1965d9f74SJames Wright# Runtime options 2965d9f74SJames Wright 3965d9f74SJames Wright## Common Options 4ce03971bSJames WrightThe Navier-Stokes HONEE app is controlled via command-line options. 5965d9f74SJames WrightThe following options are common among all problem types: 6965d9f74SJames Wright 7965d9f74SJames Wright:::{list-table} Common Runtime Options 8965d9f74SJames Wright:header-rows: 1 9965d9f74SJames Wright 10965d9f74SJames Wright* - Option 11965d9f74SJames Wright - Description 12965d9f74SJames Wright - Default value 13965d9f74SJames Wright 14965d9f74SJames Wright* - `-ceed` 15965d9f74SJames Wright - CEED resource specifier 16965d9f74SJames Wright - `/cpu/self/opt/blocked` 17965d9f74SJames Wright 18965d9f74SJames Wright* - `-problem` 19965d9f74SJames Wright - Problem to solve (`advection`, `density_current`, `euler_vortex`, `shocktube`, `blasius`, `channel`, `gaussian_wave`, and `taylor_green`) 20965d9f74SJames Wright - `density_current` 21965d9f74SJames Wright 22965d9f74SJames Wright* - `-implicit` 23965d9f74SJames Wright - Use implicit time integrator formulation 24965d9f74SJames Wright - 25965d9f74SJames Wright 26965d9f74SJames Wright* - `-degree` 27965d9f74SJames Wright - Polynomial degree of tensor product basis (must be >= 1) 28965d9f74SJames Wright - `1` 29965d9f74SJames Wright 30965d9f74SJames Wright* - `-q_extra` 31965d9f74SJames Wright - Number of extra quadrature points 32965d9f74SJames Wright - `0` 33965d9f74SJames Wright 34965d9f74SJames Wright* - `-ts_monitor_solution` 35965d9f74SJames Wright - PETSc output format, such as `cgns:output-%d.cgns` (requires PETSc `--download-cgns`) 36965d9f74SJames Wright - 37965d9f74SJames Wright 38965d9f74SJames Wright* - `-ts_monitor_solution_interval` 39965d9f74SJames Wright - Number of time steps between visualization output frames. 40965d9f74SJames Wright - `1` 41965d9f74SJames Wright 42965d9f74SJames Wright* - `-viewer_cgns_batch_size` 43965d9f74SJames Wright - Number of frames written per CGNS file if the CGNS file name includes a format specifier (`%d`). 44965d9f74SJames Wright - `20` 45965d9f74SJames Wright 46965d9f74SJames Wright* - `-checkpoint_interval` 47965d9f74SJames Wright - Number of steps between writing binary checkpoints. `0` has no output, `-1` outputs final state only 48965d9f74SJames Wright - `10` 49965d9f74SJames Wright 50965d9f74SJames Wright* - `-checkpoint_vtk` 51965d9f74SJames Wright - Checkpoints include VTK (`*.vtu`) files for visualization. Consider `-ts_monitor_solution`instead. 52965d9f74SJames Wright - `false` 53965d9f74SJames Wright 54965d9f74SJames Wright* - `-viz_refine` 55965d9f74SJames Wright - Use regular refinement for VTK visualization 56965d9f74SJames Wright - `0` 57965d9f74SJames Wright 58965d9f74SJames Wright* - `-output_dir` 59965d9f74SJames Wright - Output directory for binary checkpoints and VTK files (if enabled). 60965d9f74SJames Wright - `.` 61965d9f74SJames Wright 62965d9f74SJames Wright* - `-output_add_stepnum2bin` 63965d9f74SJames Wright - Whether to add step numbers to output binary files 64965d9f74SJames Wright - `false` 65965d9f74SJames Wright 66965d9f74SJames Wright* - `-continue` 67965d9f74SJames Wright - Continue from previous solution (input is step number of previous solution) 68965d9f74SJames Wright - `0` 69965d9f74SJames Wright 70965d9f74SJames Wright* - `-continue_filename` 71965d9f74SJames Wright - Path to solution binary file from which to continue from 72965d9f74SJames Wright - `[output_dir]/ns-solution.bin` 73965d9f74SJames Wright 74965d9f74SJames Wright* - `-continue_time_filename` 75965d9f74SJames Wright - Path to time stamp binary file (only for legacy checkpoints) 76965d9f74SJames Wright - `[output_dir]/ns-time.bin` 77965d9f74SJames Wright 78965d9f74SJames Wright* - `-bc_wall` 79965d9f74SJames Wright - Use wall boundary conditions on this list of faces 80965d9f74SJames Wright - 81965d9f74SJames Wright 82965d9f74SJames Wright* - `-wall_comps` 83965d9f74SJames Wright - An array of constrained component numbers for wall BCs 84965d9f74SJames Wright - 85965d9f74SJames Wright 86965d9f74SJames Wright* - `-bc_slip` 87965d9f74SJames Wright - Use weak slip boundary condition on this list of faces 88965d9f74SJames Wright - 89965d9f74SJames Wright 90965d9f74SJames Wright* - `-bc_symmetry_x` 91965d9f74SJames Wright - Use symmetry boundary conditions, for the x component, on this list of faces 92965d9f74SJames Wright - 93965d9f74SJames Wright 94965d9f74SJames Wright* - `-bc_symmetry_y` 95965d9f74SJames Wright - Use symmetry boundary conditions, for the y component, on this list of faces 96965d9f74SJames Wright - 97965d9f74SJames Wright 98965d9f74SJames Wright* - `-bc_symmetry_z` 99965d9f74SJames Wright - Use symmetry boundary conditions, for the z component, on this list of faces 100965d9f74SJames Wright - 101965d9f74SJames Wright 102965d9f74SJames Wright* - `-bc_inflow` 103965d9f74SJames Wright - Use inflow boundary conditions on this list of faces 104965d9f74SJames Wright - 105965d9f74SJames Wright 106965d9f74SJames Wright* - `-bc_outflow` 107965d9f74SJames Wright - Use outflow boundary conditions on this list of faces 108965d9f74SJames Wright - 109965d9f74SJames Wright 110965d9f74SJames Wright* - `-bc_freestream` 111965d9f74SJames Wright - Use freestream boundary conditions on this list of faces 112965d9f74SJames Wright - 113965d9f74SJames Wright 114965d9f74SJames Wright* - `-ts_monitor_turbulence_spanstats_collect_interval` 115965d9f74SJames Wright - Number of timesteps between statistics collection 116965d9f74SJames Wright - `1` 117965d9f74SJames Wright 118965d9f74SJames Wright* - `-ts_monitor_turbulence_spanstats_viewer` 119965d9f74SJames Wright - Sets the PetscViewer for the statistics file writing, such as `cgns:output-%d.cgns` (requires PETSc `--download-cgns`). Also turns the statistics collection on. 120965d9f74SJames Wright - 121965d9f74SJames Wright 122965d9f74SJames Wright* - `-ts_monitor_turbulence_spanstats_viewer_interval` 123965d9f74SJames Wright - Number of timesteps between statistics file writing (`-1` means only at end of run) 124965d9f74SJames Wright - `-1` 125965d9f74SJames Wright 126965d9f74SJames Wright* - `-ts_monitor_turbulence_spanstats_viewer_cgns_batch_size` 127965d9f74SJames Wright - Number of frames written per CGNS file if the CGNS file name includes a format specifier (`%d`). 128965d9f74SJames Wright - `20` 129965d9f74SJames Wright 130965d9f74SJames Wright* - `-ts_monitor_wall_force` 131965d9f74SJames Wright - Viewer for the force on each no-slip wall, e.g., `ascii:force.csv:ascii_csv` to write a CSV file. 132965d9f74SJames Wright - 133965d9f74SJames Wright 134965d9f74SJames Wright* - `-mesh_transform` 135965d9f74SJames Wright - Transform the mesh, usually for an initial box mesh. 136965d9f74SJames Wright - `none` 137965d9f74SJames Wright 138965d9f74SJames Wright* - `-snes_view` 139965d9f74SJames Wright - View PETSc `SNES` nonlinear solver configuration 140965d9f74SJames Wright - 141965d9f74SJames Wright 142965d9f74SJames Wright* - `-log_view` 143965d9f74SJames Wright - View PETSc performance log 144965d9f74SJames Wright - 145965d9f74SJames Wright 146965d9f74SJames Wright* - `-help` 147965d9f74SJames Wright - View comprehensive information about run-time options 148965d9f74SJames Wright - 149ce03971bSJames Wright 150ce03971bSJames Wright* - `-test_type` 151ce03971bSJames Wright - Run in test mode and specify whether solution (`solver`) or turbulent statistics (`turb_spanstats`) output should be verified 152ce03971bSJames Wright - `none` 153ce03971bSJames Wright 154ce03971bSJames Wright* - `-compare_final_state_atol` 155ce03971bSJames Wright - Test absolute tolerance 156ce03971bSJames Wright - `1E-11` 157ce03971bSJames Wright 158ce03971bSJames Wright* - `-compare_final_state_filename` 159ce03971bSJames Wright - Test filename 160ce03971bSJames Wright - 161ce03971bSJames Wright 162965d9f74SJames Wright::: 163965d9f74SJames Wright 164965d9f74SJames WrightFor the case of a square/cubic mesh, the list of face indices to be used with `-bc_wall`, `bc_inflow`, `bc_outflow`, `bc_freestream` and/or `-bc_symmetry_x`, `-bc_symmetry_y`, and `-bc_symmetry_z` are: 165965d9f74SJames Wright 166965d9f74SJames Wright:::{list-table} 2D Face ID Labels 167965d9f74SJames Wright:header-rows: 1 168965d9f74SJames Wright* - PETSc Face Name 169965d9f74SJames Wright - Cartesian direction 170965d9f74SJames Wright - Face ID 171965d9f74SJames Wright 172965d9f74SJames Wright* - faceMarkerBottom 173965d9f74SJames Wright - -z 174965d9f74SJames Wright - 1 175965d9f74SJames Wright 176965d9f74SJames Wright* - faceMarkerRight 177965d9f74SJames Wright - +x 178965d9f74SJames Wright - 2 179965d9f74SJames Wright 180965d9f74SJames Wright* - faceMarkerTop 181965d9f74SJames Wright - +z 182965d9f74SJames Wright - 3 183965d9f74SJames Wright 184965d9f74SJames Wright* - faceMarkerLeft 185965d9f74SJames Wright - -x 186965d9f74SJames Wright - 4 187965d9f74SJames Wright::: 188965d9f74SJames Wright 189965d9f74SJames Wright:::{list-table} 3D Face ID Labels 190965d9f74SJames Wright:header-rows: 1 191965d9f74SJames Wright* - PETSc Face Name 192965d9f74SJames Wright - Cartesian direction 193965d9f74SJames Wright - Face ID 194965d9f74SJames Wright 195965d9f74SJames Wright* - faceMarkerBottom 196965d9f74SJames Wright - -z 197965d9f74SJames Wright - 1 198965d9f74SJames Wright 199965d9f74SJames Wright* - faceMarkerTop 200965d9f74SJames Wright - +z 201965d9f74SJames Wright - 2 202965d9f74SJames Wright 203965d9f74SJames Wright* - faceMarkerFront 204965d9f74SJames Wright - -y 205965d9f74SJames Wright - 3 206965d9f74SJames Wright 207965d9f74SJames Wright* - faceMarkerBack 208965d9f74SJames Wright - +y 209965d9f74SJames Wright - 4 210965d9f74SJames Wright 211965d9f74SJames Wright* - faceMarkerRight 212965d9f74SJames Wright - +x 213965d9f74SJames Wright - 5 214965d9f74SJames Wright 215965d9f74SJames Wright* - faceMarkerLeft 216965d9f74SJames Wright - -x 217965d9f74SJames Wright - 6 218965d9f74SJames Wright::: 219965d9f74SJames Wright 220965d9f74SJames Wright## Boundary conditions 221965d9f74SJames Wright 222965d9f74SJames WrightBoundary conditions for compressible viscous flows are notoriously tricky. 223965d9f74SJames WrightHere we offer some recommendations. 224965d9f74SJames Wright 225965d9f74SJames Wright### Inflow 226965d9f74SJames Wright 227965d9f74SJames WrightIf in a region where the flow velocity is known (e.g., away from viscous walls), use `bc_freestream`, which solves a Riemann problem and can handle inflow and outflow (simultaneously and dynamically). 228965d9f74SJames WrightIt is stable and the least reflective boundary condition for acoustics. 229965d9f74SJames Wright 230965d9f74SJames WrightIf near a viscous wall, you may want a specified inflow profile. 231965d9f74SJames WrightUse `bc_inflow` and see {ref}`example-blasius` and discussion of synthetic turbulence generation for ways to analytically generate developed inflow profiles. 232965d9f74SJames WrightThese conditions may be either weak or strong, with the latter specifying velocity and temperature as essential boundary conditions and evaluating a boundary integral for the mass flux. 233965d9f74SJames WrightThe strong approach gives sharper resolution of velocity structures. 234965d9f74SJames WrightWe have described the primitive variable formulation here; the conservative variants are similar, but not equivalent. 235965d9f74SJames Wright 236965d9f74SJames Wright### Outflow 237965d9f74SJames Wright 238965d9f74SJames WrightIf you know the complete exterior state, `bc_freestream` is the least reflective boundary condition, but is disruptive to viscous flow structures. 239965d9f74SJames WrightIf thermal anomalies must exit the domain, the Riemann solver must resolve the contact wave to avoid reflections. 240965d9f74SJames WrightThe default Riemann solver, HLLC, is sufficient in this regard while the simpler HLL converts thermal structures exiting the domain into grid-scale reflecting acoustics. 241965d9f74SJames Wright 242965d9f74SJames WrightIf acoustic reflections are not a concern and/or the flow is impacted by walls or interior structures that you wish to resolve to near the boundary, choose `bc_outflow`. This condition (with default `outflow_type: riemann`) is stable for both inflow and outflow, so can be used in areas that have recirculation and lateral boundaries in which the flow fluctuates. 243965d9f74SJames Wright 244965d9f74SJames WrightThe simpler `bc_outflow` variant, `outflow_type: pressure`, requires that the flow be a strict outflow (or the problem becomes ill-posed and the solver will diverge). 245965d9f74SJames WrightIn our experience, `riemann` is slightly less reflective but produces similar flows in cases of strict outflow. 246965d9f74SJames WrightThe `pressure` variant is retained to facilitate comparison with other codes, such as PHASTA-C, but we recommend `riemann` for general use. 247965d9f74SJames Wright 248965d9f74SJames Wright### Periodicity 249965d9f74SJames Wright 250965d9f74SJames WrightPETSc provides two ways to specify periodicity: 251965d9f74SJames Wright 252965d9f74SJames Wright1. Topological periodicity, in which the donor and receiver dofs are the same, obtained using: 253965d9f74SJames Wright 254965d9f74SJames Wright```yaml 255965d9f74SJames Wrightdm_plex: 256965d9f74SJames Wright shape: box 257965d9f74SJames Wright box_faces: 10,12,4 258965d9f74SJames Wright box_bd: none,none,periodic 259965d9f74SJames Wright``` 260965d9f74SJames Wright 261965d9f74SJames WrightThe coordinates for such cases are stored as a new field with special cell-based indexing to enable wrapping through the boundary. 262965d9f74SJames WrightThis choice of coordinates prevents evaluating boundary integrals that cross the periodicity, such as for the outflow Riemann problem in the presence of spanwise periodicity. 263965d9f74SJames Wright 264965d9f74SJames Wright2. Isoperiodicity, in which the donor and receiver dofs are distinct in local vectors. This is obtained using `zbox`, as in: 265965d9f74SJames Wright 266965d9f74SJames Wright```yaml 267965d9f74SJames Wrightdm_plex: 268965d9f74SJames Wright shape: zbox 269965d9f74SJames Wright box_faces: 10,12,4 270965d9f74SJames Wright box_bd: none,none,periodic 271965d9f74SJames Wright``` 272965d9f74SJames Wright 273965d9f74SJames WrightIsoperiodicity enables standard boundary integrals, and is recommended for general use. 274965d9f74SJames WrightAt the time of this writing, it only supports one direction of periodicity. 275965d9f74SJames WrightThe `zbox` method uses [Z-ordering](https://en.wikipedia.org/wiki/Z-order_curve) to construct the mesh in parallel and provide an adequate initial partition, which makes it higher performance and avoids needing a partitioning package. 276965d9f74SJames Wright 277da02a6e7SJames Wright## Advection-Diffusion 278965d9f74SJames Wright 279da02a6e7SJames WrightThere is a reduced mode for pure advection, which holds density $\rho$ and momentum density $\rho \bm u$ constant while advecting "total energy density" $E$. 280965d9f74SJames WrightThe advection problems can be run in both 2D and 3D, based on the DM defined for the problem. 281965d9f74SJames WrightThe following additional command-line options are available: 282965d9f74SJames Wright 283965d9f74SJames Wright:::{list-table} Advection Runtime Options 284965d9f74SJames Wright:header-rows: 1 285965d9f74SJames Wright 286965d9f74SJames Wright* - Option 287965d9f74SJames Wright - Description 288965d9f74SJames Wright - Default value 289965d9f74SJames Wright - Unit 290965d9f74SJames Wright 291965d9f74SJames Wright* - `-rc` 292965d9f74SJames Wright - Characteristic radius of thermal bubble 293965d9f74SJames Wright - `1000` 294965d9f74SJames Wright - `m` 295965d9f74SJames Wright 296965d9f74SJames Wright* - `-units_meter` 297965d9f74SJames Wright - 1 meter in scaled length units 298965d9f74SJames Wright - `1E-2` 299965d9f74SJames Wright - 300965d9f74SJames Wright 301965d9f74SJames Wright* - `-units_second` 302965d9f74SJames Wright - 1 second in scaled time units 303965d9f74SJames Wright - `1E-2` 304965d9f74SJames Wright - 305965d9f74SJames Wright 306965d9f74SJames Wright* - `-units_kilogram` 307965d9f74SJames Wright - 1 kilogram in scaled mass units 308965d9f74SJames Wright - `1E-6` 309965d9f74SJames Wright - 310965d9f74SJames Wright 311965d9f74SJames Wright* - `-strong_form` 312965d9f74SJames Wright - Strong (1) or weak/integrated by parts (0) residual 313965d9f74SJames Wright - `0` 314965d9f74SJames Wright - 315965d9f74SJames Wright 316965d9f74SJames Wright* - `-stab` 317965d9f74SJames Wright - Stabilization method (`none`, `su`, or `supg`) 318965d9f74SJames Wright - `none` 319965d9f74SJames Wright - 320965d9f74SJames Wright 321965d9f74SJames Wright* - `-stab_tau` 322965d9f74SJames Wright - Formulation for $\tau$ in stabilization (`ctau`, `advdiff_shakib`) 323965d9f74SJames Wright - `ctau` 324965d9f74SJames Wright - 325965d9f74SJames Wright 326965d9f74SJames Wright* - `-Ctau_t` 327965d9f74SJames Wright - Scaling factor on the temporal portion of the $\tau$ formulation 328965d9f74SJames Wright - 0. 329965d9f74SJames Wright - 330965d9f74SJames Wright 331965d9f74SJames Wright* - `-Ctau_a` 332965d9f74SJames Wright - Scaling factor on the advection portion of the $\tau$ formulation 333965d9f74SJames Wright - $P^2$ 334965d9f74SJames Wright - 335965d9f74SJames Wright 336fbabb365SJames Wright* - `-Ctau_d` 337fbabb365SJames Wright - Scaling factor on the diffusion portion of the $\tau$ formulation 338fbabb365SJames Wright - $P^4$ 339fbabb365SJames Wright - 340fbabb365SJames Wright 341965d9f74SJames Wright* - `-CtauS` 342965d9f74SJames Wright - Scale coefficient for stabilization tau (nondimensional) 343965d9f74SJames Wright - `0` 344965d9f74SJames Wright - 345965d9f74SJames Wright 346965d9f74SJames Wright* - `-wind_type` 3473d1afcc1SJames Wright - Wind type in Advection (`rotation`, `translation`, `boundary_layer`) 348965d9f74SJames Wright - `rotation` 349965d9f74SJames Wright - 350965d9f74SJames Wright 351965d9f74SJames Wright* - `-wind_translation` 352965d9f74SJames Wright - Constant wind vector when `-wind_type translation` 353965d9f74SJames Wright - `1,0,0` 354965d9f74SJames Wright - 355965d9f74SJames Wright 356965d9f74SJames Wright* - `-diffusion_coeff` 357965d9f74SJames Wright - Diffusion coefficient 358965d9f74SJames Wright - `0` 359965d9f74SJames Wright - 360965d9f74SJames Wright 361965d9f74SJames Wright* - `-E_wind` 362965d9f74SJames Wright - Total energy of inflow wind when `-wind_type translation` 363965d9f74SJames Wright - `1E6` 364965d9f74SJames Wright - `J` 365965d9f74SJames Wright 366965d9f74SJames Wright* - `-advection_ic_type` 3673d1afcc1SJames Wright - Initial condition type, (`sphere`, `cylinder`, `cosine_hill`, `skew`, `wave`, `boundary_layer`) 368965d9f74SJames Wright - `sphere` 369965d9f74SJames Wright - 370965d9f74SJames Wright 371965d9f74SJames Wright* - `-bubble_continuity` 372965d9f74SJames Wright - Different shapes for `sphere` and `cylinder` initial conditions, from `smooth`, `back_sharp`, `thick`, or `cosine` 373965d9f74SJames Wright - `smooth` 374965d9f74SJames Wright - 375da02a6e7SJames Wright 376da02a6e7SJames Wright* - `-wave_type` 377da02a6e7SJames Wright - The wave form used for `-advection_ic_type wave` (`sine`, `square`) 378da02a6e7SJames Wright - `sine` 379da02a6e7SJames Wright - 380da02a6e7SJames Wright 381da02a6e7SJames Wright* - `-wave_frequency` 382da02a6e7SJames Wright - Frequency of the wave 383da02a6e7SJames Wright - $2\pi$ 384da02a6e7SJames Wright - `1/s` 385da02a6e7SJames Wright 386da02a6e7SJames Wright* - `-wave_phase` 387da02a6e7SJames Wright - Phase angle of the wave 388da02a6e7SJames Wright - $2\pi$ 389da02a6e7SJames Wright - 390*b4fd18dfSJames Wright 391*b4fd18dfSJames Wright* - `-bl_height_factor` 392*b4fd18dfSJames Wright - For `boundary_layer` IC, sets the height of the linear boundary layer initial condition in proportion to the domain height 393*b4fd18dfSJames Wright - $1$ 394*b4fd18dfSJames Wright - 395965d9f74SJames Wright::: 396965d9f74SJames Wright 397965d9f74SJames WrightFor 3D advection, an example of the `rotation` mode can be run with: 398965d9f74SJames Wright 399965d9f74SJames Wright``` 400965d9f74SJames Wright./navierstokes -problem advection -dm_plex_box_faces 10,10,10 -dm_plex_dim 3 -dm_plex_box_lower 0,0,0 -dm_plex_box_upper 8000,8000,8000 -bc_wall 1,2,3,4,5,6 -wall_comps 4 -wind_type rotation -implicit -stab su 401965d9f74SJames Wright``` 402965d9f74SJames Wright 403965d9f74SJames Wrightand the `translation` mode with: 404965d9f74SJames Wright 405965d9f74SJames Wright``` 406965d9f74SJames Wright./navierstokes -problem advection -dm_plex_box_faces 10,10,10 -dm_plex_dim 3 -dm_plex_box_lower 0,0,0 -dm_plex_box_upper 8000,8000,8000 -wind_type translation -wind_translation .5,-1,0 -bc_inflow 1,2,3,4,5,6 407965d9f74SJames Wright``` 408965d9f74SJames Wright 409965d9f74SJames WrightFor 2D advection, an example of the `rotation` mode can be run with: 410965d9f74SJames Wright 411965d9f74SJames Wright``` 412965d9f74SJames Wright./navierstokes -problem advection -dm_plex_box_faces 20,20 -dm_plex_box_lower 0,0 -dm_plex_box_upper 1000,1000 -bc_wall 1,2,3,4 -wall_comps 4 -wind_type rotation -implicit -stab supg 413965d9f74SJames Wright``` 414965d9f74SJames Wright 415965d9f74SJames Wrightand the `translation` mode with: 416965d9f74SJames Wright 417965d9f74SJames Wright``` 418965d9f74SJames Wright./navierstokes -problem advection -dm_plex_box_faces 20,20 -dm_plex_box_lower 0,0 -dm_plex_box_upper 1000,1000 -units_meter 1e-4 -wind_type translation -wind_translation 1,-.5 -bc_inflow 1,2,3,4 419965d9f74SJames Wright``` 420965d9f74SJames WrightNote the lengths in `-dm_plex_box_upper` are given in meters, and will be nondimensionalized according to `-units_meter`. 421965d9f74SJames Wright 422965d9f74SJames Wright## Inviscid Ideal Gas 423965d9f74SJames Wright 424965d9f74SJames Wright### Isentropic Euler vortex 425965d9f74SJames Wright 426965d9f74SJames WrightFor the Isentropic Vortex problem, the following additional command-line options are available: 427965d9f74SJames Wright 428965d9f74SJames Wright:::{list-table} Isentropic Vortex Runtime Options 429965d9f74SJames Wright:header-rows: 1 430965d9f74SJames Wright 431965d9f74SJames Wright* - Option 432965d9f74SJames Wright - Description 433965d9f74SJames Wright - Default value 434965d9f74SJames Wright - Unit 435965d9f74SJames Wright 436965d9f74SJames Wright* - `-center` 437965d9f74SJames Wright - Location of vortex center 438965d9f74SJames Wright - `(lx,ly,lz)/2` 439965d9f74SJames Wright - `(m,m,m)` 440965d9f74SJames Wright 441965d9f74SJames Wright* - `-units_meter` 442965d9f74SJames Wright - 1 meter in scaled length units 443965d9f74SJames Wright - `1E-2` 444965d9f74SJames Wright - 445965d9f74SJames Wright 446965d9f74SJames Wright* - `-units_second` 447965d9f74SJames Wright - 1 second in scaled time units 448965d9f74SJames Wright - `1E-2` 449965d9f74SJames Wright - 450965d9f74SJames Wright 451965d9f74SJames Wright* - `-mean_velocity` 452965d9f74SJames Wright - Background velocity vector 453965d9f74SJames Wright - `(1,1,0)` 454965d9f74SJames Wright - 455965d9f74SJames Wright 456965d9f74SJames Wright* - `-vortex_strength` 457965d9f74SJames Wright - Strength of vortex < 10 458965d9f74SJames Wright - `5` 459965d9f74SJames Wright - 460965d9f74SJames Wright 461965d9f74SJames Wright* - `-c_tau` 462965d9f74SJames Wright - Stabilization constant 463965d9f74SJames Wright - `0.5` 464965d9f74SJames Wright - 465965d9f74SJames Wright::: 466965d9f74SJames Wright 467965d9f74SJames WrightThis problem can be run with: 468965d9f74SJames Wright 469965d9f74SJames Wright``` 470965d9f74SJames Wright./navierstokes -problem euler_vortex -dm_plex_box_faces 20,20,1 -dm_plex_box_lower 0,0,0 -dm_plex_box_upper 1000,1000,50 -dm_plex_dim 3 -bc_inflow 4,6 -bc_outflow 3,5 -bc_symmetry_z 1,2 -mean_velocity .5,-.8,0. 471965d9f74SJames Wright``` 472965d9f74SJames Wright 473965d9f74SJames Wright### Sod shock tube 474965d9f74SJames Wright 475965d9f74SJames WrightFor the Shock Tube problem, the following additional command-line options are available: 476965d9f74SJames Wright 477965d9f74SJames Wright:::{list-table} Shock Tube Runtime Options 478965d9f74SJames Wright:header-rows: 1 479965d9f74SJames Wright 480965d9f74SJames Wright* - Option 481965d9f74SJames Wright - Description 482965d9f74SJames Wright - Default value 483965d9f74SJames Wright - Unit 484965d9f74SJames Wright 485965d9f74SJames Wright* - `-units_meter` 486965d9f74SJames Wright - 1 meter in scaled length units 487965d9f74SJames Wright - `1E-2` 488965d9f74SJames Wright - 489965d9f74SJames Wright 490965d9f74SJames Wright* - `-units_second` 491965d9f74SJames Wright - 1 second in scaled time units 492965d9f74SJames Wright - `1E-2` 493965d9f74SJames Wright - 494965d9f74SJames Wright 495965d9f74SJames Wright* - `-yzb` 496965d9f74SJames Wright - Use YZB discontinuity capturing 497965d9f74SJames Wright - `none` 498965d9f74SJames Wright - 499965d9f74SJames Wright 500965d9f74SJames Wright* - `-stab` 501965d9f74SJames Wright - Stabilization method (`none`, `su`, or `supg`) 502965d9f74SJames Wright - `none` 503965d9f74SJames Wright - 504965d9f74SJames Wright::: 505965d9f74SJames Wright 506965d9f74SJames WrightThis problem can be run with: 507965d9f74SJames Wright 508965d9f74SJames Wright``` 509965d9f74SJames Wright./navierstokes -problem shocktube -yzb -stab su -bc_symmetry_z 3,4 -bc_symmetry_y 1,2 -bc_wall 5,6 -dm_plex_dim 3 -dm_plex_box_lower 0,0,0 -dm_plex_box_upper 1000,100,100 -dm_plex_box_faces 200,1,1 -units_second 0.1 510965d9f74SJames Wright``` 511965d9f74SJames Wright 512965d9f74SJames Wright## Newtonian viscosity, Ideal Gas 513965d9f74SJames Wright 514965d9f74SJames WrightFor the Density Current, Channel, and Blasius problems, the following common command-line options are available: 515965d9f74SJames Wright 516965d9f74SJames Wright:::{list-table} Newtonian Ideal Gas problems Runtime Options 517965d9f74SJames Wright:header-rows: 1 518965d9f74SJames Wright 519965d9f74SJames Wright* - Option 520965d9f74SJames Wright - Description 521965d9f74SJames Wright - Default value 522965d9f74SJames Wright - Unit 523965d9f74SJames Wright 524965d9f74SJames Wright* - `-units_meter` 525965d9f74SJames Wright - 1 meter in scaled length units 526965d9f74SJames Wright - `1` 527965d9f74SJames Wright - 528965d9f74SJames Wright 529965d9f74SJames Wright* - `-units_second` 530965d9f74SJames Wright - 1 second in scaled time units 531965d9f74SJames Wright - `1` 532965d9f74SJames Wright - 533965d9f74SJames Wright 534965d9f74SJames Wright* - `-units_kilogram` 535965d9f74SJames Wright - 1 kilogram in scaled mass units 536965d9f74SJames Wright - `1` 537965d9f74SJames Wright - 538965d9f74SJames Wright 539965d9f74SJames Wright* - `-units_Kelvin` 540965d9f74SJames Wright - 1 Kelvin in scaled temperature units 541965d9f74SJames Wright - `1` 542965d9f74SJames Wright - 543965d9f74SJames Wright 544965d9f74SJames Wright* - `-stab` 545965d9f74SJames Wright - Stabilization method (`none`, `su`, or `supg`) 546965d9f74SJames Wright - `none` 547965d9f74SJames Wright - 548965d9f74SJames Wright 549965d9f74SJames Wright* - `-c_tau` 550965d9f74SJames Wright - Stabilization constant, $c_\tau$ 551965d9f74SJames Wright - `0.5` 552965d9f74SJames Wright - 553965d9f74SJames Wright 554965d9f74SJames Wright* - `-Ctau_t` 555965d9f74SJames Wright - Stabilization time constant, $C_t$ 556965d9f74SJames Wright - `1.0` 557965d9f74SJames Wright - 558965d9f74SJames Wright 559965d9f74SJames Wright* - `-Ctau_v` 560965d9f74SJames Wright - Stabilization viscous constant, $C_v$ 561965d9f74SJames Wright - `36, 60, 128 for degree = 1, 2, 3` 562965d9f74SJames Wright - 563965d9f74SJames Wright 564965d9f74SJames Wright* - `-Ctau_C` 565965d9f74SJames Wright - Stabilization continuity constant, $C_c$ 566965d9f74SJames Wright - `1.0` 567965d9f74SJames Wright - 568965d9f74SJames Wright 569965d9f74SJames Wright* - `-Ctau_M` 570965d9f74SJames Wright - Stabilization momentum constant, $C_m$ 571965d9f74SJames Wright - `1.0` 572965d9f74SJames Wright - 573965d9f74SJames Wright 574965d9f74SJames Wright* - `-Ctau_E` 575965d9f74SJames Wright - Stabilization energy constant, $C_E$ 576965d9f74SJames Wright - `1.0` 577965d9f74SJames Wright - 578965d9f74SJames Wright 579cbdfeaf4SJames Wright* - `-div_diff_flux_projection_method` 580cbdfeaf4SJames Wright - Method used to calculate divergence of diffusive flux projection (`none`, `direct`, or `indirect`) 581cbdfeaf4SJames Wright - `none` 582cbdfeaf4SJames Wright - 583cbdfeaf4SJames Wright 584cbdfeaf4SJames Wright* - `-div_diff_flux_projection_ksp*` 585cbdfeaf4SJames Wright - Control the KSP object for the projection of the divergence of diffusive flux 586cbdfeaf4SJames Wright - N/A 587cbdfeaf4SJames Wright - 588cbdfeaf4SJames Wright 589965d9f74SJames Wright* - `-cv` 590965d9f74SJames Wright - Heat capacity at constant volume 591965d9f74SJames Wright - `717` 592965d9f74SJames Wright - `J/(kg K)` 593965d9f74SJames Wright 594965d9f74SJames Wright* - `-cp` 595965d9f74SJames Wright - Heat capacity at constant pressure 596965d9f74SJames Wright - `1004` 597965d9f74SJames Wright - `J/(kg K)` 598965d9f74SJames Wright 599965d9f74SJames Wright* - `-gravity` 600965d9f74SJames Wright - Gravitational acceleration vector 601965d9f74SJames Wright - `0,0,0` 602965d9f74SJames Wright - `m/s^2` 603965d9f74SJames Wright 604965d9f74SJames Wright* - `-lambda` 605965d9f74SJames Wright - Stokes hypothesis second viscosity coefficient 606965d9f74SJames Wright - `-2/3` 607965d9f74SJames Wright - 608965d9f74SJames Wright 609965d9f74SJames Wright* - `-mu` 610965d9f74SJames Wright - Shear dynamic viscosity coefficient 611965d9f74SJames Wright - `1.8e-5` 612965d9f74SJames Wright - `Pa s` 613965d9f74SJames Wright 614965d9f74SJames Wright* - `-k` 615965d9f74SJames Wright - Thermal conductivity 616965d9f74SJames Wright - `0.02638` 617965d9f74SJames Wright - `W/(m K)` 618965d9f74SJames Wright 619965d9f74SJames Wright* - `-newtonian_unit_tests` 620965d9f74SJames Wright - Developer option to test properties 621965d9f74SJames Wright - `false` 622965d9f74SJames Wright - boolean 623965d9f74SJames Wright 624965d9f74SJames Wright* - `-state_var` 625965d9f74SJames Wright - State variables to solve solution with. `conservative` ($\rho, \rho \bm{u}, \rho e$), `primitive` ($P, \bm{u}, T$), or `entropy` ($\frac{\gamma - s}{\gamma - 1} - \frac{\rho}{P} (e - c_v T),\ \frac{\rho}{P} \bm{u},\ -\frac{\rho}{P}$) where $s = \ln(P\rho^{-\gamma})$ 626965d9f74SJames Wright - `conservative` 627965d9f74SJames Wright - string 628965d9f74SJames Wright 629965d9f74SJames Wright* - `-idl_decay_time` 630965d9f74SJames Wright - Characteristic timescale of the pressure deviance decay. The timestep is good starting point 631965d9f74SJames Wright - `-1` (disabled) 632965d9f74SJames Wright - `s` 633965d9f74SJames Wright 634965d9f74SJames Wright* - `-idl_start` 635965d9f74SJames Wright - Start of IDL in the x direction 636965d9f74SJames Wright - `0` 637965d9f74SJames Wright - `m` 638965d9f74SJames Wright 639965d9f74SJames Wright* - `-idl_length` 640965d9f74SJames Wright - Length of IDL in the positive x direction 641965d9f74SJames Wright - `0` 642965d9f74SJames Wright - `m` 643965d9f74SJames Wright 644965d9f74SJames Wright* - `-idl_pressure` 645965d9f74SJames Wright - Pressure used for IDL reference pressure 646965d9f74SJames Wright - `-reference_pressure` 647965d9f74SJames Wright - `Pa` 648965d9f74SJames Wright 649965d9f74SJames Wright* - `-sgs_model_type` 650965d9f74SJames Wright - Type of subgrid stress model to use. Currently only `data_driven` is available 651965d9f74SJames Wright - `none` 652965d9f74SJames Wright - string 653965d9f74SJames Wright 654965d9f74SJames Wright* - `-sgs_model_dd_leakyrelu_alpha` 655965d9f74SJames Wright - Slope parameter for Leaky ReLU activation function. `0` corresponds to normal ReLU 656965d9f74SJames Wright - 0 657965d9f74SJames Wright - 658965d9f74SJames Wright 659965d9f74SJames Wright* - `-sgs_model_dd_parameter_dir` 660965d9f74SJames Wright - Path to directory with data-driven model parameters (weights, biases, etc.) 661965d9f74SJames Wright - `./dd_sgs_parameters` 662965d9f74SJames Wright - string 663965d9f74SJames Wright 664965d9f74SJames Wright* - `-sgs_model_dd_model_implementation` 665965d9f74SJames Wright - Which computational implementation to use for SGS DD model (`fused`, `sequential_ceed`, `sequential_torch`) 666965d9f74SJames Wright - `fused` 667965d9f74SJames Wright - string 668965d9f74SJames Wright 669965d9f74SJames Wright* - `-sgs_model_dd_torch_model_path` 670965d9f74SJames Wright - Path to the PyTorch `*.pt` file containing the DD inference model 671965d9f74SJames Wright - 672965d9f74SJames Wright - string 673965d9f74SJames Wright 674965d9f74SJames Wright* - `-sgs_model_dd_torch_model_device` 675965d9f74SJames Wright - What hardware to perform the model inference on (`cpu`, `cuda`, `hip`, `xpu`) 676965d9f74SJames Wright - Default matches the libCEED backend 677965d9f74SJames Wright - string 678965d9f74SJames Wright 679965d9f74SJames Wright* - `-diff_filter_monitor` 680965d9f74SJames Wright - Enable differential filter TSMonitor 681965d9f74SJames Wright - `false` 682965d9f74SJames Wright - boolean 683965d9f74SJames Wright 684965d9f74SJames Wright* - `-diff_filter_grid_based_width` 685965d9f74SJames Wright - Use filter width based on the grid size 686965d9f74SJames Wright - `false` 687965d9f74SJames Wright - boolean 688965d9f74SJames Wright 689965d9f74SJames Wright* - `-diff_filter_width_scaling` 690965d9f74SJames Wright - Anisotropic scaling for filter width in wall-aligned coordinates (snz) 691965d9f74SJames Wright - `1,1,1` 692965d9f74SJames Wright - `m` 693965d9f74SJames Wright 694965d9f74SJames Wright* - `-diff_filter_kernel_scaling` 695965d9f74SJames Wright - Scaling to make differential kernel size equivalent to other filter kernels 696965d9f74SJames Wright - `0.1` 697965d9f74SJames Wright - `m^2` 698965d9f74SJames Wright 699965d9f74SJames Wright* - `-diff_filter_wall_damping_function` 700965d9f74SJames Wright - Damping function to use at the wall for anisotropic filtering (`none`, `van_driest`) 701965d9f74SJames Wright - `none` 702965d9f74SJames Wright - string 703965d9f74SJames Wright 704965d9f74SJames Wright* - `-diff_filter_wall_damping_constant` 705965d9f74SJames Wright - Constant for the wall-damping function. $A^+$ for `van_driest` damping function. 706965d9f74SJames Wright - 25 707965d9f74SJames Wright - 708965d9f74SJames Wright 709965d9f74SJames Wright* - `-diff_filter_friction_length` 710965d9f74SJames Wright - Friction length associated with the flow, $\delta_\nu$. Used in wall-damping functions 711965d9f74SJames Wright - 0 712965d9f74SJames Wright - `m` 713965d9f74SJames Wright 714965d9f74SJames Wright* - `-sgs_train_enable` 715965d9f74SJames Wright - Whether to enable *in situ* training of data-driven SGS model. Require building with SmartRedis. 716965d9f74SJames Wright - `false` 717965d9f74SJames Wright - boolean 718965d9f74SJames Wright 719965d9f74SJames Wright* - `-sgs_train_write_data_interval` 720965d9f74SJames Wright - Number of timesteps between writing training data into SmartRedis database 721965d9f74SJames Wright - `1` 722965d9f74SJames Wright - 723965d9f74SJames Wright 724965d9f74SJames Wright* - `-sgs_train_overwrite_data` 725965d9f74SJames Wright - Whether new training data should overwrite old data on database 726965d9f74SJames Wright - `true` 727965d9f74SJames Wright - boolean 728965d9f74SJames Wright 729965d9f74SJames Wright* - `-sgs_train_filter_widths` 730965d9f74SJames Wright - List of scalar values for different filter widths to calculate for training data 731965d9f74SJames Wright - 732965d9f74SJames Wright - `m` 733965d9f74SJames Wright 734965d9f74SJames Wright* - `-smartsim_collocated_num_ranks` 735965d9f74SJames Wright - Number of MPI ranks associated with each collocated database (i.e. ranks per node) 736965d9f74SJames Wright - `1` 737965d9f74SJames Wright - 738965d9f74SJames Wright::: 739965d9f74SJames Wright 740965d9f74SJames Wright### Gaussian Wave 741965d9f74SJames Wright 742965d9f74SJames WrightThe Gaussian wave problem has the following command-line options in addition to the Newtonian Ideal Gas options: 743965d9f74SJames Wright 744965d9f74SJames Wright:::{list-table} Gaussian Wave Runtime Options 745965d9f74SJames Wright:header-rows: 1 746965d9f74SJames Wright 747965d9f74SJames Wright* - Option 748965d9f74SJames Wright - Description 749965d9f74SJames Wright - Default value 750965d9f74SJames Wright - Unit 751965d9f74SJames Wright 752965d9f74SJames Wright* - `-freestream_riemann` 753965d9f74SJames Wright - Riemann solver for boundaries (HLL or HLLC) 754965d9f74SJames Wright - `hllc` 755965d9f74SJames Wright - 756965d9f74SJames Wright 757965d9f74SJames Wright* - `-freestream_velocity` 758965d9f74SJames Wright - Freestream velocity vector 759965d9f74SJames Wright - `0,0,0` 760965d9f74SJames Wright - `m/s` 761965d9f74SJames Wright 762965d9f74SJames Wright* - `-freestream_temperature` 763965d9f74SJames Wright - Freestream temperature 764965d9f74SJames Wright - `288` 765965d9f74SJames Wright - `K` 766965d9f74SJames Wright 767965d9f74SJames Wright* - `-freestream_pressure` 768965d9f74SJames Wright - Freestream pressure 769965d9f74SJames Wright - `1.01e5` 770965d9f74SJames Wright - `Pa` 771965d9f74SJames Wright 772965d9f74SJames Wright* - `-epicenter` 773965d9f74SJames Wright - Coordinates of center of perturbation 774965d9f74SJames Wright - `0,0,0` 775965d9f74SJames Wright - `m` 776965d9f74SJames Wright 777965d9f74SJames Wright* - `-amplitude` 778965d9f74SJames Wright - Amplitude of the perturbation 779965d9f74SJames Wright - `0.1` 780965d9f74SJames Wright - 781965d9f74SJames Wright 782965d9f74SJames Wright* - `-width` 783965d9f74SJames Wright - Width parameter of the perturbation 784965d9f74SJames Wright - `0.002` 785965d9f74SJames Wright - `m` 786965d9f74SJames Wright 787965d9f74SJames Wright::: 788965d9f74SJames Wright 789fc37ad8cSJames WrightThis problem can be run with the `examples/gaussianwave.yaml` file via: 790965d9f74SJames Wright 791965d9f74SJames Wright``` 792fc37ad8cSJames Wright./build/navierstokes -options_file examples/gaussianwave.yaml 793965d9f74SJames Wright``` 794965d9f74SJames Wright 795fc37ad8cSJames Wright```{literalinclude} ../examples/gaussianwave.yaml 796965d9f74SJames Wright:language: yaml 797965d9f74SJames Wright``` 798965d9f74SJames Wright 799965d9f74SJames Wright### Vortex Shedding - Flow past Cylinder 800965d9f74SJames Wright 801965d9f74SJames WrightThe vortex shedding, flow past cylinder problem has the following command-line options in addition to the Newtonian Ideal Gas options: 802965d9f74SJames Wright 803965d9f74SJames Wright:::{list-table} Vortex Shedding Runtime Options 804965d9f74SJames Wright:header-rows: 1 805965d9f74SJames Wright 806965d9f74SJames Wright* - Option 807965d9f74SJames Wright - Description 808965d9f74SJames Wright - Default value 809965d9f74SJames Wright - Unit 810965d9f74SJames Wright 811965d9f74SJames Wright* - `-freestream_velocity` 812965d9f74SJames Wright - Freestream velocity vector 813965d9f74SJames Wright - `0,0,0` 814965d9f74SJames Wright - `m/s` 815965d9f74SJames Wright 816965d9f74SJames Wright* - `-freestream_temperature` 817965d9f74SJames Wright - Freestream temperature 818965d9f74SJames Wright - `288` 819965d9f74SJames Wright - `K` 820965d9f74SJames Wright 821965d9f74SJames Wright* - `-freestream_pressure` 822965d9f74SJames Wright - Freestream pressure 823965d9f74SJames Wright - `1.01e5` 824965d9f74SJames Wright - `Pa` 825965d9f74SJames Wright 826965d9f74SJames Wright::: 827965d9f74SJames Wright 828965d9f74SJames WrightThe initial condition is taken from `-reference_temperature` and `-reference_pressure`. 829965d9f74SJames WrightTo run this problem, first generate a mesh: 830965d9f74SJames Wright 831965d9f74SJames Wright```console 832fc37ad8cSJames Wright$ make -C examples/meshes 833965d9f74SJames Wright``` 834965d9f74SJames Wright 835965d9f74SJames WrightThen run by building the executable and running: 836965d9f74SJames Wright 837965d9f74SJames Wright```console 838fc37ad8cSJames Wright$ make -j 839fc37ad8cSJames Wright$ mpiexec -n 6 build/navierstokes -options_file examples/vortexshedding.yaml -{ts,snes}_monitor_ 840965d9f74SJames Wright``` 841965d9f74SJames Wright 842965d9f74SJames WrightThe vortex shedding period is roughly 5.6 and this problem runs until time 100 (2000 time steps). 843fc37ad8cSJames WrightThe above run writes a file named `force.csv` (see `ts_monitor_wall_force` in `examples/vortexshedding.yaml`), which can be postprocessed by running to create a figure showing lift and drag coefficients over time. 844965d9f74SJames Wright 845965d9f74SJames Wright```console 846965d9f74SJames Wright$ python postprocess/vortexshedding.py 847965d9f74SJames Wright``` 848965d9f74SJames Wright 849fc37ad8cSJames Wright```{literalinclude} ../examples/vortexshedding.yaml 850965d9f74SJames Wright:language: yaml 851965d9f74SJames Wright``` 852965d9f74SJames Wright 853965d9f74SJames Wright### Density current 854965d9f74SJames Wright 855965d9f74SJames WrightThe Density Current problem has the following command-line options in addition to the Newtonian Ideal Gas options: 856965d9f74SJames Wright 857965d9f74SJames Wright:::{list-table} Density Current Runtime Options 858965d9f74SJames Wright:header-rows: 1 859965d9f74SJames Wright 860965d9f74SJames Wright* - Option 861965d9f74SJames Wright - Description 862965d9f74SJames Wright - Default value 863965d9f74SJames Wright - Unit 864965d9f74SJames Wright 865965d9f74SJames Wright* - `-center` 866965d9f74SJames Wright - Location of bubble center 867965d9f74SJames Wright - `(lx,ly,lz)/2` 868965d9f74SJames Wright - `(m,m,m)` 869965d9f74SJames Wright 870965d9f74SJames Wright* - `-dc_axis` 871965d9f74SJames Wright - Axis of density current cylindrical anomaly, or `(0,0,0)` for spherically symmetric 872965d9f74SJames Wright - `(0,0,0)` 873965d9f74SJames Wright - 874965d9f74SJames Wright 875965d9f74SJames Wright* - `-rc` 876965d9f74SJames Wright - Characteristic radius of thermal bubble 877965d9f74SJames Wright - `1000` 878965d9f74SJames Wright - `m` 879965d9f74SJames Wright 880965d9f74SJames Wright* - `-theta0` 881965d9f74SJames Wright - Reference potential temperature 882965d9f74SJames Wright - `300` 883965d9f74SJames Wright - `K` 884965d9f74SJames Wright 885965d9f74SJames Wright* - `-thetaC` 886965d9f74SJames Wright - Perturbation of potential temperature 887965d9f74SJames Wright - `-15` 888965d9f74SJames Wright - `K` 889965d9f74SJames Wright 890965d9f74SJames Wright* - `-P0` 891965d9f74SJames Wright - Atmospheric pressure 892965d9f74SJames Wright - `1E5` 893965d9f74SJames Wright - `Pa` 894965d9f74SJames Wright 895965d9f74SJames Wright* - `-N` 896965d9f74SJames Wright - Brunt-Vaisala frequency 897965d9f74SJames Wright - `0.01` 898965d9f74SJames Wright - `1/s` 899965d9f74SJames Wright::: 900965d9f74SJames Wright 901965d9f74SJames WrightThis problem can be run with: 902965d9f74SJames Wright 903965d9f74SJames Wright``` 904965d9f74SJames Wright./navierstokes -problem density_current -dm_plex_box_faces 16,1,8 -degree 1 -dm_plex_box_lower 0,0,0 -dm_plex_box_upper 2000,125,1000 -dm_plex_dim 3 -rc 400. -bc_wall 1,2,5,6 -wall_comps 1,2,3 -bc_symmetry_y 3,4 -mu 75 905965d9f74SJames Wright``` 906965d9f74SJames Wright 907965d9f74SJames Wright### Channel flow 908965d9f74SJames Wright 909965d9f74SJames WrightThe Channel problem has the following command-line options in addition to the Newtonian Ideal Gas options: 910965d9f74SJames Wright 911965d9f74SJames Wright:::{list-table} Channel Runtime Options 912965d9f74SJames Wright:header-rows: 1 913965d9f74SJames Wright 914965d9f74SJames Wright* - Option 915965d9f74SJames Wright - Description 916965d9f74SJames Wright - Default value 917965d9f74SJames Wright - Unit 918965d9f74SJames Wright 919965d9f74SJames Wright* - `-umax` 920965d9f74SJames Wright - Maximum/centerline velocity of the flow 921965d9f74SJames Wright - `10` 922965d9f74SJames Wright - `m/s` 923965d9f74SJames Wright 924965d9f74SJames Wright* - `-theta0` 925965d9f74SJames Wright - Reference potential temperature 926965d9f74SJames Wright - `300` 927965d9f74SJames Wright - `K` 928965d9f74SJames Wright 929965d9f74SJames Wright* - `-P0` 930965d9f74SJames Wright - Atmospheric pressure 931965d9f74SJames Wright - `1E5` 932965d9f74SJames Wright - `Pa` 933965d9f74SJames Wright 934965d9f74SJames Wright* - `-body_force_scale` 935965d9f74SJames Wright - Multiplier for body force (`-1` for flow reversal) 936965d9f74SJames Wright - 1 937965d9f74SJames Wright - 938965d9f74SJames Wright::: 939965d9f74SJames Wright 940fc37ad8cSJames WrightThis problem can be run with the `examples/channel.yaml` file via: 941965d9f74SJames Wright 942965d9f74SJames Wright``` 943fc37ad8cSJames Wright./build/navierstokes -options_file examples/channel.yaml 944965d9f74SJames Wright``` 945fc37ad8cSJames Wright```{literalinclude} ../examples/channel.yaml 946965d9f74SJames Wright:language: yaml 947965d9f74SJames Wright``` 948965d9f74SJames Wright 949965d9f74SJames Wright(example-blasius)= 950965d9f74SJames Wright 951965d9f74SJames Wright### Blasius boundary layer 952965d9f74SJames Wright 953965d9f74SJames WrightThe Blasius problem has the following command-line options in addition to the Newtonian Ideal Gas options: 954965d9f74SJames Wright 955965d9f74SJames Wright:::{list-table} Blasius Runtime Options 956965d9f74SJames Wright:header-rows: 1 957965d9f74SJames Wright 958965d9f74SJames Wright* - Option 959965d9f74SJames Wright - Description 960965d9f74SJames Wright - Default value 961965d9f74SJames Wright - Unit 962965d9f74SJames Wright 963965d9f74SJames Wright* - `-velocity_infinity` 964965d9f74SJames Wright - Freestream velocity 965965d9f74SJames Wright - `40` 966965d9f74SJames Wright - `m/s` 967965d9f74SJames Wright 968965d9f74SJames Wright* - `-temperature_infinity` 969965d9f74SJames Wright - Freestream temperature 970965d9f74SJames Wright - `288` 971965d9f74SJames Wright - `K` 972965d9f74SJames Wright 973965d9f74SJames Wright* - `-pressure_infinity` 974965d9f74SJames Wright - Atmospheric pressure, also sets IDL reference pressure 975965d9f74SJames Wright - `1.01E5` 976965d9f74SJames Wright - `Pa` 977965d9f74SJames Wright 978965d9f74SJames Wright* - `-temperature_wall` 979965d9f74SJames Wright - Wall temperature 980965d9f74SJames Wright - `288` 981965d9f74SJames Wright - `K` 982965d9f74SJames Wright 983965d9f74SJames Wright* - `-delta0` 984965d9f74SJames Wright - Boundary layer height at the inflow 985965d9f74SJames Wright - `4.2e-3` 986965d9f74SJames Wright - `m` 987965d9f74SJames Wright 988965d9f74SJames Wright* - `-platemesh_modify_mesh` 989965d9f74SJames Wright - Whether to modify the mesh using the given options below. 990965d9f74SJames Wright - `false` 991965d9f74SJames Wright - 992965d9f74SJames Wright 993965d9f74SJames Wright* - `-platemesh_refine_height` 994965d9f74SJames Wright - Height at which `-platemesh_Ndelta` number of elements should refined into 995965d9f74SJames Wright - `5.9E-4` 996965d9f74SJames Wright - `m` 997965d9f74SJames Wright 998965d9f74SJames Wright* - `-platemesh_Ndelta` 999965d9f74SJames Wright - Number of elements to keep below `-platemesh_refine_height` 1000965d9f74SJames Wright - `45` 1001965d9f74SJames Wright - 1002965d9f74SJames Wright 1003965d9f74SJames Wright* - `-platemesh_growth` 1004965d9f74SJames Wright - Growth rate of the elements in the refinement region 1005965d9f74SJames Wright - `1.08` 1006965d9f74SJames Wright - 1007965d9f74SJames Wright 1008965d9f74SJames Wright* - `-platemesh_top_angle` 1009965d9f74SJames Wright - Downward angle of the top face of the domain. This face serves as an outlet. 1010965d9f74SJames Wright - `5` 1011965d9f74SJames Wright - `degrees` 1012965d9f74SJames Wright 1013965d9f74SJames Wright* - `-platemesh_y_node_locs_path` 1014965d9f74SJames Wright - Path to file with y node locations. If empty, will use mesh warping instead. 1015965d9f74SJames Wright - `""` 1016965d9f74SJames Wright - 1017965d9f74SJames Wright 1018965d9f74SJames Wright* - `-stg_use` 1019965d9f74SJames Wright - Whether to use STG for the inflow conditions 1020965d9f74SJames Wright - `false` 1021965d9f74SJames Wright - 1022965d9f74SJames Wright 1023965d9f74SJames Wright* - `-n_chebyshev` 1024965d9f74SJames Wright - Number of Chebyshev terms 1025965d9f74SJames Wright - `20` 1026965d9f74SJames Wright - 1027965d9f74SJames Wright 1028965d9f74SJames Wright* - `-chebyshev_` 1029965d9f74SJames Wright - Prefix for Chebyshev snes solve 1030965d9f74SJames Wright - 1031965d9f74SJames Wright - 1032965d9f74SJames Wright 1033965d9f74SJames Wright::: 1034965d9f74SJames Wright 1035fc37ad8cSJames WrightThis problem can be run with the `examples/blasius.yaml` file via: 1036965d9f74SJames Wright 1037965d9f74SJames Wright``` 1038fc37ad8cSJames Wright./build/navierstokes -options_file examples/blasius.yaml 1039965d9f74SJames Wright``` 1040965d9f74SJames Wright 1041fc37ad8cSJames Wright```{literalinclude} ../examples/blasius.yaml 1042965d9f74SJames Wright:language: yaml 1043965d9f74SJames Wright``` 1044965d9f74SJames Wright 1045965d9f74SJames Wright### STG Inflow for Flat Plate 1046965d9f74SJames Wright 1047965d9f74SJames WrightUsing the STG Inflow for the blasius problem adds the following command-line options: 1048965d9f74SJames Wright 1049965d9f74SJames Wright:::{list-table} Blasius Runtime Options 1050965d9f74SJames Wright:header-rows: 1 1051965d9f74SJames Wright 1052965d9f74SJames Wright* - Option 1053965d9f74SJames Wright - Description 1054965d9f74SJames Wright - Default value 1055965d9f74SJames Wright - Unit 1056965d9f74SJames Wright 1057965d9f74SJames Wright* - `-stg_inflow_path` 1058965d9f74SJames Wright - Path to the STGInflow file 1059965d9f74SJames Wright - `./STGInflow.dat` 1060965d9f74SJames Wright - 1061965d9f74SJames Wright 1062965d9f74SJames Wright* - `-stg_rand_path` 1063965d9f74SJames Wright - Path to the STGRand file 1064965d9f74SJames Wright - `./STGRand.dat` 1065965d9f74SJames Wright - 1066965d9f74SJames Wright 1067965d9f74SJames Wright* - `-stg_alpha` 1068965d9f74SJames Wright - Growth rate of the wavemodes 1069965d9f74SJames Wright - `1.01` 1070965d9f74SJames Wright - 1071965d9f74SJames Wright 1072965d9f74SJames Wright* - `-stg_u0` 1073965d9f74SJames Wright - Convective velocity, $U_0$ 1074965d9f74SJames Wright - `0.0` 1075965d9f74SJames Wright - `m/s` 1076965d9f74SJames Wright 1077965d9f74SJames Wright* - `-stg_mean_only` 1078965d9f74SJames Wright - Only impose the mean velocity (no fluctutations) 1079965d9f74SJames Wright - `false` 1080965d9f74SJames Wright - 1081965d9f74SJames Wright 1082965d9f74SJames Wright* - `-stg_strong` 1083965d9f74SJames Wright - Strongly enforce the STG inflow boundary condition 1084965d9f74SJames Wright - `false` 1085965d9f74SJames Wright - 1086965d9f74SJames Wright 1087965d9f74SJames Wright* - `-stg_fluctuating_IC` 1088965d9f74SJames Wright - "Extrude" the fluctuations through the domain as an initial condition 1089965d9f74SJames Wright - `false` 1090965d9f74SJames Wright - 1091965d9f74SJames Wright 1092965d9f74SJames Wright* - `-stg_dx` 1093965d9f74SJames Wright - Set the element size in the x direction. Default is calculated for box meshes, assuming equispaced elements. 1094965d9f74SJames Wright - 1095965d9f74SJames Wright - `m` 1096965d9f74SJames Wright 1097965d9f74SJames Wright* - `-stg_h_scale_factor` 1098965d9f74SJames Wright - Scale element size for cutoff frequency calculation 1099965d9f74SJames Wright - $1/p$ 1100965d9f74SJames Wright - 1101965d9f74SJames Wright 1102965d9f74SJames Wright::: 1103965d9f74SJames Wright 1104fc37ad8cSJames WrightThis problem can be run with the `examples/blasius.yaml` file via: 1105965d9f74SJames Wright 1106965d9f74SJames Wright``` 1107fc37ad8cSJames Wright./build/navierstokes -options_file examples/blasius.yaml -stg_use true 1108965d9f74SJames Wright``` 1109965d9f74SJames Wright 1110965d9f74SJames WrightNote the added `-stg_use true` flag 1111fc37ad8cSJames WrightThis overrides the `stg: use: false` setting in the `examples/blasius.yaml` file, enabling the use of the STG inflow. 1112