Esempio n. 1
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def MCC_CM_calculator(validation_labels_linear, predicted_labels_linear):
    #Return MCC and confusion matrix

    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    MCC = round(MCC,3)
    MCC_line = "MCC=" + str(MCC)

    CM = confusion_matrix(validation_labels_linear, predicted_labels_linear)

    CM_lines = ";p_E;p_G;p_L\n"

    for i in range(len(CM[0])):
        if i == 0:
            l = "r_E"
        elif i == 1:
            l = "r_G"
        elif i == 2:
            l = "r_L"

        CM_lines += l + ";"
        for j in CM[0][i]:
            CM_lines += str(j) + ";"
        CM_lines += "\n"

    return MCC_line, CM_lines
Esempio n. 2
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def MCC_CM_calculator(validation_labels_linear, predicted_labels_linear):
    #Return MCC and confusion matrix

    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    MCC = round(MCC, 3)
    MCC_line = "MCC=" + str(MCC)

    CM = confusion_matrix(validation_labels_linear, predicted_labels_linear)

    CM_lines = ";p_E;p_G;p_L\n"

    for i in range(len(CM[0])):
        if i == 0:
            l = "r_E"
        elif i == 1:
            l = "r_G"
        elif i == 2:
            l = "r_L"

        CM_lines += l + ";"
        for j in CM[0][i]:
            CM_lines += str(j) + ";"
        CM_lines += "\n"

    return MCC_line, CM_lines
Esempio n. 3
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def MCC_CM_calculator(validation_labels_linear, predicted_labels_linear):
    '''Return MCC and confusion matrix'''

    #print(len(validation_labels_linear), validation_labels_linear.shape)
    #print(len(predicted_labels_linear), predicted_labels_linear.shape)
    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    MCC = round(MCC,3)
    MCC_line = "MCC=" + str(MCC) + "\n"

    CM = confusion_matrix(validation_labels_linear, predicted_labels_linear)
    CM_lines = ""

    for i in range(len(CM)):
        for j in CM[i]:
            CM_lines += str(j) + ";"
        CM_lines += "\n"

    return MCC_line, CM_lines
Esempio n. 4
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def MCC_CM_calculator(validation_labels_linear, predicted_labels_linear):
    '''Return MCC and confusion matrix'''

    #print(len(validation_labels_linear), validation_labels_linear.shape)
    #print(len(predicted_labels_linear), predicted_labels_linear.shape)
    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    MCC = round(MCC, 3)
    MCC_line = "MCC=" + str(MCC) + "\n"

    CM = confusion_matrix(validation_labels_linear, predicted_labels_linear)
    CM_lines = ""

    for i in range(len(CM)):
        for j in CM[i]:
            CM_lines += str(j) + ";"
        CM_lines += "\n"

    return MCC_line, CM_lines
Esempio n. 5
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def main():
    WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_tf_dim_ordering_tf_kernels.h5'
    WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.1/vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5'

    parser = myArgumentParser(description='Run a prediction experiment using pretrained VGG16, specified on the deepstreet DataSet.',
            fromfile_prefix_chars='@')
    parser.add_argument('--gpu', type=int, default=0, help='GPU Device (default: %(default)s)')
    parser.add_argument('--output_dir', type=str, default="./experiment_output/",help='Output directory')
    parser.add_argument('--input_dir', type=str, default="./",help='Input directory')
    parser.add_argument('--debug', type=bool, default=False, help='Debug mode')

    args = parser.parse_args()
    GPU = args.gpu
    OUTDIR = args.output_dir+"/"
    INDIR = args.input_dir+"/"
    DEBUG = args.debug

    if not os.path.exists(OUTDIR):
        os.makedirs(OUTDIR)


    if DEBUG:
        validation_data_dir = INDIR + "small_dataset/val/"
    else:
        #validation_data_dir = "dataset/val/"
        validation_data_dir = INDIR + "val/"

    if os.path.exists(INDIR + validation_data_dir + ".DS_Store"):
        os.remove(INDIR + validation_data_dir + ".DS_Store")

    #set dimensions of the images
    img_rows, img_cols = 224, 224

    if K.image_data_format() == 'channels_first':
        shape_ord = (3, img_rows, img_cols)
    else:  # channel_last
        shape_ord = (img_rows, img_cols, 3)

    vgg16_model = vgg16.VGG16(weights=None, include_top=False, input_tensor=Input(shape_ord))
    vgg16_model.summary()

    #add last fully-connected layers
    x = Flatten(input_shape=vgg16_model.output.shape)(vgg16_model.output)
    x = Dense(4096, activation='relu', name='ft_fc1')(x)
    x = Dropout(0.5)(x)
    x = BatchNormalization()(x)
    predictions = Dense(43, activation='softmax')(x)

    model = Model(inputs=vgg16_model.input, outputs=predictions)

    #compile the model
    model.compile(optimizer=optimizers.SGD(lr=1e-4, momentum=0.9),
                loss='categorical_crossentropy', metrics=['accuracy'])


    #load validation images and create labels list
    validation_filenames = os.listdir(validation_data_dir)
    validation_filenames.sort()
    validation_images = []
    validation_labels = []

    for name in validation_filenames:
        if name.endswith(".ppm"):
            validation_images.append(validation_data_dir + name)
            label = name.split("_")[0]
            label_int = int(label)
            labels_array = [0]*43
            labels_array[label_int] = 1
            validation_labels.append(labels_array)
        else:
            validation_filenames.remove(name)

    print("Validation Filenames loaded.")


    validation = np.array(load_im2(validation_images, img_cols, img_rows))
    print("Validation images loaded.")

    model.load_weights("experiment_output/vgg16_deepstreet_training1.h5")

    predicted_labels = model.predict(validation)
    print("Labels predicted.")

    #write summary file
    prediction_summary = open(OUTDIR + "vgg16_deepstreet_t_prediction_summary_deepstreet_v.txt", "w")
    prediction_summary.write("\t".join(['FILENAME', 'REAL_LABEL', 'PREDICTED_LABELS']) + '\n')

    predicted_labels_linear = []
    validation_labels_linear = []

    #make linear labels list
    for lbl in validation_labels:
        for i,val in enumerate(lbl):
            if val == 1:
                validation_labels_linear.append(i)


    for i in range(len(predicted_labels)):
        cls_prob = predicted_labels[i]     #percentage of belonging for i image

        predicted_label_index = np.argmax(cls_prob) #get the index of the class with higher probability
        line = [validation_images[i], str(validation_labels_linear[i]), str(predicted_label_index), str(round(cls_prob[predicted_label_index],3))]

        s = ""
        for i in range(42):
            s += "{}:{}; ".format(i,round(cls_prob[i],3))
            #s += str(i) + ":" + str(round(cls_prob[i],3)) + "; "
        s += "42:{}".format(round(cls_prob[42],3))
        #s += "42:" + str(round(cls_prob[42],3))

        line.append(s)

        predicted_labels_linear.append(np.argmax(cls_prob))
        prediction_summary.write(";".join(line) + "\n")
        prediction_summary.flush()


    validation_labels_linear = np.array(validation_labels_linear)
    predicted_labels_linear = np.array(predicted_labels_linear)

    #calculate MCC
    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    print(MCC)

    prediction_summary.write("MCC = {}".format(MCC))
    prediction_summary.flush()
    prediction_summary.close()

    #compute confusion matrix and save the image
    conf_matrix = confusion_matrix(validation_labels_linear,predicted_labels_linear)[0]
    plt.matshow(conf_matrix)
    plt.colorbar()
    plt.savefig("confusion_matrix.png")

    end = timer()
    print("Total time: ", end - start)
Esempio n. 6
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        if lbl[1] == 1:
            validation_labels_linear.append(1)
        if lbl[2] == 1:
            validation_labels_linear.append(2)

    validation_labels_linear = np.array(validation_labels_linear)
    predicted_labels_linear = np.array(predicted_labels_linear)

    MCC = multimcc(validation_labels_linear, predicted_labels_linear)
    mcc_list.append(MCC)
    perc_white.append(p)
    prediction_summary.write("MCC=" + str(MCC) + "\n")
    prediction_summary.flush()

    prediction_summary.write(
        str(confusion_matrix(validation_labels_linear,
                             predicted_labels_linear)))
    prediction_summary.flush()
    prediction_summary.close()

mcc_list = np.array(mcc_list)
perc_white = np.array(perc_white)

fig = plt.figure()
ax = fig.add_subplot(111)
mcc_list_round = [round(i, 3) for i in mcc_list]
j_old = 0.0
for i, j in zip(perc_white, mcc_list_round):
    if j_old != j:
        ax.annotate(str(j), xy=(i, j + 0.01))
    j_old = j
Esempio n. 7
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        elif  cl == 1 and j == 2:
            real_label = "Late"

    line = [validation_images[i], real_label, str(round(cls_prob[0],3)), str(round(cls_prob[1],3)), str(round(cls_prob[2],3))]
    predicted_labels_linear.append(np.argmax(cls_prob))
    prediction_summary.write(";".join(line)+"\n")
    prediction_summary.flush()



validation_labels_linear = []

for lbl in validation_labels:
    if lbl[0] == 1:
        validation_labels_linear.append(0)
    if lbl[1] == 1:
        validation_labels_linear.append(1)
    if lbl[2] == 1:
        validation_labels_linear.append(2)

validation_labels_linear = np.array(validation_labels_linear)
predicted_labels_linear = np.array(predicted_labels_linear)

MCC = multimcc(validation_labels_linear, predicted_labels_linear)
prediction_summary.write("MCC=" + str(MCC) + "\n")
prediction_summary.flush()

prediction_summary.write(str(confusion_matrix(validation_labels_linear, predicted_labels_linear)))
prediction_summary.flush()
prediction_summary.close()