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EbookBell Team
4.4
62 reviewsThis book is about several questions regarding how to describe the quantization of the current density in an antenna and about the nature of the quantum electromagnetic field produced by such a quantum current
density. The second quantized current density can be built out of the Dirac field of electrons and positrons while the free electromagnetic or photon field is built out of solutions to the wave equation with
coefficients being operators, namely the creation and annihilation operators of the photons.
Table of Contents:
1. Basic quantum electrodynamics required for the analysis of quantum antennas
2. Effects of the gravitational field on a quantum antenna and some basic non-Abelian gauge theory
3. Conducting fluids as quantum antennas
4. Quantum robots in motion carrying Dirac current as quantum antennas
5. Design of quantum gates using electrons, positrons and photons, quantum information theory and quantum stochastic filtering
6. Pattern classification for image fields in motion using Lorentz group representations
7. Optimization problems in classical and quantum stochastics and information with antenna design applications
8. Quantum waveguides and cavity resonators
9. Classical and quantum filtering and control based on Hudson-Parthasarathy calculus, and filter design methods
10. Gravity interacting with waveguide quantum fields with filtering and control
11. Basic triangle geometry required for understanding Riemannian geometry in Einstein’s theory of gravity
12. Design of gates using Abelian and non-Abelian gauge quantum field theories with performance analysis using the Hudson-Parthasarathy quantum stochastic calculus
13. Quantum gravity with photon interactions, cavity resonators with inhomogeneities, classical and quantum optimal control of fields
14. Quantization of cavity fields
15. Classical and quantum drone design
16. Current in a quantum antenna
17. Photons in a gravitational field with gate design applications and image processing in electromagnetics
18. Quantum fluid antennas interacting with media
