Title of Invention

"A PLANAR INVERTED-F ANTENNA HAVING A PLURALITY OF RESONANT FREQUENCY BANDWIDTHS OF OPERATION"

Abstract A planar inverted-F antenna (20) having a plurality of resonant frequency bandwidths of operation, comprising a signal feed (28), a ground feed (25); and a conductive element (21) in communication with the signal and ground feed (28, 25), the conductive element (21) comprising a looped track (22) that, in operation, provides a high band resonator and a low band resonator, the looped track conductive element (22) having a length (L1) and width (W1) and center aperture (22a) having a length (L2) and width (W2), and wherein the looped track (22) is continuous and comprises four sides (221, 222, 223, 224) with four corner portions that define a track perimeter enclosing the center aperture (22a), with adjacent sides being contiguous about corner portions thereof, wherein corresponding pairs of the four sides (221, 222, 223, 224) face each other across the center aperture (22a), and wherein one corresponding pair (221,223 ) has a longer length than the other pair (222,224), and wherein the ground and signal feeds (25, 28) are positioned adjacent each other proximate a common outer edge portion (221) of the looped track (22), such that the conductive element (21), configured by the dimension of the looped track (22) and the center aperture (22a) and the position of the ground and the signal feed (25, 28), defines about a ½ wave resonator at a low frequency band and defines two about ½ wave resonators at a high frequency band when operating as the high band resonator.
Full Text The present invention relates to a planar inverted-f antenna having a plurality of resonant frequency bandwidths of operation.
FIELD OF THE INVENTION The present invention relates to the field of communications, and, more particularly, to antennas and wireless terminals incorporating the same.
BACKGROUND OF TEE INVENTION
The size of wireless terminals has been decreasing with many contemporary wireless terminals being less than 11 centimeters in length. Correspondingly, there is increasing interest in small antennas that can be utilized as internally mounted antennas for wireless terminals. Inverted-F antennas, for example, may be well suited for use within the confines of wireless terminals, particularly wireless terminals undergoing miniaturization. Typically, conventional inverted-F antennas include a conductive element that is maintained in a spaced apart relationship with a ground plane. Exemplary inverted-F antennas are described in U.S. Patent Nos. 6,538,604 and 6,380,905, which are incorporated herein by reference in their entirety.
Furthermore, it may be desirable for a wireless terminal to operate within multiple frequency bands in order to utilize more than one communications system. For example, Global System for Mobile communication (GSM) is a digital mobile telephone system that typically operates at a low frequency band, such as between 880 MHz and 960 MHz. Digital Communications System (DCS) is a digital mobile telephone system that typically operates at high frequency bands, such as between 1710 MHz and 1880 MHz. In addition, global positioning systems (GPS) or Bluetooth systems use frequencies of 1.575 or 2.4-2.48 GHz. The frequency bands allocated for mobile terminals in North America include 824-894 MHz for Advanced Mobile Phone Service (AMPS) and 1850-1990 MHz for Personal Communication Services (PCS). Other frequency bands are used in other jurisdictions. Accordingly, internal antennas are being provided for operation within multiple frequency bands. Conventionally, PIFA configurations have branched structures such as described in U.S. Patent No. 5,926,139, and position the PIFA a relatively large distance, typically from about 7-10 mm, from the ground plane to radiate effectively. Kin-Lu Wong, in Planar Antennas for Wireless Communications, Ch. 1, p. 4, (Wiley, Jan. 2003), illustrates some potential radiating top patches for dual-frequency PIFAS. The contents of each of these references are hereby incorporated by reference in their entirety herein. Despite the foregoing, there remains a need for alternative multi-band planar antennas.
SUMMARY OF THE INVENTION
Embodiments of the present invention provide antennas for communications devices and wireless terminals. The antennas include a looped conductive planar element that may be particularly suitable for a planar inverted-F antenna (PIFA) element.
In certain embodiments, planar inverted-F antennas are configured to operate at a plurality of resonant frequency bandwidths of operation (typically between about 2-4) and include: (a) a signal feed; (b) a ground feed; and (c) a looped conductive element in communication with the signal and ground feed.
In certain embodiments, the antennas can be positioned about 3 mm from the ground plane that may be provided by a printed circuit board (overlying or underlying the looped antenna element). The ground plane may also be looped in a size and configuration that substantially corresponds to the looped conductive element.
In some embodiments, the looped conductive element is configured with a center aperture that extends substantially the entire distance between the internal edge portions of the looped conductive element. The conductive element can have a substantially rectangular shaped perimeter, with each side being contiguous with the two adjacent sides, the perimeter with a width of about 37 mm and a height of about 46.5 mm.
In particular embodiments, the antenna is configured to operate at a first (low band) of between about 824-894 MHz and at least one second (high band) of between about 1850-1990 MHz.
Certain embodiments are directed to a planar inverted-F antenna having a plurality of resonant frequency bandwidths of operation. The PIFA includes: a signal
feed; a ground feed; and a conductive element in communication with the signal and ground feed. The conductive element includes a looped track element that, in operation, provides a high band resonator and a low band resonator.
Other embodiments are directed toward wireless terminals. The wireless terminals include: (a) a housing configured to enclose a transceiver that transmits and receives wireless communications signals; (b) a ground plane disposed within the housing; (c) a planar inverted-F antenna disposed within the housing and electrically connected with the transceiver; (d) a signal feed electrically connected to a looped track element; and (e) a ground feed electrically connected to the looped track element proximate the signal feed. The antenna includes: a planar dielectric substrate and a planar conductive element disposed on the planar dielectric substrate. The conductive element includes a looped track conductive element having a length and width and a center portion encased by the looped track, the looped track being configured to define about a VA wave resonator at a low frequency band and about a½ wave resonator at a high frequency band.
In certain embodiments, the looped track element comprises an endless perimeter with four sides, wherein the ground and signal feeds are positioned adjacent each other proximate a common side at an upper or lower edge portion of the common side of the looped track element.
Still other embodiments are directed to methods for exciting a planar inverted F antenna having low and high band operational modes. The method includes: (a) providing a conductive element with a looped track element, the looped track element configured to form about a ¼ wave resonator at a low frequency band and about a ½ wave resonator at a high frequency band; (b) generating a current null along at least one portion of the looped track at a selected low band operation; and (c) generating a current null at two spaced apart portions (typically substantially opposing sides) of the looped track at a selected high band operation.
These and other embodiments will be described further below.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1A is an enlarged schematic top view of a looped planar inverted-F antenna configuration according to embodiments of the present invention;
Figure 1B is a schematic diagram of the antenna shown in Figure 1A with an exemplary simulated high band radiation partem with in-phase current as indicated by the current vectors.
Figure 1C is a schematic diagram of the antenna shown in Figure 1A with an exemplary simulated low band % wave resonance pattern with current direction indicated by the current vectors.
Figure 1D is a top view of a looped antenna illustrating a high band current vector plot according to embodiments of the present invention.
Figure 1E is a top view of a looped antenna similar to that shown in Figure 1D but with supplemental tuning features according to embodiments of the present invention.
Figure 2 A is a top view of another looped planar inverted-F antenna according to embodiments of the present invention.
Figure 2B is a VSWR graph at 3mm and 6mm height (from a ground plane) of the antenna shown in Figure 2 A. The 6mm (higher) element is shown with a heavier line weight.
Figure 2C is a polar coordinate graph of a front elevation radiation partem at 1850 MHz of the antenna shown in Figure 2 A measured at about a 6 mm antenna height.
Figure 2D is a polar coordinate graph of a front elevation radiation pattern at 1990 MHz of the antenna shown in Figure 2 A measured at about a 6 mm antenna height.
Figure 3 A is a top view of a planar inverted-F antenna according to additional embodiments of the present invention.
Figure 3B is a VSWR. graph of the antenna shown in Figure 3A positioned at about 3 mm from the ground plane.
Figure 3C is a polar coordinate graph of a front elevation radiation pattern at 1580 MHz (GPS) of the antenna shown in Figure 3A measured at about a 3 mm antenna height.
Figures 3D-3F are polar coordinate graphs of a front elevation, side elevation, and azimuth directions, respectively, of the radiation pattern at 2.1 GHz of the antenna shown in Figure 3A measured at about a 3 mm antenna height.
Figure 4 A is a top view of a planar inverted-F antenna according to yet other embodiments of the present invention.
Figure 4B is a VSWR graph of the antenna shown in Figure 4A positioned at about a 3 mm height from the ground plane.
Figure 4C is a polar coordinate graph of a front elevation radiation pattern at 1850 MHz of the antenna shown in Figure 4A measured at about a 3 mm antenna height.
Figure 4D is a polar coordinate graph of a front elevation radiation pattern at 1990 MHz of the antenna shown in Figure 4A measured at about a 3 mm antenna height.
Figure 5A is a top view of a planar inverted-F antenna according to still further embodiments of the present invention.
Figure 5B is a VSWR graph of four different resonant bands provided by the antenna shown in Figure 5A.
Figure 6A is a looped antenna configuration with a gray scale pattern of current density at 0.95 GHz with a scale ranging from Odb to -40db of electric current (with 0 db =29.796 A/m).
Figure 6B is the looped antenna configuration shown in Figure 6A with a gray scale pattern of current density at 2.4 GHz with a scale ranging from Odb to -40db of electric current (with 0 db =29.796 A/m).
Figure 7 is a VSWR plot of a basic looped design antenna according to embodiments of the present invention.
Figures 8 A and 8B are top views of a looped antenna configuration with current vectors illustrating that high band currents can oscillate between opposing corners according to embodiments of the present invention.
Figure 9A is top view of a looped antenna with a modified ground plane design that substantially corresponds to the looped antenna configuration according to embodiments of the present invention.
Figure 9B is a VSWR plot of the antenna shown in Figure 9A.
Figure 10 A is a top view of the antenna shown in Figure 4 A with a simulated excitation of the antenna at 1850 MHz operation according to embodiments of the present invention.
Figure 10B is the simulated radiation partem of the average current simulation shown in Figure 10A.
Figure 10C is a top view of the antenna shown in Figure 4A with a simulated excitation of the antenna at 1990 MHz operation according to embodiments of the present invention.
Figure 10D is the simulated radiation pattern of the average current simulation shown in Figure IOC.
Figure 11A is a top view of the antenna shown in Figure 2 A with a simulated excitation of the antenna at 1850 MHz operation according to embodiments of the present invention.
Figure 11B is the simulated radiation pattern of the average current simulation shown in Figure 11 A.
Figure 11C is a top view of the antenna shown in Figure 2 A with a simulated excitation of the antenna at 1990 MHz operation according to embodiments of the present invention.
Figure 11D is the simulated radiation pattern of the average current simulation shown in Figure 11C.
Figure 12 is a partial side view of a wireless communication device according to embodiments of the present invention.
Figures 13A-13C are schematic front views of wireless communication devices having a looped antenna configuration positioned about the perimeter of a display according to embodiments of the present invention.
Figures 14A-14C are schematic front views of wireless communication devices having a looped antenna configuration positioned about the perimeter of a keypad or keyboard according to embodiments of the present invention.
DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout. It will be appreciated that although discussed with
respect to a certain antenna embodiment, features or operation of one antenna embodiment can apply to others.
In the drawings, the thickness of lines, layers, features, components and/or regions may be exaggerated for clarity. It will be understood that when a feature, such as a layer, region or substrate, is referred to as being "on" another feature or element, it can be directly on the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another feature or element, there are no intervening elements present. It will also be understood that, when a feature or element is referred to as being "connected" or "coupled" to another feature or element, it can be directly connected to the other element or intervening elements may be present. In contrast, when a feature or element is referred to as being "directly connected" or "directly coupled" to another element, there are no intervening elements present. The terms "looped" or "loop" track means a track or trace having a closed or substantially closed turn or an endless configuration.
Embodiments of the present invention will now be described in detail below with reference to the figures. The inverted-F conductive element can be configured to operate at a plurality, typically at least first and second, of resonant frequency bands and, in certain particular embodiments, can also be configured to operate at a third or more resonant frequency bands. Antennas according to embodiments of the present invention may be useful in, for example, multiple mode wireless terminals that support two or more different resonant frequency bands, such as world phones and/or dual mode phones. In certain embodiments, the antennas of the present invention can operate in a low frequency band and a high frequency band. The terms "low frequency band" or "low band" are used interchangeably and, in certain embodiments, include frequencies below about 1 GHz, and typically comprises at least one of 824-894 MHz or 880-960 MHz. The terms "high frequency band" and "high band" are used interchangeably and, in certain embodiments, include frequencies above 1 GHz, and typically frequencies between about 1.5-2.5 GHz. Frequencies in high band can include selected ones or ranges within about 1700-1990 MHz, 1990-2100 MHz, and/or 2.4-2.485 GHz.
In certain particular embodiments, the high frequency band may include frequencies that are less than twice that of the frequencies of the low frequency band.
For example for a low band mode operating with frequencies between about 824-894 MHz, the high band mode can operate at frequencies below about 1.648-1.788 GHz.
In certain embodiments, the antenna may be configured to provide resonance for a global positioning system (GPS) as the terminal into which this antenna is to be built, can include a GPS receiver. GPS operates at approximately 1,575 MHz. GPS is well known to those skilled in the art. GPS is a space-based triangulation system using satellites and computers to measure positions anywhere on the earth. Compared to other land-based systems, GPS is less limited in its coverage, typically provides continuous twenty-four hour coverage regardless of weather conditions, and is highly accurate. In the current implementation, a constellation of twenty-four satellites that orbit the earth continually emit the GPS radio frequency. The additional resonance of the antenna as described above permits the antenna to be used to receive these GPS signals.
As used herein, the term "wireless terminal" may include, but is not limited to, a cellular wireless terminal with or without a multi-line display; a Personal Communications System (PCS) terminal that may combine a cellular wireless terminal with data processing, facsimile and data communications capabilities; a PDA that can include a wireless terminal, pager, internet/intranet access, web browser, organizer, calendar and/or a GPS receiver; and a conventional laptop and/or palmtop receiver or other appliance that includes a wireless terminal transceiver. Wireless terminals may also be referred to as "pervasive computing" devices and may be mobile terminals.
It will be understood by those having skill in the art of communications devices that an antenna is a device that may be used for transmitting and/or receiving electrical signals. During transmission, an antenna may accept energy from a transmission line and radiate this energy into space. During reception, an antenna may gather energy from an incident wave and provide this energy to a transmission line. The amount of power radiated from or received by an antenna is typically described in terms of gain.
Voltage Standing Wave Ratio (VSWR) relates to the impedance match of an antenna feed point with a feed line or transmission line of a communications device, such as a wireless terminal. To radiate radio frequency energy with minimum loss, or to pass along received RF energy to a wireless terminal receiver with minimum loss, the impedance of a wireless terminal antenna is conventionally matched to the
impedance of a transmission line or feed point. Conventional wireless terminals typically employ an antenna that is electrically connected to a transceiver operatively associated with a signal processing circuit positioned on an internally disposed printed circuit board. In order to increase the power transfer between an antenna and a transceiver, the transceiver and the antenna may be interconnected such that their respective impedances are substantially "matched," i.e., electrically tuned to compensate for undesired antenna impedance components, to provide a 50-Ohm (Ω) (or desired) impedance value at the feed point.
Referring to Figure 1A, the antenna 20 includes a conductive element 21 with at least one conductive looped track element 22 having four sides 221, 222,223 and 224. As shown, edge portions of adjacent sides are contiguous. The looped track element 22 also has an associated center aperture 22a. The antenna 20 includes a signal feed 28 and ground feed 25. In certain embodiments, the ground 25 may be positioned on a common side portion of the element 21 below the signal feed 28 a distance of about 3-6 mm.
As shown, the center aperture 22a can be sized with a length and width, L2, W2, respectively, that separate the inner perimeter of the track a sufficient distance to inhibit parasitic coupling of opposing sides of the track. Examples of separation distances configured to limit coupling at conventional frequencies is at least about 3-4 mm. In certain particular embodiments, L2 may be about 39 mm and W2 may be about 29 mm with the element track 22 having a width (W1-W2 or L1-L2) between about 3-6 mm.
In certain embodiments, larger separation distances are used to that the high-band can be approximately twice the frequency of the low band. As the aperture 22a size or length L2 and/or width W2 decreases, the high-band frequency increases. With separations between the opposite sides of the tracks of less than 10 mm, it is possible to tune the antenna for a resonance of about 800-900 MHz in addition to frequencies of 2.2 GHZ or higher high band operation. However, for applications using about an 800-900 MHz resonance in addition to a 1.7-1.9 MHz resonance, larger separations of the primary parallel radiating branches (shown as left 223 and right 221 sides) may be desirable.
The aperture 22a can be an air space or filled with a non-conductive material (or a combination thereof). In operation, gain or tuning should not be degraded if a
user positions fingers or hand over the non-conductive center region. In particular embodiments, the looped track element 22 is sized to provide an aperture 22a that can receive a display (such as a LCD) or other component therein. The length of the track L1 may be on the order of about 47 mm and the width W1 may be on the order of about 37 mm.
The looped antenna 20 configuration may be particularly suitable for clam-shell or flip type housing (wireless communication) designs. Claim-shell designs can have low profiles, larger image areas to accommodate a larger display on the flip and the user may place a digit in the center of the flip during operation. The looped antenna 20 can be used with these designs because it also has a relatively low (flat) profile, certain embodiments can be configured without center components (inhibiting user detuning during operation), and it uses a relatively large x, y area (length and width) relative to other PIFA or portable communication device antenna designs.
Generally described, in operation at low band (which can be described as band "A"), the conductive element 21 can act like a substantially solid conductive sheet with about a ¼ wave resonance. The resonant frequency in low band can be established by the selection of a suitable length (L1) and width (W1) of the looped track element 22 and/or adjusting the distance from the feed 28 to the upper edge portion 22e1 of the looped track element 22. Increasing the area (L1and/or W1) of the looped track element 22 can lower the resonant frequency while decreasing the area (L1 and/or W1) can raise the resonant frequency. The low band may also or alternatively be tuned by adjusting the distance from the feed and ground connections to the null corner 22n (Figure 1C).
At high band, the looped track element 22 can provide a primary high-band resonator (which can be described as "B1"). In operation at high band, as shown in Figures 1B,1D and 1E two distinct standing waves form on opposing sides or edges of the looped track 22, each at about a ½wavelength resonance. Two non-adjacent sides (shown as the left and right sides 223, 221) of the looped track 22 can be at increased or maximum current while the opposing two sides of the looped track 22 are at a reduced or lower current (the low current sides are shown as top and bottom sides 224, 222). In this way, this configuration substantially functions as two parallel radiators with the horizontal components canceling and the radiation being generated substantially vertically and which may provide a cross-polarization that is about 10 db below the primary polarization. The main radiation peak is away from the looped
track 22 and the back radiation can be relatively low. Figure 1E also illustrates extra tuning branches 23 positioned on the left side 223 of the antenna 20 which may be particularly suitable for tuning 900/1800 bands used in Europe or other jurisdictions.
In certain embodiments, such as shown in Figures 1D and 1E, the ground plane 125 can have substantially the same shape as the element 22. This is not required but may allow the element 22 to be positioned closer to the ground plane 125. The configuration of the ground plane 125 away from the element 22 is shown as extending laterally a further distance, however this dimension and/or shape may be adjusted so that it aligns substantially with the element 22 (such as for the right side of the figure).
The high band resonance can be tuned or adjusted by altering the size of the inner perimeter (or spacing) of the looped track element 22 path (i.e., L2 and/or W2) and by adding tuning components such as the tuning branch 23 (shown as an optional feature by the broken line designation in Figure 1A). In certain embodiments, the width (W2) of the looped track and/or the width of the sides of the track 22 (particularly the left and right sides or the primary resonator sides) can be selected to tune the resonance at high band to a desired operational band. The external tuning branch 23 may be particularly suitable for tuning for when the second resonance band is less than about twice the frequency of the primary resonance band.
In certain embodiments, as will be discussed further below, the antenna 20 is configured to have between about 2-4 resonant bands with the low band including frequencies in the range of between about 824-894 MHz. The looped configuration (alone or with secondary branches as will be discussed below) can allow for multiple high-band resonances as well as a multi-band PIFA with good gain for high band at a distance of about 3 mm from the ground plane (typically defined by an underlying printed circuit board).
Figure 1B illustrates a simulated high band radiation pattern with current vectors illustrated. As shown, the current is substantially in-phase in high band operation and there are two null corners 22n located at substantially diametrically opposing edge portions of the looped track 22 (where the horizontal sides merge into the vertical sides away from the ground and signal feeds 25, 28).
Figure 1C illustrates a simulated low band radiation (such as at about 850 MHz) with a radiation pattern with current vectors illustrated. In this embodiment, a null corner 22K is disposed on a different edge portion of the looped track 22 than in
the high band operation. As shown, the null corner 22n is located on the edge portion furthermost away from the signal and ground feed 28,25, respectively.
Figure 2A illustrates that the antenna 20 may include a conductive element 21 that comprises the looped track 22 that provides a primary high band resonator "B1" as well as a secondary branch 30 that provides a secondary resonator "B2" (about a ¼ wave resonator) at high band. The secondary branch 30 may be configured with an aperture 30a that separates two substantially parallel strips as shown. The secondary branch 30 may be configured to angularly extend away from the side of the looped track 22 so as to inhibit destructive interference with the first high-band resonance B1.
In addition, the secondary branch 30 may be positioned internal of the looped track 22 proximate the signal and ground 28, 25, as shown, or may alternatively be positioned to extend external of the looped track and outwardly away therefrom (not shown). The antenna conductive element 22 may comprise a corner member 32 between two adjacent sides 22 that can be used to tune the antenna 20. The gain of this antenna configuration can be a mixture of horizontal and vertically polarized components, which may be due in part to the angle at which the secondary branch 30 is oriented. The secondary branch 30 may be capacitively coupled to a portion of the looped track 22 such as a far comer portion thereof to have this resonance (B2) be adjacent the other high-band resonance (B1).
The secondary branch 30 is shown as the inner branch in this embodiment and, in operation, provides one resonance (in this embodiment the higher of the two high-band frequencies). The inner secondary branch 30 has polarization diversity and can provide a more omni-directional pattern. The outer loop 22 forms the lower high-band resonance and is vertically polarized with relatively low (typically about -l0db) cross polarization. Accordingly, the VSWR of the high band can be better than about 4:1 at about a 3 mm height which can be improved to about 2.5:1 at about a 6 mm height, across the high band (for example, across 1850-1990 MHz). Alternatively, the secondary high band resonance B2 can be separated for other frequency bands such as UMTS or Bluetooth (2.1 or 2.4 GHz). When used for higher frequencies, the bandwidth may be wider.
The length (L1) of the looped track 22 can be about 46.5 mm; the width can be about 37 mm. The height or separation distance from the ground plane may be about 5 mm or less, and typically about 3 mm, although performance may be improved by increasing this distance (particularly low band performance). The ground pin may be
positioned about 5 mm vertically below the feed. In the configuration shown in Figure 2 A, the antenna operates at low and high bands of about 824-894 MHz and 1850-1900 MHz, respectively. Figure 2B is a representative VSWR graph illustrating low band resonance "A," primary high band resonance B1 (from the looped track 22) and secondary high band resonance B2 (from branch 30) corresponding to the antenna 20 shown in Figure 2A (at 3 mm and 6 mm heights). At the 3 mm height, VSWR at band edges is about 8:1 for low and 3-4:1 for high band. At 6 mm height, VSWR is closer to 4:1 for low band a 2.5:1 for high band. In the figures where lower and higher element positions are drawn on the same plot, the outermost lines correspond to the higher placed elements 22.
Figures 2C and 2D illustrate an exemplary antenna radiation pattern at about a 6mm antenna height at 1850 MHz (Figure 2C) and 1900 MHz (Figure 2D) associated with the antenna configuration shown in Figure 2A.
Figure 3 A is another embodiment of an antenna 20 with a looped track 22. In this embodiment, the antenna 20 is configured to generate three resonance bands, a low band "A" at between about 824-894 MHz, and two high bands B1, B2- The high bands can be tuned so that one is at 1575 MHz and one at 2.1-2.4 GHz (the higher band being B1 and primarily attributed to the looped track 22). -The antenna 20 includes a secondary band branch 135 (which creates band B2 at the GPS resonance (1575 MHz) and can widen the high-band resonance). The high band range can be broadened by thickening (increasing the area or the width of the conductive trace) maximal current regions of the radiating element 22. The secondary branch 135 can be formed by slotting or splitting the left side (leg 223) of the looped element 22 and can provide additional bandwidth, as well as an additional resonant frequency. The additional resonant frequency can be tuned by adjusting the length of the slot used to create the secondary branch 135. As shown, the first side 221 has an extra strip or width of track 130 that, in operation, can form part of the high band and low band resonators. In certain embodiments, the extra thickness may provide increased bandwidth in high band operation.
The antenna conductive element 22 can include a slit 135 along the vertical side 223 positioned across from the signal 28. The upper side 224 may be narrower across than the other sides. The high-band can be tuned to higher frequencies as desired. Figure 3B illustrates a VSWR graph of the embodiment shown in Figure 3A at about a 3 mm height. In this embodiment, the high band B1 is relatively wide
and can cover about 15% bandwidth (2150-2485 MH2) at VSWR of about 3:1. The length L1 and width W1 of the track 22 may be about 46.5 mm and 39 mm, respectively.
Figure 3C illustrates an exemplary radiation pattern that may be provided by the antenna 20 shown in Figure 3A at about 1580 MHz (generally corresponding to GPS). Peak values for front, side and azimuth directions are along -1.23, -2.3, and -0.85 dbi, respectively. Figures 3D-3F illustrate exemplary radiation patterns that may be provided by the antenna 20 shown in Figure 3A at about 2.1 GHz (2.4 GHz patterns were similar). The pattern shown is directional with high vertical gain, particularly at Azimuth. The peak gain values are between about 3 and 4 dbi.
Figure 4 A illustrates yet another embodiment of the antenna 20 having a conductive element 21 with a looped track 22. The length L1 and width W1 of the looped track element 22 may be about 45 mm and 38 mm, respectively. The ground 25 for the main looped element 22 may be located at about 3 mm below the signal feed 28. The conductive element 21 can include a secondary branch 235 that is a side parasitic element 235. The parasitic element 235 can be positioned proximate but spaced apart from (devoid of direct contact with) the looped track 22.
The parasitic element branch 235 can be disposed on the left and outside the left most side 223 of the track 22 and can be grounded 25 at its top outer edge portion as shown. Because this edge portion can be in a high current zone, the branch 235 can be excited and a resonance generated. Unlike the primary high band resonance, this resonance can radiate predominantly about the edge of the printed circuit board, which may provide an increased omni-directional pattern and multiple polarizations. The parasitic element 235 may be a vertical strip with a length that is greater than a major portion of the length of one of the longer sides 223 of the track 22. The length of the parasitic element can be sized to substantially correspond (approximately) to the electrical wavelength of the resonance (i.e., ¼ wavelength of the resonance frequency). The left side 223 may have a cut out receiving region 22r that is sized to receive the parasitic element 235 therein with the left side 223 being narrower alongside the portion adjacent the parasitic element 235. The antenna conductive element 21 may include tuning corner members 132 and 232.
The parasitic element 235 can be the dominant radiator at the high end of the high band (typically about 1930-1990 MHz). The antenna 20 radiates at low band at between about 824-894 MHz. The high band B may operate between about 1.85-1.99
MHz. Figure 4B illustrates an exemplary VS WR graph for the embodiment shown in Figure 4A at a 3 mm height from the ground plane.
Figure 4C illustrates an exemplary radiation pattern for the antenna 20 shown in Figure 4A at 1850 MHz measured at about a 3 mm height. Figure 4D illustrates an exemplary radiation pattern for the antenna shown in Figure 4A at 1990 MHz measured at about a 3 mm height.
The embodiments shown in Figure 2A and Figure 4A may provide omnidirectional gain at the higher end of the band. Thus, in receive mode, the communications device may be inhibited from dropping a call or signal based on the user's position (i.e., which direction the user is facing).
Figure 5A illustrates yet another antenna 20 having a looped track 22. This embodiment is a quad-band antenna. It operates at low band "A" and high bands B, C and D (Figure 5B). As before, a secondary branch 135 can be positioned along the outer side of one of the legs of the looped track 22 (typically the side opposite the side holding the signal and ground) and run a major portion of the length L1 (typically at least about 75% of the length, and more typically substantially the entire length L1)-This secondary branch 135 can generate resonance B (typically about 1575 MHz for GPS). The looped track 22 can provide radiation at 1850-1990 (typically primarily from the left and right sides). As shown, the conductive element 21 also includes a third resonance branch 335 and a fourth resonance branch 435. The third resonance branch 335 can contribute to resonance C (typically about 1850-1890 MHz) and/or generate resonance D. The fourth branch 435 can generate or contribute to resonance D (typically about 2400-2485 for Bluetooth). As before the ground 25 can be placed below the signal feed 28 between about 3-6 mm, and typically between about 4-6 mm.
The fourth branch 435 can be the top branch and can be configured to primarily control tuning for high band C (such as 1850-1990 MHz) and/or the third (center) branch 335 can be configured to tune for band D (Bluetooth). The configuration of the secondary branch 135 (shown as the left branch) can be used to tune GPS (1575 MHz). As before, the length and width of the looped track (Lb W1, Figure 1) and/or the width of the element sides can be used to tune or define the low band resonance.
Figure 6A illustrates simulated electric current for the antenna 20 (with looped track 22) and underlying looped ground 125 with sides configured to substantially correspond to the sides of the element track 22 shown at 0.95 GHz with
the adjacent gray scale chart illustrating current density A/m from 0 (29.7696 A/m) to -40 db. Figure 6B illustrates the same antenna 20 with the electric current simulated at 1800 MHz. In certain embodiments, the looped ground plane 125 may have sides that are wider or longer but a center aperture that substantially corresponds to the center aperture 22a of the looped track 22 (not shown).
Figure 7 illustrates an exemplary VS WR of an antenna 20 having a basic looped track 22 according to embodiments of the present invention with the antenna having about a 3 mm antenna height from ground. As shown, there is a % wave resonance at low band (913 MHz) and a plurality of high band resonances including Vi wave resonance at 1.8 GHz. Other high band resonances include 2.9 GHz, 3.45 GHz, 4.75 GHz and 5.95 GHz. Additional higher order modes may be present but were not measured with the equipment used.
Figures 8A and 8B illustrate that high-band currents can oscillate between opposing sides (shown for example, as comers C1, C2) of the looped track 22. The current on the left and right (and top and bottom) is substantially parallel and traveling in the same direction {i.e., they are not canceling each other).
Figure 9 A again illustrates the antenna 20 with looped track 22 positioned about 3 mm (Z distance) from a ground plane 125 that also has a looped track 125t configuration (shown positioned under the antenna track 22). Removing the ground below the antenna aperture 22a and replacing it with a similarly shaped ground element 125, acceptable bandwidth and gain can be achieved at about a 3 mm height. The front to back ratio may still be about 4 db at high band, though low-band may become omni-directional. In this embodiment, the gain may be substantially vertical at both high and low bands. Figure 9B illustrates an exemplary VSWR of the antenna 20 and ground plane 125 shown in Figure 9A.
Figures 10A and 10C illustrate simulated average currents for the antenna 20 shown in Figure 4A at 1850 MHz (Figure 10A) and 1990 MHz (Figure 10C) over a printed circuit board 161. Figure 10B illustrates a simulated radiation pattern for the 1850 MHz current shown in Figure 10A. Figure 10D illustrates a simulated radiation pattern for the 1990 MHz current shown in Figure IOC. The pattern at 1990 MHz is more omni-directional than that at 1850 MHz.
Figures 11A and 11C illustrate simulated average currents for the antenna 20 shown in Figure 2A at 1850 MHz (Figure 11A) and 1990 MHz (Figure 11C). Figure 11133 illustrates a simulated radiation pattern for the 1850 MHz current shown
in Figure 11A. Figure 11D illustrates a simulated radiation pattern for the 1990 MHz current shown in Figure 11C. The top center of the printed circuit board 161 at 1990 MHz illustrates increased activity under the center branch. Thus, in this embodiment, the center branch 30 is the primary radiator.
The simulations were carried out using the commercial available software package IE3D available from Zeland Software, Inc., located in Fremont, CA.
It is noted that although the looped track element 22 is shown in the figures as being substantially rectangular, other looped track configurations may be used. For example, ovals, parallelograms, or even appropriately configured curvilinear tracks with sufficient separation between opposing sides. In certain embodiments, the minimum distance around the inner loop should be sufficient to define two ½ wavelength paths for the high band operation. In certain embodiments, the outer distance around the loop (or distance from the feed/ground to the opposite side) should be sufficient to define two ¼ wavelength paths for the primary resonance.
Further, as is known to those of skill in the art, matching components may be added to improve the impedance match to a 50 Ohm source and/or to increase bandwidth and low-band gain. For example, adding about 1-3 nH of inductance in series with the feed may improve low-band without significantly influencing high-band. The ground plane may be modified by adding slots, apertures, and the like to make the antenna appear further from the ground plane to improve performance. A high-dielectric material may be added between the conductive element 21 and the ground plane 125 to allow for additional shrinking of the geometry of the antenna 20. Reducing the aperture 22a size may reduce gain. Resonating slots can be added to the ground plane 125 to significantly increase bandwidth at low-band and/or high band. Gain may be "shifted" from high band to low band as desired by bringing the ground pin closer to the signal feed.
An inverted-F antenna according to some embodiments of the invention can be assembled into a device with a wireless terminal such as a radiotelephone terminal with an internal ground plane and transceiver components operable to transmit and receive radiotelephone communication signals. The ground plane may be about 40 mm wide and about 125 mm in length.
The antenna 20 can be disposed substantially parallel to the ground plane 125 and is connected to the ground plane and the transceiver components via respective ground and signal feeds. The antenna 2® may be formed or shaped with a certain size
and a position with respect to the ground plane so as to conform to the shape of the radiotelephone terminal housing or a subassembly therein. For example, the antenna may be placed on a substrate that defines a portion of an enclosed acoustic chamber. Thus, the antenna may not be strictly "planar" although in the vernacular of the art, it might still be referred to as a planar inverted-F antenna.
In addition, it will be understood that although the term "ground plane" is used throughout the application, the term "ground plane", as used herein, is not limited to the form of a plane. For example, the "ground plane" may be a strip or any shape or reasonable size and may include non-planar structures such as shield cans or other metallic objects.
The antenna conductive element may be provided with or without an underlying substrate dielectric backing, such as, for example, FR4 or polyimide. In addition, the antenna may include air gaps in the spaces between the branches or segments. Alternatively, the spaces may be at least partially filled with a dielectric substrate material or the conductive pattern formed over a backing sheet Furthermore, an inverted-F conductive element, according to embodiments of the present invention, may have been disposed on and/or within a dielectric substrate.
The antenna conductive element 21 may be formed of copper and/or other suitable conductive material. For example, the conductive element branches may be formed from copper sheet. Alternatively, the conductive element branches may be formed from copper layered on a dielectric substrate. However, conductive element branches for inverted-F conductive elements according to the present invention may be formed from various conductive materials and are not limited to copper as is well - known to those of skill in the art. The antenna can be fashioned in any suitable manner, including, but not limited to, metal stamping, forming the conductive material in a desired pattern on a flex film or other substrate whether by depositing, inking, painting, etching or otherwise providing conductive material traces onto the substrate material.
It will be understood that, although antennas according to embodiments of the present invention are described herein with respect to wireless terminals, embodiments of the present invention are not limited to such a configuration. For example, antennas according to embodiments of the present invention may be used within wireless terminals that may only transmit or only receive wireless communications signals. For example, conventional AM/FM radios or any receiver
utilizing an antenna may only receive communications signals. Alternatively, remote data input devices may only transmit communications signals.
Referring now to Figure 12, a wireless terminal 200 is illustrated. As shown, the antenna 20 includes a conductive element 21 that is maintained in spaced apart relationship with a ground plane 125 that is typically held on a printed circuit board 161. The antenna element 21 is in communication with a signal feed 28 and a ground feed 25. The signal and ground feeds 28, 25 can be positioned adjacent each other and disposed on a common edge portion of the element 21. In certain embodiments, the signal and ground feeds 28, 25 are positioned proximate a common outer edge portion. The term "common outer edge portion" means the signal and ground feeds are positioned adjacent each other near or on an outside or end portion of the looped track 22 of the conductive element 21 (with no conductive element spacing them apart). This configuration is in contrast to where the ground is positioned on a first portion of the element and the signal across from the ground with an expanse of conductive element that separates the signal and feed (such as for center fed configurations).
Referring again to Figure 12, a conventional arrangement of electronic components that allow a wireless terminal 200 to transmit and receive wireless terminal communication signals will be described in further detail. As illustrated, an antenna 20 for receiving and/or transmitting wireless terminal communication signals is electrically connected to transceiver circuitry components 161s. The components 161s can include a radio-frequency (RF) transceiver that is electrically connected to a controller such as a microprocessor. The controller can be electrically connected to a speaker that is configured to transmit a signal from the controller to a user of a wireless terminal. The controller can also electrically connected to a microphone that receives a voice signal from a user and transmits the voice signal through the controller and transceiver to a remote device. The controller can be electrically connected to a keypad and display that facilitate wireless terminal operation. The design of the transceiver, controller, and microphone are well known to those of skill in the art and need not be described further herein.
The wireless communication device 200 shown in Figure 12 may be a radiotelephone type radio terminal of the cellular or PCS type, which makes use of an antenna 20 according to embodiments of the present invention. As shown, the device 20© includes a signal feed 28 that extends from a signal receiver and/or transmitter
(e.g., an RF transceiver) comprising electronic transceiver components 161s. The ground plane 125 serves as the ground plane for the planar inverted-F antenna 20. The antenna 20 may include a dielectric substrate backing shown schematically by dotted line 208. The antenna 20 can include wrapped portions 212, which serve to connect the conductive element 21 to the signal and ground feeds 28, 25. The ground feed 25 is connected to the ground plane 125. The antenna 20 can be installed substantially parallel to the ground plane 125, subject to form shapes, distortions and curvatures as might be present for the particular application, as previously discussed. The signal feed 28 can pass through an aperture 214 in the ground plane 125 and is connected to the transceiver components 161s. The transceiver components 161s, the ground plane 125, and the inverted-F antenna 20 can be enclosed in a housing 165 for the wireless (i.e., radiotelephone) terminal. The housing 165 can include a back portion 165b and front portion 165f. The wireless device 200 may include other components such as a keypad and display as noted above. The ground plane 125 may be configured to underlie or overlie the antenna 20.
It is noted that the branch pattern configurations of the antennas 20 shown herein may be re-oriented, such as rotated such as 10-90, typically 90, 180 or 270 degrees. In addition or alternatively, the configurations may be re-oriented in a mirrored pattern (such as left to right). The antennas 20 may be configured to occupy an area that is less than about 1200 mm . Typically, the antenna has a perimeter that is less than about 40 mm height x 40 mm width x 11 mm depth. In certain embodiments, the antenna 20 can be configured to be equal to or less than about 31 mm height and/or width with a depth that is less than about 11 mm (typically 4-7 mm).
Figures 13A-13C are schematic front views of wireless communication devices 200 having an antenna 20 with a looped conductive element positioned about the perimeter of a display 500 according to embodiments of the present invention. The display 500 can be any suitable graphic or image display such as an LCD. The looped conductive element 22 may be sized and configured to be offset a distance from the display perimeter or to be closely spaced relative thereto. The device 200 may include a keypad (alphanumeric key entry) on the same surface as shown in Figure 13A, on a different member (in a flip or clam-shell configuration as shown in Figure 13B), or on a rear surface (Figure 13C). The flip configuration may be particularly suitable to form a wireless communication device such as a cellular
telephone, which employs two attached housing members that flip or pivot from a closed stored position to an open position.
Figures 14A-14C are schematic front views of wireless communication devices 200 having an antenna 20 with a looped conductive element 22 positioned about the perimeter of a keypad or keyboard 505 according to embodiments of the present invention. The keypad 505 may be disposed in different configurations on the device similar to the configurations discussed for the displays 500 above. The device 200 may include looped elements in more than one location, such as combinations of the positions shown in Figures 13A-13C and 14A-14C. The looped element 22 may also be positioned on the rear surface below the display or keypad (not shown).
In the drawings and specification, there have been disclosed embodiments of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being set forth in the following claims. Thus, the foregoing is illustrative of the present invention and is not to be construed as limiting thereof. Although a few exemplary embodiments of this invention have been described, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention as defined in the claims. In the claims, means-plus-function clauses, where used, are intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Therefore, it is to be understood that the foregoing is illustrative of the present invention and is not to be construed as limited to the specific embodiments disclosed, and that modifications to the disclosed embodiments, as well as other embodiments, are intended to be included within the scope of the appended claims. The invention is defined by the following claims, with equivalents of the claims to be included therein.











WE CLAIM:
1. A planar inverted-F antenna (20) having a plurality of resonant frequency bandwidths of operation, comprising:
a signal feed (28);
a ground feed (25); and
a conductive element (21) in communication with the signal and ground feed (28, 25),
the conductive element (21) comprising a looped track (22) that, in operation, provides a high band resonator and a low band resonator,
the looped track conductive element (22) having a length (L1) and width (W1) and center aperture (22a) having a length (L2) and width (W2), and
wherein the looped track (22) is continuous and comprises four sides (221, 222, 223, 224) with four corner portions that define a track perimeter enclosing the center aperture (22a), with adjacent sides being contiguous about corner portions thereof, wherein corresponding pairs of the four sides (221, 222, 223, 224) face each other across the center aperture (22a), and wherein one corresponding pair (221,223) has a longer length than the other pair (222,224), and
wherein the ground and signal feeds (25, 28) are positioned adjacent each other proximate a common outer edge portion (221) of the looped track (22),
such that the conductive element (21), configured by the dimension of the looped track (22) and the center aperture (22a) and the position of the ground and the signal feed (25, 28), defines about a ¼ wave resonator at a low frequency band and defines two about ½ wave resonators at a high frequency band when operating as the high band resonator.
2. An antenna (20) as claimed in claim 1, wherein at high band two ½ wave resonances are disposed one on each of two opposing sides of the looped track (22).
3. An antenna (20) as claimed in claim 1, wherein, during operation at high band, the looped track (22) is configured and positioned with respect to the signal and ground feeds (28, 25) to define current null spaces (22n) at two portions that are opposed from each other.
4. An antenna (20) as claimed in claim 1, wherein, during operation at low band, the looped track (22) is configured and positioned with respect to the signal and ground feeds (28, 25) to define one current null space (22n) in one corner portion with the current travelling along the looped track (22) away from the signal feed (28) toward the null space corner (22n) from at least three of the four sides (221, 222, 223, 224) with the current traveling in a substantially common direction along corresponding pairs of the four sides (221, 222, 223, 224).
5. An antenna (20) as claimed in claim 1, wherein at high band, current travels in a direction that oscillates between two null space portions (22n, 22n) with current travelling in substantially the same direction in two opposing sides (221, 223).
6. An antenna (20) as claimed in claim 3, wherein the four sides (221, 222, 223, 224) include a left (223) and right side (221) which define a first corresponding pair and a top (224) and bottom side (222) which define a second corresponding pair, and wherein the signal and ground feed (28, 25) are disposed on the right side of the looped track (22).
7. An antenna (20) as claimed in claim 5, wherein the looped track (22) has a substantially rectangular shape.
8. An antenna (20) as claimed in claim 1, wherein the looped track (22) has an outer and inner perimeter that encases an inner center aperture (22a), and wherein a secondary branch (30) of the conductive element (21) extends away from the looped track (22) and is in conductive communication with the signal feed (28) and resonates at high band.
9. An antenna (20) as claimed in claim 8, wherein the secondary branch (30) extends inwardly into the center aperture (22a) of the looped track (22).
10. An antenna (20) as claimed in claim 9, wherein the secondary branch (30) extends outwardly away from the center aperture (22a) of the looped track (22).
11. An antenna (20) as claimed in claim 8, wherein the secondary branch (30) is attached to and angularly extends away from a first side (221) of the looped track (22) and resonates at high band at about 1990 MHz, and wherein the looped track (22) resonates at high band at about 1850 MHz.
12. An antenna (20) as claimed in claim 1, wherein one end portion of a secondary branch (30) with opposing end portions is attached to a selected side of the looped track with the secondary branch (30) having a strip (30a) that is spaced apart from and extends substantially parallel to and along a major portion of the length the selected side of the perimeter and is in conductive communication with the signal feed (28).
13. An antenna (20) as claimed in claim 12, wherein the secondary branch (30) radiates at about 1575 MHz.
14. An antenna (20) as claimed in claim 13, wherein the looped track (22) resonates at about 2.1 GHz at high band and about 824-894 MHz at low band.
15. An antenna (20) as claimed in claim 1, wherein a secondary branch (235) is spaced apart from and extends substantially parallel to and along a portion of the length of one side of the perimeter and a second ground feed (25) is in conductive communication with the secondary branch (235), wherein said secondary branch (235) is parasitically coupled to the looped track (22) during operation.
16. An antenna (20) as claimed in claim 15, wherein the second ground feed (25) is disposed adjacent a top outer edge portion of the secondary branch (235), and wherein the secondary branch (235) is the primary resonator at a portion of the high band between about 1930-1990 MHz, wherein the antenna (20) radiates at low band at between about 824-894 MHz and at high band between about 1.85-1.99 GHz.
17. An antenna (20) as claimed in claim 1, wherein the conductive element (21) is configured with first, second and third branches (135, 335, 435) that are in communication with the signal and ground feed (28, 25) to provide a quad band antenna.
18. An antenna (20) as claimed in claim 17, wherein said antenna first branch (135) has opposing end portions, one end portion being attached to a selected side of the looped track (22) with the second branch (335) having a strip that is spaced apart from and extends substantially parallel to and along a major portion of the length of the selected one side of the perimeter and is in conductive communication with the signal feed (28).
19. An antenna (20) as claimed in claim 18, wherein said antenna second branch (335) extends substantially orthogonally off one side of the looped track (22), the one side being adjacent the signal feed (28).
20 An antenna (20) as claimed in claim 19, wherein said antenna third branch (435) is disposed above the uppermost side of the looped track (22) and extends substantially parallel thereto.
21. An antenna (20) as claimed in claim 20, wherein said quad antenna resonates at low band at between about 824-894 MHz and at high band at about 1575 MHz, 1850-1990 MHz, and about 2400-2485 MHz.
22. An antenna (20) as claimed in claim 1, wherein the looped track (22) is substantially rectangular, and wherein at least one internal comer portion includes an angularly oriented comer tuning member (132, 232) that connect adjacent sides of the track (22).
23. An antenna (20) as claimed in claim 1, wherein a ground plane (125) is in communication with the ground feed (25) and the conductive element (21).
24. An antenna (20) as claimed in claim 23, wherein the ground plane (125) is configured as a looped ground plane.
25. An antenna (20) as claimed in claim 24, wherein the looped ground plane configuration has a shape and size that substantially corresponds to the looped track antenna configuration.
26. An antenna (20) as claimed in claim 23, wherein the antenna (20) is positioned at about a distance of between about 3-6mm from the ground plane (125).
27. An antenna (20) as claimed in claim 26, wherein the antenna (20) is positioned at about a 3 mm or less distance from the ground plane (125).
28. A method for exciting a planar inverted F antenna (20) having low and high band operational modes:
providing a conductive element (21) with a looped track element (22), the looped track conductive element (22) having a length (L1) and width (W1) and a center aperture (22a) having a length (L2) and width (W2), and
wherein the looped track (22) is continuous and comprises four sides (221,222,223,224) with four comer portions that define a track perimeter enclosing the center aperture (22a), with adjacent sides being contiguous about comer portions thereof, wherein corresponding pairs of
the four sides (221, 222, 223, 224) face each other across the center aperture (22a), and wherein one corresponding pair (221, 223) has a longer length than the other pair (222, 224), and
wherein a ground and a signal feed (25,28) are positioned adjacent each other proximate a common outer edge portion (221) of the looped track (22),
such that the conductive element (21), configured by the dimensions of the looped track (22) and the center aperture (22a) and the position of the ground and the signal feed (25, 28), defines about a ½ wave resonator at a low frequency band and defines two about ½ wave resonators at a high frequency band when operating as the high band resonator-generating a current null (22n) along at least one portion of the looped track element (22) at a selected low band operation; and
generating a current null (22n) at two spaced apart portions of the looped track element (22) at a selected high band operation period.
29. A method as claimed in claim 28, comprising positioning the looped track element (22) at about 3-6mm from a ground plane (125).
30. A method as claimed in claim 29, comprising configuring the ground plane (125) as a looped ground plane.
31. A method as claimed in claim 28, wherein the step of generating a current null (22n) at two spaced apart portions of the looped track element (22) at a selected high band operation comprises generating two current nulls (22n, 22n) at opposing sides of the looped track (22).
32. A method as claimed in claim 31, comprising generating two substantially parallel V2 wave resonators at high band, one along each of the two sides of the looped track element (22) that is devoid of a current nulls.
33. A method as claimed in claim 32, wherein one current null (22n) is located at a center portion of an upper side (224) of the looped track element (22) and the other current null (22n) is located at a center portion of a lower side (222) of the looped track element (22).
34. A method as claimed in claim 33, wherein the parallel resonators are the left (223) and right (221) sides of the looped track element (22).
35. A method as claimed in claim 34, comprising positioning a signal feed (28) and ground feed (25) proximate an upper outer edge portion of the right side (221) of the looped track (22) with the ground feed (25) located about 3-6 mm below the signal feed (28) along the right side (221) of the looped track element (22).
36. A wireless terminal (200), in combination with the antenna as claimed in claim 1, comprising:

(a) a housing (165) configured to enclose a transceiver (161s) that transmits and receives wireless communications signals;
(b) a ground plane (125) disposed within the housing (165);
(c) the planar inverted-F antenna (20) as claimed in claim 1 disposed within the housing (165) and electrically connected with the transceiver (161s), wherein the planar conductive looped track element (22) is disposed on a planar dielectric substrate (208).

37. A wireless terminal (200) as claimed in claim 36, wherein the ground and signal feeds (25, 28) are positioned within about 3-6 mm of each other proximate a common side at an upper or lower edge portion of the common side of the looped track element (22).
38. A wireless terminal (200) as claimed in claim 37, wherein the ground feed (25) is positioned below the signal feed (28) when viewed from the top.
39. A wireless terminal (200) as claimed in claim 36, wherein, during operation at high band, the looped track element (22) is configured and positioned with respect to the signal and ground feeds (28, 25) to define two current null spaces (22n), one on each of two sides of the looped track element so that the null spaces (22n) are substantially opposite from each other separated by the center aperture (22a).
40. A wireless terminal (200) as claimed in claim 36, wherein a secondary branch (30) is attached to and angularly extends away from a first side (221) of the looped track element (22) and resonates at high band at a center frequency of about 1960 MHz, and wherein the looped track element (22) resonates at high band at a center frequency of about 1880 MHz.
41. A wireless terminal (200) as claimed in claim 36, wherein the antenna (20) is positioned at about a 6mm distance or less from the ground plane (125).
42. A wireless terminal (200) as claimed in claim 36, wherein the antenna (20) is positioned at about a 3-6 mm distance from the ground plane (125).
43. A wireless terminal (200) as claimed in claim 36, wherein the center aperture (22a) of the looped track (22) is an air gap adapted to receive a display (500) therein.
44. A wireless terminal (200) as claimed in claim 36, wherein the looped track (22) extends around the outer perimeter of a liquid crystal display (500).
45. A wireless terminal (200) as claimed in claim 36, wherein the center aperture (22a) of the looped track (22) is an air space that is sized and configured to receive a display member therein, wherein a display (500) having a perimeter is positioned in the center aperture (22a) of the looped track element (22) such that the looped track element perimeter follows the perimeter of the display (500).
46. A wireless terminal (200) as claimed in claim 45, wherein the wireless terminal (200) comprises a flip housing member that holds the display (500) and looped track element (22) and can pivot from a closed stored position to an open position.
47. A wireless terminal (200) as claimed in claim 36, wherein the center aperture (22a) of the looped track (22) is an air space that is sized and configured to receive a keypad (505) therein, wherein a keypad (505) having a perimeter is positioned in the center aperture (22a) of the looped track element (22) such that the looped track perimeter follows the perimeter of the keypad (505).

Documents:

511-DELNP-2005-Correspondence Others-(29-07-2011).pdf

511-DELNP-2005-Form-3-(29-07-2011).pdf

5114-DELNP-2005-Abstract-(29-07-2010).pdf

5114-delnp-2005-abstract.pdf

5114-delnp-2005-assignment.pdf

5114-delnp-2005-Claims-(09-09-2014).pdf

5114-DELNP-2005-Claims-(29-07-2010).pdf

5114-delnp-2005-claims.pdf

5114-delnp-2005-Correspondence Others-(02-05-2012).pdf

5114-delnp-2005-Correspondence Others-(09-09-2014).pdf

5114-delnp-2005-Correspondence Others-(19-08-2014).pdf

5114-DELNP-2005-Correspondence-Others (16-11-2009).pdf

5114-DELNP-2005-Correspondence-Others-(29-07-2010).pdf

5114-delnp-2005-correspondence-others.pdf

5114-DELNP-2005-Description (Complete)-(29-07-2010).pdf

5114-delnp-2005-description (complete).pdf

5114-DELNP-2005-Drawings-(29-07-2010).pdf

5114-delnp-2005-drawings.pdf

5114-DELNP-2005-Form-1-(29-07-2010).pdf

5114-delnp-2005-form-1.pdf

5114-delnp-2005-form-18.pdf

5114-DELNP-2005-Form-2-(29-07-2010).pdf

5114-delnp-2005-form-2.pdf

5114-DELNP-2005-Form-3 (16-11-2009).pdf

5114-delnp-2005-Form-3-(02-05-2012).pdf

5114-delnp-2005-form-3.pdf

5114-delnp-2005-form-5.pdf

5114-delnp-2005-GPA-(19-08-2014).pdf

5114-DELNP-2005-GPA-(29-07-2010).pdf

5114-delnp-2005-gpa.pdf

5114-delnp-2005-pct-101.pdf

5114-delnp-2005-pct-210.pdf

5114-delnp-2005-pct-220.pdf

5114-delnp-2005-pct-237.pdf

5114-delnp-2005-pct-304.pdf

5114-delnp-2005-pct-401.pdf

5114-delnp-2005-pct-408.pdf

5114-delnp-2005-pct-409.pdf

5114-delnp-2005-pct-416.pdf

abstract.jpg

Petition under rule 137 (5114-DELNP-2005).pdf


Patent Number 263468
Indian Patent Application Number 5114/DELNP/2005
PG Journal Number 44/2014
Publication Date 31-Oct-2014
Grant Date 30-Oct-2014
Date of Filing 08-Nov-2005
Name of Patentee SONY ERICSSON MOBILE COMMUNICATIONS AB
Applicant Address NYA VATTENTORNET, S-221 88 LUND, SWEDEN
Inventors:
# Inventor's Name Inventor's Address
1 SCOTT LADELL VANCE 132 WOODLAND DRIVE, CARY, NC 27513, U.S.A
PCT International Classification Number H01Q 9/04
PCT International Application Number PCT/IB2004/000085
PCT International Filing date 2004-01-14
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/458,865 2003-06-11 U.S.A.