Single-photon avalanche diodes (SPADs) have emerged as the primary solid-state photodetectors for use in time-resolved imaging and very low light optical detection for their high sensitivity, fast impulse response, and CMOS process compatibility. For each application, diode structure and size must be optimized empirically, where device performance is difficult to predict theoretically. To assist in this iterative design process, this paper presents side-by-side characterization of multiple SPAD structures implemented using different p-n junctions in a single, deep sub-micron CMOS process. Detailed characterization of the sensors enables comparative analysis of important performance parameters, such as dark count rate and spectral response, across multiple p-n junction types, device structures, and SPAD size variants. A new approach for experimental analysis of after-pulsing is also presented. The characterized SPAD test array comprises multiple size and structural variants implemented in a general purpose 180nm CMOS process.