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Efficient Federated Learning Over Heterogeneous Clients via Automated Model Transformation


Conceitos essenciais
FedTrans, a multi-model federated learning framework, automatically generates and trains high-accuracy, hardware-compatible models for individual clients at scale by leveraging model transformation techniques.
Resumo

The paper introduces FedTrans, a multi-model federated learning (FL) training framework that automatically produces and trains high-accuracy, hardware-compatible models for individual clients at scale. FedTrans addresses the key challenges in FL, including client system heterogeneity and client data heterogeneity, by employing a novel model transformation mechanism.

Key highlights:

  • FedTrans begins with a basic global model and identifies accuracy bottlenecks in the model architecture during training. It then employs model transformation to derive new models for heterogeneous clients on the fly, such as widening or deepening specific model cells.
  • FedTrans judiciously assigns the transformed models to individual clients while performing soft aggregation on multi-model updates to minimize total training costs.
  • Evaluations using realistic FL settings show that FedTrans improves individual client model accuracy by 14% - 72% while slashing training costs by 1.6× - 20× over state-of-the-art solutions.
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Estatísticas
"Federated learning (FL) aims to train machine learning (ML) models across potentially millions of edge client devices." "Training and customizing models for FL clients is notoriously challenging due to the heterogeneity of client data, device capabilities, and the massive scale of clients, making individualized model exploration prohibitively expensive." "FedTrans improves individual client model accuracy by 14% - 72% while slashing training costs by 1.6× - 20× over state-of-the-art solutions."
Citações
"FedTrans begins with a small model and progressively expands models in flight to produce well-trained models with different complexities, delivering high-accuracy models for diverse hardware-capable clients at a low cost." "FedTrans identifies suitable timing for generating new models to maximize the effectiveness of warmup, and performs aggregation of model weights across models to accelerate training convergence, by exploiting model architectural similarity."

Perguntas Mais Profundas

How can FedTrans be extended to handle highly heterogeneous client data distributions more effectively?

FedTrans can be extended to handle highly heterogeneous client data distributions more effectively by incorporating adaptive model transformation strategies. One approach could be to dynamically adjust the transformation process based on the diversity of client data distributions. For example, FedTrans could prioritize certain types of transformations for clients with significantly different data distributions to ensure that the models are tailored to each client's unique data characteristics. Additionally, incorporating techniques from transfer learning and domain adaptation could help FedTrans adapt more effectively to diverse data distributions by leveraging knowledge from related tasks or domains.

What are the potential privacy implications of the model transformation and weight sharing techniques used in FedTrans, and how can they be addressed?

The model transformation and weight sharing techniques used in FedTrans may raise privacy concerns as they involve sharing model weights and potentially sensitive information across clients. One potential implication is the risk of exposing sensitive client data through shared model parameters. To address these privacy implications, FedTrans can implement privacy-preserving techniques such as differential privacy, federated learning with secure aggregation, or homomorphic encryption. These methods can help protect the confidentiality of client data while still allowing for effective model transformation and weight sharing.

How can the model transformation and assignment strategies in FedTrans be generalized to other federated learning applications beyond computer vision and natural language processing?

The model transformation and assignment strategies in FedTrans can be generalized to other federated learning applications by focusing on the core principles of adaptability and scalability. One way to achieve this is by developing a modular and flexible framework that can accommodate different types of machine learning models and data types. By abstracting the transformation and assignment processes, FedTrans can be applied to a wide range of federated learning tasks, including healthcare, finance, IoT, and more. Additionally, incorporating domain-specific knowledge and constraints into the transformation and assignment strategies can help tailor FedTrans to specific application domains.
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