I am quite new to machine leaning and python. Any help would be appreciated.

usually in matlab it's easy to plot it. i want to draw the roc curve to evaluate the performance of the face recognition system, i calculate the euclidian distance and the cosine similarity between two images and i would like to apply the computation of it's two parameters on a database ( test train). how can I draw the roc curve on this is database images

and how can i mesure the performance of autoencoder.

this code doesn't work :

predictions_prob = your_model.predict_proba(x_test)
false_positive_rate, recall, thresholds = roc_curve(y_test, predictions_prob[:,1])
roc_auc = auc(false_positive_rate, recall)
plt.plot(false_positive_rate, recall, 'g', label = 'AUC %s = %0.2f' % ('model name', roc_auc))
plt.plot([0,1], [0,1], 'r--')
plt.legend(loc = 'lower right')
plt.title('ROC Curve')

system recognition code:

from keras.models import Model, Sequential
from keras.layers import Input, Convolution2D, ZeroPadding2D, MaxPooling2D, 
Flatten, Dense, Dropout, Activation
from PIL import Image
import numpy as np
from keras.preprocessing.image import load_img, save_img, img_to_array
from keras.applications.imagenet_utils import preprocess_input
from keras.preprocessing import image
import matplotlib.pyplot as plt

model = Sequential()
## 16 couches
model.add(ZeroPadding2D((1, 1), input_shape=(256, 256, 3)))

from keras.models import model_from_json

vgg_face_descriptor = Model(inputs=model.layers[0].input
                            , outputs=model.layers[-2].output)

def preprocess_image(image_path):
    img = load_img(image_path, target_size=(256, 256))
    img = img_to_array(img)
    img = np.expand_dims(img, axis=0)
    img = preprocess_input(img)
    return img

def findCosineSimilarity(source_representation, test_representation):
    a = np.matmul(np.transpose(source_representation), test_representation)
    b = np.sum(np.multiply(source_representation, source_representation))
    c = np.sum(np.multiply(test_representation, test_representation))
    return 1 - (a / (np.sqrt(b) * np.sqrt(c)))

def findEuclideanDistance(source_representation, test_representation):
    euclidean_distance = source_representation - test_representation
    euclidean_distance = np.sum(np.multiply(euclidean_distance, euclidean_distance))
    euclidean_distance = np.sqrt(euclidean_distance)
    return euclidean_distance

vgg_face_descriptor = Model(inputs=model.layers[0].input, outputs=model.layers[-2].output)

epsilon = 6.384185791015625e-08
import matplotlib.pyplot as plt
import numpy as np

def verifyFace(img1, img2):
    img1_representation = vgg_face_descriptor.predict(preprocess_image(img1))[0, :]
    img2_representation = vgg_face_descriptor.predict(preprocess_image(img2))[0, :]

    cosine_similarity = findCosineSimilarity(img1_representation, img2_representation)
    euclidean_distance = findEuclideanDistance(img1_representation, img2_representation)

    print("Cosine similarity: ", cosine_similarity)
    print("Euclidean distance: ", euclidean_distance)

    if (cosine_similarity < epsilon):
        print("verified... they are same person")
        print("unverified! they are not same person!")

verifyFace("1tst.jpg", "1train.jpg")

verifyFace("1tst.jpg", "2train.jpg")

verifyFace("1tst.jpg", "3train.jpg")

verifyFace("1tst.jpg", "4train.jpg")

verifyFace("1tst.jpg", "5train.jpg")

verifyFace("1tst.jpg", "6train.jpg")

verifyFace("1tst.jpg", "7train.jpg")

verifyFace("1tst.jpg", "8train.jpg")
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  • 1
    I am looking for the solution too – KKKK074 Feb 12 at 21:15
  • What's your y_test? And what do you mean by doesn't work? – keineahnung2345 Feb 13 at 2:22

Assuming y_test is a numpy array containing 0 and 1, in which 0 means the two faces are not the same(negative), 1 means the two faces are the same(positive).

Also assuming you use verifyFace in prediction. Let's say it's output is pred, which contains distance between each pairs.

By definition, two faces lower than a threshold will be considered positive. This is just the opposite of typical binary classification task.

So here is a workaround:

from sklearn.metrics import roc_curve, auc

max_dist = max(pred)
pred = np.array([1-e/max_dist for e in pred])
fpr, tpr, thresholds = roc_curve(y_test, pred)
roc_auc = auc(fpr, tpr)
lw = 2
plt.plot(fpr, tpr, color='darkorange',
         lw=lw, label='ROC curve (area = %0.2f)' % roc_auc)
plt.plot([0, 1], [0, 1], color='navy', lw=lw, linestyle='--')
plt.xlim([0.0, 1.0])
plt.ylim([0.0, 1.05])
plt.xlabel('False Positive Rate')
plt.ylabel('True Positive Rate')
plt.title('Receiver operating characteristic example')
plt.legend(loc="lower right")

The key concept is to convert pred so it looks like a sequence of confidence.

Ref: How to use prediction score in creating ROC curve with Scikit-Learn

Receiver Operating Characteristic (ROC)

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