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ThreshNet: An Efficient DenseNet Using Threshold Mechanism to Reduce Connections

Computer Vision and Pattern Recognition 2026-02-06 v2

Abstract

With the continuous development of neural networks for computer vision tasks, more and more network architectures have achieved outstanding success. As one of the most advanced neural network architectures, DenseNet shortcuts all feature maps to solve the model depth problem. Although this network architecture has excellent accuracy with low parameters, it requires an excessive inference time. To solve this problem, HarDNet reduces the connections between the feature maps, making the remaining connections resemble harmonic waves. However, this compression method may result in a decrease in the model accuracy and an increase in the parameters and model size. This network architecture may reduce the memory access time, but its overall performance can still be improved. Therefore, we propose a new network architecture, ThreshNet, using a threshold mechanism to further optimize the connection method. Different numbers of connections for different convolution layers are discarded to accelerate the inference of the network. The proposed network has been evaluated with image classification using CIFAR 10 and SVHN datasets under platforms of NVIDIA RTX 3050 and Raspberry Pi 4. The experimental results show that, compared with HarDNet68, GhostNet, MobileNetV2, ShuffleNet, and EfficientNet, the inference time of the proposed ThreshNet79 is 5%, 9%, 10%, 18%, and 20% faster, respectively. The number of parameters of ThreshNet95 is 55% less than that of HarDNet85. The new model compression and model acceleration methods can speed up the inference time, enabling network models to operate on mobile devices.

Keywords

Cite

@article{arxiv.2201.03013,
  title  = {ThreshNet: An Efficient DenseNet Using Threshold Mechanism to Reduce Connections},
  author = {Rui-Yang Ju and Ting-Yu Lin and Jia-Hao Jian and Jen-Shiun Chiang and Wei-Bin Yang},
  journal= {arXiv preprint arXiv:2201.03013},
  year   = {2026}
}

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IEEE Access

R2 v1 2026-06-24T08:44:06.194Z