knitr::opts_chunk$set(message = FALSE, warning = FALSE)

@cliff+ord:69, published forty years ago, marked a turning point in the treatment of spatial autocorrelation in quantitative geography. It provided the framework needed by any applied researcher to attempt an implementation for a different system, possibly using a different programming language. In this spirit, here we examine how spatial weights have been represented in implementations and may be reproduced, how the tabulated results in the paper may be reproduced, and how they may be extended to cover simulation.

One of the major assertions of @cliff+ord:69 is that their statistic advances the measurement of spatial autocorrelation with respect to @moran:50 and @geary:54 because a more general specification of spatial weights could be used. This more general form has implications both for the preparation of the weights themselves, and for the calculation of the measures. We will look at spatial weights first, before moving on to consider the measures presented in the paper and some of their subsequent developments. Before doing this, we will put together a data set matching that used in @cliff+ord:69. They provide tabulated data for the counties of the Irish Republic, but omit Dublin from analyses. A shapefile included in this package, kindly made available by Michael Tiefelsdorf, is used as a starting point:

library(spdep) if (require(rgdal, quietly=TRUE)) { eire <- readOGR(system.file("shapes/eire.shp", package="spData")[1]) } else { require(maptools, quietly=TRUE) eire <- readShapeSpatial(system.file("shapes/eire.shp", package="spData")[1]) } row.names(eire) <- as.character(eire$names) proj4string(eire) <- CRS("+proj=utm +zone=30 +ellps=airy +units=km")

class(eire) names(eire)

and read into a SpatialPolygonsDataFrame — classes used for handling spatial data in are fully described in @bivandetal:08. To this we need to add the data tabulated in the paper in Table 2,[^1] p. 40, here in the form of a text file with added rainfall values from Table 9, p. 49:

fn <- system.file("etc/misc/geary_eire.txt", package="spdep")[1] ge <- read.table(fn, header=TRUE) names(ge)

Since we assigned the county names as feature identifiers when reading the shapefiles, we do the same with the extra data, and combine the objects:

row.names(ge) <- as.character(ge$county) all.equal(row.names(ge), row.names(eire)) library(maptools) eire_ge <- spCbind(eire, ge)

Finally, we need to drop the Dublin county omitted in the analyses conducted in @cliff+ord:69:

eire_ge1 <- eire_ge[!(row.names(eire_ge) %in% "Dublin"),] length(row.names(eire_ge1))

To double-check our data, let us calculate the sample Beta coefficients, using the formulae given in the paper for sample moments:

skewness <- function(z) {z <- scale(z, scale=FALSE); ((sum(z^3)/length(z))^2)/((sum(z^2)/length(z))^3)} kurtosis <- function(z) {z <- scale(z, scale=FALSE); (sum(z^4)/length(z))/((sum(z^2)/length(z))^2)}

These differ somewhat from the ways in which skewness and kurtosis are computed in modern statistical software, see for example @joanes+gill:98. However, for our purposes, they let us reproduce Table 3, p. 42:

print(sapply(as(eire_ge1, "data.frame")[13:24], skewness), digits=3) print(sapply(as(eire_ge1, "data.frame")[13:24], kurtosis), digits=4) print(sapply(as(eire_ge1, "data.frame")[c(13,16,18,19)], function(x) skewness(log(x))), digits=3) print(sapply(as(eire_ge1, "data.frame")[c(13,16,18,19)], function(x) kurtosis(log(x))), digits=4)

Using the tabulated value of $23.6$ for the percentage of agricultural
holdings above 50 in 1950 in Waterford, the skewness and kurtosis cannot
be reproduced, but by comparison with the [`irishdata`

]{} dataset in ,
it turns out that the value should rather be $26.6$, which yields the
tabulated skewness and kurtosis values.

Before going on, the variables considered are presented in Table [vars].

variable description

pagval2_10 Percentage number agricultural holdings in valuation group £2–£10 (1950) pagval10_50 Percentage number agricultural holdings in valuation group £10–£50 (1950) pagval50p Percentage number agricultural holdings in valuation group above £50 (1950) cowspacre Milch cows per 1000 acres crops and pasture (1952) ocattlepacre Other cattle per 1000 acres crops and pasture (1952) pigspacre Pigs per 1000 acres crops and pasture (1952) sheeppacre Sheep per 1000 acres crops and pasture (1952) townvillp Town and village population as percentage of total (1951) carspcap Private cars registered per 1000 population (1952) radiopcap Radio licences per 1000 population (1952) retailpcap Retail sales £ per person (1951) psinglem30_34 Single males as percentage of all males aged 30–34 (1951) rainfall Average of rainfall for stations in Ireland, 1916–1950, mm

: Description of variables in the Geary data set.[]{data-label="vars"}

As a basis for comparison, we will first read the unstandardised weighting matrix given in Table A1, p. 54, of the paper, reading a file corrected for the misprint giving O rather than D as a neighbour of V:

fn <- system.file("etc/misc/unstand_sn.txt", package="spdep")[1] unstand <- read.table(fn, header=TRUE) summary(unstand)

In the file, the counties are represented by their serial letters, so ordering and conversion to integer index representation is required to reach a representation similar to that of the SpatialStats module for spatial neighbours:

class(unstand) <- c("spatial.neighbour", class(unstand)) of <- ordered(unstand$from) attr(unstand, "region.id") <- levels(of) unstand$from <- as.integer(of) unstand$to <- as.integer(ordered(unstand$to)) attr(unstand, "n") <- length(unique(unstand$from))

Having done this, we can change its representation to a [`listw`

]{}
object, assigning an appropriate style (generalised binary) for
unstandardised values:

lw_unstand <- sn2listw(unstand) lw_unstand$style <- "B" lw_unstand

Note that the values of S0, S1, and S2 correspond closely with those given on page 42 of the paper, $0.84688672$, $0.01869986$ and $0.12267319$. The discrepancies appear to be due to rounding in the printed table of weights.

The contiguous neighbours represented in this object ought to match
those found using [`poly2nb`

]{}. However, we see that the reproduced
contiguities have a smaller link count:

nb <- poly2nb(eire_ge1) nb

The missing link is between Clare and Kerry, perhaps by the Tarbert–Killimer ferry, but the counties are not contiguous, as Figure [plot_nb] shows:

xx <- diffnb(nb, lw_unstand$neighbours, verbose=TRUE)

plot(eire_ge1, border="grey60") plot(nb, coordinates(eire_ge1), add=TRUE, pch=".", lwd=2) plot(xx, coordinates(eire_ge1), add=TRUE, pch=".", lwd=2, col=3)

par(mfrow=c(1,2)) plot(eire_ge1, border="grey40") title(xlab="25 Irish counties") text(coordinates(eire_ge1), labels=as.character(eire_ge1$serlet), cex=0.8) plot(eire_ge1, border="grey60") title(xlab="Contiguities") plot(nb, coordinates(eire_ge1), add=TRUE, pch=".", lwd=2) plot(xx, coordinates(eire_ge1), add=TRUE, pch=".", lwd=2, col=3) legend("topleft", legend=c("Contiguous", "Ferry"), lwd=2, lty=1, col=c(1,3), bty="n", cex=0.7) par(mfrow=c(1,1))

An attempt has also been made to reproduce the generalised weights for
25 Irish counties reported by @cliff+ord:69, after Dublin is omitted.
Reproducing the inverse distance component $d_{ij}^{-1}$ of the
generalised weights $d_{ij}^{-1} \beta_{i(j)}$ is eased by the statement
in @cliff+ord:73 [p. 55] that the points chosen to represent the
counties were their “geographic centres,” so not very different from the
centroids yielded by applying a chosen computational geometry function.
The distance metric is not given, and may have been in kilometers or
miles — both were tried, but the results were not sensitive to the
difference as it applies equally across the weights; miles are used
here. Computing the proportion of shared distance measure $\beta_{i(j)}$
is harder, because it requires the availability of the full topology of
the input polygons. @bivandetal:08 [p. 244] show how to employ the
[`vect2neigh`

]{} function (written by Markus Neteler) in the package
when using GRASS GIS vector handling to create a full topology from
spaghetti vector data and to extract border segment lengths; a similar
approach also is mentioned there using ArcGIS coverages for the same
purpose. GRASS was used to create the topology, and next the proportion
of shared distance measure was calculated.

load(system.file("etc/misc/raw_grass_borders.RData", package="spdep")[1])

library(maptools) SG <- Sobj_SpatialGrid(eire_ge1)$SG library(spgrass6) grass_home <- "/home/rsb/topics/grass/g64/grass-6.4.0svn" initGRASS(grass_home, home=tempdir(), SG=SG, override=TRUE) writeVECT6(eire_ge1, "eire", v.in.ogr_flags=c("o", "overwrite")) res <- vect2neigh("eire", ID="serlet")

grass_borders <- sn2listw(res) raw_borders <- grass_borders$weights int_tot <- attr(res, "total") - attr(res, "external") prop_borders <- lapply(1:length(int_tot), function(i) raw_borders[[i]]/int_tot[i]) dlist <- nbdists(grass_borders$neighbours, coordinates(eire_ge1)) inv_dlist <- lapply(dlist, function(x) 1/(x/1.609344)) combo_km <- lapply(1:length(inv_dlist), function(i) inv_dlist[[i]]*prop_borders[[i]]) combo_km_lw <- nb2listw(grass_borders$neighbours, glist=combo_km, style="B") summary(combo_km_lw)

To compare, we need to remove the Tarbert–Killimer ferry link manually, and view the summary of the original weights, as well as a correlation coefficient between these and the reconstructed weights. Naturally, unless the boundary coordinates used here are identical with those in the original analysis, presumably measured by hand, small differences will occur.

red_lw_unstand <- lw_unstand Clare <- which(attr(lw_unstand, "region.id") == "C") Kerry <- which(attr(lw_unstand, "region.id") == "H") Kerry_in_Clare <- which(lw_unstand$neighbours[[Clare]] == Kerry) Clare_in_Kerry <- which(lw_unstand$neighbours[[Kerry]] == Clare) red_lw_unstand$neighbours[[Clare]] <- red_lw_unstand$neighbours[[Clare]][-Kerry_in_Clare] red_lw_unstand$neighbours[[Kerry]] <- red_lw_unstand$neighbours[[Kerry]][-Clare_in_Kerry] red_lw_unstand$weights[[Clare]] <- red_lw_unstand$weights[[Clare]][-Kerry_in_Clare] red_lw_unstand$weights[[Kerry]] <- red_lw_unstand$weights[[Kerry]][-Clare_in_Kerry] summary(red_lw_unstand) cor(unlist(red_lw_unstand$weights), unlist(combo_km_lw$weights))

Even though the differences in the general weights, for identical contiguities, are so small, the consequences for the measure of spatial autocorrelation are substantial, Here we use the fifth variable, other cattle per 1000 acres crops and pasture (1952), and see that the reconstructed weights seem to “reveal” more autocorrelation than the original weights.

flatten <- function(x, digits=3, statistic="I") { res <- c(format(x$estimate, digits=digits), format(x$statistic, digits=digits), format.pval(x$p.value, digits=digits)) res <- matrix(res, ncol=length(res)) colnames(res) <- paste(c("", "E", "V", "SD_", "P_"), "I", sep="") rownames(res) <- deparse(substitute(x)) res } `reconstructed weights` <- moran.test(eire_ge1$ocattlepacre, combo_km_lw) `original weights` <- moran.test(eire_ge1$ocattlepacre, red_lw_unstand) print(rbind(flatten(`reconstructed weights`), flatten(`original weights`)), quote=FALSE)

Our targets for reproduction are Tables 4 and 5 in @cliff+ord:69 [pp. 43–44], the first containing standard deviates under normality and randomisation for the original Moran measure with binary weights, the original Geary measure with binary weights, the proposed measure with unstandardised general weights, and the proposed measure with row-standardised general weights. In addition, four variables were log-transformed on the basis of the skewness and kurtosis results presented above. We carry out the transformation of these variables, and generate additional binary and row-standardised general spatial weights objects — note that the weights constants for the row-standardised general weights agree with those given on p. 42 in the paper, after allowing for small differences due to rounding in the weights values displayed in the paper (p. 54):

eire_ge1$ln_pagval2_10 <- log(eire_ge1$pagval2_10) eire_ge1$ln_cowspacre <- log(eire_ge1$cowspacre) eire_ge1$ln_pigspacre <- log(eire_ge1$pigspacre) eire_ge1$ln_sheeppacre <- log(eire_ge1$sheeppacre) vars <- c("pagval2_10", "ln_pagval2_10", "pagval10_50", "pagval50p", "cowspacre", "ln_cowspacre", "ocattlepacre", "pigspacre", "ln_pigspacre", "sheeppacre", "ln_sheeppacre", "townvillp", "carspcap", "radiopcap", "retailpcap", "psinglem30_34") nb_B <- nb2listw(lw_unstand$neighbours, style="B") nb_B lw_std <- nb2listw(lw_unstand$neighbours, glist=lw_unstand$weights, style="W") lw_std

The standard representation of the measures is:

$$I = \frac{n}{\sum_{i=1}^{n}\sum_{j=1}^{n}w_{ij}} \frac{\sum_{i=1}^{n}\sum_{j=1}^{n}w_{ij}(x_i-\bar{x})(x_j-\bar{x})}{\sum_{i=1}^{n}(x_i - \bar{x})^2}$$

for Moran’s $I$ — in the paper termed the proposed statistic, and for Geary’s $C$:

$$C = \frac{(n-1)}{2\sum_{i=1}^{n}\sum_{j=1}^{n}w_{ij}} \frac{\sum_{i=1}^{n}\sum_{j=1}^{n}w_{ij}(x_i-x_j)^2}{\sum_{i=1}^{n}(x_i - \bar{x})^2}$$

where $x_i, i=1, \ldots, n$ are $n$ observations on the numeric variable
of interest, and $w_{ij}$ are the spatial weights. In order to reproduce
the standard deviates given in the paper, it is sufficient to apply
[`moran.test`

]{} to the variables with three different spatial weights
objects, and two different values of the [`randomisation=`

]{} argument.
In addition, [`geary.test`

]{} is applied to a single spatial weights
objects, and two different values of the [`randomisation=`

]{} argument.

system.time({ MoranN <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=nb_B, randomisation=FALSE)) MoranR <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=nb_B, randomisation=TRUE)) GearyN <- lapply(vars, function(x) geary.test(eire_ge1[[x]], listw=nb_B, randomisation=FALSE)) GearyR <- lapply(vars, function(x) geary.test(eire_ge1[[x]], listw=nb_B, randomisation=TRUE)) Prop_unstdN <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=lw_unstand, randomisation=FALSE)) Prop_unstdR <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=lw_unstand, randomisation=TRUE)) Prop_stdN <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=lw_std, randomisation=FALSE)) Prop_stdR <- lapply(vars, function(x) moran.test(eire_ge1[[x]], listw=lw_std, randomisation=TRUE)) }) res <- sapply(c("MoranN", "MoranR", "GearyN", "GearyR", "Prop_unstdN", "Prop_unstdR", "Prop_stdN", "Prop_stdR"), function(x) sapply(get(x), "[[", "statistic")) rownames(res) <- vars ores <- res[,c(1,2,5:8)]

In order to conduct 8 different tests on 16 variables, we use
[`lapply`

]{} on the list of variables in the specified order, then
[`sapply`

]{} on a list of output objects by name to generate a table in
the same row and column order as the original (we save a copy of six
columns for comparison with bootstrap results below):

options("width"=100)

print(formatC(res, format="f", digits=4), quote=FALSE)

options("width"=90)

The values of the standard deviates agree with those in Table 4 in the original paper, with the exception of those for the proposed statistic with standardised weights under normality for all untransformed variables. We can see what has happened by substituting the weights constants for the standardised weights with those for unstandardised weights:

wc_unstd <- spweights.constants(lw_unstand) wrong_N_sqVI <- sqrt((wc_unstd$nn*wc_unstd$S1 - wc_unstd$n*wc_unstd$S2 + 3*wc_unstd$S0*wc_unstd$S0)/((wc_unstd$nn-1)*wc_unstd$S0*wc_unstd$S0)-((-1/(wc_unstd$n-1))^2)) raw_data <- grep("^ln_", vars, invert=TRUE) I <- sapply(Prop_stdN, function(x) x$estimate[1])[raw_data] EI <- sapply(Prop_stdN, function(x) x$estimate[2])[raw_data] res <- (I - EI)/wrong_N_sqVI names(res) <- vars[raw_data] print(formatC(res, format="f", digits=4), quote=FALSE)

Next, let us look at Table 5 in the original paper. Here we only tabulate the values of the measures themselves, and, since the expectation is constant for each measure, the square root of the variance of the measure under randomisation — extracting values calculated above:

res <- lapply(c("MoranR", "GearyR", "Prop_unstdR", "Prop_stdR"), function(x) sapply(get(x), function(y) c(y$estimate[1], sqrt(y$estimate[3])))) res <- t(do.call("rbind", res)) colnames(res) <- c("I", "sigma_I", "C", "sigma_C", "unstd_r", "sigma_r", "std_r", "sigma_r") rownames(res) <- vars print(formatC(res, format="f", digits=4), quote=FALSE)

The values are as follows, and match the original with the exception of those for the initial version of Moran’s $I$ in the first two columns. If we write a function implementing equations 3 and 4:

$$I = \frac{\sum_{i=1}^{n}\sum_{j=i+1}^{n}w_{ij}(x_i-\bar{x})(x_j-\bar{x})}{\sum_{i=1}^{n}(x_i - \bar{x})^2}$$

where crucially the inner summation is over $i+1 \ldots n$, not $1 \ldots n$, we can reproduce the values of the measure shown in the original Table 5:

oMoranf <- function(x, nb) { z <- scale(x, scale=FALSE) n <- length(z) glist <- lapply(1:n, function(i) {ii <- nb[[i]]; ifelse(ii > i, 1, 0)}) lw <- nb2listw(nb, glist=glist, style="B") wz <- lag(lw, z) I <- (sum(z*wz)/sum(z*z)) I } res <- sapply(vars, function(x) oMoranf(eire_ge1[[x]], nb=lw_unstand$neighbours)) print(formatC(res, format="f", digits=4), quote=FALSE)

The variance term given in equation 7 in the original paper is for the case of normality, not randomisation; the reference on p. 28 to equation 38 on p. 26 does not permit the reproduction of the values in the second column of Table 5. The variance equation given as equation 1.35 by @cliff+ord:73 [p. 9] does not do so either, so for the time being it is not possible to say how the tabulated values were computed. Note that since the standard deviances are reproduced correctly, and can be reproduced from the second column values using the measure and its expectance, it is just a matter of establishing which formula was used, but this has so far not proved possible.

@cliff+ord:69 do not conduct simulation experiments, although their sequels do, notably @cliff+ord:73, among many others. Simulation studies are necessarily more demanding computationally, especially if spatially autocorrelated variables are to be created, as in @cliff+ord:73 [pp. 146–153]. In the same book, they also report the use of permutation tests, also known as Monte Carlo or Hope hypothesis testing procedures [@cliff+ord:73 pp. 50–52]. These procedures provided a way to examine the distribution of the statistic of interest by exchanging at random the observed values between observations, and then comparing the simulated distribution under the null hypothesis of no spatial patterning with the observed value of the statistic in question.

MoranI.boot <- function(var, i, ...) { var <- var[i] return(moran(x=var, ...)$I) } Nsim <- function(d, mle) { n <- length(d) rnorm(n, mle$mean, mle$sd) } f_bperm <- function(x, nsim, listw) { boot(x, statistic=MoranI.boot, R=nsim, sim="permutation", listw=listw, n=length(x), S0=Szero(listw)) } f_bpara <- function(x, nsim, listw) { boot(x, statistic=MoranI.boot, R=nsim, sim="parametric", ran.gen=Nsim, mle=list(mean=mean(x), sd=sd(x)), listw=listw, n=length(x), S0=Szero(listw)) } nsim <- 4999 set.seed(1234)

First let us define a function [`MoranI.boot`

]{} just to return the
value of Moran’s $I$ for variable [`var`

]{} and permutation index
[`i`

]{}, and a function [`Nsim`

]{} to generate random samples from the
variable of interest assuming Normality. To make it easier to process
the variables in turn, we encapsulate calls to [`boot`

]{} in wrapper
functions [`f_bperm`

]{} and [`f_bpara`

]{}. Running 4999 simulations for
each of 16 for three different weights specifications and both
parametric and permutation bootstrap takes quite a lot of time.

system.time({ MoranNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=nb_B)) MoranRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=nb_B)) Prop_unstdNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=lw_unstand)) Prop_unstdRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=lw_unstand)) Prop_stdNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=lw_std)) Prop_stdRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=lw_std)) })

zzz <- system.time({ MoranNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=nb_B)) MoranRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=nb_B)) Prop_unstdNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=lw_unstand)) Prop_unstdRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=lw_unstand)) Prop_stdNb <- lapply(vars, function(x) f_bpara(x=eire_ge1[[x]], nsim=nsim, listw=lw_std)) Prop_stdRb <- lapply(vars, function(x) f_bperm(x=eire_ge1[[x]], nsim=nsim, listw=lw_std)) }) res <- lapply(c("MoranNb", "MoranRb", "Prop_unstdNb", "Prop_unstdRb", "Prop_stdNb", "Prop_stdRb"), function(x) sapply(get(x), function(y) (y$t0 - mean(y$t))/sd(y$t))) res <- t(do.call("rbind", res)) colnames(res) <- c("MoranNb", "MoranRb", "Prop_unstdNb", "Prop_unstdRb", "Prop_stdNb", "Prop_stdRb") rownames(res) <- vars save(zzz, res, file="backstore/boot_res.RData")

bsfn <- system.file("etc/backstore/boot_res.RData", package="spdep") load(bsfn) zzz

res <- lapply(c("MoranNb", "MoranRb", "Prop_unstdNb", "Prop_unstdRb", "Prop_stdNb", "Prop_stdRb"), function(x) sapply(get(x), function(y) (y$t0 - mean(y$t))/sd(y$t))) res <- t(do.call("rbind", res)) colnames(res) <- c("MoranNb", "MoranRb", "Prop_unstdNb", "Prop_unstdRb", "Prop_stdNb", "Prop_stdRb") rownames(res) <- vars

We collate the results to compare with the analytical standard deviates under Normality and randomisation, and see that in fact the differences are not at all large, as expressed by the median absolute difference between the tables. We can also see that inferences based on a one-sided $\alpha=0.05$ cut-off are the same for the analytical and bootstrap approaches. This indicates that we can, in general, rely on the analytical standard deviates, and that bootstrap methods will not help if assumptions underlying the measures are not met.

print(formatC(res, format="f", digits=4), quote=FALSE) oores <- ores - res apply(oores, 2, mad) alpha_0.05 <- qnorm(0.05, lower.tail=FALSE) all((res >= alpha_0.05) == (ores >= alpha_0.05))

These assumptions affect the shape of the distribution of the measure in
its tails; one possibility is to use a Saddlepoint approximation to find
an equivalent to the analytical or bootstrap-based standard deviate for
inference [@tiefelsdorf:02]. The Saddlepoint approximation requires the
eigenvalues of the weights matrix and iterative root-finding for global
Moran’s $I$, while for local Moran’s $I_i$, analytical forms are known.
Even with this computational burden, the Saddlepoint approximation for
global Moran’s $I$ runs quite quickly. First we need to fit null linear
models (only including an intercept) to the variables, then apply
[`lm.morantest.sad`

]{} to the fitted model objects:

lm_objs <- lapply(vars, function(x) lm(formula(paste(x, "~1")), data=eire_ge1)) system.time({ MoranSad <- lapply(lm_objs, function(x) lm.morantest.sad(x, listw=nb_B)) Prop_unstdSad <- lapply(lm_objs, function(x) lm.morantest.sad(x, listw=lw_unstand)) Prop_stdSad <- lapply(lm_objs, function(x) lm.morantest.sad(x, listw=lw_std)) }) res <- sapply(c("MoranSad", "Prop_unstdSad", "Prop_stdSad"), function(x) sapply(get(x), "[[", "statistic")) rownames(res) <- vars

Although the analytical standard deviates (under Normality) are larger than those reached using the Saddlepoint approximation when measured by median absolute deviation, the differences do not lead to different inferences at this chosen cut-off. This reflects the fact that the shape of the distribution is very sensitive to small $n$, but for moderate $n$ and global Moran’s $I$, the effects are seen only further out in the tails. The consequences for local Moran’s $I_i$ are much stronger, because the clique of neighbours of each observation is typically very small. It is perhaps of interest that the differences are much smaller for the case of general weights than for unstandardised binary weights.

print(formatC(res, format="f", digits=4), quote=FALSE) oores <- res - ores[,c(1,3,5)] apply(oores, 2, mad) all((res >= alpha_0.05) == (ores[,c(1,3,5)] >= alpha_0.05))

In addition we could choose to use the exact distribution of Moran’s $I$, as described by @tiefelsdorf:00; its implementation is covered in @bivandetal:09. The global case also needs the eigenvalues of the weights matrix, and the solution of a numerical integration function, but for these cases, the timings are quite acceptable.

system.time({ MoranEx <- lapply(lm_objs, function(x) lm.morantest.exact(x, listw=nb_B)) Prop_unstdEx <- lapply(lm_objs, function(x) lm.morantest.exact(x, listw=lw_unstand)) Prop_stdEx <- lapply(lm_objs, function(x) lm.morantest.exact(x, listw=lw_std)) }) res <- sapply(c("MoranEx", "Prop_unstdEx", "Prop_stdEx"), function(x) sapply(get(x), "[[", "statistic")) rownames(res) <- vars

The output is comparable with that of the Saddlepoint approximation, and the inferences drawn here are the same for the chosen cut-off as for the analytical standard deviates calculated under Normality.

print(formatC(res, format="f", digits=4), quote=FALSE) oores <- res - ores[,c(1,3,5)] apply(oores, 2, mad) all((res >= alpha_0.05) == (ores[,c(1,3,5)] >= alpha_0.05))

@lietal:07 take up the challenge in @cliff+ord:69 [p. 31], to try to give the statistic a bounded fixed range. Their APLE measure is intended to approximate the spatial dependence parameter of a simultaneous autoregressive model better than Moran’s $I$, and re-scales the measure by a function of the eigenvalues of the spatial weights matrix. APLE requires the use of row standardised weights.

vars_scaled <- lapply(vars, function(x) scale(eire_ge1[[x]], scale=FALSE)) nb_W <- nb2listw(lw_unstand$neighbours, style="W") pre <- spdep:::preAple(0, listw=nb_W) MoranAPLE <- sapply(vars_scaled, function(x) spdep:::inAple(x, pre)) pre <- spdep:::preAple(0, listw=lw_std, override_similarity_check=TRUE) Prop_stdAPLE <- sapply(vars_scaled, function(x) spdep:::inAple(x, pre)) res <- cbind(MoranAPLE, Prop_stdAPLE) colnames(res) <- c("APLE W", "APLE Gstd") rownames(res) <- vars

In order to save time, we use the two internal functions
[`spdep:::preAple`

]{} and [`spdep:::inAple`

]{}, since for each
definition of spatial weights, the same eigenvalue calculations need to
be made. The notation using the [`:::`

]{} operator says that the
function with named after the operator is to be found in the namespace
of the package named before the operator. The APLE values repeat the
pattern that we have already seen — for some variables, the measured
autocorrelation is very similar irrespective of spatial weights
definition, while for others, the change in the definition from binary
to general does make a difference.

print(formatC(res, format="f", digits=4), quote=FALSE)

pal <- grey.colors(9, 1, 0.5, 2.2) oopar <- par(mfrow=c(1,3), mar=c(1,1,3,1)+0.1) z <- t(listw2mat(nb_B)) brks <- c(0,0.1,1) image(1:25, 1:25, z[,ncol(z):1], breaks=brks, col=pal[c(1,9)], main="Binary", axes=FALSE) box() z <- t(listw2mat(lw_unstand)) brks <- c(0,quantile(c(z)[c(z) > 0], seq(0,1,1/8))) image(1:25, 1:25, z[,ncol(z):1], breaks=brks, col=pal, main="General", axes=FALSE) box() z <- t(listw2mat(lw_std)) brks <- c(0,quantile(c(z)[c(z) > 0], seq(0,1,1/8))) image(1:25, 1:25, z[,ncol(z):1], breaks=brks, col=pal, main="Std. general", axes=FALSE) box() par(oopar)

\caption{Three contrasted spatial weights definitions.} \label{plot_wts}

eire_ge1$nb_B <- sapply(nb_B$weights, sum) eire_ge1$lw_unstand <- sapply(lw_unstand$weights, sum) library(lattice) trellis.par.set(sp.theme()) p1 <- spplot(eire_ge1, c("nb_B"), main="Binary") p2 <- spplot(eire_ge1, c("lw_unstand"), main="General") print(p1, split=c(1,1,2,1), more=TRUE) print(p2, split=c(2,1,2,1), more=FALSE)

\caption{Sums of weights by county for two contrasted spatial weights definitions --- for row standardisation, all counties sum to unity.} \label{plot_map}

The differences found in the case of a few variables in inference using the original binary weights, and the general weights proposed by @cliff+ord:69 are necessarily related to the the weights thenselves. Figures [plot_wts] and [plot_map] show the values of the weights in sparse matrix form, and the sums of weights by county where these sums are not identical by design. In the case of binary weights, the matrix entries are equal, but the sums up-weight counties with many neighbours.

General weights up-weight counties that are close to each other, have more neighbours, and share larger boundary proportions (an asymmetric relationship). There is a further impact of using boundary proportions, in that the boundary between the county and the exterior is subtracted, thus boosting the weights between edge counties and their neighbours, even if there are few of them. Standardised general weights up-weight further up-weight counties with few neighbours, chiefly those on the edges of the study area.

With a small data set, here with $n=25$, it is very possible that edge and other configuration effects are relatively strong, and may impact inference in different ways. The issue of egde effects has not really been satisfactorily resolved, and should be kept in mind in analyses of data sets of this size and shape.

[^1]: cropped scans of tables are available from https://github.com/rsbivand/CO69.

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