powered by
Calculate Moran's I as linear regression using ordinary least squares (OLS).
OLSMoransI( X, W, normalize = TRUE, alternative = c("two.sided", "less", "greater"), p.adjust.method = "BH" )
A matrix with observations as rows and features as columns.
A weight matrix across all observations, i.e inverse of a pairwise distance matrix.
Whether to normalize the weight matrix such that each row adds up to one. Default is TRUE.
TRUE
Alternative hypothesis used, default is two.sided.
two.sided
Method used for multiple comparisons correction, default is BH. See p.adjust.
BH
p.adjust
A list containing the following:
Morans.I, the Moran's I.
Z.I, the Z score of Moran's I.
X, data matrix used for calculating Moran's I.
Y, a matrix of spatial lags.
Expected.I, the expectation of Moran's I under the null hypothesis.
SD.I, the standard deviation of Moran's I under the null hypothesis.
p.val, p-values.
p.adj, adjusted p-values.
alternative, alternative hypothesis used.
p.adjust.method, method used for multiple comparisons correction.
Anselin, L. Local indicators of spatial association-LISA. Geogr. Anal. 27, 93<U+2013>115 (2010)
# NOT RUN { { data.use <- quakes[1:100,] W <- 1/as.matrix(dist(data.use[,1:2])) diag(W) <- 0 res <- OLSMoransI(data.use[,3:4], W) } # }
Run the code above in your browser using DataLab