AU2001269413A1 - Internal antennas for mobile communication devices - Google Patents
Internal antennas for mobile communication devicesInfo
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- AU2001269413A1 AU2001269413A1 AU2001269413A AU2001269413A AU2001269413A1 AU 2001269413 A1 AU2001269413 A1 AU 2001269413A1 AU 2001269413 A AU2001269413 A AU 2001269413A AU 2001269413 A AU2001269413 A AU 2001269413A AU 2001269413 A1 AU2001269413 A1 AU 2001269413A1
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- slot
- ground plane
- antenna according
- antenna
- feed
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Description
INTERNAL ANTENNAS
FOR MOBILE COMMUNICATION DEVICES
FIELD OF THE INVENTION
The present invention relates generally to antennas and, more
particularly, to small and high efficiency antennas for mobile and handset
communication devices.
BACKGROUND OF THE INVENTION
Mobile communication devices are becoming smaller as the
technology is developed. For an antenna to operate properly, it should usually
be about half a wavelength in size, except for monopole-like antennas (which normally operate above a ground plane), where a quarter wavelength is
required. For advanced mobile communication devices, e.g., cellular handset
units, such dimension are impractical since the overall handset dimension is
smaller than half a wavelength of the appropriate frequency.
Using small antennas reduces their efficiency, and hence requires
higher power to be supplied in order to operate the device. Higher power
causes shorter battery cycles between charging and increases the radiation
into the user's head/body. The level of power radiated into the human head is
most significant, and serious limitations and specifications are prescribed in
order to protect the users.
Operation of such devices adjacent to a human body also changes the
field and/or current distribution along the antenna, and hence changes its
radiation pattern, as well as the radiation efficiency. Practically speaking, the
reduction in efficiency may be even in the range of 10 - 20 dB or more. The
result is a requirement for higher power to operate the device with the
consequent disadvantages described above. The use of external whip
antennas, such the "STUBBY" or retractable antennas, is also inconvenient, as
the antennas are often "caught up" inside the pocket. They also detract from
the aesthetic appearance of the mobile communication device and most
important - the radiation pattern is quasi-omni, so no enhancement is
achieved in radiation at the user's head/body.
Internal antennas supplied by several companies are relatively
inefficient as compared to external antennas. Furthermore, these known
internal antennas generally do not decrease the radiation into the user's head/body, and in many cases even increases such radiation. The antenna
gain is also generally poor (especially while used adjacent to the head/body),
and the SAR (Specific Absorption Ratio) results are generally high.
Another problem in the known internal antenna is the narrow
bandwidth of operation. In addition to the narrow bandwidth where the input
impedance is matched the radiation efficiency is even further reduced. The
latter is considered an even more difficult problem in cases where dual
frequency bands or triple-band operations of the mobile communication
devices are required, such as cellular GSM 900/1800, 900/1900,
900/1800/1900 MHz, etc.
Internal antennas for mobile communication devices are known that
utilize a resonant radiation element as the main radiator. In particular, printed
antennas, e.g. patches and slots, are very convenient to use because of their
ease of manufacture, their low profile, and their low production cost. If such
printed elements could be used in mobile communication devices with respect
to efficiency, gain, impedance matching and reproducibility, it would be the
best choice. Unfortunately, such elements, because of the small size of the
mobile communication device, will show very low efficiency and hence low
gain, and it will be difficult to match their impedance to that of the mobile communication device.
Generally, slots excited by a feed line (e.g., by microstrip or stripline
structures) or by a coax cable, are usually narrow band. In order to achieve matching of the slot even over a narrow band, the excitation of the slot is
generally made off-center, to reduce the input impedance of the slot, which is
naturally very high. US Patent No. 5,068,670 by one of the inventors in this
application and thereby incorporated by reference describes a broadband slot
antenna achieved by adding matching networks at both sides of the slot. In
the preferred embodiment, the feed lines are located off-center of the slot.
The direction of maximum radiation of an off-center excited slot is
changed with frequency due to the asymmetrical electric and magnetic field
distributions excited along the slot. While narrow bandwidth slots are not
significantly affected by this phenomenon, broadband slots are indeed
affected. The best solution is to excite the slot symmetrically by dual feed and
load lines, which may be split from a single excitation feed. Each of the strip
arms has a dual matching network in order to widen the bandwidth of the
antenna. The length and width of each arm may be equal in order to achieve
full symmetrical structure, but may also differ in order to maximize the
bandwidth. If the arms are not identical, there will be some squint with frequency.
The slot may be a non-resonant one, by making it open at both ends
("open-ended"), or a resonant one, by making it closed at both ends
("short-ended"). The radiation efficiency depends on the field distribution -
amplitude and phase, along the slot. The electromagnetic fields in
short-ended slots must vanish at both ends of the slot; and since they are
continuous, their value at any point along the slots cannot reach the required
level as with shorter slots. Therefore, short-ended slots are relatively large, usually in the range of half wavelength at the operation frequency.
The electromagnetic fields in open-ended slots may have finite value
at their ends and should not vanish. It follows that a reasonable value of the
field can be reached even for relatively short-length slots. The excitation point
may then be optimized for single or dual feeds. It should be taken into
consideration that radiation pattern will be different from the usual one.
Further, the load type of the strip for open-ended slots would preferably be of
the form of a short circuit, to eliminate a floating ground at the far end of the
slot. As a result, this configuration is more complex to match by means of the
reactive part of the slot impedance. Furthermore, a floating ground would
decrease the antenna efficiency.
EP 0924797 describes a slot antenna configuration in which the slot is
curved along two axes, and is excited at its center point by a coax cable.
There are a number of disadvantages of such configuration as suggested by
this patent. Thus, the matching of such a slot is very difficult due to the
centered excitation point (as described above and in US Patent No.
5,068,670). In addition, the part of the slot which contributes to the radiation
in the desired direction is very small while, due to the folded arms of the slot
which are parallel, the fields are opposite in polarization and hence cancel the
radiation at most desired directions. Further, the excitation is complex and
costly to implement. Finally, slots which are open-ended at one end are less
efficient as compared to short-ended slots, and cause radiation in undesired
directions. The radiation pattern will be asymmetrical due to the radiation from the open end of the slot, since the fields do not vanish, as above-mentioned.
US Patent Nos. 5,929,813 and 6,025,802 describe similar antennas.
Such antennas are actually loop antennas where a "wired slot" generates a loop antenna. There are a number of disadvantages of such configuration as
suggested by this patent. Thus, "wired slot" is open at the connecting points,
is cut along the edge of the antenna and is also folded on the metal sheet,
hence it causes radiation in undesired directions and with opposed
(horizontal) polarization. The "wired slot" is excited by the antenna connector
very close to the antenna (and telephone) edge; hence, radiation at the user's
head is not reduced. Actually, because of the phone's PCB, which significantly
contributes to the radiation at CDMA/TDMA/GSM frequencies (800 and 900
MHz), it would appear that the radiation at the user's head is even increased.
Further, in the embodiment of a dual frequency operation according
to these referenced patents, the radiation pattern in the higher band has
nulls, or at least significant reduction at certain angles and is far from being
omni-directional in the azimuth plane. In this configuration each "wired slot"
affects the operation of the other band where it is not supposed to influence
the loop produced by this configuration is parallel to the user's head in "talk
position" (e.g. a position where the user holds the mobile communication
device adjacent to his head), and hence the fields' distributions are
significantly changed by the human body.
As a result, the performance of the antenna is reduced, high transmitted power level would be required, and the sensitivity of reception
would be less than required.
US Patent No. 6,002,367 describes a patch-slot antenna excited by a
feed line, similar to the structure described in US Patent No. 5,068,670. The
patch is excited by electromagnetic coupling of the feed line to the patch
through the slot along its center line, and is very small as compared to the
wavelength at the operational frequency; hence it does not radiate efficiently.
The patch (or patches) added above the slot is (are) excited by the feed line;
the load line (described in several embodiments) and the grounding of the
patch tune the patch. This antenna mechanism is similar to that of the
well-known Planar Inverted "F" Antenna (PIFA), where the grounding of the
element tunes the antenna, except for the signal feeding, which is made by a
feed line rather than a probe (PIFA). The performance of the antenna is poor
and its operational bandwidth is very narrow . It is complicated to build and
relatively expensive, and no real reduction in the radiation at the user's
head/body is achieved. In addition, the structure's height is large even in the
simplest embodiment of a single patch. For modern mobile communication
devices, which are very compact in size, such dimensions are impractical.
Other antenna constructions are described in WO 99/13528, and
WO 99/36988 (US 5,945,954) but such antennas also suffer from one or more
of the drawbacks discussed above.
OBJECTS AND BRIEF SUMMARY OF THE INVENTION
An object of the invention is to provide an internal antenna for mobile
communication devices which, although very small as compared to conventional antennas, yet is nevertheless capable of operating at high
efficiency.
Another object of the invention is to provide an internal antenna for
mobile communication devices displaying low Specific Absorption Ratio (SAR)
with respect to the radiation at the head/body of a human person.
A further object of the invention is to provide an internal antenna for
mobile communication devices wherein operation in the vicinity of a human
head/body does not significantly interfere with the performance of the
antenna.
Another object of the invention is to provide an internal antenna for
mobile communication devices that can efficiently operate in wide frequency
bands - single, dual or multi-band.
A further object of the invention is to provide an internal antenna for
mobile communication devices that can be manufactured inexpensively in
volume as compared to the conventional external antennas.
Yet another object and advantage of the invention is to provide an
internal antenna for mobile communication devices that presents a more
aesthetic appearance than the comparable devices equipped with
conventional external antennas.
According to one aspect of the present invention, there is provided a
multi-band microwave antenna which is resonant and radiant at a high
frequency band and at least one lower frequency band, comprising: a
dielectric substrate having opposed faces; an electrically-conductive layer
serving as a ground plane on one face of the dielectric substrate; an
electrically conductive feed line carried on the opposite face of the dielectric substrate, the feed line having at least one feed end and at least one load
end; a slot formed in the ground plane having a feed side and a load side
with respect to the feed end and load end, the slot being electromagnetically
coupled to the load end of the feed line such that the slot is resonant and
radiant at the high frequency band; and a further electrical conductor
electrically connected to the ground plane to serve as a continuation thereof
at the load side of the slot, the further electrical conductor being
dimensioned, located and electromagnetically coupled to the slot at the lower
frequency band such as to cause the slot to be resonant and radiant also at
the at least one lower frequency band.
The explanation for the enhancement in the lower operational
frequency is as follows: Electrical currents are generated along the ground
plane of the antenna, which contribute to the radiation of the antenna. In a
finite ground plane, these currents generate electric and magnetic fields at
both ends of the ground plane (those ends which are perpendicular to the
direction of propagation of the currents), acting like a patch antenna. The
currents generated along the ground plane must be continuous and therefore,
if the size of the ground plane is small, no significant current amplitude will be
achieved, (theoretically, around one-half wavelength is required for maximum
current to be generated). By adding the second ground plane, the generated currents do not need to vanish at the first ground plane's edge and thus
contribute to the radiation of the slot. The reason for the order of one half
wavelength is based on the phase of the current which has a difference of
180° at both edges. The generated electromagnetic fields at the edges, which
are the product of multiplication of the current and the normal to the edge (which is opposed in direction at both edges) yields in-phase electromagnetic
fields and hence contribute to the radiation at desired directions.
In order to keep the antenna surface small as usually required for
mobile communication devices, the second ground plane may be folded or
placed above or below the first ground plane, and then the two layers may be
connected by pins or other metal members to achieve this continuation of the
ground plane and the generated currents. The latter enables the continuation
of the currents without affecting the vicinity of the antenna. This added layer
may be located in the gap required between the antenna and the
communication device, so the total volume remains the same. This gap is
required in order to eliminate cancellation of the electromagnetic field/s due
to reflected fields off the mobile communication device's PCB.
The folded ground plane may be further folded, e.g., by mean of a
third layer, in order to further enlarge its length, at the cost of complexity of
production.
As mentioned, the folded second ground plane also serves as a
reflector, which reflects the electromagnetic fields off the user's head
direction. Such reflector reduces the radiation at the user's head/body, and
increases the antenna gain mainly towards the half free space opposite to the user.
Further, The ground plane of the antenna can also be extended and folded at its feed side (instead of or in addition to the extension at its load
side), to minimize such radiation in the direction of the user. A practical
method to implement such second extension at the feed side of the ground
plane is to add another electrically conductive layer underneath the antenna, in the gap between the device's PCB and the antenna, which is electrically
connected to the grounded pin (or pins).
The electrical conductor serving as a continuation of the ground plane
may also be in the form of an added stub. Such an implementation of the
invention saves the need for an extra layer, simplifying the manufacturing and
assembly processes, as well as reducing the antenna cost.
Plated-through-holes (PTH), metal pins, pads, or any type of electrical
conductive members may connect the ground plane on one side and the
added stub on the other side.
The entire antenna may be produced on a single-layer flexible printed
circuit board then folded thereby eliminating the need for a separated second
layer and special connections thereto. It may also be produced on a single
dielectric substrate in which the electrical conductor serving as a continuation
of the ground plane is formed on the same face as the feed lines but
insulated therefrom.
The width of the electrical contacts controls the operational frequency
of the lower band. A narrow connection lowers the operational frequency of
the lower band, while a wider connection increases the operation frequency
of the lower band. The connection may be of the inductive type to act as a
low pass filter, and therefor would hardly affect the upper band.
The connection of the antenna to the mobile communication device can be through conductive pins. Either cylindrical, flat or other cross-section
pins can be used. The pins can be spring-loaded pins, rigid pins with elastic
elements on either the communication device's PCB or the antenna, or
threaded rigid pins. In another embodiment, conductive pins can be soldered
to the communication device.
Another method of connection can be through a coaxial connector.
The connection can also be made using a flexible PCB as the substrate of the
antenna, which can be directly mounted or connected via connector or
through pins to the PCB of the communication device.
In the preferred embodiments of the invention described below, the
antenna is of the type described in the above-cited US Patent No. 5,068,670
(of one of the joint inventors in the present application and incorporated by
reference herein), in that it includes an electrically conductive feed line carried
on a face of a dielectric substrate opposite to that serving as the ground
plane, and a slot formed in the ground plane having a feed side
electromagnetically coupled to the feed end of the feed line, and a load side
electromagnetically coupled to the load end of the feed line, such that the slot
is resonant and radiant at a predetermined high frequency band.
According to another aspect of the present invention, the slot formed
in the ground plane of such an antenna is curved.
The enhancement achieved by curving the slot is in reducing the overall size of the antenna board. Especially in the case of a slot with both
ends shorted, the effect of curving the slot is minimal regarding performance,
since the side arms of such slot are in the neighborhood of the slot's ends. As
described earlier, the electric and magnetic fields in a short ended slot vanish
at the end of such slot, and since they must be continuous, it follows that
their values near the ends of the slot are low and hence are not effected by
curving the slot. The region near the center of such slot is the most
significant, and the values of the fields are high.
The combination of such curved slot and a distributed feed line
(preferably similar on that described in US patent 5,068,670) provides
particularly good results especially with such small antennas.
A typical antenna dimension in a typical DCS/PCS frequencies (1800
and 1900 MHz) should be around 60-80 mm. This size is impractical for
modern mobile communication devices, where a typical room for an internal
antenna is in the range of only (35 - 45) mm X (12 - 30) mm. Prior art slots
used so far, such US Patent Nos. 5,929,813 and 6,025,802 (by Nokia) are fed
directly by pins. Further, the structure suggested by these patents are, in
fact, loop antennas rather than slot antennas.
PCT/US99/0085, WO 99/36988 (by Rangestar) presents slot antennas
for cellular handsets. This suggested antenna is fed by coax and therefore
there is no room for any impedance matching rather than the excitation point
position along the slot. This configuration is also complex regarding assembly,
since it must be soldered, and the wires of the coax may be often broken. Furthermore, the slot is straight rather than curved and is very small in length
as compared to the wavelength at the operating frequency, and hence its
efficiency and especially its operational bandwidth are inherently very poor.
Thus, curving the slot while yet exciting it by a distributed feed line having a feed end (preferably including a transformer effected by changing its
length and width in order to match the slot impedance) and a load end (which
includes a reactive load - either an open stub, short stub or lumped elements
for mainly reducing the reactive part of the slot impedance to a level of zero)
provides particularly excellent results (regarding radiation-efficiency, gain and
operational bandwidth) when curving the slot, and exciting it by a distributed
feed line.
A five-band antenna was built accordingly, fully covering the entire
800, 900, 1800, 1900 and 2400 MHz bands.
A multi-slot configuration can be made according to the present
invention, by having two slots excited either serially by the same feed line,
e.g., crossing the first slot at its excitation point, continuing to second slot,
crossing the second slot at its excitation point, and then having the load end
part of the feed line. This embodiment enables the entire antenna to operate
at the further frequency bands.
According to a further preferred embodiment, each of the slots (in
multi-slot configuration) may be excited by a separate feed line, the feed lines being in parallel to each other.
In another configuration according to the present invention, a further feed line may excite each of the two slots, while each of the feed lines
constructed according to either the series or parallel methods as
above-mentioned. It is to be appreciated that any combination of series and
parallel feed lines may apply to the latter antenna according to the present invention.
The electrical connection to the antenna can be at any suitable point
on the antenna. For example, plated through holes may be produced on the
antenna PCB at a pre-design stage, and pins from the communication device's
PCB may be inserted into these holes and soldered. In another possible
arrangement, spring loaded pins may produce the electrical connection by
direct contact with pads on the PCBs of the antenna and the communication
device. In a further possible arrangement, electromagnetic coupling between
a feed line on the communication device's PCB and the antenna can make the
electrical connection to the antenna.
A preferred implementation is to have the antenna (or at least one of
its layers, if more than one) an integral part of the communication device's
PCB. In the most general case, the device's PCB is a multi-layer PCB, and the
antenna can be easily produced directly on that PCB, thereby eliminating any
need for any further connection or a separate PCB. The conductive reflector if
applicable as a separate layer may then be a simple metal sheet placed close
to the front cover of the device's PCB, being electrically connected to the
antenna, e.g. by conductive pins.
A further implementation is to have the upper layer of the device's
PCB a flexible layer, containing the antenna and the conductive reflector on it,
in which either the ground panel or the conductive reflector panel is folded to
produce the final antenna.
Another preferred embodiment is to have the antenna an integral part
of the communication device's battery, which is usually placed on the backside of the communication device. In such structure, the contact
elements will preferably be of the type of spring-loaded pins. A preferred
position to place the antenna is in the top of the back side of the
communication device, in order to minimize interference with its operation
and performance while holding the communication device in the user's hands
and/or near the user's body/head.
It will thus be seen that the present invention may be implemented
by an antenna comprised of a resonant slot (i.e., "short ended" slot) cut in a
ground plane of a printed circuit board, excited by at least one feed line
crossing the slot at least at a single excitation point along the slot. This
excitation point is designed to optimize the slot impedance to the feed line
point at the desired operation frequency. The excitation may also be
performed by a dual feed line, to excite the slot symmetrically to ensure
symmetrical radiation of the slot, or asymmetrically to widen the frequency
bandwidth of operation by a combination of two different excitations. In order
to enhance the antenna efficiency, the load end side of the feed preferably is
of a reactive type rather than a matched load. The design of the feed end of
the feed line and the load end of the feed line may be made according to US
Patent No. 5,068,670, to maximize the operational bandwidth of the antenna.
The slot is preferably curved on the ground plane in which it was cut in, in
order to ensure the small size of the antenna.
The load end is, as above-mentioned, of a reactive load type. It may be a shorted stub (simulating a short circuit, where the end of the stub is
connected to the ground plane, e.g., by a plated-through-hole), an opened
stub (simulating an open circuit), or lumped element/s (simulating a reactive
load which may represent an impedance other than a short circuit or open
circuit). Any combination of reactive loads may serve as the load end in the
described antenna constructions.
As previously mentioned, modern mobile communication devices now
require dual or triple band of operation. Therefore, the slot is designed to
operate in the higher band/s (e.g., in the 1800 and/or 1900 MHz for cellular
phone devices). In order for the antenna to operate also in the lower
frequency band (e.g., in the 800 and/or 900 MHz for cellular phone devices),
an extension of the ground plane may be produced at the far end of the slot
by means of a sheet of metal electrically connected to the edge of the ground
plane to add a further band of operation to the antenna (e.g., in the 800
and/or 900 MHz for cellular phone devices). The added piece of ground plane,
together with the PCB of the mobile communication device, both tune the
lower operational frequency band. Since the PCB of the communication device
is pre-produced and in most cases is independent of the antenna design, the
tuning is usually controlled by the shape, length, width and type of
connection of the extended ground plane.
The above-mentioned extended ground plane may be applied on a
PCB folded to the other side of the antenna's PCB or as a second layer placed
either at an angle, or parallel, to the antenna's PCB in order to save surface of
the antenna. In a preferred implementation, the ground plane extension is made by means of feed line stubs on the other side of the antenna's PCB and
electrically connected to the ground plane by plated through hole/s or
conductive pin/s. These stubs are designed so they do not significantly
interfere with either the feed/s and load/s of the feed line exciting the slot or
the slot itself.
Further features and advantages of the invention will be apparent
from the description below.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention is herein described, by way of example only, with
reference to the accompanying drawings, wherein:
Fig. 1 illustrates one form of mobile communication device including
one arrangement for incorporating therein an internal antenna constructed in
accordance with the present invention;
Fig. 2 illustrates a mobile communication device including another
arrangement for incorporating therein an internal antenna constructed in
accordance with the present invention;
Fig. 3 illustrates one form of internal antenna constructed in
accordance with the present invention in its unfolded condition, Figs. 3a - 3c
diagrammatically illustrating how such an antenna may be folded;
Fig. 4 illustrates a construction similar to that of Fig. 3, but with a slot open at one end in the reflector, rather than closed at both ends as in Figs. 3;
Fig. 5 illustrates another form of internal antenna constructed in
accordance with the present invention also in its unfolded condition, Figs. 5a -
5c diagrammatically illustrating how such an antenna may be folded;
Fig. 6 illustrates an internal antenna constructed in accordance with
the present invention on a single flexible PCB (printed circuit board) in its
unfolded condition, Figs. 6a - 6c diagrammatically illustrating how such an
antenna may be folded;
Fig. 7 illustrates an internal antenna constructed on a single flexible
PCB in accordance with the present invention;
Figs. 7a - 7c illustrate how the PCB of Fig. 7 may be folded;
Figs. 8, 8a and 8b illustrate an internal antenna constructed on a
single rigid PCB layer;
Figs. 8a and 8b illustrate the opposite faces of the PCB of Fig. 8;
Figs. 9, 9a and 9b are views corresponding to those of Figs. 8, 8a,
and 8b, but illustrating a modification in the construction of that antenna;
Figs. 10, 10a, 10b and 10c illustrate an internal antenna constructed
on a single rigid PCB layer with some modifications comparing to Figs. 8;
Fig. 11 illustrates another form of internal antenna with double
reflectors, Figs. 11a - lie diagrammatically illustrating how such an antenna may be folded twice;
Figs. 12, 12a, 12b and 12c illustrate an internal antenna constructed
on a single rigid PCB layer with further modifications;
Figs. 13 and 13a-13c illustrate an internal antenna constructed in
accordance with the present invention on a single PCB having two slots fed by two feed lines, Figs. 13a and 13b illustrating the opposite faces of the PCB of
Fig. 13, and Fig. 13c illustrating a side view.
Figs. 14 and 14a - 14c illustrate a similar construction to Fig. 13 but with one feed line; and
Fig. 15 illustrates an antenna similar to Fig. 3 but with an open slot in
the reflector, Fig. 15a being a side view, and Figs. 15b and 15c showing the
assembly.
DESCRIPTION OF PREFERRED EMBODIMENTS
Fig. 1 illustrates the main components of a mobile communication
device, such as a cellular telephone handset, constructed in accordance with
the present invention. Such a device, generally designated 2, includes a front
cover 3, a main PCB (printed circuit board) 4, and a back cover 5 usually also
containing the battery (not shown). The foregoing components may be
conventional, and therefore further details are not set forth.
In accordance with the present invention, the mobile device 2
includes an internal antenna, generally designated 6, disposed between the
main PCB 4 and the back cover 5 and connected to the PCB by feeding pins 8.
In the embodiment illustrated in Fig. 1, the internal antenna 6 is located
substantially parallel to the plane of the main PCB 4 to which it is connected by the feeding pins 8. Fig. 2 illustrates a variation wherein the internal
antenna, therein designated 16, is disposed substantially perpendicularly to
the main PCB 4 to which it is connected by feeding pins 18.
The present invention deals primarily with the structure of the internal antenna e.g. 6, 16, as described below particularly with respect to the various
embodiments of such an internal antenna as illustrated in Figs. 3 - 15.
Figs. 3 and 3a - 3c illustrate one preferred construction for the
internal antenna 6 in Fig. 1 or the internal antenna 16 in Fig. 2.
Thus, as shown in Figs. 3 and 3a - 3c, the internal antenna, therein
designated 100, is constituted of two panels 101, 102 mechanically and
electrically connected together along one edge by one or more electrically
conductive pins 112 (only one being shown) passing through
plated-through-holes (PTH) Ilia, 111b. It will be appreciated that spring
loaded pins, or other pin types, may be used for connecting the two layers.
Panel 101 is a PCB (printed circuit board) constituted of a dielectric
substrate having an electrically-conductive layer 103 on one face, serving as
the ground plane and cut with a resonant slot 104. Slot 104 is of curved,
U-shaped configuration, closed at both of its ends, to define two closed side
arms 104a, 104b joined by a bridge 104c. Resonant slot 104 is excited by an electrically conductive feed line 105 carried on the face of the dielectric panel
101 opposite to that of the ground plane 103.
The embodiment illustrated in Fig. 3 is a symmetric construction, wherein the two side arms 104a, 104b are substantially parallel, of
substantially the same length and width, and are excited by a common excitation point, namely the point where the feed line 105 crosses the slot. It
will be appreciated, however, that the antenna could be of a non-parallel,
and/or an asymmetrical structure, wherein the closed side arms 104a, 104b
are non-parallel, have different lengths or widths, and/or are
non-symmetrically excited by the feed lines, respectively.
The electrically conductive feed line 105 (dashed line in Fig. 3) carried
on the opposite side of the PCB excites the slot 104. The main feed line arm
105a connects the input signal pin 108a, passing through a PTH, dividing the
power into two feed line transformer sections 105b and 105c, exciting the slot
104 at two points. The transformer sections 105b and 105c can be either
identical as in Fig. 3 or different in length and/or width. The feed line sections
105b and 105c continue from the excitation points underneath the slot and
perform the function of reactive loads 106a and 106b, respectively.
The reactive loads for this embodiment are shorted to the ground 103
on the other side of the PCB via the PTHs 107a and 107b, respectively. These
reactive loads enhance and improve the matching of the slot impedance; that
is, they mainly reduce the reactive part of the slot impedance to the order of
zero at a broad frequency range. Thus, the transmitted power is
electromagentically coupled off feed lines 105b and 105c to the slot 104,
enabling radiation off slot 104. The same applies to reception, where the
received power is electromagnetically coupled off slot 104 to feed lines 105b
and 105c.
The length and/or width of each arm of the feeding line 105, and/or
the reactive load 106, and/or each part of the slot 104a-104c, can be changed. These parameters, as well as the excitation point of the slot, the
height above the main PCB 4, and the angle between the antenna 6 or 16
and the main PCB 4, the distance between the pins 8 and the diameter
thereof, the substrate type and thickness, etc., set the higher frequency band
of the antenna. In this illustrated preferred embodiment of the present
invention, the structure is fully symmetric, and hence the radiation pattern off
slot 104 will be symmetrical.
An important feature of the present invention is that the internal
antenna 100 is resonant and radiant not only at a predetermined high
frequency, as determined by slot 104 cut in the ground plane 103, the
feeding line 105, and the reactive loads 106, but also at a lower frequency
band, so as to be capable of use as a multi-band microwave antenna. For this
purpose, the antenna 100 in Fig. 3 includes a further panel 102 (e.g. a PCB)
being an electrical conductor 110, electrically connected to the ground plane
103 by an electrically-conductive pin 112 (Figs. 3b, 3c) inserted in PTHs Ilia
and 111b preformed in panels 101 and 102, respectively. Electrical conductor
110 thus serves as a continuation of the ground plane 103 at the load side of
the slot 104. A slot 109 cut in electrical conductor 110 acts as an
electromagnetic load for slot 104 at the lower frequency band such as to
cause the slot to be resonant and radiant also at a lower frequency band. The
length and/or width of each arm 109a - 109c of slot 109 can be changed, as
well as the direction of the opening the slot and slot's position on electrical
conductor 110. The slot 109 may be different in length, width and shape as compared to slot 6 or 16. These parameters affect the low frequency's
behavior of the antenna 100.
The electrical conductor 110, in addition to its contribution to the
lower frequency band, also assists in reducing radiation at the user's head by
serving as a reflector for reflecting the electromagnetic waves scattered by
slot 104; it thereby also reduces the SAR level. Depending on the type and
structure of the antenna, the SAR is reduced by about 3 dB in a typical
CDMA TDMA/GSM frequency bands (800 and 900 MHz), and by more than 5
dB in a typical PCS/DCS frequency bands (1,800 and 1,900 MHz). Further, the
very high efficiency of the antenna enables the transmitted RF power level of
the communication device to be reduced, and thereby increases the user's
safety as well as the battery operational cycle between charges.
As indicated earlier, Fig. 3 illustrates a slot 104 having a symmetrical
dual feed structure by transformer sections 105b and 105c and reactive load
106a and 106b. Fig. 3 illustrates, three feed pins used according to that
embodiment: a signal feed pin 108a, and a pair of ground pins 108b and 108c
on opposite sides thereof. Such an arrangement maintains the structure's
symmetry and also reduces the characteristic impedance of the transmission
line representing the pins. The characteristic impedance of a three-pin
symmetrical structure is about one-half the characteristic impedance of a
two-pin structure. This makes it easier, in most cases, to match the antenna
to the output impedance of the transmitter and/or the input impedance of the
receiver through these pins.
The reactive load 106 matches the reactive part of the impedance of the slot 104 at each excitation point at the higher band. The reflector 102, in
addition to all parameters described above as affecting the high frequency
band, also matches the slot impedance in the lower band. The combined
impedance generated by the slot 104 and the reactive load 106, or the
reflector 102, is transmitted by the transformer sections 105b or 105c to the
junction between the main feed arm 105a and the transformer sections 105a
and 105b. Both impedances, from the two sides, are combined and mirrored
through the main feed arm 105a and the input pins 8 to the handset. The slot
104, the reactive load 106, the panel 102 (reflector 110), the feed line 105,
and the input pins 8 may be designed to ensure wide band operation for the
antenna, i.e., both at the lower band, and at one or more higher bands.
Fig. 3a illustrates a side view of the two panels 101, 102, before they
are mechanically and electrically connected; Fig. 3b illustrates one manner of
connecting the two panels, such that panel 101 containing the ground plane
103, slot 104 and feed line 105 overlie panel 102 containing the reflector 110
and slot 109 (may also be asymmetrical); whereas Fig. 3c illustrates the
reverse arrangement wherein panel 102 overlies panel 101. An important
antenna parameter is the angle formed between the two panels 101, 102. It
is possible to change the angle between the panels, to change the panel
which is the overlying one, as well as to change the face of the panel facing
upwardly, but such changes would require fine tuning of the feed line. In
addition, while Figs. 3, 3a, and 3b illustrate the two panels as being
mechanically and electrically interconnected together by a single pin 112 received within plated through holes Ilia and 111b, respectively, in the two
panels, it will be appreciated that a plurality of such pins and PTHs may be
used for this purpose.
Fig. 4 illustrates an antenna, designated 1000, similar to antenna 100
of Fig. 3, except the slot 109 in the conductive reflector 110 is open at one
end, as shown by arm 109d in Fig. 4.
Fig. 5 illustrates another construction of internal antenna, therein
generally designated 200, which is similar to the one illustrated in Fig. 3,
except that it includes only two feeding pins, namely, one signal pin 208a and
one ground pin 208b. This changes the characteristic impedance of the
transmission line representing the electrical interface between the antenna
and the handset. The location of the two feeding pins 208a, 208b is off the
center of the antenna; therefore, the radiation pattern is asymmetrical.
As seen in Fig. 5, in this embodiment the excitation of the slot 104 in
panel 101 is by a single feed line 205 and a single excitation point; also the
reactive load 206 is open-ended. This feed also makes the radiation pattern of
the antenna asymmetric.
The length and width of the feed line or the reactive load as well as
the excitation point, can be changed. The reflector panel 102 includes a
closed slot 109 cut in a conductive layer 110, as in Fig. 3. The characteristic
of reflector slot 109 can be different from the radiating slot 104 in the ground
plane 103. The closed side arms 109a and 109b of the reflector slot 109 can
be either identical or can differ from each other in length and width.
The two panels 101, 102 may be mechanically and electrically secured together in the desired relationship, and at the desired angle, by one
or more electrically-conductive pins shown at 112 in Figs. 5b and 5c. As
described above with respect to Figs. 3 and 3a - 3c, the relationship between
the two panels, and the angle defined by the two panels, may be altered
according to the particular application, and the feed line can be fine tuned
according to the desired order of panels and angle between the panels.
Fig. 6 illustrates an internal antenna, therein generally designated
300, which is similar to the antenna of Fig. 3 but is built on a single,
double-size, double-sided, flexible PCB panel, rather than on two rigid PCB
panels. Such a construction eliminates the need for the PTHs 111, and pins
112 in the assembly of Fig. 3. The two faces A, B of the single flexible panel
illustrated in Fig. 6 are prepared with the various elements as described
above with respect to Fig. 3, and as shown in side view in Fig. 6a; and the
single panel is then simply folded along the fold axis 317 to a predetermined
annular position as shown in Fig. 6b or in Fig. 6c, according to the particular
application.
The feed pins 108a - 108c, and the feed line 105, are similar to those
described above with respect to Fig. 3. The reactive load 206 is an open
reactive load, as in Fig. 5. The main difference in the antenna of Fig. 6 is the
addition of the open-ended tune stub 313. This stub enhances the bandwidth of the antenna, and improves the matching of the antenna to the handset. Its
length and width can be changed according to the particular application.
The electrically conductive layer defining the ground plane 103 at one
side of the panel is formed with an enlarged cut out or interruption (i.e., an
area without any conductor) 314 on the opposite side of the panel defining the reflector, to thereby define two stub reflectors 316a, 316b at the opposite
ends of the panel. The length and/or width of the stub reflectors 316a, 316b
can be the same for a symmetric structure, or different for a non-symmetric
structure providing a wider bandwidth. The two stub reflectors 316a, 316b
are electrically connected via reflector feeds 318a, 318b, and electrical
juncture section 315 to the ground plane 103. The two reflector feed 318a,
318b may be of the same length and width for a symmetrical structure, or of
a different length and/or width for a non-symmetrical structure to provide a
wider bandwidth. The juncture 315 acts like a filter and therefore its
dimensions (length and width) affect the low-frequency band.
Fig. 6a is an end view of the panel of Fig. 6 before it is folded; and
Figs. 6b and 6c illustrate two possible manners of folding the panel,
corresponding to the arrangements illustrated in Figs. 3b and 3c, respectively.
The shape of portion 314 of the dielectric substrate may be varied, as
desired, to change the length and/or width of the stub reflectors 316a, 316b
and of the reflector feeds 318a, 318b. In addition, the dielectric substrate
portion 314 may be formed with one or more openings to accommodate the
feeding pins 108.
The antenna illustrated in Fig. 7, therein generally designated 400,
is similar to antenna 300 illustrated in Fig. 6, and is also constructed on a
single flexible panel which is folded to produce the ground plane, slot and
feed line on one side, and the reflector on the opposite side. In this case, however, the radiating slot, therein designated 404, now formed in the
ground plane 103 is open ended, on both ends; that is, its two side arms
404a, 404b are open at one side and joined at the opposite side by a
bridge 404c. For this reason, the excitation of the slot 404 is different from
that described above with respect to Fig. 6.
Thus, in the antenna structure illustrated in Fig. 7, the tuning stub
313 is shorted to the ground plane 103 via a printed-through-hole (PTH) 419
to perform the main excitation of the slot 404. The feed line 105 with the
reactive loads 206 act as a secondary excitation of the slot to achieve a
multi-feed excited slot. The open side arms 404a and 404b can be either
identical to each other for a symmetrical structure, or can be of different
lengths and/or widths from each other for a non-symmetrical structure. The
excitation points of the slot 404 by the feed line can be symmetric or
non-symmetric as described above.
Fig. 7a is a side view of the flexible panel of Fig. 7, and Figs. 7b and
7c illustrate two possible arrangements for folding the flexible panel
corresponding to the arrangements illustrated in Figs. 6b and 6c, respectively.
Fig. 8 illustrates another antenna construction, generally designated
500, wherein the antenna is constructed on a single, rigid PCB panel, having
an upper face as shown in Fig. 8a and a lower face as shown in Fig. 8b. such
an arrangement eliminates the need to fold a flexible panel, or to connect
together two panels, when assembling the antenna into the handset.
The upper face of the panel (Fig. 8a) is provided with an
electrically-conductive layer serving as ground plane 103, and with the radiating slot 104 cut in the ground plane. In addition, the
electrically-conductive layer in the opposite edges of the ground plane 103 is
removed, to provide the interruptions 521a, 521b in the ground plane, that is
areas without any conductor.
The opposite face of the PCB, as shown in Fig. 8b, is formed with
feed line 105, tuning stub 313 and with the reflector comprising the two stub
reflectors 520a, 520b (corresponding to stub reflectors 316a, 316b in Fig. 7),
connected by the reflector feeds 522a, 522b (corresponding to reflector feeds
318a, 318b in Fig. 7). In the construction of Fig. 8, however, the stub
reflectors 520a, 520b are excited by a PTH 523 connected to the ground
plane 103 in the opposite (upper) side of the PCB. The feed reflectors 522a,
522b, thus act as transformers to the stub reflectors 520a, 520b, such that
the reflector function in the antenna construction of Fig. 7, is now fulfilled by
the stub reflectors 520a, 520b and feed reflectors 522a, 522b formed on the
same face (lower face) of the PCB panel as the feed line 105 and the tuning
stub 313 in the antenna construction of Fig. 8. The interruptions 521a, 521b
in the ground plane provide a further control parameter for the lower
frequency band, and may also enhance the radiation and impedance
matching of the antenna.
The interruptions 521a, 521b in the ground plane 103, the stub
reflectors 520a, 520b, and the feed reflectors 522a, 522b can be symmetrical
as illustrated in Fig. 8, or can be non-symmetrical. The dimensions of these
elements, including their lengths and/or widths can be varied to control the
low band behavior of the antenna. The slot 104 cut in the ground plane 103, the feed line 105, the tuning stub 313, and the reactive loads 206a, 206b,
may be of the same configuration as described above particularly with respect
to the antenna of Fig. 6, but their dimensions would be different due to the
fact that the length of the ground plane 103 is smaller because of the
interruptions 521a, 521b.
It will be appreciated that the single-panel construction illustrated in
Fig. 8 simplifies the manufacture and assembly of the antenna, and therefore
reduces its cost.
Fig. 9 illustrates an antenna construction, generally designated
600, which is very similar to that of Fig. 8, except the radiating slot therein
designated 604, is a half-open slot. That is, one side arm 604a is open,
and the other side arm 604b is closed, the two side arms being connected
together to a bridge 604c.
Another variation in the construction of antenna 600 illustrated in Fig.
9 is that it includes two feed pins 208a, 208b, rather than three feed pins
108a - 108c as in Fig. 8. The feed line 105 is of the dual-feed type, exciting
the two side arms 604a, 604b of the slot 604.
Further modification is that, in order to have a wide band operation in
the high band, two kinds of reactive loads are provided in antenna 600
illustrated in Fig. 9, namely: a reactive load 106 shorted via PTH 107 to the
ground plane 103, and a reactive load 206 which is open ended. Such an
arrangement provides a non-symmetrical structure, with the operation in the
low band being the same as in antenna 500 illustrated in Fig. 8.
Fig. 10 illustrates an antenna construction, generally designated
700, similar to design 500 presented in Fig. 8 but with several important
modifications. Antenna design 700 is constructed on a single rigid PCB,
having an upper face shown in Fig. 10a and a lower face shown in Fig.
10b. Fig. 10c presents the side view.
The upper face (Fig. 10a) is provided with a slot 104 cut in the
ground plane 103 as in design 500, but here there is only one interruption
521 in the ground plane 103, while on the other side of the upper face, a
reflector extension 724 is connected to the stub reflector 520a on the
lower side through the PTH 523a. Thus a gap 725 is created between the
ground plane 103 and the reflector extension 724. The slot 104 is not in a
U shape but further folded at its ends.
The lower face of antenna design 700, shown in Fig. 10b,
demonstrates a major difference comparing to design 500. The excitation
point, PTH 523, of the stub reflectors 520a and 520b is not symmetric
therefore the feed reflectors 522a and 522b are not symmetrical. Further
more, on one side the stub reflector 520a is extended to the upper face of
the antenna connected through PTH 523a to reflector extension 724, while
on the other side the stub reflector 520b is folded, creating the arm
reflector 726.
Thus, by the non-symmetrical structure of the reflectors an
additional frequency band can be added to the antenna in the low band.
By controlling the location of PTH 523, the width and length of each feed
reflector 522a and 522b, each stub reflector 520a and 520b, the arm
reflector 726, the reflector extension 724 and the gap 725 the antenna can
be separately tuned to operate in two low frequency bands.
Another difference is the absence of the tuning stub 313 as in
design 500. Instead, the tuning stub 713 is connected directly to the signal
input pin 108a.
While the stub reflectors shown are open ended, it is appreciated
that each of the stub reflectors can also be grounded at its end, either by a
PTH or even directly - in the case of extended stub reflector 724.
Fig. 11 illustrates an antenna design, generally designated 800, similar to design 200 of Fig. 5, with two major modifications. First, the electrically-conductive layer 110 defining the reflector is continuous and
unslotted, rather than being formed with a slot as shown at 109 in Fig. 5.
Second, another panel, 102', with continuous electrically-conductive layer
110' is presented. This panel, 102', is connected to panel 102 with pin 112'
through PTHs 111c and Hid. Figs, lib and lie present the antenna in its
double folded position.
Fig. 12 illustrates an antenna, generally designated 900, similar to
antenna 500 of Fig. 8, except that here the stub reflectors 520a and 520b are
inwardly of the reactive loads 206a and 206b of the feed line 105, respectively.
Fig. 13 illustrates an antenna, generally designated 1100, wherein the
antenna is constructed on a single, rigid PCB panel, having an upper face as shown in Fig. 13a and a lower face as shown in Fig. 13b. The two slots, 104
and 104', cut in the ground plane 103, have a dual feed and a symmetrical
construction. Feed line 105 and its reactive loads 206a and 206b symmetrically excite slot 104. Feed line 105' with its reactive loads 206a' and
206b' does the same to slot 104'. The combined impedances of each slot with
its reactive loads and its feed line are parallel summed to the input pins 108.
Although the design shown here is totally symmetrical, the slots 104 and 104',
the feed lines 105 and 105', the reactive loads 206 and 206' and the
excitation point of each one of them can be asymmetrical.
Fig. 13c shows a side view of antenna 1100, wherein the upper and
lower side of the antenna can alter.
Fig. 14 illustrates an antenna, generally designated 1200, similar to
antenna 1100 (Fig. 13) except that the slots 104 and 104' cut in the ground
plane 103 have a single feed point and a single feed line 205. The feed line
205 has a transformer section between the two slots to improve the
matching. Thus both slots have a single reactive load. The impedances here
are summed in series. Slots 104 and 104' have a symmetrical structure, but
this in not essential. Fig. 14a illustrates the upper side, and Fig. 14b the lower
side while Fig. 14c is a side view.
Fig. 15 illustrates an antenna, generally designated 1300, similar to
antenna 100 in Fig. 3 except that the slot 1309 cut in the ground continuation
110 of panel 102 is open ended at both sides. Thus both identical and parallel
side arms 1309a and 1309b connected by the bridge 1309c are open at one
end. The side arms 1309a and 1309b can be different from each other to
have an asymmetrical construction. The electrically conductive plane 110 is
thus floating.
While the invention has been described with respect to several
preferred embodiments, it will be appreciated that these are set forth merely for purposes of example, and that many other variations of the invention may
be made. For example, any of the described antenna constructions may
include any of the described feeding pins, and at any angle with respect to
the main PCB. Conductive paths from one side of a substrate to the opposite
side may be by conductor pins, plated-through-holes (PTH), or both. The
number of signal feeding pins may vary according to the particular
application; for example, in some applications it may be desirable to have one
signal pin and a circular array of ground pins (e.g., four), to simulate a coax
feed.
Many other variations, modifications and applications of the invention
will be obvious to those skilled in the art.
Claims (45)
1. A multi-band antenna which is resonant and radiant at a high
frequency band and at least one lower frequency band, comprising:
a dielectric substrate having opposed faces;
an electrically-conductive layer serving as a ground plane on one
face of the dielectric substrate;
an electrically conductive feed line carried on the opposite face of
the dielectric substrate, said feed line having at least one feed end and at
least one load end;
a slot formed in said ground plane having a feed side and a load
side with respect to said feed end and load end, said slot being
electromagnetically coupled to said feed line such that said slot is resonant
and radiant at said high frequency band; and a further electrical conductor electrically connected to said
ground plane to serve as a continuation thereof at the load side of said
slot, said further electrical conductor being dimensioned, located and
electromagnetically coupled to said slot at said lower frequency band such
as to cause said slot to be resonant and radiant also at said at least one
lower frequency band.
2. The antenna according to Claim 1, wherein said further electrical
conductor serving as a continuation of the ground plane is also in the form of
an electrically-conductive layer and also acts as a reflector.
3. The antenna according to Claim 2, wherein said latter
electrically-conductive layer is continuous and unslotted.
4. The antenna according to Claim 2, wherein said latter
electrically-conductive layer is formed with a slot closed at both ends.
5. The antenna according to Claim 2, wherein said latter
electrically-conductive layer is formed with a slot open at at least one end.
6. The antenna according to Claim 1, wherein said further electrical
conductor serving as a continuation of the ground plane is a conductor
shaped to define at least one stub reflector.
7. The antenna according to Claim 6, wherein said ground plane is
interrupted at the side thereof in alignment with said stub reflector.
8. The antenna according to Claim 1, wherein said further electrical conductor serving as a continuation of the ground plane is shaped to define
two stub reflectors each electrically connected to said ground plane by a reflector feed.
9. The antenna according to Claim 1, wherein said further electrical
conductor serving as a continuation of the ground plane is carried on a
second dielectric substrate secured at an angle to said dielectric substrate of
the ground plane, to form an assembly in which the two electrically-conductive layers are electrically connected together.
10. The antenna according to Claim 1, wherein said dielectric
substrate is flexible; is formed on one portion with said ground plane, feed
line and slot, and on another portion with said further electrical conductor
serving as a configuration of the ground plane; and is folded at a
predetermined angle with the two electrically-conductive layers connected
together.
11. The antenna according to Claim 1, wherein said further electrical
conductor serving as a continuation of the ground plane is carried on the
same dielectric substrate as said ground plane.
12. The antenna according to Claim 11, wherein said further electrical
conductor serving as a continuation of the ground plane is carried on the
same face of said dielectric substrate as said feed line but is insulated
therefrom.
13. The antenna according to Claim 11, wherein said further electrical
conductor serving as a continuation of the ground plane is in the form of stub
reflectors.
14. The antenna according to Claim 1, wherein said slot in the ground
plane is curved.
15. The antenna according to Claim 1, wherein said feed line includes at least a pair of feed ends and a power divider which divides the power
between said pair of feed ends.
16. The antenna according to Claim 1, wherein each feed end
includes a change in dimension to match the impedance of the respective part
of the slot at the feed side of the slot.
17. The antenna according to Claim 1, wherein each load end
includes a change in dimension to match the impedance of the respective part
of the slot to the load side of the slot.
18. The antenna according to Claim 1, wherein each load end of the
feed line includes a reactive load.
19. The antenna according to Claim 1, wherein said slot in the ground
plane is closed at both ends.
20. The antenna according to Claim 1, wherein slot in the ground
plane is open at least at one end.
21. The antenna according to Claim 1, wherein said ground plane is
formed with two curved slots electromagnetically coupled to said feed line.
22. The antenna according to Claim 1, wherein said ground plane is
formed with two curved slots, and said dielectric substrate includes two feed
lines electromagnetically coupled to said two curved slots.
23. A microwave antenna resonant and radiant at a high frequency
band, comprising:
a dielectric substrate having opposed faces; an electrically-conductive layer serving as a ground plane on one
face of the dielectric substrate; an electrically conductive feed line carried on the opposite face of
the dielectric substrate, said feed line having at least one feed end and at
least one load end; and a curved slot formed in said ground plane having a feed side
and a load side and a load side with respect to said feed end and load end,
said slot electromagnetically coupled to said feed line, such that said slot is
resonant and radiant at said high frequency band.
24. The antenna according to Claim 23, wherein said curved slot is
substantially of a U-configuration, including two side arms joined by a bridge.
25. The antenna according to Claim 23, wherein said feed line
includes at least a pair of feed ends and a power divider which divides the
power between said pair of feed ends.
26. The antenna according to Claim 25, wherein said feed line
includes a tuning stub to match the input impedance of said slot.
27. The antenna according to Claim 25, wherein said pair of feed
ends of the feed line are symmetrically coupled to said curved slot.
28. The antenna according to Claim 23, wherein each feed end
includes a change in dimension to match the impedance of the respective part
of the slot at the feed side of the slot.
29. The antenna according to Claim 23, wherein each load end includes a change in dimension to match the impedance of the respective part
of the slot to the load side of the slot.
30. The antenna according to Claim 23, wherein each load end of the
feed line includes a reactive load.
31. The antenna according to Claim 23, wherein said curved slot in
the ground plane is closed at both ends.
32. The antenna according to Claim 23, wherein said curved slot in
the ground plane is open at at least one end.
33. An antenna according to Claim 23, wherein said antenna includes
a further electrical conductor electrically connected to said ground plane to
serve as a continuation thereof at the load side of said slot and
electromagnetically coupled to said slot at least at one lower frequency band such as to cause said slot also to be resonant and radiant at said lower
frequency.
34. The antenna according to Claim 33, wherein said further electrical
conductor serving as a continuation of the ground plane is also in the form of
an electrically-conductive layer and also acts as a reflector.
35. The antenna according to Claim 43, wherein said latter
electrically-conductive layer is continuous and unslotted.
36. The antenna according to Claim 34, wherein said latter
electrically-conductive layer is also formed with a slot.
37. The antenna according to Claim 33, wherein said further electrical conductor serving as a continuation of the ground plane is a shape to define
at least one stub reflector.
38. The antenna according to Claim 37, wherein said ground plane is
interrupted at the side thereof in alignment with said stub reflector.
39. The antenna according to Claim 33, wherein said further electrical
conductor serving as a continuation of the ground plane is carried on a
second dielectric substrate secured at an angle to said dielectric substrate of
the ground plane, to form an assembly in which the two
electrically-conductive layers are electrically connected together,
40. The antenna according to Claim 33, wherein said further electrical
conductor serving as a continuation of the ground plane is carried on the face
of said dielectric substrate carrying said feed line but electrically insulated
therefrom.
41. The antenna according to Claim 23, wherein said ground plane is
formed with two curved slots electromagnetically coupled to said feed line.
42. The antenna according to Claim 23, wherein said ground plane is
formed with two curved slots, and said dielectric substrate includes two feed
lines electromagnetically coupled to said two curved slots.
43. An antenna which is resonant and radiant at a predetermined frequency band, comprising:
an electrically-conductive ground plane;
and an electrical conductor electrically connected to said ground
plane to serve as a continuation thereof, said electrical conductor being
dimensioned, located and electromagnetically coupled to said antenna such
as to enhance the operation thereof at said predetermined frequency band.
44. The antenna according to Claim 43, wherein said further electrical conductor serving as a continuation of the ground plane is in the form of an
electrically-conductive layer and also acts as a reflector.
45. The antenna according to Claim 43, wherein said antenna further comprises:
an electrically conductive feed line having at least one feed end
and at least one load end;
and a slot formed in said ground plane having a feed side and a
load side with respect to said feed end and load end, said slot being
electromagnetically coupled to said feed line such that said slot is resonant
and radiant at a higher frequency band than said predetermined frequency
band.
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US09/649,023 US6466176B1 (en) | 2000-07-11 | 2000-08-28 | Internal antennas for mobile communication devices |
US09/649,023 | 2000-08-28 | ||
PCT/IL2001/000626 WO2002005384A1 (en) | 2000-07-11 | 2001-07-09 | Internal antennas for mobile communication devices |
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AU2001269413B2 AU2001269413B2 (en) | 2005-08-04 |
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AU6941301A Pending AU6941301A (en) | 2000-07-11 | 2001-07-09 | Internal antennas for mobile communication devices |
AU2001269413A Ceased AU2001269413B2 (en) | 2000-07-11 | 2001-07-09 | Internal antennas for mobile communication devices |
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Application Number | Title | Priority Date | Filing Date |
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AU6941301A Pending AU6941301A (en) | 2000-07-11 | 2001-07-09 | Internal antennas for mobile communication devices |
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EP (2) | EP2063490A1 (en) |
JP (2) | JP4156921B2 (en) |
KR (2) | KR100790941B1 (en) |
CN (1) | CN100416919C (en) |
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IL (2) | IL153802A0 (en) |
NZ (1) | NZ523541A (en) |
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DE29925006U1 (en) | 1999-09-20 | 2008-04-03 | Fractus, S.A. | Multilevel antenna |
US6680704B2 (en) | 2001-05-03 | 2004-01-20 | Telefonaktiebolaget Lm Ericsson(Publ) | Built-in patch antenna |
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- 2001-07-09 ES ES01947774T patent/ES2315288T3/en not_active Expired - Lifetime
- 2001-07-09 CN CNB018154727A patent/CN100416919C/en not_active Expired - Fee Related
- 2001-07-09 IL IL15380201A patent/IL153802A0/en active IP Right Grant
- 2001-07-09 NZ NZ523541A patent/NZ523541A/en unknown
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