variable: create greta variables
In goldingn/greta: Simple and Scalable Statistical Modelling in R
Description
Usage
Arguments
Details
Examples
Description
variable() creates greta arrays representing unknown
parameters, to be learned during model fitting. These parameters are not
associated with a probability distribution. To create a variable greta
array following a specific probability distribution, see
distributions().
Usage
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variable(lower = -Inf, upper = Inf, dim = NULL)
cholesky_variable(dim, correlation = FALSE)
simplex_variable(dim)
ordered_variable(dim)
Arguments
lower, upper
optional limits to variables. These must be specified as
numerics, they cannot be greta arrays (though see details for a
workaround). They can be set to -Inf (lower) or Inf
(upper), though lower must always be less than upper.
dim
the dimensions of the greta array to be returned, either a scalar
or a vector of positive integers. See details.
correlation
whether to return a cholesky factor corresponding to a
correlation matrix (diagonal elements equalling 1, off-diagonal elements
between -1 and 1).
Details
lower and upper must be fixed, they cannot be greta
arrays. This ensures these values can always be transformed to a continuous
scale to run the samplers efficiently. However, a variable parameter with
dynamic limits can always be created by first defining a variable
constrained between 0 and 1, and then transforming it to the required
scale. See below for an example.
The constraints in simplex_variable() and ordered_variable()
operate on the final dimension, which must have more than 1 element.
Passing in a scalar value for dim therefore results in a row-vector.
Examples
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## Not run:
# a scalar variable
a <- variable()
# a positive length-three variable
b <- variable(lower = 0, dim = 3)
# a 2x2x2 variable bounded between 0 and 1
c <- variable(lower = 0, upper = 1, dim = c(2, 2, 2))
# create a variable, with lower and upper defined by greta arrays
min <- as_data(iris$Sepal.Length)
max <- min^2
d <- min + variable(0, 1, dim = nrow(iris)) * (max - min)
## End(Not run)
# 4x4 cholesky factor variables for covariance and correlation matrices
e_cov <- cholesky_variable(dim = 4)
e_correl <- cholesky_variable(dim = 4, correlation = TRUE)
# these can be converted to symmetic matrices with chol2symm
# (equivalent to t(e_cov) %*% e_cov, but more efficient)
cov <- chol2symm(e_cov)
correl <- chol2symm(e_correl)
# a 4D simplex (sums to 1, all values positive)
f <- simplex_variable(4)
# a 4D simplex on the final dimension
g <- simplex_variable(dim = c(2, 3, 4))
# a 2D variable with each element higher than the one in the cell to the left
h <- ordered_variable(dim = c(3, 4))
# more constraints can be added with monotonic transformations, e.g. an
# ordered positive variable
i <- exp(ordered_variable(5))
goldingn/greta documentation built on May 24, 2021, 11 a.m.
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Description Usage Arguments Details Examples
Description
variable() creates greta arrays representing unknown
parameters, to be learned during model fitting. These parameters are not
associated with a probability distribution. To create a variable greta
array following a specific probability distribution, see
distributions().
Usage
1 2 3 4 5 6 7 | variable(lower = -Inf, upper = Inf, dim = NULL)
cholesky_variable(dim, correlation = FALSE)
simplex_variable(dim)
ordered_variable(dim)
|
Arguments
lower, upper |
optional limits to variables. These must be specified as
numerics, they cannot be greta arrays (though see details for a
workaround). They can be set to |
dim |
the dimensions of the greta array to be returned, either a scalar or a vector of positive integers. See details. |
correlation |
whether to return a cholesky factor corresponding to a correlation matrix (diagonal elements equalling 1, off-diagonal elements between -1 and 1). |
Details
lower and upper must be fixed, they cannot be greta
arrays. This ensures these values can always be transformed to a continuous
scale to run the samplers efficiently. However, a variable parameter with
dynamic limits can always be created by first defining a variable
constrained between 0 and 1, and then transforming it to the required
scale. See below for an example.
The constraints in simplex_variable() and ordered_variable()
operate on the final dimension, which must have more than 1 element.
Passing in a scalar value for dim therefore results in a row-vector.
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 | ## Not run:
# a scalar variable
a <- variable()
# a positive length-three variable
b <- variable(lower = 0, dim = 3)
# a 2x2x2 variable bounded between 0 and 1
c <- variable(lower = 0, upper = 1, dim = c(2, 2, 2))
# create a variable, with lower and upper defined by greta arrays
min <- as_data(iris$Sepal.Length)
max <- min^2
d <- min + variable(0, 1, dim = nrow(iris)) * (max - min)
## End(Not run)
# 4x4 cholesky factor variables for covariance and correlation matrices
e_cov <- cholesky_variable(dim = 4)
e_correl <- cholesky_variable(dim = 4, correlation = TRUE)
# these can be converted to symmetic matrices with chol2symm
# (equivalent to t(e_cov) %*% e_cov, but more efficient)
cov <- chol2symm(e_cov)
correl <- chol2symm(e_correl)
# a 4D simplex (sums to 1, all values positive)
f <- simplex_variable(4)
# a 4D simplex on the final dimension
g <- simplex_variable(dim = c(2, 3, 4))
# a 2D variable with each element higher than the one in the cell to the left
h <- ordered_variable(dim = c(3, 4))
# more constraints can be added with monotonic transformations, e.g. an
# ordered positive variable
i <- exp(ordered_variable(5))
|
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