I know I could implement a root mean squared error function like this:

def rmse(predictions, targets):
    return np.sqrt(((predictions - targets) ** 2).mean())

What I'm looking for if this rmse function is implemented in a library somewhere, perhaps in scipy or scikit-learn?

  • 3
    you wrote the function right there. Most likely if the function is that simple to write, it is not going to be in a library. you're better off creating a director called modules and just putting useful functions in it and adding it to your path – Ryan Saxe Jun 19 '13 at 17:27
  • 3
    I think this is a pretty good question and don't understand the downvote (+1 for me as I'd prefer to use a library implementation over rolling out my own). – NPE Jun 19 '13 at 17:29
  • 6
    @RyanSaxe I disagree. I would find it a lot more reassuring to call a library function than to reimplement it myself. For instance, I wrote .sum() instead of .mean() first by mistake. In addition, I suppose this function is used so much that I see no reason why it shouldn't be available as a library function. – siamii Jun 19 '13 at 17:30
  • 1
    @siamii: I understand that 100%, I was just speculating at the reason why this kind of function may not be in scipy. If it is I cannot seem to find it – Ryan Saxe Jun 19 '13 at 17:35
  • To people who tried this and it didn't work: if predictions and targets are for example of type int16 the square might overflow (giving negative numbers). So you might need an .astype('int') or .astype('double') before using the square, like np.sqrt(((predictions - targets).astype('double') ** 2).mean()). – John Jul 26 at 8:40

sklearn.metrics has a mean_squared_error function. The RMSE is just the square root of whatever it returns.

from sklearn.metrics import mean_squared_error
from math import sqrt

rms = sqrt(mean_squared_error(y_actual, y_predicted))

What is RMSE? Also known as MSE or RMS. What problem does it solve?

If you understand RMSE: (Root mean squared error), MSE: (Mean Squared Error) and RMS: (Root Mean Squared), then asking for a library to calculate it for you is unnecessary over-engineering. All these metrics are a single line of python code at most 2 inches long. The three metrics rmse, mse and rms are all conceptually identical.

RMSE answers the question: "How similar, on average, are the numbers in list1 to list2?". The two lists must be the same size. I want to "wash out the noise between any two given elements, wash out the size of the data collected, and get a single number feel for change over time".

Intuition and ELI5 for RMSE:

Imagine you are learning to throw darts at a dart board. Every day you practice for one hour. You want to figure out if you are getting better or getting worse. So every day you make 10 throws and measure the distance between the bullseye and where your dart hit.

You make a list of those numbers. Use the root mean squared error between the distances at day 1 and a list containing all zeros. Do the same on the 2nd and nth days. What you will get is a single number that hopefully decreases over time. When your RMSE number is zero, you hit bullseyes every time. If the number goes up, you are getting worse.

Example in calculating root mean squared error in python:

import numpy as np
d = [0.000, 0.166, 0.333]
p = [0.000, 0.254, 0.998]

print("d is: " + str(["%.8f" % elem for elem in d]))
print("p is: " + str(["%.8f" % elem for elem in p]))

def rmse(predictions, targets):
    return np.sqrt(((predictions - targets) ** 2).mean())

rmse_val = rmse(np.array(d), np.array(p))
print("rms error is: " + str(rmse_val))

Which prints:

d is: ['0.00000000', '0.16600000', '0.33300000']
p is: ['0.00000000', '0.25400000', '0.99800000']
rms error between lists d and p is: 0.387284994115

The mathematical notation:

enter image description here

The rmse done in small steps so it can be understood:

def rmse(predictions, targets):

    differences = predictions - targets                       #the DIFFERENCEs.

    differences_squared = differences ** 2                    #the SQUAREs of ^

    mean_of_differences_squared = differences_squared.mean()  #the MEAN of ^

    rmse_val = np.sqrt(mean_of_differences_squared)           #ROOT of ^

    return rmse_val                                           #get the ^

How does every step of RMSE work:

Subtracting one number from another gives you the distance between them.

8 - 5 = 3         #distance between 8 and 5 is 3
-20 - 10 = -30    #distance between -20 and 10 is +30

If you multiply any number times itself, the result is always positive because negative times negative is positive:

3*3     = 9   = positive
-30*-30 = 900 = positive

Add them all up, but wait, then an array with many elements would have a larger error than a small array, so average them by the number of elements.

But wait, we squared them all earlier to force them positive. Undo the damage with a square root!

That leaves you with a single number that represents, on average, the distance between every value of list1 to it's corresponding element value of list2.

If the RMSE value goes down over time we are happy because variance is decreasing.

RMSE isn't the most accurate line fitting strategy, total least squares is:

Root mean squared error measures the vertical distance between the point and the line, so if your data is shaped like a banana, flat near the bottom and steep near the top, then the RMSE will report greater distances to points high, but short distances to points low when in fact the distances are equivalent. This causes a skew where the line prefers to be closer to points high than low.

If this is a problem the total least squares method fixes this: https://mubaris.com/2017-09-28/linear-regression-from-scratch

Gotchas that can break this RMSE function:

If there are nulls or infinity in either input list, then output rmse value is is going to not make sense. There are three strategies to deal with nulls / missing values / infinities in either list: Ignore that component, zero it out or add a best guess or a uniform random noise to all timesteps. Each remedy has its pros and cons depending on what your data means. In general ignoring any component with a missing value is preferred, but this biases the RMSE toward zero making you think performance has improved when it really hasn't. Adding random noise on a best guess could be preferred if there are lots of missing values.

In order to guarantee relative correctness of the RMSE output, you must eliminate all nulls/infinites from the input.

RMSE has zero tolerance for outlier data points which don't belong

Root mean squared error squares relies on all data being right and all are counted as equal. That means one stray point that's way out in left field is going to totally ruin the whole calculation. To handle outlier data points and dismiss their tremendous influence after a certain threshold, see Robust estimators that build in a threshold for dismissal of outliers.

This is probably faster?:

n = len(predictions)
rmse = np.linalg.norm(predictions - targets) / np.sqrt(n)

Actually, I did write a bunch of those as utility functions for statsmodels

http://statsmodels.sourceforge.net/devel/tools.html#measure-for-fit-performance-eval-measures

and http://statsmodels.sourceforge.net/devel/generated/statsmodels.tools.eval_measures.rmse.html#statsmodels.tools.eval_measures.rmse

Mostly one or two liners and not much input checking, and mainly intended for easily getting some statistics when comparing arrays. But they have unit tests for the axis arguments, because that's where I sometimes make sloppy mistakes.

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