Recurrent Highway Networks
Julian Georg Zilly
and
Rupesh Kumar Srivastava
and
Jan Koutník
and
Jürgen Schmidhuber
arXiv e-Print archive - 2016 via arXiv
Keywords:
cs.LG, cs.CL, cs.NE
First published: 2016/07/12 (7 years ago) Abstract: Many sequential processing tasks require complex nonlinear transition
functions from one step to the next. However, recurrent neural networks with
'deep' transition functions remain difficult to train, even when using Long
Short-Term Memory (LSTM) networks. We introduce a novel theoretical analysis of
recurrent networks based on Gersgorin's circle theorem that illuminates several
modeling and optimization issues and improves our understanding of the LSTM
cell. Based on this analysis we propose Recurrent Highway Networks, which
extend the LSTM architecture to allow step-to-step transition depths larger
than one. Several language modeling experiments demonstrate that the proposed
architecture results in powerful and efficient models. On the Penn Treebank
corpus, solely increasing the transition depth from 1 to 10 improves word-level
perplexity from 90.6 to 65.4 using the same number of parameters. On the larger
Wikipedia datasets for character prediction (text8 and enwik8), RHNs outperform
all previous results and achieve an entropy of 1.27 bits per character.
multi layer RNN in which first layer is LSTM, following layers $l$ have $t$,$c$ gates that control whether the state of the layer is carried from previous state or transferred previous layer:
$s_l^{[t]} = h_l^{[t]} \cdot t_l^{[t]} + s_{l-1}^{[t]} \cdot c
_l^{[t]}$