TRANSP output information
These pages contain details of some of the TRANSP output variables. The TRANSP output is dynamic and it depends on the number of species and other parameters. The table below can be considered as an example of TRANSP output and does not include all possible combinations of the output variables. The table gives name of the output variables, short description, and the description of most common first dimensions of the output variables, if these variables are arrays.
| Variable name | Units | Description | 1st dimension | |
| X | x"r/a" ctr | xc | ||
| XB | x"r/a" bdy | xb | ||
| RZON | CM | RADIUS | xc | |
| RBOUN | CM | RADIUS | xb | |
| RMNMP | CM | MIDPLANE RADII | xb | |
| RMJMP | CM | FLUX SURFACE CTRS | xb | |
| THETA | RADIANS | POL. ANGLE | theta | |
| BDENSTOTMP | #/CM**3 | Fast ion density, GC on midplane | midplane R | |
| EBAPLAV_MP | eV | FAST ION <Epll> , GC on midplane | midplane R | |
| EBAPPAV_MP | eV | FAST ION <Eperp>, GC on midplane | midplane R | |
| VBTORAV_MP | CM/SEC | FAST ION <Vtor>, GC on midplane | midplane R | |
| BDIFBX_D | CM**2/SEC | D anom beam ion diffusivity | ||
| BVELBX_D | CM/SEC | D anom beam ion velocity | ||
| BDENS2_D | N/CM**3 | D Beam ion density, GC | ||
| BEPRP2_D | eV | D Beam ion <Eperp>, GC | ||
| BEPLL2_D | eV | D Beam ion <Epll>, GC | ||
| BVTOR2_D | cm/sec | D Beam ion <Vtor>, GC | ||
| RSNBX_D_D | 1/sec | D_0 cx sink by D beam ions | ||
| RSNBI_D_D | 1/sec | D_0 ii sink by D beam ions | ||
| RMJSYM | CM | MAJOR RADII (DATA MAPPING) | major rad. | |
| XIRSYM | FLUX LABEL (DATA MAPPING) | major rad. | ||
| RMAJM | CM | MIDPLANE-FLUX SURFACE RADII | midplane R | |
| MCINDX | 2d MC grid (x,th) | 2d MC grid index | ||
| BMVOL | CM**3 | 2d MC grid zone volumes | 2d MC grid index | |
| ILIM | LIMITER CONTOUR INDEX | <LM. IND.> | ||
| RLIM | CM | LIMITER R PTS | <LM. IND.> | |
| YLIM | CM | LIMITER Y PTS | <LM. IND.> | |
| SURF | CM**2 | FLUX SURFACE AREA | xb | |
| DAREA | CM**2 | ZONE CROSS SECTIONAL AREA | xc | |
| DVOL | CM**3 | ZONE VOLUME | xc | |
| DRAV | CM | FLUX SURFACE AVG <DR> | xc | |
| LPOL | CM | POLOIDAL PATH LENGTH | xb | |
| GRI | CM**-1 | <1/R> FLUX SURFACE VOL.AVG | xc | |
| GR2I | CM**-2 | <1/R**2> FLUX SURFACE VOL.AVG | xc | |
| GX2R2I | CM**-4 | <GRAD(XI)**2/R**2> FLX.SURF.AVG | xc | |
| GXI2 | CM**-2 | <GRAD(XI)**2> FLUX SURF VOL.AVG | xc | |
| GXI | CM**-1 | <GRAD(XI)> FLUX SURF VOL.AVG | xc | |
| DRAVFAC | <dr>*<1/dr> | xc | ||
| GR2 | CM**2 | <R**2> FLUX SURFACE VOL.AVG | xc | |
| GR2X2 | <R**2*GRAD(XI)**2> FLX.SURF.AVG | xc | ||
| GRIXI | <1/(R*GRAD(XI))> FLX.SURF.AVG | xc | ||
| GAMNC | CM**-1 | NC gamma, <n.grad(theta)> | xc | |
| GX2B2I | 1/T^2*CM^2 | <grad(XI)**2/B**2> | xc | |
| PSFM1 | CM**-2 | NC Pfirsch-Schluter 1 moment | ||
| PSFM2 | CM**-2 | NC Pfirsch-Schluter 2 moment | ||
| PSFM3 | CM**-2 | NC Pfirsch-Schluter 3 moment | ||
| PSFM4 | CM**-2 | NC Pfirsch-Schluter 4 moment | ||
| PSFM5 | CM**-2 | NC Pfirsch-Schluter 5 moment | ||
| PSFM6 | CM**-2 | NC Pfirsch-Schluter 6 moment | ||
| PSFM7 | CM**-2 | NC Pfirsch-Schluter 7 moment | ||
| PSFM8 | CM**-2 | NC Pfirsch-Schluter 8 moment | ||
| PSFM9 | CM**-2 | NC Pfirsch-Schluter 9 moment | ||
| PSFM10 | CM**-2 | NC Pfirsch-Schluter 10 moment | ||
| PSFM11 | CM**-2 | NC Pfirsch-Schluter 11 moment | ||
| PSFM12 | CM**-2 | NC Pfirsch-Schluter 12 moment | ||
| PSFM13 | CM**-2 | NC Pfirsch-Schluter 13 moment | ||
| PSFM14 | CM**-2 | NC Pfirsch-Schluter 14 moment | ||
| PSFM15 | CM**-2 | NC Pfirsch-Schluter 15 moment | ||
| PSFM16 | CM**-2 | NC Pfirsch-Schluter 16 moment | ||
| ELONG | Flux surface elongation | |||
| TRIANG | Flux surface triangularity | |||
| TRIANGU | Flux surf. upper triangularity | |||
| TRIANGL | Flux surf. lower triangularity | |||
| SQUARE_UO | Flux surf upper outer squareness | |||
| SQUARE_LO | Flux surf lower outer squareness | |||
| VBRC | VB INTENS | VB PROFILE (CALCULATED) | xc | |
| YMPA | CM | MIDPLANE | xb | |
| RMC00 | CM | 0TH ASYM R MOMENT | xb | |
| YMC00 | CM | 0TH ASYM Y MOMENT | xb | |
| RMC01 | CM | 1st ASYM R COS MOMENT | ||
| RMS01 | CM | 1st ASYM R SIN MOMENT | ||
| YMC01 | CM | 1st ASYM Y COS MOMENT | ||
| YMS01 | CM | 1st ASYM Y SIN MOMENT | ||
| RMC02 | CM | 2nd ASYM R COS MOMENT | ||
| RMS02 | CM | 2nd ASYM R SIN MOMENT | ||
| YMC02 | CM | 2nd ASYM Y COS MOMENT | ||
| YMS02 | CM | 2nd ASYM Y SIN MOMENT | ||
| RMC03 | CM | 3rd ASYM R COS MOMENT | ||
| RMS03 | CM | 3rd ASYM R SIN MOMENT | ||
| YMC03 | CM | 3rd ASYM Y COS MOMENT | ||
| YMS03 | CM | 3rd ASYM Y SIN MOMENT | ||
| RMC04 | CM | 4th ASYM R COS MOMENT | ||
| RMS04 | CM | 4th ASYM R SIN MOMENT | ||
| YMC04 | CM | 4th ASYM Y COS MOMENT | ||
| YMS04 | CM | 4th ASYM Y SIN MOMENT | ||
| RMC05 | CM | 5th ASYM R COS MOMENT | ||
| RMS05 | CM | 5th ASYM R SIN MOMENT | ||
| YMC05 | CM | 5th ASYM Y COS MOMENT | ||
| YMS05 | CM | 5th ASYM Y SIN MOMENT | ||
| RMC06 | CM | 6th ASYM R COS MOMENT | ||
| RMS06 | CM | 6th ASYM R SIN MOMENT | ||
| YMC06 | CM | 6th ASYM Y COS MOMENT | ||
| YMS06 | CM | 6th ASYM Y SIN MOMENT | ||
| RMC07 | CM | 7th ASYM R COS MOMENT | ||
| RMS07 | CM | 7th ASYM R SIN MOMENT | ||
| YMC07 | CM | 7th ASYM Y COS MOMENT | ||
| YMS07 | CM | 7th ASYM Y SIN MOMENT | ||
| RMC08 | CM | 8th ASYM R COS MOMENT | ||
| RMS08 | CM | 8th ASYM R SIN MOMENT | ||
| YMC08 | CM | 8th ASYM Y COS MOMENT | ||
| YMS08 | CM | 8th ASYM Y SIN MOMENT | ||
| RMC09 | CM | 9th ASYM R COS MOMENT | ||
| RMS09 | CM | 9th ASYM R SIN MOMENT | ||
| YMC09 | CM | 9th ASYM Y COS MOMENT | ||
| YMS09 | CM | 9th ASYM Y SIN MOMENT | ||
| RMC10 | CM | 10th ASYM R COS MOMENT | ||
| RMS10 | CM | 10th ASYM R SIN MOMENT | ||
| YMC10 | CM | 10th ASYM Y COS MOMENT | ||
| YMS10 | CM | 10th ASYM Y SIN MOMENT | ||
| RMC11 | CM | 11th ASYM R COS MOMENT | ||
| RMS11 | CM | 11th ASYM R SIN MOMENT | ||
| YMC11 | CM | 11th ASYM Y COS MOMENT | ||
| YMS11 | CM | 11th ASYM Y SIN MOMENT | ||
| RMC12 | CM | 12th ASYM R COS MOMENT | ||
| RMS12 | CM | 12th ASYM R SIN MOMENT | ||
| YMC12 | CM | 12th ASYM Y COS MOMENT | ||
| YMS12 | CM | 12th ASYM Y SIN MOMENT | ||
| RMC13 | CM | 13th ASYM R COS MOMENT | ||
| RMS13 | CM | 13th ASYM R SIN MOMENT | ||
| YMC13 | CM | 13th ASYM Y COS MOMENT | ||
| YMS13 | CM | 13th ASYM Y SIN MOMENT | ||
| RMC14 | CM | 14th ASYM R COS MOMENT | ||
| RMS14 | CM | 14th ASYM R SIN MOMENT | ||
| YMC14 | CM | 14th ASYM Y COS MOMENT | ||
| YMS14 | CM | 14th ASYM Y SIN MOMENT | ||
| RMC15 | CM | 15th ASYM R COS MOMENT | ||
| RMS15 | CM | 15th ASYM R SIN MOMENT | ||
| YMC15 | CM | 15th ASYM Y COS MOMENT | ||
| YMS15 | CM | 15th ASYM Y SIN MOMENT | ||
| RMC16 | CM | 16th ASYM R COS MOMENT | ||
| RMS16 | CM | 16th ASYM R SIN MOMENT | ||
| YMC16 | CM | 16th ASYM Y COS MOMENT | ||
| YMS16 | CM | 16th ASYM Y SIN MOMENT | ||
| GMAG | JLES/CM3 | GMAG (RT) PRESSURE PROFILE | xc | |
| AMAG | BZ**2/BPOL**2 PROFILE | xc | ||
| SERUN | N/CM3/SEC | RUNAWAY ELEC SOURCE RATE | xc | |
| BPOL | TESLA | POLOIDAL FIELD | xb | |
| CUR | AMPS/CM2 | TOTAL PLASMA CURRENT | xc | |
| CUROH | AMPS/CM2 | OHMIC PLASMA CURRENT | xc | |
| CURXT | AMPS/CM2 | DRIVEN PLASMA CURRENT (SMOOTHED) | xc | |
| CURXTU | AMPS/CM2 | DRIVEN PLASMA CURRENT (UNSMOOTHED) | xc | |
| CONPLJB | TESLA | Approximate <J.B>/Jtor | xc | |
| PLJB | AMP*TESLA/CM2 | <J.B> FLUX SURFACE VOL.AVG | xc | |
| PLJBXT | AMP*TESLA/CM2 | <J.B> DRIVEN (SMOOTHED, USED) | xc | |
| PLJBXTU | AMP*TESLA/CM2 | <J.B> DRIVEN (UNSMOOTHED) | xc | |
| PLJBXTR | AMP*TESLA/CM2 | <J.B> DRIVEN, FROM RESISTIVITY | xc | |
| PLJBOH | AMP*TESLA/CM2 | <J.B> OHMIC | xc | |
| PLJBSNC | AMP*TESLA/CM2 | <J.B> NCLASS Bootstrap | xc | |
| PLJBSNEO | AMP*TESLA/CM2 | <J.B> NEO-gk Bootstrap | xc | |
| PLEB | VOLT*TESLA/CM | <E.B> FLUX SURFACE VOL.AVG | xc | |
| CURGP | AMPS/CM2 | GRAD(P) TOROIDAL CUR | xc | |
| PLCURPLL | AMPS | POLOIDAL CUR (J PLL) | xb | |
| PLCURPRP | AMPS | POLOIDAL CUR (J PERP) | xb | |
| PLCURTOT | AMPS | TOTAL POLOIDAL CUR TO WALL | xb | |
| QCHK | MHD EQUILIBRIUM Q CHECK | xb | ||
| Q | Q PROFILE | xb | ||
| SHAT | Magnetic shear (r/q)*(dq/dr) | xc | ||
| HLFLX | Wb/rad | M,N=1 HELICAL FLUX | xb | |
| ARAT | ASPECT RATIO | xb | ||
| V | VOLTS | VOLTAGE | xc | |
| VCHEK | VOLTS | VOLTAGE CHECK | xc | |
| VPOH | VOLTS | VOLTAGE for POH calculation | xc | |
| POH | WATTS/CM3 | OHMIC HEATING POWER | xc | |
| UDEXB | WATTS/CM3 | E CROSS B POWER | xc | |
| UBTDT | WATTS/CM3 | D/DT(FIELD ENERGY) | xc | |
| UBPDT | WATTS/CM3 | D/DT(POLOIDAL FIELD ENERGY) | xc | |
| UBCMP | WATTS/CM3 | B(POL) COMPRESSION | xc | |
| UMGBA | WATTS/CM3 | MAGDIF ENERGY BALANCE | xc | |
| UBPOL | JLES/CM3 | POLOIDAL FIELD ENERGY | xc | |
| UBTOR | JLES/CM3 | TOROIDAL FIELD ENERGY | xc | |
| PLFLX | Wb/rad | POLOIDAL FLUX | xb | |
| PLFLX2PI | WEBERS | TOTAL POLOIDAL FLUX | xb | |
| TRFLX | WEBERS | TOROIDAL FLUX | xb | |
| TRFCK | WEBERS | MHD TOROIDAL FLUX CHECK | xb | |
| ETA_USE | OHM*CM | RESISTIVITY USED OR INFERRED | xc | |
| ETA_NC | OHM*CM | NC RESISTIVITY (old fit) | xc | |
| ETA_SP | OHM*CM | SPITZER RESISTIVITY | xc | |
| ETA_SPS | OHM*CM | SPITZER RESISTIVITY (Sauter) | xc | |
| ZEFMD | MAGDIF ZEFF PROFILE | xc | ||
| ZEFFP | PLASMA COMPOSITION ZEFF PROFILE | xc | ||
| ZEFFI | ZEFF DATA (UNCONSTRAINED) | xc | ||
| ZEFFPRO | ZEFF PROFILE FROM ZF2 DATA FILE | xc | ||
| CURBS | AMPS/CM2 | BOOTSTRAP CURRENT | xc | |
| CURBSNEO | AMPS/CM2 | NEO-gk Bootstrap Current | xc | |
| CURBSHAG | AMPS/CM2 | SAUTER HAGER Bootstrap Current | xc | |
| CURBSWNC | AMPS/CM2 | NCLASS Bootstrap Current | xc | |
| CURBSEPS | AMPS/CM2 | Aspect Ratio Bootstrap Current | xc | |
| CURBSSAU | AMPS/CM2 | Sauter Bootstrap Current as Used | xc | |
| CURBSSAU0 | AMPS/CM2 | Sauter Bootstrap Current Original Form | xc | |
| CURBSSAU1 | AMPS/CM2 | Sauter Bootstrap Current CS Chang Form | xc | |
| CURBSNE | AMPS/CM2 | Ne contrib Sauter Bootstrap Cur | xc | |
| CURBSTE | AMPS/CM2 | Te contrib Sauter Bootstrap Cur | xc | |
| CURBSNI | AMPS/CM2 | Ni contrib Sauter Bootstrap Cur | xc | |
| CURBSTI | AMPS/CM2 | Ti contrib Sauter Bootstrap Cur | xc | |
| ETA_WNC | OHM*CM | NCLASS Resistivity | xc | |
| ETA_TSC | OHM*CM | TSC Neoclassical Resistivity | xc | |
| ETA_SNC | OHM*CM | Sauter Neoclassical Resistivity | xc | |
| FMCK_WNC | NCLASS Fm convergence check | xc | ||
| CONDIWNC | CM**2/SEC | NCLASS ion heat diffusivity | xb | |
| CONDWNCE | CM**2/SEC | NCLASS e- heat diffusivity | xb | |
| CONDWNCX | CM**2/SEC | NCLASS Imp heat diffusivity | xb | |
| CONDNC_TOK | CM**2/SEC | NCLASS TOK Imp heat diffusivity | ||
| GFLNC_TOK | N/CM3/SEC | div(NC ptcl flux) TOK imp | ||
| QFLNC_TOK | WATTS/CM3 | div(NC heat flux) TOK imp | ||
| QFLNCC_TOK | WATTS/CM3 | div(NC class heat flux) TOK imp | ||
| CONDICWNC | CM**2/SEC | NCLASS ion class heat diffus | xb | |
| GFLNC_E | N/CM3/SEC | div(NC ptcl flux) electrons | xc | |
| QFLNC_E | WATTS/CM3 | div(NC heat flux) electrons | xc | |
| QFLNCC_E | WATTS/CM3 | div(NC class heat flux) electr | xc | |
| GFLNC_X | N/CM3/SEC | div(NC ptcl flux) impurity | xc | |
| QFLNC_X | WATTS/CM3 | div(NC heat flux) impurity | xc | |
| QFLNCC_X | WATTS/CM3 | div(NC class heat flux) impurity | xc | |
| GFLNC_I | N/CM3/SEC | div(NC ptcl flux) thermal ions | xc | |
| QFLNC_I | WATTS/CM3 | div(NC heat flux) thermal ions | xc | |
| QFLNCC_I | WATTS/CM3 | div(NC class heat flux) thermals | xc | |
| BBNTX_DD | N/CM3/SEC | DD BEAM-BEAM NEUTRONS | xc | |
| BBNT2_DD | N/CM3/SEC | DD BEAM-BEAM NEUTRONS | 2d MC grid index | |
| BTNTR_DD | CM3/SEC | SIGV DD BEAM-TARGET NEUTRONS | xc | |
| BTNTX_DD | N/CM3/SEC | DD BEAM-TARGET NEUTRONS | xc | |
| BTNT2_DD | N/CM3/SEC | DD BEAM-TARGET NEUTRONS | 2d MC grid index | |
| BTNTX | N/CM3/SEC | BEAM-TARGET NEUTRONS | xc | |
| BBNTX | N/CM3/SEC | BEAM-BEAM NEUTRONS | xc | |
| POHB | WATTS/CM3 | POWER: OH CIRCUIT TO FAST IONS | xc | |
| PCPRB | WATTS/CM3 | POWER: COMPRESSION OF FAST IONS | xc | |
| PBEPHI | WATTS/CM3 | Electrostatic field -> fast ions | xc | |
| BTRAP0_D | D beam full E dep banana frac. | xc | ||
| BTRAP_D | D beam ions banana fraction | xc | ||
| NB_F1_D | N/CM**3 | density: full energy D beam | xc | |
| NB_F2_D | N/CM**3 | density: half energy D beam | xc | |
| NB_F3_D | N/CM**3 | density: 1/3 energy D beam | xc | |
| PBE_F1_D | WATTS/CM3 | Pbe: full energy D beam | xc | |
| PBE_F2_D | WATTS/CM3 | Pbe: half energy D beam | xc | |
| PBE_F3_D | WATTS/CM3 | Pbe: 1/3 energy D beam | xc | |
| PBI_F1_D | WATTS/CM3 | Pbi: full energy D beam | xc | |
| PBI_F2_D | WATTS/CM3 | Pbi: half energy D beam | xc | |
| PBI_F3_D | WATTS/CM3 | Pbi: 1/3 energy D beam | xc | |
| VPB_F1_D | T*(cm/sec) | Vpll.B: full energy D beam | xc | |
| VPB_F2_D | T*(cm/sec) | Vpll.B: half energy D beam | xc | |
| VPB_F3_D | T*(cm/sec) | Vpll.B: 1/3 energy D beam | xc | |
| SNCX_D | N/CM3/SEC | CX sink rate beam D | xc | |
| SNCXMC_D | N/CM3/SEC | MC CX sink rate beam D,orbit | xc | |
| BDENS | N/CM**3 | BEAM ION DENSITY | xc | |
| BBETA | BEAM BETA POLOIDAL | xc | ||
| BTBE | BEAM BETA TOROIDAL | xc | ||
| BBPLL | BEAM BETA PLL (POLOIDAL) | xc | ||
| BBPRP | BEAM BETA PERP (POLOIDAL) | xc | ||
| CURB | AMPS/CM2 | BEAM DRIVEN CURRENT | xc | |
| PBI | WATTS/CM3 | BEAM HEATING OF IONS | xc | |
| PBE | WATTS/CM3 | BEAM HEATING OF ELECTRONS | xc | |
| OMEGB | RAD/SEC | BEAM ION AVG ANG.VELOCITY | xc | |
| UCURB | AMPS/CM2 | UNSHIELDED BEAM CURRENT | xc | |
| UJBCO | AMPS/CM2 | UNSHIELDED BEAM CUR (CO BEAMS) | xc | |
| UJBCR | AMPS/CM2 | UNSHIELDED BEAM CUR (CTR BEAMS) | xc | |
| SDBBI | N/CM3/SEC | BEAM DEPOSITION: BEAM-BEAM II | xc | |
| SDBBX | N/CM3/SEC | BEAM DEPOSITION: BEAM-BEAM CX | xc | |
| SDB_II | N/CM3/SEC | BEAM DEP: ioniz. on therm. ions | xc | |
| SDB_IE | N/CM3/SEC | BEAM DEP: ioniz. on electrons | xc | |
| SDB_IZ | N/CM3/SEC | BEAM DEP: ioniz. on impurities | xc | |
| PBTH | WATTS/CM3 | FAST ION THERMALIZATION POWER | xc | |
| SBE | N/CM3/SEC | ELECTRON SCE FAST ION DEPOSITION | xc | |
| SBTH | N/CM3/SEC | FAST ION THERMALIZATION SOURCE | xc | |
| PBCX | WATTS/CM3 | THERMAL ION LOSS, FAST ION CX | xc | |
| SBCX0 | N/CM3/SEC | FAST ION CX: NEUTRALS BORN | xc | |
| SBXR_II | N/CM3/SEC | FAST ION RECAPTURE on th.ions | xc | |
| SBXR_IE | N/CM3/SEC | FAST ION RECAPTURE on electrons | xc | |
| SBXR_IZ | N/CM3/SEC | FAST ION RECAPTURE on impurities | xc | |
| SBXRB | N/CM3/SEC | FAST ION CX: BEAM-BEAM RECAPTURE | xc | |
| EXCS_D_1 | FULL E D: DEPO EXCIT. FACTOR | xc | ||
| EXCS_D_2 | HALF E D: DEPO EXCIT. FACTOR | xc | ||
| EXCS_D_3 | 1/3 E D: DEPO EXCIT. FACTOR | xc | ||
| EXCS_D_X | CX D: RECAP EXCIT. FACTOR | xc | ||
| BDENS_D | N/CM**3 | D BEAM ION DENSITY | xc | |
| EBEAM_D | EV | AVG D BEAM ION ENERGY | xc | |
| MCDENS_D | N/CM**3 | D BEAM ION DENSITY (MC LIST) | xc | |
| MCDEPS_D | N/CM**3 | NEW D BEAM IONS (MC DEP) | xc | |
| NMC_D | N | Beam D No. of MC Ions | xc | |
| WNMC_D | #ptcls | Beam D No. of MC Ions | xc | |
| DNBDT_D | N/CM3/SEC | D/DT(D BEAM ION DENS) | xc | |
| OMEGB_D | RAD/SEC | D BEAM ION AVG ANG.VELOCITY | xc | |
| PBI_D | WATTS/CM3 | D B->TH ION HEATING | xc | |
| PBCX_D | WATTS/CM3 | THERMAL ION LOSS, CX W/ D BEAM | xc | |
| PBTH_D | WATTS/CM3 | D BEAM THERMALIZATION POWER | xc | |
| PBE_D | WATTS/CM3 | D BEAM->ELECTRON HEATING | xc | |
| SBE_D | N/CM3/SEC | ELECTRON SCE D BEAM DEPOSITION | xc | |
| SBTH_D | N/CM3/SEC | D BEAM THERMALIZATION SOURCE | xc | |
| IBRORB_D | AMPS | D BEAM ION RADIAL CUR (ORBIT) | xb | |
| BDEP_D | N/CM3/SEC | D BEAM DEPOSITION (TOTAL) | xc | |
| SDEP_D | N/CM3/SEC | D BEAM ORBIT AV DEP (TOTAL) | xc | |
| BDEPE_D1 | N/CM3/SEC | FULL E D BEAM DEP (TOTAL) | xc | |
| BDEPE_D2 | N/CM3/SEC | HALF E D BEAM DEP (TOTAL) | xc | |
| BDEPE_D3 | N/CM3/SEC | 1/3 E D BEAM DEP (TOTAL) | xc | |
| SDBBI_D | N/CM3/SEC | D BEAM DEPOSITION: BEAM-BEAM II | xc | |
| SDBBX_D | N/CM3/SEC | D BEAM DEPOSITION: BEAM-BEAM CX | xc | |
| SDBII_D | N/CM3/SEC | D BEAM DEP: IONIZ. on therm.ions | xc | |
| SDBIE_D | N/CM3/SEC | D BEAM DEP: IONIZ. on electrons | xc | |
| SDBIZ_D | N/CM3/SEC | D BEAM DEP: IONIZ. on impurities | xc | |
| SDBBI_D1 | N/CM3/SEC | Full E D BEAM DEP: BEAM-BEAM II | xc | |
| SDBBX_D1 | N/CM3/SEC | Full E D BEAM DEP: BEAM-BEAM CX | xc | |
| SDBII_D1 | N/CM3/SEC | Full E D BEAM DEP: II on th.ions | xc | |
| SDBIE_D1 | N/CM3/SEC | Full E D BEAM DEP: II on (e-) | xc | |
| SDBIZ_D1 | N/CM3/SEC | Full E D BEAM DEP: IONIZ. on imp | xc | |
| SDBBI_D2 | N/CM3/SEC | Half E D BEAM DEP: BEAM-BEAM II | xc | |
| SDBBX_D2 | N/CM3/SEC | Half E D BEAM DEP: BEAM-BEAM CX | xc | |
| SDBII_D2 | N/CM3/SEC | Half E D BEAM DEP: II on th.ions | xc | |
| SDBIE_D2 | N/CM3/SEC | Half E D BEAM DEP: II on (e-) | xc | |
| SDBIZ_D2 | N/CM3/SEC | Half E D BEAM DEP: IONIZ. on imp | xc | |
| SDBBI_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: BEAM-BEAM II | xc | |
| SDBBX_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: BEAM-BEAM CX | xc | |
| SDBII_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: II on th.ions | xc | |
| SDBIE_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: II on (e-) | xc | |
| SDBIZ_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: IONIZ. on imp | xc | |
| SBCX0_D | N/CM3/SEC | D BEAM CX: NEUTRALS BORN | xc | |
| SBXR_I_D | N/CM3/SEC | D B RECAP by ioniz: th.ions | xc | |
| SBXR_E_D | N/CM3/SEC | D B RECAP by ioniz: electrons | xc | |
| SBXR_Z_D | N/CM3/SEC | D B RECAP by ioniz: impurities | xc | |
| SBXRB_D | N/CM3/SEC | D BEAM CX: RECAPTURE: BEAM-BEAM | xc | |
| FPBX_D | D BEAM DRAG >IMPURITIES | xc | ||
| FPAX_D | D BEAM SCATTERING >IMPURITIES | xc | ||
| TSL1A_D | SECONDS | D FULL E TAU(SLOWING DOWN,CO) | xc | |
| TSL2A_D | SECONDS | D HALF E TAU(SLOWING DOWN,CO) | xc | |
| TSL3A_D | SECONDS | D 1/3 E TAU(SLOWING DOWN,CO) | xc | |
| TSL1B_D | SECONDS | D FULL E TAU(SLOWING DOWN,CTR) | xc | |
| TSL2B_D | SECONDS | D HALF E TAU(SLOWING DOWN,CTR) | xc | |
| TSL3B_D | SECONDS | D 1/3 E TAU(SLOWING DOWN,CTR) | xc | |
| TPA1A_D | SECONDS | D FULL E TAU(SCATTERING,CO) | xc | |
| TPA2A_D | SECONDS | D HALF E TAU(SCATTERING,CO) | xc | |
| TPA3A_D | SECONDS | D 1/3 E TAU(SCATTERING,CO) | xc | |
| TPA1B_D | SECONDS | D FULL E TAU(SCATTERING,CTR) | xc | |
| TPA2B_D | SECONDS | D HALF E TAU(SCATTERING,CTR) | xc | |
| TPA3B_D | SECONDS | D 1/3 E TAU(SCATTERING,CTR) | xc | |
| FBTH1 | N/CM**3 | FI DIST 0.< R/A <.2 | theta | |
| FBTH2 | N/CM**3 | FI DIST .2< R/A <.4 | theta | |
| FBTH3 | N/CM**3 | FI DIST .4< R/A <.6 | theta | |
| FBTH4 | N/CM**3 | FI DIST .6< R/A <.8 | theta | |
| FBTH5 | N/CM**3 | FI DIST .8< R/A <1. | theta | |
| N0BCXD0 | N/CM**3 | CX FAST NEUTRAL DENSITY (D0) | xc | |
| N0BD0 | N/CM**3 | 1.GEN FAST NEUTRAL DENSITY (D0) | xc | |
| SBHD | N/CM3/SEC | D+ ION SCE DUE TO BEAM | xc | |
| SB0XD | N/CM3/SEC | D0 NEUTRAL SINK BEAM CX | xc | |
| SB0ID | N/CM3/SEC | D0 NEUTRAL SINK BEAM II | xc | |
| SDCXD | N/CM3/SEC | BEAM DEPOSITION: CX W/D+ IONS | xc | |
| SBXRD | N/CM3/SEC | BEAM CX: RECAPTURE BY CX W/D+ | xc | |
| SDCXD_D | N/CM3/SEC | D BEAM DEPOSITION: CX W/D+ IONS | xc | |
| SBXRD_D | N/CM3/SEC | D BEAM CX: RECAPTURE BY CX W/D+ | xc | |
| SDCXD_D1 | N/CM3/SEC | Full E D BEAM DEP: CX W/D+ IONS | xc | |
| SDCXD_D2 | N/CM3/SEC | Half E D BEAM DEP: CX W/D+ IONS | xc | |
| SDCXD_D3 | N/CM3/SEC | 1/3 E D BEAM DEP: CX W/D+ IONS | xc | |
| TQBE | Nt-M/CM3 | BEAM TORQUE TO ELECTRONS | xc | |
| TQBI | Nt-M/CM3 | BEAM TORQUE TO IONS | xc | |
| TQBCO | Nt-M/CM3 | BEAM COLLISIONAL TORQUE | xc | |
| TQRPL | Nt-M/CM3 | BEAM RPL JXB TORQUE | xc | |
| TQBTH | Nt-M/CM3 | BEAM THERMALIZATION TORQUE | xc | |
| TQJXB | Nt-M/CM3 | BEAM JXB TORQUE | xc | |
| TQBCX | Nt-M/CM3 | BEAM CX ANTI-TORQUE | xc | |
| RQBE | WATTS/CM3 | BEAM WORK -> ELECTRON ROTATION | xc | |
| RQBI | WATTS/CM3 | BEAM WORK -> ION ROTATION | xc | |
| RQBCO | WATTS/CM3 | BEAM WORK -> ROTATION (COL.) | xc | |
| RQBTH | WATTS/CM3 | BEAM WORK -> ROTATION (THRMALIZ) | xc | |
| PBTHA | WATTS/CM3 | BEAM WORK -> ROTATION (TH-ASSYM) | xc | |
| RQJXB | WATTS/CM3 | BEAM WORK -> ROTATION (JXB) | xc | |
| RQRPL | WATTS/CM3 | BEAM WORK -> ROTATION RPL (JXB) | xc | |
| TQOHB | Nt-M/CM3 | TORQUE OH CIRCUIT --> BEAM | xc | |
| TQXFR | FRACTION OF TQBCO -> IMPURITIES | xc | ||
| RQOHB | WATTS/CM3 | WORK: OH->BEAM, ROTATION | xc | |
| TQBCO_D | Nt-M/CM3 | D BEAM COLLISIONAL TORQUE | xc | |
| TQJXB_D | Nt-M/CM3 | D BEAM JXB TORQUE | xc | |
| TQRPL_D | Nt-M/CM3 | D BEAM RPL JXB TORQUE | xc | |
| CURBRORB | AMPS | FAST ION RADIAL CURRENT (ORBIT) | xb | |
| CURBRABD | AMPS | FAST ION RAD.CUR (ANOM DIFFUS or AEP) | xb | |
| CURBRFSH | AMPS | FAST ION RAD.CUR (FISHBONES) | xb | |
| CURBRRIP | AMPS | FAST ION RAD.CUR (RIPPLE LOSS) | xb | |
| BN0T1 | N/CM**3 | N0(BEAM):1.GEN 1/1*EB | xc | |
| BN0T2 | N/CM**3 | N0(BEAM):1.GEN 1/2*EB | xc | |
| BN0T3 | N/CM**3 | N0(BEAM):1.GEN 1/3*EB | xc | |
| SCEAL | N/CM3/SEC | FUSION ALPHA SOURCE | xc | |
| PALE | WATTS/CM3 | ALPHA ELECTRON HEATING | xc | |
| PALI | WATTS/CM3 | ALPHA ION HEATING | xc | |
| BTAL | ALPHA TOROIDAL BETA | xc | ||
| UALPHPP | JLES/CM3 | ALPHA ION PERP ENERGY DENSITY | xc | |
| UALPHPA | JLES/CM3 | ALPHA ION PLL ENERGY DENSITY | xc | |
| TAUSAL | SECONDS | ALPHA SLOWING DOWN TIME | xc | |
| NALPHA | N/CM**3 | ALPHA ION DENSITY | xc | |
| EPOTNC | VOLTS | ER POTENTIAL: NC ANALYSIS | xb | |
| VTORE_NC | CM/SEC | NC electron toroidal velocity | midplane R | |
| VTORX_NC | CM/SEC | NC impurity toroidal velocity | midplane R | |
| OMGX | rad/sec | NC impurity angular velocity | xc | |
| VPOLE_NC | CM/SEC | NC electron poloidal velocity | midplane R | |
| VPOLX_NC | CM/SEC | NC impurity poloidal velocity | midplane R | |
| VTOR_AVG | CM/SEC | momentum balance avg velocity | midplane R | |
| SQZE_NC | NC electron orbit squeezing | xc | ||
| SQZX_NC | NC impurity orbit squeezing | xc | ||
| VPOL_AVG | CM/SEC | NC avg poloidal velocity | midplane R | |
| VNDNC_E | CM/SEC | NCLASS e- radial particle convection velocity | xb | |
| DFENC | CM**2/SEC | NCLASS e- particle diffusivity | xb | |
| ERTOT | V/CM | NC radial E Field | midplane R | |
| ERPRESS | V/CM | NC radial E field, Pressure term | midplane R | |
| ERVPOL | V/CM | NC radial E field, Vpol term | midplane R | |
| ERVTOR | V/CM | NC radial E field, Vtor term | midplane R | |
| SREXB_NC | RAD/SEC | ExB shear rate from nclass | midplane R | |
| SREXB_NCL | RAD/SEC | ExB shear rate (nclass,R>R_axis) | ||
| JBFAC | Species avg Jb shielding | xc | ||
| JBFACZ1 | Z=1 Jb shielding | xc | ||
| DFINC_TOK | CM**2/SEC | Nclass particle diffusivity for TOK | ||
| PTDFI_TOK | CM**2/SEC | Predictive Particle Diffusivity for TOK | ||
| VNDNC_TOK | CM/SEC | Nclass avg radial particle convection velocity forTOK | ||
| VTORNC_TOK | CM/SEC | NC TOK imp toroidal velocity | ||
| VPOLNC_TOK | CM/SEC | NC TOK imp poloidal velocity | ||
| OMG_D | rad/sec | NC D angular velocity | ||
| VTORD_NC | CM/SEC | NC D+ toroidal velocity | midplane R | |
| VPOLD_NC | CM/SEC | NC D+ poloidal velocity | midplane R | |
| SQZD_NC | NC D+ orbit squeezing | xc | ||
| VNDNC_D | CM/SEC | Nclass D+ avg radial particle convection velocity | xb | |
| DFINC_D | CM**2/SEC | Nclass D+ particle diffusivity | xb | |
| DFINS_D | CM**2/SEC | Predictive D+ particle diffusivity | xb | |
| VTORX | CM/SEC | impurity toroidal velocity data | midplane R | |
| NE | N/CM**3 | ELECTRON DENSITY | xc | |
| NETW | N/CM**3 | NE(R) ASSYMMETRY | xc | |
| TE | EV | ELECTRON TEMPERATURE | xc | |
| PMASS | GRAMS/CM3 | PLASMA MASS DENSITY | xc | |
| OMEGA | RAD/SEC | TOROIDAL ANGULAR VELOCITY | xc | |
| OMEGA_NC | RAD/SEC | N.C. TOROIDAL ANGULAR VELOCITY | xc | |
| OMEGDATA | RAD/SEC | Toroidal Ang.Velocity Data | xc | |
| UPHI | JLES/CM3 | THERMAL PLASMA ROTATIONAL ENERGY | xc | |
| PPHI | NtM-S/CM3 | ANGULAR MOMENTUM DENSITY | xc | |
| VRPOT | VOLTS | RADIAL ELECTRICAL POTENTIAL | xb | |
| EPOTRO | VOLTS | RADIAL POTENTIAL due to ROTATION | xb | |
| AMOI | NtMS2/CM3 | Total Therm Ang Inertia Dens | xc | |
| MOIG_D | NtMS2/CM3 | D Therm Ang Inertia Dens | ||
| MOIG_X | NtMS2/CM3 | Impurity Therm Ang Inertia Dens | xc | |
| MOIS_TOK | NtMS2/CM3 | TOK Therm Ang Inertia Dens | ||
| PPHIN | NtM-S/CM3 | NCLASS Ang Mom Dens | xc | |
| PPHIGN_D | NtM-S/CM3 | D NCLASS Ang Mom Dens | ||
| PPHIGN_X | NtM-S/CM3 | Impurity NCLASS Ang Mom Dens | xc | |
| PION | WATTS/CM3 | NEUTRAL IONIZATION WORK | xc | |
| PRAD | WATTS/CM3 | NET RADIATED POWER USED | xc | |
| PRADC | WATTS/CM3 | NET RADIATED POWER (THEORY) | xc | |
| PRAD_BR | WATTS/CM3 | BREMSSTRAHLUNG RADIATION | xc | |
| PRAD_LI | WATTS/CM3 | LINE RADIATION | xc | |
| PRAD_CY | WATTS/CM3 | CYCLOTRON RADIATION | xc | |
| PRADS_TOK | WATTS/CM3 | TOK Impurity Radiation | ||
| PRLS_TOK | WATTS/CM3 | TOK Impurity Line Radiation | ||
| PRBS_TOK | WATTS/CM3 | TOK Impurity Brem Radiation | ||
| PRX_SINGL | WATTS/CM3 | SINGL Impurity Radiation | ||
| PRLX_SINGL | WATTS/CM3 | SINGL Impurity Line Radiation | ||
| PRBX_SINGL | WATTS/CM3 | SINGL Impurity Brem Radiation | ||
| PRAD0 | WATTS/CM3 | RADIATION: BOLO DATA | xc | |
| PRAD_ADJ | WATTS/CM3 | RADIATION: BOLO DATA ADJUSTED | xc | |
| PCNVE | WATTS/CM3 | ELECTRON CONVECTION LOSS | xc | |
| CONDE | CM**2/SEC | ELECTRON HEAT DIFFUSIVITY | xb | |
| CONDEPR | CM**2/SEC | chi(e) predictive model | xb | |
| CONDEF | CM**2/SEC | 1 FLUID "EFFECTIVE" CHI | xb | |
| VELE | CM/SEC | ELECTRON RADIAL VELOCITY | xb | |
| PLABD | N/CM**3 | PELLET ABLATION (DATA) | xc | |
| VMO_PBAL | CM/SEC | Momentum v_rad from ptcl-bal | xb | |
| VMO_DATA | CM/SEC | Momentum v_rad input data | xb | |
| VMO_PINCH | CM/SEC | Momentum v_rad pinch term | xb | |
| VMO_THMOD | CM/SEC | Momentum v_rad, transport model | xb | |
| VMO_NET | CM/SEC | Momentum v_rad used in run | xb | |
| DIFB | CM**2/SEC | ANOMOLOUS FAST ION DIFFUSIVITY | xb | |
| VELB | CM/SEC | ANOMOLOUS FAST ION VELOCITY | xb | |
| CLOGE | ELECTRON COULOMB LOG | xc | ||
| GAINE | WATTS/CM3 | ELECTRON GAIN | xc | |
| PCMPE | WATTS/CM3 | ELECTRON COMPRESSION | xc | |
| PCNDE | WATTS/CM3 | ELECTRON CONDUCTION LOSS | xc | |
| KETOT | CM**2/SEC | CHI(E) "COUNTING" CONVECTION | xb | |
| DNEDT | N/CM3/SEC | D/DT(ELECTRON DENSITY) | xc | |
| DIVFE | N/CM3/SEC | DIV(ELECTRON FLUX) | xc | |
| VELWE | CM/SEC | ELECTRON WARE VELOCITY | xb | |
| SCEW | N/CM3/SEC | ELECTRON SCE (WALL NEUTRALS) | xc | |
| SCEV | N/CM3/SEC | ELECTRON SCE (VOL. NEUTRALS) | xc | |
| SCEZ | N/CM3/SEC | ELECTRON SCE (Impurity Ioniz.) | xc | |
| EPTR_MOD | N/CM3/SEC | Div(electron flux) (model) | xc | |
| EPTR_OBS | N/CM3/SEC | Div(electron flux) (observed) | xc | |
| EETR_MOD | WATTS/CM3 | Div(elec energy flux) (model) | xc | |
| EETR_OBS | WATTS/CM3 | Div(elec energy flux) (observed) | xc | |
| RESPROFPE | ELECTRON PARTICLE EQN. RES | xc | ||
| RESPROFPI | THERMAL PARTICLE EQN. RES | xc | ||
| RESPROFPX | IMPURITY PARTICLE EQN. RES | xc | ||
| RESPROFTE | ELECTRON ENERGY EQN. RES | xc | ||
| RESPROFTI | ION ENERGY EQN. RES | xc | ||
| RESPROFOMG | ANG. MOMENTUM EQN. RES | xc | ||
| BTE | ELECTRON BETA TOROIDAL | xc | ||
| TAUPE | SECONDS | ELECTRON PTCL CONFINEMNT | xb | |
| TAPWE | SECONDS | ELECTRON TAU(P) WARE CORRECTION | xb | |
| DIFFE | CM**2/SEC | ELEC PTCL DIFFUSIVITY | xb | |
| DIFFNE | CM**2/SEC | TOTAL ELEC PTCL DIFFUSIVITY | xb | |
| DIFWE | CM**2/SEC | ELEC PTCL DIFFUSIVITY (WARE) | xb | |
| TEE | SECONDS | ELECTRON ENERGY CONFINEMENT | xb | |
| TEEST | SECONDS | ELECTRON ENERGY CONFINEMENT (*) | xb | |
| DEINT | CM**2/SEC | INTOR ELECTRON DIFFUSIVITY | xb | |
| ETAE | D(LN(TE))/D(LN(NE)) | xb | ||
| XETE0 | CM**2/SEC | CHI:E(ETA(E)) GUZDAR | xb | |
| VETAE | ETA(E) VALIDITY CHK | xb | ||
| XETAE | CM**2/SEC | CHI:E(ETA(E)) ACTIVE | xb | |
| THNTX | N/CM3/SEC | THERMONUCLEAR NEUTRONS | xc | |
| TTNTX | N/CM3/SEC | TOTAL NEUTRONS | xc | |
| FTOTDT | N/CM3/SEC | TOTAL D-T FUSION | xc | |
| FTOTDDN | N/CM3/SEC | TOTAL D(D,N)HE3 FUSION | xc | |
| FTOT2TT | N/CM3/SEC | TOTAL T(T,2N)HE4 FUSION | xc | |
| FTOTDDP | N/CM3/SEC | TOTAL D(D,P)T FUSION | xc | |
| BTFR_DDP | CM3/SEC | SIGV D(D,P)T BEAM-TARGET FUSION | xc | |
| BTFX_DDP | N/CM3/SEC | D(D,P)T BEAM-TARGET FUSION | xc | |
| BTF2_DDP | N/CM3/SEC | D(D,P)T BEAM-TARGET FUSION | 2d MC grid index | |
| BBFX_DDP | N/CM3/SEC | D(D,P)T BEAM-BEAM PROTONS | xc | |
| BBF2_DDP | N/CM3/SEC | D(D,P)T BEAM-BEAM PROTONS | 2d MC grid index | |
| THNTX_DD | N/CM3/SEC | DD THERMONUCLEAR NEUTRONS | xc | |
| NI | N/CM**3 | TOTAL ION DENSITY | xc | |
| ND | N/CM**3 | DEUTERIUM ION DENSITY | xc | |
| NEDATA | N/CM**3 | ne (experimental data) | xc | |
| TIPRO | EV | MEASURED TI PROFILE | xc | |
| TI | EV | ION TEMPERATURE | xc | |
| CLOGI | ION COULOMB LOG | xc | ||
| XKFAC | CHI(I) MULTIPLIER | xb | ||
| FKJUL | CM**2/SEC | CHI(I) NC RUTHERFORD-JULICH: TRANSP | xb | |
| FKHZH | CM**2/SEC | CHI(I) NC HAZELTINE-HINTON: TRANSP | xb | |
| FKBOL | CM**2/SEC | CHI(I) NC BOLTON: TRANSP | xb | |
| FKCHH | CM**2/SEC | CHI(I) NC CHANG-HINTON ORIGINAL: TRANSP | xb | |
| FKCH2 | CM**2/SEC | CHI(I) NC CHANG-HINTON VSN 2: TRANSP | xb | |
| FKCHZ | CM**2/SEC | CHI(I) NC CHANG-HINTON Z-CORR: TRANSP | xb | |
| FKJUL_K1 | CM**2/SEC | CHI(I) NC RUTHERFORD-JULICH: KAPISN_1 | xb | |
| FKHZH_K1 | CM**2/SEC | CHI(I) NC HAZELTINE-HINTON: KAPISN_1 | xb | |
| FKBOL_K1 | CM**2/SEC | CHI(I) NC BOLTON: KAPISN_1 | xb | |
| FKCHH_K1 | CM**2/SEC | CHI(I) NC CHANG-HINTON ORIGINAL: KAPISN_1 | xb | |
| FKCH2_K1 | CM**2/SEC | CHI(I) NC CHANG-HINTON VSN 2: KAPISN_1 | xb | |
| FKCHZ_K1 | CM**2/SEC | CHI(I) NC CHANG-HINTON Z-CORR: KAPISN_1 | xb | |
| FKJUL_K0 | CM**2/SEC | CHI(I) NC RUTHERFORD-JULICH: KAPISN_0 | xb | |
| FKHZH_K0 | CM**2/SEC | CHI(I) NC HAZELTINE-HINTON: KAPISN_0 | xb | |
| FKBOL_K0 | CM**2/SEC | CHI(I) NC BOLTON: KAPISN_0 | xb | |
| FKCHH_K0 | CM**2/SEC | CHI(I) NC CHANG-HINTON ORIGINAL: KAPISN_0 | xb | |
| FKCH2_K0 | CM**2/SEC | CHI(I) NC CHANG-HINTON VSN 2: KAPISN_0 | xb | |
| FKCHZ_K0 | CM**2/SEC | CHI(I) NC CHANG-HINTON Z-CORR: KAPISN_0 | xb | |
| NCFTMINUS | NC trapping fraction lower limit | |||
| NCFTPLUS | NC trapping fraction upper limit | |||
| NCFT | NC trapping fraction (net) | |||
| BMAX | Tesla | Bmax on flux surface | ||
| BMIN | Tesla | Bmin on flux surface | ||
| GBR2 | Tesla*cm2 | <B*R**2> flux surface average | xc | |
| GB1 | Tesla | <B> flux surface average | xc | |
| GB2 | Tesla**2 | <B**2> flux surface average | xc | |
| GB2I | Tesla**-2 | <B**-2> flux surface average | xc | |
| ETAI | D(LN(TI))/D(LN("NI")) | xb | ||
| ETAIE | D(LN(TI))/D(LN(NE)) | xb | ||
| XETI0 | CM**2/SEC | CHI(ETA(I)) RAW | xb | |
| VETAI | ETA(I) VALIDITY CHECK | xb | ||
| GAINI | WATTS/CM3 | ION GAIN | xc | |
| PCMPI | WATTS/CM3 | ION COMPRESSION | xc | |
| PCOND | WATTS/CM3 | ION CONDUCTION LOSS | xc | |
| PCX | WATTS/CM3 | CHARGE EXCHANGE LOSS | xc | |
| PNI | WATTS/CM3 | NEUTRAL IONIZATION SOURCE | xc | |
| QIE | WATTS/CM3 | ION-ELECTRON COUPLING | xc | |
| QIESLVTX | WATTS/CM3 | ION-ELECTRON COUPLING(SLVTX) | xc | |
| P0NET | WATTS/CM3 | NET CHARGE EXCHANGE LOSS | xc | |
| PCONV | WATTS/CM3 | ION CONVECTION LOSS | xc | |
| CONDI | CM**2/SEC | ION HEAT DIFFUSIVITY | xb | |
| CONDIPR | CM**2/SEC | chi(i) predictive model | xb | |
| XKINC | CM**2/SEC | NEOCLASSICAL CHI(I) | xb | |
| XKEPALEO | CM**2/SEC | PALEOCLASSICAL CHI(E) | xb | |
| VPEPALEO | CM/SEC | PALEOCLASSICAL THERMAL PINCH | xb | |
| XKAPIGKF | CM**2/SEC | IFS-PPPL GYROFLUID MODEL CHI(I) | xb | |
| XKAPEGKF | CM**2/SEC | IFS-PPPL GYROFLUID MODEL CHI(E) | xb | |
| RLTCRGKF | R/LTi: critical ITG main br. | xb | ||
| RLTCRGKZ | R/LTi: critical ITG Carbon br. | xb | ||
| RLTI | R/LTi: actual ITG:R*Grad(Ti)/Ti | xb | ||
| XKIGLF23 | CM**2/SEC | GLF23 MODEL CHI(I) | xb | |
| XKEGLF23 | CM**2/SEC | GLF23 MODEL CHI(E) | xb | |
| DIFFIGLF | CM**2/SEC | GLF23 ION DIFFUSIVITY | xb | |
| ETPHIGLF | CM**2/SEC | GLF23 MOM (TOR) DIFFUSIVITY | xb | |
| XKINEO | CM**2/SEC | NEO MODEL CHI(I) | xb | |
| XKENEO | CM**2/SEC | NEO MODEL CHI(E) | xb | |
| DIFFINEO | CM**2/SEC | NEO ION DIFFUSIVITY | xb | |
| ETPHINEO | CM**2/SEC | NEO MOM (TOR) DIFFUSIVITY | xb | |
| VTINEO | CM/SEC | NEO THERMAL CONVECT. VEL | xb | |
| VTENEO | CM/SEC | NEO THERMAL CONVECT. VEL | xb | |
| VNINEO | CM/SEC | NEO ION PARTICLE CONVECT. VEL. | xb | |
| VPHINEO | CM/SEC | NEO TOR MOM CONVECT. VEL. | xb | |
| OME1W19 | RAD/SEC | WEILAND19 FREQUENCY MODE=1 | ||
| OME2W19 | RAD/SEC | WEILAND19 FREQUENCY MODE=2 | ||
| GAM1W19 | 1/SEC | WEILAND19 GROWTH RATE MODE=1 | ||
| GAM2W19 | 1/SEC | WEILAND19 GROWTH RATE MODE=2 | ||
| SREXBMOD | RAD/SEC | ExB Shear Rate (transport model) | xb | |
| SREXBA | RAD/SEC | ExB Shear Rate (selected) | xb | |
| SREXBV1 | RAD/SEC | ExB Shear Rate (exbshear.f90) | xb | |
| SREXBV2 | RAD/SEC | ExB Shear Rate (exbshear2.f90) | xb | |
| SREXBPHI | RAD/SEC | ExB Shear Rate (V_tor) | xb | |
| SREXBTHT | RAD/SEC | ExB Shear Rate (V_pol) | xb | |
| SREXBGRP | RAD/SEC | ExB Shear Rate (dp/dr) | xb | |
| XKIMMM07 | CM**2/SEC | MMM07 MODEL CHI(I) | xb | |
| XKEMMM07 | CM**2/SEC | MMM07 MODEL CHI(E) | xb | |
| XKZMMM07 | CM**2/SEC | MMM07 MODEL CHI(Z) | xb | |
| XPTMMM07 | CM**2/SEC | MMM07 MODEL CHI(Phi) | xb | |
| XPPMMM07 | CM**2/SEC | MMM07 MODEL CHI(Theta) | xb | |
| XKDMMM07 | CM**2/SEC | MMM07 MODEL D(E) | xb | |
| XKIW19 | CM**2/SEC | WEILAND19 MODEL CHI(I) | xb | |
| XKEW19 | CM**2/SEC | WEILAND19 MODEL CHI(E) | xb | |
| XKZW19 | CM**2/SEC | WEILAND19 MODEL CHI(Z) | xb | |
| XDIW19 | CM**2/SEC | WEILAND19 MODEL D(I) | xb | |
| XPTW19 | CM**2/SEC | WEILAND19 MODEL CHI(Phi) | xb | |
| XPPW19 | CM**2/SEC | WEILAND19 MODEL CHI(Theta) | xb | |
| XKIDRBM | CM**2/SEC | DRBM MODEL CHI(I) | xb | |
| XKEDRBM | CM**2/SEC | DRBM MODEL CHI(E) | xb | |
| XKHDRBM | CM**2/SEC | DRBM ION DIFFUSIVITY | xb | |
| VKHDRBM | CM/SEC | DRBM ION CONVECTIVE VELOCITY | xb | |
| GAMDRBM | 1/SEC | DRBM GRTH RATE MODE=1 | xb | |
| OMGDRBM | RAD/SEC | DRBM FREQUENCY MODE=1 | xb | |
| KYRSDRBM | - | DRBM MODEL KY*RHOS AT MAX GROWTH RATE | xc | |
| XKEMTM | CM**2/SEC | MTM MODEL CHI(E) | xb | |
| XDBMTM | - | MTM MODEL DB/B | xc | |
| GAMMAMTM | 1/SEC | MTM MODEL GROWTH RATE | xc | |
| OMEGAMTM | RAD/SEC | MTM MODEL FREQUENCY | xc | |
| KYRSMTM | - | MTM MODEL KY*RHOS AT MAX GROWTH RATE | xc | |
| XKEETG | CM**2/SEC | ETG MODEL CHI(E) | xb | |
| GAMMAETG | 1/SEC | ETG MODEL GROWTH RATE | xc | |
| OMEGAETG | RAD/SEC | ETG MODEL FREQUENCY | xc | |
| KYRSETG | - | ETG MODEL KY*RHOS AT MAX GROWTH RATE | xc | |
| XKICDBM | CM**2/SEC | CDBM MODEL CHI(I) | xb | |
| XKECDBM | CM**2/SEC | CDBM MODEL CHI(E) | xb | |
| VPHIMMM07 | CM/SEC | MMM07 TOR. CONV. VEL. | xb | |
| MODOT | Nt-M/CM3 | MOMENTUM GAIN | xc | |
| M0NET | Nt-M/CM3 | NET CX MOMENTUM LOSS | xc | |
| MVISC | Nt-M/CM3 | VISCOUS TRANSPORT | xc | |
| MCONV | Nt-M/CM3 | CONVECTIVE TRANSPORT | xc | |
| RODOT | WATTS/CM3 | ROTATIONAL ENERGY GAIN | xc | |
| R0NET | WATTS/CM3 | CX ROTATIONAL ENERGY LOSS | xc | |
| RVISC | WATTS/CM3 | VISCOUS ROT.ENERGY LOSS | xc | |
| RCONV | WATTS/CM3 | CONVECTIVE ROT.ENERGY LOSS | xc | |
| RCMPR | WATTS/CM3 | ROTATION COMPRESSION | xc | |
| RSFRC | WATTS/CM3 | ROTATION SOURCE FRICTION | xc | |
| QROTF | WATTS/CM3 | E(ROT)=>ION HEATING: FRICTION | xc | |
| QROTC | WATTS/CM3 | E(ROT)=>ION HEATING: CONVECTIVE | xc | |
| QROT | WATTS/CM3 | E(ROT)=> ION HEAT: CONV+FRICTION | ||
| TAUPHI | SECONDS | MOMENTUM CONFINEMENT | xb | |
| CHPHI | CM**2/SEC | MOMENTUM DIFFUSIVITY | xb | |
| CHPHM | CM**2/SEC | MOMENTUM CHI(PHI) MODEL | xb | |
| CHPHDAT | CM**2/SEC | MOMENTUM CHI(PHI) DATA | xb | |
| CHPHMNC | CM**2/SEC | MOMENTUM CHI(PHI) NEOCLASSICAL | xb | |
| DNIDT | N/CM3/SEC | D/DT(TOTAL ION DENSITY) | xc | |
| DIVFI | N/CM3/SEC | DIV(TOTAL ION FLUX) | xc | |
| SBTOT | N/CM3/SEC | TOTAL ION SCE(BEAM + HALO) | xc | |
| SWTOT | N/CM3/SEC | TOTAL ION SCE(WALL NEUTRALS) | xc | |
| SBAL_ION | N/CM3/SEC | Total Ion Particle Balance | xc | |
| IPTR_MOD | N/CM3/SEC | Div(total ion flux) (model) | xc | |
| IPTR_OBS | N/CM3/SEC | Div(total ion flux) (observed) | xc | |
| IETR_MOD | WATTS/CM3 | Div(ion energy flux) (model) | xc | |
| IETR_OBS | WATTS/CM3 | Div(ion energy flux) (observed) | xc | |
| AMTR_MOD | Nt-M/CM3 | Div(ang. momentum flux) (model) | xc | |
| AMTR_OBS | Nt-M/CM3 | Div(ang. momentum flux) (obs.) | xc | |
| UPWIND_TE | Electron Energy Balance UPWIND ADJUST | xb | ||
| UPWIND_TI | Ion Energy Balance UPWIND ADJUST | xb | ||
| UPWIND_MO | Angular Momentum Balance UPWIND ADJUST | xb | ||
| XZIMPJ | Zonal Avg Z of Impurity | xc | ||
| ZIMPS_TOK | TOK Avg. Mult. Impurity Z | |||
| AIMPJ | Zonal avg A of impurity | xc | ||
| VELIAV | CM/SEC | density averaged ion radial velocity | xb | |
| VEL_TE | CM/SEC | electron energy radial velocity | xb | |
| VEL_TI | CM/SEC | ion energy radial velocity | xb | |
| DNIMP | N/CM3/SEC | D/DT(IMPURITY DENSITY) | xc | |
| DFIMP | N/CM3/SEC | DIV(IMPURITY FLUX) | xc | |
| DIFFX | CM**2/SEC | EFF. IMP ION DIFFUSIVITY | xb | |
| SCIMP | N/CM3/SEC | IMPURITY SOURCE | xc | |
| VELIM | CM/SEC | IMPURITY RADIAL VELOCITY | xb | |
| DZIMP | N/CM3/SEC | D/DT(IMPURITY SPECIE) | xc | |
| XPTR_MOD | N/CM3/SEC | Div(impurity flux) (model) | xc | |
| XPTR_OBS | N/CM3/SEC | Div(impurity flux) (observed) | xc | |
| DNDDT | N/CM3/SEC | D/DT(ION DENS D+) | xc | |
| DIVFD | N/CM3/SEC | DIV(ION FLUX D+) | xc | |
| DIFFD | CM**2/SEC | EFF. D+ ION DIFFUSIVITY | ||
| SVD | N/CM3/SEC | TOT ION SCE BEAM+HALO D+ | ||
| SWD | N/CM3/SEC | TOT ION SCE WALL D+ | ||
| SBAL_D | N/CM3/SEC | D PTCL BALANCE | xc | |
| UPWIND_D | D ION UPWIND ADJUST ACTIVATION | xb | ||
| VELD | CM/SEC | ION VELOCITY (NET) D+ | ||
| TAUPD | SECONDS | D+ ION PTCL CONFINEMENT | ||
| PTRD_MOD | N/CM3/SEC | Div(D ion flux) (model) | xc | |
| PTRD_OBS | N/CM3/SEC | Div(D ion flux) (observed) | xc | |
| GFLNC_D | N/CM3/SEC | div(NC ptcl flux) thermal D+ | xc | |
| QFLNC_D | WATTS/CM3 | div(NC heat flux) thermal D+ | xc | |
| QFLNCC_D | WATTS/CM3 | div(NC class heat flux) D+ | xc | |
| CONDWNCD | CM**2/SEC | NCLASS D+ heat diffusivity | xb | |
| TEI | SECONDS | ION ENERGY CONFINEMENT | xb | |
| TEIST | SECONDS | ION ENERGY CONFINEMENT (*) | xb | |
| DIFFI | CM**2/SEC | ION DIFFUSIVITY FROM TOTAL FLUX | xb | |
| DIFFI0 | CM**2/SEC | INPUT ION DIFFUSIVITY (NMODEL=4) | xb | |
| DFI_D | CM**2/SEC | D+ ION DIFFUSIVITY (NMODEL=4) | xb | |
| VND_D | CM/SEC | D+ NON-DIFFUSIVE FLOW VELOCITY | xb | |
| BTI | ION BETA TOROIDAL | xc | ||
| TAUPI | SECONDS | ION PTCL CONFINEMENT | xb | |
| NIMP | N/CM**3 | TOTAL IMPURITY DENSITY | xc | |
| NIMP_SINGL | N/CM**3 | SINGL Impurity Density | ||
| SIMDATA | N/CM**3 | TOTAL MULT. IMPURITY INPUT | xc | |
| NIMPS_TOK | N/CM**3 | TOK Total Impurity Density | ||
| NIMPDATA | N/CM**3 | IMPURITY DENSITY INPUT DATA | xc | |
| TX | EV | IMPURITY TEMPERATURE | xc | |
| TMJ | EV | H/HE MAJORITY TEMPERATURE | xc | |
| TMJSM | EV | H/HE MAJORITY TEMP(SMOOTHED) | xc | |
| TIAV | EV | TIavg=(nx*TX+nmj*TMJ)/(nx+nmj) | xc | |
| DN0VD | N/CM**3 | VOL NEUTRAL DENSITY G=D | ||
| DN0WD | N/CM**3 | WALL NEUTRAL DENS G=D | ||
| T0VD | EV | VOL NEUTRAL TEMP G=D | ||
| T0WD | EV | WALL NEUTRAL TEMP G=D | ||
| OM0VD | RAD/SEC | VOL NEUTRAL ANG.VEL G=D | ||
| OM0WD | RAD/SEC | WALL NEUTRAL ANG.VEL G=D | ||
| S0V0D | N/CM3/SEC | RECOMB NEUTRAL SCE G=D | ||
| SIV0D | N/CM3/SEC | RECOMB RECAP ION SCE G=D | ||
| N0V0_D | N/CM**3 | RECOMB neutral density G=D | ||
| T0V0_D | EV | RECOMB neutral temp G=D | ||
| OM0V0_D | RAD/SEC | RECOMB neutral ang. veloc. G=D | ||
| S0RECO | N/CM3/SEC | TOTAL RECOMB NEUTRAL SCE | xc | |
| SERECO | N/CM3/SEC | TOTAL RECOMB RECAP ION SCE | xc | |
| SFCXRECO | N/CM3/SEC | RECOMB NEUTRALS -> FAST ION CX | xc | |
| FLX0_RECO | N/CM3/SEC | DIV(RECOMB NEUTRAL FLUX) | xc | |
| BALN0_RECO | N/CM3/SEC | RECOMB NEUTRAL PTCL BALANCE | xc | |
| P0RECO | WATTS/CM3 | RECOMB NEUTRAL SCE POWER | xc | |
| PCXRECO | WATTS/CM3 | CX POWER TO RECOMB NEUTRALS | xc | |
| PIRECO | WATTS/CM3 | RECOMB NEUTRAL RECAPTURE POWER | xc | |
| PFLX0RECO | WATTS/CM3 | DIV(RECOMB NEUTRAL POWER FLUX) | xc | |
| BALE0_RECO | WATTS/CM3 | RECOMB NEUTRAL POWER BALANCE | xc | |
| TQ0RECO | Nt-M/CM3 | RECOMB NEUTRAL SCE TORQUE | xc | |
| TQCXRECO | Nt-M/CM3 | CX TORQUE TO RECOMB NEUTRALS | xc | |
| TQIRECO | Nt-M/CM3 | RECOMB NEUTRAL RECAPTURE TORQUE | xc | |
| TQ0FLRECO | Nt-M/CM3 | DIV(RECOMB NEUTRAL ANG.MO. FLUX) | xc | |
| TQBA0_RECO | Nt-M/CM3 | RECOMB NEUTRAL ANG.MO. BALANCE | xc | |
| PSC_HALO | WATTS/CM3 | beam halo source/sink power | xc | |
| PCX_HALO | WATTS/CM3 | beam halo driven cx power | xc | |
| TQSC_HALO | Nt-M/CM3 | beam halo source/sink torque | xc | |
| TQCX_HALO | Nt-M/CM3 | beam halo driven cx torque | xc | |
| SBCXD | N/CM3/SEC | D_0 NEUTRAL SOURCE BEAM HALO | ||
| SIHALO_D | N/CM3/SEC | BEAM HALO RECAP ION SCE G=D | ||
| N0BH_D | N/CM**3 | beam halo neutral density G=D | ||
| T0BH_D | EV | beam halo neutral temp G=D | ||
| OM0BH_D | RAD/SEC | beam halo n0 ang. veloc. G=D | ||
| S0HALO | N/CM3/SEC | TOTAL (e-) in HALO NEUTRAL SCE | xc | |
| SEHALO | N/CM3/SEC | (e-) RECAP in HALO ION SCEs | xc | |
| SFCXHALO | N/CM3/SEC | HALO NEUTRALS (e-)=> FAST ION CX | xc | |
| FLX0_HALO | N/CM3/SEC | DIV(HALO (e-) NEUTRAL FLUX) | xc | |
| BALN0_HALO | N/CM3/SEC | HALO (e-) NEUTRAL PTCL BALANCE | xc | |
| P0HALO | WATTS/CM3 | HALO NEUTRAL SCE POWER | xc | |
| PCXHALO | WATTS/CM3 | CX POWER TO HALO NEUTRALS | xc | |
| PIHALO | WATTS/CM3 | HALO NEUTRAL RECAPTURE POWER | xc | |
| PFLX0HALO | WATTS/CM3 | DIV(HALO NEUTRAL POWER FLUX) | xc | |
| BALE0_HALO | WATTS/CM3 | HALO NEUTRAL POWER BALANCE | xc | |
| TQ0HALO | Nt-M/CM3 | HALO NEUTRAL SCE TORQUE | xc | |
| TQCXHALO | Nt-M/CM3 | CX TORQUE TO HALO NEUTRALS | xc | |
| TQIHALO | Nt-M/CM3 | HALO NEUTRAL RECAPTURE TORQUE | xc | |
| TQ0FLHALO | Nt-M/CM3 | DIV(HALO NEUTRAL ANG.MO. FLUX) | xc | |
| TQBA0_HALO | Nt-M/CM3 | HALO NEUTRAL ANG.MO. BALANCE | xc | |
| SISGF_D | N/CM3/SEC | gas flow ION SCE G=D | ||
| N0SGF_D | N/CM**3 | gas flow neutral dens G=D | ||
| SESGF | N/CM3/SEC | gas flow electron source | xc | |
| SFCXSGF | N/CM3/SEC | gas flow (e-)=> FAST ION CX | xc | |
| FLX0_SGF | N/CM3/SEC | DIV(gas flow (e-) NEUTRAL FLUX) | xc | |
| BALN0_SGF | N/CM3/SEC | gas flow (e-) NEUTRAL PTCL BAL. | xc | |
| PCXSGF | WATTS/CM3 | CX POWER to gas flow NEUTRALS | xc | |
| PISGF | WATTS/CM3 | gas fl neutral ionization POWER | xc | |
| PFLX0SGF | WATTS/CM3 | DIV(gas flow NEUTRAL POWER FLUX) | xc | |
| BALE0_SGF | WATTS/CM3 | gas flow NEUTRAL POWER BALANCE | xc | |
| TQCXSGF | Nt-M/CM3 | CX TORQUE TO gas flow NEUTRALS | xc | |
| TQISGF | Nt-M/CM3 | gas fl NEUTRAL ionization TORQUE | xc | |
| TQ0FLSGF | Nt-M/CM3 | DIV(gas fl NEUTRAL ANG.MO. FLUX) | xc | |
| TQBA0_SGF | Nt-M/CM3 | gas flow NEUTRAL ANG.MO. BALANCE | xc | |
| T0CX_GFD | EV | CX NEUTRAL TEMP. gas flow D | ||
| OM0CX_GFD | RAD/SEC | CX ANG. VELOC. gas flow D | ||
| CFPCX_GFD | WATTS/CM3/EV | CX POWER COEFF. gas flow D | ||
| CFTCX_GFD | Nt-M/CM3/(RAD/S) | CX TORQUE COEFF. gas flow D | ||
| SEGF_D | N/CM3/SEC | D gas flow electron source | ||
| SFCXGF_D | N/CM3/SEC | D gas (e-)=> FAST ION CX | ||
| FLX0_GF_D | N/CM3/SEC | D DIV(gas (e-) NEUTRAL FLUX) | ||
| BALN0_GF_D | N/CM3/SEC | D gas (e-) NEUTRAL PTCL BAL. | ||
| PCXGF_D | WATTS/CM3 | CX POWER to D gas NEUTRALS | ||
| PIGF_D | WATTS/CM3 | D gas flow ionization POWER | ||
| PFLX0GF_D | WATTS/CM3 | D DIV(gas flow POWER FLUX) | ||
| BALE0_GF_D | WATTS/CM3 | D gas flow POWER BALANCE | ||
| TQCXGF_D | Nt-M/CM3 | CX TORQUE TO D gas NEUTRALS | ||
| TQIGF_D | Nt-M/CM3 | D gas flow ionization TORQUE | ||
| TQ0FLGF_D | Nt-M/CM3 | D DIV(gas flow ANG.MO. FLUX) | ||
| TQBA0_GF_D | Nt-M/CM3 | D gas flow ANG.MO. BALANCE | ||
| N0GF_D_D | N/CM**3 | D n0 due to D gas flow | ||
| T0GF_D_D | EV | D T0 due to D gas flow | ||
| OM0GF_D_D | RAD/SEC | D omega0 due to D gas flow | ||
| SIGF_D_D | N/CM3/SEC | D ion sce from D gas flow | ||
| SISRC_D | N/CM3/SEC | recycling ION SCE G=D | ||
| N0SRC_D | N/CM**3 | recycling neutral dens G=D | ||
| SESRC | N/CM3/SEC | recycling electron source | xc | |
| SFCXSRC | N/CM3/SEC | recyling (e-)=> FAST ION CX | xc | |
| FLX0_SRC | N/CM3/SEC | DIV(recyling (e-) NEUTRAL FLUX) | xc | |
| BALN0_SRC | N/CM3/SEC | recyling (e-) NEUTRAL PTCL BAL. | xc | |
| PCXSRC | WATTS/CM3 | CX POWER to recyling NEUTRALS | xc | |
| PISRC | WATTS/CM3 | recyc neutral ionization POWER | xc | |
| PFLX0SRC | WATTS/CM3 | DIV(recyling NEUTRAL POWER FLUX) | xc | |
| BALE0_SRC | WATTS/CM3 | recyling NEUTRAL POWER BALANCE | xc | |
| TQCXSRC | Nt-M/CM3 | CX TORQUE TO recyling NEUTRALS | xc | |
| TQISRC | Nt-M/CM3 | recyc NEUTRAL ionization TORQUE | xc | |
| TQ0FLSRC | Nt-M/CM3 | DIV(recyc NEUTRAL ANG.MO. FLUX) | xc | |
| TQBA0_SRC | Nt-M/CM3 | recyling NEUTRAL ANG.MO. BALANCE | xc | |
| T0CX_RCD | EV | CX NEUTRAL TEMP. recyc. D | ||
| OM0CX_RCD | RAD/SEC | CX ANG. VELOC. recyc. D | ||
| CFPCX_RCD | WATTS/CM3/EV | CX POWER COEFF. recyc. D | ||
| CFTCX_RCD | Nt-M/CM3/(RAD/S) | CX TORQUE COEFF. recyc. D | ||
| SERC_D | N/CM3/SEC | D recyc electron source | ||
| SFCXRC_D | N/CM3/SEC | D recyc (e-)=> FAST ION CX | ||
| FLX0_RC_D | N/CM3/SEC | D DIV(recyc (e-) NEUTRAL FLUX) | ||
| BALN0_RC_D | N/CM3/SEC | D recyc (e-) NEUTRAL PTCL BAL. | ||
| PCXRC_D | WATTS/CM3 | CX POWER to D recyc NEUTRALS | ||
| PIRC_D | WATTS/CM3 | D recyc ionization POWER | ||
| PFLX0RC_D | WATTS/CM3 | D DIV(recyc POWER FLUX) | ||
| BALE0_RC_D | WATTS/CM3 | D recyc POWER BALANCE | ||
| TQCXRC_D | Nt-M/CM3 | CX TORQUE TO D recyc NEUTRALS | ||
| TQIRC_D | Nt-M/CM3 | D recyc ionization TORQUE | ||
| TQ0FLRC_D | Nt-M/CM3 | D DIV(recyc ANG.MO. FLUX) | ||
| TQBA0_RC_D | Nt-M/CM3 | D recyc ANG.MO. BALANCE | ||
| N0RC_D_D | N/CM**3 | D n0 due to D recyc | ||
| T0RC_D_D | EV | D T0 due to D recyc | ||
| OM0RC_D_D | RAD/SEC | D omega0 due to D recyc | ||
| SIRC_D_D | N/CM3/SEC | D ion sce from D recyc | ||
| BALN0 | N/CM3/SEC | BALANCE CHECK | xc | |
| S0VOL | N/CM3/SEC | TOTAL NEUTRAL VOL E-SCE | xc | |
| FLX0I | N/CM3/SEC | DIV(NEUTRAL INFLUX) | xc | |
| FLX0X | N/CM3/SEC | DIV(NEUTRAL OUTFLUX) | xc | |
| SFETO | N/CM3/SEC | ELECTRONS -> FAST NEUTRALS | xc | |
| SCEE | N/CM3/SEC | ELECTRON SOURCE (TH.NEUTRALS) | xc | |
| BALE0 | WATTS/CM3 | NEUTRAL POWER BALANCE | xc | |
| S0VLE | WATTS/CM3 | TOTAL NEUTRAL VOL SCE | xc | |
| FL0EI | WATTS/CM3 | DIV(NEUTRAL E-INFLUX) | xc | |
| FL0EX | WATTS/CM3 | DIV(NEUTRAL E-OUTFLUX) | xc | |
| TQBA0 | Nt-M/CM3 | NEUTRAL TORQUE BALANCE | xc | |
| TQ0VL | Nt-M/CM3 | NEUTRAL VOL SCE TORQUE | xc | |
| TQ0FL | Nt-M/CM3 | DIV(neutral ANG.MOMENTUM FLUX) | xc | |
| TQCX | Nt-M/CM3 | CHARGE EXCHANGE TORQUE | xc | |
| TQIZ | Nt-M/CM3 | IONIZATION TORQUE | xc | |
| UE | JLES/CM3 | ELECTRON ENERGY DENSITY | xc | |
| UTOTL | JLES/CM3 | TOTAL ENERGY DENSITY | xc | |
| GFUN | G: PARA/DIAMAGNETISM | xb | ||
| GFUNC | G: GRAD-SHAF EQUILIBRIUM CHECK | xb | ||
| FBX | |B|/|BT(EXTERNAL)| | midplane R | ||
| FBTX | |BT|/|BT(EXTERNAL)| | midplane R | ||
| BTX | TESLA | |BT(EXTERNAL)| | midplane R | |
| XILMP | TOROIDAL FLUX LABEL | midplane R | ||
| TRFMP | WEBERS | TOROIDAL FLUX | midplane R | |
| PLFMP | Wb/rad | POLOIDAL FLUX | midplane R | |
| QMP | ROTATIONAL TRANSFORM | midplane R | ||
| HLFMP | Wb/rad | HELICAL FLUX | midplane R | |
| FBPBT | |BP|/|BT| COMPUTED | midplane R | ||
| JGPHR2I | AMPS/CM | <J.grad(phi)>/<1/R**2> | xc | |
| PLJBBGPI | AMPS/CM | <J.B>/<B.grad(phi)> | xc | |
| QDATA | Q profile (Ufile data) | xb | ||
| RGRID | cm | R axis for psi(R,Z) | R axis for psi(R,Z) | |
| ZGRID | cm | Z axis for psi(R,Z) | Z axis for psi(R,Z) | |
| PSIRZ | Wb/rad | psi(R,Z) on rectangular R,Z grid | psi(R,Z) as the grid axis | |
| UBPRP | JLES/CM3 | BEAM PERP ENERGY DENSITY | xc | |
| UBPAR | JLES/CM3 | BEAM PLL ENERGY DENSITY | xc | |
| PTOWB | PASCALS | KINETIC MHD PRESSURE W/FAST IONS | xc | |
| PCHK | PASCALS | P: Surf. Avg. Grad-Shaf Check | xc | |
| PPLAS | PASCALS | PLASMA PRESSURE | xc | |
| PMHD_IN | PASCALS | PRESSURE INPUT to MHD SOLVER | xc | |
| PMHDT_IN | PASCALS | THERMAL PRESSURE to MHD SOLVER | xc | |
| PMHDR_IN | PASCALS | ROTATION PRESSURE to MHD SOLVER | xc | |
| PMHDF_IN | PASCALS | NONTHERMAL PRESS to MHD SOLVER | xc | |
| UBPRP_D | JLES/CM3 | D BEAM PERP ENERGY DENSITY | xc | |
| UBPAR_D | JLES/CM3 | D BEAM PLL ENERGY DENSITY | xc | |
| BDC01 | AMPS/CM2 | nb: Beam#01(D),SHLD BEAM DRIVEN | ||
| UDC01 | AMPS/CM2 | nb: Beam#01(D),UNSHLD BEAM DRIVE | ||
| NB01_TOT | N/CM**3 | nb: Beam#01(D), total density | ||
| NB01_E1 | N/CM**3 | nb: Beam#01(D), E-frac no.1 | ||
| NB01_E2 | N/CM**3 | nb: Beam#01(D), E-frac no.2 | ||
| NB01_E3 | N/CM**3 | nb: Beam#01(D), E-frac no.3 | ||
| BDEP01_TOT | N/CM3/SEC | bdep: Beam#01(D),total depositio | ||
| BDEP01_E1 | N/CM3/SEC | bdep: Beam#01(D), E-frac no.1 | ||
| BDEP01_E2 | N/CM3/SEC | bdep: Beam#01(D), E-frac no.2 | ||
| BDEP01_E3 | N/CM3/SEC | bdep: Beam#01(D), E-frac no.3 | ||
| PBTOT01 | WATTS/CM3 | Beam#01(D), total power | ||
| PBE01_TOT | WATTS/CM3 | Beam#01(D), electron heating | ||
| PBE01_E1 | WATTS/CM3 | Pbe: Beam#01(D), E-frac no.1 | ||
| PBE01_E2 | WATTS/CM3 | Pbe: Beam#01(D), E-frac no.2 | ||
| PBE01_E3 | WATTS/CM3 | Pbe: Beam#01(D), E-frac no.3 | ||
| PBI01_TOT | WATTS/CM3 | Beam#01(D), ion heating | ||
| PBI01_E1 | WATTS/CM3 | Pbi: Beam#01(D), E-frac no.1 | ||
| PBI01_E2 | WATTS/CM3 | Pbi: Beam#01(D), E-frac no.2 | ||
| PBI01_E3 | WATTS/CM3 | Pbi: Beam#01(D), E-frac no.3 | ||
| PBTH01 | WATTS/CM3 | Beam#01(D), thermalization power | ||
| VPB01_E1 | T*CM/SEC | Vpll*B: Beam no.01(D), E-frac#1 | ||
| VPB01_E2 | T*CM/SEC | Vpll*B: Beam no.01(D), E-frac#2 | ||
| VPB01_E3 | T*CM/SEC | Vpll*B: Beam no.01(D), E-frac#3 | ||
| TQTOT01 | Nt-M/CM3 | Beam#01(D) total torque | ||
| TQCOL01 | Nt-M/CM3 | Beam#01(D) collisional torque | ||
| TQJB01 | Nt-M/CM3 | Beam#01(D) JxB torque | ||
| TQTH01 | Nt-M/CM3 | Beam#01(D) thermalization torque | ||
| TQJBD01 | Nt-M/CM3 | Beam#01(D) JxB torque | ||
| BDC02 | AMPS/CM2 | nb: Beam#02(D),SHLD BEAM DRIVEN | ||
| UDC02 | AMPS/CM2 | nb: Beam#02(D),UNSHLD BEAM DRIVE | ||
| NB02_TOT | N/CM**3 | nb: Beam#02(D), total density | ||
| NB02_E1 | N/CM**3 | nb: Beam#02(D), E-frac no.1 | ||
| NB02_E2 | N/CM**3 | nb: Beam#02(D), E-frac no.2 | ||
| NB02_E3 | N/CM**3 | nb: Beam#02(D), E-frac no.3 | ||
| BDEP02_TOT | N/CM3/SEC | bdep: Beam#02(D),total depositio | ||
| BDEP02_E1 | N/CM3/SEC | bdep: Beam#02(D), E-frac no.1 | ||
| BDEP02_E2 | N/CM3/SEC | bdep: Beam#02(D), E-frac no.2 | ||
| BDEP02_E3 | N/CM3/SEC | bdep: Beam#02(D), E-frac no.3 | ||
| PBTOT02 | WATTS/CM3 | Beam#02(D), total power | ||
| PBE02_TOT | WATTS/CM3 | Beam#02(D), electron heating | ||
| PBE02_E1 | WATTS/CM3 | Pbe: Beam#02(D), E-frac no.1 | ||
| PBE02_E2 | WATTS/CM3 | Pbe: Beam#02(D), E-frac no.2 | ||
| PBE02_E3 | WATTS/CM3 | Pbe: Beam#02(D), E-frac no.3 | ||
| PBI02_TOT | WATTS/CM3 | Beam#02(D), ion heating | ||
| PBI02_E1 | WATTS/CM3 | Pbi: Beam#02(D), E-frac no.1 | ||
| PBI02_E2 | WATTS/CM3 | Pbi: Beam#02(D), E-frac no.2 | ||
| PBI02_E3 | WATTS/CM3 | Pbi: Beam#02(D), E-frac no.3 | ||
| PBTH02 | WATTS/CM3 | Beam#02(D), thermalization power | ||
| VPB02_E1 | T*CM/SEC | Vpll*B: Beam no.02(D), E-frac#1 | ||
| VPB02_E2 | T*CM/SEC | Vpll*B: Beam no.02(D), E-frac#2 | ||
| VPB02_E3 | T*CM/SEC | Vpll*B: Beam no.02(D), E-frac#3 | ||
| TQTOT02 | Nt-M/CM3 | Beam#02(D) total torque | ||
| TQCOL02 | Nt-M/CM3 | Beam#02(D) collisional torque | ||
| TQJB02 | Nt-M/CM3 | Beam#02(D) JxB torque | ||
| TQTH02 | Nt-M/CM3 | Beam#02(D) thermalization torque | ||
| TQJBD02 | Nt-M/CM3 | Beam#02(D) JxB torque | ||
| BDC03 | AMPS/CM2 | nb: Beam#03(D),SHLD BEAM DRIVEN | ||
| UDC03 | AMPS/CM2 | nb: Beam#03(D),UNSHLD BEAM DRIVE | ||
| NB03_TOT | N/CM**3 | nb: Beam#03(D), total density | ||
| NB03_E1 | N/CM**3 | nb: Beam#03(D), E-frac no.1 | ||
| NB03_E2 | N/CM**3 | nb: Beam#03(D), E-frac no.2 | ||
| NB03_E3 | N/CM**3 | nb: Beam#03(D), E-frac no.3 | ||
| BDEP03_TOT | N/CM3/SEC | bdep: Beam#03(D),total depositio | ||
| BDEP03_E1 | N/CM3/SEC | bdep: Beam#03(D), E-frac no.1 | ||
| BDEP03_E2 | N/CM3/SEC | bdep: Beam#03(D), E-frac no.2 | ||
| BDEP03_E3 | N/CM3/SEC | bdep: Beam#03(D), E-frac no.3 | ||
| PBTOT03 | WATTS/CM3 | Beam#03(D), total power | ||
| PBE03_TOT | WATTS/CM3 | Beam#03(D), electron heating | ||
| PBE03_E1 | WATTS/CM3 | Pbe: Beam#03(D), E-frac no.1 | ||
| PBE03_E2 | WATTS/CM3 | Pbe: Beam#03(D), E-frac no.2 | ||
| PBE03_E3 | WATTS/CM3 | Pbe: Beam#03(D), E-frac no.3 | ||
| PBI03_TOT | WATTS/CM3 | Beam#03(D), ion heating | ||
| PBI03_E1 | WATTS/CM3 | Pbi: Beam#03(D), E-frac no.1 | ||
| PBI03_E2 | WATTS/CM3 | Pbi: Beam#03(D), E-frac no.2 | ||
| PBI03_E3 | WATTS/CM3 | Pbi: Beam#03(D), E-frac no.3 | ||
| PBTH03 | WATTS/CM3 | Beam#03(D), thermalization power | ||
| VPB03_E1 | T*CM/SEC | Vpll*B: Beam no.03(D), E-frac#1 | ||
| VPB03_E2 | T*CM/SEC | Vpll*B: Beam no.03(D), E-frac#2 | ||
| VPB03_E3 | T*CM/SEC | Vpll*B: Beam no.03(D), E-frac#3 | ||
| TQTOT03 | Nt-M/CM3 | Beam#03(D) total torque | ||
| TQCOL03 | Nt-M/CM3 | Beam#03(D) collisional torque | ||
| TQJB03 | Nt-M/CM3 | Beam#03(D) JxB torque | ||
| TQTH03 | Nt-M/CM3 | Beam#03(D) thermalization torque | ||
| TQJBD03 | Nt-M/CM3 | Beam#03(D) JxB torque | ||
| BDC04 | AMPS/CM2 | nb: Beam#04(D),SHLD BEAM DRIVEN | ||
| UDC04 | AMPS/CM2 | nb: Beam#04(D),UNSHLD BEAM DRIVE | ||
| NB04_TOT | N/CM**3 | nb: Beam#04(D), total density | ||
| NB04_E1 | N/CM**3 | nb: Beam#04(D), E-frac no.1 | ||
| NB04_E2 | N/CM**3 | nb: Beam#04(D), E-frac no.2 | ||
| NB04_E3 | N/CM**3 | nb: Beam#04(D), E-frac no.3 | ||
| BDEP04_TOT | N/CM3/SEC | bdep: Beam#04(D),total depositio | ||
| BDEP04_E1 | N/CM3/SEC | bdep: Beam#04(D), E-frac no.1 | ||
| BDEP04_E2 | N/CM3/SEC | bdep: Beam#04(D), E-frac no.2 | ||
| BDEP04_E3 | N/CM3/SEC | bdep: Beam#04(D), E-frac no.3 | ||
| PBTOT04 | WATTS/CM3 | Beam#04(D), total power | ||
| PBE04_TOT | WATTS/CM3 | Beam#04(D), electron heating | ||
| PBE04_E1 | WATTS/CM3 | Pbe: Beam#04(D), E-frac no.1 | ||
| PBE04_E2 | WATTS/CM3 | Pbe: Beam#04(D), E-frac no.2 | ||
| PBE04_E3 | WATTS/CM3 | Pbe: Beam#04(D), E-frac no.3 | ||
| PBI04_TOT | WATTS/CM3 | Beam#04(D), ion heating | ||
| PBI04_E1 | WATTS/CM3 | Pbi: Beam#04(D), E-frac no.1 | ||
| PBI04_E2 | WATTS/CM3 | Pbi: Beam#04(D), E-frac no.2 | ||
| PBI04_E3 | WATTS/CM3 | Pbi: Beam#04(D), E-frac no.3 | ||
| PBTH04 | WATTS/CM3 | Beam#04(D), thermalization power | ||
| VPB04_E1 | T*CM/SEC | Vpll*B: Beam no.04(D), E-frac#1 | ||
| VPB04_E2 | T*CM/SEC | Vpll*B: Beam no.04(D), E-frac#2 | ||
| VPB04_E3 | T*CM/SEC | Vpll*B: Beam no.04(D), E-frac#3 | ||
| TQTOT04 | Nt-M/CM3 | Beam#04(D) total torque | ||
| TQCOL04 | Nt-M/CM3 | Beam#04(D) collisional torque | ||
| TQJB04 | Nt-M/CM3 | Beam#04(D) JxB torque | ||
| TQTH04 | Nt-M/CM3 | Beam#04(D) thermalization torque | ||
| TQJBD04 | Nt-M/CM3 | Beam#04(D) JxB torque | ||
| BDC05 | AMPS/CM2 | nb: Beam#05(D),SHLD BEAM DRIVEN | ||
| UDC05 | AMPS/CM2 | nb: Beam#05(D),UNSHLD BEAM DRIVE | ||
| NB05_TOT | N/CM**3 | nb: Beam#05(D), total density | ||
| NB05_E1 | N/CM**3 | nb: Beam#05(D), E-frac no.1 | ||
| NB05_E2 | N/CM**3 | nb: Beam#05(D), E-frac no.2 | ||
| NB05_E3 | N/CM**3 | nb: Beam#05(D), E-frac no.3 | ||
| BDEP05_TOT | N/CM3/SEC | bdep: Beam#05(D),total depositio | ||
| BDEP05_E1 | N/CM3/SEC | bdep: Beam#05(D), E-frac no.1 | ||
| BDEP05_E2 | N/CM3/SEC | bdep: Beam#05(D), E-frac no.2 | ||
| BDEP05_E3 | N/CM3/SEC | bdep: Beam#05(D), E-frac no.3 | ||
| PBTOT05 | WATTS/CM3 | Beam#05(D), total power | ||
| PBE05_TOT | WATTS/CM3 | Beam#05(D), electron heating | ||
| PBE05_E1 | WATTS/CM3 | Pbe: Beam#05(D), E-frac no.1 | ||
| PBE05_E2 | WATTS/CM3 | Pbe: Beam#05(D), E-frac no.2 | ||
| PBE05_E3 | WATTS/CM3 | Pbe: Beam#05(D), E-frac no.3 | ||
| PBI05_TOT | WATTS/CM3 | Beam#05(D), ion heating | ||
| PBI05_E1 | WATTS/CM3 | Pbi: Beam#05(D), E-frac no.1 | ||
| PBI05_E2 | WATTS/CM3 | Pbi: Beam#05(D), E-frac no.2 | ||
| PBI05_E3 | WATTS/CM3 | Pbi: Beam#05(D), E-frac no.3 | ||
| PBTH05 | WATTS/CM3 | Beam#05(D), thermalization power | ||
| VPB05_E1 | T*CM/SEC | Vpll*B: Beam no.05(D), E-frac#1 | ||
| VPB05_E2 | T*CM/SEC | Vpll*B: Beam no.05(D), E-frac#2 | ||
| VPB05_E3 | T*CM/SEC | Vpll*B: Beam no.05(D), E-frac#3 | ||
| TQTOT05 | Nt-M/CM3 | Beam#05(D) total torque | ||
| TQCOL05 | Nt-M/CM3 | Beam#05(D) collisional torque | ||
| TQJB05 | Nt-M/CM3 | Beam#05(D) JxB torque | ||
| TQTH05 | Nt-M/CM3 | Beam#05(D) thermalization torque | ||
| TQJBD05 | Nt-M/CM3 | Beam#05(D) JxB torque | ||
| BDC06 | AMPS/CM2 | nb: Beam#06(D),SHLD BEAM DRIVEN | ||
| UDC06 | AMPS/CM2 | nb: Beam#06(D),UNSHLD BEAM DRIVE | ||
| NB06_TOT | N/CM**3 | nb: Beam#06(D), total density | ||
| NB06_E1 | N/CM**3 | nb: Beam#06(D), E-frac no.1 | ||
| NB06_E2 | N/CM**3 | nb: Beam#06(D), E-frac no.2 | ||
| NB06_E3 | N/CM**3 | nb: Beam#06(D), E-frac no.3 | ||
| BDEP06_TOT | N/CM3/SEC | bdep: Beam#06(D),total depositio | ||
| BDEP06_E1 | N/CM3/SEC | bdep: Beam#06(D), E-frac no.1 | ||
| BDEP06_E2 | N/CM3/SEC | bdep: Beam#06(D), E-frac no.2 | ||
| BDEP06_E3 | N/CM3/SEC | bdep: Beam#06(D), E-frac no.3 | ||
| PBTOT06 | WATTS/CM3 | Beam#06(D), total power | ||
| PBE06_TOT | WATTS/CM3 | Beam#06(D), electron heating | ||
| PBE06_E1 | WATTS/CM3 | Pbe: Beam#06(D), E-frac no.1 | ||
| PBE06_E2 | WATTS/CM3 | Pbe: Beam#06(D), E-frac no.2 | ||
| PBE06_E3 | WATTS/CM3 | Pbe: Beam#06(D), E-frac no.3 | ||
| PBI06_TOT | WATTS/CM3 | Beam#06(D), ion heating | ||
| PBI06_E1 | WATTS/CM3 | Pbi: Beam#06(D), E-frac no.1 | ||
| PBI06_E2 | WATTS/CM3 | Pbi: Beam#06(D), E-frac no.2 | ||
| PBI06_E3 | WATTS/CM3 | Pbi: Beam#06(D), E-frac no.3 | ||
| PBTH06 | WATTS/CM3 | Beam#06(D), thermalization power | ||
| VPB06_E1 | T*CM/SEC | Vpll*B: Beam no.06(D), E-frac#1 | ||
| VPB06_E2 | T*CM/SEC | Vpll*B: Beam no.06(D), E-frac#2 | ||
| VPB06_E3 | T*CM/SEC | Vpll*B: Beam no.06(D), E-frac#3 | ||
| TQTOT06 | Nt-M/CM3 | Beam#06(D) total torque | ||
| TQCOL06 | Nt-M/CM3 | Beam#06(D) collisional torque | ||
| TQJB06 | Nt-M/CM3 | Beam#06(D) JxB torque | ||
| TQTH06 | Nt-M/CM3 | Beam#06(D) thermalization torque | ||
| TQJBD06 | Nt-M/CM3 | Beam#06(D) JxB torque | ||
| BDC07 | AMPS/CM2 | nb: Beam#07(D),SHLD BEAM DRIVEN | ||
| UDC07 | AMPS/CM2 | nb: Beam#07(D),UNSHLD BEAM DRIVE | ||
| NB07_TOT | N/CM**3 | nb: Beam#07(D), total density | ||
| NB07_E1 | N/CM**3 | nb: Beam#07(D), E-frac no.1 | ||
| NB07_E2 | N/CM**3 | nb: Beam#07(D), E-frac no.2 | ||
| NB07_E3 | N/CM**3 | nb: Beam#07(D), E-frac no.3 | ||
| BDEP07_TOT | N/CM3/SEC | bdep: Beam#07(D),total depositio | ||
| BDEP07_E1 | N/CM3/SEC | bdep: Beam#07(D), E-frac no.1 | ||
| BDEP07_E2 | N/CM3/SEC | bdep: Beam#07(D), E-frac no.2 | ||
| BDEP07_E3 | N/CM3/SEC | bdep: Beam#07(D), E-frac no.3 | ||
| PBTOT07 | WATTS/CM3 | Beam#07(D), total power | ||
| PBE07_TOT | WATTS/CM3 | Beam#07(D), electron heating | ||
| PBE07_E1 | WATTS/CM3 | Pbe: Beam#07(D), E-frac no.1 | ||
| PBE07_E2 | WATTS/CM3 | Pbe: Beam#07(D), E-frac no.2 | ||
| PBE07_E3 | WATTS/CM3 | Pbe: Beam#07(D), E-frac no.3 | ||
| PBI07_TOT | WATTS/CM3 | Beam#07(D), ion heating | ||
| PBI07_E1 | WATTS/CM3 | Pbi: Beam#07(D), E-frac no.1 | ||
| PBI07_E2 | WATTS/CM3 | Pbi: Beam#07(D), E-frac no.2 | ||
| PBI07_E3 | WATTS/CM3 | Pbi: Beam#07(D), E-frac no.3 | ||
| PBTH07 | WATTS/CM3 | Beam#07(D), thermalization power | ||
| VPB07_E1 | T*CM/SEC | Vpll*B: Beam no.07(D), E-frac#1 | ||
| VPB07_E2 | T*CM/SEC | Vpll*B: Beam no.07(D), E-frac#2 | ||
| VPB07_E3 | T*CM/SEC | Vpll*B: Beam no.07(D), E-frac#3 | ||
| TQTOT07 | Nt-M/CM3 | Beam#07(D) total torque | ||
| TQCOL07 | Nt-M/CM3 | Beam#07(D) collisional torque | ||
| TQJB07 | Nt-M/CM3 | Beam#07(D) JxB torque | ||
| TQTH07 | Nt-M/CM3 | Beam#07(D) thermalization torque | ||
| TQJBD07 | Nt-M/CM3 | Beam#07(D) JxB torque | ||
| BDC08 | AMPS/CM2 | nb: Beam#08(D),SHLD BEAM DRIVEN | ||
| UDC08 | AMPS/CM2 | nb: Beam#08(D),UNSHLD BEAM DRIVE | ||
| NB08_TOT | N/CM**3 | nb: Beam#08(D), total density | ||
| NB08_E1 | N/CM**3 | nb: Beam#08(D), E-frac no.1 | ||
| NB08_E2 | N/CM**3 | nb: Beam#08(D), E-frac no.2 | ||
| NB08_E3 | N/CM**3 | nb: Beam#08(D), E-frac no.3 | ||
| BDEP08_TOT | N/CM3/SEC | bdep: Beam#08(D),total depositio | ||
| BDEP08_E1 | N/CM3/SEC | bdep: Beam#08(D), E-frac no.1 | ||
| BDEP08_E2 | N/CM3/SEC | bdep: Beam#08(D), E-frac no.2 | ||
| BDEP08_E3 | N/CM3/SEC | bdep: Beam#08(D), E-frac no.3 | ||
| PBTOT08 | WATTS/CM3 | Beam#08(D), total power | ||
| PBE08_TOT | WATTS/CM3 | Beam#08(D), electron heating | ||
| PBE08_E1 | WATTS/CM3 | Pbe: Beam#08(D), E-frac no.1 | ||
| PBE08_E2 | WATTS/CM3 | Pbe: Beam#08(D), E-frac no.2 | ||
| PBE08_E3 | WATTS/CM3 | Pbe: Beam#08(D), E-frac no.3 | ||
| PBI08_TOT | WATTS/CM3 | Beam#08(D), ion heating | ||
| PBI08_E1 | WATTS/CM3 | Pbi: Beam#08(D), E-frac no.1 | ||
| PBI08_E2 | WATTS/CM3 | Pbi: Beam#08(D), E-frac no.2 | ||
| PBI08_E3 | WATTS/CM3 | Pbi: Beam#08(D), E-frac no.3 | ||
| PBTH08 | WATTS/CM3 | Beam#08(D), thermalization power | ||
| VPB08_E1 | T*CM/SEC | Vpll*B: Beam no.08(D), E-frac#1 | ||
| VPB08_E2 | T*CM/SEC | Vpll*B: Beam no.08(D), E-frac#2 | ||
| VPB08_E3 | T*CM/SEC | Vpll*B: Beam no.08(D), E-frac#3 | ||
| TQTOT08 | Nt-M/CM3 | Beam#08(D) total torque | ||
| TQCOL08 | Nt-M/CM3 | Beam#08(D) collisional torque | ||
| TQJB08 | Nt-M/CM3 | Beam#08(D) JxB torque | ||
| TQTH08 | Nt-M/CM3 | Beam#08(D) thermalization torque | ||
| TQJBD08 | Nt-M/CM3 | Beam#08(D) JxB torque | ||
| BDC09 | AMPS/CM2 | nb: Beam#09(D),SHLD BEAM DRIVEN | ||
| UDC09 | AMPS/CM2 | nb: Beam#09(D),UNSHLD BEAM DRIVE | ||
| NB09_TOT | N/CM**3 | nb: Beam#09(D), total density | ||
| NB09_E1 | N/CM**3 | nb: Beam#09(D), E-frac no.1 | ||
| NB09_E2 | N/CM**3 | nb: Beam#09(D), E-frac no.2 | ||
| NB09_E3 | N/CM**3 | nb: Beam#09(D), E-frac no.3 | ||
| BDEP09_TOT | N/CM3/SEC | bdep: Beam#09(D),total depositio | ||
| BDEP09_E1 | N/CM3/SEC | bdep: Beam#09(D), E-frac no.1 | ||
| BDEP09_E2 | N/CM3/SEC | bdep: Beam#09(D), E-frac no.2 | ||
| BDEP09_E3 | N/CM3/SEC | bdep: Beam#09(D), E-frac no.3 | ||
| PBTOT09 | WATTS/CM3 | Beam#09(D), total power | ||
| PBE09_TOT | WATTS/CM3 | Beam#09(D), electron heating | ||
| PBE09_E1 | WATTS/CM3 | Pbe: Beam#09(D), E-frac no.1 | ||
| PBE09_E2 | WATTS/CM3 | Pbe: Beam#09(D), E-frac no.2 | ||
| PBE09_E3 | WATTS/CM3 | Pbe: Beam#09(D), E-frac no.3 | ||
| PBI09_TOT | WATTS/CM3 | Beam#09(D), ion heating | ||
| PBI09_E1 | WATTS/CM3 | Pbi: Beam#09(D), E-frac no.1 | ||
| PBI09_E2 | WATTS/CM3 | Pbi: Beam#09(D), E-frac no.2 | ||
| PBI09_E3 | WATTS/CM3 | Pbi: Beam#09(D), E-frac no.3 | ||
| PBTH09 | WATTS/CM3 | Beam#09(D), thermalization power | ||
| VPB09_E1 | T*CM/SEC | Vpll*B: Beam no.09(D), E-frac#1 | ||
| VPB09_E2 | T*CM/SEC | Vpll*B: Beam no.09(D), E-frac#2 | ||
| VPB09_E3 | T*CM/SEC | Vpll*B: Beam no.09(D), E-frac#3 | ||
| TQTOT09 | Nt-M/CM3 | Beam#09(D) total torque | ||
| TQCOL09 | Nt-M/CM3 | Beam#09(D) collisional torque | ||
| TQJB09 | Nt-M/CM3 | Beam#09(D) JxB torque | ||
| TQTH09 | Nt-M/CM3 | Beam#09(D) thermalization torque | ||
| TQJBD09 | Nt-M/CM3 | Beam#09(D) JxB torque | ||
| BDC10 | AMPS/CM2 | nb: Beam#10(D),SHLD BEAM DRIVEN | ||
| UDC10 | AMPS/CM2 | nb: Beam#10(D),UNSHLD BEAM DRIVE | ||
| NB10_TOT | N/CM**3 | nb: Beam#10(D), total density | ||
| NB10_E1 | N/CM**3 | nb: Beam#10(D), E-frac no.1 | ||
| NB10_E2 | N/CM**3 | nb: Beam#10(D), E-frac no.2 | ||
| NB10_E3 | N/CM**3 | nb: Beam#10(D), E-frac no.3 | ||
| BDEP10_TOT | N/CM3/SEC | bdep: Beam#10(D),total depositio | ||
| BDEP10_E1 | N/CM3/SEC | bdep: Beam#10(D), E-frac no.1 | ||
| BDEP10_E2 | N/CM3/SEC | bdep: Beam#10(D), E-frac no.2 | ||
| BDEP10_E3 | N/CM3/SEC | bdep: Beam#10(D), E-frac no.3 | ||
| PBTOT10 | WATTS/CM3 | Beam#10(D), total power | ||
| PBE10_TOT | WATTS/CM3 | Beam#10(D), electron heating | ||
| PBE10_E1 | WATTS/CM3 | Pbe: Beam#10(D), E-frac no.1 | ||
| PBE10_E2 | WATTS/CM3 | Pbe: Beam#10(D), E-frac no.2 | ||
| PBE10_E3 | WATTS/CM3 | Pbe: Beam#10(D), E-frac no.3 | ||
| PBI10_TOT | WATTS/CM3 | Beam#10(D), ion heating | ||
| PBI10_E1 | WATTS/CM3 | Pbi: Beam#10(D), E-frac no.1 | ||
| PBI10_E2 | WATTS/CM3 | Pbi: Beam#10(D), E-frac no.2 | ||
| PBI10_E3 | WATTS/CM3 | Pbi: Beam#10(D), E-frac no.3 | ||
| PBTH10 | WATTS/CM3 | Beam#10(D), thermalization power | ||
| VPB10_E1 | T*CM/SEC | Vpll*B: Beam no.10(D), E-frac#1 | ||
| VPB10_E2 | T*CM/SEC | Vpll*B: Beam no.10(D), E-frac#2 | ||
| VPB10_E3 | T*CM/SEC | Vpll*B: Beam no.10(D), E-frac#3 | ||
| TQTOT10 | Nt-M/CM3 | Beam#10(D) total torque | ||
| TQCOL10 | Nt-M/CM3 | Beam#10(D) collisional torque | ||
| TQJB10 | Nt-M/CM3 | Beam#10(D) JxB torque | ||
| TQTH10 | Nt-M/CM3 | Beam#10(D) thermalization torque | ||
| TQJBD10 | Nt-M/CM3 | Beam#10(D) JxB torque | ||
| BDC11 | AMPS/CM2 | nb: Beam#11(D),SHLD BEAM DRIVEN | ||
| UDC11 | AMPS/CM2 | nb: Beam#11(D),UNSHLD BEAM DRIVE | ||
| NB11_TOT | N/CM**3 | nb: Beam#11(D), total density | ||
| NB11_E1 | N/CM**3 | nb: Beam#11(D), E-frac no.1 | ||
| NB11_E2 | N/CM**3 | nb: Beam#11(D), E-frac no.2 | ||
| NB11_E3 | N/CM**3 | nb: Beam#11(D), E-frac no.3 | ||
| BDEP11_TOT | N/CM3/SEC | bdep: Beam#11(D),total depositio | ||
| BDEP11_E1 | N/CM3/SEC | bdep: Beam#11(D), E-frac no.1 | ||
| BDEP11_E2 | N/CM3/SEC | bdep: Beam#11(D), E-frac no.2 | ||
| BDEP11_E3 | N/CM3/SEC | bdep: Beam#11(D), E-frac no.3 | ||
| PBTOT11 | WATTS/CM3 | Beam#11(D), total power | ||
| PBE11_TOT | WATTS/CM3 | Beam#11(D), electron heating | ||
| PBE11_E1 | WATTS/CM3 | Pbe: Beam#11(D), E-frac no.1 | ||
| PBE11_E2 | WATTS/CM3 | Pbe: Beam#11(D), E-frac no.2 | ||
| PBE11_E3 | WATTS/CM3 | Pbe: Beam#11(D), E-frac no.3 | ||
| PBI11_TOT | WATTS/CM3 | Beam#11(D), ion heating | ||
| PBI11_E1 | WATTS/CM3 | Pbi: Beam#11(D), E-frac no.1 | ||
| PBI11_E2 | WATTS/CM3 | Pbi: Beam#11(D), E-frac no.2 | ||
| PBI11_E3 | WATTS/CM3 | Pbi: Beam#11(D), E-frac no.3 | ||
| PBTH11 | WATTS/CM3 | Beam#11(D), thermalization power | ||
| VPB11_E1 | T*CM/SEC | Vpll*B: Beam no.11(D), E-frac#1 | ||
| VPB11_E2 | T*CM/SEC | Vpll*B: Beam no.11(D), E-frac#2 | ||
| VPB11_E3 | T*CM/SEC | Vpll*B: Beam no.11(D), E-frac#3 | ||
| TQTOT11 | Nt-M/CM3 | Beam#11(D) total torque | ||
| TQCOL11 | Nt-M/CM3 | Beam#11(D) collisional torque | ||
| TQJB11 | Nt-M/CM3 | Beam#11(D) JxB torque | ||
| TQTH11 | Nt-M/CM3 | Beam#11(D) thermalization torque | ||
| TQJBD11 | Nt-M/CM3 | Beam#11(D) JxB torque | ||
| BDC12 | AMPS/CM2 | nb: Beam#12(D),SHLD BEAM DRIVEN | ||
| UDC12 | AMPS/CM2 | nb: Beam#12(D),UNSHLD BEAM DRIVE | ||
| NB12_TOT | N/CM**3 | nb: Beam#12(D), total density | ||
| NB12_E1 | N/CM**3 | nb: Beam#12(D), E-frac no.1 | ||
| NB12_E2 | N/CM**3 | nb: Beam#12(D), E-frac no.2 | ||
| NB12_E3 | N/CM**3 | nb: Beam#12(D), E-frac no.3 | ||
| BDEP12_TOT | N/CM3/SEC | bdep: Beam#12(D),total depositio | ||
| BDEP12_E1 | N/CM3/SEC | bdep: Beam#12(D), E-frac no.1 | ||
| BDEP12_E2 | N/CM3/SEC | bdep: Beam#12(D), E-frac no.2 | ||
| BDEP12_E3 | N/CM3/SEC | bdep: Beam#12(D), E-frac no.3 | ||
| PBTOT12 | WATTS/CM3 | Beam#12(D), total power | ||
| PBE12_TOT | WATTS/CM3 | Beam#12(D), electron heating | ||
| PBE12_E1 | WATTS/CM3 | Pbe: Beam#12(D), E-frac no.1 | ||
| PBE12_E2 | WATTS/CM3 | Pbe: Beam#12(D), E-frac no.2 | ||
| PBE12_E3 | WATTS/CM3 | Pbe: Beam#12(D), E-frac no.3 | ||
| PBI12_TOT | WATTS/CM3 | Beam#12(D), ion heating | ||
| PBI12_E1 | WATTS/CM3 | Pbi: Beam#12(D), E-frac no.1 | ||
| PBI12_E2 | WATTS/CM3 | Pbi: Beam#12(D), E-frac no.2 | ||
| PBI12_E3 | WATTS/CM3 | Pbi: Beam#12(D), E-frac no.3 | ||
| PBTH12 | WATTS/CM3 | Beam#12(D), thermalization power | ||
| VPB12_E1 | T*CM/SEC | Vpll*B: Beam no.12(D), E-frac#1 | ||
| VPB12_E2 | T*CM/SEC | Vpll*B: Beam no.12(D), E-frac#2 | ||
| VPB12_E3 | T*CM/SEC | Vpll*B: Beam no.12(D), E-frac#3 | ||
| TQTOT12 | Nt-M/CM3 | Beam#12(D) total torque | ||
| TQCOL12 | Nt-M/CM3 | Beam#12(D) collisional torque | ||
| TQJB12 | Nt-M/CM3 | Beam#12(D) JxB torque | ||
| TQTH12 | Nt-M/CM3 | Beam#12(D) thermalization torque | ||
| TQJBD12 | Nt-M/CM3 | Beam#12(D) JxB torque | ||
| BDC13 | AMPS/CM2 | nb: Beam#13(D),SHLD BEAM DRIVEN | ||
| UDC13 | AMPS/CM2 | nb: Beam#13(D),UNSHLD BEAM DRIVE | ||
| NB13_TOT | N/CM**3 | nb: Beam#13(D), total density | ||
| NB13_E1 | N/CM**3 | nb: Beam#13(D), E-frac no.1 | ||
| NB13_E2 | N/CM**3 | nb: Beam#13(D), E-frac no.2 | ||
| NB13_E3 | N/CM**3 | nb: Beam#13(D), E-frac no.3 | ||
| BDEP13_TOT | N/CM3/SEC | bdep: Beam#13(D),total depositio | ||
| BDEP13_E1 | N/CM3/SEC | bdep: Beam#13(D), E-frac no.1 | ||
| BDEP13_E2 | N/CM3/SEC | bdep: Beam#13(D), E-frac no.2 | ||
| BDEP13_E3 | N/CM3/SEC | bdep: Beam#13(D), E-frac no.3 | ||
| PBTOT13 | WATTS/CM3 | Beam#13(D), total power | ||
| PBE13_TOT | WATTS/CM3 | Beam#13(D), electron heating | ||
| PBE13_E1 | WATTS/CM3 | Pbe: Beam#13(D), E-frac no.1 | ||
| PBE13_E2 | WATTS/CM3 | Pbe: Beam#13(D), E-frac no.2 | ||
| PBE13_E3 | WATTS/CM3 | Pbe: Beam#13(D), E-frac no.3 | ||
| PBI13_TOT | WATTS/CM3 | Beam#13(D), ion heating | ||
| PBI13_E1 | WATTS/CM3 | Pbi: Beam#13(D), E-frac no.1 | ||
| PBI13_E2 | WATTS/CM3 | Pbi: Beam#13(D), E-frac no.2 | ||
| PBI13_E3 | WATTS/CM3 | Pbi: Beam#13(D), E-frac no.3 | ||
| PBTH13 | WATTS/CM3 | Beam#13(D), thermalization power | ||
| VPB13_E1 | T*CM/SEC | Vpll*B: Beam no.13(D), E-frac#1 | ||
| VPB13_E2 | T*CM/SEC | Vpll*B: Beam no.13(D), E-frac#2 | ||
| VPB13_E3 | T*CM/SEC | Vpll*B: Beam no.13(D), E-frac#3 | ||
| TQTOT13 | Nt-M/CM3 | Beam#13(D) total torque | ||
| TQCOL13 | Nt-M/CM3 | Beam#13(D) collisional torque | ||
| TQJB13 | Nt-M/CM3 | Beam#13(D) JxB torque | ||
| TQTH13 | Nt-M/CM3 | Beam#13(D) thermalization torque | ||
| TQJBD13 | Nt-M/CM3 | Beam#13(D) JxB torque | ||
| BDC14 | AMPS/CM2 | nb: Beam#14(D),SHLD BEAM DRIVEN | ||
| UDC14 | AMPS/CM2 | nb: Beam#14(D),UNSHLD BEAM DRIVE | ||
| NB14_TOT | N/CM**3 | nb: Beam#14(D), total density | ||
| NB14_E1 | N/CM**3 | nb: Beam#14(D), E-frac no.1 | ||
| NB14_E2 | N/CM**3 | nb: Beam#14(D), E-frac no.2 | ||
| NB14_E3 | N/CM**3 | nb: Beam#14(D), E-frac no.3 | ||
| BDEP14_TOT | N/CM3/SEC | bdep: Beam#14(D),total depositio | ||
| BDEP14_E1 | N/CM3/SEC | bdep: Beam#14(D), E-frac no.1 | ||
| BDEP14_E2 | N/CM3/SEC | bdep: Beam#14(D), E-frac no.2 | ||
| BDEP14_E3 | N/CM3/SEC | bdep: Beam#14(D), E-frac no.3 | ||
| PBTOT14 | WATTS/CM3 | Beam#14(D), total power | ||
| PBE14_TOT | WATTS/CM3 | Beam#14(D), electron heating | ||
| PBE14_E1 | WATTS/CM3 | Pbe: Beam#14(D), E-frac no.1 | ||
| PBE14_E2 | WATTS/CM3 | Pbe: Beam#14(D), E-frac no.2 | ||
| PBE14_E3 | WATTS/CM3 | Pbe: Beam#14(D), E-frac no.3 | ||
| PBI14_TOT | WATTS/CM3 | Beam#14(D), ion heating | ||
| PBI14_E1 | WATTS/CM3 | Pbi: Beam#14(D), E-frac no.1 | ||
| PBI14_E2 | WATTS/CM3 | Pbi: Beam#14(D), E-frac no.2 | ||
| PBI14_E3 | WATTS/CM3 | Pbi: Beam#14(D), E-frac no.3 | ||
| PBTH14 | WATTS/CM3 | Beam#14(D), thermalization power | ||
| VPB14_E1 | T*CM/SEC | Vpll*B: Beam no.14(D), E-frac#1 | ||
| VPB14_E2 | T*CM/SEC | Vpll*B: Beam no.14(D), E-frac#2 | ||
| VPB14_E3 | T*CM/SEC | Vpll*B: Beam no.14(D), E-frac#3 | ||
| TQTOT14 | Nt-M/CM3 | Beam#14(D) total torque | ||
| TQCOL14 | Nt-M/CM3 | Beam#14(D) collisional torque | ||
| TQJB14 | Nt-M/CM3 | Beam#14(D) JxB torque | ||
| TQTH14 | Nt-M/CM3 | Beam#14(D) thermalization torque | ||
| TQJBD14 | Nt-M/CM3 | Beam#14(D) JxB torque | ||
| TQJXBT | Nt-M/CM3 | BEAM JXB TORQUE | xc | |
| TQJBD | Nt-M/CM3 | BEAM DEP. JXB TORQUE | xc | |
| SSHAF | CM | SHAFRANOV SHIFT | xb | |
| SSHAFDA | CM | SHAFRANOV SHIFT (MHD DATA) | xb | |
| UI | JLES/CM3 | ION ENERGY DENSITY | xc | |
| UTHRM | JLES/CM3 | THERMAL ENERGY DENSITY | xc | |
| UFASTPP | JLES/CM3 | FAST ION PERP ENERGY DENSITY | ||
| UFASTPA | JLES/CM3 | FAST ION PLL ENERGY DENSITY | ||
| NUSTI | ION COLLISIONALITY | xc | ||
| NUSTE | ELECTRON COLLISIONALITY | xc | ||
| TAUES | SECONDS | PLASMA ENERGY CONFINEMENT (*) | xb | |
| TAUE | SECONDS | PLASMA ENERGY CONFINEMENT | xb | |
| BTPL | PLASMA BETA TOROIDAL | xc | ||
| BTTOT | TOTAL BETA TOROIDAL | xc | ||
| BTROT | ROTATION BETA TOROIDAL | xc | ||
| BOL_USE | W/cm**3 | BOL data as used | ||
| BOL_IN | W/cm**3 | BOL data as input | ||
| NER_USE | n/cm**3 | NER data as used | ||
| NER_IN | n/cm**3 | NER data as input | ||
| NIM_USE | n/cm**3 | NIM data as used | ||
| NIM_IN | n/cm**3 | NIM data as input | ||
| OMG_USE | rad/sec | OMG data as used | ||
| OMG_IN | rad/sec | OMG data as input | ||
| QPR_USE | QPR data as used | |||
| QPR_IN | QPR data as input | |||
| TER_USE | eV | TER data as used | ||
| TER_IN | eV | TER data as input | ||
| TI2_USE | eV | TI2 data as used | ||
| TI2_IN | eV | TI2 data as input | ||
| ZF2_USE | ZF2 data as used | |||
| ZF2_IN | ZF2 data as input | |||
| IHEAT | WATTS/CM3 | TOTAL ION HEATING | xc | |
| TIBAL | WATTS/CM3 | ION POWER BALANCE | xc | |
| BOGUSI | WATTS/CM3 | BOGUS HEATING TO KEEP TI > 0 | xc | |
| EHEAT | WATTS/CM3 | TOTAL ELECTRON HEATING | xc | |
| TEBAL | WATTS/CM3 | ELECTRON POWER BALANCE | xc | |
| BOGUSE | WATTS/CM3 | BOGUS HEATING TO KEEP TE > 0 | xc | |
| TQIN | Nt-M/CM3 | TOTAL INPUT TORQUE | xc | |
| PHBAL | Nt-M/CM3 | ANGULAR MOMENTUM BALANCE | xc | |
| TQNTV | Nt-M/CM3 | torque due to NTV neoclassical toroidal viscosity | xc | |
| RQNTV | WATTS/CM3 | NTV torque work | xc | |
| UPHIN | WATTS/CM3 | TOTAL ROTATIONAL ENERGY INPUT | xc | |
| UPBAL | WATTS/CM3 | ROTATIONAL ENERGY BALANCE | xc | |
| IRAEPT | AMPS | FAST ION RAD.CUR DUE TO AEP (MHD) ACTIVITY | xb | |
| PBAEPB_D | WATTS/CM3 | AEP POWER D beam | ||
| IRAEPB_D | AMPS | D BEAM ION RAD.CUR (AEP, MHD activity) | ||
| PBAEPMD_1 | WATTS/CM3 | AEP POWER D beam by mode1 | ||
| PBAEPMD_2 | WATTS/CM3 | AEP POWER D beam by mode2 | ||
| PBAEPMD_3 | WATTS/CM3 | AEP POWER D beam by mode3 | ||
| PBAEPMD_4 | WATTS/CM3 | AEP POWER D beam by mode4 | ||
| PBAEPMD_5 | WATTS/CM3 | AEP POWER D beam by mode5 | ||
| PBAEPMD_6 | WATTS/CM3 | AEP POWER D beam by mode6 | ||
| PBAEPMD_7 | WATTS/CM3 | AEP POWER D beam by mode7 | ||
| PBAEPMD_8 | WATTS/CM3 | AEP POWER D beam by mode8 | ||
| PBAEPMD_9 | WATTS/CM3 | AEP POWER D beam by mode9 | ||
| PBAEPMD_10 | WATTS/CM3 | AEP POWER D beam by mode10 | ||
| TR_YEAR | DOI 10.11578/dc.20180627.4 | |||
| TR_MAJV | Major version number | |||
| TR_MINV | Minor version number | |||
| PBINJ_D | WATTS | DBEAM MC IONS POWER INJECTED | ||
| PBDEPMC_D | WATTS | DBEAM MC IONS POWER DEPOSITED | ||
| PBSHINE_D | WATTS | DBEAM SHINE-THRU POWER | ||
| PBDEPBA_D | WATTS | DBEAM POWER, BALANCE CHECK | ||
| BPHINJS_D | NT-M | DBEAM MOMENTUM INJECTED | ||
| BPHSHIN_D | NT-M | DBEAM SH_THRU MOMENTUM | ||
| BPHDEP0_D | NT-M | DBEAM DEPOSITED MOMENTUM, ION point | ||
| BPHDEPGC_D | NT-M | DBEAM DEPOSITED MOMENTUM, at GC | ||
| BPHDPBA_D | NT-M | DBEAM MOMENTUM, BALANCE CHECK | ||
| GSERROR | REL.EQUIL.GRAD-SHAFRANOV ERROR | |||
| RZITER | RZSOLVER iterations | |||
| UL2PB | LI/2+BETA(POLOIDAL) UFILE | |||
| VISBC | VB UNITS | CHORDAL VB LIGHT (CALCULATED) | ||
| MNEUT | N/SEC | MEASURED NEUTRONS | ||
| UBDIA | UFILE BETA(DIAMAGNETIC) | |||
| BZ | TESLA | BZ @R=RMAJOR OUTSIDE PLASMA | ||
| BZXR | TESLA*CM | VACUUM FIELD "BZ*R" | ||
| TFLUX | WEBERS | ENCLOSED TOROIDAL FLUX | ||
| PLFLXA | Wb/rad | ENCLOSED POLOIDAL FLUX | ||
| PSI0_TR | Wb/rad | Psi_poloidal(axis) in simulation | ||
| PSI0_DATA | Wb/rad | Psi_poloidal(axis) input data | ||
| DFLXM | WEBERS | MEASURED DIAMAGNETIC FLUX | ||
| DFLUX | WEBERS | COMPUTED DIAMAGNETIC FLUX | ||
| ELDOT | 1/SEC | ELDOT: GRID MOTION | ||
| SEEDG | N/SEC | ELECTRONS VIA BDY | ||
| PEEDG | WATTS | ELECTRON ENERGY VIA BDY | ||
| PIEDG | WATTS | ION ENERGY VIA BDY | ||
| PCUR | AMPS | MEASURED PLASMA CURRENT | ||
| PCUREQ | AMPS | EQ PLASMA CURRENT | ||
| PCURC | AMPS | CALCULATED PLASMA CURRENT | ||
| VSUR0 | VOLTS | SURFACE VOLTAGE | ||
| ZEFFM | AXIAL MAGDIF. ZEFF | |||
| ZEFFC | AXIAL PLASMA COMPOSITION ZEFF | |||
| ZEFFI0 | INPUT AXIAL ZEFF (UNCONSTRAINED) | |||
| VSUR | VOLTS | MEAS.AVG. SURFACE VOLTAGE | ||
| VSURC | VOLTS | CALC.AVG. SURFACE VOLTAGE | ||
| FLSTA | 0=NORMAL | FALSI ERROR CODE | ||
| PVOL | CM**3 | PLASMA VOLUME | ||
| PAREA | CM**2 | PLASMA CROSS SECTION AREA | ||
| PVOLB | CM**3 | PLASMA VOLUME FROM BOUNDARY | ||
| PVOLF | CM**3 | PLASMA VOLUME FROM FLUX SURF | ||
| RMAJDIFF | CM | MAX DIFF BOUND AND FLUX MIDPLANE | ||
| RMAJBLIM | CM | RMAJ EXTENT OF THE BOUNDARY | ||
| RMAJDFRAC | MAX DIFF BOUND/MIDPLANE WIDTH | |||
| YMPBDY | CM | MIDPLANE | ||
| RMCB0 | CM | 0TH ASYM R BOUND MOMENT | ||
| YMCB0 | CM | 0TH ASYM Y BOUND MOMENT | ||
| RMCB1 | CM | 1st ASYM R COS BOUND MOMENT | ||
| RMSB1 | CM | 1st ASYM R SIN BOUND MOMENT | ||
| YMCB1 | CM | 1st ASYM Y COS BOUND MOMENT | ||
| YMSB1 | CM | 1st ASYM Y SIN BOUND MOMENT | ||
| RMCB2 | CM | 2nd ASYM R COS BOUND MOMENT | ||
| RMSB2 | CM | 2nd ASYM R SIN BOUND MOMENT | ||
| YMCB2 | CM | 2nd ASYM Y COS BOUND MOMENT | ||
| YMSB2 | CM | 2nd ASYM Y SIN BOUND MOMENT | ||
| RMCB3 | CM | 3rd ASYM R COS BOUND MOMENT | ||
| RMSB3 | CM | 3rd ASYM R SIN BOUND MOMENT | ||
| YMCB3 | CM | 3rd ASYM Y COS BOUND MOMENT | ||
| YMSB3 | CM | 3rd ASYM Y SIN BOUND MOMENT | ||
| RMCB4 | CM | 4th ASYM R COS BOUND MOMENT | ||
| RMSB4 | CM | 4th ASYM R SIN BOUND MOMENT | ||
| YMCB4 | CM | 4th ASYM Y COS BOUND MOMENT | ||
| YMSB4 | CM | 4th ASYM Y SIN BOUND MOMENT | ||
| RMCB5 | CM | 5th ASYM R COS BOUND MOMENT | ||
| RMSB5 | CM | 5th ASYM R SIN BOUND MOMENT | ||
| YMCB5 | CM | 5th ASYM Y COS BOUND MOMENT | ||
| YMSB5 | CM | 5th ASYM Y SIN BOUND MOMENT | ||
| RMCB6 | CM | 6th ASYM R COS BOUND MOMENT | ||
| RMSB6 | CM | 6th ASYM R SIN BOUND MOMENT | ||
| YMCB6 | CM | 6th ASYM Y COS BOUND MOMENT | ||
| YMSB6 | CM | 6th ASYM Y SIN BOUND MOMENT | ||
| RMCB7 | CM | 7th ASYM R COS BOUND MOMENT | ||
| RMSB7 | CM | 7th ASYM R SIN BOUND MOMENT | ||
| YMCB7 | CM | 7th ASYM Y COS BOUND MOMENT | ||
| YMSB7 | CM | 7th ASYM Y SIN BOUND MOMENT | ||
| RMCB8 | CM | 8th ASYM R COS BOUND MOMENT | ||
| RMSB8 | CM | 8th ASYM R SIN BOUND MOMENT | ||
| YMCB8 | CM | 8th ASYM Y COS BOUND MOMENT | ||
| YMSB8 | CM | 8th ASYM Y SIN BOUND MOMENT | ||
| RMCB9 | CM | 9th ASYM R COS BOUND MOMENT | ||
| RMSB9 | CM | 9th ASYM R SIN BOUND MOMENT | ||
| YMCB9 | CM | 9th ASYM Y COS BOUND MOMENT | ||
| YMSB9 | CM | 9th ASYM Y SIN BOUND MOMENT | ||
| RMCB10 | CM | 10th ASYM R COS BOUND MOMENT | ||
| RMSB10 | CM | 10th ASYM R SIN BOUND MOMENT | ||
| YMCB10 | CM | 10th ASYM Y COS BOUND MOMENT | ||
| YMSB10 | CM | 10th ASYM Y SIN BOUND MOMENT | ||
| RMCB11 | CM | 11th ASYM R COS BOUND MOMENT | ||
| RMSB11 | CM | 11th ASYM R SIN BOUND MOMENT | ||
| YMCB11 | CM | 11th ASYM Y COS BOUND MOMENT | ||
| YMSB11 | CM | 11th ASYM Y SIN BOUND MOMENT | ||
| RMCB12 | CM | 12th ASYM R COS BOUND MOMENT | ||
| RMSB12 | CM | 12th ASYM R SIN BOUND MOMENT | ||
| YMCB12 | CM | 12th ASYM Y COS BOUND MOMENT | ||
| YMSB12 | CM | 12th ASYM Y SIN BOUND MOMENT | ||
| RMCB13 | CM | 13th ASYM R COS BOUND MOMENT | ||
| RMSB13 | CM | 13th ASYM R SIN BOUND MOMENT | ||
| YMCB13 | CM | 13th ASYM Y COS BOUND MOMENT | ||
| YMSB13 | CM | 13th ASYM Y SIN BOUND MOMENT | ||
| RMCB14 | CM | 14th ASYM R COS BOUND MOMENT | ||
| RMSB14 | CM | 14th ASYM R SIN BOUND MOMENT | ||
| YMCB14 | CM | 14th ASYM Y COS BOUND MOMENT | ||
| YMSB14 | CM | 14th ASYM Y SIN BOUND MOMENT | ||
| RMCB15 | CM | 15th ASYM R COS BOUND MOMENT | ||
| RMSB15 | CM | 15th ASYM R SIN BOUND MOMENT | ||
| YMCB15 | CM | 15th ASYM Y COS BOUND MOMENT | ||
| YMSB15 | CM | 15th ASYM Y SIN BOUND MOMENT | ||
| RMCB16 | CM | 16th ASYM R COS BOUND MOMENT | ||
| RMSB16 | CM | 16th ASYM R SIN BOUND MOMENT | ||
| YMCB16 | CM | 16th ASYM Y COS BOUND MOMENT | ||
| YMSB16 | CM | 16th ASYM Y SIN BOUND MOMENT | ||
| RAXIS | CM | MAJOR RADIUS OF MAG. AXIS | ||
| YAXIS | CM | ASYMMETRIC GEO: Y OF MAG. AXIS | ||
| LIO2 | INDUCTANCE (LI/2) | |||
| HIO2 | INDUCTANCE (HI/2) | |||
| POHT | WATTS | OHMIC INPUT POWER | ||
| IPXVS | WATTS | PCUR * VSUR | ||
| CPTIM | HOURS | CPU TIME USED SO FAR | ||
| WALLTIME | HOURS | Elapsed wall clock time | ||
| CPPTRANSP | HOURS | CPU(WALL) TIME USED IN PTRANSP | ||
| PT_CPTIME | HOURS | CPU TIME USED (PT_SOLVER) | ||
| PT_WTIME | HOURS | WALL TIME USED (PT_SOLVER) | ||
| VOLTSEC0 | V*s | Axial flux consumption | ||
| VOLTSECBM | V*s | Boundary flux consumption based on meas. data | ||
| VOLTSECA | V*s | Poynting Average flux consumption | ||
| LI_1 | Inductance definition Li_1 | |||
| LI_3 | Inductance definition Li_3 | |||
| LI_VDIFF | Inductance: TRANSP V-diff norm. | |||
| RLI_3 | CM | Bdy R = (Rmin+Rmax)/2 for Li_3 | ||
| DT | SECONDS | ENERGY BALANCE TIMESTEP | ||
| DTG | SECONDS | TIMESTEP FOR GEOMETRY | ||
| DTSCE | SECONDS | TIMESTEP FOR SOURCES | ||
| DTPROFIL | SECONDS | TIME SPACING FOR PROFILE OUTPUT | ||
| DTSCALAR | SECONDS | TIME SPACING FOR SCALAR OUTPUT | ||
| DTMAXG | SECONDS | MAXIMUM TIMESTEP FOR GEOMETRY | ||
| CPOUT | HOURS | CPU TIME: OUTPUT SYSTEM | ||
| CPTRK | HOURS | CPU TIME: STRAIGHT LINE TRACKER | ||
| CPLH | HOURS | CPU TIME: JET LOWER HYBRID | ||
| CPGEOM | HOURS | CPU TIME: FLUX SURFACE GEOMETRY | ||
| CPMHDQ | HOURS | CPU TIME: MHD EQUILIBRIUM | ||
| CPGEOCAL | HOURS | CPU TIME: Flux Surf. Averages | ||
| LIO2M | LI/2 (MAGNETICS DATA ESTIMATE) | |||
| LIO2C | LI/2 (COMPUTED FROM J PROFILE) | |||
| ALPC | MAG:ALPHA, CALCULATED | |||
| RTPC | CM | MAG:RT, CALCULATED | ||
| MUIM | MAGNETICS EST. MU(DIA) | |||
| MUIC | TRANSP EST. MU(DIA) MHD EQ | |||
| LAMDM | MAGNETICS EST. LAMDA | |||
| LAMDC | KINETIC+J EST. LAMDA | |||
| BPDM | MAGNETICS EST. BETA(DIA) | |||
| BPDC | KINETIC BETA(DIA) | |||
| SHFSM | MAGNETICS EST. S1+S2 | |||
| SHFSC | CALCULATED S1+S2 | |||
| Q0 | Q ON AXIS | |||
| Q95 | Q at 0.95 poloidal flux | |||
| XIQ1 | xi of Q=1 surface | |||
| XIQ2 | xi of Q=2 surface | |||
| XIQ3 | xi of Q=3 surface | |||
| XIQ3_2 | xi of Q=3/2 surface | |||
| BBNTS_DD | N/SEC | DD BEAM-BEAM NEUTRONS | ||
| BTNTS_DD | N/SEC | DD BEAM-TARGET NEUTRONS | ||
| BPHTO | WATTS | TOTAL FAST ION HEATING | ||
| BPTI | WATTS | BEAM POWER TO IONS | ||
| BPTE | WATTS | BEAM POWER TO ELECTRONS | ||
| BBPER | BEAM BETA(POLOIDAL) PERP | |||
| BBPAR | BEAM BETA(POLOIDAL) PLL | |||
| BTNTS | N/SEC | BEAM-TARGET NEUTRONS | ||
| BBNTS | N/SEC | BEAM-BEAM NEUTRONS | ||
| EINJ | EV | MAX INITIAL BEAM ENERGY | ||
| SINJ | N/SEC | FAST NEUTRALS INJECTED | ||
| COFRC | BEAM FRACTION "CO" | |||
| BPSHI | WATTS | FAST ION SHINE-THRU POWER | ||
| BPCAP | WATTS | BEAM POWER CAPTURED | ||
| SFDEP | N/SEC | FAST ION SCE: DEPOSITION | ||
| SFRCAP | N/SEC | FAST ION CX RECAPTURE | ||
| PINJ | WATTS | BEAM POWER INJECTED | ||
| CPMCFI | HOURS | CPU: MONTE CARLO FAST ION CODE | ||
| CPBDEP | HOURS | CPU: FAST ION DEPOSITION | ||
| CPBMCINI | HOURS | CPU: FAST ION MC TABLE SETUP | ||
| CPXPGL | HOURS | CPU: xplasma load | ||
| CPBORB | HOURS | CPU: FAST ION ORBIT + COLLISIONS | ||
| CPBOUT | HOURS | CPU: FAST ION OUTPUT RENORM | ||
| CPBMAX | HOURS | MAX THREAD CPU TIME: NUBEAM | ||
| CPBMIN | HOURS | MIN THREAD CPU TIME: NUBEAM | ||
| CPBROOT | HOURS | ROOT THREAD CPU TIME: NUBEAM | ||
| WC_NUBEAM | HOURS | WALL CLOCK TIME: NUBEAM | ||
| BPLIM | WATTS | FAST ION ORBIT LOSS | ||
| BPCXI | WATTS | FAST ION POWER TO CX (INT) | ||
| BPCXX | WATTS | FAST ION POWER TO CX (EXT) | ||
| BPCI0 | WATTS | FAST ION CX SCE POWER (INT) | ||
| BPCX0 | WATTS | FAST ION CX SCE POWER (EXT) | ||
| BPCRI | WATTS | FAST ION CX RECAPTURE (INT) | ||
| BPCRX | WATTS | FAST ION CX RECAPTURE (EXT) | ||
| BPCXE | WATTS | FAST ION CX TRACKER ERROR | ||
| BPTH | WATTS | FAST ION POWER THERMALIZED | ||
| BPST | WATTS | FAST ION POWER STORED | ||
| BPOH | WATTS | POWER: OH CIRCUIT TO FAST IONS | ||
| BPCPR | WATTS | POWER: COMPRESSION OF FAST IONS | ||
| BPEPHI | WATTS | Electrostatic field -> fast ions | ||
| BPBAL | WATTS | FAST ION POWER BALANCE | ||
| BPERR | WATTS | FAST ION ORBIT POWER ERROR | ||
| BSTH | N/SEC | FAST ION THERMALIZATIONS | ||
| BSORB | N/SEC | FAST ION ORBIT LOSSES | ||
| BSORBPR | total prompt loss fraction of injected beam ions | |||
| BSNXI | N/SEC | FAST ION CX SINK (INT) | ||
| BSNXO | N/SEC | FAST ION CX SINK (EXT) | ||
| BSBAL | N/SEC | FAST ION PTCL BALANCE | ||
| BDNDT | N/SEC | D/DT(FAST ION POPULATION) | ||
| BDNDTX | N/SEC | D/DT(FAST IONS OUTSIDE PLASMA) | ||
| EINJAV_D | EV | D: avg full injection energy | ||
| TRAPB0_D | D beam full E dep banana frac. | |||
| TRAPB_D | D beam ions banana fraction | |||
| BPLIM_D | WATTS | D BEAM ORBIT LOSS | ||
| BPSHI_D | WATTS | D BEAM SHINE-THRU POWER | ||
| BPCXI_D | WATTS | D BEAM POWER TO CX (INT) | ||
| BPCXX_D | WATTS | D BEAM POWER TO CX (EXT) | ||
| BPCI0_D | WATTS | D BEAM CX SCE POWER (INT) | ||
| BPCX0_D | WATTS | D BEAM CX SCE POWER (EXT) | ||
| BPCRI_D | WATTS | D BEAM CX RECAPTURE (INT) | ||
| BPCRX_D | WATTS | D BEAM CX RECAPTURE (EXT) | ||
| BPCXE_D | WATTS | D BEAM CX TRACKER ERROR | ||
| BPTH_D | WATTS | D BEAM POWER THERMALIZED | ||
| BPST_D | WATTS | D BEAM POWER STORED | ||
| BPOH_D | WATTS | POWER: OH CIRCUIT TO D BEAM | ||
| BPEPHI_D | WATTS | ELECTROSTATIC ACCEL.: D BEAM | ||
| PRFB_D | WATTS | RF POWER -> D BEAM IONS | ||
| BPCPR_D | WATTS | POWER: COMPRESSION OF D BEAM | ||
| BPTI_D | WATTS | D BEAM POWER TO IONS | ||
| BPTE_D | WATTS | D BEAM POWER TO ELECTRONS | ||
| BPBAL_D | WATTS | D BEAM POWER BALANCE | ||
| BPERR_D | WATTS | D BEAM ORBIT POWER ERROR | ||
| PINJ_D | WATTS | TOTAL INJECTED D BEAM POWER | ||
| SINJ_D | N/SEC | FAST D BEAM NEUTRALS INJECTED | ||
| SINJEA_D | N/SEC | D DEP E.CONSERVATION ADJUST | ||
| COFRC_D | D BEAM FRACTION "CO" | |||
| BDNDT_D | N/SEC | D/DT(D BEAM ION POPULATION) | ||
| BDNDTX_D | N/SEC | D/DT(D BEAM IONS OUTSIDE PLASMA) | ||
| BSTH_D | N/SEC | D BEAM THERMALIZATIONS | ||
| BSORB_D | N/SEC | D BEAM ORBIT LOSSES | ||
| BSORBPR_D | FRACTION OF D BEAM ORBIT PROMPT LOSSES | |||
| BSNXI_D | N/SEC | D BEAM CX SINK (INT) | ||
| BSNXO_D | N/SEC | D BEAM CX SINK (EXT) | ||
| BSBAL_D | N/SEC | D BEAM PTCL BALANCE | ||
| SBSHINE_D | N/SEC | D BEAM SHINE-THROUGH | ||
| SBDEPRR_D | N/SEC | D BEAM DEP "RUSSIAN ROULETTE" | ||
| SBDEPMC_D | N/SEC | D BEAM MC IONS DEPOSITED | ||
| SBDEPBA_D | N/SEC | D BEAM DEP PTCL BALANCE | ||
| SBDEPSC_D | N/SEC | D BEAM TOTAL DEPOSITION SCE | ||
| SBDEPIZ_D | N/SEC | D BEAM DEP: TH.IONIZATION | ||
| SBDEPCX_D | N/SEC | D BEAM DEP: CX W/THERMAL IONS | ||
| SBDBBIZ_D | N/SEC | D BEAM DEP: BEAM-BEAM IONIZ. | ||
| SBDBBCX_D | N/SEC | D BEAM DEP: BEAM-BEAM CX | ||
| SBCX0MC_D | N/SEC | D BEAM CX NEUTRALS LAUNCHED | ||
| SBCXESC_D | N/SEC | D BEAM CX NEUTRALS ESCAPED | ||
| SBCXRR_D | N/SEC | D BEAM CX NEUTRALS "R.R." | ||
| SBCXRMC_D | N/SEC | D BEAM CX MC IONS RECAPTURED | ||
| SBCXBAL_D | N/SEC | D BEAM CX NEUTRAL PTCL BAL | ||
| SBORBRR_D | N/SEC | D BEAM ORBIT CODE "R.R." | ||
| SBDTBMC_D | N/SEC | D BEAM MC RATE OF CHANGE | ||
| SBORBAL_D | N/SEC | D BEAM ORBIT PTCL BALANCE | ||
| SBXRCSC_D | N/SEC | D BEAM TOTAL RECAPTURE SCE | ||
| SBXRCIZ_D | N/SEC | D BEAM RECAP: TH.IONIZATION | ||
| SBXRCCX_D | N/SEC | D BEAM RECAP: TH.CX | ||
| SBRBBIZ_D | N/SEC | D BEAM RECAP: BEAM-BEAM IONIZ. | ||
| SBRBBCX_D | N/SEC | D BEAM RECAP: BEAM-BEAM CX | ||
| SNBXTOT_D | N/SEC | TOTAL D BEAM ION CX SINK | ||
| SNBXW0_D | N/SEC | D BEAM ION CX SINK: WALL NEUTS | ||
| SNBXV0_D | N/SEC | D BEAM ION CX SINK: HALO NEUTS | ||
| SNBXBB0_D | N/SEC | D BEAM ION CX W/ BEAM NEUTS | ||
| SNBXBB1_D | N/SEC | D BEAM ION CX W/ FAST CX NEUTS | ||
| SBCXX | N/SEC | CX FAST ION LOSS | ||
| NMCTOT_D | N | Beam D Total MC Ions | ||
| NAEPTOT_D | N | Beam D Tot MC Ions evolved by AEP | ||
| NMCLOSS_D | N | Beam D MC Prompt Loss | ||
| WNMCTOT_D | #ptcls | Beam D Total MC Ions | ||
| NNEW_D | N | Beam D MC Deposited | ||
| NCX0_D | N | # CX events D orbiting | ||
| SDEPUC_D | N/SEC | Beam D orbit averaged UNCONFINED | ||
| SBCXX_D | N/SEC | CX D BEAM ION LOSS | ||
| BPTHA | WATTS | NB PWR: ASSYM.THERMALIZATION | ||
| BPTHS | WATTS | NB PWR: TH.SCE.FRICTION | ||
| BPTHR | WATTS | NB PWR: THERMALIZATION>ROTATION | ||
| BPJXB | WATTS | NB PWR: JXB TORQUE | ||
| BPCOL | WATTS | NB PWR: COLLISIONAL TORQUE | ||
| BPTHA_D | WATTS | D BEAM PWR: ASSYM.THERMALIZATION | ||
| BPTHS_D | WATTS | D BEAM PWR: TH.SCE.FRICTION | ||
| BPTHR_D | WATTS | D BEAM PWR: THERMALIZ>ROTATION | ||
| BPJXB_D | WATTS | D BEAM PWR: JXB TORQUE | ||
| BPTDFB_D | WATTS | D BEAM PWR: ANOM.DIFF TORQUE | ||
| BPCOL_D | WATTS | D BEAM PWR: COLLISIONAL TORQUE | ||
| BPHI | NT-M-SEC | FAST ION ANGULAR MOMENTUM | ||
| BPHST | NT-M | FI ROT. ANGULAR MOMENTUM GAIN | ||
| BPHCK | NT-M | FI ROT. BALANCE CHECK | ||
| BPHER | NT-M | FI ORBIT TORQUE ERROR | ||
| BPHDP | NT-M | FI ROT. DEPOSITION | ||
| BPHOH | NT-M | FI ROT. FROM OH | ||
| BPHW0 | NT-M | FI ROT. NEUTRAL ESCAPE | ||
| BPHTH | NT-M | FI ROT. THERMALIZATION | ||
| BPHOR | NT-M | FI ROT. ORBIT LOSS | ||
| BPHXB | NT-M | FI ROT. JXB TORQUE | ||
| BPHCL | NT-M | FI ROT. COLLISIONAL TORQUE | ||
| BPHCX | NT-M | FI ROT. CX LOSS | ||
| BPHRC | NT-M | FI ROT. CX RECAPTURE | ||
| BPHI_D | NT-M-SEC | D BEAM ION ANGULAR MOMENTUM | ||
| BPHST_D | NT-M | D BEAM: ANGULAR MOMENTUM GAIN | ||
| BPHCK_D | NT-M | D BEAM: BALANCE CHECK | ||
| BPHER_D | NT-M | D BEAM ORBIT TORQUE ERROR | ||
| BPHDP_D | NT-M | D BEAM: DEPOSITION, ION point | ||
| BPHOH_D | NT-M | D BEAM: FROM OH | ||
| BPHW0_D | NT-M | D BEAM: NEUTRAL ESCAPE | ||
| BPHTH_D | NT-M | D BEAM: THERMALIZATION | ||
| BPHOR_D | NT-M | D BEAM: ORBIT LOSS | ||
| BPHXB_D | NT-M | D BEAM: JXB TORQUE | ||
| BPHDFB_D | NT-M | D BEAM: ANOM.DIFF. TORQUE | ||
| BPHCL_D | NT-M | D BEAM: COLLISIONAL TORQUE | ||
| BPHCX_D | NT-M | D BEAM: CX LOSS | ||
| BPHRC_D | NT-M | D BEAM: CX RECAPTURE | ||
| BPALPHPP | ALPHA FAST ION BETA PERP (POL) | |||
| BPALPHPA | ALPHA FAST ION BETA PLL (POL) | |||
| TEPED | eV | ELECTRON PEDESTAL TEMPERATURE | ||
| TIPED | eV | ION PEDESTAL TEMPERATURE | ||
| NEPED | N/CM**3 | ELECTRON PEDESTAL DENSITY | ||
| TEPEDW | ELECTRON PEDESTAL WIDTH: TE | |||
| TIPEDW | ION PEDESTAL WIDTH | |||
| NEPEDW | ELECTRON PEDESTAL WIDTH: NE | |||
| LHMODE | H-Mode indicator | |||
| SC_TEPED | TE PEDESTAL HEIGHT SCALE FACTOR | |||
| SC_TIPED | TI PEDESTAL HEIGHT SCALE FACTOR | |||
| SC_NEPED | NE PEDESTAL HEIGHT SCALE FACTOR | |||
| PL2HREQ | WATTS | L-H transition power | ||
| PL2HTOT | WATTS | Total heating power | ||
| SX_TE | Te solver range [0:x] | |||
| SX_TI | Ti solver range [0:x] | |||
| SX_OMEGA | Ang. velocity solver range [0:x] | |||
| SX_NE | ne solver range [0:x] | |||
| BETAE | ELECTRON BETA (POLOIDAL) | |||
| BETAR | ROTATION BETA (POLOIDAL) | |||
| TAUEE | SECONDS | ELECTRON ENERGY CONFINEMENT | ||
| TE0 | EV | ELECTRON TEMPERATURE ON AXIS | ||
| TEEDG | EV | ELECTRON TEMPERATURE AT/BEYOND BDY | ||
| NEEDG | N/CM**3 | ELECTRON DENSITY AT/BEYOND BDY | ||
| TEPHA | EV | SIMULATED PHA TE | ||
| ECEGAP | CM | ECE B(R) monotonicity gap | ||
| RESL2PE | ELECTRON PARTICLE EQN. L2-RES | |||
| RESL2PI | THERMAL PARTICLE EQN. L2-RES | |||
| RESL2PX | IMPURITY PARTICLE EQN. L2-RES | |||
| RESL2TE | ELECTRON ENERGY EQN. L2-RES | |||
| RESL2TI | ION ENERGY EQN. L2-RES | |||
| RESL2OMG | ANG. MOMENTUM EQN. L2-RES | |||
| NPTRITER | Number Newton Iterations in PT_SOLVER | |||
| TAUE98Y | SECONDS | TauE98y confinement scaling | ||
| TAUE98YE | SECONDS | TauE98y,e confinement scaling | ||
| TAUE98Y1 | SECONDS | TauE98y,1 confinement scaling | ||
| TAUE98Y1E | SECONDS | TauE98y,1e confinement scaling | ||
| TAUE98Y2 | SECONDS | TauE98y,2 confinement scaling | ||
| TAUE98Y2E | SECONDS | TauE98y,2e confinement scaling | ||
| H98Y | TauE98y confinement Hfactor | |||
| H98YE | TauE98y,e confinement Hfactor | |||
| H98Y1 | TauE98y,1 confinement Hfactor | |||
| H98Y1E | TauE98y,1e confinement Hfactor | |||
| H98Y2 | TauE98y,2 confinement Hfactor | |||
| H98Y2E | TauE98y,2e confinement Hfactor | |||
| TAUE89P | SECONDS | TauE89P confinement scaling | ||
| TAUE89PE | SECONDS | TauE89P,e confinement scaling | ||
| H89P | TauE89P confinement Hfactor | |||
| H89PE | TauE89P,e confinement Hfactor | |||
| TAUE97LG | SECONDS | TauE97L,g confinement scaling | ||
| TAUE97LTH | SECONDS | TauE97L,th confinement scaling | ||
| H97LG | TauE97L,g confinement Hfactor | |||
| H97LTH | TauE97L,th confinement Hfactor | |||
| HST06 | TauE ST06 confinement Hfactor | |||
| HST06E | TauE,e ST06 confinement Hfactor | |||
| TAUEST06 | SECONDS | TauE ST06 confinement scaling | ||
| TAUEST06E | SECONDS | TauE,e ST06 confinement scaling | ||
| TI0 | EV | ION TEMPERATURE ON AXIS | ||
| TIEDG | EV | ION TEMPERATURE AT/BEYOND BDY | ||
| OMEDG | RAD/SEC | ANGULAR VELOCITY AT/BEYOND BDY | ||
| NEUTX | N/SEC | THERMONUCLEAR NEUTRONS | ||
| NEUTT | N/SEC | TOTAL NEUTRONS | ||
| BETAI | THERMAL ION BETA POLOIDAL | |||
| TOTDT | N/SEC | TOTAL D-T FUSION | ||
| TOTDDN | N/SEC | TOTAL D(D,N)HE3 FUSION | ||
| TOT2TT | N/SEC | TOTAL T(T,2N)HE4 FUSION | ||
| TOTDDP | N/SEC | TOTAL D(D,P)T FUSION | ||
| BTFS_DDP | N/SEC | D(D,P)T FUSION | ||
| BBFS_DDP | N/SEC | D(D,P)T BEAM-BEAM PROTONS | ||
| NEUTX_DD | N/SEC | DD THERMONUCLEAR NEUTRONS | ||
| XNEUTDT | N/SEC | TOTAL DT NEUTRON EMISSION, NUBEAM | ||
| XNEUTDD | N/SEC | TOTAL DD NEUTRON EMISSION, NUBEAM | ||
| XNEUTTT | N/SEC | TOTAL TT NEUTRON EMISSION, NUBEAM | ||
| XPROTD3 | N/SEC | TOTAL D HE3 PROTON EMISSION, NUBEAM | ||
| FIEFAC | Ti <-> Te switching factor | |||
| GIEFAC | Ti/Te ratio when Te used for Ti | |||
| XZIMP | Avg Z of Impurity | |||
| XZIMPD | Avg Z of Impurity Data | |||
| AIMP | Avg A of impurity | |||
| USERSC1 | User Scalar #1 | |||
| KATX | EV | COMPUTED K(ALPHA) T(IMPURITY) | ||
| KAINT | ARB.UNITS | K(ALPHA) LINE INTENSITY | ||
| RTXUV | CM | UV DOPPLER TI RADIUS | ||
| TXUV | EV | UV DOPPLER T(IMPURITY) | ||
| XKFA1 | ION CHI(I) MULTIPLIER | |||
| XKFA2 | Q<1 ION NC CHI(I) MULTIPLIER | |||
| TIDAT | EV | TI DATA (FOR COMPARISON) | ||
| T0RECYC | EV | RECYCLING GAS TEMPERATURE (AVG) | ||
| T0GASFL | EV | GAS FLOW TEMPERATURE (AVG) | ||
| OM0RECYC | RAD/SEC | RECYCLING GAS Ang. Veloc. (AVG) | ||
| OM0GASFL | RAD/SEC | GAS FLOW Ang. Veloc. (AVG) | ||
| GASD | N/SEC | D0 GAS FLOW SOURCE | ||
| RCYD | N/SEC | D0 RECYCLING SOURCE | ||
| E0INR | EV | T0 (RECYCLING) @EDGE | ||
| P0FIN | WATTS | NEUTRAL INFLUX POWER | ||
| P0RFL | WATTS | NEUTRAL POWER REFLECTED IN | ||
| P0CXT | WATTS | TOTAL CX POWER | ||
| P0INZ | WATTS | NEUTRAL POWER IONIZED | ||
| P0ESC | WATTS | NEUTRAL POWER ESCAPED | ||
| P0BAL | WATTS | NEUTRAL POWER BALANCE CHECK | ||
| CPSC0 | HOURS | CPU: NEUTRAL TRANSPORT MODEL | ||
| ASHAF | CM | SHAFRANOV AXIS SHIFT | ||
| ASHAFDA | CM | SHAFRANOV AXIS SHIFT (MHD DATA) | ||
| TAUEA | SECONDS | ENERGY CONFINEMENT (THERMAL) | ||
| TAUA1 | SECONDS | ENERGY CONFINEMENT (TOTAL) | ||
| BETAT | TOTAL BETA(POLOIDAL) | |||
| LI2PB | LI/2 + BETA(POLOIDAL) | |||
| BPEQ | EQUILIBRIUM BETA(POLOIDAL) | |||
| BPDIA | DIAMAGNETIC BETA(POLOIDAL) | |||
| BTEQ | EQUILIBRIUM BETA(TOROIDAL) | |||
| BTDIA | DIAMAGNETIC BETA(TOROIDAL) | |||
| BPEQ1 | 1D EQUILIBRIUM BETA(POLOIDAL) | |||
| BPDA1 | 1D DIAMAGNETIC BETA(POLOIDAL) | |||
| LIO21 | 1D DEFINITION OF LI/2 | |||
| L2PB1 | 1D DEFINITION LI/2+BETA | |||
| BPFASTPP | TOTAL FAST ION BETA(POL) PERP | |||
| BPFASTPA | TOTAL FAST ION BETA(POL) PLL | |||
| NBEQ | 0 limited, -1 lower, 1 upper Div as used | |||
| NBGUESS | 0 limited, -1 lower, 1 upper Div as guessed from boundary | |||
| EINJ01_E1 | eV | Einj: beam#01(D), E-frac#1 | ||
| EINJ01_E2 | eV | Einj: beam#01(D), E-frac#2 | ||
| EINJ01_E3 | eV | Einj: beam#01(D), E-frac#3 | ||
| PINJ01 | WATTS | Beam#01(D) injected power | ||
| BPSH01_E1 | WATTS | Beam#01(D) shine-thru power, E-f | ||
| BPSH01_E2 | WATTS | Beam#01(D) shine-thru power, E-f | ||
| BPSH01_E3 | WATTS | Beam#01(D) shine-thru power, E-f | ||
| DINJ01_E1 | eV | Einj RMS Var.: beam#01(D), E#1 | ||
| DINJ01_E2 | eV | Einj RMS Var.: beam#01(D), E#2 | ||
| DINJ01_E3 | eV | Einj RMS Var.: beam#01(D), E#3 | ||
| EINJ02_E1 | eV | Einj: beam#02(D), E-frac#1 | ||
| EINJ02_E2 | eV | Einj: beam#02(D), E-frac#2 | ||
| EINJ02_E3 | eV | Einj: beam#02(D), E-frac#3 | ||
| PINJ02 | WATTS | Beam#02(D) injected power | ||
| BPSH02_E1 | WATTS | Beam#02(D) shine-thru power, E-f | ||
| BPSH02_E2 | WATTS | Beam#02(D) shine-thru power, E-f | ||
| BPSH02_E3 | WATTS | Beam#02(D) shine-thru power, E-f | ||
| DINJ02_E1 | eV | Einj RMS Var.: beam#02(D), E#1 | ||
| DINJ02_E2 | eV | Einj RMS Var.: beam#02(D), E#2 | ||
| DINJ02_E3 | eV | Einj RMS Var.: beam#02(D), E#3 | ||
| EINJ03_E1 | eV | Einj: beam#03(D), E-frac#1 | ||
| EINJ03_E2 | eV | Einj: beam#03(D), E-frac#2 | ||
| EINJ03_E3 | eV | Einj: beam#03(D), E-frac#3 | ||
| PINJ03 | WATTS | Beam#03(D) injected power | ||
| BPSH03_E1 | WATTS | Beam#03(D) shine-thru power, E-f | ||
| BPSH03_E2 | WATTS | Beam#03(D) shine-thru power, E-f | ||
| BPSH03_E3 | WATTS | Beam#03(D) shine-thru power, E-f | ||
| DINJ03_E1 | eV | Einj RMS Var.: beam#03(D), E#1 | ||
| DINJ03_E2 | eV | Einj RMS Var.: beam#03(D), E#2 | ||
| DINJ03_E3 | eV | Einj RMS Var.: beam#03(D), E#3 | ||
| EINJ04_E1 | eV | Einj: beam#04(D), E-frac#1 | ||
| EINJ04_E2 | eV | Einj: beam#04(D), E-frac#2 | ||
| EINJ04_E3 | eV | Einj: beam#04(D), E-frac#3 | ||
| PINJ04 | WATTS | Beam#04(D) injected power | ||
| BPSH04_E1 | WATTS | Beam#04(D) shine-thru power, E-f | ||
| BPSH04_E2 | WATTS | Beam#04(D) shine-thru power, E-f | ||
| BPSH04_E3 | WATTS | Beam#04(D) shine-thru power, E-f | ||
| DINJ04_E1 | eV | Einj RMS Var.: beam#04(D), E#1 | ||
| DINJ04_E2 | eV | Einj RMS Var.: beam#04(D), E#2 | ||
| DINJ04_E3 | eV | Einj RMS Var.: beam#04(D), E#3 | ||
| EINJ05_E1 | eV | Einj: beam#05(D), E-frac#1 | ||
| EINJ05_E2 | eV | Einj: beam#05(D), E-frac#2 | ||
| EINJ05_E3 | eV | Einj: beam#05(D), E-frac#3 | ||
| PINJ05 | WATTS | Beam#05(D) injected power | ||
| BPSH05_E1 | WATTS | Beam#05(D) shine-thru power, E-f | ||
| BPSH05_E2 | WATTS | Beam#05(D) shine-thru power, E-f | ||
| BPSH05_E3 | WATTS | Beam#05(D) shine-thru power, E-f | ||
| DINJ05_E1 | eV | Einj RMS Var.: beam#05(D), E#1 | ||
| DINJ05_E2 | eV | Einj RMS Var.: beam#05(D), E#2 | ||
| DINJ05_E3 | eV | Einj RMS Var.: beam#05(D), E#3 | ||
| EINJ06_E1 | eV | Einj: beam#06(D), E-frac#1 | ||
| EINJ06_E2 | eV | Einj: beam#06(D), E-frac#2 | ||
| EINJ06_E3 | eV | Einj: beam#06(D), E-frac#3 | ||
| PINJ06 | WATTS | Beam#06(D) injected power | ||
| BPSH06_E1 | WATTS | Beam#06(D) shine-thru power, E-f | ||
| BPSH06_E2 | WATTS | Beam#06(D) shine-thru power, E-f | ||
| BPSH06_E3 | WATTS | Beam#06(D) shine-thru power, E-f | ||
| DINJ06_E1 | eV | Einj RMS Var.: beam#06(D), E#1 | ||
| DINJ06_E2 | eV | Einj RMS Var.: beam#06(D), E#2 | ||
| DINJ06_E3 | eV | Einj RMS Var.: beam#06(D), E#3 | ||
| EINJ07_E1 | eV | Einj: beam#07(D), E-frac#1 | ||
| EINJ07_E2 | eV | Einj: beam#07(D), E-frac#2 | ||
| EINJ07_E3 | eV | Einj: beam#07(D), E-frac#3 | ||
| PINJ07 | WATTS | Beam#07(D) injected power | ||
| BPSH07_E1 | WATTS | Beam#07(D) shine-thru power, E-f | ||
| BPSH07_E2 | WATTS | Beam#07(D) shine-thru power, E-f | ||
| BPSH07_E3 | WATTS | Beam#07(D) shine-thru power, E-f | ||
| DINJ07_E1 | eV | Einj RMS Var.: beam#07(D), E#1 | ||
| DINJ07_E2 | eV | Einj RMS Var.: beam#07(D), E#2 | ||
| DINJ07_E3 | eV | Einj RMS Var.: beam#07(D), E#3 | ||
| EINJ08_E1 | eV | Einj: beam#08(D), E-frac#1 | ||
| EINJ08_E2 | eV | Einj: beam#08(D), E-frac#2 | ||
| EINJ08_E3 | eV | Einj: beam#08(D), E-frac#3 | ||
| PINJ08 | WATTS | Beam#08(D) injected power | ||
| BPSH08_E1 | WATTS | Beam#08(D) shine-thru power, E-f | ||
| BPSH08_E2 | WATTS | Beam#08(D) shine-thru power, E-f | ||
| BPSH08_E3 | WATTS | Beam#08(D) shine-thru power, E-f | ||
| DINJ08_E1 | eV | Einj RMS Var.: beam#08(D), E#1 | ||
| DINJ08_E2 | eV | Einj RMS Var.: beam#08(D), E#2 | ||
| DINJ08_E3 | eV | Einj RMS Var.: beam#08(D), E#3 | ||
| EINJ09_E1 | eV | Einj: beam#09(D), E-frac#1 | ||
| EINJ09_E2 | eV | Einj: beam#09(D), E-frac#2 | ||
| EINJ09_E3 | eV | Einj: beam#09(D), E-frac#3 | ||
| PINJ09 | WATTS | Beam#09(D) injected power | ||
| BPSH09_E1 | WATTS | Beam#09(D) shine-thru power, E-f | ||
| BPSH09_E2 | WATTS | Beam#09(D) shine-thru power, E-f | ||
| BPSH09_E3 | WATTS | Beam#09(D) shine-thru power, E-f | ||
| DINJ09_E1 | eV | Einj RMS Var.: beam#09(D), E#1 | ||
| DINJ09_E2 | eV | Einj RMS Var.: beam#09(D), E#2 | ||
| DINJ09_E3 | eV | Einj RMS Var.: beam#09(D), E#3 | ||
| EINJ10_E1 | eV | Einj: beam#10(D), E-frac#1 | ||
| EINJ10_E2 | eV | Einj: beam#10(D), E-frac#2 | ||
| EINJ10_E3 | eV | Einj: beam#10(D), E-frac#3 | ||
| PINJ10 | WATTS | Beam#10(D) injected power | ||
| BPSH10_E1 | WATTS | Beam#10(D) shine-thru power, E-f | ||
| BPSH10_E2 | WATTS | Beam#10(D) shine-thru power, E-f | ||
| BPSH10_E3 | WATTS | Beam#10(D) shine-thru power, E-f | ||
| DINJ10_E1 | eV | Einj RMS Var.: beam#10(D), E#1 | ||
| DINJ10_E2 | eV | Einj RMS Var.: beam#10(D), E#2 | ||
| DINJ10_E3 | eV | Einj RMS Var.: beam#10(D), E#3 | ||
| EINJ11_E1 | eV | Einj: beam#11(D), E-frac#1 | ||
| EINJ11_E2 | eV | Einj: beam#11(D), E-frac#2 | ||
| EINJ11_E3 | eV | Einj: beam#11(D), E-frac#3 | ||
| PINJ11 | WATTS | Beam#11(D) injected power | ||
| BPSH11_E1 | WATTS | Beam#11(D) shine-thru power, E-f | ||
| BPSH11_E2 | WATTS | Beam#11(D) shine-thru power, E-f | ||
| BPSH11_E3 | WATTS | Beam#11(D) shine-thru power, E-f | ||
| DINJ11_E1 | eV | Einj RMS Var.: beam#11(D), E#1 | ||
| DINJ11_E2 | eV | Einj RMS Var.: beam#11(D), E#2 | ||
| DINJ11_E3 | eV | Einj RMS Var.: beam#11(D), E#3 | ||
| EINJ12_E1 | eV | Einj: beam#12(D), E-frac#1 | ||
| EINJ12_E2 | eV | Einj: beam#12(D), E-frac#2 | ||
| EINJ12_E3 | eV | Einj: beam#12(D), E-frac#3 | ||
| PINJ12 | WATTS | Beam#12(D) injected power | ||
| BPSH12_E1 | WATTS | Beam#12(D) shine-thru power, E-f | ||
| BPSH12_E2 | WATTS | Beam#12(D) shine-thru power, E-f | ||
| BPSH12_E3 | WATTS | Beam#12(D) shine-thru power, E-f | ||
| DINJ12_E1 | eV | Einj RMS Var.: beam#12(D), E#1 | ||
| DINJ12_E2 | eV | Einj RMS Var.: beam#12(D), E#2 | ||
| DINJ12_E3 | eV | Einj RMS Var.: beam#12(D), E#3 | ||
| EINJ13_E1 | eV | Einj: beam#13(D), E-frac#1 | ||
| EINJ13_E2 | eV | Einj: beam#13(D), E-frac#2 | ||
| EINJ13_E3 | eV | Einj: beam#13(D), E-frac#3 | ||
| PINJ13 | WATTS | Beam#13(D) injected power | ||
| BPSH13_E1 | WATTS | Beam#13(D) shine-thru power, E-f | ||
| BPSH13_E2 | WATTS | Beam#13(D) shine-thru power, E-f | ||
| BPSH13_E3 | WATTS | Beam#13(D) shine-thru power, E-f | ||
| DINJ13_E1 | eV | Einj RMS Var.: beam#13(D), E#1 | ||
| DINJ13_E2 | eV | Einj RMS Var.: beam#13(D), E#2 | ||
| DINJ13_E3 | eV | Einj RMS Var.: beam#13(D), E#3 | ||
| EINJ14_E1 | eV | Einj: beam#14(D), E-frac#1 | ||
| EINJ14_E2 | eV | Einj: beam#14(D), E-frac#2 | ||
| EINJ14_E3 | eV | Einj: beam#14(D), E-frac#3 | ||
| PINJ14 | WATTS | Beam#14(D) injected power | ||
| BPSH14_E1 | WATTS | Beam#14(D) shine-thru power, E-f | ||
| BPSH14_E2 | WATTS | Beam#14(D) shine-thru power, E-f | ||
| BPSH14_E3 | WATTS | Beam#14(D) shine-thru power, E-f | ||
| DINJ14_E1 | eV | Einj RMS Var.: beam#14(D), E#1 | ||
| DINJ14_E2 | eV | Einj RMS Var.: beam#14(D), E#2 | ||
| DINJ14_E3 | eV | Einj RMS Var.: beam#14(D), E#3 | ||
| XBFAC | MHD BETA ADJUSTMENT FACTOR | |||
| PBAEPT | WATTS | FAST ION POWER DUE TO AEP (MHD) ACTIVITY | ||
| NTBMD_1 | N | # of time steps in MHD transport for D beam by mode1 | ||
| NTBMD_2 | N | # of time steps in MHD transport for D beam by mode2 | ||
| NTBMD_3 | N | # of time steps in MHD transport for D beam by mode3 | ||
| NTBMD_4 | N | # of time steps in MHD transport for D beam by mode4 | ||
| NTBMD_5 | N | # of time steps in MHD transport for D beam by mode5 | ||
| NTBMD_6 | N | # of time steps in MHD transport for D beam by mode6 | ||
| NTBMD_7 | N | # of time steps in MHD transport for D beam by mode7 | ||
| NTBMD_8 | N | # of time steps in MHD transport for D beam by mode8 | ||
| NTBMD_9 | N | # of time steps in MHD transport for D beam by mode9 | ||
| NTBMD_10 | N | # of time steps in MHD transport for D beam by mode10 | ||
| DIFBX | CM**2/SEC | Fast ion anomalous diffusivity | ||
| VELBX | CM/SEC | Fast ion anomalous velocity | ||
| PBDEPB_D | WATTS | the total D-beam injected power | ||
| BPHDEPB_D | NT-M | the total D-beam injected momentum | ||
| BDENSMP | #/CM**3 | Fast ion density, GC on midplane | ||
| EBAPLMP | eV | FAST ION <Epll> , GC on midplane | ||
| EBAPPMP | eV | FAST ION <Eperp>, GC on midplane | ||
| VBTORMP | CM/SEC | FAST ION <Vtor>, GC on midplane | ||
| BDENS2D | N/CM**3 | beam ion density at GC 2d grid | ||
| BEPRP2D | eV | beam ion <Eperp> at GC 2d grid | ||
| BEPLL2D | eV | beam ion <Epll> at GC 2d grid | ||
| BVTOR2D | cm/sec | beam ion <Vtor> at GC 2d grid | ||
| TIEFAC | Ti <-> Te switching factors | |||
| PTEMP | EV | PLASMA TEMPERATURES | ||
| ITEMP | EV | ION TEMPERATURES | ||
| TMJS | EV | MAJORITY TEMPERATURES | ||
| PTEMP_NC | EV | NCLASS PLASMA TEMPERATURES | ||
| PTI_NC | EV | TI & NCLASS SMOOTHED TI | ||
| PTMJ_NC | EV | TMJ & NCLASS SMOOTHED TMJ | ||
| PTX_NC | EV | TX & NCLASS SMOOTHED TX | ||
| PDENS | N/CM**3 | PLASMA DENSITIES | ||
| XDENS | N/CM**3 | IMPURITY DENSITY | ||
| XIM_SINGL | N/CM**3 | Impurity Density for SINGL | ||
| XIMS_TOK | N/CM**3 | Impurity Density for TOK | ||
| PDENS_NC | N/CM**3 | NCLASS PLASMA DENSITIES | ||
| PND_NC | N/CM**3 | ND & NCLASS SMOOTHED ND | ||
| PNX_NC | N/CM**3 | NX & NCLASS SMOOTHED NX | ||
| BDENSS | N/CM**3 | BEAM ION DENSITIES | ||
| NMC | N | Monte Carlo Ion Count Profiles | ||
| NMCTOT | N | Total No. of Monte Carlo Ions | ||
| NMCLOSS | N | No. of prompt loss MC Ions | ||
| WNMC | #ptcls | Monte Carlo Weight Profiles | ||
| WNMCTOT | #ptcls | Total Monte Carlo Weight | ||
| NAEPTOT | N | Tot No.of MC Ions evolved by AEP | ||
| NNEW | N | # Monte Carlo Deposited | ||
| NCXORB | N | # CX events during orbiting | ||
| SDEPOAUC | N/SEC | orbit av. deposition,UNCONFINED | ||
| OMEGS | RAD/SEC | PLASMA ANGULAR VELOCITIES | ||
| OMEGSFI | RAD/SEC | Avg Fast ion Angular Velocities | ||
| DENS0 | N/CM**3 | THERMAL NEUTRAL DENSITIES | ||
| DENS0RECO | N/CM**3 | Recomb. source neutral densities | ||
| T0RECO | EV | Recomb. source neutral temps | ||
| OM0RECO | RAD/SEC | Recomb. source ang. velocities | ||
| DENS0HALO | N/CM**3 | Beam halo neutral densities | ||
| T0HALO | EV | Beam halo neutral temps | ||
| OM0HALO | RAD/SEC | Beam halo ang. velocities | ||
| DENS0SGF | N/CM**3 | summed gas flow neutral dens. | ||
| DENS0SRC | N/CM**3 | summed recycling neutral dens. | ||
| DENS0AGF | N/CM**3 | all gas flow densities | ||
| T0AGF | EV | all gas flow temperatures | ||
| OMEG0AGF | RAD/SEC | all gas flow ang. velocities | ||
| SI_AGF | N/CM3/SEC | all gas flow ion sources | ||
| DENS0ARC | N/CM**3 | all recyc densities | ||
| T0ARC | EV | all recyc temperatures | ||
| OMEG0ARC | RAD/SEC | all recyc ang. velocities | ||
| SI_ARC | N/CM3/SEC | all recyc ion sources | ||
| N0BAL_RECO | N/CM3/SEC | Recomb. neutral ptcl balance | ||
| E0BAL_RECO | WATTS/CM3 | Recomb. neutral power balance | ||
| TQ0BA_RECO | Nt-M/CM3 | Recomb. neutral ang momentum bal | ||
| N0BAL_HALO | N/CM3/SEC | Beam Halo neutral ptcl balance | ||
| E0BAL_HALO | WATTS/CM3 | Beam Halo neutral power balance | ||
| TQ0BA_HALO | Nt-M/CM3 | Beam Halo neutral ang mo. bal | ||
| N0BAL_SGF | N/CM3/SEC | gas flow neutral ptcl bal sum | ||
| E0BAL_SGF | WATTS/CM3 | gas flow neutral power bal sum | ||
| TQ0BA_SGF | Nt-M/CM3 | gas flow neutral ang mo. bal sum | ||
| N0BAL_AGF | N/CM3/SEC | gas flow neutral ptcl bal all | ||
| E0BAL_AGF | WATTS/CM3 | gas flow neutral power bal all | ||
| TQ0BA_AGF | Nt-M/CM3 | gas flow neutral ang mo. bal all | ||
| N0BAL_SRC | N/CM3/SEC | recyc neutral ptcl bal sum | ||
| E0BAL_SRC | WATTS/CM3 | recyc neutral power bal sum | ||
| TQ0BA_SRC | Nt-M/CM3 | recyc neutral ang mo. bal sum | ||
| N0BAL_ARC | N/CM3/SEC | recyc neutral ptcl bal all | ||
| E0BAL_ARC | WATTS/CM3 | recyc neutral power bal all | ||
| TQ0BA_ARC | Nt-M/CM3 | recyc neutral ang mo. bal all | ||
| T0CX | EV | CX neutral temperatures | ||
| OMEG0CX | RAD/SEC | CX angular velocities | ||
| PCX_COEFF | WATTS/CM3/EV | CX Power Coefficients | ||
| TCX_COEFF | Nt-M/CM3/(RAD/S) | CX Torque Coefficients | ||
| P0VOLSC | WATTS/CM3 | Power in volume neutral sources | ||
| TQ0VOLSC | Nt-M/CM3 | Torque in volume neutral sources | ||
| DNSB0 | N/CM**3 | BEAM NEUTRAL DENSITIES | ||
| SINBN0 | N/CM3/SEC | FAST ION THERMAL NEUTRAL SINKS | ||
| RSNBX | 1/sec | CX rates with beam ions | ||
| RSNBI | 1/sec | II rates with beam ions | ||
| T0 | EV | THERMAL NEUTRAL TEMPERATURES | ||
| OMEG0 | RAD/SEC | THERMAL NEUTRAL ANG.VELOCITIES | ||
| IEBAL | WATTS/CM3 | ION POWER BALANCE | ||
| IEHEAT | WATTS/CM3 | ION HEATING | ||
| CQIE | WATTS/CM3 | ION-ELECTRON COUPLING | ||
| IEBALR | WATTS/CM3 | IEBAL: ROTATION TERMS | ||
| EEBAL | WATTS/CM3 | ELECTRON POWER BALANCE | ||
| EEHEAT | WATTS/CM3 | ELECTRON HEATING | ||
| ROBAL | WATTS/CM3 | ROTATION POWER BALANCE | ||
| ROBALI | WATTS/CM3 | ROTATIONAL ENERGY INPUTS | ||
| BTQJXBS | Nt-M/CM3 | FAST ION TORQUES (JXB) | ||
| BTQRPLS | Nt-M/CM3 | FAST ION RPL TORQUES (JXB) | ||
| BTQCOLS | Nt-M/CM3 | FAST ION COLLISIONAL TORQUES | ||
| MOBAL | Nt-M/CM3 | ANGULAR MOMENTUM BALANCE | ||
| MOI | NtMS2/CM3 | ANGULAR INERTIA DENSITY | ||
| MOI_IMP | NtMS2/CM3 | IMPURITY ANGULAR INERTIA DENSITY | ||
| AMOM | NtM-S/CM3 | ANGULAR MOMENTUM DENSITY | ||
| AMOM_IMP | NtM-S/CM3 | IMP ANGULAR MOMENTUM DENSITY | ||
| MOBALI | Nt-M/CM3 | INPUT TORQUES | ||
| TQJXBD | Nt-M/CM3 | BEAM TOT. JXB TORQUE | ||
| IPBAL | N/CM3/SEC | ION PTCL BALANCE | ||
| EPBAL | N/CM3/SEC | ELECTRON PTCL BALANCE | ||
| IMBAL | N/CM3/SEC | IMPURITY PTCL BALANCE | ||
| GDBAL | N/CM3/SEC | PTCL BALANCE ION (D+) | ||
| IPTR | N/CM3/SEC | ION PTCL TRANSPORT | ||
| EPTR | N/CM3/SEC | ELECTRON PTCL TRANSPORT | ||
| XPTR | N/CM3/SEC | IMPURITY PTCL TRANSPORT | ||
| PTR_D | N/CM3/SEC | D+ Ion Transport | ||
| IETR | WATTS/CM3 | ION ENERGY TRANSPORT | ||
| EETR | WATTS/CM3 | ELECTRON ENERGY TRANSPORT | ||
| AMTR | Nt-M/CM3 | ANGULAR MOMENTUM TRANSPORT | ||
| RESPROF | TRANSPORT EQUATION RESIDUAL PROFS | |||
| RESL2 | TRANSPORT EQUATION L2-NORM RESIDUAL | |||
| UPWIND | UPWIND ADJUSTMENT PARAMETERS | |||
| PRVEL | CM/SEC | PTCL RADIAL VELOCITIES | ||
| TRVEL | CM/SEC | Generalized transport velocities | ||
| VMO | CM/SEC | Momentum Advection Velocities | ||
| TAUH | SECONDS | TauE98y1,2 confinement scalings | ||
| HH | TauE98y1,2 confinement ratio H factors | |||
| TAUH89 | SECONDS | TauE89P confinement scalings | ||
| HH89 | TauE89P confinement ratio H factors | |||
| TAUL | SECONDS | TauE97L confinement scalings | ||
| HL | TauE97L confinement ratio H factors | |||
| TAUSCAL | SECONDS | TauE98y & TauE97L scalings | ||
| HFAC | TauE98y & TaeE97L H factors | |||
| UDENS | JLES/CM3 | ENERGY DENSITY | ||
| UDENSPP | JLES/CM3 | FAST ION PERP ENERGY DENSITY | ||
| UDENSPA | JLES/CM3 | FAST ION PLL ENERGY DENSITY | ||
| BUDENS | JLES/CM3 | BEAM ION ENERGY DENSITIES | ||
| BPHIS | NT-M-SEC | BEAM & FAST ION ANGULAR MOMENTA | ||
| PRESS | PASCALS | PLASMA PRESSURE | ||
| MPMHD | PASCALS | PLASMA PRESSURE to MHD SOLVER | ||
| ECON | SECONDS | ENERGY CONFINEMENT | ||
| ECONST | SECONDS | ENERGY CONFINEMENT ("*" VSNS) | ||
| PDIFF | CM**2/SEC | PTCL DIFFUSIVITIES | ||
| VNDIFF | CM/SEC | ION NON-DIFFUSIVE FLOW VELOCITY | ||
| PDIFFI | CM**2/SEC | INPUT DIFFUSIVITIES | ||
| PTDIFF | CM**2/SEC | PTCL PREDICTIVE DIFFUSIVITIES | ||
| PCON | SECONDS | PTCL CONFINEMENT | ||
| KAPA | CM**2/SEC | THERMAL DIFFUSIVITY 1 | ||
| KAPA6 | CM**2/SEC | THERMAL DIFFUSIVITY 6 | ||
| KAPAN | CM**2/SEC | THERMAL DIFFUSIVITY ANALYSIS | ||
| CHIS | CM**2/SEC | DIFFUSIVITIES | ||
| CONDS | CM**2/SEC | DIFFUSIVITIES | ||
| CONDWNCS | CM**2/SEC | NCLASS DIFFUSIVITIES | ||
| CNDWNCIMP | CM**2/SEC | NCLASS HEAT DIFFUSIVITIES FOR IMP | ||
| ETATH | ETA(THERMAL)S | |||
| CHIPH | CM**2/SEC | MODEL VS EXP CHI(PHI) | ||
| CHIPHA | CM**2/SEC | ANALYSIS vs. PREDICTIVE MODEL Chi(Phi) | ||
| TCONS | SECONDS | CONFINEMENT TIMES | ||
| NCFKI | CM**2/SEC | FITS TO NEOCLASSICAL KAPA(I) | ||
| NCFKI_KAP | CM**2/SEC | NC KAPA(I) KAPISN FITS (istringer=1) | ||
| NCFKI_RJ | CM**2/SEC | NC KAPA(I) RUTHERFORD-JULICH FITS | ||
| NCFKI_HH | CM**2/SEC | NC KAPA(I) Hazeltine-Hinton FITS | ||
| NCFKI_B | CM**2/SEC | NC KAPA(I) BOLTON FITS | ||
| NCFKI_CH | CM**2/SEC | NC KAPA(I) Chang-Hinton FITS | ||
| NCFKI_CH2 | CM**2/SEC | NC KAPA(I) Chang-Hinton FITS v2 | ||
| NCFKI_CHZ | CM**2/SEC | NC KAPA(I) Chang-Hinton FITS Z-corr | ||
| NCFTS | Neoclassical trapping fractions | |||
| BMINMAX | Tesla | Bmin & Bmax on flux surfaces | ||
| CHI_GKF | CM**2/SEC | IFS-PPPL GYROFLUID CHIS | ||
| CHI_GLF | CM**2/SEC | GLF23 CHIS | ||
| CHI_NEO | CM**2/SEC | NEO CHIS | ||
| V_NEO | CM/SEC | NEO VELOCITIES | ||
| CHI_CDBM | CM**2/SEC | CDBM CHIS | ||
| MMM_GR | 1/SEC | MMM GROWTH RATES (MODE 1 & 2) | ||
| MMM_FR | RAD/SEC | MMM FREQUENCY (MODE 1 & 2) | ||
| DRBM_GR | 1/SEC | DRBM GROWTH RATES (MODE 1, 2, 3) | ||
| DRBM_FR | RAD/SEC | DRBM FREQUENCY (MODE 1, 2, 3) | ||
| ITG | ION TEMPERATURE GRADIENT DATA | |||
| BETOR | BETA TOROIDALS | |||
| N0BAL | N/CM3/SEC | NEUTRAL PTCL BALANCE (E-) | ||
| E0BAL | WATTS/CM3 | PLASMA FRAME NEUTRAL POWER BAL | ||
| TQ0BA | Nt-M/CM3 | NEUTRAL TORQUE BALANCE | ||
| SRECO | N/CM3/SEC | RECOMBINATION SCE/SINK | ||
| SHALO | N/CM3/SEC | BEAM HALO SCE/SINK | ||
| SSGF | N/CM3/SEC | SUMMED GAS FLOW ION SCES | ||
| SSRC | N/CM3/SEC | SUMMED RECYCLING ION SCES | ||
| SREXB | RAD/SEC | ExB Shearing Rates | ||
| SREXB_T | RAD/SEC | ExB Shearing Rate Terms | ||
| PCURNC | AMPS/CM2 | NC Bootstrap Cur Comparison | ||
| GFL_NC | N/CM3/SEC | NC Ptcl Transport | ||
| QFL_NC | WATTS/CM3 | NC Heat Transport | ||
| QFL_NCC | WATTS/CM3 | NC class Heat Transport | ||
| QFL_NCD | WATTS/CM3 | NC Heat Transport D+ | ||
| SBDYD | N/SEC | D0 BOUNDARY SOURCES | ||
| T0EDGE | EV | EDGE GAS TEMPERATURE | ||
| OM0EDGE | RAD/SEC | EDGE GAS ANGULAR VELOCITY | ||
| BDEP0 | N/CM3/SEC | BEAM DEPOSITION | ||
| BDEP0_D | N/CM3/SEC | BEAM DEPOSITION (D) | ||
| BDEN_D | N/CM**3 | BEAM D DENSITY PROFILES | ||
| BDEP0_D1 | N/CM3/SEC | Full Energy Beam Depo. (D) | ||
| BDEP0_D2 | N/CM3/SEC | Half Energy Beam Depo. (D) | ||
| BDEP0_D3 | N/CM3/SEC | 1/3 Energy Beam Depo. (D) | ||
| BDEPS | N/CM3/SEC | BEAM DEPOSITION TOTAL SOURCE | ||
| BDEPS_D | N/CM3/SEC | D BEAM DEP FULL/HALF/THIRD SCES | ||
| EXFS_D | approx excit. enhancmnt of D dep | |||
| BRCAP | N/CM3/SEC | FAST ION RECAPTURE | ||
| BRCAP_D | N/CM3/SEC | BEAM RECAPTURE (D) | ||
| FBTH | N/CM**3 | FAST ION DENSITIES | ||
| IRBCMP | AMPS | fast ion rad. cur (2 methods) | ||
| IRB | AMPS | fast ion radial currents | ||
| IRB_D | AMPS | beam ion radial currents (D) | ||
| FPBX | FRACTIONAL BEAM DRAG->IMPURITIES | |||
| FPAX | FRAC. BEAM SCATTERING>IMPURITIES | |||
| PCURFEQ | AMPS/CM2 | FEQ PLASMA CURRENTS | ||
| PCURS | AMPS/CM2 | PLASMA CURRENTS | ||
| CURNB | AMPS/CM2 | SH BEAM DRIVEN CURRENT | ||
| PCURSAU | AMPS/CM2 | SAUTER BOOTSTRAP CURRENTS | ||
| SUMCUR | AMPS | Summed toroidal currents | ||
| PLJBS | AMP*TESLA/CM2 | <J.B> PROFILES | ||
| PLJBXTS | AMP*TESLA/CM2 | <J.B>ext sum & from resistivity | ||
| PLCUR | AMPS | POLOIDAL CURRENT TO BOUNDARY | ||
| ZEFF | Z-EFFECTIVE PROFILES | |||
| TECOM | eV | TE DATA INPUT | ||
| NECOM | n/cm**3 | NE DATA INPUT | ||
| TICOM | eV | TI DATA INPUT | ||
| PBOLO | WATTS/CM3 | PRAD USED AND BOLOMETER DATA | ||
| CPBOLO | WATTS/CM3 | PRAD READ AND CALCULATED | ||
| PBOLOS | WATTS/CM3 | PRAD CALCULATED BY SPECIES | ||
| PBX_SINGL | WATTS/CM3 | PRAD CALCULATED FOR SINGL | ||
| PBS_TOK | WATTS/CM3 | PRAD CALCULATED FOR TOK | ||
| PBSLI_TOK | WATTS/CM3 | PRAD LINE RAD FOR TOK | ||
| PBSBR_TOK | WATTS/CM3 | PRAD BREM RAD FOR TOK | ||
| P0BLC | WATTS | LAB FRAME NEUTRAL POWER BALANCE | ||
| ZEFF0 | RESIS. & COMPOSITION ZEFF @AXIS | |||
| LAMDA | LAMDA COMPARISON | |||
| ALPHA | MAGNETIC ALPHA COMPARISON | |||
| RTCOM | CM | MAGNETIC RT COMPARISON | ||
| L2COM | MAGNETIC LI/2 COMPARISON | |||
| MUCOM | MAGNETIC MUDIA COMPARISON | |||
| SHCOM | MAGNETIC S1+S2 COMPARISON | |||
| DFLX | WEBERS | PARA/DIAMAGNETIC FLUX | ||
| TFLUXCMP | WEBERS | TOROIDAL FLUX COMPARISON | ||
| PLFLXCMP | Wb/rad | POLOIDAL FLUX COMPARISON | ||
| PSI0 | Wb/rad | Poloidal flux on axis | ||
| ETAS | OHM*CM | RESISTIVITIES | ||
| FBPOL | TRANSP POLOIDAL BETAS | |||
| FBPOLPP | FAST ION PERP BETA(POLOIDAL)S | |||
| FBPOLPA | FAST ION PLL BETA(POLOIDAL)S | |||
| LBPOL | POLOIDAL BETAS, LI/2+BETA | |||
| LINORM | VARIOUS NORMALIZED INDUCTANCES | |||
| MBPOL | EQ. + DIA. BETA(POLOIDAL) | |||
| MBTOR | EQ. + DIA. BETA(TOROIDAL) | |||
| XKFMG | ION NEOCLASSICAL MULTIPLIERS | |||
| VSCMP | VOLTS | SURFACE VOLTAGE COMPARISON | ||
| IPCMP | AMPS | PLASMA CURRENT COMPARISON | ||
| BZXRCMP | TESLA*CM | BZXR COMPARISON | ||
| NEUTTH | N/SEC | THERMONUCLEAR NEUTRON EMISSION | ||
| PNTNS | N/CM3/SEC | NEUTRON EMISSIVITIES | ||
| XFUSN | N/SEC | FUSION REACTION RATES | ||
| PFUSN | N/CM3/SEC | FUSION REACTION RATE PROFILES | ||
| XFUSN_DD | N/SEC | DD REACTION RATES | ||
| XFUSN_P | N/SEC | PROTONS FUSION REACTION RATES | ||
| XFUSN_DT | N/SEC | DT REACTION RATES | ||
| XFUSN_TT | N/SEC | TT REACTION RATES | ||
| XNEUT | N/SEC | NEUTRON EMISSION | ||
| XNEUT_DD | N/SEC | DD NEUTRON EMISSION | ||
| PNTNS_DD | N/CM3/SEC | DD NEUTRON EMISSIVITIES | ||
| PNTN2_DD | N/CM3/SEC | DD NEUTRON EMISSIVITIES | ||
| XNEUT_DT | N/SEC | DT NEUTRON EMISSION | ||
| XPROT | N/CM3/SEC | PROTON EMISSION | ||
| XNEUT_TT | N/SEC | TT NEUTRON EMISSION | ||
| PFUSN_DD | N/CM3/SEC | DD REACTION RATE PROFILES | ||
| PFUSN_DT | N/CM3/SEC | DT REACTION RATE PROFILES | ||
| PFUSN_TT | N/CM3/SEC | TT REACTION RATE PROFILES | ||
| SBBAL | N/SEC | FAST ION PTCL BALANCE | ||
| SBBAL_D | N/SEC | BEAM PTCL BALANCE (D) | ||
| SBDEPB_D | N/SEC | BEAM DEPOSITION PTCL BAL (D) | ||
| SBDEPS_D | N/SEC | BEAM DEPOSITION SOURCES (D) | ||
| SBCX0B_D | N/SEC | BEAM CX NEUTRAL PTCL BAL (D) | ||
| SBORBA_D | N/SEC | BEAM ORBIT PTCL BAL (D) | ||
| SBRCAP_D | N/SEC | BEAM CX RECAPTURE (D) | ||
| SBCXSN_D | N/SEC | BEAM ION CX SINKS (D) | ||
| PBLOS | WATTS | FAST ION POWER LOSSES | ||
| PBLOS_D | WATTS | BEAM POWER LOSSES (D) | ||
| PBROT | WATTS | FAST ION POWER TO ROTATION | ||
| PBROT_D | WATTS | BEAM POWER TO ROTATION (D) | ||
| PBCXB | WATTS | FAST ION CX POWER TERMS | ||
| PBCXB_D | WATTS | BEAM CX POWER TERMS (D) | ||
| BPHBX | NT-M | FAST ION CX MOMENTUM BALANCE | ||
| BPHBX_D | NT-M | BEAM CX MOMENTUM BALANCE (D) | ||
| PBBAL | WATTS | FAST ION POWER BALANCE | ||
| PBBAL_D | WATTS | BEAM POWER BALANCE (D) | ||
| BHEAT | WATTS | HEATING BY FAST IONS | ||
| BHEAT_D | WATTS | BEAM HEATING (D BEAMS) | ||
| ABTRAP_D | D beam ion banana fractions | |||
| FBTRAP_D | D beam ion banana fractions | |||
| BMHTG | WATTS/CM3 | FAST ION HEATING PROFILES | ||
| PHALO | WATTS/CM3 | BEAM HALO POWERS | ||
| TQHALO | Nt-M/CM3 | BEAM HALO TORQUES | ||
| PEFIS | WATTS/CM3 | ELEC HEATING BY FAST ION SPECIES | ||
| PIFIS | WATTS/CM3 | ION HEATING BY FAST ION SPECIES | ||
| PTHFIS | WATTS/CM3 | P(THERM) BY FAST ION SPECIES | ||
| SEFIS | N/CM3/SEC | ELEC SOURCES BY FAST ION SPECIES | ||
| STHFIS | N/CM3/SEC | THERMALIZATION BY F.I. SPECIES | ||
| BPHBA | NT-M | FAST ION MOMENTUM BALANCE | ||
| BPHBA_D | NT-M | BEAM MOMENTUM BALANCE (D) | ||
| UBCUR | AMPS/CM2 | UNSHIELDED BEAM CURRENTS | ||
| PHEAT_IN | WATTS | INPUT HEATING POWERS | ||
| PHEAT | WATTS | HEATING POWERS | ||
| PFI0 | WATTS | FAST ION SOURCE POWERS | ||
| CPDIS | HOURS | CPU TIME DISTRIBUTION | ||
| BMCPU | HOURS | CPU TIME USE: BEAM CODE | ||
| BMPLL | HOURS | CPU TIME (MPI RUN): BEAM CODE | ||
| CPGEO | HOURS | CPU TIME USE: MHD GEOMETRY | ||
| CPWALL | HOURS | WALL CLOCK & CPU TIME | ||
| PT_TIME | HOURS | WALL CLOCK & CPU TIME USE : PT_SOLVER | ||
| LIHI2 | INDUCTANCE | |||
| POHC | WATTS | OHMIC HEATING, IP*VS | ||
| PEDGE | WATTS | EXPANSION/SCRAPEOFF POWER | ||
| NETWD | N/CM**3 | NE DATA PROFILE ASYMMETRY | ||
| TSHF0 | CM | SHAFRANOV & DATA SHIFT ON AXIS | ||
| TSHAF | CM | SHAFRANOV SHIFT: CODE & DATA | ||
| QP | Q PROFILES | |||
| XIQ | xi of Q surfaces | |||
| GCHK | G PARA/DIAMAGNETIC CHECK | |||
| JMHD | AMPS/CM | FLUX SURFACE AVGS INVOLVING J | ||
| VCHK | VOLTS | VOLTAGE CHECK | ||
| TCHK | WEBERS | TOROIDAL FLUX CHECK | ||
| UBDOT | WATTS/CM3 | FIELD ENERGY GAIN | ||
| MGBAL | WATTS/CM3 | MAGDIF ENERGY BALANCE | ||
| MFLUX | WEBERS | MAGNETIC FLUXES | ||
| PCMPR | WATTS/CM3 | COMPRESSION POWERS | ||
| PLABL | N/CM**3 | PELLET ABLATION | ||
| FB | B FIELD FACTORS | |||
| FBP | |BP|/|BT| COMPARISON | |||
| VISBR | VB UNITS | SINGLE CHORD VB LIGHT | ||
| VISBP | VB INTENS | PROFILE VB LIGHT | ||
| TESAW | EV | SAWTOOTH DATA: TE | ||
| PL2H | WATTS | L-H power condition | ||
| PED_WID | pedestal model widths | |||
| PED_THGT | eV | temperature pedestal heights | ||
| PED_NHGT | N/CM**3 | density pedestal height | ||
| PED_SCAL | pedestal scale factors | |||
| SX_RANGE | solver ranges [0:x] | |||
| TBSL_D | SECONDS | D BEAM SLOWING DOWN TIMES | ||
| TBPA_D | SECONDS | D BEAM PITCH ANGLE SCATTERING | ||
| TAUSL | SECONDS | FAST ION SLOWING DOWN TIMES | ||
| TAUPA | SECONDS | FAST ION P.A. SCATTERING TIMES | ||
| PRFFI | WATTS | ICRF POWER to FAST IONS | ||
| UBDC01 | AMPS/CM2 | Beam#01(D) UNSHLD BEAM DR CUR | ||
| SBDC01 | AMPS/CM2 | Beam#01(D) SHLD BEAM DR CUR | ||
| NB01 | N/CM**3 | Beam#01(D) densities | ||
| BDEP01 | N/CM3/SEC | Beam#01(D) deposition | ||
| TQJXBD01 | Nt-M/CM3 | Beam#01(D) JxB torque | ||
| PBE01 | WATTS/CM3 | Beam#01(D) electon heating | ||
| PBI01 | WATTS/CM3 | Beam#01(D) ion heating | ||
| PBL01 | WATTS/CM3 | Beam#01(D) heating power el+i+th | ||
| TQB01 | Nt-M/CM3 | Beam#01(D) torque | ||
| VPB01 | T*CM/SEC | Beam#01(D) vpll.B profiles | ||
| EINJ01 | eV | Beam#01(D) Injected Energies | ||
| BPSH01 | WATTS | Beam#01(D) shine-thru power by e | ||
| UBDC02 | AMPS/CM2 | Beam#02(D) UNSHLD BEAM DR CUR | ||
| SBDC02 | AMPS/CM2 | Beam#02(D) SHLD BEAM DR CUR | ||
| NB02 | N/CM**3 | Beam#02(D) densities | ||
| BDEP02 | N/CM3/SEC | Beam#02(D) deposition | ||
| TQJXBD02 | Nt-M/CM3 | Beam#02(D) JxB torque | ||
| PBE02 | WATTS/CM3 | Beam#02(D) electon heating | ||
| PBI02 | WATTS/CM3 | Beam#02(D) ion heating | ||
| PBL02 | WATTS/CM3 | Beam#02(D) heating power el+i+th | ||
| TQB02 | Nt-M/CM3 | Beam#02(D) torque | ||
| VPB02 | T*CM/SEC | Beam#02(D) vpll.B profiles | ||
| EINJ02 | eV | Beam#02(D) Injected Energies | ||
| BPSH02 | WATTS | Beam#02(D) shine-thru power by e | ||
| UBDC03 | AMPS/CM2 | Beam#03(D) UNSHLD BEAM DR CUR | ||
| SBDC03 | AMPS/CM2 | Beam#03(D) SHLD BEAM DR CUR | ||
| NB03 | N/CM**3 | Beam#03(D) densities | ||
| BDEP03 | N/CM3/SEC | Beam#03(D) deposition | ||
| TQJXBD03 | Nt-M/CM3 | Beam#03(D) JxB torque | ||
| PBE03 | WATTS/CM3 | Beam#03(D) electon heating | ||
| PBI03 | WATTS/CM3 | Beam#03(D) ion heating | ||
| PBL03 | WATTS/CM3 | Beam#03(D) heating power el+i+th | ||
| TQB03 | Nt-M/CM3 | Beam#03(D) torque | ||
| VPB03 | T*CM/SEC | Beam#03(D) vpll.B profiles | ||
| EINJ03 | eV | Beam#03(D) Injected Energies | ||
| BPSH03 | WATTS | Beam#03(D) shine-thru power by e | ||
| UBDC04 | AMPS/CM2 | Beam#04(D) UNSHLD BEAM DR CUR | ||
| SBDC04 | AMPS/CM2 | Beam#04(D) SHLD BEAM DR CUR | ||
| NB04 | N/CM**3 | Beam#04(D) densities | ||
| BDEP04 | N/CM3/SEC | Beam#04(D) deposition | ||
| TQJXBD04 | Nt-M/CM3 | Beam#04(D) JxB torque | ||
| PBE04 | WATTS/CM3 | Beam#04(D) electon heating | ||
| PBI04 | WATTS/CM3 | Beam#04(D) ion heating | ||
| PBL04 | WATTS/CM3 | Beam#04(D) heating power el+i+th | ||
| TQB04 | Nt-M/CM3 | Beam#04(D) torque | ||
| VPB04 | T*CM/SEC | Beam#04(D) vpll.B profiles | ||
| EINJ04 | eV | Beam#04(D) Injected Energies | ||
| BPSH04 | WATTS | Beam#04(D) shine-thru power by e | ||
| UBDC05 | AMPS/CM2 | Beam#05(D) UNSHLD BEAM DR CUR | ||
| SBDC05 | AMPS/CM2 | Beam#05(D) SHLD BEAM DR CUR | ||
| NB05 | N/CM**3 | Beam#05(D) densities | ||
| BDEP05 | N/CM3/SEC | Beam#05(D) deposition | ||
| TQJXBD05 | Nt-M/CM3 | Beam#05(D) JxB torque | ||
| PBE05 | WATTS/CM3 | Beam#05(D) electon heating | ||
| PBI05 | WATTS/CM3 | Beam#05(D) ion heating | ||
| PBL05 | WATTS/CM3 | Beam#05(D) heating power el+i+th | ||
| TQB05 | Nt-M/CM3 | Beam#05(D) torque | ||
| VPB05 | T*CM/SEC | Beam#05(D) vpll.B profiles | ||
| EINJ05 | eV | Beam#05(D) Injected Energies | ||
| BPSH05 | WATTS | Beam#05(D) shine-thru power by e | ||
| UBDC06 | AMPS/CM2 | Beam#06(D) UNSHLD BEAM DR CUR | ||
| SBDC06 | AMPS/CM2 | Beam#06(D) SHLD BEAM DR CUR | ||
| NB06 | N/CM**3 | Beam#06(D) densities | ||
| BDEP06 | N/CM3/SEC | Beam#06(D) deposition | ||
| TQJXBD06 | Nt-M/CM3 | Beam#06(D) JxB torque | ||
| PBE06 | WATTS/CM3 | Beam#06(D) electon heating | ||
| PBI06 | WATTS/CM3 | Beam#06(D) ion heating | ||
| PBL06 | WATTS/CM3 | Beam#06(D) heating power el+i+th | ||
| TQB06 | Nt-M/CM3 | Beam#06(D) torque | ||
| VPB06 | T*CM/SEC | Beam#06(D) vpll.B profiles | ||
| EINJ06 | eV | Beam#06(D) Injected Energies | ||
| BPSH06 | WATTS | Beam#06(D) shine-thru power by e | ||
| UBDC07 | AMPS/CM2 | Beam#07(D) UNSHLD BEAM DR CUR | ||
| SBDC07 | AMPS/CM2 | Beam#07(D) SHLD BEAM DR CUR | ||
| NB07 | N/CM**3 | Beam#07(D) densities | ||
| BDEP07 | N/CM3/SEC | Beam#07(D) deposition | ||
| TQJXBD07 | Nt-M/CM3 | Beam#07(D) JxB torque | ||
| PBE07 | WATTS/CM3 | Beam#07(D) electon heating | ||
| PBI07 | WATTS/CM3 | Beam#07(D) ion heating | ||
| PBL07 | WATTS/CM3 | Beam#07(D) heating power el+i+th | ||
| TQB07 | Nt-M/CM3 | Beam#07(D) torque | ||
| VPB07 | T*CM/SEC | Beam#07(D) vpll.B profiles | ||
| EINJ07 | eV | Beam#07(D) Injected Energies | ||
| BPSH07 | WATTS | Beam#07(D) shine-thru power by e | ||
| UBDC08 | AMPS/CM2 | Beam#08(D) UNSHLD BEAM DR CUR | ||
| SBDC08 | AMPS/CM2 | Beam#08(D) SHLD BEAM DR CUR | ||
| NB08 | N/CM**3 | Beam#08(D) densities | ||
| BDEP08 | N/CM3/SEC | Beam#08(D) deposition | ||
| TQJXBD08 | Nt-M/CM3 | Beam#08(D) JxB torque | ||
| PBE08 | WATTS/CM3 | Beam#08(D) electon heating | ||
| PBI08 | WATTS/CM3 | Beam#08(D) ion heating | ||
| PBL08 | WATTS/CM3 | Beam#08(D) heating power el+i+th | ||
| TQB08 | Nt-M/CM3 | Beam#08(D) torque | ||
| VPB08 | T*CM/SEC | Beam#08(D) vpll.B profiles | ||
| EINJ08 | eV | Beam#08(D) Injected Energies | ||
| BPSH08 | WATTS | Beam#08(D) shine-thru power by e | ||
| UBDC09 | AMPS/CM2 | Beam#09(D) UNSHLD BEAM DR CUR | ||
| SBDC09 | AMPS/CM2 | Beam#09(D) SHLD BEAM DR CUR | ||
| NB09 | N/CM**3 | Beam#09(D) densities | ||
| BDEP09 | N/CM3/SEC | Beam#09(D) deposition | ||
| TQJXBD09 | Nt-M/CM3 | Beam#09(D) JxB torque | ||
| PBE09 | WATTS/CM3 | Beam#09(D) electon heating | ||
| PBI09 | WATTS/CM3 | Beam#09(D) ion heating | ||
| PBL09 | WATTS/CM3 | Beam#09(D) heating power el+i+th | ||
| TQB09 | Nt-M/CM3 | Beam#09(D) torque | ||
| VPB09 | T*CM/SEC | Beam#09(D) vpll.B profiles | ||
| EINJ09 | eV | Beam#09(D) Injected Energies | ||
| BPSH09 | WATTS | Beam#09(D) shine-thru power by e | ||
| UBDC10 | AMPS/CM2 | Beam#10(D) UNSHLD BEAM DR CUR | ||
| SBDC10 | AMPS/CM2 | Beam#10(D) SHLD BEAM DR CUR | ||
| NB10 | N/CM**3 | Beam#10(D) densities | ||
| BDEP10 | N/CM3/SEC | Beam#10(D) deposition | ||
| TQJXBD10 | Nt-M/CM3 | Beam#10(D) JxB torque | ||
| PBE10 | WATTS/CM3 | Beam#10(D) electon heating | ||
| PBI10 | WATTS/CM3 | Beam#10(D) ion heating | ||
| PBL10 | WATTS/CM3 | Beam#10(D) heating power el+i+th | ||
| TQB10 | Nt-M/CM3 | Beam#10(D) torque | ||
| VPB10 | T*CM/SEC | Beam#10(D) vpll.B profiles | ||
| EINJ10 | eV | Beam#10(D) Injected Energies | ||
| BPSH10 | WATTS | Beam#10(D) shine-thru power by e | ||
| UBDC11 | AMPS/CM2 | Beam#11(D) UNSHLD BEAM DR CUR | ||
| SBDC11 | AMPS/CM2 | Beam#11(D) SHLD BEAM DR CUR | ||
| NB11 | N/CM**3 | Beam#11(D) densities | ||
| BDEP11 | N/CM3/SEC | Beam#11(D) deposition | ||
| TQJXBD11 | Nt-M/CM3 | Beam#11(D) JxB torque | ||
| PBE11 | WATTS/CM3 | Beam#11(D) electon heating | ||
| PBI11 | WATTS/CM3 | Beam#11(D) ion heating | ||
| PBL11 | WATTS/CM3 | Beam#11(D) heating power el+i+th | ||
| TQB11 | Nt-M/CM3 | Beam#11(D) torque | ||
| VPB11 | T*CM/SEC | Beam#11(D) vpll.B profiles | ||
| EINJ11 | eV | Beam#11(D) Injected Energies | ||
| BPSH11 | WATTS | Beam#11(D) shine-thru power by e | ||
| UBDC12 | AMPS/CM2 | Beam#12(D) UNSHLD BEAM DR CUR | ||
| SBDC12 | AMPS/CM2 | Beam#12(D) SHLD BEAM DR CUR | ||
| NB12 | N/CM**3 | Beam#12(D) densities | ||
| BDEP12 | N/CM3/SEC | Beam#12(D) deposition | ||
| TQJXBD12 | Nt-M/CM3 | Beam#12(D) JxB torque | ||
| PBE12 | WATTS/CM3 | Beam#12(D) electon heating | ||
| PBI12 | WATTS/CM3 | Beam#12(D) ion heating | ||
| PBL12 | WATTS/CM3 | Beam#12(D) heating power el+i+th | ||
| TQB12 | Nt-M/CM3 | Beam#12(D) torque | ||
| VPB12 | T*CM/SEC | Beam#12(D) vpll.B profiles | ||
| EINJ12 | eV | Beam#12(D) Injected Energies | ||
| BPSH12 | WATTS | Beam#12(D) shine-thru power by e | ||
| UBDC13 | AMPS/CM2 | Beam#13(D) UNSHLD BEAM DR CUR | ||
| SBDC13 | AMPS/CM2 | Beam#13(D) SHLD BEAM DR CUR | ||
| NB13 | N/CM**3 | Beam#13(D) densities | ||
| BDEP13 | N/CM3/SEC | Beam#13(D) deposition | ||
| TQJXBD13 | Nt-M/CM3 | Beam#13(D) JxB torque | ||
| PBE13 | WATTS/CM3 | Beam#13(D) electon heating | ||
| PBI13 | WATTS/CM3 | Beam#13(D) ion heating | ||
| PBL13 | WATTS/CM3 | Beam#13(D) heating power el+i+th | ||
| TQB13 | Nt-M/CM3 | Beam#13(D) torque | ||
| VPB13 | T*CM/SEC | Beam#13(D) vpll.B profiles | ||
| EINJ13 | eV | Beam#13(D) Injected Energies | ||
| BPSH13 | WATTS | Beam#13(D) shine-thru power by e | ||
| UBDC14 | AMPS/CM2 | Beam#14(D) UNSHLD BEAM DR CUR | ||
| SBDC14 | AMPS/CM2 | Beam#14(D) SHLD BEAM DR CUR | ||
| NB14 | N/CM**3 | Beam#14(D) densities | ||
| BDEP14 | N/CM3/SEC | Beam#14(D) deposition | ||
| TQJXBD14 | Nt-M/CM3 | Beam#14(D) JxB torque | ||
| PBE14 | WATTS/CM3 | Beam#14(D) electon heating | ||
| PBI14 | WATTS/CM3 | Beam#14(D) ion heating | ||
| PBL14 | WATTS/CM3 | Beam#14(D) heating power el+i+th | ||
| TQB14 | Nt-M/CM3 | Beam#14(D) torque | ||
| VPB14 | T*CM/SEC | Beam#14(D) vpll.B profiles | ||
| EINJ14 | eV | Beam#14(D) Injected Energies | ||
| BPSH14 | WATTS | Beam#14(D) shine-thru power by e | ||
| PINJB | WATTS | the total/beam injected power | ||
| TQTOTNB | Nt-M/CM3 | the total/beam torque | ||
| TQCOLNB | Nt-M/CM3 | the total collisional torque | ||
| TQTHNB | Nt-M/CM3 | the total thermalization torque | ||
| TQJBNB | Nt-M/CM3 | the total/beam JxB torque | ||
| TQJBNBD | Nt-M/CM3 | the dep/beam JxB torque | ||
| BDENSNB | N/CM**3 | the total/beam density | ||
| BDEPNB | N/CM3/SEC | the total/beam deposition | ||
| PBTOTNB | WATTS/CM3 | the total/beam power | ||
| PBENB | WATTS/CM3 | the electon heating/beam power | ||
| PBINB | WATTS/CM3 | the ion heating/beam power | ||
| PBTHNB | WATTS/CM3 | the thermalization power | ||
| SNCXTOT_D | N/CM3/SEC | total CX sink rate D | ||
| NB_F_D | N/CM**3 | D Beam ion density by E.fraction | ||
| PB_F_D | WATTS/CM3 | D Beam heating by E.fraction | ||
| VPB_F_D | T*(cm/sec) | D Beam vpll.B flow by E.fraction | ||
| EINJAV | EV | avg beam voltages by species | ||
| EPOT | VOLTS | ELECTROSTATIC POTENTIAL | ||
| VTORMP | CM/SEC | TOROIDAL VELOCITIES ON MIDPLANE | ||
| OMGNC | rad/sec | NC TOROIDAL ANGULAR VELOCITIES | ||
| VPOLMP | CM/SEC | POLOIDAL VELOCITIES ON MIDPLANE | ||
| NCSQUEEZ | NC ORBIT SQUEEZING FACTORS | |||
| JBFACS | BEAM CURRENT SHIELDING FACTOR | |||
| VNDNC | CM/SEC | Nclass particle convection velocities | ||
| DFNC | CM**2/SEC | Nclass particle diffusivities | ||
| GEOPARM | surface geometry parameters | |||
| SQPARM | squareness parameters | |||
| CZIMP | Impurity Z Data Comparison | |||
| ZIMP | Average Mult. Impurity Z | |||
| PSFMTOT | CM**-2 | NC Pfirsch-Schluter moments | ||
| PVOLS | CM**3 | PLASMA VOLUMES | ||
| FLUXRATE | 1/SEC | Relative motion of grids | ||
| RMAJB | CM | EQUILIBRIUM RMAJ FLUX/BOUNDARY | ||
| DTS | SECONDS | TIMESTEPS | ||
| DTGEQ | SECONDS | Equilibrium Timesteps | ||
| BN00 | N/CM**3 | BEAM 1.GEN NEUTRAL DENSITY | ||
| ERAD | V/CM | NC Diagnostic Radial E Field | ||
| NBXPNT | Dominant X point or 0 for limited | |||
| APMHD | Wb/rad | Psi of Equilibrium Points relative to machine axis | ||
| VOLTSEC | V*s | Volt-Second Flux Consumption | ||
| CMG_D | rad/sec | D gas rotation comparison | ||
| CMGX | rad/sec | total impurity gas rotation comparison | ||
| BOLCOM | W/cm**3 | BOL data map check | ||
| NERCOM | n/cm**3 | NER data map check | ||
| NIMCOM | n/cm**3 | NIM data map check | ||
| OMGCOM | rad/sec | OMG data map check | ||
| QPRCOM | QPR data map check | |||
| TERCOM | eV | TER data map check | ||
| TI2COM | eV | TI2 data map check | ||
| ZF2COM | ZF2 data map check | |||
| IRAEP | AMPS | FAST ION RAD.CUR DUE TO AEP (MHD) ACTIVITY | ||
| PBAEPS_D | WATTS/CM3 | AEP POWER D beam by MODE 1-10 | ||
| NAEPTB_D | N | AEP # TIME STEPS D beam by MODE 1-10 |
Project sponsored by the Office of Fusion Energy Sciences of the US DOE