Quantum mechanics has been remarkably successful in predicting experimental outcomes, yet foundational questions—such as the nature of wave function collapse and the mechanism of quantum entanglement—remain unresolved. Standard interpretations invoke observer-dependence, intrinsic randomness, or non-local interactions, leading to conceptual difficulties. This work proposes a unifying explanation based on a universal balance-based system framework. Within this approach, quantum systems are treated as interconnected, defect-free systems whose behavior emerges through feedback mechanisms. Wave function collapse corresponds to the enforcement of systemic balance under new constraints, while entanglement arises from globally enforced balance across spatially separated nodes. This framework preserves empirical predictions of quantum mechanics, is consistent with relativistic causality, and provides a coherent conceptual foundation that links microscopic quantum phenomena to universal system dynamics.
Angelito Enriquez Malicse (Thu,) studied this question.