Greenwood statistic

The Greenwood statistic is a spacing statistic and can be used to evaluate clustering of events in time or locations in space.^[1]

Definition[edit]

In general, for a given sequence of events in time or space the statistic is given by:.^[1]

G(n)=\sum _{i=1}^{n+1}D_{i}^{2},

where $D_{i}$ represents the interval between events or points in space and is a number between 0 and 1 such that the sum of all $D_{i}=1$ .

Where intervals are given by numbers that do not represent a fraction of the time period or distance, the Greenwood statistic is modified ^[2] and is given by:

G(n)={\frac {\sum _{i=1}^{n+1}X_{i}^{2}}{T_{n}^{2}}},

where:

T_{n}=\sum _{i=1}^{n+1}X_{i},

and $X_{i}$ represents the length of the 'ith interval, which is either the time between events or the distances between points in space.

A reformulation of the statistic yields

G(n)={\tfrac {1}{n+1}}({\tfrac {n}{n+1}}C_{v}^{2}+1),

where $C_{v}$ is the sample coefficient of variation of the n + 1 interval lengths.

Properties[edit]

The Greenwood statistic is a comparative measure that has a range of values between 0 and 1. For example, applying the Greenwood statistic to the arrival of 11 buses in a given time period of say 1 hour, where in the first example all eleven buses arrived at a given point each 6 minutes apart, would give a result of roughly 0.10. However, in the second example if the buses became bunched up or clustered so that 6 buses arrived 10 minutes apart and then 5 buses arrived 2 minutes apart in the last 10 minutes, the result is roughly 0.17. The result for a random distribution of 11 bus arrival times in an hour will fall somewhere between 0.10 and 0.17. So this can be used to tell how well a bus system is running and in a similar way, the Greenwood statistic was also used to determine how and where genes are placed in the chromosomes of living organisms.^[3] This research showed that there is a definite order to where genes are placed, particularly with regard to what function the genes perform, and this is important in the science of genetics.

References[edit]

^ ^a ^b Greenwood, Major (1946) The Statistical Study of Infectious Diseases. Journal of the Royal Statistical Society, 109(2): 85–110. JSTOR 2981176
^ D'Agostino, Ralph B. and Stephens, Michael A. (1986) Goodness-of-fit techniques, Marcel Dekker, Inc., New York
^ Riley, M. C. et al. (2007) Locational distribution of gene functional classes in Arabidopsis thaliana, BMC Bioinformatics. 8:112

[MG1-1] Greenwood, Major (1946) The Statistical Study of Infectious Diseases. Journal of the Royal Statistical Society, 109(2): 85–110. JSTOR 2981176

[2] D'Agostino, Ralph B. and Stephens, Michael A. (1986) Goodness-of-fit techniques, Marcel Dekker, Inc., New York

[3] Riley, M. C. et al. (2007) Locational distribution of gene functional classes in Arabidopsis thaliana, BMC Bioinformatics. 8:112

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