net.simplace.sim.model.FWSimComponent

net.simplace.sim.components.experimental.lintulcc.LintulCC

All Implemented Interfaces:: net.simplace.sim.util.FWSimFieldContainer

public class LintulCC extends net.simplace.sim.model.FWSimComponent

LintulCC - Calculates Biomass by photosynthesis.

LintulCC Rodriguez et al., 2001) originaly is a standalone crop model which simulate crop growth processes, biomass, and yield. This model is different from other crop models (in SIMPLACE) in term of:

simulating phenology by keep track the number of leaf at main stem using phyllochron concept (Muholland et al., 1997)
photosynthesis is calculated using Farquhar model (Farquhar et al., 1982) coupling with stomatal conductance model from Leuning (Leuning, 1995)
evaporative demand (potential evapotranspiration) is calculated using Penman-Monteith model with explicit use of canopy resistance
photosynthesis and stomatal conductance could be simulated at sub-daily using the disaggregated daily weather (using sine curve approach);
photosynthesis and stomatal conductance are simulated separately for sunlit and shaded leaves considering the light direct, diffuse, and scattered light.

Further detail information, modeling approaches, and equations can be found in Chapter 1 of the LintulCC and Extensions documentation (pdf).

References

Farquhar, G. D. and Caemmerer, S. Von: Modelling of Photosynthetic Response to Environmental Conditions, in Physiological Plant Ecology II, edited by O. L. Lange, pp. 550–582, Springer-Verlag Berlin Heidelberg., 1982.

Leuning, R.: A critical appraisal of a combined stomatal-photosynthesis model for C3 plants, Plant Cell Environ., 18(4), 339–355, doi:10.1111/j.1365-3040.1995.tb00370.x, 1995.

Mulholland B. J., Craigon J., Black C.R., Stokes D.T., Zhang P., Colls J.J, Atherton J.G. 1997. Timing of critical developmental stages and leaf production in field-grown spring wheat for use in crop models. Journal of Agricultural Science, Cambridge (129), 155-161

Rodriguez, D., Ewert, F., Goudriaan, J., Manderscheid, R., Burkart, S., and Weigel, H. J.: Modelling the response of wheat canopy assimilation to atmospheric CO2 concentrations, New Phytol., 150, 337–346, https://doi.org/10.1046/j.1469-8137.2001.00106.x, 2001

Author:

G. Krauss, Thuy Nguyen

See Also:

LintulCCFunctions

Component Variables

Content Type	Name	Description	Data Type	Unit	Min Value	Max Value	Default Value
constant	cA	Parameter in the Angtrom formular	DOUBLE	1	-	-	1.35
constant	cB	Parameter in the Angtrom formular	DOUBLE	1	-	-	-0.35
constant	cCO2A	Atmospheric CO2 concentration	DOUBLE	μmol/mol	-	-	0.0
constant	cDOYEM	Day of year of crop emergency. If not set, then emergence will occur on the DOY where iDoSow is true.	INT	d	-	-	-
constant	cEAKMC	Energy activation for Michaelis-mentent constant for CO2	DOUBLE	J mol-1	-	-	79430.0
constant	cEAKMO	Energy activation for Michaelis-mentent constant for CO2	DOUBLE	J mol-1	-	-	36380.0
constant	cEAVCMX	Energy activation for maximimum carboxylation rate of Rubisc	DOUBLE	J mol-1	-	-	65330.0
constant	cGFDUR	Thermal time time of grain filling duration (from anthesis to maturity or harvest)	DOUBLE	°C d	-	-	-
constant	cHeatStressTableFactor	Heat stress factor as function of temperature (c.f. TMPTB)	DOUBLEARRAY	1	-	-	0.5 0.5 1.0 1.0 0.5 0.0
constant	cHeatStressTableTemperature	Temperature (tmax - .25*(tmax-tmin)) for heat stress factor (c.f. TMPTB)	DOUBLEARRAY	°C	-	-	0.0 8.0 10.0 29.0 35.0 40.0
constant	cILAI	Initial value of LAI	DOUBLE	m2/m2	-	-	0.0
constant	cILPN	Initial value of number of leaf primordia	DOUBLE	1	-	-	0.0
constant	cIRRIG	Irrigation switch (1 irrigation on and 0 is off)	BOOLEAN	1	-	-	false
constant	cIWLVG	Initial value of dry weight of green leaf	DOUBLE	g/m2	-	-	0.0
constant	cIWRT	Initial value of dry weight of root	DOUBLE	g/m2	-	-	0.0
constant	cIWSO	Initial value of dry weight of organ	DOUBLE	g/m2	-	-	0.0
constant	cIWST	Initial value of dry weight of stem	DOUBLE	g/m2	-	-	0.0
constant	cJMUMOL	Conversion energy from radiation to mole photon	DOUBLE	mol MJ-1	-	-	4.56
constant	cKC25	CO2 turnover rate of Rubisco at 25°C (micromol CO2 g-1 Rubisco s-1)	DOUBLE	micromol g-1 s-1	-	-	2.0
constant	cKDF	Extinction coefficient of leaf for diffuse flux	DOUBLE	1	-	-	-
constant	cKMC25	Michaelis-Menten constant for CO2 at temperature 25°C	DOUBLE	μmol/mol	-	-	404.9
constant	cKMO25	Michaelis-Menten constant for O2 at temperature 25°C	DOUBLE	μmol/mol	-	-	278.4
constant	cLAICR	Critical leaf area index	DOUBLE	m2/m2	-	-	4.0
constant	cLAT	Latitude of the weather station	DOUBLE	°	-	-	0.0
constant	cLeavesPartitioningTableFraction	Fraction of total dry matter to leaves as function of DVS (c.f. PCLTB)	DOUBLEARRAY	1	-	-	0.325 0.325 0.48 0.48
constant	cLeavesPartitioningTableTsum	Tsum for fraction of total dry matter to leaves (c.f. PCLTB)	DOUBLEARRAY	°C d	-	-	0.0 100.0 265.0 670.0
constant	cMAINLV	Maintenance respiration coefficient of leaves, g CH2O g-1 DM d-1	DOUBLE	g/g	-	-	-
constant	cMAINRT	Maintenance respiration coefficient of root, g CH2O g-1 DM d-1	DOUBLE	g/g	-	-	-
constant	cMAINSO	Maintenance respiration coefficient of organ, g CH2O g-1 DM d-1	DOUBLE	g/g	-	-	-
constant	cMAINST	Maintenance respiration coefficient of stems, g CH2O g-1 DM d-1	DOUBLE	g/g	-	-	-
constant	cMODDTR	Factor to modify daily solar radiation	DOUBLE	1	-	-	1.0
constant	cMODTMP	Temperature increment to modify daily temperature	DOUBLE	°C	-	-	0.0
constant	cMaxSLA	Maximum Specific leaf area	DOUBLE	m2/g	-	-	0.03
constant	cMinSLA	Mininum Specific leaf area	DOUBLE	m2/g	-	-	0.017
constant	cO2	Atmospheric O2 concentration	DOUBLE	μmol/mol	-	-	0.0
constant	cPCLTB	Fraction table for leaves	DOUBLEARRAY	1	-	-	-
constant	cPCRTB	Fraction table for roots	DOUBLEARRAY	1	-	-	-
constant	cPOTGGR	-	DOUBLE	1	-	-	-
constant	cPsiC	Psychromatic instrument constant	DOUBLE	kPa °C-1	-	-	0.066
constant	cQ10	Factor acounting for increase in maintance respiration with a 10°C rise temperature	DOUBLE	1	-	-	-
constant	cRGRL	Relative growth rate of leaf area during exponential growth	DOUBLE	(°C d)-1	-	-	-
constant	cRbound	Boundary layer resistance	DOUBLE	s m-1	-	-	7.0
constant	cRoCp	Volumetric heat capacity	DOUBLE	MJ m-3 °C-1	-	-	0.0012
constant	cRootsPartitioningTableFraction	Fraction of total dry matter to roots as function of DVS (c.f. PCRTB)	DOUBLEARRAY	1	-	-	0.5 0.5 0.35 0.35
constant	cRootsPartitioningTableTsum	Tsum for fraction of total dry matter to roots (c.f. PCRTB)	DOUBLEARRAY	°C d	-	-	0.0 100.0 265.0 670.0
constant	cSAINTC	Switch for rain interception calculation (0 no intercept, 1 intercept)	DOUBLE	1	-	-	0.0
constant	cSCP	Scattering coefficients of leaf for PAR	DOUBLE	1	-	-	0.2
constant	cSRNOFF	Switch for runoff calculation (0 no runoff, 1 runoff)	DOUBLE	1	-	-	0.0
constant	cTBASE	Base temperature	DOUBLE	°C	-	-	0.0
constant	cTKL	Thickness of the soil layers	DOUBLEARRAY	mm	-	-	-
constant	cTMPTB	Table for heatstress factor	DOUBLEARRAY	1	-	-	-
constant	cTTSSE	Temperature sum from sowing to emegerce	DOUBLE	°C d	-	-	-
constant	cWCAD	Volumetric water content in each soil layer at dry air	DOUBLEARRAY	cm3/cm3	-	-	-
constant	cWCFC	Volumetric water content at field capacity in each soil layer	DOUBLEARRAY	cm3/cm3	-	-	-
constant	cWCLI	Initial value of water content in each layer WCL	DOUBLEARRAY	cm3/cm3	-	-	-
constant	cWCST	Volumetric water content at saturation in each soil layer	DOUBLEARRAY	cm3/cm3	-	-	-
constant	cWCWP	Volumetric water content at wilting point in each soil layer	DOUBLEARRAY	cm3/cm3	-	-	-
input	iDoHarvest	-	BOOLEAN	-	-	-	false
input	iDoSow	-	BOOLEAN	-	-	-	false
input	iRAIN	Daily precipitation	DOUBLE	mm/d	-	-	0.0
input	iRDD	Daily global radiation	DOUBLE	J/m2	-	-	0.0
input	iRootLengthDensityPerLayer	Root length density	DOUBLEARRAY	cm/cm3	-	-	-
input	iTMMN	Daily minimum temperature	DOUBLE	°C	-	-	0.0
input	iTMMX	Daily maximum temperature	DOUBLE	°C	-	-	0.0
input	iVP	Actual vapour pressure	DOUBLE	kPa	-	-	0.0
input	iWN	Wind speed	DOUBLE	m s-1	-	-	-
state	sCAEVAP	Total actual evapotranspiration	DOUBLE	mm	-	-	0.0
state	sCAINTC	Actual amount of precipitation intercepted by the canopy	DOUBLE	mm	-	-	0.0
state	sCDRAIN	Total drainage	DOUBLE	mm	-	-	0.0
state	sCRNOFF	Total water runoff	DOUBLE	mm	-	-	0.0
state	sCRRAIN	Total precipitation	DOUBLE	mm	-	-	0.0
state	sCTRANS	Total transpiration	DOUBLE	mm	-	-	0.0
state	sDVS	Development stage of crop (from 0 to 2)	DOUBLE	1	0.0	-	0.0
state	sLAI	Leaf area index	DOUBLE	m2/m2	-	-	0.0
state	sMSLN	Main stem leaf number	DOUBLE	1	-	-	0.0
state	sMSLPN	Main stem leaf perimodia number	DOUBLE	1	-	-	0.0
state	sPARSUM	Photosynthesis active radiation sum	DOUBLE	J/m2	-	-	0.0
state	sTSUM	Thermal time degree	DOUBLE	°C d	-	-	0.0
state	sWLVG	Dry weight of green leaf	DOUBLE	g/m2	-	-	0.0
state	sWRT	Dry weight of root	DOUBLE	g/m2	-	-	0.0
state	sWSO	Dry weight of organ	DOUBLE	g/m2	-	-	0.0
state	sWST	Dry weight of stem	DOUBLE	g/m2	-	-	0.0
rate	rAEVAP	Actual soil evaporation rate derived from Penman evaporation	DOUBLE	mm/d	-	-	0.0
rate	rAINTC	Daily precipitation intercepted by the canopy	DOUBLE	mm/d	-	-	0.0
rate	rATRANS	Daily actual transpiration	DOUBLE	mm/d	-	-	0.0
rate	rDRAIN	Drainage rate below the root zone	DOUBLE	mm/d	-	-	0.0
rate	rDVR	Rate of phenological development	DOUBLE	1	-	-	0.0
rate	rPAR	Instantaneous flux of photosynthesis active radiation	DOUBLE	J/(m2 s)	-	-	0.0
rate	rRLAI	Daily change of green leaf area LAI	DOUBLE	m2/(m2 d)	-	-	0.0
rate	rRLE	Rate change of leaf appearance	DOUBLE	d-1	-	-	0.0
rate	rRLPI	Rate change of leaf primordia	DOUBLE	d-1	-	-	0.0
rate	rRNOFF	Daily runoff	DOUBLE	mm/d	-	-	0.0
rate	rRRAIN	Daily precipitation	DOUBLE	mm/d	-	-	0.0
rate	rRTSUM	Rate change of thermal time degree	DOUBLE	°C d	-	-	0.0
rate	rRWLVG	Daily change of dry weight of leaf /Dry matter growth rate of leaf	DOUBLE	g/m2	-	-	0.0
rate	rRWRT	Daily change of dry weight of root /Dry matter growth rate of root	DOUBLE	g/m2	-	-	0.0
rate	rRWSO	Daily change of dry weight of organ /Dry matter growth rate of organ	DOUBLE	g/m2	-	-	0.0
rate	rRWST	Daily change of dry weight of stem /Dry matter growth rate of stem	DOUBLE	g/m2	-	-	0.0
out	ALB	Albedo, reflection coefficient for short-ware radiation	DOUBLE	1	-	-	0.0
out	ALBS	Albedo, reflection coefficient for soil surface	DOUBLE	1	-	-	0.0
out	AMAXshade	Light saturated leaf photosynthetic of shaded leaf	DOUBLE	g/(m2 s)	-	-	0.0
out	AMAXsun	Light saturated leaf photosynthetic of sunlit leaf	DOUBLE	g/(m2 s)	-	-	0.0
out	AWPAW	Available plant water (cumulative water devides to total soil thickness)	DOUBLE	1	-	-	0.0
out	AnthesisDOY	DOY of Anthesis	INT	1	1	366	-
out	AnthesisDate	Date of Anthesis	DATE	1	-	-	-
out	BBRAD	Black body radiation	DOUBLE	J/(m2 s)	-	-	0.0
out	CATRANS	Cumulative actual transpiration	DOUBLE	mm	-	-	0.0
out	CDSF1	Cumulative water stress factor reduces grain yield	DOUBLE	1	-	-	0.0
out	CO2Ishade	CO2 concentration of shaded leaf	DOUBLE	μmol/mol	-	-	0.0
out	CO2Isun	CO2 concentration of sunlit leaf	DOUBLE	μmol/mol	-	-	0.0
out	CROPHT	Crop height	DOUBLE	m	-	-	0.0
out	CROPlimit	Estimate of water uptake that limited by PTRAN at each soil layer	DOUBLE	mm/d	-	-	0.0
out	CUMREMOB	Cumulative mobilized assimilated from stem to grain	DOUBLE	g/m2	-	-	0.0
out	CropCycleCount	Number of finished crop cycles, incremented at harvest	INT	1	0	1000	0
out	DAE	Day after emergency	INT	d	-	-	0
out	DANTH	Day of anthesis	INT	d	-	-	0
out	DAVTMP	Daily average temperature	DOUBLE	°C	-	-	0.0
out	DFGROshade	Daily gross assimiliate of shaded leave	DOUBLE	micromol m-2 s-1	-	-	0.0
out	DFGROsun	Daily gross assimiliate of sun leave	DOUBLE	micromol m-2 s-1	-	-	0.0
out	DLAI	Death rate of leaf area	DOUBLE	m2/(m2 d)	-	-	0.0
out	DLEAVES	Death leaf rate due to aging and water stress	DOUBLE	d-1	-	-	0.0
out	DLV	Death rate of leaf in term of weigh	DOUBLE	g/(m2 d)	-	-	0.0
out	DOYEMactual	Day of year of crop emergency. Corresponds to cDOYEM if cDOYEM is given, otherwise to the DOY when iDoSow occurs.	INT	d	-	-	0
out	DRScropH2O	Daily canopy resistance to water vapor	DOUBLE	s m-1	-	-	0.0
out	DSF1	Water stress factor on leaf growth	DOUBLE	1	-	-	0.0
out	DTEFF	Daily effective temperature	DOUBLE	°C	-	-	0.0
out	DTGA	Daily total gross CO2 asimilation of the crop	DOUBLE	g/(m2 d)	-	-	0.0
out	DTR	Daily solar radiation =RDD*MODDRT	DOUBLE	J/(m2 d)	-	-	0.0
out	DVSFAC	http://www.wurvoc.org/vocabularies/om-1.8/gram_per_square_metre	DOUBLE	1	-	-	0.0
out	DgsCO2	Daily stomatal conductance to CO2	DOUBLE	mm/d	-	-	0.0
out	DryFactor	Dryness factor in each soil layer)	DOUBLEARRAY	1	0.0	1.0	-
out	EFFshade	Quantum yield of shaded leaf	DOUBLE	g/MJ	-	-	0.0
out	EFFsun	Quantum yield of sunlit leaf	DOUBLE	g/MJ	-	-	0.0
out	EMERG	Parameter to indicate the emergency	INT	1	-	-	0
out	ET0	Potential evapotranspiration (ETD+ ETR)	DOUBLE	mm/d	-	-	0.0
out	ETD	Evapotranspiration due to radiation term	DOUBLE	mm/d	-	-	0.0
out	ETR	Evapotranspiration due to evaporative term (vpd)	DOUBLE	mm/d	-	-	0.0
out	EmergenceDOY	DOY of Emergence	INT	1	1	366	-
out	EmergenceDate	Date of Emergence	DATE	1	-	-	-
out	FCLEAR	Sky clearness function in calculation of net long-wave radiation	DOUBLE	J/(m2 s)	-	-	0.0
out	FSLLA	Fration of sunlit leaf area	DOUBLE	1	-	-	0.0
out	GLAI	Net growth rate of leaf area index	DOUBLE	m2/(m2 d)	-	-	0.0
out	GLV	Dry matter of growth rate of leaves	DOUBLE	g/(m2 d)	-	-	0.0
out	GRAINN	Total grain weight	DOUBLE	g/m2	-	-	0.0
out	GSshadeH2O	Stomatal conductance shaded leaf to H2O	DOUBLE	m s-1	-	-	0.0
out	GSsunH2O	Stomatal conductance sunlit leaf to H2O	DOUBLE	m s-1	-	-	0.0
out	GTOTAL	Daily total gross CH2O assimilation of the crop	DOUBLE	g/(m2 d)	-	-	0.0
out	HasEmerged	Has emerged	BOOLEAN	1	-	-	false
out	HasFlowered	Gas flowered	BOOLEAN	1	-	-	false
out	HasMatured	Is mature	BOOLEAN	1	-	-	false
out	INTRAD	Intercep PAR for radiation use efficiency calcuation	DOUBLE	MJ/(m2 d)	-	-	0.0
out	IsAnthesis	true if Anthesis date	BOOLEAN	1	-	-	false
out	IsEmergence	true if Emergence date	BOOLEAN	1	-	-	false
out	IsMaturity	true if maturity date	BOOLEAN	1	-	-	false
out	LAIANTH	Leaf area index at anthesis	DOUBLE		-	-	0.0
out	LAYERRT	Root length in certain layer	DOUBLEARRAY	mm	-	-	-
out	MAINT	Maintenance respiration after considration of effective temperature	DOUBLE	g/m2	-	-	0.0
out	MAINTS	Maintenance respiration after considration of effective temperature	DOUBLE	g/m2	-	-	0.0
out	MaturityDOY	DOY of Maturity	INT	1	1	366	-
out	MaturityDate	Date of Maturity	DATE	1	-	-	-
out	NNR	Days after last rain	DOUBLE	1	-	-	0.0
out	ONRAD	Net radiation (net short-ware radiation minus net long-wave radiation)	DOUBLE	J/(m2 s)	-	-	0.0
out	ORLOSS	Net long-wave radiation	DOUBLE	J/(m2 s)	-	-	0.0
out	PARINT	Intercepted PAR	DOUBLE	MJ/(m2 d)	-	-	0.0
out	PAW	Water stress factor by soil (WC-WP/FC-WP)	DOUBLEARRAY	1	-	-	-
out	PCEDW	Partitioning fraction to storage organs	DOUBLE		-	-	0.0
out	PCLDW	Partitioning fraction to leaves	DOUBLE	1	-	-	0.0
out	PCRDW	Partitioning fraction to roots	DOUBLE	1	-	-	0.0
out	PCSDW	Partitioning fraction to stems	DOUBLE	1	-	-	0.0
out	PHEADW	Weight of shoot at emgerce, at flag leaf emergence, and at anthesis	DOUBLEARRAY	g/m2	-	-	-
out	PHEDAE	Days at emgerce, at flag leaf emergence, and at anthesis	INTARRAY	d	-	-	0 0 0
out	PHOTMP	Daily average temperature after modifying temperature factor (MODTMP)	DOUBLE	°C	-	-	0.0
out	PHY	Phylochron	DOUBLE	°C d	-	-	0.0
out	PRWSO	Assimilate source for grain growth	DOUBLE	m2/m2	-	-	0.0
out	PTRANS	Potential transpiration rate derived form Penman-Monteith	DOUBLE	mm/d	-	-	0.0
out	PotentialDRScropH2O	Daily canopy resistance to water vapor (no water stress)	DOUBLE	s m-1	-	-	0.0
out	RCPHOE	Rate change of photoperiod at emergence dates	DOUBLE	h	-	-	0.0
out	RDRSH	Relative death rate due to self-shading at high LAI	DOUBLE	d-1	-	-	-
out	REMOB	Mobilization of assimilate from stem to the grain	DOUBLE	g/m2	-	-	0.0
out	RLAYER	Number of soil layer with root	INT	1	-	-	0
out	RLV	Root length	DOUBLEARRAY	mm	-	-	-
out	RNS	Net short-wave radiation	DOUBLE	J/(m2 s)	-	-	0.0
out	ROOTlimit	Estimate of water uptake that limited by root at each soil layer	DOUBLE	mm/d	-	-	0.0
out	RRATIO	Ratio of root to total root+shoot dry matter	DOUBLE	1	-	-	0.0
out	RSINK	Sink for grain growth	DOUBLE	g/m2	-	-	0.0
out	RUE	Radiation use efficiency	DOUBLE	g/MJ	-	-	0.0
out	SDWANT	Weight of stem at anthesis	DOUBLE	g/m2	-	-	0.0
out	SLA	Specific leaf area	DOUBLE	m2/g	-	-	0.0
out	SOILlimit	Estimate of water uptake that limited by soil at each soil layer	DOUBLE	mm/d	-	-	0.0
out	STRESS	Transpiration reduction factor (ATRAN/PTRAN)	DOUBLE	1	-	-	0.0
out	SVAP	Saturated vapor pressure	DOUBLE	kPa	-	-	0.0
out	SWITCH	The switch of phenology stage	INT	1	-	-	0
out	TAEVAP	Cumulative actual soil evaporation	DOUBLE	mm	-	-	0.0
out	TDW	total dry matter (= root + shoot)	DOUBLE	g/m2	-	-	0.0
out	TEFF	Effective temperature for growth respiration	DOUBLE	°C	-	-	0.0
out	TFAC	Temperature factor reduces grain yield	DOUBLE	1	-	-	0.0
out	TPAW	Total water stress factor by soil (WC-WP/FC-WP) after consider the root	DOUBLE	1	-	-	0.0
out	TPVAP	Cumulative potential soil evaporation	DOUBLE	mm	-	-	0.0
out	TRANSLOC	Translocation of assimilation rates into the roots due to the lack of sink	DOUBLE	g/m2	-	-	0.0
out	TSUMend	Thermal time at end of growing season	DOUBLE	°C d	-	-	0.0
out	TTANTH	Thermal time from sowing to anthesis	DOUBLE	°C d	-	-	0.0
out	TTFLE	Thermal time from sowing to the appearance of flag leave	DOUBLE	°C d	-	-	0.0
out	TTMAT	Thermal time from sowing to maturity	DOUBLE	°C d	-	-	0.0
out	TWPAW	Daily water stress index calculated based on soil water content	DOUBLE	1	-	-	0.0
out	VPD	Vapor pressure deficit of the air	DOUBLE	kPa	-	-	0.0
out	WCHECK	Water balance check	DOUBLE	1	-	-	0.0
out	WCL	Volumetric in each soil layer	DOUBLEARRAY	cm3/cm3	-	-	-
out	WL	Amount of water in soil compartments	DOUBLEARRAY	mm	-	-	-
out	WSHOOT	Weight of shoot (stem+leaf+storage organ)	DOUBLE	g/m2	-	-	0.0
out	WUperLayer	Estimate of water uptake each soil layer	DOUBLEARRAY	mm	-	-	-
out	WithCrop	Crop is present	BOOLEAN	1	-	-	false
out	ZRT	Root depth	DOUBLE	mm	-	-	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

LintulCC()

Empty constructor used by class.forName()

LintulCC(String aName, HashMap<String,net.simplace.sim.util.FWSimVariable<?>> aFieldMap, HashMap<String,String> aInputMap, org.jdom2.Element aSimComponentElement, net.simplace.sim.util.FWSimVarMap aVarMap, int aOrderNumber)
Method Summary

Modifier and Type

Method

Description

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.

void

init()

void

initVariables()

void

process()

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
- LintulCC
  
  public LintulCC(String aName, HashMap<String,net.simplace.sim.util.FWSimVariable<?>> aFieldMap, HashMap<String,String> aInputMap, org.jdom2.Element aSimComponentElement, net.simplace.sim.util.FWSimVarMap aVarMap, int aOrderNumber)
  
  Parameters:
  
  aName -
  
  aFieldMap -
  
  aInputMap -
  
  aSimComponentElement -
  
  aVarMap -
  
  aOrderNumber -
- LintulCC
  
  public LintulCC()
  
  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:
  
  FWSimComponent.createVariables()
- init
  
  public void init()
  
  Specified by:
  
  init in class net.simplace.sim.model.FWSimComponent
- initVariables
  
  public void initVariables()
- process
  
  public void process()
  
  Specified by:
  
  process in class net.simplace.sim.model.FWSimComponent
- 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:
  
  FWSimComponent.clone(net.simplace.sim.util.FWSimVarMap)

Class LintulCC

References

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

LintulCC

LintulCC

Method Details

createVariables

init

initVariables

process

fillTestVariables

clone