Objects of maxlogL class (outputs frommaxlogL and maxlogLreg) stores the estimated parameters of probability density/mass functions by Maximum Likelihood. The variance-covariance matrix is computed from Fisher information matrix, which is obtained by means of the Inverse Hessian matrix of estimators:
\[\begin{equation} Var(\hat{\boldsymbol{\theta}}) = I^{-1}(\hat{\boldsymbol{\theta}}) = C(\hat{\boldsymbol{\theta}}), \end{equation}\]
where \(I(\hat{\boldsymbol{\theta}})\) is the Fisher Information Matrix. Hence, the standard errors can be calculated as the square root of the diagonal elements of matrix \(C\), as follows:
\[\begin{equation} SE(\hat{\boldsymbol{\theta}}) = \sqrt{C_{jj}(\hat{\boldsymbol{\theta}})}, \end{equation}\]
To install the package, type the following commands:
if (!require('devtools')) install.packages('devtools')
devtools::install_github('Jaimemosg/EstimationTools', force = TRUE)In EstimationTools Hessian matrix is computed in the following way:
optim, with option hessian = TRUE in maxlogL function.hessian function from numDeriv package.bootstrap_maxlogL.Additionally, EstimationTools allows implementation of bootstrap for standard error estimation, even if the Hessian computation does not fail.
maxlogL functionLets fit the following distribution:
\[ \begin{aligned} X &\sim N(\mu, \:\sigma^2) \\ \mu &= 160 \quad (\verb|mean|) \\ \sigma &= 6 \quad (\verb|sd|) \end{aligned} \]
The following chunk illustrates the fitting with Hessian computation via optim:
library(EstimationTools)
x <- rnorm(n = 10000, mean = 160, sd = 6)
theta_1 <- maxlogL(x = x, dist = 'dnorm', control = list(trace = 1),
link = list(over = "sd", fun = "log_link"),
fixed = list(mean = 160))
#> 0: 44092.265: 1.00000
#> 1: 32559.624: 2.00000
#> 2: 32353.608: 1.92434
#> 3: 32224.471: 1.77589
#> 4: 32217.226: 1.80614
#> 5: 32217.113: 1.80286
#> 6: 32217.113: 1.80277
#> 7: 32217.113: 1.80277
summary(theta_1)
#> _______________________________________________________________
#> Optimization routine: nlminb
#> Standard Error calculation: Hessian from optim
#> _______________________________________________________________
#> AIC BIC
#> 64434.23 64434.23
#> _______________________________________________________________
#> Estimate Std. Error Z value Pr(>|z|)
#> sd 6.0664 0.0429 141.4 <2e-16 ***
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> _______________________________________________________________
#> Note: p-values valid under asymptotic normality of estimators
#> ---
## Hessian
print(theta_1$fit$hessian)
#> [,1]
#> [1,] 543.4525
## Standard errors
print(theta_1$fit$StdE)
#> [1] 0.04289624
print(theta_1$outputs$StdE_Method)
#> [1] "Hessian from optim"Note that Hessian was computed with no issues. Now, lets check the aforementioned feature in maxlogL: the user can implement bootstrap algorithm available in bootstrap_maxlogL function. To illustrate this, we are going to create another object theta_2:
# Bootstrap
theta_2 <- maxlogL(x = x, dist = 'dnorm', control = list(trace = 1),
link = list(over = "sd", fun = "log_link"),
fixed = list(mean = 160))
#> 0: 44092.265: 1.00000
#> 1: 32559.624: 2.00000
#> 2: 32353.608: 1.92434
#> 3: 32224.471: 1.77589
#> 4: 32217.226: 1.80614
#> 5: 32217.113: 1.80286
#> 6: 32217.113: 1.80277
#> 7: 32217.113: 1.80277
bootstrap_maxlogL(theta_2, R = 200)
#>
#> ...Bootstrap computation of Standard Error. Please, wait a few minutes...
#>
#>
#> --> Done <---
summary(theta_2)
#> _______________________________________________________________
#> Optimization routine: nlminb
#> Standard Error calculation: Bootstrap
#> _______________________________________________________________
#> AIC BIC
#> 64434.23 64434.23
#> _______________________________________________________________
#> Estimate Std. Error Z value Pr(>|z|)
#> sd 6.06645 0.04099 148 <2e-16 ***
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> _______________________________________________________________
#> Note: p-values valid under asymptotic normality of estimators
#> ---
## Hessian
print(theta_2$fit$hessian)
#> [,1]
#> [1,] 543.4525
## Standard errors
print(theta_2$fit$StdE)
#> [1] 0.04098827
print(theta_2$outputs$StdE_Method)
#> [1] "Bootstrap"Notice that Standard Errors calculated with optim (\(0.042896\)) and those calculated with bootstrap implementation (\(0.040988\)) are approximately equals, but no identical.