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I've been training a U-Net for single class small lesion segmentation, and have been getting consistently volatile validation loss. I have about 20k images split 70/30 between training and validation sets-so I don't think the issue is too little data. I've tried shuffling and resplitting the sets a few times with no change in volatility-so I don't think the validation set is unrepresentative. I have tried lowering the learning rate with no effect on volatility. And I have tried a few loss functions (dice coefficient, focal tversky, weighted binary cross-entropy). I'm using a decent amount of augmentation so as to avoid overfitting. I've also run through all my data (512x512 float64s with corresponding 512x512 int64 masks--both stored as numpy arrays) do double check that the value range, dtypes, etc. aren't screwy...and I even removed any ROIs in the masks under 35 pixels in area which I thought might be artifact and messing with loss.

I'm using keras ImageDataGen.flow_from_directory...I was initially using zca_whitening and brightness_range augmentation but I think this causes issues with flow_from_directory and the link between mask and image being lost.. so I skipped this.

I've tried validation generators with and without shuffle=True. Batch size is 8.

Here's some of my code, happy to include more if it would help:

# loss 

from keras.losses import binary_crossentropy
import keras.backend as K
import tensorflow as tf 

epsilon = 1e-5
smooth = 1

def dsc(y_true, y_pred):
    smooth = 1.
    y_true_f = K.flatten(y_true)
    y_pred_f = K.flatten(y_pred)
    intersection = K.sum(y_true_f * y_pred_f)
    score = (2. * intersection + smooth) / (K.sum(y_true_f) + K.sum(y_pred_f) + smooth)
    return score

def dice_loss(y_true, y_pred):
    loss = 1 - dsc(y_true, y_pred)
    return loss

def bce_dice_loss(y_true, y_pred):
    loss = binary_crossentropy(y_true, y_pred) + dice_loss(y_true, y_pred)
    return loss

def confusion(y_true, y_pred):
    smooth=1
    y_pred_pos = K.clip(y_pred, 0, 1)
    y_pred_neg = 1 - y_pred_pos
    y_pos = K.clip(y_true, 0, 1)
    y_neg = 1 - y_pos
    tp = K.sum(y_pos * y_pred_pos)
    fp = K.sum(y_neg * y_pred_pos)
    fn = K.sum(y_pos * y_pred_neg) 
    prec = (tp + smooth)/(tp+fp+smooth)
    recall = (tp+smooth)/(tp+fn+smooth)
    return prec, recall

def tp(y_true, y_pred):
    smooth = 1
    y_pred_pos = K.round(K.clip(y_pred, 0, 1))
    y_pos = K.round(K.clip(y_true, 0, 1))
    tp = (K.sum(y_pos * y_pred_pos) + smooth)/ (K.sum(y_pos) + smooth) 
    return tp 

def tn(y_true, y_pred):
    smooth = 1
    y_pred_pos = K.round(K.clip(y_pred, 0, 1))
    y_pred_neg = 1 - y_pred_pos
    y_pos = K.round(K.clip(y_true, 0, 1))
    y_neg = 1 - y_pos 
    tn = (K.sum(y_neg * y_pred_neg) + smooth) / (K.sum(y_neg) + smooth )
    return tn 

def tversky(y_true, y_pred):
    y_true_pos = K.flatten(y_true)
    y_pred_pos = K.flatten(y_pred)
    true_pos = K.sum(y_true_pos * y_pred_pos)
    false_neg = K.sum(y_true_pos * (1-y_pred_pos))
    false_pos = K.sum((1-y_true_pos)*y_pred_pos)
    alpha = 0.7
    return (true_pos + smooth)/(true_pos + alpha*false_neg + (1-alpha)*false_pos + smooth)

def tversky_loss(y_true, y_pred):
    return 1 - tversky(y_true,y_pred)

def focal_tversky(y_true,y_pred):
    pt_1 = tversky(y_true, y_pred)
    gamma = 0.75
    return K.pow((1-pt_1), gamma)



    model = BlockModel((len(os.listdir(os.path.join(imageroot,'train_ct','train'))), 512, 512, 1),filt_num=16,numBlocks=4)
    #model.compile(optimizer=Adam(learning_rate=0.001), loss=weighted_cross_entropy)
    #model.compile(optimizer=Adam(learning_rate=0.001), loss=dice_coef_loss)
    model.compile(optimizer=Adam(learning_rate=0.001), loss=focal_tversky)
    train_mask = os.path.join(imageroot,'train_masks')
    val_mask = os.path.join(imageroot,'val_masks')

    model.load_weights(model_weights_path) #I'm initializing with some pre-trained weights from a similar model

     data_gen_args_mask = dict(
        rotation_range=10,
        shear_range=20,
        width_shift_range=0.1, 
        height_shift_range=0.1,
        zoom_range=[0.8,1.2],
        horizontal_flip=True,
        #vertical_flip=True,
        fill_mode='nearest',
        data_format='channels_last'
        )

    data_gen_args = dict(
        **data_gen_args_mask
    )

    image_datagen_train = ImageDataGenerator(**data_gen_args)
    mask_datagen_train = ImageDataGenerator(**data_gen_args)#_mask)

    image_datagen_val = ImageDataGenerator()
    mask_datagen_val = ImageDataGenerator()

    seed = 1
    BS = 8

    steps = int(np.floor((len(os.listdir(os.path.join(train_ct,'train'))))/BS))
    print(steps)
    val_steps = int(np.floor((len(os.listdir(os.path.join(val_ct,'val'))))/BS))
    print(val_steps)

    train_image_generator = image_datagen_train.flow_from_directory(
         train_ct,
         target_size = (512, 512),
         color_mode = ("grayscale"),
         classes=None,
         class_mode=None,
         seed = seed,
         shuffle = True,
         batch_size = BS)

    train_mask_generator = mask_datagen_train.flow_from_directory(
        train_mask,
        target_size = (512, 512),
        color_mode = ("grayscale"),
        classes=None,
        class_mode=None,
        seed = seed,
        shuffle = True,
        batch_size = BS)

    val_image_generator = image_datagen_val.flow_from_directory(
        val_ct,
        target_size = (512, 512),
        color_mode = ("grayscale"),
        classes=None,
        class_mode=None,
        seed = seed,
        shuffle = True,
        batch_size = BS)

    val_mask_generator = mask_datagen_val.flow_from_directory(
        val_mask,
        target_size = (512, 512),
        color_mode = ("grayscale"),
        classes=None,
        class_mode=None,
        seed = seed,
        shuffle = True,
        batch_size = BS)

    train_generator = zip(train_image_generator, train_mask_generator)
    val_generator = zip(val_image_generator, val_mask_generator)

# make callback for checkpointing

    plot_losses = PlotLossesCallback(skip_first=0,plot_extrema=False)
    %matplotlib inline

    filepath = os.path.join(versionPath, model_version + "_saved-model-{epoch:02d}-{val_loss:.2f}.hdf5")

    if reduce:
        cb_check = [ModelCheckpoint(filepath,monitor='val_loss',
                        verbose=1,save_best_only=False,
                        save_weights_only=True,mode='auto',period=1),
                        reduce_lr,
                        plot_losses]
    else:
        cb_check = [ModelCheckpoint(filepath,monitor='val_loss',
                        verbose=1,save_best_only=False,
                        save_weights_only=True,mode='auto',period=1),
                        plot_losses]

# train model
    history = model.fit_generator(train_generator, epochs=numEp,
                    steps_per_epoch=steps,
                    validation_data=val_generator,
                    validation_steps=val_steps, 
                    verbose=1,
                    callbacks=cb_check,
                    use_multiprocessing = False
                             )

And here's how my loss looks:

enter image description here

Another potentially relevant thing: I tweaked the flow_from_directory code a bit (added npy to the white list). But training loss looks fine so assuming the issue isnt here

  • 1
    Guess 1: Although you're using the same seed, you might be getting trolled by using shuffle=True. I'd try False just in case. ---- Guess 2: you've got BatchNormalization layers in your model in one of these cases: a) there are pretrained segments and you set trainable=False for these segments ; b) the BN layer is after a Dropout layer. – Daniel Möller Feb 5 at 22:18
  • I initially had shuffle=False for val generators and got the same issues. Printed out layer.trainable for layer in model.layers and got all True except the first layer. No dropout layers in model.summary/model.layers, BN are after conv or deconv only – user3470496 Feb 5 at 22:35
  • I didn't find anything strange in your code, so all I can do is keep trying to guess the problem. -- Even though you say your BNs are ok, you could try to remove the BN layers, and make sure they are "trainable=True" before compilation. ---- Another thing that I can imagine is that your image names are not consistent with the mask names in the val directories. ---- Another guess, maybe you have way too many empty masks in validation (and your loss seems to depend on having a good denominator) – Daniel Möller Feb 8 at 4:41
  • Hint, you can take len(train_image_generator) and len(val_image_generator) as number of steps, and also compare the lengths of the other generators – Daniel Möller Feb 8 at 4:43
  • 1
    This would be a lot easier for you, or anyone, to debug if you can first walk through this step by step and confirm that batch-wise this works the way you expect. Outside model.fit. Start with: look at the pairs generated by your image loaders: are they paired up properly? – mdaoust Feb 8 at 15:34
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Two suggestions:

  1. Switch to the classic validation data format (i.e. numpy array) instead of using a generator -- this will ensure you always use the exactly same validation data every time. If you see a different validation curve, then there is something "random" in the validation generator giving you different data at different epochs.

  2. Use a fixed set of samples (100 or 1000 should be enough w/o any data augmentation) for both training and validation. If everything goes well, you should see your network quickly overfit to this dataset and your training and validation curves should very much similar. If not, debug your network.

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