# How to fit autoregressive poisson mixed model (count time series) in R?

My task is to assess how various environmental variables affect annual population fluctuations. For this, I need to fit poisson autoregressive model for time-series counts:

Where Ni,j is the count of observed individuals at site i in year j, x_{i,j} is environmental variable at site i in year j - these are the input data, and the rest are parameters: \mu_{i,j} is the expected number of individuals at site i in year j, and \gamma_{j} is random effect for each year.

Is it possible to fit such a model in R? I want to avoid fitting it in Bayesian framework since the computation takes way to long (I have to process 5000 of such models) I tried to transform the model for GLM, but once I had to add the random effect (gamma) it is no longer possible.

-
I'm very skeptical that non-bayesian solution for this exist for this precise model formulation, as $\mu_{i,j}$ will be a quantity estiamted from the model. it's highly unusual for estimated quantities to appear as offsets on the right hand side of the model. if you had $\log(N_{i, j})$, i.e. the realized values, instead of the expected value $\log(\mu_{i,j})$ as offset on the right hand side this would be very easy to fit with standard software for GLMMs: Simply use N as an offset variable. Let me know if this is possible for you, then i will add a more detailed answer. – fabians Mar 21 '14 at 16:44

First, let's create some simulated data (all the ad hoc functions at the end of the answer):

set.seed(12345) # updated to T=20 and L=40 for comparative purposes.

T = 20 # number of years
L = 40  # number of sites
N0 = 100 # average initial pop (to simulate data)
sd_env = 0.8 # to simulate the env (assumed mean 0)
env  = matrix(rnorm(T*L, mean=0, sd=sd_env), nrow=T, ncol=L)

# 'real' parameters
alpha  = 0.1
beta   = 0.05
sd     = 0.4
gamma  = rnorm(T-1, mean=0, sd=sd)
mu_ini = log(rpois(n=L, lambda=N0)) #initial means

par_real = list(alpha=alpha, beta=beta, gamma=gamma,
sd=sd, mu_ini=mu_ini)

mu = dynamics(par=par_real, x=env, T=T, L=L)

# observed abundances
n = matrix(rpois(length(mu), lambda=mu), nrow=T, ncol=L)


Now, for a given set of parameters, we can simulate the expected number of individuals at each site and year. And since we have the observed number of individuals, we can write the likelihood function for the observations (being Poisson distributed) and add a penalty for the annual deviates in the growth rate (to make it normal distributed). For this, the function dynamics will simulate the model and the function .getLogLike will calculate the objective function. Now we need to optimize the objective function. The parameters to estimate are alpha, beta, the annual deviates (gamma) and the initial expected number of individuals (mu_ini), and maybe sigma.

For the first try, we can provide 0 for all parameters as initial guesses but for the initial expected numbers for which we can use the initial observed abundances (that's the MLE anyway).

fit0 = fitModel0(obs=n, env=env, T=T, L=L)

Optimal parameters:
alpha        beta      gamma1      gamma2      gamma3
0.28018842  0.05464360 -0.12904373 -0.15795001 -0.04502903
gamma4      gamma5      gamma6      gamma7      gamma8
0.05045117  0.08435066  0.28864816  0.24111786 -0.80569709
gamma9     gamma10     gamma11     gamma12     gamma13
0.22786951  0.10326086 -0.50096088 -0.08880594 -0.33392310
gamma14     gamma15     gamma16     gamma17     gamma18
0.22664634 -0.47028311  0.11782381 -0.16328820  0.04208037
gamma19     mu_ini1     mu_ini2     mu_ini3     mu_ini4
0.17648808  4.14267523  4.19187205  4.05573114  3.90406443
mu_ini5     mu_ini6     mu_ini7     mu_ini8     mu_ini9
4.08975038  4.17185883  4.03679049  4.23091760  4.04940333
mu_ini10    mu_ini11    mu_ini12    mu_ini13    mu_ini14
4.19355333  4.05543081  4.15598515  4.18266682  4.09095730
mu_ini15    mu_ini16    mu_ini17    mu_ini18    mu_ini19
4.17922360  3.87211968  4.04509178  4.19385641  3.98403521
mu_ini20    mu_ini21    mu_ini22    mu_ini23    mu_ini24
4.08531659  4.19294203  4.29891769  4.21025211  4.16297457
mu_ini25    mu_ini26    mu_ini27    mu_ini28    mu_ini29
4.19265543  4.28925869  4.10752810  4.10957212  4.14953247
mu_ini30    mu_ini31    mu_ini32    mu_ini33    mu_ini34
4.09690570  4.34234547  4.18169575  4.01663339  4.32713905
mu_ini35    mu_ini36    mu_ini37    mu_ini38    mu_ini39
4.08121891  3.98256819  4.08658375  4.05942834  4.06988174
mu_ini40
4.05655031


This works, but normally some parameters can be correlated and more difficult to identify from data, so a sequential approach can be used (can read Bolker et al. 2013 for more info). In this case, we increase progresively the number of parameters, improving the initial guess for the optimization at each phase of the calibration. For this example, the first phase only estimate alpha and beta, and using guesses for a linear model of the growth rate and the environment. Then, in the second phase we use the estimates from the first optimization and add the annual deviates as parameters (gamma). Finally, we use the estimates of the second optimization and add the initial expected values as parameters. We add the initial expected values last assuming the initial observed values are already very close and a good guess to start, but on the other side we have no clear idea of the values of the remaining parameters.

fit  = fitModel(obs=n, env=env, T=T, L=L)

Phase 1: alpha and beta only
Optimal parameters:
alpha       beta
0.18172961 0.06323379

neg-LogLikelihood:  -5023687
Phase 2: alpha, beta and gamma
Optimal parameters:
alpha        beta      gamma1      gamma2      gamma3
0.20519928  0.06238850 -0.35908716 -0.21453015 -0.05661066
gamma4      gamma5      gamma6      gamma7      gamma8
0.18963170  0.17800563  0.34303170  0.28960181 -0.72374927
gamma9     gamma10     gamma11     gamma12     gamma13
0.28464203  0.16900331 -0.40719047 -0.01292168 -0.25535610
gamma14     gamma15     gamma16     gamma17     gamma18
0.28806711 -0.38924648  0.19224527 -0.07875934  0.10880154
gamma19
0.24518786

neg-LogLikelihood:  -5041345
Phase 3: alpha, beta, gamma and mu_ini
Optimal parameters:
alpha          beta        gamma1        gamma2
0.1962334008  0.0545361273 -0.4298024242 -0.1984379386
gamma3        gamma4        gamma5        gamma6
0.0240318556  0.1909639571  0.1116636126  0.3465693397
gamma7        gamma8        gamma9       gamma10
0.3478695629 -0.7500599493  0.3600551021  0.1361405398
gamma11       gamma12       gamma13       gamma14
-0.3874453347 -0.0005839263 -0.2305008546  0.2819608670
gamma15       gamma16       gamma17       gamma18
-0.3615273177  0.1792020332 -0.0685681922  0.1203006457
gamma19       mu_ini1       mu_ini2       mu_ini3
0.2506129351  4.6639314468  4.7205977429  4.5802529032
mu_ini4       mu_ini5       mu_ini6       mu_ini7
4.4293994068  4.6182382472  4.7039110982  4.5668031666
mu_ini8       mu_ini9      mu_ini10      mu_ini11
4.7610910879  4.5844180026  4.7226353021  4.5823048717
mu_ini12      mu_ini13      mu_ini14      mu_ini15
4.6814189824  4.7130039559  4.6135420745  4.7100006841
mu_ini16      mu_ini17      mu_ini18      mu_ini19
4.4080115751  4.5758092977  4.7209394881  4.5150790425
mu_ini20      mu_ini21      mu_ini22      mu_ini23
4.6171948847  4.7141188899  4.8303375556  4.7392110431
mu_ini24      mu_ini25      mu_ini26      mu_ini27
4.6893526309  4.7237687961  4.8234804183  4.6333012324
mu_ini28      mu_ini29      mu_ini30      mu_ini31
4.6392335265  4.6817044754  4.6260620666  4.8713345071
mu_ini32      mu_ini33      mu_ini34      mu_ini35
4.7107116580  4.5471434622  4.8540773708  4.6129553933
mu_ini36      mu_ini37      mu_ini38      mu_ini39
4.5134108799  4.6231016082  4.5823454113  4.5969785420
mu_ini40
4.5835763300

neg-LogLikelihood:  -5047251


Comparing both calibrations of the model, we can see the second one provides a lower value for the objective function. Also, comparing the correlation between the 'real' annual deviates and the estimated ones, we have a higher correlation for the second calibration:

cor(gamma, fit0$par$gamma)
[1] 0.8708379
cor(gamma, fit$par$gamma)
[1] 0.9871758


And looking at the outputs, we can see we have some problems with the estimation of the initial expected values (underestimated for all sites) in the first calibration (with real data, normally a multi-phase calibration works way better):

par(mfrow=c(3,2), mar=c(3,5,1,1), oma=c(1,1,1,1))
for(i in 1:4) {
ylim=c(0, 1.1*log(max(fit$fitted, n))) plot(log(fit$fitted[,i]), type="l", col="blue", ylim=ylim,
ylab="mu (log)")
lines(log(fit0$fitted[,i]), col="green") points(log(mu[,i]), col="red") mtext(paste("Site ", i), 3, adj=0.05, line=-2) if(i==3) { mtext(c("observed", "fitModel0", "fitModel1"), 1, adj=0.95, line=-1.5:-3.5, col=c("red", "green", "blue"), cex=0.8) } } mus = rbind(mu_ini, fit$par$mu_ini, fit0$par$mu_ini) barplot(mus, beside=TRUE, col=c("red", "blue", "green"), ylab="Initial expected population", xlab="Sites", border=NA) gam = rbind(gamma, fit$par$gamma, fit0$par$gamma) barplot(gam, beside=TRUE, col=c("red", "blue", "green"), ylab="Annual deviates", border=NA)  Finally, system.time(fitModel(obs=n, env=env, T=T, L=L)) user system elapsed 9.85 0.00 9.85  Which is around four time slower than the solution proposed by @Thierry using INLA (from summary(model)): Time used: Pre-processing Running inla Post-processing Total 0.1070 2.3131 0.0460 2.4661  However, after byte compiling my functions, we get:  user system elapsed 7.53 0.00 7.53  It's 24% faster, and now is only 3 times slower than the INLA method. Still, I think is reasonable even for thousands of experiments (my own model takes 5 days just for one optimization, so maybe I have a bias here) and since we're using simulated data, we can compare the reliability of the parameter estimates in addition to the computer time. # The functions ----------------------------------------------------------- require(compiler) dynamics = function(par, obs, x, T, L) { alpha = par$alpha
beta   = par$beta gamma = if(!is.null((par$gamma))) par$gamma else rep(0, T-1) mu_ini = if(!is.null(par$mu_ini)) exp(par$mu_ini) else obs[1,] mu = matrix(nrow=T, ncol=L) mu[1,] = mu_ini for(t in seq_len(T-1)) { log_mu_new = log(mu[t,]) + alpha + beta*x[t,] + gamma[t] mu[t+1, ] = exp(log_mu_new) } return(mu) } dynamics = cmpfun(dynamics) reListPars = function(par) { out = list() out$alpha = as.numeric(par["alpha"])
out$beta = as.numeric(par["beta"]) if(!is.na(par["sd"])) out$sd = as.numeric(par["sd"])
gammas =  as.numeric(par[grepl("gamma", names(par))])
if(length(gammas)>0) out$gamma = gammas mu_inis = as.numeric(par[grepl("mu_ini", names(par))]) if(length(mu_inis)>0) out$mu_ini = mu_inis
return(out)
}

reListPars = cmpfun(reListPars)

.getLogLike = function(par, obs, env, T, L) {
par = reListPars(par)
if(is.null(par$sd)) { par$sd = if(!is.null(par$gamma)) sd(par$gamma)+0.01 else 1
}
mu = dynamics(par=par, obs=obs, x=env, T=T, L=L)
logLike = sum(obs*log(mu) - mu) - sum(par$gamma^2/(2*par$sd^2))
return(-logLike)
}

.getLogLike = cmpfun(.getLogLike)

.getUpper = function(par) {
par$alpha = 10*par$alpha + 1
par$beta = 10*abs(par$beta) + 1
if(!is.null(par$gamma)) { if(!is.null(par$sd)) sd = par$sd else sd=sd(par$gamma)
if(sd==0) sd=1
par$gamma = rep(qnorm(0.999, sd=sd), length(par$gamma))
}
if(!is.null(par$mu_ini)) par$mu_ini = 5*par$mu_ini if(!is.null(par$sd)) par$sd = 10*par$sd
par = unlist(par)
return(par)
}

.getUpper = cmpfun(.getUpper)

.getLower = function(par) {
par$alpha = 0 # alpha>0? par$beta  = -10*abs(par$beta) - 1 if(!is.null(par$gamma)) {
if(!is.null(par$sd)) sd = par$sd else sd=sd(par$gamma) if(sd==0) sd=1 par$gamma = rep(qnorm(1-0.999, sd=sd), length(par$gamma)) } if(!is.null(par$mu_ini)) par$mu_ini = 0.2*par$mu_ini
if(!is.null(par$sd)) par$sd = 0.0001*par$sd par = unlist(par) return(par) } .getLower = cmpfun(.getLower) fitModel = function(obs, env, T, L) { r = log(obs[-1,]/obs[-T,]) guess = data.frame(rate=as.numeric(r), env=as.numeric(env[-T,])) mod1 = lm(rate ~ env, data=guess) output = list() output$par = NULL

# Phase 1: alpha an beta only
cat("Phase 1: alpha and beta only\n")

par = list()
par$alpha = as.numeric(coef(mod1)[1]) par$beta  = as.numeric(coef(mod1)[2])

opt = optim(par=unlist(par), fn=.getLogLike, gr=NULL,
obs=obs, env=env, T=T, L=L, method="L-BFGS-B",
upper=.getUpper(par), lower=.getLower(par))
opt$bound = data.frame(par=unlist(par), low=.getLower(par), upp=.getUpper(par)) output$phase1 = opt

cat("Optimal parameters: \n")
print(opt$par) cat("\nneg-LogLikelihood: ", opt$value, "\n")

# phase 2: alpha, beta and gamma
cat("Phase 2: alpha, beta and gamma\n")

optpar = reListPars(opt$par) par$alpha = optpar$alpha par$beta  = optpar$beta par$gamma = rep(0, T-1)

opt = optim(par=unlist(par), fn=.getLogLike, gr=NULL,
obs=obs, env=env, T=T, L=L, method="L-BFGS-B",
upper=.getUpper(par), lower=.getLower(par))
opt$bound = data.frame(par=unlist(par), low=.getLower(par), upp=.getUpper(par)) output$phase2 = opt

cat("Optimal parameters: \n")
print(opt$par) cat("\nneg-LogLikelihood: ", opt$value, "\n")

# phase 3: alpha, beta, gamma and mu_ini
cat("Phase 3: alpha, beta, gamma and mu_ini\n")

optpar = reListPars(opt$par) par$alpha = optpar$alpha par$beta  = optpar$beta par$gamma = optpar$gamma par$mu_ini = log(obs[1,])

opt = optim(par=unlist(par), fn=.getLogLike, gr=NULL,
obs=obs, env=env, T=T, L=L, method="L-BFGS-B",
upper=.getUpper(par), lower=.getLower(par),
control=list(maxit=1000))
opt$bound = data.frame(par=unlist(par), low=.getLower(par), upp=.getUpper(par)) output$phase3 = opt

cat("Optimal parameters: \n")
print(opt$par) cat("\nneg-LogLikelihood: ", opt$value, "\n")

output$par = reListPars(opt$par)

output$fitted = dynamics(par=output$par, obs=obs, x=env, T=T, L=L)
output$observed = obs output$env = env

return(output)

}

fitModel = cmpfun(fitModel)

fitModel0 = function(obs, env, T, L) {

output = list()
output$par = NULL par = list() par$alpha = 0
par$beta = 0 par$gamma = rep(0, T-1)
par$mu_ini = log(obs[1,]) opt = optim(par=unlist(par), fn=.getLogLike, gr=NULL, obs=obs, env=env, T=T, L=L, method="L-BFGS-B", upper=.getUpper(par), lower=.getLower(par)) opt$bound = data.frame(par=unlist(par), low=.getLower(par),
upp=.getUpper(par))

output$phase1 = opt cat("Optimal parameters: \n") print(opt$par)
cat("\nneg-LogLikelihood: ", opt$value, "\n") output$par = reListPars(opt$par) output$fitted = dynamics(par=output$par, obs=obs, x=env, T=T, L=L) output$observed = obs
output$env = env return(output) } fitModel0 = cmpfun(fitModel0)  - How is the object n defined? – Thierry Mar 24 '14 at 7:49 Uff, did you just write your own optimizer based on optim? Is this a "clean" frequentist approach to modelling, or at least as clean glm? I mean, this approach is completely new to me, is it documented somewhere, with all the things like model validation, precision etc.? I am a bit conservative to completely new methods, how they have been tested etc. I also need to cite the method somehow in an article. Anyway, I will try your script and compare to my bayesian analysis and come back to you. – TMS Mar 24 '14 at 9:34 @Thierry: I missed one line: # observed abundances n = matrix(rpois(length(mu), lambda=mu), nrow=T, ncol=L) added to the code. – Ricardo Oliveros-Ramos Mar 24 '14 at 11:35 Somebody downvote, so maybe there's a mistake or something wrong, but not sure which part is "new". The idea is: the model have some parameters. We used the parameters to simulate the model. Then compared the observations to the model outputs given the assumed distribution of the observations (Poisson) and calculated the likelihood as function of the parameters. Then, we minimize the negative log-likelihood function to get the "optimal" parameters. I think you can do the same for GLM or AR models, even if other alternatives available for parameter estimation (e.g. bayesian). – Ricardo Oliveros-Ramos Mar 24 '14 at 11:57 About doing it in several steps is to improve the estimate of annual deviates which are one of the focus in the study, right? When using local optimization methods, you can get stuck in a local minimum, so it's useful to start at better initial estimates for your parameters. I do this all the time, so I'm very interested in getting feedback. – Ricardo Oliveros-Ramos Mar 24 '14 at 12:00 The model formula is not the same as what you have given, but from the title of your question it seems like the hhh4 function in the surveillance package on CRAN might be of interest. It allows you to fit Poisson autoregressive models with random effects. There are some examples in the bottom of the documentation for that function. I believe that currently the fixed effects must be limited to an intercept, a long-term time trend, and a seasonal component for each site, but perhaps that will work for you. - This doesn't look bad. Can you please update your answer so that it is appparent that the model requested can actually be fitted with this function, and how? – TMS Mar 27 '14 at 11:33 You have chance to win the bounty if you answer fast. – TMS Mar 28 '14 at 12:13 I read cran.r-project.org/web/packages/surveillance/vignettes/hhh4.pdf and I don't think my model can be fit with hhh4. There is no trend component in my model. – TMS Mar 29 '14 at 11:47 I realize I missed the chance for bounty but I'll see if I can answer your question anyway. If your x_{i,j} is a scalar you could treat it as time and then \beta could be estimated as a time trend. But I think the appearance of log(\mu_{i,j}) on the right-hand side and a random effect for each year does make your model outside the scope of hhh4. To use that function, you could possibly use a negative binomial response in place of the Poisson with random effect and then put N_{i,j} in place of log(\mu_{i,j}) on the right-hand side. Of course, you could also then use MASS::glm.nb to fit it. – e3bo Mar 29 '14 at 14:47 Have a look at the INLA package http://www.r-inla.org It is Bayesian, but uses Integrated nested Laplace approximation which makes the speed of a model compareable to that of frequentist models (glm, glmm). Starting from mu and env from Ricardo Oliveros-Ramos with L = 40. First prepare the dataset dataset <- data.frame( count = rpois(length(mu), lambda = mu), year = rep(seq_len(T), L), site = rep(seq_len(L), each = T), env = as.vector(env) ) library(reshape2) n <- as.matrix(dcast(year ~ site, data = dataset, value.var = "count")[, -1]) dataset$year2 <- dataset\$year


Run the model

library(INLA)
system.time(
model <- inla(
count ~
env +
f(year, model = "ar1", replicate = site) +
f(year2, model = "iid"),
data = dataset,
family = "poisson"
)
)
user  system elapsed
0.18    0.14    3.77


Compare the speed with the solution from Ricardo

system.time(test <- fitModel(obs=n, env=env, T=T, L=L))
user  system elapsed
11.06    0.00   11.06


Compare the speed with a frequentist glmm (without autocorrelation)

library(lme4)
system.time(
m <- glmer(
count ~ env + (1|site) + (1|year),
data = dataset,
family = poisson
)
)
user  system elapsed
0.44    0.00    0.44


The speed of inla without autocorrelation

system.time(
model <- inla(
count ~
env +
f(site, model = "iid") +
f(year, model = "iid"),
data = dataset,
family = "poisson"
)
)
user  system elapsed
0.19    0.11    2.09

-
I didn't know about this package, looks useful. I'm updating my answer with L=40. Would you mind to add the estimated parameters for comparative purposes? Also, you missed the 'env' variable in your data. – Ricardo Oliveros-Ramos Mar 24 '14 at 12:42
I have updated the code. The INLA model will have different parameters because the parametrisation is different. mu_ij = site_ij + \alpha + \beta * env + \gamma_j with site_ij = \rho * site_i(j-1) + \epsilon_ij – Thierry Mar 24 '14 at 13:15
But, in that case, that's not the model. log(mu_ij/mu_i(j-1)) is the growth rate of the population, and that's what we want to model at the end, being constant (alpha, species specific), varying as function of the environment (at each site) and with an random annual fluctuation (for every year). – Ricardo Oliveros-Ramos Mar 24 '14 at 13:31
Thierry, it seems you completely missed the autoregression part - the log(mu_i,j) on the right side of the equation? – TMS Mar 27 '14 at 11:23