I have a 1D array of independent variable values (x_array) that match the timesteps in a 3D numpy array of spatial data with multiple time-steps (y_array). My actual data is much larger: 300+ timesteps and up to 3000 * 3000 pixels:

import numpy as np
from scipy.stats import linregress

# Independent variable: four time-steps of 1-dimensional data 
x_array = np.array([0.5, 0.2, 0.4, 0.4])

# Dependent variable: four time-steps of 3x3 spatial data
y_array = np.array([[[-0.2,   -0.2,   -0.3],
                     [-0.3,   -0.2,   -0.3],
                     [-0.3,   -0.4,   -0.4]],

                    [[-0.2,   -0.2,   -0.4],
                     [-0.3,   np.nan, -0.3],
                     [-0.3,   -0.3,   -0.4]],

                    [[np.nan, np.nan, -0.3],
                     [-0.2,   -0.3,   -0.7],
                     [-0.3,   -0.3,   -0.3]],

                    [[-0.1,   -0.3,   np.nan],
                     [-0.2,   -0.3,   np.nan],
                     [-0.1,   np.nan, np.nan]]])

I want to compute a per-pixel linear regression and obtain R-squared, P-values, intercepts and slopes for each xy pixel in y_array, with values for each timestep in x_array as my independent variable.

I can reshape to get the data in a form to input it into np.polyfit which is vectorised and fast:

# Reshape so rows = number of time-steps and columns = pixels:
y_array_reshaped = y_array.reshape(len(y_array), -1)

# Do a first-degree polyfit
np.polyfit(x_array, y_array_reshaped, 1)

However, this ignores pixels that contain any NaN values (np.polyfit does not support NaN values), and does not calculate the statistics I require (R-squared, P-values, intercepts and slopes).

The answer here uses scipy.stats import linregress which does calculate the statistics I need, and suggests avoiding NaN issues by masking out these NaN values. However, this example is for two 1D arrays, and I can't work out how to apply a similar masking approach to my case where each column in y_array_reshaped will have a different set of NaN values.

My question: How can I calculate regression statistics for each pixel in a large multidimensional array (300 x 3000 x 3000) containing many NaN values in a reasonably fast, vectorised way?

Desired result: A 3 x 3 array of regression statistic values (e.g. R-squared) for each pixel in y_array, even if that pixel contains NaN values at some point in the time series

  • 1
    This blogpost looks like it describes what you're looking for.
    – shoyer
    Commented Aug 31, 2018 at 21:43
  • This is a great answer, and works ridiculously fast: several milliseconds for the example above. If you want to leave a slightly more detailed answer linking the blog post and explaining why it answers the question, I'd happily mark it as accepted! Commented Sep 3, 2018 at 3:09

5 Answers 5


This blog post mentioned in the comments above contains an incredibly fast vectorized function for cross-correlation, covariance, and regression for multi-dimensional data in Python. It produces all of the regression outputs I need, and does so in milliseconds as it relies entirely on simple vectorised array operations in xarray.

May 2024 update: I've updated the function to ensure it function correctly accounts for different numbers of NaN values in each pixel, and to correctly calculate P-values for different alternative hypotheses (thanks big-zhao!):

def xr_regression(x, y, lag_x=0, lag_y=0, dim="time", alternative="two-sided"):
    Takes two xr.Datarrays of any dimensions (input data could be a 1D
    time series, or for example, have three dimensions e.g. time, lat,
    lon), and returns covariance, correlation, coefficient of
    determination, regression slope, intercept, p-value and standard
    error, and number of valid observations (n) between the two datasets
    along their aligned first dimension.

    Datasets can be provided in any order, but note that the regression
    slope and intercept will be calculated for y with respect to x.

    Inspired by:

    x, y : xarray DataArray
        Two xarray DataArrays with any number of dimensions, both
        sharing the same first dimension
    lag_x, lag_y : int, optional
        Optional integers giving lag values to assign to either of the
        data, with lagx shifting x, and lagy shifting y with the
        specified lag amount.
    dim : str, optional
        An optional string giving the name of the dimension on which to
        align (and optionally lag) datasets. The default is 'time'.
    alternative : string, optional
        Defines the alternative hypothesis. Default is 'two-sided'.
        The following options are available:

        * 'two-sided': slope of the regression line is nonzero
        * 'less': slope of the regression line is less than zero
        * 'greater':  slope of the regression line is greater than zero

    regression_ds : xarray.Dataset
        A dataset comparing the two input datasets along their aligned
        dimension, containing variables including covariance, correlation,
        coefficient of determination, regression slope, intercept,
        p-value and standard error, and number of valid observations (n).


    # Shift x and y data if lags are specified
    if lag_x != 0:
        # If x lags y by 1, x must be shifted 1 step backwards. But as
        # the 'zero-th' value is nonexistant, xarray assigns it as
        # invalid (nan). Hence it needs to be dropped
        x = x.shift(**{dim: -lag_x}).dropna(dim=dim)

        # Next re-align the two datasets so that y adjusts to the
        # changed coordinates of x
        x, y = xr.align(x, y)

    if lag_y != 0:
        y = y.shift(**{dim: -lag_y}).dropna(dim=dim)

    # Ensure that the data are properly aligned to each other.
    x, y = xr.align(x, y)

    # Compute data length, mean and standard deviation along dim
    n = y.notnull().sum(dim=dim)
    xmean = x.mean(dim=dim)
    ymean = y.mean(dim=dim)
    xstd = x.std(dim=dim)
    ystd = y.std(dim=dim)

    # Compute covariance, correlation and coefficient of determination
    cov = ((x - xmean) * (y - ymean)).sum(dim=dim) / (n)
    cor = cov / (xstd * ystd)
    r2 = cor**2

    # Compute regression slope and intercept
    slope = cov / (xstd**2)
    intercept = ymean - xmean * slope

    # Compute t-statistics and standard error
    tstats = cor * np.sqrt(n - 2) / np.sqrt(1 - cor**2)
    stderr = slope / tstats

    # Calculate p-values for different alternative hypotheses.
    if alternative == "two-sided":
        pval = t.sf(np.abs(tstats), n - 2) * 2
    elif alternative == "greater":
        pval = t.sf(tstats, n - 2)
    elif alternative == "less":
        pval = t.cdf(np.abs(tstats), n - 2)
    # Wrap p-values into an xr.DataArray
    pval = xr.DataArray(pval, dims=cor.dims, coords=cor.coords)

    # Combine into single dataset
    regression_ds = xr.merge(

    return regression_ds

The answer provided here https://hrishichandanpurkar.blogspot.com/2017/09/vectorized-functions-for-correlation.html is absolutely good in that it mostly utilises the great power of numpy vectorization and broadcasting but it assumes the data to be analysed are complete, which is not usually the case in real research cycle. One answer above intended to address the missing data problem but I personally think more codes needs to be updated simply because np.mean() will return nan if there is nan in the data. Fortunately, numpy has provided nanmean(), nanstd(), and so forth for us to use to calculate mean, standard error, and so forth by ignoring nans in the data. Meanwhile, the program in the original blog targets data formatted netCDF. Some might not know this but be more familiar with the raw numpy.array format. Therefore, I provide here a code example showing how to calculate co-variance, correlation coefficients, and so forth between two 3-D dimensional arrays (n-D dimensional is of the same logic). Note that I let x_array to be the indexes of the first dimension of y_array for convenience but x_array can surely be read from outside in real analysis.


def linregress_3D(y_array):
    # y_array is a 3-D array formatted like (time,lon,lat)
    # The purpose of this function is to do linear regression using time series of data over each (lon,lat) grid box with consideration of ignoring np.nan
    # Construct x_array indicating time indexes of y_array, namely the independent variable.
    for i in range(y_array.shape[0]): x_array[i,:,:]=i+1 # This would be fine if time series is not too long. Or we can use i+yr (e.g. 2019).
    # Compute the number of non-nan over each (lon,lat) grid box.
    # Compute mean and standard deviation of time series of x_array and y_array over each (lon,lat) grid box.
    # Compute co-variance between time series of x_array and y_array over each (lon,lat) grid box.
    # Compute correlation coefficients between time series of x_array and y_array over each (lon,lat) grid box.
    # Compute slope between time series of x_array and y_array over each (lon,lat) grid box.
    # Compute intercept between time series of x_array and y_array over each (lon,lat) grid box.
    # Compute tstats, stderr, and p_val between time series of x_array and y_array over each (lon,lat) grid box.
    from scipy.stats import t
    # Compute r_square and rmse between time series of x_array and y_array over each (lon,lat) grid box.
    # r_square also equals to cor**2 in 1-variable lineare regression analysis, which can be used for checking.
    # Do further filteration if needed (e.g. We stipulate at least 3 data records are needed to do regression analysis) and return values
    n=n*1.0 # convert n from integer to float to enable later use of np.nan
    return n,slope,intercept,p_val,r_square,rmse

Sample output

I have used this program to test two 3-D arrays with 227x3601x6301 pixels and it completed the work within 20 minutes, each less than 10 minutes.


I'm not sure how this would scale up (perhaps you could use dask), but here is a pretty straightforward way to do this with a pandas DataFrame using the apply method:

import pandas as pd
import numpy as np
from scipy.stats import linregress

# Independent variable: four time-steps of 1-dimensional data 
x_array = np.array([0.5, 0.2, 0.4, 0.4])

# Dependent variable: four time-steps of 3x3 spatial data
y_array = np.array([[[-0.2,   -0.2,   -0.3],
                     [-0.3,   -0.2,   -0.3],
                     [-0.3,   -0.4,   -0.4]],

                    [[-0.2,   -0.2,   -0.4],
                     [-0.3,   np.nan, -0.3],
                     [-0.3,   -0.3,   -0.4]],

                    [[np.nan, np.nan, -0.3],
                     [-0.2,   -0.3,   -0.7],
                     [-0.3,   -0.3,   -0.3]],

                    [[-0.1,   -0.3,   np.nan],
                     [-0.2,   -0.3,   np.nan],
                     [-0.1,   np.nan, np.nan]]])

def lin_regress(col):
    "Mask nulls and apply stats.linregress"
    col = col.loc[~pd.isnull(col)]
    return linregress(col.index.tolist(), col)

# Build the DataFrame (each index represents a pixel)
df = pd.DataFrame(y_array.reshape(len(y_array), -1), index=x_array.tolist())

# Apply a our custom linregress wrapper to each function, split the tuple into separate columns
final_df = df.apply(lin_regress).apply(pd.Series)

# Name the index and columns to make this easier to read
final_df.columns, final_df.index.name = 'slope, intercept, r_value, p_value, std_err'.split(', '), 'pixel_number'



                 slope  intercept   r_value       p_value   std_err
0             0.071429  -0.192857  0.188982  8.789623e-01  0.371154
1            -0.071429  -0.207143 -0.188982  8.789623e-01  0.371154
2             0.357143  -0.464286  0.944911  2.122956e-01  0.123718
3             0.105263  -0.289474  0.229416  7.705843e-01  0.315789
4             1.000000  -0.700000  1.000000  9.003163e-11  0.000000
5            -0.285714  -0.328571 -0.188982  8.789623e-01  1.484615
6             0.105263  -0.289474  0.132453  8.675468e-01  0.557000
7            -0.285714  -0.228571 -0.755929  4.543711e-01  0.247436
8             0.071429  -0.392857  0.188982  8.789623e-01  0.371154

At numpy level , you can use np.vectorize.

First define the tricky part for each set of data :

def compute(x,y):
        return linregress(x[mask],y[mask])

Then define the function which will crunch your data:

comp = np.vectorize(compute,signature="(k),(k)->(),(),(),(),()")

Then apply, reorganizing data to follow broadcasting rules:

res = comp(x_array,rollaxis(y_array,0,3))



Now final[i,j] contains the five parameters returned by linregress for the pixel (i,j) .

It's roughly equivalent than the pandas method answer, but 2.5 X faster .
It takes about 5 seconds for a 300x(100x100 image) problem, so count an hour for yours. I don't think it's easy to do better, since the time is essentially spent in the linregress function.


I read the answer from Robbie, and it was great; it worked well with my projects. However, there may be a small improvement needed in the calculation of P-values as follows:

pval = t.sf(np.abs(tstats['var'].values),n['var'].values - 2) * 2 # two-sided
pval = t.sf(tstats['var'].values, n['var'].values - 2) # greater
pval = t.cdf(np.abs(tstats['var'].values), n['var'].values - 2) # less

# if alternative == 'less':
#     prob = distributions.t.cdf(t, df)
# elif alternative == 'greater':
#     prob = distributions.t.sf(t, df)
# elif alternative == 'two-sided':
#     prob = 2 * distributions.t.sf(np.abs(t), df)

This approach references the handling of t-tests in the SciPy package. I have only verified the correctness for two-sided tests. For one-tailed tests, I simply replicated the source code from the SciPy package, which I have pasted below. I hope this is helpful.

This adjustment is necessary because an error will be raised in the newer version of xarray. Emphasizing np.abs(tstats) may be very important for the correct calculation of P-values! Anyway, such a modification works well for me.

  • Great suggestion - I've updated my original answer to use your code! Commented May 15 at 1:18

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.