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https://github.com/guyabel/tsbugs


https://github.com/guyabel/tsbugs

Last synced: 11 months ago
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README 

          
---

output: github_document

---



```{r, include = FALSE}

knitr::opts_chunk$set(

  collapse = TRUE,

  comment = "#>",

  fig.path = "man/figures/README-",

  out.width = "100%"

)

```



# tsbugs



## Installation



You can install the development version from [GitHub](https://github.com/) with:



``` r

# install.packages("devtools")

devtools::install_github("guyabel/tsbugs")

```



The package is no longer on CRAN.



## Details



The functions in the tsbugs package are aimed to automate the writing of time series models to run in WinBUGS or OpenBUGS. I created these functions when working on [model averaging for time series models](https://www.demographic-research.org/volumes/vol29/43/default.htm). I found it a lot easier to build R functions to write the BUGS models than the more error-inducing process of copy and pasting BUGS scripts, and then making slight alterations to create new models. It also allowed me to add arguments to specify different lag lengths, prior distributions, variance assumptions and data lengths. Below are examples for three types of time series models; autorgressive models with 

  

  - [Constant variance](https://github.com/guyabel/tsbugs#autoregressive-models)

  - [Stochastic volatility](https://github.com/guyabel/tsbugs#stochastic-volatility-models)

  - [Random variance shift models](https://github.com/guyabel/tsbugs#random-variance-shift-models)



## Autoregressive Models



The `ar.bugs` command builds a BUGS script for autoregressive (AR) models ready to use in R2OpenBUGS. For example, consider the `LakeHuron` data.

```{r, fig.show='hide'}

LH <- LakeHuron

par(mfrow=c(2,1))

plot(LH, main="Level (ft)")

plot(diff(LH), main="Differenced Level")

```

tsbugs1-cvdata


We can construct a AR(1) model for this data (after differencing the data to obtain a stationary mean) as such:

```{r}

library(tsbugs)

ar1 <- ar.bugs(y=diff(LH), ar.order=1)

print(ar1$bug)

```

The `ar.bugs` function allows for alternative specifications for prior distributions, forecasts and the inclusion of mean term:

```{r}

ar2 <- ar.bugs(y=diff(LH), ar.order=2, ar.prior="dunif(-1,1)", var.prior="dgamma(0.001,0.001)",

               k = 10, mean.centre = TRUE)

print(ar2$bug)

```

The tsbugs objects can be used with R2OpenBUGS to easily run models from R. This is made even easier using the `inits` and `nodes` functions (also in the tsbugs package). For example:

```{r, eval = FALSE}

writeLines(ar2$bug, "ar2.txt")

library("R2OpenBUGS")

ar2.bug <- bugs(data = ar2$data,

                inits = list(inits(ar2)),

                param = c(nodes(ar2, "prior")$name, "y.new"),

                model = "ar2.txt",

                n.iter = 11000, n.burnin = 1000, n.chains = 1)

```

Note, 1) the model is written to a `.txt` file (as required by R2OpenBUGS), 2) the data used is part of the `tsbugs` object. The `ar.bugs` command cleans the data and adds missing values at the end of the series for foretasted values, 3) the initial values offered by the inits function are very crude, and with more complicated data or models, users might be better off specifying there own list of initial values. The parameter traces and posterior distributions can be plotted using the coda package:

```{r, eval=FALSE}

library(coda)

param.mcmc <- as.mcmc(ar2.bug$sims.matrix[,nodes(ar2, "prior")$name])

plot(param.mcmc[,1:4])

```

tsbugs1-cvparam



The fanplot package can be used to plot the entire series of posterior predictive distributions. We may also plot (after deriving using the `diffinv` function) the posterior predictive distributions of the lake level:

```{r, eval=FALSE}

# derive future level

ynew.mcmc <- ar2.bug$sims.list$y.new

lhnew.mcmc <- apply(ynew.mcmc, 1, diffinv, xi = tail(LH,1))

lhnew.mcmc <- t(lhnew.mcmc[-1,])



# plot differenced

par(mfrow=c(2,1))

plot(diff(LH), xlim = k0 + c(-50, 10), main="Differenced Level")



# add fan

library("fanplot")

k0 <- end(LH)[1]

fan(ynew.mcmc, start=k0+1, rcex=0.5)



# plot undifferenced

plot(LH, xlim=k0+c(-50,10), main="Level")

fan(lhnew.mcmc, start=k0+1, rcex=0.5)

```

tsbugs1-cvforc



## Stochastic Volatility Models



The `sv.bugs` command builds a BUGS script for stochastic volatility SV models ready to use in R2OpenBUGS. For example, consider the `svpdx` data.

```{r, eval=FALSE}

# plot

plot(svpdx$pdx, type = "l",

     main = "Return of Pound-Dollar exchange rate data from 2nd October 1981 to 28th June 1985", 

     cex.main = 0.8)

```

tsbugs1-svdata


We can construct a AR(0)-SV model for this data, and also obtain posterior simulations using the `sv.bugs` command:

```{r}

y <- svpdx$pdx

sv0 <- sv.bugs(y, sim=TRUE)

print(sv0$bug)

```

This model closely matches those presented in Meyer and Yu (2002). There are further options in the tsbugs package to incorporate different priors that do not involve transformations such as those for `psi1` above. Using R2OpenBUGS we can fit the model,

```{r, eval=FALSE}

# decent initial value for variance in first period

init <- inits(sv0, warn=FALSE)

init$psi0 <- log(var(y))

# write bug

writeLines(sv0$bug, "sv0.txt")

# might take a while to compile

sv0.bug <- bugs(data = sv0$data,

                inits = list(init),

                param = c(nodes(sv0, "prior")$name,"y.sim","h"),

                model = "sv0.txt",

                n.iter = 11000, n.burnin = 1000, n.chains = 1)

```

The volatility and estimates can be easily extracted,

```{r, eval=FALSE}

h.mcmc <- sv0.bug$sims.list$h

```

Which allows us to directly view the estimated volatility process or the time-dependent standard deviation using the fanplot package,

```{r, eval=FALSE}

# plot

plot(NULL, xlim = c(1, 945)+c(0,40), ylim = c(-4,2), main="Estimated Volatility from SV Model")

# fan

fan(h.mcmc, type = "interval")

```

tsbugs1-svh
We can also plot the posterior simulations from the model:

```{r, eval=FALSE}

# derive percentiles

y.mcmc <- sv0.bug$sims.list$y.sim

# plot

plot(NULL, type = "l", xlim = c(1, 945)+c(0,20), ylim = range(y), 

     main = "Posterior Model Simulations and Data")

fan(y.mcmc)

lines(y)

```

tsbugs1-svysim



## Random Variance Shift Models



The `rv.bugs` command builds a BUGS script for random variance (RV) shift models, similar to that of McCulloch and Tsay (1993) ready to use in R2OpenBUGS. Consider the `ew` data.

```{r, eval=FALSE}

r <- ts(ew[2:167]/ew[1:166]-1, start=1841)

y <- diff(r)

plot(y, main="Difference in England and Wales Population Growth Rate")

```

tsbugs1-rvdata
We can create a BUGS script to fit a RV model to this data, including posterior simulations, using the `rv.bugs` command:

```{r, eval=FALSE}

rv0 <- rv.bugs(y, sim=TRUE)

print(rv0)

```

and then run the script in R2OpenBUGS (this can take a couple of hours):

```{r, eval=FALSE}

# decent inital value for variance in first period

init <- inits(rv0, warn=FALSE)

init$isig02<-sd(y)^-2

# write bug

writeLines(rv0$bug,"rv0.txt")

# might take a while to compile

rv0.bug <- bugs(data = rv0$data,

                inits = list(init),

                param = c(nodes(rv0, "prior")$name,"y.sim",

                          "h","delta","beta"),

                model = "rv0.txt",

                n.iter = 11000, n.burnin = 1000, n.chains = 1)

```

We can plot the posterior simulations from the model using the fanplot package:

```{r, eval=FALSE}

# derive percentiles

y0 <- tsp(y)[1]

y.mcmc <- rv0.bug$sims.list$y.sim



# plot

plot(NULL, xlim=tsp(y)[1:2]+c(-5,5), ylim = range(y),

     main="Posterior Simulations")

fan(y.mcmc, start = y0, rlab=c(10,50,90), llab=TRUE)

lines(y)

```

tsbugs1-rvysim
Alongside the posterior distributions of the standard deviations,

```{r, eval=FALSE}

# derive sigma

h.mcmc <- rv0.bug$sims.list$h

sigma.mcmc <- sqrt(exp(h.mcmc))

# plots

plot(NULL, xlim =tsp(y)[1:2]+c(-5,5), ylim = c(0,0.008), main="Standard Deviation")

fan(sigma.mcmc, start = y0, rlab=c(5,50,95), llab = c(5,50,95))

```

tsbugs1-rvhsigma
The posterior distributions of the probability of a variance shift and multiplier effect of the shift in variance (`delta[t]` and `beta[t]` in the BUGS model) can also be plotted. Note, when there is no variance shift, the posterior of the `beta[t]` is similar to the prior distribution.

```{r, eval=FALSE}

#extract data

delta.mcmc <- rv0.bug$sims.list$delta

beta.mcmc <- rv0.bug$sims.list$beta



# plots

par(mfrow=c(2,1))

plot(NULL, xlim = tsp(y)[1:2]+c(-5,5), ylim = c(0,1), main="Probability of Variance Change Point")

fan(delta.mcmc, start=y0, ln = NULL, rlab = NULL)



plot(NULL, xlim = tsp(y)[1:2]+c(-5,5), ylim = c(-2,2), main="Variance Multiplier")

fan(beta.mcmc, start=y0)

```

tsbugs1-rvbeta