Generator of electric and magnetic fields, a corresponding field detector, and a sample analyzer and treatment apparatus incorporating the field generator and/or field detector

US 20030169132A1
Filed: 03/26/2003
Published: 09/11/2003
Est. Priority Date: 05/13/1996
Status: Active Grant

First Claim

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7. A detector for electromagnetic fields comprises at least one super-toroidal conductor and means responsive to electrical current generated in said conductor by a varying electromagnetic field.

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Abstract

The present invention relates to a method and a device for measuring the electromagnetic field generated by living organisms and nonliving bodies, for generating such a field, and also producing an effect on (treatment of) bodies with the help of such a field.

According to the invention the electromagnetic field generated by living organisms or nonliving bodies can be measured by creation of an electromagnetic field with a frequency corresponding to the internal frequency or external resonance frequency of the body under test, wherein the electric and magnetic components of the field are created separately from one another with the help of two different systems, whereby the angle between the electric and magnetic field vectors of the electromagnetic field is changed smoothly within a set range (in this particular case within the range from zero to 360 degrees), wherein the waves reflected from the examined body are picked up with the help of a specially designed receiver system, the signal at the output: of the receiver system being constantly recorded and the parameters characteristic of the examined body (object) being fed into the data bank of the system radiating the electromagnetic field, as the reflected signal is picked up.

A device for measuring the electromagnetic field radiated by living organisms and nonliving bodies, comprising a transmitter system, which creates an electromagnetic and which is controlled by a signal modulated by two periodic signals, and a receiver system which picks up waves reflected by the examined body, comprises according to the invention two different radiating systems to create separately the electric and magnetic components of the field, where the transmitter system comprises transmitting aerials and control circuits connected thereto and where the receiver system comprises receiving aerials, an amplifier connected thereto, and a recording unit connected to the amplifier output; then a systems control unit is connected to the receiver system and the transmitter system, the transmitter system comprising at least eight aerials or a number thereof which is a multiple of four and the receiver system comprising at least four aerials or a number thereof which is a multiple of four, the number of aerials of the receiver system and that of the transmitter system forming a ratio of at least one to two.

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48 Claims

7. A detector for electromagnetic fields comprises at least one super-toroidal conductor and means responsive to electrical current generated in said conductor by a varying electromagnetic field.
- View Dependent Claims (8, 9)
- - 8. A detector as claimed in claim 7 wherein said conductor comprises a super-toroidal conductor of odd order and a super-toroidal conductor of even order.
  - 9. A detector as claimed in claim 7 wherein said conductor comprises a super-toroidal conductor of a first predetermined order and a super-toroidal conductor of a second predetermined order higher than said first predetermined order, said super-toroidal conductor of said first predetermined order providing a toroidal former and said super-toroidal conductor of said second predetermined order being wound on said toroidal former.

10. A sample analyser comprising a chamber, a sample holder within the chamber, at least a first super-toroidal conductor in the chamber which includes a length 1 of the conductor which is wound continuously in the same hand, means for energising said first super-toroidal conductor to generate, in the region of any sample on the sample holder, an electromagnetic field varying with at least one frequency component at a frequency which is equal to or greater than 2c/1 where c is the speed of light in free space, and means for determining a response of the generated field to the presence of a sample on the sample holder.
- View Dependent Claims (11, 12, 13, 14, 15, 16, 17)
- - 11. A sample analyser as claimed in claim 10, wherein said means for determining includes at least a further super-toroidal conductor in the chamber and means responsive to electrical currents generated in said further conductor by said field generated by said first super-toroidal conductor.
  - 12. A sample analyser as claimed in claim 10, wherein said means for energising comprises at least a second super-toroidal conductor in the chamber, and a high gain broad band radio frequency amplifier having an input connected to receive signals corresponding to electrical currents generated in said second conductor by a varying electromagnetic field in said chamber and is having an output connected to energise the first conductor to form a closed radio frequency loop, said high gain amplifier having sufficient gain that the loop gain exceeds unity at frequencies within the band width of the amplifier.
  - 13. A sample analyser as claimed in claim 12 wherein said means for determining a response includes at least a third super-toroidal conductor in the chamber and means responsive to electrical currents generated in said further conductor by said field generated by said first super-toroidal conductor.
  - 14. A sample analyser as claimed in claim 13 wherein the chamber contains at least two super-toroidal conductor assemblies, each said assembly comprising an inner super-toroidal conductor of a first predetermined order providing a toroidal former, and an outer super-toroidal conductor of a second predetermined order wound on said toroidal former provided by said inner super-toroidal conductor, the inner conductor of one toroidal assembly and the outer conductor of the other toroidal assembly together forming said second toroidal conductors connected to the input of said high gain amplifier, and the outer conductor of said one toroidal assembly and the inner conductor of said other toroidal assembly together forming said third toroidal conductors.
  - 15. A sample analyser as claimed in claim 14 wherein said chamber contains a further said super-toroidal conductor assembly, the inner and outer conductors of said further assembly together forming said first toroidal conductors connected to the output of said high gain amplifier.
  - 16. A sample analyser as claimed in claim 15 wherein said sample holder holds the sample substantially on the axis of said further super-toroidal conductor assembly.
  - 17. A sample analyser as claimed in claim 14 wherein said two super-toroidal conductor assemblies are located coaxially on opposite sides of said sample holder.

18. Treatment apparatus for treating a desired component of a specimen, comprising at least one treatment super-toroidal conductor having a length 1 of the conductor which is wound continuously in the same hand, means to energise the treatment super-toroidal conductor at at least one selected frequency which is equal to or greater than 2c/1 where c is the speed of light in free space, so as to generate a strongly spatial inhomogeneous electric and magnetic fields at said frequency, and means to expose the specimen to said generated inhomogeneous field.
- View Dependent Claims (19, 20, 21, 22)
- - 19. Treatment apparatus as claimed in claim 18 and including a sample analyser comprising a chamber, at least a first super-toroidal conductor in the chamber which includes a length 1 of the conductor which is wound continuously in the same hand, means for energising said first super-toroidal conductor to generate, in the region of any sample on the sample holder, an electromagnetic field varying with at least one frequency component at a frequency which is equal to or greater than 2c/1 where c is the speed of light in free space, and means for determining a response of the generated field to the presence of a sample on the sample holder, wherein said means to energise said treatment super-toroidal conductor is arranged so that said at least one selected frequency is selected in accordance with said response determined by said determining means of the analyser to the presence on the analyser sample holder of a sample corresponding to the desired component of the specimen to be treated.
  - 20. Treatment apparatus as claimed in claim 19 wherein said determining means in said analyser includes at least a further super-toroidal conductor in the chamber and means responsive to electrical currents generated in said further conductor by said field generated by said first super-toroidal conductor.
  - 21. Treatment apparatus as claimed in claim 20, further comprising a treatment chamber of similar dimensions to said chamber of said analyser, and, in said treatment chamber, first and second super-toroidal conductor assemblies, each said assembly comprising an inner super-toroidal conductor of a first predetermined order providing a toroidal former, and an outer super-toroidal conductor of a second predetermined order wound on said toroidal former provided by said inner conductor, the inner conductor of one toroidal assembly and the outer conductor of the other toroidal assembly forming said treatment super-toroidal conductors and being connected to be energised by electrical currents derived from said currents generated in said further super-toroidal conductor in said analyser.
  - 22. Treatment apparatus as claimed in claim 21 and including a broad band radio frequency noise generator and/or a modulator providing pulses of said broad band noise at a selected pulse rate and having a selected pulse width, and means to energise said toroidal assemblies with said pulses from said modulator.

23. A method of treatment of a living organism comprising the steps of generating a strongly spatial inhomogeneous oscillating electric and magnetic fields, and exposing the living organism to said electric and magnetic fields for treatment.
- View Dependent Claims (24, 25)
- - 24. A method as claimed in claim 23 wherein the electric and magnetic fields have a frequency content selected to be specific to the living organism to be treated.
  - 25. A method as claimed in claim 23 wherein the field is generated by energising a super-toroidal winding with a frequency which is high relative to 2c/1, where c is the speed of light in free space and 1 is the length of wire in the super-toroidal winding.

26. Method for measuring the electromagnetic field generated by living organisms and nonliving bodies through the creation of an electromagnetic field whose frequency corresponds to (coincides with) the examined body'"'"'s internal or external resonance frequency, characterised in that the electric and magnetic components of the field are created separately from one another with the help of two different systems, whereby the angle between the electric and magnetic vectors of the electromagnetic field is changed smoothly within a set range (in this particular case within the range of from zero to 360 degrees), whereby the waves reflected from the examined body are picked up with the help of a specially designed receiver system, the signal at the output of the receiver system being constantly recorded and the parameters characteristic of the examined body .(object) being fed into the data bank of the system radiating the electromagnetic field, as the reflected signal is picked up.
- View Dependent Claims (27, 28, 30, 31, 32, 33, 34, 35, 36, 37)
- - 27. A method according to claim 26, characterised in that a body whose content is unknown, but with at least one known component, is placed in the electromagnetic field of the radiating system;
    - the parameters characteristic of the examined body and those corresponding to the electromagnetic field of the radiating system recorded as soon as the system picks up at least one reflected signal are compared to the already measured parameters of known materials to establish the body'"'"'s material components.
  - 28. A method according to claim 26, characterised in that a body whose condition. (state) is unknown is placed in the electromagnetic field of the radiating system;
    - the parameters characteristic of the examined material and those corresponding to the electromagnetic field of the radiating system are compared to the already measured parameters of known materials to determine the composition of the examined object (body).
  - 30. A method according to any of the preceding claims 26-29, characterised in that the electric and magnetic vectorial components are generated with the help of electric and magnetic radiators, where the super-toroidal aerials of the first or higher, but invariably odd, order are electric radiators and the super-toroidal aerials of the second or higher, but invariably even, order are magnetic radiators.
  - 31. A method according to claim 30, characterised in that the electromagnetic field is created by two periodic signals being within the band of from one kilocycle to 1000 gigacycles per second and being modulated by a low frequency signal within the band of from 0.001 to 100 cycles per second.
  - 32. A method according to claim 31, characterised in that both periodic signals are sinusoidal.
  - 33. A method according to claim 31 and claim 32, characterised in that the angle between the electric and magnetic vectors of the field is set by changing the difference in the phase of the modulated signals fed into each aerial.
  - 34. A method according to claim 33, characterised in that the low frequency sinusoidal signal which modulates the high frequency signal creating the electromagnetic field is broken off after a certain part of the wave has passed and formed a definite phase angle.
  - 35. A method according to claim 34, characterised in that to produce a stimulating effect the low frequency sinusoidal signal should be dampened (eliminated) as soon as it forms a phase angle of 0.33*T.
  - 36. A method according to claim 34, characterised in that to produce an inhibiting effect the low frequency sinusoidal signal should be dampened (eliminated) as soon as it forms a phase angle of 0.25 *T.
  - 37. A method according to any of the preceding claims 26-36, characterised in that if the examined object is of microscopic magnitude and if its effective field angle is unknown, the angle between the electric and magnetic vectors of the electromagnetic field induced by the electromagnetic radiating system is changed in stages;
    - in the course of the change the frequency of the signal generating the electromagnetic field is constantly identical to the examined object'"'"'s internal frequency;
      
      every time it changes a series of measurements are made with the help of a low frequency signal which is dampened (eliminated) as soon as one phase angle is equal to 0.25 *T and the other phase angle is equal to 0.33 *T;
      
      the magnitude of the vectorial angle is considered to be characteristic of the examined object, if the reflected feedback signal is the greatest, when the parameters of the field of the said object coincide with those of the field created by the radiating generators.

29. A method for producing an effect on (treatment of) living organisms and nonliving bodies, whereby an electromagnetic field is created, whose frequency coincides with the internal and external resonance frequencies of the body, which is characterised in that the said body is located at a distance of 30 or more kilometres from the system radiating the field, and in that the angle between the electric and magnetic components of the electromagnetic field is equal to the body'"'"'s characteristic vectorial angle.
- View Dependent Claims (1, 2, 3, 4, 5, 6, 38, 42, 43)
- - 1. A field generator comprising at least one super-toroidal conductor and means to energise the super-toroidal conductor to generate varying electric and magnetic fields.
  - 2. A generator as claimed in claim 1 wherein said conductor includes a length 1 and said means to energise is operative to generate an electromagnetic field varying with at least one frequency component at a frequency which is equal to or greater than 2c/1 where c is the speed of light in free space.
  - 3. A generator as claimed in claim 1 wherein said conductor comprises a super-toroidal conductor of odd order and a super-toroidal conductor of even order.
  - 4. A generator as claimed in claim 1 wherein said conductor comprises a super-toroidal conductor of a first predetermined order and a super-toroidal conductor of a second predetermined order higher than said first predetermined order, said super-toroidal conductor of said first predetermined order providing a toroidal former and said super-toroidal conductor of said second predetermined order being wound on said toroidal former.
  - 5. A generator as claimed in claim 2 wherein said means to energise is operative to energise said conductor to generate an electromagnetic field having a plurality of frequency components at frequencies greater than 2c/1.
  - 6. A generator as claimed in claim 5 wherein said frequency components include frequencies greater than 10c/1.
  - 38. A method according to any of the preceding claims 29-36, characterised in that the examined object is located at a distance of 30 or more kilometres from the system radiating the field, imprints (copies) of the electromagnetic fields characteristic of the given object and its geographic location (ground) are placed between the turns creating (inducing) an auxiliary electromagnetic field parallel to the (Earth'"'"'s) geomagnetic field, the auxiliary electromagnetic field parallel to the geomagnetic field being “
    - superimposed”
      
      on the electromagnetic field of the examined object, where the angle between the electric and magnetic. vectors of the conditioning (operant) field should be equal to the characteristic vectorial angle of the examined object or the vectorial angle of the material acting on the object.
  - 42. A device according to claim 41, characterised in that the aerials are arranged on the vertices of squares, the aerials arranged opposite one another being super-toroidal aerials radiating only an electric or only a magnetic field, whereas those arranged side by side being super-toroidal aerials differing from the former in that they radiate either an electric or a magnetic field.
  - 43. A device according to claim 38, characterised in that twinned low and high frequency aerials connected to separate aerials are connected to a frequency synchroniser and phase adjustment means—
    - an effective phase shifter—
      
      and also in that the generators and the input of the phase adjustment means—
      
      an effective phase shifter—
      
      is connected to the output of the central control unit, a control computer.

39. A device for measuring the electromagnetic field radiated by living organisms and nonliving bodies, comprising a transmitter system, which creates an electromagnetic and which is controlled by a signal modulated by two periodic signals, and a receiver system which picks up waves reflected by the examined body, characterised in that two different radiating systems are used separately to create the electric and magnetic components of the field, where the transmitter system comprises transmitting aerials and control circuits connected thereto and where the receiver system comprises receiving aerials, an amplifier connected thereto, and a recording unit connected to the amplifier output;
- then a systems control unit is connected to the receiver system and the transmitter system, the transmitter system comprising at least eight aerials or a number thereof which is a multiple of four and the receiver system comprising at least four aerials or a number thereof which is a multiple of four, the number of aerials of the receiver system and that of the transmitter system forming a ratio of at least one to two.
- View Dependent Claims (41, 45, 46, 47, 48)
- - 41. A device according to claims 39 or 40, characterised in that the aerials used are super-toroids of the first or higher, but invariably odd, order, and the magnetic field radiators (aerials) are super-toroids of the second or higher, but invariably even, order.
  - 45. A device according to any of the preceding claims 39-44, characterised in that to produce an effect on objects (bodies) located at a distance of 30 or more kilometres an accessory aerial comprising a super-toroid(L3) of the second order is placed close to the system radiating the operant field, a Helmholtz coil (L1), which is coupled to the adjustable secondary side of a mains-operated transformer, is connected in parallel to the turns of the super-toroidal aerial, another Helmholtz coil (L2) which is linked in parallel to a condenser (C), is coupled to the first Helmholtz coil (L1) by means of mutual inductance, the control circuit comprising two high and low frequency generators is connected to this oscillatory circuit which in turn is connected to the generator of the modulator.
  - 46. A device according to claim 45, characterised in that both Helmholtz coils (L1 and L2) are arranged close to one another on the same axis, the axis being parallel to the (Earth'"'"'s) geomagnetic lines, in that imprints (copies) of the electromagnetic fields characteristic of the said object and its geographic location (ground) are placed between the coils inducing an auxiliary electromagnetic field parallel to the geomagnetic field.
  - 47. A device according to claim 46, characterised in that the imprints (copies) of the electric fields characteristic of the geographic location (ground) and the exposed object (body) are transferred in frozen form in glycerine, paraffin, tar or mixtures thereof.
  - 48. A device according to claim 47, characterised in that if paraffin is used there should 10 units of mass of paraffin to one unit of mass of metal powder (whose composition is given in units of mass):
    - one unit of mass of silver, two units of mass of copper, three units of mass of iron, four units of mass of aluminium, and four-nine units of mass of tin.

40. A device acting upon living organisms and nonliving bodies with the help of a magnetic field, comprising a transmitter system which creates an electromagnetic field and which is controlled by a signal modulated by two periodic signals, characterised in that it uses two different radiating systems separately producing the electric and magnetic components of the field, where the transmitter system comprises transmitting aerials and control circuits connected to the transmitter system, the transmitter system comprising at least two aerials or a number thereof which is invariably a multiple of two.

42-1. A device according to any of the preceding claims 29-42, characterised in that a high frequency signal generator is connected to each aerial of the transmitter system, where the high frequency signal generator output is connected to the input of the modulated signal modulator and the output of the low frequency signal generator is connected to the input of the modulated signal modulator, and the output of the modulator is connected through a pulse chopper to the appropriate transmitting aerial.

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Current Assignee
Scalar Technology Limited
Original Assignee
HEX Technology Holdings Limited Jersey Channel Islands
Inventors
Vaiser, Leonid Vladimirovich, Kokorin, Boris Ivanovich

Granted Patent

US 6,770,023 B2
Time in Patent Office

Days
Field of Search
US Class Current

333/227
CPC Class Codes

H01Q 7/00 Loop antennas with a substa...

Generator of electric and magnetic fields, a corresponding field detector, and a sample analyzer and treatment apparatus incorporating the field generator and/or field detector

First Claim

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48 Claims

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Generator of electric and magnetic fields, a corresponding field detector, and a sample analyzer and treatment apparatus incorporating the field generator and/or field detector

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

Citations

48 Claims

Specification

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