a Language Modeling Method to Audio Era

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a Language Modeling Method to Audio Era


Producing sensible audio requires modeling data represented at completely different scales. For instance, simply as music builds complicated musical phrases from particular person notes, speech combines temporally native constructions, similar to phonemes or syllables, into phrases and sentences. Creating well-structured and coherent audio sequences in any respect these scales is a problem that has been addressed by coupling audio with transcriptions that may information the generative course of, be it textual content transcripts for speech synthesis or MIDI representations for piano. Nevertheless, this method breaks when making an attempt to mannequin untranscribed features of audio, similar to speaker traits essential to assist folks with speech impairments get better their voice, or stylistic elements of a piano efficiency.

In “AudioLM: a Language Modeling Method to Audio Era”, we suggest a brand new framework for audio technology that learns to generate sensible speech and piano music by listening to audio solely. Audio generated by AudioLM demonstrates long-term consistency (e.g., syntax in speech, melody in music) and excessive constancy, outperforming earlier techniques and pushing the frontiers of audio technology with functions in speech synthesis or computer-assisted music. Following our AI Ideas, we have additionally developed a mannequin to establish artificial audio generated by AudioLM.

From Textual content to Audio Language Fashions
Lately, language fashions skilled on very massive textual content corpora have demonstrated their distinctive generative skills, from open-ended dialogue to machine translation and even common sense reasoning. They’ve additional proven their capability to mannequin different alerts than texts, such as pure photos. The important thing instinct behind AudioLM is to leverage such advances in language modeling to generate audio with out being skilled on annotated information.

Nevertheless, some challenges have to be addressed when shifting from textual content language fashions to audio language fashions. First, one should deal with the truth that the info fee for audio is considerably increased, thus resulting in for much longer sequences — whereas a written sentence could be represented by a number of dozen characters, its audio waveform usually incorporates tons of of 1000’s of values. Second, there’s a one-to-many relationship between textual content and audio. Which means the identical sentence could be rendered by completely different audio system with completely different talking kinds, emotional content material and recording situations.

To beat each challenges, AudioLM leverages two sorts of audio tokens. First, semantic tokens are extracted from w2v-BERT, a self-supervised audio mannequin. These tokens seize each native dependencies (e.g., phonetics in speech, native melody in piano music) and international long-term construction (e.g., language syntax and semantic content material in speech, concord and rhythm in piano music), whereas closely downsampling the audio sign to permit for modeling lengthy sequences.

Nevertheless, audio reconstructed from these tokens demonstrates poor constancy. To beat this limitation, along with semantic tokens, we depend on acoustic tokens produced by a SoundStream neural codec, which seize the small print of the audio waveform (similar to speaker traits or recording situations) and permit for high-quality synthesis. Coaching a system to generate each semantic and acoustic tokens leads concurrently to excessive audio high quality and long-term consistency.

Coaching an Audio-Solely Language Mannequin
AudioLM is a pure audio mannequin that’s skilled with none textual content or symbolic illustration of music. AudioLM fashions an audio sequence hierarchically, from semantic tokens as much as positive acoustic tokens, by chaining a number of Transformer fashions, one for every stage. Every stage is skilled for the following token prediction primarily based on previous tokens, as one would prepare a textual content language mannequin. The primary stage performs this activity on semantic tokens to mannequin the high-level construction of the audio sequence.

Within the second stage, we concatenate all the semantic token sequence, together with the previous coarse acoustic tokens, and feed each as conditioning to the coarse acoustic mannequin, which then predicts the long run tokens. This step fashions acoustic properties similar to speaker traits in speech or timbre in music.

Within the third stage, we course of the coarse acoustic tokens with the positive acoustic mannequin, which provides much more element to the ultimate audio. Lastly, we feed acoustic tokens to the SoundStream decoder to reconstruct a waveform.

After coaching, one can situation AudioLM on a number of seconds of audio, which permits it to generate constant continuation. To be able to showcase the overall applicability of the AudioLM framework, we think about two duties from completely different audio domains:

  • Speech continuation, the place the mannequin is predicted to retain the speaker traits, prosody and recording situations of the immediate whereas producing new content material that’s syntactically right and semantically constant.
  • Piano continuation, the place the mannequin is predicted to generate piano music that’s coherent with the immediate when it comes to melody, concord and rhythm.

Within the video beneath, you possibly can hearken to examples the place the mannequin is requested to proceed both speech or music and generate new content material that was not seen throughout coaching. As you pay attention, observe that the whole lot you hear after the grey vertical line was generated by AudioLM and that the mannequin has by no means seen any textual content or musical transcription, however moderately simply discovered from uncooked audio. We launch extra samples on this webpage.

To validate our outcomes, we requested human raters to hearken to quick audio clips and determine whether or not it’s an unique recording of human speech or an artificial continuation generated by AudioLM. Based mostly on the rankings collected, we noticed a 51.2% success fee, which isn’t statistically considerably completely different from the 50% success fee achieved when assigning labels at random. Which means speech generated by AudioLM is tough to differentiate from actual speech for the common listener.

Our work on AudioLM is for analysis functions and we’ve no plans to launch it extra broadly right now. In alignment with our AI Ideas, we sought to grasp and mitigate the likelihood that folks may misread the quick speech samples synthesized by AudioLM as actual speech. For this function, we skilled a classifier that may detect artificial speech generated by AudioLM with very excessive accuracy (98.6%). This exhibits that regardless of being (virtually) indistinguishable to some listeners, continuations generated by AudioLM are very straightforward to detect with a easy audio classifier. It is a essential first step to assist shield towards the potential misuse of AudioLM, with future efforts doubtlessly exploring applied sciences similar to audio “watermarking”.

Conclusion
We introduce AudioLM, a language modeling method to audio technology that gives each long-term coherence and excessive audio high quality. Experiments on speech technology present not solely that AudioLM can generate syntactically and semantically coherent speech with none textual content, but additionally that continuations produced by the mannequin are virtually indistinguishable from actual speech by people. Furthermore, AudioLM goes effectively past speech and may mannequin arbitrary audio alerts similar to piano music. This encourages the long run extensions to different forms of audio (e.g., multilingual speech, polyphonic music, and audio occasions) in addition to integrating AudioLM into an encoder-decoder framework for conditioned duties similar to text-to-speech or speech-to-speech translation.

Acknowledgments
The work described right here was authored by Zalán Borsos, Raphaël Marinier, Damien Vincent, Eugene Kharitonov, Olivier Pietquin, Matt Sharifi, Olivier Teboul, David Grangier, Marco Tagliasacchi and Neil Zeghidour. We’re grateful for all discussions and suggestions on this work that we obtained from our colleagues at Google.

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