DravidianCodeMix: Sentiment Analysis and Offensive Language Identification Dataset for Dravidian Languages in Code-Mixed Text

This paper describes the development of a multilingual, manually annotated dataset for three under-resourced Dravidian languages generated from social media comments. The dataset was annotated for sentiment analysis and offensive language identification for a total of more than 60,000 YouTube comments. The dataset consists of around 44,000 comments in Tamil-English, around 7,000 comments in Kannada-English, and around 20,000 comments in Malayalam-English. The data was manually annotated by volunteer annotators and has a high inter-annotator agreement in Krippendorff's alpha. The dataset contains all types of code-mixing phenomena since it comprises user-generated content from a multilingual country. We also present baseline experiments to establish benchmarks on the dataset using machine learning methods. The dataset is available on Github (https://github.com/bharathichezhiyan/DravidianCodeMix-Dataset) and Zenodo (https://zenodo.org/record/4750858\#.YJtw0SYo\_0M).Comment: 36 page

The Uli Dataset: An Exercise in Experience Led Annotation of oGBV

Online gender based violence has grown concomitantly with adoption of the internet and social media. Its effects are worse in the Global majority where many users use social media in languages other than English. The scale and volume of conversations on the internet has necessitated the need for automated detection of hate speech, and more specifically gendered abuse. There is, however, a lack of language specific and contextual data to build such automated tools. In this paper we present a dataset on gendered abuse in three languages- Hindi, Tamil and Indian English. The dataset comprises of tweets annotated along three questions pertaining to the experience of gender abuse, by experts who identify as women or a member of the LGBTQIA community in South Asia. Through this dataset we demonstrate a participatory approach to creating datasets that drive AI systems

The Simple4All entry to the Blizzard Challenge 2013

We describe the synthetic voices entered into the 2013 Blizzard Challenge by the SIMPLE4ALL consortium. The 2013 Blizzard Challenge presents an opportunity to test and benchmark some of the tools we have been developing to address two problems of interest: 1) how best to learn from plentiful ‘found’ data, and 2) how to produce systems in arbitrary new languages with minimal annotated data and language-specific expertise on the part of the system builders. We here explain how our tools were used to address these problems on the different tasks of the challenge, and provide some discussion of the evaluation results. Index Terms: statistical parametric speech synthesis, speech alignment, speech segmentation, style diarisation, unsupervise

Self-supervised learning in natural language processing

Most natural language processing (NLP) learning algorithms require labeled data. While this is given for a select number of (mostly English) tasks, the availability of labeled data is sparse or non-existent for the vast majority of use-cases. To alleviate this, unsupervised learning and a wide array of data augmentation techniques have been developed (Hedderich et al., 2021a). However, unsupervised learning often requires massive amounts of unlabeled data and also fails to perform in difficult (low-resource) data settings, i.e., if there is an increased distance between the source and target data distributions (Kim et al., 2020). This distributional distance can be the case if there is a domain drift or large linguistic distance between the source and target data. Unsupervised learning in itself does not exploit the highly informative (labeled) supervisory signals hidden in unlabeled data. In this dissertation, we show that by combining the right unsupervised auxiliary task (e.g., sentence pair extraction) with an appropriate primary task (e.g., machine translation), self-supervised learning can exploit these hidden supervisory signals more efficiently than purely unsupervised approaches, while functioning on less labeled data than supervised approaches. Our self-supervised learning approach can be used to learn NLP tasks in an efficient manner, even when the amount of training data is sparse or the data comes with strong differences in its underlying distribution, e.g., stemming from unrelated languages. For our general approach, we applied unsupervised learning as an auxiliary task to learn a supervised primary task. Concretely, we have focused on the auxiliary task of sentence pair extraction for sequence-to-sequence primary tasks (i.e., machine translation and style transfer) as well as language modeling, clustering, subspace learning and knowledge integration for primary classification tasks (i.e., hate speech detection and sentiment analysis). For sequence-to-sequence tasks, we show that self-supervised neural machine translation (NMT) achieves competitive results on high-resource language pairs in comparison to unsupervised NMT while requiring less data. Further combining self-supervised NMT with unsupervised NMT-inspired augmentation techniques makes the learning of low-resource (similar, distant and unrelated) language pairs possible. Further, using our self-supervised approach, we show how style transfer can be learned without the need for parallel data, generating stylistic rephrasings of highest overall performance on all tested tasks. For sequence-to-label tasks, we underline the benefit of auxiliary task-based augmentation over primary task augmentation. An auxiliary task that showed to be especially beneficial to the primary task performance was subspace learning, which led to impressive gains in (cross-lingual) zero-shot classification performance on similar or distant target tasks, also on similar, distant and unrelated languages.Die meisten Lernalgorithmen der Computerlingistik (CL) benötigen gelabelte Daten. Diese sind zwar für eine Auswahl an (hautpsächlich Englischen) Aufgaben verfügbar, für den Großteil aller Anwendungsfälle sind gelabelte Daten jedoch nur spärrlich bis gar nicht vorhanden. Um dem gegenzusteuern, wurde eine große Auswahl an Techniken entwickelt, welche sich das unüberwachte Lernen oder Datenaugmentierung zu eigen machen (Hedderich et al., 2021a). Unüberwachtes Lernen benötigt jedoch massive Mengen an ungelabelten Daten und versagt, wenn es mit schwierigen (resourcenarmen) Datensituationen konfrontiert wird, d.h. wenn eine größere Distanz zwischen der Quellen- und Zieldatendistributionen vorhanden ist (Kim et al., 2020). Eine distributionelle Distanz kann zum Beispiel der Fall sein, wenn ein Domänenunterschied oder eine größere sprachliche Distanz zwischen der Quellenund Zieldaten besteht. Unüberwachtes Lernen selbst nutzt die hochinformativen (gelabelten) Überwachungssignale, welche sich in ungelabelte Daten verstecken, nicht aus. In dieser Dissertation zeigen wir, dass selbstüberwachtes Lernen, durch die Kombination der richtigen unüberwachten Hilfsaufgabe (z.B. Satzpaarextraktion) mit einer passenden Hauptaufgabe (z.B. maschinelle Übersetzung), diese versteckten Überwachsungssignale effizienter ausnutzen kann als pure unüberwachte Lernalgorithmen, und dabei auch noch weniger gelabelte Daten benötigen als überwachte Lernalgorithmen. Unser selbstüberwachter Lernansatz erlaubt es uns, CL Aufgaben effizient zu lernen, selbst wenn die Trainingsdatenmenge spärrlich ist oder die Daten mit starken distributionellen Differenzen einher gehen, z.B. weil die Daten von zwei nicht verwandten Sprachen stammen. Im Generellen haben wir unüberwachtes Lernen als Hilfsaufgabe angewandt um eine überwachte Hauptaufgabe zu erlernen. Konkret haben wir uns auf Satzpaarextraktion als Hilfsaufgabe für Sequenz-zu-Sequenz Hauptaufgaben (z.B. maschinelle Übersetzung und Stilübertragung) konzentriert sowohl als auch Sprachmodelierung, Clustern, Teilraumlernen und Wissensintegration zum erlernen von Klassifikationsaufgaben (z.B. Hassredenidentifikation und Sentimentanalyse). Für Sequenz-zu-Sequenz Aufgaben zeigen wir, dass selbstüberwachte maschinelle Übersetzung (MÜ) im Vergleich zur unüberwachten MÜ wettbewerbsfähige Ergebnisse auf resourcenreichen Sprachpaaren erreicht und währenddessen weniger Daten zum Lernen benötigt. Wenn selbstüberwachte MÜ mit Augmentationstechniken, inspiriert durch unüberwachte MÜ, kombiniert wird, wird auch das Lernen von resourcenarmen (ähnlichen, entfernt verwandten und nicht verwandten) Sprachpaaren möglich. Außerdem zeigen wir, wie unser selbsüberwachter Lernansatz es ermöglicht Stilübertragung ohne parallele Daten zu erlernen und dabei stylistische Umformulierungen von höchster Qualität auf allen geprüften Aufgaben zu erlangen. Für Sequenz-zu-Label Aufgaben unterstreichen wir den Vorteil, welchen hilfsaufgabenseitige Augmentierung über hauptaufgabenseitige Augmentierung hat. Eine Hilfsaufgabe welche sich als besonders hilfreich für die Qualität der Hauptaufgabe herausstellte ist das Teilraumlernen, welches zu beeindruckenden Leistungssteigerungen für (sprachübergreifende) zero-shot Klassifikation ähnlicher und entfernter Zielaufgaben (auch für ähnliche, entfernt verwandte und nicht verwandte Sprachen) führt

Representation Learning beyond Semantic Similarity: Character-aware and Function-specific Approaches

Representation learning is a research area within machine learning and natural language processing (NLP) concerned with building machine-understandable representations of discrete units of text. Continuous representations are at the core of modern machine learning applications, and representation learning has thereby become one of the central research areas in NLP. The induction of text representations is typically based on the distributional hypothesis, and consequently encodes general information about word similarity. Words or phrases with similar meaning obtain similar representations in a vector space constructed for this purpose. This established methodology excels for morphologically-simple languages such as English, and in data-rich settings. However, several useful lexical relations such as entailment or selectional preference, are not captured or get conflated with other relations. Another challenge is dealing with low-data regimes for morphologically-complex and under-resourced languages. In this thesis we construct novel representation learning methods that go beyond the limitations of the distributional hypothesis and investigate solutions that induce vector spaces with diverse properties. In particular, we look at how the vector space induction process influences the contained information, and how the information manifests in a number of core NLP tasks: semantic similarity, lexical entailment, selectional preference, and language modeling. We contribute novel evaluations of state-of-the-art models highlighting their current capabilities and limitations. An analysis of language modeling in 50 typologically-diverse languages demonstrates that representations can indeed pose a performance bottleneck. We introduce a novel approach to leveraging subword-level information in word representations: our solution lifts this bottleneck in low-resource scenarios. Finally, we introduce a novel paradigm of function-specific representation learning that aims to integrate fine-grained semantic relations and real-world knowledge into the word vector spaces. We hope this thesis can serve as a valuable overview on word representations, and inspire future work in modeling \textit{semantic similarity and beyond}.ERC Consolidator Grant LEXICAL (648909