FedSpace: An Efficient Federated Learning Framework at Satellites and
Ground Stations
- URL: http://arxiv.org/abs/2202.01267v1
- Date: Wed, 2 Feb 2022 20:09:27 GMT
- Title: FedSpace: An Efficient Federated Learning Framework at Satellites and
Ground Stations
- Authors: Jinhyun So, Kevin Hsieh, Behnaz Arzani, Shadi Noghabi, Salman
Avestimehr, Ranveer Chandra
- Abstract summary: Large-scale deployments of low Earth orbit (LEO) satellites collect massive amount of Earth imageries and sensor data.
It is often infeasible to download all the high-resolution images and train these machine learning models on the ground because of limited downlink bandwidth, sparse connectivity, and regularization constraints on the imagery resolution.
We propose Federated Learning (FL), where ground stations and satellites collaboratively train a global ML model without sharing the captured images on the satellites.
- Score: 10.250105527148731
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Large-scale deployments of low Earth orbit (LEO) satellites collect massive
amount of Earth imageries and sensor data, which can empower machine learning
(ML) to address global challenges such as real-time disaster navigation and
mitigation. However, it is often infeasible to download all the high-resolution
images and train these ML models on the ground because of limited downlink
bandwidth, sparse connectivity, and regularization constraints on the imagery
resolution. To address these challenges, we leverage Federated Learning (FL),
where ground stations and satellites collaboratively train a global ML model
without sharing the captured images on the satellites. We show fundamental
challenges in applying existing FL algorithms among satellites and ground
stations, and we formulate an optimization problem which captures a unique
trade-off between staleness and idleness. We propose a novel FL framework,
named FedSpace, which dynamically schedules model aggregation based on the
deterministic and time-varying connectivity according to satellite orbits.
Extensive numerical evaluations based on real-world satellite images and
satellite networks show that FedSpace reduces the training time by 1.7 days
(38.6%) over the state-of-the-art FL algorithms.
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