From 650bebb643bb18a1ef27eb6f7d4e5d7fd814fa51 Mon Sep 17 00:00:00 2001
From: Olivier Sauter <olivier.sauter@epfl.ch>
Date: Fri, 12 Jun 2015 13:27:29 +0000
Subject: [PATCH] add transp_EXPNAME keyword to load TRANSP data from shotfile
 at IPP

git-svn-id: https://spcsvn.epfl.ch/repos/TCV/gdat/trunk@4819 d63d8f72-b253-0410-a779-e742ad2e26cf
---
 crpptbx/AUG/TRANSP_signals.m | 585 +++++++++++++++++++++++++++++++++++
 crpptbx/AUG/loadAUGdata.m    |  46 ++-
 2 files changed, 629 insertions(+), 2 deletions(-)
 create mode 100644 crpptbx/AUG/TRANSP_signals.m

diff --git a/crpptbx/AUG/TRANSP_signals.m b/crpptbx/AUG/TRANSP_signals.m
new file mode 100644
index 00000000..4dad4808
--- /dev/null
+++ b/crpptbx/AUG/TRANSP_signals.m
@@ -0,0 +1,585 @@
+%TIME ; Time-Base ; Time grid of time traces
+%Setup ; Parameter-Set ; Namelist parameters and switches
+%NBIpar ; Parameter-Set ; Parameters of Neutral Beam Injection
+clear transp_sig
+i=0;
+i=i+1;transp_sig{i,1}= 'ALPC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAG:ALPHA, CALCULATED [ ]';
+i=i+1;transp_sig{i,1}= 'ASHAF'; transp_sig{i,2}='Signal'; transp_sig{i,3}='SHAFRANOV AXIS SHIFT [CM ]';
+i=i+1;transp_sig{i,1}= 'BBNTS'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM-BEAM NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BBPAR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM BETA(POLOIDAL) PLL [ ]';
+i=i+1;transp_sig{i,1}= 'BBPER'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM BETA(POLOIDAL) PERP [ ]';
+i=i+1;transp_sig{i,1}= 'BDNDT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D/DT(FAST ION POPULATION) [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDNDTX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D/DT(FAST IONS OUTSIDE PLASMA) [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BETAE'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELECTRON BETA (POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BETAI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='THERMAL ION BETA POLOIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BETAR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ROTATION BETA (POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BETAT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL BETA(POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BPCAP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM POWER CAPTURED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCI0'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX SCE POWER (INT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCPR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: COMPRESSION OF FAST IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCRI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX RECAPTURE (INT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCRX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX RECAPTURE (EXT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCX0'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX SCE POWER (EXT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCXE'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX TRACKER ERROR [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCXI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION POWER TO CX (INT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPCXX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION POWER TO CX (EXT) [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPDA1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='1D DIAMAGNETIC BETA(POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BPDC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='KINETIC BETA(DIA) [ ]';
+i=i+1;transp_sig{i,1}= 'BPDIA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='DIAMAGNETIC BETA(POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BPDM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAGNETICS EST. BETA(DIA) [ ]';
+i=i+1;transp_sig{i,1}= 'BPEPHI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Electrostatic field -> fast ions [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPEPHI_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELECTROSTATIC ACCEL.: D BEAM [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPEQ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='EQUILIBRIUM BETA(POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BPERR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION ORBIT POWER ERROR [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPFASTPA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL FAST ION BETA(POL) PLL [ ]';
+i=i+1;transp_sig{i,1}= 'BPFASTPP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL FAST ION BETA(POL) PERP [ ]';
+i=i+1;transp_sig{i,1}= 'BPHCK'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. BALANCE CHECK [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHCL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. COLLISIONAL TORQUE [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHCX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. CX LOSS [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHDFB_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM: ANOM.DIFF. TORQUE [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHDP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. DEPOSITION [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHER'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ORBIT TORQUE ERROR [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION ANGULAR MOMENTUM [NT-M-SEC ]';
+i=i+1;transp_sig{i,1}= 'BPHOH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. FROM OH [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHOR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. ORBIT LOSS [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHRC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. CX RECAPTURE [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHST'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. ANGULAR MOMENTUM GAIN [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHTH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. THERMALIZATION [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHTO'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL FAST ION HEATING [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPHW0'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. NEUTRAL ESCAPE [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPHXB'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FI ROT. JXB TORQUE [NT-M ]';
+i=i+1;transp_sig{i,1}= 'BPLIM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION ORBIT LOSS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPOH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: OH CIRCUIT TO FAST IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPSHI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION SHINE-THRU POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPST'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION POWER STORED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPTE'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM POWER TO ELECTRONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPTH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION POWER THERMALIZED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BPTI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM POWER TO IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'BSBAL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION PTCL BALANCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BSNXI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX SINK (INT) [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BSNXO'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX SINK (EXT) [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BSORB'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION ORBIT LOSSES [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BSTH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION THERMALIZATIONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BTDIA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='DIAMAGNETIC BETA(TOROIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BTEQ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='EQUILIBRIUM BETA(TOROIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'BTNTS'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM-TARGET NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BTNTS_DD'; transp_sig{i,2}='Signal'; transp_sig{i,3}='DD BEAM-TARGET NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'BZ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BZ @R=RMAJOR OUTSIDE PLASMA [TESLA ]';
+i=i+1;transp_sig{i,1}= 'BZXR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='VACUUM FIELD "BZ*R" [TESLA*CM ]';
+i=i+1;transp_sig{i,1}= 'BZXRC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CALCULATED VACUUM FIELD "BZ*R" [TESLA*CM ]';
+i=i+1;transp_sig{i,1}= 'CPTIM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CPU TIME USED SO FAR [HOURS ]';
+i=i+1;transp_sig{i,1}= 'DFLUX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='COMPUTED DIAMAGNETIC FLUX [WEBERS ]';
+i=i+1;transp_sig{i,1}= 'DT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ENERGY BALANCE TIMESTEP [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'DTG'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TIMESTEP FOR GEO & SOURCES [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'DTPROFIL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TIME SPACING FOR PROFILE OUTPUT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'DTSCALAR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TIME SPACING FOR SCALAR OUTPUT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'E0INR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='T0 (RECYCLING) @EDGE [EV ]';
+i=i+1;transp_sig{i,1}= 'ECEGAP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ECE B(R) monotonicity gap [CM ]';
+i=i+1;transp_sig{i,1}= 'EINJ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAX INITIAL BEAM ENERGY [EV ]';
+i=i+1;transp_sig{i,1}= 'EINJAV_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D: avg full injection energy [EV ]';
+i=i+1;transp_sig{i,1}= 'ELDOT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELDOT: GRID MOTION [1/SEC ]';
+i=i+1;transp_sig{i,1}= 'FLSTA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FALSI ERROR CODE [0=NORMAL ]';
+i=i+1;transp_sig{i,1}= 'GASD'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D0 GAS FLOW SOURCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'GASH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='H0 GAS FLOW SOURCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'GSERROR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='REL.EQUIL.GRAD-SHAFRANOV ERROR [ ]';
+i=i+1;transp_sig{i,1}= 'HIO2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='INDUCTANCE (HI/2) [ ]';
+i=i+1;transp_sig{i,1}= 'IPXVS'; transp_sig{i,2}='Signal'; transp_sig{i,3}='PCUR * VSUR [WATTS ]';
+i=i+1;transp_sig{i,1}= 'KAINT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='K(ALPHA) LINE INTENSITY [ARB.UNITS ]';
+i=i+1;transp_sig{i,1}= 'KATX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='COMPUTED K(ALPHA) T(IMPURITY) [EV ]';
+i=i+1;transp_sig{i,1}= 'L2PB1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='1D DEFINITION LI/2+BETA [ ]';
+i=i+1;transp_sig{i,1}= 'LAMDC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='KINETIC+J EST. LAMDA [ ]';
+i=i+1;transp_sig{i,1}= 'LAMDM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAGNETICS EST. LAMDA [ ]';
+i=i+1;transp_sig{i,1}= 'LI2PB'; transp_sig{i,2}='Signal'; transp_sig{i,3}='LI/2 + BETA(POLOIDAL) [ ]';
+i=i+1;transp_sig{i,1}= 'LIO2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='INDUCTANCE (LI/2) [ ]';
+i=i+1;transp_sig{i,1}= 'LIO21'; transp_sig{i,2}='Signal'; transp_sig{i,3}='1D DEFINITION OF LI/2 [ ]';
+i=i+1;transp_sig{i,1}= 'LIO2C'; transp_sig{i,2}='Signal'; transp_sig{i,3}='LI/2 (COMPUTED FROM J PROFILE) [ ]';
+i=i+1;transp_sig{i,1}= 'LIO2M'; transp_sig{i,2}='Signal'; transp_sig{i,3}='LI/2 (MAGNETICS DATA ESTIMATE) [ ]';
+i=i+1;transp_sig{i,1}= 'MUIC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TRANSP EST. MU(DIA) MHD EQ [ ]';
+i=i+1;transp_sig{i,1}= 'MUIM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAGNETICS EST. MU(DIA) [ ]';
+i=i+1;transp_sig{i,1}= 'NEUTT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'NEUTX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='THERMONUCLEAR NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'NEUTX_DD'; transp_sig{i,2}='Signal'; transp_sig{i,3}='DD THERMONUCLEAR NEUTRONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'NMCLOSS_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam D MC Prompt Loss [N ]';
+i=i+1;transp_sig{i,1}= 'NMCTOT_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam D Total MC Ions [N ]';
+i=i+1;transp_sig{i,1}= 'P0BAL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='NEUTRAL POWER BALANCE CHECK [WATTS ]';
+i=i+1;transp_sig{i,1}= 'P0CXT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL CX POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'P0ESC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='NEUTRAL POWER ESCAPED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'P0FIN'; transp_sig{i,2}='Signal'; transp_sig{i,3}='NEUTRAL INFLUX POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'P0INZ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='NEUTRAL POWER IONIZED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'P0RFL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='NEUTRAL POWER REFLECTED IN [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PAREA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='PLASMA CROSS SECTION AREA [CM**2 ]';
+i=i+1;transp_sig{i,1}= 'PCUR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MEASURED PLASMA CURRENT [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PCURC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CALCULATED PLASMA CURRENT [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PCUREQ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='EQ PLASMA CURRENT [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PEEDG'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELECTRON ENERGY VIA BDY [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECHT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ECRF ELECTRON HEATING [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ECRF INPUT POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 1 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 2 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN3'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 3 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN4'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 4 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN5'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 5 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN6'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 6 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN7'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 7 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PECIN8'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER FROM GYRO 8 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHA1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER ON ICRF ANTENNA #1 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHA2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER ON ICRF ANTENNA #2 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHA3'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER ON ICRF ANTENNA #3 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHA4'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER ON ICRF ANTENNA #4 [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHBAL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='RF POWER BALANCE [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHE'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: ICH DIRECT TO ELECTRONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHEXT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='RF POWER BEYOND SEPARATRIX [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHFAST'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: ICH DIRECT TO Fast ions [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHI'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: ICH DIRECT TO TH.IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHMC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: ICH TO MODE CONVERSION [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHMIN'; transp_sig{i,2}='Signal'; transp_sig{i,3}='POWER: ICH TO MINORITY IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PICHTOT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL ICRF ANTENNA POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PIEDG'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ION ENERGY VIA BDY [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='BEAM POWER INJECTED [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ01'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#01(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ02'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#02(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ03'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#03(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ04'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#04(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ05'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#05(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ06'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#06(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ07'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#07(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PINJ08'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam#08(D) injected power [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PLFLXA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ENCLOSED POLOIDAL FLUX [WEBERS ]';
+i=i+1;transp_sig{i,1}= 'POHT'; transp_sig{i,2}='Signal'; transp_sig{i,3}='OHMIC INPUT POWER [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PRFB_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='RF POWER -> D BEAM IONS [WATTS ]';
+i=i+1;transp_sig{i,1}= 'PVOL'; transp_sig{i,2}='Signal'; transp_sig{i,3}='PLASMA VOLUME [CM**3 ]';
+i=i+1;transp_sig{i,1}= 'RAXIS'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAJOR RADIUS OF MAG. AXIS [CM ]';
+i=i+1;transp_sig{i,1}= 'RCYD'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D0 RECYCLING SOURCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'RCYH'; transp_sig{i,2}='Signal'; transp_sig{i,3}='H0 RECYCLING SOURCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'RTPC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAG:RT, CALCULATED [CM ]';
+i=i+1;transp_sig{i,1}= 'RTXUV'; transp_sig{i,2}='Signal'; transp_sig{i,3}='UV DOPPLER TI RADIUS [CM ]';
+i=i+1;transp_sig{i,1}= 'RZITER'; transp_sig{i,2}='Signal'; transp_sig{i,3}='RZSOLVER iterations [ ]';
+i=i+1;transp_sig{i,1}= 'SBCX0MC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM CX NEUTRALS LAUNCHED [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXBAL_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM CX NEUTRAL PTCL BAL [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXESC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM CX NEUTRALS ESCAPED [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXRMC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM CX MC IONS RECAPTURED [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXRR_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM CX NEUTRALS "R.R." [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CX FAST ION LOSS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDBBCX_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP: BEAM-BEAM CX [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDBBIZ_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP: BEAM-BEAM IONIZ. [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPBA_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP PTCL BALANCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPCX_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP: CX W/THERMAL IONS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPIZ_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP: TH.IONIZATION [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPMC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM MC IONS DEPOSITED [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPRR_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM DEP "RUSSIAN ROULETTE" [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDEPSC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM TOTAL DEPOSITION SCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBDTBMC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM MC RATE OF CHANGE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBORBAL_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ORBIT PTCL BALANCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBORBRR_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ORBIT CODE "R.R." [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBRBBCX_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM RECAP: BEAM-BEAM CX [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBRBBIZ_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM RECAP: BEAM-BEAM IONIZ. [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBSHINE_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM SHINE-THROUGH [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRCCX_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM RECAP: TH.CX [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRCIZ_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM RECAP: TH.IONIZATION [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRCSC_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM TOTAL RECAPTURE SCE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SEEDG'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELECTRONS VIA BDY [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SFDEP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION SCE: DEPOSITION [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SFRCAP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST ION CX RECAPTURE [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SHFSC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CALCULATED S1+S2 [ ]';
+i=i+1;transp_sig{i,1}= 'SHFSM'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MAGNETICS EST. S1+S2 [ ]';
+i=i+1;transp_sig{i,1}= 'SINJ'; transp_sig{i,2}='Signal'; transp_sig{i,3}='FAST NEUTRALS INJECTED [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SNBXBB0_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ION CX W/ BEAM NEUTS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SNBXBB1_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ION CX W/ FAST CX NEUTS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SNBXTOT_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL D BEAM ION CX SINK [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SNBXV0_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ION CX SINK: HALO NEUTS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'SNBXW0_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D BEAM ION CX SINK: WALL NEUTS [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'TAUA1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ENERGY CONFINEMENT (TOTAL) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TAUEA'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ENERGY CONFINEMENT (THERMAL) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TAUEE'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ELECTRON ENERGY CONFINEMENT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TFLUX'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ENCLOSED TOROIDAL FLUX [WEBERS ]';
+i=i+1;transp_sig{i,1}= 'TOTDDN'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL D(D,N)HE3 FUSION [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'TOTDDP'; transp_sig{i,2}='Signal'; transp_sig{i,3}='TOTAL D(D,P)T FUSION [N/SEC ]';
+i=i+1;transp_sig{i,1}= 'TRAPB0_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D beam full E dep banana frac. [ ]';
+i=i+1;transp_sig{i,1}= 'TRAPB_D'; transp_sig{i,2}='Signal'; transp_sig{i,3}='D beam ions banana fraction [ ]';
+i=i+1;transp_sig{i,1}= 'TXUV'; transp_sig{i,2}='Signal'; transp_sig{i,3}='UV DOPPLER T(IMPURITY) [EV ]';
+i=i+1;transp_sig{i,1}= 'VISBC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CHORDAL VB LIGHT (CALCULATED) [VB UNITS ]';
+i=i+1;transp_sig{i,1}= 'VSUR'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MEAS.AVG. SURFACE VOLTAGE [VOLTS ]';
+i=i+1;transp_sig{i,1}= 'VSUR0'; transp_sig{i,2}='Signal'; transp_sig{i,3}='SURFACE VOLTAGE [VOLTS ]';
+i=i+1;transp_sig{i,1}= 'VSURC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='CALC.AVG. SURFACE VOLTAGE [VOLTS ]';
+i=i+1;transp_sig{i,1}= 'WNMCTOT_'; transp_sig{i,2}='Signal'; transp_sig{i,3}='Beam D Total MC Ions [#ptcls ]';
+i=i+1;transp_sig{i,1}= 'XBFAC'; transp_sig{i,2}='Signal'; transp_sig{i,3}='MHD BETA ADJUSTMENT FACTOR [ ]';
+i=i+1;transp_sig{i,1}= 'XIQ1'; transp_sig{i,2}='Signal'; transp_sig{i,3}='xi of Q=1 surface [ ]';
+i=i+1;transp_sig{i,1}= 'XIQ2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='xi of Q=2 surface [ ]';
+i=i+1;transp_sig{i,1}= 'XIQ3'; transp_sig{i,2}='Signal'; transp_sig{i,3}='xi of Q=3 surface [ ]';
+i=i+1;transp_sig{i,1}= 'XIQ3_2'; transp_sig{i,2}='Signal'; transp_sig{i,3}='xi of Q=3/2 surface [ ]';
+i=i+1;transp_sig{i,1}= 'YAXIS'; transp_sig{i,2}='Signal'; transp_sig{i,3}='ASYMMETRIC GEO: Y OF MAG. AXIS [CM ]';
+i=i+1;transp_sig{i,1}= 'YMPBDY'; transp_sig{i,2}='Signal'; transp_sig{i,3}='"MIDPLANE" Y OF ASYM BDY SURFACE [CMU ]';
+i=i+1;transp_sig{i,1}= 'TIME3'; transp_sig{i,2}='Time-Base'; transp_sig{i,3}='Time grid for profile data';
+i=i+1;transp_sig{i,1}= 'X'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='rho_tor (full radial resolution)';
+i=i+1;transp_sig{i,1}= 'AMOI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Total Therm Ang Inertia Dens [NtM2/CM3 ]';
+i=i+1;transp_sig{i,1}= 'BBETA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM BETA POLOIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BBNTX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM-BEAM NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDENS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM ION DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BDEPE_D1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FULL E D BEAM DEP (TOTAL) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDEPE_D2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='HALF E D BEAM DEP (TOTAL) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDEPE_D3'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='1/3 E D BEAM DEP (TOTAL) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDEP_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D BEAM DEPOSITION (TOTAL) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BN0T1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEUTRALS:1.GEN 1/1*EB [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BN0T2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEUTRALS:1.GEN 1/2*EB [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BN0T3'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEUTRALS:1.GEN 1/3*EB [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BTBE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BTE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BTI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BTNTX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM-TARGET NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BTPL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='PLASMA BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BTRAP0_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D beam full E dep banana frac. [ ]';
+i=i+1;transp_sig{i,1}= 'BTRAP_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D beam ions banana fraction [ ]';
+i=i+1;transp_sig{i,1}= 'BTROT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ROTATION BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'BTTOT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL BETA TOROIDAL [ ]';
+i=i+1;transp_sig{i,1}= 'CICHD_AL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH DIRECT CUR DRIVE [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CICHM_AL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH MINORITY CUR DRIVE [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CLOGE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON COULOMB LOG [ ]';
+i=i+1;transp_sig{i,1}= 'CLOGI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION COULOMB LOG [ ]';
+i=i+1;transp_sig{i,1}= 'CUR'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL PLASMA CURRENT [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DRIVEN CURRENT [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURBS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BOOTSTRAP CURRENT [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURBSEPS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Aspect Ratio Bootstrap Current [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURBSSAU'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Sauter Bootstrap Current [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURBSWNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NCLASS Bootstrap Current [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CURGP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GRAD(P) TOROIDAL CUR [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'CUROH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='OHMIC PLASMA CURRENT [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'DAREA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ZONE CROSS SECTIONAL AREA [CM**2 ]';
+i=i+1;transp_sig{i,1}= 'DIVFD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DIV(ION FLUX D+) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIVFE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DIV(ELECTRON FLUX) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIVFI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DIV(TOTAL ION FLUX) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'DN0VD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOL NEUTRAL DENSITY G=D [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'DN0VH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOL NEUTRAL DENSITY G=H [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'DN0WD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='WALL NEUTRAL DENS G=D [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'DN0WH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='WALL NEUTRAL DENS G=H [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'DNDDT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D/DT(ION DENS D+) [N/CM3/SEC]';
+i=i+1;transp_sig{i,1}= 'DVOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ZONE VOLUME [CM**3 ]';
+i=i+1;transp_sig{i,1}= 'EBEAM_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='AVG D BEAM ION ENERGY [EV ]';
+i=i+1;transp_sig{i,1}= 'ECCUR'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 1) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 2) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR3'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 3) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR4'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 4) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR5'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 5) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR6'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 6) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR7'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 7) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'ECCUR8'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH CURRENT (GYRO 8) [A/CM2 ]';
+i=i+1;transp_sig{i,1}= 'EHEAT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ELECTRON HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'ETA_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC RESISTIVITY (old fit) [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_SNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Sauter Neoclassical Resistivity [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_SP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='SPITZER RESISTIVITY [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_SPS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='SPITZER RESISTIVITY (Sauter) [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_TSC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TSC Neoclassical Resistivity [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_USE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RESISTIVITY USED OR INFERRED [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'ETA_WNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NCLASS Resistivity [OHM*CM ]';
+i=i+1;transp_sig{i,1}= 'FMCK_WNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NCLASS Fm convergence check [ ]';
+i=i+1;transp_sig{i,1}= 'FPAX_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D BEAM SCATTERING >IMPURITIES [ ]';
+i=i+1;transp_sig{i,1}= 'FPBX_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D BEAM DRAG >IMPURITIES [ ]';
+i=i+1;transp_sig{i,1}= 'FTOTDDN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL D(D,N)HE3 FUSION [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'FTOTDDP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL D(D,P)T FUSION [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'GAINE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON GAIN [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'GAINI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION GAIN [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'GMAG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GMAG (RT) PRESSURE PROFILE [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'GR2X2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='<R**2*GRAD(XI)**2> FLX.SURF.AVG [ ]';
+i=i+1;transp_sig{i,1}= 'GXI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='<GRAD(XI)> FLUX SURF VOL.AVG [CM**-1 ]';
+i=i+1;transp_sig{i,1}= 'GXI2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='<GRAD(XI)**2> FLUX SURF VOL.AVG [CM**-2 ]';
+i=i+1;transp_sig{i,1}= 'IHEAT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ION HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'JBFAC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Species avg Jb shielding [ ]';
+i=i+1;transp_sig{i,1}= 'JBFACZ1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Z=1 Jb shielding [ ]';
+i=i+1;transp_sig{i,1}= 'M0NET'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NET CX MOMENTUM LOSS [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'MCONV'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CONVECTIVE TRANSPORT [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'MODOT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MOMENTUM GAIN [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'MVISC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VISCOUS TRANSPORT [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'N0BCXD0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CX FAST NEUTRAL DENSITY (D0) [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'N0BD0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='1.GEN FAST NEUTRAL DENSITY (D0) [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NB_F1_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='density: full energy D beam [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NB_F2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='density: half energy D beam [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NB_F3_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='density: 1/3 energy D beam [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NCFT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC trapping fraction (net) [ ]';
+i=i+1;transp_sig{i,1}= 'NCFTMINU'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC trapping fraction lower limit [ ]';
+i=i+1;transp_sig{i,1}= 'NCFTPLUS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC trapping fraction upper limit [ ]';
+i=i+1;transp_sig{i,1}= 'ND'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DEUTERIUM ION DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='HYDROGEN ION DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NHE4'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='HELIUM-4 ION DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ION DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NIMP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL IMPURITY DENSITY [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'NMC_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Beam D No. of MC Ions [N ]';
+i=i+1;transp_sig{i,1}= 'NUSTE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON COLLISIONALITY [ ]';
+i=i+1;transp_sig{i,1}= 'NUSTI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION COLLISIONALITY [ ]';
+i=i+1;transp_sig{i,1}= 'OMEGA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOROIDAL ANGULAR VELOCITY [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEGA_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='N.C. TOROIDAL ANGULAR VELOCITY [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEGB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM ION AVG ANG.VELOCITY [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEGB_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D BEAM ION AVG ANG.VELOCITY [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEGDATA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Toroidal Ang.Velocity Data [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'P0NET'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NET CHARGE EXCHANGE LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBCX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='THERMAL ION LOSS, FAST ION CX [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM HEATING OF ELECTRONS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBEPHI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Electrostatic field -> fast ions [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBE_F1_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbe: full energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBE_F2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbe: half energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBE_F3_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbe: 1/3 energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM HEATING OF IONS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBI_F1_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbi: full energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBI_F2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbi: half energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBI_F3_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Pbi: 1/3 energy D beam [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PBTH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION THERMALIZATION POWER [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCMPE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON COMPRESSION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCMPI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION COMPRESSION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCNDE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON CONDUCTION LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCNVE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON CONVECTION LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCOND'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION CONDUCTION LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCONV'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION CONVECTION LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCPRB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POWER: COMPRESSION OF FAST IONS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PCX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHARGE EXCHANGE LOSS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 1) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 2) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH3'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 3) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH4'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 4) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH5'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 5) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH6'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 6) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH7'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 7) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEECH8'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ECRH ELECTRON HEATING (GYRO 8) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PEICH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF ELECTRON HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PHBAL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ANGULAR MOMENTUM BALANCE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PICF01N0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF PWR, Nphi= 12, FREQ#1 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PICF02N0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF PWR, Nphi= 12, FREQ#2 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PICF03N0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF PWR, Nphi= 12, FREQ#3 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PICF04N0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF PWR, Nphi= 12, FREQ#4 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PIC_F1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RF PWR Absorbed, Freq.1 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PIC_F2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RF PWR Absorbed, Freq.2 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PIC_F3'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RF PWR Absorbed, Freq.3 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PIC_F4'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RF PWR Absorbed, Freq.4 [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PIICH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRF ION HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PION'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEUTRAL IONIZATION WORK [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PMHD_IN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='PRESSURE INPUT to MHD SOLVER [PASCALS ]';
+i=i+1;transp_sig{i,1}= 'PNI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEUTRAL IONIZATION SOURCE [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'POH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='OHMIC HEATING POWER [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'POHB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POWER: OH CIRCUIT TO FAST IONS [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PPLAS'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='PLASMA PRESSURE [PASCALS ]';
+i=i+1;transp_sig{i,1}= 'PRAD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NET RADIATED POWER [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PRADC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NET RADIATED POWER CALCULATED [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PRADS_TO'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOK Impurity Radiation [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PRAD_BR'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BREMSSTRAHLUNG RADIATION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PRAD_CY'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CYCLOTRON RADIATION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PRAD_LI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='LINE RADIATION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PTMIN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MINORITY TRANSPORT [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'PTOWB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='KINETIC MHD PRESSURE W/FAST IONS [PASCALS ]';
+i=i+1;transp_sig{i,1}= 'QICHA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ICH HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QICHE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH DIRECT ELECTRON HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QICHFAST'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH Heating of Beam & Fusn Ions [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QICHI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH DIRECT TH.ION HEATING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QICHMC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH HEATING BY MODE CONVERSION [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QICHMIN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH PWR TO MINORITY [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QIE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION-ELECTRON COUPLING [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'QMINICH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICRH Power (Renormalized QL0) [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'S0RCD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RECOMB NEUTRAL SCE G=D [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'S0RCH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RECOMB NEUTRAL SCE G=H [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'S0VLE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL NEUTRAL VOL SCE [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'S0VOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL NEUTRAL VOL E-SCE [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SB0ID'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D0 NEUTRAL SINK BEAM II [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SB0IH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='H0 NEUTRAL SINK BEAM II [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SB0XD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D0 NEUTRAL SINK BEAM CX [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SB0XH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='H0 NEUTRAL SINK BEAM CX [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCX0'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION CX: NEUTRALS BORN [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D0 NEUTRAL SOURCE BEAM CX [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBCXH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='H0 NEUTRAL SOURCE BEAM CX [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON SCE FAST ION DEPOSITION [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBHD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D+ ION SCE DUE TO BEAM [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBHH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='H+ ION SCE DUE TO BEAM [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBTH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION THERMALIZATION SOURCE [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBTOT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ION SCE(VOL. NEUTRALS) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION CX: BEAM-BEAM RECAPTURE [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM CX: RECAPTURE BY CX W/D+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXRH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM CX: RECAPTURE BY CX W/H+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXR_IE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RECAPTURE on electrons [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXR_II'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RECAPTURE on th.ions [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SBXR_IZ'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RECAPTURE on impurities [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SCEE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON SOURCE (TH.NEUTRALS) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SCEV'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON SCE (VOL. NEUTRALS) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SCEW'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON SCE (WALL NEUTRALS) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SCIMP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='IMPURITY SOURCE [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDBBI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEPOSITION: BEAM-BEAM II [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDBBX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEPOSITION: BEAM-BEAM CX [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDB_IE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEP: ioniz. on electrons [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDB_II'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEP: ioniz. on therm. ions [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDB_IZ'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEP: ioniz. on impurities [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDCXD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEPOSITION: CX W/D+ IONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SDCXH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM DEPOSITION: CX W/H+ IONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SERUN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='RUNAWAY ELEC SOURCE RATE [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SFETO'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRONS -> FAST NEUTRALS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SVD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOT ION SCE VOL. D+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SVH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOT ION SCE VOL. H+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SWD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOT ION SCE WALL D+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SWH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOT ION SCE WALL H+ [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'SWTOT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ION SCE(WALL NEUTRALS) [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'T0VD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOL NEUTRAL TEMP G=D [EV ]';
+i=i+1;transp_sig{i,1}= 'T0VH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOL NEUTRAL TEMP G=H [EV ]';
+i=i+1;transp_sig{i,1}= 'T0WD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='WALL NEUTRAL TEMP G=D [EV ]';
+i=i+1;transp_sig{i,1}= 'T0WH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='WALL NEUTRAL TEMP G=H [EV ]';
+i=i+1;transp_sig{i,1}= 'TE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON TEMPERATURE [EV ]';
+i=i+1;transp_sig{i,1}= 'THNTX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='THERMONUCLEAR NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'TI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION TEMPERATURE [EV ]';
+i=i+1;transp_sig{i,1}= 'TPA1A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D FULL E TAU(SCATTERING,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TPA2A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D HALF E TAU(SCATTERING,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TPA3A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D 1/3 E TAU(SCATTERING,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TQBCO'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM COLLISIONAL TORQUE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TQBTH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM THERMALIZATION TORQUE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TQICHMIN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ICH Torque TO MINORITY IONS [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TQIN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL INPUT TORQUE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TQJXB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM JXB TORQUE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TQRPL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM RPL JXB TORQUE [Nt-M/CM3 ]';
+i=i+1;transp_sig{i,1}= 'TSL1A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D FULL E TAU(SLOWING DOWN,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TSL2A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D HALF E TAU(SLOWING DOWN,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TSL3A_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D 1/3 E TAU(SLOWING DOWN,CO) [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TTNTX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'TX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='IMPURITY TEMPERATURE [EV ]';
+i=i+1;transp_sig{i,1}= 'UBPAR'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM PLL ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UBPOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POLOIDAL FIELD ENERGY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UBPRP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='BEAM PERP ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UBTOR'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOROIDAL FIELD ENERGY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UCURB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='UNSHIELDED BEAM CURRENT [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'UDEXB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='E CROSS B POWER [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UFASTPA'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION PLL ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UFASTPP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION PERP ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UJBCO'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='UNSHIELDED BEAM CUR (CO BEAMS) [AMPS/CM2 ]';
+i=i+1;transp_sig{i,1}= 'UPHI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='THERMAL PLASMA ROTATIONAL ENERGY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UPHIN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ROTATIONAL ENERGY INPUT [WATTS/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UTHRM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='THERMAL ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'UTOTL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL ENERGY DENSITY [JLES/CM3 ]';
+i=i+1;transp_sig{i,1}= 'V'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOLTAGE [VOLTS ]';
+i=i+1;transp_sig{i,1}= 'VPB_F1_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Vpll.B: full energy D beam [T*(cm/sec)]';
+i=i+1;transp_sig{i,1}= 'VPB_F2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Vpll.B: half energy D beam [T*(cm/sec)]';
+i=i+1;transp_sig{i,1}= 'VPB_F3_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Vpll.B: 1/3 energy D beam [T*(cm/sec)]';
+i=i+1;transp_sig{i,1}= 'VPOH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VOLTAGE for POH calculation [VOLTS ]';
+i=i+1;transp_sig{i,1}= 'WNMC_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Beam D No. of MC Ions [#ptcls ]';
+i=i+1;transp_sig{i,1}= 'ZEFFI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='INPUT ZEFF (UNCONSTRAINED) [ ]';
+i=i+1;transp_sig{i,1}= 'ZEFMD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MAGDIF ZEFF PROFILE [ ]';
+i=i+1;transp_sig{i,1}= 'XB'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='rho_tor "boundary"';
+i=i+1;transp_sig{i,1}= 'BPOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POLOIDAL FIELD [Tesla ]';
+i=i+1;transp_sig{i,1}= 'CHPHI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MOMENTUM DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CONDE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON HEAT DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CONDEF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='1 FLUID "EFFECTIVE" CHI [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CONDI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION HEAT DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CONDICWN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NCLASS ion class heat conduct [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CONDIWNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NCLASS ion heat conductivity [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'CURBRABD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RAD.CUR (ANOM DIFFUS) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'CURBRFSH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RAD.CUR (FISHBONES) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'CURBRORB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RADIAL CURRENT (ORBIT) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'CURBRRIP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FAST ION RAD.CUR (RIPPLE LOSS) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'DIFB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ANOMOLOUS FAST ION DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='EFF. D+ ION DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELEC PTCL DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='EFF. H+ ION DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION DIFFUSIVITY FROM TOTAL FLUX [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFIGLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 ION DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFWE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELEC PTCL DIFFUSIVITY (WARE) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'DIFFX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='EFF. IMP ION DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'ELONG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Flux surface elongation [ ]';
+i=i+1;transp_sig{i,1}= 'ETAE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D(LN(TE))/D(LN(NE)) [ ]';
+i=i+1;transp_sig{i,1}= 'ETAI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D(LN(TI))/D(LN("NI")) [ ]';
+i=i+1;transp_sig{i,1}= 'ETAIE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D(LN(TI))/D(LN(NE)) [ ]';
+i=i+1;transp_sig{i,1}= 'ETPARGLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 MOM (PAR) DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'ETPERGLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 MOM (PERP) DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'ETPHIGLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 MOM (TOR) DIFFUSIVITY [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'EXBGLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 EXB SHEAR RATE [/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKBOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC BOLTON [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKCH2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC CHANG-HINTON VSN 2 [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKCHH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC CHANG-HINTON ORIGINAL [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKCHZ'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC CHANG-HINTON Z-CORR [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKHZH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC HAZELTINE-HINTON [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FKJUL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='CHI(I) NC RUTHERFORD-JULICH [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'FRAT1GLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 LEADING MODE FREQUENCY [/SEC ]';
+i=i+1;transp_sig{i,1}= 'FRAT2GLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 SCND LEADING MODE FREQ [/SEC ]';
+i=i+1;transp_sig{i,1}= 'GAMMMM1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 GRTH RATE MODE=1 [1/SEC ]';
+i=i+1;transp_sig{i,1}= 'GAMMMM2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 GRTH RATE MODE=2 [1/SEC ]';
+i=i+1;transp_sig{i,1}= 'GFUN'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='G: PARA/DIAMAGNETISM [ ]';
+i=i+1;transp_sig{i,1}= 'GFUNC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='G: GRAD-SHAF EQUILIBRIUM CHECK [ ]';
+i=i+1;transp_sig{i,1}= 'GRAT1GLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 GROWTH RT OF LEADING MODE [/SEC ]';
+i=i+1;transp_sig{i,1}= 'GRAT2GLF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 GRTH RT SCND LEADING MODE [/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEMMM1'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 FREQUENCY MODE=1 [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'OMEMMM2'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 FREQUENCY MODE=2 [RAD/SEC ]';
+i=i+1;transp_sig{i,1}= 'PLCURPLL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POLOIDAL CUR (J PLL) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PLCURPRP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POLOIDAL CUR (J PERP) [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PLCURTOT'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL POLOIDAL CUR TO WALL [AMPS ]';
+i=i+1;transp_sig{i,1}= 'PLFLX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='POLOIDAL FLUX [Wb/rad ]';
+i=i+1;transp_sig{i,1}= 'PLFLX2PI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOTAL POLOIDAL FLUX [Webers ]';
+i=i+1;transp_sig{i,1}= 'Q'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Q PROFILE [ ]';
+i=i+1;transp_sig{i,1}= 'RLTCRGKF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='R/LTi: critical ITG main br. [ ]';
+i=i+1;transp_sig{i,1}= 'RLTCRGKZ'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='R/LTi: critical ITG Carbon br. [ ]';
+i=i+1;transp_sig{i,1}= 'RLTI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='R/LTi: actual ITG:R*Grad(Ti)/Ti [ ]';
+i=i+1;transp_sig{i,1}= 'RMJMP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FLUX SURFACE CTRS [CM ]';
+i=i+1;transp_sig{i,1}= 'RMNMP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MIDPLANE RADII [CM ]';
+i=i+1;transp_sig{i,1}= 'SREXBMMM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ExB Shear Rate (MMM95) [SEC**-1 ]';
+i=i+1;transp_sig{i,1}= 'SSHAF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='SHAFRANOV SHIFT [CM ]';
+i=i+1;transp_sig{i,1}= 'SURF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='FLUX SURFACE AREA [CM**2 ]';
+i=i+1;transp_sig{i,1}= 'TAPWE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON TAU(P) WARE CORRECTION [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TAUE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='PLASMA ENERGY CONFINEMENT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TAUPE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON PTCL CONFINEMNT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TAUPI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION PTCL CONFINEMENT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TEE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON ENERGY CONFINEMENT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'TEI'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION ENERGY CONFINEMENT [SECONDS ]';
+i=i+1;transp_sig{i,1}= 'THDIG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION DIFF (WEILAND) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THDKB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION DIFF (KB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THDRB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION DIFF (RB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THEIG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ELEC THER DIFF (WEILAND) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THEKB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ELEC THER DIFF (KB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THERB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ELEC THER DIFF (RB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THIIG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION THER DIFF (WEILAND) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THIKB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION THER DIFF (KB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THIRB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 ION THER DIFF (RB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THZIG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 IMP DIFF (WEILAND) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THZKB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 IMP DIFF (KB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'THZRB'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 IMP DIFF (RB) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'TRFLX'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOROIDAL FLUX [Webers ]';
+i=i+1;transp_sig{i,1}= 'TRIANG'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Flux surface triangularity [ ]';
+i=i+1;transp_sig{i,1}= 'TRIANGL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Flux surf. lower triangularity [ ]';
+i=i+1;transp_sig{i,1}= 'TRIANGU'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Flux surf. upper triangularity [ ]';
+i=i+1;transp_sig{i,1}= 'VCONEMMM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 MODEL ELEC. CONV. VEL. [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VCONIMMM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 MODEL ION CONV. VEL. [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VCONZMMM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 MODEL IMP. CONV. VEL. [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VELD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION VELOCITY (NET) D+ [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VELE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON RADIAL VELOCITY [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VELH'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ION VELOCITY (NET) H+ [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VELIM'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='IMPURITY RADIAL VELOCITY [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VELWE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='ELECTRON WARE VELOCITY [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VMO_PBAL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='Momentum v_rad from ptcl-bal [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKAPEGKF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='IFS-PPPL GYROFLUID MODEL CHI(E) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKAPIGKF'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='IFS-PPPL GYROFLUID MODEL CHI(I) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKEGLF23'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 MODEL CHI(E) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKEMMM95'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 MODEL CHI(E) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKIGLF23'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='GLF23 MODEL CHI(I) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKIMMM95'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MMM95 MODEL CHI(I) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'XKINC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NEOCLASSICAL CHI(I) [CM**2/SEC ]';
+i=i+1;transp_sig{i,1}= 'RMAJM'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='R values';
+i=i+1;transp_sig{i,1}= 'TRFMP'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='TOROIDAL FLUX [WEBERS ]';
+i=i+1;transp_sig{i,1}= 'VPOLD_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC D+ poloidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VPOLE_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC electron poloidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VPOLH_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC H+ poloidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VPOLX_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC impurity poloidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VTORD_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC D+ toroidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VTORE_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC electron toroidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VTORH_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC H+ toroidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'VTORX_NC'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='NC impurity toroidal velocity [CM/SEC ]';
+i=i+1;transp_sig{i,1}= 'RMJSYM'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='R values (both field sides)';
+i=i+1;transp_sig{i,1}= 'VP2_USE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='VP2 data as used [rad/sec ]';
+i=i+1;transp_sig{i,1}= 'MSElabel'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='MSE label';
+i=i+1;transp_sig{i,1}= 'BPHI_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='B_phi at (R,Z) of detector [TESLA ]';
+i=i+1;transp_sig{i,1}= 'BR_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='B_R at (R,Z) of detector [TESLA ]';
+i=i+1;transp_sig{i,1}= 'BZ_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='B_Z at (R,Z) of detector [TESLA ]';
+i=i+1;transp_sig{i,1}= 'ER_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='E_R at (R,Z) of detector [V/M ]';
+i=i+1;transp_sig{i,1}= 'EZ_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='E_Z at (R,Z) of detector [V/M ]';
+i=i+1;transp_sig{i,1}= 'GAM1_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MSE Signal (due to B only) [ ]';
+i=i+1;transp_sig{i,1}= 'GAM2_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='MSE Signal (due to B and E) [ ]';
+i=i+1;transp_sig{i,1}= 'VBA_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='beam energy/nucleon [eV/AMU ]';
+i=i+1;transp_sig{i,1}= 'X_MSE'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='flux surface x=sqrt(phi/phlim) [ ]';
+i=i+1;transp_sig{i,1}= 'MCINDX'; transp_sig{i,2}='Area-Base'; transp_sig{i,3}='Monte Carlo index for f(r,theta)';
+i=i+1;transp_sig{i,1}= 'BBNT2_DD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DD BEAM-BEAM NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BDENS2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D Beam ion density [N/CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BEPRP2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D Beam ion <Eperp> [eV ]';
+i=i+1;transp_sig{i,1}= 'BEPLL2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D Beam ion <Epll> [eV ]';
+i=i+1;transp_sig{i,1}= 'BMVOL'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='2d MC grid zone volumes [CM**3 ]';
+i=i+1;transp_sig{i,1}= 'BTNT2_DD'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='DD BEAM-TARGET NEUTRONS [N/CM3/SEC ]';
+i=i+1;transp_sig{i,1}= 'BVTOR2_D'; transp_sig{i,2}='Signal-Group'; transp_sig{i,3}='D Beam ion <Vtor> [cm/sec ]';
diff --git a/crpptbx/AUG/loadAUGdata.m b/crpptbx/AUG/loadAUGdata.m
index 9d03424f..8978a6eb 100644
--- a/crpptbx/AUG/loadAUGdata.m
+++ b/crpptbx/AUG/loadAUGdata.m
@@ -84,6 +84,7 @@ function [trace,error,varargout]=loadAUGdata(shot,data_type,varargin)
 % sxR : from SXR/A or B adding R of chords (from old stuff, not sure still OK)
 % sxb : 'SXB/J' chords
 % sxf : 'SXF/I' chords
+% transp_EXPNAME : data from TRA using experiment name = "EXPNAME"
 % ece : 
 % ece_rho : 
 % eced : 
@@ -188,6 +189,10 @@ if size(data_type_eff,1)==1
   if ~isempty(strmatch(lower(data_type_eff_noext),[{'ssx'}],'exact'))
     data_type_eff_noext='ssx';
   end
+  if ~isempty(strmatch(lower(data_type_eff_noext(1:min(7,length(data_type_eff_noext)))),[{'transp_'}],'exact'))
+    shotfile_exp = data_type_eff_noext(8:end)
+    data_type_eff_noext='transp'
+  end
   if ~isempty(strmatch(data_type_eff_noext,[{'ECE'}],'exact'))
     data_type_eff_noext='ece';
   end
@@ -283,7 +288,7 @@ AUGkeywrdall=[{'Ip'} {'b0'} {'zmag'} {'rmag'}  {'rgeo'} {'zgeo'} {'vol'} {'qrho'
 	      {'delta'} {'deltatop'} {'deltabot'} {'neint'} {'ne'} {'te'}  ...
 	      {'nerho'} {'neterho'} {'terho'} {'cxrs'} {'cxrs_rho'} {'equil'} {'equil_fpp'} {'equil_eqm'} ...
 	      {'equil_eqr'} {'equil_eqh'} {'sxr'} {'sxR'} {'sxb'} {'sxf'} {'ssx_g'} {'ssx_h'} {'ssx_i'} {'ssx_j'} {'ssx'} ...
-	      {'ece'} {'ece_rho'} {'eced'} {'eced_rho'} {'eced_rmd'} {'Halpha'} {'pgyro'} {'powers'} ...
+	      {'transp'} {'ece'} {'ece_rho'} {'eced'} {'eced_rho'} {'eced_rmd'} {'Halpha'} {'pgyro'} {'powers'} ...
 	      {'betan'}  {'betap'}]; % rm, not yet implemented: {'rcont'} {'zcont'}
 AUGsig.iip=strmatch('Ip',AUGkeywrdall,'exact');
 AUGsig.ib0=strmatch('b0',AUGkeywrdall,'exact');
@@ -326,6 +331,7 @@ AUGsig.issx_h=strmatch('ssx_h',AUGkeywrdall,'exact');
 AUGsig.issx_i=strmatch('ssx_i',AUGkeywrdall,'exact');
 AUGsig.issx_j=strmatch('ssx_j',AUGkeywrdall,'exact');
 AUGsig.issx=strmatch('ssx',AUGkeywrdall,'exact');
+AUGsig.itransp=strmatch('transp',AUGkeywrdall,'exact');
 AUGsig.iece=strmatch('ece',AUGkeywrdall,'exact');
 AUGsig.ieced=strmatch('eced',AUGkeywrdall,'exact');
 AUGsig.iece_rho=strmatch('ece_rho',AUGkeywrdall,'exact');
@@ -361,6 +367,7 @@ AUGkeywrdcase(AUGsig.issx_h)=AUGkeywrdall(AUGsig.issx_h);
 AUGkeywrdcase(AUGsig.issx_i)=AUGkeywrdall(AUGsig.issx_i);
 AUGkeywrdcase(AUGsig.issx_j)=AUGkeywrdall(AUGsig.issx_j);
 AUGkeywrdcase(AUGsig.issx)=AUGkeywrdall(AUGsig.issx);
+AUGkeywrdcase(AUGsig.itransp)={data_type_eff_noext};
 AUGkeywrdcase(AUGsig.iece)=AUGkeywrdall(AUGsig.iece);
 AUGkeywrdcase(AUGsig.ieced)=AUGkeywrdall(AUGsig.ieced);
 AUGkeywrdcase(AUGsig.iece_rho)=AUGkeywrdall(AUGsig.iece_rho);
@@ -410,6 +417,7 @@ AUGexplocation(:)={'AUGD'};
 AUGexplocation(AUGsig.ieced)={'ECED'};
 AUGexplocation(AUGsig.ieced_rho)={'ECED'};
 AUGexplocation(AUGsig.ieced_rmd)={'ECED'};
+AUGexplocation(AUGsig.itransp)={shotfile_exp};
 
 if shot==-9
   clear trace
@@ -1513,7 +1521,41 @@ switch AUGkeywrdcase{index}
       trace.freq_ech_units =[]';
      trace.name=[num2str(shot) '/' ppftype '/' 'P_OH, PNBI_TOT, PECR_TOT, PICR_TOT'];
     end
-    
+
+%&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&
+  case {'transp'} %  for TRANSP
+    %  LOAD TRA data into substructures
+    shotfile_exp_eff = AUGexplocation{index}
+    trace.t=[];
+    trace.x=[];
+    ppftype='TRA';
+    TRANSP_signals;
+    for i=1:size(transp_sig,1)
+      if strcmp(lower(transp_sig{i,2}),'signal') || strcmp(lower(transp_sig{i,2}),'signal-group')
+	try
+	  eval(['[trace.' transp_sig{i,1} ',e]=rdaAUG_eff(shot,ppftype,''' transp_sig{i,1} ''',shotfile_exp_eff);']);
+	catch
+	  eval(['trace.' transp_sig{i,1} '=[];']);
+	end
+      elseif strcmp(lower(transp_sig{i,2}),'area-base')
+	clear adata_area
+	try
+	  [adata_area]=sf2ab(ppftype,shot,transp_sig{i,1},'-exp',shotfile_exp_eff);
+	catch
+	  adata_area.value = cell(0);
+	end
+	eval(['trace.' transp_sig{i,1} '=adata_area;']);
+      elseif strcmp(lower(transp_sig{i,2}),'time-base')
+	clear adata_time
+	try
+	  [adata_time]=sf2tb(ppftype,shot,transp_sig{i,1},'-exp',shotfile_exp_eff);
+	catch
+	  adata_time.value = cell(0);
+	end
+	eval(['trace.' transp_sig{i,1} '=adata_time;']);
+      end
+    end
+
   otherwise
     disp('case not yet defined')
     
-- 
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