Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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'

share|improve this question
    
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

2 Answers 2

up vote 0 down vote accepted

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))
 {
  positions <- grep(1,adjacency00[k,])-1
  nghbrd <- UNSD00[c(positions,k),]

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

share|improve this answer

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
POLYID.adjency <- read.table(text ='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',header = TRUE)
# I create the graph
require(igraph)
g <- graph.adjacency(adjmatrix=POLYID.adjency)
V(g)$label <- V(g)$name

As option you can plot it :

 plot(g)

enter image description here

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
share|improve this answer
    
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.