# Best way to interpolate a numpy.ndarray along an axis

I have 4-dimensional data, say for the temperature, in an `numpy.ndarray`. The shape of the array is `(ntime, nheight_in, nlat, nlon)`.

I have corresponding 1D arrays for each of the dimensions that tell me which time, height, latitude, and longitude a certain value corresponds to, for this example I need `height_in` giving the height in metres.

Now I need to bring it onto a different height dimension, `height_out`, with a different length.

The following seems to do what I want:

``````ntime, nheight_in, nlat, nlon = t_in.shape

nheight_out = len(height_out)
t_out = np.empty((ntime, nheight_out, nlat, nlon))

for time in range(ntime):
for lat in range(nlat):
for lon in range(nlon):
t_out[time, :, lat, lon] = np.interp(
height_out, height_in, t[time, :, lat, lon]
)
``````

But with 3 nested loops, and lots of switching between python and numpy, I don't think this is the best way to do it.

Any suggestions on how to improve this? Thanks

`scipy`'s `interp1d` can help:

``````import numpy as np
from scipy.interpolate import interp1d

ntime, nheight_in, nlat, nlon = (10, 20, 30, 40)

heights = np.linspace(0, 1, nheight_in)

t_in = np.random.normal(size=(ntime, nheight_in, nlat, nlon))
f_out = interp1d(heights, t_in, axis=1)

nheight_out = 50
new_heights = np.linspace(0, 1, nheight_out)
t_out = f_out(new_heights)
``````
• Thanks a lot, but is it possible that your method uses more memory than the one I showed above. While testing it, I noticed that your method was considerably faster than mine until the array sizes exceeded a certain level (90x50x181x360 in my case), where suddenly yours became much slower than mine. Mar 9, 2015 at 3:47
• `interp1d` requires a lot of memory, and does not extrapolate May 14, 2015 at 20:47
• @fjarri no there is no better solution, just wanted to let future readers know about the caveats; specially memory consumption which is very high and can be replaced with `InterpolatedUnivariateSpline` on 1d slices. May 15, 2015 at 3:05
• Just a supplementary. Readers can check this link if they are interested in linear interpolation along an axis with a lot of missing data in the data array. Jul 31, 2019 at 19:46
• Seems that scipy's interp1d is pending deprecation at present time (docs.scipy.org/doc/scipy/reference/generated/…) with less than extreme clarity provided as to a clear scipy replacement Oct 21, 2023 at 14:32

I was looking for a similar function that works with irregularly spaced coordinates, and ended up writing my own function. As far as I see, the interpolation is handled nicely and the performance in terms of memory and speed is also quite good. I thought I'd share it here in case anyone else comes across this question looking for a similar function:

``````import numpy as np
import warnings

def interp_along_axis(y, x, newx, axis, inverse=False, method='linear'):
""" Interpolate vertical profiles, e.g. of atmospheric variables
using vectorized numpy operations

This function assumes that the x-xoordinate increases monotonically

ps:
* Updated to work with irregularly spaced x-coordinate.
* Updated to work with irregularly spaced newx-coordinate
* Updated to easily inverse the direction of the x-coordinate
* Updated to fill with nans outside extrapolation range
* Updated to include a linear interpolation method as well
(it was initially written for a cubic function)

Peter Kalverla
March 2018

--------------------
Algorithm from: http://www.paulinternet.nl/?page=bicubic
It approximates y = f(x) = ax^3 + bx^2 + cx + d
where y may be an ndarray input vector
Returns f(newx)

The algorithm uses the derivative f'(x) = 3ax^2 + 2bx + c
and uses the fact that:
f(0) = d
f(1) = a + b + c + d
f'(0) = c
f'(1) = 3a + 2b + c

Rewriting this yields expressions for a, b, c, d:
a = 2f(0) - 2f(1) + f'(0) + f'(1)
b = -3f(0) + 3f(1) - 2f'(0) - f'(1)
c = f'(0)
d = f(0)

These can be evaluated at two neighbouring points in x and
as such constitute the piecewise cubic interpolator.
"""

# View of x and y with axis as first dimension
if inverse:
_x = np.moveaxis(x, axis, 0)[::-1, ...]
_y = np.moveaxis(y, axis, 0)[::-1, ...]
_newx = np.moveaxis(newx, axis, 0)[::-1, ...]
else:
_y = np.moveaxis(y, axis, 0)
_x = np.moveaxis(x, axis, 0)
_newx = np.moveaxis(newx, axis, 0)

# Sanity checks
if np.any(_newx[0] < _x[0]) or np.any(_newx[-1] > _x[-1]):
# raise ValueError('This function cannot extrapolate')
warnings.warn("Some values are outside the interpolation range. "
"These will be filled with NaN")
if np.any(np.diff(_x, axis=0) < 0):
raise ValueError('x should increase monotonically')
if np.any(np.diff(_newx, axis=0) < 0):
raise ValueError('newx should increase monotonically')

# Cubic interpolation needs the gradient of y in addition to its values
if method == 'cubic':
# For now, simply use a numpy function to get the derivatives
# This produces the largest memory overhead of the function and
# could alternatively be done in passing.

# This will later be concatenated with a dynamic '0th' index
ind = [i for i in np.indices(_y.shape[1:])]

# Allocate the output array
original_dims = _y.shape
newdims = list(original_dims)
newdims[0] = len(_newx)
newy = np.zeros(newdims)

# set initial bounds
i_lower = np.zeros(_x.shape[1:], dtype=int)
i_upper = np.ones(_x.shape[1:], dtype=int)
x_lower = _x[0, ...]
x_upper = _x[1, ...]

for i, xi in enumerate(_newx):
# Start at the 'bottom' of the array and work upwards
# This only works if x and newx increase monotonically

# Update bounds where necessary and possible
needs_update = (xi > x_upper) & (i_upper+1<len(_x))
# print x_upper.max(), np.any(needs_update)
while np.any(needs_update):
i_lower = np.where(needs_update, i_lower+1, i_lower)
i_upper = i_lower + 1
x_lower = _x[[i_lower]+ind]
x_upper = _x[[i_upper]+ind]

# Check again
needs_update = (xi > x_upper) & (i_upper+1<len(_x))

# Express the position of xi relative to its neighbours
xj = (xi-x_lower)/(x_upper - x_lower)

# Determine where there is a valid interpolation range
within_bounds = (_x[0, ...] < xi) & (xi < _x[-1, ...])

if method == 'linear':
f0, f1 = _y[[i_lower]+ind], _y[[i_upper]+ind]
a = f1 - f0
b = f0

newy[i, ...] = np.where(within_bounds, a*xj+b, np.nan)

elif method=='cubic':
f0, f1 = _y[[i_lower]+ind], _y[[i_upper]+ind]
df0, df1 = ydx[[i_lower]+ind], ydx[[i_upper]+ind]

a = 2*f0 - 2*f1 + df0 + df1
b = -3*f0 + 3*f1 - 2*df0 - df1
c = df0
d = f0

newy[i, ...] = np.where(within_bounds, a*xj**3 + b*xj**2 + c*xj + d, np.nan)

else:
raise ValueError("invalid interpolation method"
"(choose 'linear' or 'cubic')")

if inverse:
newy = newy[::-1, ...]

return np.moveaxis(newy, 0, axis)
``````

And this is a small example to test it:

``````import numpy as np
import matplotlib.pyplot as plt
from scipy.interpolate import interp1d as scipy1d

# toy coordinates and data
nx, ny, nz = 25, 30, 10
x = np.arange(nx)
y = np.arange(ny)
z = np.tile(np.arange(nz), (nx,ny,1)) + np.random.randn(nx, ny, nz)*.1
testdata = np.random.randn(nx,ny,nz) # x,y,z

# Desired z-coordinates (must be between bounds of z)
znew = np.tile(np.linspace(2,nz-2,50), (nx,ny,1)) + np.random.randn(nx, ny, 50)*0.01

# Inverse the coordinates for testing
z = z[..., ::-1]
znew = znew[..., ::-1]

# Now use own routine
ynew = interp_along_axis(testdata, z, znew, axis=2, inverse=True)

# Check some random profiles
for i in range(5):
randx = np.random.randint(nx)
randy = np.random.randint(ny)

checkfunc = scipy1d(z[randx, randy], testdata[randx,randy], kind='cubic')
checkdata = checkfunc(znew)

fig, ax = plt.subplots()
ax.plot(testdata[randx, randy], z[randx, randy], 'x', label='original data')
ax.plot(checkdata[randx, randy], znew[randx, randy], label='scipy')
ax.plot(ynew[randx, randy], znew[randx, randy], '--', label='Peter')
ax.legend()
plt.show()
``````

• Nice!! Very useful! Thaanks! Sep 13, 2019 at 15:40

Following the criteria of numpy.interp, one can assign the left/right bounds to the points outside the range adding this lines after `within_bounds = ...`

``````out_lbound = (xi <= _x[0,...])
out_rbound = (_x[-1,...] <= xi)
``````

and

``````newy[i, out_lbound] = _y[0, out_lbound]
newy[i, out_rbound] = _y[-1, out_rbound]
``````

after `newy[i, ...] = ...`.

If I understood well the strategy used by @Peter9192, I think the changes are in the same line. I've checked a little bit, but maybe some strange case could not work properly.