The primary obstacle to developing technologies for low-resource languages is the lack of representative, usable data. In this paper, we report the deployment of technology-driven data collection methods for creating a corpus of more than 60,000 translations from Hindi to Gondi, a low-resource vulnerable language spoken by around 2.3 million tribal people in south and central India. During this process, we help expand information access in Gondi across 2 different dimensions (a) The creation of linguistic resources that can be used by the community, such as a dictionary, children's stories, Gondi translations from multiple sources and an Interactive Voice Response (IVR) based mass awareness platform; (b) Enabling its use in the digital domain by developing a Hindi-Gondi machine translation model, which is compressed by nearly 4 times to enable it's edge deployment on low-resource edge devices and in areas of little to no internet connectivity. We also present preliminary evaluations of utilizing the developed machine translation model to provide assistance to volunteers who are involved in collecting more data for the target language. Through these interventions, we not only created a refined and evaluated corpus of 26,240 Hindi-Gondi translations that was used for building the translation model but also engaged nearly 850 community members who can help take Gondi onto the internet.

Leveraging shared learning through Massively Multilingual Models, state-of-the-art machine translation models are often able to adapt to the paucity of data for low-resource languages. However, this performance comes at the cost of significantly bloated models which are not practically deployable. Knowledge Distillation is one popular technique to develop competitive, lightweight models: In this work, we first evaluate its use to compress MT models focusing on languages with extremely limited training data. Through our analysis across 8 languages, we find that the variance in the performance of the distilled models due to their dependence on priors including the amount of synthetic data used for distillation, the student architecture, training hyperparameters and confidence of the teacher models, makes distillation a brittle compression mechanism. To mitigate this, we explore the use of post-training quantization for the compression of these models. Here, we find that while distillation provides gains across some low-resource languages, quantization provides more consistent performance trends for the entire range of languages, especially the lowest-resource languages in our target set.

我们介绍Samanantar，是最大的公开可用的并行Corpora Collection，用于指示语言。该集合中的英语和11个上线语言之间总共包含4970万句对（来自两种语言系列）。具体而言，我们从现有的公共可用并行基层编译1240万句对，另外，从网络上挖掘3740万句对，导致4倍增加。我们通过组合许多语料库，工具和方法来挖掘网站的并行句子：（a）Web爬行单格式语料库，（b）文档OCR，用于从扫描的文档中提取句子，（c）用于对齐句子的多语言表示模型，以及（d）近似最近的邻居搜索搜索大量句子。人类评估新矿业的Corpora的样本验证了11种语言的高质量平行句子。此外，我们使用英语作为枢轴语言，从英式并行语料库中提取所有55个指示语言对之间的834百万句子对。我们培训了跨越Samanantar上所有这些语言的多语种NMT模型，这在公开可用的基准上表现出现有的模型和基准，例如弗洛雷斯，建立萨曼塔尔的效用。我们的数据和模型可在Https://indicnlp.ai4bharat.org/samanantar/上公开提供，我们希望他们能够帮助推进NMT和Multibingual NLP的研究。

在现实世界的情况下，分布（OOD）数据集可能与培训数据集有很大的分配变化。当训练有素的分类器部署在不同的动态环境中时，这种现象通常发生，这会导致性能显着下降。为了解决这个问题，我们提出了这项工作中端到端的深度多任务网络。观察旋转预测（自我监督）精度和语义分类精度之间的牢固关系，我们在多任务网络中引入了一个附加的辅助分类头，以及语义分类和旋转预测头。为了观察该加法分类器在改善旋转预测头上的影响，我们提出的学习方法被构成双层优化问题，其中训练了上层级别以更新语义分类和旋转预测头的参数。在较低级别的优化中，仅通过固定语义分类头的参数来通过语义分类头进行更新。该方法已通过三个看不见的OOD数据集进行了验证，在该数据集中，它比其他两种基线方法表现出了清晰的语义分类精度。我们的代码可在github \ url {https://github.com/harshita-555/ossl}上获得