127

My problem:

I have a dataset which is a large JSON file. I read it and store it in the trainList variable.

Next, I pre-process it - in order to be able to work with it.

Once I have done that I start the classification:

  1. I use the kfold cross validation method in order to obtain the mean accuracy and train a classifier.
  2. I make the predictions and obtain the accuracy & confusion matrix of that fold.
  3. After this, I would like to obtain the True Positive(TP), True Negative(TN), False Positive(FP) and False Negative(FN) values. I'll use these parameters to obtain the Sensitivity and Specificity.

Finally, I would use this to put in HTML in order to show a chart with the TPs of each label.

Code:

The variables I have for the moment:

trainList #It is a list with all the data of my dataset in JSON form
labelList #It is a list with all the labels of my data 

Most part of the method:

#I transform the data from JSON form to a numerical one
X=vec.fit_transform(trainList)

#I scale the matrix (don't know why but without it, it makes an error)
X=preprocessing.scale(X.toarray())

#I generate a KFold in order to make cross validation
kf = KFold(len(X), n_folds=10, indices=True, shuffle=True, random_state=1)

#I start the cross validation
for train_indices, test_indices in kf:
    X_train=[X[ii] for ii in train_indices]
    X_test=[X[ii] for ii in test_indices]
    y_train=[listaLabels[ii] for ii in train_indices]
    y_test=[listaLabels[ii] for ii in test_indices]

    #I train the classifier
    trained=qda.fit(X_train,y_train)

    #I make the predictions
    predicted=qda.predict(X_test)

    #I obtain the accuracy of this fold
    ac=accuracy_score(predicted,y_test)

    #I obtain the confusion matrix
    cm=confusion_matrix(y_test, predicted)

    #I should calculate the TP,TN, FP and FN 
    #I don't know how to continue

20 Answers 20

202

For the multi-class case, everything you need can be found from the confusion matrix. For example, if your confusion matrix looks like this:

confusion matrix

Then what you're looking for, per class, can be found like this:

overlay

Using pandas/numpy, you can do this for all classes at once like so:

FP = confusion_matrix.sum(axis=0) - np.diag(confusion_matrix)  
FN = confusion_matrix.sum(axis=1) - np.diag(confusion_matrix)
TP = np.diag(confusion_matrix)
TN = confusion_matrix.values.sum() - (FP + FN + TP)

# Sensitivity, hit rate, recall, or true positive rate
TPR = TP/(TP+FN)
# Specificity or true negative rate
TNR = TN/(TN+FP) 
# Precision or positive predictive value
PPV = TP/(TP+FP)
# Negative predictive value
NPV = TN/(TN+FN)
# Fall out or false positive rate
FPR = FP/(FP+TN)
# False negative rate
FNR = FN/(TP+FN)
# False discovery rate
FDR = FP/(TP+FP)

# Overall accuracy
ACC = (TP+TN)/(TP+FP+FN+TN)
13
  • 4
    when I want to calculate the value of TN, I get this error: 'numpy.ndarray' object has no attribute 'values' I am using python 3.
    – Aizzaac
    Apr 24, 2017 at 13:39
  • 18
    This assumes you are using a pandas DataFrame instance here for the confusion matrix. If you are using a numpy array simply remove the .values part.
    – macKaiver
    Sep 5, 2017 at 7:40
  • 2
    Can anyone explain what is the difference between this accuracy (ACC) and accuracy measured by sklearn.metrics.accuracy_score. Because there is a difference in the result of both results. And by explaining I mean which one is more reliable. Mar 17, 2019 at 20:25
  • 4
    Awesome answer @lucidv01d -- I found myself reusing this code enough times that I wrote a package to provide access to these metrics directly from a pandas DataFrame. Your answer, username and profile page are properly attributed :)
    – Kevin
    Oct 9, 2019 at 0:20
  • 3
    This is a super answer. @lucidc01d can you share how you did the viz for this?
    – ShikharDua
    Oct 11, 2019 at 0:25
75

If you have two lists that have the predicted and actual values; as it appears you do, you can pass them to a function that will calculate TP, FP, TN, FN with something like this:

def perf_measure(y_actual, y_hat):
    TP = 0
    FP = 0
    TN = 0
    FN = 0

    for i in range(len(y_hat)): 
        if y_actual[i]==y_hat[i]==1:
           TP += 1
        if y_hat[i]==1 and y_actual[i]!=y_hat[i]:
           FP += 1
        if y_actual[i]==y_hat[i]==0:
           TN += 1
        if y_hat[i]==0 and y_actual[i]!=y_hat[i]:
           FN += 1

    return(TP, FP, TN, FN)

From here I think you will be able to calculate rates of interest to you, and other performance measure like specificity and sensitivity.

7
60

According to scikit-learn documentation,

http://scikit-learn.org/stable/modules/generated/sklearn.metrics.confusion_matrix.html#sklearn.metrics.confusion_matrix

By definition a confusion matrix C is such that C[i, j] is equal to the number of observations known to be in group i but predicted to be in group j.

Thus in binary classification, the count of true negatives is C[0,0], false negatives is C[1,0], true positives is C[1,1] and false positives is C[0,1].

CM = confusion_matrix(y_true, y_pred)

TN = CM[0][0]
FN = CM[1][0]
TP = CM[1][1]
FP = CM[0][1]
1
  • 1
    This will give you an index out of bounds error if there is only a single group.
    – Hagbard
    Jun 14, 2021 at 10:26
28

The one liner to get true postives etc. out of the confusion matrix is to ravel it:

from sklearn.metrics import confusion_matrix

y_true = [1, 1, 0, 0]
y_pred = [1, 0, 1, 0]   

tn, fp, fn, tp = confusion_matrix(y_true, y_pred, labels=[0, 1]).ravel()
print(tn, fp, fn, tp)  # 1 1 1 1

One should set the labels parameter in case the data contains only a single case, e.g. only true positives. Setting labels correctly ensures that the confusion matrix has a 2x2 shape.

3
  • This will result in "ValueError: not enough values to unpack (expected 4, got 1)" if there are only values in one group.
    – Hagbard
    Jun 14, 2021 at 10:42
  • That seems surprising - what does your confusion matrix look like? This may be an interesting edge case (true values only representing 1 class). As long as there are real values with labels = 1, I think the confusion matrix will be a 2x2.
    – Dr. Andrew
    Jun 15, 2021 at 8:53
  • 1
    @Hagbard I updated the answer so that it should also work when only a single case is present in the data.
    – Jarno
    Jun 15, 2021 at 9:26
26

You can obtain all of the parameters from the confusion matrix. The structure of the confusion matrix(which is 2X2 matrix) is as follows (assuming the first index is related to the positive label, and the rows are related to the true labels):

TP|FN
FP|TN

So

TP = cm[0][0]
FN = cm[0][1]
FP = cm[1][0]
TN = cm[1][1]

More details at https://en.wikipedia.org/wiki/Confusion_matrix

6
  • In my case the confusion matrix is not 2x2, but 3x3 or 4x4. For example, I can get these two arrays: y_predicted:[0 0 0 0 0 1 1 2 0 2 2 3 2 2 2 2] y_true: [0 0 0 0 0 1 1 2 2 2 2 2 2 2 2 2] And I obtain this confusion matrix: [[5 0 0 0] [0 2 0 0] [1 0 7 1] [0 0 0 0]]
    – Euskalduna
    Jul 10, 2015 at 8:12
  • I assumed binary classification. It appears that there are 3 or 4 classes for your classifier. Jul 10, 2015 at 17:37
  • 2
    For that if you look at the wikipedia link, there is an example given about cats, dogs, and horses. The concept of true positive, true negative etc makes more sense to me in the presence of two classes i.e Positive and negative. For your case, I am not sure what TP, FP means. You can put TP as maybe sum of diagonal elements, but I am not sure. You could assume one classification as positive and all others as negative to compute TP, FP etc for that, but again I am not sure. Jul 10, 2015 at 17:45
  • 2
    Are you sure you don't have the FP and FN locations switched? I thought it was supposed to be [TP, FN],[FP, TN]. This is what is shown on the Wikipedia page also. Mar 14, 2017 at 20:17
  • @ChrisNielsen yes, it was switched - I have edited the answer to be correct
    – emem
    May 11, 2020 at 0:47
9

Just in case some is looking for the same in MULTI-CLASS Example

def perf_measure(y_actual, y_pred):
    class_id = set(y_actual).union(set(y_pred))
    TP = []
    FP = []
    TN = []
    FN = []

    for index ,_id in enumerate(class_id):
        TP.append(0)
        FP.append(0)
        TN.append(0)
        FN.append(0)
        for i in range(len(y_pred)):
            if y_actual[i] == y_pred[i] == _id:
                TP[index] += 1
            if y_pred[i] == _id and y_actual[i] != y_pred[i]:
                FP[index] += 1
            if y_actual[i] == y_pred[i] != _id:
                TN[index] += 1
            if y_pred[i] != _id and y_actual[i] != y_pred[i]:
                FN[index] += 1


    return class_id,TP, FP, TN, FN
1
  • What a beautiful code, thanks bro, this is something need to be appreciated actually Apr 29, 2022 at 1:36
7

In the scikit-learn 'metrics' library there is a confusion_matrix method which gives you the desired output.

You can use any classifier that you want. Here I used the KNeighbors as example.

from sklearn import metrics, neighbors

clf = neighbors.KNeighborsClassifier()

X_test = ...
y_test = ...

expected = y_test
predicted = clf.predict(X_test)

conf_matrix = metrics.confusion_matrix(expected, predicted)

>>> print conf_matrix
>>>  [[1403   87]
     [  56 3159]]

The docs: http://scikit-learn.org/stable/modules/generated/sklearn.metrics.confusion_matrix.html#sklearn.metrics.confusion_matrix

1
  • 2
    So far the most concise response
    – lotrus28
    Apr 16, 2018 at 12:53
6

this works fine
Source - https://scikit-learn.org/stable/modules/generated/sklearn.metrics.confusion_matrix.html

tn, fp, fn, tp = confusion_matrix(y_test, predicted).ravel()
5

I wrote a version that works using only numpy. I hope it helps you.

import numpy as np

def perf_metrics_2X2(yobs, yhat):
    """
    Returns the specificity, sensitivity, positive predictive value, and 
    negative predictive value 
    of a 2X2 table.

    where:
    0 = negative case
    1 = positive case

    Parameters
    ----------
    yobs :  array of positive and negative ``observed`` cases
    yhat : array of positive and negative ``predicted`` cases

    Returns
    -------
    sensitivity  = TP / (TP+FN)
    specificity  = TN / (TN+FP)
    pos_pred_val = TP/ (TP+FP)
    neg_pred_val = TN/ (TN+FN)

    Author: Julio Cardenas-Rodriguez
    """
    TP = np.sum(  yobs[yobs==1] == yhat[yobs==1] )
    TN = np.sum(  yobs[yobs==0] == yhat[yobs==0] )
    FP = np.sum(  yobs[yobs==1] == yhat[yobs==0] )
    FN = np.sum(  yobs[yobs==0] == yhat[yobs==1] )

    sensitivity  = TP / (TP+FN)
    specificity  = TN / (TN+FP)
    pos_pred_val = TP/ (TP+FP)
    neg_pred_val = TN/ (TN+FN)

    return sensitivity, specificity, pos_pred_val, neg_pred_val
0
5

In scikit version 0.22, you can do it like this

from sklearn.metrics import multilabel_confusion_matrix

y_true = ["cat", "ant", "cat", "cat", "ant", "bird"]
y_pred = ["ant", "ant", "cat", "cat", "ant", "cat"]

mcm = multilabel_confusion_matrix(y_true, y_pred,labels=["ant", "bird", "cat"])

tn = mcm[:, 0, 0]
tp = mcm[:, 1, 1]
fn = mcm[:, 1, 0]
fp = mcm[:, 0, 1]
4

you can try sklearn.metrics.classification_report as below:

import sklearn
y_true = [1, 1, 0, 0, 0, 1, 0, 1, 0, 0, 0]
y_pred = [1, 1, 1, 0, 0, 0, 1, 1, 0, 1, 0]

print sklearn.metrics.classification_report(y_true, y_pred)

output:

         precision    recall  f1-score   support

      0       0.80      0.57      0.67         7
      1       0.50      0.75      0.60         4

      avg / total       0.69      0.64      0.64        11
2

if you have more than one classes in your classifier, you might want to use pandas-ml at that part. Confusion Matrix of pandas-ml give more detailed information. check that

RESULT

2

Although it does not relate to scikit-learn, what you could also do is

tp = sum(y_test & pred)
fp = sum(1-y_test & pred ) 
tn = sum(1-y_test & 1-pred)
fn = sum(y_test & 1-pred)
1
  • this is thousands of times faster than the accepted answer and gives the same result
    – Frobot
    Jul 1, 2023 at 17:28
1

I think both of the answers are not fully correct. For example, suppose that we have the following arrays;
y_actual = [1, 1, 0, 0, 0, 1, 0, 1, 0, 0, 0]

y_predic = [1, 1, 1, 0, 0, 0, 1, 1, 0, 1, 0]

If we compute the FP, FN, TP and TN values manually, they should be as follows:

FP: 3 FN: 1 TP: 3 TN: 4

However, if we use the first answer, results are given as follows:

FP: 1 FN: 3 TP: 3 TN: 4

They are not correct, because in the first answer, False Positive should be where actual is 0, but the predicted is 1, not the opposite. It is also same for False Negative.

And, if we use the second answer, the results are computed as follows:

FP: 3 FN: 1 TP: 4 TN: 3

True Positive and True Negative numbers are not correct, they should be opposite.

Am I correct with my computations? Please let me know if I am missing something.

2
  • I think best answer for this quesition is this one: stackoverflow.com/questions/31345724/…
    – ykorkmaz
    Sep 12, 2016 at 16:10
  • I apologise for this silly question, but is the true position of scikit's confusion matrix as follows? Top row TN | FP and bottom row FN | TP? I have been trying to figure out which is which. Maybe the documentation could be written for idiots like me as well? :-)
    – salvu
    Sep 28, 2017 at 23:36
1
#False positive cases
train = pd.merge(X_train, y_train,left_index=True, right_index=True)
y_train_pred = pd.DataFrame(y_train_pred)
y_train_pred.rename(columns={0 :'Predicted'}, inplace=True )
train = train.reset_index(drop=True).merge(y_train_pred.reset_index(drop=True),
left_index=True,right_index=True)
train['FP'] = np.where((train['Banknote']=="Forged") & (train['Predicted']=="Genuine"),1,0)
train[train.FP != 0]
1
  • print("Genuine : Forged") print(quizData['Banknote'].value_counts()['Genuine'], ":", quizData['Banknote'].value_counts()['Forged']) Oct 20, 2020 at 5:03
1
def getTPFPTNFN(y_true, y_pred):
    TP, FP, TN, FN = 0, 0, 0, 0
    for s_true, s_pred in zip (y_true, y_pred):
        if s_true == 1:
            if s_pred == 1: 
                TP += 1
            else:
                FN += 1
        else:
            if s_pred == 0:
                TN += 1
            else:
                FP += 1
    return TP, FP, TN, FN
0

#FalseNegatives

test = pd.merge(Variables_test, Banknote_test,left_index=True, right_index=True)
Banknote_test_pred = pd.DataFrame(banknote_test_pred)
Banknote_test_pred.rename(columns={0 :'Predicted'}, inplace=True )
test = test.reset_index(drop=True).merge(Banknote_test_pred.reset_index(drop=True), left_index=True, right_index=True)
test['FN'] = np.where((test['Banknote']=="Genuine") & (test['Predicted']=="Forged"),1,0)
test[test.FN != 0]
3
  • gen = quizData["Banknote"].value_counts()["Genuine"] forg = quizData["Banknote"].value_counts()["Forged"] print("The ratio of 'Genuine' : 'Forged' banknotes is", gen/forg) Oct 20, 2020 at 4:57
  • # quizData["Banknote"].value_counts() genuine = 0 forged = 0 for i in range(len(quizData)): if quizData.loc[i]["Banknote"] == "Genuine": genuine += 1 else: forged += 1 print("The ratio of 'Genuine' : 'Forged' banknotes is", genuine/forged) Oct 20, 2020 at 4:57
  • Please don't add code as a comment as it is very hard to read/use. If you have additional code to add to your answer, click edit under your answer and add it directly to the answer.
    – David Buck
    Oct 20, 2020 at 5:54
0

None of the answers given so far worked for me as I sometimes ended up having a confusion matrix with a single entry only. The following code is able to mitigate this issue:

from sklearn.metrics import confusion_matrix
CM = confusion_matrix(y, y_hat)
            
try:
    TN = CM[0][0]
except IndexError:
    TN = 0
try:
    FN = CM[1][0]
except IndexError:
    FN = 0
try:
    TP = CM[1][1]
except IndexError:
    TP = 0
try:
    FP = CM[0][1]
except IndexError:
    FP = 0

Please note that "y" is the groundtruth and "y_hat" is the prediction.

-1

I have tried some of the answers and found them not working.

This works for me:

from sklearn.metrics import classification_report

print(classification_report(y_test, predicted)) 
1
  • This does not show you the number of TP, FP, TN, FN. Which the questioner wants.
    – Freddie
    Aug 11, 2020 at 14:47
-2

Here's a fix to invoketheshell's buggy code (which currently appears as the accepted answer):

def performance_measure(y_actual, y_hat):
    TP = 0
    FP = 0
    TN = 0
    FN = 0

    for i in range(len(y_hat)): 
        if y_actual[i] == y_hat[i]==1:
            TP += 1
        if y_hat[i] == 1 and y_actual[i] == 0:
            FP += 1
        if y_hat[i] == y_actual[i] == 0:
            TN +=1
        if y_hat[i] == 0 and y_actual[i] == 1:
            FN +=1

    return(TP, FP, TN, FN)

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