The study, based on the perception-action theory, examined the environmental (height), biological/organism (vision), and task constraints to the movement variability of repetitive stepping. Six healthy college-aged participants (mean age=21.2 years, SD=±0.74; mean height=169.3 cm, SD=±6.35; mean weight=59 kg, SD=±12.96) were asked to follow a 30-seconds auditory signal (90 steps/min) stepping on-and-off adjustable platform (F1010W Original Club Step) with 2 different heights, i.e. 30 cm and 10 cm for high and low stepping conditions, respectively. The effect of visual feedback (eyes open and closed) was also tested in both high and low stepping conditions. Three-dimensional dynamic controls of the head, trunk, shoulder, elbow, wrist, ilium, knee, and ankle joints were measured kinematically via a Motion Analysis System, which is consisted of 8 Falcon Analog Cameras. It was found that the high stepping led to a mediolateral increase in the head and trunk swing. The second finding was that it showed more elbow and wrist swings in the anterior-posterior dimension when the eyes were closed. Furthermore, with either the eyes were open or closed the elbows and wrists represented asymmetrical movement trajectories (anterior-posterior swings). It suggested that the asymmetries of the upper extremities seemed to function for the compensation of the symmetries and balance of the lower extremities in the repetitive stepping task. The analysis of the autocorrelation function (ACF) revealed that visual information plays a significant role in coordinating the repetitive stepping movements.