supertone-inc/supertonic

Supertonic — Lightning Fast, On-Device, Accurate TTS

Supertonic 3 Banner

Supertonic is a lightning-fast, on-device multilingual text-to-speech system designed for local inference with minimal overhead. Powered by ONNX Runtime, it runs entirely on your device—no cloud, no API calls, no privacy concerns.

✨ Highlights

⚡ Blazingly Fast — Low-latency, real-time synthesis across desktop, browser, mobile, and edge — fast enough to turn an entire webpage into audio in under a second
🌍 31-Language Multilingual — Synthesize directly from text across 31 languages, or pass lang="na" to let Supertonic process the text language-agnostically when you don’t know the input language — no separate language adapters needed
🪶 99M-Parameter Open-Weight Model — A compact, fully open-weight checkpoint — a fraction of the size of 0.7B–2B class open TTS systems — for smaller downloads, faster cold starts, and lower memory footprint
📱 Edge-Device Ready — Runs locally on desktop, mobile, browsers, and resource-constrained hardware like Raspberry Pi or e-readers, with zero network dependency, complete privacy, and no GPU required
🔊 44.1kHz High-Quality Audio — Outputs studio-grade 44.1kHz 16-bit WAV directly, ready for production playback without any external upsampler
🎭 Expression Tags — 10 inline tags (e.g. <laugh>, <breath>, <sigh>) bring natural human nuance into generated speech without prompt engineering or reference audio
🛠️ Multi-Runtime SDKs — Ready-to-use examples through ONNX Runtime across Python, Node.js, Browser (WebGPU), Java, C++, C#, Go, Swift, iOS, Rust, and Flutter

🌍 Supported Languages (31)

Arabic (ar), Bulgarian (bg), Croatian (hr), Czech (cs), Danish (da), Dutch (nl), English (en), Estonian (et), Finnish (fi), French (fr), German (de), Greek (el), Hindi (hi), Hungarian (hu), Indonesian (id), Italian (it), Japanese (ja), Korean (ko), Latvian (lv), Lithuanian (lt), Polish (pl), Portuguese (pt), Romanian (ro), Russian (ru), Slovak (sk), Slovenian (sl), Spanish (es), Swedish (sv), Turkish (tr), Ukrainian (uk), Vietnamese (vi)

Not sure which language your text is in? Pass lang="na" and Supertonic will handle the input in a language-agnostic way — no explicit language tag required.

📰 Update News

2026.05.18 - Python SDK v1.3.1 adds supertonic serve, a local HTTP server with native /v1/tts and OpenAI-compatible /v1/audio/speech endpoints. See the serve documentation.
2026.05.18 - Voice Builder now supports Supertonic 3. Create a permanent custom voice profile for Supertonic and download version-specific JSON files for both Supertonic 2 and Supertonic 3. If you already created a Supertonic 2 voice, the matching Supertonic 3 JSON is now available from My Page.
2026.04.29 - 🎉 Supertonic 3 released with 31-language support, improved reading accuracy, fewer repeat/skip failures, and v2-compatible public ONNX assets. Demo | Models
2026.01.22 - Voice Builder is now live! Turn your voice into a deployable, edge-native TTS with permanent ownership.
2026.01.06 - 🎉 Supertonic 2 released with 5-language support. The v2 code path is preserved on the release/supertonic-2 branch.
2025.12.10 - Added supertonic PyPI package! Install via pip install supertonic. For details, visit supertonic-py documentation
2025.12.10 - Added 6 new voice styles (M3, M4, M5, F3, F4, F5). See Voices for details
2025.12.08 - Optimized ONNX models via OnnxSlim now available on Hugging Face Models
2025.11.24 - Added Flutter SDK support with macOS compatibility

Quick Start

Install the Python SDK and generate speech immediately. On the first run, Supertonic downloads the model assets from Hugging Face automatically.

1

pip install supertonic

Python

 1
 2
 3
 4
 5
 6
 7
 8
 9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24


from supertonic import TTS

# First run downloads the model from Hugging Face automatically.
tts = TTS(auto_download=True)

style = tts.get_voice_style(voice_name="M1")

text = "Supertonic is a lightning fast, on-device TTS system."

wav, duration = tts.synthesize(
    text=text,
    lang="en",                      # Language code (e.g., "en", "ko", "na" for language-agnostic)
    voice_style=style,              # Voice style object
    total_steps=8,                  # Quality: 5 (low) to 12 (high), default 8 (medium)
    speed=1.05,                     # Speed: 0.7 (slow) to 2.0 (fast)
)
# wav: numpy array of shape (1, num_samples,) with dtype=np.float32, sampled at 44100 Hz
# duration: numpy array of shape (1,) containing the duration of the generated audio in seconds

tts.save_audio(wav, "output.wav")
# import soundfile as sf
# sf.write("output.wav", wav.squeeze(), 44100)

print(f"Generated {duration[0]:.2f}s of audio")

Local HTTP Server

The Python SDK can also run Supertonic as a local HTTP service. This is useful when you want to call Supertonic from tools that already speak HTTP, such as local agents, browser extensions, Electron apps, workflow automation tools, or OpenAI-compatible audio clients.

1
2


pip install 'supertonic[serve]'
supertonic serve --host 127.0.0.1 --port 7788

Once running, use the native POST /v1/tts endpoint or the OpenAI-compatible POST /v1/audio/speech endpoint. The server also exposes interactive OpenAPI docs at http://127.0.0.1:7788/docs. See the supertonic-py serve guide for request examples, batch synthesis, and custom Voice Builder JSON import.

Getting Started

First, clone the repository:

1
2


git clone https://github.com/supertone-inc/supertonic.git
cd supertonic

Prerequisites

Before running the examples, download the ONNX models and preset voices, and place them in the assets directory:

Note: The Hugging Face repository uses Git LFS. Please ensure Git LFS is installed and initialized before cloning or pulling large model files.

macOS: brew install git-lfs && git lfs install

Generic: see https://git-lfs.com for installers

1
2


git lfs install
git clone https://huggingface.co/Supertone/supertonic-3 assets

Some language examples need native runtimes:

Go: install the ONNX Runtime C library. On macOS, brew install onnxruntime is enough; the Go example auto-detects Homebrew paths.
Java: use a JDK, not just a JRE. On macOS, brew install openjdk@17 works.
C#: targets .NET 9 and allows major-version roll-forward, so .NET 9 or newer runtimes can run it.

Then run the Python example:

1
2
3


cd py
uv sync
uv run example_onnx.py

This generates outputs/output.wav using the default preset voice.

Other Runtime Examples

Run Supertonic in other languages and platforms

Node.js Example (Details)

1
2
3


cd nodejs
npm install
npm start

Browser Example (Details)

1
2
3


cd web
npm install
npm run dev

Java Example (Details)

1
2
3


cd java
mvn clean install
mvn exec:java

C++ Example (Details)

1
2
3
4


cd cpp
mkdir build && cd build
cmake .. && cmake --build . --config Release
./example_onnx

C# Example (Details)

1
2
3


cd csharp
dotnet restore
dotnet run

Go Example (Details)

1
2
3


cd go
go mod download
go run example_onnx.go helper.go

Swift Example (Details)

1
2
3


cd swift
swift build -c release
.build/release/example_onnx

Rust Example (Details)

1
2
3


cd rust
cargo build --release
./target/release/example_onnx

iOS Example (Details)

1
2
3


cd ios/ExampleiOSApp
xcodegen generate
open ExampleiOSApp.xcodeproj

In Xcode: Targets → ExampleiOSApp → Signing: select your Team, then choose your iPhone as run destination and build.

Technical Details

Runtime: ONNX Runtime for cross-platform inference
Browser Support: onnxruntime-web for client-side inference
Batch Processing: Supports batch inference for improved throughput
Audio Output: Outputs 44.1kHz 16-bit WAV files

Performance Highlights

Supertonic 3 is designed for practical on-device inference: compact enough to run locally, while staying competitive with much larger open TTS systems.

Reading Accuracy

Supertonic 3 reading accuracy compared with measured model ranges and VoxCPM2

Evaluated on the Minimax-MLS-test benchmark, Supertonic 3 stays within a competitive WER/CER range against much larger open TTS models such as VoxCPM2, while preserving a lightweight on-device deployment path. Asterisked languages (*) use CER; the others use WER.

📊 Detailed per-language results (WER / CER*)

Lang	VoxCPM2	OmniVoice	Qwen3-TTS	Supertonic 2	Supertonic 3
arabic*	4.14	1.74	—	—	2.14
czech	23.73	2.40	—	—	3.02
dutch	0.84	0.77	—	—	1.47
english	2.11	2.02	2.25	2.52	2.06
finnish	2.29	3.94	—	—	5.40
french	4.41	4.74	3.82	5.09	4.89
german	0.85	0.96	0.52	—	0.86
greek	3.22	2.96	—	—	3.54
hindi*	5.85	5.14	—	—	5.34
indonesian	1.25	1.67	—	—	1.34
italian	1.74	1.29	1.40	—	1.75
japanese*	3.35	3.81	3.67	—	4.61
korean*	4.70	3.22	4.07	3.65	3.26
polish	1.30	0.64	—	—	1.63
portuguese	1.74	1.40	1.21	1.52	2.48
romanian	22.39	2.29	—	—	2.19
russian	3.31	4.53	4.48	—	3.99
spanish	1.34	0.99	0.75	1.81	1.13
turkish	0.88	2.18	—	—	1.00
ukrainian	5.85	0.71	—	—	1.23
vietnamese	1.48	0.79	—	—	4.49

Lower is better. * indicates CER (character error rate); all other rows use WER (word error rate). Dashes (—) indicate the model does not officially support the language or no result is available.

Supertonic 2 to Supertonic 3

Supertonic 2 and Supertonic 3 comparison

Compared with Supertonic 2, Supertonic 3 reduces repeat and skip failures, improves speaker similarity across the shared-language set, and expands language coverage from 5 to 31 languages. It keeps the v2-compatible public ONNX interface, so existing integrations can move to v3 with the same inference contract.

Runtime Footprint

Supertonic CPU runtime compared with GPU baselines

Supertonic 3 runs fast on CPU, even compared with larger baselines measured on A100 GPU, and uses substantially less memory. The open-weight fixed-voice setting does not require a GPU, which makes local, browser, and edge deployment much easier.

Model Size

Model size comparison

At about 99M parameters across the public ONNX assets, Supertonic 3 is much smaller than 0.7B to 2B class open TTS systems. The smaller model size is a practical advantage for download size, startup time, and on-device inference.

Voice Cloning

This open-weight repository focuses on fixed-voice, local TTS and does not include an official voice-cloning pipeline. If you want to bring your own voice to local Supertonic deployment, Voice Builder turns a short reference recording into version-specific JSON files for Supertonic 2 and Supertonic 3, so the same custom voice can move with you across supported Supertonic versions.

For a managed creation workflow, Supertone Play and the Supertone API provide hosted TTS and voice services with 700+ commercially usable preset voices. You can also listen to Supertonic 3 zero-shot samples on the official showcase.

Demo

Try it now: Experience Supertonic in your browser with our Interactive Demo, or get started with pre-trained models from Hugging Face Hub

Raspberry Pi

Watch Supertonic running on a Raspberry Pi, demonstrating on-device, real-time text-to-speech synthesis:

https://github.com/user-attachments/assets/ea66f6d6-7bc5-4308-8a88-1ce3e07400d2

E-Reader

Experience Supertonic on an Onyx Boox Go 6 e-reader in airplane mode, achieving an average RTF of 0.3× with zero network dependency:

https://github.com/user-attachments/assets/64980e58-ad91-423a-9623-78c2ffc13680

Chrome Extension

Turns any webpage into audio in under one second, delivering lightning-fast, on-device text-to-speech with zero network dependency—free, private, and effortless:

https://github.com/user-attachments/assets/cc8a45fc-5c3e-4b2c-8439-a14c3d00d91c

Programming Language Support

We provide ready-to-use TTS inference examples across multiple ecosystems:

Language/Platform	Path	Description
Python	`py/`	ONNX Runtime inference
Node.js	`nodejs/`	Server-side JavaScript
Browser	`web/`	WebGPU/WASM inference
Java	`java/`	Cross-platform JVM
C++	`cpp/`	High-performance C++
C#	`csharp/`	.NET ecosystem
Go	`go/`	Go implementation
Swift	`swift/`	macOS applications
iOS	`ios/`	Native iOS apps
Rust	`rust/`	Memory-safe systems
Flutter	`flutter/`	Cross-platform apps

For detailed usage instructions, please refer to the README.md in each language directory.

Natural Text Handling

Supertonic is designed to handle complex, real-world text inputs that contain natural prose, punctuation, abbreviations, and proper nouns.

🎧 View audio samples more easily: Check out our Interactive Demo for a better viewing experience of all audio examples

Overview of Test Cases:

Category	Key Challenges	Supertonic	ElevenLabs	OpenAI	Gemini	Microsoft
Financial Expression	Decimal currency, abbreviated magnitudes (M, K), currency symbols, currency codes	✅	❌	❌	❌	❌
Phone Number	Area codes, hyphens, extensions (ext.)	✅	❌	❌	❌	❌
Technical Unit	Decimal numbers with units, abbreviated technical notations	✅	❌	❌	❌	❌

Example 1: Financial Expression

Text:

“The startup secured $5.2M in venture capital, a huge leap from their initial $450K seed round.”

Challenges:

Decimal point in currency ($5.2M should be read as “five point two million”)
Abbreviated magnitude units (M for million, K for thousand)
Currency symbol ($) that needs to be properly pronounced as “dollars”

Audio Samples:

System	Result	Audio Sample
Supertonic	✅	🎧 Play Audio
ElevenLabs Flash v2.5	❌	🎧 Play Audio
OpenAI TTS-1	❌	🎧 Play Audio
Gemini 2.5 Flash TTS	❌	🎧 Play Audio
VibeVoice Realtime 0.5B	❌	🎧 Play Audio

Example 2: Phone Number

Text:

“You can reach the hotel front desk at (212) 555-0142 ext. 402 anytime.”

Challenges:

Area code in parentheses that should be read as separate digits
Phone number with hyphen separator (555-0142)
Abbreviated extension notation (ext.)
Extension number (402)

Audio Samples:

System	Result	Audio Sample
Supertonic	✅	🎧 Play Audio
ElevenLabs Flash v2.5	❌	🎧 Play Audio
OpenAI TTS-1	❌	🎧 Play Audio
Gemini 2.5 Flash TTS	❌	🎧 Play Audio
VibeVoice Realtime 0.5B	❌	🎧 Play Audio

Example 3: Technical Unit

Text:

“Our drone battery lasts 2.3h when flying at 30kph with full camera payload.”

Challenges:

Decimal time duration with abbreviation (2.3h = two point three hours)
Speed unit with abbreviation (30kph = thirty kilometers per hour)
Technical abbreviations (h for hours, kph for kilometers per hour)
Technical/engineering context requiring proper pronunciation

Audio Samples:

System	Result	Audio Sample
Supertonic	✅	🎧 Play Audio
ElevenLabs Flash v2.5	❌	🎧 Play Audio
OpenAI TTS-1	❌	🎧 Play Audio
Gemini 2.5 Flash TTS	❌	🎧 Play Audio
VibeVoice Realtime 0.5B	❌	🎧 Play Audio

Note: These samples demonstrate how each system handles text normalization and pronunciation of complex expressions without requiring pre-processing or phonetic annotations.

Built with Supertonic

Project	Description	Links
TLDRL	Free, on-device TTS extension for reading any webpage	Chrome
Read Aloud	Open-source TTS browser extension	Chrome · Edge · GitHub
PageEcho	E-Book reader app for iOS	App Store
VoiceChat	On-device voice-to-voice LLM chatbot in the browser	Demo · GitHub
OmniAvatar	Talking avatar video generator from photo + speech	Demo
CopiloTTS	Kotlin Multiplatform TTS SDK via ONNX Runtime	GitHub
Voice Mixer	PyQt5 tool for mixing and modifying voice styles	GitHub
Supertonic MNN	Lightweight library based on MNN (fp32/fp16/int8)	GitHub · PyPI
Transformers.js	Hugging Face’s JS library with Supertonic support	GitHub PR · Demo
Pinokio	1-click localhost cloud for Mac, Windows, and Linux	Pinokio · GitHub

Models & Versions

	Supertonic 3	Supertonic 2	Supertonic 1
Status	🟢 Latest	Stable	Legacy
Parameters	~99M	~66M	~66M
Languages	31	5	1 (en)
Expression Tags	✅ 10 tags	—	—
Code	main	release/supertonic-2	—
Weights	🤗 HF	🤗 HF	🤗 HF
Interactive Demo	🤗 Space	🤗 Space	🤗 Space
Audio Samples	DemoPage	—	DemoPage

Citation

The following papers describe the core technologies used in Supertonic. If you use this system in your research or find these techniques useful, please consider citing the relevant papers:

SupertonicTTS: Main Architecture

This paper introduces the overall architecture of SupertonicTTS, including the speech autoencoder, flow-matching based text-to-latent module, and efficient design choices.

1
2
3
4
5
6
7


@article{kim2025supertonic,
  title={SupertonicTTS: Towards Highly Efficient and Streamlined Text-to-Speech System},
  author={Kim, Hyeongju and Yang, Jinhyeok and Yu, Yechan and Ji, Seunghun and Morton, Jacob and Bous, Frederik and Byun, Joon and Lee, Juheon},
  journal={arXiv preprint arXiv:2503.23108},
  year={2025},
  url={https://arxiv.org/abs/2503.23108}
}

Length-Aware RoPE: Text-Speech Alignment

This paper presents Length-Aware Rotary Position Embedding (LARoPE), which improves text-speech alignment in cross-attention mechanisms.

1
2
3
4
5
6
7


@article{kim2025larope,
  title={Length-Aware Rotary Position Embedding for Text-Speech Alignment},
  author={Kim, Hyeongju and Lee, Juheon and Yang, Jinhyeok and Morton, Jacob},
  journal={arXiv preprint arXiv:2509.11084},
  year={2025},
  url={https://arxiv.org/abs/2509.11084}
}

Self-Purifying Flow Matching: Training with Noisy Labels

This paper describes the self-purification technique for training flow matching models robustly with noisy or unreliable labels.

1
2
3
4
5
6
7


@article{kim2025spfm,
  title={Training Flow Matching Models with Reliable Labels via Self-Purification},
  author={Kim, Hyeongju and Yu, Yechan and Yi, June Young and Lee, Juheon},
  journal={arXiv preprint arXiv:2509.19091},
  year={2025},
  url={https://arxiv.org/abs/2509.19091}
}

License

This project’s sample code is released under the MIT License. - see the LICENSE for details.

The accompanying model is released under the OpenRAIL-M License. - see the LICENSE file for details.

This model was trained using PyTorch, which is licensed under the BSD 3-Clause License but is not redistributed with this project. - see the LICENSE for details.