Sub-Quantum Physics 4: Oscillator Ground State from Aether Stochastic White Noise

Abstract

A standard treatment of the motion of the classical simple harmonic oscillator driven by a ?kinetic gas?-type white noise stochastic process is shown to have direct relevance to the quantum oscillator ground state. When the driving excitation involves normally distributed impulses, the position probability density of the oscillator is normal, just as for the quantum oscillator ground state. For both the classical oscillator and the quantum oscillator ground state, the position probability density function has the functional form exp[-V(y)/E₀]. In each case the argument numerator function V(y) is Ky²/2 , where is the position variable (the distance from the neutral point) and K is the force constant. The argument denominator for the classical oscillator is E₀ = kT where k is Boltzmann?s constant and T is the absolute temperature. The denominator for the quantum oscillator ground state is just the quantum zero-point energy E₀ = hv/2 where h is Planck?s constant and v is the oscillator natural frequency. The resemblance between the densities for the stochasitcally-driven classical oscillator and the quantum oscillator ground state lends support to the author?s previous assertion that the quantum oscillator can be seen as an essentially classical object driven by stochastic bombardment from an underlying aether. The article presents the stochastic methodology.