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Federated Learning with Dynamically Adjusted Learning Rates for Resource-Constrained Wireless Networks


Kernekoncepter
The proposed FLARE framework allows participating devices to dynamically adjust their individual learning rates and local training iterations based on their instantaneous computing powers, mitigating the impact of device and data heterogeneity in wireless federated learning.
Resumé

The paper presents a new Federated Learning with Adjusted leaRning ratE (FLARE) framework to address the challenges of device and data heterogeneity in wireless federated learning (WFL). The key idea is to enable the participating devices to adjust their individual learning rates and local training iterations, adapting to their instantaneous computing powers.

The authors establish a general convergence analysis of FLARE under non-convex models with non-i.i.d. datasets and imbalanced computing powers. By minimizing the derived convergence upper bound, they further optimize the scheduling of FLARE to exploit the channel heterogeneity. A nested problem structure is revealed to facilitate iteratively allocating the bandwidth with binary search and selecting devices with a new greedy method. A linear problem structure is also identified, and a low-complexity linear programming scheduling policy is designed when training models have large Lipschitz constants.

Experiments demonstrate that FLARE consistently outperforms the baselines in test accuracy and converges much faster with the proposed scheduling policy, under both i.i.d. and non-i.i.d. data distributions, as well as uniform and non-uniform device selection.

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Statistik
The number of CPU cycles required to compute a data sample is 110 cycles/bit for MNIST and 85 cycles/bit for CIFAR-10. The model size is 1 × 10^7 bits for MNIST and 6.4 × 10^7 bits for CIFAR-10.
Citater
"The key idea is to allow the participating devices to adjust their individual learning rates and local training iterations, adapting to their instantaneous computing powers." "Experiments demonstrate that FLARE consistently outperforms the baselines in test accuracy, and converges much faster with the proposed scheduling policy."

Dybere Forespørgsler

How can the FLARE framework be extended to handle asynchronous aggregation in wireless federated learning

To extend the FLARE framework to handle asynchronous aggregation in wireless federated learning, we can introduce a mechanism that allows devices to communicate their local updates to the server at different times. This asynchronous aggregation approach can help mitigate delays caused by varying channel conditions and device capabilities. Here are some key steps to incorporate asynchronous aggregation into FLARE: Delayed Aggregation: Devices can send their local updates to the server at different times, based on their individual computation speeds and channel conditions. The server can aggregate these updates as they arrive, allowing for more flexible and efficient communication. Dynamic Synchronization: Implement a dynamic synchronization mechanism where the server waits for a certain period to collect updates from all devices before proceeding with the aggregation. This adaptive synchronization can help optimize the overall convergence process in the presence of asynchrony. Error Handling: Develop error-handling mechanisms to address potential issues that may arise due to delays in communication or asynchronous updates. This can involve retransmission protocols, data reconciliation techniques, or adaptive learning rate adjustments to account for delayed updates. By incorporating these strategies, FLARE can effectively handle asynchronous aggregation in wireless federated learning, improving the overall efficiency and convergence of the learning process.

What are the potential challenges and considerations in applying FLARE to federated learning scenarios with dynamic device participation

Applying FLARE to federated learning scenarios with dynamic device participation introduces several challenges and considerations that need to be addressed: Dynamic Device Selection: FLARE needs to adapt to the changing set of participating devices in each round. This requires robust algorithms for device selection based on real-time factors such as device availability, channel conditions, and computational capabilities. Heterogeneous Environments: Dynamic device participation can lead to increased heterogeneity in the data distributions, computing powers, and communication conditions. FLARE must be able to handle this heterogeneity effectively to ensure fair and efficient learning across all devices. Communication Overhead: With devices joining and leaving the network dynamically, there may be increased communication overhead. FLARE should optimize communication protocols to minimize latency and bandwidth usage while accommodating dynamic participation. Resource Allocation: Dynamic device participation may require adaptive resource allocation strategies to ensure optimal utilization of computing resources, bandwidth, and energy. FLARE needs to balance these resources efficiently to support varying numbers of participating devices. By addressing these challenges and considerations, FLARE can be successfully applied to federated learning scenarios with dynamic device participation, enabling adaptive and efficient learning in dynamic environments.

How can the FLARE framework be adapted to incorporate additional system-level constraints, such as energy efficiency or fairness, in the device scheduling and resource allocation process

To adapt the FLARE framework to incorporate additional system-level constraints such as energy efficiency or fairness in device scheduling and resource allocation, the following modifications can be made: Energy-Efficient Scheduling: Introduce energy consumption models for devices and incorporate energy efficiency constraints into the scheduling algorithm. FLARE can prioritize devices with lower energy consumption or adjust learning rates based on energy levels to optimize energy usage. Fairness Considerations: Implement fairness metrics in the device selection process to ensure equitable participation and model updates across all devices. FLARE can incorporate fairness constraints to distribute training opportunities evenly among devices, promoting balanced learning outcomes. Constraint Optimization: Extend the optimization framework of FLARE to include constraints on energy consumption, fairness, or other system-level metrics. This involves formulating the scheduling problem as a constrained optimization task, where the objective function is optimized subject to the specified constraints. Dynamic Constraint Handling: Develop adaptive algorithms that can dynamically adjust device scheduling and resource allocation based on real-time system constraints. FLARE should be able to react to changes in energy availability, fairness requirements, or other constraints to maintain system efficiency and performance. By integrating these adaptations, FLARE can effectively incorporate additional system-level constraints into the device scheduling and resource allocation process, enhancing energy efficiency, fairness, and overall system performance in federated learning scenarios.
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