Finite-Precision Quantum Mechanics

Standard quantum mechanics is an idealisation based on infinite-precision objects: point states, exact probabilities, and sharp measurements. Yet every real experiment has finite resolution, and for macroscopic systems we never have access to the microscopic state. Following Heisenberg's call for a theory built only on observable quantities, and von Neumann's insight that a complete description of a macroscopic system is neither possible nor necessary, we elevate the macroscopic state to a fundamental concept. We introduce Interval Quantum Mechanics (IQM), in which the state of a quantum system is never a point but a quantum parcel - a basic weak-star open set of density matrices defined by finitely many open expectation intervals. Such a parcel is the exact mathematical representation of the set of all microscopic states that are compatible with the measured values of a finite set of macroscopic observables. We show that unitary evolution lifts to a deterministic flow on parcels, and that a finite-precision (fuzzy) measurement process is represented by a volume-contracting update that refines the initial parcel into a more constrained open set, strictly increasing the geometric information defined as the Hilbert-Schmidt volume of the parcel. By introducing a second impossible set, we obtain a double-parcel whose information increases monotonically - resolving the von Neumann entropy paradox. The framework eliminates foundational puzzles without additional interpretational assumptions: wave-particle duality becomes a smooth trade-off; Schroedinger's cat is never in a literal superposition; and the spooky action at a distance of entanglement disappears, replaced by a purely epistemic geometric update. All empirical predictions of standard quantum mechanics are recovered exactly in the infinite-precision limit, which is never physically attained.