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I am plotting a 3D polar plot of field strength around an antenna. A sample of the data looks like this:

0.5  0  -22
0.5  0  -21
0.5  0  -22
0.5  0  -21
0.5  0  -22
0.5  0  -22
0.5  0  -22
0.5  0  -22

Where the 1st column is a radius from the antenna, the 2nd is an angle around the antenna and the 3rd is a dBm value of the field strength.

I have taken a number of samples at each point which are averaged by my script. 3 corresponding lists R, P and Z which contain the radius, the angle and the linear value for field strength at each unique point.

I want to plot a 3D polar plot of the values. And to do this I convert the R and P values from polar coordinates to Cartesian coordinates X and Y.

# transform them to cartesian system 
X,Y = R*np.cos(P),R*np.sin(P) 

I then use the following code to interpolate the data

xi = np.linspace(X.min(),X.max(),100)
yi = np.linspace(Y.min(),Y.max(),100)

zi = griddata((X, Y), Z, (xi[None,:], yi[:,None]), method='linear')

Then I create a grid and plot the data as follows

xig, yig = np.meshgrid(xi, yi)

surf = ax.plot_surface(xig, yig, zi,linewidth=0)

This creates the following plot


Is there a way to make the surface more smooth? Interpolating the data using griddata type=cubic does not work and just fills the matrix zi with "nan" values. Perhaps there is a better 3D alternative or I'm doing something wrong?

Using the suggested interp2d function has just resulted in zi being filled with nan values. I have used it in the following ways:

zi = griddata((X, Y), Z, (xi[None,:], yi[:,None]), method='linear')
interp2d(xi, yi, zi, kind='cubic')


zi = griddata((X, Y), Z, (xi[None,:], yi[:,None]), method='linear')
zi = interp2d(xi, yi, zi, kind='cubic')

Both of which gave the following error,

Warning:     No more knots can be added because the number of B-spline coefficients
already exceeds the number of data points m. Probably causes: either
s or m too small. (fp>s)
kx,ky=3,3 nx,ny=104,105 m=10000 fp=nan s=0.000000

I also tried

interp = interp2d(X,Y,Z,kind='cubic'); new_zi = interp(xi, yi)

This gave me a similar error:

Warning:     No more knots can be added because the number of B-spline coefficients
already exceeds the number of data points m. Probably causes: either
s or m too small. (fp>s)
kx,ky=3,3 nx,ny=14,15 m=104 fp=nan s=0.000000

although m is much smaller.

It looks like the problem is the s being 0 and fp=nan. What are these values?

share|improve this question
You could make xi and yi coarser, and the run interp2d(xi, yi, zi, kind='cubic') on a finer grid. – Jaime Apr 16 '13 at 16:19
So instead of xi = np.linspace(X.min(),X.max(),100) recue the hundred to a smaller number? – mark mcmurray Apr 16 '13 at 16:25
@Jaime I get an error as xi and Z are not the same lengths. is there a way to solve this problem? – mark mcmurray Apr 16 '13 at 16:34
You're using it a bit wrong. interp = scipy.interpolate.interp2d(X,Y,Z,kind='cubic'); new_zi = interp(xi, yi) (At least I think that is what @Jaime is suggesting) – Ethan Coon Apr 16 '13 at 17:24
@EthanCoon I think interp2d requires a rectangular grid, which you would build by first calling griddata on X, Y, Z. – Jaime Apr 16 '13 at 17:31

s is the parameter which sets the error from the given points (that is how far the interpolated surface can miss the source points by). If s=0, then the interpolation must hit every point exactly. If there is noise in your data, the higher derivatives will not be smooth which it turn will 1) make your fitted surface look awful as it contorts itself to mach the values and the higher derivatives 2) require alot of control points.

For noisy data, higher order interpolation can actually be much worse than linear interpolation.

According to the interp2D documentation it is really just calling bisplrep (doc), which you can work with directly, and gives you access to a lot more knobs.

To get 'smother' interpolation, you are going to have to accept some degree of smoothing of your original data. If that is ok or not is up to you.

share|improve this answer

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