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Most recent edit on 2008-08-29 22:24:36 by CharlesFrancis
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With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics.
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With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Edited on 2008-08-29 22:08:16 by CharlesFrancis
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Edited on 2008-08-13 03:46:29 by CharlesFrancis
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← Quantum Electrodynamics ↑ →
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← Quantum Electrodynamics →
Edited on 2008-05-26 10:25:28 by CharlesFrancis
Additions:
With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Regularisation and Renormalisation
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With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to established science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Edited on 2008-03-11 11:05:22 by CharlesFrancis
Additions:
With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to established science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Deletions:
With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to established science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Edited on 2008-03-11 11:04:03 by CharlesFrancis
Additions:
With the exception of special relativity, Quantum electrodynamics» is the most empirically accurate» theory known to established science, but it is fraught with mathematical difficulties and divergence problems. I follow a straightforward approach, based heavily on the Dirac-Von Neumann interpretation. The focus is on showing that the general considerations of relativity and quantum mechanics lead to both quantum and classical electrodynamics. I believe that this approach gives a much truer view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Classical Electromagnetism
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Quantum electrodynamics is perhaps the most empirically accurate theory known to established science, but it is fraught with mathematical difficulties and divergence problems. The approach here is based heavily on the Dirac-Von Neumann interpretation and focusses on showing that the general considerations of relativy and quantum mechanics lead to quantum and classical electrodynamics. This approach gives a simpler view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
Classical Electromagnetism - under construction
Edited on 2008-03-11 10:28:34 by CharlesFrancis
No differences.
Oldest known version of this page was edited on 2008-03-11 10:28:02 by CharlesFrancis []
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← Quantum Electrodynamics →
Quantum electrodynamics is perhaps the most empirically accurate theory known to established science, but it is fraught with mathematical difficulties and divergence problems. The approach here is based heavily on the Dirac-Von Neumann interpretation and focusses on showing that the general considerations of relativy and quantum mechanics lead to quantum and classical electrodynamics. This approach gives a simpler view of underlying physics than is generally presented from quantum field theory. The resulting calculations and predictions using Feynman rules are, of course, the same. Attention will be drawn to mathematical issues raised by the approach. These will be addressed in Relational Quantum Gravity.
← Relativistic Quantum Theory Relational Quantum Gravity →
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