English

Phasor-Driven Acceleration for FFT-based CNNs

Computer Vision and Pattern Recognition 2024-06-05 v1 Machine Learning Signal Processing

Abstract

Recent research in deep learning (DL) has investigated the use of the Fast Fourier Transform (FFT) to accelerate the computations involved in Convolutional Neural Networks (CNNs) by replacing spatial convolution with element-wise multiplications on the spectral domain. These approaches mainly rely on the FFT to reduce the number of operations, which can be further decreased by adopting the Real-Valued FFT. In this paper, we propose using the phasor form, a polar representation of complex numbers, as a more efficient alternative to the traditional approach. The experimental results, evaluated on the CIFAR-10, demonstrate that our method achieves superior speed improvements of up to a factor of 1.376 (average of 1.316) during training and up to 1.390 (average of 1.321) during inference when compared to the traditional rectangular form employed in modern CNN architectures. Similarly, when evaluated on the CIFAR-100, our method achieves superior speed improvements of up to a factor of 1.375 (average of 1.299) during training and up to 1.387 (average of 1.300) during inference. Most importantly, given the modular aspect of our approach, the proposed method can be applied to any existing convolution-based DL model without design changes.

Keywords

Cite

@article{arxiv.2406.00290,
  title  = {Phasor-Driven Acceleration for FFT-based CNNs},
  author = {Eduardo Reis and Thangarajah Akilan and Mohammed Khalid},
  journal= {arXiv preprint arXiv:2406.00290},
  year   = {2024}
}

Comments

Presented in the 21st Conference on Robots and Vision (CRV 2024) Workshop

R2 v1 2026-06-28T16:49:20.981Z