# Reprojecting polar to cartesian grid

I have a polar (r,theta) grid (which means that each cell is an annulus section) containing values of some physical quantity (e.g. temperature), and I would like to re-grid (or re-project) these values onto a cartesian grid. Are there any Python packages that can do this?

I am not interested in converting the coordinates of the centers of the cells from polar to cartesian - this is very easy. Instead, I'm looking for a package that can actually re-grid the data properly.

Thanks for any suggestions!

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That's not an easy problem, and it would be both interesting and a huge bear to write. I think it would take me 2-3 days to come up with something horribly inefficient. –  Omnifarious Jan 29 '10 at 19:53

``````import numpy as np

import matplotlib
matplotlib.use('Agg')
import matplotlib.pyplot as mpl

from scipy.interpolate import interp1d
from scipy.ndimage import map_coordinates

def polar2cartesian(r, t, grid, x, y, order=3):

X, Y = np.meshgrid(x, y)

new_r = np.sqrt(X*X+Y*Y)
new_t = np.arctan2(X, Y)

ir = interp1d(r, np.arange(len(r)), bounds_error=False)
it = interp1d(t, np.arange(len(t)))

new_ir = ir(new_r.ravel())
new_it = it(new_t.ravel())

new_ir[new_r.ravel() > r.max()] = len(r)-1
new_ir[new_r.ravel() < r.min()] = 0

return map_coordinates(grid, np.array([new_ir, new_it]),
order=order).reshape(new_r.shape)

# Define original polar grid

nr = 10
nt = 10

r = np.linspace(1, 100, nr)
t = np.linspace(0., np.pi, nt)
z = np.random.random((nr, nt))

# Define new cartesian grid

nx = 100
ny = 200

x = np.linspace(0., 100., nx)
y = np.linspace(-100., 100., ny)

# Interpolate polar grid to cartesian grid (nearest neighbor)

fig = mpl.figure()
ax.imshow(polar2cartesian(r, t, z, x, y, order=0), interpolation='nearest')
fig.savefig('test1.png')

# Interpolate polar grid to cartesian grid (cubic spline)

fig = mpl.figure()
ax.imshow(polar2cartesian(r, t, z, x, y, order=3), interpolation='nearest')
fig.savefig('test2.png')
``````

Which is not strictly re-gridding, but works fine for what I need. Just posting the code in case it is useful to anyone else. Feel free to suggest improvements!

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You can do this more compactly with `scipy.ndimage.geometric_transform`. Here is some sample code:

``````import numpy as N
import scipy as S
import scipy.ndimage

temperature = <whatever>
# This is the data in your polar grid.
# The 0th and 1st axes correspond to r and θ, respectively.
# For the sake of simplicity, θ goes from 0 to 2π,
# and r's units are just its indices.

def polar2cartesian(outcoords, inputshape, origin):
"""Coordinate transform for converting a polar array to Cartesian coordinates.
inputshape is a tuple containing the shape of the polar array. origin is a
tuple containing the x and y indices of where the origin should be in the
output array."""

xindex, yindex = outcoords
x0, y0 = origin
x = xindex - x0
y = yindex - y0

r = N.sqrt(x**2 + y**2)
theta = N.arctan2(y, x)
theta_index = N.round((theta + N.pi) * inputshape[1] / (2 * N.pi))

return (r,theta_index)

temperature_cartesian = S.ndimage.geometric_transform(temperature, polar2cartesian,
order=0,
output_shape = (temperature.shape[0] * 2, temperature.shape[0] * 2),
extra_keywords = {'inputshape':temperature.shape,
'center':(temperature.shape[0], temperature.shape[0])})
``````

You can change `order=0` as desired for better interpolation. The output array `temperature_cartesian` is 2r by 2r here, but you can specify any size and origin you like.

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I came to this post some time ago when trying to do something similar, this is, reprojecting polar data into a cartesian grid and vice-versa. The solution proposed here works fine. However, it takes some time to perform the coordinate transform. I just wanted to share another approach which can reduce the processing time up to 50 times or more.

The algorithm uses the `scipy.ndimage.interpolation.map_coordinates` function.

Let's see a little example:

``````import numpy as np

# Auxiliary function to map polar data to a cartesian plane
def polar_to_cart(polar_data, theta_step, range_step, x, y, order=3):

from scipy.ndimage.interpolation import map_coordinates as mp

# "x" and "y" are numpy arrays with the desired cartesian coordinates
# we make a meshgrid with them
X, Y = np.meshgrid(x, y)

# Now that we have the X and Y coordinates of each point in the output plane
# we can calculate their corresponding theta and range
Tc = np.degrees(np.arctan2(Y, X)).ravel()
Rc = (np.sqrt(X**2 + Y**2)).ravel()

# Negative angles are corrected
Tc[Tc < 0] = 360 + Tc[Tc < 0]

# Using the known theta and range steps, the coordinates are mapped to
# those of the data grid
Tc = Tc / theta_step
Rc = Rc / range_step

# An array of polar coordinates is created stacking the previous arrays
coords = np.vstack((Ac, Sc))

# To avoid holes in the 360º - 0º boundary, the last column of the data
# copied in the begining
polar_data = np.vstack((polar_data, polar_data[-1,:]))

# The data is mapped to the new coordinates
# Values outside range are substituted with nans
cart_data = mp(polar_data, coords, order=order, mode='constant', cval=np.nan)

# The data is reshaped and returned
return(cart_data.reshape(len(y), len(x)).T)

polar_data = ... # Here a 2D array of data is assumed, with shape thetas x ranges

# We create the x and y axes of the output cartesian data
x = y = np.arange(-100000, 100000, 1000)

# We call the mapping function assuming 1 degree of theta step and 500 meters of
# range step. The default order of 3 is used.
cart_data = polar_to_cart(polar_data, 1, 500, x, y)
``````

I hope this helps someone in the same situation as me.

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