Duncan Lardeau Juvenile Rainbow Trout Abundance 2022

The suggested citation for this analytic report is:

Thorley, J.L. and Amies-Galonski, E. (2022) Duncan Lardeau Juvenile Rainbow Trout Abundance 2022. A Poisson Consulting Analysis Appendix. URL: https://www.poissonconsulting.ca/f/1424347820.

Background

Rainbow Trout rear in the Lardeau and Lower Duncan rivers. Since 2006 (with the exception of 2015) annual spring snorkel surveys have been conducted to estimate the abundance and distribution of age-1 Rainbow Trout. From 2006 to 2010 the surveys were conducted at fixed index sites. Since 2011 fish observations have been mapped to the river based on their spatial coordinates as recorded by GPS.

The primary aims of the current analyses were to:

  • Estimate the spring abundance of age-1 fish by year.
  • Estimate the egg deposition.
  • Estimate the stock-recruitment relationship between the egg deposition and the abundance of age-1 recruits the following spring.
  • Estimate the survival from age-1 to age-2.
  • Estimate the expected number of spawners without in river and/or in lake variation.

Methods

Data Preparation

The data were provided by the Ministry of Forests, Lands and Natural Resource Operations (MFLNRO). The historical and current snorkel count data were manipulated using R version 4.2.1 (R Core Team 2021) and organised in an SQLite database.

Statistical Analysis

Model parameters were estimated using Bayesian methods. The estimates were produced using JAGS (Plummer 2003) and STAN (Carpenter et al. 2017). For additional information on Bayesian estimation the reader is referred to McElreath (2016), respectively.

Unless stated otherwise, the Bayesian analyses used weakly informative normal and half-normal prior distributions (Gelman, Simpson, and Betancourt 2017). The posterior distributions were estimated from 1500 Markov Chain Monte Carlo (MCMC) samples thinned from the second halves of 3 chains (Kery and Schaub 2011, 38–40). Model convergence was confirmed by ensuring that the potential scale reduction factor \(\hat{R} \leq 1.05\) (Kery and Schaub 2011, 40) and the effective sample size (Brooks et al. 2011) \(\textrm{ESS} \geq 150\) for each of the monitored parameters (Kery and Schaub 2011, 61).

The parameters are summarised in terms of the point estimate, lower and upper 95% credible limits (CLs) and the surprisal s-value (Greenland 2019). The estimate is the median (50th percentile) of the MCMC samples while the 95% CLs are the 2.5th and 97.5th percentiles. The s-value can be considered a test of directionality. More specifically it indicates how surprising (in bits) it would be to discover that the true value of the parameter is in the opposite direction to the estimate. An s-value of 4.3 bits, which is equivalent to a p-value (Kery and Schaub 2011; Greenland and Poole 2013) of 0.05, indicates that the surprise would be equivalent to throwing 4.3 heads in a row.

The results are displayed graphically by plotting the modeled relationships between particular variables and the response(s) with the remaining variables held constant. In general, continuous and discrete fixed variables are held constant at their mean and first level values, respectively, while random variables are held constant at their typical values (expected values of the underlying hyperdistributions) (Kery and Schaub 2011, 77–82). When informative the influence of particular variables is expressed in terms of the effect size (i.e., percent or n-fold change in the response variable) with 95% credible intervals (CIs, Bradford, Korman, and Higgins 2005).

The analyses were implemented using R version 4.2.1 (R Core Team 2021) and the mbr family of packages.

Model Descriptions

Length Correction

The annual bias (inaccuracy) and error (imprecision) in observer’s fish length estimates when spotlighting (standing) and snorkeling were quantified from the divergence of their length distribution from the length distribution for all observers (including measured fish) in that year. More specifically, the length correction that minimised the Jensen-Shannon divergence (Lin 1991) between the two distributions provided a measure of the inaccuracy while the minimum divergence (the Jensen-Shannon divergence was calculated with log to base 2 which means it lies between 0 and 1) provided a measure of the imprecision.

After correcting the fish lengths, age-1 individuals were assumed to be those with a fork length \(\leq\) 100 mm.

Abundance

The abundance was estimated from the count data using an overdispersed Poisson model (Kery and Schaub 2011, 55–56). The annual abundance estimates represent the total number of fish in the study area.

Key assumptions of the abundance model include:

  • The lineal fish density varies with year, useable width and river kilometer as a polynomial, and randomly with site.
  • The observer efficiency at marking sites varies by study design (GPS versus Index).
  • The observer efficiency also varies by visit type (marking versus count) within study design and randomly by snorkeller.
  • The expected count at a site is the expected lineal density multiplied by the site length, the observer efficiency and the proportion of the site surveyed.
  • The residual variation in the actual count is gamma-Poisson distributed.

Condition

The condition of fish with a fork length \(\geq\) 500 mm was estimated via an analysis of mass-length relations (He et al. 2008).

More specifically the model was based on the allometric relationship

\[ W = \alpha_c L^{\beta_c}\]

where \(W\) is the weight (mass), \(\alpha_c\) is the coefficent, \(\beta_c\) is the exponent and \(L\) is the length.

To improve chain mixing the relation was log-transformed, i.e.,

\[ \log(W) = \log(\alpha_c) + \beta_c \log(L).\]

Key assumptions of the condition model include:

  • \(\alpha_c\) can vary randomly by year.
  • The residual variation in weight is log-normally distributed.

Fecundity

The fecundity of females with a fork length \(\geq\) 500 mm was estimated via an analysis of fecundity-mass relations.

More specifically the model was based on the allometric relationship

\[ F = \alpha_f W^{\beta_f}\]

where \(F\) is the fecundity, \(\alpha_f\) is the coefficent, \(\beta_f\) is the exponent and \(W\) is the weight.

To improve chain mixing the relation was log-transformed.

Key assumptions of the fecundity model include:

  • The residual variation in fecundity is log-normally distributed.

Spawner Size

The average length of the spawners in each year (for years for which it was unavailable) was estimated from the mean weight of Rainbow Trout in the Kootenay Lake Rainbow Trout Mailout Survey (KLRT) using a linear regression. This approach was suggested by Rob Bison.

Egg Deposition

The egg deposition in each year was estimated by

  1. converting the average length of spawners to the average weight using the condition relationship for a typical year
  2. adjusting the average weight by the annual condition effect (interpolating where unavailable)
  3. converting the average weight to the average fecundity using the fecundity relationship
  4. multiplying the average fecundity by the AUC based estimate of the number of females (assuming a sex ratio of 1:1)

Stock-Recruitment

The relationship between the number of eggs (\(E\)) and the abundance of age-1 individuals the following spring (\(R\)) was estimated using a Beverton-Holt stock-recruitment model (Walters and Martell 2004):

\[ R = \frac{\alpha_s \cdot E}{1 + \beta_s \cdot E} \quad,\]

where \(\alpha_s\) is the maximum number of recruits per egg (egg survival), and \(\beta_s\) is the density dependence.

Key assumptions of the stock-recruitment model include:

  • The residual variation in the number of recruits is log-normally distributed with the standard deviation scaling with the uncertainty in the number of recruits.

The age-1 carrying capacity (\(K\)) is given by:

\[ K = \frac{\alpha_s}{\beta_s} \quad.\]

and the \(E_{K/2}\) Limit Reference Point (Mace 1994) (\(E_{0.5 R_{max}}\)), which corresponds to the stock (number of eggs) that produce 50% of the maximum recruitment (\(K\)), by \[E_{K/2} = \frac{1}{\beta_s}\]

The LRP was also converted into a number of spawners in a typical year (assuming 6,000 eggs per spawner and a sex ratio of 1:1).

Age-1 to Age-2 Survival

The relationship between the number of age-1 individuals and the number of age-2 individuals the following year was estimated using a linear regression through the origin where the slope was constrained to lie between 0 and 1 by a logistic transformation.

Key assumptions of the survival rate model include:

  • The residual variation in the number of age-2 individuals is log-normally distributed.

Reproductive Rate

The maximum reproductive rate (the number of spawners per spawner at low density) not accounting for fishing mortality was calculated by multiplying \(\beta_s\) (number of recruits per egg at low density) from the stock-recruitment relationship by the inlake survival by the estimated eggs per spawner in each year (assuming a sex ratio of 1:1). The inlake survival from age-1 to spawning was calculated by dividing the subsequent number of spawners by the number of recruits assuming that equal numbers of fish spawn at age 5, 6 and 7.

Expected Spawners

The expected spawners without in river and/or in lake variation was calculated from the stock-recruitment relationship and assuming an age-1 to spawner survival of 0.69%.

Results

Model Templates

Abundance

  data {

    int<lower=0> nMarked;
    int<lower=0> Marked[nMarked];
    int<lower=0> Resighted[nMarked];
    int<lower=0> IndexMarked[nMarked];

    int<lower=0> nObs;
    int Marking[nObs];
    int Index[nObs];
    int<lower=0> nSwimmer;
    int<lower=0> Swimmer[nObs];
    int<lower=0> nYear;
    int<lower=0> Year[nObs];
    real Rkm[nObs];
    int<lower=0> nSite;
    int<lower=0> Site[nObs];

    real SiteLength[nObs];
    real SurveyProportion[nObs];

    int Count[nObs];
  }
  parameters {
    real bEfficiency;
    real bEfficiencyIndex;

    real bDensity;
    real<lower=0> sDensityYear;
    vector[nYear] bDensityYear;

    vector[4] bDensityRkm;
    real<lower=0> sDensitySite;
    vector[nSite] bDensitySite;

    real bEfficiencyMarking;
    real bEfficiencyMarkingIndex;

    real<lower=0,upper=5> sEfficiencySwimmer;
    vector[nSwimmer] bEfficiencySwimmer;

    real<lower=0> sDispersion;
  }
  model {

    vector[nObs] eDensity;
    vector[nObs] eEfficiency;
    vector[nObs] eAbundance;
    vector[nObs] eCount;

    sDispersion ~ gamma(0.01, 0.01);

    bDensity ~ normal(0, 2);
    bDensityRkm ~ normal(0, 2);
    sDensitySite ~ uniform(0, 5);
    bDensitySite ~ normal(0, sDensitySite);
    sDensityYear ~ uniform(0, 5);
    bDensityYear ~ normal(0, sDensityYear);

    bEfficiency ~ normal(0, 5);
    bEfficiencyIndex ~ normal(0, 5);
    bEfficiencyMarking ~ normal(0, 5);
    bEfficiencyMarkingIndex ~ normal(0, 5);
    sEfficiencySwimmer ~ uniform(0, 5);
    bEfficiencySwimmer ~ normal(0, sEfficiencySwimmer);

    for (i in 1:nMarked) {
      target += binomial_lpmf(Resighted[i] | Marked[i],
        inv_logit(
          bEfficiency +
          bEfficiencyIndex * IndexMarked[i] +
          bEfficiencyMarking +
          bEfficiencyMarkingIndex * IndexMarked[i]
        ));
    }

    for (i in 1:nObs) {
      eDensity[i] = exp(bDensity +
                        bDensityRkm[1] * Rkm[i] +
                        bDensityRkm[2] * pow(Rkm[i], 2.0) +
                        bDensityRkm[3] * pow(Rkm[i], 3.0) +
                        bDensityRkm[4] * pow(Rkm[i], 4.0) +
                        bDensitySite[Site[i]] +
                        bDensityYear[Year[i]]);

      eEfficiency[i] = inv_logit(
        bEfficiency +
        bEfficiencyIndex * Index[i] +
        bEfficiencyMarking * Marking[i] +
        bEfficiencyMarkingIndex * Index[i] * Marking[i] +
        bEfficiencySwimmer[Swimmer[i]]);

      eAbundance[i] = eDensity[i] * SiteLength[i];

      eCount[i] = eAbundance[i] * eEfficiency[i] * SurveyProportion[i];
    }

    target += neg_binomial_2_lpmf(Count | eCount, sDispersion);
  }

Block 1. Abundance model description.

Condition

 data {
  int nYear;
  int nObs;

  vector[nObs] Length;
  vector[nObs] Weight;
  int Year[nObs];

parameters {
  real bWeight;
  real bWeightLength;
  real sWeightYear;

  vector[nYear] bWeightYear;
  real sWeight;

model {

  vector[nObs] eWeight;

  bWeight ~ normal(-10, 5);
  bWeightLength ~ normal(3, 2);

  sWeightYear ~ normal(-2, 5);

  for (i in 1:nYear) {
    bWeightYear[i] ~ normal(0, exp(sWeightYear));
  }

  sWeight ~ normal(-2, 5);
  for(i in 1:nObs) {
    eWeight[i] = bWeight + bWeightLength * log(Length[i]) + bWeightYear[Year[i]];
    Weight[i] ~ lognormal(eWeight[i], exp(sWeight));
  }

Block 2.

Fecundity

 data {
  int nObs;

  vector[nObs] Weight;
  vector[nObs] Fecundity;

parameters {
  real bFecundity;
  real bFecundityWeight;
  real sFecundity;

model {

  vector[nObs] eFecundity;

  bFecundity ~ uniform(0, 5);
  bFecundityWeight ~ uniform(0, 2);
  sFecundity ~ uniform(0, 1);

  for(i in 1:nObs) {
    eFecundity[i] = log(bFecundity) + bFecundityWeight * log(Weight[i]);
    Fecundity[i] ~ lognormal(eFecundity[i], sFecundity);
  }

Block 3.

Stock-Recruitment

model {
  a ~ dunif(0, 1)
  b ~ dunif(0, 0.1)
  sScaling ~ dunif(0, 5)

  eRecruits <- a * Stock / (1 + Stock * b)

  for(i in 1:nObs) {
    esRecruits[i] <- SDLogRecruits[i] * sScaling
    Recruits[i] ~ dlnorm(log(eRecruits[i]), esRecruits[i]^-2)
  }

Block 4. Stock-Recruitment model description.

Age-1 to Age-2 Survival

model {
  bSurvival ~ dnorm(0, 2^-2)
  sRecruits ~ dnorm(0, 2^-2) T(0,)

  for(i in 1:nObs) {
    logit(eSurvival[i]) <- bSurvival
    eRecruits[i] <- Stock[i] * eSurvival[i]
    Recruits[i] ~ dlnorm(log(eRecruits[i]), sRecruits^-2)
  }

Block 5. In-river survival model description.

Tables

Abundance

Table 1. Parameter descriptions.

Parameter Description
bDensity Intercept for log(eDensity)
bDensityRkm[i] ith-order polynomial coefficients of effect of river kilometer on bDensity
bDensitySite[i] Effect of ith Site on bDensity
bDensityYear[i] Effect of ith Year on bDensity
bEfficiency Intercept of logit(eEfficiency)
bEfficiencyIndex Effect of Index on bEfficiency
bEfficiencyMarking Effect of Marking on bEfficiency
bEfficiencyMarkingIndex Effect of Marking and Index on bEfficiency
bEfficiencySwimmer[i] Effect of ith Swimmer on bEfficiency
eAbundance[i] Expected abundance of fish at site of ith visit
eCount[i] Expected total number of fish at site of ith visit
eDensity[i] Expected lineal density of fish at site of ith visit
eEfficiency[i] Expected observer efficiency on ith visit
Index Whether the ith visit was to an index site
Marking[i] Whether the ith visit was to a site with marked fish
Rkm[i] River kilometer of ith visit
sDensitySite SD of bDensitySite
sDispersion Overdispersion of Count[i]
sEfficiencySwimmer SD of bEfficiencySwimmer
Site[i] Site of ith visit
SiteLength[i] Length of site of ith visit
SurveyProportion[i] Proportion of site surveyed on ith visit
Swimmer[i] Snorkeler on ith site visit
Year[i] Year of ith site visit
Age-1

Table 2. Model coefficients.

term estimate lower upper svalue
bDensity -1.3191132 -1.8036455 -0.8421649 10.551708
bDensityRkm[1] -0.1819292 -0.3431282 -0.0211975 5.597512
bDensityRkm[2] 0.5891371 0.3713218 0.7927338 10.551708
bDensityRkm[3] -0.1188817 -0.1948475 -0.0413166 8.966746
bDensityRkm[4] -0.2692633 -0.3393116 -0.1999669 10.551708
bEfficiency -1.7272366 -1.9859901 -1.4610558 10.551708
bEfficiencyIndex 0.3305805 -0.3095163 0.9597061 1.612129
bEfficiencyMarking 0.4856047 0.2859932 0.6981010 10.551708
bEfficiencyMarkingIndex 0.8690524 0.2239517 1.5136807 6.464245
sDensitySite 0.6856303 0.6222728 0.7570833 10.551708
sDensityYear 0.7059636 0.4944832 1.1250281 10.551708
sDispersion 1.3284629 1.2013796 1.4637219 10.551708
sEfficiencySwimmer 0.4098476 0.2426286 0.7359159 10.551708

Table 3. Model summary.

n K nchains niters nthin ess rhat converged
3722 13 3 500 5 602 1.007 TRUE

Table 4. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean -0.2980727 -0.3699643 -0.4009939 -0.3363147 10.55171
variance 0.5909931 0.8442941 0.8014782 0.8858560 10.55171
skewness 0.1956923 0.5616299 0.4830672 0.6468136 10.55171
kurtosis -0.5584910 -0.1640892 -0.3479898 0.0521683 10.55171

Table 5. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
3722 13 3 500 1.007 1.007 1.005 TRUE
Age-2

Table 6. Model coefficients.

term estimate lower upper svalue
bDensity -2.1576868 -2.6213089 -1.6653381 10.5517083
bDensityRkm[1] -0.2157413 -0.4034171 -0.0341461 5.7968208
bDensityRkm[2] 0.0557773 -0.2042295 0.2872866 0.5114185
bDensityRkm[3] 0.0393208 -0.0476804 0.1257511 1.3893169
bDensityRkm[4] -0.0941128 -0.1771044 -0.0111043 5.5073141
bEfficiency -1.9978359 -2.3747448 -1.6009734 10.5517083
bEfficiencyIndex 0.5628056 -0.0712645 1.2530742 3.6568905
bEfficiencyMarking 0.8569872 0.5400716 1.1501859 10.5517083
bEfficiencyMarkingIndex 1.9990177 1.0076340 3.0541744 10.5517083
sDensitySite 0.8049001 0.7232594 0.9023313 10.5517083
sDensityYear 0.5559179 0.3689279 0.8712329 10.5517083
sDispersion 1.1933538 1.0242173 1.3906007 10.5517083
sEfficiencySwimmer 0.3245985 0.1851998 0.5761867 10.5517083

Table 7. Model summary.

n K nchains niters nthin ess rhat converged
3722 13 3 500 5 630 1.007 TRUE

Table 8. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean -0.3063702 -0.3359416 -0.3657830 -0.3061164 4.247928
variance 0.5692734 0.7155772 0.6703516 0.7618617 10.551708
skewness 0.7342701 0.9015469 0.8178274 0.9937097 10.551708
kurtosis -0.1561344 0.3828791 0.1200317 0.7127704 10.551708

Table 9. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
3722 13 3 500 1.007 1.007 1.004 TRUE

Condition

Table 10. Parameter descriptions.

Parameter Description
bWeight Intercept of log(eWeight)
bWeightLength Intercept of effect of log(Length) on bWeight
bWeightYear[i] Effect of ith Year on bWeight
eWeight[i] Expected Weight of ith fish
Length[i] Fork length of ith fish
sWeight Log standard deviation of residual variation in log(Weight)
sWeightYear Log standard deviation of bWeightYear
Weight[i] Recorded weight of ith fish
Year[i] Year ith fish was captured

Table 11. Model coefficients.

term estimate lower upper svalue
bWeight -8.998896 -9.662142 -8.355493 10.55171
bWeightLength 2.640312 2.542921 2.742534 10.55171
sWeight -1.418006 -1.457405 -1.379056 10.55171
sWeightYear -1.546157 -1.822178 -1.220710 10.55171

Table 12. Model summary.

n K nchains niters nthin ess rhat converged
1203 4 3 500 2 333 1.006 TRUE

Table 13. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean -0.0000528 -0.0013656 -0.0569195 0.0519441 0.0528591
variance 0.9795977 0.9999839 0.9186811 1.0841535 0.6106607
skewness -11.7238979 0.0003004 -0.1382502 0.1408926 10.5517083
kurtosis 291.0626050 -0.0196823 -0.2737206 0.3170168 10.5517083

Table 14. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
1203 4 3 500 1.006 1.011 1.006 TRUE

Fecundity

Table 15. Parameter descriptions.

Parameter Description
bFecundity Intercept of eFecundity
bFecundityWeight Effect of log(Weight) on log(bFecundity)
eFecundity[i] Expected Fecundity of ith fish
Fecundity[i] Fecundity of ith fish (eggs)
sFecundity SD of residual variation in log(Fecundity)
Weight[i] Weight of ith fish (mm)

Table 16. Model coefficients.

term estimate lower upper svalue
bFecundity 3.8451441 1.6349607 4.9258934 10.55171
bFecundityWeight 0.8622963 0.8323059 0.9604228 10.55171
sFecundity 0.1280776 0.0932338 0.1821577 10.55171

Table 17. Model summary.

n K nchains niters nthin ess rhat converged
22 3 3 500 2 192 1.009 TRUE

Table 18. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean 0.0054488 -0.0057738 -0.4236269 0.4095535 0.0468893
variance 0.9088132 0.9618860 0.4954824 1.6577328 0.2018742
skewness -2.1506877 0.0248265 -0.9156415 0.9072533 10.5517083
kurtosis 6.6256696 -0.4101113 -1.2057443 1.5717577 10.5517083

Table 19. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
22 3 3 500 1.009 1.011 1.009 TRUE

Stock-Recruitment

Table 20. Parameter descriptions.

Parameter Description
a Recruits per Stock at low density
b Density-dependence
eRecruits[i] Expected number of recruits from ith spawn year
esRecruits[i] Expected SD of residual variation in Recruits
Recruits[i] Number of recruits from ith spawn year
SDLogRecruits[i] Standard deviation of uncertainty in log(Recruits[i])
sScaling Scaling term for SD of residual variation in log(eRecruits)
Stock[i] Number of eggs in ith spawn year
Age-1

Table 21. Model coefficients.

term estimate lower upper svalue
a 0.4051283 0.2071657 0.9445078 10.55171
b 0.0000038 0.0000014 0.0000119 10.55171
sScaling 2.5545827 1.7642273 3.9754967 10.55171

Table 22. Model summary.

n K nchains niters nthin ess rhat converged
16 3 3 500 100 1500 1 TRUE

Table 23. Estimated carry capacity (with 95% CRIs).

estimate lower upper
105000 68500 167000

Table 24. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean -0.1016783 0.0076871 -0.4865492 0.4725687 0.6283808
variance 5.3987033 0.9589201 0.3997350 1.8077224 10.5517083
skewness 0.2346433 0.0105483 -0.9783509 1.0353895 0.6705943
kurtosis -0.8544186 -0.5287379 -1.3345995 1.6357222 0.7918201

Table 25. Estimated reference points (with 80% CRIs).

Metric estimate lower upper
eggs 263000.00000 111000 542000.0000
spawners 87.66667 37 180.6667

Table 26. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
16 3 3 500 1 1.003 1.002 TRUE

Age-1 to Age-2 Survival

Table 27. Parameter descriptions.

Parameter Description
bSurvival logit(eSurvival)
eSurvival[i] Expected annual survival for ith spawn year
Recruits[i] Number of age-2 juveniles from ith spawn year
sRecruits SD of residual variation in Recruits
Stock[i] Number of age-1 juveniles from ith spawn year
Age-2

Table 28. Model coefficients.

term estimate lower upper svalue
bSurvival -0.8137082 -1.1563345 -0.4251621 8.966746
sRecruits 0.4513792 0.3138275 0.7416565 10.551708

Table 29. Model summary.

n K nchains niters nthin ess rhat converged
14 2 3 500 1 501 1.005 TRUE

Table 30. Model posterior predictive checks.

moment observed median lower upper svalue
zeros NA NA NA NA NA
mean -0.0301543 0.0069067 -0.5361851 0.5320427 0.1734134
variance 0.8642184 0.9392247 0.4013889 1.8791225 0.2884391
skewness -0.3165703 0.0443921 -1.1136626 1.0758502 1.0183785
kurtosis -1.0777998 -0.5898205 -1.3883224 1.6315864 1.6660119

Table 31. Model sensitivity.

n K nchains niters rhat_1 rhat_2 rhat_all converged
14 2 3 500 1.005 1.005 1.004 TRUE

Figures

Length Correction

figures/length/measured.png

Figure 29. Measured length-frequency histogram by year.

figures/length/corrected.png

Figure 30. Corrected length-frequency histogram by year and observation type.

Abundance

Age-1

figures/abundance/Age1/abundance-year.png

Figure 31. Predicted abundance of age-1 Rainbow Trout in the Duncan and Lardeau Rivers by year (with 95% CRIs).

figures/abundance/Age1/density-site.png

Figure 32. Predicted lineal density of age-1 Rainbow Trout in 2010 by river kilometre (with 95% CRIs).

figures/abundance/Age1/efficiency-type.png

Figure 33. Predicted observer efficiency for age-1 Rainbow Trout by visit type and study design (with 95% CRIs).

Age-2

figures/abundance/Age2/abundance-year.png

Figure 34. Predicted abundance of age-2 Rainbow Trout in the Duncan and Lardeau Rivers by year (with 95% CRIs).

figures/abundance/Age2/density-site.png

Figure 35. Predicted lineal density of age-2 Rainbow Trout in 2010 by river kilometre (with 95% CRIs).

figures/abundance/Age2/efficiency-type.png

Figure 36. Predicted observer efficiency for age-2 Rainbow Trout by visit type and study design (with 95% CRIs).

Condition

figures/condition/year.png

Figure 37. The percent change in the body condition for an average length fish relative to a typical year by year (with 95% CRIs).

Fecundity

figures/fecundity/fecundity.png

Figure 38. The fecundity-weight relationship (with 95% CRIs).

Spawner Size

figures/fishery/length.png

Figure 39. The mean length of spawning Rainbow Trout by the mean weight of Rainbow Trout in the KLRT.

figures/fishery/weight.png

Figure 40. The mean weight of Rainbow Trout in the KLRT by year.

Egg Deposition

figures/eggs/eggs-spawners.png

Figure 41. The spawner abundance by year.

figures/eggs/eggs-fecundity.png

Figure 42. The estimated spawner fecundity by year.

figures/eggs/eggs-eggs.png

Figure 43. The egg deposition by year.

Stock-Recruitment

Age-1

figures/sr/Age1/stock-recruitment.png

Figure 44. Predicted stock-recruitment relationship between spawners and age-1 recruits (with 95% CRIs).

figures/sr/Age1/recruits-per-spawner.png

Figure 45. Predicted egg survival to age-1 by egg deposition (with 95% CRIs).

figures/sr/Age1/percent-carry-capacity.png

Figure 46. Predicted percent of age-1 recruits carry capacity by egg deposition (with 80% CRIs).

Age-1 to Age-2 Survival

Age-2

figures/inriver/Age2/survival.png

Figure 47. Predicted relationship between age-1 and age-2 abundance (with 95% CRIs).

figures/inriver/Age2/age1toage2survival.png

Figure 48. Estimated age-1 and age-2 survival by spawn year.

Inlake

figures/inlake/inlake-spawners.png

Figure 49. The number of spawners by return year.

figures/inlake/inlake-deposition.png

Figure 50. The estimated egg deposition by return year.

figures/inlake/inlake-recruits.png

Figure 51. The number of expected age-1 recruits by spawn year based on the estimated egg deposition.

figures/inlake/inlake-survival.png

Figure 52. Survival from expected age-1 to spawners by return year.

Reproductive Rate (age-1)

figures/rmax/inlake.png

Figure 53. Survival from age-1 to spawning by return year.

Reproductive Rate (age-2)

figures/rmax2/inlake.png

Figure 54. Survival from age-2 to spawning by return year.

Expected Spawners

figures/espawners/spawnersexpected.png

Figure 55. Expected spawners by return year and in river and in lake variation based on age-1 recruitment.

figures/espawners/spawnersexpected2.png

Figure 56. Expected spawners by return year and in river and in lake variation based on age-2 recruitment.

Acknowledgements

The organisations and individuals whose contributions have made this analysis report possible include:

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