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Robust Federated Finetuning of Foundation Models via Alternating Minimization of LoRA
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Robust Federated Finetuning of Foundation Models via Alternating Minimization of LoRA
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Parameter-Efficient Fine-Tuning (PEFT) has risen as an innovative training strategy that updates only a select few model parameters, significantly lowering both computational and memory demands. PEFT also helps to decrease data transfer in federated learning settings, where communication depends on the size of updates. In this work, we explore the constraints of previous studies that integrate a well-known PEFT method named LoRA with federated fine-tuning, then introduce RoLoRA, a robust federated fine-tuning framework that utilizes an alternating minimization approach for LoRA, providing greater robustness against decreasing fine-tuning parameters and increasing data heterogeneity. Our results indicate that RoLoRA not only presents the communication benefits but also substantially enhances the robustness and effectiveness in multiple federated fine-tuning scenarios.
Forward citations
Cited by 2 Pith papers
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FedMark-FM: Auditable, Risk-Adjusted Data Markets for Federated Foundation-Model Adaptation
FedMark-FM is an auditable data-market framework that prices heterogeneous foundation-model artifacts via pipeline-ordered Shapley valuation and risk-adjusted payments, selecting zero strategic clients while improving...
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Rethinking LoRA for Privacy-Preserving Federated Learning in Large Models
LA-LoRA decouples LoRA matrix updates in DPFL settings to improve robustness to privacy noise, delivering up to 16.83% higher accuracy than prior LoRA variants on Swin-B under strict epsilon=1.
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