A Differentially Private Framework for Deep Learning With Convexified Loss Functions
Journal Publication ResearchOnline@JCUAbstract
Differential privacy (DP) has been applied in deep learning for preserving privacy of the underlying training sets. Existing DP practice falls into three categories—objective perturbation (injecting DP noise into the objective function), gradient perturbation (injecting DP noise into the process of gradient descent) and output perturbation (injecting DP noise into the trained neural networks, scaled by the global sensitivity of the trained model parameters). They suffer from three main problems. First, conditions on objective functions limit objective perturbation in general deep learning tasks. Second, gradient perturbation does not achieve a satisfactory privacy-utility trade-off due to over-injected noise in each epoch. Third, high utility of the output perturbation method is not guaranteed because of the loose upper bound on the global sensitivity of the trained model parameters as the noise scale parameter. To address these problems, we analyse a tighter upper bound on the global sensitivity of the model parameters. Under a black-box setting, based on this global sensitivity, to control the overall noise injection, we propose a novel output perturbation framework by injecting DP noise into a randomly sampled neuron (via the exponential mechanism) at the output layer of a baseline non-private neural network trained with a convexified loss function. We empirically compare the privacy-utility trade-off, measured by accuracy loss to baseline non-private models and the privacy leakage against black-box membership inference (MI) attacks, between our framework and the open-source differentially private stochastic gradient descent (DP-SGD) approaches on six commonly used real-world datasets. The experimental evaluations show that, when the baseline models have observable privacy leakage under MI attacks, our framework achieves a better privacy-utility trade-off than existing DP-SGD implementations, given an overall privacy budget ε ≤ 1 for a large number of queries.
Journal
IEEE Transactions on Information Forensics and Security
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Volume
17
ISBN/ISSN
1556-6021
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Pages Count
15
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Publisher
Institute of Electrical and Electronics Engineers
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DOI
10.1109/TIFS.2022.3169911