Component Variables

Content Type	Name	Description	Data Type	Unit	Min Value	Max Value	Default Value
constant	cAMDVST	Table of AMDVS as a function of DVS	DOUBLEARRAY		-	-	0.0 1.0 1.0 1.0 2.0 0.5 2.5 0.0
constant	cAMTMPT	Table of AMTMP as function of DDTMP	DOUBLEARRAY		-	-	-10.0 0.0 0.0 0.0 10.0 1.0 25.0 1.0 35.0 0.0 50.0 0.0
constant	cAMX	Potential CO 2 assimilation rate at light saturatPotential CO 2 assimilation rate at light saturation for individual leaveson for	DOUBLE	g m-2 s-1	-	-	0.00111
constant	cASRQLV	Assimilate requirement for leaf dry matter production	DOUBLE	g g-1	-	-	1.463
constant	cASRQRT	Assimilate requirement for root dry matter production	DOUBLE	g g-1	-	-	1.444
constant	cASRQSO	Assimilate requirement for storage organ dry matter production	DOUBLE	g g-1	-	-	1.415
constant	cASRQST	Assimilate requirement for stem dry matter production	DOUBLE	g g-1	-	-	1.513
constant	cCFLV	Mass fraction carbon in the leaves	DOUBLE	g g-1	-	-	0.459
constant	cCFRT	Mass fraction carbon in the roots	DOUBLE	g g-1	-	-	0.467
constant	cCFSO	Mass fraction carbon in the storage organs	DOUBLE	g g-1	-	-	0.471
constant	cCFST	Mass fraction carbon in the stems	DOUBLE	g g-1	-	-	0.494
constant	cCONVL	Conversion factor for remobilization of stem carbohydrates into glucose	DOUBLE		-	-	0.947
constant	cCompatibilityMode	compatibility mode for GLA calculation	BOOLEAN		-	-	true
constant	cDOYEM	latitude	INT	d	-	-	90
constant	cDVRRT	Table of DVR in post-anthesis phase as function of temperature	DOUBLEARRAY		-	-	-10.0 0.0 0.0 0.0 30.0 0.031
constant	cDVRVT	Table of DVR in pre-anthesis phase as function of temperature	DOUBLEARRAY		-	-	-10.0 0.0 0.0 0.0 30.0 0.027
constant	cEAR	Ear area/weight ratio	DOUBLE	m2 g-1	-	-	6.3E-4
constant	cEDPTFT	Table to read the root activity coefficient	DOUBLEARRAY		-	-	-0.5 0.0 -0.05 0.0 0.0 0.15 0.15 0.6 0.3 0.8 0.5 1.0 2.0 1.0
constant	cEES	Soil-specific extinction coefficient	DOUBLE	mm-1	-	-	0.002
constant	cEFF	Initial light conversion factor for individual leaves	DOUBLE	g J-1	-	-	1.25E-5
constant	cEZRTC	constantant for root elongation	DOUBLE	mm d-1	-	-	12.0
constant	cFDVRR	factor phenology post-anthesis	DOUBLE		-	-	1.0
constant	cFDVRV	factor phenology pre-anthesis	DOUBLE		-	-	1.0
constant	cFLVTB	Table of FLV as function of DVS	DOUBLEARRAY		-	-	0.0 0.65 0.1 0.65 0.25 0.7 0.5 0.5 0.7 0.15 0.95 0.0 2.5 0.0
constant	cFRDR	Parameter to determine rate of increase in RDR	DOUBLE		-	-	1.0
constant	cFRTRL	Fraction stem weight eventually translocated to storage organs	DOUBLE		-	-	0.2
constant	cFSHTB	Table of FSH as function of DVS	DOUBLEARRAY		-	-	0.0 0.5 0.1 0.5 0.2 0.6 0.35 0.78 0.4 0.83 0.5 0.87 0.6 0.9 0.7 0.93 0.8 0.95 0.9 0.97 1.0 0.98 1.1 0.99 1.2 1.0 2.5 1.0
constant	cFSOTB	Table of FSO as function of DVS	DOUBLEARRAY		-	-	0.0 0.0 0.95 0.0 1.05 1.0 2.5 1.0
constant	cFSTTB	Table of FST as function of DVS	DOUBLEARRAY		-	-	0.0 0.35 0.1 0.35 0.25 0.3 0.5 0.5 0.7 0.85 0.95 1.0 1.05 0.0 2.5 0.0
constant	cIDSLR	Initial of DSLR	DOUBLE	d	-	-	1.0
constant	cIDVS	Initial development stage	DOUBLE	-	-	-	0.0
constant	cIEAI	Initial ear area index	DOUBLE	m2 m-2	-	-	0.0
constant	cILAI	Initial leaf area index	DOUBLE	m2 m-2	-	-	0.012
constant	cINTC	Interception capacity of precipitation of 1 layer of leaves	DOUBLE	mm d-1	-	-	0.25
constant	cKDF	Extinction coefficient for leaves	DOUBLE	m2 ha-1	-	-	0.6
constant	cLAICR	Critical leaf area index beyond which death to self-shading occurs	DOUBLE	m2 m-2	-	-	4.0
constant	cLAT	latitude	DOUBLE	°	-	-	51.97
constant	cMAINLV	Maintenance respiration coefficient of leaves	DOUBLE	g g-1 d-1	-	-	0.03
constant	cMAINRT	Maintenance respiration coefficient of roots	DOUBLE	g g-1 d-1	-	-	0.015
constant	cMAINSO	Maintenance respiration coefficient of storage organs	DOUBLE	g g-1 d-1	-	-	0.01
constant	cMAINST	Maintenance respiration coefficient of stems	DOUBLE	g g-1 d-1	-	-	0.015
constant	cMDRATE	Maximum drainage rate of the subsoil	DOUBLE	mm d-1	-	-	50.0
constant	cQ10	Factor accounting for increase in maintenance respiration with a 10 °C rise temperature	DOUBLE		-	-	2.0
constant	cRGRL	Relative growth rate of leaf area during exponential growth	DOUBLE	°C-1 d-1	-	-	0.009
constant	cSCP	Scattering coefficient of leaves for PAR	DOUBLE		-	-	0.2
constant	cSLA	Specific leaf area	DOUBLE	m2 g-1	-	-	0.022
constant	cTBASE	Base temperature for juvenile leaf area growth	DOUBLE	°C	-	-	0.0
constant	cTKL1	Thickness of the soil layer 1	DOUBLE	mm	-	-	200.0
constant	cTKL2	Thickness of the soil layer 2	DOUBLE	mm	-	-	400.0
constant	cTKL3	Thickness of the soil layer 3	DOUBLE	mm	-	-	600.0
constant	cTKL4	Thickness of the soil layer 4	DOUBLE	mm	-	-	800.0
constant	cTRANSC	Characteristic potential transpiration rate (see Table 2.2)	DOUBLE	mm d-1	-	-	9.0
constant	cTREF	Reference temperature	DOUBLE	°C	-	-	25.0
constant	cWCAD1	Volumetric water content in each soil layer at dry air	DOUBLE	cm3 cm-3	-	-	0.025
constant	cWCAD2	Volumetric water content in each soil layer at dry air	DOUBLE	cm3 cm-3	-	-	0.025
constant	cWCAD3	Volumetric water content in each soil layer at dry air	DOUBLE	cm3 cm-3	-	-	0.025
constant	cWCAD4	Volumetric water content in each soil layer at dry air	DOUBLE	cm3 cm-3	-	-	0.025
constant	cWCFC1	Volumetric water content at field capacity in each soil layer	DOUBLE	cm3 cm-3	-	-	0.23
constant	cWCFC2	Volumetric water content at field capacity in each soil layer	DOUBLE	cm3 cm-3	-	-	0.23
constant	cWCFC3	Volumetric water content at field capacity in each soil layer	DOUBLE	cm3 cm-3	-	-	0.23
constant	cWCFC4	Volumetric water content at field capacity in each soil layer	DOUBLE	cm3 cm-3	-	-	0.23
constant	cWCLI1	Initial value for WCL1	DOUBLE	cm3 cm-3	-	-	0.2
constant	cWCLI2	Initial value for WCL2	DOUBLE	cm3 cm-3	-	-	0.2
constant	cWCLI3	Initial value for WCL3	DOUBLE	cm3 cm-3	-	-	0.2
constant	cWCLI4	Initial value for WCL4	DOUBLE	cm3 cm-3	-	-	0.2
constant	cWCST1	Volumetric water content at saturation in each soil layer	DOUBLE	cm3 cm-3	-	-	0.4
constant	cWCST2	Volumetric water content at saturation in each soil layer	DOUBLE	cm3 cm-3	-	-	0.4
constant	cWCST3	Volumetric water content at saturation in each soil layer	DOUBLE	cm3 cm-3	-	-	0.4
constant	cWCST4	Volumetric water content at saturation in each soil layer	DOUBLE	cm3 cm-3	-	-	0.4
constant	cWCWET1	Volumetric water content where water logging begins	DOUBLE	cm3 cm-3	-	-	0.35
constant	cWCWET2	Volumetric water content where water logging begins	DOUBLE	cm3 cm-3	-	-	0.35
constant	cWCWET3	Volumetric water content where water logging begins	DOUBLE	cm3 cm-3	-	-	0.35
constant	cWCWET4	Volumetric water content where water logging begins	DOUBLE	cm3 cm-3	-	-	0.35
constant	cWCWP1	Volumetric water content at wilting point in each soil layer	DOUBLE	cm3 cm-3	-	-	0.075
constant	cWCWP2	Volumetric water content at wilting point in each soil layer	DOUBLE	cm3 cm-3	-	-	0.075
constant	cWCWP3	Volumetric water content at wilting point in each soil layer	DOUBLE	cm3 cm-3	-	-	0.075
constant	cWCWP4	Volumetric water content at wilting point in each soil layer	DOUBLE	cm3 cm-3	-	-	0.075
constant	cWLVDI	Initial value for WLVD	DOUBLE	g m-2	-	-	0.0
constant	cWLVI	Initial dry weight of the leaves	DOUBLE	g m-2	-	-	0.5
constant	cWRTI	Initial dry weight of the roots	DOUBLE	g m-2	-	-	0.8
constant	cWSOI	Initial value for WSO	DOUBLE	g m-2	-	-	0.0
constant	cWSTI	Initial value for WST	DOUBLE	g m-2	-	-	0.3
constant	cZRTI	Initial value for ZRT	DOUBLE	mm	-	-	5.0
constant	cZRTMC	Maximum value for rooted depth as crop characteristic	DOUBLE	mm	-	-	1200.0
constant	cZRTMS	Maximum value for rooted depth as soil characteristic	DOUBLE	mm	-	-	1200.0
input	iATRANS	Total actual transpiration rate of the canopy	DOUBLE	mm d-1	-	-	0.0
input	iIDEV	DevStage from Lintul.Phenology	DOUBLE	mm d-1	-	-	0.0
input	iPTRANS	Potential transpiration rate derived from Penman evaporation	DOUBLE	mm d-1	-	-	0.0
input	iRAIN	Daily precipitation (from AB/TPE weather system)	DOUBLE		-	-	0.0
input	iRDD	Daily solar radiation	DOUBLE	J m-2 d-1	-	-	0.0
input	iTMMN	Daily minimum temperature (from AB/TPE weather system)	DOUBLE	°	-	-	0.0
input	iTMMX	Daily maximum temperature (from AB/TPE weather system)	DOUBLE	°	-	-	0.0
input	iVP	Actual vapour pressure (from AB/TPE weather system)	DOUBLE	kPa	-	-	0.0
input	iWN	Wind speed (from AB/TPE weather system)	DOUBLE	m s-1	-	-	0.0
state	sDSLR	Number of days since last rain	DOUBLE	d	-	-	0.0
state	sDVS	Development stage of the crop	DOUBLE	-	-	-	0.0
state	sEAI	Ear area index	DOUBLE	m2 m-2	-	-	0.0
state	sLAI	Leaf area index	DOUBLE	m2 m-2	-	-	0.0
state	sTAEVAP	Cumulative actual soil evaporation	DOUBLE	mm	-	-	0.0
state	sTAINTC	Total amount of rainfall intercepted by the canopy	DOUBLE	mm	-	-	0.0
state	sTATRAN	Total amount of water transpired by the crop	DOUBLE	mm	-	-	0.0
state	sTDRAIN	Total drainage	DOUBLE	mm	-	-	0.0
state	sTDTGA	Total gross CO 2 assimilation of the crop	DOUBLE	g m-2	-	-	0.0
state	sTEVAPD	Cumulative potential soil evaporation due to drying power of the air	DOUBLE	mm	-	-	0.0
state	sTEVAPR	Cumulative potential soil evaporation due to radiation	DOUBLE	mm	-	-	0.0
state	sTNASS	Total net CO 2 assimilation	DOUBLE	g m-2	-	-	0.0
state	sTPENM	Cumulative potential evapotranspiration	DOUBLE	mm	-	-	0.0
state	sTPEVAP	Cumulative potential ecaporatio	DOUBLE	mm	-	-	0.0
state	sTPTRAN	Cumulative actual soil evaporation	DOUBLE	mm	-	-	0.0
state	sTRAIN	Total precipitation	DOUBLE	mm	-	-	0.0
state	sTRNOFF	Total runoff	DOUBLE	mm	-	-	0.0
state	sWL1	Amount of water in soil compartment 1	DOUBLE	mm	-	-	0.0
state	sWL2	Amount of water in soil compartment 2	DOUBLE	mm	-	-	0.0
state	sWL3	Amount of water in soil compartment 3	DOUBLE	mm	-	-	0.0
state	sWL4	Amount of water in soil compartment 4	DOUBLE	mm	-	-	0.0
state	sWLVD	Dry weight of dead leaves	DOUBLE	g m-2	-	-	0.0
state	sWLVG	Dry weight of green leaves	DOUBLE	g m-2	-	-	0.0
state	sWRT	Dry weight of the roots	DOUBLE	g m-2	-	-	0.0
state	sWSO	Dry weight of storage organs	DOUBLE	g m-2	-	-	0.0
state	sWST	Dry weight of the stems	DOUBLE	g m-2	-	-	0.0
state	sZRT	Rooted depth	DOUBLE	mm	-	-	0.0
rate	rAEVAP	Actual soil evaporation rate, derived from Penman evaporation	DOUBLE	mm d-1	-	-	0.0
rate	rAINTC	Actual amount of precipitation intercepted by the canopy	DOUBLE	mm d-1	-	-	0.0
rate	rDLV	Death rate of leaves	DOUBLE	g m-2 d-1	-	-	0.0
rate	rDRAIN	Drainage rate below the root zone	DOUBLE	mm d-1	-	-	0.0
rate	rDTGA	Daily total gross CO 2 assimilation of the crop	DOUBLE	g m-2 d-1	-	-	0.0
rate	rDVR	Development rate	DOUBLE	d-1	-	-	0.0
rate	rEVAPD	Potential soil evaporation due to drying power of the air	DOUBLE	mm d-1	-	-	0.0
rate	rEVAPR	Potential soil evaporation due to radiation	DOUBLE	mm d-1	-	-	0.0
rate	rEZRT	Rate of root elogation	DOUBLE	mm d-1	-	-	0.0
rate	rGRT	Dry matter growth rate of roots	DOUBLE	g m-2 d-1	-	-	0.0
rate	rGSO	Dry matter growth rate of storage organs	DOUBLE	g m-2 d-1	-	-	0.0
rate	rGST	Dry matter growth rate of stems	DOUBLE	g m-2 d-1	-	-	0.0
rate	rPENMAN	Penman reference value for potential evaporation	DOUBLE	mm d-1	-	-	0.0
rate	rPEVAP	Potential soil evaporation	DOUBLE	mm d-1	-	-	0.0
rate	rRDSLR	Day with no rain	DOUBLE	d d-1	-	-	0.0
rate	rREAI	Growth rate ear area index	DOUBLE	m2 m-2 d-1	-	-	0.0
rate	rRLAI	Growth rate leaf area index	DOUBLE	m2 m-2 d-1	-	-	0.0
rate	rRNOFF	Runoff	DOUBLE	mm d-1	-	-	0.0
rate	rRRAIN	Daily precipitation	DOUBLE	mm d-1	-	-	0.0
rate	rRTNASS	net CO 2 assimilation rate	DOUBLE	g m-2 d-1	-	-	0.0
rate	rRWL1	Rate of increase for WL1	DOUBLE	mm d-1	-	-	0.0
rate	rRWL2	Rate of increase for WL2	DOUBLE	mm d-1	-	-	0.0
rate	rRWL3	Rate of increase for WL3	DOUBLE	mm d-1	-	-	0.0
rate	rRWL4	Rate of increase for WL4	DOUBLE	mm d-1	-	-	0.0
rate	rRWLVG	Green leaf growth rate	DOUBLE	g m-2 d-1	-	-	0.0
out	CHECK	Variable to check the water balance (should be zero)	DOUBLE	mm	-	-	0.0
out	CHKDIF	Difference between carbon added to the crop since initialization and the net total of integrated carbon fluxes, relative to their sum	DOUBLE	g m-2	-	-	0.0
out	CPEW	reduction partitioning	DOUBLE		-	-	0.0
out	CROPF	Crop factor for crop water requirement	DOUBLE		-	-	0.0
out	DAVTMPXX	Weight of green and dead leaves	DOUBLE	g m-2	-	-	0.0
out	DS0	Daily extraterrestrial radiation	DOUBLE	J m-2 s-1	-	-	0.0
out	DVS	development stage	DOUBLE	g m-2	-	-	0.0
out	EMERGXX	Weight of green and dead leaves	DOUBLE	g m-2	-	-	0.0
out	GPHOT	assimilation	DOUBLE	g m-2 d-1	-	-	0.0
out	HI	Harvest index	DOUBLE	g g-1	-	-	0.0
out	PCEW	reduction assimilation	DOUBLE		-	-	0.0
out	TADRW	Total above ground biomass	DOUBLE	g m-2	-	-	0.0
out	TDRW	Total biomass	DOUBLE	g m-2	-	-	0.0
out	TKLT	Sum of thickness of the soil layers	DOUBLE	mm	-	-	0.0
out	TNASSI	Initial value of TNASS	DOUBLE	g m-2	-	-	0.0
out	WCUMI	Initial value for WCUM	DOUBLE	mm	-	-	0.0
out	WL1I	Initial amount for WL1	DOUBLE	mm	-	-	0.0
out	WL2I	Initial amount for WL2	DOUBLE	mm	-	-	0.0
out	WL3I	Initial amount for WL3	DOUBLE	mm	-	-	0.0
out	WL4I	Initial amount for WL4	DOUBLE	mm	-	-	0.0
out	WLV	Weight of green and dead leaves	DOUBLE	g m-2	-	-	0.0
out	ZRTM	Maximum value for rooted depth	DOUBLE	mm	-	-	0.0
out	oFLV	assimilation	DOUBLE	g m-2 d-1	-	-	0.0
out	oFRT	assimilation	DOUBLE	g m-2 d-1	-	-	0.0
out	oFSO	assimilation	DOUBLE	g m-2 d-1	-	-	0.0
out	oFST	assimilation	DOUBLE	g m-2 d-1	-	-	0.0
out	oMAINT	assimilation	DOUBLE	g m-2 d-1	-	-	0.0

Nested Class Summary

Nested classes/interfaces inherited from class net.simplace.sim.model.FWSimComponent
net.simplace.sim.model.FWSimComponent.TEST_STATE
Field Summary

Fields inherited from class net.simplace.sim.model.FWSimComponent
iFieldMap, iFrequence, iInputMap, iJexlRule, iMasterComponentGroup, iName, iOrderNumber, isComponentGroup, iSimComponentElement, iSimModel, iVarMap
Constructor Summary

Constructors

Constructor

Description

Sucros2Crop()

Empty constructor used by class.forName()
Method Summary

Modifier and Type

Method

Description

protected void

calculateRates()

protected net.simplace.sim.model.FWSimComponent

clone(net.simplace.sim.util.FWSimVarMap aVarMap)

/** creates a clone from this SimComponent for use in other threads

HashMap<String,net.simplace.sim.util.FWSimVariable<?>>

createVariables()

Create the FWSimVariables as interface for this SimComponent

HashMap<String,net.simplace.sim.util.FWSimVariable<?>>

fillTestVariables(int aParamIndex, net.simplace.sim.model.FWSimComponent.TEST_STATE aDefineOrCheck)

called for single component test to check the components algorithm.

protected void

init()

Initializes the fields by getting input and output FWSimVariables from VarMap

void

initializeVariables()

protected void

integrateStates()

protected void

process()

Process the algorithm and write the results back to VarMap

Methods inherited from class net.simplace.sim.model.FWSimComponent
addVariable, bind, checkCondition, createSimComponent, createSimComponent, createSimComponent, createSimComponent, doProcess, getConstantVariables, getContentType, getCreateFormXML, getDescription, getEditFormXML, getFieldMap, getFrequence, getFrequenceRuleScript, getInputs, getInputVariables, getMasterComponentGroup, getName, getOrderNumber, getOutputVariables, getVariable, getVariableField, getVarMap, initialize, isConditionCheck, isVariableAvailable, performLinks, performLinks, readInputs, removeVariable, reset, runComponentTest, setVariablesDefault, toComponentLinkingXML, toDocXML, toGroupXML, toOutputDefinitionXML, toResourcesDataXML, toResourcesDefinitionXML, toString, toXML, writeVarInfos

Methods inherited from class java.lang.Object
clone, equals, finalize, getClass, hashCode, notify, notifyAll, wait, wait, wait

Constructor Details
- Sucros2Crop
  
  public Sucros2Crop()
  
  Empty constructor used by class.forName()
Method Details
- createVariables
  
  public HashMap<String,net.simplace.sim.util.FWSimVariable<?>> createVariables()
  
  Create the FWSimVariables as interface for this SimComponent
  Specified by:
  
  createVariables in interface net.simplace.sim.util.FWSimFieldContainer
  
  Specified by:
  
  createVariables in class net.simplace.sim.model.FWSimComponent
  
  See Also:
  
  net.simplace.simulation.model.FWSimComponent#createVariables()
- init
  
  protected void init()
  
  Initializes the fields by getting input and output FWSimVariables from VarMap
  Specified by:
  
  init in class net.simplace.sim.model.FWSimComponent
  
  See Also:
  
  net.simplace.simulation.model.FWSimComponent#init()
- initializeVariables
  
  public void initializeVariables()
- process
  
  protected void process()
  
  Process the algorithm and write the results back to VarMap
  Specified by:
  
  process in class net.simplace.sim.model.FWSimComponent
  
  See Also:
  
  net.simplace.simulation.model.FWSimComponent#process()
- calculateRates
  
  protected void calculateRates()
- integrateStates
  
  protected void integrateStates()
- fillTestVariables
  
  public HashMap<String,net.simplace.sim.util.FWSimVariable<?>> fillTestVariables(int aParamIndex, net.simplace.sim.model.FWSimComponent.TEST_STATE aDefineOrCheck)
  
  called for single component test to check the components algorithm.
  Specified by:
  
  fillTestVariables in class net.simplace.sim.model.FWSimComponent
  
  See Also:
  
  net.simplace.sim.util.FWSimFieldContainer#fillTestVariables(int aParamIndex, TEST_STATE aDefineOrCheck)
- clone
  
  protected net.simplace.sim.model.FWSimComponent clone(net.simplace.sim.util.FWSimVarMap aVarMap)
  
  /** creates a clone from this SimComponent for use in other threads
  Specified by:
  
  clone in class net.simplace.sim.model.FWSimComponent
  
  See Also:
  
  net.simplace.simulation.model.FWSimComponent#clone(net.simplace.simulation.util.FWSimVarMap)

Class Sucros2Crop

Component Variables

Nested Class Summary

Nested classes/interfaces inherited from class net.simplace.sim.model.FWSimComponent

Field Summary

Fields inherited from class net.simplace.sim.model.FWSimComponent

Constructor Summary

Method Summary

Methods inherited from class net.simplace.sim.model.FWSimComponent

Methods inherited from class java.lang.Object

Constructor Details

Sucros2Crop

Method Details

createVariables

init

initializeVariables

process

calculateRates

integrateStates

fillTestVariables

clone