--- license: apache-2.0 pipeline_tag: text-to-speech tags: - text-to-speech - tts - audio - speech-synthesis - voice-cloning - autoregressive - flow-matching - post-trained library_name: dots_tts base_model: rednote-hilab/dots.tts-base --- # dots.tts-soar

GitHub Playground Demo Page

**dots.tts** is a **2B-parameter fully continuous, end-to-end autoregressive (AR) text-to-speech system**. The backbone pairs a semantic encoder, an LLM, and an autoregressive flow-matching acoustic head over a 48 kHz AudioVAE — no discrete codec tokens anywhere in the pipeline. This repository hosts **`dots.tts-soar`** — the pretrained backbone further refined with **Self-corrective Alignment (SCA)**, a reward-free flow-matching-native post-training stage. SCA pushes the model to the **highest zero-shot fidelity and speaker similarity** of the three releases and is the **recommended default for production zero-shot voice cloning**.
dots.tts-base Pretrain (~1.5M h). Fine-tuning, full CFG / NFE control.
dots.tts-soar you are here — + Self-corrective Alignment. Highest zero-shot fidelity and speaker similarity; also recommended for fine-tuning.
dots.tts-mf + MeanFlow distillation. Few-step inference (NFE = 4), low latency.
--- ## Quick Start ### Installation ```bash conda create -n dots_tts python=3.10 -y conda activate dots_tts python -m pip install --upgrade pip python -m pip install "git+https://github.com/rednote-hilab/dots.tts.git" \ -c "https://raw.githubusercontent.com/rednote-hilab/dots.tts/main/constraints/recommended.txt" ``` ### CLI ```bash # Continuation voice cloning (reference audio + transcript) — recommended dots.tts \ --model-name-or-path rednote-hilab/dots.tts-soar \ --text "Hello, this is a zero-shot voice cloning demonstration." \ --prompt-audio /path/to/reference.wav \ --prompt-text "The exact transcript of the reference audio." \ --output clone.wav ``` ### Python API ```python from dots_tts.runtime import DotsTtsRuntime import soundfile as sf runtime = DotsTtsRuntime.from_pretrained( "rednote-hilab/dots.tts-soar", precision="bfloat16", ) result = runtime.generate( text="Hello, this is a quick speech synthesis test.", prompt_audio_path="/path/to/reference.wav", prompt_text="The exact transcript of the reference audio.", num_steps=10, guidance_scale=1.2, ) sf.write("output.wav", result["audio"].float().cpu().squeeze().numpy(), result["sample_rate"]) ``` ### Recommended sampling settings | Flag | Recommended | Notes | |---|---:|---| | `--num-steps` | `10`–`32` | Flow-matching sampling steps; higher = better quality, slower | | `--guidance-scale` | `1.2` (default) | Standard CFG; SCA already tightens text and timbre adherence so small CFG suffices | ### Fine-tuning Both `dots.tts-base` and `dots.tts-soar` are valid fine-tuning starting points. Pick `dots.tts-soar` when you want to inherit its tightened text/timbre alignment on top of the pretrained backbone. See the [training script](https://github.com/rednote-hilab/dots.tts/blob/main/scripts/train_dots_tts.py) and [smoke config](https://github.com/rednote-hilab/dots.tts/blob/main/configs/dots_tts.yaml) in the source repository: ```bash accelerate launch scripts/train_dots_tts.py --config configs/dots_tts.yaml ``` --- ## Architecture A frozen **AudioVAE** encodes 48 kHz mono waveform into a continuous latent and decodes it back via a BigVGAN-style causal decoder. An **autoregressive backbone** predicts that latent one patch at a time: - **Semantic encoder** — re-encodes each newly generated VAE patch into a compact embedding for the LLM, stripping high-variance acoustic detail. - **LLM** — initialized from **Qwen2.5-1.5B-Base**, consumes BPE text directly (no phonemes), emits one hidden state per audio step. - **AR flow-matching head** — a DiT that conditions on the LLM hidden state and the AR prefix to denoise the next VAE patch, with a frozen CAM++ speaker x-vector as side input. **Self-corrective Alignment** is a reward-free, flow-matching-native post-training stage applied on top of `dots.tts-base`. It improves text and speaker adherence without changing inference cost or sampling schedule. --- ## Performance — `dots.tts-soar` ### Seed-TTS-Eval — **state-of-the-art average SIM (79.2)** | Model | Params | test-en WER↓ / SIM↑ | test-zh WER↓ / SIM↑ | test-zh-hard WER↓ / SIM↑ | **Avg WER↓ / SIM↑** | |---|---:|:---:|:---:|:---:|:---:| | Seed-TTS | — | 2.25 / 76.2 | 1.12 / 79.6 | 7.59 / 77.6 | 3.65 / 77.8 | | Qwen3-TTS | 1.7B | **1.23** / 71.7 | 1.22 / 77.0 | 6.76 / 74.8 | 3.07 / 74.5 | | VoxCPM 2 | 2B | 1.84 / 75.3 | 0.97 / 79.5 | 8.13 / 75.3 | 3.65 / 76.7 | | dots.tts-base | 2B | 1.34 / 76.8 | 0.96 / 80.5 | **6.46** / 79.2 | **2.92** / 78.8 | | **dots.tts-soar** | **2B** | 1.30 / **77.1** | **0.94** / **81.0** | 6.60 / **79.5** | 2.95 / **79.2** | ### MiniMax Multilingual — **highest average SIM (83.9) across 24 languages** | Model | Avg WER↓ | Avg SIM↑ | |---|:---:|:---:| | MiniMax | **2.8** | 76.6 | | Fish-Audio S2 | 3.7 | 78.0 | | VoxCPM 2 | 5.7 | 82.3 | | dots.tts-base | 6.6 | 83.5 | | **dots.tts-soar** | 6.8 | **83.9** | ### CV3-Eval — **leads both cross-lingual SIM subsets** | Model | en→zh SIM↑ | zh→en SIM↑ | |---|:---:|:---:| | CosyVoice 3 (1.5B) | 66.9 | 66.4 | | dots.tts-base | 74.6 | 71.9 | | **dots.tts-soar** | **75.0** | **72.8** | ### EmergentTTS-Eval — **top Syntactic Complexity in the table (65.7%)** On head-to-head judging vs. `gpt-4o-mini-tts`, `dots.tts-soar` posts **65.7% on Syntactic Complexity — above every closed-source system listed**, while keeping competitive Emotions / Questions scores. See the [project README](https://github.com/rednote-hilab/dots.tts#-performance) for full benchmark tables. --- ## Risks and Limitations - **Misuse risk.** High-fidelity zero-shot voice cloning can produce highly realistic synthetic speech. This checkpoint is intended for research and authorized deployment. Do **not** use it for impersonation, fraud, or disinformation. Combine downstream use with consent-aware reference-audio policies, robust synthetic-speech detection, and content watermarking. Clearly mark AI-generated audio. - **Low-resource WER gap.** A BPE backbone inherits the text LLM's language coverage at the cost of a higher data appetite. On script-divergent and under-represented languages (Arabic, Hindi, Turkish, Vietnamese) WER is higher than on high-resource languages; speaker similarity is preserved. - **Speech-heavy training.** The backbone is trained on a speech-heavy mixture. Singing and unified speech + sound generation are not covered. --- ## Citation ```bibtex @article{dotstts2026, title = {dots.tts Technical Report}, author = {dots.tts Team}, journal = {arXiv preprint}, year = {2026}, } ``` ## License Released under [Apache-2.0](https://www.apache.org/licenses/LICENSE-2.0).