---

license: other license_name: ltx-2-community-license-agreement license_link: https://github.com/Lightricks/LTX-2/blob/main/LICENSE tags:

• comfyui
• diffusion-single-file

---

Separated LTX2.3 checkpoint for alternative way to load the models in Comfy

The fp8 quantizations were done with the basic static weight scales and are set to not run with fp8 matmuls, the models marked input_scaled additionally have activation scaling, and are set to run with fp8 matmuls on supported hardware.

---

language:

• en
• de
• es
• fr
• ja
• ko
• zh
• it
• pt library_name: gguf license: other license_name: ltx-2-community-license-agreement license_link: https://github.com/Lightricks/LTX-2/blob/main/LICENSE pipeline_tag: image-to-video arxiv: 2601.03233 base_model:
• Lightricks/LTX-2.3 tags:
• image-to-video
• text-to-video
• video-to-video
• image-text-to-video
• audio-to-video
• text-to-audio
• video-to-audio
• audio-to-audio
• text-to-audio-video
• image-to-audio-video
• image-text-to-audio-video
• ltx-2
• ltx-2-3
• ltx-video
• ltxv
• lightricks pinned: true demo: https://app.ltx.studio/ltx-2-playground/i2v

---

This GGUF file is a direct conversion of Lightricks/LTX-2.3

Type | Name | Location | Download | ------------ | -------------------------------------------------- | --------------------------------- | ------------------------- | Main Model | LTX-2.3 | ComfyUI/models/unet | GGUF (this repo) | Text Encoder | Gemma 3 | ComfyUI/models/text_encoders | Safetensors / GGUF | | Text Encoder | Text Projection | ComfyUI/models/text_encoders | Safetensors| | VAE Video / VAE Audio | vae | ComfyUI/models/vae | Safetensors |

Since this is a quantized model, all original licensing terms and usage restrictions remain in effect.

---

license: apache-2.0 base_model:

• black-forest-labs/FLUX.2-klein-9B pipeline_tag: image-to-image tags:
• lora

---

LoRA can significantly improve Klein consistency without any cue words. Video tutorial: https://youtu.be/JXMbbbdfnSg

---

tags:

• flux.2
• image-to-image
• virtual-try-off
• fal
• lora
• diffusers
• template:diffusion-lora widget:
• output: url: images/5.png text: >- TRYOFF extract the t-shirt over a white background, product photography style. NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).
• output: url: images/3.png text: >- TRYOFF extract the dress over a white background, product photography style. NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).
• output: url: images/2.png text: >- TRYOFF extract the pants over a white background, product photography style. NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).
• output: url: images/6.png text: >- TRYOFF extract the outfit over a white background, product photography style. NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).
• output: url: images/1.png text: >- TRYOFF extract the t-shirt over a white background, product photography style. NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).

- output:

url: images/4.png

text: >-

TRYOFF extract the upper body over a white background, product photography style.

NO HUMAN VISIBLE (the garments maintain their 3D form like an invisible mannequin).

• output: url: images/7.png text: >- TRYOFF extract full outfit in the reference image over a white background, high-end professional product photography. Present the outfit as a complete, vertically stacked ensemble arranged as if worn. The items are stacked as if worn. The top-layer garment is dominant, followed directly by the bottom-layer garment. The footwear is placed below the bottom-layer hem, aligning with where the feet would naturally be. Lighting: Clean, even, diffused studio lighting (softbox or beauty dish style). The illumination must highlight all varying textures (e.g., pebble leather, suede, knit, or canvas) without creating harsh shadows. base_model: black-forest-labs/FLUX.2-klein-9B instance_prompt: TRYOFF license: apache-2.0 pipeline_tag: image-to-image

---

FLUX.2-klein-base-9B Virtual Try-Off LoRA

<Gallery />

Virtual Try-Off: Given an image of a person wearing clothing and a garment category prompt, the model generates a clean image of the garment as if it were photographed alone.
The model reconstructs the clothing item while preserving its style, texture, color, and design from the input image.
1 input image (person wearing clothes) + text category → 1 output garment image
Built with fal.ai.

Usage

• Try LoRA on fal.ai Playground
• Try the workflow (image-to-video) at fal.ai Workflow

Training

Trained with fal.ai trainer.

• Base model: FLUX.2-klein-base-9B
• Steps: 10000
• Learning Rate: 0.00005
• Dataset: 300 image pairs (model + garment) of shape 1024x1024

Author

Created by Riza Velioglu at fal.ai

---

tags:

• ltx
• ltx-2
• comfyui
• comfy
• gguf
• ltx-video
• ltx-2-3
• ltxv
• text-to-video
• image-to-video
• audio-to-video
• video-to-video

---

The workflows are based on the extracted models from https://huggingface.co/Kijai/LTX2.3_comfy The extracted models might run easier on your computer (as separate files). (but you can easily swap out the model loader for the ComfyUI default model loader if you want to load the checkpoint with "all in one" vae built-in etc)

Model Downloads:

• Main split models used in these workflows (LTX-2.3 dev & distilled safetensor, embeddings, audio and video vae): https://huggingface.co/Kijai/LTX2.3_comfy

• Gemma 3 12B it safetensor: https://huggingface.co/Comfy-Org/ltx-2/

• Gemma 3 12B it GGUF: https://huggingface.co/unsloth/gemma-3-12b-it-GGUF/

• Optional LTX-2.3 GGUF models (for GGUF workflows):

1. Quantstack: https://huggingface.co/QuantStack/LTX-2.3-GGUF
2. Vantage : https://huggingface.co/vantagewithai/LTX-2.3-GGUF

---

Needed nodes:

• https://github.com/kijai/ComfyUI-KJNodes (NB! Must be up to date for LTX-2 support)

• https://github.com/city96/ComfyUI-GGUF (NB! Must be up to date for LTX-2 support)

• ComfyUI itself must be updated to very latest

---

Lighttricks LTX-2.3 main repro: https://huggingface.co/Lightricks/LTX-2.3
Lightricks LTX-2.3 Collection (loras etc): https://huggingface.co/collections/Lightricks/ltx-23

---

library_name: diffusers license: apache-2.0

<!-- <p align="center"> <img src="https://github.com/MLP-Lab/KORMo-tutorial/blob/main/tutorial/attachment/kormo_logo.png?raw=true" style="width: 100%; max-width: 1100px;"> </p> --> <p align="center"> <img src="https://github.com/MLP-Lab/KORMo-tutorial/blob/main/tutorial/attachment/kormo_logo.svg?raw=true" style="width: 40%; max-width: 1100px;"> </p>

🚀 Update News

• 2026-03-05: Official release of KORMo-Diffusion.
• 2026-03-02: Official release of KORMo-VL.
• 2025-10-13: Official release of KORMo-10B-sft.

---

💡 About KORMo-VL-Diffusion

KORMo-VL is a vision-language model developed from scratch by the KAIST MLP Lab (https://sites.google.com/view/aailab), built on top of KORMo-10B. The system consists of two components:

• Vision-Language Model (VLM)
• Image Generation Model

The KORMo-VL-Diffusion model, designed for image generation, was trained from scratch with a high proportion of images reflecting Korean daily environments and culture. <span style="color:red">Unfortunately, due to limited GPU resources during the research process, we are sharing the intermediate results of the model at this stage.</span>

---

KORMo-VL은 KAIST MLP 연구실에서 from scratch로 개발한 시각-언어 모델로, KORMo-10B를 기반으로 (1) 시각-언어 모델과 (2) 이미지 생성 모델로 구성되어 있습니다.

이 중 이미지 생성을 위한 KORMo-VL-Diffusion 모델은 한국의 생활 환경과 문화를 반영하기 위해 국내 환경 이미지를 가능한 높은 비율로 사용하여 from scratch부터 학습된 모델입니다. <span style="color:red">다만 연구 진행 중 GPU 자원을 추가로 확보하지 못해 현재는 중간 결과물을 공유하게 되었습니다.</span>

• LLM: KORMo-VL
• Model Structure: Qwen-Image를 구조를 참조해 재개발함 (20B 정도의 Diffusion부분을 변형해 scratch부터 학습)
• Languages: Korean / English
• Training Data: Synthetic data + public datasets (e.g., AI Hub, details to be released)

향후 해당 모델을 충분히 학습할 수 있는 환경이 마련된다면 완성된 모델로 발전시키는 것을 목표로 하고 있습니다. 중간 결과물 위에서 추가 튜닝이나 연구를 진행하고 싶은 분들은 자유롭게 활용해 보시기 바랍니다.

📈 T2I Performance

English Prompt

| Prompt | Generated Image | | :--- | :--- | | Prompt: Dense forest | <img src="https://huggingface.co/KORMo-VL/KORMo-VL-Diffusion/resolve/main/example_images/Dense%20forest.webp" width="400"> | | Prompt: Black pattern mug | <img src="https://huggingface.co/KORMo-VL/KORMo-VL-Diffusion/resolve/main/example_images/black%20pattern%20mug%20cpup.webp" width="400"> |

Korean Prompt

| Prompt | Generated Image | | :--- | :--- | | Prompt: 울창한 숲 | <img src="https://huggingface.co/KORMo-VL/KORMo-VL-Diffusion/resolve/main/example_images/Dense%20forest.webp" width="400"> | | Prompt: 검은 무늬의 머그컵 | <img src="https://huggingface.co/KORMo-VL/KORMo-VL-Diffusion/resolve/main/example_images/%EA%B2%80%EC%9D%80%20%EB%AC%B4%EB%8A%AC%EC%9D%98%20%EB%A8%B8%EA%B7%B8%EC%BB%B5.webp" width="400"> |

KORMo-VL-Diffusion Demo

prompt: 아름다운 정원의 꽃들

<video width="640" height="360" controls> <source src="https://huggingface.co/KORMo-VL/KORMo-VL-Diffusion/resolve/main/kormo_diffusion_assets/kormo_t2i.mp4" type="video/mp4"> </video>

📦 Installation

uv pip install transformers==4.57.1 pillow torchvision diffusers

---

🚀 Inference Example

github repo 활용 예정

---

Contact

• KyungTae Lim, Professor at KAIST. ktlim@kaist.ac.kr

Contributor (https://sites.google.com/view/aailab)

• Junghun Yuk
• INho won
• HANGYEOL YOO
• Junmyeong Lee
• KyungTae Lim

Citation

@misc{KORMo,
  author = {Minjun Kim, Hyeonseok Lim, Hangyeol Yoo, Inho Won, Seungwoo Song, Minkyung Cho, Junghun Yuk, Changsu Choi, Dongjae Shin, Huije Lee, Hoyun Song, Alice Oh, and KyungTae Lim},
  title = {KORMo: Korean Open Reasoning Model for Everyone},
  year = {2025},
  publisher = {GitHub},
  journal = {Technical Report},
  paperLink = {\url{https://arxiv.org/abs/2510.09426}},
 },
}

---

language:

• en
• de
• es
• fr
• ja
• ko
• zh
• it
• pt library_name: diffusers license: other license_name: ltx-2-community-license-agreement license_link: https://github.com/Lightricks/LTX-2/blob/main/LICENSE pipeline_tag: image-to-video arxiv: 2601.03233 tags:
• image-to-video
• text-to-video
• video-to-video
• image-text-to-video
• audio-to-video
• text-to-audio
• video-to-audio
• audio-to-audio
• text-to-audio-video
• image-to-audio-video
• image-text-to-audio-video
• ltx-2
• ltx-2-3
• ltx-video
• ltxv
• lightricks pinned: true demo: https://app.ltx.studio/ltx-2-playground/i2v

---

LTX-2.3 FP8 Model Card

This is the FP8 versions of the LTX-2.3 model. All information below is derived from the base model.

This model card focuses on the LTX-2.3 model, which is a significant update to the LTX-2 model with improved audio and visual quality as well as enhanced prompt adherence. LTX-2 was presented in the paper LTX-2: Efficient Joint Audio-Visual Foundation Model.

💻💻 If you want to dive in right to the code - it is available here. 💾💾

LTX-2.3 is a DiT-based audio-video foundation model designed to generate synchronized video and audio within a single model. It brings together the core building blocks of modern video generation, with open weights and a focus on practical, local execution.

Model Checkpoints

| Name | Notes | |------------------------------------|--------------------------------------------------------------------------------------------------------------------| | ltx-2.3-22b-dev-fp8 | The full model, flexible and trainable in bf16 | | ltx-2.3-22b-distilled-fp8 (coming soon) | The distilled version of the full model, 8 steps, CFG=1 |

Model Details

• Developed by: Lightricks
• Model type: Diffusion-based audio-video foundation model
• Language(s): English

Online demo

LTX-2.3 is accessible right away via the API Playground.

Run locally

Direct use license

You can use the models - full, distilled, upscalers and any derivatives of the models - for purposes under the license.

ComfyUI

We recommend you use the built-in LTXVideo nodes that can be found in the ComfyUI Manager. For manual installation information, please refer to our documentation site.

PyTorch codebase

The LTX-2 codebase is a monorepo with several packages. From model definition in 'ltx-core' to pipelines in 'ltx-pipelines' and training capabilities in 'ltx-trainer'. The codebase was tested with Python >=3.12, CUDA version >12.7, and supports PyTorch ~= 2.7.

Installation

git clone https://github.com/Lightricks/LTX-2.git
cd LTX-2

# From the repository root
uv sync
source .venv/bin/activate

Inference

To use our model, please follow the instructions in our ltx-pipelines package.

Diffusers 🧨

LTX-2.3 support in the Diffusers Python library is coming soon!

General tips:

• Width & height settings must be divisible by 32. Frame count must be divisible by 8 + 1.
• In case the resolution or number of frames are not divisible by 32 or 8 + 1, the input should be padded with -1 and then cropped to the desired resolution and number of frames.
• For tips on writing effective prompts, please visit our Prompting guide

Limitations

• This model is not intended or able to provide factual information.
• As a statistical model this checkpoint might amplify existing societal biases.
• The model may fail to generate videos that matches the prompts perfectly.
• Prompt following is heavily influenced by the prompting-style.
• The model may generate content that is inappropriate or offensive.
• When generating audio without speech, the audio may be of lower quality.

Train the model

Currently it is recommended to train the bf16 model. Recipes for training the fp8 model are welcome as community contributions.

Citation

@article{hacohen2025ltx2,
  title={LTX-2: Efficient Joint Audio-Visual Foundation Model},
  author={HaCohen, Yoav and Brazowski, Benny and Chiprut, Nisan and Bitterman, Yaki and Kvochko, Andrew and Berkowitz, Avishai and Shalem, Daniel and Lifschitz, Daphna and Moshe, Dudu and Porat, Eitan and Richardson, Eitan and Guy Shiran and Itay Chachy and Jonathan Chetboun and Michael Finkelson and Michael Kupchick and Nir Zabari and Nitzan Guetta and Noa Kotler and Ofir Bibi and Ori Gordon and Poriya Panet and Roi Benita and Shahar Armon and Victor Kulikov and Yaron Inger and Yonatan Shiftan and Zeev Melumian and Zeev Farbman},
  journal={arXiv preprint arXiv:2601.03233},
  year={2025}
}

---

license: apache-2.0 tags:

• uncensored
• qwen3.5
• qwen
• gguf language:
• en
• zh
• multilingual

---

Qwen3.5-27B-Uncensored-HauhauCS-Aggressive

Qwen3.5-27B uncensored by HauhauCS.

About

0/465 refusals. Fully uncensored with zero capability loss.

No changes to datasets or capabilities. Fully functional, 100% of what the original authors intended - just without the refusals.

These are meant to be the best lossless uncensored models out there.

Aggressive Variant

Stronger uncensoring with more thorough refusal removal. If this variant is too loose for your use case, a Balanced variant may follow.

Note: The model is fully unlocked and will not refuse prompts. However, it may occasionally append a short disclaimer at the end of a response (e.g. "This is general information, not legal advice..."). This is baked into the base model's training and not a refusal — the actual content is still generated in full.

Downloads

| File | Quant | Size | |------|-------|------| | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-BF16.gguf | BF16 | 51 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-Q8_0.gguf | Q8_0 | 27 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-Q6_K.gguf | Q6_K | 21 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-Q5_K_M.gguf | Q5_K_M | 19 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-Q4_K_M.gguf | Q4_K_M | 16 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-IQ4_XS.gguf | IQ4_XS | 14 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-Q3_K_M.gguf | Q3_K_M | 13 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-IQ3_M.gguf | IQ3_M | 12 GB | | Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-IQ2_M.gguf | IQ2_M | 8.8 GB | | mmproj-Qwen3.5-27B-Uncensored-HauhauCS-Aggressive-f16.gguf | Vision encoder | 885 MB |

IQ quants (IQ2_M, IQ3_M, IQ4_XS) were generated with importance matrix calibration for better quality at low bit rates.

Vision support: This model is natively multimodal. The mmproj file is the vision encoder — you need it alongside the main GGUF to use image/video inputs. Load both files in llama.cpp, LM Studio, or any compatible runtime.

Specs

• 27B dense parameters, 64 layers
• Hybrid architecture: Gated DeltaNet linear attention + full softmax attention (3:1 ratio)
• 262K native context (extendable to 1M with YaRN)
• Natively multimodal (text, image, video)
• Multi-token prediction (MTP) support
• 248K vocabulary, 201 languages
• Based on Qwen3.5-27B

Recommended Settings

From the official Qwen authors:

Thinking mode (default):

• temperature=0.6, top_p=0.95, top_k=20, min_p=0

Non-thinking mode:

• temperature=0.7, top_p=0.8, top_k=20, min_p=0

Important:

• Maintain at least 128K context to preserve thinking capabilities
• For production/high-throughput: use vLLM, SGLang, or KTransformers

Note: This is a brand new architecture (released 2026-03-02). llama.cpp support landed very recently — make sure you're on a recent build. Works with llama.cpp, LM Studio, Jan, koboldcpp, etc.

Also check out the 9B variant, the 4B variant, and all releases at HauhauCS.

Usage

Works with llama.cpp, LM Studio, Jan, koboldcpp, etc.

---

language:

• en
• de
• es
• fr
• ja
• ko
• zh
• it
• pt library_name: diffusers license: other license_name: ltx-2-community-license-agreement license_link: https://github.com/Lightricks/LTX-2/blob/main/LICENSE pipeline_tag: image-to-video arxiv: 2601.03233 tags:
• image-to-video
• text-to-video
• video-to-video
• image-text-to-video
• audio-to-video
• text-to-audio
• video-to-audio
• audio-to-audio
• text-to-audio-video
• image-to-audio-video
• image-text-to-audio-video
• ltx-2
• ltx-2-3
• ltx-video
• ltxv
• lightricks pinned: true demo: https://app.ltx.studio/ltx-2-playground/i2v

---

LTX-2.3 FP8 Quantized

FP8 quantized versions of the LTX-2.3 22B models by Lightricks.

Quantized Checkpoints

| Name | Original | Size | |------|----------|------| | ltx-2.3-22b-dev-fp8_mixed.safetensors | ltx-2.3-22b-dev | ~30 GB | | ltx-2.3-22b-distilled-fp8_mixed.safetensors | ltx-2.3-22b-distilled | ~30 GB |

Quantization Details

• Format: float8_e4m3fn (E4M3, max=448)
• Method: Static per-tensor W8A8 quantization
• Scope: Transformer blocks 1–42 (block 0 and last 5 blocks kept in BF16)
• Targets: All linear projection weight matrices in attn1, attn2, audio_attn1, audio_attn2, audio_to_video_attn, video_to_audio_attn, ff.net, audio_ff.net — specifically to_q, to_k, to_v, to_out.0, ff.net.0.proj, ff.net.2 and their audio equivalents
• Scale: Per-tensor weight_scale = max(|W|) / 448 stored as F32 scalar alongside each weight. Static input_scale = 1.0 placeholder matching the source model format
• Non-quantized: Biases, norms, scale_shift_tables, gate_logits kept as BF16/F32
• Quantized tensors: 1176 / 5947 total (28 patterns × 42 blocks)
• Output size: ~29.94 GB (down from ~46 GB BF16)

Original Model

This is a quantized derivative of Lightricks/LTX-2.3. All original model details, usage instructions, and license terms apply.

LTX-2.3 is a DiT-based audio-video foundation model designed to generate synchronized video and audio within a single model.

Citation

@article{hacohen2025ltx2,
  title={LTX-2: Efficient Joint Audio-Visual Foundation Model},
  author={HaCohen, Yoav and Brazowski, Benny and Chiprut, Nisan and Bitterman, Yaki and Kvochko, Andrew and Berkowitz, Avishai and Shalem, Daniel and Lifschitz, Daphna and Moshe, Dudu and Porat, Eitan and Richardson, Eitan and Guy Shiran and Itay Chachy and Jonathan Chetboun and Michael Finkelson and Michael Kupchick and Nir Zabari and Nitzan Guetta and Noa Kotler and Ofir Bibi and Ori Gordon and Poriya Panet and Roi Benita and Shahar Armon and Victor Kulikov and Yaron Inger and Yonatan Shiftan and Zeev Melumian and Zeev Farbman},
  journal={arXiv preprint arXiv:2601.03233},
  year={2025}
}

---

license: mit language:

• ja base_model:
• facebook/dacvae-watermarked pipeline_tag: audio-to-audio tags:
• VAE
• Speech
• Voice

---

Semantic-DACVAE-Japanese

Semantic-DACVAE-Japanese is a fine-tuned version of facebook/dacvae-watermarked, specifically optimized for Japanese speech.

By incorporating WavLM semantic distillation inspired by the Semantic-VAE paper and performing additional training on Japanese datasets, this model achieves more natural reconstructions and higher subjective quality for Japanese audio compared to the original base model.

Furthermore, according to the Semantic-VAE paper, this semantic distillation approach should also improve the training efficiency and performance of downstream TTS models.

🌟 Overview

• Base Model: facebook/dacvae-watermarked
• Enhancements: Integrated WavLM semantic distillation inspired by Semantic-VAE paper.
• Training Data: Fine-tuned explicitly on Japanese speech datasets.
• License: MIT

📊 Evaluation

We evaluated the model using the UTMOSv2 metric to measure the quality of the reconstructed audio. Our model demonstrates a clear improvement in naturalness over the original base model across both tested datasets.

1. Emilia-YODAS (Japanese Subset)

Tested on 100 samples (not included in training) from the Japanese subset of amphion/Emilia-Dataset.

| Audio Source | Mean UTMOSv2 (n=100) | | :--- | :---: | | Original Audio | 2.2099 | | facebook/dacvae-watermarked | 2.2841 | | Aratako/Semantic-DACVAE-Japanese | 2.4812 |

2. Private Test Dataset (Japanese)

Tested on 100 private Japanese speech samples.

| Audio Source | Mean UTMOSv2 (n=100) | | :--- | :---: | | Original Audio | 2.0322 | | facebook/dacvae-watermarked | 1.8775 | | Aratako/Semantic-DACVAE-Japanese | 2.1629 |

🚀 Quick Start

Installation

First, set up your environment and install the official repository:

# Create a virtual environment
uv venv --python=3.10

# Install the official dacvae package
uv pip install git+https://github.com/facebookresearch/dacvae

Inference

Below is a basic example of inference.

import soundfile as sf
import torch
import torchaudio
from audiotools import AudioSignal
from dacvae import DACVAE
from huggingface_hub import hf_hub_download

# 1. Load the model
model = DACVAE.load(hf_hub_download(repo_id="Aratako/Semantic-DACVAE-Japanese", filename="weights.pth")).eval()

# Disable/bypass the default watermark since this model was fine-tuned without it
model.decoder.alpha = 0.0
model.decoder.watermark = lambda x, message=None, d=model.decoder: d.wm_model.encoder_block.forward_no_conv(x)

# 2. Load and preprocess audio
wav_np, sr = sf.read("input.wav", dtype="float32")
wav = torch.from_numpy(wav_np.T) if wav_np.ndim == 2 else torch.from_numpy(wav_np).unsqueeze(0)
wav = torchaudio.functional.resample(wav.mean(0, keepdim=True), sr, model.sample_rate)

signal = AudioSignal(wav.unsqueeze(0), model.sample_rate)
signal.normalize(-16.0)
signal.ensure_max_of_audio()
x = signal.audio_data.float()  # (1, 1, T)

# 3. Encode and Decode
with torch.no_grad():
    z = model.encoder(model._pad(x))
    z, _ = model.quantizer.in_proj(z).chunk(2, dim=1)
    y = model.decode(z)[0].cpu()

# 4. Save reconstructed audio
sf.write("recon.wav", y.squeeze(0).numpy(), model.sample_rate)

📜 Acknowledgements

• Base Model: Weights derived from facebook/dacvae-watermarked.
• Training Code: Leveraged the codebase from Descript Audio Codec (DAC).
• Methodology: Semantic distillation approach heavily inspired by the Semantic-VAE paper.

🖊️ Citation

@misc{semantic-dacvae-japanese,
  author = {Chihiro Arata},
  title = {Semantic-DACVAE-Japanese: Audio VAE for Japanese Speech},
  year = {2026},
  publisher = {Hugging Face},
  journal = {Hugging Face repository},
  howpublished = {\url{https://huggingface.co/Aratako/Semantic-DACVAE-Japanese}}
}