Type:	Package
Title:	Simulating Forest Growth using the 3-PG Model
Description:	Provides a flexible and easy-to-use interface for the Physiological Processes Predicting Growth (3-PG) model written in Fortran. The r3PG serves as a flexible and easy-to-use interface for the 3-PGpjs (monospecific, evenaged and evergreen forests) described in Landsberg & Waring (1997) <doi:10.1016/S0378-1127(97)00026-1> and the 3-PGmix (deciduous, uneven-aged or mixed-species forests) described in Forrester & Tang (2016) <doi:10.1016/j.ecolmodel.2015.07.010>.
Date:	2023-09-18
Version:	0.1.6
License:	GPL-3
Depends:	R (≥ 3.5.0)
Suggests:	knitr (≥ 1.15.1), rmarkdown (≥ 1.3), R.rsp (≥ 0.40.0), testthat (≥ 1.0.2), roxygen2, BayesianTools, sensitivity, dplyr, ggplot2
VignetteBuilder:	R.rsp
Encoding:	UTF-8
LazyData:	true
RoxygenNote:	7.1.2
URL:	https://github.com/trotsiuk/r3PG
BugReports:	https://github.com/trotsiuk/r3PG/issues
NeedsCompilation:	yes
Packaged:	2023-09-19 08:09:36 UTC; trotsiuk
Author:	Volodymyr Trotsiuk [aut, cre], Florian Hartig [aut], David Forrester [aut], Ramiro Silveyra Gonzalez [aut]
Maintainer:	Volodymyr Trotsiuk <volodymyr.trotsiuk@wsl.ch>
Repository:	CRAN
Date/Publication:	2023-09-19 08:50:04 UTC

Simulating Forest Growth using the 3-PG Process-Based Vegetation Model

Description

The r3PG package provides a flexible and easy-to-use interface for Fortran implementations of the 3-PGpjs (monospecific, evenaged and evergreen forests) or 3-PGmix (deciduous, uneven-aged or mixed-species forests) forest growth models. The user can flexibly switch between various options and submodules, to use the original 3-PGpjs model version for monospecific, even-aged and evergreen forests and the 3-PGmix model, which can also simulate multi-cohort stands (e.g. mixtures, uneven-aged) that contain deciduous species. The core function to run the model is run_3PG. For more background, please consult the vignette via vignette(package = "r3PG")

Value

None

References

Forrester, D. I., 2020. 3-PG User Manual. Swiss Federal Institute for Forest, Snow and Landscape Research WSL, Birmensdorf, Switzerland. 70 p. Available at the following web site: http://sites.google.com/site/davidforresterssite/home/projects/3PGmix/3pgmixdownload

Forrester, D. I., & Tang, X. (2016). Analysing the spatial and temporal dynamics of species interactions in mixed-species forests and the effects of stand density using the 3-PG model. Ecological Modelling, 319, 233–254. doi:10.1016/j.ecolmodel.2015.07.010

Landsberg, J. J., & Waring, R. H., 1997. A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning. Forest Ecology and Management, 95(3), 209–228. doi:10.1016/S0378-1127(97)00026-1

Sands, P. J., 2010. 3PGpjs user manual. Available at the following web site: https://3pg.sites.olt.ubc.ca/files/2014/04/3PGpjs_UserManual.pdf

See Also

run_3PG

Examples

out <- run_3PG(
  site = d_site,
  species = d_species,
  climate = d_climate,
  thinning = d_thinning,
  parameters = d_parameters,
  size_dist = d_sizeDist,
  settings = list(light_model = 2, transp_model = 2, phys_model = 2,
                  correct_bias = 1, calculate_d13c = 0),
  check_input = TRUE, df_out = TRUE) # note that default is TRUE

str(out) # List output format

Climate input

Description

Table containing the information about monthly values for climatic data.

Usage

d_climate

Format

A data frame with 156 rows and 7 variables:

year

calendar year

month

month

tmp_min

monthly mean daily minimum temperature (C)

tmp_max

monthly mean daily maximum temperature (C)

tmp_ave

monthly mean daily average temperature (C). (optional)

prcp

monthly rainfall (mm month-1)

srad

monthly mean daily solar radiation (MJ m-2 d-1)

frost_days

frost days per month (d month-1)

co2

monthly mean atmospheric co2 (ppm), required if calculate_d13c=1 (optional)

d13catm

Monthly mean isotopic composition of air (‰), required if calculate_d13c=1 (optional)

Parameters input

Description

Table containing the information about parameters.

Usage

d_parameters

Format

A data frame with 65 rows and x variables:

parameter

name of the parameter, must be consistent in naming with i_parameters

Fagus sylvatica

parameter values for species 1

Pinus sylvestris

parameter values for species 2

Site input

Description

Table containing the information about site conditions.

Usage

d_site

Format

A data frame with 1 rows and 8 variables:

latitude

site latitude in the WGS84 coordinate system

altitude

site altitude, m a.s.l.

soil_class

soil class, according to table 2 user manual of 3PGpjs. 1 - Sandy; 2 - Sandy loam; 3 - Clay loam; 4 - Clay; 0 - No effect of available soil water on production

asw_i

initial available soil water (mm)

asw_max

minimum available soil water (mm)

asw_min

maximum available soil water (mm)

from

year and month indicating the start of simulation. Provided in form of year-month. E.g. "2000-01"

to

year and month indicating the end of simulation. Provided in form of year-month. E.g. "2009-12", will include December 2009 as last simulation month

sizeDist input

Description

Table containing the information about size distribution.

Usage

d_sizeDist

Format

A data frame with 47 rows and x variables:

parameter

name of the parameter, must be consistent in naming with i_sizeDist

Fagus sylvatica

parameter values for species 1

Pinus sylvestris

parameter values for species 2

Species input

Description

Table containing the information about species level data. Each row corresponds to one species/cohort.

Usage

d_species

Format

A data frame with number of rows corresponding to each species/cohort and 8 variables:

species

species or cohort id/name. It must be consistent with species names in d_thinning, d_parameters and d_sizeDist tables.

planted

year and month indicating when the species was planted. Provided in form of year-month. E.g. "2000-01"

fertility

soil fertility for a given species. Range from 0 to 1

stems_n

number of trees per ha

biom_stem

stem biomass for a given species (Mg/ha)

biom_root

root biomass for a given species (Mg/ha)

biom_foliage

initial foliage biomass (Mg/ha). If this is a leafless period, provide the spring foliage biomass.

Thinning input

Description

Table containing the information about thinnings

Usage

d_thinning

Format

A data frame with 3 rows and 6 variables:

species

species or cohort id/name. It must be consistent with species names in d_species, d_parameters and d_sizeDist tables.

age

age when thinning is performed

stems_n

number of trees remaining after thinning

stem

type of thinning (above/below). Default is 1

root

type of thinning (above/below). Default is 1

foliage

type of thinning (above/below). Default is 1

Get parameter sets

Description

Gets parameter sets from published studies with 3PG

Usage

get_parameters(mode = "overview", sp_names = NULL)

Arguments

Details

This function access the parameter database stored in the package, which is named i_parameters_lit, and also accessible without this function. If mode = overview, a simplified table with all existing parameter sets will be returned. A extended version including information about to the source and remarks can be obtained with mode = comments. A complete description of the source is returned with mode = source. The full version of this table (species,source, comments, parameters) will be returned if mode = full. Alternatively, with mode = parameters and mode = sizeDist, it is possible to obtain parameters in the format required by run_3PG.

Passing species names with sp_names will selecting from the table the desired species. Please note that one species might have more than one available parameter sets, unless species names contain the parset_id value. Please also note that mode = source is not compatible with sp_names.

The parameter sets were obtained from published studies. For basic information about this dataset check in i_parameters_lit. Relevant information about the parameter sets and the corresponding studies is provided in the table. For further information, please consider checking the original publications.

Value

a data frame with parameter sets for all available species, or only the requested species, if sp_names is not null.

See Also

run_3PG, i_parameters_lit

Examples

# see an overview of the existing parameter sets
get_parameters(mode = 'overview')
get_parameters(mode = 'overview', sp_names = c('Eucalyptus globulus', 'Pinus sylvestris' ) )

# see existing parameter sets and comments
get_parameters(mode = 'comments')
get_parameters(mode = 'comments', sp_names = c('Eucalyptus globulus', 'Pinus sylvestris' ) )

# see parameters and source information
get_parameters(mode = 'source')

# obtain parameter sets in for some species in the format required by run_3PG
get_parameters(mode = 'parameters', sp_names = c('Fagus sylvatica', 'Picea abies'))
get_parameters(mode = 'parameters', sp_names = 'Fagus sylvatica 34' )
get_parameters(mode = 'sizeDist', sp_names = c('Fagus sylvatica 9', 'Picea abies 37'))

# see parameter sets with full information (species, source, parameters)
get_parameters(mode = 'full')
get_parameters(mode = 'full', sp_names = c('Fagus sylvatica', 'Pinus radiata' ) )

Information about model outputs

Description

A dataset containing the list of output variables and their description.

Usage

i_output

Format

A data frame with 150 rows and 7 variables:

group_id

serial number of the group

variable_id

serial number of the variable

variable_group

group name to which variable belongs

variable_name

variable name as named in output

description

description of the variable

unit

unit of the variable

variable_vba

corresponding name of the variable as output from Excel version of 3-PGmix

Information about parameters

Description

A dataset containing the parameters order and description.

Usage

i_parameters

Format

A data frame with 82 rows and 3 variables:

parameter

parameter name

description

description of the parameter

unit

unit

default

default value for E.globulus from original 3-PG

Information about literature parameters

Description

A dataset containing parameter sets from published studies with 3PG

Usage

i_parameters_lit

Format

A data frame with 110 rows and 124 variables:

parset_id

id of the parameter set

species

species scientific name

age

whether the parameter set was was used in even or uneven stands.

type

whether the parameter set was used in monocultures or mixed stands.

year

year of publication

region

geographical region in which the parameters were tested. NAs values are allowed.

country

country or countries in which the parameters were tested.

notes

any relevant remark about how the parameters were processed. NAs are allowed.

source

short reference to publication

source_comments

any relevant comment about the parameters present in the publication. NAs are allowed.

source_full

full reference to publication

link

a link to the publication, e.g. doi

pFS2

Foliage:stem partitioning ratio - D = 2 cm

pFS20

Foliage:stem partitioning ratio - D = 20 cm

aWS

Constant in the stem mass v. diam. relationship

nWS

Power in the stem mass v. diam. relationship

pRx

Maximum fraction of NPP to roots

pRn

Minimum fraction of NPP to roots

gammaF1

Maximum litterfall rate

gammaF0

Litterfall rate at t = 0

tgammaF

Age at which litterfall rate has median value

gammaR

Average monthly root turnover rate

leafgrow

If deciduous, leaves are produced at end of this month

leaffall

If deciduous, leaves all fall at start of this month

Tmin

Minimum temperature for growth

Topt

Optimum temperature for growth

Tmax

Maximum temperature for growth

kF

Days production lost per frost day

SWconst

Moisture ratio deficit for fq = 0.5

SWpower

Power of moisture ratio deficit

fCalpha700

Assimilation enhancement factor at 700 ppm

fCg700

Canopy conductance enhancement factor at 700 ppm

m0

Value of m when FR = 0

fN0

Value of fNutr when FR = 0

fNn

Power of (1-FR) in fNutr

MaxAge

Maximum stand age used in age modifier

nAge

Power of relative age in function for fAge

rAge

Relative age to give fAge = 0.5

gammaN1

Mortality rate for large t

gammaN0

Seedling mortality rate (t = 0)

tgammaN

Age at which mortality rate has median value

ngammaN

Shape of mortality response

wSx1000

Max. stem mass per tree - 1000 trees/hectare

thinPower

Power in self-thinning rule

mF

Fraction mean single-tree foliage biomass lost per dead tree

mR

Fraction mean single-tree root biomass lost per dead tree

mS

Fraction mean single-tree stem biomass lost per dead tree

SLA0

Specific leaf area at age 0

SLA1

Specific leaf area for mature leaves

tSLA

Age at which specific leaf area = (SLA0+SLA1)/2

k

Extinction coefficient for absorption of PAR by canopy

fullCanAge

Age at canopy closure

MaxIntcptn

Maximum proportion of rainfall evaporated from canopy

LAImaxIntcptn

LAI for maximum rainfall interception

cVPD

LAI for 50% reduction of VPD in canopy

alphaCx

Canopy quantum efficiency

Y

Ratio NPP/GPP

MinCond

Minimum canopy conductance

MaxCond

Maximum canopy conductance

LAIgcx

LAI for maximum canopy conductance

CoeffCond

Defines stomatal response to VPD

BLcond

Canopy boundary layer conductance

RGcGw

The ratio of diffusivities of CO2 and water vapour in air

D13CTissueDif

d13C difference of modelled tissue and new photosynthate

aFracDiffu

Fractionation against 13C in diffusion

bFracRubi

Enzymatic fractionation by Rubisco

fracBB0

Branch and bark fraction at age 0

fracBB1

Branch and bark fraction for mature stands

tBB

Age at which fracBB = (fracBB0+fracBB1)/2

rhoMin

Minimum basic density - for young trees

rhoMax

Maximum basic density - for older trees

tRho

Age at which rho = (rhoMin+rhoMax)/2

aH

Constant in the stem height relationship

nHB

Power of DBH in the stem height relationship

nHC

Power of competition in the stem height relationship

aV

Constant in the stem volume relationship

nVB

Power of DBH in the stem volume relationship

nVH

Power of height in the stem volume relationship

nVBH

Power of DBH^2 x height in the stem volume relationship

crownshape

Crown shape (1=cone, 2=ellipsoid, 3=half-ellipsoid, 4=rectangular)

aK

Constant in the crown diameter relationship

nKB

Power of DBH in the crown diameter relationship

nKH

Power of height in the crown diameter relationship

nKC

Power of competition in the crown diameter relationship

nKrh

Power of relative height in the crown diameter relationship

aHL

Constant in the LCL relationship

nHLB

Power of DBH in the LCL relationship

nHLL

Power of LAI in the LCL relationship

nHLC

Power of competition in the LCL relationship

nHLrh

Power of relative height in the LCL relationship

Dscale0

Constant in the relationship for Weibull scale parameter of D distribution

DscaleB

Slope of DBH in relationship for Weibull scale parameter of D distribution

Dscalerh

Slope of relative height in relationship for Weibull scale parameter of D distribution

Dscalet

Slope of age in relationship for Weibull scale parameter of D distribution

DscaleC

Slope of competition in relationship for Weibull scale parameter of D distribution

Dshape0

Constant in the relationship for Weibull shape parameter of D distribution

DshapeB

Slope of DBH in relationship for Weibull shape parameter of D distribution

Dshaperh

Slope of relative height in relationship for Weibull shape parameter of D distribution

Dshapet

Slope of age in relationship for Weibull shape parameter of D distribution

DshapeC

Slope of competition in relationship for Weibull shape parameter of D distribution

Dlocation0

Constant in the relationship for Weibull location parameter of D distribution

DlocationB

Slope of DBH in relationship for Weibull location parameter of D distribution

Dlocationrh

Slope of relative height in relationship for Weibull location parameter of D distribution

Dlocationt

Slope of age in relationship for Weibull location parameter of D distribution

DlocationC

Slope of competition in relationship for Weibull location parameter of D distribution

wsscale0

Constant in the relationship for Weibull scale parameter of ws distribution

wsscaleB

Slope of DBH in relationship for Weibull scale parameter of ws distribution

wsscalerh

Slope of relative height in relationship for Weibull scale parameter of ws distribution

wsscalet

Slope of age in relationship for Weibull scale parameter of ws distribution

wsscaleC

Slope of competition in relationship for Weibull scale parameter of ws distribution

wsshape0

Constant in the relationship for Weibull shape parameter of ws distribution

wsshapeB

Slope of DBH in relationship for Weibull shape parameter of ws distribution

wsshaperh

Slope of relative height in relationship for Weibull shape parameter of ws distribution

wsshapet

Slope of age in relationship for Weibull shape parameter of ws distribution

wsshapeC

Slope of competition in relationship for Weibull shape parameter of ws distribution

wslocation0

Constant in the relationship for Weibull location parameter of ws distribution

wslocationB

Slope of DBH in relationship for Weibull location parameter of ws distribution

wslocationrh

Slope of relative height in relationship for Weibull location parameter of ws distribution

wslocationt

Slope of age in relationship for Weibull location parameter of ws distribution

wslocationC

Slope of competition in relationship for Weibull location parameter of ws distribution

Qa

Intercept of net v. solar radiation relationship

Qb

Slope of net v. solar radiation relationship

gDM_mol

Molecular weight of dry matter

molPAR_MJ

Conversion of solar radiation to PAR

Details

Each row refers to an unique parameter set. The function get_parameters eases the use to this dataset.

Information about size distribution parameters

Description

A dataset containing the parameters order and description.

Usage

i_sizeDist

Format

A data frame with 30 rows and 3 variables:

parameter

parameter name

description

description of the parameter

unit

unit

default

default value equal to 0

Subsets or replicate a climate data

Description

Prepares the climate table, by either replicating the average climate for the required number of years, or by sub-setting from a longer time-series of climate data.

Usage

prepare_climate(climate, from = "2000-04", to = "2010-11")

Arguments

Details

This function prepares the climate table for run_3PG.

In case a user provides only average climate, this is replicated for the desired simulation period.

In case a larger climate file is provided, the simulation period is selected from this.

Value

a data.frame with number of rows corresponding to number of simulated month and 10 columns

See Also

run_3PG, prepare_input, prepare_parameters, prepare_sizeDist, prepare_thinning

Examples

# sub-setting climate data
prepare_climate( climate = d_climate, from = '2003-04', to = '2010-11')

# replicating climate data
set.seed(1)
climate = data.frame( tmp_min = rnorm(12, mean = 10),
                      tmp_max = rnorm(12, mean = 20),
                      prcp = sample(c(0:200), 12),
                      srad = sample(c(1:100), 12),
                      frost_days = sample(c(0:30), 12))

prepare_climate( climate = climate, from = '2000-04', to = '2010-11')

Check and prepare input for running 3-PG model

Description

Checks and prepares all input tables to be used in run_3PG. For detailed descriptions see Forrester (2020).

Usage

prepare_input(site, species, climate, thinning = NULL, parameters = NULL,
  size_dist = NULL, settings = NULL)

Arguments

Details

This function checks and prepares the input data for the run_3PG. The output is a list with 7 tables. Each of them corresponds to the one from input.

Value

a list with seven tables. Each table corresponds to one of the input tables.

References

Forrester, D. I., 2020. 3-PG User Manual. Swiss Federal Institute for Forest, Snow and Landscape Research WSL, Birmensdorf, Switzerland. 70 p. Available at the following web site: http://sites.google.com/site/davidforresterssite/home/projects/3PGmix/3pgmixdownload

Sands, P. J., 2010. 3PGpjs user manual. Available at the following web site: https://3pg.sites.olt.ubc.ca/files/2014/04/3PGpjs_UserManual.pdf

See Also

run_3PG, prepare_parameters, prepare_sizeDist, prepare_thinning, prepare_climate, prepare_site

Examples

prepare_input( site = d_site, species = d_species, climate = d_climate, d_thinning)

Prepare parameters table

Description

Prepares the parameters table, by either replicating the defaults or replicating defaults for each of the species.

Usage

prepare_parameters(parameters = NULL, sp_names = c("Fagus sylvatica",
  "Pinus sylvestris"))

Arguments

Details

This function prepares the parameter table for run_3PG

Value

a data.frame with 47 rows and columns corresponding to each species.

See Also

run_3PG, prepare_input, prepare_sizeDist, prepare_thinning, prepare_climate

Examples

# replace some
prepare_parameters( parameters = d_parameters[1:4,],
  sp_names = c('Fagus sylvatica', 'Pinus sylvestris' ))

# Make default
prepare_parameters( parameters = NULL, sp_names = c('Quercus', 'Abies'))

Check the site data for consistency

Description

Prepares the site table, by checking whether the input information is consistent.

Usage

prepare_site(site)

Arguments

Details

This function check the site table for run_3PG.

Value

a data.frame with one row

See Also

run_3PG, prepare_input, prepare_parameters, prepare_sizeDist, prepare_thinning

Examples

# check site data
prepare_site( site = d_site)

Prepare parameters table

Description

Prepares the parameters table, by either replicating the defaults or replicating defaults for each of the species.

Usage

prepare_sizeDist(size_dist = NULL, sp_names = c("Fagus sylvatica",
  "Pinus sylvestris"))

Arguments

Details

This function prepares the parameter table for run_3PG.

Value

a data.frame with 47 rows and columns corresponding to each species.

See Also

run_3PG, prepare_input, prepare_parameters, prepare_thinning, prepare_climate

Examples

# replace some
prepare_sizeDist( size_dist = d_sizeDist[1:4,],
  sp_names = c('Fagus sylvatica', 'Pinus sylvestris' ))

# Make default
prepare_sizeDist( size_dist = NULL, sp_names = c('Quercus', 'Abies'))

Check the species data for consistency

Description

Prepares the species table, by checking whether the input information is consistent.

Usage

prepare_species(species)

Arguments

Details

This function check the species table for run_3PG.

Value

a data.frame with one row

See Also

run_3PG, prepare_input, prepare_parameters, prepare_sizeDist, prepare_thinning, prepare_site

Examples

# check species data
prepare_species( species = d_species)

Check and prepare management information.

Description

Prepares the management table and checks for consistency.

Usage

prepare_thinning(thinning = NULL, sp_names = c("Fagus sylvatica",
  "Pinus sylvestris"))

Arguments

Details

This function prepares the thinning table for run_3PG.

In case there is no thinning it will return empty 3-d array.

In case there will be thinning it will return 3-d array, where one dimension correspond to each species.

Value

a 3-dimentional array, where third dimention correspond to each species.

See Also

run_3PG, prepare_input, prepare_parameters, prepare_sizeDist, prepare_climate

Examples

prepare_thinning( thinning = NULL, sp_names = c('Quercus', 'Abies'))

prepare_thinning( thinning = d_thinning, sp_names = c('Fagus sylvatica', 'Pinus sylvestris'))

Runs a 3-PG model simulation

Description

Runs the 3-PGpjs (monospecific, evenaged and evergreen forests) or 3-PGmix (deciduous, uneven-aged or mixed-species forests) model. For more details on parameters and structure of input visit prepare_input.

Usage

run_3PG(site, species, climate, thinning = NULL, parameters = NULL,
  size_dist = NULL, settings = NULL, check_input = TRUE, df_out = TRUE)

Arguments

Details

'r3PG' provides an implementation of the Physiological Processes Predicting Growth 3-PG model, which simulates forest growth and productivity. The 'r3PG' serves as a flexible and easy-to-use interface for the '3-PGpjs' (monospecific, evenaged and evergreen forests) and the '3-PGmix' (deciduous, uneven-aged or mixed-species forests) model written in 'Fortran'. The package, allows for fast and easy interaction with the model, and 'Fortran' re-implementation facilitates computationally intensive sensitivity analysis and calibration. The user can flexibly switch between various options and submodules, to use the original '3-PGpjs' model version for monospecific, even-aged and evergreen forests and the '3-PGmix' model, which can also simulate multi-cohort stands (e.g. mixtures, uneven-aged) that contain deciduous species.

This implementation of 3-PG includes several major variants / modifications of the model in particular the ability to switch between 3-PGpjs (the more classic model version for monospecific stands) vs. 3-PGmix (a version for mixed stands), as well as options for bias corrections and \delta^13 C calculations (see parameters).

Value

either a 4-dimentional array or a data.frame, depending on the parameter df_out. More details on the output is i_output

Note

The run_3PG also checks the quality of input data. When names, or structures are not consistent with requirements it will return an error. Turn this off to optimize for speed.

References

Forrester, D. I., 2020. 3-PG User Manual. Swiss Federal Institute for Forest, Snow and Landscape Research WSL, Birmensdorf, Switzerland. 70 p. Available at the following web site: http://sites.google.com/site/davidforresterssite/home/projects/3PGmix/3pgmixdownload

Forrester, D. I., & Tang, X. (2016). Analysing the spatial and temporal dynamics of species interactions in mixed-species forests and the effects of stand density using the 3-PG model. Ecological Modelling, 319, 233–254. doi:10.1016/j.ecolmodel.2015.07.010

Landsberg, J. J., & Waring, R. H., 1997. A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning. Forest Ecology and Management, 95(3), 209–228. doi:10.1016/S0378-1127(97)00026-1

Sands, P. J., 2010. 3PGpjs user manual. Available at the following web site: https://3pg.sites.olt.ubc.ca/files/2014/04/3PGpjs_UserManual.pdf

See Also

prepare_input, prepare_parameters, prepare_sizeDist, prepare_thinning, prepare_climate

Examples

out <- run_3PG(
  site = d_site,
  species = d_species,
  climate = d_climate,
  thinning = d_thinning,
  parameters = d_parameters,
  size_dist = d_sizeDist,
  settings = list(light_model = 2, transp_model = 2, phys_model = 2,
                  correct_bias = 1, calculate_d13c = 0),
  check_input = TRUE, df_out = TRUE) # note that default is TRUE

str(out) # List output format