--- tags: - image-classification - birder library_name: birder license: apache-2.0 --- # Model Card for regnet_y_8g_intermediate-eu-common RegNet Y image classification model. The model follows a two-stage training process: first undergoing intermediate training on a large-scale dataset containing diverse bird species from around the world, then fine-tuned specifically on the `eu-common` dataset containing common European bird species. The species list is derived from the Collins bird guide [^1]. [^1]: Svensson, L., Mullarney, K., & Zetterström, D. (2022). Collins bird guide (3rd ed.). London, England: William Collins. ## Model Details - **Model Type:** Image classification and detection backbone - **Model Stats:** - Params (M): 38.8 - Input image size: 384 x 384 - **Dataset:** eu-common (707 classes) - **Papers:** - Designing Network Design Spaces: ## Model Usage ### Image Classification ```python import birder from birder.inference.classification import infer_image (net, class_to_idx, signature, rgb_stats) = birder.load_pretrained_model("regnet_y_8g_intermediate-eu-common", inference=True) # Get the image size the model was trained on size = birder.get_size_from_signature(signature) # Create an inference transform transform = birder.classification_transform(size, rgb_stats) image = "path/to/image.jpeg" # or a PIL image (out, _) = infer_image(net, image, transform) # out is a NumPy array with shape of (1, num_classes) ``` ### Image Embeddings ```python import birder from birder.inference.classification import infer_image (net, class_to_idx, signature, rgb_stats) = birder.load_pretrained_model("regnet_y_8g_intermediate-eu-common", inference=True) # Get the image size the model was trained on size = birder.get_size_from_signature(signature) # Create an inference transform transform = birder.classification_transform(size, rgb_stats) image = "path/to/image.jpeg" # or a PIL image (out, embedding) = infer_image(net, image, transform, return_embedding=True) # embedding is a NumPy array with shape of (1, embedding_size) ``` ### Detection Feature Map ```python from PIL import Image import birder (net, class_to_idx, signature, rgb_stats) = birder.load_pretrained_model("regnet_y_8g_intermediate-eu-common", inference=True) # Get the image size the model was trained on size = birder.get_size_from_signature(signature) # Create an inference transform transform = birder.classification_transform(size, rgb_stats) image = Image.open("path/to/image.jpeg") features = net.detection_features(transform(image).unsqueeze(0)) # features is a dict (stage name -> torch.Tensor) print([(k, v.size()) for k, v in features.items()]) # Output example: # [('stage1', torch.Size([1, 96, 96, 96])), # ('stage2', torch.Size([1, 192, 48, 48])), # ('stage3', torch.Size([1, 384, 24, 24])), # ('stage4', torch.Size([1, 768, 12, 12]))] ``` ## Citation ```bibtex @misc{radosavovic2020designingnetworkdesignspaces, title={Designing Network Design Spaces}, author={Ilija Radosavovic and Raj Prateek Kosaraju and Ross Girshick and Kaiming He and Piotr Dollár}, year={2020}, eprint={2003.13678}, archivePrefix={arXiv}, primaryClass={cs.CV}, url={https://arxiv.org/abs/2003.13678}, } ```