Difference between revisions of "Documentation/Labs/Plotting2DLineSegments"
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− | install.packages | + | if (require(Morpho)) {} else install.packages('Morpho') |
+ | if (require(geomorph)) {} else install.packages('geomorph') | ||
+ | |||
#define the location to save the temp zipfile | #define the location to save the temp zipfile |
Latest revision as of 05:16, 7 February 2019
Home < Documentation < Labs < Plotting2DLineSegmentsWe need a way to plot 2D arbitrary line segments to visualize 3D deformation vectors projected on each plane. Below is a code snippet that does this in R using a plotting function called segments which takes a starting coordinate set (x0,y0) and an end coordinate set (x1,y1) and plots a line segments. By convention (x0,y0) is the coordinate of that landmark in the meanshape space, and the segment drawn is the amount it will be displaced by the selected PC (which is also calculated by adding the eigenvectors times some arbitrary scale to the mean coordinate).
if (require(Morpho)) {} else install.packages('Morpho') if (require(geomorph)) {} else install.packages('geomorph') #define the location to save the temp zipfile zip = 'c:/tmp/Gorilla_Skull_LMs.zip' download.file(url = 'https://github.com/SlicerMorph/SampleData/blob/master/Gorilla_Skull_LMs.zip?raw=true', destfile = zip, method = 'auto', mode='wb') files = unzip(zip, list = T)$Name no.subjects = length(files) no.landmarks = nrow (Morpho::read.fcsv(unzip(zip, files[1]))) lms = array(dim = c(no.landmarks, 3, no.subjects)) for (i in 1:no.subjects) lms[,,i] = Morpho::read.fcsv(unzip(zip, files=files[i])) gpa = geomorph::gpagen(lms) pca = geomorph::plotTangentSpace(gpa$coords) par(mfrow=c(2,2)) par(pty="s") plot(gpa$consensus[,c(1,2)], pch=20, main ='mean shape') plot(gpa$consensus[,c(1,2)],pch=20, main = 'XY plane', asp=1) for (i in 1:41) segments(x0=gpa$consensus[i,1], y0=gpa$consensus[i,2], x1=pca$pc.shapes$PC1max[i,1], y1=pca$pc.shapes$PC1max[i,2], col='red') for (i in 1:41) segments(x0=gpa$consensus[i,1], y0=gpa$consensus[i,2], x1=pca$pc.shapes$PC2max[i,1], y1=pca$pc.shapes$PC2max[i,2], col='green') plot(gpa$consensus[,c(1,3)],pch=20, main = 'XZ plane', asp=1) for (i in 1:41) segments(x0=gpa$consensus[i,1], y0=gpa$consensus[i,3], x1=pca$pc.shapes$PC1max[i,1], y1=pca$pc.shapes$PC1max[i,3], col='red') for (i in 1:41) segments(x0=gpa$consensus[i,1], y0=gpa$consensus[i,3], x1=pca$pc.shapes$PC2max[i,1], y1=pca$pc.shapes$PC2max[i,3], col='green') plot(gpa$consensus[,c(2,3)],pch=20, main = 'YZ plane', asp=1) for (i in 1:41) segments(x0=gpa$consensus[i,2], y0=gpa$consensus[i,3], x1=pca$pc.shapes$PC1max[i,2], y1=pca$pc.shapes$PC1max[i,3], col='red') for (i in 1:41) segments(x0=gpa$consensus[i,2], y0=gpa$consensus[i,3], x1=pca$pc.shapes$PC2max[i,2], y1=pca$pc.shapes$PC2max[i,3], col='green')