Quantum tunneling is conventionally described as a probabilistic consequence of wave mechanics. While this description is mathematically precise, it often lacks a clear physical interpretation and is frequently presented as evidence of intrinsic randomness or non-classical behavior. This paper proposes a system-level interpretation of quantum tunneling based on three physically grounded principles: system completeness, conservation of balance, and continuous feedback between interacting components. It is shown that tunneling arises naturally when a complete physical system redistributes localized imbalance under strict constraints, without violating causality or conservation laws. The proposed framework preserves all standard quantum-mechanical predictions while providing a more intuitive and physically transparent interpretation of tunneling phenomena.
Angelito Enriquez Malicse (Thu,) studied this question.