# R lattice wireframe: how to increase the resolution of 3D graph

I have a question which I don't have the answer to after a while of research.

``````temp.df<-subset(spread.df, x<5 & x>1 & y>1 & y<5)

wireframe((temp.df\$z ~ temp.df\$x + temp.df\$y),
scales=list(arrows=F),
screen = list(z = 40,x= -60)
)
``````

If I run this code, the x and y axes are from 2 to 4 with only one increment in between, which is 3. This makes the graph very low res. Is there a way to bump the resolution without manipulating my original data set? By higher resolution, I mean subdividing the surface of the wireframe.

Thank you!

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how many rows do you have in temp.df? –  Troy Dec 2 '13 at 17:32
@Troy I have 9 rows in temp.df after subsetting the data. The graph looks very coarse because of the low number of data points on hand. –  lulumink Dec 2 '13 at 17:49
So you're basically asking for a 2D interpolation function. Here's one: `akima::interp` –  Carl Witthoft Dec 2 '13 at 18:10
@CarlWitthoft thanks alot! I think that's what I want. But it won't really change the surface. Do you happen to know any other regression function that can better represent my data? –  lulumink Dec 2 '13 at 21:26
You might try scouting around for a 2-D spline function, but Idon't know of one offhand. –  Carl Witthoft Dec 3 '13 at 0:16
show 1 more comment

OK here is how you can interpolate the surface with the `akima` package. By default it will give you a 40x40 grid, based on the existing surface:

``````require(akima)
require(reshape2)

temp.df<-expand.grid(x=2:4,y=2:4,z=0)
temp.df\$z<-rnorm(9,10,3)

surface<-melt(interp(temp.df\$x,temp.df\$y,temp.df\$z)) # melt() stretches out the surface to x,y,z as you've put into the original example
flat<-surface[!is.na(surface\$X1)&!is.na(surface\$X2),] # drop the NAs

#CONVERT SCALES BACK (INTERP GIVES YOU A 40x40 grid over the existing range)

points<-data.frame(x=min(temp.df\$x)+(flat\$X1-1)/(40/diff(range(temp.df\$x))),
y=min(temp.df\$y)+(flat\$X2-1)/(40/diff(range(temp.df\$x))),
z=flat\$value)

wireframe((points\$z ~ points\$x + points\$y),
scales=list(arrows=F),
screen = list(z = 40,x= -60)
)
``````

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Just promise you didn't need my comment above to get this answer :-) –  Carl Witthoft Dec 2 '13 at 19:21
Same thought at the same time, I think! –  Troy Dec 2 '13 at 19:22
you guys are awesome! thanks alot for the work! points\$z ~ points\$x + points\$y, is there a better regressional approach than this one here? I know I also used this one, but am just curious if there's another one that can better represent the data. –  lulumink Dec 2 '13 at 20:13