Image resolution limit optimization for quantum imaging with undetected light

Quantum imaging with undetected light (QIUL) is a technique with great potential for imaging applications where extreme wavelengths are required to illuminate the object and, in particular, when low light intensities are crucial to not damage or modify the sample under study. This technique is based on the concept of induced coherence and makes use of spatial correlations. Therefore, either momentum or position correlations can be exploited by constructing a suitable system to access them. Depending on the selected configuration, image resolution is differently governed by the parameters of the quantum imaging source, e.g. crystal length, pump waist, and the down-converted wavelengths. Here, we present a tool to optimize the resolution limit of the imaging system given a specific application.