# How to use an adjacency matrix to determine which rows to 'pass' to a function in r?

New to R, and I have a long-ish question:

I have a shapefile/map, and I'm aiming to calculate a certain index for every polygon in that map, based on attributes of that polygon and each polygon that neighbors it.

I have an adjacency matrix -- which I think is the same as a "1st-order queen contiguity weights matrix", although I'm not sure -- that describes which polygons border which other polygons, e.g.,

``````POLYID A B C D E
A  0 0 1 0 1
B  0 0 1 0 0
C  1 1 0 1 0
D  0 0 1 0 1
E  1 0 0 1 0
``````

The above indicates, for instance, that polygons 'C' and 'E' adjoin polygon 'A'; polygon 'B' adjoins only polygon 'C', etc.

The attribute table I have has one polygon per row:

``````POLYID TOT L10K 10_15K 15_20K ...
A 500   24     30     77 ...
``````

Where TOT, L10K, etc. are the variables I use to calculate an index.

There are 525 polygons/rows in my data, so I'd like to use the adjacency matrix to determine which rows' attributes to incorporate into the calculation of the index of interest. For now, I can calculate the index when I subset the rows that correspond to one 'bundle' of neighboring polygons, and then use a loop (if it's of interest, I'm calculating the Centile Gap Index, a measure of local income segregation). E.g., subsetting the 'neighborhood' of the Detroit City Schools:

``````Detroit <- UNSD00[c(142,150,164,221,226,236,295,327,157,177,178,364,233,373,418,424,449,451,487),]
``````

Then record the marginal column proportions and a running total:

``````catprops <- vector()
for(i in 4:19)
{
catprops[(i-3)]<-sum(Detroit[,i])/sum(Detroit[,3])
}
catprops <- as.data.frame(catprops)
catprops[,2]<-cumsum(catprops[,1])
``````

Columns 4:19 are the necessary ones in the attribute table.

Then I use the following code to calculate the index -- note that the loop has "i in 1:19" because the Detroit subset has 19 polygons.

``````cgidistsum <- 0
for(i in 1:19)
{
pranks <- vector()
for(j in 4:19)
{
if (Detroit[i,j]==0)
pranks <- append(pranks,0)
else if (j == 4)
pranks <- append(pranks,seq(0,catprops[1,2],by=catprops[1,2]/Detroit[i,j]))
else
pranks <- append(pranks,seq(catprops[j-4,2],catprops[j-3,2],by=catprops[j-3,1]/Detroit[i,j]))
}
distpranks <- vector()
distpranks<-abs(pranks-median(pranks))
cgidistsum <- cgidistsum + sum(distpranks)
}
cgi <- (.25-(cgidistsum/sum(Detroit[,3])))/.25
``````

My apologies if I've provided more information than is necessary. I would really like to exploit the adjacency matrix in order to calculate the CGI for each 'bundle' of these rows.

If you happen to know how I could started with this, that would be great.

and my apologies for any novice mistakes, I'm new to R!

EDIT:

I've since figured out how to approach this, but for the sake of problem clarity and in response to one question asked in the comments, let me say that a polygon's neighborhood is the union of itself and every polygon it is adjacent to. In the example I gave above, for polygon 'A', that would be the union of polygon's 'A', 'C', and 'E'

-
Thanks @DWin for your helpful formatting edits. I will take note of them for the future. –  dubhousing Dec 14 '12 at 2:03
a lot of information is confusing. Can you explain the index calculation in pseudo code? I mean in English, distinguishing the case the polygon is adjacent or not? –  agstudy Dec 14 '12 at 4:27

This is what I ended up doing, although it doesn't appear to be as elegant as @agstudy 's:

``````for(k in 1:nrow(adjacency00))
{
nghbrd <- UNSD00[c(positions,k),]
``````

etc., thereby creating a frame of adjacent polygons on which to conduct subsequent calculations

-

It is not clear how you do you want to exploit the adjency matrix.

One idea is to formulate your problem as a graph one. The igraph is suitable to manipulate adjacent edges and vertex.

here my idea:

``````# I read the adjency matrix
A  0 0 1 0 1
B  0 0 1 0 0
C  1 1 0 1 0
D  0 0 1 0 1
E  1 0 0 1 0',header = TRUE)
# I create the graph
require(igraph)
V(g)\$label <- V(g)\$name
``````

As option you can plot it :

`````` plot(g)
``````

Now I use the attributes matrix , to create an attribute for each edge ( since each Row is an edge)

# I create a dummy attributes matrix

``````POLYID.attributes <- read.table(text =' TOT L10K 10_15K 15_20K
A 500   24     30     77
B 400   25     30     87
C 300   26     30     97
D 200   27     30     57
E 100   28     30     47',header = TRUE)

# I set the attributes
for(x in colnames(POLYID.attributes)){
g <- set.vertex.attribute(g, name = x,
value=  POLYID.attributes[,x])

}
``````

Now all the problem info is in the graph.

``````str(g)
IGRAPH DN-- 5 10 --
+ attr: name (v/c), label (v/c), TOT (v/n), L10K (v/n),
X10_15K (v/n), X15_20K (v/n)
+ edges (vertex names):
[1] A->C A->E B->C C->A C->B C->D D->C D->E E->A E->D
``````

Now I can get the information of each node using igraph options, e.g:

e. get the L10K attributes of the polygon adjacent to B

``````V(g)[get.adjlist(g,'out')\$B]\$L10K
[1] 26
``````

Here I compute the sum of TOT of all the polygons adjacent to the plyogon A:

`````` sum(V(g)[get.adjlist(g,'out')\$A]\$TOT)
400
``````
-
Wow @agstudy. That is very, very cool. And explicitly spatial. Unfortunately, I figured out my own, kludgy way to do this (explained in a separate answer). But I will definitely keep this one in mind!) –  dubhousing Dec 17 '12 at 18:57
@dubhousing why not use mine? It is difficult ? or no time to use it? –  agstudy Dec 17 '12 at 19:05
my apologies, but i figured mine out 1st, came back here to report, and saw yours. mine works well enough, and I am indeed very short on time, which means I probably wouldn't be able to dwell on your approach sufficiently to understand it. Thanks again, though. –  dubhousing Dec 17 '12 at 19:08
@dubhousing no problem. I am just curious to see the behaviour of the graph method in real case. –  agstudy Dec 17 '12 at 19:12