Patent Grant
10164329
The present invention relates generally to the field of wireless communication. In particular, the present invention relates to distributed antenna systems capable of robust multi-band operation for use in wireless communications.
Continued adoption of cellular systems for data transfer as well as voice communications along with introduction of new mobile communications devices such as Tablet devices make cellular coverage in urban environments a priority. In particular, improving cellular coverage in public venues where large a number of cellular users are present is important to provide a seamless user experience in the mobile communication arena. Distributed antenna systems (DAS) are being installed in sports arenas, convention centers and other public areas and are used to provide stronger RF signals to improve the communication link for cellular and data services. These DAS systems are crucial to maintaining capacity of cellular systems as users increase the amount of data that is uploaded and downloaded.
Initial DAS antenna systems were only required to operate over a few frequency bands, making the antenna design process easier. As the communications industry has moved from 2G to 3G cellular systems, frequency band count for DAS antennas has increased. With the advent of 4G communication systems such as Long Term Evolution (LTE), additional frequency bands are required from a DAS antenna system which increases the difficulty in terms of antenna design. LTE also brings a two antenna requirement needed to implement a Multiple Input Multiple Output (MIMO) antenna system.
As the density of mobile communication users increases in public spaces such as sports arenas and convention centers, and as more users access high data rate features such as file sharing and video downloads the signal to noise characteristics and RF signal levels of the cellular signals indoors become more important parameters. To maintain low noise floors in communication systems a parameter that is important to address in the antenna design is Passive Intermodulation (PIM). PIM products are generated when two RF signals at different frequencies are injected into an antenna port; the antenna, though being a passive device, can generate spurious responses due to “natural diode” junctions in the antenna. These natural diode junctions can be formed at the junction of two metal surfaces where the metals are dissimilar. Corrosion and oxidation at these junctions can also cause spurious frequency components due to mixing of the two RF signals. Proper antenna design and material selection is important to meet stringent, low PIM requirements. As PIM components increase, these spurious frequency components add to the noise level, which in turn results in reduced signal to noise ratio of the communication system. This will result in reduced data rates for users.
Low PIM requirements can be difficult to obtain in high gain antenna applications due to the large number of antenna elements typically used to form an array. Arraying multiple antenna elements together is a common technique used to generate higher gain antennas. The multiple connection points required when arraying multiple antennas together provide more opportunities for PIM to be produced; these connection points can be antenna element to ground plane connections, connector to ground plane interfaces, and coaxial transmission line interfaces.
Initially, low gain antennas were used implement DAS systems in public venues. To maximize capacity as the number of mobile users increased at public venues, higher gain antennas were used to replace the low gain, near omni-directional antennas. These higher gain antennas are typically a linear array of elements which provide a narrow or reduced beamwidth in one plane while maintaining a broad or wide beamwidth in the other principal plane passing through the main lobe of the radiation pattern. As the density of mobile communication users increases further there is a need to move from antennas that have a narrow beamwidth in one plane to narrow beamwidth in both principal planes of the radiation pattern. This move to full 2D arrays will bring more complexity to the arraying process as well as complexity in regards to maintaining PIM performance.
This patent describes a wideband antenna array capable of efficient transmission and reception in multiple frequency bands while maintaining low passive intermodulation (PIM) performance. Two arrays are co-located to provide a MIMO (Multiple Input Multiple Output) antenna solution. When multiple frequency bands are required to be serviced across lower cellular bands (700 to 960 MHz) and upper cellular frequency bands (1710 to 2700 MHz) a pair of arrays can be implemented for each frequency range, resulting in four arrays co-located to service lower and upper frequency bands for MIMO operation.
In one aspect of the present invention, a two conductor antenna is designed to cover a wide frequency range and provide a constant beamwidth across the frequency range. The two conductor antenna is designed to operate in proximity to a ground plane. This two conductor antenna can be used to populate an array that covers the wide frequency range. The antenna is designed such that the first conductor which is connected to the transmission line that feeds the antenna is completely isolated from the ground plane. The second conductor that acts as a counterpoise or “ground arm” of the antenna is also completely isolated from the ground plane. Portions of each conductor are positioned in close proximity to the ground plane, with these portions of each conductor dimensioned and spaced to form a capacitively coupled region when placed in proximity to the ground plane. This capacitively coupled region provides a region of low impedance at the frequency range of operation of the antenna. PIM products are reduced or avoided using this type design due to a lack of conductor to conductor interfaces, where two conductors would normally come into contact.
In one embodiment of the invention, the first conductor of a two conductor antenna contains a portion of conductor that is positioned in close proximity to the second conductor. The first conductor can be positioned in parallel to the second conductor and aligned within the same plane as the second conductor to form a region between the first and second conductors where portions of each conductor form a coupling region. This coupling region can be altered by varying the distance between the first and second conductor and the length of each conductor. This coupling region can be used to alter or optimize the impedance match of the antenna element at the frequency range of interest. This coupling region provides a method of impedance matching the antenna while maintaining low PIM attributes due to the lack of conductor on conductor contact regions.
In another embodiment of the invention, a first conductor is positioned in proximity to a second conductor, with the second conductor acting as a counterpoise to the first conductor. The first and second conductors are positioned next to a ground plane. A portion of the first conductor at the top of the conductor is oriented predominantly parallel to the ground plane. This portion of conductor is dimensioned to decrease the frequency of operation of the resultant antenna formed by the first and second conductors positioned in proximity to the ground plane. A portion of the second conductor can also be oriented and positioned predominantly parallel to the ground plane to decrease the frequency response of the resultant antenna.
In another embodiment of the invention, a first conductor is positioned in proximity to a second conductor, with the second conductor acting as a counterpoise to the first conductor. A third conductor is positioned in proximity to the second conductor, with the third conductor oriented predominantly perpendicular to the first conductor. All three conductors are positioned close to a ground plane. Both the first and third conductors are fed from separate transmission lines, resulting in a pair of driven antennas that utilize the same counterpoise conductor. The isolation between the two antennas is optimized by proper selection of the angle formed by the first and third conductors. The impedance match of the two antennas can be optimized by altering the spacing between the driven conductor, the first or third conductor, and the second conductor. All three conductors are isolated from the ground plane to provide low PIM attributes.
In another embodiment of the invention, the conductor used as a counterpoise is wedge shaped to better facilitate coupling to by multiple conductors. When the counterpoise conductor is wedge shaped with a predominantly 90 degree included angle, then two driven conductors can be coupled to the wedge shaped counterpoise conductor, and each driven conductor will couple to a planar section of the wedge shaped conductor that can be oriented in the same plane as a planar driven conductor.
In another embodiment of the invention, a first planar conductor is positioned in proximity to a second conductor, with the second conductor acting as a counterpoise for the first conductor. Both first and second conductors are positioned close to a ground plane. A transmission line is connected to a corner of the first planar conductor to provide a driven antenna. Portions of the first planar conductor are removed close to the ground plane to form a slot region between the transmission line and the end of the first planar conductor. At the end of the first planar conductor opposite from the transmission line a portion of the first conductor is positioned in proximity to the ground plane to form a region where the first conductor couples to the ground plane. The resultant slot region formed between the transmission line and the end of the first planar conductor can be altered in length and width to adjust the frequency response of the resulting antenna.
In another embodiment of the invention, when very wide bandwidth is required from the antenna a first planar conductor is positioned in proximity to a second conductor, with the first and second conductors overlapping each other. The overlap region can be used to alter the impedance properties of the antenna and the overlap region can vary along one or multiple edges of the planar first and second conductors. The second conductor acting as a counterpoise for the first conductor. Both first and second conductors are positioned close to a ground plane. A transmission line is connected to a corner of the first planar conductor to provide a driven antenna. Portions of the first planar conductor are removed close to the ground plane to form a slot region between the transmission line and the end of the first planar conductor. At the end of the first planar conductor opposite from the transmission line a portion of the first conductor is positioned in proximity to the ground plane to form a region where the first conductor couples to the ground plane. The resultant slot region formed between the transmission line and the end of the first planar conductor can be altered in length and width to adjust the frequency response of the resulting antenna.
The previous embodiment can be altered to provide a second antenna integrated into the first antenna by adding an additional pair of conductors, conductors three and four. Conductor three can be fed with a transmission line similar to the previous embodiment and conductor four can be connected to conductor two such that conductors two and four are now a single counterpoise for a two antenna assembly. If conductor four is connected to conductor two at a perpendicular orientation and if conductor three is parallel to conductor four then the two antennas formed by the four conductors will provide dual polarization capability with the two polarizations being perpendicular to each other.
Another embodiment of this invention relates to the transmission line configuration used to feed the previously described embodiments. The ground conductor of the transmission line used to feed an antenna can be capacitively coupled to the ground plane that the antenna is attached to eliminate the physical contact between conductors. Likewise the center conductor of the transmission line can be capacitively coupled to the antenna element. When implemented on some previous embodiments the result is an antenna and transmission line assembly where there are no conductor to conductor (metal to metal) contacts. This configuration will provide for improved PIM performance.
In another embodiment of the invention multiple antennas as previously described are combined on a single ground plane to form an array. A transmission line feed network is used along with combiners to feed the multi-element array. The entire array and feed network can be assembled without conductor on conductor contact, allowing for improved PIM performance from the array. Utilizing the pair of perpendicular antenna elements as previously described will result in a pair of arrays co-located on the same ground plane, with two combining feed networks feeding the two arrays. Dual polarization performance will result from the co-located arrays.
Now turning to the drawings,
This application claims benefit of priority with U.S. Provisional Ser. No. 62/159,090, filed May 8, 2015; the contents of which are hereby incorporated by reference.
| Number | Name | Date | Kind |
|---|---|---|---|
| 7724717 | Porras et al. | May 2010 | B2 |
| 7913022 | Baxter | Mar 2011 | B1 |
| 8610626 | Chang | Dec 2013 | B2 |
| 9263787 | Dupuy et al. | Feb 2016 | B2 |
| 9270374 | Cune et al. | Feb 2016 | B2 |
| 20110057852 | Holland | Mar 2011 | A1 |
| 20140266962 | Dupuy et al. | Sep 2014 | A1 |
| 20150162665 | Boryssenko | Jun 2015 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20170125912 A1 | May 2017 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62159090 | May 2015 | US |
