The present invention is directed to the field of wireless networking, with particular applicability to rollouts in which there is a large quantity of wireless traffic in a given operational area. It is becoming increasingly common to implement wireless local area networks (WLANs) in addition to or in place of traditional LANs. In a traditional LAN, each client device, e.g. a personal computer etc., requires a physical, hard-wired connection to the network. However, with a WLAN, each client device includes a wireless capability (such as an insertable, embedded card or fully integrated capability) for wirelessly communicating with the network via an access point (AP) that includes an antenna, a transceiver and a hard-wired connection to the network. In this way, users may carry their hand-held devices and laptop computers within a physical area and still maintain a network connection.
However, in “crowded” enterprise rollouts, it can be difficult for a large number of users to simultaneously access the network due to the contention-based protocol used. Accordingly, it has been contemplated that multiple wireless channels can be used for allowing user access. Three non-overlapping channels have been allocated in the 2.4 GHz band, and eleven channels in the 5 GHz band. Using multiple available channels, an AP may be implemented in a single-package topology that enables simultaneous transmission and reception on nearby frequency channels at the same interval in time. A problem inherent with such a topology is a high degree of self-interference between signals on adjacent channels, resulting in poor quality of service. It is thus desirable to provide signal isolation between each transceiver in the AP. Depending on the tranceiver architecture, there will be an additional antenna-to-antenna isolation requirement that must be met to achieve the overall required signal isolation.
A special problem arises when a multiplicity of antenna elements used to support a single unit, multichannel AP are in close proximity to each other and whose element-to-element isolation is low. The overall requirement is to cover a large (omnidirectional) area with all of the AP channels, either in concert or sectorially. Absorber materials are known for providing antenna isolation, but these materials are expensive, bulky, and otherwise unsuitable as the sole method for achieving the required isolation. Physical separation between the antennas is also a solution, however this would lead to a product that could not be neatly integrated into a single reasonably sized housing. This problem can be also addressed by the use of “smart” antennas, in which the antenna can be “steered” toward a particular client or group of clients to send and receive signals and yet maintain high isolation from other steered beams. Directional antennas with high front-to-back ratios (F/B ratio) can also be used in some applications, such as when a geometrically isolated area must be covered. However, a special case arises when a two channel system is desired. These might be two channels in the 2.4 GHz band or two channels in the 5 GHz band. In these situations, one desires a hemispherical radiation pattern so that the coverage area can be divided into two sectors. The isolation must still be high to allow simultaneous operation of those two transceivers. A novel solution to this special problem is disclosed herein.
The difficulties and drawbacks of previous-type implementations are addressed by the presently-disclosed embodiments in which a wireless device is disclosed, including an antenna system comprising one or more antenna elements for sending and receiving a wireless signal. One or more conductive members are included, having an edge displaced from and substantially directed toward at least one antenna element, and cooperating therewith to establish a hemispherical beam pattern for a wireless signal.
As will be realized, the invention is capable of other and different embodiments and its several details are capable of modifications in various respects, all without departing from the invention. Accordingly, the drawings and description are to be regarded as illustrative and not restrictive.
Particular reference is now made to the figures, where it is understood that like reference numbers refer to like elements. As shown in
Applicants have discovered that metallic fins 14 configured with antennas 12 in the disclosed manner simultaneously provide signal isolation and a dual hemispherical radiation pattern for each antenna 12. It has been contemplated that the metallic fins 14 can be formed of brass having a thickness of about 5 mils and dimensions of 3 inches×4 inches at a nominal operating frequency of 2.4 GHz. Appropriate scaling is required for operation at other frequencies, inversely proportional to frequency. It is of course appreciated that any suitable metal or other conductor could be substituted for brass. The antennas 12 are preferably dipoles selected to provide a wide bandwidth with a small aperture and a suitable elemental radiation pattern.
In an exemplary embodiment shown in
Various permutations of element size and orientation were discovered that result in varying degrees of isolation, as will be shown below in the discussion of the other embodiments. For example, as shown in
Because a dipole is an omni-directional radiating element, the isolation between two antennas is poor without any additional isolation element. For example, at one wavelength of separation (4.8″ at 2450 MHz), 2 dipoles have only 22 dB of isolation. However, with the presence of two of the fins 14, an isolation of greater than 45 dB is obtained, as shown in
The hemispheric pattern and resulting high isolation obtained by the present arrangement enables a dual hemispherical antenna system in which two antenna elements 12a, 12b of
The benefits of the present system can be realized in a variety of configurations. In one embodiment, for example, a single antenna element 12 can be configured to cooperate with the conductive member 14. In a preferred embodiment, as particularly shown in
As is shown in
Another embodiment of the present antenna system 10 is shown in
Preferably, the pair of antenna elements 12a associated with a first conductive member 14a is adapted to operate on a first wireless frequency band. The pair of antenna elements 12b associated with a second conductive member 14b is adapted to operate on a second wireless frequency band. The respective wireless frequency bands can be 2.4 GHz and 5 GHz wireless bands. However, it should be understood that this embodiment is not limited to only two bands. The antenna system 10 can include a number of conductive members arranged in a “star” type configuration, with respective pairs of antenna elements, all without departing from the invention.
In the preferred embodiment, the conductive member 14 is two substantially coplanar elements that are coplanar with the one or more antenna elements 12. However, as shown in
The present dual hemisphere antenna arrangement provides a 180-degree sector antenna implementation with low “scalloping”, greater than the gain of an omnidirectional antenna and at least 51 dB of isolation (so as to keep the transmit signal out of the receiver alternate channel). Also, the materials used in the present embodiments are inexpensive and the topology would be straightforward to manufacture. Thus, the present system achieves superior results over previous-type systems with an inexpensive solution that simultaneously has 180° beamwidth and 51 dB of isolation. This is an improvement over known-type sectorized antennas, such as are common in the cellular world, that rely on physical separation, polarization diversity, and expensive diplexers to achieve isolation.
The present conductive member 14 is essentially a reflector screen that provides a high degree of isolation between two dipole antennas, simultaneously yielding a hemispherical radiation pattern in the H-plane. The solution does not require the use of traditional frequency selective surfaces where the benefit might be only 6 dB per octave per surface to get the 51 dB+ isolation. Similarly, the present invention does not require polarization screens since the two antenna elements 12 operate at the same polarization, and a slant polarization would result in a 4 dB penalty of forward gain against the link budget. Finally, the present results are obtained in a compact package which would be very desirable from a consumer marketing standpoint.
As described hereinabove, the present invention solves many problems associated with previous type systems. However, it will be appreciated that various changes in the details, materials and arrangements of parts which have been herein described and illustrated in order to explain the nature of the invention may be made by those skilled in the area within the principle and scope of the invention will be expressed in the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
6140972 | Johnston et al. | Oct 2000 | A |
6317100 | Elson et al. | Nov 2001 | B1 |
6864852 | Chiang et al. | Mar 2005 | B2 |
20020024468 | Palmer et al. | Feb 2002 | A1 |
20030048226 | Gothard et al. | Mar 2003 | A1 |