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Cross-Situational Learning Towards Robot Grounding
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In: https://hal.archives-ouvertes.fr/hal-03628290 ; 2022 (2022)
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Cross-Situational Learning Towards Robot Grounding
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In: https://hal.archives-ouvertes.fr/hal-03628290 ; 2022 (2022)
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Context-Based Fake News Detection Model Relying on Deep Learning Models
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In: Electronics; Volume 11; Issue 8; Pages: 1255 (2022)
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Deep Sentiment Analysis Using CNN-LSTM Architecture of English and Roman Urdu Text Shared in Social Media
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In: Applied Sciences; Volume 12; Issue 5; Pages: 2694 (2022)
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Methods, Models and Tools for Improving the Quality of Textual Annotations
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In: Modelling; Volume 3; Issue 2; Pages: 224-242 (2022)
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Deep Learning XAI for Bus Passenger Forecasting: A Use Case in Spain
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In: Mathematics; Volume 10; Issue 9; Pages: 1428 (2022)
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How Well Do LSTM Language Models Learn Filler-gap Dependencies?
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In: Proceedings of the Society for Computation in Linguistics (2022)
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Deep Learning Methods for Human Behavior Recognition
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Lu, Jia. - : Auckland University of Technology, 2021
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Εφαρμογές βαθιάς μάθησης ... : Applications of deep learning ...
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An Auditory Saliency Pooling-Based LSTM Model for Speech Intelligibility Classification
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In: Symmetry ; Volume 13 ; Issue 9 (2021)
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Discriminative Multi-Stream Postfilters Based on Deep Learning for Enhancing Statistical Parametric Speech Synthesis
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In: Biomimetics ; Volume 6 ; Issue 1 (2021)
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Korean Prosody Phrase Boundary Prediction Model for Speech Synthesis Service in Smart Healthcare
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In: Electronics ; Volume 10 ; Issue 19 (2021)
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Dynamic gesture classification of American Sign Language using deep learning
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Neural semantic role labeling with more or less supervision
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Cai, Rui. - : The University of Edinburgh, 2021
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Abstract:
In recent years, thanks to the relative maturity of neural network models, the task of automatically identifying and labeling the semantic roles has been the focus of renewed interest. These models have the capacity to learn continuous representations automatically and thereby forgo the need for extensive feature engineering. Semantic role labeling (SRL) has generally been recognized as a core task in natural language processing (NLP) and has been shown to benefit a range of NLP applications such as machine translation, information extraction and summarization. Recent SRL systems have usually been trained on datasets whose semantic role annotations have been produced on the top of tree-banked corpora. This reflects the intimate relationship between syntactic information and semantic roles. In order to effectively incorporate syntactic information into neural network models, we train the semantic role labeler jointly with two auxiliary tasks: predicting the dependency label of a word, and determining whether there exists an arc linking it to the predicate. The auxiliary tasks provide syntactic information that is specific to SRL and can be learnt from training data (dependency annotations). This liberates our SRL system from the dependence on external parsers, which is believed to be noisy (e.g., on out-of-domain data or infrequent constructions). Supervised neural SRL models, which derive their efficacy via sufficient annotated data, are driven by data. Nonetheless, the reliance on high-quality annotations obscures the development of SRL systems in low-resource scenarios (e.g., rare languages or domains). In order to reduce the annotation effort involved, we have rendered semi-supervised learning for SRL as simple as possible. More specifically, we propose an end-to-end SRL model and demonstrate it could effectively leverage unlabeled data within the cross-view training modeling paradigm. Our semantic role labeler is jointly trained with auxiliary tasks subsidiary to SRL. Consequently, our system may be applied directly to plain text, and it is essentially self-sufficient. For true low-resource languages, we cannot even expect to perform semi-supervised learning for them, as SRL annotations are only available for a handful of the world’s languages. To build a competitive semantic role labeler for these low-resource languages, we have resorted to cross-lingual semantic role labeling, which can transfer supervision in a source language to target languages (low-resource languages). The backbone of our model is an LSTM-based semantic role labeler jointly trained with a semantic role compressor and multilingual word embeddings. The compressor collects useful information from the output of semantic role labeler and compress it into fixed-size cross-lingual representations. Our model (in contrast to earlier efforts, which deployed automatic alignments in order to transfer annotations) exists in a space of mul-tilingual embeddings. For the target language, moreover, it affords direct supervision for the prediction of semantic roles. For model evaluation, we have also contributed two quality-controlled datasets, which we hope will be useful for the development of cross-lingual models.
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Keyword:
LSTM-based semantic role labeler; natural language processing; semantic role labeling; supervised neural SRL models; tree-banked corpora
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URL: https://doi.org/10.7488/era/1538 https://hdl.handle.net/1842/38272
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An auditory saliency pooling-based LSTM model for speech intelligibility classification
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A study on the impact of neural architectures for Unsupervised Machine Translation
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Structure-(in)dependent Interpretation of Phrases in Humans and LSTMs
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In: Proceedings of the Society for Computation in Linguistics (2021)
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Narrow-band Deep Filtering for Multichannel Speech Enhancement
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In: https://hal.inria.fr/hal-02378413 ; 2020 (2020)
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Place perception from the fusion of different image representation
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In: Li, P, Li, X, Li, X, Pan, H, Khyam, MO, Noor-A-Rahim, M, Ge, SS, (2020). Place perception from the fusion of different image representation. Pattern Recognition, Vol. 110, p. 1-11 http://dx.doi.org/10.1016/j.patcog.2020.107680 (2020)
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Identifying complaints from product reviews: a case study on Hindi
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In: Singh, Raghvendra Pratap, Haque, Rejwanul orcid:0000-0003-1680-0099 , Hasanuzzaman, Mohammed orcid:0000-0003-1838-0091 and Way, Andy orcid:0000-0001-5736-5930 (2020) Identifying complaints from product reviews: a case study on Hindi. In: 28th Irish Conference on Artificial Intelligence and Cognitive Science, 7-8 Dec 2020, Dublin, Ireland. (2020)
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