DE3445047A1 - Measuring arrangement for determining the optimum reaction between electromagnetic waves and gravitation, and method for evaluating this measurement for medical and biological applications - Google Patents

Abstract

Optimum reaction between electromagnetic waves and effects based on gravitation are produced in biological systems and in the human body by applying a swept UHF oscillation to the system or the body in such a way that the saw-tooth sweep voltage has a minimum slope of the wave front, the sweep frequency is approx. 160 Hz (or a multiple of this frequency), the swept UHF oscillation being in the region of 200 - 400 MHz, 400 - 800 MHz (or a multiple of these frequencies). The position of the range of effectiveness of these oscillations, and the optimum magnitude of the control voltage, whose ratio of fall time to rise time is at least 10:1 are determined in a special measuring arrangement. The latter consists of a control unit for generating the sweep voltage, a UHF sweeper, a wideband measurement receiver and a dual-trace oscilloscope for comparing the control signal to the AF output signal of the measurement receiver.

Description

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Patent description:

The registered procedure is based on the supply of frequency-modulated electromagnetic vibrations in the UHF or microwave range to biological systems such as human Body. The type of modulation is used in the described measuring arrangement to determine the optimal reaction between electro magnetic waves and gravitation determined. It is characterized by periodically occurring frequency swings of one Minimum steepness, its sequence and size by a sawtooth-shaped Control voltage can be determined. According to the invention, these signals can also have an optimal effect at a specific repetition frequency can only be achieved with certain frequency ranges of the modulated carrier vibrations.

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To the state of the art:

The invention is based on the knowledge that the biological processes such as growth and cell division, but also in the human Processes taking place in the body are based on the action of weak binding forces, such as those in chemistry as "Van der Waalsche" forces leading to valence bonds known · are. These forces are i.a. explained by the action of mass attraction or gravity. Characteristic of those under consideration Drawn processes here is the occurrence of a weak light effect, as it is, for example, in the works by Joachim Stauff and H.Schmidkunz (Journal of Phys. Chemistry, New Series Volume 33 (1962) pp.273-297 as well as in the same volume 35 (1962) pp.295-313). The reaction, on the other hand, of light on living biological systems via what is considered to be selective Recipient-acting DNA molecules is detailed in a publication by Fritz-Α. Popp (F.-A. Popp / G.Becker / H.L.König / W.Peschka (Eds.)! Electromagnetic Bio-Information, Munich 1979, pp.123-149).

u Selective stimulation of cell growth by the application of electro 'magnetic waves in the microwave range is from W.Grundler /

'F.Keilmann / H.Fröhlich (same in: Physics Letters Vol.62A, No.6 (1.977) pp-463-466).

These publications contain features that are included in the invention be assumed to be known. To stress. the novelty value of the invention is then referred to Effect of gravity went into more detail in order to develop a measuring arrangement and a method.

As a mass attraction, gravitation causes the movement of masses in geometrically calculable paths (Kepler's laws), as Gravity with a negligibly small mass of the test specimen compared to the field-generating mass (e.g. in the gravity field the earth) an acceleration independent of the mass in a force field (free fall, Galilei). The characteristic of gravity is an interaction of a non-polar character, which is produced either by generating the change in the magnitudes of motion can be proven experimentally according to direction or speed.

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The characteristic of the occurrence of a movement quantity is accordingly;

inextricably linked to the effects of gravity. This is of particular importance for the experimentally known but in the theoretical context by no means clarified interaction between gravitation and electromagnetic Vibrations. With light e.g. the view of the dualism wave and corpuscle applies, whereby in the corpuscular Property of light all effects caused by mass, so also gravity are included.

The registered device takes the occurrence of a quantity of movement in electromagnetic waves according to the corpuscular theory on the basis of an experimentally reproducible and theoretically interpretable interaction between gravitation and electromagnetic Waves.

The measurement method is based on that in the Lorentz transformation Expressed knowledge that processes and effects occurring in a moving system take place in the A transformation occurs when a (receiving) system is at rest experienced in the dimension in the same length and in time. \

Carrying out the experimental measurement process is subject to a » Assumption, which is used to interpret the measurement results as well as the proof of an interaction between electromagnetic Waves and gravitation has proven to be sufficient, namely the assumption of a periodic occurrence, the electromagnetic Waves as well as the quantity of motion associated with the masses.

The method preferably uses the known phenomenon of electromagnetic resonance.

An F-modulated electromagnetic oscillation is generated in a wobbler by means of a sawtooth-shaped signal whose rise to fall time has at least a ratio Γ: i CD TrßfnTu sufficiently large \ amplitude.

One receives the generated oscillation in a heterodyne receiver, which has an NF-F demodulator · The oscillator part of the test receiver must have a bandwidth of 300 MHz to 350 MHz

BATH ORIGINAL

MHz (or harmonic multiples of these frequencies).

A control signal repetition frequency of the wobbler is set in the range from 150 Hz to 170 Hz with a sufficiently large amplitude
and tunes the receiver in such a way that the NF-Auseang des
Demodulator part of a pulse train in such a way on tri11 / Υαε "reη tips are in phase with the steep edge of the sawtooth.

It appears,

a) that this phenomenon occurs only at a very specific oscillator frequency the heterodyne receiver can be observed at approx. 320 MHz (and its harmonics);

b) that no signal occurs at the point of the falling edge;

c) that these images only occur at a certain frequency of the Pulse trains occur which are in the range of 150 Hz to 170 Hz;

d) that a certain minimum steepness of the rising edge of the
Wobbiers is required to generate these images.

Discussion of the measurement method;

If there is a periodically occurring quantity of movement in the electromagnetic waves, then when the
electromagnetic waves on a stationary reference system (e.g. measuring receiver) periodic frequency shifts (according to Lorentz)
occur depending on the size of the movement. This shift is now verified by resonance with a
artificially generated F-modulated electromagnetic oscillation with a sufficiently large frequency deviation. Another support
for the process is the appearance of the so-called "Kinetobarian effect" (nWPeschka · in FAPopp et al: Electromagnetic Bio-Information Munich 1979 p.81-9A), which repercussions
describes between electromagnetic waves and matter (with the help of air or water) at discrete frequencies, e.g. also in the 300 MHz range. In the applicant's experiment, the frequencies with approx. 320 MHz and harmonics of the same were determined as suitable carrier frequencies.

The measurements now showed that with a wobble of 400 MHz up to 800 MHz and a sawtooth width of approx. 6 ms a spike-shaped one (Peak) resonance signal occurred at about 640 MHz. the

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The amplitude of the signal was dependent on the transmission field strength of the Wobblers. A comparison of the sawtooth control voltage with the resonance signal on the screen of an oscilloscope showed that the resonance signal was in phase with the steep rise of the sawtooth. The repetition frequency of the sawtooth became 160 Hz no more defined signals resulted. On the other hand, signals could still be received when the Where the pulse frequency was a multiple of 160 Hz (e.g. 320 Hz etc.).

It should also be noted that the test receiver used works with an IF of 38.9 MHz. As crucial for the resonance phenomena is the oscillator frequency, this must be added to or subtracted from the frequency values read will.

To represent the measuring device:

Fig. 1 shows the schematic structure of the measuring device, Fig. 2 shows the image to be observed in the oscillograph Signals, namely shows a) the control signal and

b) the received signal.

Were used:

As exciter: B + K Precision 3020 Sweep / Function Generator as HF wobbler: Nordmende SW 3330 service wobbler as test receiver: KWS-Electronic antenna test receiver type 154 as an oscillograph:. HAMEG Oscilloscope HM 412

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Claims (9)

Measuring arrangement for determining the optimal reaction between electromagnetic waves and gravitation and a method for evaluating this measurement for medical and biological use. 1. The device and method are characterized by a) that an F-modulated HF oscillation in a wobbler is produced, b) that this electromagnetic oscillation is received in a measuring receiver that works according to the superimposition principle, c) that the wobbler with a sawtooth-shaped control pulse, whose ratio of rise to fall time is at least 1:10, is controlled, d) that the test receiver is tuned in such a way that at a certain reception frequency of the Sttg-e-count «a sequence of Peak pulses are received, their location with the steep Edge of the saw tooth matches, e) that the amplitude curves of the two signals are dependent of different excitation parameters can be compared with one another, and f) that an oscillograph suitable for phase comparison is used to compare the two signals. 2. The method according to claim 1, characterized in that the amplitude of the control signal is increased starting from zero until the onset of said peak pulses can be observed. 3. The method according to claim 1, characterized in that the sawtooth repetition frequency of the wobbler at a certain frequency is in the range from 150 Hz to 170 Hz. 4. The method according to claim 1, characterized in that the oscillator range of the heterodyne receiver is within the limits 300 MHz to 350 MHz and their harmonics (600 to 700 MHz, 1.2 to 1.4 GHz, etc.). BATH ORIGINAL 5. The method according to claim 1, characterized in that the associated wobble range of the transmitter is substantially larger, e.g. 200 to 400 MHz (and accordingly 400 to 800 MHz etc.) is selected. 6. The method according to claim 1, characterized in that the oscillator frequency of the heterodyne receiver in the context of Measurement accuracy is 320 MHz and its harmonics. 7. The method according to claim 1, characterized in that using a wobbler in a body or biological System electromagnetic oscillations of certain F-Modula-v '·. ~ tion are generated in such a way that certain natural vibrations occurring in the body or in the biological system due to an interaction between electromagnetic waves and gravity can be optimally excited. 8. The method according to claim 7, characterized in that the F-modulation in the manner described in the measuring arrangement is generated and that the sawtooth voltage used to control the wobbler is to be determined in accordance with the measuring arrangement Possesses minimum araplitude. 9. The method according to claim 8, characterized in that the wobble range to be used the frequencies 320 MHz, 640 MHz, 1.28 GHz and «harmonics of the same. cöpv