Two-time interpretation of quantum mechanics

TL;DR

The paper proposes a two-time, time-symmetric interpretation of quantum mechanics that introduces a final boundary condition for the universe, resolving the measurement problem while maintaining standard quantum predictions.

Contribution

It introduces a novel two-time interpretation with a final boundary condition, providing a deterministic and local solution to the measurement problem without deviating from standard quantum mechanics.

Findings

Single measurement outcomes are determined by a final boundary condition.

Quantum superpositions are dynamically reduced via two-time decoherence.

The interpretation explains weak measurement phenomena with the two-time formalism.

Abstract

We suggest an interpretation of quantum mechanics, inspired by the ideas of Aharonov et al. of a time-symmetric description of quantum theory. We show that a special final boundary condition for the Universe, may be consistently defined as to determine single classical-like measurement outcomes, thus solving the "measurement problem". No other deviation is made from standard quantum mechanics, and the resulting theory is deterministic (in a two-time sense) and local. Quantum mechanical probabilities are recovered in general, but are eliminated from the description of any single measurement. We call this the Two-time interpretation of quantum mechanics. We analyze ideal measurements, showing how the quantum superposition is, in effect, dynamically reduced to a single classical state via a "two-time decoherence" process. We discuss some philosophical aspects of the suggested interpretation. We also discuss weak measurements using the two-time formalism, and remark that in these measurement situations, special final boundary conditions for the Universe, might explain some unaccounted for phenomena.