Ejemplo n.º 1
0
def main(dataset_paths):

    for i in range(int(const.get('K'))):
        if const.get('PICKLE_LOAD'):
            car = pickleLoad('car')
        else:
            if const.get('VERBOSE'):
                print('car────────────────────────')
            car = Anfis(dataset_paths['car'], i=i)
            car.train(const.get('EPOCHS'))
            if const.get('VERBOSE'):
                printTime(car.anfis.time)

        if const.get('PICKLE_LOAD'):
            truck = pickleLoad('truck')
        else:
            if const.get('VERBOSE'):
                print('truck──────────────────────')
            truck = Anfis(dataset_paths['truck'], i=i)
            truck.train(const.get('EPOCHS'))
            if const.get('VERBOSE'):
                printTime(truck.anfis.time)

    printResult(car, 'car')
    printResult(truck, 'truck')

    if const.get('PICKLE_DUMP'):
        pickleDump(car, 'car')
        pickleDump(truck, 'truck')
Ejemplo n.º 2
0
def pickleDump(anfis, type):
    path = "{video}_{features}_{epochs}_{k}_{type}.pkl".format(
            video=const.get('VIDEO_NUM'),
            features=','.join(const.get('FEATURE')),
            epochs=const.get('EPOCHS'),
            k=const.get('K'),
            type=type
        )

    pd.to_pickle(anfis, path)
    print("ANFIS for {0} is pickled at {1}".format(type, path))
Ejemplo n.º 3
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def pickleLoad(type):
    path = "{video}_{features}_{epochs}_{k}_{type}.pkl".format(
            video=const.get('VIDEO_NUM'),
            features=','.join(const.get('FEATURE')),
            epochs=const.get('EPOCHS'),
            k=const.get('K'),
            type=type
        )

    if not exists(path):
        print('{path} not found'.format(path=path))
        exit()

    return pd.read_pickle(path)
Ejemplo n.º 4
0
    def generateMf(self, train_x, test_x):
        mf = []

        for i in range(len(train_x[0])):
            mf1 = mean(train_x[:, i])
            mf2 = mean(test_x[:, i])

            if int(const.get('VIDEO_NUM')) == 1 and const.get('FEATURE')[i] == 'contrast':
                mf1 += 30
                mf2 -= 30

            mf.append([
                ['gaussmf', {'mean' : mf1, 'sigma' : 10}],
                ['gaussmf', {'mean' : mf2, 'sigma' : 7}],
            ])

        return mf
Ejemplo n.º 5
0
def printResult(anfis, name):
    
    accuracy  = round(anfis.anfis.accuracy, 4)
    precision = round(anfis.anfis.precision, 4)
    recall    = round(anfis.anfis.recall, 4)
    f_measure = calcF_measure(precision, recall)

    if const.get('VERBOSE'):
        print('{0}───────────────────────────────────'.format(name))
        print('accuracy','precision','recall', '\tf_measure', sep="\t")
        print( accuracy,  precision,  recall, f_measure, sep="\t\t")
        print()
    else:
        print(','.join(const.get('FEATURE')))
        print(const.get('VIDEO_NAME')[int(const.get('VIDEO_NUM'))])
        print(name)
        print(accuracy, f_measure, sep=',')
Ejemplo n.º 6
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    def __init__(self, dataset_paths, k=5, i=0):
        
        train_x = []
        test_x = []

        for path in dataset_paths:
            dataset = self.loadDataset(path)
            train_data, test_data = self.splitDataset(dataset[:, 1:], k, i)

            last = train_data.shape[1] - 1
            train_x = concat(train_x, train_data[:, 0:last], 1)
            train_y = train_data[:, last]
            test_x = concat(test_x, test_data[:, 0:last], 1)
            test_y = test_data[:, last]
        
        if const.get('VERBOSE'):
            print('train data: ', train_x.shape[0])
            print('test data:  ', test_x.shape[0])
            print()

        self.mfc = mf.MemFuncs(self.generateMf(train_x, test_x))
        self.anfis = anfis.ANFIS(train_x, train_y, test_x, test_y, self.mfc)
Ejemplo n.º 7
0
    def play(self, save, classify, anfises, start_from=0):
        if classify:
            if anfises is None:
                print('Error: you need to set anfis object')
                exit()
            elif anfises['car'].isTrained is False and anfises[
                    'truck'].isTrained is False:
                print('Error: you need to train anfis before')
                exit()

        for _ in range(start_from):
            self.moveToNextFrame()

        classifier = cv2.CascadeClassifier(const.get('CASCADE_PATH'))

        if save:
            os.makedirs(image_path(self.file_name), exist_ok=True)

        cnt = 1
        rectangle_color = None
        while self.current_color is not None:

            objects = classifier.detectMultiScale(
                self.current_color,
                scaleFactor=1.05,
                minNeighbors=2,
                minSize=(10, 10),
            )

            for object in objects:
                (x, y) = tuple(object[0:2])
                (w, h) = tuple(object[2:4])

                if classify:
                    glcm = Object(self.current_gray[y:y + h, x:x + w])
                    features = glcm.get(const.get('FEATURE'))

                    result = [
                        twmeggs.predict(anfises['car'], np.array(
                            [features]))[0][0] > 0.5,
                        twmeggs.predict(anfises['truck'], np.array(
                            [features]))[0][0] > 0.5,
                    ]

                    if result == [True, False]:
                        rectangle_color = const.get('RECT_COLOR_CAR')
                    elif result == [False, True]:
                        rectangle_color = const.get('RECT_COLOR_TRUCK')

                    cv2.imwrite(
                        image_path(self.file_name + '/{0}.png'.format(cnt)),
                        self.current_gray[y:y + h, x:x + w])
                if save:
                    cnt += 1

                if rectangle_color is not None:
                    cv2.rectangle(
                        self.current_color,
                        (x, y),
                        (x + w, y + h),
                        rectangle_color,
                        2,
                    )

            if cv2.waitKey(1) == ord('q'):
                break

            self.showFrame()
            self.moveToNextFrame()

        cv2.destroyAllWindows()
Ejemplo n.º 8
0
def main(
        path=const.get('VIDEO_PATH'), save=False, classify=False,
        anfises=None):
    video = Video(path)
    video.play(save=bool(save), classify=bool(classify), anfises=anfises)
    video.close()
Ejemplo n.º 9
0
    def train(self, epochs=5, tolerance=1e-5, initialGamma=1000, k=0.01):
        # Jang's Hybrid off-line training
        start = time.time()

        convergence = False
        epoch = 1

        while (epoch < epochs) and (convergence is False):

            # layer four: forward pass
            [layerFour, wSum, w] = forwardHalfPass(self, self.trainX)

            # layer five: least squares estimate
            layerFive = np.array(self.LSE(layerFour, self.trainY,
                                          initialGamma))
            self.consequents = layerFive
            # np.dot: 内積
            layerFive = np.dot(layerFour, layerFive)

            # error
            error = np.mean((self.trainY - layerFive.T)**2)

            if const.get('VERBOSE'):
                if epoch > 1:
                    diff = error - self.errors[-1]
                    print('{epoch} error: {error} ({diff})'.format(epoch=epoch,
                                                                   error=error,
                                                                   diff=diff))
                else:
                    print('{epoch} error: {error}'.format(epoch=epoch,
                                                          error=error))

            self.errors = np.append(self.errors, error)
            if error < self.min_error:
                self.min_error = error

            if error < tolerance:
                convergence = True

            # back propagation
            if convergence is False:
                cols = list(range(len(self.trainX[0, :])))
                # dE_dAlpha = [
                #     [array([a, b]), array([c, d])],
                #     [array([e, f]), array([g, h])]
                # ]
                dE_dAlpha = list(
                    backprop(self, colX, cols, wSum, w, layerFive)
                    for colX in range(self.trainX.shape[1]))

            # eta: 学習率
            eta = self.calcEta(k, dE_dAlpha)

            ## handling of variables with a different number of MFs
            dAlpha = copy.deepcopy(dE_dAlpha)
            if not (self.memFuncsHomo):
                for x in range(len(dE_dAlpha)):
                    for y in range(len(dE_dAlpha[x])):
                        for z in range(len(dE_dAlpha[x][y])):
                            dAlpha[x][y][z] = -eta * dE_dAlpha[x][y][z]
            else:
                # dAlpha = [
                #     [[-eta*a -eta*b][-eta*c -eta*d]]
                #     [[-eta*e -eta*f][-eta*g -eta*h]]
                # ]
                dAlpha = -eta * np.array(dE_dAlpha)

            for i in range(len(self.memFuncs)):
                for MFs in range(len(self.memFuncsByVariable[i])):
                    # paramList = ['mean', 'sigma']
                    paramList = sorted(self.memFuncs[i][MFs][1])
                    for param in range(len(paramList)):
                        # Update memFuncs
                        self.memFuncs[i][MFs][1][
                            paramList[param]] += dAlpha[i][MFs][param]

            epoch += 1

        self.fittedValues = predict(self, self.testX)

        self.aggregate()

        self.time = round(time.time() - start, 2)

        self.isTrained = True