pytorch-image-models/docs/models/efficientnet-pruned.md

# Summary

**EfficientNet** is a convolutional neural network architecture and scaling method that uniformly scales all dimensions of depth/width/resolution using a *compound coefficient*. Unlike conventional practice that arbitrary scales  these factors, the EfficientNet scaling method uniformly scales network width, depth, and resolution with a set of fixed scaling coefficients. For example, if we want to use $2^N$ times more computational resources, then we can simply increase the network depth by $\alpha ^ N$,  width by $\beta ^ N$, and image size by $\gamma ^ N$, where $\alpha, \beta, \gamma$ are constant coefficients determined by a small grid search on the original small model. EfficientNet uses a compound coefficient $\phi$ to uniformly scales network width, depth, and resolution in a  principled way.

The compound scaling method is justified by the intuition that if the input image is bigger, then the network needs more layers to increase the receptive field and more channels to capture more fine-grained patterns on the bigger image.

The base EfficientNet-B0 network is based on the inverted bottleneck residual blocks of [MobileNetV2](https://paperswithcode.com/method/mobilenetv2), in addition to [squeeze-and-excitation blocks](https://paperswithcode.com/method/squeeze-and-excitation-block).

This collection consists of pruned EfficientNet models.

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

```python
import timm
model = timm.create_model('efficientnet_b1_pruned', 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. `efficientnet_b1_pruned`. 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('efficientnet_b1_pruned', 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{tan2020efficientnet,
      title={EfficientNet: Rethinking Model Scaling for Convolutional Neural Networks}, 
      author={Mingxing Tan and Quoc V. Le},
      year={2020},
      eprint={1905.11946},
      archivePrefix={arXiv},
      primaryClass={cs.LG}
}
```

```
@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/rwightman/pytorch-image-models}}
}
```

<!--
Models:
- Name: efficientnet_b1_pruned
  Metadata:
    FLOPs: 489653114
    Training Data:
    - ImageNet
    Architecture:
    - 1x1 Convolution
    - Average Pooling
    - Batch Normalization
    - Convolution
    - Dense Connections
    - Dropout
    - Inverted Residual Block
    - Squeeze-and-Excitation Block
    - Swish
    File Size: 25595162
    Tasks:
    - Image Classification
    ID: efficientnet_b1_pruned
    Crop Pct: '0.882'
    Image Size: '240'
    Interpolation: bicubic
  Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1208
  In Collection: EfficientNet Pruned
- Name: efficientnet_b3_pruned
  Metadata:
    FLOPs: 1239590641
    Training Data:
    - ImageNet
    Architecture:
    - 1x1 Convolution
    - Average Pooling
    - Batch Normalization
    - Convolution
    - Dense Connections
    - Dropout
    - Inverted Residual Block
    - Squeeze-and-Excitation Block
    - Swish
    File Size: 39770812
    Tasks:
    - Image Classification
    ID: efficientnet_b3_pruned
    Crop Pct: '0.904'
    Image Size: '300'
    Interpolation: bicubic
  Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1230
  In Collection: EfficientNet Pruned
- Name: efficientnet_b2_pruned
  Metadata:
    FLOPs: 878133915
    Training Data:
    - ImageNet
    Architecture:
    - 1x1 Convolution
    - Average Pooling
    - Batch Normalization
    - Convolution
    - Dense Connections
    - Dropout
    - Inverted Residual Block
    - Squeeze-and-Excitation Block
    - Swish
    File Size: 33555005
    Tasks:
    - Image Classification
    ID: efficientnet_b2_pruned
    Crop Pct: '0.89'
    Image Size: '260'
    Interpolation: bicubic
  Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1219
  In Collection: EfficientNet Pruned
Collections:
- Name: EfficientNet Pruned
  Paper:
    title: Knapsack Pruning with Inner Distillation
    url: https://paperswithcode.com//paper/knapsack-pruning-with-inner-distillation
  type: model-index
Type: model-index
-->
Model index files and script to generate it 3 years ago			`# Summary`

			EfficientNet is a convolutional neural network architecture and scaling method that uniformly scales all dimensions of depth/width/resolution using a compound coefficient. Unlike conventional practice that arbitrary scales these factors, the EfficientNet scaling method uniformly scales network width, depth, and resolution with a set of fixed scaling coefficients. For example, if we want to use $2^N$ times more computational resources, then we can simply increase the network depth by $\alpha ^ N$, width by $\beta ^ N$, and image size by $\gamma ^ N$, where $\alpha, \beta, \gamma$ are constant coefficients determined by a small grid search on the original small model. EfficientNet uses a compound coefficient $\phi$ to uniformly scales network width, depth, and resolution in a principled way.

			`The compound scaling method is justified by the intuition that if the input image is bigger, then the network needs more layers to increase the receptive field and more channels to capture more fine-grained patterns on the bigger image.`

			`The base EfficientNet-B0 network is based on the inverted bottleneck residual blocks of [MobileNetV2](https://paperswithcode.com/method/mobilenetv2), in addition to [squeeze-and-excitation blocks](https://paperswithcode.com/method/squeeze-and-excitation-block).`

			`This collection consists of pruned EfficientNet models.`

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

			```python
			`import timm`
			`model = timm.create_model('efficientnet_b1_pruned', 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. `efficientnet_b1_pruned`. 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('efficientnet_b1_pruned', 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{tan2020efficientnet,`
			`title={EfficientNet: Rethinking Model Scaling for Convolutional Neural Networks},`
			`author={Mingxing Tan and Quoc V. Le},`
			`year={2020},`
			`eprint={1905.11946},`
			`archivePrefix={arXiv},`
			`primaryClass={cs.LG}`
			`}`
			```

			```
			`@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/rwightman/pytorch-image-models}}`
			`}`
			```

			`<!--`
			`Models:`
			`- Name: efficientnet_b1_pruned`
			`Metadata:`
			`FLOPs: 489653114`
			`Training Data:`
			`- ImageNet`
			`Architecture:`
			`- 1x1 Convolution`
			`- Average Pooling`
			`- Batch Normalization`
			`- Convolution`
			`- Dense Connections`
			`- Dropout`
			`- Inverted Residual Block`
			`- Squeeze-and-Excitation Block`
			`- Swish`
			`File Size: 25595162`
			`Tasks:`
			`- Image Classification`
			`ID: efficientnet_b1_pruned`
			`Crop Pct: '0.882'`
			`Image Size: '240'`
			`Interpolation: bicubic`
			`Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1208`
			`In Collection: EfficientNet Pruned`
			`- Name: efficientnet_b3_pruned`
			`Metadata:`
			`FLOPs: 1239590641`
			`Training Data:`
			`- ImageNet`
			`Architecture:`
			`- 1x1 Convolution`
			`- Average Pooling`
			`- Batch Normalization`
			`- Convolution`
			`- Dense Connections`
			`- Dropout`
			`- Inverted Residual Block`
			`- Squeeze-and-Excitation Block`
			`- Swish`
			`File Size: 39770812`
			`Tasks:`
			`- Image Classification`
			`ID: efficientnet_b3_pruned`
			`Crop Pct: '0.904'`
			`Image Size: '300'`
			`Interpolation: bicubic`
			`Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1230`
			`In Collection: EfficientNet Pruned`
			`- Name: efficientnet_b2_pruned`
			`Metadata:`
			`FLOPs: 878133915`
			`Training Data:`
			`- ImageNet`
			`Architecture:`
			`- 1x1 Convolution`
			`- Average Pooling`
			`- Batch Normalization`
			`- Convolution`
			`- Dense Connections`
			`- Dropout`
			`- Inverted Residual Block`
			`- Squeeze-and-Excitation Block`
			`- Swish`
			`File Size: 33555005`
			`Tasks:`
			`- Image Classification`
			`ID: efficientnet_b2_pruned`
			`Crop Pct: '0.89'`
			`Image Size: '260'`
			`Interpolation: bicubic`
			`Code: https://github.com/rwightman/pytorch-image-models/blob/a7f95818e44b281137503bcf4b3e3e94d8ffa52f/timm/models/efficientnet.py#L1219`
			`In Collection: EfficientNet Pruned`
			`Collections:`
			`- Name: EfficientNet Pruned`
			`Paper:`
			`title: Knapsack Pruning with Inner Distillation`
fix typo in urls 3 years ago			`url: https://paperswithcode.com//paper/knapsack-pruning-with-inner-distillation`
Model index files and script to generate it 3 years ago			`type: model-index`
			`Type: model-index`
			`-->`