Kendall tau rank correlation coefficient

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In statistics, the Kendall rank correlation coefficient, commonly referred to as Kendall's tau (τ) coefficient, is a statistic used to measure the association between two measured quantities. A tau test is a non-parametric hypothesis test which uses the coefficient to test for statistical dependence.

Specifically, it is a measure of rank correlation: that is, the similarity of the orderings of the data when ranked by each of the quantities. It is named after Maurice Kendall, who developed it in 1938,^[1] though Gustav Fechner had proposed a similar measure in the context of time series in 1897.^[2]

Definition[]

Let (x₁, y₁), (x₂, y₂), …, (x_n, y_n) be a set of joint observations from two random variables X and Y respectively, such that all the values of (x_i) and (y_i) are unique. Any pair of observations (x_i, y_i) and (x_j, y_j) are said to be concordant if the ranks for both elements agree: that is, if both x_i > x_j and y_i > y_j or if both x_i < x_j and y_i < y_j. They are said to be discordant, if x_i > x_j and y_i < y_j or if x_i < x_j and y_i > y_j. If x_i = x_j or y_i = y_j, the pair is neither concordant nor discordant.

The Kendall τ coefficient is defined as:

${\displaystyle \tau = \frac{(\text{number of concordant pairs}) - (\text{number of discordant pairs})}{\frac{1}{2} n (n-1) } .}$^[3]

Properties[]

The denominator is the total number of pairs, so the coefficient must be in the range −1 ≤ τ ≤ 1.

• If the agreement between the two rankings is perfect (i.e., the two rankings are the same) the coefficient has value 1.
• If the disagreement between the two rankings is perfect (i.e., one ranking is the reverse of the other) the coefficient has value −1.
• If X and Y are independent, then we would expect the coefficient to be approximately zero.

Hypothesis test[]

The Kendall rank coefficient is often used as a test statistic in a statistical hypothesis test to establish whether two variables may be regarded as statistically dependent. This test is non-parametric, as it does not rely on any assumptions on the distributions of X or Y.

Under a null hypothesis of X and Y being independent, the sampling distribution of τ will have an expected value of zero. The precise distribution cannot be characterized in terms of common distributions, but may be calculated exactly for small samples; for larger samples, it is common to use an approximation to the normal distribution, with mean zero and variance

${\displaystyle \frac{2(2n+5)}{9n (n-1)}}$.^[4]

Accounting for ties[]

A pair {(x_i, y_i), (x_j, y_j)} is said to be tied if x_i = x_j or y_i = y_j; a tied pair is neither concordant nor discordant. When tied pairs arise in the data, the coefficient may be modified in a number of ways to keep it in the range [-1, 1]:

Tau-a[]

Tau-a statistic tests the strength of association of the cross tabulations. Both variables have to be ordinal. Tau-a will not make any adjustment for ties.

Tau-b[]

Tau-b statistic, unlike tau-a, makes adjustments for ties and is suitable for square tables. Values of tau-b range from −1 (100% negative association, or perfect inversion) to +1 (100% positive association, or perfect agreement). A value of zero indicates the absence of association.

The Kendall tau-b coefficient is defined as:

${\displaystyle \tau_B = \frac{n_c-n_d}{\sqrt{(n_0-n_1)(n_0-n_2)}}}$

where

${\displaystyle \begin{array}{ccl} n_0 & = & n(n-1)/2\\ n_1 & = & \sum_i t_i (t_i-1)/2 \\ n_2 & = & \sum_j u_j (u_j-1)/2 \\ t_i & = & \mbox{Number of tied values in the } i^{th} \mbox{ group of ties for the first quantity} \\ u_j & = & \mbox{Number of tied values in the } j^{th} \mbox{ group of ties for the second quantity} \end{array} }$

Tau-c[]

Tau-c differs from tau-b as in being more suitable for rectangular tables than for square tables.

Significance tests[]

When two quantities are statistically independent, the distribution of ${\displaystyle \tau}$ is not easily characterizable in terms of known distributions. However, for ${\displaystyle \tau_A}$ the following statistic, ${\displaystyle z_A}$, is approximately characterized by a standard normal distribution when the quantities are statistically independent:

${\displaystyle z_A = {3 (n_c - n_d) \over \sqrt{n(n-1)(2n+5)/2} }}$

Thus, if you want to test whether two quantities are statistically dependent, compute ${\displaystyle z_A}$, and find the cumulative probability for a standard normal distribution at ${\displaystyle -|z_A|}$. For a 2-tailed test, multiply that number by two and this gives you the p-value. If the p-value is below your acceptance level (typically 5%), you can reject the null hypothesis that the quantities are statistically independent and accept the hypothesis that they are dependent.

Numerous adjustments should be added to ${\displaystyle z_A}$ when accounting for ties. The following statistic, ${\displaystyle z_B}$, provides an approximation coinciding with the ${\displaystyle \tau_B}$ distribution and is again approximately characterized by a standard normal distribution when the quantities are statistically independent:

${\displaystyle z_B = {n_c - n_d \over \sqrt{ v } }}$

where

${\displaystyle \begin{array}{ccl} v & = & (v_0 - v_t - v_u)/18 + v_1 + v_2 \\ v_0 & = & n (n-1) (2n+5) \\ v_t & = & \sum_i t_i (t_i-1) (2 t_i+5)\\ v_u & = & \sum_j u_j (u_j-1)(2 u_j+5) \\ v_1 & = & \sum_i t_i (t_i-1) \sum_j u_j (u_j-1) / (2n(n-1)) \\ v_2 & = & \sum_i t_i (t_i-1) (t_i-2) \sum_j u_j (u_j-1) (u_j-2) / (9 n (n-1) (n-2)) \end{array} }$

Algorithms[]

The direct computation of the numerator ${\displaystyle n_c - n_d}$, involves two nested iterations, as characterized by the following pseudo-code:

numer := 0
for i:=1..N do
    for j:=1..(i-1) do
        numer := numer + sgn(x[i] - x[j]) * sgn(y[i] - y[j])
return numer

Although quick to implement, this algorithm is ${\displaystyle O(n^2)}$ in complexity and becomes very slow on large samples. A more sophisticated algorithm^[5] built upon the Merge Sort algorithm can be used to compute the numerator in ${\displaystyle O(n \cdot \log{n})}$ time.

Begin by ordering your data points sorting by the first quantity, ${\displaystyle x}$, and secondarily (among ties in ${\displaystyle x}$) by the second quantity, ${\displaystyle y}$. With this initial ordering, ${\displaystyle y}$ is not sorted, and the core of the algorithm consists of computing how many steps a Bubble Sort would take to sort this initial ${\displaystyle y}$. An enhanced Merge Sort algorithm, with ${\displaystyle O(n \log n)}$ complexity, can be applied to compute the number of swaps, ${\displaystyle S(y)}$, that would be required by a Bubble Sort to sort ${\displaystyle y_i}$. Then the numerator for ${\displaystyle \tau}$ is computed as:

${\displaystyle n_c-n_d = n_0 - n_1 - n_2 + n_3 - 2 S(y)}$,

where ${\displaystyle n_3}$ is computed like ${\displaystyle n_1}$ and ${\displaystyle n_2}$, but with respect to the joint ties in ${\displaystyle x}$ and ${\displaystyle y}$.

A Merge Sort partitions the data to be sorted, ${\displaystyle y}$ into two roughly equal halves, ${\displaystyle y_{left}}$ and ${\displaystyle y_{right}}$, then sorts each half recursive, and then merges the two sorted halves into a fully sorted vector. The number of Bubble Sort swaps is equal to:

${\displaystyle S(y) = S(y_{left}) + S(y_{right}) + M(Y_{left},Y_{right})}$

where ${\displaystyle Y_{left}}$ and ${\displaystyle Y_{right}}$ are the sorted versions of ${\displaystyle y_{left}}$ and ${\displaystyle y_{right}}$, and ${\displaystyle M(\cdot,\cdot)}$ characterizes the Bubble Sort swap-equivalent for a merge operation. ${\displaystyle M(\cdot,\cdot)}$ is computed as depicted in the following pseudo-code:

function M(L[1..n], R[1..m])
    n := n + m
    i := 1
    j := 1
    nSwaps := 0
    while i + j <= n do
        if i > m or R[j] < L[i] then
            nSwaps := nSwaps + m - (i-1)
            j := j + 1
        else
            i := i + 1
    return nSwaps

A side effect of the above steps is that you end up with both a sorted version of ${\displaystyle x}$ and a sorted version of ${\displaystyle y}$. With these, the factors ${\displaystyle t_i}$ and ${\displaystyle u_j}$ used to compute ${\displaystyle \tau_B}$ are easily obtained in a single linear-time pass through the sorted arrays.

A second algorithm with ${\displaystyle O(n \cdot \log{n})}$ time complexity, based on AVL trees, was devised by David Christensen.^[6]

See also[]

• Correlation
• Gamma test (statistics)
• Kendall tau distance
• Kendall's W
• Rank correlation
• Spearman's rank correlation coefficient
• Theil–Sen estimator

References[]

• Abdi, H. (2007). Encyclopedia of Measurement and Statistics, Thousand Oaks (CA): Sage.
• Kendall, M. (1948) Rank Correlation Methods, Charles Griffin & Company Limited

External links[]

• Tied rank calculation
• Why Kendall tau?
• Software for computing Kendall's tau on very large datasets
• Online software: computes Kendall's tau rank correlation
• The CORR Procedure: Statistical Computations

[[[Category:Nonparametric statistical tests]]