---
title: "Ex 3: Lake"
output: html_vignette
vignette: >
%\VignetteIndexEntry{Ex 3: Lake}
%\VignetteEngine{knitr::rmarkdown}
\usepackage[utf8]{inputenc}
---
Here we step through the Lake Example using the **script** version of MixSIAR. For a demonstration using the **GUI** version, see the [MixSIAR Manual](https://github.com/brianstock/MixSIAR/blob/master/inst/mixsiar_manual_small.pdf). For a thorough walkthrough of how to use MixSIAR in a script, see the [Wolves Example](https://brianstock.github.io/MixSIAR/articles/wolves_ex.html), which provides more commentary and explanation.
For a clean, runnable `.R` script, look at `mixsiar_script_lake.R` in the `example_scripts` folder of the MixSIAR package install:
```{r, eval=FALSE}
library(MixSIAR)
mixsiar.dir <- find.package("MixSIAR")
paste0(mixsiar.dir,"/example_scripts")
```
You can run the lake example script directly with:
```{r, eval=FALSE}
source(paste0(mixsiar.dir,"/example_scripts/mixsiar_script_lake.R"))
```
## Lake Example
The Lake Example data is simulated based on [Francis et al. 2011](https://doi.org/10.1111/j.1461-0248.2011.01597.x) and we include it as a example of how MixSIAR can include a **continuous effect**. Here we examine the diet of zooplankton in 21 lakes using:
+ 2 biotracers ($\delta^{13}$C, $\delta^{15}$N)
+ 1 **continuous effect** (Secchi Depth : Mixed Layer Depth)
+ Raw source data
MixSIAR fits a continuous covariate as a linear regression in ILR/transform-space. Two terms are fit for the proportion of each source: an intercept and a slope. The [plot](https://github.com/brianstock/MixSIAR/blob/master/Manual/lake_posterior_density_diet_p_Secchi.Mixed.pdf) uses the posterior median estimates of the intercept and slope, and the lines are curved because of the ILR-transform back into p-space. For details, or if you would like to make modifications, see ?plot_continous_var.R.
Fitting a model with a continuous effect is more complex than the categorical fixed/random effects and can be a bit finicky.
### Load MixSIAR package
```{r}
library(MixSIAR)
```
### Load mixture data
See ?load_mix_data for details.
The lake consumer data has 1 covariate, which we fit as a continuous effect (`cont_effects="Secchi.Mixed"`). There are no fixed/random effects (`factors=NULL`, `fac_random=NULL`, `fac_nested=NULL`).
```{r}
# Replace the system.file call with the path to your file
mix.filename <- system.file("extdata", "lake_consumer.csv", package = "MixSIAR")
mix <- load_mix_data(filename=mix.filename,
iso_names=c("d13C","d15N"),
factors=NULL,
fac_random=NULL,
fac_nested=NULL,
cont_effects="Secchi.Mixed")
```
### Load source data
See ?load_source_data for details.
We have no fixed/random effects in the model (`source_factors=NULL`), and we do not have concentration dependence data (`conc_dep=FALSE`). We have the original "raw" source data, not means and SDs (`data_type="raw"`).
```{r}
# Replace the system.file call with the path to your file
source.filename <- system.file("extdata", "lake_sources.csv", package = "MixSIAR")
source <- load_source_data(filename=source.filename,
source_factors=NULL,
conc_dep=FALSE,
data_type="raw",
mix)
```
### Load discrimination data
See ?load_discr_data for details.
```{r}
# Replace the system.file call with the path to your file
discr.filename <- system.file("extdata", "lake_discrimination.csv", package = "MixSIAR")
discr <- load_discr_data(filename=discr.filename, mix)
```
### Plot data
This is your chance to check:
+ Are the data loaded correctly?
+ Is your mixture data in the source polygon?
+ Are one or more of your sources confounded/hidden?
```{r, eval=FALSE}
# Make an isospace plot
plot_data(filename="isospace_plot", plot_save_pdf=TRUE, plot_save_png=FALSE, mix,source,discr)
```
### Calculate convex hull area
Calculate normalized surface area of the convex hull polygon(s) as in [Brett (2014)](https://www.int-res.com/articles/suppl/m514p001_supp.pdf).
**Note 1:** discrimination SD is added to the source SD (see ?calc_area for details)
```{r}
# Calculate the convex hull area, standardized by source variance
calc_area(source=source,mix=mix,discr=discr)
```
### Plot prior
Define your prior, and then plot using "plot_prior"
+ RED = your prior
+ DARK GREY = "uninformative"/generalist (alpha = 1)
+ LIGHT GREY = "uninformative" Jeffrey's prior (alpha = 1/n.sources)
```{r, eval=FALSE}
# default "UNINFORMATIVE" / GENERALIST prior (alpha = 1)
plot_prior(alpha.prior=1,source)
```
### Write JAGS model file
In the Lake Example we demo the "Residual only" error option. The differences between "Residual * Process", "Residual only", and "Process only" are explained in [Stock and Semmens (2016)](https://doi.org/10.1002/ecy.1517).
```{r, eval=FALSE}
# Write the JAGS model file
model_filename <- "MixSIAR_model.txt"
resid_err <- TRUE
process_err <- FALSE
write_JAGS_model(model_filename, resid_err, process_err, mix, source)
```
### Run model
Choose one of the MCMC run options:
| run == | Chain Length | Burn-in | Thin | # Chains |
| ------------- | ------------- | ------------- | ------------- | ------------- |
| "test" | 1,000 | 500 | 1 | 3 |
| "very short" | 10,000 | 5,000 | 5 | 3 |
| "short" | 50,000 | 25,000 | 25 | 3 |
| "normal" | 100,000 | 50,000 | 50 | 3 |
| "long" | 300,000 | 200,000 | 100 | 3 |
| "very long" | 1,000,000 | 500,000 | 500 | 3 |
| "extreme" | 3,000,000 | 1,500,000 | 500 | 3 |
First use `run = "test"` to check if 1) the data are loaded correctly and 2) the model is specified correctly:
```{r, eval=FALSE}
jags.1 <- run_model(run="test", mix, source, discr, model_filename)
```
After a test run works, increase the MCMC run to a value that may converge:
```{r, eval=FALSE}
jags.1 <- run_model(run="normal", mix, source, discr, model_filename)
```
### Analyze diagnostics and output
MixSIAR fits a continuous covariate as a linear regression in ILR/transform-space. Two terms are fit for the proportion of each source: an intercept and a slope. The [plot](https://github.com/brianstock/MixSIAR/blob/master/Manual/lake_posterior_density_diet_p_Secchi.Mixed.pdf) uses the posterior median estimates of the intercept and slope, and the lines are curved because of the ILR-transform back into p-space. For details, or if you would like to make modifications, see ?plot_continous_var. See ?output_JAGS for output options.
The other posterior plots MixSIAR produces for a continuous effect show the estimated diet for the minimum, median, and maximum individuals.
```{r, eval=FALSE}
output_JAGS(jags.1, mix, source, output_options)
```