Robust Over-the-Air Computation with Type-Based Multiple Access
This work addresses security and efficiency challenges in wireless aggregation for applications like federated learning, offering a scalable solution for next-generation networks, though it appears incremental as it builds on existing TBMA concepts.
This paper tackles the problem of Byzantine attacks in over-the-air computation by proposing type-based multiple access (TBMA) as a robust alternative to classical direct aggregation, demonstrating through simulations that TBMA maintains high accuracy under adversarial conditions and reduces channel state information requirements and energy consumption.
This paper utilizes the properties of type-based multiple access (TBMA) to investigate its effectiveness as a robust approach for over-the-air computation (AirComp) in the presence of Byzantine attacks, this is, adversarial strategies where malicious nodes intentionally distort their transmissions to corrupt the aggregated result. Unlike classical direct aggregation (DA) AirComp, which aggregates data in the amplitude of the signals and are highly vulnerable to attacks, TBMA distributes data over multiple radio resources, enabling the receiver to construct a histogram representation of the transmitted data. This structure allows the integration of classical robust estimators and supports the computation of diverse functions beyond the arithmetic mean, which is not feasible with DA. Through extensive simulations, we demonstrate that robust TBMA significantly outperforms DA, maintaining high accuracy even under adversarial conditions, and showcases its applicability in federated learning (FEEL) scenarios. Additionally, TBMA reduces channel state information (CSI) requirements, lowers energy consumption, and enhances resiliency by leveraging the diversity of the transmitted data. These results establish TBMA as a scalable and robust solution for AirComp, paving the way for secure and efficient aggregation in next-generation networks.