How do you find the top correlations in a correlation matrix with Pandas? There are many answers on how to do this with R (Show correlations as an ordered list, not as a large matrix or Efficient way to get highly correlated pairs from large data set in Python or R), but I am wondering how to do it with pandas? In my case the matrix is 4460x4460, so can't do it visually.
15 Answers
You can use DataFrame.values
to get an numpy array of the data and then use NumPy functions such as argsort()
to get the most correlated pairs.
But if you want to do this in pandas, you can unstack
and sort the DataFrame:
import pandas as pd
import numpy as np
shape = (50, 4460)
data = np.random.normal(size=shape)
data[:, 1000] += data[:, 2000]
df = pd.DataFrame(data)
c = df.corr().abs()
s = c.unstack()
so = s.sort_values(kind="quicksort")
print so[4470:4460]
Here is the output:
2192 1522 0.636198
1522 2192 0.636198
3677 2027 0.641817
2027 3677 0.641817
242 130 0.646760
130 242 0.646760
1171 2733 0.670048
2733 1171 0.670048
1000 2000 0.742340
2000 1000 0.742340
dtype: float64

11With Pandas v 0.17.0 and higher you should use sort_values instead of order. You will get an error if you try using the order method.– Friendm1Sep 5, 2017 at 16:06

1Also, in order to get the highly correlated pairs, you need to use
sort_values(ascending=False)
.– sotmotDec 30, 2020 at 11:43 
"numpy array of the data and then use NumPy functions such as argsort() to get the most correlated pairs."  could you show an example of this too?– LevonFeb 28, 2021 at 20:50

All these solutions using
sort_values
need aby
argument now. But what to use if I want to sort all dataframe values, not just one column? Apr 28, 2022 at 18:06
@HYRY's answer is perfect. Just building on that answer by adding a bit more logic to avoid duplicate and self correlations and proper sorting:
import pandas as pd
d = {'x1': [1, 4, 4, 5, 6],
'x2': [0, 0, 8, 2, 4],
'x3': [2, 8, 8, 10, 12],
'x4': [1, 4, 4, 4, 5]}
df = pd.DataFrame(data = d)
print("Data Frame")
print(df)
print()
print("Correlation Matrix")
print(df.corr())
print()
def get_redundant_pairs(df):
'''Get diagonal and lower triangular pairs of correlation matrix'''
pairs_to_drop = set()
cols = df.columns
for i in range(0, df.shape[1]):
for j in range(0, i+1):
pairs_to_drop.add((cols[i], cols[j]))
return pairs_to_drop
def get_top_abs_correlations(df, n=5):
au_corr = df.corr().abs().unstack()
labels_to_drop = get_redundant_pairs(df)
au_corr = au_corr.drop(labels=labels_to_drop).sort_values(ascending=False)
return au_corr[0:n]
print("Top Absolute Correlations")
print(get_top_abs_correlations(df, 3))
That gives the following output:
Data Frame
x1 x2 x3 x4
0 1 0 2 1
1 4 0 8 4
2 4 8 8 4
3 5 2 10 4
4 6 4 12 5
Correlation Matrix
x1 x2 x3 x4
x1 1.000000 0.399298 1.000000 0.969248
x2 0.399298 1.000000 0.399298 0.472866
x3 1.000000 0.399298 1.000000 0.969248
x4 0.969248 0.472866 0.969248 1.000000
Top Absolute Correlations
x1 x3 1.000000
x3 x4 0.969248
x1 x4 0.969248
dtype: float64

3instead of get_redundant_pairs(df), you can use "cor.loc[:,:] = np.tril(cor.values, k=1)" and then "cor = cor[cor>0]"– SarahMar 21, 2017 at 5:59

2I'm getting erro for line
au_corr = au_corr.drop(labels=labels_to_drop).sort_values(ascending=False)
:#  partial selection or nonunique index
Jul 6, 2018 at 12:46
Few lines solution without redundant pairs of variables:
corr_matrix = df.corr().abs()
#the matrix is symmetric so we need to extract upper triangle matrix without diagonal (k = 1)
sol = (corr_matrix.where(np.triu(np.ones(corr_matrix.shape), k=1).astype(bool))
.stack()
.sort_values(ascending=False))
#first element of sol series is the pair with the biggest correlation
Then you can iterate through names of variables pairs (which are pandas.Series multiindexes) and theirs values like this:
for index, value in sol.items():
# do some staff

4probably a bad idea to use
os
as a variable name because it masks theos
fromimport os
if available in the code– ShadiAug 29, 2018 at 7:29 
1

1

1

2
Combining some features of @HYRY and @arun's answers, you can print the top correlations for dataframe df
in a single line using:
df.corr().unstack().sort_values().drop_duplicates()
Note: the one downside is if you have 1.0 correlations that are not one variable to itself, the drop_duplicates()
addition would remove them

1

@shadi yes, you are correct. However, we assume the only correlations which will be identically equal are correlations of 1.0 (i.e. a variable with itself). Chances are that the correlation for two unique pairs of variables (i.e.
v1
tov2
andv3
tov4
) would not be exactly the same Aug 29, 2018 at 21:42 
Definitely my favoirite, simplicity itself. in my usage, I filtered first for high corrleations Aug 22, 2020 at 12:18

1This is good. I would add .sort_values(ascending = False) to improve visibility Oct 29, 2022 at 14:22
I liked Addison Klinke's post the most, as being the simplest, but used Wojciech Moszczyńsk’s suggestion for filtering and charting, but extended the filter to avoid absolute values, so given a large correlation matrix, filter it, chart it, and then flatten it:
Created, Filtered and Charted
dfCorr = df.corr()
filteredDf = dfCorr[((dfCorr >= .5)  (dfCorr <= .5)) & (dfCorr !=1.000)]
plt.figure(figsize=(30,10))
sn.heatmap(filteredDf, annot=True, cmap="Reds")
plt.show()
Function
In the end, I created a small function to create the correlation matrix, filter it, and then flatten it. As an idea, it could easily be extended, e.g., asymmetric upper and lower bounds, etc.
def corrFilter(x: pd.DataFrame, bound: float):
xCorr = x.corr()
xFiltered = xCorr[((xCorr >= bound)  (xCorr <= bound)) & (xCorr !=1.000)]
xFlattened = xFiltered.unstack().sort_values().drop_duplicates()
return xFlattened
corrFilter(df, .7)
FollowUp
Eventually, I refined the functions
# Returns correlation matrix
def corrFilter(x: pd.DataFrame, bound: float):
xCorr = x.corr()
xFiltered = xCorr[((xCorr >= bound)  (xCorr <= bound)) & (xCorr !=1.000)]
return xFiltered
# flattens correlation matrix with bounds
def corrFilterFlattened(x: pd.DataFrame, bound: float):
xFiltered = corrFilter(x, bound)
xFlattened = xFiltered.unstack().sort_values().drop_duplicates()
return xFlattened
# Returns correlation for a variable from flattened correlation matrix
def filterForLabels(df: pd.DataFrame, label):
try:
sideLeft = df[label,]
except:
sideLeft = pd.DataFrame()
try:
sideRight = df[:,label]
except:
sideRight = pd.DataFrame()
if sideLeft.empty and sideRight.empty:
return pd.DataFrame()
elif sideLeft.empty:
concat = sideRight.to_frame()
concat.rename(columns={0:'Corr'},inplace=True)
return concat
elif sideRight.empty:
concat = sideLeft.to_frame()
concat.rename(columns={0:'Corr'},inplace=True)
return concat
else:
concat = pd.concat([sideLeft,sideRight], axis=1)
concat["Corr"] = concat[0].fillna(0) + concat[1].fillna(0)
concat.drop(columns=[0,1], inplace=True)
return concat

how to remove the very last one? HofstederPowerDx and Hofsteder PowerDx are the same variables, right?– LucOct 20, 2020 at 9:29

one can use .dropna() in the functions. I just tried it in VS Code and it works, where I use the first equation to create and filter the correlation matrix, and another to flatten it. If you use that, you might want to experiment with removing .dropduplicates() to see whether you need both .dropna() and dropduplicates(). Oct 21, 2020 at 13:16

A notebook that includes this code and some other improvements is here: github.com/JamesIgoe/GoogleFitAnalysis Oct 21, 2020 at 13:39

I believe the code is summing up the r value twice here, please correct if I am wrong, Apr 17, 2021 at 5:52

@Sidrah  I did some basic spot checking and it seems to be accurate, but if you've tried to use it and it is doubling fro you, let me know. Apr 18, 2021 at 18:04
Use the code below to view the correlations in the descending order.
# See the correlations in descending order
corr = df.corr() # df is the pandas dataframe
c1 = corr.abs().unstack()
c1.sort_values(ascending = False)

1

You can do graphically according to this simple code by substituting your data.
corr = df.corr()
kot = corr[corr>=.9]
plt.figure(figsize=(12,8))
sns.heatmap(kot, cmap="Greens")

3Would I want something like
kot = corr[abs(corr) >= 0.9]
in case of strong negative correlations too?– LevonFeb 28, 2021 at 20:42
Combining most the answers above into a short snippet:
def top_entries(df):
mat = df.corr().abs()
# Remove duplicate and identity entries
mat.loc[:,:] = np.tril(mat.values, k=1)
mat = mat[mat>0]
# Unstack, sort ascending, and reset the index, so features are in columns
# instead of indexes (allowing e.g. a pretty print in Jupyter).
# Also rename these it for good measure.
return (mat.unstack()
.sort_values(ascending=False)
.reset_index()
.rename(columns={
"level_0": "feature_a",
"level_1": "feature_b",
0: "correlation"
}))
Lot's of good answers here. The easiest way I found was a combination of some of the answers above.
corr = corr.where(np.triu(np.ones(corr.shape), k=1).astype(np.bool))
corr = corr.unstack().transpose()\
.sort_values(by='column', ascending=False)\
.dropna()
The following function should do the trick. This implementation
 Removes self correlations
 Removes duplicates
 Enables the selection of top N highest correlated features
and it is also configurable so that you can keep both the self correlations as well as the duplicates. You can also to report as many feature pairs as you wish.
def get_feature_correlation(df, top_n=None, corr_method='spearman',
remove_duplicates=True, remove_self_correlations=True):
"""
Compute the feature correlation and sort feature pairs based on their correlation
:param df: The dataframe with the predictor variables
:type df: pandas.core.frame.DataFrame
:param top_n: Top N feature pairs to be reported (if None, all of the pairs will be returned)
:param corr_method: Correlation compuation method
:type corr_method: str
:param remove_duplicates: Indicates whether duplicate features must be removed
:type remove_duplicates: bool
:param remove_self_correlations: Indicates whether self correlations will be removed
:type remove_self_correlations: bool
:return: pandas.core.frame.DataFrame
"""
corr_matrix_abs = df.corr(method=corr_method).abs()
corr_matrix_abs_us = corr_matrix_abs.unstack()
sorted_correlated_features = corr_matrix_abs_us \
.sort_values(kind="quicksort", ascending=False) \
.reset_index()
# Remove comparisons of the same feature
if remove_self_correlations:
sorted_correlated_features = sorted_correlated_features[
(sorted_correlated_features.level_0 != sorted_correlated_features.level_1)
]
# Remove duplicates
if remove_duplicates:
sorted_correlated_features = sorted_correlated_features.iloc[:2:2]
# Create meaningful names for the columns
sorted_correlated_features.columns = ['Feature 1', 'Feature 2', 'Correlation (abs)']
if top_n:
return sorted_correlated_features[:top_n]
return sorted_correlated_features

1Maybe make abs() a parameter. Other than that, excellent function. Very reusable and well documented.– natbusaFeb 27, 2022 at 11:12
Use itertools.combinations
to get all unique correlations from pandas own correlation matrix .corr()
, generate list of lists and feed it back into a DataFrame in order to use '.sort_values'. Set ascending = True
to display lowest correlations on top
corrank
takes a DataFrame as argument because it requires .corr()
.
def corrank(X: pandas.DataFrame):
import itertools
df = pd.DataFrame([[(i,j),X.corr().loc[i,j]] for i,j in list(itertools.combinations(X.corr(), 2))],columns=['pairs','corr'])
print(df.sort_values(by='corr',ascending=False))
corrank(X) # prints a descending list of correlation pair (Max on top)

3While this code snippet may be the solution, including an explanation really helps to improve the quality of your post. Remember that you are answering the question for readers in the future, and those people might not know the reasons for your code suggestion.– haindlSep 22, 2017 at 11:06
I didn't want to unstack
or overcomplicate this issue, since I just wanted to drop some highly correlated features as part of a feature selection phase.
So I ended up with the following simplified solution:
# map features to their absolute correlation values
corr = features.corr().abs()
# set equality (self correlation) as zero
corr[corr == 1] = 0
# of each feature, find the max correlation
# and sort the resulting array in ascending order
corr_cols = corr.max().sort_values(ascending=False)
# display the highly correlated features
display(corr_cols[corr_cols > 0.8])
In this case, if you want to drop correlated features, you may map through the filtered corr_cols
array and remove the oddindexed (or evenindexed) ones.

This just gives one index (feature) and not something like feature1 feature2 0.98. Change line
corr_cols = corr.max().sort_values(ascending=False)
tocorr_cols = corr.unstack()
– aunsidOct 8, 2019 at 20:17 
Well the OP did not specify a correlation shape. As I mentioned, I didn't want to unstack, so I just brought a different approach. Each correlation pair is represented by 2 rows, in my suggested code. But thanks for the helpful comment! Oct 9, 2019 at 23:10
I was trying some of the solutions here but then I actually came up with my own one. I hope this might be useful for the next one so I share it here:
def sort_correlation_matrix(correlation_matrix):
cor = correlation_matrix.abs()
top_col = cor[cor.columns[0]][1:]
top_col = top_col.sort_values(ascending=False)
ordered_columns = [cor.columns[0]] + top_col.index.tolist()
return correlation_matrix[ordered_columns].reindex(ordered_columns)
This is a improve code from @MiFi. This one order in abs but not excluding the negative values.
def top_correlation (df,n):
corr_matrix = df.corr()
correlation = (corr_matrix.where(np.triu(np.ones(corr_matrix.shape), k=1).astype(np.bool))
.stack()
.sort_values(ascending=False))
correlation = pd.DataFrame(correlation).reset_index()
correlation.columns=["Variable_1","Variable_2","Correlacion"]
correlation = correlation.reindex(correlation.Correlacion.abs().sort_values(ascending=False).index).reset_index().drop(["index"],axis=1)
return correlation.head(n)
top_correlation(ANYDATA,10)
simple is better
from collections import defaultdict
res = defaultdict(dict)
corr = returns.corr().replace(1, 1)
names = list(corr)
for name in names:
idx = corr[name].argmax()
max_pairwise_name = names[idx]
res[name][max_pairwise_name] = corr.loc[max_pairwisename, name]
Now res contains the maximum pairwise correlation for each pair