From: treon3verdery@gmail.com   
      
   When broadcating an image or video frame the BGR/kycm values could each be a   
   separate silhoutte that combine like halftone dots to make an image. The big   
   indium phosphide monopixel bucket could turn on and off at Thz speeds,   
   building the optical/Em    
   unconnected beam splitter pixel transistor matrix that is a picture at a 64 or   
   128 bit row/column length so every line of the ghost 2D image is a computer   
   instruction or a few assembly language instructions (this could read assembly   
   language in parallel    
   with indium phosphide 7.5 Thz time   
    resolution/clock speed)   
      
   Thoughts and technologies about petahz wifi that is a million or more times   
   faster than wifi 6E, also, the uses of wikipedia: Ghost Imaging at very   
   parallel, petahz frequency, supercommunicative computers. If 7.5 Thz or higher   
   indium phosphide Analog to    
   Digital converters are possible then it is possible to hardwire them as a   
   level of, at a ghost imaging employing computer either the photon/EM bucket or   
   the separate path Radiopixel/radio-ixel parts of a ghost imaging structure.   
   the gist is that a    
   multiparallel array of wifi/radio radio can be read instantly, as the array is   
   being the same as the fastest "single pixel"/one em wave bucket detector. So   
   if that detector's semiconductor technology can respond at 1000Thz (petahz and   
   higher) then plural    
   parallel data can be loaded into the beamsplit array (at photonic ghost   
   imaging this is a pixel array, at EM/radio this could be an array of quantum   
   dot sized metal antennas i saw published) one approach is to strobe actual   
   light emitting quantum dot    
   antennas with a picosecond or femtosecond laser, that generates a pulse train   
   that is modulated by the contents of each radio-ixel's electrical   
   characteristics, that is does it have charge. If it does then the metal   
   quantum dot sized antenna emits more    
   detectable photons. So, that radio detector array then can respond to   
   picosecond or femtosecond fluctuations in the radio signal, making wifi with   
   faster data transfer than petahz, hopping over THz radio data speeds entirely.   
   This petaHz data    
   transmission can be made use of by the parallel processors of the CPU cores,   
   GPU, or AI processing unit. If radio/EM based logic is possible at petahz it   
   is 200 times faster than 2021 5GHz CPUs.  Stated simply again the ghost   
   imaging monopixel as radio    
   sensor is the the fastest best semiconductor and circuit that can be made   
   because its frequency determines the plural data speed of the wifi. If   
   separate areas of a computer chip communicate with each other using petaHz   
   radio, or also if PHz radio logic    
   is possible, then both computer speed and parallelicity go up. A completely   
   new effect to me is that one IC chip in physical package could radio send   
   petahz data to other ic physical packages, about 10^6 times faster than   
   physical Ghz circuit traces can.    
   That gives the ability to do computational sharing and fusion between chips   
   that could be CM apart, keeping all the individual chips cool. One possible   
   high speed/frequency response radio-ixel ghost imaging antenna is a quantum   
   dot sized metal shape,    
   with 30%-70% response improving 200 picometer thick ferrite coating on it,   
   with a phosphor that lights up when trough and peak radio waves at petahz are   
   absorbed by it, depending on the observer effect that may be sufficient.   
   Because the data that    
   matters is actually then, according to ghost imaging, instantiated at the   
   separate path pixel/antenna array. the pixel bucket data has, to me, no known   
   use, (other than to adjust sampling frequency) but the separate radio-ixel   
   array has many uses. The    
   array could communicate the data it got off the radio from physical   
   connections attached to amplifiers on the IC, perhaps vertically, ballistic   
   transistor based amplifiers might be much faster as well.   
      
   Could wifi radio use soliton EM and soliton antennas to reach further   
      
   Noting really high frequency petahz or higher micometer or nanometer radios   
   could   
      
      
   [continued in next message]   
      
   --- SoupGate-Win32 v1.05   
    * Origin: you cannot sedate... all the things you hate (1:229/2)