Krishna Sri Ipsit Mantri


2023

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Transfer Learning for Low-Resource Clinical Named Entity Recognition
Nevasini Sasikumar | Krishna Sri Ipsit Mantri
Proceedings of the 5th Clinical Natural Language Processing Workshop

We propose a transfer learning method that adapts a high-resource English clinical NER model to low-resource languages and domains using only small amounts of in-domain annotated data. Our approach involves translating in-domain datasets to English, fine-tuning the English model on the translated data, and then transferring it to the target language/domain. Experiments on Spanish, French, and conversational clinical text datasets show accuracy gains over models trained on target data alone. Our method achieves state-of-the-art performance and can enable clinical NLP in more languages and modalities with limited resources.

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RWKV: Reinventing RNNs for the Transformer Era
Bo Peng | Eric Alcaide | Quentin Anthony | Alon Albalak | Samuel Arcadinho | Stella Biderman | Huanqi Cao | Xin Cheng | Michael Chung | Leon Derczynski | Xingjian Du | Matteo Grella | Kranthi Gv | Xuzheng He | Haowen Hou | Przemyslaw Kazienko | Jan Kocon | Jiaming Kong | Bartłomiej Koptyra | Hayden Lau | Jiaju Lin | Krishna Sri Ipsit Mantri | Ferdinand Mom | Atsushi Saito | Guangyu Song | Xiangru Tang | Johan Wind | Stanisław Woźniak | Zhenyuan Zhang | Qinghua Zhou | Jian Zhu | Rui-Jie Zhu
Findings of the Association for Computational Linguistics: EMNLP 2023

Transformers have revolutionized almost all natural language processing (NLP) tasks but suffer from memory and computational complexity that scales quadratically with sequence length. In contrast, recurrent neural networks (RNNs) exhibit linear scaling in memory and computational requirements but struggle to match the same performance as Transformers due to limitations in parallelization and scalability. We propose a novel model architecture, Receptance Weighted Key Value (RWKV), that combines the efficient parallelizable training of transformers with the efficient inference of RNNs. Our approach leverages a linear attention mechanism and allows us to formulate the model as either a Transformer or an RNN, thus parallelizing computations during training and maintains constant computational and memory complexity during inference. We scale our models as large as 14 billion parameters, by far the largest dense RNN ever trained, and find RWKV performs on par with similarly sized Transformers, suggesting future work can leverage this architecture to create more efficient models. This work presents a significant step towards reconciling trade-offs between computational efficiency and model performance in sequence processing tasks.