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We recommend installing the stable, peer-reviewed version of TruncExpFam, available on CRAN:
After successful installation, the package can be loaded with
TruncExpFam comes equipped with functions to generate random samples
from no less than 12 different probability distributions from the
truncated exponential family. You can read more about them by running
?rtrunc
on your R console.
As an example, we will sample 100 values from a chi-square distribution with 14 degrees of freedom:
By default, however, rtrunc()
doesn’t generate a
truncated distribution. As a matter of fact, the code above will
generate the exact same sample as if were drawn from
stats::rchisq()
, watch:
set.seed(3067)
x2 <- rtrunc(20, "chisq", df = 14)
set.seed(3067)
x3 <- rchisq(20, 14)
identical(x2, x3)
#> [1] FALSE
Oh, wait… Those objects are supposed to be identical! What happened? Let’s investigate:
x2
#> [1] 16.531982 10.021074 12.480308 16.165519 11.083118 32.684427 16.661472
#> [8] 18.085124 10.921481 11.150269 10.673091 12.012880 7.986689 7.500130
#> [15] 10.951995 6.725427 10.789780 5.616512 20.081876 8.138363
x3
#> [1] 16.531982 10.021074 12.480308 16.165519 11.083118 32.684427 16.661472
#> [8] 18.085124 10.921481 11.150269 10.673091 12.012880 7.986689 7.500130
#> [15] 10.951995 6.725427 10.789780 5.616512 20.081876 8.138363
str(x2)
#> 'trunc_chisq' num [1:20] 16.5 10 12.5 16.2 11.1 ...
#> - attr(*, "parameters")=List of 1
#> ..$ df: num 14
#> - attr(*, "truncation_limits")=List of 2
#> ..$ a: num 0
#> ..$ b: num Inf
#> - attr(*, "continuous")= logi TRUE
str(x3)
#> num [1:20] 16.5 10 12.5 16.2 11.1 ...
class(x2)
#> [1] "trunc_chisq"
class(x3)
#> [1] "numeric"
OK, so you can tell that the generated numbers are the same, but
x2
and x3
are not literally the same objects
because the former has a different class. These trunc_*
classes are actually very special, because they contain some extra
information about the distribution that a simple vector does not. One
can access such information using
print(x2, details = TRUE)
:
print(x2, details = TRUE)
#> [1] 16.531982 10.021074 12.480308 16.165519 11.083118 32.684427 16.661472
#> [8] 18.085124 10.921481 11.150269 10.673091 12.012880 7.986689 7.500130
#> [15] 10.951995 6.725427 10.789780 5.616512 20.081876 8.138363
#> attr(,"class")
#> [1] "trunc_chisq"
#> attr(,"parameters")
#> attr(,"parameters")$df
#> [1] 14
#>
#> attr(,"truncation_limits")
#> attr(,"truncation_limits")$a
#> [1] 0
#>
#> attr(,"truncation_limits")$b
#> [1] Inf
#>
#> attr(,"continuous")
#> [1] TRUE
Just to be sure that the sample itself matches:
Speaking of alternative ways to generate the same sample, for the
sake of convenience and of users familiar with the sampling functions
from the stats package, the wrapper function rtruncchisq()
is also available. The results, as you can see below, are identical:
So far, all samples generated are actually not truncated. This is
because, by default, the truncation limits a
and
b
are set to the limits of the distribution support, which
are 0 and Inf for the chi-squared distribution.
Let us use a simpler distribution for this second example by sampling from Poisson(10):
y1 <- rtruncpois(1e4, 10)
summary(y1)
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> 0.00 8.00 10.00 10.01 12.00 26.00
var(y1)
#> [1] 10.04213
As expected, the values are all larger than 0 and the mean and variance are 10. If we wanted to generate instead from a Poisson(10) truncated at, say, 8 and 20, we would run:
y2 <- rtruncpois(1e4, 10, a = 9, b = 20)
summary(y2)
#> Min. 1st Qu. Median Mean 3rd Qu. Max.
#> 9.00 10.00 11.00 11.63 13.00 20.00
var(y2)
#> [1] 5.159541
Notice how, even with a large sample, the observed mean and variance are still quite far from 10.
One reliable method of estimating the original lambda used to
generate y2
is by running the
mlEstimationTruncDist()
function:
lambda <- mlEstimationTruncDist(y2, print.iter = TRUE)
#> Estimating parameters for the poisson distribution
#> it delta.L2 parameter(s)
#> 1 0.0007325 11.626
#> 2 0.0005043 11.315
#> 3 0.0003465 11.064
#> 4 0.0002378 10.86
#> 5 0.0001631 10.694
#> 6 0.0001119 10.558
#> 7 7.674e-05 10.447
#> 8 5.264e-05 10.356
#> 9 3.611e-05 10.281
#> 10 2.478e-05 10.219
#> 11 1.7e-05 10.169
#> 12 1.167e-05 10.127
#> 13 8.007e-06 10.092
lambda
#> lambda
#> 10.06366
More information about that function and how you can tweak it is
available on ?mlEstimationTruncDist
.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.