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Anomaly detection plays a crucial role in time series analysis and forecasting. Anomalies, also known as outliers, are unusual observations that don’t follow the expected time series patterns. They can be caused by a variety of factors, including errors in the data collection process, unexpected events, or sudden changes in the patterns of the time series. Anomalies can provide critical information about a system, like a potential problem or malfunction. After identifying them, it is important to understand what caused them, and then decide whether to remove, replace, or keep them.
TimeGPT
has a method for detecting anomalies, and users
can call it from nixtlar
. This vignette will explain how to
do this. It assumes you have already set up your API key. If you haven’t
done this, please read the Get
Started vignette first.
For this vignette, we’ll use the electricity consumption dataset that
is included in nixtlar
, which contains the hourly prices of
five different electricity markets.
To detect anomalies, use
nixtlar::nixtla_client_detect_anomalies
, which requires the
following parameter:
ds
and y
. If your column names are
different, specify them with time_col
and
target_col
, respectively. If you are working with multiple
series, you must also include a column with unique identifiers. The
default name for this column is unique_id
; if different,
specify it with id_col
.nixtla_client_anomalies <- nixtlar::nixtla_client_detect_anomalies(df)
#> Frequency chosen: h
head(nixtla_client_anomalies)
#> unique_id ds y anomaly TimeGPT TimeGPT-lo-99
#> 1 BE 2016-10-27 00:00:00 52.58 FALSE 56.07623 -28.58337
#> 2 BE 2016-10-27 01:00:00 44.86 FALSE 52.41973 -32.23986
#> 3 BE 2016-10-27 02:00:00 42.31 FALSE 52.81474 -31.84486
#> 4 BE 2016-10-27 03:00:00 39.66 FALSE 52.59026 -32.06934
#> 5 BE 2016-10-27 04:00:00 38.98 FALSE 52.67297 -31.98662
#> 6 BE 2016-10-27 05:00:00 42.31 FALSE 54.10659 -30.55301
#> TimeGPT-hi-99
#> 1 140.7358
#> 2 137.0793
#> 3 137.4743
#> 4 137.2499
#> 5 137.3326
#> 6 138.7662
The anomaly_detection
method from TimeGPT
evaluates each observation and uses a prediction interval to determine
if it is an anomaly or not. By default,
nixtlar::nixtla_client_detect_anomalies
uses a 99%
prediction interval. Observations that fall outside this interval will
be considered anomalies and will have a value of True
in
the anomaly
column (False
otherwise). To
change the prediction interval, for example to 95%, use the argument
level=c(95)
. Keep in mind that multiple levels are not
allowed, so when given several values,
nixtlar::nixtla_client_detect_anomalies
will use the
maximum.
nixtlar
includes a function to plot the historical data
and any output from nixtlar::nixtla_client_forecast
,
nixtlar::nixtla_client_historic
,
nixtlar::nixtla_client_detect_anomalies
and
nixtlar::nixtla_client_cross_validation
. If you have long
series, you can use max_insample_length
to only plot the
last N historical values (the forecast will always be plotted in
full).
When using nixtlar::nixtla_client_plot
with the output
of nixtlar::nixtla_client_detect_anomalies
, set
plot_anomalies=TRUE
to plot the anomalies.
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.