Omnigenous umbilic stellarators: data and analysis files
Omnigenous umbilic stellarators: data and analysis files
The directory structure is shown below├── FIELDLINES_analysis│ ├── beak_equilibrium_A8_beta1p0_2100.0_reducedFalse.h5│ ├── FIELDLINES_inputs\│ ├── FIELDLINES_outputs\│ ├── medium_beak_hres.nc│ ├── mgrid_testcoil.nc│ ├── mgrid_umbilic_DESC.nc│ ├── mgrid_umbilic.nc│ └── wout_umbilic.nc├── HBT-EP_optimization│ ├── 3D_plot1.html│ ├── 3D_plot2.html│ ├── beaked_medium_0.125.npz│ ├── beak_equilibrium_A8_beta1p0_2100.0_reducedFalse.h5│ ├── beak_equilibrium_medium_beak_beta1p0.h5│ ├── beak_equilibrium_umbilic_curve_A8_beta1p0.h5│ ├── Boozer_contours\│ ├── curvature_plot2.pdf│ ├── curvature_plot2.png│ ├── curvature_plot2.svg│ ├── curvature_plot.pdf│ ├── deformed_HBT_medium_bulge.svg│ ├── extract_points_from_svg.py│ ├── HBT-EP_iota_profile.pdf│ ├── HBT-EP_pressure_profile.pdf│ ├── medium_beak_optimized_coilset_2p100kA_N12_mindist0p020_PFcurrent_59kA_shorterTF.h5│ ├── modB_3d_plot2.pdf│ ├── modB_3d_plot2.png│ ├── modB_3d_plot2.svg│ ├── modB_3d_plot.pdf│ ├── post_process_3d.py│ ├── post_process_3d_umbilicoil_only.py│ ├── post_process_Boozer.py│ ├── post_process_fieldline_ridge.py│ ├── post_process_profiles.py│ ├── post_process_Xsection.py│ ├── Xsection_optimized2.pdf│ ├── Xsection_optimized2.svg│ ├── Xsection_optimized.pdf│ ├── Xsection_optimized.png│ └── Xsection_optimized.svg├── HBT_reverse_current│ ├── 3D_plot1.html│ ├── 3D_plot2.html│ ├── beak_beta1p0_coilset_reversed_current4.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased4100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased6100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_4_umbilic-8100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_4_umbilic-8100.h5│ ├── beak_equilibrium_A8_beta1p0_6_umbilic-16100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_6_umbilic-8100_fixcur.h5│ ├── coil_position.npy│ ├── curvature_plot1_reversed.pdf│ ├── curvature_plot1_reversed.svg│ ├── curvature_plot1.svg│ ├── iota_estimate.py│ ├── modB_3d_plot_reversed.pdf│ ├── modB_3d_plot_reversed.svg│ ├── modB_3d_plot.svg│ ├── post_process_3d.py│ ├── post_process_3d_umbilicoil_only.py│ ├── post_process_iota_contribution.py│ ├── post_process_umbilic_coils_pts.py│ ├── post_process_Xsection.py│ ├── Xsection_optimized_reverse2.svg│ ├── Xsection_optimized_reverse.pdf│ └── Xsection_optimized_reverse.svg├── HBT_umbilic_coil_current_scan│ ├── 2100\│ ├── 4100\│ ├── 6100\│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased4100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased4100.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased6100_fixcur.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_increased6100.h5│ ├── beak_equilibrium_A8_beta1p0_2100.0_reducedFalse.h5│ ├── Boozer_contours│ ├── calculate_toroidal_current_sign.py│ ├── iota_fraction_w_umbilic_current.pdf│ ├── medium_beak_optimized_coilset_2p100kA_N12_mindist0p020_PFcurrent_59kA_shorterTF.h5│ ├── post_process_Boozer.py│ └── post_process_iota_contribution.py├── OP_DB_optimized│ ├── Boozer_contours\│ ├── eq_NFP1_A+7.0_tor+0.1_mr+0.20_shift+0.00_wd-0.05_elong+3.00_wellwt+2.0_vacuum_final2.h5│ ├── eq_NFP2_A+6.0_tor+0.0_mr+0.10_shift+0.00_wd+0.00_elong+2.00_wellwt+2.0_vacuum_final2.h5│ ├── NFP1_A+7_tor+0.05_mr+0.2_shift0.0_wd-0.05_elong+3.0_wellwt+2.0_iotashift+0.0│ └── post_process_Boozer.py├── pwO_calculations│ ├── Boozer_contours\│ ├── eq_NFP1_A+7.0_tor+0.1_mr+0.20_shift+0.00_wd-0.05_elong+3.00_wellwt+2.0_vacuum_final2.h5│ ├── Jpar_and_Boozer_OP_DB_NFP1.pdf│ ├── Jpar_and_Boozer_OP_DB_NFP1.svg│ ├── Jpar_and_Boozer_OP_DB.pdf│ ├── Jpar_and_Boozer_OP_DB.svg│ ├── Jpar_and_Boozer_UT131.pdf│ ├── Jpar_and_Boozer_UT131.svg│ ├── Jpar_and_Boozer_UT225.pdf│ ├── Jpar_and_Boozer_UT225.svg│ ├── Jpar_OP_DB_NFP1.npz│ ├── Jpar_OP_DB_NFP1.svg│ ├── Jpar_OP_DB_NFP2.npz│ ├── Jpar_OP_DB_NFP2.svg│ ├── Jpar_UT131_rho0p5.npz│ ├── Jpar_UT131.svg│ ├── Jpar_UT225_rho0p75.npz│ ├── Jpar_UT225.svg│ ├── plot_Jpar.py│ └── post_process_Boozer.py├── README.md├── US131_3D_render_Figure1│ ├── UToL423_full.svg│ ├── UToL423_render.pdf│ ├── UToL423_render.png│ ├── UToL423_render.svg│ ├── UToL423_single_period_render2.pdf│ ├── UToL423_single_period_render.pdf│ ├── UToL423_single_period_render.png│ ├── UToL423_single_period_render.svg│ └── UToLs_data.nb├── US131_coil_design│ ├── 3D_magax_plot.html│ ├── 3D_plot1.html│ ├── coil_layout_white_bkg.svg│ ├── coil_stage_two_optimization9.ipynb│ ├── data_co.npy│ ├── data_counter.npy│ ├── eq_high-res_optimized.h5│ ├── optimized_coilset9.h5│ ├── paraview-utils.ipynb│ ├── post_process_3d.py│ ├── post_process_Bn_2d.py│ ├── post_process_magaxis.py│ ├── post_process_poincare.py│ ├── save_vtk.py│ ├── test0.svg.pvtmp.svg│ ├── test1.svg│ ├── test2_bkp.svg│ ├── test2.svg│ ├── test2.svg.pvtmp.svg│ ├── US131_Bn_umbilic_curve.svg│ ├── US131_coilset.pdf│ ├── US131_collage2.pdf│ ├── US131_collage2.svg│ ├── US131_magax1.svg│ ├── US131_poincare_trace.pdf│ └── US131_poincare_trace.svg├── US131_Figure2│ ├── eq_limiota_m1_n3_L14_M14_N14_QA_init.h5│ ├── normF_UToL131.pdf│ ├── normF_UToL131.svg│ ├── normF_UToL131_zoom.pdf│ ├── normF_UToL131_zoom.svg│ ├── post_process_normF_inset.py│ └── post_process_normF.py├── US131_optimization│ ├── Boozer_contours\│ ├── boundary_plot\│ ├── driver_umbilic_ripple2.py│ ├── driver_umbilic_ripple3.py│ ├── driver_umbilic_ripple.py│ ├── eq_high-res_initial.h5│ ├── eq_high-res_optimized.h5│ ├── fieldline_umbilicedge.svg│ ├── iota_comparison.pdf│ ├── iota_comparison_projection.pdf│ ├── iota_comparison_projection.svg│ ├── iota_comparison.svg│ ├── post_process_3D.py│ ├── post_process_Boozer.py│ ├── post_process_boundary.py│ ├── post_process_fieldline_umbiliccurve.py│ ├── post_process_iota.py│ ├── post_process_magaxis.py│ ├── post_process_ripple.py│ ├── post_process_Xsection.py│ ├── ripple_comparison.pdf│ ├── ripple_initial.npz│ ├── ripple_optimized.npz│ ├── save_VMEC_wout.py│ ├── US131_fieldline_umbilicedge.pdf│ ├── US131_fieldline_umbilicedge.svg│ └── wout_umbilic_131.nc└── US252_optimization ├── Boozer_contours\ ├── boundary_plots\ ├── curvature_3d_OP_optimized.html ├── curvature_optimized_3D_UT225_2.svg ├── curvature_optimized_3D_UT225.pdf ├── curvature_optimized_3D_UT225.svg ├── curve_omni_m2_NFP5_14.h5 ├── driver_OP.py ├── eq_final_high-res.h5 ├── eq_initial_high-res_m2_NFP5.h5 ├── eq_omni_m2_NFP5_14.h5 ├── fieldline_umbilicedge.svg ├── F_norm_omni_m2_NFP5_14.png ├── iota_fraction_UT225.pdf ├── job_runner.sl ├── Jpar_UT225.pdf ├── modB_3d_OP_initial.html ├── modB_3d_OP_optimized.html ├── post_process_3D_and_curve.py ├── post_process_3D.py ├── post_process_Boozer.py ├── post_process_boundary2.py ├── post_process_boundary.py ├── post_process_fieldline_umbiliccurve.py ├── post_process_high_curvature.py ├── post_process_iota_contribution.py ├── post_process_ripple.py ├── ripple_comparison_UT225.pdf ├── ripple_initial.npz ├── ripple_optimized.npz
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