WO2007112900A1 - Method and device for generating electromagnetic fields - Google Patents

Method and device for generating electromagnetic fields Download PDF

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Publication number
WO2007112900A1
WO2007112900A1 PCT/EP2007/002738 EP2007002738W WO2007112900A1 WO 2007112900 A1 WO2007112900 A1 WO 2007112900A1 EP 2007002738 W EP2007002738 W EP 2007002738W WO 2007112900 A1 WO2007112900 A1 WO 2007112900A1
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WO
WIPO (PCT)
Prior art keywords
field vector
target axis
flux lines
vector
electromagnetic field
Prior art date
Application number
PCT/EP2007/002738
Other languages
French (fr)
Inventor
Carlo Buoli
Fabio Morgia
Original Assignee
Siemens S.P.A.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Siemens S.P.A. filed Critical Siemens S.P.A.
Publication of WO2007112900A1 publication Critical patent/WO2007112900A1/en

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Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q19/00Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
    • H01Q19/06Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using refracting or diffracting devices, e.g. lens
    • H01Q19/09Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using refracting or diffracting devices, e.g. lens wherein the primary active element is coated with or embedded in a dielectric or magnetic material
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/40Radiating elements coated with or embedded in protective material
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q3/00Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
    • H01Q3/44Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system varying the electric or magnetic characteristics of reflecting, refracting, or diffracting devices associated with the radiating element
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/0407Substantially flat resonant element parallel to ground plane, e.g. patch antenna
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/16Resonant antennas with feed intermediate between the extremities of the antenna, e.g. centre-fed dipole
    • H01Q9/26Resonant antennas with feed intermediate between the extremities of the antenna, e.g. centre-fed dipole with folded element or elements, the folded parts being spaced apart a small fraction of operating wavelength
    • H01Q9/27Spiral antennas

Definitions

  • the invention relates to techniques for generating electromagnetic fields.
  • the depth of penetration s - expressed in meters - of an electromagnetic wave into a medium can be expressed as
  • the resistivity of a body tissue is about 5.10 ⁇ 5 Ohm. meter.
  • EP-A-O 755 092 discloses a micro ' strip patch or slot radiating element, working in the range of 20GHz, coupled to a dielectric rod antenna by way of a tapered tubular dielectric guide formed integrally with the rod.
  • An array of radiating elements may be formed on a common substrate, and the dielectric guide/rod antennae may be arranged to direct the energy radiated from these elements to a secondary antenna element such as a lens or a dish.
  • Such an arrangment is not adapted for using electromagnetic field for low frequency (e.g 500 Mhz) penetration of a given medium or substance where a very narrow concentration (1-5 Tnm max) around a target axis is required.
  • the object of the invention is thus to provide a solution for generating an electromagnetic with one out of the electrical field vector E and the magnetic field vector H concentrated around a target (or incidence) axis.
  • a preferred embodiment of the arrangement described herein is a device for generating an electromagnetic field E, H having the electrical field vector E or the magnetic field vector H concentrated around a target axis.
  • the device includes an electromagnetic field source for inducing a near-field configuration of the electromagnetic field having flux lines of the electrical field vector E or the magnetic field vector H that have components both along the target axis and orthogonal thereto.
  • a suppressor element is coupled to the field source in order to suppress the components of the flux lines of the electrical field vector E or the magnetic field vector H that extend orthogonal to the target axis, whereby the electrical field vector E or the magnetic field vector H is concentrated around the target axis .
  • the electrical field vector E or the magnetic field vector H is concentrated in a "spot" much smaller than the associated wavelength.
  • This result is achieved starting from a near-field configuration of a electromagnetic field having flux lines of the electrical field vector E (or the magnetic field vector H) that have components both along the target axis and orthogonal thereto.
  • FIG. 1 is a front view of an electromagnetic field generator as described herein,-
  • FIG. 2 is a cross-sectional view along line II-II of figure 1 ;
  • Figures 3 is a schematic representation of the behaviour of the electrical/magnetic field vectors as produced by the generator of figures 1 and 2 ;
  • FIG. 4 is a front view of an alternative embodiment of a generator as described herein,- _
  • FIG. 5 is a cross-sectional view along line V-V of figure 4,
  • FIG. 6 is a front view of a further alternative embodiment of a generator as described herein
  • - Figure 7 is a cross-sectional view along line VII-VII of figure 6,
  • Figure 8 is a schematic representation of the behaviour of the electrical/magnetic field vectors as produced by the generator of figures 6 and 7, and - Figure 9 is representative of a possible development of the arrangement described herein.
  • reference G denotes an electromagnetic generator (i.e. an oscillator) with a frequency up to 3 GHz, typically 500MHz.
  • Such generators are conventional in the area of telecommunications.
  • Exemplary of such a generator is, for instance, the generator type 83630L produced by Agilent Technologies, Inc.
  • the electromagnetic field from the generator G is fed into a conventional coaxial cable 10 including a metal (e.g. copper) core 12, an insulating (e.g. Teflon) sheath 14 and an outer metal (e.g. copper) shield 10a.
  • a metal e.g. copper
  • an insulating e.g. Teflon
  • an outer metal e.g. copper
  • the coaxial cable 10 is terminated, opposite to the generator G, with an
  • radiation source that is an "antenna" comprised of a metal disc 16, such as e.g. a copper disc mounted at the center of an insulating substrate 18 comprised e.g. of the material known as FR4.
  • the metallic ground plane 10b of the substrate 18 is connected (e.g. soldered) to the outer shield
  • the metallic core 12 of the coaxial cable 10 extends through a central hole 20 of the substrate 18 to contact the metal disc 16.
  • these flux lines F would be aligned with a "target” or "incidence” axis z essentially corresponding to the common axis of the distal end of the coaxial cable 10 and the source 16, 18. Then, as the distance from the source 16, 18 increases, these flux lines F would gradually spread out as schematically shown in broken lines in figure 2 to include - at each point in space closely surrounding the target axis z:
  • the magnetic field vector H will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis.
  • the (near- field) fields as considered here - and primarily the electrical field E - are intrinsically non propagative. This is in contrast to propagative i.e. wave-like electromagnetic fields wherein the electrical field vector E and the magnetic field vector H are prevalently orthogonal to each other and to the propagation direction.
  • exemplary of such a propagative electromagnetic field is prevalently TEM electromagnetic field (wave) that typically propagates along the length of a coaxial cable such as cable 10 remote of the termination where the disc 16 and the substrate 18 are located.
  • the electromagnetic wave propagating along the cable will have an electrical field vector E with flux lines directed radially from the core 12 to the shield 10a (thus lying in the x, y planes and orthogonal to the z axis) and the flux lines of the magnetic field H extending around the core 12 (again lying in the x, y planes concentric and orthogonal to the z axis) .
  • the electrical field vector E will exhibit flux lines having a component extending along the target axis z .
  • the element designated 22 in figures 2 and 3 is a disc of a ferromagnetic material such as ferrite with a diameter typically much larger than the disc 16 (e.g. 10 times) .
  • the ferrite disc 22 surrounds the disc 16 (with the exception of the side exposed to the coaxial cable 10, i.e. opposite the insulating substrate 18) with the purpose of suppressing the components of the flux lines F of the electrical field vector E that extend in the x, y directions, thereby maintaining only those components that are parallel to the axis of incidence z.
  • the electrical field vector E in the space surrounding the target axis z is generally angled to the z axis in that it exhibits, in addition to a component along the z axis, also components in the x, y directions.
  • Figure 3 schematically represents the effect deriving from the presence of the suppressor element 22. Specifically, figure 3 illustrates the typical behaviour (i.e. orientation) of the electrical field vector E up to a distance d of the order of 10cm from the source 16, 18 when the arrangement of figures 1 and 2 is supplemented with the suppressor ferrite disc 22.
  • the electrical field vector E is substantially aligned with the z-axis since its components in the x, y directions are suppressed.
  • the element 22 will thus concentrate the electrical field vector E around the target axis z in that the modulus of the electrical field vector E will have a maximum value in correspondence with the target axis z and a value gradually decreasing with the distance from the target axis z due to the suppression of the components in the x, " y directions.
  • the suppression action referred to in the foregoing, also implies a sort of "capturing" of the magnetic field by the element 22.
  • the magnetic field is "captured” in proximity of the ends of the copper disc 16 mounted at the center of an insulating substrate 18, being the metallic ground plane of the substrate 18 connected (e.g. soldered) to ground (i.e. to the outer shield 10a of the coaxial cable 10) .
  • the element 22 introduces therefore the effect of "capturing” and to exalting, in the edge of the copper disc 16, the circular magnetic field. Said element 22 introduces therefore the effect of a further strengthens - by secondary- induction - the action of concentrating the electrical field E in the target axis z.
  • the magnetic field vector H will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis (see figure 3) .
  • figure 3 corresponds to an ideal behaviour.
  • the suppressive effect of the ferrite element 22 will not be absolute, so that residues of the components in the x, y directions will cause the electrical field vector E to be slightly diverging with respect to the target axis z, while having a dominant component aligned with that axis.
  • the concentration effect just described can be further increased by superposing to the element 22 a layer 22a (see figure 2) of a resistive material which further enhances the suppression effect of the x, y components.
  • a dielectric lens 22b can be arranged in the space facing the source 16, 18 to perform a focusing action on the (already concentrated) electric field E.
  • FIGS 4 and 5 illustrate an alternative embodiment of the generator described with reference to figures 1 and 2.
  • the generator G is again connected to a source comprised of a metallic pad 16 mounted on an insulating substrate 18.
  • a source comprised of a metallic pad 16 mounted on an insulating substrate 18.
  • the strip line 24 includes a metallic strip- like core 12a extending between metallic ground planes 12b. Again, a ferrite disc 22 is mounted on the metal pad 16 to suppress the components of the electrical field in the x, y plane thus leading to a result substantially similar to that shown in figure 3.
  • suppressor materials can be easily devised e.g. in the form of garnets having the desired properties (e.g. relative magnetic permeability ⁇ r in the range e.g. 100-1000) .
  • Ferrites and garnets of the types mentioned in the foregoing are currently available from companies such as TCI Ceramics (USA) or Trans Tech (USA) .
  • Alternative arrangements to those described in the foregoing may be devised to induce a substantially dual (i.e. complementary) near-field configuration of flux lines for the vectors E and H, namely the magnetic field vector H having flux lines that are originally parallel to the z axis and then open out to include components in the x, y directions, with the flux lines for the electrical field vector E lying in the x, y planes concentric and orthogonal to s the z axis.
  • FIGS. 6 to 8 illustrate the generator G again feeding a strip line 24 including a metallic strip-like core .12a extending between metallic ground planes 12b.
  • a spiral coil 21 extends over the upper surface of the insulating substrate 18 to connect a distal extension of the core 12a and an extension of the upper ground plane 12b of the strip line 24.
  • these flux lines F would gradually spread out as schematically shown in broken lines in figure 7 to close around the coil or antenna 21 and thus include - at each point in space closely surrounding the target axis z: - a component extending along the target axis z, and - components extending orthogonal to the z axis, namely in the x, y directions.
  • the electrical field vector E will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis.
  • figure 8 shows the effect of placing a suppressor element 22' of a dielectric material surrounding the spiral coil or antenna 21.
  • the magnetic field vector H in the space surrounding the target axis z would be generally angled to the z axis in that would exhibit, in addition to a component along the z axis, also components in the x, y directions (see the aproximately circular trajectories F in figure 7) .
  • the dielectric suppressor element 22' when the dielectric suppressor element 22' is present, the components in the x, y directions are suppressed (figure 8) and the magnetic field vector H is substantially aligned with the z-axis.
  • the element 22' will concentrate the magnetic field vector H in that the modulus of that vector will have a maximum value in correspondence with the target axis z and a value gradually decreasing with the distance from that axis due to the suppression of the components in the x, y directions .
  • dielectric materials of the types mentioned in the foregoing are currently available with companies such as TCI Ceramics (USA) or Trans Tech (USA) .
  • figure 8 corresponds to an ideal behaviour.
  • the suppressive effect of the dielectric element 22' will not be absolute, so that residues of the components in the x, y directions will cause the magnetic field vector H to be slightly diverging with respect to the z axis, while having a dominant component aligned with the z axis.
  • the power generated by the generator G will depend on the envisaged application of the radiation. Experiments carried out so far by the applicant indicates that power levels in the range between a few milliwatts and a few watts are adapted to cover most applications as envisaged at present in the medical field.
  • coaxial cable 10/strip-line 24 can be notionally of any length
  • lengths in the range of a few mm to a few meters are typically adopted within the framework of the present invention. These values represent a reasonable compromise between the need of minimizing losses and attenuation along the cable 10 and the need of at least partly remotizing and/or rendering freely displaceable with respect to the generator G the electromagnetic field source I ⁇ , 18 fed via the cable 10.
  • the arrangement described herein lends itself to realising multi-beam arrangements including a plurality of sources 16, 18, 21 having associated suppressor elements 22, 22'. Those multi-beam arrangements are adopted to be operated as phased arrays to "steer" the resulting (electrical or magnetic) field in a general scanning movement of the target area .
  • Figure 9 is representative of a possible development of any of the arrangements described herein. While illustrated, by way of example, with reference to the embodiment of figure 3, the development of figure 9 lends itself to be used in connection with any of the embodiments disclosed herein.
  • figure 9 relies on the concept of "duplicating" any of the arrangements previously described by providing a pair of electromagnetic field sources (16, 18, in the exemplary case of figure 9) arranged for inducing respective, complementary electromagnetic field configurations. These sources have associated respective suppressor elements 22 for suppressing (via said described effect of "capturing” and to exalting, in the edge of the copper disc 16, the circular magnetic field) the components of the flux lines (F) of the electrical field vector E (this is the case of the exemplary embodiment of figure 9, but the same result can be achieved also for the magnetic field) extending orthogonal to the target axis, to provide a filed concentrated around the target axis (z) .
  • the two sources - i.e. essentially the two cables 10 - are fed via respective generators by ensuring constructive interaction of the concentrated fields produced thereby, i.e. with properly opposed phases, in what can be approximately termed a "push-pull" arrangement.
  • the two sources can be fed from a single generator GEN via a power splitter PSP and: a phase shifter PHS, and a step attenuator ATT, on one of the two propagation paths ensuring the desired Dhase and attenuation relationship.
  • the arrangement of figure 9 can be resorted to in order to produce concentrated fields extending between two sources located e.g. 1 meter apart from each other for the penetration of a given medium GME, eg a human body.
  • said secondary induction is generated by said ferrite element 22 in a direction where said conventional coaxial cable 10 does not spontaneously generate electrical field E, being, as above explained the electrical field E spointaneously generated (in absence of said ferrite element 22) in a radial and transversal direction SED (Spontaneous Emission Direction) with respect to the z axis.

Abstract

A device is disclosed for generating an electromagnetic field (E, H) having the electrical field vector (E) or the magnetic field vector (H) concentrated around a target axis (z). The device includes an electromagnetic field source (16, 18; 21) for inducing a near-field configuration of the electromagnetic field having flux lines (F) of the electrical field vector (E) or the magnetic field vector (H) that have components both parallel to the target axis (z) and orthogonal thereto (x, y). A suppressor element (22; 22' ), such as e.g. a ferrite or a dielectric disc is coupled to the field source (16, 18; 21) for suppressing the components of the flux lines (F) of the electrical field vector (E) or the magnetic field vector (H) that extend orthogonal to the target axis (z).

Description

"Method and device for generating electromagnetic fields"
***
Field of the invention
The invention relates to techniques for generating electromagnetic fields.
The invention was developed with specific attention paid to its possible use in the medical field. However, reference to this possible field of application must in no way to be construed in a limiting sense of the scope of the invention.
Description of the related art
Using electromagnetic fields for investigating the characteristics of a given medium or substance, for instance with the aim of locating very small inhomogeneities, is a well established approach in a number of domains ranging from material technology to the medical field as witnessed, e.g. by X-ray techniques. The scope of application of these investigation techniques involving the use of electromagnetic fields is continuously increasing as demonstrated i.a. by US- A-2002/0120189.
In general terms, the depth of penetration s - expressed in meters - of an electromagnetic wave into a medium (e.g. a body or substance) can be expressed as
s = sqrt (p / (π f μ) ) [m]
where:
- f is the frequency of the electromagnetic wave (Hz) ,
- p is the resistivity of the medium,
- μ is the magnetic permeability of the same medium, and
- sqrt denotes the square root operation. For instance, the resistivity of a body tissue is about 5.10~5 Ohm. meter.
This corresponds to a depth of penetration of about 18 centimetres at a frequency of 500 MHz, which would represent an acceptable value for a number of applications. The corresponding wavelength λ = c/f (where c denotes the speed of light) at a frequency of 500 MHz is about 0.6 meters, which does not permit good focusing other than under quite specific circumstances (e.g. structures that for some reasons concentrate the electromagnetic field) .
Much higher frequencies (for instance X-ray frequencies, to which much smaller wavelengths correspond) are thus currently used for high-resolution investigations. A basic drawback associated with the use of such high frequencies lies in their high energetic contents. Such high- energy, ionizing electromagnetic fields may give rise to undesired negative effects for the persons performing or subject to the investigation. For that reason X-ray apparatus, e. g. as used in material technology investigation or quality control in industry, must be properly shielded for personnel safety while X-ray inspection is resorted to as seldom as possible in current medical practice. This fact has rendered imaging techniques such as breast imaging techniques at microwave frequencies a promising field of investigation: see, e.g. E. C. Fear et al . "Enhancing Breast Tumor Detection with Near-Field Imaging" - IEEE Microwave Magazine, March 2002, pp. 48-56. EP-A-O 755 092 discloses a micro'strip patch or slot radiating element, working in the range of 20GHz, coupled to a dielectric rod antenna by way of a tapered tubular dielectric guide formed integrally with the rod. An array of radiating elements may be formed on a common substrate, and the dielectric guide/rod antennae may be arranged to direct the energy radiated from these elements to a secondary antenna element such as a lens or a dish.
Such an arrangment is not adapted for using electromagnetic field for low frequency (e.g 500 Mhz) penetration of a given medium or substance where a very narrow concentration (1-5 Tnm max) around a target axis is required. Object and summary of the invention
Despite the notable success already achieved, providing a significant and consistent contrast betweeen malignant and other breast tissues without having to resort e.g. to complex arrangements including a large number of transmit/receive antennas is still an open problem. In that respect, a general understanding in the art is that electromagnetic fields having moderate energy contents (e.g. nonionizing microwaves) could be advantageously used in detection techniques as considered in the foregoing if these fields could be produced in the form of electromagnetic fields having their electrical field vector or their magnetic field vector concentrated over a width of e.g. a few millimetres around a target or incidence axis. This wold permit to use these fields to scan e.g. materials, tissues to locate, for instance, inhomogeneities therein with a high degree of resolution.
The object of the invention is thus to provide a solution for generating an electromagnetic with one out of the electrical field vector E and the magnetic field vector H concentrated around a target (or incidence) axis.
According to the present invention, that object is achieved by means of a method having the features set forth in the claims that follow. The invention also relates to a corresponding device.
The claims are an integral part of the disclosure of the invention provided herein.
In brief, a preferred embodiment of the arrangement described herein is a device for generating an electromagnetic field E, H having the electrical field vector E or the magnetic field vector H concentrated around a target axis. The device includes an electromagnetic field source for inducing a near-field configuration of the electromagnetic field having flux lines of the electrical field vector E or the magnetic field vector H that have components both along the target axis and orthogonal thereto. A suppressor element is coupled to the field source in order to suppress the components of the flux lines of the electrical field vector E or the magnetic field vector H that extend orthogonal to the target axis, whereby the electrical field vector E or the magnetic field vector H is concentrated around the target axis . As a result a the electrical field vector E or the magnetic field vector H is concentrated in a "spot" much smaller than the associated wavelength.
This result is achieved starting from a near-field configuration of a electromagnetic field having flux lines of the electrical field vector E (or the magnetic field vector H) that have components both along the target axis and orthogonal thereto.
These fields are essentially non propagative, i.e. essentially non wave-like. This is in contrast with documents such as EP-A-O 755 092 (already cited in the foregoing) . While disclosing that a ferrite rod is capable of influencing an electromagnetic field, these documents disclose conventional arrangements including one or more antennas that produce propagative i.e. wave-like electromagnetic fields wherein the electrical field vector E and the magnetic field vector H are prevalently orthogonal to each other and to the propagation direction..
Brief description of the annexed representations
The invention will now be described, by way of example only, by reference to the annexed figures of drawing, wherein:
- Figure 1 is a front view of an electromagnetic field generator as described herein,-
- Figure 2 is a cross-sectional view along line II-II of figure 1 ;
Figures 3 is a schematic representation of the behaviour of the electrical/magnetic field vectors as produced by the generator of figures 1 and 2 ;
- Figure 4 is a front view of an alternative embodiment of a generator as described herein,- _
- Figure 5 is a cross-sectional view along line V-V of figure 4,
- Figure 6 is a front view of a further alternative embodiment of a generator as described herein, - Figure 7 is a cross-sectional view along line VII-VII of figure 6,
Figure 8 is a schematic representation of the behaviour of the electrical/magnetic field vectors as produced by the generator of figures 6 and 7, and - Figure 9 is representative of a possible development of the arrangement described herein.
In figure 2 reference G denotes an electromagnetic generator (i.e. an oscillator) with a frequency up to 3 GHz, typically 500MHz. Such generators are conventional in the area of telecommunications. Exemplary of such a generator is, for instance, the generator type 83630L produced by Agilent Technologies, Inc.
The electromagnetic field from the generator G is fed into a conventional coaxial cable 10 including a metal (e.g. copper) core 12, an insulating (e.g. Teflon) sheath 14 and an outer metal (e.g. copper) shield 10a.
In a manner that is conventional per se, the coaxial cable 10 is terminated, opposite to the generator G, with an
(ir) radiation source (that is an "antenna") comprised of a metal disc 16, such as e.g. a copper disc mounted at the center of an insulating substrate 18 comprised e.g. of the material known as FR4. The metallic ground plane 10b of the substrate 18 is connected (e.g. soldered) to the outer shield
10a of the coaxial cable 10. The metallic core 12 of the coaxial cable 10 extends through a central hole 20 of the substrate 18 to contact the metal disc 16.
The arrangement so far described (namely an arrangement
- not - including the element 22 to be described later) would generally induce in the space immediately surrounding the source or antenna 16, 18 - namely in "near-field" conditions
- flux lines F of the electrical field E extending along trajectories as schematically shown in broken lines in figure 2.
Originally (i.e. in close proximity of the output end of the coaxial cable 10) , these flux lines F would be aligned with a "target" or "incidence" axis z essentially corresponding to the common axis of the distal end of the coaxial cable 10 and the source 16, 18. Then, as the distance from the source 16, 18 increases, these flux lines F would gradually spread out as schematically shown in broken lines in figure 2 to include - at each point in space closely surrounding the target axis z:
- a component extending along the target axis z, and
- components extending orthogonal to the z axis, namely in the x, y directions. In the arrangement shown in figure 1 and 2 the magnetic field vector H will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis.
Once again it will be appreciated that the (near- field) fields as considered here - and primarily the electrical field E - are intrinsically non propagative. This is in contrast to propagative i.e. wave-like electromagnetic fields wherein the electrical field vector E and the magnetic field vector H are prevalently orthogonal to each other and to the propagation direction. Exemplary of such a propagative electromagnetic field is prevalently TEM electromagnetic field (wave) that typically propagates along the length of a coaxial cable such as cable 10 remote of the termination where the disc 16 and the substrate 18 are located. In that case, the electromagnetic wave propagating along the cable will have an electrical field vector E with flux lines directed radially from the core 12 to the shield 10a (thus lying in the x, y planes and orthogonal to the z axis) and the flux lines of the magnetic field H extending around the core 12 (again lying in the x, y planes concentric and orthogonal to the z axis) .
Thus, only at the terminated end of the cable 10 where the disc 16 and the substrate 18 are located, the electrical field vector E will exhibit flux lines having a component extending along the target axis z .
The element designated 22 in figures 2 and 3 is a disc of a ferromagnetic material such as ferrite with a diameter typically much larger than the disc 16 (e.g. 10 times) . The ferrite disc 22 surrounds the disc 16 (with the exception of the side exposed to the coaxial cable 10, i.e. opposite the insulating substrate 18) with the purpose of suppressing the components of the flux lines F of the electrical field vector E that extend in the x, y directions, thereby maintaining only those components that are parallel to the axis of incidence z.
As described in the foregoing, when no suppression of the components in the x, y directions is performed, the electrical field vector E in the space surrounding the target axis z is generally angled to the z axis in that it exhibits, in addition to a component along the z axis, also components in the x, y directions.
Figure 3 schematically represents the effect deriving from the presence of the suppressor element 22. Specifically, figure 3 illustrates the typical behaviour (i.e. orientation) of the electrical field vector E up to a distance d of the order of 10cm from the source 16, 18 when the arrangement of figures 1 and 2 is supplemented with the suppressor ferrite disc 22.
When the ferrite element 22 is present, the electrical field vector E is substantially aligned with the z-axis since its components in the x, y directions are suppressed. The element 22 will thus concentrate the electrical field vector E around the target axis z in that the modulus of the electrical field vector E will have a maximum value in correspondence with the target axis z and a value gradually decreasing with the distance from the target axis z due to the suppression of the components in the x, "y directions. The suppression action referred to in the foregoing, also implies a sort of "capturing" of the magnetic field by the element 22. In particular the magnetic field is "captured" in proximity of the ends of the copper disc 16 mounted at the center of an insulating substrate 18, being the metallic ground plane of the substrate 18 connected (e.g. soldered) to ground (i.e. to the outer shield 10a of the coaxial cable 10) . The element 22 introduces therefore the effect of "capturing" and to exalting, in the edge of the copper disc 16, the circular magnetic field. Said element 22 introduces therefore the effect of a further strengthens - by secondary- induction - the action of concentrating the electrical field E in the target axis z.
For instance, the modulus of the vector E will be, at a radial distance of 10 mm from the z axis, 2OdB lower that the modulus in correspondence with the z axis (i.e. x=y=0) . The magnetic field vector H will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis (see figure 3) .
Those of skill in the art will otherwise appreciate that the representation of figure 3 corresponds to an ideal behaviour. In fact, the suppressive effect of the ferrite element 22 will not be absolute, so that residues of the components in the x, y directions will cause the electrical field vector E to be slightly diverging with respect to the target axis z, while having a dominant component aligned with that axis. The concentration effect just described can be further increased by superposing to the element 22 a layer 22a (see figure 2) of a resistive material which further enhances the suppression effect of the x, y components.
A dielectric lens 22b can be arranged in the space facing the source 16, 18 to perform a focusing action on the (already concentrated) electric field E.
Figures 4 and 5 illustrate an alternative embodiment of the generator described with reference to figures 1 and 2.
In the embodiment of Figures 4 and 5, the generator G is again connected to a source comprised of a metallic pad 16 mounted on an insulating substrate 18. In the embodiment of
Figures 4 and 5, the source 16, 18 is fed with the electromagnetic field generated by the generator G via a so- called strip line 24.
The strip line 24 includes a metallic strip- like core 12a extending between metallic ground planes 12b. Again, a ferrite disc 22 is mounted on the metal pad 16 to suppress the components of the electrical field in the x, y plane thus leading to a result substantially similar to that shown in figure 3.
The arrangements shown in the drawings lend themselves to adjustment both in structural terms (diameter of the pad 16, thickness thereof, and so on, shape and size of the ferrite 22) as well as regard the features of the "suppressor" material here exemplified in the form of a ferrite . Reference to a ferrite is dictated by the prompt availability of such material in different versions with different characteristics (losses, dielectric constant) .
However, alternative suppressor materials can be easily devised e.g. in the form of garnets having the desired properties (e.g. relative magnetic permeability μr in the range e.g. 100-1000) .
Ferrites and garnets of the types mentioned in the foregoing are currently available from companies such as TCI Ceramics (USA) or Trans Tech (USA) . Alternative arrangements to those described in the foregoing may be devised to induce a substantially dual (i.e. complementary) near-field configuration of flux lines for the vectors E and H, namely the magnetic field vector H having flux lines that are originally parallel to the z axis and then open out to include components in the x, y directions, with the flux lines for the electrical field vector E lying in the x, y planes concentric and orthogonal tos the z axis.
For instance figures 6 to 8 illustrate the generator G again feeding a strip line 24 including a metallic strip-like core .12a extending between metallic ground planes 12b.
A spiral coil 21 extends over the upper surface of the insulating substrate 18 to connect a distal extension of the core 12a and an extension of the upper ground plane 12b of the strip line 24.
The arrangement so far described (namely an arrangement - not - including the suppressor element 22' to be described later) would generally induce in . the space immediately surrounding the spiral coil or antenna 21 - namely in "near- field" conditions - flux lines F of the magnetic field H, extending along trajectories as schematically shown in broken lines in figure 7. Originally (i.e. in correspondence of the plane of the coil 21) these flux lines F would be aligned with the target axis z orthogonal to the plane of the support 18, i.e. orthogonal to the plane of the spiral coil or antenna 21. Then, as the distance from the upper plane of the spiral coil or antenna 21 increases, these flux lines F would gradually spread out as schematically shown in broken lines in figure 7 to close around the coil or antenna 21 and thus include - at each point in space closely surrounding the target axis z: - a component extending along the target axis z, and - components extending orthogonal to the z axis, namely in the x, y directions.
In the arrangement shown in figures 6 to 8 the electrical field vector E will have corresponding flux lines that lie in the x, y planes concentric and orthogonal to the z axis.
In essential duality with figure 3, figure 8 shows the effect of placing a suppressor element 22' of a dielectric material surrounding the spiral coil or antenna 21.
In fact, when no suppression of the components in the x, y directions is performed, the magnetic field vector H in the space surrounding the target axis z would be generally angled to the z axis in that would exhibit, in addition to a component along the z axis, also components in the x, y directions (see the aproximately circular trajectories F in figure 7) .
Conversely, when the dielectric suppressor element 22' is present, the components in the x, y directions are suppressed (figure 8) and the magnetic field vector H is substantially aligned with the z-axis.
Again, the element 22' will concentrate the magnetic field vector H in that the modulus of that vector will have a maximum value in correspondence with the target axis z and a value gradually decreasing with the distance from that axis due to the suppression of the components in the x, y directions .
The suppression effect just described in respect of the components of the flux lines in the x, y directions can be achieved by using a dielectric materials having high dielectric constants (er = 38, 80) .
Again, dielectric materials of the types mentioned in the foregoing are currently available with companies such as TCI Ceramics (USA) or Trans Tech (USA) .
Those of skill in the art will again appreciate that the representation of figure 8 corresponds to an ideal behaviour. In fact, the suppressive effect of the dielectric element 22' will not be absolute, so that residues of the components in the x, y directions will cause the magnetic field vector H to be slightly diverging with respect to the z axis, while having a dominant component aligned with the z axis.
The power generated by the generator G will depend on the envisaged application of the radiation. Experiments carried out so far by the applicant indicates that power levels in the range between a few milliwatts and a few watts are adapted to cover most applications as envisaged at present in the medical field.
While the coaxial cable 10/strip-line 24 can be notionally of any length, lengths in the range of a few mm to a few meters are typically adopted within the framework of the present invention. These values represent a reasonable compromise between the need of minimizing losses and attenuation along the cable 10 and the need of at least partly remotizing and/or rendering freely displaceable with respect to the generator G the electromagnetic field source Iέ, 18 fed via the cable 10. The arrangement described herein lends itself to realising multi-beam arrangements including a plurality of sources 16, 18, 21 having associated suppressor elements 22, 22'. Those multi-beam arrangements are adopted to be operated as phased arrays to "steer" the resulting (electrical or magnetic) field in a general scanning movement of the target area .
Figure 9 is representative of a possible development of any of the arrangements described herein. While illustrated, by way of example, with reference to the embodiment of figure 3, the development of figure 9 lends itself to be used in connection with any of the embodiments disclosed herein.
In brief, the development of figure 9 relies on the concept of "duplicating" any of the arrangements previously described by providing a pair of electromagnetic field sources (16, 18, in the exemplary case of figure 9) arranged for inducing respective, complementary electromagnetic field configurations. These sources have associated respective suppressor elements 22 for suppressing (via said described effect of "capturing" and to exalting, in the edge of the copper disc 16, the circular magnetic field) the components of the flux lines (F) of the electrical field vector E (this is the case of the exemplary embodiment of figure 9, but the same result can be achieved also for the magnetic field) extending orthogonal to the target axis, to provide a filed concentrated around the target axis (z) .
The two sources - i.e. essentially the two cables 10 - are fed via respective generators by ensuring constructive interaction of the concentrated fields produced thereby, i.e. with properly opposed phases, in what can be approximately termed a "push-pull" arrangement.
As schematically shown in figure 9, the two sources can be fed from a single generator GEN via a power splitter PSP and: a phase shifter PHS, and a step attenuator ATT, on one of the two propagation paths ensuring the desired Dhase and attenuation relationship. The arrangement of figure 9 can be resorted to in order to produce concentrated fields extending between two sources located e.g. 1 meter apart from each other for the penetration of a given medium GME, eg a human body. It is pointed out that, according to the invention, said secondary induction is generated by said ferrite element 22 in a direction where said conventional coaxial cable 10 does not spontaneously generate electrical field E, being, as above explained the electrical field E spointaneously generated (in absence of said ferrite element 22) in a radial and transversal direction SED (Spontaneous Emission Direction) with respect to the z axis.
Consequently, without prejudice to the underlying principle of the invention, the details and embodiments may vary, even significantly, with respect to what has been described and illustrated, without departing from the scope of the invention as defined by the annexed claims.

Claims

1. A method of . generating an electromagnetic field (E, H) having one out of the electrical field vector (E) and the magnetic field vector (H) concentrated around a target axis (z), the method including the steps of: inducing a near-field configuration of said electromagnetic field having flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) , wherein said flux lines (F) have components both parallel to said target axis (z) and orthogonal thereto (x, y) , and subjecting said near-field configuration to suppression of said components of said flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) extending orthogonal to said target axis (z), whereby said one out of said electrical field vector (E) and said magnetic field vector (H) is concentrated around said target axis (z) .
2. The method of claim 1, characterized in that it includes the steps of : inducing a near-field configuration of said electromagnetic field wherein said electrical field vector (E) has flux lines (F) with components both parallel to said target axis (z) and orthogonal thereto (x, y) , and subjecting said near-field configuration to suppression of said components of said flux lines (F) of said electrical field vector (E) extending orthogonal to said target (z) , whereby said electrical field vector (E) is concentrated around said target axis (z) .
3. The method of claim 2, characterized in that it includes the step of subjecting said near-field configuration to suppression of said components of said flux lines (F) of said electrical field vector CE) extending orthogonal to said target axis (z) by using a ferromagnetic material (22) , preferably a material having a relative magnetic permeability in the range of 100-1000.
4. The method of claim 3, characterized in that it includes the step of selecting said ferromagnetic material out of ferrite and garnet .
5. The method of claim 1, characterized in that it includes the steps of : - inducing a near-field configuration of said electromagnetic field wherein said magnetic field vector (H) has flux lines (F) with components both parallel to said target axis (z) and orthogonal thereto (x, y) , and subjecting said near-field configuration to suppression of said components of said flux lines (F) of said magnetic field vector (H) extending orthogonal to said target axis (z) , whereby said magnetic field vector (H) is concentrated around said target axis (z) .
6. The method of claim 5, characterized in that it includes the step of subjecting said near-field configuration to suppression of said components of said flux lines (F) of said magnetic field vector (H) extending orthogonal to said target axis (z) by using a dielectric material (22') .
7. The method of claim 6, characterized in that it includes the step of selecting as said dielectric material a dielectric material having a dielectric constant in the range 32-80.
8. The method of any of the preceding claims, characterized in that it includes the step of generating said electromagnetic field (E, H) with a frequency in the range up to 3 GHz, preferably a few hundreds MHz.
9. A device for generating an electromagnetic field (E, H) having one out of the electrical field vector (E) and the magnetic field vector (H) concentrated around a target axis (z) , the device including:
- an electromagnetic field source (16, 18; 21) for inducing a near- field configuration of said electromagnetic field having flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) , wherein said flux lines (F) have components both parallel to said target axis (z) and orthogonal thereto (x, y) , and - a suppressor element (22, 22') coupled to said electromagnetic field source (16, 18; 21) for suppressing in said near- field configuration the components of said flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) extending orthogonal to said target axis whereby said device generates said one out of said electrical field vector (E) and said magnetic field vector (H) concentrated around said target axis (z) .
10. The device of claim 9, characterized in that it includes: said electromagnetic field source (16, 18) for inducing a near-field configuration of said electromagnetic field wherein said electrical field vector (E) has flux lines
(F) with components both parallel to said target axis (z) and orthogonal thereto (x, y) , and said suppressor element (22) coupled to said electromagnetic field source (16, 18) for suppressing in said near-field configuration the components of said flux lines
(F) of said electrical field vector (E) extending orthogonal to said target axis (z), whereby said device generates said electrical field vector (E) concentrated around said target axis (z) .
11. The device of claim 10, characterized in that said suppressor element (22) is comprised of a ferromagnetic material, preferably a material having a relative magnetic permeability in the range 100-1000.
12. The device of claim 11, characterized in that said suppressor element (22) is comprised of a material selected out of ferrite and garnet .
13. The device of any of claims 10 to 12, characterised in that it includes a layer (22a) of a resistive material associated with said suppressor element (22) to further suppress said flux lines (F) of said electrical field vector (E) extending orthogonal to said target axis (z) .
14. The device of any of claims 10 to 13, characterised in that it includes a dielectric lens (22b) to focus said electrical field vector (E) concentrated around said target axis (z) .
15. The device of claim 9, characterized in that it includes :
- said electromagnetic field source (21) for inducing a near-field configuration of said electromagnetic field wherein said magnetic field vector (H) has flux lines (F) with components both parallel to said target axis (z) and orthogonal thereto (x, y) , and said suppressor element (22') coupled to said electromagnetic field source (21) for suppressing in said near-field configuration the components of said flux lines (F) of said magnetic field vector (H) extending orthogonal to said target axis (z) , whereby said device generates said magnetic field vector (H) concentrated around said target axis (z) .
16. The device of claim 15, characterized in that said suppressor element (22') is comprised of a dielectric material .
17. The device of claim 16, characterized in that said suppressor element (22') is comprised of a dielectric material having a dielectric constant in the range 38-80.
18. The device of any of the preceding claims 9 to 17, characterized in that it includes an electromagnetic field generator (G) for feeding said electromagnetic field source
(16, 18; 21), wherein said electromagnetic field generator (G) is operable for generating said electromagnetic field (E, H) with a frequency in the range between up to 3 GHz, preferably a few hundreds MHz.
19. The device of claim 9, characterized in that said electromagnetic field source (16, 18) includes an irradiating member (16; 21) and in that said suppressor element (22; 22') at least partly surrounds said irradiating member (16; 21) .
20. The device of claim 19, characterized in that said irradiating member (16; 21) is arranged over an insulating substrate (18) and in that said suppressor element (22; 22') surrounds said irradiating member (16; 21) opposite said insulating substrate (18) .
21. The device of claim 15, characterised in that said electromagnetic field source includes an irradiating coil (21) .
22. The device of claim 21, characterised in that said irradiating coil is a spiral coil (21) arranged over an insulating substrate (18) .
23. The device of any of the preceding claims 9 to 22, characterized in that said electromagnetic field source (16, 18) is fed via a coaxial cable (10) .
24. The device of any of the preceding claims 9 to 22, characterized in that said electromagnetic field source (16, 18) is fed via a strip line (24) .
25. The device of any of claims 9 to 24, characterized in that it includes: - a pair of said electromagnetic field sources (16, 18; 21) for inducing respective near- field configurations of said electromagnetic field having flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) , wherein said flux lines (F) have components both parallel to said target axis (z) and orthogonal thereto (x, y) , and
- respective suppressor elements (22, 22') coupled to said electromagnetic field sources (16, 18; 21) for suppressing in said near- field configuration the components of said flux lines (F) of said one out of said electrical field vector (E) and said magnetic field vector (H) extending orthogonal to said target axis whereby said device generates said one out of said electrical field vector (E) and said magnetic field vector (H) concentrated around said target axis (z) .
26. The device of claim 25, characterized in that said pair of electromagnetic field sources (16, 18; 21) are fed with different phases to ensure constructive interaction therebetween in generating said one out of said electrical field vector (E) and said magnetic field vector (H) concentrated around said target axis (z) .
27. The device of either of claims 25 or 26, characterized in that said pair of electromagnetic field sources (16, 18; 21) are fed via a single electromagnetic field generator (GEN) via a power splitter (PSP) and: a phase shifter (PHS), and a step attenuator (ATT) , on one of the two propagation paths..
PCT/EP2007/002738 2006-03-30 2007-03-28 Method and device for generating electromagnetic fields WO2007112900A1 (en)

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EP06425221A EP1841008A1 (en) 2006-03-30 2006-03-30 Method and device for generating electromagnetic fields
EP06425221.6 2006-03-30

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TWI573108B (en) * 2016-03-18 2017-03-01 國立虎尾科技大學 Electromagnetic induction teaching aid kit

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3653054A (en) * 1970-10-28 1972-03-28 Rca Corp Symmetrical trough waveguide antenna array
US4131896A (en) * 1976-02-10 1978-12-26 Westinghouse Electric Corp. Dipole phased array with capacitance plate elements to compensate for impedance variations over the scan angle
US5327148A (en) * 1993-02-17 1994-07-05 Northeastern University Ferrite microstrip antenna
EP0755092A2 (en) * 1995-07-17 1997-01-22 Plessey Semiconductors Limited Antenna arrangements
EP1300910A2 (en) * 2000-10-19 2003-04-09 Jastero Trading Limited Method and small-size antenna with increased effective height
US20040119646A1 (en) * 2002-08-30 2004-06-24 Takeshi Ohno Dielectric loaded antenna apparatus with inclined radiation surface and array antenna apparatus including the dielectric loaded antenna apparatus
US20040164907A1 (en) * 2003-02-25 2004-08-26 Killen William D. Slot fed microstrip antenna having enhanced slot electromagnetic coupling

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3653054A (en) * 1970-10-28 1972-03-28 Rca Corp Symmetrical trough waveguide antenna array
US4131896A (en) * 1976-02-10 1978-12-26 Westinghouse Electric Corp. Dipole phased array with capacitance plate elements to compensate for impedance variations over the scan angle
US5327148A (en) * 1993-02-17 1994-07-05 Northeastern University Ferrite microstrip antenna
EP0755092A2 (en) * 1995-07-17 1997-01-22 Plessey Semiconductors Limited Antenna arrangements
EP1300910A2 (en) * 2000-10-19 2003-04-09 Jastero Trading Limited Method and small-size antenna with increased effective height
US20040119646A1 (en) * 2002-08-30 2004-06-24 Takeshi Ohno Dielectric loaded antenna apparatus with inclined radiation surface and array antenna apparatus including the dielectric loaded antenna apparatus
US20040164907A1 (en) * 2003-02-25 2004-08-26 Killen William D. Slot fed microstrip antenna having enhanced slot electromagnetic coupling

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