How to compute the mean IU (mean Intersection over Union) score as in this paper?
Long, Jonathan, Evan Shelhamer, and Trevor Darrell. "Fully Convolutional Networks for Semantic Segmentation."
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1See also: how to calculate the IoU with Python– Martin ThomaMar 18, 2017 at 12:26
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4 Answers
For each class Intersection over Union (IU) score is:
true positive / (true positive + false positive + false negative)
The mean IU is simply the average over all classes.
Regarding the notation in the paper:
- n_cl : the number of classes
- t_i : the total number of pixels in class i
n_ij : the number of pixels of class i predicted to belong to class j. So for class i:
- n_ii : the number of correctly classified pixels (true positives)
- n_ij : the number of pixels wrongly classified (false positives)
- n_ji : the number of pixels wrongly not classifed (false negatives)
You can find the matlab code to compute this directly in the Pascak DevKit here
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3I think this is only for rectangular bounding boxes. For irregular shapes, I think this should work. Feb 11, 2017 at 14:03
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2What if I compute IOU like
true positive / (true positive + false positive + false negative)for each image in my dataset, what to do next? Should I compute average of all image IOU? What if on some images some classes are not presented and not predicted soI = 0andU = 0, so do I need to make 'counter' for each class separately when averaging IOU?– mrgloomApr 5, 2018 at 14:47 -
1you have to calculate tp/(tp + fp + fn) over all images in your test set. That means you sum up tp, fp, fn over all images in your test set for each class and after that you do calculate the IoU. Taking the average of each individual image IoU results in a wrong global IoU. Aug 20, 2018 at 13:17
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"Taking the average of each individual image IoU" I'm not saying this. You compute the IoU for all pixels in each class, then you take the average IoU over all classes.– MikiAug 20, 2018 at 13:28
from sklearn.metrics import confusion_matrix
import numpy as np
def compute_iou(y_pred, y_true):
# ytrue, ypred is a flatten vector
y_pred = y_pred.flatten()
y_true = y_true.flatten()
current = confusion_matrix(y_true, y_pred, labels=[0, 1])
# compute mean iou
intersection = np.diag(current)
ground_truth_set = current.sum(axis=1)
predicted_set = current.sum(axis=0)
union = ground_truth_set + predicted_set - intersection
IoU = intersection / union.astype(np.float32)
return np.mean(IoU)
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I had to use
return np.nanmeanhere, because 0 can be in a valid confusion matrix (us correctly never trying to predict something, leaves 0 confusion) Aug 25, 2020 at 2:23
This should help
def computeIoU(y_pred_batch, y_true_batch):
return np.mean(np.asarray([pixelAccuracy(y_pred_batch[i], y_true_batch[i]) for i in range(len(y_true_batch))]))
def pixelAccuracy(y_pred, y_true):
y_pred = np.argmax(np.reshape(y_pred,[N_CLASSES_PASCAL,img_rows,img_cols]),axis=0)
y_true = np.argmax(np.reshape(y_true,[N_CLASSES_PASCAL,img_rows,img_cols]),axis=0)
y_pred = y_pred * (y_true>0)
return 1.0 * np.sum((y_pred==y_true)*(y_true>0)) / np.sum(y_true>0)
answered Feb 11, 2017 at 14:05
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1The output
y_predis of the shapen_classes*h*wwe want to convert these into a single image where the pixel values equals the class at that pixel and that is why we take arg max across the class axis. May 17, 2017 at 15:46
The jaccard_similarity_score (per How to find IoU from segmentation masks?) can be used to get the same results as @Alex-zhai's code above:
import numpy as np
from sklearn.metrics import jaccard_score
y_true = np.array([[0, 1, 1],
[1, 1, 0]])
y_pred = np.array([[1, 1, 1],
[1, 0, 0]])
labels = [0, 1]
jaccards = []
for label in labels:
jaccard = jaccard_score(y_pred.flatten(),y_true.flatten(), pos_label=label)
jaccards.append(jaccard)
print(f'avg={np.mean(jaccards)}')