EP1371111B1

EP1371111B1 - Magnetic dipole and shielded spiral sheet antennas structures and methods

Info

Publication number: EP1371111B1
Application number: EP02724937A
Authority: EP
Inventors: Eli Yablonovitch; Laurent Desclos; Sebastian Rowson
Original assignee: Ethertronics Inc
Current assignee: Kyocera AVX Components San Diego Inc
Priority date: 2001-02-12
Filing date: 2002-02-11
Publication date: 2008-10-22
Anticipated expiration: 2022-02-11
Also published as: EP1371111A4; KR20030084925A; KR20080064907A; KR20100037168A; ATE412259T1; WO2002065583A1; DE60229503D1; KR20090016491A; EP1371111A1; KR100945124B1

Abstract

The spiral sheet antenna (10) allows a small efficient antenna structure that is much smaller than the electromagnetic wavelength. It achieves the small size by introducing a high effective dielectric constant through geometry rather than through a special high dielectric constant material. It typically includes a rectangular cylinder-like shape, with a seam. The edges of the seam can overlap to make a high capacitance, or they can make a high capacitance by simply having the edges of the seam very close to each other. The highcapacitance serves the same role as a high dielectric constant material in a conventional compact antenna.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application relates to concurrently filed, co-pending application U.S. patent application Ser. No. 09/781,720 , entitled "Magnetic Dipole Antenna Structure and Method" by Eli Yablonovitch et al., owned by the assignee of this application, filed on February 12, 2001.
This application relates to concurrently filed, co-pending application U.S. patent application Ser. No. 09/781,779 , entitled "Spiral Sheet Antenna Structure and Method" by Eli Yablonovitch et al., owned by the assignee of this application, filed on February 12, 2001.
This application relates to concurrently filed, co-pending application U.S. patent application Ser. No. 09/781,780 , entitled "Shielded Spiral Sheet Antenna Structure and Method" by Eli Yablonovitch et al., owned by the assignee of this application, filed on February 12, 2001.
This application relates to concurrently filed, co-pending application U.S. patent application Ser. No. 09/781,723 , entitled "Internal Circuit Board in an Antenna structure and Method Thereof" by Eli Yablonovitch et al., owned by the assignee of this application, filed on February 12, 2001.

BACKGROUND INFORMATION

Field of the Invention

The present invention relates generally to the field of wireless communication, and particularly to the design of an antenna.

Description of Related Art

Document US 5,781,158 discloses several antennas with a metallic structure of cylindrical shape with a first plate, a second plate and a third plate connected by vertical connections. A dielectric substrate is arranged between the plates, the plates and the dielectric substrate thereby serving as a capacitive structure.
Document WO 01/08255 A1 discloses an antenna assembly for a wireless communication device for receiving and transmitting a communication signal. The wireless communication device has a ground plane element and a feedline conductor. The antenna assembly includes a configured radiating conductor element having a pair of opposed ends disposed proximate the ground plane element and an intermediate extending portion disposed away from the ground plane element to define an interior region. While the first and the second end are each coupled to the ground plane element, the coupling of the second end is a capacitive coupling.
An antenna according to the present invention is defined by claim 1. Preferred embodiments are subject to the dependent claims.
Small antennas are required for portable wireless communications. To produce a resonant antenna structure at a certain radio frequency, it is usually necessary for the structure to be of a size equal to one-half of the electromagnetic wavelength, or for some designs, one-quarter of the electromagnetic wavelength. This is usually still too large.
A conventional solution, to reduce the size further, is to reduce the effective wavelength of the electromagnetic waves, by inserting a material of a high dielectric constant. Then, the internal wavelength is reduced by the square root of the dielectric constant. This requires special high dielectric constant materials that add cost, weight and cause an efficiency penalty. Accordingly, the present invention addresses these needs.

SUMMARY OF THE INVENTION

The present invention provides an effective increase in the dielectric constant purely by geometry, using a spiral sheet configuration. The dielectric material can have a dielectric constant >1, or it can simply be air with dielectric constant=1. Therefore cheaper dielectric materials can be used. Indeed there is nothing cheaper than air.
An antenna comprises a first plate and a second plate, the combination of the first and second plates serving as a capacitive structure; and a third metallic structure, coupled to the first and second plates, thereby producing a cylindrical or substantially cylindrical current distribution, with two openings or holes at either end of the cylinder-like shape. Although a cylindrical current distribution is described, other shapes of current distribution can be practiced provided that the current is distributed around two openings or holes, that would construct an antenna without departing from the spirit of the present invention.
Advantageously, the present invention discloses an antenna structure that is more compact, reducing the overall size of a wireless device. The present invention further advantageously reduces the cost of building an antenna by using air as the dielectric. Moreover, the present invention provides a shield to block radio energy from being absorbed in a body, which potentially could be harmful to a person's health. The present invention also designs an antenna structure in which radio energy tends to flow in the direction away from a person. Furthermore, the present invention efficiently uses the available internal space in an antenna to maximize the space utility in an antenna and cellphone. Therefore, the dimension of a cellphone becomes even more compact.
Other structures and methods are disclosed in the detailed description below. This summary does not purport to define the invention. The invention is defined by the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a pictorial diagram illustrating a cross-sectional view of a spiral sheet antenna for producing a spiral sheet current distribution not covered by the set of claims. The overlapping plates 11 and 12 form a seam between the two openings at the ends.
FIGS. 2A-2B are pictorial diagrams illustrating a perspective view of two similar antenna structures having different aspect ratio in length and width, respectively, of a spiral sheet antenna for producing a spiral sheet current distribution not covered by the set of claims.
FIG. 3 is a pictorial diagram illustrating a first possible drive configuration for a spiral sheet antenna not covered by the set of claims.
FIG. 4 is a pictorial diagram illustrating a second possible drive configuration for a spiral sheet antenna not covered by the set of claims.
FIG. 5 is a pictorial diagram illustrating a first embodiment of a cylinder-like antenna having two holes at the ends, with a seam between the two holes for producing a circular current distribution with a double parallel plate not covered by the set of claims.
FIG. 6 is a pictorial diagram illustrating a perspective view of a cylinder-like antenna having two holes at the ends, with a seam between the two holes for producing a circular current distribution with a double parallel plate not covered by the set of claims.
FIGS. 7A-7B are pictorial diagrams illustrating a perspective view and a cross-section view, respectively, of a third drive configuration of the cylinder-like antenna shown in FIG. 6 for exciting a circular current distribution with a double parallel plate seam not covered by the set of claims.
FIG. 8 is a pictorial diagram illustrating a third embodiment of a magnetic dipole sheet antenna having two holes at the ends, with a slot seam between the two holes, allowing a circular current distribution not covered by the set of claims.
FIGS. 9A-9B are pictorial diagrams illustrating a perspective view and a side cross-section view, respectively, of a shielded spiral sheet antenna not covered by the set of claims having two holes at the ends and an overlapping seam between the holes, providing shielding from absorbers adjacent to the antenna..
FIGS. 10A-10B are pictorial diagrams illustrating side views of an operational mathematical technique for determining shielding effectiveness in a shield spiral sheet antenna not covered by the set of claims.
FIG. 11 is a pictorial diagram illustrating an operational procedure for determining the center of a hole in a shielded spiral sheet antenna not covered by the set of claims.
FIGS. 12A-12B are pictorial diagrams illustrating a shielded spiral sheet antenna not covered by the set of claims with overlapping capacitive seam structure in accordance with the present invention. FIG. 12B is a side cross-section view showing the path 128-129 followed by magnetic field lines B.
FIG. 13 is a pictorial diagram illustrating a multi-frequency, multi-tap antenna with spring contacts W1 and W2 in accordance with the present invention.
FIG. 14 is a pictorial diagram illustrating the placement of internal circuit boards inside an antenna not covered by the set of claims.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT(S)

FIG. 1 is a pictorial diagram illustrating a cross-sectional view of a spiral sheet antenna 10, resembling a rectangular cylindrical shape, with two holes at the ends, and a capacitive seam connecting the two holes, for producing a cylindrical current distribution. The spiral sheet antenna 10 can be constructed with three plates, a first plate 11, a second plate 12, and a third plate 13. The variable d 14 represents the spacing between the first plate 11 and the second plate 12, and the variable t 15 represents the thickness of all three plates. A vertical connection 16 connects between the third plate 13 and the first plate 11, while the third plate 13 connects to the second plate 12 via a vertical connection 17. The length of the third plate 13, between vertical connections 16 and 17 is selected to be less than a quarter wavelength, λ/4n, where n is the square root of the dielectric constant.
The structure of the spiral sheet antenna 10 increases the effective dielectric constant by a factor of t/d. Effective increase in capacitance is due to overlapping plates between the plate 11 and the plate 12. In effect, the spiral antenna 10 produces a large dielectric constant, without the need for a high dielectric constant material, just from electrode geometry alone, i.e. ε_relative = t/d. Effectively, treating the spiral sheet antenna as a patch type antenna, the required length of the patch then becomes $a = \frac{λ}{4} \sqrt{\frac{d}{t}} \times \frac{1}{\sqrt{ε_{r}}}$
, where ε _r is the relative dielectric constant of the capacitor dielectric.
FIGS. 2A is a pictorial diagram illustrating a perspective view of a spiral sheet antenna 20 for producing a cylinder-like current distribution. The spiral sheet antenna 20 has a first hole 21 and a second hole 22, at the ends, and a capacitive seam connecting the two holes. The alternating current (AC) magnetic field vector B , is shown entering hole 21 and exiting hole 22.
FIG. 2B is a pictorial diagram illustrating a spiral sheet antenna 25 for producing a cylinder-like current distribution with a different aspect ratio, with a first hole 26 and a second hole 27. The structure shape in FIG. 2B is the same as the structure shape in FIG. 2A. However, the aspect ratio, in FIG. 2B, is different from the aspect ratio in FIG. 2A. The curved vector I represents the general direction of the AC currents.
The spiral antennas 20 and 25 in FIGS. 2A and 2B operate like a single-turn solenoids. A single-turn solenoid consists of a cylinder-like current distribution. A 2A. However, the aspect ratio, in FIG. 2B, is different from the aspect ratio in FIG. 2A. The curved vector I represents the general direction of the AC currents.
The spiral antennas 20 and 25 in FIGS. 2A and 2B operate like a single-turn solenoids. A single-turn solenoid consists of a cylinder like current distribution. A significant portion of the electromagnetic radiation produced by the spiral antennas 20 and 25 arises from the alternating current (AC) magnetic field vector B that enters and exits from the holes at the end of the single turn solenoid.
Advantageously, the antennas 20 and 25 do not require a high dielectric constant ceramic to attain a small dimensional size. The inherent capacitance in the structure of the antennas 20 and 25 allows a low frequency operation according to the formula: $ω α \sqrt{\frac{1}{LC}}$
, where ω is the frequency in radians/second, L is the inductance of the single turn solenoid formed by 11, 16, 13, 17 and 12 in FIG. 1., and C is the capacitance from the thin overlapping region labeled as the thickness d 15, or the spacing 14.
FIG. 3 is a pictorial diagram illustrating a first drive or feed configuration 30 for a spiral sheet antenna producing a cylindrical current distribution. The first drive configuration 30 has a first plate 31, a second plate 32, a third plate 33, a first hole 34, and a second hole 35. A drive cable 36 attaches and drives the spiral sheet antenna 20. In this embodiment, the co-axial drive cable 36 matches any desired input impedance. An optional vertical short circuit wire, 37, can assist in providing an impedance matching shunt to the spiral sheet antenna 20.
FIG. 4 is a pictorial diagram illustrating a second drive configuration 40 of a spiral sheet antenna for producing a rectangular cylinder-like current distribution. The antenna might have a high electrical conductivity, e.g. copper depending on the required antenna Q-factor.
FIGS. 3 and 4 illustrate two sample drive configurations applied to the spiral sheet antenna 20, and are not meant to be an exhaustive listing since many possibilities abound. One of ordinary skill in the art should recognize that there are numerous other similar, equivalent, or different drive configurations that can be practiced. A spiral sheet antenna 20 produces an AC magnetic field that radiates efficiently in a structure that is smaller than $\frac{λ}{4 \sqrt{ε_{r}}}$
, that is a typical restriction for a patch antenna, where λ is the electromagnetic wavelength in vacuum, and $\sqrt{ε_{r}}$
is the microwave refractive index.
The antenna being described here can be regarded as a rectangular metallic enclosure with two openings, (at the ends of the rectangle), and a seam connecting the two holes. The seam functions as a capacitor and can be implemented in several different ways. First, the seam can be constructed as an overlapping region as shown in 20. Second, a seam can be constructed as slot between to metal sheets as shown in 80. where two edges meet. Third, a seam can be constructed with a slot under which there is an additional metal sheet underneath as shown in 60.
FIG. 5 is a pictorial diagram 50 illustrating a first example of a rectangular cylindrical sheet antenna with an opening at each end of the rectangular cylinder, and with a seam 54 connecting the two holes at the ends. The seam 54 comprises of a slot over a double parallel plate. The rectangular cylindrical current distribution structure 50 has a second plate 52 overlapping with a first plate 51 in two areas on either side of the slot or seam 54 to provide capacitance. The third plate 53 is far from the first and second plates 51 and 52, and therefore contributes little to the capacitance. The rectangular cylindrical current distribution structure 50 thus yields the benefit of a large dielectric constant, without the need for a special dielectric material. However, the capacitance is diminished by a factor 4 due to the two capacitors in series from the overlap of the first and second plates 51 and 52,compared to the same two plates in parallel.
FIG. 6 is a pictorial diagram 60, a perspective view illustrating the second example of a seam configuration in a rectangular cylindrical sheet antennas. A first hole 61 is positioned in the front of the pictorial diagram 60, while a second hole 62 is positioned at the back of the pictorial diagram 60.The rectangular cylindrical sheet antenna may be driven in a number of different ways. A possible approach is to place a wire parallel to the long axis, but off-center to drive currents across the slot. FIG. 7A is a pictorial diagram 70 illustrating this, the second type of drive configuration (of the third seam example, illustrated in FIG. 6) for the rectangular cylindrical sheet antenna. A co-axial feed cable 74 extends and connects through a third plate 73, a second plate 72, and a first plate 71, to an off-center drive wire 75. FIG. 7B is a pictorial diagram 76 illustrating a side view of this second type of drive configuration A drive wire 77 is shown in cross-section in FIG. 7B.
FIG. 8 is a pictorial diagram 80 illustrating a third example of a rectangular cylindrical sheet antenna with a slot seam for producing a magnetic dipole current distribution. The pictorial diagram 80 will not operate at as low a frequency as the spiral sheet structure, all other things being equal, since the capacitance of a slot seam is less than the capacitance of the over-lapping sheets in the spiral sheet structure.
FIG. 9A is a pictorial diagram illustrating a perspective view, and FIG. 9B illustrating a side view, of a first example of a shielded spiral sheet antenna 90 for producing a cylinder-like current distribution. The structure in the shielded spiral sheet antenna 90 is similar to the structure in the spiral sheet antenna 20. A first hole 91 is at one end of the rectangle, and a second hole 92 is at the other end of the rectangle. An over-lapping seam 93, connects the two holes together. In the case of a cellphone the pair of holes 91 and 92 is positioned to face away from a user's ear. A base plate 94, of the shielded spiral sheet antenna 90, is positioned facing the human body, extending 94a beyond the third plate 13 at one end and extending 94b beyond the third plate 13 at the other end. The shielded spiral sheet antenna 90 therefore faces away from the human body. The width of the border w and w' determines the degree of front-to-back shielding ratio. If w ≈ t and w'≈ t, then a shielding ratio of 3dB or better can be achieved.
FIGS. 10A and 10B are pictorial diagrams illustrating side views of a operational mathematical technique for defining a shielded spiral sheet antenna. To define the shielded spiral sheet antenna 100, two center points are chosen, a geometrical center point of a top opening 101 and a geometrical center point of a bottom opening 102. A path 103, L_s, represents the shortest path between the geometrical center point of a top opening 101 and the geometrical center point of a bottom opening 102 on the short side. A path 104, L_e, represents the longest path between the geometrical center point of a top opening 101 and the geometrical center point of a bottom opening 102 on the longer side. The path 103 is shorter than the path 104 that faces a user.
The mathematical relationship between the different variables should be governed by the following inequality, L_s - L_e > αt, Eq. (1), in order to provide a good shielding, front-to-back. A value of α ≈ 1 provides some good degree of shielding.
FIG. 11 is a pictorial diagram 110 illustrating an operational procedure for determining the center of a hole for the purposes of our operational mathematical technique for defining a shielded spiral antenna. The geometrical center of the top and bottom openings can be defined as a type of geometrical "center-of-gravity": $\sum_{edges of opening} (\vec{R} - {\vec{R}}_{0}) = 0$

where Ris the set of position vectors at the edges of the opening, and R ₀ is the center-of-gravity center point that satisfies the Eq. (2).
This equation defines the center point for use in the mathematical specification in Eq (1). The point around which all the vectors sum to zero, defines the center of the hole, or opening. The type of metallic shielding specified FIGS. 9A, 9B, 10A, and 10B, are useful for shielding cell phone antennas from the user.
FIG. 12A is a pictorial diagram 120 illustrating a perspective view of a second example of a shielded spiral sheet antenna (with overlapping capacitive structure). A first hole 124 and a second hole 125 are positioned to face away from the user. In effect, both the first and second holes 124 and 125 are facing the front. A seam 126 connects between the first hole 124 and the second hole 125.
FIG. 12B is a pictorial diagram 127 illustrating a side cross-sectional view of FIG. 12A, with AC magnetic field illustrated. The structure diagram has two holes for the magnetic field entering 128 and exiting 129 the antenna. The rectangular openings shown, may be smaller than the width of the rectangle. A rectangular container is intended as an illustration. The rectangular container may be in a shape resembling a cell phone body instead.
FIG. 13 is a pictorial diagram illustrating a dual frequency, dual-tap antenna 130 with a first hole 131, a second hole 132, and a third hole 133. A first seam 135 connects between the first hole 131 and the third hole 133. A second seam 136 connects between the hole 132 and the hole 133. Spring contacts w₁ and w₂ can connect to different circuits on a circuit board, such as for operating with main cell phone bands including Personal Communication System (PCS) at 1900 MHz, Global Positioning Systems (GPS) at 1575 MHz, bluetooth, Advanced mobile phone system (amps) at 850 MHz, and 900 MHz cell phone bands. The spring contacts are only an example. The concept is to use multiple taps for the different frequencies that might be needed in a wireless system. The multi-taps would be derived from a single antenna structure.
In general, the antenna structure consists of a metallic enclosure, with holes, or openings. For each independent antenna, or for each frequency band, an additional hole or opening must be provided on the metallic enclosure. For the example in FIG. 13, two frequencies, require 3 holes. Likewise n-frequencies would require (n+1) holes or openings, connected by n seams. Some of the n-frequencies might be identical, for the purpose of space or polarization diversity.
FIG. 14 is a pictorial diagram 140 illustrating the placement of one or more internal circuit boards 143 inside an antenna. Radio Frequency Magnetic fields enter a first hole 141 and exit through a second hole 142. The internal volume in an antenna can be wisely utilized as not to waste any unused empty space. The extra space can be filled with one or more active circuit boards 143 for operation of a cell phone. The internal circuit boards do not interfere much with the internal AC RF magnetic fields inside the antenna structure. This allows the antenna volume to be put to good use in a small volume cell phone.
The above embodiment is only illustrative of the principles of this invention and are not intended to limit the invention to the particular embodiment described.
Furthermore, although the term "holes" are used, it is apparent to one of ordinary skill in the art that other similar or equivalent concepts may be used, such as opening, gaps, spacing, etc.

Claims

Antenna (130), comprising:
a metallic structure of cylindrical shape having a first plate (11; 31), a second plate (12; 32) and a third plate (13; 53), wherein a vertical connection (16) connects the third plate (13) and the first plate (11) on the whole length of the cylindrical shape metallic structure, while the third plate (13) connects to the second plate (12) via a further vertical connection (17) on the whole length of the cylindrical shape metallic structure; and wherein the plates and connections are arranged to form two holes being openings (21, 22; 26, 27; 34; 35; 91, 92; 131, 132) at the ends of the cylindrical metallic structure; wherein the first plate (11; 31) and the second plate (12; 32) define on the whole length of the cylindrical shape metallic structure in slot seams (54; 93; 126) realizing a capacitive structure and connecting the two openings (21, 22; 26, 27; 91, 92; 131, 132)
characterized by in that the antenna comprises n + 1 holes (133) connected by said seams (54; 93; 126), wherein n > 1.
Antenna (130) of claim 1, wherein an electrical length of the antenna is less than one-quarter wavelength.
Antenna (130) according to anyone of the preceding claims, further comprising a pair of wires coupled to the antenna (130), the pair of wires providing energy to the antenna (130).
Antenna (130) according to anyone of claims 1 to 3, further comprising a wire and a ground, the wire and the ground coupled to the antenna (130) for providing energy to the antenna (130).
Antenna (130) according to anyone of the preceding claims, wherein the antenna (130) is provided to use air as dielectric material.
System, comprising:
an antenna (130) according to one of the preceding claims; and

a circuit board (143) inside the antenna structure.