Introduction to the Auxiliary Modulation Coordinate: A Reduction to Quantum Mechanics

Our auxiliary modulation coordinate framework builds upon established quantum field theory principles developed by Weinberg [1] and Peskin Schroeder [2]. Weinberg’s comprehensive treatment of field theory provides essential mathematical tools for handling field propagation across dimensions, which we extend by adding the modulation dimension ε. While Weinberg focuses on standard spacetime, our approach introduces a third dynamic axis (modulation), but utilizes similar differential equation structures.The algebraic methods from Peskin Schroeder’s work—particularly their treatment of field oscillators and propagators—provide technical foundations that we adapt to handle modulation propagation. The deterministic underpinnings of our approach connect to Bohm’s hidden variables theory [3], though with crucial differences. Where Bohm introduces a separate “pilot wave” to guide particles, our theory identifies modulation itself as the guiding principle, with no separate hidden variables needed. Similarly, while ’t Hooft’s cellular automaton interpretation [4] shares our deterministic goals, his discrete computational model contrasts with our continuous field-based approach. Both theories aim to restore determinism to quantum mechanics, but through fundamentally different mechanisms.Carroll’s recent work [5] on how classical reality emerges from quantum fields provides a valuable contemporary perspective that parallels our own. Carroll argues that quantum field theory underlies everyday reality, but focuses primarily on decoherence as the emergence mechanism. In contrast, our theory identifies modulation coherence as the key organizing principle, offering a more fundamental explanation for emergence that could potentially address limitations in Carroll’s decoherence-based approach.