Coefficient of variation explained

Coefficient of variation should not be confused with Coefficient of determination.

\sigma

to the mean

\mu

(or its absolute value,, and often expressed as a percentage ("%RSD"). The CV or RSD is widely used in analytical chemistry to express the precision and repeatability of an assay. It is also commonly used in fields such as engineering or physics when doing quality assurance studies and ANOVA gauge R&R, by economists and investors in economic models, and in psychology/neuroscience.

Definition

The coefficient of variation (CV) is defined as the ratio of the standard deviation

\sigma

to the mean

\mu

,

CV=

\sigma
\mu

.

[1]

It shows the extent of variability in relation to the mean of the population.The coefficient of variation should be computed only for data measured on scales that have a meaningful zero (ratio scale) and hence allow relative comparison of two measurements (i.e., division of one measurement by the other). The coefficient of variation may not have any meaning for data on an interval scale.[2] For example, most temperature scales (e.g., Celsius, Fahrenheit etc.) are interval scales with arbitrary zeros, so the computed coefficient of variation would be different depending on the scale used. On the other hand, Kelvin temperature has a meaningful zero, the complete absence of thermal energy, and thus is a ratio scale. In plain language, it is meaningful to say that 20 Kelvin is twice as hot as 10 Kelvin, but only in this scale with a true absolute zero. While a standard deviation (SD) can be measured in Kelvin, Celsius, or Fahrenheit, the value computed is only applicable to that scale. Only the Kelvin scale can be used to compute a valid coefficient of variability.

Measurements that are log-normally distributed exhibit stationary CV; in contrast, SD varies depending upon the expected value of measurements.

{(Q3-Q1)/2}

divided by the average of the quartiles (the midhinge),

{(Q1+Q3)/2}

.

In most cases, a CV is computed for a single independent variable (e.g., a single factory product) with numerous, repeated measures of a dependent variable (e.g., error in the production process). However, data that are linear or even logarithmically non-linear and include a continuous range for the independent variable with sparse measurements across each value (e.g., scatter-plot) may be amenable to single CV calculation using a maximum-likelihood estimation approach.[3]

Examples

In the examples below, we will take the values given as randomly chosen from a larger population of values.

In these examples, we will take the values given as the entire population of values.

Estimation

s

to the sample mean

\bar{x}

:

\widehat{c\rm

} = \frac

But this estimator, when applied to a small or moderately sized sample, tends to be too low: it is a biased estimator. For normally distributed data, an unbiased estimator[4] for a sample of size n is:

\widehat{c\rm

}^*=\bigg(1+\frac\bigg)\widehat

Log-normal data

Many datasets follow an approximately log-normal distribution.[5] In such cases, a more accurate estimate, derived from the properties of the log-normal distribution,[6] [7] [8] is defined as:

\widehat{cv}\rm=

2
s
ln
\sqrt{e

-1}

where

{sln

} \, is the sample standard deviation of the data after a natural log transformation. (In the event that measurements are recorded using any other logarithmic base, b, their standard deviation

sb

is converted to base e using

sln=sbln(b)

, and the formula for

\widehat{cv}\rm

remains the same.[9]) This estimate is sometimes referred to as the "geometric CV" (GCV)[10] [11] in order to distinguish it from the simple estimate above. However, "geometric coefficient of variation" has also been defined by Kirkwood[12] as:
GCVK

=

sln
{e

-1}

This term was intended to be analogous to the coefficient of variation, for describing multiplicative variation in log-normal data, but this definition of GCV has no theoretical basis as an estimate of

c\rm

itself.

For many practical purposes (such as sample size determination and calculation of confidence intervals) it is

sln

which is of most use in the context of log-normally distributed data. If necessary, this can be derived from an estimate of

c\rm

or GCV by inverting the corresponding formula.

Comparison to standard deviation

Advantages

The coefficient of variation is useful because the standard deviation of data must always be understood in the context of the mean of the data. In contrast, the actual value of the CV is independent of the unit in which the measurement has been taken, so it is a dimensionless number. For comparison between data sets with different units or widely different means, one should use the coefficient of variation instead of the standard deviation.

Disadvantages

Applications

The coefficient of variation is also common in applied probability fields such as renewal theory, queueing theory, and reliability theory. In these fields, the exponential distribution is often more important than the normal distribution.The standard deviation of an exponential distribution is equal to its mean, so its coefficient of variation is equal to 1. Distributions with CV < 1 (such as an Erlang distribution) are considered low-variance, while those with CV > 1 (such as a hyper-exponential distribution) are considered high-variance. Some formulas in these fields are expressed using the squared coefficient of variation, often abbreviated SCV. In modeling, a variation of the CV is the CV(RMSD). Essentially the CV(RMSD) replaces the standard deviation term with the Root Mean Square Deviation (RMSD). While many natural processes indeed show a correlation between the average value and the amount of variation around it, accurate sensor devices need to be designed in such a way that the coefficient of variation is close to zero, i.e., yielding a constant absolute error over their working range.

In actuarial science, the CV is known as unitized risk.[13]

In industrial solids processing, CV is particularly important to measure the degree of homogeneity of a powder mixture. Comparing the calculated CV to a specification will allow to define if a sufficient degree of mixing has been reached.[14]

In fluid dynamics, the CV, also referred to as Percent RMS, %RMS, %RMS Uniformity, or Velocity RMS, is a useful determination of flow uniformity for industrial processes. The term is used widely in the design of pollution control equipment, such as electrostatic precipitators (ESPs),[15] selective catalytic reduction (SCR), scrubbers, and similar devices. The Institute of Clean Air Companies (ICAC) references RMS deviation of velocity in the design of fabric filters (ICAC document F-7).[16] The guiding principal is that many of these pollution control devices require "uniform flow" entering and through the control zone. This can be related to uniformity of velocity profile, temperature distribution, gas species (such as ammonia for an SCR, or activated carbon injection for mercury absorption), and other flow-related parameters. The Percent RMS also is used to assess flow uniformity in combustion systems, HVAC systems, ductwork, inlets to fans and filters, air handling units, etc. where performance of the equipment is influenced by the incoming flow distribution.

Laboratory measures of intra-assay and inter-assay CVs

CV measures are often used as quality controls for quantitative laboratory assays. While intra-assay and inter-assay CVs might be assumed to be calculated by simply averaging CV values across CV values for multiple samples within one assay or by averaging multiple inter-assay CV estimates, it has been suggested that these practices are incorrect and that a more complex computational process is required.[17] It has also been noted that CV values are not an ideal index of the certainty of a measurement when the number of replicates varies across samples − in this case standard error in percent is suggested to be superior.[18] If measurements do not have a natural zero point then the CV is not a valid measurement and alternative measures such as the intraclass correlation coefficient are recommended.[19]

As a measure of economic inequality

The coefficient of variation fulfills the requirements for a measure of economic inequality.[20] [21] [22] If x (with entries xi) is a list of the values of an economic indicator (e.g. wealth), with xi being the wealth of agent i, then the following requirements are met:

cv assumes its minimum value of zero for complete equality (all xi are equal). Its most notable drawback is that it is not bounded from above, so it cannot be normalized to be within a fixed range (e.g. like the Gini coefficient which is constrained to be between 0 and 1). It is, however, more mathematically tractable than the Gini coefficient.

As a measure of standardisation of archaeological artefacts

Archaeologists often use CV values to compare the degree of standardisation of ancient artefacts.[23] [24] Variation in CVs has been interpreted to indicate different cultural transmission contexts for the adoption of new technologies.[25] Coefficients of variation have also been used to investigate pottery standardisation relating to changes in social organisation.[26] Archaeologists also use several methods for comparing CV values, for example the modified signed-likelihood ratio (MSLR) test for equality of CVs.[27] [28]

Examples of misuse

Comparing coefficients of variation between parameters using relative units can result in differences that may not be real. If we compare the same set of temperatures in Celsius and Fahrenheit (both relative units, where kelvin and Rankine scale are their associated absolute values):

Celsius: [0, 10, 20, 30, 40]

Fahrenheit: [32, 50, 68, 86, 104]

The sample standard deviations are 15.81 and 28.46, respectively. The CV of the first set is 15.81/20 = 79%. For the second set (which are the same temperatures) it is 28.46/68 = 42%.

If, for example, the data sets are temperature readings from two different sensors (a Celsius sensor and a Fahrenheit sensor) and you want to know which sensor is better by picking the one with the least variance, then you will be misled if you use CV. The problem here is that you have divided by a relative value rather than an absolute.

Comparing the same data set, now in absolute units:

Kelvin: [273.15, 283.15, 293.15, 303.15, 313.15]

Rankine: [491.67, 509.67, 527.67, 545.67, 563.67]

The sample standard deviations are still 15.81 and 28.46, respectively, because the standard deviation is not affected by a constant offset. The coefficients of variation, however, are now both equal to 5.39%.

Mathematically speaking, the coefficient of variation is not entirely linear. That is, for a random variable

X

, the coefficient of variation of

aX+b

is equal to the coefficient of variation of

X

only when

b=0

. In the above example, Celsius can only be converted to Fahrenheit through a linear transformation of the form

ax+b

with

b0

, whereas Kelvins can be converted to Rankines through a transformation of the form

ax

.

Distribution

Provided that negative and small positive values of the sample mean occur with negligible frequency, the probability distribution of the coefficient of variation for a sample of size

n

of i.i.d. normal random variables has been shown by Hendricks and Robey to be[29]

\mathrmF_ = \frac \exp \left(-\frac \cdot \frac \right) \frac\sideset\sum_^\frac \cdot \frac \cdot \frac \, \mathrmc_,

where the symbol \sideset\sum indicates that the summation is over only even values of

n-1-i

, i.e., if

n

is odd, sum over even values of

i

and if

n

is even, sum only over odd values of

i

.

This is useful, for instance, in the construction of hypothesis tests or confidence intervals. Statistical inference for the coefficient of variation in normally distributed data is often based on McKay's chi-square approximation for the coefficient of variation.[30] [31] [32] [33] [34] [35] Methods for

Alternative

Liu (2012) reviews methods for the construction of a confidence interval for the coefficient of variation.[36] Notably, Lehmann (1986) derived the sampling distribution for the coefficient of variation using a non-central t-distribution to give an exact method for the construction of the CI.[37]

Similar ratios

Standardized moments are similar ratios,

k}
{\mu
k}/{\sigma
where

\muk

is the kth moment about the mean, which are also dimensionless and scale invariant. The variance-to-mean ratio,

\sigma2/\mu

, is another similar ratio, but is not dimensionless, and hence not scale invariant. See Normalization (statistics) for further ratios.

In signal processing, particularly image processing, the reciprocal ratio

\mu/\sigma

(or its square) is referred to as the signal-to-noise ratio in general and signal-to-noise ratio (imaging) in particular.

Other related ratios include:

\sigma2/\mu2

k
\mu
k/\sigma

\sigma2/\mu

2
\sigma
W/\mu

W

(windowed VMR)

See also

External links

R package to test for significant differences between multiple coefficients of variation

Notes and References

  1. Book: Everitt, Brian. The Cambridge Dictionary of Statistics. Cambridge University Press. 1998. 978-0521593465. Cambridge, UK New York. registration.
  2. Web site: What is the difference between ordinal, interval and ratio variables? Why should I care? . 22 February 2008 . GraphPad Software Inc . live . https://web.archive.org/web/20081215175508/http://graphpad.com/faq/viewfaq.cfm?faq=1089 . 15 December 2008 . dmy-all .
  3. Odic. Darko. Im. Hee Yeon. Eisinger. Robert. Ly. Ryan. Halberda. Justin. June 2016. PsiMLE: A maximum-likelihood estimation approach to estimating psychophysical scaling and variability more reliably, efficiently, and flexibly. Behavior Research Methods. 48. 2. 445–462. 10.3758/s13428-015-0600-5. 1554-3528. 25987306. free.
  4. Sokal RR & Rohlf FJ. Biometry (3rd Ed). New York: Freeman, 1995. p. 58.
  5. 10.1641/0006-3568(2001)051[0341:LNDATS]2.0.CO;2 . Log-normal Distributions across the Sciences: Keys and Clues . 2001 . Limpert . Eckhard . Stahel . Werner A. . Abbt . Markus . BioScience . 51 . 5 . 341–352. free .
  6. 10.1093/biomet/51.1-2.25 . Confidence intervals for the coefficient of variation for the normal and log normal distributions . 1964 . Koopmans . L. H. . Owen . D. B. . Rosenblatt . J. I. . Biometrika . 51 . 1–2 . 25–32.
  7. 1601532 . 1992 . Diletti . E . Hauschke . D . Steinijans . VW . Sample size determination for bioequivalence assessment by means of confidence intervals . 30 . S51–8 . International Journal of Clinical Pharmacology, Therapy, and Toxicology. Suppl 1 .
  8. 10.1081/BIP-100101013 . Why Are Pharmacokinetic Data Summarized by Arithmetic Means? . 2000 . Julious . Steven A. . Debarnot . Camille A. M. . Journal of Biopharmaceutical Statistics . 10 . 55–71 . 10709801 . 1. 2805094 .
  9. Reed . JF . Lynn . F . Meade . BD . 2002 . Use of Coefficient of Variation in Assessing Variability of Quantitative Assays . Clin Diagn Lab Immunol . 9 . 6. 1235–1239 . 10.1128/CDLI.9.6.1235-1239.2002 . 12414755 . 130103 .
  10. Sawant, S.; Mohan, N. (2011) "FAQ: Issues with Efficacy Analysis of Clinical Trial Data Using SAS", PharmaSUG2011, Paper PO08
  11. Schiff . MH . etal . 2014 . Head-to-head, randomised, crossover study of oral versus subcutaneous methotrexate in patients with rheumatoid arthritis: drug-exposure limitations of oral methotrexate at doses >=15 mg may be overcome with subcutaneous administration. Ann Rheum Dis . 73. 8. 1–3 . 10.1136/annrheumdis-2014-205228 . 24728329 . 4112421.
  12. Kirkwood . TBL . Geometric means and measures of dispersion . Biometrics . 1979 . 35 . 4 . 908–9 . 2530139 .
  13. Book: Broverman. Samuel A.. Actex study manual, Course 1, Examination of the Society of Actuaries, Exam 1 of the Casualty Actuarial Society. 2001. Actex Publications. Winsted, CT. 9781566983969. 104. 2001. 7 June 2014.
  14. Web site: Measuring Degree of Mixing – Homogeneity of powder mix - Mixture quality - PowderProcess.net. www.powderprocess.net. 2 May 2018. live. https://web.archive.org/web/20171114145327/https://www.powderprocess.net/Measuring_Degree_Mixing.html. 14 November 2017. dmy-all.
  15. Web site: Improved Methodology for Accurate CFD and Physical Modeling of ESPs . Banka . A . Dumont . B . Franklin . J . Klemm . G . Mudry . R . 2018 . International Society of Electrostatic Precipitation (ISESP) Conference 2018 .
  16. Web site: F7 - Fabric Filter Gas Flow Model Studies . 1996 . Institute of Clean Air Companies (ICAC) .
  17. Rodbard. D. Statistical quality control and routine data processing for radioimmunoassays and immunoradiometric assays.. Clinical Chemistry. October 1974. 20. 10. 1255–70. 10.1093/clinchem/20.10.1255. 4370388. free.
  18. Eisenberg. Dan. Improving qPCR telomere length assays: Controlling for well position effects increases statistical power. American Journal of Human Biology. 2015. 10.1002/ajhb.22690. 25757675. 27. 4. 570–5. 4478151.
  19. Eisenberg. Dan T. A.. Telomere length measurement validity: the coefficient of variation is invalid and cannot be used to compare quantitative polymerase chain reaction and Southern blot telomere length measurement technique. International Journal of Epidemiology. 45. 4. 30 August 2016. 1295–1298. 10.1093/ije/dyw191. 27581804. 0300-5771. free.
  20. Book: Champernowne . D. G.. Cowell . F. A.. 1999 . Economic Inequality and Income Distribution . Cambridge University Press .
  21. Book: Campano . F. . Salvatore . D. . 2006 . Income distribution . Oxford University Press .
  22. Web site: Policy Impacts on Inequality – Simple Inequality Measures . Bellu . Lorenzo Giovanni . Liberati . Paolo . 2006 . EASYPol, Analytical tools . Policy Support Service, Policy Assistance Division, FAO . 13 June 2016 . live . https://web.archive.org/web/20160805101141/http://www.fao.org/docs/up/easypol/448/simple_inequality_mesures_080en.pdf . 5 August 2016 . dmy-all .
  23. Eerkens . Jelmer W. . Bettinger . Robert L. . Techniques for Assessing Standardization in Artifact Assemblages: Can We Scale Material Variability? . American Antiquity . July 2001 . 66 . 3 . 493–504 . 10.2307/2694247. 2694247 . 163507589 .
  24. Roux . Valentine . Ceramic Standardization and Intensity of Production: Quantifying Degrees of Specialization . American Antiquity . 2003 . 68 . 4 . 768–782 . 10.2307/3557072 . 3557072 . 147444325 . en . 0002-7316.
  25. Bettinger . Robert L. . Eerkens . Jelmer . Point Typologies, Cultural Transmission, and the Spread of Bow-and-Arrow Technology in the Prehistoric Great Basin . American Antiquity . April 1999 . 64 . 2 . 231–242 . 10.2307/2694276. 2694276 . 163198451 .
  26. Wang . Li-Ying . Marwick . Ben . Standardization of ceramic shape: A case study of Iron Age pottery from northeastern Taiwan . Journal of Archaeological Science: Reports . October 2020 . 33 . 102554 . 10.1016/j.jasrep.2020.102554. 2020JArSR..33j2554W . 224904703 .
  27. Krishnamoorthy . K. . Lee . Meesook . Improved tests for the equality of normal coefficients of variation . Computational Statistics . February 2014 . 29 . 1–2 . 215–232 . 10.1007/s00180-013-0445-2. 120898013 .
  28. Book: Marwick . Ben . Krishnamoorthy . K . cvequality: Tests for the equality of coefficients of variation from multiple groups . 2019 . R package version 0.2.0. .
  29. Hendricks. Walter A.. Robey. Kate W.. 1936. The Sampling Distribution of the Coefficient of Variation. The Annals of Mathematical Statistics. 7. 3. 129–32. 10.1214/aoms/1177732503. 2957564. free.
  30. 1267363 . Comparisons of approximations to the percentage points of the sample coefficient of variation . 1970 . Iglevicz . Boris . Myers . Raymond . Technometrics . 12 . 1 . 166–169. 10.2307/1267363 .
  31. Book: Bennett . B. M. . Contribution to Applied Statistics . On an Approximate Test for Homogeneity of Coefficients of Variation . 1976 . 22 . 169–171 . 10.1007/978-3-0348-5513-6_16 . Experientia Supplementum . 978-3-0348-5515-0 .
  32. 2685039 . Confidence intervals for a normal coefficient of variation . 1996 . Vangel . Mark G. . The American Statistician . 50 . 1 . 21–26 . 10.1080/00031305.1996.10473537. .
  33. 10.1002/(SICI)1097-0258(19960330)15:6<647::AID-SIM184>3.0.CO;2-P . An asymptotic test for the equality of coefficients of variation from k populations . Statistics in Medicine . 15 . 6 . 647 . 1996 . Feltz . Carol J . Miller . G. Edward . 8731006 .
  34. Estimator and tests for common coefficients of variation in normal distributions . 23 September 2013 . Forkman . Johannes . Communications in Statistics – Theory and Methods . 38 . 2 . 21–26 . 10.1080/03610920802187448 . 2009 . 29168286 . live . https://web.archive.org/web/20131206021229/http://pub.epsilon.slu.se/4489/1/forkman_j_110214.pdf . 6 December 2013 . dmy-all .
  35. 10.1007/s00180-013-0445-2 . Improved tests for the equality of normal coefficients of variation . Computational Statistics . 29 . 1–2 . 215–232 . 2013 . Krishnamoorthy . K . Lee . Meesook . 120898013 .
  36. Liu . Shuang . Confidence Interval Estimation for Coefficient of Variation . Georgia State University . 2014-02-25 . live . https://web.archive.org/web/20140301102042/http://scholarworks.gsu.edu/cgi/viewcontent.cgi?article=1116&context=math_theses . 1 March 2014 . dmy-all . p.3 . 2012.
  37. Lehmann, E. L. (1986). Testing Statistical Hypothesis. 2nd ed. New York: Wiley.