1dc936754SJeremy L Thompson // Copyright (c) 2017-2024, Lawrence Livermore National Security, LLC and other CEED contributors. 21a74fa30SJames Wright // All Rights Reserved. See the top-level LICENSE and NOTICE files for details. 31a74fa30SJames Wright // 41a74fa30SJames Wright // SPDX-License-Identifier: BSD-2-Clause 51a74fa30SJames Wright // 61a74fa30SJames Wright // This file is part of CEED: http://github.com/ceed 71a74fa30SJames Wright 81a74fa30SJames Wright /// @file 91a74fa30SJames Wright /// Geometric factors (3D) for Navier-Stokes example using PETSc 10*c7ece6efSJeremy L Thompson #pragma once 111a74fa30SJames Wright 121a74fa30SJames Wright #include <ceed.h> 131a74fa30SJames Wright #include <math.h> 141a74fa30SJames Wright 151a74fa30SJames Wright #include "utils.h" 161a74fa30SJames Wright 171a74fa30SJames Wright /** 181a74fa30SJames Wright * @brief Calculate dXdx from dxdX for 3D elements 191a74fa30SJames Wright * 201a74fa30SJames Wright * Reference (parent) coordinates: X 211a74fa30SJames Wright * Physical (current) coordinates: x 221a74fa30SJames Wright * Change of coordinate matrix: dxdX_{i,j} = x_{i,j} (indicial notation) 231a74fa30SJames Wright * Inverse of change of coordinate matrix: dXdx_{i,j} = (detJ^-1) * X_{i,j} 241a74fa30SJames Wright * 251a74fa30SJames Wright * Determinant of Jacobian: 261a74fa30SJames Wright * detJ = J11*A11 + J21*A12 + J31*A13 271a74fa30SJames Wright * Jij = Jacobian entry ij 281a74fa30SJames Wright * Aij = Adjugate ij 291a74fa30SJames Wright * 301a74fa30SJames Wright * Inverse of Jacobian: 311a74fa30SJames Wright * dXdx_i,j = Aij / detJ 321a74fa30SJames Wright * 331a74fa30SJames Wright * @param[in] Q Number of quadrature points 341a74fa30SJames Wright * @param[in] i Current quadrature point 351a74fa30SJames Wright * @param[in] dxdX_q Mapping Jacobian (gradient of the coordinate space) 361a74fa30SJames Wright * @param[out] dXdx Inverse of mapping Jacobian at quadrature point i 371a74fa30SJames Wright * @param[out] detJ_ptr Determinate of the Jacobian, may be NULL is not desired 381a74fa30SJames Wright */ 391a74fa30SJames Wright CEED_QFUNCTION_HELPER void InvertMappingJacobian_3D(CeedInt Q, CeedInt i, const CeedScalar (*dxdX_q)[3][CEED_Q_VLA], CeedScalar dXdx[3][3], 401a74fa30SJames Wright CeedScalar *detJ_ptr) { 411a74fa30SJames Wright const CeedScalar dxdX_11 = dxdX_q[0][0][i]; 421a74fa30SJames Wright const CeedScalar dxdX_21 = dxdX_q[0][1][i]; 431a74fa30SJames Wright const CeedScalar dxdX_31 = dxdX_q[0][2][i]; 441a74fa30SJames Wright const CeedScalar dxdX_12 = dxdX_q[1][0][i]; 451a74fa30SJames Wright const CeedScalar dxdX_22 = dxdX_q[1][1][i]; 461a74fa30SJames Wright const CeedScalar dxdX_32 = dxdX_q[1][2][i]; 471a74fa30SJames Wright const CeedScalar dxdX_13 = dxdX_q[2][0][i]; 481a74fa30SJames Wright const CeedScalar dxdX_23 = dxdX_q[2][1][i]; 491a74fa30SJames Wright const CeedScalar dxdX_33 = dxdX_q[2][2][i]; 501a74fa30SJames Wright const CeedScalar A11 = dxdX_22 * dxdX_33 - dxdX_23 * dxdX_32; 511a74fa30SJames Wright const CeedScalar A12 = dxdX_13 * dxdX_32 - dxdX_12 * dxdX_33; 521a74fa30SJames Wright const CeedScalar A13 = dxdX_12 * dxdX_23 - dxdX_13 * dxdX_22; 531a74fa30SJames Wright const CeedScalar A21 = dxdX_23 * dxdX_31 - dxdX_21 * dxdX_33; 541a74fa30SJames Wright const CeedScalar A22 = dxdX_11 * dxdX_33 - dxdX_13 * dxdX_31; 551a74fa30SJames Wright const CeedScalar A23 = dxdX_13 * dxdX_21 - dxdX_11 * dxdX_23; 561a74fa30SJames Wright const CeedScalar A31 = dxdX_21 * dxdX_32 - dxdX_22 * dxdX_31; 571a74fa30SJames Wright const CeedScalar A32 = dxdX_12 * dxdX_31 - dxdX_11 * dxdX_32; 581a74fa30SJames Wright const CeedScalar A33 = dxdX_11 * dxdX_22 - dxdX_12 * dxdX_21; 591a74fa30SJames Wright const CeedScalar detJ = dxdX_11 * A11 + dxdX_21 * A12 + dxdX_31 * A13; 601a74fa30SJames Wright 611a74fa30SJames Wright dXdx[0][0] = A11 / detJ; 621a74fa30SJames Wright dXdx[0][1] = A12 / detJ; 631a74fa30SJames Wright dXdx[0][2] = A13 / detJ; 641a74fa30SJames Wright dXdx[1][0] = A21 / detJ; 651a74fa30SJames Wright dXdx[1][1] = A22 / detJ; 661a74fa30SJames Wright dXdx[1][2] = A23 / detJ; 671a74fa30SJames Wright dXdx[2][0] = A31 / detJ; 681a74fa30SJames Wright dXdx[2][1] = A32 / detJ; 691a74fa30SJames Wright dXdx[2][2] = A33 / detJ; 701a74fa30SJames Wright if (detJ_ptr) *detJ_ptr = detJ; 711a74fa30SJames Wright } 721a74fa30SJames Wright 731a74fa30SJames Wright /** 74baadde1fSJames Wright * @brief Calculate dXdx from dxdX for 3D elements 75baadde1fSJames Wright * 76baadde1fSJames Wright * Reference (parent) coordinates: X 77baadde1fSJames Wright * Physical (current) coordinates: x 78baadde1fSJames Wright * Change of coordinate matrix: dxdX_{i,j} = x_{i,j} (indicial notation) 79baadde1fSJames Wright * Inverse of change of coordinate matrix: dXdx_{i,j} = (detJ^-1) * X_{i,j} 80baadde1fSJames Wright * 81baadde1fSJames Wright * Determinant of Jacobian: 82baadde1fSJames Wright * detJ = J11*A11 + J21*A12 + J31*A13 83baadde1fSJames Wright * Jij = Jacobian entry ij 84baadde1fSJames Wright * Aij = Adjugate ij 85baadde1fSJames Wright * 86baadde1fSJames Wright * Inverse of Jacobian: 87baadde1fSJames Wright * dXdx_i,j = Aij / detJ 88baadde1fSJames Wright * 89baadde1fSJames Wright * @param[in] Q Number of quadrature points 90baadde1fSJames Wright * @param[in] i Current quadrature point 91baadde1fSJames Wright * @param[in] dxdX_q Mapping Jacobian (gradient of the coordinate space) 92baadde1fSJames Wright * @param[out] dXdx Inverse of mapping Jacobian at quadrature point i 93baadde1fSJames Wright * @param[out] detJ_ptr Determinate of the Jacobian, may be NULL is not desired 94baadde1fSJames Wright */ 95baadde1fSJames Wright CEED_QFUNCTION_HELPER void InvertMappingJacobian_2D(CeedInt Q, CeedInt i, const CeedScalar (*dxdX_q)[2][CEED_Q_VLA], CeedScalar dXdx[2][2], 96baadde1fSJames Wright CeedScalar *detJ_ptr) { 97baadde1fSJames Wright const CeedScalar dxdX_11 = dxdX_q[0][0][i]; 98baadde1fSJames Wright const CeedScalar dxdX_21 = dxdX_q[0][1][i]; 99baadde1fSJames Wright const CeedScalar dxdX_12 = dxdX_q[1][0][i]; 100baadde1fSJames Wright const CeedScalar dxdX_22 = dxdX_q[1][1][i]; 101baadde1fSJames Wright const CeedScalar detJ = dxdX_11 * dxdX_22 - dxdX_21 * dxdX_12; 102baadde1fSJames Wright 103baadde1fSJames Wright dXdx[0][0] = dxdX_22 / detJ; 104baadde1fSJames Wright dXdx[0][1] = -dxdX_12 / detJ; 105baadde1fSJames Wright dXdx[1][0] = -dxdX_21 / detJ; 106baadde1fSJames Wright dXdx[1][1] = dxdX_11 / detJ; 107baadde1fSJames Wright if (detJ_ptr) *detJ_ptr = detJ; 108baadde1fSJames Wright } 109baadde1fSJames Wright 110baadde1fSJames Wright /** 1111a74fa30SJames Wright * @brief Calculate face element's normal vector from dxdX 1121a74fa30SJames Wright * 1131a74fa30SJames Wright * Reference (parent) 2D coordinates: X 1141a74fa30SJames Wright * Physical (current) 3D coordinates: x 1151a74fa30SJames Wright * Change of coordinate matrix: 1161a74fa30SJames Wright * dxdX_{i,j} = dx_i/dX_j (indicial notation) [3 * 2] 1171a74fa30SJames Wright * Inverse change of coordinate matrix: 1181a74fa30SJames Wright * dXdx_{i,j} = dX_i/dx_j (indicial notation) [2 * 3] 1191a74fa30SJames Wright * 1201a74fa30SJames Wright * (J1,J2,J3) is given by the cross product of the columns of dxdX_{i,j} 1211a74fa30SJames Wright * 1221a74fa30SJames Wright * detJb is the magnitude of (J1,J2,J3) 1231a74fa30SJames Wright * 1241a74fa30SJames Wright * Normal vector = (J1,J2,J3) / detJb 1251a74fa30SJames Wright * 1261a74fa30SJames Wright * @param[in] Q Number of quadrature points 1271a74fa30SJames Wright * @param[in] i Current quadrature point 1281a74fa30SJames Wright * @param[in] dxdX_q Mapping Jacobian (gradient of the coordinate space) 1291a74fa30SJames Wright * @param[out] normal Inverse of mapping Jacobian at quadrature point i 1301a74fa30SJames Wright * @param[out] detJ_ptr Determinate of the Jacobian, may be NULL is not desired 1311a74fa30SJames Wright */ 132ff20bea9SJames Wright CEED_QFUNCTION_HELPER void NormalVectorFromdxdX_3D(CeedInt Q, CeedInt i, const CeedScalar (*dxdX_q)[3][CEED_Q_VLA], CeedScalar normal[3], 1331a74fa30SJames Wright CeedScalar *detJ_ptr) { 1341a74fa30SJames Wright const CeedScalar dxdX[3][2] = { 1351a74fa30SJames Wright {dxdX_q[0][0][i], dxdX_q[1][0][i]}, 1361a74fa30SJames Wright {dxdX_q[0][1][i], dxdX_q[1][1][i]}, 1371a74fa30SJames Wright {dxdX_q[0][2][i], dxdX_q[1][2][i]} 1381a74fa30SJames Wright }; 1391a74fa30SJames Wright // J1, J2, and J3 are given by the cross product of the columns of dxdX 1401a74fa30SJames Wright const CeedScalar J1 = dxdX[1][0] * dxdX[2][1] - dxdX[2][0] * dxdX[1][1]; 1411a74fa30SJames Wright const CeedScalar J2 = dxdX[2][0] * dxdX[0][1] - dxdX[0][0] * dxdX[2][1]; 1421a74fa30SJames Wright const CeedScalar J3 = dxdX[0][0] * dxdX[1][1] - dxdX[1][0] * dxdX[0][1]; 1431a74fa30SJames Wright 1441a74fa30SJames Wright const CeedScalar detJ = sqrt(J1 * J1 + J2 * J2 + J3 * J3); 1451a74fa30SJames Wright 1461a74fa30SJames Wright normal[0] = J1 / detJ; 1471a74fa30SJames Wright normal[1] = J2 / detJ; 1481a74fa30SJames Wright normal[2] = J3 / detJ; 1491a74fa30SJames Wright if (detJ_ptr) *detJ_ptr = detJ; 1501a74fa30SJames Wright } 1511a74fa30SJames Wright 1521a74fa30SJames Wright /** 1532c512a7bSJames Wright * This QFunction sets up the geometric factor required for integration when reference coordinates are in 1D and the physical coordinates are in 2D 1542c512a7bSJames Wright * 1552c512a7bSJames Wright * Reference (parent) 1D coordinates: X 1562c512a7bSJames Wright * Physical (current) 2D coordinates: x 1572c512a7bSJames Wright * Change of coordinate vector: 1582c512a7bSJames Wright * J1 = dx_1/dX 1592c512a7bSJames Wright * J2 = dx_2/dX 1602c512a7bSJames Wright * 1612c512a7bSJames Wright * detJb is the magnitude of (J1,J2) 1622c512a7bSJames Wright * 1632c512a7bSJames Wright * We require the determinant of the Jacobian to properly compute integrals of the form: int( u v ) 1642c512a7bSJames Wright * 1652c512a7bSJames Wright * Normal vector is given by the cross product of (J1,J2)/detJ and ẑ 1662c512a7bSJames Wright * 1672c512a7bSJames Wright * @param[in] Q Number of quadrature points 1682c512a7bSJames Wright * @param[in] i Current quadrature point 1692c512a7bSJames Wright * @param[in] dxdX_q Mapping Jacobian (gradient of the coordinate space) 1702c512a7bSJames Wright * @param[out] normal Inverse of mapping Jacobian at quadrature point i 1712c512a7bSJames Wright * @param[out] detJ_ptr Determinate of the Jacobian, may be NULL is not desired 1722c512a7bSJames Wright */ 1732c512a7bSJames Wright CEED_QFUNCTION_HELPER void NormalVectorFromdxdX_2D(CeedInt Q, CeedInt i, const CeedScalar (*dxdX_q)[CEED_Q_VLA], CeedScalar normal[2], 1742c512a7bSJames Wright CeedScalar *detJ_ptr) { 1752c512a7bSJames Wright const CeedScalar J1 = dxdX_q[0][i]; 1762c512a7bSJames Wright const CeedScalar J2 = dxdX_q[1][i]; 1772c512a7bSJames Wright 1782c512a7bSJames Wright CeedScalar detJb = sqrt(J1 * J1 + J2 * J2); 1792c512a7bSJames Wright normal[0] = J2 / detJb; 1802c512a7bSJames Wright normal[1] = -J1 / detJb; 1812c512a7bSJames Wright if (detJ_ptr) *detJ_ptr = detJb; 1822c512a7bSJames Wright } 1832c512a7bSJames Wright 1842c512a7bSJames Wright /** 1851a74fa30SJames Wright * @brief Calculate inverse of mapping Jacobian, (dxdX)^-1 1861a74fa30SJames Wright * 1871a74fa30SJames Wright * Reference (parent) 2D coordinates: X 1881a74fa30SJames Wright * Physical (current) 3D coordinates: x 1891a74fa30SJames Wright * Change of coordinate matrix: 1901a74fa30SJames Wright * dxdX_{i,j} = dx_i/dX_j (indicial notation) [3 * 2] 1911a74fa30SJames Wright * Inverse change of coordinate matrix: 1921a74fa30SJames Wright * dXdx_{i,j} = dX_i/dx_j (indicial notation) [2 * 3] 1931a74fa30SJames Wright * 1941a74fa30SJames Wright * dXdx is calculated via Moore–Penrose inverse: 1951a74fa30SJames Wright * 1961a74fa30SJames Wright * dX_i/dx_j = (dxdX^T dxdX)^(-1) dxdX 1971a74fa30SJames Wright * = (dx_l/dX_i * dx_l/dX_k)^(-1) dx_j/dX_k 1981a74fa30SJames Wright * 1991a74fa30SJames Wright * @param[in] Q Number of quadrature points 2001a74fa30SJames Wright * @param[in] i Current quadrature point 2011a74fa30SJames Wright * @param[in] dxdX_q Mapping Jacobian (gradient of the coordinate space) 2021a74fa30SJames Wright * @param[out] dXdx Inverse of mapping Jacobian at quadrature point i 2031a74fa30SJames Wright */ 2041a74fa30SJames Wright CEED_QFUNCTION_HELPER void InvertBoundaryMappingJacobian_3D(CeedInt Q, CeedInt i, const CeedScalar (*dxdX_q)[3][CEED_Q_VLA], CeedScalar dXdx[2][3]) { 2051a74fa30SJames Wright const CeedScalar dxdX[3][2] = { 2061a74fa30SJames Wright {dxdX_q[0][0][i], dxdX_q[1][0][i]}, 2071a74fa30SJames Wright {dxdX_q[0][1][i], dxdX_q[1][1][i]}, 2081a74fa30SJames Wright {dxdX_q[0][2][i], dxdX_q[1][2][i]} 2091a74fa30SJames Wright }; 2101a74fa30SJames Wright 2111a74fa30SJames Wright // dxdX_k,j * dxdX_j,k 2121a74fa30SJames Wright CeedScalar dxdXTdxdX[2][2] = {{0.}}; 2131a74fa30SJames Wright for (CeedInt j = 0; j < 2; j++) { 2141a74fa30SJames Wright for (CeedInt k = 0; k < 2; k++) { 2151a74fa30SJames Wright for (CeedInt l = 0; l < 3; l++) dxdXTdxdX[j][k] += dxdX[l][j] * dxdX[l][k]; 2161a74fa30SJames Wright } 2171a74fa30SJames Wright } 2181a74fa30SJames Wright 2191a74fa30SJames Wright const CeedScalar detdxdXTdxdX = dxdXTdxdX[0][0] * dxdXTdxdX[1][1] - dxdXTdxdX[1][0] * dxdXTdxdX[0][1]; 2201a74fa30SJames Wright 2211a74fa30SJames Wright // Compute inverse of dxdXTdxdX 2221a74fa30SJames Wright CeedScalar dxdXTdxdX_inv[2][2]; 2231a74fa30SJames Wright dxdXTdxdX_inv[0][0] = dxdXTdxdX[1][1] / detdxdXTdxdX; 2241a74fa30SJames Wright dxdXTdxdX_inv[0][1] = -dxdXTdxdX[0][1] / detdxdXTdxdX; 2251a74fa30SJames Wright dxdXTdxdX_inv[1][0] = -dxdXTdxdX[1][0] / detdxdXTdxdX; 2261a74fa30SJames Wright dxdXTdxdX_inv[1][1] = dxdXTdxdX[0][0] / detdxdXTdxdX; 2271a74fa30SJames Wright 2281a74fa30SJames Wright // Compute dXdx from dxdXTdxdX^-1 and dxdX 2291a74fa30SJames Wright for (CeedInt j = 0; j < 2; j++) { 2301a74fa30SJames Wright for (CeedInt k = 0; k < 3; k++) { 2311a74fa30SJames Wright dXdx[j][k] = 0; 2321a74fa30SJames Wright for (CeedInt l = 0; l < 2; l++) dXdx[j][k] += dxdXTdxdX_inv[l][j] * dxdX[k][l]; 2331a74fa30SJames Wright } 2341a74fa30SJames Wright } 2351a74fa30SJames Wright } 236