Combining Probabilistic Logic and Deep Learning for Self-Supervised Learning
Deep learning has proven effective for various application tasks, but its applicability is limited by the reliance on annotated examples. Self-supervised learning has emerged as a promising direction to alleviate the supervision bottleneck, but existing work focuses on leveraging co-occurrences in u...
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| creator | Poon, Hoifung Wang, Hai Lang, Hunter |
| description | Deep learning has proven effective for various application tasks, but its
applicability is limited by the reliance on annotated examples. Self-supervised
learning has emerged as a promising direction to alleviate the supervision
bottleneck, but existing work focuses on leveraging co-occurrences in unlabeled
data for task-agnostic representation learning, as exemplified by masked
language model pretraining. In this chapter, we explore task-specific
self-supervision, which leverages domain knowledge to automatically annotate
noisy training examples for end applications, either by introducing labeling
functions for annotating individual instances, or by imposing constraints over
interdependent label decisions. We first present deep probabilistic logic(DPL),
which offers a unifying framework for task-specific self-supervision by
composing probabilistic logic with deep learning. DPL represents unknown labels
as latent variables and incorporates diverse self-supervision using
probabilistic logic to train a deep neural network end-to-end using variational
EM. Next, we present self-supervised self-supervision(S4), which adds to DPL
the capability to learn new self-supervision automatically. Starting from an
initial seed self-supervision, S4 iteratively uses the deep neural network to
propose new self supervision. These are either added directly (a form of
structured self-training) or verified by a human expert (as in feature-based
active learning). Experiments on real-world applications such as biomedical
machine reading and various text classification tasks show that task-specific
self-supervision can effectively leverage domain expertise and often match the
accuracy of supervised methods with a tiny fraction of human effort. |
| doi_str_mv | 10.48550/arxiv.2107.12591 |
| format | Article |
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applicability is limited by the reliance on annotated examples. Self-supervised
learning has emerged as a promising direction to alleviate the supervision
bottleneck, but existing work focuses on leveraging co-occurrences in unlabeled
data for task-agnostic representation learning, as exemplified by masked
language model pretraining. In this chapter, we explore task-specific
self-supervision, which leverages domain knowledge to automatically annotate
noisy training examples for end applications, either by introducing labeling
functions for annotating individual instances, or by imposing constraints over
interdependent label decisions. We first present deep probabilistic logic(DPL),
which offers a unifying framework for task-specific self-supervision by
composing probabilistic logic with deep learning. DPL represents unknown labels
as latent variables and incorporates diverse self-supervision using
probabilistic logic to train a deep neural network end-to-end using variational
EM. Next, we present self-supervised self-supervision(S4), which adds to DPL
the capability to learn new self-supervision automatically. Starting from an
initial seed self-supervision, S4 iteratively uses the deep neural network to
propose new self supervision. These are either added directly (a form of
structured self-training) or verified by a human expert (as in feature-based
active learning). Experiments on real-world applications such as biomedical
machine reading and various text classification tasks show that task-specific
self-supervision can effectively leverage domain expertise and often match the
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applicability is limited by the reliance on annotated examples. Self-supervised
learning has emerged as a promising direction to alleviate the supervision
bottleneck, but existing work focuses on leveraging co-occurrences in unlabeled
data for task-agnostic representation learning, as exemplified by masked
language model pretraining. In this chapter, we explore task-specific
self-supervision, which leverages domain knowledge to automatically annotate
noisy training examples for end applications, either by introducing labeling
functions for annotating individual instances, or by imposing constraints over
interdependent label decisions. We first present deep probabilistic logic(DPL),
which offers a unifying framework for task-specific self-supervision by
composing probabilistic logic with deep learning. DPL represents unknown labels
as latent variables and incorporates diverse self-supervision using
probabilistic logic to train a deep neural network end-to-end using variational
EM. Next, we present self-supervised self-supervision(S4), which adds to DPL
the capability to learn new self-supervision automatically. Starting from an
initial seed self-supervision, S4 iteratively uses the deep neural network to
propose new self supervision. These are either added directly (a form of
structured self-training) or verified by a human expert (as in feature-based
active learning). Experiments on real-world applications such as biomedical
machine reading and various text classification tasks show that task-specific
self-supervision can effectively leverage domain expertise and often match the
accuracy of supervised methods with a tiny fraction of human effort.</description><subject>Computer Science - Artificial Intelligence</subject><subject>Computer Science - Learning</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNo9j81KxDAUhbOZhcz4AK7MC7Qmtz-3XUr9hYDCzL7cJDdDoNOWVAd9e7WKm3MW5-PAJ8SVVnnZVJW6ofQRzzlohbmGqtUXwnTTycYxjkf5miZLNg5xeYtOmun4nTR6ecc8S8OUVipMSe55CNn-feZ0jgv7_3EnNoGGhS__eisOD_eH7ikzL4_P3a3JqEadITsHbSDtXcEtYeMVFr5srK2UAyCvMVhLZU2u9AiebG2RNYBrCJiw2Irr39tVp59TPFH67H-0-lWr-AIfl0k3</recordid><startdate>20210727</startdate><enddate>20210727</enddate><creator>Poon, Hoifung</creator><creator>Wang, Hai</creator><creator>Lang, Hunter</creator><scope>AKY</scope><scope>GOX</scope></search><sort><creationdate>20210727</creationdate><title>Combining Probabilistic Logic and Deep Learning for Self-Supervised Learning</title><author>Poon, Hoifung ; Wang, Hai ; Lang, Hunter</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a671-7ecc29fa1dc3e9a78d073d48bb50c22ad17fbba46ac4d72dab6b7e122c8a2ea73</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2021</creationdate><topic>Computer Science - Artificial Intelligence</topic><topic>Computer Science - Learning</topic><toplevel>online_resources</toplevel><creatorcontrib>Poon, Hoifung</creatorcontrib><creatorcontrib>Wang, Hai</creatorcontrib><creatorcontrib>Lang, Hunter</creatorcontrib><collection>arXiv Computer Science</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Poon, Hoifung</au><au>Wang, Hai</au><au>Lang, Hunter</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Combining Probabilistic Logic and Deep Learning for Self-Supervised Learning</atitle><date>2021-07-27</date><risdate>2021</risdate><abstract>Deep learning has proven effective for various application tasks, but its
applicability is limited by the reliance on annotated examples. Self-supervised
learning has emerged as a promising direction to alleviate the supervision
bottleneck, but existing work focuses on leveraging co-occurrences in unlabeled
data for task-agnostic representation learning, as exemplified by masked
language model pretraining. In this chapter, we explore task-specific
self-supervision, which leverages domain knowledge to automatically annotate
noisy training examples for end applications, either by introducing labeling
functions for annotating individual instances, or by imposing constraints over
interdependent label decisions. We first present deep probabilistic logic(DPL),
which offers a unifying framework for task-specific self-supervision by
composing probabilistic logic with deep learning. DPL represents unknown labels
as latent variables and incorporates diverse self-supervision using
probabilistic logic to train a deep neural network end-to-end using variational
EM. Next, we present self-supervised self-supervision(S4), which adds to DPL
the capability to learn new self-supervision automatically. Starting from an
initial seed self-supervision, S4 iteratively uses the deep neural network to
propose new self supervision. These are either added directly (a form of
structured self-training) or verified by a human expert (as in feature-based
active learning). Experiments on real-world applications such as biomedical
machine reading and various text classification tasks show that task-specific
self-supervision can effectively leverage domain expertise and often match the
accuracy of supervised methods with a tiny fraction of human effort.</abstract><doi>10.48550/arxiv.2107.12591</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Artificial Intelligence Computer Science - Learning |
| title | Combining Probabilistic Logic and Deep Learning for Self-Supervised Learning |
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