Incorporates uncertainty in its qqplot display(s) so that the user might have a better sense of the evidence against the specified distributional hypothesis.
Quantile–quantile plots, or qqplots, are an important visual tool for many applications but their interpretation requires some care and often more experience. This apparent subjectivity is unnecessary. By drawing on the computational and display facilities now widely available, qqplots are easily enriched to help with their interpretation.
A new enhanced qqplot, the self-calibrating qqplot, is introduced and
demonstrated on a variety of examples (all examples from the original
paper appear on the help/reference page for qqtest
).
Possibilities are endless. Some standard examples include normal qqplots, log-normal plots, half-normal plots (e.g. for factorial experiments), and the comparison of empirical distributions. Self-calibration is had by visually incorporating sampling variation in the qqplot display in a variety of ways.
qqtest
draws a quantile quantile plot for visually
assessing whether the data come from a test distribution that has been
defined in one of many ways. The vertical axis plots the data quantiles,
the horizontal those of a test distribution. The default behaviour
generates 1000 samples from the test distribution and overlays the plot
with shaded pointwise interval estimates for the ordered quantiles from
the test distribution. A small number of independently generated
exemplar quantile plots can also be overlaid.
Both the interval estimates and the exemplars provide different comparative information to assess the evidence provided by the qqplot for or against the hypothesis that the data come from the test distribution (default is normal or gaussian).
Finally, a visual test of significance (a lineup plot) can also be displayed to test the null hypothesis that the data come from the test distribution.
A self-calibrating plot can be created for any distribution whose quantile function can be provided by the user, making them useful for a wide variety of applications.
The plots are particularly helpful to students gaining experience in interpreting quantile-quantile plots, and to instructors hoping to teach basic understanding and interpretation of quantile-quantile plots.
Please read the reference for more explanation on and the historical development of the quantile-quantile plot.
The package also contains a collection of data sets which have appeared in the literature through the historical development of the quantile plot and the quantile quantile plots. See the reference/help for information on these.
The package also provides the usual functions for a distribution which we have used with considerable success in teaching undergraduate introductory statistics courses. This distribution is a simply transformation of the chi-squared, namely if X has a chi-squared distribution on m degrees of freedom then Y = sqrt(X/m) has a K distribution on m degrees of freedom.
This is a much more natural distribution to work with in the practice
and development of standard normal theory inference as described in
nearly every first course in Statistics. It is, for example, the
distribution of the sample standard deviation divided by sigma,
i.e. s/sigma
. It is also much more nearly symmetric and
concentrates around y = 1 as its degrees of freedom increase. It has
much to recommend it. See the article/vignette on the K
distribution.
The package provides the usual suite of functions:
dkay()
, pkay()
, qkay()
, and
rkay()
. (These seem particularly apt name choices given the
Scottish pronunciation of “Kay” is the same as “Chi”.)
To install qqtest
:
devtools::install_github("rwoldford.github.io/qqtest/")
install.packages("qqtest")
Documentation: https://rwoldford.github.io/qqtest/
R. Wayne Oldford (2016), “Self calibrating quantile-quantile plots”, The American Statistician, 70, pp. 74-90.
https://doi.org/10.1080/00031305.2015.1090338