TropNNC: Structured Neural Network Compression Using Tropical Geometry
We present TropNNC, a framework for compressing neural networks with linear and convolutional layers and ReLU activations. TropNNC is a structured compression framework based on a geometrical approach to machine/deep learning, using tropical geometry and extending the work of Misiakos et al. (2022)....
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| creator | Fotopoulos, Konstantinos Maragos, Petros Misiakos, Panagiotis |
| description | We present TropNNC, a framework for compressing neural networks with linear
and convolutional layers and ReLU activations. TropNNC is a structured
compression framework based on a geometrical approach to machine/deep learning,
using tropical geometry and extending the work of Misiakos et al. (2022). We
use the Hausdorff distance of zonotopes in its standard continuous form to
achieve a tighter approximation bound for tropical polynomials compared to
previous work. This enhancement leads to the development of an effective
compression algorithm that achieves superior functional approximations of
neural networks. Our method is significantly easier to implement compared to
other frameworks, and does not depend on the availability of training data
samples. We validate our framework through extensive empirical evaluations on
the MNIST, CIFAR, and ImageNet datasets. Our results demonstrate that TropNNC
achieves performance on par with state-of-the-art methods like ThiNet (even
surpassing it in compressing linear layers) and CUP. To the best of our
knowledge, it is the first method that achieves this using tropical geometry. |
| doi_str_mv | 10.48550/arxiv.2409.03945 |
| format | Article |
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and convolutional layers and ReLU activations. TropNNC is a structured
compression framework based on a geometrical approach to machine/deep learning,
using tropical geometry and extending the work of Misiakos et al. (2022). We
use the Hausdorff distance of zonotopes in its standard continuous form to
achieve a tighter approximation bound for tropical polynomials compared to
previous work. This enhancement leads to the development of an effective
compression algorithm that achieves superior functional approximations of
neural networks. Our method is significantly easier to implement compared to
other frameworks, and does not depend on the availability of training data
samples. We validate our framework through extensive empirical evaluations on
the MNIST, CIFAR, and ImageNet datasets. Our results demonstrate that TropNNC
achieves performance on par with state-of-the-art methods like ThiNet (even
surpassing it in compressing linear layers) and CUP. To the best of our
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and convolutional layers and ReLU activations. TropNNC is a structured
compression framework based on a geometrical approach to machine/deep learning,
using tropical geometry and extending the work of Misiakos et al. (2022). We
use the Hausdorff distance of zonotopes in its standard continuous form to
achieve a tighter approximation bound for tropical polynomials compared to
previous work. This enhancement leads to the development of an effective
compression algorithm that achieves superior functional approximations of
neural networks. Our method is significantly easier to implement compared to
other frameworks, and does not depend on the availability of training data
samples. We validate our framework through extensive empirical evaluations on
the MNIST, CIFAR, and ImageNet datasets. Our results demonstrate that TropNNC
achieves performance on par with state-of-the-art methods like ThiNet (even
surpassing it in compressing linear layers) and CUP. To the best of our
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and convolutional layers and ReLU activations. TropNNC is a structured
compression framework based on a geometrical approach to machine/deep learning,
using tropical geometry and extending the work of Misiakos et al. (2022). We
use the Hausdorff distance of zonotopes in its standard continuous form to
achieve a tighter approximation bound for tropical polynomials compared to
previous work. This enhancement leads to the development of an effective
compression algorithm that achieves superior functional approximations of
neural networks. Our method is significantly easier to implement compared to
other frameworks, and does not depend on the availability of training data
samples. We validate our framework through extensive empirical evaluations on
the MNIST, CIFAR, and ImageNet datasets. Our results demonstrate that TropNNC
achieves performance on par with state-of-the-art methods like ThiNet (even
surpassing it in compressing linear layers) and CUP. To the best of our
knowledge, it is the first method that achieves this using tropical geometry.</abstract><doi>10.48550/arxiv.2409.03945</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Computer Vision and Pattern Recognition |
| title | TropNNC: Structured Neural Network Compression Using Tropical Geometry |
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