I was trying to classify the wine data set here -http://archive.ics.uci.edu/ml/datasets/Wine+Quality using logistic regression (with method ='bfgs' and l1 norm) and caught a singular value matrix error(raise LinAlgError('Singular matrix'), in-spite of full rank [which I tested using np.linalg.matrix_rank(data[train_cols].values) ] .
This is how I came to the conclusion that some features might be linear combinations of others. Towards this, I experimented of using Grid search/LinearSVC - and I get the error below, along with my code & data-set .
I can see that only 6/7 features are actually "independent" - which I interpret when comparing the rows of x_train_new and x_train (so I can get which columns are redundant)
# Train & test DATA CREATION from sklearn.svm import LinearSVC import numpy, random import pandas as pd df = pd.read_csv("https://github.com/ekta1007/Predicting_wine_quality/blob/master/wine_red_dataset.csv") #,skiprows=0, sep=',') df=df.dropna(axis=1,how='any') # also tried how='all' - still get NaN errors as below header=list(df.columns.values) # or df.columns X = df[df.columns - [header[-1]]] # header[-1] = ['quality'] - this is to make the code genric enough Y = df[header[-1]] # df['quality'] rows = random.sample(df.index, int(len(df)*0.7)) # indexing the rows that will be picked in the train set x_train, y_train = X.ix[rows],Y.ix[rows] # Fetching the data frame using indexes x_test,y_test = X.drop(rows),Y.drop(rows) # Training the classifier using C-Support Vector Classification. clf = LinearSVC(C=0.01, penalty="l1", dual=False) #,tol=0.0001,fit_intercept=True, intercept_scaling=1) clf.fit(x_train, y_train) x_train_new = clf.fit_transform(x_train, y_train) #print x_train_new #works clf.predict(x_test) # does NOT work and gives NaN errors for some x_tests clf.score(x_test, y_test) # Does NOT work clf.coef_ # Works, but I am not sure, if this is OK, given huge NaN's - or does the coef's get impacted ? clf.predict(x_train) 552 NaN 209 NaN 427 NaN 288 NaN 175 NaN 427 NaN 748 7 552 NaN 429 NaN [... and MORE] Name: quality, Length: 1119 clf.predict(x_test) 76 NaN 287 NaN 420 7 812 NaN 443 7 420 7 430 NaN 373 5 624 5 [..and More] Name: quality, Length: 480
The strange thing is that when I run clf.predict(x_train) I still see some NaN's - What am I doing wrong ?After all the model was trained using this, and this should NOT occur , right ?
According to this thread, I also checked that there are no null's in my csv file (though I relabeled the "quality' to 5 and 7 labels only (from range(3,10) How to fix "NaN or infinity" issue for sparse matrix in python?
Also - here's the data type of x_test & y_test/train...
x_test <class 'pandas.core.frame.DataFrame'> Int64Index: 480 entries, 1 to 1596 Data columns: alcohol 480 non-null values chlorides 480 non-null values citric acid 480 non-null values density 480 non-null values fixed acidity 480 non-null values free sulfur dioxide 480 non-null values pH 480 non-null values residual sugar 480 non-null values sulphates 480 non-null values total sulfur dioxide 480 non-null values volatile acidity 480 non-null values dtypes: float64(11) y_test 1 5 10 5 18 5 21 5 30 5 31 7 36 7 40 5 50 5 52 7 53 5 55 5 57 5 60 5 61 5 [..And MORE] Name: quality, Length: 480
clf.score(x_test, y_test) Traceback (most recent call last): File "<pyshell#31>", line 1, in <module> clf.score(x_test, y_test) File "C:\Python27\lib\site-packages\sklearn\base.py", line 279, in score return accuracy_score(y, self.predict(X)) File "C:\Python27\lib\site-packages\sklearn\metrics\metrics.py", line 742, in accuracy_score y_true, y_pred = check_arrays(y_true, y_pred) File "C:\Python27\Lib\site-packages\sklearn\utils\validation.py", line 215, in check_arrays File "C:\Python27\Lib\site-packages\sklearn\utils\validation.py", line 18, in _assert_all_finite ValueError: Array contains NaN or infinity. #I also explicitly checked for NaN's as here -: for i in df.columns: df[i].isnull()
Tip : Please also mention if my thought process on using LinearSVC is correct, given my use case, or should I use Grid-search ?
Disclaimer : Parts of this code have been built on suggestions in similar contexts from StackOverflow and miscellaneous sources - My real use case is just trying to access if this method is a good fit for my scenario. That's all.