Antenna system for improving the performance of a short range wireless network

An antenna system for providing network access services to wireless users generates at least a first and a second antenna beam, where the second antenna beam is movable with respect to the first. Additional antenna beams may also be generated. During installation of the antenna system, an installer may adjust the position of the second antenna beam (and possibly other antenna beams) in a manner that enhances the maximum data-rate coverage area of the antenna system for a given deployment region.

BACKGROUND OF THE INVENTION

Short range wireless technologies (e.g., IEEE 802.11a, IEEE 802.11b, Bluetooth®, Ultrawideband, HomeRF, HIPERLAN, etc.) are becoming increasingly popular for providing communication between both fixed and portable devices. Such technologies are capable of providing low power, low-cost, high-bandwidth communication to a variety of users. In one possible application, such technologies may be used to provide wireless communication between a user device and a network access point. The network access point may serve, for example, as a gateway to the Internet or to another large network. Such network access points have traditionally used omni-directional antennas to communicate with surrounding users. Thus, the strength at which signals are received by a user device from the access point drops rapidly with increasing distance from the access point. As the receive signal strength drops off, the data rate that is sustainable over the wireless link decreases accordingly. As a result, maximum data rates are only supportable within a small area about the access point. It is generally desirable that the area of maximum data rate coverage about a wireless access point be as large as practically possible. It is also generally desirable that the area within which maximum data rates are achievable be easily conformable to a region within which the access point is being deployed.

DETAILED DESCRIPTION

FIG. 1is a bottom view of an antenna system10in accordance with an embodiment of the present invention. In at least one application, the antenna system10is used to provide short range wireless access point services to users who desire connection to a network. As used herein, the term “short-range” refers to distances of 100 meters or less. As illustrated, the antenna system10includes a main panel12and four pivotable side panels14,16,18,20. The main panel12and each of the side panels14,16,18,20has a corresponding array of antenna elements22disposed thereon. Each array of elements22is operative for generating a corresponding antenna beam (receive and/or transmit) during system operation. Thus, the antenna system10ofFIG. 1will generate5main beams during normal operation (side lobes may also be present).FIG. 2is a sectional side view of the antenna system10ofFIG. 1illustrating the connection of the side panels16,20to the main panel12using hinges24. Any form of hinge may be used. As will be described in greater detail, a locking mechanism may also be provided to lock each side panel14,16,18,20in a fixed position when the antenna system10is eventually installed. The antenna system10may also include a mount26for use in mounting the system10within a deployment region (e.g., a region within which network access services are to be provided). The mount26may include any structure or structures capable of facilitating attachment of the antenna system10in a desired position in the deployment region. The mount26may also provide a conduit for any electrical and/or feed lines that will need to be directed to the antenna system.

When deployed, the antenna system10is mounted in an elevated position within the deployment region. This may include, for example, a ceiling mount, a pole mount, a wall mount, or other similar mount locations. During antenna operation, each of the beams generated by the antenna system10is directed in a generally downward direction to “illuminate” a corresponding portion of the floor space below. The overall coverage pattern of the antenna system10is a combination of the individual footprints of each of these beams. During installation of the antenna system10, an installer may make adjustments to the antenna system10, based on the characteristics of the particular deployment region, so that an optimal coverage pattern is obtained for the region. That is, the antenna system10may be adjusted in a manner that is designed to maximize the area within which maximum data rates are supportable within the deployment region. To accomplish this, the installer may, for example, adjust and appropriately fix the angular orientation of each of the side panels14,16,18,20with respect to the main panel12.

The angle of the side panels14,16,18,20may be adjusted based upon some physical characteristic of the deployment region such as, for example, the distance between the mounted antenna system10and the floor below (i.e., the deployment height). When the deployment height of the antenna system10is low (e.g., when the antenna system is ceiling mounted and the ceiling height is low), larger side panel angles may be used to broaden the area of maximum data rate coverage. In contrast, when the deployment height is larger, smaller side panel angles may be used to achieve more uniform coverage within the region. In one possible installation technique, an installer may first estimate the deployment height of the antenna system10and then adjust and fix the angles of the side panels14,16,18,20accordingly. A table maybe provided that lists the appropriate side panel angles for different ranges of deployment height. The side panel angles may be adjusted either before or after the antenna system10is actually mounted.

Other techniques for adjusting the angles of the side panels14,16,18,20during installation may alternatively be used. For example, in one approach, a flat reflective element (e.g., a mirror) is provided on one or more of the side panels of the antenna system10for use in adjusting the side panels14,16,18,20. One installer may then adjust the angle of a side panel while another installer directs, for example, a laser pointing device at the reflective element from a point where the corresponding beam is to be centered. When the laser pointer is reflected directly back upon itself, the angle of the side panel is fixed in place. A similar technique utilizes an installer's eyesight to determine whether proper alignment of the beam has been achieved. That is, one installer may stand at the point where the corresponding beam is to be centered and view the reflective element using an optical device, such as binoculars or a telescope, while another installer adjusts the angle of the corresponding side panel. When the first installer sees his own image in the reflector, he instructs the second installer to fix the side panel in place. An installer may determine the appropriate place to stand during adjustment based on criteria such as, for example, the size and shape of the room, the deployment height, knowledge of antenna beam width, etc.

In at least one implementation, one or more of the antenna arrays22associated with the side panels14,16,18,20have electronic beam steering capability. That is, phased array techniques are used to provide an additional level of adjustability in the direction of the beam. Phased array techniques may also be used to provide some degree of beam shaping capability. These capabilities may be used by an installer to further improve the maximum data rate coverage pattern within the deployment region (e.g., after the mechanical adjustments have been made). For example, an installer may be able to direct a beam from one of the side panels to the left or right to obtain enhanced coverage in, for example, an odd shaped corner of a room. The installer may also decide to adjust the shape of the antenna beam (e.g., the beamwidth, etc.) to better suit a particular deployment region. To electronically adjust the direction of the main beam associated with a side panel, the excitation phases of the corresponding array elements may be adjusted. To electronically adjust the shape of the main beam, the excitation phases and amplitudes of the corresponding array elements may be adjusted. An adjustable beamformer network is typically used to provide such functionality. Such beamforming techniques are well known in the art. Once an installer has achieved an optimal beam direction and/or shape for the beam associated with a side panel, the corresponding phase and/or amplitude values are fixed within the associated beamformer and do not change thereafter (unless the antenna system10is subsequently moved or a periodic recalibration is performed).

It should be appreciated that the antenna system10ofFIG. 1is merely illustrative of certain inventive principles and many modifications can be made thereto. For example, any number of pivotable side panels may be used. In one possible implementation, for example, only a single pivotable side panel is provided. In addition, the side panels and the main panel may assume any shape. For example, in another possible implementation, the main panel12has a hexagonal shape and six side panels are provided, one hinged on each edge of the hexagon. As will be appreciated, any number of different configurations can be used. Likewise, the number and configuration of the antenna elements within each array may be varied. In at least one embodiment, as illustrated inFIG. 3, an antenna system30is provided that includes a main panel12having a single antenna element28and side panels14,16,18,20that each include an array of elements. It may also be desirable to include only a single element within one or more of the side panels. Any of a wide variety of different antenna element types may be used within an antenna system in accordance with the invention. In one approach, for example, microstrip patch elements are used on each of the panels. Other types of elements that can be used include, for example, dipoles, ground planes, slots, loops, and others, including combinations of the above. Any type of polarization can be used including, for example, linear, circular, elliptical, or cross-polarization.

As described previously, the antenna system10ofFIG. 1will typically include one or more locking mechanisms for locking the side panels14,16,18,20in place during installation. As will be appreciated, any structure that is capable of locking a pivotable side panel in place may be used. In one approach, for example, the hinges24coupling the side panels to the main panel include screws (e.g., with a wingnut) that may be tightened to lock a corresponding panel in place. Clamps, brackets, and other mechanical structures may alternatively be used.FIG. 4is a perspective view illustrating a fixture36that is used in at least one embodiment of the invention to fix the angle of the side panels14,16,18,20. The fixture36includes a base portion38having blocks40,42,44,46disposed in corresponding corners thereof. In one approach, the base portion38includes a wire frame that holds the corner blocks40,42,44,46in position. Planar materials may alternatively be used. The blocks40,42,44,46are preferably pyramidal in shape, although other shapes (e.g., square, rectangular, etc.) may alternatively be used. The actual shape of each block will typically depend upon the number and arrangement of the side panels being used. As illustrated inFIG. 5, the blocks40,42,44,46may include detents48, with corresponding angle indications, on appropriate sides thereof for use in setting the angle of the corresponding side panels. Stops50may also be provided to set upper and lower limits on the angle of the panels.

FIG. 6is a perspective view illustrating the fixture36ofFIG. 4with the antenna system10ofFIG. 1inserted therein. As shown, each of the side panels16,18,20of the antenna system10are press fit between corresponding pairs of blocks. After the antenna system10has been inserted into the fixture36, the installer may adjust the angle of each of the side panels14,16,18,20by moving the panel to the appropriate detent on the corresponding blocks. The panel is thereafter held in place by the compression force of the blocks. The antenna system10may then remain within this fixed position throughout its deployment life. In one embodiment, the blocks40,42,44,46are formed of a lightweight plastic material, although other materials may alternatively be used. Preferably, the material will be dielectric in nature. In at least one implementation, a radome structure is attached to the blocks40,42,44,46of the fixture36to cover and protect the antenna system10during deployment. The material used to provide the radome will preferably be low loss or transparent to radio frequency (RF) energy in the operational frequency range of the antenna system10.

As discussed above, the antenna system of the present invention will preferably be mounted in an elevated position within a deployment region. The side panel angles may then be adjusted and fixed in a manner that enhances the maximum data rate coverage area within the region.FIG. 7is a sectional side view of a room60having a ceiling-mounted antenna system10for use in providing network access services to wireless users within the room60. As shown, the main panel12of the antenna system10generates a main beam62in a generally downward direction that covers a central portion of the floor space of the room (side lobes may also be generated). Similarly, side panel16generates a main beam64in a generally downward direction that covers a side portion of the floor space and side panel20generates a main beam66in a generally downward direction that covers an opposite side portion of the floor space. Similar beams may be generated by the other side panels14,18of the antenna system10. Because almost the entire floor space is illuminated in a relatively uniform fashion, maximum data rates may be supported throughout the room60.FIG. 8illustrates a room70having a wall-mounted antenna system10that includes a main panel12and a single side panel16. The main panel12generates a beam72in a generally downward direction that covers a first side portion of the floor space of room70and side panel16generates a beam74in a generally downward direction that covers a second side portion of the floor space of room70. As will be appreciated, many alternative antenna system deployment scenarios are also possible.

FIG. 9is a bottom view of an antenna system80in accordance with another embodiment of the present invention. The antenna system80includes a single panel82having a number of separate antenna arrays84,86,88,90,92disposed thereon. In the illustrated embodiment, the panel82includes a main array84centrally located on the panel82and four side arrays86,88,90,92distributed around the main array84. The number, size, and arrangement of the arrays on the panel82and the size and shape of the panel82may vary from implementation to implementation. During operation, each of the arrays84,86,88,90,92on the panel82generates a corresponding antenna beam (receive and/or transmit). The antenna system80maybe electronically adjusted during installation to maximize the area of full data rate coverage within a corresponding deployment region. In one approach, for example, each of the side arrays86,88,90,92has an electronically steerable beam that may be adjusted by the installer during the installation process. The installer may, for example, make one or more measurements within the deployment region (e.g., deployment height, room size, distance to walls, etc.) and then set the angles of the individual beams accordingly using phased array techniques. In at least one embodiment, the shapes of one or more of the individual beams may also be adjusted during installation (by, for example, adjusting the excitation amplitude and phase of individual elements within a corresponding array). The beam generated by the main array84may or may not be adjustable. In at least one embodiment, a single antenna element is used in place of the main array84. Separate beamformers maybe provided for each of the arrays84,86,88,90,92on the panel82. Once an installer has achieved an optimal beam direction and/or shape for the beam associated with one of the arrays84,86,88,90,92, the corresponding phase and/or amplitude values are fixed within the associated beamformer and do not change thereafter (unless the antenna system80is subsequently moved or a periodic recalibration is performed).

FIG. 10is a sectional side view of the antenna system80ofFIG. 9. As shown, the antenna system80may include an optional mount94coupled to the panel82for use in mounting the system80within the deployment region. The mount may include any structure or structures capable of facilitating attachment of the antenna system80in an elevated position in the deployment region.

FIG. 11is a sectional side view of a room100having a ceiling-mounted antenna system80for use in providing network access services to wireless users within the room100. As shown, the panel82of the antenna system80generates a main beam102in a generally downward direction that covers a central portion of the floor space of the room100. Similarly, one side array on the panel82generates a beam104that covers a side portion of the floor space and another side array generates a beam106that covers an opposite side portion of the floor space. Similar beams may be generated by the other side arrays on the panel82. Because almost the entire floor space is illuminated in a relatively uniform fashion, maximum data rates may be supported throughout the room100.FIG. 12illustrates a room110having a wall-mounted antenna system80. The main antenna array on the panel82generates a beam112that covers a first side portion of the floor space of room110and a side array on the panel82generates a beam114that covers a second side portion of the floor space of room110. As will be appreciated, many alternative antenna system deployment scenarios are also possible.

FIG. 13is a bottom view of an antenna system120in accordance with yet another embodiment of the present invention. The antenna system120includes a single panel122having an array124of antenna elements disposed thereon. The number and type of elements within the array124and the size and shape of the panel122may vary from implementation to implementation. During operation, the array124generates multiple simultaneous antenna beams (receive and/or transmit) within a deployment region. A multiple-beam beamforming network is used in conjunction with the array124to generate the multiple antenna beams. The multiple-beam beamforming network will typically be co-located with the antenna system120. Such beam forming structures are well known in the art. In one implementation, one or more of the beams generated by the array124are electronically steerable to allow an installer to adjust the beam(s) in a manner that enhances the maximum data rate coverage area of the system120within the deployment region. After optimal beam positions have been achieved for a particular deployment region, the beamformer settings are fixed and the beams remain stationary thereafter.