[WH_FEM__MAX_ELEMENT_NODES][3];
double whPt_whV_x_whV_xi[3][3];
double J_V;
double whV_N_x_arrayIn[WH_FEM__MAX_ELEMENT_NODES][3];
WH_Fem__NumInt__Gauss3D__whV_xi_Ip
(shapeType, order, Ip,
whV_xi_Ip);
WH_Fem__NumInt__Gauss3D__w_Ip
(shapeType, order, Ip,
&w_Ip);
WH_Fem__Shape3D__whP_N_whV_xi_arrayIn
(elementType, nNodes, whV_xi_Ip,
whP_N_whV_xi_arrayIn);
WH_Fem__Isoparam3D__Volume__whPt_whV_x_whV_xi
(nNodes, whP_N_whV_xi_arrayIn, whV_x_arrayIn,
whPt_whV_x_whV_xi);
WH_Fem__Isoparam3D__Volume__J_V
(shapeType, whPt_whV_x_whV_xi,
&J_V);
WH_Fem__Isoparam3D__whP_N_whV_x_arrayIn
(whPt_whV_x_whV_xi, nNodes, whP_N_whV_xi_arrayIn,
whV_N_x_arrayIn);
for (In = 0; In < nNodes; In++) {
for (Jn = 0; Jn < nNodes; Jn++) {
double whV_tmp[3];
double K_cnd;
WH_Tensor3D__whT_cdot_whV_OUT_whV
(whT_lambda, whV_N_x_arrayIn[Jn],
whV_tmp);
WH_Tensor3D__whV_cdot_whV_OUT_s
(whV_N_x_arrayIn[In], whV_tmp,
&K_cnd);
OUT__K_cnd_arrayInJn[In * nNodes + Jn]
+= K_cnd * J_V * w_Ip;
}
}
}
}