# TinyWave Expressive Speech 2B **TinyWave Expressive Speech 2B** is a compact speech-to-speech language model distilled from the 7B SPIRIT-LM-Expressive teacher. It is trained to generate rich, expressive spoken language—capturing prosody, emotion, and speaker variation—purely from speech inputs. Using a HuBERT-based discrete tokenizer augmented with **pitch and style tokens**, this model offers **high-fidelity expressive generation** with just 2B parameters, making it ideal for **low-latency deployment** in storytelling, assistive speech technologies, and interactive voice systems. > 📖 For details, see the [TinyWave paper (arXiv:2506.23670)](https://arxiv.org/abs/2506.23670) and [project website](https://mohammadmahdinoori.github.io/tinywave-landing/). --- ## 🔧 Usage This model requires **SPIRIT-LM's expressive speech tokenizer** for both encoding and decoding HuBERT-based audio tokens. ### 1. Clone SPIRIT-LM and Install Dependencies ```bash git clone https://github.com/facebookresearch/spiritlm cd spiritlm pip install -e '.[eval]' ```` --- ### 2. Load Tokenizer ```python from spiritlm.speech_tokenizer import spiritlm_expressive speech_tokenizer = spiritlm_expressive() ``` --- ### 3. Inference Code (Speech-to-Speech) ```python from transformers import LlamaForCausalLM, AutoTokenizer import torchaudio import torch # Load model and tokenizer MODEL_PATH = "tinywave/speech-expressive-2b" tokenizer = AutoTokenizer.from_pretrained(MODEL_PATH) model = LlamaForCausalLM.from_pretrained(MODEL_PATH, device_map="auto", torch_dtype=torch.bfloat16) # Load expressive speech tokenizer speech_tokenizer = spiritlm_expressive() def get_inference(audio_path): audio, _ = torchaudio.load(audio_path) input_values = audio.view(1, 1, -1).to(speech_tokenizer.hubert_model.device).float() tokens = speech_tokenizer.encode_string(input_values) input_ids = tokenizer(tokens, return_tensors="pt").input_ids.to(model.device) output = model.generate(input_ids, max_new_tokens=256, top_p=0.9, temperature=0.9, do_sample=True) return tokenizer.decode(output[0]) ``` --- ### 4. Decode to WAV ```python import numpy as np from scipy.io.wavfile import write def save_array_to_wav_int16(audio_array: np.ndarray, sampling_rate=16000, filename="output.wav"): scaled = np.int16(audio_array / np.max(np.abs(audio_array)) * 32767) write(filename, sampling_rate, scaled) decoded_audio = speech_tokenizer.decode(generated_output.replace(" ", "").replace("", "").replace("", ""), speaker_id=2) save_array_to_wav_int16(decoded_audio, filename="generated.wav") ``` --- ## 🗣️ Inference Examples ### 🎧 Expressive Speech Continuation Input: Spoken sentence (`.wav`) Output: Expressive continuation in the same tone, pitch, and speaking style. --- ## 🧠 Model Details | Feature | Description | | ------------------- | ----------------------------------------------- | | Architecture | 2B parameter distilled transformer | | Tokenizer | SPIRIT-LM Expressive (HuBERT + prosody) | | Input Type | Discrete HuBERT tokens only (speech-only) | | Output Type | Discrete audio tokens (speech continuation) | | Teacher Model | SPIRIT-LM-Expressive 7B | | Tasks | Expressive speech continuation | | Distillation Method | Layer-aligned: hidden states, attention, logits | --- ## 📎 Citation ```bibtex @article{nouriborji2025tinywave, title={Efficient Interleaved Speech Modeling through Knowledge Distillation}, author={Nouriborji, Mohammadmahdi and Rohanian, Morteza}, journal={arXiv preprint arXiv:2506.23670}, year={2025} } ``` --- ## 📂 Resources * 🔗 [Project Page](https://mohammadmahdinoori.github.io/tinywave-landing/) * 💬 [Demo Samples](https://mohammadmahdinoori.github.io/tinywave-landing/#samples) * 🧠 [Training & Codebase](https://github.com/mohammadmahdinoori/TinyWave)