Perception As Geometric Collapse

This paper proposes a geometric resolution model for perception and quantum measurement, reframing the classical double-slit experiment as a dimensional mismatch between wavefront continuity and spatial observation. By modeling visual perception as a collapse of curvature onto a flattened detection surface—mirroring how the retina linearizes incoming light—the work bridges cognitive processes with quantum field behavior. It argues that quantum uncertainty arises not from intrinsic randomness, but from geometric tension during projection collapse across dimensional boundaries. The model further explores how modifying slit geometry or detection surfaces could empirically validate this theory, offering a new lens for interpreting consciousness, measurement, and physical field continuity.