The questioner gave an excellent answer by taking advantage of `numba`

. I really appreciate it but I cannot totally agree with the contents within `interpolate_numba`

function. I do not think the logic of linear interpolation over a specific point is to find the average value of its left and right neighbors. For illustration, let's say we have an array [1,nan,nan,4,nan,6], the `interpolate_numba`

function above will probably return [1,2.5,2.5,4,5,6] (only theoretical deduction), whereas `pandas`

wrapper will surely return [1,2,3,4,5,6]. Instead, I believe the logic of linear interpolation over a specific point is to find its left and right neighbors, use their values to determine a line (i.e. slope and intercept), and finally calculate the interpolation value. The following shows my code. To make things easy, I assume the input data is a 3-D array containing nan values. I stipulate the first and last elements are equivalent to their right and left nearest neighbors (i.e. `limit_direction='both'`

in `pandas`

). I do not specify the maximum number of consecutive interpolations (i.e. no `limit`

in `pandas`

).

```
import numpy as np
from numba import jit
@jit(nopython=True)
def f(arr_3d):
result=np.zeros_like(arr_3d)
for i in range(arr_3d.shape[1]):
for j in range(arr_3d.shape[2]):
arr=arr_3d[:,i,j]
# If all elements are nan then cannot conduct linear interpolation.
if np.sum(np.isnan(arr))==arr.shape[0]:
result[:,i,j]=arr
else:
# If the first elemet is nan, then assign the value of its right nearest neighbor to it.
if np.isnan(arr[0]):
arr[0]=arr[~np.isnan(arr)][0]
# If the last element is nan, then assign the value of its left nearest neighbor to it.
if np.isnan(arr[-1]):
arr[-1]=arr[~np.isnan(arr)][-1]
# If the element is in the middle and its value is nan, do linear interpolation using neighbor values.
for k in range(arr.shape[0]):
if np.isnan(arr[k]):
x=k
x1=x-1
x2=x+1
# Find left neighbor whose value is not nan.
while x1>=0:
if np.isnan(arr[x1]):
x1=x1-1
else:
y1=arr[x1]
break
# Find right neighbor whose value is not nan.
while x2<arr.shape[0]:
if np.isnan(arr[x2]):
x2=x2+1
else:
y2=arr[x2]
break
# Calculate the slope and intercept determined by the left and right neighbors.
slope=(y2-y1)/(x2-x1)
intercept=y1-slope*x1
# Linear interpolation and assignment.
y=slope*x+intercept
arr[x]=y
result[:,i,j]=arr
return result
```

Initializing a 3-D array containing some nans, I have checked my code which can give as same answer as those from `pandas`

wrapper. It will be a little bit confusing to go through `pandas`

wrapper code since pandas can only address 2-dimensional data.

Using my code

```
y1=np.ones((2,2))
y2=y1+1
y3=y2+np.nan
y4=y2+2
y5=y1+np.nan
y6=y4+2
y1[1,1]=np.nan
y2[0,0]=np.nan
y4[1,1]=np.nan
y6[1,1]=np.nan
y=np.stack((y1,y2,y3,y4,y5,y6),axis=0)
print(y)
print("="*10)
f(y)
```

Using pandas wrapper

```
import pandas as pd
y1=np.ones((2,2)).flatten()
y2=y1+1
y3=y2+np.nan
y4=y2+2
y5=y1+np.nan
y6=y4+2
y1[3]=np.nan
y2[0]=np.nan
y4[3]=np.nan
y6[3]=np.nan
y=pd.DataFrame(np.stack([y1,y2,y3,y4,y5,y6],axis=0))
y=y.interpolate(method='linear', limit_direction='both', axis=0)
y_numpy=y.to_numpy()
y_numpy.shape=((6,2,2))
print(np.stack([y1,y2,y3,y4,y5,y6],axis=0).reshape(6,2,2))
print("="*10)
print(y_numpy)
```

Output will be the same

```
[[[ 1. 1.]
[ 1. nan]]
[[nan 2.]
[ 2. 2.]]
[[nan nan]
[nan nan]]
[[ 4. 4.]
[ 4. nan]]
[[nan nan]
[nan nan]]
[[ 6. 6.]
[ 6. nan]]]
==========
[[[1. 1.]
[1. 2.]]
[[2. 2.]
[2. 2.]]
[[3. 3.]
[3. 2.]]
[[4. 4.]
[4. 2.]]
[[5. 5.]
[5. 2.]]
[[6. 6.]
[6. 2.]]]
```

Using `test_arr`

data increasing its size to (92,4800,4800) as input, I found only approximately 40 s was needed to complete the interpolation!

```
test_arr = np.random.randint(low=-10000, high=10000, size=(92, 4800, 4800))
test_arr[1:90:7, :, :] = np.nan # NaN fill value in original data
test_arr[2,:,:] = np.nan
test_arr[:, 1:479:6, 1:479:8] = np.nan
%time f(test_arr)
```

Output

```
CPU times: user 32.5 s, sys: 9.13 s, total: 41.6 s
Wall time: 41.6 s
```

`(92, 480, 480)`

. If you increase it to the size of the real dataset`(92, 4800, 4800)`

and propagate it with moreNaNthis method takes considerably longer.