The creation and operation of a cost-effective sunlight tracking mechanism, ranging beyond a conventional motorised sole axis to an electronic composite double direction, are discussed in this investigation. Electromechanical components were created using various computational techniques and approaches to improve their sunlight monitoring process. In order to demonstrate the gadget, a combination of a dual-axis photovoltaic navigation system that utilises the two-dimensional photovoltaic mapping and an ongoing monitoring method depending on luminescence sensors is devised, constructed, and evaluated. In order to aid in everyday monitoring, these detectors of light additionally consider night-time, overcast, and sunshine circumstances. The intended sensor can keep tabs on the sunlight's projected location across different periods and climates; In order to direct the surveillance system in looking for the sunlight orientation for the changing seasons movement, the electricity regulating gadget needs an accurate clock mechanism. Therefore, the intended sensor became a mixed one when each these two sensors were combined. When matched to a stationary and ongoing double pole solar navigation system, the energy gains and battery life are examined. The electrical efficiency of an integrated double axes solar positioning technique is approximately equivalent to the benefit of an ongoing double axes photovoltaic monitoring system, yet the combination monitor uses 44.44% fewer kW during operating than the continuous monitoring device.