HyperDrive: Scheduling Serverless Functions in the Edge-Cloud-Space 3D Continuum

TL;DR

HyperDrive is a novel SLO-aware scheduler for serverless functions in the 3D continuum, optimizing placement across Cloud, Edge, and space nodes to meet stringent latency and resource constraints in satellite-based scenarios.

Contribution

It introduces HyperDrive, the first scheduler tailored for the 3D continuum, addressing unique challenges of satellite mobility, heat dissipation, and energy constraints.

Findings

Achieves 71% lower network latency compared to baselines.

Successfully supports wildfire disaster response with high data processing needs.

Demonstrates effective function placement in a complex space-Earth environment.

Abstract

The number of Low Earth Orbit~(LEO) satellites has grown enormously in the past years. Their abundance and low orbits allow for low latency communication with a satellite almost anywhere on Earth, and high-speed inter-satellite laser links~(ISLs) enable a quick exchange of large amounts of data among satellites. As the computational capabilities of LEO satellites grow, they are becoming eligible as general-purpose compute nodes. In the 3D continuum, which combines Cloud and Edge nodes on Earth and satellites in space into a seamless computing fabric, workloads can be executed on any of the aforementioned compute nodes, depending on where it is most beneficial. However, scheduling on LEO satellites moving at approx. 27,000 km/h requires picking the satellite with the lowest latency to all data sources (ground and, possibly, earth observation satellites). Dissipating heat from onboard hardware is challenging when facing the sun and workloads must not drain the satellite's batteries. These factors make meeting SLOs more challenging than in the Edge-Cloud continuum, i.e., on Earth alone. We present HyperDrive, an SLO-aware scheduler for serverless functions specifically designed for the 3D continuum. It places functions on Cloud, Edge, or Space compute nodes, based on their availability and ability to meet the SLO requirements of the workflow. We evaluate HyperDrive using a wildfire disaster response use case with high Earth Observation data processing requirements and stringent SLOs, showing that it enables the design and execution of such next-generation 3D scenarios with 71% lower network latency than the best baseline scheduler.