Prof. Dr-lng. Konstantin Meyl



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1.8 Conclusion



 

The experiment impressively proves that it cannot concern waves, according to Hertz. The 

power transmission shown is in principle not possible with the waves, according to Hertz. 

Whereas scalar waves are capable of a loss less transfer of energy, wherefore the experiment is 

to be regarded as proof for the existence of scalar waves.

 

1.9 Consequences



 

If a transmitter is operated openly, without a receiver that absorbs the energy, the danger exists 

that the transmitter "looks" for any receiver itself and that could be a biological system. Any 

humans, who go coincidentally into resonance, would now absorb the sent energy or a certain 

quantity of it. This is comparable with a positive pole, from which electrical flux lines emanate 

and which is searching for its negative pole. Here the electrical flux lines will end, as well if 

the distance is very large. As well known the range is theoretically infinite. In contrast to the 

example, the case of resonance concerns only swinging poles, which swing with the adjusted 

frequency constantly between plus and minus.

 

As long as the power consumption by humans is not measured, an acute danger of 



electromagnetic pollution exists. Apart from the employment for medical purposes, the 

operation of scalar wave transmitters is to be rejected, which abuses humans as a receiver. It is 

to be made certain that the sent power is completely received i. e. collected and applied to a 

consumer load.

 

If we reduce the amplitude of the waveform generator so far that the light emitting diodes on 



the transmitter side shine not more brightly as those on the receiver side we can be safe that no 

biological effect will arise. If more energy is transmitted, as the receiver can absorbe, further 

receivers should be switched in addition so that no vagabonding stray fields appear, which 

could be absorbed by biological systems. The optimal point is found, if during the reduction of 

the transmission amplitude, the receiver just begins to react with a reduction of the received 

energy.


 

 

Fig.6: Basic set up of the wireless transfer of energy device



 

(here shown with attached frequency counter from the experimentation kit)

 



-11-

 

2nd experiment, subject: 



Feedback (from receiver to transmitter)

 

2.1



 

Experimentator: Prof. 

Dr.-Ing. Konstantin Meyl 

2.2


 

Place and date: 

D-78112 St. Georgen, 21st of June 2000 

2.3


 

To the status of physics of electromagnetic waves (according to Heinrich Hertz) 

Terrestrial radio stations cannot determine on their transmitted power, how many listeners they 

have. There is no feedback from the receiver to the transmitter. If the effects in the experiment 

would be caused by radio waves (thus as the waves, according to Hertz), it might not be able to 

determine at the transmitter whether a receiver is attached or not.

 

2.4 Expectation according to the scalar wave theory by Konstantin Meyl



 

Scalar waves spread not evenly but are the result of a resonance between transmitter and 

receiver. And in such a way power is only deducted, if an appropriate receiver goes into 

resonance with the transmitter. That means, that there should have to be a direct feedback from 

the receiver to the transmitter.

 

2.5 Experimental setup



 

To be able to observe possible feedback, the point of resonance must be found again first. This 

is adjusted, if on the receiver the major peak can be observed and the LED's shine most 

brightly. The experimental setup is in the first instance the same (like 1.5: The waveform 

generator is attached on one side over two shorting plugs to the couple coil. This teslacoil 

functions as transmitter. The cable connection is plugged at the outside end of both teslacoils 

and the waveform generator is attached to the wall power supply). After this is done the 

amplitude controller has to be fully untwisted (in the clockwise direction up to the limit stop) 

and the frequency is slowly adjusted with the frequency controller and the light emitting diodes 

at the receiver are thereby observed. If the major peak should not be able to be determined 

clearly, it is recommended to reduce the voltage with the amplitude controller. Thus the major 

peak appears no longer so bright, but can be distinguished clearly from the auxiliary peaks.

 

2.6 Carrying out the experiment



 

After finding the major peak, the amplitude controller is turned back so far that the light 

emitting diodes on the transmitter side do not shine any longer, while the light emitting diodes 

on the receiver side still shine. If the cable connection is carefully unplugged, the light emitting 

diodes installed onto the transmitter side shine again. The LED's, installed on the receiver side, 

extinguish.

 

2.7 Interpretation of experiment results



 

The same effect arises, if the frequency at the waveform generator is adjusted. In this case the 

receivers LED's go out, while the LED's at the transmitter light up, because the resonance 

frequency is left and therefore no more power arrives at the receiver.

 

The light emitting diodes on the transmitter side give information about the power taken off 



from any receivers. If the brightness changes if the ground wire is connected from the 

transmitter to a heating element, it can be examined whether unwanted receivers possibly exist.

 



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