Model card for maxxvitv2_nano_rw_256.sw_in1k
A timm specific MaxxViT-V2 image classification model. Trained in timm
on ImageNet-1k by Ross Wightman.
ImageNet-1k training done on TPUs thanks to support of the TRC program.
Model Variants in maxxvit.py
MaxxViT covers a number of related model architectures that share a common structure including:
- CoAtNet - Combining MBConv (depthwise-separable) convolutional blocks in early stages with self-attention transformer blocks in later stages.
- MaxViT - Uniform blocks across all stages, each containing a MBConv (depthwise-separable) convolution block followed by two self-attention blocks with different partitioning schemes (window followed by grid).
- CoAtNeXt - A timm specific arch that uses ConvNeXt blocks in place of MBConv blocks in CoAtNet. All normalization layers are LayerNorm (no BatchNorm).
- MaxxViT - A timm specific arch that uses ConvNeXt blocks in place of MBConv blocks in MaxViT. All normalization layers are LayerNorm (no BatchNorm).
- MaxxViT-V2 - A MaxxViT variation that removes the window block attention leaving only ConvNeXt blocks and grid attention w/ more width to compensate.
Aside from the major variants listed above, there are more subtle changes from model to model. Any model name with the string rw
are timm
specific configs w/ modelling adjustments made to favour PyTorch eager use. These were created while training initial reproductions of the models so there are variations.
All models with the string tf
are models exactly matching Tensorflow based models by the original paper authors with weights ported to PyTorch. This covers a number of MaxViT models. The official CoAtNet models were never released.
Model Details
- Model Type: Image classification / feature backbone
- Model Stats:
- Params (M): 23.7
- GMACs: 6.3
- Activations (M): 23.1
- Image size: 256 x 256
- Papers:
- MaxViT: Multi-Axis Vision Transformer: https://arxiv.org/abs/2204.01697
- A ConvNet for the 2020s: https://arxiv.org/abs/2201.03545
- Dataset: ImageNet-1k
Model Usage
Image Classification
from urllib.request import urlopen
from PIL import Image
import timm
img = Image.open(urlopen(
'https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/beignets-task-guide.png'
))
model = timm.create_model('maxxvitv2_nano_rw_256.sw_in1k', pretrained=True)
model = model.eval()
# get model specific transforms (normalization, resize)
data_config = timm.data.resolve_model_data_config(model)
transforms = timm.data.create_transform(**data_config, is_training=False)
output = model(transforms(img).unsqueeze(0)) # unsqueeze single image into batch of 1
top5_probabilities, top5_class_indices = torch.topk(output.softmax(dim=1) * 100, k=5)
Feature Map Extraction
from urllib.request import urlopen
from PIL import Image
import timm
img = Image.open(urlopen(
'https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/beignets-task-guide.png'
))
model = timm.create_model(
'maxxvitv2_nano_rw_256.sw_in1k',
pretrained=True,
features_only=True,
)
model = model.eval()
# get model specific transforms (normalization, resize)
data_config = timm.data.resolve_model_data_config(model)
transforms = timm.data.create_transform(**data_config, is_training=False)
output = model(transforms(img).unsqueeze(0)) # unsqueeze single image into batch of 1
for o in output:
# print shape of each feature map in output
# e.g.:
# torch.Size([1, 96, 128, 128])
# torch.Size([1, 96, 64, 64])
# torch.Size([1, 192, 32, 32])
# torch.Size([1, 384, 16, 16])
# torch.Size([1, 768, 8, 8])
print(o.shape)
Image Embeddings
from urllib.request import urlopen
from PIL import Image
import timm
img = Image.open(urlopen(
'https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/beignets-task-guide.png'
))
model = timm.create_model(
'maxxvitv2_nano_rw_256.sw_in1k',
pretrained=True,
num_classes=0, # remove classifier nn.Linear
)
model = model.eval()
# get model specific transforms (normalization, resize)
data_config = timm.data.resolve_model_data_config(model)
transforms = timm.data.create_transform(**data_config, is_training=False)
output = model(transforms(img).unsqueeze(0)) # output is (batch_size, num_features) shaped tensor
# or equivalently (without needing to set num_classes=0)
output = model.forward_features(transforms(img).unsqueeze(0))
# output is unpooled, a (1, 768, 8, 8) shaped tensor
output = model.forward_head(output, pre_logits=True)
# output is a (1, num_features) shaped tensor
Model Comparison
By Top-1
model | top1 | top5 | samples / sec | Params (M) | GMAC | Act (M) |
---|---|---|---|---|---|---|
maxvit_xlarge_tf_512.in21k_ft_in1k | 88.53 | 98.64 | 21.76 | 475.77 | 534.14 | 1413.22 |
maxvit_xlarge_tf_384.in21k_ft_in1k | 88.32 | 98.54 | 42.53 | 475.32 | 292.78 | 668.76 |
maxvit_base_tf_512.in21k_ft_in1k | 88.20 | 98.53 | 50.87 | 119.88 | 138.02 | 703.99 |
maxvit_large_tf_512.in21k_ft_in1k | 88.04 | 98.40 | 36.42 | 212.33 | 244.75 | 942.15 |
maxvit_large_tf_384.in21k_ft_in1k | 87.98 | 98.56 | 71.75 | 212.03 | 132.55 | 445.84 |
maxvit_base_tf_384.in21k_ft_in1k | 87.92 | 98.54 | 104.71 | 119.65 | 73.80 | 332.90 |
maxvit_rmlp_base_rw_384.sw_in12k_ft_in1k | 87.81 | 98.37 | 106.55 | 116.14 | 70.97 | 318.95 |
maxxvitv2_rmlp_base_rw_384.sw_in12k_ft_in1k | 87.47 | 98.37 | 149.49 | 116.09 | 72.98 | 213.74 |
coatnet_rmlp_2_rw_384.sw_in12k_ft_in1k | 87.39 | 98.31 | 160.80 | 73.88 | 47.69 | 209.43 |
maxvit_rmlp_base_rw_224.sw_in12k_ft_in1k | 86.89 | 98.02 | 375.86 | 116.14 | 23.15 | 92.64 |
maxxvitv2_rmlp_base_rw_224.sw_in12k_ft_in1k | 86.64 | 98.02 | 501.03 | 116.09 | 24.20 | 62.77 |
maxvit_base_tf_512.in1k | 86.60 | 97.92 | 50.75 | 119.88 | 138.02 | 703.99 |
coatnet_2_rw_224.sw_in12k_ft_in1k | 86.57 | 97.89 | 631.88 | 73.87 | 15.09 | 49.22 |
maxvit_large_tf_512.in1k | 86.52 | 97.88 | 36.04 | 212.33 | 244.75 | 942.15 |
coatnet_rmlp_2_rw_224.sw_in12k_ft_in1k | 86.49 | 97.90 | 620.58 | 73.88 | 15.18 | 54.78 |
maxvit_base_tf_384.in1k | 86.29 | 97.80 | 101.09 | 119.65 | 73.80 | 332.90 |
maxvit_large_tf_384.in1k | 86.23 | 97.69 | 70.56 | 212.03 | 132.55 | 445.84 |
maxvit_small_tf_512.in1k | 86.10 | 97.76 | 88.63 | 69.13 | 67.26 | 383.77 |
maxvit_tiny_tf_512.in1k | 85.67 | 97.58 | 144.25 | 31.05 | 33.49 | 257.59 |
maxvit_small_tf_384.in1k | 85.54 | 97.46 | 188.35 | 69.02 | 35.87 | 183.65 |
maxvit_tiny_tf_384.in1k | 85.11 | 97.38 | 293.46 | 30.98 | 17.53 | 123.42 |
maxvit_large_tf_224.in1k | 84.93 | 96.97 | 247.71 | 211.79 | 43.68 | 127.35 |
coatnet_rmlp_1_rw2_224.sw_in12k_ft_in1k | 84.90 | 96.96 | 1025.45 | 41.72 | 8.11 | 40.13 |
maxvit_base_tf_224.in1k | 84.85 | 96.99 | 358.25 | 119.47 | 24.04 | 95.01 |
maxxvit_rmlp_small_rw_256.sw_in1k | 84.63 | 97.06 | 575.53 | 66.01 | 14.67 | 58.38 |
coatnet_rmlp_2_rw_224.sw_in1k | 84.61 | 96.74 | 625.81 | 73.88 | 15.18 | 54.78 |
maxvit_rmlp_small_rw_224.sw_in1k | 84.49 | 96.76 | 693.82 | 64.90 | 10.75 | 49.30 |
maxvit_small_tf_224.in1k | 84.43 | 96.83 | 647.96 | 68.93 | 11.66 | 53.17 |
maxvit_rmlp_tiny_rw_256.sw_in1k | 84.23 | 96.78 | 807.21 | 29.15 | 6.77 | 46.92 |
coatnet_1_rw_224.sw_in1k | 83.62 | 96.38 | 989.59 | 41.72 | 8.04 | 34.60 |
maxvit_tiny_rw_224.sw_in1k | 83.50 | 96.50 | 1100.53 | 29.06 | 5.11 | 33.11 |
maxvit_tiny_tf_224.in1k | 83.41 | 96.59 | 1004.94 | 30.92 | 5.60 | 35.78 |
coatnet_rmlp_1_rw_224.sw_in1k | 83.36 | 96.45 | 1093.03 | 41.69 | 7.85 | 35.47 |
maxxvitv2_nano_rw_256.sw_in1k | 83.11 | 96.33 | 1276.88 | 23.70 | 6.26 | 23.05 |
maxxvit_rmlp_nano_rw_256.sw_in1k | 83.03 | 96.34 | 1341.24 | 16.78 | 4.37 | 26.05 |
maxvit_rmlp_nano_rw_256.sw_in1k | 82.96 | 96.26 | 1283.24 | 15.50 | 4.47 | 31.92 |
maxvit_nano_rw_256.sw_in1k | 82.93 | 96.23 | 1218.17 | 15.45 | 4.46 | 30.28 |
coatnet_bn_0_rw_224.sw_in1k | 82.39 | 96.19 | 1600.14 | 27.44 | 4.67 | 22.04 |
coatnet_0_rw_224.sw_in1k | 82.39 | 95.84 | 1831.21 | 27.44 | 4.43 | 18.73 |
coatnet_rmlp_nano_rw_224.sw_in1k | 82.05 | 95.87 | 2109.09 | 15.15 | 2.62 | 20.34 |
coatnext_nano_rw_224.sw_in1k | 81.95 | 95.92 | 2525.52 | 14.70 | 2.47 | 12.80 |
coatnet_nano_rw_224.sw_in1k | 81.70 | 95.64 | 2344.52 | 15.14 | 2.41 | 15.41 |
maxvit_rmlp_pico_rw_256.sw_in1k | 80.53 | 95.21 | 1594.71 | 7.52 | 1.85 | 24.86 |
By Throughput (samples / sec)
model | top1 | top5 | samples / sec | Params (M) | GMAC | Act (M) |
---|---|---|---|---|---|---|
coatnext_nano_rw_224.sw_in1k | 81.95 | 95.92 | 2525.52 | 14.70 | 2.47 | 12.80 |
coatnet_nano_rw_224.sw_in1k | 81.70 | 95.64 | 2344.52 | 15.14 | 2.41 | 15.41 |
coatnet_rmlp_nano_rw_224.sw_in1k | 82.05 | 95.87 | 2109.09 | 15.15 | 2.62 | 20.34 |
coatnet_0_rw_224.sw_in1k | 82.39 | 95.84 | 1831.21 | 27.44 | 4.43 | 18.73 |
coatnet_bn_0_rw_224.sw_in1k | 82.39 | 96.19 | 1600.14 | 27.44 | 4.67 | 22.04 |
maxvit_rmlp_pico_rw_256.sw_in1k | 80.53 | 95.21 | 1594.71 | 7.52 | 1.85 | 24.86 |
maxxvit_rmlp_nano_rw_256.sw_in1k | 83.03 | 96.34 | 1341.24 | 16.78 | 4.37 | 26.05 |
maxvit_rmlp_nano_rw_256.sw_in1k | 82.96 | 96.26 | 1283.24 | 15.50 | 4.47 | 31.92 |
maxxvitv2_nano_rw_256.sw_in1k | 83.11 | 96.33 | 1276.88 | 23.70 | 6.26 | 23.05 |
maxvit_nano_rw_256.sw_in1k | 82.93 | 96.23 | 1218.17 | 15.45 | 4.46 | 30.28 |
maxvit_tiny_rw_224.sw_in1k | 83.50 | 96.50 | 1100.53 | 29.06 | 5.11 | 33.11 |
coatnet_rmlp_1_rw_224.sw_in1k | 83.36 | 96.45 | 1093.03 | 41.69 | 7.85 | 35.47 |
coatnet_rmlp_1_rw2_224.sw_in12k_ft_in1k | 84.90 | 96.96 | 1025.45 | 41.72 | 8.11 | 40.13 |
maxvit_tiny_tf_224.in1k | 83.41 | 96.59 | 1004.94 | 30.92 | 5.60 | 35.78 |
coatnet_1_rw_224.sw_in1k | 83.62 | 96.38 | 989.59 | 41.72 | 8.04 | 34.60 |
maxvit_rmlp_tiny_rw_256.sw_in1k | 84.23 | 96.78 | 807.21 | 29.15 | 6.77 | 46.92 |
maxvit_rmlp_small_rw_224.sw_in1k | 84.49 | 96.76 | 693.82 | 64.90 | 10.75 | 49.30 |
maxvit_small_tf_224.in1k | 84.43 | 96.83 | 647.96 | 68.93 | 11.66 | 53.17 |
coatnet_2_rw_224.sw_in12k_ft_in1k | 86.57 | 97.89 | 631.88 | 73.87 | 15.09 | 49.22 |
coatnet_rmlp_2_rw_224.sw_in1k | 84.61 | 96.74 | 625.81 | 73.88 | 15.18 | 54.78 |
coatnet_rmlp_2_rw_224.sw_in12k_ft_in1k | 86.49 | 97.90 | 620.58 | 73.88 | 15.18 | 54.78 |
maxxvit_rmlp_small_rw_256.sw_in1k | 84.63 | 97.06 | 575.53 | 66.01 | 14.67 | 58.38 |
maxxvitv2_rmlp_base_rw_224.sw_in12k_ft_in1k | 86.64 | 98.02 | 501.03 | 116.09 | 24.20 | 62.77 |
maxvit_rmlp_base_rw_224.sw_in12k_ft_in1k | 86.89 | 98.02 | 375.86 | 116.14 | 23.15 | 92.64 |
maxvit_base_tf_224.in1k | 84.85 | 96.99 | 358.25 | 119.47 | 24.04 | 95.01 |
maxvit_tiny_tf_384.in1k | 85.11 | 97.38 | 293.46 | 30.98 | 17.53 | 123.42 |
maxvit_large_tf_224.in1k | 84.93 | 96.97 | 247.71 | 211.79 | 43.68 | 127.35 |
maxvit_small_tf_384.in1k | 85.54 | 97.46 | 188.35 | 69.02 | 35.87 | 183.65 |
coatnet_rmlp_2_rw_384.sw_in12k_ft_in1k | 87.39 | 98.31 | 160.80 | 73.88 | 47.69 | 209.43 |
maxxvitv2_rmlp_base_rw_384.sw_in12k_ft_in1k | 87.47 | 98.37 | 149.49 | 116.09 | 72.98 | 213.74 |
maxvit_tiny_tf_512.in1k | 85.67 | 97.58 | 144.25 | 31.05 | 33.49 | 257.59 |
maxvit_rmlp_base_rw_384.sw_in12k_ft_in1k | 87.81 | 98.37 | 106.55 | 116.14 | 70.97 | 318.95 |
maxvit_base_tf_384.in21k_ft_in1k | 87.92 | 98.54 | 104.71 | 119.65 | 73.80 | 332.90 |
maxvit_base_tf_384.in1k | 86.29 | 97.80 | 101.09 | 119.65 | 73.80 | 332.90 |
maxvit_small_tf_512.in1k | 86.10 | 97.76 | 88.63 | 69.13 | 67.26 | 383.77 |
maxvit_large_tf_384.in21k_ft_in1k | 87.98 | 98.56 | 71.75 | 212.03 | 132.55 | 445.84 |
maxvit_large_tf_384.in1k | 86.23 | 97.69 | 70.56 | 212.03 | 132.55 | 445.84 |
maxvit_base_tf_512.in21k_ft_in1k | 88.20 | 98.53 | 50.87 | 119.88 | 138.02 | 703.99 |
maxvit_base_tf_512.in1k | 86.60 | 97.92 | 50.75 | 119.88 | 138.02 | 703.99 |
maxvit_xlarge_tf_384.in21k_ft_in1k | 88.32 | 98.54 | 42.53 | 475.32 | 292.78 | 668.76 |
maxvit_large_tf_512.in21k_ft_in1k | 88.04 | 98.40 | 36.42 | 212.33 | 244.75 | 942.15 |
maxvit_large_tf_512.in1k | 86.52 | 97.88 | 36.04 | 212.33 | 244.75 | 942.15 |
maxvit_xlarge_tf_512.in21k_ft_in1k | 88.53 | 98.64 | 21.76 | 475.77 | 534.14 | 1413.22 |
Citation
@misc{rw2019timm,
author = {Ross Wightman},
title = {PyTorch Image Models},
year = {2019},
publisher = {GitHub},
journal = {GitHub repository},
doi = {10.5281/zenodo.4414861},
howpublished = {\url{https://github.com/huggingface/pytorch-image-models}}
}
@article{tu2022maxvit,
title={MaxViT: Multi-Axis Vision Transformer},
author={Tu, Zhengzhong and Talebi, Hossein and Zhang, Han and Yang, Feng and Milanfar, Peyman and Bovik, Alan and Li, Yinxiao},
journal={ECCV},
year={2022},
}
@article{dai2021coatnet,
title={CoAtNet: Marrying Convolution and Attention for All Data Sizes},
author={Dai, Zihang and Liu, Hanxiao and Le, Quoc V and Tan, Mingxing},
journal={arXiv preprint arXiv:2106.04803},
year={2021}
}
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