Fisher transformation

In statistics, the Fisher transformation (or Fisher z-transformation) of a Pearson correlation coefficient is its inverse hyperbolic tangent (artanh). When the sample correlation coefficient r is near 1 or -1, its distribution is highly skewed, which makes it difficult to estimate confidence intervals and apply tests of significance for the population correlation coefficient ρ.^[1][2][3] The Fisher transformation solves this problem by yielding a variable whose distribution is approximately normally distributed, with a variance that is stable over different values of r.

Given a set of N bivariate sample pairs (X_i, Y_i), i = 1, …, N, the sample correlation coefficient r is given by

${\displaystyle r=\frac{\mathrm{cov}(X,Y)}{{\sigma }_X{\sigma }_Y}=\frac{{\displaystyle \sum _{i=1}^N}(X_i-\overline{X})(Y_i-\overline{Y})}{\sqrt{{\displaystyle \sum _{i=1}^N}(X_i-\overline{X}{)}^2}\sqrt{{\displaystyle \sum _{i=1}^N}(Y_i-\overline{Y}{)}^2}}.}$

Here ${\displaystyle \mathrm{cov}(X,Y)}$ stands for the covariance between the variables ${\displaystyle X}$ and ${\displaystyle Y}$ and ${\displaystyle \sigma }$ stands for the standard deviation of the respective variable. Fisher's z-transformation of r is defined as

${\displaystyle z=\frac{1}{2}\ln \left(\frac{1+r}{1-r}\right)=\mathrm{artanh}(r),}$

where "ln" is the natural logarithm function and "artanh" is the inverse hyperbolic tangent function.

If (X, Y) has a bivariate normal distribution with correlation ρ and the pairs (X_i, Y_i) are independent and identically distributed, then z is approximately normally distributed with mean

${\displaystyle \frac{1}{2}\ln \left(\frac{1+\rho }{1-\rho }\right),}$

and standard error

${\displaystyle \frac{1}{\sqrt{N-3}},}$

where N is the sample size, and ρ is the true correlation coefficient.

This transformation, and its inverse

${\displaystyle r=\frac{\exp (2z)-1}{\exp (2z)+1}=\tanh (z),}$

can be used to construct a large-sample confidence interval for r using standard normal theory and derivations. See also application to partial correlation.

Hotelling gives a concise derivation of the Fisher transformation.^[4]

To derive the Fisher transformation, one starts by considering an arbitrary increasing, twice-differentiable function of ${\displaystyle r}$, say ${\displaystyle G(r)}$. Finding the first term in the large-${\displaystyle N}$ expansion of the corresponding skewness ${\displaystyle {\kappa }_3}$ results^[5] in

${\displaystyle {\kappa }_3=\frac{6\rho -3(1-{\rho }^2)G^{\prime \prime }(\rho )/G^{\prime }(\rho )}{\sqrt{N}}+O(N^{-3/2}).}$

Setting ${\displaystyle {\kappa }_3=0}$ and solving the corresponding differential equation for ${\displaystyle G}$ yields the inverse hyperbolic tangent ${\displaystyle G(\rho )=\mathrm{artanh}(\rho )}$ function.

Similarly expanding the mean m and variance v of ${\displaystyle \mathrm{artanh}(r)}$, one gets

m = ${\displaystyle \mathrm{artanh}(\rho )+\frac{\rho }{2N}+O(N^{-2})}$

and

v = ${\displaystyle \frac{1}{N}+\frac{6-{\rho }^2}{2N^2}+O(N^{-3})}$

respectively.

The extra terms are not part of the usual Fisher transformation. For large values of ${\displaystyle \rho }$ and small values of ${\displaystyle N}$ they represent a large improvement of accuracy at minimal cost, although they greatly complicate the computation of the inverse – a closed-form expression is not available. The near-constant variance of the transformation is the result of removing its skewness – the actual improvement is achieved by the latter, not by the extra terms. Including the extra terms, i.e., computing (z-m)/v^1/2, yields:

${\displaystyle \frac{z-\mathrm{artanh}(\rho )-\frac{\rho }{2N}}{\sqrt{\frac{1}{N}+\frac{6-{\rho }^2}{2N^2}}}}$

which has, to an excellent approximation, a standard normal distribution.^[6]

The application of Fisher's transformation can be enhanced using a software calculator as shown in the figure. Assuming that the r-squared value found is 0.80, that there are 30 data ^{[clarification needed]}, and accepting a 90% confidence interval, the r-squared value in another random sample from the same population may range from 0.588 to 0.921. When r-squared is outside this range, the population is considered to be different. However, if a certain data set is analysed with two different regression models while the first model yields r-squared = 0.80 and the second r-squared is 0.49, one may conclude that the second model is insignificant as the value 0.49 is below the critical value 0.588.

The Fisher transformation is an approximate variance-stabilizing transformation for r when X and Y follow a bivariate normal distribution. This means that the variance of z is approximately constant for all values of the population correlation coefficient ρ. Without the Fisher transformation, the variance of r grows smaller as |ρ| gets closer to 1. Since the Fisher transformation is approximately the identity function when |r| < 1/2, it is sometimes useful to remember that the variance of r is well approximated by 1/N as long as |ρ| is not too large and N is not too small. This is related to the fact that the asymptotic variance of r is 1 for bivariate normal data.

The behavior of this transform has been extensively studied since Fisher introduced it in 1915. Fisher himself found the exact distribution of z for data from a bivariate normal distribution in 1921; Gayen in 1951^[8] determined the exact distribution of z for data from a bivariate Type A Edgeworth distribution. Hotelling in 1953 calculated the Taylor series expressions for the moments of z and several related statistics^[9] and Hawkins in 1989 discovered the asymptotic distribution of z for data from a distribution with bounded fourth moments.^[10]

An alternative to the Fisher transformation is to use the exact confidence distribution density for ρ given by^[11][12] $${\displaystyle \pi (\rho |r)=\frac{\mathrm{\Gamma }(\nu +1)}{\sqrt{2\pi }\mathrm{\Gamma }(\nu +\frac{1}{2})}(1-r^2{)}^{\frac{\nu -1}{2}}\cdot (1-{\rho }^2{)}^{\frac{\nu -2}{2}}\cdot (1-r\rho {)}^{\frac{1-2\nu }{2}}F(\frac{3}{2},-\frac{1}{2};\nu +\frac{1}{2};\frac{1+r\rho }{2})}$$ where ${\displaystyle F}$ is the Gaussian hypergeometric function and ${\displaystyle \nu =N-1>1}$ .

While the Fisher transformation is mainly associated with the Pearson product-moment correlation coefficient for bivariate normal observations, it can also be applied to Spearman's rank correlation coefficient in more general cases.^[13] A similar result for the asymptotic distribution applies, but with a minor adjustment factor: see the cited article for details.

• Data transformation (statistics)
• Meta-analysis (this transformation is used in meta analysis for stabilizing the variance)
• Partial correlation
• Pearson correlation coefficient § Inference

• R implementation

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