The weird package contains functions and data used in the book Thatβs Weird: Anomaly Detection Using R by Rob J Hyndman. It also loads several packages needed to do the analysis described in the book.
You can install the stable version from CRAN with:
install.packages("weird")
You can install the development version of weird from GitHub with:
# install.packages("devtools")
devtools::install_github("robjhyndman/weird-package")
library(weird)
will load the following packages:
- dplyr, for data manipulation.
- ggplot2, for data visualisation.
- distributional, for handling probability distributions.
You also get a condensed summary of conflicts with other packages you have loaded:
library(weird)
#> ββ Attaching packages ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ weird 1.0.2.9000 ββ
#> β dplyr 1.1.4 β distributional 0.5.0
#> β ggplot2 3.5.1
#> ββ Conflicts ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ weird_conflicts ββ
#> β dplyr::filter() masks stats::filter()
#> β dplyr::lag() masks stats::lag()
The oldfaithful
data set contains eruption data from the Old Faithful
Geyser in Yellowstone National Park, Wyoming, USA, from 1 January 2015
to 1 October 2021. The data were obtained from the
geysertimes.org website. Recordings are
incomplete, especially during the winter months when observers may not
be present. There also appear to be some recording errors. The data set
contains 2261 observations of 3 variables: time
giving the time at
which each eruption began, duration
giving the length of the eruption
in seconds, and waiting
giving the time to the next eruption in
seconds. In the analysis below, we omit the eruption with duration
greater than 1 hour as this is likely to be a recording error. Some of
the long waiting
values are probably due to omitted eruptions, and so
we also omit eruptions with waiting
greater than 2 hours.
oldfaithful
#> # A tibble: 2,261 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2015-01-02 14:53:00 271 5040
#> 2 2015-01-09 23:55:00 247 6060
#> 3 2015-02-07 00:49:00 203 5460
#> 4 2015-02-14 01:09:00 195 5221
#> 5 2015-02-21 01:12:00 210 5401
#> 6 2015-02-28 01:11:00 185 5520
#> 7 2015-03-07 00:50:00 160 5281
#> 8 2015-03-13 21:57:00 226 6000
#> 9 2015-03-13 23:37:00 190 5341
#> 10 2015-03-20 22:26:00 102 3961
#> # βΉ 2,251 more rows
The package provides the kde_bandwidth()
function for estimating the
bandwidth of a kernel density estimate, dist_kde()
for constructing
the distribution, and gg_density()
for plotting the resulting density.
The figure below shows the kernel density estimate of the duration
variable obtained using these functions.
of <- oldfaithful |>
filter(duration < 3600, waiting < 7200)
dist_kde(of$duration) |>
gg_density(show_points = TRUE, jitter = TRUE) +
labs(x = "Duration (seconds)")
The same functions also work with bivariate data. The figure below shows
the kernel density estimate of the duration
and waiting
variables.
of |>
select(duration, waiting) |>
dist_kde() |>
gg_density(show_points = TRUE, alpha = 0.15) +
labs(x = "Duration (seconds)", y = "Waiting time (seconds)")
Some old methods of anomaly detection used statistical tests. While these are not recommended, they are still widely used, and are provided in the package for comparison purposes.
of |> filter(peirce_anomalies(duration))
#> # A tibble: 1 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700
of |> filter(chauvenet_anomalies(duration))
#> # A tibble: 1 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700
of |> filter(grubbs_anomalies(duration))
#> # A tibble: 1 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700
of |> filter(dixon_anomalies(duration))
#> # A tibble: 1 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700
In this example, they only detect the tiny 1-second duration, which is almost certainly a recording error. An explanation of these tests is provided in Chapter 4 of the book
Boxplots are widely used for anomaly detection. Here are three
variations of boxplots applied to the duration
variable.
of |>
ggplot(aes(x = duration)) +
geom_boxplot() +
scale_y_discrete() +
labs(y = "", x = "Duration (seconds)")
of |> gg_hdrboxplot(duration) +
labs(x = "Duration (seconds)")
of |> gg_hdrboxplot(duration, show_points = TRUE) +
labs(x = "Duration (seconds)")
The latter two plots are highest density region (HDR) boxplots, which allow the bimodality of the data to be seen. The dark shaded region contains 50% of the observations, while the lighter shaded region contains 99% of the observations. The plots use vertical jittering to reduce overplotting, and highlight potential outliers (those points lying outside the 99% HDR which have surprisal probability less than 0.0005). An explanation of these plots is provided in Chapter 5 of the book.
It is also possible to produce bivariate boxplots. Several variations are provided in the package. Here are two types of bagplot.
of |>
gg_bagplot(duration, waiting) +
labs(x = "Duration (seconds)", y = "Waiting time (seconds)")
of |>
gg_bagplot(duration, waiting, scatterplot = TRUE) +
labs(x = "Duration (seconds)", y = "Waiting time (seconds)")
And here are two types of HDR boxplot
of |>
gg_hdrboxplot(duration, waiting) +
labs(x = "Duration (seconds)", y = "Waiting time (seconds)")
of |>
gg_hdrboxplot(duration, waiting, scatterplot = TRUE) +
labs(x = "Duration (seconds)", y = "Waiting time (seconds)")
The latter two plots show possible outliers in black (again, defined as points outside the 99% HDR which have surprisal probability less than 0.0005).
Several functions are provided for providing anomaly scores for all observations.
- The
surprisals()
function uses either a fitted statistical model, or a kernel density estimate, to compute density scores. - The
stray_scores()
function uses the stray algorithm to compute anomaly scores. - The
lof_scores()
function uses local outlier factors to compute anomaly scores. - The
glosh_scores()
function uses the Global-Local Outlier Score from Hierarchies algorithm to compute anomaly scores. - The
lookout_prob()
function uses the lookout algorithm of Kandanaarachchi & Hyndman (2022) to compute anomaly probabilities.
Here are the top 0.02% most anomalous observations identified by each of the methods.
of |>
mutate(
surprisal = surprisals(cbind(duration, waiting), probability = FALSE),
strayscore = stray_scores(cbind(duration, waiting)),
lofscore = lof_scores(cbind(duration, waiting), k = 150),
gloshscore = glosh_scores(cbind(duration, waiting)),
lookout = lookout_prob(cbind(duration, waiting))
) |>
filter(
surprisal > quantile(surprisal, prob = 0.998) |
strayscore > quantile(strayscore, prob = 0.998) |
lofscore > quantile(lofscore, prob = 0.998) |
gloshscore > quantile(gloshscore, prob = 0.998) |
lookout < 0.002
) |>
arrange(lookout)
#> # A tibble: 10 Γ 8
#> time duration waiting surprisal strayscore lofscore gloshscore lookout
#> <dttm> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700 17.9 0.380 3.78 1 0
#> 2 2020-06-01 21:04:00 120 6060 17.8 0.132 1.88 1 0.00000000103
#> 3 2021-01-22 18:35:00 170 3600 16.9 0.0606 1.09 0.860 0.0000417
#> 4 2020-08-31 09:56:00 170 3840 16.7 0.0606 1.01 0.816 0.000390
#> 5 2015-11-21 20:27:00 150 3420 16.2 0.0772 1.27 1 0.0305
#> 6 2017-09-22 18:51:00 281 7140 15.0 0.0333 2.64 1 0.0791
#> 7 2020-10-15 17:11:00 220 7080 15.7 0.0429 2.42 1 0.130
#> 8 2017-08-12 13:14:00 120 4920 15.0 0.0690 1.53 1 0.166
#> 9 2020-05-18 21:21:00 272 7080 14.5 0.0333 2.42 1 0.289
#> 10 2018-09-22 16:37:00 253 7140 14.6 0.0200 2.63 1 0.413
The surprisals()
function can also compute the probability of
obtaining surprisal values at least as extreme as those observed. In
fact, this is the default behaviour, obtained when probability = TRUE
.
of |>
mutate(
surprisal = surprisals(cbind(duration, waiting), probability = FALSE),
prob = surprisals(cbind(duration, waiting))
) |>
arrange(prob)
#> # A tibble: 2,197 Γ 5
#> time duration waiting surprisal prob
#> <dttm> <dbl> <dbl> <dbl> <dbl>
#> 1 2018-04-25 19:08:00 1 5700 17.9 0.000455
#> 2 2020-06-01 21:04:00 120 6060 17.8 0.000910
#> 3 2021-01-22 18:35:00 170 3600 16.9 0.00137
#> 4 2020-08-31 09:56:00 170 3840 16.7 0.00182
#> 5 2015-11-21 20:27:00 150 3420 16.2 0.00228
#> 6 2017-05-03 06:19:00 90 4740 16.2 0.00273
#> 7 2020-09-16 14:44:00 160 6120 16.1 0.00319
#> 8 2020-07-23 23:17:00 186 4320 16.1 0.00364
#> 9 2019-07-25 06:32:00 300 5280 15.9 0.00410
#> 10 2020-09-15 18:01:00 160 5880 15.9 0.00455
#> # βΉ 2,187 more rows
Some anomaly detection methods require the data to be scaled first, so
all observations are on the same scale. However, many scaling methods
are not robust to anomalies. The mvscale()
function provides a
multivariate robust scaling method, that optionally takes account of the
relationships betwen variables, and uses robust estimates of center,
scale and covariance by default. The centers are removed using medians,
the scale function is the IQR, and the covariance matrix is estimated
using a robust OGK estimate. The data are scaled using the Cholesky
decomposition of the inverse covariance. Then the scaled data are
returned. The scaled variables are rotated to be orthogonal, so are
renamed as z1
, z2
, etc. Non-rotated scaling is possible by setting
cov = NULL
.
mvscale(of)
#> Warning in mvscale(of): Ignoring non-numeric columns: time
#> # A tibble: 2,197 Γ 3
#> time z1 z2
#> <dttm> <dbl> <dbl>
#> 1 2015-01-02 14:53:00 2.02 -1.33
#> 2 2015-01-09 23:55:00 0.0758 0.728
#> 3 2015-02-07 00:49:00 -1.64 -0.485
#> 4 2015-02-14 01:09:00 -1.86 -0.968
#> 5 2015-02-21 01:12:00 -1.25 -0.604
#> 6 2015-02-28 01:11:00 -2.57 -0.364
#> 7 2015-03-07 00:50:00 -3.63 -0.847
#> 8 2015-03-13 21:57:00 -0.913 0.606
#> 9 2015-03-13 23:37:00 -2.19 -0.726
#> 10 2015-03-20 22:26:00 -5.50 -3.51
#> # βΉ 2,187 more rows
mvscale(of, cov = NULL)
#> Warning in mvscale(of, cov = NULL): Ignoring non-numeric columns: time
#> # A tibble: 2,197 Γ 3
#> time duration waiting
#> <dttm> <dbl> <dbl>
#> 1 2015-01-02 14:53:00 1.40 -1.24
#> 2 2015-01-09 23:55:00 0.316 0.676
#> 3 2015-02-07 00:49:00 -1.67 -0.451
#> 4 2015-02-14 01:09:00 -2.03 -0.900
#> 5 2015-02-21 01:12:00 -1.35 -0.562
#> 6 2015-02-28 01:11:00 -2.48 -0.338
#> 7 2015-03-07 00:50:00 -3.61 -0.787
#> 8 2015-03-13 21:57:00 -0.631 0.564
#> 9 2015-03-13 23:37:00 -2.25 -0.675
#> 10 2015-03-20 22:26:00 -6.22 -3.27
#> # βΉ 2,187 more rows