Characterizing the Training Dynamics of Private Fine-Tuning with Langevin Diffusion
Abstract
We show that differentially private full fine-tuning (DP-FFT) can distort pre-trained backbone features based on both theoretical and empirical results. We identify the cause of the distortion as the misalignment between the pre-trained backbone and the randomly initialized linear head. We prove that a sequential fine-tuning strategy can mitigate the feature distortion: first-linear-probing-then-fine-tuning (DP-LP-FFT). A new approximation scheme allows us to derive approximate upper and lower bounds on the training loss of DP-LP and DP-FFT, in a simple but canonical setting of 2-layer neural networks with ReLU activation. Experiments on real-world datasets and architectures are consistent with our theoretical insights. Moreover, our theory suggests a trade-off of privacy budget allocation in multi-phase fine-tuning methods like DP-LP-FFT.
Cite
Text
Ke et al. "Characterizing the Training Dynamics of Private Fine-Tuning with Langevin Diffusion." NeurIPS 2024 Workshops: FITML, 2024.Markdown
[Ke et al. "Characterizing the Training Dynamics of Private Fine-Tuning with Langevin Diffusion." NeurIPS 2024 Workshops: FITML, 2024.](https://mlanthology.org/neuripsw/2024/ke2024neuripsw-characterizing/)BibTeX
@inproceedings{ke2024neuripsw-characterizing,
title = {{Characterizing the Training Dynamics of Private Fine-Tuning with Langevin Diffusion}},
author = {Ke, Shuqi and Hou, Charlie and Oh, Sewoong and Fanti, Giulia},
booktitle = {NeurIPS 2024 Workshops: FITML},
year = {2024},
url = {https://mlanthology.org/neuripsw/2024/ke2024neuripsw-characterizing/}
}