Introduction: Eye detection is critical in a variety of applications, ranging from facial recognition in human-computer interfaces to the analysis of human behavior and disease diagnosis. Scientific literature highlights the eyes as the most significant feature of the face, prompting extensive research in eye detection. Given the iris region's circular nature, the Hough Transform for Circles (HTC) emerges as a promising technique for identifying eyes. Utilizing the parametric equation of a circle, the HTC facilitates eye location through the template matching method. Moreover, HTC offers a non-invasive alternative to active approaches such as infrared eye detection and can reconstruct image shapes even with information loss due to digital processing. This study aims to apply HTC for detecting eyes on human faces.

Methods: Digital processing was conducted on 30 resized images (200x233) sourced from a public database. During the detection stage, code was implemented to derive the Hough space and recognize circles. An eye pair detector was then developed using the coordinates of the centers and radii of the circles identified by the Hough Transform. Finally, pairs of eyes were detected on various male and female faces.

Results and Discussion: Experiments on diverse faces revealed that applying HTC alone was insufficient for accurate eye identification, as circles other than the eyes were frequently detected. This led to the hypothesis that accurate identification could be achieved by focusing solely on the eye region, leveraging the symmetry of the face. This hypothesis was confirmed, demonstrating that the region corresponding to the eyes could be accurately identified by analyzing facial symmetry.

Conclusions: The findings indicate that it is feasible to non-invasively detect the eye region on human faces using the Hough Circles Transform. By incorporating the analysis of facial symmetry, specifically the interocular distance, HTC can reliably identify the eye region.