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<h1>Faster than Light Communication:  Quantum Entanglement</h1>
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<a href="https://glowinggoldenglobe.com/glowing-golden-globe-3-1" target="_top" class="class_a_2" >Contact</a>
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<p>
On the web date:  September 17, 2022
<br>
Document creation date:  September 17, 2022 &nbsp;<a href="https://glowinggoldenglobe.github.io/Faster-Than-Light-Communication/original_text.pdf" target="_top" class="class_a_1" >original_text_pdf</a>
<br>
Document text edit, updated:  September 19, 2022 &nbsp;<a href="https://glowinggoldenglobe.github.io/Faster-Than-Light-Communication/Faster_Than_Light_Data_Transfer.pdf" target="_top" class="class_a_1" >this_web_page_pdf</a>
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<br>Richard Craddock
<br>207 Hillcrest Rd Apt 133
<br>Mobile, Alabama  36608, USA
<br>Earth, Milky Way, Quadrant 1, Universe 1, Creation, God    
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<h2>Introduction</h2>
<p>
Faster than light data transfer - possible.
<br>Author:  I'm not a professor. I'm not a formal research scientist. I didn't verify the results with any science organization or science community, yet (6:35 PM CDT; Mobile, AL, 36608, USA; 09 19 2022). I didn't perform any lab experiments. Nevertheless, I think I solved the problem.
<br>
Opinion - Solved. The long-awaited solution to faster-than-light-communication is completed. It is accomplished. It is finished. It has, now, been solved. It is described, herein.
</p>
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<h2>Standards of Duration</h2>


<h3>Example</h3>
<p>Point A</p>
<ul><li>Standard of Duration of Observation-Measurement:  50 miliseconds</li></ul>
<p>Point B</p>
<ul><li>Standard of Duration of Observation-Measurement:  200 miliseconds</li></ul>
<p>
Four Parts of 50s is 200 (i.e., 50 MS * 4 = 200 MS;  at Point A, where there is a set of 4 consecutive observerations, each 50 MS in duration, then the total is 200 MS (the duration of the observation at Point B).
<br>It takes four events of observations each at a duration of 50 miliseconds to elapse the duration of the observation at Point B of 200 miliseconds.
</p>

<h3>Standard Set Duration</h3>
<ul>
    <li>Example.  At Point A  -  Four Observations each at durations of 50 miliseconds, equaling a total <i>sum duration</i>, at Point B, of a single, simultaneous observation of 200 miliseconds</li>
    <li>"Standard Set Duration" (also called, standard-set-duration-variable) refers to a variable which is assigned a value in a standard unit of measure of time (such as miliseconds) representing the duration of a set of observations used for comparison, for a calculation which solves for the measurement of the change in particle orientation for coding and/or decoding as and/or to character messages.  The standard-set-druation-variable describes (is assigned a value which defines...) the duration of increments of observations of a set of observations of a-system-of-sets-of-observations;  and where said variable is used to describe a fundamental unit of measure as an assigned specific value of measure by which other measures are compared; thereby, things (users, machines, and/or programs) use it as a point of reference, thus making it a "standard" for the system of measurements.</li>
    <li>There are multiple variables which the term, "standards set duration" describes.  Example.  (1)  Point A standard-set-duration-variable;  (2)  Point B standard-set-duration-variable.  At least one standard-set-duration-variable is assigned a value for each Point location of measurement of quantum entangled particles; and it's value can be unique (different) versus every other other Point location without causing measurement errors or conclusion errors.</li>
    <li>The "Standard Set Duration" is the regular duration of observation of a quantum entangled particle, at a particular Point (observation) location, which duration is used as a point of reference for: (1) purposes of measurement, as well as for (2) purposes of maintaining regular, timed, synchronous, simultaneous observations among multiple Point (observation) locations.</li>
    <li>Example.  The "Standard Set Duration" may be a variable quantity per set-of-machine-devices-at-a-Point-location-for-measurement-of-messages-of-faster-than-light-communication-using-quantum-entanglement.</li>

</ul>

<h4>Sum Duration</h4>
<p>A set's <i>sum duration</i> is its sum of durations where its numerical sum value is equal to the standard set duration at the <i>mirrored point</i> location.</p>

<h4>Mirrored Point</h4>
<p>
For purposes of this document, the definition of "mirrored point" is as follows:
Where Point A is measuring entangled particles corresponding to its entangled particles at Point B, Point A is a the mirrored point location of Point B, and Point B is a mirrored point location of Point A.
</p>

<h3>Standard Set of Particles</h3>
<ul>
    <li>Each particle observed is observed via the usage of a standard-set-duration, as described, above.</li>
    <li>Each code-message-character is deciphered via measuring a change in a particle position-observed.</li>
    <li>Each code-message-character is deciphered via measuring a set-of-particles.  That is to say, for each single character to be sent from Point B to Point A, what is used to send said single (only-one-character) character message is a set-of-particles - a set of observations of a set of several particles, where each set of observations measures each particle of the set of particles one time (once; one measurement per particle of a set of particles per instance of a single set of observations).</li>
</ul>


<h2>Quantity of Particles Per Measurement Per Single-Digit Code Message of Particle(s) Position-Observed</h2>


<h3>Method 1</h3>
<p>Where change in position = Code Message Sent</p>
<ul><li>If and only if change in particle position occurs at Point A as at least one observation of a set of four observations</li></ul>
<p>Where a standard-set-duration of 4-observations-at-Point-A occurs for a standard-set-of-particles</p>
<ul>
    <li>Where a variable is the variable-per-set-of-machine-devices-for-measuring-messages-from-said-set-of-devices-as-a-machine-for-measuring-said-messages</li>
    <li>Where an example-machine is an example-machine-measuring-system-of-a-set-of-devices (so-called, and example, because it is an example for purposes of this document, whereas, a machine-measuring-system-of-devices-for-measuring-messages-at-faster-than-light-speed may otherwise be use a different set of assigned quantities for variables versus the quantity-values assigned to the same variables in this document-example of such a machine-system.</li>
    <li>Where the variable-standard-set-of-particles is, for this example-machine is 100 particles in each set of particles.  In other words, standard-set-of-particles-variable = 100, for this example.</li>
    <li>If Point B changes its observation-duration from 200 miliseconds to 100 miliseconds, then, it is expected (and required) that at least one particle in a set-of-particles will change its position, (2) and will be measured as a change in position at Point A within a set of 4 observations during the simultaneous change-in-duration-of-observation at Point B.  It is, of course, expected, that the third observation (observation-3-of-4 of a set-of-4-observations) will notice the change in position of at least one particle in its set of observed particles as a reflection of the mirror of the change-in-duration-of-observation at Point B from 200 miliseconds to 100 miliseconds.</li>
</ul>


<h3>Method 2</h3>
<p>Where change in position = Code Message Sent</p>
<ul>
    <li>If and only if the change in the particle position-observed</li>
    <li>If a standard-set-of-particles-variable = 100</li>
    <li>If the 200 miliseconds observation duration changes to 400 miliseconds;  correspondingly the change of a set of particles will not change for the duration of two (2) sets-of-observations of particles at Point A, and, thus, the observation at Point A will record that the absence of a change for 2 sets-of-observations represents a code-character of the message.</li>
</ul>
<p>
Where the probability is 50%, the odds are overcome via the measurement of a set, and, indeed, multiple sets for the same single-code-message-character where the said "sets" are sets-of-particles representing that single-code-message-character. That is to say, each code-character of a message is to be represented and measured-using-an-entire-set-of-particles versus merely using one-particle-per-code-character-of-a-message;  and, in this way, the probability-problem of a measurement of a position of a particle per observation is overcome, additionally, via using a set of observations rather than merely a single observation to find a change (ambiguity, but understood).
</p>

<h3>Defintions and Explanations</h3>
<p>
"change in particle position"  is the equivalent of  "the change in the particle position-observed"

single-code-message-character
The term, single-code-message-character is used in this document to differentiate between using a single particle to measure a character versus using an entire set of particles to measure only one character of a message.  And, the measuring system, described in this document, above, always uses a set of particles to measure any one, single character of a message, and it never uses a single particle, alone (only), to measure a single character.
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