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Computes mean Intersection-Over-Union metric for one-hot encoded labels.
Inherits From: MeanIoU, IoU, Metric, Layer, Module
tf.keras.metrics.OneHotMeanIoU(
num_classes: int,
name: str = None,
dtype: Optional[Union[str, tf.dtypes.DType]] = None,
ignore_class: Optional[int] = None,
sparse_y_pred: bool = False,
axis: int = -1
)
General definition and computation:
Intersection-Over-Union is a common evaluation metric for semantic image segmentation.
For an individual class, the IoU metric is defined as follows:
iou = true_positives / (true_positives + false_positives + false_negatives)
To compute IoUs, the predictions are accumulated in a confusion matrix,
weighted by sample_weight and the metric is then calculated from it.
If sample_weight is None, weights default to 1.
Use sample_weight of 0 to mask values.
This class can be used to compute the mean IoU for multi-class
classification tasks where the labels are one-hot encoded (the last axis
should have one dimension per class). Note that the predictions should also
have the same shape. To compute the mean IoU, first the labels and
predictions are converted back into integer format by taking the argmax over
the class axis. Then the same computation steps as for the base MeanIoU
class apply.
Note, if there is only one channel in the labels and predictions, this class
is the same as class MeanIoU. In this case, use MeanIoU instead.
Also, make sure that num_classes is equal to the number of classes in the
data, to avoid a "labels out of bound" error when the confusion matrix is
computed.
Args |
|---|
num_classes
(num_classes, num_classes) will be
allocated to accumulate predictions from which the metric is calculated.
name
dtype
ignore_class
ignore_class=None), all classes are considered.
sparse_y_pred
False, the tf.argmax function
will be used to determine each sample's most likely associated label.
axis
Standalone usage:
y_true = tf.constant([[0, 0, 1], [1, 0, 0], [0, 1, 0], [1, 0, 0]])y_pred = tf.constant([[0.2, 0.3, 0.5], [0.1, 0.2, 0.7], [0.5, 0.3, 0.1],[0.1, 0.4, 0.5]])sample_weight = [0.1, 0.2, 0.3, 0.4]m = tf.keras.metrics.OneHotMeanIoU(num_classes=3)m.update_state(y_true=y_true, y_pred=y_pred, sample_weight=sample_weight)# cm = [[0, 0, 0.2+0.4],# [0.3, 0, 0],# [0, 0, 0.1]]# sum_row = [0.3, 0, 0.7], sum_col = [0.6, 0.3, 0.1]# true_positives = [0, 0, 0.1]# single_iou = true_positives / (sum_row + sum_col - true_positives))# mean_iou = (0 + 0 + 0.1 / (0.7 + 0.1 - 0.1)) / 3m.result().numpy()0.048
Usage with compile() API:
model.compile(
optimizer='sgd',
loss='mse',
metrics=[tf.keras.metrics.OneHotMeanIoU(num_classes=3)])
Methods
merge_state
merge_state(
metrics
)
Merges the state from one or more metrics.
This method can be used by distributed systems to merge the state computed by different metric instances. Typically the state will be stored in the form of the metric's weights. For example, a tf.keras.metrics.Mean metric contains a list of two weight values: a total and a count. If there were two instances of a tf.keras.metrics.Accuracy that each independently aggregated partial state for an overall accuracy calculation, these two metric's states could be combined as follows:
m1 = tf.keras.metrics.Accuracy()_ = m1.update_state([[1], [2]], [[0], [2]])
m2 = tf.keras.metrics.Accuracy()_ = m2.update_state([[3], [4]], [[3], [4]])
m2.merge_state([m1])m2.result().numpy()0.75
| Args |
|---|
metrics
| Raises |
|---|
ValueError
reset_state
reset_state()
Resets all of the metric state variables.
This function is called between epochs/steps, when a metric is evaluated during training.
result
result()
Compute the intersection-over-union via the confusion matrix.
update_state
update_state(
y_true, y_pred, sample_weight=None
)
Accumulates the confusion matrix statistics.
| Args |
|---|
y_true
y_pred
sample_weight
Tensor whose rank is either 0, or the same rank as y_true,
and must be broadcastable to y_true.
| Returns | |
|---|---|
| Update op. |