Winsorizing

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Winsorizing or winsorization is the transformation of statistics by limiting extreme values in the statistical data to reduce the effect of possibly spurious outliers. It is named after the engineer-turned-biostatistician Charles P. Winsor (1895–1951). The effect is the same as clipping in signal processing.

The distribution of many statistics can be heavily influenced by outliers. A typical strategy is to set all outliers to a specified percentile of the data; for example, a 90% winsorization would see all data below the 5th percentile set to the 5th percentile, and data above the 95th percentile set to the 95th percentile. Winsorized estimators are usually more robust to outliers than their more standard forms, although there are alternatives, such as trimming, that will achieve a similar effect.

Example[]

Consider the data set consisting of:

{92, 19, 101, 58, 1053, 91, 26, 78, 10, 13, −40, 101, 86, 85, 15, 89, 89, 28, −5, 41}       (N = 20, mean = 101.5)

The data below the 5th percentile lies between −40 and −5, while the data above the 95th percentile lies between 101 and 1053 (pertinent values shown in bold); accordingly, a 90% winsorization would result in the following:

{92, 19, 101, 58, 101, 91, 26, 78, 10, 13, −5, 101, 86, 85, 15, 89, 89, 28, −5, 41}       (N = 20, mean = 55.65)

After winsorization the mean has dropped to nearly half its previous value, and is consequently more in line with the data it represents.

Python can winsorize data using SciPy library :

from scipy.stats.mstats import winsorize
winsorize([92, 19, 101, 58, 1053, 91, 26, 78, 10, 13, -40, 101, 86, 85, 15, 89, 89, 28, -5, 41], limits=[0.05, 0.05])

R can winsorize data using the DescTools package:[1]

library(DescTools)
a<-c(92, 19, 101, 58, 1053, 91, 26, 78, 10, 13, -40, 101, 86, 85, 15, 89, 89, 28, -5, 41)
DescTools::Winsorize(a, probs = c(0.05, 0.95))

Distinction from trimming[]

Note that winsorizing is not equivalent to simply excluding data, which is a simpler procedure, called trimming or truncation, but is a method of censoring data.

In a trimmed estimator, the extreme values are discarded; in a winsorized estimator, the extreme values are instead replaced by certain percentiles (the trimmed minimum and maximum).

Thus a winsorized mean is not the same as a truncated mean. For instance, the 10% trimmed mean is the average of the 5th to 95th percentile of the data, while the 90% winsorized mean sets the bottom 5% to the 5th percentile, the top 5% to the 95th percentile, and then averages the data. In the previous example the trimmed mean would be obtained from the smaller set:

{92, 19, 101, 58,       91, 26, 78, 10, 13,       101, 86, 85, 15, 89, 89, 28, −5, 41}       (N = 18, mean = 56.5)

In this case, the winsorized mean can equivalently be expressed as a weighted average of the truncated mean and the 5th and 95th percentiles (for the 10% winsorized mean, 0.05 times the 5th percentile, 0.9 times the 10% trimmed mean, and 0.05 times the 95th percentile) though in general winsorized statistics need not be expressible in terms of the corresponding trimmed statistic.

More formally, they are distinct because the order statistics are not independent.

Uses[]

Winsorization is a used in the survey methodology context in order to "trim" extreme survey non-response weights.[2]

See also[]

References[]

  1. ^ Andri Signorell et al. (2021). DescTools: Tools for descriptive statistics. R package version 0.99.41.
  2. ^ Lee, Brian K., Justin Lessler, and Elizabeth A. Stuart. "Weight trimming and propensity score weighting." PloS one 6.3 (2011): e18174. link
  • Hastings, Jr., Cecil; Mosteller, Frederick; Tukey, John W.; Winsor, Charles P. (1947). "Low moments for small samples: a comparative study of order statistics". Annals of Mathematical Statistics. 18 (3): 413–426. doi:10.1214/aoms/1177730388.
  • Dixon, W. J. (1960). "Simplified Estimation from Censored Normal Samples". Annals of Mathematical Statistics. 31 (2): 385–391. doi:10.1214/aoms/1177705900.
  • Tukey, J. W. (1962). "The Future of Data Analysis". Annals of Mathematical Statistics. 33 (1): 1–67 [p. 18]. doi:10.1214/aoms/1177704711. JSTOR 2237638.

External links[]

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