16 April, 2002

INTERNATIONAL GLOBAL H-MODE CONFINEMENT DATA BASE
Version DB3 Variables.

Recommended ASCII format for DB3  

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All the variables listed in alphabetical order :

AMIN 34 DELTAU 38 HITER92Y 133 PECRH 87 SH95 6 VTORV 143
AREA 41 DIVMAT 46 HITER96L 131 PECRHC 86 SPIN 140 WALMAT 45
AUXHEAT 9 DIVNAME 3 IAE2000N 154 PELLET 27 STANDARD 145 WDIA 104
BEILI2 59 DNELDT 67 IAE2000X 155 PFLOSS 82 TAUC92 128 WEKIN 107
BEIMHD 60 DWDIA 94 IAEA92 149 PGASA 21 TAUC93 129 WFANI 112
BEPDIA 63 DWDIAPAR 95 ICANTEN 90 PGASZ 22 TAUDIA 118 WFANIIC 117
BEPMHD 61 DWHC 97 ICFORM 116 PHASE 10 TAUMHD 119 WFFORM 111
BETMHD 62 DWMHD 96 ICFREQ 88 PICRH 92 TAUTH 127 WFICFORM 115
BGASA 23 ECHFREQ 83 ICSCHEME 89 PICRHC 91 TAUTH1 120 WFICRH 113
BGASA2 25 ECHLOC 85 IEML 53 PINJ 76 TAUTH2 121 WFICRHP 114
BGASZ 24 ECHMODE 84 IGRADB 51 PINJ2 78 TAUTOT 126 WFPAR 110
BGASZ2 26 ELMDUR 14 INDENT 40 PL 124 TE0 99 WFPER 109
BMHDMDIA 64 ELMFREQ 12 IP 55 PLTH 125 TE0TSC 100 WIKIN 108
BSOURCE 77 ELMINT 15 ISEQ 19 PNBI 81 TEV 98 WKIN 106
BSOURCE2 79 ELMMAX 13 KAPPA 35 POHM 74 TI0 102 WMHD 105
BT 52 ELMTYPE 11 KAREA 36 PRAD 73 TICX0 103 WTH 123
COCTR 80 ENBI 75 LCUPDATE 4 PREMAG 54 TIME 7 WTOT 122
CONFIG 31 EVAP 48 LHTIME 17 Q95 57 TIME_ID 8 XGASA 30
DALFDV 50 FUEL RATE 28 LIMMAT 47 RGEO 32 TIV 101 XGASZ 29
DALFMP 49 H89 130 MEFF 20 RMAG 33 TOK 1 XPLIM 44
DATE 5 H93 132 NE0 69 SELDB1 146 TOK_ID 2 ZEFF 71
DB2P5 150 HEPS97 134 NE0TSC 70 SELDB2 147 TORQ 141 ZEFFNEO 72
DB2P8 151 HIPB98Y 135 NEL 65 SELDB2X 148 TPI 18  
DB3IS 152 HIPB98Y1 136 NELFORM 66 SELDB3 156 VOL 42  
DB3V5 153 HIPB98Y2 137 NEV 68 SELDB3X 157 VSURF 56  
DELTA 37 HIPB98Y3 138 OLTIME 16 SEPLIM 43 VTOR0 142    
DELTAL 39 HIPB98Y4 139 PALPHA 93 SHOT 58 VTORIMP 144  

Introduction

The time averaging for the majority of data is 2 ms for ASDEX, 50 - 100 ms for ASDEX Upgrade, 20-340 ms for Alcator C-mod ( 0.3 - 5 TAUTH), 1 ms for COMPASS-D, 5 ms for DIII-D, 100 ms for JET, 2.5 ms for JFT-2M, 25 ms for JT-60U, 3.75 ms for PBX-M, 5 ms for PDX, ??? ms for TCV, ??? ms for TEXTOR, ??? ms for TFTR, ??? ms for TdeV, 1 ms for START, 1 ms for T-10, 0.5 ms for TUMAN-3M.

MHD analysis from Alcator C-mod, COMPASS-D, DIII-D, JET (shots from 1994 onwards) and START use a full equilibrium fit (EFIT). PDX and TUMAN-3M use a full equilibrium MHD fit for representative discharges. Data from ASDEX, JET (shots before 1994), JFT-2M, PBX-M and TFTR are obtained with a current filament approach except for some of the JFT-2M variables (RMAG, Q95, bI + 0.5 li, bp, BT, W) which are calculated with a full equilibrium fit. ASDEX Upgrade use a full equilibrium code fit based on function parameterisation. JT-60U (ELMy H-mode data) use a full equilibrium code fit based on function parameterisation putting q(0) = 1. T-10 data are obtained with ASTRA equilibrium solver using 3-moment approach (G. Pereverzev, P.N. Yushmanov, ASTRA Automated System for Transport Analysis in a Tokamak, IPP 5/98, February 2002). TCV, TEXTOR, TdeV ?????

In the list of variables the abbreviation Na is used if a variable is not available. The normal level of accuracy of a variable is given as a percentage in brackets (often without further explanation). Some variables are combinations of other variables; in these cases, the uncertainty in the resultant variable, which is the appropriate combination of uncertainties in the basis variables, is denoted by Co.


General

1. TOK: This variable designates which tokamak has supplied the data.
Possible values are:

TOK Address on the WEB TOK_ID
ASDEX ASDEX, IPP-Garching Germany 1
AUG ASDEX Upgrade, IPP-Garching Germany 2
CMOD Alcator C-mod, MIT USA 3
COMPASS COMPASS-D, Culham UK 4
D3D DIII-D, GA USA 5
JET JET, EURATOM UK 6
JFT2M JFT-2M, JAERI Japan 7
JT60U JT-60U, JAERI Japan 8
PBXM PBX-M, PPPL USA 9
PDX PDX, PPPL USA 10
TCV TCV, EURATOM Switzerland 11
TEXTOR TEXTOR, EURATOM Germany 12
TFTR TFTR, PPPL USA 13
TDEV TdeV, Montreal, Canada 14
START START, Culham, UK 15
T10 T10, Kurchachov Institute, Russia 16
TUMAN3M TUMAN-3M, Ioffe Institute, Russia 17

2. TOK_ID: This integer variable designates which tokamak has supplied the data.
Possible values are listed in table for TOK.

3. DIVNAME: Describes each device's divertor configuration

TOK Possible values
ASDEX DV-IPRE
DV-IPOST

DV-II-O
DV-II-C
          1  <=  SHOT  <= 13583
13584  <=  SHOT  <= 20282
20283  <=  SHOT  <= 25776
25777  <=  SHOT
AUG NONAME
CMOD NONAME
COMPASS DIV1
D3D OPEN
ADP
RDP
56348  <=  SHOT  <= 69648
70678  <=  SHOT  <= 90768
98889  <=  SHOT  <= 98893
JET MARK0
MARKI
MARKIIA
MARKIIAP

MARKGB
SHOT  < 27968
28792  <  SHOT  < 35779
35953  <  SHOT  < 38912
38983  < SHOT  < 45081
45202  <  SHOT
JFT2M NONAME
JT60U NONAME
PBXM NONAME
PDX NONAME
TCV OPEN
TEXTOR NONAME
TFTR NONAME
TDEV NONAME
START OPEN
T10 NONAME
TUMAN3M NONAME

4. LCUPDATE: The date of the most recent update for any variable listed in the database.
The format is YYYYMMDD (Year-Month-Day).

5. DATE: The date the shot was taken. The format is YYYYMMDD (Year-Month-Day).

6. SHOT: The shot from which the data are taken.

7. TIME: Time during the shot at which the data are taken in seconds.

8. TIME_ID: Integer equivalent of TIME, defined as INT[1000 ROUND{TIME, 0.001}]
where INT is the integer part and ROUND rounds TIME to the 3rd decimal place. 
Except for TUMAN-3M where INT[100000 ROUND{TIME, 0.00001}] is used. 

9. AUXHEAT: Type of auxiliary heating.
Possible values are:

NONE No Auxiliary heating
NB Neutral Beam Injection
IC Ion Cyclotron Resonance Heating
EC Electron Cyclotron Resonance Heating
ECOA Electron Cyclotron Resonance Heating ( Off-axis )
ECIC Combined ECRH + ICRH
NBIC Combined NBI + ICRH

10. PHASE: The phase of the discharge at TIME.
Possible values are:

OHM Ohmic
L L-mode
RI Radiative I-mode
LHLHL H-mode with frequent LH transitions
H ELM-free H-mode
HSELM H-mode with small ELMs
HSELMH H-mode with high frequency small  ELMs
HGELM H-mode with large ELMs
HGELMH H-mode with high frequency large ELMs

11. ELMTYPE: Type of ELMs.
Possible values are:

NONE No ELMs
TYPE-I Type I ELMs
TYPE-II Type II ELMs ( no TYPE-II in Database) 
TYPE-III Type III ELMs
TYPE-RF ICRH ELMs on JET
UNKNOWN
or
TYPE-?
Type has not been determined

12. ELMFREQ: The ELM frequency in Hertz.
JT60U: Average over 400-500 msec.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na), D3D (Na), JET (regular ELMS: 1%, irregular ELMs: 50%), JFT2M (Na), JT60U (Average of 400-500 msec), PBXM (Na), PDX (Na), TCV (1%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

13. ELMMAX: The average ELM amplitude of the H-alpha signal (minus base level) in arbitrary units.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

14. ELMDUR: The average ELM duration of the H-alpha signal in seconds.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

15. ELMINT: The average ELM integral of the H-alpha signal (minus base level)  in arbitrary units.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

16. OLTIME: The time of the Ohmic to L-mode transition (start of auxiliary heating) in seconds.

17. LHTIME: The time of the L to H transition in seconds.

18. TPI: Time point indicator (ASDEX only).
Possible values are:

0 Indicator  not  used
1-3 Ohmic points
4 L-mode
5-7 H-mode points up to the time at which DWDIA = 0
8-9 Extra H-mode points

19. ISEQ: Parameter scan identifier

Possible options for ASDEX are:

Toroidal magnetic field scans BT1, BT2P4, BT3, BT4, BT5, BT6, BT7
High beta investigations, Ti profile measurements HBE1, HBE2, HBE3
QCYL scan QC1P3
Search for long ELM-free periods EF11
Density variation NE1
Spectroscopic investigations SP11
Power scans (PNBI) P1, P2, QC1P3, BT2P4
Comparison shots for helium program G1
Search for high confinement times HT1
No scan NONE

Possible options for AUG are:

??? ARS
??? DL
??? LH 
??? NCTM 
??? JET_AUG
??? MW20
??? NI_1_2
??? RHO*
??? CDH
??? H-L
??? DRIFT
??? Z-RAM
??? B-LIM
??? DIII-D
??? RAD:N2
??? CONF.
??? ELM_DOC
??? BETALIM
??? ICRH_NE
??? WPNI
No scan NONE

Possible options for CMOD are : 

No scan NONE

Possible options for COMPASS are : 

No scan NONE

Possible options for D3D are:

Elongation scans KAPPA1, KAPPA2, KAPPA3
L-mode rho* scans LRHO1, LRHO2, LRHO3
H-mode rho* scans HRHO1, HRHO2, HRHO3
Nu* scans LNU1, HNU1
Beta scans LBETA1, HBETA1
Rho* scaling from DIII-D/JET comparison JET1
High density, good confinement with pellets HINE
Reference shot without gas puff HI_GP_REF
High density, good confinement with gas puff HI_GP
No scan NONE

Possible options for JET are:

Tokamak identity scans DIIID, D3D1, AUG, CMOD, CMOD1
L-mode rho* scans LRHO1, LRHO2, LRHO3
H-mode rho* scans RHO1, RHO2, RHO3, RHO4, LOW-RHO
Nu* scans NU1
Beta scans BETA1, HIGH-BETA
Configuration scans H/SFE/VLT, H/SFE/LT, H/SFE/HT, H/SFE/VHT, H/SFE/VH, H/SFE/??
H/LFE/HT
H/HFE/LT, H/HFE/HT, H/HFE/??
HC/SFE/LT
HK/LT/99, HK/HT/99
LK/LT/99
V/SFE/LTS, V/SFE/LT, V/SFE/HT, V/SFE/VHT
V/HFE/LT, V/HFE/HT
V/LFE/LT
C/SFE/LT
SEPTUM
No scan NONE

Possible options for JFT2M are:

Gas scans:
Intense gas puff for comparison with Hydrogen  pellet H-mode
Intense gas puff for comparison with Deuterium  pellet H-mode
Intense gas puff in Hydrogen
Intense gas puff in Deuterium

G1
G2
G3IP2
G4IP3
Current scans:
BT = 1.25T
Hydrogen plasma
Deuterium plasma
Hydrogen plasma
Deuterium plasma

IP1
G3IP2
IP3, G4IP3
P3IP4NE1
P4IP5NE2
Power scans (PNBI):
CO or CTR with IP = 0.25MA
CO + CTR with IP = 0.24MA
Hydrogen
Deuterium

P1
P2
P3IP4NE1
P4IP5NE2
Density scans (NEL):
Hydrogen
Deuterium

P3IP4NE1
P4IP5NE2
Toroidal field scans:
IP = 0.16MA
IP = 0.21MA

BT1
BT2
Pellet scans:
Hydrogen pellet into Hydrogen
Deuterium pellet into Deuterium

PE1
PE2
ENBI scans:
BSOURCE = 603010
BSOURCE = 801010

EB1
EB2
AMIN scan with IP = 0.22MA  ( same Q95) AM1
Scan of 801010 ( CO or CTR) and 603010 ( CO or CTR) BS1
IEML and PNBI scan looking for steady state H-mode region IE1
XPLIM scan with IP = 0.24MA XP1
No scan NONE

Possible options for JT60U are : 

No scan NONE

Possible options for PBXM are : 

No scan NONE

Possible options for PDX are : 

No scan NONE

Possible options for TCV are : 

No scan NONE

Possible options for TEXTOR are:

Search for high confinement times HT1
No scan NONE

Possible options for TFTR are : 

No scan NONE

Possible options for TDEV are : 

No scan NONE

Possible options for START are : 

No scan NONE

Possible options for T10 are : 

No scan NONE

Possible options for TUMAN3M are : 

No scan NONE


Plasma composition

20. MEFF: Effective atomic mass in AMU.
Based on concentration measurements in JET, START and TFTR or calculated as
= 0.5 (PGASA + 0.5 (BGASA + BGASA2)) if PINJ > 0 and PINJ2 > 0.
= 0.5 (PGASA + BGASA) if only PINJ > 0.
= PGASA otherwise.
JET: A few Ohmic observations PNBI <= 3 kW. For these observations MEFF = PGASA.
Normal level of accuracy is
ASDEX (10%), AUG (20%), CMOD (3%), COMPASS (10%),  D3D (pure gas: 1% , mixed gas: 20% ), JET (20%), JFT2M (???%), JT60U (5%), PBXM (25%), PDX (25%), TCV (0%), TEXTOR (???%), TFTR (0.2), TDEV (???%),  START (50%), T10 (10%), TUMAN3M (5%).

21. PGASA: Mass number of the plasma working gas (real value).
Possible values are:

1 Hydrogen
2 Deuterium
2.5 Deuterium and Tritium
3 3He or Tritium
4 4He
14 Nitrogen

22. PGASZ: Charge number of the plasma working gas (integer value).
Possible values are:

1 Hydrogen, Deuterium or Tritium
2 Helium
7 Nitrogen

23. BGASA: Mass number of the neutral beam gas (real value).
Possible values are:

0 When PINJ = 0
1 Hydrogen
2 Deuterium
3 3He or Tritium
4 4He

24. BGASZ: Charge number of the neutral beam gas (integer value).
Possible values are:

0 When PINJ = 0
1 Hydrogen, Deuterium or Tritium
2 Helium

25. BGASA2: Mass number of the second neutral beam gas (real value).
Possible values are:

0 When PINJ2 = 0
1 Hydrogen
2 Deuterium
3 3He or Tritium

26. BGASZ2: Charge number of the second neutral beam gas (integer value).
Possible values are:

0 When PINJ2 = 0
1 Hydrogen, Deuterium or Tritium
2 Helium

27. PELLET: Pellet material if a pellet(s) has been injected.
Possible values are:

NONE No pellets
H Hydrogen pellet(s)
D Deuterium pellet(s)
GP_H Strong Hydrogen gas fuelling
GP_D Strong Deuterium gas fuelling
GAS-FUEL Strong gas fuelling (JET)

28. FUELRATE: Fuel rate in electrons per second of extra gas.
Normal level of accuracy is
ASDEX (Na), AUG (20%), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

29. XGASZ: Atomic Charge of extra fuelled gas.
Possible values are:

0 No extra fuelled gas
1 Hydrogen
2 Helium
7 Nitrogen
10 Neon
18 Argon
36 Krypton

30. XGASA: Atomic Mass of extra fuelled gas.
Possible values are:

0 No extra fuelled gas
1 Hydrogen
2 Deuterium
4 Helium
14 Nitrogen
20.18 Neon
39.95 Argon
83.8 Krypton


Geometry

31. CONFIG: The plasma configuration.
Possible values are:

SN Single null
SN(L)

Single null with the x-point at the bottom of the machine
SN(U) Single null with the x-point at the top of  the machine
DN Double null
DND Double null divertor
IW Inner wall.
LIM Outboard limiter
BOT Limited on bottom of vessel
TOP Limited on top of vessel
MAR Marginally diverted/limited

Tokamak details:

TOK SN SN(L) SN(U) DN DND IW LIM BOT TOP MAR
ASDEX                
AUG                  
CMOD              
COMPASS                  
D3D        
JET            
JFT2M                
JT60U                  
PBXM                  
PDX                  
START                  
T10                  
TCV                
TDEV                  
TEXTOR                  
TFTR                  
TUMAN3M                  

ASDEX: DN if vertical shift DZ is less than 5 mm, otherwise SN.
D3D: DN if two nulls and the separatrix flux surface are inside the divertor tiles and on the same flux surface within 0.25 cm.
JFT2M: DN if two nulls are inside the limiter.

32. RGEO: The plasma geometrical major radius in meters, from an MHD equilibrium fit, defined as the average of the minimum and the maximum radial extent of the plasma.
Normal level of accuracy is
ASDEX (1%), AUG (0.5%), CMOD (0.6%), COMPASS (1cm),  D3D (0.6%), JET (1%), JFT2M (0.75%), JT60U (0.5%), PBXM (0.65%), PDX (0.75%), TCV (1%), TEXTOR (0.5%), TFTR (1cm), TDEV (???%), START (2cm), T10 (1%), TUMAN3M (2%).

33. RMAG: The major radius of the magnetic axis in meters from an MHD equilibrium fit.
ASDEX: Formula based on a number of equilibriums.
Normal level of accuracy is
ASDEX (1%), AUG (1%), CMOD (1%), COMPASS (Na),  D3D (1%), JET (2%), JFT2M (2%), JT60U (0.5%), PBXM (1%), PDX (4%), TCV (1%), TEXTOR (2%), TFTR (4cm), TDEV (???%), START (Na), T10 (1%), TUMAN3M (Na).

34. AMIN: The horizontal plasma minor radius in meters from an MHD equilibrium fit.
ASDEX: Formula based on a number of equilibriums.
Normal level of accuracy is
ASDEX (1.5%), AUG (1%), CMOD (2%), COMPASS (1cm),  D3D (0.5%), JET (3%), JFT2M (3%), JT60U (1%), PBXM (3%), PDX (3%), TCV (2%), TEXTOR (3%), TFTR (1cm), TDEV (???%), START (2cm), T10 (3%), TUMAN3M (3%).

35. KAPPA: The plasma elongation determined from an MHD equilibrium fit.
ASDEX: Formula based on a number of equilibriums.
PDX: k = 1 for all records.
Normal level of accuracy is
ASDEX (2%), AUG (1%), CMOD (1%), COMPASS (10%),  D3D (1%), JET (5%), JFT2M (10%), JT60U (2%), PBXM (10%), PDX (10%), TCV (2%), TEXTOR (4%), TFTR (0.04), TDEV (???%), START (10%), T10 (5%), TUMAN3M (5%).

36. KAREA: New plasma elongation definition (= VOL / (2p RGEO) / ( p AMIN2) )
Normal level of accuracy is 
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

37. DELTA: The triangularity of the plasma boundary from an MHD equilibrium fit.
Normal level of accuracy is
ASDEX (3%), AUG (10%), CMOD (3%), COMPASS (10%),  D3D (10%), JET (10%), JFT2M (10%), JT60U (5%), PBXM (25%), PDX (Na), TCV (3%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (10%), T10 (Na),  TUMAN3M (Na).

38. DELTAU: Upper triangularity of the plasma boundary from an MHD equilibrium fit.
Normal level of accuracy is
ASDEX (Na), AUG (10%), CMOD (2%), COMPASS (10%),  D3D (10%), JET (10%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (3%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (10%), T10 (Na), TUMAN3M (Na).

39. DELTAL: Lower triangularity of the plasma boundary from an MHD equilibrium fit.
Normal level of accuracy is
ASDEX (Na), AUG (10%), CMOD (1%), COMPASS (10%),  D3D (10%), JET (10%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (3%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (10%), T10 (Na), TUMAN3M (Na).

40. INDENT: Indentation of the plasma determined from an MHD equilibrium fit.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (Na), JFT2M (Na), JT60U (Na), PBXM ( 15%), PDX (Na), TCV (Na), TDEV (???%), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

41. AREA: Area of plasma cross section in m2 determined from an MHD equilibrium fit. 
ASDEX: Formula based on a number of equilibriums.
Normal level of accuracy is
ASDEX (2%), AUG (3%), CMOD (3%), COMPASS (Na),  D3D (3%), JET (6%), JFT2M (5%), JT60U (5%), 
PBXM (10%), PDX (5%), TCV (1%), TEXTOR (5%), TFTR (5%), TDEV (???%), START (10%), T10 (6%), TUMAN3M (6%).

42. VOL: The plasmas volume in m3 determined from an MHD equilibrium fit.
ASDEX: Formula based on a number of equilibriums.
Normal level of accuracy is
ASDEX (3%), AUG (3%), CMOD (3%), COMPASS (10%),  D3D (3%), JET (6%), JFT2M (5%), JT60U (2%), PBXM (10%), PDX (5%), TCV (1%), TEXTOR (5%), TFTR (6%), TDEV (???%), START (10%), T10 (7%), TUMAN3M (8%).

43. SEPLIM: The minimum distance between the separatrix flux surface and either the vessel wall or limiters in meters from an MHD equilibrium fit.
ASDEX: Formula based on a number of equilibriums.
Normal level of accuracy is
ASDEX (1cm), AUG (Na), CMOD (0.5cm), COMPASS (Na),  D3D (0.5cm), JET (1cm), JFT2M (1cm), JT60U (1cm), PBXM (0.5cm), PDX (1cm), TCV (2%), TEXTOR (0.5cm), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

44. XPLIM: The minimum distance between the X-point and either the vessel walls or limiters in meters from an MHD equilibrium fit. The value is positive if X-point is inside either the vessel wall or limiters.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (3cm), JET (5cm), JFT2M (3cm), JT60U (2cm), PBXM (5cm), PDX (5cm), TCV (2%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).


Machine condition

45. WALMAT: The material of the vessel wall.
Possible values are:

C Carbon
SS for Stainless Steel
IN for Inconel
IN/C for Inconel with Carbon
CSS for (partly) Carbon on Stainless Steel.
AL for Aluminum

46. DIVMAT: The material of the divertor tiles.
Possible values are:

SS for Stainless Steel
C
CC
for Carbon
TI1
TI2
for Titanium,
BE for Beryllium
C/BE for Carbon at the top and Beryllium at the bottom
W for Wolfram
MO for Molybdenum
IN for Inconel
NONE for no Divertor

47. LIMMAT: The material of the limiters.
Possible values are:

C for Carbon
BE for Beryllium
MO for Molybdenum
NONE for no Limiter

48. EVAP: The evaporated material used to cover the inside of the vessel.
Possible values are:

BOR
BO
for Boron
BOROA for Boron (B2H6 + CH4 + H2)
BOROB for Boron (B2H6 + H2)
BOROC for Boron
BOROX for Boron
B2D6 for Boron
CARB for Carbon
CARBH for Carbon (CH4 + D2)
CARBORANE for Orto-Carborane (C2B10H12) into He Glow
DECABORA ???
TI for Titanium
BE for Beryllium
SILICON for Silicon
SID4 for Silicon
NONE for no evaporation

49. DALFMP: Da emission on the midplane.
Normal level of accuracy is 
ASDEX (Na), AUG (20%), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (5%), PDX (5%), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

50. DALFDV: Da emission in the divertor.
Normal level of accuracy is 
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (5%), PDX (5%), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).


Magnetics

51. IGRADB: Indicates, when CONFIG = SN, whether the ion grad B drift is towards ( = 1)
or pointing away from ( = -1) the X-point.

52. BT: The vacuum Toroidal magnetic field in Tesla at RGEO determined from the TF coil current.
AUG: Normally negative BT values.
CMOD: Normally negative BT values.
JET: Negative BT values indicate operation with reversed Toroidal field.
Normal level of accuracy is 
ASDEX (1%), AUG (1%), CMOD (1%), COMPASS (2%),  D3D (1%), JET (1%), JFT2M (1%), JT60U (1%), PBXM (1%), PDX (1%), TCV (1%), TEXTOR (1%), TFTR (2%), TDEV (???%), START (6%), T10 (1%), TUMAN3M (3%).

53. IEML: Ergodic magnetic field coil current in Amperes.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (Na), JFT2M ( 1%), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

54. PREMAG: Indicates if startup was done with ( = YES) or without ( = NO) pre-magnetization current.
JET: If PREMAG = NO for pre 94 shots then WMHD is missing.

55. IP: The plasma current in Amperes determined from an external Rogowski loop with vessel current subtraction. 
CMOD: Normally negative IP values.
JET: Normally negative IP values. Positive IP values indicate operation with reversed current.
TDEV: Normally negative IP values.
Normal level of accuracy is
ASDEX (1%), AUG (1%), CMOD (2%), COMPASS (1%),  D3D (1%), JET (1%), JFT2M (1%), JT60U (0.5%), PBXM (1%), PDX (1%), TCV (1%), TEXTOR (1%), TFTR (2%), TDEV (???%), START (2%), T10 (1%), TUMAN3M (3%).

56. VSURF: The loop voltage at the plasma boundary in volts.
Normal level of accuracy is
ASDEX (5%), AUG (10%), CMOD (5%), COMPASS (10%),  D3D (Na), JET (5%), JFT2M (5%), JT60U (20%), PBXM (50%), PDX (10%), TCV (3%), TEXTOR (5%), TFTR (5%+0.05V), TDEV (???%), START (10%), T10 (20%), TUMAN3M (5%).

57. Q95: The plasma safety factor from an MHD equilibrium fit evaluated at the flux surface
that encloses 95% of the total poloidal flux.
ASDEX: Q95 = qcyl (1 + (AMIN/RGEO)2 (1 + 0.5 BEILI22))
with qcyl = 5 106 (BT/IP) (AMIN2/RGEO) (1 + KAPPA2)/2.
TFTR: Q at boundary defined by limiter.
Normal level of accuracy is
ASDEX (10%), AUG (5%), CMOD (3%), COMPASS (10%),  D3D (3%), JET (10%), JFT2M (10%), JT60U (5%), PBXM (10%), PDX (10%), TCV (3%), TEXTOR (10%), TFTR (6%), TDEV (???%), START (10%), T10 (10%), TUMAN3M (Na).

58. SH95: The magnetic shear at the flux surface that encloses 95% of the total poloidal flux.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (50%), JET (50%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

59. BEILI2: This quantity is determined from MHD or probe measurements (ASDEX), and represents bI + 0.5 li,
where bI is the Shafranov beta and li the internal inductance.
Normal level of accuracy is
ASDEX (10%), AUG (3%), CMOD (3%), COMPASS (Na),  D3D (3%), JET (5%), JFT2M (10%), JT60U (5%), PBXM (10%), PDX (10%), TCV (3%), TEXTOR (20%), TFTR (4%), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

60. BEIMHD: Beta Shafranov from MHD.
ASDEX: BEIMHD equals BEILI2 minus an estimate of li/2 obtained during the Ohmic phase assuming a resistive equilibrium.
TFTR: BEIMHD equals (2BEPMHD + BEPDIA)/3. 
Normal level of accuracy is
ASDEX (15%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (0.05/bp), JET (12%), JFT2M (15%), JT60U (Na), PBXM (15%), PDX (15%), TCV (10%), TEXTOR (15%), TFTR (4%BEILI2 + 0.1), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

61. BEPMHD: Poloidal beta computed from the MHD equilibrium fit.
ASDEX: BEPMHD equals BEIMHD.
TFTR: BEPMHD equals BEILI2 - li/2 with li/2 from time evolution model.
Normal level of accuracy is
ASDEX (15%), AUG (10%), CMOD (0.05bp), COMPASS (Na),  D3D (0.05bp), JET (Na), JFT2M (15%), JT60U (7%),  PBXM (20%), PDX (20%), TCV (10%), TEXTOR (15%), TFTR (4%BEILI2 + 0.1), TDEV (Na), START (Na), T10 (10%),  TUMAN3M (Na).

62. BETMHD: Toroidal beta computed from the MHD equilibrium fit.
TFTR: Computed from BEPMHD.
Normal level of accuracy is
ASDEX (18%), AUG (15%), CMOD (0.05/bp), COMPASS (Na),  D3D (0.05/bp), JET (12%), JFT2M (15%), JT60U (7%),  PBXM (20%), PDX (20%), TCV (10%), TEXTOR (15%), TFTR (4% + fractional error BEIMHD), TDEV (???%), START (15%), T10 (10%), TUMAN3M (Na).

63. BEPDIA: Poloidal diamagnetic beta.
ASDEX: Corrected poloidal diamagnetic beta using an average of the 3 Ohmic points in the database.
Normal level of accuracy is
ASDEX (15%), AUG (10%), CMOD (Na), COMPASS (0.1),  D3D (Na), JET (20%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (4% + 100kJ/WDIA), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

64. BMHDMDIA: Offset during the Ohmic phase between MHD and diamagnetic.
ASDEX: Between diamagnetic beta poloidal and MHD beta poloidal ( 5%).
JFT2M: Between diamagnetic energy and MHD energy in Joule ( 10-20%).
ASDEX (5%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (Na), JFT2M (10-20%), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).


Densities

65. NEL: Central line average electron density in m-3 from interferometer or LIDAR (JET).
JET: NEL has been approximated if no measurement is available by
Ohmic: NEL ~ exp{2.931 + 0.873 ln(NEV) + 0.064 ln(NE0)}
H-mode: NEL ~ exp{3.745 + 0.825 ln(NEV) + 0.092 ln(NE0)}
The variable NELFORM indicates if NEL is measured or approximated.
Normal level of accuracy is
ASDEX (3%), AUG (3%), CMOD (5%), COMPASS (5%),  D3D (21018 m-3), JET (8%), JFT2M (2%), JT60U (10%),  PBXM (5%), PDX (5%), TCV (5%), TEXTOR (2%), TFTR (5%), TDEV (???%), START (5%), T10 (3%), TUMAN3M (10%).

66. NELFORM: Indicates if NEL is not a direct measurement.
= 1 if NEL has been approximated by formula for JET,
= 0 otherwise.

67. DNELDT: The time rate of change of NEL in m-3/s.
Normal level of accuracy is
ASDEX (2%), AUG (3%), CMOD (5%), COMPASS (Na),  D3D (21018 m-3/s), JET (8%), JFT2M (2%), JT60U (10%),  PBXM (5%), PDX (5%), TCV (5%), TEXTOR (5%), TFTR (5%), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

68. NEV: The volume averaged electron density in m-3.
ASDEX: Determined from 4 HCN interferometer channels fitting n(x) = n(1) + (n(0) - n(1)) (1 - xa)b,
0 <= x <= 1. For all volume integrations (NEV, TEV, WEKIN), a circular plasma was assumed.
D3D: Determined by a spline density profile fit to the CO2 and Thomson scattering density data.
JET: Determined from weighted summation over 6 interferometer channels.
JFT2M: Determined from an analytic fit with fixed profile shape to 2 interferometer channels.
Normal level of accuracy is
ASDEX (5%), AUG (10%), CMOD (7%), COMPASS (Na),  D3D (10%), JET (8%), JFT2M (2%), JT60U (10%), PBXM (5%), PDX (5%), TCV (5%), TEXTOR (10%), TFTR (10%), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

69. NE0: The central electron density at the magnetic axis in m-3 determined in same manner as NEV.
Normal level of accuracy is
ASDEX (10%), AUG (20%), CMOD (10%), COMPASS (Na),  D3D (15%), JET (10%), JFT2M (Na), JT60U (20%), PBXM (Na), PDX (Na), TCV (10%), TEXTOR (10%), TFTR (10%), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

70. NE0TSC. The electron density in m-3 determined from Thomson scattering.
ASDEX: Average of the 3 YAG laser channels closest to the equatorial plane.
D3D: Thomson scattering point that is closest to the magnetic axis (less than 10 cm).
Normal level of accuracy is
ASDEX (5%), AUG (30%), CMOD (Na), COMPASS (Na),  D3D (10%), JET (Na), JFT2M (Na), JT60U (10%), PBXM (Na), PDX (Na), TCV (10%), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).


Impurities

71. ZEFF: Line average plasma effective charge determined from visible Bremsstrahlung.
Normal level of accuracy is
ASDEX (10%), AUG (Na), CMOD (20%), COMPASS (Na),  D3D (20%), JET (30%), JFT2M (Na), JT60U (15%), PBXM (Na), PDX (Na), TCV (20%), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (30%), TUMAN3M (Na).

72. ZEFFNEO: Plasma effective charge as determined by neo-classical resistivity.
ASDEX: Determined such that the current profile calculated from Zeff-neo, Te (r) and Uloop is consistent
with the measured total Ip.
JET: Determined using volume averaged quantities.
Normal level of accuracy is
ASDEX (15%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (25%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

73. PRAD: Total radiated power in watts as measured by Bolometer.
Normal level of accuracy is
ASDEX (20%), AUG (20%), CMOD (20%), COMPASS (Na),  D3D (15%), JET (10-15%), JFT2M (10-20%), JT60U (20%), PBXM (25%), PDX (Na), TCV (Na), TEXTOR (15%), TFTR (Na), TDEV (???%)START (???%), T10 (25%), TUMAN3M (Na).


Input powers

74. POHM: Total Ohmic power in watts.
ASDEX: Determined from max{0, VSURF IP}.
AUG: Calculated as VSURF IP, where VSURF is corrected for flux variations between the loop and the plasma surface.
CMOD: Calculated as Vres IP, where Vres is calculated from VSURF corrected for inductive effects.
COMPASS: Calculated as VSURF IP.
D3D: Calculated using CB10 Ip2 RGEO2 / (WT ne), where B10 is the central visible Bremsstrahlung signal.
When ne is determined from the radial (vertical) CO2 chord, C is equal to 1.0310-19(9.92 10-20).
JET: Corrected for inductance effects.
JFT2M: Calculated as VSURF IP.
JT60U: Calculated as VSURF IP for SHOT < 33635.
Calculated for SHOT >= 33635 on the basis of Te profile with the assumption of uniform ZEFF and toroidal electric field. Neo-classical resistivity was applied. This calculation is automatically performed by the  transport analysis code (TOPICS) on the basis of diagnostic data.
PBXM: Calculated as VSURF IP.
PDX: Calculated using VSURF and IP corrected for inductance effects.
TCV: Calculated as??????
TEXTOR: Calculated as VSURF IP.
TFTR: POHM = IP VSURF d(3.14 10-7 RGEO IP2 li)/dt
TDEV: Calculated as??????
START: Calculated using VSURF and IP corrected for inductance effects.
T10: Calculated as VSURF IP.
TUMAN3M: Calculated as VSURF IP.
Normal level of accuracy is
ASDEX (Ohmic: 5% H: 50%), AUG (15%), CMOD (15%), COMPASS (10%),  D3D (15%), JET (20%), JFT2M (10%), JT60U (20%), PBXM (50%), PDX (20%), TCV (10%), TEXTOR (10%), TFTR (300kW), TDEV (???%), START (10%), T10 (20%), TUMAN3M (6%).

75. ENBI: Neutral beam energy weighted by power in volts. This quantity is calculated from
S( Ei Pi / S(Pi) ) where Ei and Pi are the beam energy and power for source i, respectively.
ASDEX: the primary energy component is given.
Normal level of accuracy is
ASDEX (0.2KV), AUG (5%), CMOD (Na), COMPASS (Na),  D3D (10%), JET (12%), JFT2M (5%), JT60U (5%), PBXM (15%), PDX (15%), TCV (Na), TEXTOR (5%), TFTR (5%), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

76. PINJ: The injected neutral beam power with beam of (BGASA, BGASZ) that passes into the torus in watts.
Zero if no beams are on. Notice total injected neutral beam power is PINJ + PINJ2.
Normal level of accuracy is
ASDEX (5%), AUG (5%), CMOD (Na), COMPASS (Na),  D3D (10%), JET (6%), JFT2M (5%), JT60U (5%), PBXM (5%), PDX (10%), TCV (Na), TEXTOR (5%), TFTR (15% absolute, 2% relative), TDEV (Na), START (5%), T10 (Na), TUMAN3M (Na).

77. BSOURCE: The power fractions injected by neutral beam.
For example if P1 = 80%, P2 = 10% and P3 = 10% then BSOURCE = 801010.

78. PINJ2: The injected neutral beam power from a second source with beam of (BGASA2, BGASZ2)
in watts. Zero if no beams of second source are on.
Normal level of accuracy is
ASDEX (Na), AUG (5%), CMOD (Na), COMPASS (Na),  D3D (Na), JET (6%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (5%), TFTR (15% absolute, 2% relative), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

79. BSOURCE2: The power fractions injected by neutral beam with the second source.
JET: For 89-90 data the possibilities for BSOURCE and BSOURCE2 are
781606 for 80kV D, 652114 for 140kV D, 990000 for 3He or 4He beams.

80. COCTR: Fraction of beam power co-injected as compared to the total beam power injected.

81. PNBI: Total injected neutral beam power minus shine through in watts. Zero if no beams are on.
Normal level of accuracy is
ASDEX (10%), AUG (10%), CMOD (Na), COMPASS (Na),  D3D (10%), JET (10%), JFT2M (10%), JT60U (10%), PBXM (10%), PDX (10%), TCV (Na), TEXTOR (10%), TFTR (15% absolute, 5% relative), TDEV (Na), START (20%), T10 (Na), TUMAN3M (Na).

82. PFLOSS: Amount of neutral beam power in watts that is lost from the plasma through charge exchange
and unconfined orbits.
ASDEX: From fits to FREYA code results.
D3D: PNBI exp{3.3 - 2.5 IP/106}/100.
JET: PINJ exp{3.35 - 0.667|IP|/106 - 0.2 NEL/1019}/100.
JFT2M: From fits to Monte Carlo code results.
PBXM: From a fits to the TRANSP code results.
PDX: From a fits to the TRANSP code results.
Normal level of accuracy is
ASDEX (30%), AUG (20%), CMOD (Na), COMPASS (Na),  D3D (30%), JET (50%), JFT2M (20%), JT60U (20%), PBXM (20%), PDX (30%), TCV (Na), TEXTOR (30%), TFTR (20%), TDEV (Na), START (20%), T10 (Na), TUMAN3M (Na).

83. ECHFREQ: ECRH frequency in Hz. Zero if no ECRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (0.1%) D3D (0.1%), JET (Na), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (0.1%), TUMAN3M (Na).

84. ECHMODE: Mode of ECRH waves.
Possible values are:

NONE If  no ECRH  power has been applied to discharge
OFF If PECRH = 0 but PECRH > 0 at some other time in discharge
O is ordinary mode
X is extraordinary
X+O both ordinary and extraordinary mode

85. ECHLOC: Location of ECRH launch.
Possible values are:

NONE If  no ECRH  power has been applied to discharge
OFF If PECRH = 0 but PECRH > 0 at some other time in discharge
IN identifies waves launched from the high field side
OUT is from the low field side
IN+OUT from both low and high field side

86. PECRHC: ECRH power in watts coupled to the plasma. Zero, if no ECRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (5%) D3D (10%), JET (Na), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

87. PECRH: ECRH power in watts absorbed by the plasma. Zero if no ECRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (15%) D3D (10%), JET (Na), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (15%), TUMAN3M (Na).

88. ICFREQ: Frequency of ICRH waves in Hz. Zero, if no ICRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (1%), CMOD (0.5%), COMPASS (Na),  D3D (0.001%), JET (1%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (0.1%), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

89. ICSCHEME: ICRH heating scheme.
Possible Values:

NONE If  no ICRH  power has been applied to discharge
OFF If PICRH = 0 but PICRH > 0 at some other time in discharge
HMIN for H minority
HE3MIN for 3He minority
H2NDHARM for 2nd harmonic H heating
T2/H3MIN 3He minority in Tritium
HMIN-T2 H minority in Tritium

90. ICANTEN: Antenna phasing.
Possible Values are:

NONE If  no ICRH  power has been applied to discharge
OFF If PICRH = 0 but PICRH > 0 at some other time in discharge
DIPOLE Dipole phasing
MONOPOLE Monopole phasing

91. PICRHC: ICRH power in watts coupled to the plasma. Zero, if no ICRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (10%), CMOD (3-5%), COMPASS (Na),  D3D (5%), JET (10%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (10%), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

92. PICRH: ICRH power in watts absorbed by the plasma. Zero, if no ICRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (10%), CMOD (10%), COMPASS (Na),  D3D (10-20%), JET (10%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (10%), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

93. PALPHA: Estimated alpha heating power in Deuterium-Tritium plasmas in watts.
JET: estimated as 1.601 10-19 neutrons/s 3.5 106 W. Set to zero, if less than 0.01 106 W.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (10%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (20%), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

94. DWDIA: Time rate of change of the total plasma stored energy as determined by the diamagnetic loop in watts.
ASDEX: Parabolic fit to time evolution of diamagnetic bp over 6 ms, when DWHC = 0. Set by hand from drawing the tangent to the WDIA time trace, when DWHC = 1.
D3D: ( 25%)
JET: Running average method over 100 ms.
JFT2M: Simple derivative over 5ms.
Normal level of accuracy is
ASDEX (20%), AUG (30%), CMOD (Na), COMPASS (30%),  D3D (25%), JET (10%), JFT2M (20%), JT60U (20%),  PBXM (Na), PDX (10%), TCV (Na), TEXTOR (20%), TFTR (5% + fractional error WDIA), TDEV (???%), START (Na), T10 (15%), TUMAN3M (20%).

95. DWDIAPAR: Time derivative for ASDEX of WDIA from a parabolic fit to the three available H-mode points.
DWDIAPAR has been used in calculating TAUDIA.
Normal level of accuracy is
ASDEX (20%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (Na), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

96. DWMHD: Time rate of change of the total plasma stored energy as determined from MHD in watts.
ASDEX: As for DWDIA.
D3D: A spline fit is made to W and this fitted curve is then differentiated.
JET: As for DWDIA.
JFT2M: Simple derivative over 5ms of WMHD without correcting for the change of li from a current
filament method.
Normal level of accuracy is
ASDEX (20%), AUG (30%), CMOD (20%), COMPASS (Na),  D3D (25%), JET (20%), JFT2M (20%), JT60U (Na), PBXM (10%), PDX (10%), TCV (10%), TEXTOR (20%), TFTR (5% + fractional error WTOT), TDEV (???%), START (20%), T10 (15%), TUMAN3M (Na).

97. DWHC: Equal to 1 when DWDIA or DWMHD have been corrected by hand for ASDEX.


Temperatures

98. TEV: The volume averaged electron temperature in eV.
ASDEX: From 16 radial YAG measurements fitting Te(x) = Te(0) exp (ax2 + bx4 + cx6).
D3D: Determined by a spline temperature profile fit to the Thomson scattering data.
JET: From 51 point ECE temperature profile.
PBXM: Volume averaged electron temperature computed from BETMHD, VOL, NEL, assuming Zeff = 1.
PDX: Volume averaged electron temperature computed from BETMHD, VOL, NEL, assuming Zeff = 1.
Normal level of accuracy is
ASDEX (5%), AUG (Na), CMOD (5%), COMPASS (Na),  D3D (10%), JET (10%), JFT2M (Na), JT60U (5%), PBXM (30%), PDX (30%), TCV (5%), TEXTOR (Na), TFTR (15%), TDEV (???%), START (Na), T10 (15%), TUMAN3M (Na).

99. TE0: The electron temperature at the magnetic axis in eV.
ASDEX: From 16 radial YAG measurements under the same profile assumptions as for TEV.
D3D: Determined by a spline temperature profile fit to the Thomson scattering data.
JET: From ECE temperature profile.
Normal level of accuracy is
ASDEX (10%), AUG (30%), CMOD (10%), COMPASS (Na),  D3D (10%), JET (10%), JFT2M (Na), JT60U (10%), PBXM (Na), PDX (Na), TCV (10%), TEXTOR (15%), TFTR (10%), TDEV (???%), START (Na), T10 (15%), TUMAN3M (Na).

100. TE0TSC: The electron temperature in eV, determined from the Thomson scattering point that is closest to the magnetic axis.
ASDEX: Average of the 3 YAG laser channels closest to the equatorial plane.
D3D: Thomson scattering point that is closest to the magnetic axis (less than 10 cm).
Normal level of accuracy is
ASDEX (5%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (10%), JET (Na), JFT2M (Na), JT60U (10%), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (???%), START (Na), T10 (Na)TUMAN3M (Na).

101. TIV: The volume averaged ion temperature in eV.
D3D: Determined by a spline temperature profile fit to the charge exchange recombination data.
JET: Estimated from TIV = TI0 TEV/TE0.
PBXM: TIV = TEV.
PDX: TIV = TEV.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (10%), JET (30%), JFT2M (Na), JT60U (7%), PBXM (30%), PDX (30%), TCV (Na), TEXTOR (Na), TFTR (20%), TDEV (???%), START (Na), T10 (Na)TUMAN3M (Na).

102. TI0: The ion temperature at the magnetic axis in eV.
D3D: Determined by a spline temperature profile fit to the charge exchange recombination data.
JET: From Crystal X-ray diagnostic.
Normal level of accuracy is
ASDEX (Na), AUG (40%), CMOD (15%), COMPASS (Na),  D3D (10%), JET (10%), JFT2M (Na), JT60U (10%), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (15%), TDEV (???%), START (Na), T10 (10%), TUMAN3M (Na).

103. TICX0: The ion temperature at the magnetic axis in eV.
JET: From charge exchange recombination spectroscopy.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (10%), JFT2M (Na), JT60U (10%), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na)TUMAN3M (Na).


Energies

104. WDIA: Total plasma energy in joules as determined from the diamagnetic loop.
ASDEX: In ohmic WDIA = Wdia-meas (20%) where Wdia-meas = 0.471 RGEO 10-6 IP2 BEPDIA.
In H-mode phase WDIA = Wdia-meas - DW where DW = Wdia-meas(Ohmic) - WMHD (Ohmic).
JFT2M: In ohmic WDIA = Wdia-meas ( 1-2 kJ).
In H-mode phase WDIA = Wdia-meas - DW, where DW = Wdia-meas(Ohmic) - WMHD (Ohmic).
TFTR: WDIA = 4.71  10-7 RGEO IP2 BEPDIA.
Normal level of accuracy is
ASDEX (10%), AUG (10%), CMOD (Na), COMPASS (15%),  D3D (0.1/bp), JET (5%), JFT2M (15%), JT60U (5%), PBXM (Na), PDX (15%), TCV (Na), TEXTOR (10%), TFTR (4% + 100kJ), TDEV (???%), START (Na), T10 (10%), TUMAN3M (20%).

105. WMHD: Total plasma energy in joules as determined by a MHD equilibrium fit or based on probe
measurements and an estimate of  li/2 (ASDEX).
ASDEX: 0.471 RGEO 10-6 IP2 BEPMHD.
TFTR: WMHD = WTOT currently; it should be WMHD = (3 WTOT - WDIA)/2.
Normal level of accuracy is
ASDEX (Ohmic: 20%, H: 10%), AUG (10%), CMOD (10% +10KJ), COMPASS (Na),  D3D (0.05/bp), JET (15%), JFT2M (15%), JT60U (5%), PBXM (15%), PDX (15%), TCV (10%), TEXTOR (20%), TFTR (2% + fractional error BEIMHD), TDEV (???%), START (15%), T10 (10%), TUMAN3M (Na).

106. WKIN: Total thermal plasma energy in joules as determined from kinetic measurements.
ASDEX: WEKIN (1 + (7-ZEFF)/(7-1)). ZEFFNEO is used instead of ZEFF for Ohmic points.
JET: From a profile fit assuming flat Zeff profile and Ti profile as Te.
TEXTOR: WDIA - 1.5 WFPER.
Normal level of accuracy is
ASDEX (250%), AUG (Na), CMOD (20%), COMPASS (Na),  D3D (0.05/bp), JET (25%), JFT2M (Na), JT60U (15%),  PBXM (Na), PDX (15%), TCV (Na), TEXTOR (15%), TFTR (25%), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

107. WEKIN: Total thermal electron plasma energy in joules as determined from kinetic measurements.
Normal level of accuracy is
ASDEX (10%, H: 15%), AUG (Na), CMOD (15%), COMPASS (Na),  D3D (15%), JET (20%), JFT2M (Na), JT60U (15%),  PBXM (Na), PDX (Na), TCV (10%), TEXTOR (Na), TFTR (20%), TDEV (???%), START (Na), T10 (20%), TUMAN3M (Na).

108. WIKIN: Total thermal ion plasma energy in joules as determined from kinetic measurements.
JET: From ECE temperature profile shape normalized to Ti (o) from crystal X-ray diagnostic.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (25%), COMPASS (Na),  D3D (15%), JET (15%), JFT2M (Na), JT60U (15%), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (25%), TDEV (???%), START (Na), T10 (Na), TUMAN3M (Na).

109. WFPER: Total perpendicular fast ion energy due to NBI in joules as determined from
transport calculations. Zero, if no NBI is applied.
JET: Calculated from the PENCIL code.
JFT2M: From Monte Carlo code.
PBXM: From TRANSP runs.
PDX: From TRANSP runs.
TEXTOR: From TRANSP runs.
Normal level of accuracy is
ASDEX (Na), AUG (30%), CMOD (Na), COMPASS (Na),  D3D (Na), JET (30%), JFT2M (20%), JT60U (Na), PBXM (30%), PDX (30%), TCV (Na), TEXTOR (25%), TFTR (30%), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

110. WFPAR: Total parallel fast ion energy due to NBI in joules as determined from transport calculations.
JET: Calculated from the PENCIL code. Zero, if no NBI is applied.
JFT2M: From Monte Carlo code.
PBXM: From TRANSP runs.
PDX: From TRANSP runs.
TEXTOR: From TRANSP runs.
Normal level of accuracy is
ASDEX (Na), AUG (30%), CMOD (Na), COMPASS (Na),  D3D (Na), JET (30%), JFT2M (20%), JT60U (Na), PBXM (30%), PDX (30%), TCV (Na), TEXTOR (25%), TFTR (30%), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

111. WFFORM: Total fast ion energy due to NBI in joules estimated from approximate formula.
Zero, if no NBI is applied.
ASDEX: From regression analysis based on 176 FREYA runs:
C FT NEL-1.3 PINJ ENBI0.75 (WTOT - WFFORM)0.5 for H beam, and
C' F'T NEL-1.1 PINJ ENBI (WTOT - WFFORM)0.8 for D beam,
where C and C' are estimated constants depending on the target gas, and FT and F'T are estimated
temperature effects. Missing temperature profiles are interpolated by regression of the available YAG
temperature profiles in the database against IP, BT, NEL, NEV, EVAP and beam gas.
D3D: {0.55 Pb tse/2} {1+(2/3)(vc/vb)2 [(1/2) ln(f(vb,vc))-30.5 {p/6+tan-1(g(vb,vc))}]}
where f(vb,vc)=(vb+vc)2 / ( vb2 - vb vc + vc2) and g(vb,vc)=(2 vb - vc ) / ( 30.5 vc)
The velocities vc and vb are determined from the critical energy and the beam energy respectively, and
Pb is the injected neutral beam power. The quantity tse is the slowing down-time on electrons first
defined by Spitzer, tse = 6.3108 Ab Te1.5 / ( Zb2 ne ln(Le)), where Ab and Zb are the
atomic mass and charge of the fast ions, Te is the electron temperature in eV, ne is the electron
density in cm-3, and ln(Le) ~ 16 is the Coulomb logarithm. If ion drag were negligible, the
term in the brackets would be identically one. For DIII-D parameters, however, this term varies
rapidly with temperature. To give better agreement with ONETWO results, the above formula is
multiplied by 0.55.
JET: 0.161019PINJ/NEV for SHOT <= 18760;
1019(0.16 P80kV + 0.3 P140kV + 0.02 PHe)/NEV for SHOT > 18760.
JFT2M: WFPER + WFPAR.
PBXM: WFPER + WFPAR.
PDX: WFPER + WFPAR.
Normal level of accuracy is
ASDEX (15%), AUG (30%), CMOD (Na), COMPASS (Na),  D3D (50%), JET (50%), JFT2M (Co), JT60U (20%), PBXM (Co), PDX (Co), TCV (Na), TEXTOR (30%), TFTR (Na), TDEV (Na), START (20%), T10 (Na)TUMAN3M (Na).

112. WFANI: Estimate of fraction of perpendicular fast ion energy as compared to the total fast ion energy
due to NBI. If WFPER and WFPAR are available, WFANI = WFPER/(WFPER + WFPAR).
Zero, if no NBI is applied. 
ASDEX: From regression analysis based on 176 FREYA runs:
CNEL0.04 (NE0 (ZEFF - 1))0.045/ENBI0.14 for H beam and
C'NEL0.12 (NE0(ZEFF - 1))0.020/ENBI0.14 for D beam
where C and C' are estimated constants depending on the target gas. Missing central densities are
interpolated by regression of the available central densities in the database against IP, BT, NEL,
NEV, EVAP and PINJ. If not measured, ZEFF is assumed to be 3 for EVAP = NONE, 2.5 for
carbonized shots and 1.5 for boronised shots.
D3D: The fast ion anisotropy is calculated only from geometry; the angles of the beam center line are known
relative to the geometric axis of the tokamak and from this the perpendicular and parallel components can
be determined.
JET: 1.1610-2 NEL0.11/ENBI0.07.
Normal level of accuracy is
ASDEX (7%), AUG (40%), CMOD (Na), COMPASS (Na),  D3D (50%), JET (50%), JFT2M (Co), JT60U (Na), PBXM (Co), PDX (Co), TCV (Na), TEXTOR (30%), TFTR (20%), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

113. WFICRH: Estimate of the perpendicular fast ion energy content during ICRH heating in Joules.
It is given by 4/3 (DWDIA - DWMHD), where DWDIA and DWMHD is the increase in energy due to ICRH.
Zero, if no ICRH is applied.
JET: Estimated with the PION code.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (50%), COMPASS (Na),  D3D (Na), JET (50%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

114. WFICRHP: Estimate of the parallel fast ion energy content due to ICRH heating in Joules.
Zero, if no ICRH is applied.
JET: Estimated with the PION code. 
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (50%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

115. WFICFORM: Total fast ion energy due to ICRH in joules estimated from approximate formula.
Zero, if no ICRH is applied.
JET: = 0.3 (TE0/103)1.5 PICRH (1019/NE0) / 17 J.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (50%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

116. ICFORM: Indicates, if WFICFORM has been used in confinement calculations (=1).

117. WFANIIC: Estimate of fraction of perpendicular fast ion energy compared to the total fast ion energy due to ICRH heating.
Zero, if no ICRH is applied.
Normal level of accuracy is
ASDEX (Na), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (50%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (Na), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).


Energy confinement times

118. TAUDIA: Total diamagnetic energy confinement time in seconds.
Defined as WDIA/(POHM + PNBI + PICRH + PECRH - DWDIA).
Normal level of accuracy is
ASDEX (Ohmic: 25% H: 15%), AUG (15%), CMOD (Na), COMPASS (15%),  D3D (15%), JET (Ohmic: 25% H: 15%),  JFT2M (20%), JT60U (15%), PBXM (Na), PDX (20%), TCV (Na), TEXTOR (15%), TFTR (20% for DWDIA = 0), TDEV (???%), START (Na), T10 (25%), TUMAN3M (21%).

119. TAUMHD: Total MHD energy confinement time in seconds.
Defined as WMHD/(POHM + PNBI + PICRH + PECRH - DWMHD).
Normal level of accuracy is
ASDEX (15%), AUG (15%), CMOD (15%), COMPASS (Na),  D3D (15%), JET (35%), JFT2M (20%), JT60U (Na), PBXM (20%), PDX (20%), TCV (10%), TEXTOR (20%), TFTR (20% for DWMHD = 0), TDEV (???%), START (15%), T10 (25%), TUMAN3M (Na).

120. TAUTH1: Thermal energy confinement time in seconds.
Defined as WKIN/(POHM + PNBI+ PICRH + PECRH - DWMHD - PFLOSS).
ASDEX: DWTOT = 2/3 DWMHD + 1/3 DWDIA was used instead of DWMHD.
Normal level of accuracy is
ASDEX (Co), AUG (Na), CMOD (Co), COMPASS (Na),  D3D (Co), JET (Co), JFT2M (Na), JT60U (Co), PBXM (Co), PDX (Co), TCV (Na), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Na), T10 (Na), TUMAN3M (Na).

121. TAUTH2: Thermal energy confinement time in seconds.
Defined as WMHD-WFFORM - 0.75 WFICRH)/(POHM + PNBI + PICRH + PECRH - DWMHD - PFLOSS).
ASDEX: 1.5 WFANI WFFORM and DWTOT (see TAUTH1) were used for WFFORM
and DWMHD, respectively.
PBXM, PDX: 3/4WFPER + 3/2 WFPAR was used instead of WFFORM.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Na),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Na), PBXM (Co), PDX (Co), TCV (Na), TEXTOR (Co), TFTR (Co), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).


Recommended values

122. WTOT: Estimated total plasma energy content in Joules.
Defined as
ASDEX: WTOT = WTH + WFFORM.
AUG: WTOT = WMHD.
CMOD: WTOT = WMHD.
COMPASS: WTOT = WDIA.
D3D: WTOT = WMHD.
JET: WTOT = WTH + WFPER + WFPAR + WFICRH. If WFPER and WFPAR are missing they are replaced by WFFORM.
JFT2M: WTOT = WTH + WFFORM.
JT60U: WTOT = WDIA
PBXM: WTOT = WTH + WFPER + WFPAR.
PDX: WTOT = WTH + WFPER + WFPAR.
TCV: WTOT=??????
TEXTOR: WTOT = WTH + WFPER + WFPAR.
TFTR: WTOT = 3.14  10-7  RGEOIP2(BEPMHD + BEPDIA/2) 
TDEV: WTOT=??????
START: WTOT = WMHD.
T10: WTOT = WDIA.
TUMAN3M: WTOT = WDIA.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (6% + 100kJ), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

123. WTH: Estimated thermal plasma energy content in Joules.
Defined as
ASDEX: WTH = WDIA - 1.5 WFANI WFFORM.
AUG: WTH = WMHD - 0.75 WFPER - 1.5 WFPAR.
CMOD: WTH = WTOT - WFICRH
COMPASS: WTH = WDIA.
D3D: WTH = WMHD - WFFORM.
JET: WTH = WDIA - 1.5 (WFPER + WFICRH). If WFPER is missing WFPER is replaced by WFANI WFFORM.
JFT2M: WTH = WDIA/3 + 2 WMHD/3 - WFFORM.
JT60U: WTH = WKIN
PBXM: WTH = WMHD - 0.75 WFPER - 1.5 WFPAR.
PDX: WTH = WMHD - 0.75 WFPER - 1.5 WFPAR.
TCV: WTH=??????
TEXTOR: WTH = WDIA - 1.5 WFPER.
TFTR: WTH=??????
TDEV: WTH=??????
START: WTH = WMHD - WFFORM.
T10: WTH = WDIA.
TUMAN3M: WTH = WDIA.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

124. PL: Estimated Loss Power not corrected for charge exchange and unconfined orbit losses in watts.
Defined as
ASDEX: PL = POHM + PNBI - DWDIA/3 - 2 DWMHD/3.
AUG: PL = POHM + PNBI + PICRH + PECRH - DWMHD.
CMOD: PL = POHM + PICRH - DWMHD.
COMPASS: PL = POHM + PECRH - DWDIA.
D3D: PL = POHM + PNBI + PECRH - DWMHD.
JET: PL = POHM + PNBI + PICRH - DWDIA.
JFT2M: PL = POHM + PNBI - DWDIA.
JT60U: PL= POHM + PNBI - DWDIA
PBXM: PL = POHM + PNBI - DWMHD.
PDX: PL = POHM + PNBI - DWMHD.
TCV: PL=??????
TEXTOR: PL = POHM + PNBI + PICRH - DWDIA.
TFTR:
PL=??????
TDEV:
PL=??????
START: PL = POHM + PNBI - DWMHD.
T10: PL = POHM + PECRH - DWDIA.
TUMAN3M: PL = POHM - DWDIA.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

125. PLTH: Estimated Loss Power corrected for charge exchange and unconfined orbit losses in Watts.
Defined as PLTH = PL - PFLOSS.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

126. TAUTOT: Estimated total energy confinement time in seconds.
Defined as WTOT/PL.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

127. TAUTH: Estimated thermal energy confinement time in seconds.
Defined as WTH/PLTH.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

128. TAUC92: Correction factor for thermal confinement time TAUTH
as described in KARDAUN, O.J.W.F., et. al., Plasma Phys. Control. Nucl. Fus. Res. 3 (1993) 251.
ASDEX: TAUC92 = 1/(1.5 - 0.1 bo - 0.15 ca), for ELMy or TAUC92 = 1/(1.2 - 0.1 bo - 0.15 ca), for ELM free
with bo = 1, if EVAP = BOROA or BOROB and ca = 1, if EVAP = CARBH otherwise bo = 0 and ca = 0.
JET: TAUC92 = 1/0.85, if 870101 < = DATE < = 871231.
PDX: TAUC92 = 1/((1/3) (DALFDV/DALFMP))0.4 , for ELMy.
In all other conditions TAUC92 = 1.
Normal level of accuracy is
ASDEX (10%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (30%), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (10%), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

129. TAUC93: Correction factor for thermal confinement time TAUTH
as described in SCHISSEL, D. P., et al., EPS, Vol. 17C Part I (1993) 103.
ASDEX: TAUC93 = 1/(1.5 - 0.1 bo - 0.15 ca), for ELMy or TAUC93 = 1/(1.2 - 0.1 bo - 0.15 ca), for ELM free
with bo = 1, if EVAP = BOROA or BOROB and ca = 1, if EVAP = CARBH otherwise bo = 0 and ca = 0.
PDX: TAUC93 = 1/((1/2) (DALFDV/DALFMP))0.4 , for ELMy.
In all other conditions TAUC93 = 1.
Normal level of accuracy is
ASDEX (10%), AUG (Na), CMOD (Na), COMPASS (Na),  D3D (Na), JET (Na), JFT2M (Na), JT60U (Na), PBXM (Na), PDX (10%), TCV (Na), TEXTOR (Na), TFTR (Na), TDEV (Na), START (Na), T10 (Na), TUMAN3M (Na).

130. H89: Enhancement factor TAUTOT TAUC92 / ITER89-P
Scaling reference YUSHMANOV, P. N., et. al., Nuclear Fusion 30 (1990).
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

131. HITERL96: Enhancement factor TAUTH TAUC92 / ITERL96-P
Scaling reference KAYE, S. M., et. al., Nuclear Fusion 37 (1997) 1303.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

132. H93: Enhancement factor TAUTH TAUC92 / ITERH93-P
Scaling reference SCHISSEL, D. P., et al., EPS, Vol. 17C Part I (1993) 103.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

133. HITER92Y: Enhancement factor TAUTH TAUC92 / ITERH92Y
Scaling reference KARDAUN, O. J. W. F., et. al., Plasma Phys. Control. Nucl. Fus. Res. 3 (1993) 251.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

134. HEPS97: Enhancement factor TAUTH TAUC93 / EPS97(ELMy)
Scaling reference CORDEY, J.G., et. al., Plasma Physics and Controlled Fusion 39 (1997) B115.

Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

135. HIPB98y: Enhancement factor TAUTH TAUC92 / IPB98(y)
Scaling reference ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

136. HIPB98y1: Enhancement factor TAUTH TAUC92 / IPB98(y,1)
Scaling reference ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

137. HIPB98y2: Enhancement factor TAUTH TAUC92 / IPB98(y,2)
Scaling reference ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

138. HIPB98y3: Enhancement factor TAUTH TAUC92 / IPB98(y,3)
Scaling reference ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).

139. HIPB98y4: Enhancement factor TAUTH TAUC92 / IPB98(y,4)
Scaling reference ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175.
Normal level of accuracy is
ASDEX (Co), AUG (Co), CMOD (Co), COMPASS (Co),  D3D (Co), JET (Co), JFT2M (Co), JT60U (Co), PBXM (Co), PDX (Co), TCV (Co), TEXTOR (Co), TFTR (Co), TDEV (Co), START (Co), T10 (Co), TUMAN3M (Co).


Rotation information

140. SPIN: Definition to come.

141. TORQ: Definition to come.

142. VTOR0: Definition to come.

143. VTORV: Definition to come.

144. VTORIMP: Definition to come. Set to NONE.


Standard dataset flags

145. STANDARD: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.1.
Possible values are:

1 For observations that belonged to the standard dataset of ITERH.DB1
0 All other observations

146. SELDB1: Flagging variable making connections to DB.1. 
Notice, can only be different from zero for observations that were in DB.2. 
SELDB1=S a(I.n) 10(n-1), n=1-3.
a (I.1) = 1 If the observation was also in DB.1.
a (I.2) = 1 If the observation was in DB.1 and also satisfied the old DB.1 standard selection criteria.
a (I.3) = 1 If the observation satisfies the DB.1 standard selection criteria now (PHASE = H1 has been included).

147. SELDB2: Flagging variable for standard selection in DB.2
Notice, can only be different from zero for observations that were in DB.2.
(PABST = POHM + PNBI + PECRH + PICRH).
SELDB2=S a(II.n) 10(n-1), n=1-10.

II.1 H-mode criterion.
a (II.1) = 0
if  PHASE = H, HSELM, HGELM or HGELMH or H1 then a(II.1) = 1

II.2 NBI only with H or D injection.
a (II.2) = 0
if AUXHEAT = NB then
a (II.2) = 1
IF PINJ > 0 and (BGASA 1 or 2) then a(II.2) = 0
IF PINJ2 > 0 and (BGASA2 1 or 2) then a(II.2) = 0 

II.3 Missing confinement data 
a (II.3) = 1
*** TAUMHD check ***
if  TOK = AUG, CMOD, D3D, PBXM or PDX then
    if  TAUMHD missing then a (II.3) = 0
*** TAUDIA check ***
if  TOK = ASDEX, COMPASS, JET, JFT2M, JT60U or TEXTOR then
    if  TAUDIA missing then a (II.3) = 0.

II.4 No pellet discharges.
a (II.4) = 1
if PELLET = H or D then a (II.4) = 0

II.5 Weak dW/dt criterion (applied to either MHD or DIA).
a (II.5) = 1
if  TOK = AUG, CMOD, D3D, PBXM or PDX  then
    if NOT (-0.05 <= DWMHD/PABST <= 0.35) then a (II.5) = 0
if  TOK = ASDEX, COMPASS, JET, JFT2M, JT60U or TEXTOR  then
    if  DWDIA not missing  and NOT (-0.05 <= DWDIA/PABST <= 0.35) then a (II.5) = 0.
if  TOK = JET and PREMAG = NO then
    if  (-0.05 <= DWDIA/PABST <= 0.35) then a (II.5) = 1

II.6 Radiation criterion.
a (II.6) = 1
if PRAD/PABST > 0.6 then a (II.6) = 0
if TOK = D3D then
    if SHOT = 62950 and TIME = 3.10 then a (II.6) = 0
    if SHOT = 64446 and TIME = 3.45 then a (II.6) = 0
    if SHOT = 64514 and TIME = 3.15 then a (II.6) = 0
    if SHOT = 64514 and TIME = 2.05 then a (II.6) = 0
    if SHOT = 64519 and TIME = 2.06 then a (II.6) = 0
    if SHOT = 64523 and TIME = 2.02 then a (II.6) = 0
    if SHOT = 62879 and TIME = 2.49 then a (II.6) = 0
    if SHOT = 67801 and TIME = 2.50 then a (II.6) = 0
    if SHOT = 62881 and TIME = 2.44 then a (II.6) = 0
end of D3D exception
if TOK = JET then
    if PRAD missing then a (II.6) = 0
    if SHOT = 17010 and PRAD missing a (II.6) = 1
    if SHOT = 22332 and PRAD missing a (II.6) = 1
    if SHOT = 23201 and PRAD missing a (II.6) = 1
    if SHOT = 23206 and PRAD missing a (II.6) = 1
end of JET exception
if TOK = JFT2M and PRAD missing then a (II.6) = 0
if TOK = PBXM and PRAD missing then a (II.6) = 0

II.7 Q95 or Ip/Bt limit.
if  TOK = JET and Q95 missing  then
    Q95=5 {AMIN2 |BT| / ( RGEO |IP| / 106)} (1/2) (1 + KAPPA2) ( 1 + 3 AMIN2 / (2 RGEO2))
a (II.7) = 1
if TOK = ASDEX and Q95 < 3.1 then a (II.7) = 0
if TOK = AUG and Q95 < 3.1 then a (II.7) = 0
if TOK = COMPASS and Q95 < 3.1 then a (II.7) = 0
if TOK = CMOD and Q95 < 3.1 then a (II.7) = 0
if TOK = D3D and |IP/BT| > 106 A/T then a (II.7) = 0
if TOK = JET and Q95 < 3.1 then a (II.7) = 0
if TOK = JFT2M and Q95 < 2.7 the a (II.7) = 0
if TOK = JT60U and Q95 < 3.1 then a (II.7) = 0
if TOK = TEXTOR and Q95 < 3.1 then a (II.7) = 0

II.8 Fast ion energy limit
a (II.8) = 1
if  (WFFORM + WFICRH)/WMHD > 0.4 then a (II.8) = 0
if  TOK = D3D and WFFORM missing then
    if  (WMHD-WKIN)/WMHD > 0.4 then a (II.8) = 0
end of D3D exception
if TOK = JET and PREMAG = NO then
    a (II.8) = 1
    if (WFFORM + WFICRH) /WDIA > 0.4 then a (II.8) = 0
end of JET exception

II.9 Beta-limit + no Hot-ion H-modes.
BCR = 10-8 |IP| / ( AMIN |BT| )
a (II.9) = 1
if TOK = PBXM and BETMHD >= 4 BCR then a (II.9) = 0
if TOK = PDX and BETMHD >= 2.8 BCR then a (II.9) = 0
if TOK = D3D then
    if  TI0 >= 8 103 eV then a (II.9) = 0
end D3D
if TOK = JET then
    if  TI0 > 11 103 eV and TI0 > TE0 + 4 103 eV then a (II.9) = 0
    if  TICX0 > 11 103 eV and TICX0 > TE0 + 4 103 eV then a (II.9) = 0
end JET

II.10 No JET 1987 data.
a (II.10) = 1
if  TOK = JET and 870101 < = DATE < = 871231 then a (II.10) = 0.

148: SELDB2X: Flagging variable for extra selection criteria in DB.2
Notice, can only be different from zero for observations that were in DB.2.
(PABST = POHM + PNBI + PECRH + PICRH).
SELDB2X=S a(II.n) 10(n-11), n=11-20

II.11 High compression ratio (applies only to PDX).
a (II.11) = 1
if TOK = PDX and DALFDV/DALFMP <= 4 then a (II.11) = 0

II.12 No hot-ion H-modes.
a (II.12) = 1
if TOK = D3D then
    if  TI0 >= 8 103 eV then a (II.12) = 0
end D3D
if TOK = JET then
    if  TI0 > 11 103 eV and TI0 > TE0 + 4 103 eV then a (II.12) = 0
    if  TICX0 > 11 103 eV and TICX0 > TE0 + 4 103 eV then a (II.12) = 0
end JET

II.13 ELMs (any kind).
a (II.13) = 0
if PHASE = HGELM, HSELM, HGELMH or H1 then a (II.13) = 1

II.14 Strong auxiliary heating (K. Riedel, Nuclear Fusion 32 (1992) 1270).
a (II.14) = 1
if  1V |IP|/PABST >= 0.4 then a (II.14) = 0

II.15 Stationary density (K. Riedel, Nuclear Fusion 32 (1992) 1270).
a (II.15) = 1
if  TOK = AUG, CMOD, D3D, PBXM or PDX then 
    if DNELDT TAUMHD/NEL >= 0.4 then a (II.15) = 0
if  TOK = ASDEX, COMPASS, JET, JFT2M, JT60U or TEXTOR then 
    if DNELDT TAUDIA/NEL >= 0.4 then a (II.15) = 0

II.16 Strong dW/dt criterion (either MHD or DIA).
a (II.16) = 1
if  TOK = AUG, CMOD, D3D, PBXM or PDX  then
    if  NOT (-0.05 <= DWMHD/PABST <= 0.2) then a (II.16) = 0
if  TOK = ASDEX, COMPASS, JET, JFT2M, JT60U or TEXTOR  then
    if NOT (-0.05 <= DWDIA/PABST <= 0.2) then a (II.16) = 0

II.17 Old low Q95 limit (used in DB1, CHRISTIANSEN, J.P., et al., Nuclear Fusion 32 (1992) 291).
a (II.17) = 1
if TOK = ASDEX and Q95 < 3.1 then a (II.17) = 0
if TOK = D3D and Q95 < 3.1 then a (II.17) = 0
if TOK = JET and Q95 < 3.1 then a (II.17) = 0
if TOK = JFT2M and Q95 < 2.7 then a (II.17) = 0

II.18 No beryllisation.
a (II.18) = 1
if EVAP = BE then a (II.18) = 0

II.19 No boronisation.
a (II.19) = 1
if EVAP = BO, BOR, BOROA, BOROB, BOROC, B2D6 or DECABORA 
    then a (II.19) = 0

II.20 No carbonization.
a (II.20) = 1
if EVAP = CARB or CARBH then a (II.20) = 0

149. IAEA92: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.2.
Possible values are:

1

For ELMy observations included in the subset of upon which ITERH92-P(y) is based

see  KARDAUN, O.J.W.F., et. al., Plasma Phys. Control. Nucl. Fus. Res. 3 (1993) 251.

0

All other observations

150. DB2P5: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.3v5.
Possible values are:

1

For ELMy observations included in the subset DB2.5 as defined in JET Report JET P(98)17
or
ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175

0

All other observations

151. DB2P8: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.3v5.
Possible values are:

1

For ELMy observations included in the subset DB2.8 as defined in JET Report JET P(98)17

or ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175

0

All other observations

152. DB3IS: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.3v5.
Possible values are:

1

For ELMy observations included in the subset DB3r(IS) as defined in JET Report JET P(98)17

or ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175

0

All other observations

153. DB3V5: Standard dataset flag.
Notice, can only be different from zero for observations that were in DB.3v5.
Possible values are:

1

Standard dataset selection for version DB3v5 used  in JET Report JET P(98)17

or ITER PHYSICS BASIS Ch. 2, Nuclear Fusion 39 (1999) 2175

0

All other observations

154. IAE2000N: Standard dataset flag.
See SELDB3X for selection details.
Possible values are:

1

Small IAEA2000 standard dataset as defined in 
Kardaun, O.J.W.F., et. al., Fusion Energy 2000 
(Proc. 18th Int. Conf. Sorrento, 2000), IAEA, Vienna (2001)

0

All other observations

155. IAE2000X: Standard dataset flag.
See SELDB3X for selection details.
Possible values are:

1

Large IAEA2000 standard dataset as defined in 
Kardaun, O.J.W.F., et. al., Fusion Energy 2000 
(Proc. 18th Int. Conf. Sorrento, 2000), IAEA, Vienna (2001)

0

All other observations

156. SELDB3: Flagging variable for new standard selection
(PABST = POHM + PNBI + PECRH + PICRH).
SELDB3=S a(III.n) 10(n-1), n=1-10.

III.1 H-mode criterion.
a (III.1) = 0
if PHASE = H, HSELM, HSELMH, H1, HGELM, HGELM? or HGELMH 
    then a (III.1) = 1
*** exceptions ***
if TOK=COMPASS then
    if  SHOT = 24787 then a (III.1) = 0
    if  AUXHEAT = ECOA then a (III.1) = 0
end of COMPASS exception
if TOK=AUG then
    if  SHOT = 8175 and 1.49 < TIME < 1.51  then a (III.1) = 0
    if  SHOT = 8255 and 1.64 < TIME < 1.66  then a (III.1) = 0
end of AUG exception

III.2 No missing confinement data.
a (III.2) = 1
if  TAUTH RGEO AMIN KAPPA abs(IP) abs(BT) MEFF NEL PLTH is not defined
    then a (III.2) = 0;

III.3 No pellet discharges.
a (III.3) = 1
if PELLET = H or D 
    then a (III.3) = 0
if PELLET NONE 
    then a (III.3) = 0

III.4 Weak dW/dt criterion.
a (III.4) = 1
*** based on  DWMHD ***
if  TOK = AUG, CMOD, D3D, PBXM, PDX, TCV, TDEV, TFTR, T10 or START  then
    if NOT (-0.05 <= DWMHD/PABST <= 0.35) then a (III.4) = 0
*** based on  DWDIA ***
if  TOK = ASDEX, COMPASS, JFT2M, JT60U, TEXTOR, TFTR or TUMAN3M  then
    if NOT (-0.05 <= DWDIA/PABST <= 0.35) then a (III.4) = 0.
*** exception ***
if  TOK = JET then
    *** based on  DWMHD ***
    if SHOT <= 27968 and PREMAG NO then
        if  NOT(-0.05 <= DWMHD/PABST <= +.35) then a (III.4) =0
    *** based on  DWDIA ***
    if SHOT > 27968 or PREMAG = NO then
        if  NOT(-0.05 <= DWDIA/PABST <= +.35) then a (III.4) =0
end of JET exception

III.5 Radiation criterion.
a (III.5) = 1
if PRAD/PABST > 0.6 
    then a (III.5) = 0
*** exceptions ***
if TOK = CMOD then
    if SHOT = 960116029 and 0.85 <= TIME <= 0.95 then a (III.5) =0
end of CMOD exception
if TOK = D3D then
    if SHOT = 62950 and 3.09 <= TIME <= 3.11 then a (III.5) = 0
    if SHOT = 64446 and 3.44 <= TIME <= 3.46 then a (III.5) = 0
    if SHOT = 64514 and 3.14 <= TIME <= 3.16 then a (III.5) = 0
    if SHOT = 64514 and 2.04 <= TIME <= 2.06 then a (III.5) = 0
    if SHOT = 64519 and 2.05 <= TIME <= 2.07 then a (III.5) = 0
    if SHOT = 64523 and 2.01 <= TIME <= 2.03 then a (III.5) = 0
    if SHOT = 62879 and 2.48 <= TIME <= 2.51 then a (III.5) = 0
    if SHOT = 67801 and 2.49 <= TIME <= 2.51 then a (III.5) = 0
    if SHOT = 62881 and 2.43 <= TIME <= 2.45 then a (III.5) = 0
end of D3D exception
if TOK = JET then
    if PRAD missing then a (III.5) = 0
    if SHOT = 17010 and PRAD missing then a (III.5) = 1
    if SHOT = 22332 and PRAD missing then a (III.5) = 1
    if SHOT = 23201 and PRAD missing then a (III.5) = 1
    if SHOT = 23206 and PRAD missing then a (III.5) = 1
end of JET exception
if TOK = JFT2M and PRAD missing then a (III.5) = 0
if TOK = PBXM and PRAD missing then a (III.5) = 0
if TOK = START and PRAD missing then a (III.5) = 1
if TOK = TUMAN3M and PRAD missing then a (III.5) = 1

III.6 Q95 or Ip/Bt limit.
*** temporary estimates of Q95 ***
if  TOK = JET or TUMAN3M and Q95 missing  then
    Q95=5 {AMIN2 |BT| / ( RGEO |IP| / 106)} (1/2) (1 + KAPPA2) ( 1 + 3 AMIN2 / (2 RGEO2))
*** *************************
a (III.6) = 1
if TOK = ASDEX and Q95 < 2.2 then a (III.6) = 0
if TOK = AUG and Q95 < 2.5 then a (III.6) = 0
if TOK = CMOD and Q95 < 2.5 then a (III.6) = 0
if TOK = COMPASS and Q95 < 2.5 then a (III.6) = 1
if TOK = COMPASS and SHOT = 11768 then a (III.6) = 1
if TOK = D3D and |IP/BT| > 106 A/T then a (III.6) = 0
if TOK = JET and Q95 < 2.5 then a (III.6) = 0
if TOK = JFT2M and Q95 < 2.7 the a (III.6) = 0
if TOK = JT60U and Q95 < 2.5 then a (III.6) = 0
if TOK = TCV and Q95 < 2.2 then a (III.6) = 0
if TOK = TEXTOR and Q95 < 2.5 then a (III.6) = 0
if TOK = TFTR and Q95 < 2.2 then a (III.6) = 0
if TOK = TDEV and Q95 < 2.2 then a (III.6) = 0
if TOK = START and Q95 < 2.5 then a (III.6) = 0
if TOK = T10 and Q95 < 2.2 then a (III.6) = 0
if TOK = TUMAN3M and Q95 < 2.2 then a (III.6) = 0

III.7 Fast ion energy limit
a (III.7) = 1
*** based on WMHD ***
if  TOK = D3D, PBXM, PDX, JFT2M, ASDEX, AUG, CMOD or TCV then
    if  (WFFORM + WFICRH)/WMHD > 0.40 then a(III.7) = 0
*** based on WDIA ***
if  TOK = COMPASS, JT60U or TEXTOR then
    if  (WFFORM + WFICRH)/WDIA > 0.40 then a(III.7) = 0
*** exceptions ***
if  TOK = JT60U  and (WFFORM + WFICRH)/WDIA < 0.50 then a(III.7) = 1
if  TOK = D3D and WFFORM missing then
    if (WMHD-WKIN)/WMHD > 0.40 then a(III.7) = 0
end D3D exception
if  TOK = JET then
    if SHOT <= 27968 and PREMAG NO and (WFFORM + WFICRH)/WMHD > 0.40 
        then a(III.7) = 0
    if SHOT > 27968 or PREMAG = NO and (WFFORM + WFICRH)/WDIA > 0.40 
        then a(III.7) = 0
end JET exception

III.8 Beta - limit.  
BCR = 10-8 |IP| / ( AMIN |BT| )
a (III.8) = 1
if TOK = PBXM and BETMHD >= 4 BCR then a (III.8) = 0
if TOK = PDX and BETMHD >= 2.8 BCR then a (III.8) = 0

III.9 No Hot-ion H-modes.
a (III.9) = 1
if  TOK = D3D then
    if  TI0 >= 8 103 eV then a (III.9) = 0
end D3D
if  TOK = JET then
    if  TI0 > 11 103 eV and TI0 > TE0 + 4 103 eV then a (III.9) = 0
    if  TICX0 > 11 103 eV and TICX0 > TE0 + 4 103 eV then a (III.9) = 0
end JET
if  TOK = TFTR then 
    if  TI0 > 11 103 eV and TI0 > TE0 + 4 103 eV then a (III.9) = 0
end TFTR

III.10 No JET 1987 data.
a (III.10) = 1
if  TOK = JET and 870101 < = DATE < = 871231 then a (III.10) = 0.

157. SELDB3X: Flagging variable for extra selection criteria in DB.3
SELDB3X=S a(III.n) 10(n-11), n=11-16.

III.11 Data withdrawn from current version (SELDB3 a(III.1) = 0).
a (III.11) = 0
if  TOK = AUG then
    if SHOT = 8175 and 1.49 <= TIME <= 1.51 then a(III.11) = 1
    if SHOT = 8255 and 1.64 <= TIME <= 1.66 then a(III.11) = 1
end AUG exception
if  TOK = COMPASS then
    if SHOT = 24787 then a(III.11) = 1
    if AUXHEAT = ECOA then a(III.11) = 1
end COMPASS exception

III.12 Strong gas puff data.
a (III.12) = 0
if  PELLET NONE then do
    a (III.12) = 1
    if  PELLET = H or PELLET = D then a(III.12) = 0
end

III.13 Limit temperature ratio TI0/TE0.
a (III.13) = 0
teirat = TI0/TE0
if 0.4 <= teirat <= 2.5 then a (III.13) = 1
** Assume data within limits if data not available
if  teirat missing  then a (III.13) = 1;

III.14 Limit internal inductance li.
a (III.14) = 0
li = 2*(BEILI2-BEIMHD)
if  li <= 2 then a (III.14) = 1
** Assume data within limits if data not available
if  li missing then a (III.14)=1;

III.15 Large IAEA2000 standard dataset equivalent .(Kardaun, O.J.W.F., et. al., Fusion Energy 2000 
(Proc. 18th Int. Conf. Sorrento, 2000), IAEA, Vienna (2001)).
.
a (III.15) = 0
** usual standard dataset
if  SELDB3 = 1111111111 then a (III.15) = 1
** include gas puff data (SELDB3X = ????????10)
if  a (III.11) = 0 and a (III.12) = 1  and SELDB3 = 1111111011 then a (III.15) = 1
** consider all TFTR data
if TOK = TFTR then a (III.15) = 1
** weaken the non-stationarity criteria for TFTR
if TOK = TFTR then do
   if  NOT (-0.10 <= DWMHD/PL < 0.35) then a (III.15) = 0
end
** only ELMy data
if  substr(PHASE,1,1) H then a (III.15) = 0
if  PHASE = H then a (III.15) = 0
** exclude JET museums shots
if  TOK = JET and SHOT = 19971 then a (III.15) = 0
if  TOK = JET and SHOT = 43014 then a (III.15) = 0
** limit temperature ratio
a (III.15) = a (III.15) a (III.13)
** exclude high li shots
a (III.15) = a (III.15) a (III.14)

III.16 Small IAEA2000 standard dataset equivalent.(Kardaun, O.J.W.F., et. al., Fusion Energy 2000 
(Proc. 18th Int. Conf. Sorrento, 2000), IAEA, Vienna (2001)).

a (III.16) = 0
** usual standard dataset
if  SELDB3 = 1111111111 then a (III.16) = 1
** only ELMy data
if substr(PHASE,1,1) H then a (III.16) = 0
if  PHASE = H then a (III.16) = 0
** exclude JET museums shots
if  TOK = JET and SHOT = 19971 then a (III.16) = 0
if  TOK = JET and SHOT = 43014 then a (III.16) = 0
** limit temperature ratio
a (III.16) = a (III.16) a (III.13)
** exclude high li shots
a (III.16) = a (III.16) a (III.14)
** exclude Ohmic H-mode data;
if AUXHEAT = NONE then a (III.16) = 0


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(c) EFDA Close Support Unit, Garching - last updated 16 April 2002.
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