1. Field of the Invention
This invention relates generally to communication devices and more particularly to antennas for Multiple-Input, Multiple-Output (MIMO) media access controllers.
2. Related Art
The use of wireless communication devices for data networking continues to grow at a rapid pace. Data networks that use “WiFi” (“Wireless Fidelity”), also known as “Wi-Fi,” are relatively easy to install, convenient to use, and supported by the IEEE 802.11 standard. WiFi data networks also provide performance that makes WiFi a suitable alternative to a wired data network for many business and home users.
WiFi networks operate by employing wireless access points that provide users, having wireless (or “client”) devices in proximity to the access point, with access to varying types of data networks such as, for example, an Ethernet network or the Internet. The wireless access points include a radio that operates according to the standards specified in different sections of the IEEE 802.11 specification. Generally, radios in the access points communicate with client devices by utilizing omni-directional antennas that allow the radios to communicate with client devices in any direction. The access points are then connected (by hardwired connections) to a data network system that completes the access of the client device to the data network.
The three standards that define the radio configurations are:
1. IEEE 802.11a, which operates on the 5 GHz frequency band with data rates of up to 54 Mbs;
2. IEEE 802.11b, which operates on the 2.4 GHz frequency band with data rates of up to 11 Mbs; and
3. IEEE 802.11g, which operates on the 2.4 GHz frequency band with data rates of up to 54 Mbs.
The 802.11b and 802.11g standards provide for some degree of interoperability. Devices that conform to 802.11b may communicate with 802.11g access points. This interoperability comes at a cost as access points will switch to the lower data rate of 802.11b if any 802.11b devices are connected. Devices that conform to 802.11a may not communicate with either 802.11b or 802.11g access points. 1In addition, while the 802.11a standard provides for higher overall performance, 802.11a access points have a more limited range compared with the range offered by 802.11b or 802.11g access points.
Each standard defines ‘channels’ that wireless devices, or clients, use when communicating with an access point. The 802.11b and 802.11g standards each allow for 14 channels. The 802.11a standard allows for 23 channels. The 14 channels provided by 802.11b and 802.11g include only 3 channels that are not overlapping. The 12 channels provided by 802.11a are non-overlapping channels.
Access points provide service to a limited number of users. Access points are assigned a channel on which to communicate. Each channel allows a recommended maximum of 64 clients to communicate with the access point. In addition, access points must be spaced apart strategically to reduce the chance of interference, either between access points tuned to the same channel, or to overlapping channels. In addition, channels are shared. Only one user may occupy the channel at any given time. As users are added to a channel, each user must wait longer for access to the channel thereby degrading throughput.
One way to increase throughput is to employ multiple radios at an access point. Another way is to use multiple input, multiple output (“MIMO”) to communicate with mobile devices in the area of the access point. MIMO has the advantage of increasing the efficiency of the reception. However, MIMO entails using multiple antennas for reception and transmission at each radio. The use of multiple antennas may create problems with space on the access point, particularly when the access point uses multiple radios. In some implementations of multiple radio access points, it is desirable to implement a MIMO implementation in the same space as a previous non-MIMO implementation.
Current MIMO implementations may utilize 2-3 antennas per radio. When more than one antenna is used, the mutual coupling among the antennas due to their proximity may degrade the performance of the access point and reduce the throughput. The problem with mutual coupling is magnified when multiple radios are used in an access point.
It would be desirable to implement MIMO in multiple radio access points without significant space constraints such that it would be possible to substitute a non-MIMO multiple radio access point with a MIMO multiple radio access point in the same space. It would also be desirable to implement MIMO in a multiple radio access point while maximizing the performance of the access point in coverage and quality of service (QOS).
In view of the above, a multiple input, multiple output (“MIMO”) antenna system is provided for operation on a radio frequency (“RF”) module that may be used in a wireless access device. The MIMO antenna system includes a plurality of multi-band antenna elements connected to a radio in a MIMO configuration. The multi-band antenna elements and the radio are configured to operate on a RF module. A reflector is formed on the RF module to contain the plurality of multi-band antenna elements and to concentrate signal communication in a sector, the plurality of multi-band antenna elements oriented to provide a sector coverage pattern formed by beam patterns generated by each of the multi-band antenna elements. PCB.
Other systems, methods and features of the invention will be or will become apparent to one with skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the accompanying claims.
The examples of the invention described below can be better understood with reference to the following figures. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. In the figures, like reference numerals designate corresponding parts throughout the different views.
In the following description of the preferred embodiment, reference is made to the accompanying drawings that form a part hereof, and which show, by way of illustration, a specific embodiment in which the invention may be practiced. Other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.
A wireless local area network (“WLAN’) access device that uses a MIMO antenna array is disclosed. The WLAN access device may include a circular housing having a plurality of radial sectors and a plurality of antenna arrays, each antenna array arranged within individual radial sectors of the plurality of radial sectors.
In general, the antenna arrays used in the WLAN access device include multisector antenna systems that radiate a plurality of radiation patterns that “carve” up the airspace into equal sections of space or sectors to assure continuous coverage for a client device in communication with the WLANAA. The radiation pattern overlap may also ease management of a plurality of client devices by allowing adjacent sectors to assist each other. For example, adjacent sectors may assist each other in managing the number of client devices served with the highest throughput as controlled by an array controller. The WLANAA provides increased directional transmission and reception gain that allow the WLANAA and its respective client devices to communicate at greater distances than standard omnidirectional antenna systems, thus producing an extended coverage area when compared to an omni-directional antenna system.
The WLANAA is capable of creating a coverage pattern that resembles a typical omni-directional antenna system but covers approximately four times the area and twice the range. In general, each radio frequency (“RF”) sector is assigned a non-overlapping channel by an Array Controller.
Examples of implementations of a WLANAA in which multiple input, multiple output (“MIMO”) schemes may be implemented, and in which example implementations consistent with the present invention may also be implemented are described in:
As described below with reference to
The reflector 110 is configured to enhance the gain/ directivity of the antenna elements 106, 108. The reflector 110 may also be shaped to enhance isolation between adjacent RF modules 100 as well as front-to-back isolation. For example, as shown in
The PCB 102 may be any suitable printed circuit board implementation. The PCB 102 shown in
The RF processing circuitry 104 may be designed into the PCB 102 to provide RF signal processing functions. The RF processing circuitry 104 may be configured to operate with a controller to implement any suitable wireless LAN system. The RF processing circuitry 104 may communicate with the controller via the edge connectors 112.
In a middle layer of the three-layer board, a ‘V’ shaped metallic layer may be formed in the shape of each notch antenna 302, 304 shown in
The notch antennas 302, 304 in
In order to cover the 2.4 Ghz band, the top curved portion 302a of the top notch antenna 302 extends to form a narrowed strip that is curved within the area under the top curved portion 302a. This first narrowed strip functions as a top 2.4 Ghz resonating arm 310a on the top notch antenna 302. The bottom curved portion 302b of the top notch antenna 302 extends to form a narrowed strip that is curved within the area under the bottom curved portion 302b. This second narrowed strip functions as a bottom 2.4 Ghz resonating arm 310b on the top notch antenna 302. The top curved portion 304a of the bottom notch antenna 304 extends to form a narrowed strip that is curved within the area under the top curved portion 304a. This third narrowed strip functions as a top 2.4 Ghz resonating arm 311a on the bottom notch antenna 304. The bottom curved portion 304b of the bottom notch antenna 304 extends to form a narrowed strip that is curved within the area under the top curved portion 304b. This fourth narrowed strip functions as a bottom 2.4 Ghz resonating arm 311b on the bottom notch antenna 304. The four narrow strips shown in
The top notch antenna 302 may connect to a top feedline 322a, which is formed by a metallic trace on another layer, such as on a top layer, which extends to a main feedpoint 318 via common feedline 320 from common feedpoint 324. The top notch antenna 302 may connect to the top feedline 322a at a top notch short stub 310, which couples to the top feedline 322a via a top notch antenna feedline 312. The shape and dimensions of the top notch short stub 310 and the top notch antenna feedline 312 may be selected in order to provide a proper match with the feedline all the way to the main feedpoint 318 in the frequency range of interest.
The bottom notch antenna 304 may connect to a bottom feedline 322b, which is formed by a metallic trace on another layer, such as on a top layer, which extends to a main feedpoint 318 via common feedline 320 from common feedpoint 324. The bottom notch antenna 304 may connect to the bottom feedline 322b at a bottom notch short stub 314, which couples to the bottom feedline 322b via a bottom notch antenna feedline 316. The shape and dimensions of the bottom notch short stub 314 and the bottom notch antenna feedline 316 may be selected in order to provide a proper match with the feedline all the way to the main feedpoint 318 in the frequency range of interest.
It is noted that the implementation of the multi-band antenna element 300 described above is a dual-band antenna for wireless communication pursuant to 802.11a/n and 802.11b/g/n specifications. The multi-band antenna element 300 may be configured for implementations based on other specifications. In addition, the multi-band antenna element 300 uses Vivaldi notch antennas; however, any suitable multi-band antenna designed may be used. The 2.4 Ghz resonating arms are used to optimize the coverage of signals around 2.4 Ghz. However, other suitable shapes may be used as well.
Two or three multi-band antenna elements 300 (in
The RF module 402 generates three beams 410a-c using the three multi-band antenna elements 404a-c, each antenna element 404a-c generating a corresponding beam 410a-c.
The beams 410a-c generated by each antenna element 404a-c are formed by the directivity provided by the antenna elements 404a-c and by shape and geometry of the reflector 406. The reflector 406 is shaped in order to provide the isolation required for the different sectors to operate at full capacity without interfering with the other sectors. The reflector 406 also enhances the antenna gain in the desired frequency bands. The reflector 406 has two corner reflector portions as described above with reference to
The corner antennas 404a,c, which form beams 410a,b relative to the reflector corners are positioned to generate the two beams 410a,c such that they overlap and are squinted from a boresight.
The MIMO channel circuit 500 in
The transceiver 502 may be any suitable radio transceiver configured for operation according to 802.11a/b/g/n standards. The transceiver 502 may be switched to operate according to one of the standards and to operate as a receiver, a transmitter, or both. Based on the switch and selected standard, the transceiver 502 enables either the 2 Ghz receiver and/or transmitter lines 504a,b or the 5 Ghz receiver and/or transmitter lines 505a,b.
The dual-band antenna 502 may include any suitable multi-band antenna, including for example, a Vivaldi notch antenna array such as the multi-band antenna array described above with reference to
The high connection 512 and the low connection 514 are connected to the band selector switch 508, which may be switched to determine which signal to receive and/or transmit and to enhance the isolation between the two frequency modes. The band selector switch 508 is configured such that the un-selected connection is coupled to a resistor connected to ground. The resistor is provided with a high resistance to provide a high impedance connection for the unselected signal.
The selected signal path (i.e. high or low connection) is coupled to the FEM 506. The FEM 506 conditions the signal by using power amplifiers, low noise amplifiers, and filters for the desired signal types. In one example, the FEM 506 may be implemented using a SE595L Dual Band 802.11n Wireless LAN Font End made by SIGe Semiconductors.
The FEM 506 is connected to the 2 Ghz receiver and/or transmitter lines 504a,b or the 5 Ghz receiver and/or transmitter lines 505a,b to receive 2 Ghz or 5 Ghz signals from the wireless transceiver 502 over either the 2 Ghz or 5 Ghz transmitter lines 504a, 505a; or to couple 2 Ghz or 5 Ghz signals to the wireless transceiver 502 over either the 2 Ghz or 5 Ghz receiver lines 504b, 505b.
It will be understood that the foregoing description of numerous implementations has been presented for purposes of illustration and description. It is not exhaustive and does not limit the claimed inventions to the precise forms disclosed. For example, the above examples have been described as implemented according to IEEE 802.11a and 802.11bg. Other implementations may use other standards. In addition, examples of the wireless access points described above may use housings of different shapes, not just round housing. The number of radios in the sectors and the number of sectors defined for any given implementation may also be different. Modifications and variations are possible in light of the above description or may be acquired from practicing the invention. The claims and their equivalents define the scope of the invention.
Number | Name | Date | Kind |
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7411554 | Jung | Aug 2008 | B2 |
8669913 | Hartenstein | Mar 2014 | B2 |
Number | Date | Country | |
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20140266944 A1 | Sep 2014 | US |
Number | Date | Country | |
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Parent | 12987040 | Jan 2011 | US |
Child | 14178019 | US |