The derivation of the Heisenberg Uncertainty Principle (HU P) from the Uncertainty Theorem of Fourier Transform theory demonstrates that the H UP arises from the dependency of momentum on wave number that exists at the quantum level. It also establishes that the HUP is purely a relationship between the e ff ective widths of Fourier transform pairs of variables (i.e. conjugate variables). W e note that the HUP is not a quantum mechanical measurement principle per se . We introduce the Quantum Mechanical equivalent of the Nyquist-Shannon Sampling Theorem of Fourier Transform theory, and show that it is a better principle to describe the measurement limitations of Quantum Mechanics. We show that Brillouin zones in Solid State Physics are a manifes- tation of the Nyquist-Shannon Sampling Theorem at the quantum level. By comparison with other fields where Fourier Transform theory is used, we propose that we need to discern between measurement limitations and inherent limitations when interpreting the impact of the HUP on the nature of the quantum level. We further propose that while measurement limitations result in our perception of indeterminism at the quantum level, there is no evidence that there are any inherent limitations at the quantum level, based on the Nyquist-Shannon Sampling Theorem.
Sunday, March 23, 2014
Almost! Anyway, I not the only believer
Millette from Canada! Welcome to phase theory and Pauli sampling.
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