Radionics & Modern Science
It must be pointed out, however, that the term ‘Radionic Computer’ is not strictly correct. Any computer with enough memory and the ability to be programmed by the practitioner can be ‘called’ a radionic computer, but he would merely be storing information in exactly the same way as a small business man would do for his individualised merchandise.
For the final ideas on the possibilities for ‘Radionics in the Electronic Era’I hand over to Mike Roberts, the technical expert, and am asking him to express his thoughts on the subject in Electronic terminology. He therefore continues:
“A truly radionic computer would be another matter. It would be interfaced with the main memory and would be a system of converting the signals now interpreted by the practitioner with a pendulum or stick-pad into electrical signals compatible with the computer’s addressing and programming needs.
“The ‘output’ of the computer, as well as being available as a hard copy on paper, would have a secondary or peripheral box to enable it to convert its ‘electrical signal’ into ‘radionic rates’ or ‘geometrical patterns’.
“If the computer were able to interface directly with a radionic treatment instrument one could use a pattern or numerical value created by the computer, and then it might be possible to abandon the use of rates altogether, and this would mean, in turn, that much less memory would be required in the main computer. The name of
the condition or location of the organ under analysis might be enough, and this could be assigned a certain reference point on a matrix of connections, each organ or condition being assigned its own particular position on this matrix in much the same way as it now has a rate assigned to it.
“The actual position may not have to be displayed on the video display unit. The computer could be programmed to know which connection on the matrix any condition represented.
“Turning to the complementary display terminal one could incorporate a cursor bar that would underline the location or organ one was interested in. This cursor bar would, of course, be adjustable from top to bottom of the screen.
“Graphics could be used to advantage. A ‘picture’ of the relevant area of the body under investigation could be displayed with all the organs and points of interest labelled. Anatomical physiological diagrams could be remembered and displayed. This ‘picture’ system of presenting the information to the practitioner could be of great help in visualisation.
“The actual point of detection during an analysis, that is, the point when a practitioner would normally get a pendulum or stick-pad reaction, could be displayed as a flashing light indicator next to the organ on the screen.
“I have already designed a mini-computer that will remember a series of treatment rates and present them to the practitioner, in sequence, by the touch of a button. Where several different treatments are required for a particular case, selected treatments could be stored and automatically switched on and off through a pre-set timer, thus giving a patient what it is considered he requires, spread over perhaps 24 hours.
“Miniature diagnostic and treatment instruments not more than 12 inches wide are in production.”
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In ending my book I must again stress that in our discussions on new and more complex forms of radionic instrument’, the complexity is directed towards the mechanics of presenting information to and recovering information from the very simple factors of radionics itself.
The complexity is an aid to the Radionic Practitioner, and nothing more than a time-saving factor. Radionics itself does not demand complex or even electronic circuits. It is, as mentioned earlier, probably a very simple form of geometrical pattern energy. It does, however, require the ‘human factor’, and our researches are directed towards allowing the practitioner to make full use of his ESP faculty whilst removing as much of the labour involved in storing his conclusions as is scientifically possible.