Plotting tri-objective models
Lars Relund Nielsen
2024-10-28
Source:vignettes/tri-objective.Rmd
tri-objective.Rmd
With gMOIP
you can make plots of the criterion space for
tri-objective models (linear programming (LP), integer linear
programming (ILP), or mixed integer linear programming (MILP)). This
vignette gives examples on how to make plots of the criterion space.
First we load the package:
The criterion space can be plotted for tri-objective models. An example with many unsupported:
view <- matrix( c(0.333316594362259, 0.938472270965576, -0.0903875231742859, 0, 0.83994072675705, -0.339126199483871, -0.423665106296539, 0, -0.428250730037689, 0.0652943551540375, -0.901297807693481, 0, 0, 0, 0, 1), nc = 4)
loadView(v = view)
set.seed(1234)
pts <- genNDSet(3, 20, argsSphere = list(below = FALSE), dubND = FALSE)
pts <- classifyNDSet(pts[,1:3])
head(pts)
#> z1 z2 z3 se sne us cls
#> 1 48 87 17 TRUE FALSE FALSE se
#> 2 14 59 83 TRUE FALSE FALSE se
#> 3 70 75 12 TRUE FALSE FALSE se
#> 4 98 36 55 FALSE FALSE TRUE us
#> 5 91 40 24 TRUE FALSE FALSE se
#> 6 34 93 31 TRUE FALSE FALSE se
ini3D(argsPlot3d = list(xlim = c(min(pts[,1])-2,max(pts[,1])+2),
ylim = c(min(pts[,2])-2,max(pts[,2])+2),
zlim = c(min(pts[,3])-2,max(pts[,3])+2)))
plotPoints3D(pts[pts$se,1:3], argsPlot3d = list(col = "red"))
plotPoints3D(pts[!pts$sne,1:3], argsPlot3d = list(col = "black"))
plotPoints3D(pts[!pts$us,1:3], argsPlot3d = list(col = "blue"))
plotCones3D(pts[,1:3], rectangle = TRUE, argsPolygon3d = list(alpha = 1, color = "cornflowerblue"))
plotHull3D(pts[,1:3], addRays = TRUE, argsPolygon3d = list(alpha = 0.25, color = "red"), useRGLBBox = TRUE)
finalize3D(argsAxes3d = list(edges = "bbox"))
Example with many supported:
loadView(v = view)
pts <- genNDSet(3, 10, argsSphere = list(below = TRUE), dubND = FALSE)
pts <- classifyNDSet(pts[,1:3])
ini3D(argsPlot3d = list(xlim = c(min(pts[,1])-2,max(pts[,1])+2),
ylim = c(min(pts[,2])-2,max(pts[,2])+2),
zlim = c(min(pts[,3])-2,max(pts[,3])+2)))
plotPoints3D(pts[pts$se,1:3], argsPlot3d = list(col = "red"))
plotPoints3D(pts[!pts$sne,1:3], argsPlot3d = list(col = "black"))
plotPoints3D(pts[!pts$us,1:3], argsPlot3d = list(col = "blue"))
plotCones3D(pts[,1:3], rectangle = TRUE, argsPolygon3d = list(alpha = 1, color = "cornflowerblue"))
plotHull3D(pts[,1:3], addRays = TRUE, argsPolygon3d = list(alpha = 0.25, color = "red"), useRGLBBox = TRUE)
finalize3D(argsAxes3d = list(edges = "bbox"))
Classifying
Non-dominated points can be classified using
classifyNDSet
:
pts <- matrix(c(0,0,1, 0,1,0, 1,0,0, 0.5,0.2,0.5, 0.25,0.5,0.25), ncol = 3, byrow = TRUE)
open3d()
#> null
#> 6
ini3D(argsPlot3d = list(xlim = c(min(pts[,1])-2,max(pts[,1])+2),
ylim = c(min(pts[,2])-2,max(pts[,2])+2),
zlim = c(min(pts[,3])-2,max(pts[,3])+2)))
plotHull3D(pts, addRays = TRUE, argsPolygon3d = list(alpha = 0.5), useRGLBBox = TRUE)
pts <- classifyNDSet(pts[,1:3])
pts
#> z1 z2 z3 se sne us cls
#> 1 0.00 0.0 1.00 TRUE FALSE FALSE se
#> 2 0.00 1.0 0.00 TRUE FALSE FALSE se
#> 3 1.00 0.0 0.00 TRUE FALSE FALSE se
#> 4 0.50 0.2 0.50 FALSE FALSE TRUE us
#> 5 0.25 0.5 0.25 FALSE TRUE FALSE sne
plotPoints3D(pts[pts$se,1:3], argsPlot3d = list(col = "red"))
plotPoints3D(pts[!pts$sne,1:3], argsPlot3d = list(col = "black"))
plotPoints3D(pts[!pts$us,1:3], argsPlot3d = list(col = "blue"))
plotCones3D(pts[,1:3], rectangle = TRUE, argsPolygon3d = list(alpha = 1))
finalize3D()
rglwidget(reuse = F)
pts <- genNDSet(3,20, dubND = FALSE)[,1:3]
open3d()
#> null
#> 9
ini3D(argsPlot3d = list(xlim = c(0,max(pts$z1)+2),
ylim = c(0,max(pts$z2)+2),
zlim = c(0,max(pts$z3)+2)))
plotHull3D(pts, addRays = TRUE, argsPolygon3d = list(alpha = 0.5))
pts <- classifyNDSet(pts[,1:3])
pts
#> z1 z2 z3 se sne us cls
#> 1 3 62 45 TRUE FALSE FALSE se
#> 2 76 40 9 FALSE FALSE TRUE us
#> 3 23 45 10 TRUE FALSE FALSE se
#> 4 29 66 9 FALSE FALSE TRUE us
#> 5 22 11 60 TRUE FALSE FALSE se
#> 6 46 12 20 TRUE FALSE FALSE se
#> 7 49 2 39 TRUE FALSE FALSE se
#> 8 9 27 64 TRUE FALSE FALSE se
#> 9 32 10 29 TRUE FALSE FALSE se
#> 10 8 39 29 TRUE FALSE FALSE se
#> 11 37 5 36 TRUE FALSE FALSE se
#> 12 45 2 61 TRUE FALSE FALSE se
#> 13 19 30 18 TRUE FALSE FALSE se
#> 14 30 7 38 TRUE FALSE FALSE se
#> 15 11 33 26 TRUE FALSE FALSE se
#> 16 46 2 43 TRUE FALSE FALSE se
#> 17 12 21 39 TRUE FALSE FALSE se
#> 18 45 21 11 TRUE FALSE FALSE se
#> 19 21 26 20 TRUE FALSE FALSE se
#> 20 31 43 5 TRUE FALSE FALSE se
plotPoints3D(pts[pts$se,1:3], argsPlot3d = list(col = "red"))
plotPoints3D(pts[!pts$sne,1:3], argsPlot3d = list(col = "black"))
plotPoints3D(pts[!pts$us,1:3], argsPlot3d = list(col = "blue"))
finalize3D()
rglwidget(reuse = F)
The classification is done using the qhull
algorithm
that find the convex hull of the points including the rays. If a vertex
then if must be supported extreme. Next we use the inHull
algorithm to find out if the remaining are on the border or not
(supported non-extreme and unsupported).