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Paper detail

NanoBatch Privacy: Enabling fast Differentially Private learning on the IPU

Differentially private SGD (DPSGD) has recently shown promise in deep learning. However, compared to non-private SGD, the DPSGD algorithm places computational overheads that can undo the benefit of batching in GPUs. Micro-batching is a common method to alleviate this and is fully supported in the TensorFlow Privacy library (TFDP). However, it degrades accuracy. We propose NanoBatch Privacy, a lightweight add-on to TFDP to be used on Graphcore IPUs by leveraging batch size of 1 (without microbatching) and gradient accumulation. This allows us to achieve large total batch sizes with minimal impacts to throughput. Second, we illustrate using Cifar-10 how larger batch sizes are not necessarily optimal from a privacy versus utility perspective. On ImageNet, we achieve more than 15x speedup over TFDP versus 8x A100s and significant speedups even across libraries such as Opacus. We also provide two extensions: 1) DPSGD for pipelined models and 2) per-layer clipping that is 15x faster than the Opacus implementation on 8x A100s. Finally as an application case study, we apply NanoBatch training for use on private Covid-19 chest CT prediction.

preprint2022arXivOpen access
Edward H. LeeMario Michael KrellAlexander TsyplikhinVictoria RegeErrol ColakKristen W. Yeom
Cryptography and SecurityComputer VisionMachine LearningDistributed, Parallel, and Cluster Computing
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Edward H. LeeMario Michael KrellAlexander TsyplikhinVictoria RegeErrol ColakKristen W. Yeom

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