PaddleClas/docs/zh_cn/models/models_intro.md

模型库概览

概述

基于ImageNet1k分类数据集，PaddleClas支持的25种主流分类网络结构以及对应的117个图像分类预训练模型如下所示，训练技巧、每个系列网络结构的简单介绍和性能评估将在相应章节展现。GPU评估环境基于V100和TensorRT，CPU的评估环境基于骁龙855（SD855）。

• ResNet及其Vd系列

  • ResNet系列^[1](论文地址)
    • ResNet18
    • ResNet34
    • ResNet50
    • ResNet101
    • ResNet152
  • ResNet_vc、ResNet_vd系列^[2](论文地址)
    • ResNet50_vc
    • ResNet18_vd
    • ResNet34_vd
    • ResNet50_vd
    • ResNet50_vd_v2
    • ResNet101_vd
    • ResNet152_vd
    • ResNet200_vd
    • ResNet50_vd_ssld

• 移动端系列

  • MobileNetV3系列^[3](论文地址)
    • MobileNetV3_large_x0_35
    • MobileNetV3_large_x0_5
    • MobileNetV3_large_x0_75
    • MobileNetV3_large_x1_0
    • MobileNetV3_large_x1_25
    • MobileNetV3_small_x0_35
    • MobileNetV3_small_x0_5
    • MobileNetV3_small_x0_75
    • MobileNetV3_small_x1_0
    • MobileNetV3_small_x1_25
    • MobileNetV3_large_x1_0_ssld
    • MobileNetV3_large_x1_0_ssld_int8
    • MobileNetV3_small_x1_0_ssld
  • MobileNetV2系列^[4](论文地址)
    • MobileNetV2_x0_25
    • MobileNetV2_x0_5
    • MobileNetV2_x0_75
    • MobileNetV2
    • MobileNetV2_x1_5
    • MobileNetV2_x2_0
    • MobileNetV2_ssld
  • MobileNetV1系列^[5](论文地址)
    • MobileNetV1_x0_25
    • MobileNetV1_x0_5
    • MobileNetV1_x0_75
    • MobileNetV1
    • MobileNetV1_ssld
  • ShuffleNetV2系列^[6](论文地址)
    • ShuffleNetV2_x0_25
    • ShuffleNetV2_x0_33
    • ShuffleNetV2_x0_5
    • ShuffleNetV2
    • ShuffleNetV2_x1_5
    • ShuffleNetV2_x2_0
    • ShuffleNetV2_swish

• SEResNeXt与Res2Net系列

  • ResNeXt系列^[7](论文地址)
    • ResNeXt50_32x4d
    • ResNeXt50_64x4d
    • ResNeXt101_32x4d
    • ResNeXt101_64x4d
    • ResNeXt152_32x4d
    • ResNeXt152_64x4d
  • ResNeXt_vd系列
    • ResNeXt50_vd_32x4d
    • ResNeXt50_vd_64x4d
    • ResNeXt101_vd_32x4d
    • ResNeXt101_vd_64x4d
    • ResNeXt152_vd_32x4d
    • ResNeXt152_vd_64x4d
  • SE_ResNet_vd系列^[8](论文地址)
    • SE_ResNet18_vd
    • SE_ResNet34_vd
    • SE_ResNet50_vd
  • SE_ResNeXt系列
    • SE_ResNeXt50_32x4d
    • SE_ResNeXt101_32x4d
  • SE_ResNeXt_vd系列
    • SE_ResNeXt50_vd_32x4d
    • SENet154_vd
  • Res2Net系列^[9](论文地址)
    • Res2Net50_26w_4s
    • Res2Net50_vd_26w_4s
    • Res2Net50_14w_8s
    • Res2Net101_vd_26w_4s
    • Res2Net200_vd_26w_4s

• Inception系列

  • GoogLeNet系列^[10](论文地址)
    • GoogLeNet
  • Inception系列^[11](论文地址)
    • InceptionV4
  • Xception系列^[12](论文地址)
    • Xception41
    • Xception41_deeplab
    • Xception65
    • Xception65_deeplab
    • Xception71

• HRNet系列

  • HRNet系列^[13](论文地址)
    • HRNet_W18_C
    • HRNet_W30_C
    • HRNet_W32_C
    • HRNet_W40_C
    • HRNet_W44_C
    • HRNet_W48_C
    • HRNet_W64_C

• DPN与DenseNet系列

  • DPN系列^[14](论文地址)
    • DPN68
    • DPN92
    • DPN98
    • DPN107
    • DPN131
  • DenseNet系列^[15](论文地址)
    • DenseNet121
    • DenseNet161
    • DenseNet169
    • DenseNet201
    • DenseNet264

• EfficientNet与ResNeXt101_wsl系列

  • EfficientNet系列^[16](论文地址)
    • EfficientNetB0_small
    • EfficientNetB0
    • EfficientNetB1
    • EfficientNetB2
    • EfficientNetB3
    • EfficientNetB4
    • EfficientNetB5
    • EfficientNetB6
    • EfficientNetB7
  • ResNeXt101_wsl系列^[17](论文地址)
    • ResNeXt101_32x8d_wsl
    • ResNeXt101_32x16d_wsl
    • ResNeXt101_32x32d_wsl
    • ResNeXt101_32x48d_wsl
    • Fix_ResNeXt101_32x48d_wsl

• 其他模型

  • AlexNet系列^[18](论文地址)
    • AlexNet
  • SqueezeNet系列^[19](论文地址)
    • SqueezeNet1_0
    • SqueezeNet1_1
  • VGG系列^[20](论文地址)
    • VGG11
    • VGG13
    • VGG16
    • VGG19
  • DarkNet系列^[21](论文地址)
    • DarkNet53
  • ACNet系列^[22](论文地址)
    • ResNet50_ACNet_deploy

参考文献

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[5] Howard A G, Zhu M, Chen B, et al. Mobilenets: Efficient convolutional neural networks for mobile vision applications[J]. arXiv preprint arXiv:1704.04861, 2017.

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[9] Gao S, Cheng M M, Zhao K, et al. Res2net: A new multi-scale backbone architecture[J]. IEEE transactions on pattern analysis and machine intelligence, 2019.

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[13] Wang J, Sun K, Cheng T, et al. Deep high-resolution representation learning for visual recognition[J]. arXiv preprint arXiv:1908.07919, 2019.

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[15] Huang G, Liu Z, Van Der Maaten L, et al. Densely connected convolutional networks[C]//Proceedings of the IEEE conference on computer vision and pattern recognition. 2017: 4700-4708.

[16] Tan M, Le Q V. Efficientnet: Rethinking model scaling for convolutional neural networks[J]. arXiv preprint arXiv:1905.11946, 2019.

[17] Mahajan D, Girshick R, Ramanathan V, et al. Exploring the limits of weakly supervised pretraining[C]//Proceedings of the European Conference on Computer Vision (ECCV). 2018: 181-196.

[18] Krizhevsky A, Sutskever I, Hinton G E. Imagenet classification with deep convolutional neural networks[C]//Advances in neural information processing systems. 2012: 1097-1105.

[19] Iandola F N, Han S, Moskewicz M W, et al. SqueezeNet: AlexNet-level accuracy with 50x fewer parameters and< 0.5 MB model size[J]. arXiv preprint arXiv:1602.07360, 2016.

[20] Simonyan K, Zisserman A. Very deep convolutional networks for large-scale image recognition[J]. arXiv preprint arXiv:1409.1556, 2014.

[21] Redmon J, Divvala S, Girshick R, et al. You only look once: Unified, real-time object detection[C]//Proceedings of the IEEE conference on computer vision and pattern recognition. 2016: 779-788.

[22] Ding X, Guo Y, Ding G, et al. Acnet: Strengthening the kernel skeletons for powerful cnn via asymmetric convolution blocks[C]//Proceedings of the IEEE International Conference on Computer Vision. 2019: 1911-1920.