Shaojie Bai scite author profile

Human language is often multimodal, which comprehends a mixture of natural language, facial gestures, and acoustic behaviors. However, two major challenges in modeling such multimodal human language time-series data exist: 1) inherent data non-alignment due to variable sampling rates for the sequences from each modality; and 2) long-range dependencies between elements across modalities. In this paper, we introduce the Multimodal Transformer (MulT) to generically address the above issues in an end-to-end manner without explicitly aligning the data. At the heart of our model is the directional pairwise crossmodal attention, which attends to interactions between multimodal sequences across distinct time steps and latently adapt streams from one modality to another. Comprehensive experiments on both aligned and non-aligned multimodal time-series show that our model outperforms state-of-the-art methods by a large margin. In addition, empirical analysis suggests that correlated crossmodal signals are able to be captured by the proposed crossmodal attention mechanism in MulT.

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Deep Equilibrium Models

Bai¹,

Kolter²,

Koltun³

2019

Preprint

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Transformer Dissection: An Unified Understanding for Transformer’s Attention via the Lens of Kernel

Tsai¹,

Bai²,

Yamada³

et al. 2019

102

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Transformer is a powerful architecture that achieves superior performance on various sequence learning tasks, including neural machine translation, language understanding, and sequence prediction. At the core of the Transformer is the attention mechanism, which concurrently processes all inputs in the streams. In this paper, we present a new formulation of attention via the lens of the kernel. To be more precise, we realize that the attention can be seen as applying kernel smoother over the inputs with the kernel scores being the similarities between inputs. This new formulation gives us a better way to understand individual components of the Transformer's attention, such as the better way to integrate the positional embedding. Another important advantage of our kernel-based formulation is that it paves the way to a larger space of composing Transformer's attention. As an example, we propose a new variant of Transformer's attention which models the input as a product of symmetric kernels. This approach achieves competitive performance to the current state of the art model with less computation. In our experiments, we empirically study different kernel construction strategies on two widely used tasks: neural machine translation and sequence prediction.

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Deep Equilibrium Optical Flow Estimation

Bai

Geng

Savani

et al. 2022

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Transformer Dissection: A Unified Understanding of Transformer's Attention via the Lens of Kernel

Tsai¹,

Bai²,

Yamada³

et al. 2019

Preprint

View full text Add to dashboard Cite

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Shaojie Bai

Multimodal Transformer for Unaligned Multimodal Language Sequences

Deep Equilibrium Models

Transformer Dissection: An Unified Understanding for Transformer’s Attention via the Lens of Kernel

Deep Equilibrium Optical Flow Estimation

Transformer Dissection: A Unified Understanding of Transformer's Attention via the Lens of Kernel

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