HOTnet (b)
No preview image
Model was written in NetLogo 5.0.3
•
Viewed 384 times
•
Downloaded 24 times
•
Run 0 times
Do you have questions or comments about this model? Ask them here! (You'll first need to log in.)
Info tab cannot be displayed because of an encoding error
Comments and Questions
Please start the discussion about this model!
(You'll first need to log in.)
Click to Run Model
;; the number of hops from a fixed center of the tree turtles-own [ nhop ] ;;;;;;;;;;;;;;;;;;;;;;;; ;;; Setup Procedures ;;; ;;;;;;;;;;;;;;;;;;;;;;;; to setup clear-all set-default-shape turtles "circle" ;; make the initial network of two turtles and an edge crt 1 [ set color green set nhop 0 ] ;; first node unattached is the root of the tree crt 1 [ setxy random-xcor random-ycor set color red create-link-with turtle 0 [ set color green ] set nhop 1 ] reset-ticks end ;;;;;;;;;;;;;;;;;;;;;;; ;;; Main Procedures ;;; ;;;;;;;;;;;;;;;;;;;;;;; to go ;; new edge is green, old edges are gray ask links [ set color gray ] ;; The behavior of the model depends crucially on the value of alfa: ;; if alfa is less than a particular constant depending on the shape of the region, ;; then Euclidean distances are not important, and the resulting network is easily seen to be a star, ;; the ultimate in degree concentration, and, depending on how you look at it, the exact opposite, or absurd extreme, of a power law. ;; If alfa grows at least as fast as sqrt(n), where n is the final number of points, then Euclidean distance becomes too important, ;; and the resulting graph is a dynamic version of the Euclidean minimum spanning tree, in which high degrees do occur, ;; but with exponentially vanishing probability. ;; If, however, alfa is anywhere in between — is larger than a certain constant, but grows slower than sqrt(n) if at all — ;; then, almost certainly, the degrees obey a power law. ;;let alfa 100 let x random-xcor let y random-ycor let partner nobody ;; Node i attaches itself to the node j that minimizes the weighted sum of the two objectives: ;; alfa * dij + hj ;; where dij is the /normalized/ Euclidean distance, and hj is some measure of the “centrality” of node j, such as ;; (a) the average number of hops from other nodes; ;; (b) the maximum number of hops from another node; ;; (c) the number of hops from a fixed center of the tree; ;; all three measures result in similar power laws, in this case we use (b). set partner min-one-of turtles [ alfa * sqrt ( ;;( (x - min-pxcor + 0.5) / (max-pxcor - min-pxcor) - (xcor - min-pxcor + 0.5) / (max-pxcor - min-pxcor) ) ^ 2 + ( (x - xcor) / (max-pxcor - min-pxcor) ) ^ 2 + ;;( (y - min-pycor + 0.5) / (max-pycor - min-pycor) - (ycor - min-pycor + 0.5) / (max-pycor - min-pycor) ) ^ 2 ( (y - ycor) / (max-pycor - min-pycor) ) ^ 2 ) + hj self ] crt 1 [ setxy x y set color red if partner != nobody [ create-link-with partner [ set color green ] set nhop 1 + [ nhop ] of partner ] ] tick end ;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; Calculate max_nhop ;;; ;;;;;;;;;;;;;;;;;;;;;;;;;; to-report hj [node] let max_nhop max [nhop] of turtles ;; if all cities at max_nhop are children of current-city then decrease hj while [ all? turtles with [nhop = max_nhop] [ is-child node max_nhop] ] [ set max_nhop max_nhop - 1 ] report max_nhop + [nhop] of node end ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; Find if city at max_ops is child of current-city ;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; to-report is-child [root max-nhop] let child false if root != turtle 0 ;; all city arechildren of the root of the tree, so don't check it! [ ask root [ ask link-neighbors with [nhop > [nhop] of root] [ ifelse nhop = max-nhop [ set child true ] [ set child is-child self max-nhop] ] ] ] report child end ;;;;;;;;;;;;;;;;;;;; ;;; Compute s(g) ;;; ;;;;;;;;;;;;;;;;;;;; to-report log-likelihood let s 0 ;; for each link compute di*dj and sum it to s ask links [ set s s + [ count link-neighbors ] of end1 * [ count link-neighbors ] of end2 ] report s end ;;;;;;;;;;;;;;;;;;;;;;;; ;;; Compute S-metric ;;; ;;;;;;;;;;;;;;;;;;;;;;;; to-report relative-log-likelihood let smax 0 let counter 0 let di 0 let child 0 ;; D = { d1, d2, d3, ..., dn }, d1 >= d2 >= d3 >= ... >= dn let degree-sequence sort-by > [ count link-neighbors ] of turtles set di item 0 degree-sequence set degree-sequence remove-item 0 degree-sequence foreach degree-sequence [ set smax smax + di * ? set counter counter + 1 if di = counter ;; we have iterated through all di's childs; if di = 0 select the highest degree. [ set counter 1 ;; count the parent if it's not the root set di item child degree-sequence ;; select child; child = 0 is the root. set child child + 1 ] ] report log-likelihood / smax end ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; Save Nodes Degrees to file ;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; to save-node-degree-to-file if file-exists? "NodeDegrees.txt" [ file-delete "NodeDegrees.txt" ] file-open "NodesDegree.txt" ;; save in descending orders ;; D = { d1, d2, d3, ..., dn }, d1 >= d2 >= d3 >= ... >= dn foreach sort-by > [ count link-neighbors ] of turtles [ file-print ? ] file-close end ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; Export Graph Connectivity to txt ;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; to export-graph if file-exists? "HOTGraph.txt" [ file-delete "HOTGraph.txt" ] file-open "HOTGraph.txt" ;; write each linked couple of tourtles and their degree ask links [ file-type [who] of end1 ;; writes without blank spaces file-write [who] of end2 ;; write a space value space file-print "" ;; write carriage return ] file-close end ;;;;;;;;;;;;;; ;;; Layout ;;; ;;;;;;;;;;;;;; ;; resize-nodes, change back and forth from size based on degree to a size of 1 to resize-nodes ifelse all? turtles [size <= 1] [ ;; a node is a circle with diameter determined by ;; the SIZE variable; using SQRT makes the circle's ;; area proportional to its degree ask turtles [ set size sqrt count link-neighbors ] ask turtles with [ size >= 4 ] [ set color violet ] ] [ ask turtles [ set size 1 set color red ] ] end to layout ;; the number 3 here is arbitrary; more repetitions slows down the ;; model, but too few gives poor layouts repeat 2 [ ;; the more turtles we have to fit into the same amount of space, ;; the smaller the inputs to layout-spring we'll need to use let factor sqrt count turtles ;; numbers here are arbitrarily chosen for pleasing appearance layout-spring turtles links (3 / factor) (5 / factor) (0.5 / factor) display ;; for smooth animation ] ;; don't bump the edges of the world let x-offset max [xcor] of turtles + min [xcor] of turtles let y-offset max [ycor] of turtles + min [ycor] of turtles ;; big jumps look funny, so only adjust a little each time set x-offset limit-magnitude x-offset 0.1 set y-offset limit-magnitude y-offset 0.1 ask turtles [ setxy (xcor - x-offset / 2) (ycor - y-offset / 2) ] end to-report limit-magnitude [number limit] if number > limit [ report limit ] if number < (- limit) [ report (- limit) ] report number end ; Copyright 2012 Tomasini Marcello. ; See Info tab for full copyright and license.
There is only one version of this model, created over 11 years ago by Marcello Tomasini.
Attached files
No files
Parent: HOTnet
This model does not have any descendants.