NVIDIA FastConformer-Hybrid Large (hy)
This model transcribes speech in Armenian language with capitalization and punctuation marks support. It is a "large" version of FastConformer Transducer-CTC (around 115M parameters) model and is trained on two losses: Transducer (default) and CTC. See the section Model Architecture and NeMo documentation for complete architecture details. The model transcribes text in Armenian with all Armenian punctuation and capitalization.
This model is ready for commercial and non-commercial use.
License
License to use this model is covered by the CC-BY-4.0. By downloading the public and release version of the model, you accept the terms and conditions of the CC-BY-4.0 license.
References
[1] Fast Conformer with Linearly Scalable Attention for Efficient Speech Recognition
[2] Google Sentencepiece Tokenizer
[4] HuggingFace ASR Leaderboard
Model Architecture
FastConformer [1] is an optimized version of the Conformer model with 8x depthwise-separable convolutional downsampling. The model is trained in a multitask setup with hybrid Transducer decoder (RNNT) and Connectionist Temporal Classification (CTC) loss. You may find more information on the details of FastConformer here: Fast-Conformer Model. Model utilizes a Google Sentencepiece Tokenizer [2] tokenizer with a vocabulary size of 1024.
Input
- Input Type: Audio
- Input Format(s): .wav files
- Other Properties Related to Input: 16000 Hz Mono-channel Audio, Pre-Processing Not Needed
Output
This model provides transcribed speech as a string for a given audio sample.
- Output Type: Text
- Output Format: String
- Output Parameters: One Dimensional (1D)
- Other Properties Related to Output: May Need Inverse Text Normalization; Does Not Handle Special Characters; Outputs text in Armenian with punctuation and capitalization
Limitations
The model is non-streaming. Not recommended for word-for-word transcription and punctuation as accuracy varies based on the characteristics of input audio (unrecognized word, accent, noise, speech type, and context of speech). Since this model was trained on publicly available speech datasets, the performance of this model might degrade for speech which includes domain specific terms , or vernacular that the model has not been trained on.
How to Use this Model
The model is available for use in the NeMo toolkit [3], and can be used as a pre-trained checkpoint for inference or for fine-tuning on another dataset.
Automatically instantiate the model
import nemo.collections.asr as nemo_asr
asr_model = nemo_asr.models.EncDecHybridRNNTCTCBPEModel.from_pretrained(model_name="nvidia/stt_hy_fastconformer_hybrid_large_pc")
Transcribing using Python
First, let's get a sample
wget https://dldata-public.s3.us-east-2.amazonaws.com/2086-149220-0033.wav
Then simply do:
asr_model.transcribe(['2086-149220-0033.wav'])
Transcribing many audio files
Using Transducer mode inference:
python [NEMO_GIT_FOLDER]/examples/asr/transcribe_speech.py
pretrained_name="nvidia/stt_hy_fastconformer_hybrid_large_pc"
audio_dir="<DIRECTORY CONTAINING AUDIO FILES>"
Using CTC mode inference:
python [NEMO_GIT_FOLDER]/examples/asr/transcribe_speech.py
pretrained_name="nvidia/stt_hy_fastconformer_hybrid_large_pc"
audio_dir="<DIRECTORY CONTAINING AUDIO FILES>"
decoder_type="ctc"
Training
The [NVIDIA NeMo Toolkit] [3] was used for training the model for two hundred epochs. Model is trained with this example script.
The tokenizer for these model was built using the text transcripts of the train set with this script.
Training, Testing, and Evaluation Datasets
Training Datasets
The model is trained on composite dataset comprising of 296.19 hours of Armenian speech.
Mozilla Common Voice 17.0 Armenian [48h]
Data Collection Method: by Human
Labeling Method: by Human
Google Fleurs Armenian [12h]
Data Collection Method: by Human
Labeling Method: by Human
ArmenianGrqaserAudioBooks [21.96h]
Data Collection Method: Automated
Labeling Method: Automated
Proprietary corpus 1 [69.23h]
Data Collection Method: by Human
Labeling Method: by Human
Proprietary corpus 2 [145 h]
Data Collection Method: Automated
Labeling Method: Automated
Evaluation Datasets
Mozilla Common Voice 17.0 Armenian
Data Collection Method: by Human
Labeling Method: by Human
-
Data Collection Method: by Human
Labeling Method: by Human
Test Datasets
Mozilla Common Voice 17.0 Armenian
Data Collection Method: by Human
Labeling Method: by Human
-
Data Collection Method: by Human
Labeling Method: by Human
Software Integration
Supported Hardware Microarchitecture Compatibility:
- NVIDIA Ampere
- NVIDIA Blackwell
- NVIDIA Jetson
- NVIDIA Hopper
- NVIDIA Lovelace
- NVIDIA Pascal
- NVIDIA Turing
- NVIDIA Volta
Runtime Engine
- Nemo 2.0.0
Preferred Operating System
- Linux
Ethical Considerations
NVIDIA believes Trustworthy AI is a shared responsibility and we have established policies and practices to enable development for a wide array of AI applications. When downloaded or used in accordance with our terms of service, developers should work with their internal model team to ensure this model meets requirements for the relevant industry and use case and addresses unforeseen product misuse.
Please report security vulnerabilities or NVIDIA AI Concerns here.
Explainability
- High-Level Application and Domain: Automatic Speech Recognition
- Describe how this model works: The model transcribes audio input into text for the Armenian language
- Verified to have met prescribed quality standards: Yes
- Performance Metrics: Word Error Rate (WER), Character Error Rate (CER), Real-Time Factor
- Potential Known Risks: Transcripts may not be 100% accurate. Accuracy varies based on the characteristics of input audio (Domain, Use Case, Accent, Noise, Speech Type, Context of speech, etcetera).
Performance
Test Hardware: A6000 GPU
The performance of Automatic Speech Recognition models is measured using Word Error Rate (WER) and Char Error Rate (CER). Since this dataset is trained on multiple domains, it will generally perform well at transcribing audio in general.
The following tables summarize the performance of the available models in this collection with the Transducer decoder. Performances of the ASR models are reported in terms of Word Error Rate (WER%) and Inverse Real-Time Factor (RTFx) with greedy decoding on test sets.
Transducer
NeMo Version Tokenizer Vocabulary Size MCV test WER MCV test RTFx FLEURS test WER FLEURS test RTFx 2.0.0 SentencePiece Unigram 1024 9.90 1535.45 12.32 1144.34 CTC
NeMo Version Tokenizer Vocabulary Size MCV test WER MCV test RTFx FLEURS test WER FLEURS test RTFx 2.0.0 SentencePiece Unigram 1024 11.19 1891.04 13.23 1565.59
These are greedy WER numbers without external LM. More details on evaluation can be found at HuggingFace ASR Leaderboard [4].
Bias
- Was the model trained with a specific accent? No
- Have any special measures been taken to mitigate unwanted bias? No
- Participation considerations from adversely impacted groups [protected classes] (https://www.senate.ca.gov/content/protected-classes) in model design and testing: No
Privacy
- Generatable or reverse engineerable personal data? No
- If applicable, was a notice provided to the individuals prior to the collection of any personal data used? Not applicable
- If personal data was collected for the development of the model, was it collected directly by NVIDIA? Not applicable
- Is there dataset provenance? Yes
- If data is labeled, was it reviewed to comply with privacy laws? Yes
- Is data compliant with data subject requests for data correction or removal, if such a request was made? No, not possible with externally-sourced data
- Is a mechanism in place to honor data subject rights of access or deletion of personal data? No
- How often is the training dataset reviewed?: Before Release
Safety & Security
Use Case Restrictions:
- Non-streaming ASR model
- Model outputs text in Armenian
- Output text requires Inverse Text Normalization
- Model is noise-sensitive
- Model is not applicable for life-critical applications.
Access Reactions:
The Principle of Least Privilege (PoLP) is applied limiting access for dataset generation and model development. Restrictions enforce dataset access during training and dataset license constraints adhered to.
NVIDIA Riva: Deployment
NVIDIA Riva is an accelerated speech AI SDK deployable on-prem, in all clouds, multi-cloud, hybrid, on edge, and embedded.
Additionally, Riva provides:
- World-class out-of-the-box accuracy for the most common languages with model checkpoints trained on proprietary data with hundreds of thousands of GPU-compute hours
- Best in class accuracy with run-time word boosting (e.g., brand and product names) and customization of acoustic model, language model, and inverse text normalization
- Streaming speech recognition, Kubernetes compatible scaling, and enterprise-grade support
- Although this model isn’t supported yet by Riva, the list of supported models is here. Check out Riva live demo.
Datasets used to train nvidia/stt_hy_fastconformer_hybrid_large_pc
Evaluation results
- Test WER on MCV17test set self-reported9.900
- Test WER on FLEURStest set self-reported12.320