xref: /libCEED/examples/fluids/problems/blasius.c (revision e71202f6ed1f7658a951fb96c00ca70137d558f9) 
1 // Copyright (c) 2017-2022, Lawrence Livermore National Security, LLC and other CEED contributors.
2 // All Rights Reserved. See the top-level LICENSE and NOTICE files for details.
3 //
4 // SPDX-License-Identifier: BSD-2-Clause
5 //
6 // This file is part of CEED:  http://github.com/ceed
7 
8 /// @file
9 /// Utility functions for setting up Blasius Boundary Layer
10 
11 #include "../navierstokes.h"
12 #include "../qfunctions/blasius.h"
13 
14 /* \brief Modify the domain and mesh for blasius
15  *
16  * Modifies mesh such that `N` elements are within 1.2*`delta0` with a geometric
17  * growth ratio of `growth`. Excess elements are then geometrically distributed
18  * to the top surface.
19  *
20  * The top surface is also angled downwards, so that it may be used as an
21  * outflow. It's angle is controlled by top_angle (in units of degrees).
22  */
23 PetscErrorCode modifyMesh(DM dm, PetscInt dim, PetscReal growth, PetscInt N,
24                           PetscReal refine_height, PetscReal top_angle) {
25 
26   PetscInt ierr, narr, ncoords;
27   PetscReal domain_min[3], domain_max[3], domain_size[3];
28   PetscScalar *arr_coords;
29   Vec vec_coords;
30   PetscFunctionBeginUser;
31 
32   PetscReal angle_coeff = tan(top_angle*(M_PI/180));
33 
34   // Get domain boundary information
35   ierr = DMGetBoundingBox(dm, domain_min, domain_max); CHKERRQ(ierr);
36   for (int i=0; i<3; i++) domain_size[i] = domain_max[i] - domain_min[i];
37 
38   // Get coords array from DM
39   ierr = DMGetCoordinatesLocal(dm, &vec_coords); CHKERRQ(ierr);
40   ierr = VecGetLocalSize(vec_coords, &narr); CHKERRQ(ierr);
41   ierr = VecGetArray(vec_coords, &arr_coords); CHKERRQ(ierr);
42 
43   PetscScalar (*coords)[dim] = (PetscScalar(*)[dim]) arr_coords;
44   ncoords = narr/dim;
45 
46   // Get mesh information
47   PetscInt nmax = 3, faces[3];
48   ierr = PetscOptionsGetIntArray(NULL, NULL, "-dm_plex_box_faces", faces, &nmax,
49                                  NULL); CHKERRQ(ierr);
50 
51   // Calculate the first element height
52   PetscReal dybox = domain_size[1]/faces[1];
53   PetscReal dy1   = refine_height*(growth-1)/(pow(growth, N)-1);
54 
55   // Calculate log of sizing outside BL
56   PetscReal logdy = (log(domain_max[1]) - log(refine_height)) / (faces[1] - N);
57 
58   for(int i=0; i<ncoords; i++) {
59     PetscInt y_box_index = round(coords[i][1]/dybox);
60     if(y_box_index <= N) {
61       coords[i][1] = (1 - (coords[i][0]/domain_max[0])*angle_coeff) *
62                      dy1*(pow(growth, coords[i][1]/dybox)-1)/(growth-1);
63     } else {
64       PetscInt j = y_box_index - N;
65       coords[i][1] = (1 - (coords[i][0]/domain_max[0])*angle_coeff) *
66                      exp(log(refine_height) + logdy*j);
67     }
68   }
69 
70   ierr = VecRestoreArray(vec_coords, &arr_coords); CHKERRQ(ierr);
71   ierr = DMSetCoordinatesLocal(dm, vec_coords); CHKERRQ(ierr);
72 
73   PetscFunctionReturn(0);
74 }
75 
76 PetscErrorCode NS_BLASIUS(ProblemData *problem, DM dm, void *ctx) {
77 
78   PetscInt ierr;
79   User              user = *(User *)ctx;
80   MPI_Comm          comm = PETSC_COMM_WORLD;
81   BlasiusContext    blasius_ctx;
82   NewtonianIdealGasContext newtonian_ig_ctx;
83   CeedQFunctionContext blasius_context;
84 
85   PetscFunctionBeginUser;
86   ierr = NS_NEWTONIAN_IG(problem, dm, ctx); CHKERRQ(ierr);
87   ierr = PetscCalloc1(1, &blasius_ctx); CHKERRQ(ierr);
88 
89   // ------------------------------------------------------
90   //               SET UP Blasius
91   // ------------------------------------------------------
92   CeedQFunctionContextDestroy(&problem->ics.qfunction_context);
93   problem->ics.qfunction               = ICsBlasius;
94   problem->ics.qfunction_loc           = ICsBlasius_loc;
95   problem->apply_inflow.qfunction      = Blasius_Inflow;
96   problem->apply_inflow.qfunction_loc  = Blasius_Inflow_loc;
97   problem->apply_outflow.qfunction     = Blasius_Outflow;
98   problem->apply_outflow.qfunction_loc = Blasius_Outflow_loc;
99 
100   // CeedScalar mu = .04; // Pa s, dynamic viscosity
101   CeedScalar Uinf          = 40;   // m/s
102   CeedScalar delta0        = 4.2e-4;    // m
103   PetscReal  refine_height = 5.9e-4;    // m
104   PetscReal  growth        = 1.08; // [-]
105   PetscInt   Ndelta        = 45;   // [-]
106   PetscReal  top_angle     = 5;    // degrees
107   CeedScalar theta0        = 288.; // K
108   CeedScalar P0            = 1.01e5; // Pa
109   PetscBool  weakT         = PETSC_FALSE; // weak density or temperature
110 
111   PetscOptionsBegin(comm, NULL, "Options for CHANNEL problem", NULL);
112   ierr = PetscOptionsBool("-weakT", "Change from rho weak to T weak at inflow",
113                           NULL, weakT, &weakT, NULL); CHKERRQ(ierr);
114   ierr = PetscOptionsScalar("-Uinf", "Velocity at boundary layer edge",
115                             NULL, Uinf, &Uinf, NULL); CHKERRQ(ierr);
116   ierr = PetscOptionsScalar("-delta0", "Boundary layer height at inflow",
117                             NULL, delta0, &delta0, NULL); CHKERRQ(ierr);
118   ierr = PetscOptionsScalar("-theta0", "Wall temperature",
119                             NULL, theta0, &theta0, NULL); CHKERRQ(ierr);
120   ierr = PetscOptionsScalar("-P0", "Pressure at outflow",
121                             NULL, P0, &P0, NULL); CHKERRQ(ierr);
122   ierr = PetscOptionsBoundedInt("-Ndelta", "Velocity at boundary layer edge",
123                                 NULL, Ndelta, &Ndelta, NULL, 1); CHKERRQ(ierr);
124   ierr = PetscOptionsScalar("-refine_height",
125                             "Height of boundary layer mesh refinement",
126                             NULL, refine_height, &refine_height, NULL); CHKERRQ(ierr);
127   ierr = PetscOptionsScalar("-growth",
128                             "Geometric growth rate of boundary layer mesh",
129                             NULL, growth, &growth, NULL); CHKERRQ(ierr);
130   ierr = PetscOptionsScalar("-top_angle",
131                             "Geometric top_angle rate of boundary layer mesh",
132                             NULL, top_angle, &top_angle, NULL); CHKERRQ(ierr);
133   PetscOptionsEnd();
134 
135   PetscScalar meter           = user->units->meter;
136   PetscScalar second          = user->units->second;
137   PetscScalar Kelvin          = user->units->Kelvin;
138   PetscScalar Pascal          = user->units->Pascal;
139 
140   theta0 *= Kelvin;
141   P0     *= Pascal;
142   Uinf   *= meter / second;
143   delta0 *= meter;
144 
145   ierr = modifyMesh(dm, problem->dim, growth, Ndelta, refine_height, top_angle);
146   CHKERRQ(ierr);
147 
148   // Some properties depend on parameters from NewtonianIdealGas
149   CeedQFunctionContextGetData(problem->apply_vol_rhs.qfunction_context,
150                               CEED_MEM_HOST, &newtonian_ig_ctx);
151 
152   blasius_ctx->weakT     = !!weakT;
153   blasius_ctx->Uinf      = Uinf;
154   blasius_ctx->delta0    = delta0;
155   blasius_ctx->theta0    = theta0;
156   blasius_ctx->P0        = P0;
157   blasius_ctx->implicit  = user->phys->implicit;
158   blasius_ctx->newtonian_ctx = *newtonian_ig_ctx;
159   CeedQFunctionContextRestoreData(problem->apply_vol_rhs.qfunction_context,
160                                   &newtonian_ig_ctx);
161 
162   CeedQFunctionContextCreate(user->ceed, &blasius_context);
163   CeedQFunctionContextSetData(blasius_context, CEED_MEM_HOST,
164                               CEED_USE_POINTER,
165                               sizeof(*blasius_ctx), blasius_ctx);
166   CeedQFunctionContextSetDataDestroy(blasius_context, CEED_MEM_HOST,
167                                      FreeContextPetsc);
168 
169   problem->ics.qfunction_context = blasius_context;
170   CeedQFunctionContextReferenceCopy(blasius_context,
171                                     &problem->apply_inflow.qfunction_context);
172   CeedQFunctionContextReferenceCopy(blasius_context,
173                                     &problem->apply_outflow.qfunction_context);
174   PetscFunctionReturn(0);
175 }
176