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Dynamic Audio Data Augmentation
Key Benefits
Enhanced Robustness: By varying spectrogram parameters and injecting realistic noise, our models learn to handle a wide range of audio conditions.
Low Overhead: The augmentation is integrated into the existing pipeline, ensuring minimal additional computational cost. Data collator (low overhead) versus Dataset (higher overhead)
On-the-Fly Spectrogram Parameter Adjustment:
n_fft and hop_length: Values for n_fft and hop_length are randomly selected from predefined ranges for each audio sample, providing varied spectrogram representations.
Log-Mel Modulation:
Augmentation process integrates with the existing log-Mel spectrogram calculation. This means we modulate the parameters of the log-Mel spectrogram dynamically, ensuring no additional overhead is introduced while providing effective data augmentation.
Efficiency and Performance
Log-Mel Spectrogram Manipulation:
Augmentation process seamlessly integrates into the existing log-Mel spectrogram calculation, adding no extra overhead. This efficient design ensures that our preprocessing remains computationally lightweight and fast.
Adaptive Context-Aware Noise Injection
Preprocessing pipeline that includes adaptive context-aware noise injection to enhance model robustness. This method dynamically adjusts noise intensity based on the amplitude of the audio signal, ensuring realistic and effective augmentation.
- Types of Noise: White, pink, and environmental noise.
- Dynamic Adjustment: Noise intensity is scaled based on the amplitude of the audio signal.
- Integration: The noise injection process is seamlessly integrated into our existing log-Mel spectrogram calculation pipeline, adding minimal overhead.
Key Benefits
- Improved Generalization: Models become more resilient to noise and diverse audio conditions.
- Low Overhead: The augmentation process leverages the existing pipeline, ensuring efficient computation without significant additional cost.
Example Usage
## HF transformers or pure pytorch
data_collator = DataCollatorSpeechSeq2SeqWithPadding(
processor=processor,
decoder_start_token_id=model.config.decoder_start_token_id,
apply_augmentation=True,
apply_noise_injection=True # Enable adaptive noise injection
)
dataloader = torch.utils.data.DataLoader(dataset, batch_size=2, shuffle=True, collate_fn=data_collator)
for batch in dataloader:
outputs = model(batch)
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