English

Deep Random Forest with Ferroelectric Analog Content Addressable Memory

Emerging Technologies 2021-10-07 v1 Signal Processing

Abstract

Deep random forest (DRF), which incorporates the core features of deep learning and random forest (RF), exhibits comparable classification accuracy, interpretability, and low memory and computational overhead when compared with deep neural networks (DNNs) in various information processing tasks for edge intelligence. However, the development of efficient hardware to accelerate DRF is lagging behind its DNN counterparts. The key for hardware acceleration of DRF lies in efficiently realizing the branch-split operation at decision nodes when traversing a decision tree. In this work, we propose to implement DRF through simple associative searches realized with ferroelectric analog content addressable memory (ACAM). Utilizing only two ferroelectric field effect transistors (FeFETs), the ultra-compact ACAM cell can perform a branch-split operation with an energy-efficient associative search by storing the decision boundaries as the analog polarization states in an FeFET. The DRF accelerator architecture and the corresponding mapping of the DRF model to the ACAM arrays are presented. The functionality, characteristics, and scalability of the FeFET ACAM based DRF and its robustness against FeFET device non-idealities are validated both in experiments and simulations. Evaluation results show that the FeFET ACAM DRF accelerator exhibits 10^6x/16x and 10^6x/2.5x improvements in terms of energy and latency when compared with other deep random forest hardware implementations on the state-of-the-art CPU/ReRAM, respectively.

Keywords

Cite

@article{arxiv.2110.02495,
  title  = {Deep Random Forest with Ferroelectric Analog Content Addressable Memory},
  author = {Xunzhao Yin and Franz Müller and Ann Franchesca Laguna and Chao Li and Wenwen Ye and Qingrong Huang and Qinming Zhang and Zhiguo Shi and Maximilian Lederer and Nellie Laleni and Shan Deng and Zijian Zhao and Michael Niemier and Xiaobo Sharon Hu and Cheng Zhuo and Thomas Kämpfe and Kai Ni},
  journal= {arXiv preprint arXiv:2110.02495},
  year   = {2021}
}

Comments

44 pages, 16 figures

R2 v1 2026-06-24T06:39:27.279Z