# Efficient online linear regression algorithm in python

I got a 2-D dataset with two columns `x` and `y`. I would like to get the linear regression coefficients and interception dynamically when new data feed in. Using scikit-learn I could calculate all current available data like this:

``````from sklearn.linear_model import LinearRegression
regr = LinearRegression()
x = np.arange(100)
y = np.arange(100)+10*np.random.random_sample((100,))
regr.fit(x,y)
print(regr.coef_)
print(regr.intercept_)
``````

However, I got quite big dataset (more than 10k rows in total) and I want to calculate coefficient and intercept as fast as possible whenever there's new rows coming in. Currently calculate 10k rows takes about 600 microseconds, and I want to accelerate this process.

Scikit-learn looks like does not have online update function for linear regression module. Is there any better ways to do this?

• In sklearn, only estimators noted here have the capability of online learning. Aug 29, 2018 at 5:51
• @VivekKumar Is there any other formula or package can solve this? Aug 29, 2018 at 5:52
• sklearn.linear_model.SGDRegressor is Linear regression, but instead of using least squares method, its using Gradient decent. You should give it a try and see if your output remains close enough (or at least the "loss" is the same), plus SGD (Stochastic Gradient Decent) is much faster on big data sets with big dimensions of features. scikit-learn.org/stable/modules/generated/… Aug 29, 2018 at 6:11

I've found solution from this paper: updating simple linear regression. The implementation is as below:

``````def lr(x_avg,y_avg,Sxy,Sx,n,new_x,new_y):
"""
x_avg: average of previous x, if no previous sample, set to 0
y_avg: average of previous y, if no previous sample, set to 0
Sxy: covariance of previous x and y, if no previous sample, set to 0
Sx: variance of previous x, if no previous sample, set to 0
n: number of previous samples
new_x: new incoming 1-D numpy array x
new_y: new incoming 1-D numpy array x
"""
new_n = n + len(new_x)

new_x_avg = (x_avg*n + np.sum(new_x))/new_n
new_y_avg = (y_avg*n + np.sum(new_y))/new_n

if n > 0:
x_star = (x_avg*np.sqrt(n) + new_x_avg*np.sqrt(new_n))/(np.sqrt(n)+np.sqrt(new_n))
y_star = (y_avg*np.sqrt(n) + new_y_avg*np.sqrt(new_n))/(np.sqrt(n)+np.sqrt(new_n))
elif n == 0:
x_star = new_x_avg
y_star = new_y_avg
else:
raise ValueError

new_Sx = Sx + np.sum((new_x-x_star)**2)
new_Sxy = Sxy + np.sum((new_x-x_star).reshape(-1) * (new_y-y_star).reshape(-1))

beta = new_Sxy/new_Sx
alpha = new_y_avg - beta * new_x_avg
return new_Sxy, new_Sx, new_n, alpha, beta, new_x_avg, new_y_avg
``````

Performance comparison:

Scikit learn version that calculate 10k samples altogether.

``````from sklearn.linear_model import LinearRegression
x = np.arange(10000).reshape(-1,1)
y = np.arange(10000)+100*np.random.random_sample((10000,))
regr = LinearRegression()
%timeit regr.fit(x,y)
# 419 µs ± 14.6 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
``````

My version assume 9k sample is already calculated:

``````Sxy, Sx, n, alpha, beta, new_x_avg, new_y_avg = lr(0, 0, 0, 0, 0, x.reshape(-1,1)[:9000], y[:9000])
new_x, new_y = x.reshape(-1,1)[9000:], y[9000:]
%timeit lr(new_x_avg, new_y_avg, Sxy,Sx,n,new_x, new_y)
# 38.7 µs ± 1.31 µs per loop (mean ± std. dev. of 7 runs, 10000 loops each)
``````

10 times faster, which is expected.

• Do you get similar predictions/ coefficients comparing to sklearn? Aug 29, 2018 at 7:09
• @VivekKumar they coefficient and intercept are the same Aug 29, 2018 at 23:04
• Sxy is really n times the covariance, and Sx is really n times the variance of x, is it not? Mar 27, 2021 at 16:15

Nice! Thanks for sharing your findings :) Here is an equivalent implementation of this solution written with dot products:

``````class SimpleLinearRegressor(object):
def __init__(self):
self.dots = np.zeros(5)
self.intercept = None
self.slope = None

def update(self, x: np.ndarray, y: np.ndarray):
self.dots += np.array(
[
x.shape,
x.sum(),
y.sum(),
np.dot(x, x),
np.dot(x, y),
]
)
size, sum_x, sum_y, sum_xx, sum_xy = self.dots
det = size * sum_xx - sum_x ** 2
if det > 1e-10:  # determinant may be zero initially
self.intercept = (sum_xx * sum_y - sum_xy * sum_x) / det
self.slope = (sum_xy * size - sum_x * sum_y) / det
``````

When working with time series data, we can extend this idea to do sliding window regression with a soft (EMA-like) window.

You can use accelerated libraries that implement faster algorithms - particularly https://github.com/intel/scikit-learn-intelex

For linear regression you would get much better performance

First install package

``````pip install scikit-learn-intelex
``````

``````from sklearnex import patch_sklearn