def screwpinch(nx=68, ny=16, nz=128, xcentre=1.5, fname='screwpinch.fci.nc', a=0.2, npoints=421, show_maps=False): yperiod = 2 * np.pi field = zb.field.Screwpinch(xcentre=xcentre, yperiod=yperiod, shear=0 * 2e-1) ycoords = np.linspace(0.0, yperiod, ny, endpoint=False) start_r = xcentre + a / 2. start_z = 0. print("Making curvilinear poloidal grid") inner = zb.rzline.shaped_line(R0=xcentre, a=a / 2., elong=0, triang=0.0, indent=0, n=npoints) outer = zb.rzline.shaped_line(R0=xcentre, a=a, elong=0, triang=0.0, indent=0, n=npoints) poloidal_grid = zb.poloidal_grid.grid_elliptic(inner, outer, nx, nz) grid = zb.grid.Grid(poloidal_grid, ycoords, yperiod, yperiodic=True) maps = zb.make_maps(grid, field) zb.write_maps(grid, field, maps, str(fname), metric2d=False) calc_curvilinear_curvature(fname, field, grid, maps) if show_maps: zb.plot.plot_forward_map(grid, maps, yslice=0)
############################################################################# # Create a grid, then calculate forward and backward maps grid = zoidberg.grid.Grid(pol_grids, ycoords, yperiod, yperiodic=True) maps = zoidberg.make_maps(grid, magnetic_field) ############################################################################# # Write grid file filename = "stellarator.fci.nc" print("Writing to grid file '{0}'".format(filename)) zoidberg.write_maps(grid, magnetic_field, maps, gridfile=filename, new_names=False, metric2d=True) ############################################################################# # Plot maps yslice = 0 pol, ycoord = grid.getPoloidalGrid(yslice) pol_next, ycoord_next = grid.getPoloidalGrid(yslice + 1) # Plot the points on yslice+1 as 'bx' # Note: ravel used here only so multiple labels are not created plt.plot(np.ravel(pol_next.R), np.ravel(pol_next.Z), 'bx',
outer_line = zoidberg.rzline.circle(R0=0.0, r=0.8) ############################################################################# # Now have inner and outer boundaries for each poloidal grid # Generate a grid on each poloidal slice using the elliptic grid generator nx = 20 ny = 20 pol_grids = [ zoidberg.poloidal_grid.grid_elliptic(inner_line, outer_line, nx,ny) for inner_line in inner_lines ] ############################################################################# # Create a grid, then calculate forward and backward maps grid = zoidberg.grid.Grid( pol_grids, ycoords, yperiod, yperiodic=True) maps = zoidberg.make_maps(grid, magnetic_field) ############################################################################# # Write grid file filename = "stellarator.fci.nc" print("Writing to grid file '{0}'".format(filename)) zoidberg.write_maps(grid, magnetic_field, maps, gridfile=filename, new_names=False, metric2d=True) ############################################################################# # Plot maps zoidberg.plot.plot_forward_map(grid, maps)
def rotating_ellipse(nx=68, ny=16, nz=128, xcentre=5.5, I_coil=0.01, curvilinear=True, rectangular=False, fname='rotating-ellipse.fci.nc', a=0.4, curvilinear_inner_aligned=True, curvilinear_outer_aligned=True, npoints=421, Btor=2.5, show_maps=False, calc_curvature=True, smooth_curvature=False, return_iota=True, write_iota=False): yperiod = 2 * np.pi / 5. field = zb.field.RotatingEllipse(xcentre=xcentre, I_coil=I_coil, radius=2 * a, yperiod=yperiod, Btor=Btor) # Define the y locations ycoords = np.linspace(0.0, yperiod, ny, endpoint=False) start_r = xcentre + a / 2. start_z = 0. if rectangular: print("Making rectangular poloidal grid") poloidal_grid = zb.poloidal_grid.RectangularPoloidalGrid( nx, nz, 1.0, 1.0, Rcentre=xcentre) elif curvilinear: print("Making curvilinear poloidal grid") inner = zb.rzline.shaped_line(R0=xcentre, a=a / 2., elong=0, triang=0.0, indent=0, n=npoints) outer = zb.rzline.shaped_line(R0=xcentre, a=a, elong=0, triang=0.0, indent=0, n=npoints) if curvilinear_inner_aligned: print("Aligning to inner flux surface...") inner_lines = get_lines(field, start_r, start_z, ycoords, yperiod=yperiod, npoints=npoints) if curvilinear_outer_aligned: print("Aligning to outer flux surface...") outer_lines = get_lines(field, xcentre + a, start_z, ycoords, yperiod=yperiod, npoints=npoints) print("creating grid...") if curvilinear_inner_aligned: if curvilinear_outer_aligned: poloidal_grid = [ zb.poloidal_grid.grid_elliptic(inner, outer, nx, nz, show=show_maps) for inner, outer in zip(inner_lines, outer_lines) ] else: poloidal_grid = [ zb.poloidal_grid.grid_elliptic(inner, outer, nx, nz, show=show_maps) for inner in inner_lines ] else: poloidal_grid = zb.poloidal_grid.grid_elliptic( inner, outer, nx, nz) # Create the 3D grid by putting together 2D poloidal grids grid = zb.grid.Grid(poloidal_grid, ycoords, yperiod, yperiodic=True) maps = zb.make_maps(grid, field) zb.write_maps(grid, field, maps, str(fname), metric2d=False) if (curvilinear and calc_curvature): print("calculating curvature...") calc_curvilinear_curvature(fname, field, grid, maps) if (calc_curvature and smooth_curvature): smooth_metric(fname, write_to_file=True, return_values=False, smooth_metric=True) if (return_iota or write_iota): rindices = np.linspace(start_r, xcentre + a, nx) zindices = np.zeros((nx)) iota_bar = calc_iota(field, start_r, start_z) if (write_iota): f = DataFile(str(fname), write=True) f.write('iota_bar', iota_bar) f.close() else: print("Iota_bar = ", iota_bar)
def W7X( nx=68, ny=32, nz=256, fname='W7-X.fci.nc', vmec_file='w7-x.wout.nc', inner_VMEC=False, inner_vacuum=False, outer_VMEC=False, outer_vacuum=False, outer_vessel=False, npoints=100, a=2.5, show_maps=False, calc_curvature=True, smooth_curvature=False, plasma_field=False, configuration=0, vmec_url='http://svvmec1.ipp-hgw.mpg.de:8080/vmecrest/v1/w7x_ref_171/wout.nc' ): yperiod = 2 * np.pi / 5. ycoords = np.linspace(0.0, yperiod, ny, endpoint=False) if outer_VMEC: print("Aligning to outer VMEC flux surface...") outer_lines = get_VMEC_surfaces(phi=ycoords, s=1, npoints=nz, w7x_run=vmec_url) elif outer_vessel: print("Aligning to plasma vessel (EXPERIMENTAL) ...") outer_lines = get_W7X_vessel(phi=ycoords, nz=nz) elif (outer_vacuum or inner_vacuum): xmin = 4.05 xmax = 4.05 + 2.5 zmin = -1.35 zmax = -zmin field = zb.field.W7X_vacuum(phimax=2 * np.pi / 5., x_range=[xmin, xmax], z_range=[zmin, zmax], include_plasma_field=plasma_field) xcentre, zcentre = field.magnetic_axis(phi_axis=ycoords[0], configuration=configuration) start_r = xcentre + a / 2. start_z = zcentre if inner_vacuum: print("Aligning to inner vacuum flux surface...") inner_lines = get_lines(field, start_r, start_z, ycoords, yperiod=yperiod, npoints=npoints) if outer_vacuum: print("Aligning to outer vacuum flux surface...") outer_lines = get_lines(field, start_r + a, start_z, ycoords, yperiod=yperiod, npoints=npoints) xmin = np.min([min(outer_lines[i].R) for i in range(ny)]) xmax = np.max([max(outer_lines[i].R) for i in range(ny)]) zmin = np.min([min(outer_lines[i].Z) for i in range(ny)]) zmax = np.max([max(outer_lines[i].Z) for i in range(ny)]) if inner_VMEC: print("Aligning to inner VMEC flux surface...") inner_lines = get_VMEC_surfaces(phi=ycoords, s=0.67, npoints=nz, w7x_run=vmec_url) print("creating grid...") poloidal_grid = [ zb.poloidal_grid.grid_elliptic(inner, outer, nx, nz, show=show_maps) for inner, outer in zip(inner_lines, outer_lines) ] # Create the 3D grid by putting together 2D poloidal grids grid = zb.grid.Grid(poloidal_grid, ycoords, yperiod, yperiodic=True) field = zb.field.W7X_vacuum(phimax=2 * np.pi / 5., x_range=[xmin, xmax], z_range=[zmin, zmax], include_plasma_field=plasma_field) maps = zb.make_maps(grid, field) zb.write_maps(grid, field, maps, str(fname), metric2d=False) if calc_curvature: print("calculating curvature...") calc_curvilinear_curvature(fname, field, grid) if (calc_curvature and smooth_curvature): smooth_metric(fname, write_to_file=True, return_values=False, smooth_metric=True) if show_maps: zb.plot.plot_forward_map(grid, maps, yslice=-1)
#!/usr/bin/env python import numpy as np import zoidberg field = zoidberg.field.GEQDSK("g014220.00200") # Read magnetic field grid = zoidberg.grid.rectangular_grid(100, 10, 100, 1.5-0.1, # Range in R (max - min) 2*np.pi, # Toroidal angle 3., # Range in Z xcentre=(1.5+0.1)/2, # Middle of grid in R yperiodic=True) # Periodic in toroidal angle # Create the forward and backward maps maps = zoidberg.make_maps(grid, field) # Save to file zoidberg.write_maps(grid, field, maps, gridfile="tokamak.fci.nc") ############################################################################# # Plot maps zoidberg.plot.plot_forward_map(grid, maps)
def W7X(nx=68, ny=16, nz=256, fname='W7-X.fci.nc', VMEC=True, vmec_file='w7-x.wout.nc', inner_VMEC=True, inner_vacuum=False, outer_VMEC=True, outer_vacuum=False, outer_vessel=False, npoints=100, a=0.5, show_maps=False, calc_curvature=True, smooth_curvature=False, configuration=0): field = zb.field.W7X(phimax=2 * np.pi / 5.) yperiod = 2 * np.pi / 5. ycoords = np.linspace(0.0, yperiod, ny, endpoint=False) xcentre, zcentre = field.magnetic_axis(phi_axis=ycoords[0], configuration=configuration) start_r = xcentre + a / 2. start_z = zcentre print("Making curvilinear poloidal grid") inner = zb.rzline.shaped_line(R0=xcentre, a=a / 2., elong=0, triang=0.0, indent=0, n=npoints) outer = zb.rzline.shaped_line(R0=xcentre, a=a, elong=0, triang=0.0, indent=0, n=npoints) if inner_vacuum: print("Aligning to inner vacuum flux surface...") inner_lines = get_lines(field, start_r, start_z, ycoords, yperiod=yperiod, npoints=npoints) elif inner_VMEC: print("Aligning to inner VMEC flux surface...") inner_lines = get_VMEC_surfaces(phi=ycoords, s=0.5, npoints=nz) if outer_vacuum: print("Aligning to outer vacuum flux surface...") outer_lines = get_lines(field, start_r + a, start_z, ycoords, yperiod=yperiod, npoints=npoints) elif outer_VMEC: print("Aligning to outer VMEC flux surface...") outer_lines = get_VMEC_surfaces(phi=ycoords, s=1, npoints=nz) elif outer_vessel: print("Aligning to plasma vessel (EXPERIMENTAL) ...") outer_lines = get_W7X_vessel(phi=ycoords, nz=nz) print("creating grid...") poloidal_grid = [ zb.poloidal_grid.grid_elliptic(inner, outer, nx, nz, show=show_maps) for inner, outer in zip(inner_lines, outer_lines) ] # Create the 3D grid by putting together 2D poloidal grids grid = zb.grid.Grid(poloidal_grid, ycoords, yperiod, yperiodic=True) maps = zb.make_maps(grid, field) zb.write_maps(grid, field, maps, str(fname), metric2d=False) if calc_curvature: print("calculating curvature...") calc_curvilinear_curvature(fname, field, grid) if (calc_curvature and smooth_curvature): smooth_metric(fname, write_to_file=True, return_values=False, smooth_metric=True)
#!/usr/bin/env python import numpy as np import zoidberg field = zoidberg.field.GEQDSK("g014220.00200") # Read magnetic field grid = zoidberg.grid.rectangular_grid( 100, 10, 100, 1.5 - 0.1, # Range in R (max - min) 2 * np.pi, # Toroidal angle 3., # Range in Z xcentre=(1.5 + 0.1) / 2, # Middle of grid in R yperiodic=True) # Periodic in toroidal angle # Create the forward and backward maps maps = zoidberg.make_maps(grid, field) # Save to file zoidberg.write_maps(grid, field, maps, gridfile="tokamak.fci.nc") ############################################################################# # Plot maps zoidberg.plot.plot_forward_map(grid, maps)