-- -- PostgreSQL database dump -- SET statement_timeout = 0; SET lock_timeout = 0; SET client_encoding = 'UTF8'; SET standard_conforming_strings = on; SELECT pg_catalog.set_config('search_path', '', false); SET check_function_bodies = false; SET xmloption = content; SET client_min_messages = warning; ALTER TABLE ONLY public."PhysQuant" DROP CONSTRAINT "PhysQuant_Identifier_key"; DROP TABLE public."PhysQuant"; SET default_tablespace = ''; SET default_with_oids = false; -- -- Name: PhysQuant; Type: TABLE; Schema: public; Owner: golem; Tablespace: -- CREATE TABLE public."PhysQuant" ( "Identifier" text, "Description" text, "Latex" text, "Unit" text, "Relation symbol" text, "Value" text, "Uncertainty" text, "Comment" text, "Log" text, tag text, "Address" text ); ALTER TABLE public."PhysQuant" OWNER TO golem; -- -- Name: TABLE "PhysQuant"; Type: COMMENT; Schema: public; Owner: golem -- COMMENT ON TABLE public."PhysQuant" IS 'The GOLEM physical quantities'; -- -- Data for Name: PhysQuant; Type: TABLE DATA; Schema: public; Owner: golem -- COPY public."PhysQuant" ("Identifier", "Description", "Latex", "Unit", "Relation symbol", "Value", "Uncertainty", "Comment", "Log", tag, "Address") FROM stdin; r_VesselMajorRadius Vessel major radius R_0 m = 0.4 \N \N 0420 Automat import vessel,basic Tokamak/VacuumVessel/TechnologicalQuantities/MajorRadius r_VesselMinorRadius Vessel minor radius r_0 m = 0.1 \N \N 0420 Automat import vessel,basic Tokamak/VacuumVessel/TechnologicalQuantities/MinorRadius r_PlasmaMinorRadius Plasma minor radius a m \\approx 0.06 \N \N 0420 Automat import plasma Discharge/Plasma/PlasmaMinorRadius I_MaximumPlasmaCurrent Maximum plasma current I_{pl}^{max} kA < 8 \N \N 0420 Automat import plasma,basic /Discharge/Plasma/PlasmaCurrent/Maximum Z_EffectiveIonCharge Effective ion charge Z_eff \N \\approx 2.5 \N \N 0420 Automat import plasma,basic Discharge/Plasma/EffectiveIonCharge N_AspectRatio Aspect ratio \\varepsilon - = 0.25 \N \N 0420 Automat import vessel Tokamak/VacuumVessel/TechnologicalQuantities/AspectRatio r_LimiterRadius Limiter radius r_a m = 0.085 \N \N 0420 Automat import vessel Tokamak/VacuumVessel/TechnologicalQuantities/LimiterMinorRadius B_MaximumToroidalMagneticField Maximum toroidal magnetic field B_t^{max} T < 0.5 \N \N 0420 Automat import tokamak,basic Diagnostics/Standard/ToroidalMagneticField/Maximum n_TypicalElectronDensity Typical electron density e+19 m$^-3$ \\in (0.2,3) \N \N 0420 Automat import plasma Diagnostics/Standard/ElectronDensity S_ChamberSurface Chamber surface S_{ch} $m^2$ = 1.58 \N \N 0420 Automat import vessel Tokamak/VacuumVessel/TechnologicalQuantities/Surface V_ChamberVolume Chamber volume V_{ch} $m^3$ = 0.079 0.001 $(2*\\pi*R_0)*(\\pi*r_0^2)$ 0420 Automat import vessel Tokamak/VacuumVessel/TechnologicalQuantities/Volume V_PlasmaVolume Plasma volume V_{pl} $m^3$ \\approx 0.057 0.005 $(2*\\pi*R_0)*(\\pi*a^2)$ 0420 Automat import plasma Tokamak/Plasma/Geometricals/Volume R_VacuumChamberResistance Resistance of the vacuum chamber R_{ch} m$\\Omega$ \\approx 9.7 \N \N 2.2.20: from Golem I vessel,diagnostics Tokamak/VacuumVessel/TechnologicalQuantities/Resistance L_VacuumChamberInductance Inductance of the vacuum chamber L_{ch} $\\mu$H \\approx 0.55 \N \N 0420 Automat import vessel,diagnostics Tokamak/VacuumVessel/TechnologicalQuantities/Inductance L_BtCoil Inductance of the toroidal magnetic field coil L_{B_t} H = 0.0019 \N @ 1 kHz 2.8 mH podle Brotankové; 4.2.2020 M. Pfeifer, Escort ELC 131 D technology Tokamak/ToroidalMagneticFieldCoils/Characteristics/Inductance R_BtCoil Resistance of the toroidal magnetic field coil \N m\\Omega = 41.9 \N @ 1 kHz 61 mOhm dle Brotánkové;4.2.2020 M. Pfeifer, Escort ELC 131 D technology Tokamak/ToroidalMagneticFieldCoils/Characteristics/Resistance L_PrimaryTransformerCoil Primary Transformer Coil Inductance L_{CD} H = 0.0000018 \N @ 1 kHz 10.38 mH dle HonzyS, interni doc;4.2.2020 M. Pfeifer, Escort ELC 131 D technology Tokamak/Transformer/TransformerPrimaryCoils/CurrentDrive/Inductance R_PrimaryTransformerCoil Primary Transformer Coil Resistance R_{CD} \\Omega = 3.5 \N @ 1 kHz 3.5 Ohm je asi blbost, 45 mOhm dle HonzySt, interni doc;4.2.2020 M. Pfeifer, Escort ELC 131 D technology Tokamak/Transformer/TransformerPrimaryCoils/CurrentDrive/Resistance K_RogowskiCoil Rogowski Coil Calibration K_{RogCoil} A/Vs \\approx 5300000 \N \N \N diagnostics Diagnostics/Basic/PlasmaPlusChamberCurrent/Calibration K_BtCoil Bt coil calibration K_{BtCoil} T/Vs \\approx 70.42 \N \N 0311 according Tomas Markovic diagnostics Diagnostics/Basic/ToroidalMagneticField/Calibration C_CurrentDriveFieldCapacitorCapacity Capacity of the Current drive field capacitor C_CD F = 0.0135 \N \N 0420 Automat import infrastructure Infrastructure/CurrentDriveFieldCircuit/Capacitor/ActualCapacity C_ToroidalMagneticFieldCapacitorCapacity Capacity of the Toroidal magnetic field capacitor C_Bt F = 0.0675 \N \N 0420 Automat import infrastructure Infrastructure/ToroidalMagneticFieldCircuit/Capacitor/ActualCapacity U_ReglTrafo Regl Trafo Setup U_{ReglTrafo} U \N \N \N \N \N \N Infrastructure/Preionization/Thermoemission/ReglTrafo I_PreionizationHeaterCurrent Preionization Heater Current I_{preion} A = 5.5 \N \N #20000\t1.5;14.01.16: #205626\t5.5 zhorsilo se prorazeni do plazmatu DischargeSetup Infrastructure/Preionization/Thermoemission/PreionHeaterCurrent U_PreionizationHeaterVoltage Preionization Heater Voltage U_{preion} V = 84 \N \N #10000\t80;14.01.16: #20509 84 DischargeSetup Infrastructure/Preionization/Thermoemission/PreionHeaterVoltage t_ElectronEnergyConfinementTimeTypical (Electron) energy confinement time \\tau_e us \\approx 50 \N \N 0420 Automat import diagnostics Diagnostics/Standard/EnergyConfinementTime/Typical t_ElectronEnergyConfinementTime (Electron) energy confinement time \\tau_e us \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/EnergyConfinementTime/ B_PoloidalMagneticField Poloidal magnetic field B_p T \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/PoloidalMagneticField B_ToroidalMagneticField Toroidal magnetic field B_t T \N \N \N \N 0420 Automat import diagnostics Diagnostics/Basic/ToroidalMagneticField I_ChamberPlasmaCurrent Chamber+plasma current I_{ch+pl} kA \N \N \N \N 0420 Automat import diagnostics Diagnostics/Basic/ChamberPlusPlasmaCurrent I_PlasmaCurrent Plasma current I_{pl} kA \N \N \N \N 0420 Automat import diagnostics Diagnostics/Basic/PlasmaCurrent U_LoopVoltage Loop Voltage U_l V \N \N \N \N 0420 Automat import diagnostics Diagnostics/Basic/LoopVoltage I_ChamberCurrent Chamber current I_{ch} kA \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/ChamberCurrent R_PlasmaResistivity Plasma resistivity R_p $\\Omega$ \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/PlasmaResistivity P_HeatingPower Heating power P_{OH} kW \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/HeatingPower E_PlasmaEnergyVolume Plasma energy volume W_{pl} kJ \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/PlasmaEnergyVolume T_ElectronTemperature Electron temperature T_e eV \N \N \N \N 0420 Automat import diagnostics Discharge/Plasma/ElectronTemperature T_CentralElectronTemperatureSpitzerFormulae Central Electron temperature T_e^{Spitzer} eV \N \N \N \N 0420 Automat import plasma Diagnostics/Standard/ElectronTemperature/CentralElectronTemperatureSpitzerFormula T_IonTemperature Ion temperature T_i eV \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/IonTemperature T_MaximumElectronTemperature Maximum electron temperature T_e^max eV < 80 \N \N 0420 Automat import plasma Discharge/Plasma/ElectronTemperature/Maximum T_MaximumIonTemperature Maximum ion temperature T_i^{max} eV < 50 \N \N 0420 Automat import diagnostics Diagnostics/Standard/IonTemperature/Maximum t_DischargeDuration Discharge duration \\tau_p ms \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/DischargeDuration t_MaximumDischargeDuration Maximum discharge duration \\tau_p^{max} ms < 25 \N \N 0420 Automat import plasma Discharge/Plasma/TimeParameters/DischargeLength/Maximum t_ElectronEenergyConfinementTime (Electron) energy confinement time \\tau_e us \N \N \N \N 0420 Automat import diagnostics Diagnostics/Standard/EnergyConfinementTime U_PlasmaPotential Plasma potential \\Phi V \N \N \N \N 0420 Automat import diagnostics Discharge/Analysis/ProbeTechniques/PlasmaPotential U_FloatingPotential Floating Potential U_{fl} V \N \N \N \N \N diagnostics Discharge/Analysis/ProbeTechniques/FloatingPotential U_VoltageChargeCurrentDriveFieldCapacitor A voltage to charge the Current drive field $E_t$ capacitor U_E_t V \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/CurrentDriveFieldCircuit/Capacitor/ChargingVoltage U_VoltageRangeChargeCurrentDriveFieldCapacitor Voltage range to charge the Current drive field $E_t$ capacitor U_E_t^ V \\in (100,700) \N \N 0420 Automat import DischargeSetup Infrastructure/CurrentDriveFieldCircuit/Capacitor/ChargingVoltageRange U_RecommendedVoltageRangeChargeCurrentDriveFieldCapacitor Recommended voltage to charge the Current drive field $E_t$ capacitor U_{E_t}^{} V \\in (400,700) \N \N 0420 Automat import DischargeSetup Infrastructure/CurrentDriveFieldCircuit/Capacitor/ChargingVoltageRecommendation U_VoltageChargeToroidalMagneticFieldCapacitor A voltage to charge the Toroidal magnetic field $B_t$ capacitor U_{B_t} V \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/CurrentDriveFieldCircuit/Capacitor/ChargingVoltage U_VoltageRangeChargeToroidalMagneticFieldCapacitor Voltage range to charge the Toroidal magnetic field $B_t$ capacitor U_B_t^{} V \\in (100,1300) \N \N 0420 Automat import DischargeSetup Infrastructure/ToroidalMagneticFieldCircuit/Capacitor/ChargingVoltageRange U_RecommendedVoltageRangeChargeToroidalMagneticFieldCapacitor Recommended voltage to charge the Toroidal magnetic field $B_t$ capacitor U_B_t^{} V \\in (600,1200) \N \N 0420 Automat import DischargeSetup Infrastructure/ToroidalMagneticFieldCircuit/Capacitor/ChargingVoltageRecommendation p_HydrogenWorkingGasPressure A Hydrogen Working gas pressure p_{WG}^H mPa \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/H/Pressure p_HydrogenWorkingGasPressureRange A Hydrogen Working pressure range p_{WG}^{H} mPa \\in (0,60) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/H/PressureRange p_HydrogenRecommendedWorkingGasPressureRange Recommended Hydrogen Working pressure range p_{WG}^{H} mPa \\in (0,40) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/H/PressureRecommendation p_HeliumWorkingGasPressure A Helium Working gas pressure p_{WG}^{He} mPa \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/He/Pressure p_HeliumWorkingGasPressureRange A Helium Working pressure range p_{WG}^{He} mPa \\in (0,60) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/He/PressureRange p_HeliumRecommendedWorkingGasPressureRange Recommended Helium Working pressure range p_{WG}^{He} mPa \\in (0,40) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/He/PressureRecommendation p_ArgonWorkingGasPressure An Argon Working gas pressure p_{WG}^{Ar} mPa \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/Ar/Pressure p_ArgonWorkingGasPressureRange An Argon Working pressure range p_{WG}^{Ar} mPa \\in (0,60) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/D/PressureRange p_ArgonRecommendedWorkingGasPressureRange Recommended Argon Working pressure range p_{WG}^{Ar} mPa \\in (0,40) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/Ar/PressureRecommendation p_DeuteriumWorkingGasPressure A Deuterium Working gas pressure p_{WG}^D mPa \N \N \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/D/Pressure p_DeuteriumWorkingGasPressureRange A Deuterium Working pressure range p_{WG}^{D} mPa \\in (0,60) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/D/PressureRange p_DeuteriumRecommendedWorkingGasPressureRange Recommended Deuterium Working pressure range p_{WG}^{D} mPa \\in (0,40) \N \N 0420 Automat import DischargeSetup Infrastructure/GasManagement/WorkingGases/D/PressureRecommendation t_CurrentDriveTrigger Current Drive Trigger t_{CD} ms = 5 \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/CurrentDrive t_CurrentDriveTriggerRange Current Drive Trigger Range t_{CD}^{} ms = (0,100) \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/CurrentDriveRange t_CurrentDriveTriggerRecommendation Current Drive Trigger Recommended t_{CD}^{} ms = (5,50) \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/CurrentDriveRecommendation t_ToroidalMagneticFieldTrigger Toroidal Magnetic Field Trigger t_{Bt} ms = 5 \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/ToroidalMagneticField t_ToroidalMagneticFieldTriggerRange Toroidal Magnetic Field Trigger Range t_{Bt}^{} ms = (0,100) \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/ToroidalMagneticFieldRange t_ToroidalMagneticFieldTriggerRecommendation Toroidal Magnetic Field Trigger Recommended t_{Bt}^{} ms = (5,50) \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/ToroidalMagneticFieldRecommendation t_DASTrigger DAS Trigger t_{DAS} ms = 0 \N \N \N DischargeSetup Infrastructure/TriggerSystem/Sequence/DAS SafetyFactor Safety factor q - \N \N \N \N \N Analysis Diagnostics/Standard/SafetyFactor d_BallPen_CollectorDepth BallPen Collector Depth d_{CollectorDepth}^{BallPen} mm = 4.6 \N \N up to 221216 0.5 mm;221216: 2.25 mm uprava s Honzou Stockelem;050117: zbrouseno o dalsi 2 mm na 4.6 mm diagnostics Diagnostics/ParticleFlux/BallPenProbe/CollectorDepth l_BallPen_ManipulatorLength BallPenProbe Manipulator Length l_{manipulator}^{BallPen} mm = 232 \N Od priruby k vrsku sondy 221216: 332 mm s Honzou Stockelem, na noniu manipulatoru to odpovida 75 mm na meritku diagnostics Diagnostics/ParticleFlux/BallPenProbe/ManipulatorLength R_InnerQuadrupol Inner Quadrupol Resistance \N \\Omega = 0.1 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/InnerQuadrupol/Parameters/Resistance L_InnerQuadrupol Inner Quadrupol Inductance \N H = 0.000006 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/InnerQuadrupol/Parameters/Inductance R_OuterHorizontalStabiliationQuadrupol Outer Horizontal Stabiliation Quadrupol Resistance \N \\Omega = 3.4 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/Horizontal/Parameters/Resistance L_OuterHorizontalStabiliationQuadrupol Outer Horizontal Stabiliation Quadrupol Inductance \N H = 0.000130 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/Horizontal/Parameters/Inductance L_OuterVerticalStabiliationQuadrupol Outer Vertical Stabiliation Quadrupol Inductance \N H = 0.000105 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/Vertical/Parameters/Resistance R_OuterVerticalStabiliationQuadrupol Outer Horizontal Vertical Quadrupol Resistance \N \\Omega = 2.18 \N @ 1 kHz 4.2.2020 M. Pfeifer, Escort ELC 131 D stabilisation Infrastructure/Stabilization/Vertical/Parameters/Inductance \. -- -- Name: PhysQuant_Identifier_key; Type: CONSTRAINT; Schema: public; Owner: golem; Tablespace: -- ALTER TABLE ONLY public."PhysQuant" ADD CONSTRAINT "PhysQuant_Identifier_key" UNIQUE ("Identifier"); -- -- PostgreSQL database dump complete --