Fourier Transform, Dirac Commutator, Energy Conservation, and Correspondence Principle for Electrical Engineers

The canonical commutation relation is a fundamental postulate of the quantum theory regarding the operators needed in quantum description of physical observables. It is shown that the Fourier transform is derivable from this seemingly simple postulate along with the basic properties of the position...

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Published inIEEE journal on multiscale and multiphysics computational techniques Vol. 7; pp. 69 - 83
Main Authors Ryu, Christopher J., Kudeki, Erhan, Na, Dong-Yeop, Roth, Thomas E., Chew, Weng C.
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
classical limit
coherent state
Commutation
Commutator
Commutators
correspondence principle
Electronic mail
Finite difference time domain method
fourier transform
Fourier transforms
Hilbert space
Homomorphisms
Maxwell equations
mode transform
Nonhomogeneous media
Operators (mathematics)
Plancks constant
Quantization (signal)
Quantum mechanics
Quantum theory
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Summary:The canonical commutation relation is a fundamental postulate of the quantum theory regarding the operators needed in quantum description of physical observables. It is shown that the Fourier transform is derivable from this seemingly simple postulate along with the basic properties of the position and momentum operators. Further discussions on the canonical commutation relation reveal its connection to a more fundamental notion that energy must be conserved. This discussion also unveils the mathematical homomorphism between the classical and quantum theories for systems represented by sum separable Hamiltonians. Another link between the classical and quantum theories is established by the correspondence principle which states that the classical theory emerges from quantum theory in the limit of vanishingly small Planck constant. Finally, the quantum Maxwell's equations, which have been derived in our previous works, are presented and briefly discussed, and the 3-D mode transform is derived that can be interpreted as a generalization of the Fourier transform. We present both the details and meanings of the 3-D mode transform which will serve as a foundation for a full 3-D quantum finite-difference time-domain method.
ISSN:2379-8815
2379-8793
2379-8815
DOI:10.1109/JMMCT.2022.3148215