1727da7e7SJeremy L Thompson // Copyright (c) 2017-2022, Lawrence Livermore National Security, LLC and other CEED contributors. 2727da7e7SJeremy L Thompson // All Rights Reserved. See the top-level LICENSE and NOTICE files for details. 3a515125bSLeila Ghaffari // 4727da7e7SJeremy L Thompson // SPDX-License-Identifier: BSD-2-Clause 5a515125bSLeila Ghaffari // 6727da7e7SJeremy L Thompson // This file is part of CEED: http://github.com/ceed 7a515125bSLeila Ghaffari 8a515125bSLeila Ghaffari /// @file 9a515125bSLeila Ghaffari /// Advection initial condition and operator for Navier-Stokes example using PETSc 10a515125bSLeila Ghaffari 11a515125bSLeila Ghaffari #ifndef advection_h 12a515125bSLeila Ghaffari #define advection_h 13a515125bSLeila Ghaffari 14493642f1SJames Wright #include <ceed.h> 15d0cce58aSJeremy L Thompson #include <math.h> 16a515125bSLeila Ghaffari 17e88b842aSJames Wright #include "advection_types.h" 18e88b842aSJames Wright #include "stabilization_types.h" 191a74fa30SJames Wright #include "utils.h" 201a74fa30SJames Wright 213636f6a4SJames Wright typedef struct SetupContextAdv_ *SetupContextAdv; 223636f6a4SJames Wright struct SetupContextAdv_ { 23a515125bSLeila Ghaffari CeedScalar rc; 24a515125bSLeila Ghaffari CeedScalar lx; 25a515125bSLeila Ghaffari CeedScalar ly; 26a515125bSLeila Ghaffari CeedScalar lz; 27a515125bSLeila Ghaffari CeedScalar wind[3]; 28a515125bSLeila Ghaffari CeedScalar time; 292adefcceSJames Wright WindType wind_type; 30c51f031aSJames Wright AdvectionICType initial_condition_type; 312adefcceSJames Wright BubbleContinuityType bubble_continuity_type; 32a515125bSLeila Ghaffari }; 33a515125bSLeila Ghaffari 34a515125bSLeila Ghaffari // ***************************************************************************** 35a515125bSLeila Ghaffari // This QFunction sets the initial conditions and the boundary conditions 36a515125bSLeila Ghaffari // for two test cases: ROTATION and TRANSLATION 37a515125bSLeila Ghaffari // 38a515125bSLeila Ghaffari // -- ROTATION (default) 39a515125bSLeila Ghaffari // Initial Conditions: 40a515125bSLeila Ghaffari // Mass Density: 41a515125bSLeila Ghaffari // Constant mass density of 1.0 42a515125bSLeila Ghaffari // Momentum Density: 43a515125bSLeila Ghaffari // Rotational field in x,y 44a515125bSLeila Ghaffari // Energy Density: 45a515125bSLeila Ghaffari // Maximum of 1. x0 decreasing linearly to 0. as radial distance 46a515125bSLeila Ghaffari // increases to (1.-r/rc), then 0. everywhere else 47a515125bSLeila Ghaffari // 48a515125bSLeila Ghaffari // Boundary Conditions: 49a515125bSLeila Ghaffari // Mass Density: 50a515125bSLeila Ghaffari // 0.0 flux 51a515125bSLeila Ghaffari // Momentum Density: 52a515125bSLeila Ghaffari // 0.0 53a515125bSLeila Ghaffari // Energy Density: 54a515125bSLeila Ghaffari // 0.0 flux 55a515125bSLeila Ghaffari // 56a515125bSLeila Ghaffari // -- TRANSLATION 57a515125bSLeila Ghaffari // Initial Conditions: 58a515125bSLeila Ghaffari // Mass Density: 59a515125bSLeila Ghaffari // Constant mass density of 1.0 60a515125bSLeila Ghaffari // Momentum Density: 61a515125bSLeila Ghaffari // Constant rectilinear field in x,y 62a515125bSLeila Ghaffari // Energy Density: 63a515125bSLeila Ghaffari // Maximum of 1. x0 decreasing linearly to 0. as radial distance 64a515125bSLeila Ghaffari // increases to (1.-r/rc), then 0. everywhere else 65a515125bSLeila Ghaffari // 66a515125bSLeila Ghaffari // Boundary Conditions: 67a515125bSLeila Ghaffari // Mass Density: 68a515125bSLeila Ghaffari // 0.0 flux 69a515125bSLeila Ghaffari // Momentum Density: 70a515125bSLeila Ghaffari // 0.0 71a515125bSLeila Ghaffari // Energy Density: 72a515125bSLeila Ghaffari // Inflow BCs: 73a515125bSLeila Ghaffari // E = E_wind 74a515125bSLeila Ghaffari // Outflow BCs: 75a515125bSLeila Ghaffari // E = E(boundary) 76a515125bSLeila Ghaffari // Both In/Outflow BCs for E are applied weakly in the 77a515125bSLeila Ghaffari // QFunction "Advection_Sur" 78a515125bSLeila Ghaffari // 79a515125bSLeila Ghaffari // ***************************************************************************** 80a515125bSLeila Ghaffari 81a515125bSLeila Ghaffari // ***************************************************************************** 8204e40bb6SJeremy L Thompson // This helper function provides support for the exact, time-dependent solution (currently not implemented) and IC formulation for 3D advection 83a515125bSLeila Ghaffari // ***************************************************************************** 842b916ea7SJeremy L Thompson CEED_QFUNCTION_HELPER CeedInt Exact_Advection(CeedInt dim, CeedScalar time, const CeedScalar X[], CeedInt Nf, CeedScalar q[], void *ctx) { 853636f6a4SJames Wright const SetupContextAdv context = (SetupContextAdv)ctx; 86a515125bSLeila Ghaffari const CeedScalar rc = context->rc; 87a515125bSLeila Ghaffari const CeedScalar lx = context->lx; 88a515125bSLeila Ghaffari const CeedScalar ly = context->ly; 89a515125bSLeila Ghaffari const CeedScalar lz = context->lz; 90a515125bSLeila Ghaffari const CeedScalar *wind = context->wind; 91a515125bSLeila Ghaffari 92a515125bSLeila Ghaffari // Setup 93a515125bSLeila Ghaffari const CeedScalar x0[3] = {0.25 * lx, 0.5 * ly, 0.5 * lz}; 94a515125bSLeila Ghaffari const CeedScalar center[3] = {0.5 * lx, 0.5 * ly, 0.5 * lz}; 95a515125bSLeila Ghaffari 96a515125bSLeila Ghaffari // -- Coordinates 97a515125bSLeila Ghaffari const CeedScalar x = X[0]; 98a515125bSLeila Ghaffari const CeedScalar y = X[1]; 99a515125bSLeila Ghaffari const CeedScalar z = X[2]; 100a515125bSLeila Ghaffari 101a515125bSLeila Ghaffari // -- Energy 102a515125bSLeila Ghaffari CeedScalar r = 0.; 103c51f031aSJames Wright switch (context->initial_condition_type) { 104c51f031aSJames Wright case ADVECTIONIC_BUBBLE_SPHERE: // (dim=3) 1052b916ea7SJeremy L Thompson r = sqrt(Square(x - x0[0]) + Square(y - x0[1]) + Square(z - x0[2])); 106e88b842aSJames Wright break; 107c51f031aSJames Wright case ADVECTIONIC_BUBBLE_CYLINDER: // (dim=2) 108c58dce4fSJed Brown r = sqrt(Square(x - x0[0]) + Square(y - x0[1])); 109e88b842aSJames Wright break; 110c51f031aSJames Wright case ADVECTIONIC_COSINE_HILL: 111e88b842aSJames Wright r = sqrt(Square(x - center[0]) + Square(y - center[1])); 112e88b842aSJames Wright break; 113c51f031aSJames Wright case ADVECTIONIC_SKEW: 114e88b842aSJames Wright break; 115a515125bSLeila Ghaffari } 116a515125bSLeila Ghaffari 117a515125bSLeila Ghaffari // Initial Conditions 118e88b842aSJames Wright CeedScalar wind_scaling = 1.; 119a515125bSLeila Ghaffari switch (context->wind_type) { 1202adefcceSJames Wright case WIND_ROTATION: 121a515125bSLeila Ghaffari q[0] = 1.; 122e88b842aSJames Wright q[1] = -wind_scaling * (y - center[1]); 123e88b842aSJames Wright q[2] = wind_scaling * (x - center[0]); 124a515125bSLeila Ghaffari q[3] = 0; 125a515125bSLeila Ghaffari break; 1262adefcceSJames Wright case WIND_TRANSLATION: 127a515125bSLeila Ghaffari q[0] = 1.; 128a515125bSLeila Ghaffari q[1] = wind[0]; 129a515125bSLeila Ghaffari q[2] = wind[1]; 130a515125bSLeila Ghaffari q[3] = wind[2]; 131a515125bSLeila Ghaffari break; 132a515125bSLeila Ghaffari } 133a515125bSLeila Ghaffari 134c51f031aSJames Wright switch (context->initial_condition_type) { 135c51f031aSJames Wright case ADVECTIONIC_BUBBLE_SPHERE: 136c51f031aSJames Wright case ADVECTIONIC_BUBBLE_CYLINDER: 137a515125bSLeila Ghaffari switch (context->bubble_continuity_type) { 138a515125bSLeila Ghaffari // original continuous, smooth shape 139e88b842aSJames Wright case BUBBLE_CONTINUITY_SMOOTH: 140a515125bSLeila Ghaffari q[4] = r <= rc ? (1. - r / rc) : 0.; 141e88b842aSJames Wright break; 142a515125bSLeila Ghaffari // discontinuous, sharp back half shape 143e88b842aSJames Wright case BUBBLE_CONTINUITY_BACK_SHARP: 144a515125bSLeila Ghaffari q[4] = ((r <= rc) && (y < center[1])) ? (1. - r / rc) : 0.; 145e88b842aSJames Wright break; 146a515125bSLeila Ghaffari // attempt to define a finite thickness that will get resolved under grid refinement 147e88b842aSJames Wright case BUBBLE_CONTINUITY_THICK: 1482b916ea7SJeremy L Thompson q[4] = ((r <= rc) && (y < center[1])) ? (1. - r / rc) * fmin(1.0, (center[1] - y) / 1.25) : 0.; 149e88b842aSJames Wright break; 150e88b842aSJames Wright } 151e88b842aSJames Wright break; 152c51f031aSJames Wright case ADVECTIONIC_COSINE_HILL: { 153e88b842aSJames Wright CeedScalar half_width = context->lx / 2; 154e88b842aSJames Wright q[4] = r > half_width ? 0. : cos(2 * M_PI * r / half_width + M_PI) + 1.; 155e88b842aSJames Wright } break; 156c51f031aSJames Wright case ADVECTIONIC_SKEW: { 157e88b842aSJames Wright CeedScalar skewed_barrier[3] = {wind[0], wind[1], 0}; 158e88b842aSJames Wright CeedScalar inflow_to_point[3] = {x - context->lx / 2, y, 0}; 159e88b842aSJames Wright CeedScalar cross_product[3] = {0}; 160*8e7333c4SJames Wright const CeedScalar boundary_threshold = 20 * CEED_EPSILON; 161e88b842aSJames Wright Cross3(skewed_barrier, inflow_to_point, cross_product); 162e88b842aSJames Wright 163*8e7333c4SJames Wright q[4] = cross_product[2] > boundary_threshold ? 0 : 1; 164*8e7333c4SJames Wright if ((x < boundary_threshold && wind[0] < boundary_threshold) || // outflow at -x boundary 165*8e7333c4SJames Wright (y < boundary_threshold && wind[1] < boundary_threshold) || // outflow at -y boundary 166*8e7333c4SJames Wright (x > context->lx - boundary_threshold && wind[0] > boundary_threshold) || // outflow at +x boundary 167*8e7333c4SJames Wright (y > context->ly - boundary_threshold && wind[1] > boundary_threshold) // outflow at +y boundary 168e88b842aSJames Wright ) { 169e88b842aSJames Wright q[4] = 0; 170e88b842aSJames Wright } 171a515125bSLeila Ghaffari } break; 172a515125bSLeila Ghaffari } 173e88b842aSJames Wright 174a515125bSLeila Ghaffari return 0; 175a515125bSLeila Ghaffari } 176a515125bSLeila Ghaffari 177a515125bSLeila Ghaffari // ***************************************************************************** 178a515125bSLeila Ghaffari // This QFunction sets the initial conditions for 3D advection 179a515125bSLeila Ghaffari // ***************************************************************************** 1802b916ea7SJeremy L Thompson CEED_QFUNCTION(ICsAdvection)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { 181a515125bSLeila Ghaffari // Inputs 182a515125bSLeila Ghaffari const CeedScalar(*X)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0]; 183a515125bSLeila Ghaffari // Outputs 184a515125bSLeila Ghaffari CeedScalar(*q0)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0]; 185a515125bSLeila Ghaffari 186a515125bSLeila Ghaffari // Quadrature Point Loop 1873d65b166SJames Wright CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { 188a515125bSLeila Ghaffari const CeedScalar x[] = {X[0][i], X[1][i], X[2][i]}; 189139613f2SLeila Ghaffari CeedScalar q[5] = {0.}; 190a515125bSLeila Ghaffari 191a515125bSLeila Ghaffari Exact_Advection(3, 0., x, 5, q, ctx); 192a515125bSLeila Ghaffari for (CeedInt j = 0; j < 5; j++) q0[j][i] = q[j]; 193a515125bSLeila Ghaffari } // End of Quadrature Point Loop 194a515125bSLeila Ghaffari 195a515125bSLeila Ghaffari // Return 196a515125bSLeila Ghaffari return 0; 197a515125bSLeila Ghaffari } 198a515125bSLeila Ghaffari 199a515125bSLeila Ghaffari // ***************************************************************************** 200a515125bSLeila Ghaffari // This QFunction implements the following formulation of the advection equation 201a515125bSLeila Ghaffari // 202a515125bSLeila Ghaffari // This is 3D advection given in two formulations based upon the weak form. 203a515125bSLeila Ghaffari // 204a515125bSLeila Ghaffari // State Variables: q = ( rho, U1, U2, U3, E ) 205a515125bSLeila Ghaffari // rho - Mass Density 206a515125bSLeila Ghaffari // Ui - Momentum Density , Ui = rho ui 207a515125bSLeila Ghaffari // E - Total Energy Density 208a515125bSLeila Ghaffari // 209a515125bSLeila Ghaffari // Advection Equation: 210a515125bSLeila Ghaffari // dE/dt + div( E u ) = 0 211a515125bSLeila Ghaffari // ***************************************************************************** 2122b916ea7SJeremy L Thompson CEED_QFUNCTION(Advection)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { 213a515125bSLeila Ghaffari // Inputs 2143d65b166SJames Wright const CeedScalar(*q)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0]; 2153d65b166SJames Wright const CeedScalar(*dq)[5][CEED_Q_VLA] = (const CeedScalar(*)[5][CEED_Q_VLA])in[1]; 216ade49511SJames Wright const CeedScalar(*q_data) = in[2]; 217a515125bSLeila Ghaffari 218a515125bSLeila Ghaffari // Outputs 2193d65b166SJames Wright CeedScalar(*v)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0]; 2203d65b166SJames Wright CeedScalar(*dv)[5][CEED_Q_VLA] = (CeedScalar(*)[5][CEED_Q_VLA])out[1]; 221a515125bSLeila Ghaffari 222a515125bSLeila Ghaffari // Context 223a515125bSLeila Ghaffari AdvectionContext context = (AdvectionContext)ctx; 224a515125bSLeila Ghaffari const CeedScalar CtauS = context->CtauS; 225a515125bSLeila Ghaffari const CeedScalar strong_form = context->strong_form; 226a515125bSLeila Ghaffari 227a515125bSLeila Ghaffari // Quadrature Point Loop 2283d65b166SJames Wright CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { 229a515125bSLeila Ghaffari // Setup 230a515125bSLeila Ghaffari // -- Interp in 231a515125bSLeila Ghaffari const CeedScalar rho = q[0][i]; 2322b916ea7SJeremy L Thompson const CeedScalar u[3] = {q[1][i] / rho, q[2][i] / rho, q[3][i] / rho}; 233a515125bSLeila Ghaffari const CeedScalar E = q[4][i]; 234a515125bSLeila Ghaffari // -- Grad in 2352b916ea7SJeremy L Thompson const CeedScalar drho[3] = {dq[0][0][i], dq[1][0][i], dq[2][0][i]}; 2362b916ea7SJeremy L Thompson const CeedScalar du[3][3] = { 2372b916ea7SJeremy L Thompson {(dq[0][1][i] - drho[0] * u[0]) / rho, (dq[1][1][i] - drho[1] * u[0]) / rho, (dq[2][1][i] - drho[2] * u[0]) / rho}, 2382b916ea7SJeremy L Thompson {(dq[0][2][i] - drho[0] * u[1]) / rho, (dq[1][2][i] - drho[1] * u[1]) / rho, (dq[2][2][i] - drho[2] * u[1]) / rho}, 2392b916ea7SJeremy L Thompson {(dq[0][3][i] - drho[0] * u[2]) / rho, (dq[1][3][i] - drho[1] * u[2]) / rho, (dq[2][3][i] - drho[2] * u[2]) / rho} 240a515125bSLeila Ghaffari }; 2412b916ea7SJeremy L Thompson const CeedScalar dE[3] = {dq[0][4][i], dq[1][4][i], dq[2][4][i]}; 242ade49511SJames Wright CeedScalar wdetJ, dXdx[3][3]; 243ade49511SJames Wright QdataUnpack_3D(Q, i, q_data, &wdetJ, dXdx); 244a515125bSLeila Ghaffari // The Physics 245a515125bSLeila Ghaffari // Note with the order that du was filled and the order that dXdx was filled 246a515125bSLeila Ghaffari // du[j][k]= du_j / dX_K (note cap K to be clear this is u_{j,xi_k}) 247a515125bSLeila Ghaffari // dXdx[k][j] = dX_K / dx_j 248a515125bSLeila Ghaffari // X_K=Kth reference element coordinate (note cap X and K instead of xi_k} 249a515125bSLeila Ghaffari // x_j and u_j are jth physical position and velocity components 250a515125bSLeila Ghaffari 251a515125bSLeila Ghaffari // No Change in density or momentum 252a515125bSLeila Ghaffari for (CeedInt f = 0; f < 4; f++) { 2532b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) dv[j][f][i] = 0; 254a515125bSLeila Ghaffari v[f][i] = 0; 255a515125bSLeila Ghaffari } 256a515125bSLeila Ghaffari 257a515125bSLeila Ghaffari // -- Total Energy 258a515125bSLeila Ghaffari // Evaluate the strong form using div(E u) = u . grad(E) + E div(u) 259a515125bSLeila Ghaffari // or in index notation: (u_j E)_{,j} = u_j E_j + E u_{j,j} 260a515125bSLeila Ghaffari CeedScalar div_u = 0, u_dot_grad_E = 0; 261a515125bSLeila Ghaffari for (CeedInt j = 0; j < 3; j++) { 262a515125bSLeila Ghaffari CeedScalar dEdx_j = 0; 263a515125bSLeila Ghaffari for (CeedInt k = 0; k < 3; k++) { 264a515125bSLeila Ghaffari div_u += du[j][k] * dXdx[k][j]; // u_{j,j} = u_{j,K} X_{K,j} 265a515125bSLeila Ghaffari dEdx_j += dE[k] * dXdx[k][j]; 266a515125bSLeila Ghaffari } 267a515125bSLeila Ghaffari u_dot_grad_E += u[j] * dEdx_j; 268a515125bSLeila Ghaffari } 269a515125bSLeila Ghaffari CeedScalar strong_conv = E * div_u + u_dot_grad_E; 270a515125bSLeila Ghaffari 271a515125bSLeila Ghaffari // Weak Galerkin convection term: dv \cdot (E u) 2722b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) dv[j][4][i] = (1 - strong_form) * wdetJ * E * (u[0] * dXdx[j][0] + u[1] * dXdx[j][1] + u[2] * dXdx[j][2]); 273a515125bSLeila Ghaffari v[4][i] = 0; 274a515125bSLeila Ghaffari 275a515125bSLeila Ghaffari // Strong Galerkin convection term: - v div(E u) 276a515125bSLeila Ghaffari v[4][i] = -strong_form * wdetJ * strong_conv; 277a515125bSLeila Ghaffari 278a515125bSLeila Ghaffari // Stabilization requires a measure of element transit time in the velocity 279a515125bSLeila Ghaffari // field u. 280a515125bSLeila Ghaffari CeedScalar uX[3]; 2812b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) uX[j] = dXdx[j][0] * u[0] + dXdx[j][1] * u[1] + dXdx[j][2] * u[2]; 2823f5a39e9SJames Wright const CeedScalar TauS = CtauS / sqrt(Dot3(uX, uX)); 2832b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) dv[j][4][i] -= wdetJ * TauS * strong_conv * uX[j]; 284a515125bSLeila Ghaffari } // End Quadrature Point Loop 285a515125bSLeila Ghaffari 286a515125bSLeila Ghaffari return 0; 287a515125bSLeila Ghaffari } 288a515125bSLeila Ghaffari 289a515125bSLeila Ghaffari // ***************************************************************************** 29004e40bb6SJeremy L Thompson // This QFunction implements 3D (mentioned above) with implicit time stepping method 291a515125bSLeila Ghaffari // ***************************************************************************** 2922b916ea7SJeremy L Thompson CEED_QFUNCTION(IFunction_Advection)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { 293a515125bSLeila Ghaffari // Inputs 2943d65b166SJames Wright const CeedScalar(*q)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0]; 2953d65b166SJames Wright const CeedScalar(*dq)[5][CEED_Q_VLA] = (const CeedScalar(*)[5][CEED_Q_VLA])in[1]; 2963d65b166SJames Wright const CeedScalar(*q_dot)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[2]; 297ade49511SJames Wright const CeedScalar(*q_data) = in[3]; 2983d65b166SJames Wright 299a515125bSLeila Ghaffari // Outputs 3003d65b166SJames Wright CeedScalar(*v)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0]; 3013d65b166SJames Wright CeedScalar(*dv)[5][CEED_Q_VLA] = (CeedScalar(*)[5][CEED_Q_VLA])out[1]; 30280f5d3cbSJames Wright CeedScalar *jac_data = out[2]; 3033d65b166SJames Wright 304a515125bSLeila Ghaffari AdvectionContext context = (AdvectionContext)ctx; 305a515125bSLeila Ghaffari const CeedScalar CtauS = context->CtauS; 306a515125bSLeila Ghaffari const CeedScalar strong_form = context->strong_form; 30780f5d3cbSJames Wright const CeedScalar zeros[14] = {0.}; 308a515125bSLeila Ghaffari 309a515125bSLeila Ghaffari // Quadrature Point Loop 3103d65b166SJames Wright CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { 311a515125bSLeila Ghaffari // Setup 312a515125bSLeila Ghaffari // -- Interp in 313a515125bSLeila Ghaffari const CeedScalar rho = q[0][i]; 3142b916ea7SJeremy L Thompson const CeedScalar u[3] = {q[1][i] / rho, q[2][i] / rho, q[3][i] / rho}; 315a515125bSLeila Ghaffari const CeedScalar E = q[4][i]; 316a515125bSLeila Ghaffari // -- Grad in 3172b916ea7SJeremy L Thompson const CeedScalar drho[3] = {dq[0][0][i], dq[1][0][i], dq[2][0][i]}; 3182b916ea7SJeremy L Thompson const CeedScalar du[3][3] = { 3192b916ea7SJeremy L Thompson {(dq[0][1][i] - drho[0] * u[0]) / rho, (dq[1][1][i] - drho[1] * u[0]) / rho, (dq[2][1][i] - drho[2] * u[0]) / rho}, 3202b916ea7SJeremy L Thompson {(dq[0][2][i] - drho[0] * u[1]) / rho, (dq[1][2][i] - drho[1] * u[1]) / rho, (dq[2][2][i] - drho[2] * u[1]) / rho}, 3212b916ea7SJeremy L Thompson {(dq[0][3][i] - drho[0] * u[2]) / rho, (dq[1][3][i] - drho[1] * u[2]) / rho, (dq[2][3][i] - drho[2] * u[2]) / rho} 322a515125bSLeila Ghaffari }; 3232b916ea7SJeremy L Thompson const CeedScalar dE[3] = {dq[0][4][i], dq[1][4][i], dq[2][4][i]}; 324ade49511SJames Wright CeedScalar wdetJ, dXdx[3][3]; 325ade49511SJames Wright QdataUnpack_3D(Q, i, q_data, &wdetJ, dXdx); 326a515125bSLeila Ghaffari // The Physics 327a515125bSLeila Ghaffari // Note with the order that du was filled and the order that dXdx was filled 328a515125bSLeila Ghaffari // du[j][k]= du_j / dX_K (note cap K to be clear this is u_{j,xi_k} ) 329a515125bSLeila Ghaffari // dXdx[k][j] = dX_K / dx_j 330a515125bSLeila Ghaffari // X_K=Kth reference element coordinate (note cap X and K instead of xi_k} 331a515125bSLeila Ghaffari // x_j and u_j are jth physical position and velocity components 332a515125bSLeila Ghaffari 333a515125bSLeila Ghaffari // No Change in density or momentum 334a515125bSLeila Ghaffari for (CeedInt f = 0; f < 4; f++) { 3352b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) dv[j][f][i] = 0; 336a515125bSLeila Ghaffari v[f][i] = wdetJ * q_dot[f][i]; // K Mass/transient term 337a515125bSLeila Ghaffari } 338a515125bSLeila Ghaffari 339a515125bSLeila Ghaffari // -- Total Energy 340a515125bSLeila Ghaffari // Evaluate the strong form using div(E u) = u . grad(E) + E div(u) 341a515125bSLeila Ghaffari // or in index notation: (u_j E)_{,j} = u_j E_j + E u_{j,j} 342a515125bSLeila Ghaffari CeedScalar div_u = 0, u_dot_grad_E = 0; 343a515125bSLeila Ghaffari for (CeedInt j = 0; j < 3; j++) { 344a515125bSLeila Ghaffari CeedScalar dEdx_j = 0; 345a515125bSLeila Ghaffari for (CeedInt k = 0; k < 3; k++) { 346a515125bSLeila Ghaffari div_u += du[j][k] * dXdx[k][j]; // u_{j,j} = u_{j,K} X_{K,j} 347a515125bSLeila Ghaffari dEdx_j += dE[k] * dXdx[k][j]; 348a515125bSLeila Ghaffari } 349a515125bSLeila Ghaffari u_dot_grad_E += u[j] * dEdx_j; 350a515125bSLeila Ghaffari } 351a515125bSLeila Ghaffari CeedScalar strong_conv = E * div_u + u_dot_grad_E; 352a515125bSLeila Ghaffari CeedScalar strong_res = q_dot[4][i] + strong_conv; 353a515125bSLeila Ghaffari 354a515125bSLeila Ghaffari v[4][i] = wdetJ * q_dot[4][i]; // transient part (ALWAYS) 355a515125bSLeila Ghaffari 356a515125bSLeila Ghaffari // Weak Galerkin convection term: -dv \cdot (E u) 3572b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) dv[j][4][i] = -wdetJ * (1 - strong_form) * E * (u[0] * dXdx[j][0] + u[1] * dXdx[j][1] + u[2] * dXdx[j][2]); 358a515125bSLeila Ghaffari 359a515125bSLeila Ghaffari // Strong Galerkin convection term: v div(E u) 360a515125bSLeila Ghaffari v[4][i] += wdetJ * strong_form * strong_conv; 361a515125bSLeila Ghaffari 362a515125bSLeila Ghaffari // Stabilization requires a measure of element transit time in the velocity 363a515125bSLeila Ghaffari // field u. 364a515125bSLeila Ghaffari CeedScalar uX[3]; 3652b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) uX[j] = dXdx[j][0] * u[0] + dXdx[j][1] * u[1] + dXdx[j][2] * u[2]; 366a515125bSLeila Ghaffari const CeedScalar TauS = CtauS / sqrt(uX[0] * uX[0] + uX[1] * uX[1] + uX[2] * uX[2]); 367a515125bSLeila Ghaffari 3682b916ea7SJeremy L Thompson for (CeedInt j = 0; j < 3; j++) switch (context->stabilization) { 3692adefcceSJames Wright case STAB_NONE: 370a515125bSLeila Ghaffari break; 3712adefcceSJames Wright case STAB_SU: 3722adefcceSJames Wright dv[j][4][i] += wdetJ * TauS * strong_conv * uX[j]; 373a515125bSLeila Ghaffari break; 3742adefcceSJames Wright case STAB_SUPG: 3752adefcceSJames Wright dv[j][4][i] += wdetJ * TauS * strong_res * uX[j]; 376a515125bSLeila Ghaffari break; 377a515125bSLeila Ghaffari } 37880f5d3cbSJames Wright StoredValuesPack(Q, i, 0, 14, zeros, jac_data); 379a515125bSLeila Ghaffari } // End Quadrature Point Loop 380a515125bSLeila Ghaffari 381a515125bSLeila Ghaffari return 0; 382a515125bSLeila Ghaffari } 383a515125bSLeila Ghaffari 384a515125bSLeila Ghaffari // ***************************************************************************** 385a515125bSLeila Ghaffari // This QFunction implements consistent outflow and inflow BCs 386a515125bSLeila Ghaffari // for 3D advection 387a515125bSLeila Ghaffari // 388a515125bSLeila Ghaffari // Inflow and outflow faces are determined based on sign(dot(wind, normal)): 389a515125bSLeila Ghaffari // sign(dot(wind, normal)) > 0 : outflow BCs 390a515125bSLeila Ghaffari // sign(dot(wind, normal)) < 0 : inflow BCs 391a515125bSLeila Ghaffari // 392a515125bSLeila Ghaffari // Outflow BCs: 39304e40bb6SJeremy L Thompson // The validity of the weak form of the governing equations is extended to the outflow and the current values of E are applied. 394a515125bSLeila Ghaffari // 395a515125bSLeila Ghaffari // Inflow BCs: 396a515125bSLeila Ghaffari // A prescribed Total Energy (E_wind) is applied weakly. 397a515125bSLeila Ghaffari // ***************************************************************************** 3982b916ea7SJeremy L Thompson CEED_QFUNCTION(Advection_InOutFlow)(void *ctx, CeedInt Q, const CeedScalar *const *in, CeedScalar *const *out) { 399a515125bSLeila Ghaffari // Inputs 4003d65b166SJames Wright const CeedScalar(*q)[CEED_Q_VLA] = (const CeedScalar(*)[CEED_Q_VLA])in[0]; 401ade49511SJames Wright const CeedScalar(*q_data_sur) = in[2]; 4023d65b166SJames Wright 403a515125bSLeila Ghaffari // Outputs 404a515125bSLeila Ghaffari CeedScalar(*v)[CEED_Q_VLA] = (CeedScalar(*)[CEED_Q_VLA])out[0]; 405a515125bSLeila Ghaffari AdvectionContext context = (AdvectionContext)ctx; 406a515125bSLeila Ghaffari const CeedScalar E_wind = context->E_wind; 407a515125bSLeila Ghaffari const CeedScalar strong_form = context->strong_form; 408ade49511SJames Wright const bool is_implicit = context->implicit; 409a515125bSLeila Ghaffari 410a515125bSLeila Ghaffari // Quadrature Point Loop 4113d65b166SJames Wright CeedPragmaSIMD for (CeedInt i = 0; i < Q; i++) { 412a515125bSLeila Ghaffari // Setup 413a515125bSLeila Ghaffari // -- Interp in 414a515125bSLeila Ghaffari const CeedScalar rho = q[0][i]; 4152b916ea7SJeremy L Thompson const CeedScalar u[3] = {q[1][i] / rho, q[2][i] / rho, q[3][i] / rho}; 416a515125bSLeila Ghaffari const CeedScalar E = q[4][i]; 417a515125bSLeila Ghaffari 418ade49511SJames Wright CeedScalar wdetJb, norm[3]; 419ade49511SJames Wright QdataBoundaryUnpack_3D(Q, i, q_data_sur, &wdetJb, NULL, norm); 420ade49511SJames Wright wdetJb *= is_implicit ? -1. : 1.; 421a515125bSLeila Ghaffari 422a515125bSLeila Ghaffari // Normal velocity 423a515125bSLeila Ghaffari const CeedScalar u_normal = norm[0] * u[0] + norm[1] * u[1] + norm[2] * u[2]; 424a515125bSLeila Ghaffari 425a515125bSLeila Ghaffari // No Change in density or momentum 426a515125bSLeila Ghaffari for (CeedInt j = 0; j < 4; j++) { 427a515125bSLeila Ghaffari v[j][i] = 0; 428a515125bSLeila Ghaffari } 429a515125bSLeila Ghaffari // Implementing in/outflow BCs 430a515125bSLeila Ghaffari if (u_normal > 0) { // outflow 431a515125bSLeila Ghaffari v[4][i] = -(1 - strong_form) * wdetJb * E * u_normal; 432a515125bSLeila Ghaffari } else { // inflow 433a515125bSLeila Ghaffari v[4][i] = -(1 - strong_form) * wdetJb * E_wind * u_normal; 434a515125bSLeila Ghaffari } 435a515125bSLeila Ghaffari } // End Quadrature Point Loop 436a515125bSLeila Ghaffari return 0; 437a515125bSLeila Ghaffari } 438a515125bSLeila Ghaffari // ***************************************************************************** 439a515125bSLeila Ghaffari 440a515125bSLeila Ghaffari #endif // advection_h 441