README.md
In vandomed/dvmisc: Convenience Functions, Moving Window Statistics, and Graphics
Convenience Functions, Moving Window Statistics, and Graphics
Dane Van Domelen vandomed@gmail.com
2020-04-11
Introduction
This package contains miscellaneous functions that I think are useful
for various purposes, e.g. for:
-
Running and summarizing statistical simulation studies (sumsim,
iterate)
-
Visualizing data (histo, cart_app)
-
Calculating moving/sliding statistics (sliding_cov, sliding_cor,
moving_mean)
-
Doing something convenient (bmi3, cleancut ral)
In this README, I’ll showcase a few functions.
sumsim
This function creates tables summarizing results of statistical
simulations, providing common metrics of performance like mean bias,
standard deviation, mean standard error, mean squared error, and
confidence interval coverage.
To illustrate, suppose (X_1, ..., X_n \sim N(\mu, \sigma^2)), and we
wish to compare two estimators for (\sigma^2): the MLE ((n) in
denominator) vs. the sample variance ((n-1) in denominator).
MLE <- c()
s2 <- c()
for (ii in 1: 1000) {
x <- rnorm(n = 25)
MLE[ii] <- sum((x - mean(x))^2) / 25
s2[ii] <- sum((x - mean(x))^2) / 24
}
kable(sumsim(estimates = cbind(MLE, s2), truth = 1))
Mean bias
SD
MSE
MLE
\-0.036
0.275
0.077
s2
0.004
0.286
0.082
You can request different performance metrics through the statistics
input; some of them, like confidence interval coverage, require
specifying ses with standard errors.
histo
This function is similar to the base R function hist, but with two
added features:
-
Can overlay one or more fitted probability density/mass functions
(PDFs/PMFs) for any univariate distribution supported in R (see
?Distributions).
-
Can generate more of a barplot type histogram, where each possible
value gets its own bin centered over its value (useful for discrete
variables with not too many possible values).
Here are two examples:
# Histogram for 1,000 values from Bin(8, 0.25)
x <- rbinom(n = 1000, size = 5, prob = 0.25)
histo(x, dis = "binom", size = 5, colors = "blue", points_list = list(type = "b"))
# Histogram for 10,000 values from lognormal(0, 0.35) and various fitted PDFs.
x <- rlnorm(n = 10000, meanlog = 0, sdlog = 0.35)
histo(x, c("lnorm", "norm", "gamma"), main = "X ~ Lognormal(0, 0.35)")
moving_mean
The function moving_mean is one of dozens of moving average functions
available in R. I’m not sure it’s the absolute fastest, but it is much
faster than roll_mean in RcppRoll.
library("RcppRoll")
lengths <- c(10, 100, 1000, 10000)
multiples1 <- multiples2 <- c()
for (ii in 1: 4) {
n <- lengths[ii]
x <- rnorm(n)
medians <- summary(microbenchmark(roll_mean(x, 5), moving_mean(x, 5),
roll_mean(x, n / 5), moving_mean(x, n / 5),
times = 50))$median
multiples1[ii] <- medians[1] / medians[2]
multiples2[ii] <- medians[3] / medians[4]
}
par(mfrow = c(1, 2))
plot(1: 4, multiples1, type = "b", col = "blue", main = "5-unit MA",
ylab = "Speed multiple", xlab = "Vector length", xaxt = "n",
ylim = c(0, max(multiples1) * 1.05))
axis(side = 1, at = 1: 4, labels = lengths)
abline(h = 1)
plot(1: 4, multiples2, type = "b", col = "blue", main = "length(x)/5-unit MA",
ylab = "Speed multiple", xlab = "Vector length", xaxt = "n",
ylim = c(0, max(multiples2) * 1.05))
axis(side = 1, at = 1: 4, labels = lengths)
abline(h = 1)
cleancut
Whenever I try to use cut to categorize a continuous variable, I find
myself taking a suboptimal approach: (1) Call cut without specifying
labels, and with arguments I think will create the groups I want
(\Rightarrow) (2) Run table to see if it worked (\Rightarrow) (3)
Return to (1) if necessary (Rightarrow) (4) Call cut once again with
labels specified.
The idea of cleancut is to provide a simple character string-based
alternative. To illustrate, here’s how you break a continuous variable
into “low” (\< -1), “medium” (-1 to 1, inclusive), and “high” (> 1).
I’ll do it two ways, once without and once with labels:
x <- rnorm(100)
y.nolabels <- cleancut(x, "(-Inf, -1), [-1, 1], [1, Inf)")
y.labels <- cleancut(x, "(-Inf, -1), [-1, 1], [1, Inf)", labels = c("low", "medium", "high"))
table(y.nolabels, y.labels)
low
medium
high
(-Inf, -1)
20
0
0
\[-1, 1\]
0
64
0
\[1, Inf)
0
0
16
References
Eddelbuettel, Dirk. 2013. *Seamless R and C++ Integration with Rcpp*.
New York: Springer. .
Eddelbuettel, Dirk, and James Joseph Balamuta. 2017. “Extending extitR
with extitC++: A Brief Introduction to extitRcpp.” *PeerJ Preprints* 5
(August): e3188v1. .
Eddelbuettel, Dirk, and Romain François. 2011. “Rcpp: Seamless R and C++
Integration.” *Journal of Statistical Software* 40 (8): 1–18.
.
Ushey, Kevin. 2015. *RcppRoll: Efficient Rolling / Windowed Operations*.
.
Xie, Yihui. 2017. *Printr: Automatically Print R Objects to Appropriate
Formats According to the ’Knitr’ Output Format*.
.
vandomed/dvmisc documentation built on Oct. 2, 2020, 9:50 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Convenience Functions, Moving Window Statistics, and Graphics
Dane Van Domelen vandomed@gmail.com 2020-04-11
Introduction
This package contains miscellaneous functions that I think are useful for various purposes, e.g. for:
-
Running and summarizing statistical simulation studies (
sumsim,iterate) -
Visualizing data (
histo,cart_app) -
Calculating moving/sliding statistics (
sliding_cov,sliding_cor,moving_mean) -
Doing something convenient (
bmi3,cleancutral)
In this README, I’ll showcase a few functions.
sumsim
This function creates tables summarizing results of statistical simulations, providing common metrics of performance like mean bias, standard deviation, mean standard error, mean squared error, and confidence interval coverage.
To illustrate, suppose (X_1, ..., X_n \sim N(\mu, \sigma^2)), and we wish to compare two estimators for (\sigma^2): the MLE ((n) in denominator) vs. the sample variance ((n-1) in denominator).
MLE <- c()
s2 <- c()
for (ii in 1: 1000) {
x <- rnorm(n = 25)
MLE[ii] <- sum((x - mean(x))^2) / 25
s2[ii] <- sum((x - mean(x))^2) / 24
}
kable(sumsim(estimates = cbind(MLE, s2), truth = 1))
You can request different performance metrics through the statistics
input; some of them, like confidence interval coverage, require
specifying ses with standard errors.
histo
This function is similar to the base R function hist, but with two
added features:
-
Can overlay one or more fitted probability density/mass functions (PDFs/PMFs) for any univariate distribution supported in R (see
?Distributions). -
Can generate more of a barplot type histogram, where each possible value gets its own bin centered over its value (useful for discrete variables with not too many possible values).
Here are two examples:
# Histogram for 1,000 values from Bin(8, 0.25)
x <- rbinom(n = 1000, size = 5, prob = 0.25)
histo(x, dis = "binom", size = 5, colors = "blue", points_list = list(type = "b"))
# Histogram for 10,000 values from lognormal(0, 0.35) and various fitted PDFs.
x <- rlnorm(n = 10000, meanlog = 0, sdlog = 0.35)
histo(x, c("lnorm", "norm", "gamma"), main = "X ~ Lognormal(0, 0.35)")
moving_mean
The function moving_mean is one of dozens of moving average functions available in R. I’m not sure it’s the absolute fastest, but it is much faster than roll_mean in RcppRoll.
library("RcppRoll")
lengths <- c(10, 100, 1000, 10000)
multiples1 <- multiples2 <- c()
for (ii in 1: 4) {
n <- lengths[ii]
x <- rnorm(n)
medians <- summary(microbenchmark(roll_mean(x, 5), moving_mean(x, 5),
roll_mean(x, n / 5), moving_mean(x, n / 5),
times = 50))$median
multiples1[ii] <- medians[1] / medians[2]
multiples2[ii] <- medians[3] / medians[4]
}
par(mfrow = c(1, 2))
plot(1: 4, multiples1, type = "b", col = "blue", main = "5-unit MA",
ylab = "Speed multiple", xlab = "Vector length", xaxt = "n",
ylim = c(0, max(multiples1) * 1.05))
axis(side = 1, at = 1: 4, labels = lengths)
abline(h = 1)
plot(1: 4, multiples2, type = "b", col = "blue", main = "length(x)/5-unit MA",
ylab = "Speed multiple", xlab = "Vector length", xaxt = "n",
ylim = c(0, max(multiples2) * 1.05))
axis(side = 1, at = 1: 4, labels = lengths)
abline(h = 1)
cleancut
Whenever I try to use cut to categorize a continuous variable, I find
myself taking a suboptimal approach: (1) Call cut without specifying
labels, and with arguments I think will create the groups I want
(\Rightarrow) (2) Run table to see if it worked (\Rightarrow) (3)
Return to (1) if necessary (Rightarrow) (4) Call cut once again with
labels specified.
The idea of cleancut is to provide a simple character string-based
alternative. To illustrate, here’s how you break a continuous variable
into “low” (\< -1), “medium” (-1 to 1, inclusive), and “high” (> 1).
I’ll do it two ways, once without and once with labels:
x <- rnorm(100)
y.nolabels <- cleancut(x, "(-Inf, -1), [-1, 1], [1, Inf)")
y.labels <- cleancut(x, "(-Inf, -1), [-1, 1], [1, Inf)", labels = c("low", "medium", "high"))
table(y.nolabels, y.labels)
References
Eddelbuettel, Dirk. 2013. *Seamless R and C++ Integration with Rcpp*.
New York: Springer. .
Eddelbuettel, Dirk, and James Joseph Balamuta. 2017. “Extending extitR
with extitC++: A Brief Introduction to extitRcpp.” *PeerJ Preprints* 5
(August): e3188v1. .
Eddelbuettel, Dirk, and Romain François. 2011. “Rcpp: Seamless R and C++
Integration.” *Journal of Statistical Software* 40 (8): 1–18.
.
Ushey, Kevin. 2015. *RcppRoll: Efficient Rolling / Windowed Operations*.
.
Xie, Yihui. 2017. *Printr: Automatically Print R Objects to Appropriate
Formats According to the ’Knitr’ Output Format*.
.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.