# AutoencoderRAE The Representation Autoencoder (RAE) model introduced in [Diffusion Transformers with Representation Autoencoders](https://huggingface.co/papers/2510.11690) by Boyang Zheng, Nanye Ma, Shengbang Tong, Saining Xie from NYU VISIONx. RAE combines a frozen pretrained vision encoder (DINOv2, SigLIP2, or MAE) with a trainable ViT-MAE-style decoder. In the two-stage RAE training recipe, the autoencoder is trained in stage 1 (reconstruction), and then a diffusion model is trained on the resulting latent space in stage 2 (generation). The following RAE models are released and supported in Diffusers: | Model | Encoder | Latent shape (224px input) | |:------|:--------|:---------------------------| | [`nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08`](https://huggingface.co/nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08) | DINOv2-base | 768 x 16 x 16 | | [`nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08-i512`](https://huggingface.co/nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08-i512) | DINOv2-base (512px) | 768 x 32 x 32 | | [`nyu-visionx/RAE-dinov2-wReg-small-ViTXL-n08`](https://huggingface.co/nyu-visionx/RAE-dinov2-wReg-small-ViTXL-n08) | DINOv2-small | 384 x 16 x 16 | | [`nyu-visionx/RAE-dinov2-wReg-large-ViTXL-n08`](https://huggingface.co/nyu-visionx/RAE-dinov2-wReg-large-ViTXL-n08) | DINOv2-large | 1024 x 16 x 16 | | [`nyu-visionx/RAE-siglip2-base-p16-i256-ViTXL-n08`](https://huggingface.co/nyu-visionx/RAE-siglip2-base-p16-i256-ViTXL-n08) | SigLIP2-base | 768 x 16 x 16 | | [`nyu-visionx/RAE-mae-base-p16-ViTXL-n08`](https://huggingface.co/nyu-visionx/RAE-mae-base-p16-ViTXL-n08) | MAE-base | 768 x 16 x 16 | ## Loading a pretrained model ```python from diffusers import AutoencoderRAE model = AutoencoderRAE.from_pretrained( "nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08" ).to("cuda").eval() ``` ## Encoding and decoding a real image ```python import torch from diffusers import AutoencoderRAE from diffusers.utils import load_image from torchvision.transforms.functional import to_tensor, to_pil_image model = AutoencoderRAE.from_pretrained( "nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08" ).to("cuda").eval() image = load_image("https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/diffusers/cat.png") image = image.convert("RGB").resize((224, 224)) x = to_tensor(image).unsqueeze(0).to("cuda") # (1, 3, 224, 224), values in [0, 1] with torch.no_grad(): latents = model.encode(x).latent # (1, 768, 16, 16) recon = model.decode(latents).sample # (1, 3, 256, 256) recon_image = to_pil_image(recon[0].clamp(0, 1).cpu()) recon_image.save("recon.png") ``` ## Latent normalization Some pretrained checkpoints include per-channel `latents_mean` and `latents_std` statistics for normalizing the latent space. When present, `encode` and `decode` automatically apply the normalization and denormalization, respectively. ```python model = AutoencoderRAE.from_pretrained( "nyu-visionx/RAE-dinov2-wReg-base-ViTXL-n08" ).to("cuda").eval() # Latent normalization is handled automatically inside encode/decode # when the checkpoint config includes latents_mean/latents_std. with torch.no_grad(): latents = model.encode(x).latent # normalized latents recon = model.decode(latents).sample ``` ## AutoencoderRAE [[autodoc]] AutoencoderRAE - encode - decode - all ## DecoderOutput [[autodoc]] models.autoencoders.vae.DecoderOutput