Information
-
Patent Grant
-
6362789
-
Patent Number
6,362,789
-
Date Filed
Friday, December 22, 200023 years ago
-
Date Issued
Tuesday, March 26, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 343 700 MS
- 343 702
- 343 846
- 343 848
- 343 853
-
International Classifications
-
Abstract
A dual frequency wideband antenna assembly for use in a wireless communication device. The antenna assembly having a first resonator element disposed away from the ground plane element, said first resonator element being operatively coupled at a first location to the ground plane and being operatively coupled at a second location to the RF signal port; a second resonator element disposed away from the ground plane. The first and second resonator elements are coupled via a bridge conductor and a capacitive tuning network. The capacitive tuning network may include a discrete capacitor or an adjustable capacitor which varies in response to a signal.
Description
FIELD OF THE INVENTION
The present invention relates to an antenna assembly suitable for wireless transmission of analog and/or digital data, and more particularly to a dual frequency, wideband resonator element providing at least one adjustably tuned component.
BACKGROUND OF THE INVENTION
Recent advances in wireless communications devices have renewed interest in antennas suitable for such systems. Several factors are usually considered in selecting an antenna for a wireless telecommunications device. Significant among these factors are the size, VSWR, gain, bandwidth, and the radiation pattern of the antenna.
Currently, monopole antennas, patch antennas and helical antennas are among the various types of antennas being used in wireless communications devices. These antennas, however, have several disadvantages, such as limited bandwidth and large size. Also, these antennas exhibit significant reduction in gain at lower elevation angles (for example, 10 degrees), which makes them undesirable in some applications.
As mentioned above, one type of antenna is an external half wave single or multi-band dipole. This antenna typically extends or is extensible from the body of a wireless communication device in a linear fashion. Because of the physical configuration of this type of antenna, electromagnetic waves radiate equally toward and away from a user. Thus, there is essentially no front-to-back ratio and little or no specific absorption rate (SAR) reduction. Specific absorption rates for this type of antenna are typically 2.7 mw/g at a 0.5 watt transmission power level. With multi-band versions of this type of antenna, resonances are achieved through the use of inductor-capacitor (LC) traps. With this antenna, gains of +2 dBi arc common. While this type of antenna is acceptable in some wireless communication devices, it has drawbacks. One significant drawback is that the antenna is external to the body of the communication device. This places the antenna in an exposed position where it may be easily damaged.
A related antenna is an external quarter wave single or multi-band asymmetric wire dipole. This antenna operates much like the aforementioned antenna, but requires an additional quarter wave conductor to produce additional resonances. This type of antenna has drawbacks similar to the aforementioned antenna.
SUMMARY OF THE INVENTION
A dual band antenna assembly for use in a wireless communications device (WCD) is disclosed. The antenna assembly provides simultaneous wideband resonances over two or more different frequency bands when disposed relative to a ground plane of the wireless communications device. One or more of the operational frequency bands of the antenna assembly may be selectively adjusted via a capacitive tuning network. The selective adjustment of the capacitive tuning network may be achieved during the manufacture or subsequent use of the wireless communications device. In this manner, a tuning process over a much wider range of frequencies in each band may be achieved without an alteration of the physical size or structure of the antenna element. The selectively tunable antenna according to the present invention permits a single mechanical embodiment to accommodate a variety of different frequency bands, thus providing a manufacturing and assembly economy over prior art antennas (where timing has typically required an alteration of the physical structure of the antenna, or selection from among a plurality of differently sized antenna elements). The selective tuning of the antenna assembly of the present invention may be achieved via a variety of automatic or manual approaches. In one embodiment, the capacitive tuning network, such as a varactor, may be electrically tuned via the WCD microprocessor in response to an internal program or one or more external signals. In another embodiment, the capactive tuning network may be controlled via a manual operated switch, such as through a PIN diode switching device.
The antenna assembly includes first and second conductive surfaces disposed relative the ground plane of the WCD, preferably at the upper rear portion of the WCD. The first and second conductive surfaces are in substantial collateral relation and include a conductive bridge element disposed therebetween. The first and second conductive surfaces are also operatively coupled together via a capacitive tuning network, as further described herein. A conducting feed element operatively connects the first conductive surface to a signal line of the WCD. The feed element includes a feed arm defining a 50 ohm feed point. The first conductive surface is further coupled to the ground plane of the WCD via a grounding element.
In another embodiment, the antenna assembly is spaced a predetermined distance from the ground plane of a printed wiring board, and is operatively connected thereto at several predetermined locations by several components. One component, a capacitor or tuning network, capacitively couples the second conductive surface to the ground plane. Another component, the feed point of the antenna, operatively couples the first conductive surface to the RF input/output port or terminal of the WCD. Additionally, a third component, a grounding element, operatively connects the second radiating element to the ground plane. Since the distance between the antenna assembly and the ground plane is a function of the particular frequencies or wavelengths in use, the space between the antenna assembly and the ground plane may vary depending on the frequency band desired. However, it will be appreciated that various componentry may be positioned within the open space(s) between the antenna assembly and the ground plane to facilitate compact construction.
It is an object of the present invention to provide an antenna assembly which may be incorporated within the interior of a wireless communication device.
It is an object of the present invention to enhance operation of an antenna assembly by increasing its operational bandwidths and performance thereof.
It is another object of the present invention to provide an antenna assembly exhibiting at least one major polarization and one minor polarization.
Yet another object of the present invention is to provide a multiple band antenna for wireless communications devices that exhibits lower specific absorption rate (SAR) as compared to typical external antennas.
It is another object of the present invention to provide a multiple band antenna assembly wherein at least one of the frequency bands is selectively tunable by manual control or electrically tunable variable capacitor element.
It is yet another object of the present invention to provide a control assembly for adjusting the capacitance of the electrically tunable variable capacitor element, such as a digital control structure.
It is another object of the present invention to provide a variable capacitor element control assembly which is responsive to external signals received from the wireless communications system.
It is yet another object of the present invention to provide a variable capacitor element control assembly which is response to internal signals of the wireless communications device.
A feature of the present invention includes the provision that one or more portions of the resonator elements of the antenna assembly are tunable over a broad range of frequencies.
Another feature of the present invention includes the provision of a single feed point for a multi-band antenna system. The multiple band antenna assembly according to the present invention may exhibit a VSWR of approximately 2:1 over two different frequency bands, such as 880-960 MHz and 1710-1880 MHz or 824-894 MHz and 1850-1990 MHz. These and other objects, features and advantages will become apparent in light of the following detailed description of the preferred embodiments in connection with the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a perspective view of an antenna assembly according to the present invention disposed within a wireless communications device;
FIG. 2
is a perspective view of the antenna assembly according to the present invention disposed upon a printed circuit board assembly;
FIG. 3
is views of a resonator portion of the antenna assembly of
FIG. 1
;
FIG. 4
is a perspective view of another embodiment of an antenna assembly according to the present invention disposed on a printed circuit board assembly;
FIG. 5
is a schematic diagram of a capacitive tuning network for use with the antenna assembly according to the present invention; and
FIG. 6
includes back plan, side, and top elevational views of an antenna assembly according to the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring now to the drawings, wherein like numerals depict like parts throughout,
FIG. 1
illustrates an antenna assembly
20
according to the present invention disposed near the upper rear portion of a hand-held wireless communications device
22
. The antenna is disposed within the housing
24
of the wireless communications device
22
. The antenna assembly
20
according to the present invention includes a resonator structure
26
disposed relative to a ground plane
28
of the wireless communications device
22
. As depicted, the resonator structure
26
of the antenna assembly
20
is disposed at an upper end portion of a printed wiring board (PWB)
30
and is operatively coupled to the PWB
30
by a pair of conducting elements
40
,
42
, including a grounding conductor
40
and a feed conductor
42
. Feed conductor
42
element includes a first end which is operatively connected at a predetermined position along an edge
64
of the resonator structure
26
. The other end of the feed element
42
is operatively connected to the PWB
30
at the RF
50
ohm input/output terminal or port. The feed element
42
is illustrated as an integrated planar portion of the resonator structure
26
, though an alternative feed element
42
may include a coaxial cable, a microstrip line, or other suitable conductors. The grounding element
40
has two ends, one end of which is operatively coupled to a portion of the resonator structure
26
of the antenna assembly
20
. The other end of the grounding element
40
is operatively connected near the top of the PWB
30
to the ground plane
28
in a conventional manner.
The resonator element
26
of the antenna assembly
20
includes a substantially planar top surface
50
defining two separated conductive regions
52
,
54
. The two conductive regions
52
,
54
are coupled together via a conductive bridge element
56
and a capacitive tuning network
71
. Resonator element
26
can include first and second front surfaces
60
,
62
and a side surface
64
. Resonator structure
26
further defines a pair of removed portions
66
,
68
, the physical size of which may be varied depending on the particular application. The two conductive regions
52
,
54
are disposed in a side-by-side relationship and are operatively coupled by the conductive bridge element
56
and by a capacitor for fixed tuned operation or a capacitive tuning network
71
for electrically tuned function. Conductive bridge element
56
is illustrated as an integrated planar portion of resonator structure
26
. Alternative embodiments may include a bridge element
56
being a separate conductor, such as a wire, having different dimensions as compared to the bridge element
56
of
FIGS. 1-4
.
The first conductive region
52
is sized to resonate at the lower frequency band. The second conductive region
54
is sized to resonate at the higher frequency band and is functionally dependent on the capacitive tuning network
71
coupled between the first and second conductive regions
52
,
54
. In one embodiment, a variable capacitive tuning network
71
has range of approximately 0.7-1.4 picofarads for operation over the 1710-1800 MHz frequency band. Importantly, the capacitance value of the capacitive tuning network
71
is capable of being selectively varied to tune the resonator over a range of frequencies without changing the physical characteristics of the resonator
26
. In preferred embodiments, the capacitive tuning network
71
may be controlled via a user-manipulated switch, or even via an internal digital controller
70
. In one embodiment, a digital controller
70
may receive control input from the user, an internal program, or from an external signal such as from a cell phone system or wireless datalink base station. The external signal may be extracted from a separate transmitted signal which is received by the antenna
20
or even defined as a portion of or contained within the communication protocol.
FIG. 5
illustrates one possible capacitive tuning network
71
for use with the antenna assembly
20
. The two conductive regions
52
,
54
of
FIG. 4
are capacitively coupled together by the capacitive tuning element
158
, and a DC blocking capacitor
159
which are components of the tuning network
71
. Capacitive tuning element
158
may be a varactor element. Analog tuning network
17
of antenna assembly
120
further includes an inductor or RF choke
75
which allows a control voltage to vary the capacitance of the varactor capacitive tuning element
158
. The value of the control voltage may be controlled via a digital controller, D/A and/or CPU or manual switching, as appreciated by those skilled in the relevant arts.
In another embodiment, the capacitive tuning network
71
and associated control device
70
may be automatically responsive to a continuously or semi-continuously transmitted signal to aid in maintaining the signal quality, change of protocol of the communications link or to enable encryption. In this regard, a single resonator element
26
may be used to achieve relatively seamless transitions or “hand-offs” as the wireless communication device
22
is used between differing RF spectra, encryption, and/or communications protocols.
The antenna assemblies
20
,
120
of
FIGS. 1-4
are sized to exhibit a VSWR of approximately 2:1 over two different frequency bands, such as 880-960 MHz and 1710-1880 MHz or 824-894 MHz and 1850-1990 MHz.
FIG. 3
illustrates views of the resonator element
26
of the antenna assembly
20
of the present invention. Dimensions of the features of the components indicated in
FIG. 3
are as follows:
|
Item
Dimension (in.)
|
|
|
a
.075
|
b
.57
|
c
.36
|
d
.248
|
e
.010
|
f
.068
|
g
.05
|
h
1.00
|
i
1.1
|
j
1.42
|
k
.602
|
l
.64
|
m
.76
|
n
.315
|
o
.449
|
p
.137
|
q
1.33
|
r
0.7 pF
|
|
FIG. 4
illustrates another embodiment of the antenna assembly
120
according to the present invention. As depicted in
FIG. 4
, the antenna assembly
120
includes a resonator structure
126
disposed relative to a ground plane
128
of the wireless communications device
122
. As depicted, the resonator structure
126
of the antenna assembly
120
is disposed at an upper end portion of a printed wiring board (PWB)
130
and is operatively coupled to the PWB
130
by a feed conductor
142
. Feed conductor element
142
includes a first end which is operatively connected at a predetermined position along an edge of the resonator stricture
126
. The other end of the feed element
142
is operatively connected to the PWB
130
at the RF input/output terminal or port. The feed element
142
is illustrated as an integrated planar portion of the resonator structure
126
, though alternative feed elements may include a coaxial cable, a microstrip line or other suitable conductors.
The resonator element
126
of
FIG. 4
includes a substantially planar top surface
150
defining two separated conductive regions
152
,
154
coupled together via a bridge element
156
and a tuning network
171
, which includes a capacitive tuning element
158
(See, FIG.
5
). Bridge element
156
of
FIG. 4
is illustrated as an integrated planar portion of resonator structure
156
. Alternative embodiments may include a bridge structure
156
being a separate conductor, such as a wire, having different dimensions as compared to the bridge element
156
of FIG.
4
.
As illustrated in
FIG. 5
, the two conductive regions
152
,
154
of
FIG. 4
may be capacitively coupled together by the capacitive tuning element
158
, and DC blocking capacitor
159
which are components of the tuning network
171
. Capacitive tuning element
158
may be a varactor element. Analog tuning network
171
antenna assembly
120
further includes an inductor or RF choke
175
which allows a control voltage to vary the capacitance of the varactor capacitive tuning element
158
. The value of the control voltage may be controlled via a digital controller, CPU, or manual switching, as appreciated by those skilled in the relevant arts.
The antenna assembly
120
further includes a second tuning network
172
which is coupled between the second conductive region
154
of the resonator
126
and the ground plane
128
of the wireless communications device
122
. The second varactor
159
on tuning network
172
may be controlled in similar manner to the first varactor element
158
, i.e., via RF choke
176
, a controllable voltage via digital controller, D/A, and CPU.
FIG. 6
includes back plan, side, and top elevational views of an antenna assembly according to the present invention. The view of
FIG. 6
are not necessarily to view, but illustrate possible orientations and components of a wireless communications device including an antenna assembly according to the present invention.
It should be noted that the drawings may indicate proportions and dimensions of components of the antenna device. However, e.g., thickness of conductive layers have been exaggerated for clarity. Although, in many embodiments conductive plates have been mentioned, it is understood that it includes the use of conductive layers, possibly attached to dielectric substrate(s). Although the invention is described by the above examples, naturally, a skilled person would appreciate that many other variations than those explicitly disclosed are possible within the scope of the invention.
Additional advantages and modifications will readily occur to those skilled in the art. The invention in its broader aspects is, therefore, not limited to the specific details, representative apparatus and illustrative examples shown and described. Accordingly, departures from such details may be made without departing from the spirit or scope of the applicant's general inventive concept.
Claims
- 1. A wideband adjustable antenna assembly for use in a wireless communications device, said device having an input/output RF signal port and a ground plane, said antenna assembly comprising:a first resonator element disposed away from the ground plane element, said first resonator element being operatively coupled at a first location to the ground plane and being operatively coupled at a second location to the RF signal port; a second resonator element disposed away from the ground plane; a bridge conductor conductively coupling the first and second resonating elements; and a capacitive tuning network operatively coupled to the first and second resonating elements, said capacitive tuning network capacitively coupling the first resonating element to the second resonating element.
- 2. The antenna assembly of claim 1, wherein the capacitive tuning network is a discrete capacitor having a preselected capacitance value selected with reference to one or more frequency bands of operation.
- 3. The antenna assembly of claim 2, wherein the capacitive tuning network defines a plurality of capacitance values associated within one or more frequency bands of operation.
- 4. The antenna assembly of claim 3, wherein the capacitive tuning network includes a manual operated switch to select a preferred capacitance value.
- 5. The antenna assembly of claim 4, wherein the capacitive tuning network includes a PIN diode switch device.
- 6. The antenna assembly of claim 3, wherein the capacitive tuning network includes an electrically adjustable capacitor.
- 7. The antenna assembly of claim 6, wherein the electrically adjustable capacitor is a varactor.
- 8. The antenna assembly of claim 6, wherein the electrically adjustable capacitor is varied in response to a signal.
- 9. The antenna assembly of claim 8, wherein the signal is an external signal associated with a particular wireless communications protocol and received by the wireless communications device.
- 10. The antenna assembly of claim 8, wherein the signal is an internal signal associated with an internal program of a microprocessor.
- 11. The antenna assembly of claim 1, wherein the first and second resonator elements are substantially coplanar.
- 12. The antenna assembly of claim 1, wherein the first and second resonator elements and the bridge conductor are substantially coplanar.
US Referenced Citations (3)
Number |
Name |
Date |
Kind |
6005522 |
Arias et al. |
Dec 1999 |
A |
6140966 |
Pankinaho |
Oct 2000 |
A |
6208298 |
Uchino et al. |
Mar 2001 |
B1 |