A Cohesive Deep Drilling Field Strategy for LSST Cosmology

TL;DR

This paper proposes a cohesive strategy for deep drilling fields in LSST to optimize cosmological measurements, emphasizing the importance of survey design and simulation to meet scientific goals.

Contribution

It introduces a method to estimate observing strategy parameters and demonstrates promising survey configurations through simulations for LSST deep drilling fields.

Findings

Deep rolling surveys with high cadence are most effective.

A DDF budget of ~8.5% is optimal for meeting all cosmological requirements.

Lower budgets compromise photo-z, weak lensing, and supernova constraints.

Abstract

The Vera C. Rubin Observatory Legacy Survey of Space and Time (LSST) will image billions of astronomical objects in the wide-fast-deep primary survey and in a set of minisurveys including intensive observations of a group of deep drilling fields (DDFs). The DDFs are a critical piece of three key aspects of the LSST Dark Energy Science Collaboration (DESC) cosmological measurements: they provide a required calibration for photometric redshifts and weak gravitational lensing measurements and they directly contribute to cosmological constraints from the most distant type Ia supernovae. We present a set of cohesive DDF strategies fulfilling science requirements relevant to DESC and following the guidelines of the Survey Cadence Optimization Committee. We propose a method to estimate the observing strategy parameters and we perform simulations of the corresponding surveys. We define a set of metrics for each of the science case to assess the performance of the proposed observing strategies. We show that the most promising results are achieved with deep rolling surveys characterized by two sets of fields: ultradeep fields (z<1.1) observed at a high cadence with a large number of visits over a limited number of seasons; deep fields (z<0.7), observed with a cadence of ~3 nights for ten years. These encouraging results should be confirmed with realistic simulations using the LSST scheduler. A DDF budget of ~8.5% is required to design observing strategies satisfying all the cosmological requirements. A lower DDF budget lead to surveys that either do not fulfill photo-z/WL requirements or are not optimal for SNe Ia cosmology.