Such time-wise and space-wise oscillations of a free and unhindered travelling electron with no hidden variables, can explain the particle wave, the uncertainty principle, dark matter and entanglement, and can reconcile the definite motion of subatomic and macroscopic objects. The electron evades detection while it moves periodically beyond coincidence with the detector’s coordinates, yet adhering periodically to the relativistic constant velocity motion of macroscopic objects. The paper demonstrates mathematical feasibility of such motion and suggests experiments to test the validity. This very simple specific case shows how classical treatment as a mass in motion can accommodate both the wave nature of matter and detection uncertainty. Maybe classical mechanics failed to explain these features because the time-wise and space-wise oscillations in these simple illustrative examples were not considered. Experiments could determine the truth. According to existing models, this oscillating electron would be both electron and positron (matter and antimatter). This paper is extended at. This paper is extended by a special case of these oscillations that allows the motion to continue without loss of electromagnetic energy and provides definite amplitudes based on the kinetic energy. View at Towards explaining particle-wave duality in sensory terms.
