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knitr::opts_chunk$set(comment='.')
Mutate a data.frame
, adding random variates.
library(dplyr)
library(dmutate)
Some variables to use in formulae:
low_wt <- 70
high_wt <- 90
mu_wt <- 80
sd <- 60
p.female <- 0.24
Use mutate_random
to implement formulae in data frame.
We can put bounds on any simulated variable
data.frame(ID=1:10) %>%
mutate_random(WT[low_wt,high_wt] ~ rnorm(mu_wt,sd))
. ID WT
. 1 1 80.06845
. 2 2 89.33775
. 3 3 80.10562
. 4 4 84.24226
. 5 5 77.91191
. 6 6 78.10506
. 7 7 87.47608
. 8 8 85.73655
. 9 9 76.68176
. 10 10 73.60327
We can simulate from any probability distirbution in
R
data.frame(ID=1:10) %>% mutate_random(X ~ rcauchy(0,0.5))
. ID X
. 1 1 1.90139689
. 2 2 -0.10051859
. 3 3 0.70502454
. 4 4 0.29159943
. 5 5 -1.28752659
. 6 6 -0.17683919
. 7 7 0.10487994
. 8 8 -0.03835449
. 9 9 -0.74823471
. 10 10 -0.05401384
We can add the variate at any level
data.frame(ID=1:10) %>%
mutate(GROUP = ID%%2) %>%
mutate_random(STUDY_RE ~ rnorm(50,sqrt(50))|GROUP)
. ID GROUP STUDY_RE
. 1 1 1 35.51964
. 2 2 0 57.52245
. 3 3 1 35.51964
. 4 4 0 57.52245
. 5 5 1 35.51964
. 6 6 0 57.52245
. 7 7 1 35.51964
. 8 8 0 57.52245
. 9 9 1 35.51964
. 10 10 0 57.52245
mu <- c(2,200)
Sigma <- diag(c(10,1000))
XY <- X[0,] + Y[200,300] ~ rmvnorm(mu,Sigma)
The object
XY
. X[0, ] + Y[200, 300] ~ rmvnorm(mu, Sigma)
. <environment: 0x107283a30>
Simulate
data.frame(ID=1:10000) %>%
mutate_random(XY) %>%
summary
. ID X Y
. Min. : 1 Min. : 0.000705 Min. :200.0
. 1st Qu.: 2501 1st Qu.: 1.630148 1st Qu.:209.9
. Median : 5000 Median : 3.093676 Median :221.0
. Mean : 5000 Mean : 3.418346 Mean :224.9
. 3rd Qu.: 7500 3rd Qu.: 4.843010 3rd Qu.:235.9
. Max. :10000 Max. :13.981875 Max. :299.3
data.frame(ID=1:10) %>%
mutate(GROUP = ID%%2) %>%
mutate_random(WT[low_wt,high_wt] ~ rnorm(mu_wt,1)) %>%
mutate_random(STUDY_RE ~ rnorm(0,sqrt(50))|GROUP) %>%
mutate_random(SEX ~ rbinomial(p.female)) %>%
mutate_random(sigma ~ rgamma(1,1)) %>%
mutate_random(kappa ~ rgamma(1,1)|GROUP) %>% signif(3)
. ID GROUP WT STUDY_RE SEX sigma kappa
. 1 1 1 78.1 -0.609 0 1.7200 0.045
. 2 2 0 79.6 3.740 0 2.1300 0.193
. 3 3 1 78.7 -0.609 1 0.9670 0.045
. 4 4 0 82.0 3.740 0 0.1240 0.193
. 5 5 1 80.9 -0.609 0 0.0672 0.045
. 6 6 0 79.2 3.740 0 0.5910 0.193
. 7 7 1 81.0 -0.609 1 0.0549 0.045
. 8 8 0 79.8 3.740 0 0.9100 0.193
. 9 9 1 80.0 -0.609 1 0.0262 0.045
. 10 10 0 79.8 3.740 0 1.9900 0.193
expr
to calculate new columns in the
data.frame
using dplyr::mutate
We can easily save formulae to R
variables. We collect
formulae together into sets called covset
. For better
control for where objects are found, we can specify an environment where
objects can be found.
a <- X ~ rnorm(50,3)
b <- Y ~ expr(X/2 + c)
d <- A+B ~ rlmvnorm(log(c(20,80)),diag(c(0.2,0.2)))
cov1 <- covset(a,b,d)
e <- list(c=3)
Notice that b
has function expr
. This
assigns the column named Y
(in this case) to the result of
evaluating the expression in the data frame using
dplyr::dmutate
.
.data <- data.frame(ID=1:3)
mutate_random(.data,cov1,envir=e) %>% signif(3)
. ID X Y A B
. 1 1 52.1 29.0 15.6 64.4
. 2 2 41.2 23.6 21.8 100.0
. 3 3 47.6 26.8 11.4 31.9
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.