Ejemplo n.º 1
0
def build_model():
    l0 = InputLayer(data_sizes["sunny"])
    l1a = ConvLayer(l0, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l1b = ConvLayer(l1a, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l1c = ConvLayer(l1b, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l1 = MaxPoolLayer(l1c, pool_size=(2, 2))

    l2a = ConvLayer(l1, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l2b = ConvLayer(l2a, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l2c = ConvLayer(l2b, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l3 = MaxPoolLayer(l2c, pool_size=(3, 3))

    l4a = ConvLayer(l3, num_filters=32, filter_size=(4, 4),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l4b = ConvLayer(l4a, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l4c = ConvLayer(l4b, num_filters=32, filter_size=(3, 3),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))

    l5a = ConvLayer(l4c, num_filters=256, filter_size=(1, 1),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l5b = ConvLayer(l5a, num_filters=256, filter_size=(1, 1),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))
    l5c = ConvLayer(l5b, num_filters=1, filter_size=(1, 1),
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1),
                    nonlinearity=lasagne.nonlinearities.sigmoid)

    l_final = lasagne.layers.FlattenLayer(l5c, outdim=2)

    return {
        "inputs":{
            "sunny": l0
        },
        "outputs":{
            "segmentation": l_final,
            "top": l_final
        }
    }
Ejemplo n.º 2
0
def MaxPool(incoming, pool_size , stride, pad=(0,0), ignore_border=True, **kwargs):
    """
    Overrides the default parameters for MaxPool
    """
    ensure_set_name('conv', kwargs)

    return MaxPoolLayer(incoming, pool_size, stride, pad, ignore_border, **kwargs)
Ejemplo n.º 3
0
def build_model(input_var):

    # Three layer residual block
    def residual_block3(l, base_dim, increase_dim=False, projection=False):
        if increase_dim:
            layer_1 = batch_norm(
                ConvLayer(l,
                          num_filters=base_dim,
                          filter_size=(1, 1),
                          stride=(2, 2),
                          nonlinearity=None,
                          pad='same',
                          W=nn.init.HeNormal(gain='relu')))
        else:
            layer_1 = batch_norm(
                ConvLayer(l,
                          num_filters=base_dim,
                          filter_size=(1, 1),
                          stride=(1, 1),
                          nonlinearity=rectify,
                          pad='same',
                          W=nn.init.HeNormal(gain='relu')))
        layer_2 = batch_norm(
            ConvLayer(layer_1,
                      num_filters=base_dim,
                      filter_size=(3, 3),
                      stride=(1, 1),
                      nonlinearity=rectify,
                      pad='same',
                      W=nn.init.HeNormal(gain='relu')))
        layer_3 = batch_norm(
            ConvLayer(layer_2,
                      num_filters=4 * base_dim,
                      filter_size=(1, 1),
                      stride=(1, 1),
                      nonlinearity=rectify,
                      pad='same',
                      W=nn.init.HeNormal(gain='relu')))

        # add shortcut connection
        if increase_dim:
            if projection:
                # projection shortcut (option B in paper)
                projection = batch_norm(
                    ConvLayer(l,
                              num_filters=4 * base_dim,
                              filter_size=(1, 1),
                              stride=(2, 2),
                              nonlinearity=None,
                              pad='same',
                              b=None))
                block = NonlinearityLayer(ElemwiseSumLayer(
                    [layer_3, projection]),
                                          nonlinearity=rectify)
            else:
                # identity shortcut (option A in paper)
                # we use a pooling layer to get identity with strides,
                # since identity layers with stride don't exist in Lasagne
                identity = PoolLayer(l,
                                     pool_size=1,
                                     stride=(2, 2),
                                     mode='average_exc_pad')
                padding = PadLayer(identity, [4 * base_dim, 0, 0],
                                   batch_ndim=1)
                block = NonlinearityLayer(ElemwiseSumLayer([layer_3, padding]),
                                          nonlinearity=rectify)

        else:
            block = NonlinearityLayer(ElemwiseSumLayer([layer_3, l]),
                                      nonlinearity=rectify)

        return block

    # Input of the network
    input_layer = InputLayer(shape=(batch_size, num_channels, input_height,
                                    input_width),
                             input_var=input_var)

    # Very first conv layer
    l = batch_norm(
        ConvLayer(input_layer,
                  num_filters=64,
                  filter_size=(7, 7),
                  stride=(2, 2),
                  nonlinearity=rectify,
                  pad='same',
                  W=nn.init.HeNormal(gain='relu')))

    # Maxpool layer
    l = MaxPoolLayer(l, pool_size=(3, 3), stride=(2, 2))

    # Convolove with 1x1 filter to match input dimension with the upcoming residual block
    l = batch_norm(
        ConvLayer(l,
                  num_filters=256,
                  filter_size=(1, 1),
                  stride=(1, 1),
                  nonlinearity=rectify,
                  pad='same',
                  W=nn.init.HeNormal(gain='relu')))

    ############# First residual blocks #############
    for _ in range(num_blocks[0] - 1):
        l = residual_block3(l, base_dim=64)

    ############# Second residual blocks ############
    # Increment Dimension
    l = residual_block3(l, base_dim=128, increase_dim=True, projection=True)
    for _ in range(num_blocks[1] - 1):
        l = residual_block3(l, base_dim=128)

    ############# Third residual blocks #############
    # Increment Dimension
    l = residual_block3(l, base_dim=256, increase_dim=True, projection=True)
    for _ in range(num_blocks[2] - 1):
        l = residual_block3(l, base_dim=256)

    ############# Fourth residual blocks #############
    # Increment Dimension
    l = residual_block3(l, base_dim=512, increase_dim=True, projection=True)
    for _ in range(num_blocks[2] - 1):
        l = residual_block3(l, base_dim=512)

    # Global pooling layer
    l = GlobalPoolLayer(l)

    # Softmax Layer
    softmax_layer = DenseLayer(l,
                               num_units=output_dim,
                               W=nn.init.HeNormal(),
                               nonlinearity=softmax)

    return softmax_layer
Ejemplo n.º 4
0
def build_model():

    #################
    # Regular model #
    #################
    l0 = InputLayer(data_sizes["sliced:data:ax"])
    l0r = reshape(l0, (
        -1,
        1,
    ) + data_sizes["sliced:data:ax"][1:])

    # (batch, channel, time, axis, x, y)

    # convolve over time with small filter
    l0t = ConvolutionOverAxisLayer(
        l0r,
        num_filters=2,
        filter_size=(5, ),
        stride=(3, ),
        axis=2,
        channel=1,
        W=lasagne.init.Orthogonal(),
        b=lasagne.init.Constant(0.1),
    )

    l0r = reshape(l0t, (
        -1,
        1,
    ) + data_sizes["sliced:data:ax"][-2:])

    # first do the segmentation steps
    l1a = ConvLayer(
        l0r,
        num_filters=32,
        filter_size=(5, 5),
        stride=2,
        pad='same',
        W=lasagne.init.Orthogonal(),
        b=lasagne.init.Constant(0.1),
    )
    l1b = ConvLayer(
        l1a,
        num_filters=32,
        filter_size=(5, 5),
        stride=2,
        pad='same',
        W=lasagne.init.Orthogonal(),
        b=lasagne.init.Constant(0.1),
    )
    l1b_m = MaxPoolLayer(l1b, pool_size=(2, 2))

    l1c = ConvLayer(
        l1b_m,
        num_filters=64,
        filter_size=(3, 3),
        pad='same',
        W=lasagne.init.Orthogonal(),
        b=lasagne.init.Constant(0.1),
    )
    l1f = ConvLayer(l1c,
                    num_filters=32,
                    filter_size=(3, 3),
                    pad='same',
                    W=lasagne.init.Orthogonal(),
                    b=lasagne.init.Constant(0.1))

    l1f_m = MaxPoolLayer(l1f, pool_size=(2, 2))

    l1f_r = reshape(l1f_m, (batch_size, 2, 9, 15, 32, 4, 4))

    l0t = ConvolutionOverAxisLayer(
        l1f_r,
        num_filters=32,
        filter_size=(3, ),
        stride=(1, ),
        axis=3,
        channel=1,
        W=lasagne.init.Orthogonal(),
        b=lasagne.init.Constant(0.1),
    )

    l_d3 = lasagne.layers.DenseLayer(
        l0t, num_units=2, nonlinearity=lasagne.nonlinearities.identity)
    l_systole = MuLogSigmaErfLayer(l_d3)

    l_d3b = lasagne.layers.DenseLayer(
        l0t, num_units=2, nonlinearity=lasagne.nonlinearities.identity)
    l_diastole = MuLogSigmaErfLayer(l_d3b)

    return {
        "inputs": {
            "sliced:data:ax": l0
        },
        "outputs": {
            "systole": l_systole,
            "diastole": l_diastole
        }
    }
Ejemplo n.º 5
0
def build_model(input_width, input_height, output_dim,
                batch_size=BATCH_SIZE):

    l_in = lasagne.layers.InputLayer(
        shape=(batch_size, NUM_CHANNELS, input_width, input_height),
    )

    l_conv1 = ConvLayer(
        l_in,
        num_filters=32,
        filter_size=(3, 3),
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )

    l_conv1b = ConvLayer(
        l_conv1,
        num_filters=32,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )
    l_conv1c = ConvLayer(
        l_conv1b,
        num_filters=32,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )

    l_pool1 = MaxPoolLayer(
        l_conv1c, pool_size=(3, 3), stride=(2, 2))
    l_dropout1 = lasagne.layers.DropoutLayer(l_pool1, p=0.25)

    l_conv2 = ConvLayer(
        l_dropout1,
        num_filters=64,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )
    l_conv2b = ConvLayer(
        l_conv2,
        num_filters=64,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )
    l_conv2c = ConvLayer(
        l_conv2b,
        num_filters=64,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )

    l_pool2 = MaxPoolLayer(
        l_conv2c, pool_size=(2, 2), stride=(2, 2))
    l_dropout2 = lasagne.layers.DropoutLayer(l_pool2, p=0.25)

    l_conv3 = ConvLayer(
        l_dropout2,
        num_filters=128,
        filter_size=(3, 3), 
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )
    l_conv3b = ConvLayer(
        l_conv3,
        num_filters=128,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )
    l_conv3c = ConvLayer(
        l_conv3b,
        num_filters=128,
        filter_size=(3, 3),
        pad=0,
        nonlinearity=lasagne.nonlinearities.very_leaky_rectify,
        W=lasagne.init.Orthogonal(),
    )

    l_pool3 = lasagne.layers.GlobalPoolLayer(
        l_conv3c, pool_function=T.max)

    l_dropout3 = lasagne.layers.DropoutLayer(l_pool3, p=0.25)

    l_out = lasagne.layers.DenseLayer(
        l_dropout3,
        num_units=output_dim,
        nonlinearity=lasagne.nonlinearities.softmax,
        W=lasagne.init.Orthogonal(),
    )
    return l_out