Martin Harwit’s article “The Growth of Astrophysical Understanding” (Physics Today, Physics Today 0031-9228 5611200338 https://doi.org/10.1063/1.1634532November 2003, page 38 ) was enjoyable and insightful. The author names three frontiers in observation: angular resolution, timing, and spectrometry. I propose a fourth: expanding data volumes. This frontier has progressed steadily, from paper-and-pencil catalogs, to photographic plates, to large-format CCDs and robotic survey telescopes.

Each advancement brings new discoveries. Some examples: Tycho Brahe’s measurements of the planets were precise, but also voluminous; he had 85 data points on Mercury’s orbit, for example—a great advancement on the state of the art. The volume, as much as the precision, made Johannes Kepler’s analyses possible. John Goodricke discovered one variable star in 1784, but Henrietta Leavitt, working with thousands of stars on photographic plates, discovered the Cepheid period-luminosity relation. Today, in one of many superb examples, a huge observing project called the Sloan Digital Sky Survey is making precision measurements of large-scale structures. The project’s resolution and spectroscopy are up to date, but its multiterabyte data set is really new and exciting.

Bigger and bigger surveys are absolutely necessary for advancing our knowledge of astrophysics. They provide the opportunity to discover extremely rare phenomena and to find surprising statistical properties of known ones.