We analyse the dynamics of convolutional filters’ parameters of a convolutional neural networks during and after training, via a thermodynamic analogy which allows for a sound definition of temperature. We show that removing high temperature filters has a minor effect on the performance of the model, while removing low temperature filters influences majorly both accuracy and loss decay. This result could be exploited to implement a temperature-based pruning technique for the filters and to determine efficiently the crucial filters for an effective learning.
Lapenna, M., Faglioni, F., Fioresi, R. (2023). Thermodynamics modeling of deep learning systems for a temperature based filter pruning technique. FRONTIERS IN PHYSICS, 11, 1-12 [10.3389/fphy.2023.1145156].
Thermodynamics modeling of deep learning systems for a temperature based filter pruning technique
Lapenna, M.
Primo
;Faglioni, F.Secondo
;Fioresi, R.Ultimo
2023
Abstract
We analyse the dynamics of convolutional filters’ parameters of a convolutional neural networks during and after training, via a thermodynamic analogy which allows for a sound definition of temperature. We show that removing high temperature filters has a minor effect on the performance of the model, while removing low temperature filters influences majorly both accuracy and loss decay. This result could be exploited to implement a temperature-based pruning technique for the filters and to determine efficiently the crucial filters for an effective learning.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
