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Atom Imaging     Quantum Physics     Quantum Electronics     Quantum Magnetodynamics     Quantum Symmetry      
                                 
 Quantum Nanoelectronics 
 for 3D EM Full-wave
 Microchip Design Software
 ___________
 
          Electron Quantum Mechanics  
       Explained in CRQT Topofuncs
| MAVCAM-type Electron Topology     |                       Femtoscale Images                                      _______    | Nanoyoctoscale RQT Electron Closeup    | 
 
                                                                        
            Old electrical engineering           
  analyzes circuits and components
  in terms of standard, classical
  Newtonian, and Maxwellian models.
  That proceeds by curve fitting which
  estimates the detailed topologies of
_______________________________     electrons flowing through materials.         |                       Positron Topology             |
                                                        While approximation of the               ____________________________________
      electricity in power generation, transmission, communication, or microcircuits
      by electrical simulation software has advanced to the nanotechnical level, the present popularly applied models lack
      clear defintions for the electron itself or the electromagnetic fields and waves.  In order to redesign the system for safety and
      efficiency, developing the CAD software for a femtoscale circuit simulator in terms of relative quantum electromagnetic
      physics, CRQT physics was designed as a completely new mathematical model for 3D EM full-wave electrical simulation
      software.
                 
               Exact picoyoctoscale modeling of electrical current as individual 3D
      electrons with their magnetic fields is achieved by the grand unified GT
      integral atomic function.  The topologies of that electromagnetic energy
      flow may now be studied for any material in terms of it's electric and 
      magnetic field energy textures and densities, while displaying the pymscale
      details of each energy or force particle's structure, location, velocity, and  
      interactive quantum mechanics.  The immense complexity of that task will
      be achieved by computer programs that are bulkier, slower, and
      operated in an interactive decision making mode for selection of data
      summation options.  The results will have permanent, cumulative value that
      leads gradually to the completion of the intended comprehensive material
      data file archival system named SYMAVIA, Synthetic Molecular or Material
      Animated Video Interactive Archives. 
                                                                                                                          
               
               MAVCAM images of the electron, shown as pen and ink models                |      Ultrascale MAVCAM Mockup Model    
     above, have data point definitions by the electron topological wavefunction,       |          of an Electromagneton Emitting      |
      or simply the GT electron topofunc.  This format of electron modeling                   |_____________________________________|
      maps any volume of material to display the selected electron's state for an 
      instant t1, including cross-section closeups of internal pymscale details.  It's companion magnetic field is data imaged in the
      context of it's true pulsation mode.  A wider scene of electromagnetic energy and force fields emerges by zooming out, revealing
      how the moving electron will meet and interact with challenges to it's inertial flow.                                                 
       __________________________________________________ 
 
         The Relative Quantum Electronics Viewpoint of MAVCAM    
      
          A whole new perspective for analysis of electrical currents emerges.  Now the new CRQT model dimensions open a wide   
      vista of magnetic and electrical particles associated by force in arrays simulated for each possible variable by atomic
      topological function mapping.  This mode is electromagnetic particle visualization of circuitry driven by the unassisted relativistic
      quantum mechanics of particle dynamics.  Each particle of the four force fields is displayed with it's force interrelationships to the
      other forcons, energy particles, and electrons.  That scene of electronic modeling is a complete mechanism of quark-string
      structures in which the grand unified quantum physics equations' dynamics move the virtual electrons while displaying the
      exact Planck scale topologies of their magnetic fields.   The result is a deterministic MAVCAM electromagnetic wave physics
      system free of estimation or noise. 
 
          The visual aids above show how each regular electron holds an array of energetic negative charge particles named
      minons in it's outer diffuse region.  Their relativistic quantum mechanics, powered by superworkons, animate the minons to
      deliver concentrated negative charge forcon particles that interact with the more rigid magnetic matrix of force-linked magnetons,
      magnons, fabrixons, and magnixals.  MAVCAM is a magnetic field modeling software build system, and has produced the images
      of a varied spectrum of the magnetic energy particles,  explaining quantum magnetodynamics in terms of workon relativity.  The
      driving force transfer model clearly illustrates how magnetic attractive force pulls or repels susceptible objects, allowing verification
      of magnetic action by electron spin quantum mechanics functions and the list of magnetic field equations.  CRQT physics analysis
      of this sort develops the image of the magnetic flux variable B as the frequency of a particle, defining magnetism in 
      comprehensive, relativistic terms.  CRQT-MAVCAM is, in fact, a complete system of electrodynamics driven by Einstein-Lorenz
      relativity.
 
               Within and around the virtual electron's minosphere the positrons hover to add essential fluidity to the electron's pulsations of
 redistributive structural symmetry work.  That conservation of the momentum of a current electron's
 whole symmetric topological particle state proceeds by relativistic quantum functions, which also build
 a spectrum of waveparticles named electromagnetons.  They collect an atom's surplus force or energy 
 due to it's constant work, focusing and blending forcons to achieve construction of new electromagnetic 
 output photons.  The Stefan-Boltzmann thermal photon output rule, at left, projects an exact pymscale 
 video sequence of single electromagnetic photon emission events when viewed through the lens of
      MAVCAM.  The electromagneton pictured above gives an idea of how pymscale architectural features process stress by 
      delivering it to a succession of workons capable of proportioning the photon output event's spin states and triggering probability
      threshold.
 
              Now that an electromagnetic energy video system has revealed how positrons work in IC chips the dynamic, flowing chain 
      of quantized relativistic time, mass, and energy events driving electron motion and work may be modeled with complete
      accounting for that mechanism's concerted thermic force and energy catalysis.  Electrons are portrayed as waveparticles that
      may be referred to as wavectrons, holding both particle and wave characteristics.  The exact animated, interactive Planck scale 
      electromagnethermal MAVCAM microchip energy and force field video simulation invention is a reality.     
                    
  |________| .||. |______|| O ||......|....|..||.||| 
 
 
 Clough Essays in Quantum Mechanics                      Grand Unified Particle Physics Previews                       The Crystalon Door - The Grand Unified Theory
 
(C) 2010, Symmcon Grand Unified Theory Marketing Corp.
 

 

      Reductive Mathematical Processing of

     Electromagnetic Equations for Exact

     Transistorized IC Modeling at Ultrascales

 

            One way to think of the new physics system is to

       idealize the infinitesimal Planck scale of particles, fields,

       and waves within atoms.  Those objects pulsate, move,

       and react due to their radiation and absorption of forcons

       as defined by the Einstein-Lorenz transformation functions.

       They interact by the radiation of mass as they lose velocity,

       due to Lorenzian transform of mass to forcons with joule

       values.  Conversely, they absorb forcons while they

       gain velocity. 

 

               New physics applies Lorenz time and mass transform

       functions to calculate exact modes of electromagnetic 

       waveparticle existence.  They have been reduced to

       ultimate topologies by exhaustive mathematical separation,

       simplification, rearrangement, expansion, and boundary

       valuation of the E.L. functions.  Those processes reveal a

       wide series of modeling innovations when the remixed 

       relative quantum equations are given dynamics by solving 

       derivatives and integrals. 

 

               The Crystalon Door gives explanation of relativistic 

       quantum topological mechanics in terms of those 

       mathematical steps, the CRQT function network, built solely

       of standard algebra and calculus operations.  It does not

       allow any negative root, matrix operation, approximation,

       disconnected process, curve fitting spline,or unexplained 

       feature.  

 

               Since the GT integral atomic topofunc defines the point

       map of a pulsating atom, it provides an exact, complete

       resource for nearly all issues of material, energy, or force.

       One vital feature of this new physics format is the RQT

       imaging of electrons and electromagnetic waves.  The

       topological waveparticle function of the electron was solved,

       and the electromagnetic wave photon's.  Precise quantum

       electrodynamics was resolved at the Planck scale.

 

               While the earlier visualizations of electrons and their

       physics of motion and work seems like a vague, speculative

       venture of many different nanomodels based on the idea of

       a wavenode, those may be easily translated from their

       present levels of development to an electromagnetic energy

       and force model made up entirely of specific particles with 

       highly defined topologies, quantum states and relativistic

       interactions.  This picoyoctoscale virtualization includes

       supersymmetry as an omnipresent parameter of both

       waveparticle topology and interaction.  MAVCAM operates

       by a complete electromagnetic wave physics model of

       relative quantum topological functions.

 

 

 |_____|___|_| -e ||||  

 (C) 2010, Symmecon Grand Unified Theory Marketing Corp. 

 

      Quantum Electrodynamics for Beginners

     Relativistic Electronic Particle Physics Explained

 

           Looking at electronic schematics with the standard

      set of continuous functions for electricity flow and circuit

      component parameters gives a view shaped by basic

      measurements for standard operating conditions.

      Microcircuits, transistors, and other more modern electrical

      devices based on quantum effects by application of more

      highly detailed designs and new, quantized component

      materials have strained the old standard system of electrical

      circuit analysis and design.

 

              That inadequacy of approximative nanoscale physics

      in addressing 21st century challenges is being superceded

      now by CRQT, which went back to the beginnings of physics

      to build the grand unified atomic model as the basis for all

      science and engineering.  That project, Nabla Cubed,

      reasoned that only the composition of the valid atomic 

      topological function by unification of Einsteinian-Lorenzian 

      relativity with quantum physcics, with definition of the force

      and energy relationships of electromagnetism with gravity, 

      could build the ultimate mathematical quantum function 

      network defining electrons and their interactions.

 

             When the first GT atomic function research produced 

      the early 3D, animated, interactive, picoyoctoscale images

      of pulsating atoms the electron's model emerged as the

      Symmecon MAVCAM pen and ink mockups above and

      below display.  Now CRQT physics understands the electron

      as a standing overtone wavenode of the nucleus that has

      crystallized to a state of semimatter.  The video format allows

      observers to study electrons as waveparticles that perform

      work to conserve momentum, a set of electrocore force

      processes driven by well defined interactions of heat,

      magnetism, positrons, workons, negative charge, timefield,

      probability, and space.

 

          

  (C) 2010, Symmecon Grand Unified Theory Marketing Corp.