Think Locally, Act Globally: Federated Learning with Local and Global Representations
This work addresses privacy and efficiency issues for federated learning in distributed settings, offering incremental improvements over existing methods.
The paper tackles the scalability and privacy challenges in federated learning by proposing an algorithm that learns compact local representations on devices and a global model across them, reducing communicated parameters while retaining performance, as shown in experiments on personalized mood prediction with real-world mobile data.
Federated learning is a method of training models on private data distributed over multiple devices. To keep device data private, the global model is trained by only communicating parameters and updates which poses scalability challenges for large models. To this end, we propose a new federated learning algorithm that jointly learns compact local representations on each device and a global model across all devices. As a result, the global model can be smaller since it only operates on local representations, reducing the number of communicated parameters. Theoretically, we provide a generalization analysis which shows that a combination of local and global models reduces both variance in the data as well as variance across device distributions. Empirically, we demonstrate that local models enable communication-efficient training while retaining performance. We also evaluate on the task of personalized mood prediction from real-world mobile data where privacy is key. Finally, local models handle heterogeneous data from new devices, and learn fair representations that obfuscate protected attributes such as race, age, and gender.