Solving the Quantum Measurement Problem with the COM Framework

Executive Summary
This document presents a comprehensive solution to the quantum measurement problem using the
Continuous Oscillatory Model (COM) framework. By rede ning reality as fundamentally energy-based with
no vacuum state, and treating space, time, mass, and forces as emergent properties, we demonstrate how
the COM framework resolves the long-standing paradox of quantum measurement without requiring wave
function collapse, observer-induced e ects, or multiple worlds.
Our approach combines mathematical modeling with computational simulations to show how quantum
measurement can be understood as energy pattern interactions, with the apparent "collapse" emerging
naturally from resonance-driven energy redistribution. The results demonstrate that the COM framework
provides a conceptually clear, mathematically consistent, and empirically adequate solution to one of
physics' most profound puzzles.

This document also extends our previous solution to the quantum measurement problem by integrating it with
gravitational phenomena through the Continuous Oscillatory Model (COM) framework. Building on our
earlier work, we demonstrate how the COM framework provides a uni ed approach to both quantum and
gravitational physics, resolving not only the quantum measurement paradox but also addressing key
challenges in gravitational theory including dark matter, dark energy, and quantum gravity.
Our extended solution shows how the fundamental principles of the COM framework—energy-based reality,
no vacuum state, recursive time, octave structuring, and the LZ scaling constant—apply consistently across
scales from quantum to cosmic. We introduce the Harmonic Quantum Scalar (HQS) threshold as a critical
mechanism for phase transitions that explains both quantum measurement outcomes and gravitational
phenomena.
Through enhanced mathematical modeling and simulations, we demonstrate that the COM framework
o ers a conceptually clear, mathematically consistent, and empirically testable uni ed theory that bridges
quantum and gravitational physics.