pytorch-image-models/modelindex/models/fbnet.md

# Summary

**FBNet** is a type of convolutional neural architectures discovered through [DNAS](https://paperswithcode.com/method/dnas) neural architecture search. It utilises a basic type of image model block inspired by [MobileNetv2](https://paperswithcode.com/method/mobilenetv2) that utilises depthwise convolutions and an inverted residual structure (see components).

The principal building block is the [FBNet Block](https://paperswithcode.com/method/fbnet-block).

## How do I use this model on an image?
To load a pretrained model:

```python
import timm
model = timm.create_model('fbnetc_100', pretrained=True)
model.eval()
```

To load and preprocess the image:
```python 
import urllib
from PIL import Image
from timm.data import resolve_data_config
from timm.data.transforms_factory import create_transform

config = resolve_data_config({}, model=model)
transform = create_transform(**config)

url, filename = ("https://github.com/pytorch/hub/raw/master/images/dog.jpg", "dog.jpg")
urllib.request.urlretrieve(url, filename)
img = Image.open(filename).convert('RGB')
tensor = transform(img).unsqueeze(0) # transform and add batch dimension
```

To get the model predictions:
```python
import torch
with torch.no_grad():
    out = model(tensor)
probabilities = torch.nn.functional.softmax(out[0], dim=0)
print(probabilities.shape)
# prints: torch.Size([1000])
```

To get the top-5 predictions class names:
```python
# Get imagenet class mappings
url, filename = ("https://raw.githubusercontent.com/pytorch/hub/master/imagenet_classes.txt", "imagenet_classes.txt")
urllib.request.urlretrieve(url, filename) 
with open("imagenet_classes.txt", "r") as f:
    categories = [s.strip() for s in f.readlines()]

# Print top categories per image
top5_prob, top5_catid = torch.topk(probabilities, 5)
for i in range(top5_prob.size(0)):
    print(categories[top5_catid[i]], top5_prob[i].item())
# prints class names and probabilities like:
# [('Samoyed', 0.6425196528434753), ('Pomeranian', 0.04062102362513542), ('keeshond', 0.03186424449086189), ('white wolf', 0.01739676296710968), ('Eskimo dog', 0.011717947199940681)]
```

Replace the model name with the variant you want to use, e.g. `fbnetc_100`. You can find the IDs in the model summaries at the top of this page.

To extract image features with this model, follow the [timm feature extraction examples](https://rwightman.github.io/pytorch-image-models/feature_extraction/), just change the name of the model you want to use.

## How do I finetune this model?
You can finetune any of the pre-trained models just by changing the classifier (the last layer).
```python
model = timm.create_model('fbnetc_100', pretrained=True).reset_classifier(NUM_FINETUNE_CLASSES)
```
To finetune on your own dataset, you have to write a training loop or adapt [timm's training
script](https://github.com/rwightman/pytorch-image-models/blob/master/train.py) to use your dataset.

## How do I train this model?

You can follow the [timm recipe scripts](https://rwightman.github.io/pytorch-image-models/scripts/) for training a new model afresh.

## Citation

```BibTeX
@misc{wu2019fbnet,
      title={FBNet: Hardware-Aware Efficient ConvNet Design via Differentiable Neural Architecture Search}, 
      author={Bichen Wu and Xiaoliang Dai and Peizhao Zhang and Yanghan Wang and Fei Sun and Yiming Wu and Yuandong Tian and Peter Vajda and Yangqing Jia and Kurt Keutzer},
      year={2019},
      eprint={1812.03443},
      archivePrefix={arXiv},
      primaryClass={cs.CV}
}
```

<!--
Models:
- Name: fbnetc_100
  Metadata:
    FLOPs: 508940064
    Epochs: 360
    Batch Size: 256
    Training Data:
    - ImageNet
    Training Techniques:
    - SGD with Momentum
    - Weight Decay
    Training Resources: 8x GPUs
    Architecture:
    - 1x1 Convolution
    - Convolution
    - Dense Connections
    - Dropout
    - FBNet Block
    - Global Average Pooling
    - Softmax
    File Size: 22525094
    Tasks:
    - Image Classification
    ID: fbnetc_100
    LR: 0.1
    Layers: 22
    Dropout: 0.2
    Crop Pct: '0.875'
    Momentum: 0.9
    Image Size: '224'
    Weight Decay: 0.0005
    Interpolation: bilinear
  Code: https://github.com/rwightman/pytorch-image-models/blob/9a25fdf3ad0414b4d66da443fe60ae0aa14edc84/timm/models/efficientnet.py#L985
  In Collection: FBNet
Collections:
- Name: FBNet
  Paper:
    title: 'FBNet: Hardware-Aware Efficient ConvNet Design via Differentiable Neural
      Architecture Search'
    url: https://papperswithcode.com//paper/fbnet-hardware-aware-efficient-convnet-design
  type: model-index
Type: model-index
-->
Model index files and script to generate it 4 years ago			`# Summary`

			`FBNet is a type of convolutional neural architectures discovered through [DNAS](https://paperswithcode.com/method/dnas) neural architecture search. It utilises a basic type of image model block inspired by [MobileNetv2](https://paperswithcode.com/method/mobilenetv2) that utilises depthwise convolutions and an inverted residual structure (see components).`

			`The principal building block is the [FBNet Block](https://paperswithcode.com/method/fbnet-block).`

			`## How do I use this model on an image?`
			`To load a pretrained model:`

			```python
			`import timm`
			`model = timm.create_model('fbnetc_100', pretrained=True)`
			`model.eval()`
			```

			`To load and preprocess the image:`
			```python
			`import urllib`
			`from PIL import Image`
			`from timm.data import resolve_data_config`
			`from timm.data.transforms_factory import create_transform`

			`config = resolve_data_config({}, model=model)`
			`transform = create_transform(**config)`

			`url, filename = ("https://github.com/pytorch/hub/raw/master/images/dog.jpg", "dog.jpg")`
			`urllib.request.urlretrieve(url, filename)`
			`img = Image.open(filename).convert('RGB')`
			`tensor = transform(img).unsqueeze(0) # transform and add batch dimension`
			```

			`To get the model predictions:`
			```python
			`import torch`
			`with torch.no_grad():`
			`out = model(tensor)`
			`probabilities = torch.nn.functional.softmax(out[0], dim=0)`
			`print(probabilities.shape)`
			`# prints: torch.Size([1000])`
			```

			`To get the top-5 predictions class names:`
			```python
			`# Get imagenet class mappings`
			`url, filename = ("https://raw.githubusercontent.com/pytorch/hub/master/imagenet_classes.txt", "imagenet_classes.txt")`
			`urllib.request.urlretrieve(url, filename)`
			`with open("imagenet_classes.txt", "r") as f:`
			`categories = [s.strip() for s in f.readlines()]`

			`# Print top categories per image`
			`top5_prob, top5_catid = torch.topk(probabilities, 5)`
			`for i in range(top5_prob.size(0)):`
			`print(categories[top5_catid[i]], top5_prob[i].item())`
			`# prints class names and probabilities like:`
			`# [('Samoyed', 0.6425196528434753), ('Pomeranian', 0.04062102362513542), ('keeshond', 0.03186424449086189), ('white wolf', 0.01739676296710968), ('Eskimo dog', 0.011717947199940681)]`
			```

			Replace the model name with the variant you want to use, e.g. `fbnetc_100`. You can find the IDs in the model summaries at the top of this page.

			`To extract image features with this model, follow the [timm feature extraction examples](https://rwightman.github.io/pytorch-image-models/feature_extraction/), just change the name of the model you want to use.`

			`## How do I finetune this model?`
			`You can finetune any of the pre-trained models just by changing the classifier (the last layer).`
			```python
			`model = timm.create_model('fbnetc_100', pretrained=True).reset_classifier(NUM_FINETUNE_CLASSES)`
			```
			`To finetune on your own dataset, you have to write a training loop or adapt [timm's training`
			`script](https://github.com/rwightman/pytorch-image-models/blob/master/train.py) to use your dataset.`

			`## How do I train this model?`

			`You can follow the [timm recipe scripts](https://rwightman.github.io/pytorch-image-models/scripts/) for training a new model afresh.`

			`## Citation`

			```BibTeX
			`@misc{wu2019fbnet,`
			`title={FBNet: Hardware-Aware Efficient ConvNet Design via Differentiable Neural Architecture Search},`
			`author={Bichen Wu and Xiaoliang Dai and Peizhao Zhang and Yanghan Wang and Fei Sun and Yiming Wu and Yuandong Tian and Peter Vajda and Yangqing Jia and Kurt Keutzer},`
			`year={2019},`
			`eprint={1812.03443},`
			`archivePrefix={arXiv},`
			`primaryClass={cs.CV}`
			`}`
			```

			`<!--`
			`Models:`
			`- Name: fbnetc_100`
			`Metadata:`
			`FLOPs: 508940064`
			`Epochs: 360`
			`Batch Size: 256`
			`Training Data:`
			`- ImageNet`
			`Training Techniques:`
			`- SGD with Momentum`
			`- Weight Decay`
			`Training Resources: 8x GPUs`
			`Architecture:`
			`- 1x1 Convolution`
			`- Convolution`
			`- Dense Connections`
			`- Dropout`
			`- FBNet Block`
			`- Global Average Pooling`
			`- Softmax`
			`File Size: 22525094`
			`Tasks:`
			`- Image Classification`
			`ID: fbnetc_100`
			`LR: 0.1`
			`Layers: 22`
			`Dropout: 0.2`
			`Crop Pct: '0.875'`
			`Momentum: 0.9`
			`Image Size: '224'`
			`Weight Decay: 0.0005`
			`Interpolation: bilinear`
			`Code: https://github.com/rwightman/pytorch-image-models/blob/9a25fdf3ad0414b4d66da443fe60ae0aa14edc84/timm/models/efficientnet.py#L985`
			`In Collection: FBNet`
			`Collections:`
			`- Name: FBNet`
			`Paper:`
			`title: 'FBNet: Hardware-Aware Efficient ConvNet Design via Differentiable Neural`
			`Architecture Search'`
			`url: https://papperswithcode.com//paper/fbnet-hardware-aware-efficient-convnet-design`
			`type: model-index`
			`Type: model-index`
			`-->`