In nuclear astrophysics experiments using heavy ion accelerators, unstable secondary ions are produced and detected with implantation detectors. To validate the position of these implantations, we developed an auxiliary detector that permits ions to pass through and can be positioned in front of the main detector. This auxiliary detector is constructed with a thin, 20 x 20 cm plastic scintillator, which determines the positions of ion hits by measuring scintillation light at various points using silicon photomultipliers. As part of the thesis, we designed the mechanical structure of the detector along with the associated printed circuit boards for measuring light signals, as well as a separate circuit board for processing these signals and communicating with the user. We developed firmware for the detector, along with user software for the computer, which includes a graphical interface. We developed a physical model to describe the response of individual silicon photomultipliers at various points of ion hits and calibrated it using short flashes from a light-emitting diode (LED). We evaluated the model, determined the measurement uncertainties, and assessed the positional accuracy. The detector proved sufficiently accurate for validating ion hit positions and meets the experiment’s timing requirements. To reduce uncertainty, the configuration should be adjusted to enhance light capture.