Performing data-intensive analytics is an essential part of modern Earth science. As such, research in atmospheric physics and meteorology frequently requires the processing of very large observational and/or modeled datasets. Typically, these datase
ts (a) have high dimensionality, i.e. contain various measurements per spatiotemporal point, (b) are extremely large, containing observations over a long time period. Additionally, (c) the analytical tasks being performed on these datasets are structurally complex. Over the years, the binary format NetCDF has been established as a de-facto standard in distributing and exchanging such multi-dimensional datasets in the Earth science community -- along with tools and APIs to visualize, process, and generate them. Unfortunately, these access methods typically lack either (1) an easy-to-use but rich query interface or (2) an automatic optimization pipeline tailored towards the specialities of these datasets. As such, researchers from the field of Earth sciences (which are typically not computer scientists) unnecessarily struggle in efficiently working with these datasets on a daily basis. Consequently, in this work, we aim at resolving the aforementioned issues. Instead of proposing yet another specialized tool and interface to work with atmospheric datasets, we integrate sophisticated NetCDF processing capabilities into the established SparkSQL dataflow engine -- resulting in our system Northlight. In contrast to comparable systems, Northlight introduces a set of fully automatic optimizations specifically tailored towards NetCDF processing. We experimentally show that Northlight scales gracefully with the selectivity of the analysis tasks and outperforms the comparable state-of-the-art pipeline by up to a factor of 6x.
