IEEE ICASSP 2024 workshop
Self-supervision in Audio, Speech and Beyond
14th of April 2024, Seoul, South Korea
Workshop description
Self-Supervised Learning (SSL) of latent representations is transforming deep learning powered technologies. In the speech and audio domains, most state-of-the-art systems rely on large Transformer neural networks pretrained on thousands of hours of signal following various methods such as contrastive or multitask learning.
Recent top-tier conferences from the field have seen an exponential increase in the number of accepted articles mentioning self-supervised learning techniques, yet many challenges still prevent a wider adoption of these techniques in real-life speech and audio technologies.
In facts, SSL models currently suffer from critical complexity issues, the lack of a standardized and widely adopted evaluation protocol, dramatic biases and robustness concerns as well as disconnection with others closely related modalities (e.g. text or video).
Throughout a schedule that maximizes interactions within the audience via multiple panels and a poster session, the Self-supervision in Audio, Speech and Beyond (SASB) workshop aims at fostering interactions from the whole SSL community including experts from different modalities.
SASB will act as a dedicated place for the SSL community to properly frame the building of a technology currently appearing as a groundbreaking solution for the audio, speech and beyond communities.
More details
The ongoing success of deep learning techniques depends on the quality of the representations automatically discovered from data [4]. These representations must capture important underlying structures from the raw input, e.g. intermediate concepts, features, or latent variables that are useful for the downstream task. While supervised learning using large annotated corpora can leverage useful representations, collecting large amounts of annotated examples is costly, time-consuming, and not always feasible. This is particularly problematic for a large variety of applications. In the speech domain, for instance, there are many low-resource languages, where the progress is dramatically slower than in high-resource languages such as English. Moreover, annotations are often underspecified for many potential downstream applications, and the related supervised representations might be biased towards the task they are trained on, limiting their exportability to other applications [25].
Natural ways to mitigate these issues are unsupervised [5] and self-supervised learning [12, 19, 20, 15]. Following its increasing popularity within the computer vision community, many attempts have been done to extend self-supervised learning to discover audio and speech representations [18, 11, 21, 23, 22, 24, 3, 16]. Recent systems including wav2vec 2.0, HuBERT or WavLM [3, 16, 9] achieved unprecedented performance on highly competitive tasks including speech and speaker recognition, speech translation, emotion recognition, intent detection and many others. Nevertheless, applying self-supervised learning to speech remains particularly challenging. Speech signals, in fact, are not only high-dimensional, long, and variable-length sequences, but also entail a complex hierarchical structure that is difficult to infer without supervision (e.g. phonemes, syllables, words). Moreover, speech is characterized by an important variability due to different speaker identities, accents, recording conditions and noises that highly increase the level of complexity. Hence, novel architectures must continualy be invented to further push the state-of-the-art as well as to give low-resources languages highly-competitive speech technologies, and we believe that the SASB workshop will play a key role in facing those directions.
Then, the complexity of the speech and audio signals not only reflect in the nature of the neural architecture that must be highly tailored for the considered domain, but also with the need for extreme compute resources to train such models. For instance, it is quite common to see the largest available models to be trained for weeks or months on hundreds of high-end GPU, each worth many thousands of euros [1, 13]. Therefore, and perhaps unfortunately, speech systems are rapidly moving away from accessible paradigms to niche foundation models [6] that only a few extremely large companies can create due to the huge need for computer power and data. Hence, and despite an astonishing jump in performance on the short-term, large-scale SSL models could quickly become a major barrier for academic research as it already is impossible for the vast majority of the institutions to train them, hence relying on two or three companies. Very few attemps have been made to solve this issue [10], and we hope that the SASB workshop will foster interest around the efficiency of SSL models that appears as a critical topic in a world facing climate change.
The evaluation of SSL models also suffers from critical issues that remain to be solved. In particular, and conversely to traditional speech tasks, e.g. speech recognition, no real protocol is widely accepted by the community to assess the universality of a SSL representation. Recently, SUPERB and LeBenchmark [27, 13] proposed benchmarks to normalize the evaluation protocol. SUPERB, in particular, is being increasinly adopted by the community. Unfortunately, both benchmarks suffer from a lack of complexity in the adopted datasets as most of latest SSL models achieve near to perfect results, making it very hard to distinginsh their performance in a potential real-world scenario. Finally, and as demonstrated with SUPERB and LeBenchmark, the current trend is to evaluate SSL models solely based on their downstream performance, hence necessitating potentially dozens or hundreds of costly fine-tunings. An other direction, represented with a very scarce litterature [28], proposes to measure the quality, robustness of a given representation without downstream fine-tuning, speeding-up drastically the development process. The SASB workshop will offer a workplace for the SSL community to discuss actively how our models should be evaluated.
Social and technical biases for SSL models applied to natural language processing (NLP) are an active field of research [7]. For instance, gender biases are also found for machine translation tasks [8], as well as in facial recognition systems [8] and ASR [14]. Interestingly however, and despite the clear growing adoption of SSL in the speech community, the inclusiveness and robustness of SotA models remains a completely open question. More precisely, speech SSL architectures currently struggle at encompassing the information from the diversity of population and acoustic environments making them potentially unfair such as for large NLP SSL models [7] or unreliable with realistic conditions (e.g. noise, multiple speakers, variety of accents, genders equity ...) [17].
Finally, the speech signal itself might not be sufficient to achieve the seaked universal representation. Data2vec [2], for instance, have demonstrated that combining speech, image and text during a single SSL pre-training could lead to massive improvement over a wide variety of different tasks originating from all the domains. It is indeed natural to consider multimodality as the next step for SSL. The later could either be done at the pre-training level, such as in Data2vec, or at the fine-tuning stage, by combining different representation in a final model [26] . Nevertheless, achieving multimodal SSL is a long-term goal that we should tackle step by step as a community. With SASB, we will hope to encourage original research in the direction of SSL for audio or speech combined with an other modality such as audio-visual SSL or audio-text SSL.
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