We report on the successful development and implementation of acoustic dipole localization and tracking algorithms for millimeter-scale flow sensors arranged in an artificial lateral line configuration. Our previous work includes the development of an artificial lateral line system a novel, bioinspired flow sensing array. The artificial lateral line aims to mimic the lateral line sensory organ of many species of fish, an organ that allows the fish to perform near-field hydrodynamic imaging to navigate, capture prey, or align to a flow stream. Many of the stimuli that these fish sense can be modeled as near-field dipoles with widely understood acoustic signatures. In our previous work, we successfully developed an artificial lateral line using micro-flowsensors for applications such as dipole localization, wake tracking, and flow imaging. However, while the applications and the platform were both novel, potential uses were limited due to the size of the microsensors (and correspondingly the sensor arrays) as well as the limited distribution of the technology. In this paper, we show for the first time that a commercially available array can also be successfully used as an artificial lateral line for observing the above-mentioned phenomena, thereby enabling a new biomimetic millimeter-scale flow-sensing platform.