103,973 research outputs found
Tensorized Self-Attention: Efficiently Modeling Pairwise and Global Dependencies Together
Neural networks equipped with self-attention have parallelizable computation,
light-weight structure, and the ability to capture both long-range and local
dependencies. Further, their expressive power and performance can be boosted by
using a vector to measure pairwise dependency, but this requires to expand the
alignment matrix to a tensor, which results in memory and computation
bottlenecks. In this paper, we propose a novel attention mechanism called
"Multi-mask Tensorized Self-Attention" (MTSA), which is as fast and as
memory-efficient as a CNN, but significantly outperforms previous
CNN-/RNN-/attention-based models. MTSA 1) captures both pairwise (token2token)
and global (source2token) dependencies by a novel compatibility function
composed of dot-product and additive attentions, 2) uses a tensor to represent
the feature-wise alignment scores for better expressive power but only requires
parallelizable matrix multiplications, and 3) combines multi-head with
multi-dimensional attentions, and applies a distinct positional mask to each
head (subspace), so the memory and computation can be distributed to multiple
heads, each with sequential information encoded independently. The experiments
show that a CNN/RNN-free model based on MTSA achieves state-of-the-art or
competitive performance on nine NLP benchmarks with compelling memory- and
time-efficiency
A Convolutional Neural Network for Modelling Sentences
The ability to accurately represent sentences is central to language
understanding. We describe a convolutional architecture dubbed the Dynamic
Convolutional Neural Network (DCNN) that we adopt for the semantic modelling of
sentences. The network uses Dynamic k-Max Pooling, a global pooling operation
over linear sequences. The network handles input sentences of varying length
and induces a feature graph over the sentence that is capable of explicitly
capturing short and long-range relations. The network does not rely on a parse
tree and is easily applicable to any language. We test the DCNN in four
experiments: small scale binary and multi-class sentiment prediction, six-way
question classification and Twitter sentiment prediction by distant
supervision. The network achieves excellent performance in the first three
tasks and a greater than 25% error reduction in the last task with respect to
the strongest baseline
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