Model

Description and Discussion

Background Mortality   

March 2018              

Non-linear logistic regression model as a function of Zone, Management (PCT or Planted – yes/no), DBH, basal area, QMD, and basal area of larger trees. Each species model was fit independently and not all variables were used in each model depending on available data. Species group (genus) models were also developed. Fit by C.R. Hennigar, NB ERD, March 2018.

These models can run stochastically if Simulation.Model.IsRandom is set to TRUE (Default = FALSE).

Updated in June 2019 to always operate stochastically when trees/ha are < 0.5 (kills individual trees randomly according to mortality probability), rather than deterministically (proportion of tree record stems/hectare killed equal to mortality probability). This hybrid approach is used even when Simulation.Model.IsRandom = FALSE. When Simulation.Model.IsRandom = TRUE, mortality of individual trees in every tree record will be set stochastically.

To ensure results are repeatable from run to run, for testing, benchmarking, and validation work. Use command Simulation.Model.SetRandomSeed #, where # is a fixed positive integer. Do this for each stand simulation to force the random number generator to provide exactly the same series of random numbers during simulation. For example, the Seed value could be the plot number.

Self-Thinning      Mortality

March 2013                                                             

The maximum stocking relationship was developed with a wealth of NB forest development surveys collected since the 1980s. The relationship was formulated as a function of basal area weighted species specific-gravity. This relationship was fit at the stand-level (>= 3 plots per stand), rather than plot-level, so it may over-estimate mortality for some plot-level comparisons.

Fit by C.R. Hennigar, NB DNR 2013, following methods from Chris Woodall et al. (2005, For. Ecol. Manage. 216: 367-377). 

In April 2018, the specific gravity for red-pine was reduced from 0.46 to 0.36 when used in this maximum stocking equation because self-thinning was occurring too early in red pine plantations (C.R. Hennigar, NB ERD 2018).

Default A-Line set to 0.85 in this Variant. In some regenerating types, especially for single plantation plots, this default A-Line (0.85) has been observed to cause competition induced mortality too early during stand development. Increasing the Simulation.Model.ALine to 0.95-1.00 may be required for some of these intensively managed types.

Ingrowth

2011               

Estimates ingrowth probability, density, and composition at the 1 cm DBH boundary in each simulation cycle based on pre-cut stand conditions according to Li et al. (2011; CJFR 41: 2077-2089). This model can run stochastically if Simulation.Model.IsRandom is set to TRUE (Default = FALSE).

A number of conditional adjustments to the base Li et al. (2011) ingrowth model were introduced by C.R. Hennigar, NB DNR in 2013 to improve realism in the context of harvest, current overstory species composition, and pre-existing stand ingrowth expected from small trees and seedlings in survey records or inserted in a previous cycle via OSM commands.

In April 2018, C.R. Hennigar made further adjustments to reduce ingrowth in well managed plantations and PCTs and increase in growth in recently clearcut conditions.

DBH growth

2016

Non-linear regression models as a function of Zone, BGI, Species, DBH, basal area, QMD, and basal area of larger trees. Each species model was fit independently and not all variables were always used depending on available data. Species group (genus) models were also developed. Each species model was fit independently and not all variables were used in each model depending on available data. Fit by C.R. Hennigar, NB DNR 2016.

Height model

Sept 2017                              

Non-linear (Weibull) model as a function of Zone, BGI, Species, DBH, basal area, QMD, and basal area of larger trees. Height prediction can be boosted if a sub-sample of height trees are available in the survey data. This boosting occurs automatically on loading of the tree list if heights are present. Each species model was fit independently and not all variables were used in each model depending on available data. Fit by C.R. Hennigar, NB ERD 2017.

For more specifics on tree height imputation procedure used here, see OSM.Acadian.Calibration.HeightModel.

Height increment                                          

Currently deduced from DBH growth and height predictions. A formal height increment model by Zone and Management type will hopefully be developed over the next year or two.

Crown models

2014                                 

Maximum and largest crown width models for Maine (Russell and Weiskittel 2011. Nor. J. Appl. For. 28: 84-91).

Height to crown base models for 13 species in the Acadian region (Rijal et al. 2012. For. Chron. 88: 60-73).

Height-to-crown base increment in the Acadian region (Russell et al. 2014. Eur J. For. Res. 133:1121–1135).

Grade model  

2015                                                                    

Preliminary calibration available for New Brunswick for sugar maple and yellow birch. Fit by Walter Emrich, Northern Hardwood Research Institute 2015.

Snag model   

2016                                                    

The default snag fall rate model for the Acadian region was ported from STAMAN by C.R. Hennigar, NB DNR 2016. This STAMAN snag fall model was based on northeast snag literature (pre-2010) and no formal documentation of the original calibration work is available. Fall rates seem realistic when simulated based on comparisons between steady state simulated inventory and NB snag inventories collected in the field.

There is currently no snag decay transition model for the Acadian region. Decay models exist in the literature in Maine, Ontario, and Quebec and may be introduced in future development of this Variant.

A snag inventory imputation/initialization model has been developed for this Variant using forest development surveys collected throughout the province of NB between 2006 and 2012. The model predicts the probability of snag occurrence and snag abundance across 10cm DBH classes and can be used to initialize the simulation with snags if none were collected in the field. Developed by C.R. Hennigar, NB DNR, 2016.

This model always runs stochastically regardless of Simulation.Model.IsRandom state. This is necessary to reduce the number of snag record divisions over multiple simulation cycles.

Default Snags.MinDBH = 9999 (OFF). To turn snag modeling on, set Snags.MinDBH to 10 cm.

Taper & Volume

1983

Total and merchantable bole volumes based on Honer et al. 1983. Metric timber tables for commercial tree species of central and eastern Canada. Maritime For. Res. Centre. Info, Rep. M-X-140.

Default merchantable bole stump height set to 30 cm and top height set to 8 cm inside bark for all species; adjust these defaults using Simulation.Species.

Volume does not influence stand development. These estimates are only calculated if desired during reporting.