FedReFT: Federated Representation Fine-Tuning with All-But-Me Aggregation
- URL: http://arxiv.org/abs/2508.20295v1
- Date: Wed, 27 Aug 2025 22:03:19 GMT
- Title: FedReFT: Federated Representation Fine-Tuning with All-But-Me Aggregation
- Authors: Fatema Siddika, Md Anwar Hossen, J. Pablo Muñoz, Tanya Roosta, Anuj Sharma, Ali Jannesari,
- Abstract summary: We introduce Federated Representation Fine-Tuning (FedReFT), a novel approach to fine-tune the client's hidden representation.<n>FedReFT applies sparse intervention layers to steer hidden representations directly, offering a lightweight and semantically rich fine-tuning alternative.<n>We evaluate FedReFT on commonsense reasoning, arithmetic reasoning, instruction-tuning, and GLUE.
- Score: 12.544628972135905
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Parameter-efficient fine-tuning (PEFT) has attracted significant attention for adapting large pre-trained models by modifying a small subset of parameters. Recently, Representation Fine-tuning (ReFT) has emerged as an effective alternative. ReFT shifts the fine-tuning paradigm from updating model weights to directly manipulating hidden representations that capture rich semantic information, and performs better than state-of-the-art PEFTs in standalone settings. However, its application in Federated Learning (FL) remains challenging due to heterogeneity in clients' data distributions, model capacities, and computational resources. To address these challenges, we introduce Federated Representation Fine-Tuning (FedReFT), a novel approach to fine-tune the client's hidden representation. FedReFT applies sparse intervention layers to steer hidden representations directly, offering a lightweight and semantically rich fine-tuning alternative ideal for edge devices. However, representation-level updates are especially vulnerable to aggregation mismatch under different task heterogeneity, where naive averaging can corrupt semantic alignment. To mitigate this issue, we propose All-But-Me (ABM) aggregation, where each client receives the aggregated updates of others and partially incorporates them, enabling stable and personalized learning by balancing local focus with global knowledge. We evaluate FedReFT on commonsense reasoning, arithmetic reasoning, instruction-tuning, and GLUE, where it consistently outperforms state-of-the-art PEFT methods in FL, achieving 7x-15x higher parameter efficiency compared to leading LoRA-based approaches.
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