TY - GEN
T1 - Normalization propagation
T2 - 33rd International Conference on Machine Learning, ICML 2016
AU - Arpit, Devansh
AU - Zhou, Yingbo
AU - Kota, Bhargava U.
AU - Govindaraju, Venu
PY - 2016
Y1 - 2016
N2 - While the authors of Batch Normalization (BN) identify and address an important problem involved in training deep networks-Internal Covariate Shift-the current solution has certain drawbacks. For instance, BN depends on batch statistics for layerwise input normalization during training which makes the estimates of mean and standard deviation of input (distribution) to hidden layers inaccurate due to shifting parameter values (especially during initial training epochs). Another fundamental problem with BN is that it cannot be used with batch-size 1 during training. We address these drawbacks of BN by proposing a non-adaptive normalization technique for removing covariate shift, that we call Normalization Propagation. Our approach does not depend on batch statistics, but rather uses a data-independent parametric estimate of mean and standard-deviation in every layer thus being computationally faster compared with BN. We exploit the observation that the pre-activation before Rectified Linear Units follow Gaussian distribution in deep networks, and that once the first and second order statistics of any given dataset are normalized, we can forward propagate this normalization without the need for recalculating the approximate statistics for hidden layers.
AB - While the authors of Batch Normalization (BN) identify and address an important problem involved in training deep networks-Internal Covariate Shift-the current solution has certain drawbacks. For instance, BN depends on batch statistics for layerwise input normalization during training which makes the estimates of mean and standard deviation of input (distribution) to hidden layers inaccurate due to shifting parameter values (especially during initial training epochs). Another fundamental problem with BN is that it cannot be used with batch-size 1 during training. We address these drawbacks of BN by proposing a non-adaptive normalization technique for removing covariate shift, that we call Normalization Propagation. Our approach does not depend on batch statistics, but rather uses a data-independent parametric estimate of mean and standard-deviation in every layer thus being computationally faster compared with BN. We exploit the observation that the pre-activation before Rectified Linear Units follow Gaussian distribution in deep networks, and that once the first and second order statistics of any given dataset are normalized, we can forward propagate this normalization without the need for recalculating the approximate statistics for hidden layers.
UR - https://www.scopus.com/pages/publications/84998773543
M3 - Conference contribution
AN - SCOPUS:84998773543
T3 - 33rd International Conference on Machine Learning, ICML 2016
SP - 1800
EP - 1810
BT - 33rd International Conference on Machine Learning, ICML 2016
A2 - Weinberger, Kilian Q.
A2 - Balcan, Maria Florina
PB - International Machine Learning Society (IMLS)
Y2 - 19 June 2016 through 24 June 2016
ER -