This README file contains descriptions of the file names of each figure in the following paper: Title: Regarding the optimization of O1-mode ECRH and the feasibility of EBW startup on NSTX-U Authors: N. A. Lopez, F. M. Poli Journal: Plasma Physics Controlled Fusion Year: 2018 Figure 1 file(s): NEData_NSTU_204202Z16_43ms.txt - Slow density, 43 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 NEData_NSTU_204202Z16_90ms.txt - Slow density, 90 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 NEData_NSTU_204202Z16_125ms.txt - Slow density, 125 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 NEData_NSTU_204202Z71_41ms.txt - Fast density, 41 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 NEData_NSTU_204202Z71_53ms.txt - Fast density, 53 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 NEData_NSTU_204202Z71_59ms.txt - Fast density, 59 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 TEData_NSTU_204202Z16_43ms.txt - Slow temperature, 43 milliseconds - Units: rho = dimensionless, TE = eV TEData_NSTU_204202Z16_90ms.txt - Slow temperature, 90 milliseconds - Units: rho = dimensionless, TE = eV TEData_NSTU_204202Z16_125ms.txt - Slow temperature, 125 milliseconds - Units: rho = dimensionless, TE = eV TEData_NSTU_204202Z71_41ms.txt - Fast temperature, 41 milliseconds - Units: rho = dimensionless, TE = eV TEData_NSTU_204202Z71_53ms.txt - Fast temperature, 53 milliseconds - Units: rho = dimensionless, TE = eV TEData_NSTU_204202Z71_59ms.txt - Fast temperature, 59 milliseconds - Units: rho = dimensionless, TE = eV Figure 2 file(s): angleScanData.txt - units: CD_Fast & CD_Slow = Amps, FPA_Fast & FPA_Slow = %, PolAngle & TorAngle = degrees Width_Deploc.txt - Dep_Fast & Dep_Slow = time-averaged deposition location for fast/slow ramp [flux coordinates] - mxDep_Fast & mxDep_Slow = maximum (over time) deposition location for fast/slow ramp [flux coordinates] - mnDep_Fast & mnDep_Slow = minimum (over time) deposition location for fast/slow ramp [flux coordinates] - Wdt_Fast & Wdt_Slow = time-averaged deposition width for fast/slow ramp [flux coordinates] - mxWdt_Fast & mxWdt_Slow = maximum (over time) deposition width for fast/slow ramp [flux coordinates] - mnWdt_Fast & mnWdt_Slow = minimum (over time) deposition width for fast/slow ramp [flux coordinates] - PolAngle = poloidal injection angle [degrees] - TorAngle = toroidal injection angle [degrees] Figure 3 file(s): NSTX_limiter.dat - first column = x coords [meters], second column = y coords [meters] LCFS_fast.txt - 2 column pairs for x & y coords [meters] for 6 different flux surfaces (0.1, 0.3, 0.5, 0.7, 0.9, 1.0) LCFS_slow.txt - 2 column pairs for x & y coords [meters] for 6 different flux surfaces rayData_fastHighPol.txt - High poloidal injection ray data for fast ramp (Reflection-dominated) - 3 column pairs for x, y coords [meters] and pwr [%] for each ray (6 total) rayData_fastLowPol.txt - Low poloidal injection ray data for fast ramp (Reflection-dominated) - 3 column pairs for x, y coords [meters] and pwr [%] for each ray (6 total) rayData_slowHighPol.txt - High poloidal injection ray data for slow ramp (Deflection-dominated) - 3 column pairs for x, y coords [meters] and pwr [%] for each ray (6 total) rayData_slowLowPol.txt - Low poloidal injection ray data for slow ramp (Deflection-dominated) - 3 column pairs for x, y coords [meters] and pwr [%] for each ray (6 total) Figure 4 file(s): MinMaxIPT_Fastdens.txt - CD_Min = minimum (over angle) ECCD [Amps] - CD_Max = maximum (over angle) ECCD [Amps] - FPA_Min = minimum (over angle) Absorbed EC power [W] - FPA_Max = maximum (over angle) Absorbed EC power [W] - Te0_Min = minimum (over angle) Central electron temperature [eV] - Te0_Max = maximum (over angle) Central electron temperature [eV] - Time = elapsed time [s] MinMaxIPT_Slowdens.txt - CD_Min = minimum (over angle) ECCD [Amps] - CD_Max = maximum (over angle) ECCD [Amps] - FPA_Min = minimum (over angle) Absorbed EC power [W] - FPA_Max = maximum (over angle) Absorbed EC power [W] - Te0_Min = minimum (over angle) Central electron temperature [eV] - Te0_Max = maximum (over angle) Central electron temperature [eV] - Time = elapsed time [s] Traces_Z71.txt - (1,-5) Fast ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Traces_E28.txt - (4,3) Fast ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Traces_M17.txt - (1.5,1.5) Fast ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Traces_Z16.txt - (1,-5) Slow ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Traces_E63.txt - (4,3) Slow ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Traces_M18.txt - (1.5,1.5) Slow ramp - EC_Tot = prescribed current [Amps] - EC_Trace = non-inductive ECCD [Amps] - P_Tot = Injected Power [W] - P_Trace = Absorbed EC power [W] - T_Trace = Central electron Temperature [eV] - Time = elapsed time [s] Figure 5 file(s): ECCDPabs_Data_E28_37ms.txt - (4,3) fast ramp at 37 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_E28_51ms.txt - (4,3) fast ramp at 51 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_E63_62ms.txt - (4,3) slow ramp at 62 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_E63_94ms.txt - (4,3) slow ramp at 94 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_Z16_62ms.txt - (1,-5) slow ramp at 62 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_Z16_94ms.txt - (1,-5) slow ramp at 94 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_Z71_37ms.txt - (1,-5) fast ramp at 37 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate ECCDPabs_Data_Z71_51ms.txt - (1,-5) fast ramp at 51 milliseconds - Mean ECCD = mean value of ECCD on interval [35 39]ms [Amps*cm^-2] - Min ECCD = min value (over time) on interval [35 39]ms [Amps*cm^-2] - Max ECCD = max value (over time) on interval [35 39]ms [Amps*cm^-2] - Mean Pabs = mean value of absorbed EC power on interval [35 39]ms [W*cm^-2] - Min Pabs = min value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - Max Pabs = max value (over time) of absorbed EC power on interval [35 39]ms [W*cm^-2] - rho = flux coordinate Figure 6 file(s): NSTX_limiter.dat - first column = x coords [meters], second column = y coords [meters] LCFS_Output_L56_40ms.txt - 2 column pairs for x & y coords [meters] for 3 different flux surfaces (0.01, 0.1, 1.0) LCFS_Output_L56_50ms.txt - 2 column pairs for x & y coords [meters] for 3 different flux surfaces (0.01, 0.1, 1.0) LCFS_Output_L56_80ms.txt - 2 column pairs for x & y coords [meters] for 3 different flux surfaces (0.01, 0.1, 1.0) LCFS_Output_L56_90ms.txt - 2 column pairs for x & y coords [meters] for 3 different flux surfaces (0.01, 0.1, 1.0) LCFS_Output_L56_110ms.txt - 2 column pairs for x & y coords [meters] for 3 different flux surfaces (0.01, 0.1, 1.0) Figure 7 file(s): NEData_NSTU_204202E28_27ms.txt - Fast density, 27 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 TEData_NSTU_204202E28_27ms.txt - Fast temperature, 27 milliseconds - Units: rho = dimensionless, TE = eV NEData_NSTU_204202E63_27ms.txt - Slow density, 27 milliseconds - Units: rho = dimensionless, NE = 10^(12) cm^-3 TEData_NSTU_204202E63_27ms.txt - Slow temperature, 27 milliseconds - Units: rho = dimensionless, TE = eV Figure 8 file(s): NSTX_limiter.dat - first column = x coords [meters], second column = y coords [meters] fluxContData_NSTU_204202E28_27ms.txt - Fast ramp, 27ms flux surface coordinates - 2 column of x,y coordinated: stored following MATLAB ContourMatrix convention - 1st element of each column specifies number of total contour lines used (4 - 0.1, 0.4, 0.7, 1.0) - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_O.txt - O-mode trajectory data - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_X.txt - X-mode trajectory data - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate Figure 9 file(s): NSTX_limiter.dat - first column = x coords [meters], second column = y coords [meters] fluxContData_NSTU_204202E63_27ms.txt - Slow ramp, 27ms flux surface coordinates - 2 column of x,y coordinated: stored following MATLAB ContourMatrix convention - 1st element of each column specifies number of total contour lines used (4 - 0.1, 0.4, 0.7, 1.0) - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Slowdens_O.txt - O-mode trajectory data - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] degrees - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Slowdens_X.txt - X-mode trajectory data - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] degrees - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Slowdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] degrees - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate Figure 10 file(s): MAST_OXB_ScanData_Conv_100_6_ray_Collisional.txt - Assuming 100% O-X conversion - OCD_Fast = O-mode driven current on fast ramp [Amps] - OCD_Slow = O-mode driven current on slow ramp [Amps] - OPIN_Fast = Initial O-mode power on fast ramp [Watts] - OPIN_Slow = Initial O-mode power on slow ramp [Watts] - OPABS_Fast = Absorbed O-mode power on fast ramp [Watts] - OPABS_Slow = Absorbed O-mode power on slow ramp [Watts] - Analogous quantities for X mode (XCD_Fast, etc.) and EBW (BCD_Fast, etc.) - PolAngle = poloidal injection angle [degree] Figure 11 file(s): MAST_OXB_ScanData_Conv_100_6_ray_Collisional.txt - Assuming 100% O-X conversion - OCD_Fast = O-mode driven current on fast ramp [Amps] - OCD_Slow = O-mode driven current on slow ramp [Amps] - OPIN_Fast = Initial O-mode power on fast ramp [Watts] - OPIN_Slow = Initial O-mode power on slow ramp [Watts] - OPABS_Fast = Absorbed O-mode power on fast ramp [Watts] - OPABS_Slow = Absorbed O-mode power on slow ramp [Watts] - Analogous quantities for X mode (XCD_Fast, etc.) and EBW (BCD_Fast, etc.) - PolAngle = poloidal injection angle [degree] MAST_OXB_ScanData_Conv_75_6_ray_Collisional.txt - Assuming 75% O-X conversion - OCD_Fast = O-mode driven current on fast ramp [Amps] - OCD_Slow = O-mode driven current on slow ramp [Amps] - OPIN_Fast = Initial O-mode power on fast ramp [Watts] - OPIN_Slow = Initial O-mode power on slow ramp [Watts] - OPABS_Fast = Absorbed O-mode power on fast ramp [Watts] - OPABS_Slow = Absorbed O-mode power on slow ramp [Watts] - Analogous quantities for X mode (XCD_Fast, etc.) and EBW (BCD_Fast, etc.) - PolAngle = poloidal injection angle [degree] MAST_OXB_ScanData_Conv_50_6_ray_Collisional.txt - Assuming 50% O-X conversion - OCD_Fast = O-mode driven current on fast ramp [Amps] - OCD_Slow = O-mode driven current on slow ramp [Amps] - OPIN_Fast = Initial O-mode power on fast ramp [Watts] - OPIN_Slow = Initial O-mode power on slow ramp [Watts] - OPABS_Fast = Absorbed O-mode power on fast ramp [Watts] - OPABS_Slow = Absorbed O-mode power on slow ramp [Watts] - Analogous quantities for X mode (XCD_Fast, etc.) and EBW (BCD_Fast, etc.) - PolAngle = poloidal injection angle [degree] Figure 12 file(s): MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate MAST_OXB_RayTrajData_6_ray_Collisional_Slowdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] degrees - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate MAST_OXB_EBW_DepInd_Conv_100_6_ray_Fastdens.txt - DepInd_Fast = ray step index for onset of Collisionless damping (fast ramp) - EndInd_Fast = ray step index for termination of ray (fast ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Collisional_Fastdens.txt - DepInd_Fast = ray step index for onset of Collisional damping (fast ramp) - EndInd_Fast = ray step index for termination of ray (fast ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Slowdens.txt - DepInd_Slow = ray step index for onset of Collisionless damping (slow ramp) - EndInd_Slow = ray step index for termination of ray (slow ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Collisional_Slowdens.txt - DepInd_Slow = ray step index for onset of Collisional damping (slow ramp) - EndInd_Slow = ray step index for termination of ray (slow ramp) - PolAngle = poloidal injection angle [degrees] Figure 13 file(s): MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate MAST_OXB_RayTrajData_6_ray_Collisional_Slowdens_EBW.txt - EBW-mode trajectory data - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] degrees - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate MAST_OXB_EBW_DepInd_Conv_100_6_ray_Fastdens.txt - DepInd_Fast = ray step index for onset of Collisionless damping (fast ramp) - EndInd_Fast = ray step index for termination of ray (fast ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Collisional_Fastdens.txt - DepInd_Fast = ray step index for onset of Collisional damping (fast ramp) - EndInd_Fast = ray step index for termination of ray (fast ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Slowdens.txt - DepInd_Slow = ray step index for onset of Collisionless damping (slow ramp) - EndInd_Slow = ray step index for termination of ray (slow ramp) - PolAngle = poloidal injection angle [degrees] MAST_OXB_EBW_DepInd_Conv_100_6_ray_Collisional_Slowdens.txt - DepInd_Slow = ray step index for onset of Collisional damping (slow ramp) - EndInd_Slow = ray step index for termination of ray (slow ramp) - PolAngle = poloidal injection angle [degrees] Figure 14 file(s): fluxContData_NSTU_204202E28_27ms.txt - Fast ramp, 27ms flux surface coordinates - 2 column of x,y coordinated: stored following MATLAB ContourMatrix convention - 1st element of each column specifies number of total contour lines used (4 - 0.1, 0.4, 0.7, 1.0) - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_O.txt - O-mode trajectory data, midplane launch - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_X.txt - X-mode trajectory data, midplane launch - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Fastdens_EBW.txt - EBW-mode trajectory data, midplane launch - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate MAST_OXB_RayTrajData_6_ray_Collisional_Vert_10_Fastdens_O.txt - O-mode trajectory data, launch from -30cm - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Vert_10_Fastdens_X.txt - X-mode trajectory data, launch from -30cm - 4 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: [m] MAST_OXB_RayTrajData_6_ray_Collisional_Vert_10_Fastdens_EBW.txt - EBW-mode trajectory data, launch from -30cm - 6 column pairs for x_tor, y_tor, x_pol, y_pol coordinates (i.e. x & y for plotting tor/pol projection) & npar, rho - 25 such column pairs for each integer poloidal injection angle on [-12, 12] - The poloidal injection angle is the first element in each column - Units: x_tor, y_tor, x_pol, y_pol = [m], npar = dimensionless, rho = flux coordinate