Method and system for generating multiple radiation patterns using transform matrix

Abstract

A system and method for generating multiple radiation patterns is disclosed here. An antenna system comprises an antenna array having one or more antennas for providing a first radiation pattern and a second radiation pattern, a transform matrix for transforming one or more inputs into one or more outputs according to a transform function, wherein the outputs of the transform matrix provide signals to the antennas with predetermined phases and magnitudes for generating the first and second radiation patterns, and a transmitter for providing a first set of signals corresponding to the first radiation pattern and a second set of signals corresponding to the second radiation pattern to inputs of the transform matrix.

Description

FIELD OF THE INVENTION

This invention relates generally to antenna systems, and more particularly to the use of a transform matrix of an antenna array to generate multiple radiation patterns.

BACKGROUND

In communication systems, whether they conform to GSM, CDMA, or other technology standards, the communications between the base stations and the mobile terminals typically include one or more traffic channels for communicating data signals and one or more control channels for exchanging control signals. For some signal control channels, for example, a pilot channel of CDMA systems, the control signals have to be broadcasted omni-directionally to cover the whole or sectored cell. On the other hand, it is desirable to steer narrow beams formed for communicating through traffic channels with specified mobile equipment without interfering others nearby. The beam formed pattern is directed to particular users, and it has a narrow beam width.

Logically, this can be done by two approaches: the first approach is to generate the beamforming pattern via one set of antennas and generate the omni pattern via the other set of antennas. The second approach is to use a single set of antennas but the omni pattern needs be synthesized. However, the first approach will add the costs associated with the omni pattern generation. The physical arrangement of two antenna sets also adds some difficulties to the first approach. There are discussions about beam forming and omni broadcast synthesis issues. The difficulties of synthesizing omni-broadcast patterns with beam forming means remain as challenges awaiting newer and better engineering solutions.

Therefore, there exists a need to provide an improved approach that allows antenna arrays to provide both beam forming and omni patterns simultaneously without the need of either an additional antenna set for omni pattern or omni pattern synthesis.

SUMMARY

A system and method for generating multiple radiation patterns is disclosed here. An antenna system comprises an antenna array having one or more antennas for providing a first radiation pattern and a second radiation pattern, a transform matrix for transforming one or more inputs into one or more outputs according to a transform function, wherein the outputs of the transform matrix provide signals to the antennas with predetermined phases and magnitudes for generating the first and second radiation patterns, and a transmitter for providing a first set of signals corresponding to the first radiation pattern and a second set of signals corresponding to the second radiation pattern to inputs of the transform matrix.

One object of this present invention is to provide an antenna system, which comprises an antenna array having N antennas for providing a first radiation pattern having a narrow beam width and a second radiation pattern having a wide beam width, a transform matrix for transforming N input ends into N output ends according to a transform function M, and a transmitter. The N outputs of the transform matrix provide signals to the N antennas with predetermined phases and magnitudes for generating the first and second radiation patterns. The transmitter is configured to provide a first set of signals to the N inputs of the transform matrix corresponding to the first radiation pattern and a second set of signals corresponding to the second radiation pattern. The transform matrix combines the first and second sets of the signals for generating the predetermined phases and magnitudes needed for the first and second radiation patterns.

Another object of this invention is to disclose a method for generating multiple radiation patterns. The method comprises after determining a first output weight corresponding to a first radiation pattern having a first beam width and a second output weight corresponding to a second radiation pattern having a second beam width to be transmitted by the antenna array, first and a second input weights are obtained based on a transform function of a predetermined transform matrix coupled to the antenna array and the first and second output weights. A first and second set of input signals are then generated corresponding to the first and second radiation patterns to be programmed with the first and second input weights respectively.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram depicting a typical base station in accordance with one embodiment of the present invention.

FIG. 2 is a schematic diagram illustrating another arrangement of the typical base station shown in the FIG. 1

FIG. 3 is a diagram depicting a transform matrix in accordance with one embodiment of the present invention.

FIG. 4 is a flowchart diagram showing a process for generating weights for different radiation patterns according to one embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Although the present invention is illustrated below with regard to a few limited examples, it is understood that the present invention is applicable to any multiple access technologies. Such access technologies include Frequency Division Multiple Access (FDMA), Time Division Multiple Access (TDMA), Code Division Multiple Access (CDMA), and Orthogonal Frequency Division Multiplex (OFDM) systems and any combination thereof, whether synchronized or unsynchronized, using Frequency Division Duplex (FDD) or Time Division Duplex (TDD).

FIG. 1 illustrates an antenna system 100, which is a part of a base station, in accordance with one embodiment of the present invention. The antenna system 100 comprises at least one antenna array 110, a Tx/Rx duplexer array 120, a transform matrix 130, a transmitter 140, and an electronic circuit module 150. The antenna array 110 comprises a plurality of antennas 110 for full cell 360 degree coverage or sectored cell coverage, such as 120 degree. Besides, the antenna array 110 is connecting to the transform matrix 130 via a duplexer ends 121 of the Tx/Rx duplexer array 120, which may be implemented as a plurality of duplexers, circulators, or switchers corresponding to each antennas 110. The receiving ends 123 of the Tx/Rx duplexer array 120 are connected to receivers (not shown) of the base station 100. The transmission ends 122 of the Tx/Rx duplexer array 120 are connected to the output ends 132 of the transform matrix 130. On the other hand, the input ends 134 of the transform matrix 130 are connected to the transmitter 140, which is controlled by the electronic circuit module 150 of the base station 110. Moreover, since the number of input ends 134 and output ends 132 of the transform matrix 130 is identical, the transform matrix 130 could be denoted as an N×N transform matrix 130. In such case, the transform function of this N×N transform matrix 130 from the input ends 134 to the output ends 132 could be denoted as M. The inverse transform function of this N×N transform matrix 130 from the output ends 132 to the input ends 134 could be denoted as inv(M) or {overscore (M)}.

As an example, assuming that the number of antennas 110 of this antenna array 110 is eight, it implies that N is equaled to 8. In order to generate a first desired radiation pattern, denoted as N₁, an N×1 vectored signal weight, denoted as W₁ with appropriate phases and magnitudes corresponding to this first radiation pattern N₁, has to be fed into the transmission ends 122 from the output ends 132 of the transform matrix 130. Likewise, in order to generate the i-th desired radiation pattern, denoted as N_i, a corresponding vectored signal weight, W_i, may be fed into the transmission ends 122 and then fed into the antenna array 110.

The vectored signal weight, W_i, for each radiation pattern, N_i, can be determined according to the properties of previous signals exchanged in the communication system in the past or based upon some certain criteria. For example, a vectored signal weight steering narrow-formed beam to a specified mobile terminal is determined by identifying incoming direction of the specified mobile terminal's transmission. In another example, a predetermined vectored signal is determined after the antenna array 110 is physically settled in order to broadcast omni-directionally. The outputted signals of the transmitter 140 could be combined and placed in one or two of the output ends 132 as well as the corresponding antennas 110 by the transform matrix 130.

Since the transform matrix equation M and its inverse transform equation {overscore (M)} are known and the intended vectored signal weights could be determined dynamically or statically, vectored inputs W_i′, corresponding to each vectored signal weight W_i, of the transmitter 140 could be calculated accordingly as follows: W_i′={overscore (M)}*W_i the equation above is derived from the following transformation equation: W_i=M*W_i′ wherein W_i′ is a 1×N vector corresponding to the N×1 vector of W_i. Supposing that W_o and W_b are weights for frequency or time diverse signals, W_o is usually for common control and W_b is dedicated for traffic signals. For the purpose of common control broadcast, the radiation pattern generated with W_o has a wide beam width. On the other hand, the radiation pattern generated with W_b has a narrow beam width. Therefore, by applying the inverse transform equations above, W_o′ and W_b′ could be generated and applied by the base station to N signals, which are then fed to the input ends 134 of the transform matrix 130 to generate radiations with the original required weights W_o and W_b. This process assures that the desired two different patterns with expected weights are produced.

After the transform function M provided by the transform matrix 130, two intended radiation patterns generated with appropriate weights W_b and W_o are going to the transmission ends 122 of the Tx/Rx duplexer array 120 from the output ends 132 of the transform matrix 130. Therefore, the radio frequency signals emitted by the antennas 110 of the antenna array 110 could be formed in a narrow beam width and a wide beam width simultaneously.

FIG. 2 illustrates another arrangement of the typical base station 100 according to another embodiment of the present invention. In the embodiment shown in FIG. 1, the antenna array 110 is connected to the transform matrix 130 via the Tx/Rx duplexer array 120. However, in this embodiment shown in FIG. 2, the antenna array 110 is directly connected to the output ends 132 of the transform matrix 130. Besides, the input ends 134 of the transform matrix 130 are coupled to the duplexer ends 121 of the Tx/Rx duplexer array 120. Finally, the transmission ends 122 of the Tx/Rx duplexer array 120 are coupled to the transmitter 140. As illustrated above, the present invention allows that the duplex function of transmission and receiver to be performed before or after the transform function M.

Please refer to FIG. 3, which depicts a transform matrix 130 of a preferred embodiment in accordance with the present invention. In this regard, the transform matrix 130 is composed by a Butler matrix of 2×2 90 degree hybrids 136. The N×N Butler matrix is a beam forming network using 90 degree hybrids 136 to provide orthogonal beams. In the case of 8×8 transform matrix 130, there are 12 hybrids 136 formed in 3 rows, each row with 4 hybrids. When one of the input ends 134 of the transform matrix 130 is excited by a signal, all the output ends 132 of the transform matrix 130 are equally excited in amplitudes but with a progressive phase between the output ends 132. Since the Butler matrix is well known in telecommunication or electronics industry, it shall be understood comprehensively without further explanation.

Please refer to FIG. 4, which shows a flowchart diagram for using the transform matrix to generate weights for multiple radiation patterns in accordance with an embodiment of the present invention. As illustrated above, the base station comprises an antenna array, a Tx/Rx duplexer array, a transform matrix with a transform function M, and a transmitter. In this example, the antennas of the antenna array are coupled directly to the duplexer ends of the duplexer of the Tx/Rx duplexer array as in FIG. 1. In addition, the transmission ends of the Tx/Rx duplexer array are coupled to the output ends of the transform matrix and the input ends of the transform matrix are coupled to the transmitter. In another example of this embodiment, the antennas of the antenna array are coupled to the output ends of the transform matrix and the input ends of the transform matrix are coupled to the duplexer of the Tx/Rx duplexer array. Moreover, the transmission ends of the Tx/Rx duplexer array are coupled to the transmitter. The transform matrix may be implemented as a Butler matrix with 90 degree hybrids.

In this example, it is assumed that there are two different radiation patterns that are needed, one having a narrow beam width and the other a wide beam width. In order to differentiate the two radiation patterns, they should have their corresponding vector weights. Based on the expected first radiation pattern, a first output vectored signal weight corresponding to the first radiation pattern (e.g. having a narrow beam width) is determined dynamically in step 208. Also in step 212, a second output vectored signal weight of a second radiation pattern (e.g., having a wide beam width) is determined. These two steps may be processed concurrently or in reverse order. It is thus noted that the order of these two steps are not important. Since the transform equation of the transform matrix is known, its inverse function is also determinable. The base station has to generate signal inputs with appropriate input weights so that, when they pass the transform matrix, the output signals from the transform matrix will carry the expected first and second output vectored signal weights to form the two radiation patterns. A first input vectored signal weight could be calculated by applying the inverse of transform function with the first output vectored signal weight in step 216. Similarly, a second input vectored signal weight could be calculated by applying the inverse of transform function with the second output vectored signal weight in step 220. It is also understood that the calculation of the first and second input vectored signal weights in steps 216 and 220 could be done in parallel or in a reverse order. Therefore, in the final step 224, the base station generates the first and second signals corresponding to the first and second radiation patterns with the input vectored signal weights applied therewith. After they are applied with the corresponding weights, the first and second signals become signal vectors of N×1, where N is the number of antennas. After combining and feeding these two vector signals through the transform matrix to the antenna array, two desired radiation patterns will be generated.

As an alternative, all inputs to the transform matrix can be combined with the matrix, and only generates a single output or a selected number of outputs to be transmitted to a designated antenna or elements. For example, if a particular antenna in the antenna array is designed to transmit the wide beam pattern, the input weights can be adjusted so that signals on other antennas are nulled (e.g., W=[1, 0, 0, 0 . . . 0]). Further, it is also possible that one radiation pattern is generated by the antenna array while the other radiation pattern is only transmitted by one particular antenna within the array. Or, a subset of antennas within the antenna array is producing one pattern, while another subset of the antennas is producing other patters

The above disclosure provides many different embodiments, or examples, for implementing different features of the invention. Also, specific examples of components and processes are described to help clarify the invention. For example, the above described process can be applied to generate more than two patterns if needed. These are, of course, merely examples and are not intended to limit the invention from that described in the claims.

While the invention has been particularly shown and described with reference to the preferred embodiment thereof, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims

1. An antenna system comprising: an antenna array having one or more antennas for providing a first radiation pattern and a second radiation pattern; a transform matrix for transforming one or more inputs into one or more outputs according to a transform function M, wherein the outputs of the transform matrix provide signals to the antennas with predetermined phases and magnitudes for generating the first and second radiation patterns; and a transmitter for providing a first set of signals corresponding to the first radiation pattern and a second set of signals corresponding to the second radiation pattern to inputs of the transform matrix.

2. The antenna system of claim 1, further comprising a Tx/Rx duplexer array having one or more duplexers for duplexing a predetermined number of transmission ends with a predetermined receiving ends into a predetermined duplexer ends.

3. The antenna system of claim 2, wherein the transmission ends couple to the outputs of the transform matrix and the duplexer ends couple to the antenna array.

4. The antenna system of claim 2, wherein the transmission ends couple to the transmitter and the duplexer ends couple to the inputs of the transform matrix.

5. The antenna system of claim 1, wherein the transmission matrix is an N×N Butler matrix composed by a predetermined 90 degree hybrids.

6. The antenna system of claim 1, wherein the magnitude and phase of the first or second radiation pattern is determined dynamically according to predetermined properties of previous signals received.

7. The antenna systems of claim 1, wherein the magnitudes and phases are programmed by applying predetermined vectored signal weights corresponding to the first and second radiation patterns.

8. A method for generating multiple radiation patterns by an antenna array having a predetermined number of antennas, the method comprising: determining a first output weight corresponding to a first radiation pattern having a narrow beam width and a second output weight corresponding to a second radiation pattern having a wide beam width to be transmitted by the antenna array; obtaining a first and a second input weights based on a transform function of a predetermined transform matrix coupled to the antenna array and the first and second output weights; and generating a first and second sets of input signals corresponding to the first and second radiation patterns to be programmed with the first and second input weights respectively.

9. The method of claim 8, further comprising passing the first and second sets of input signals through a Tx/Rx duplexer before they are fed to the transform matrix.

10. The method of claim 8, further comprising passing outputs of the transform matrix through a Tx/Rx duplexer.

11. The method of claim 8, wherein the transform matrix is an N×N Butler matrix composed by a predetermined 90 degree hybrids.

12. The method of claim 8, wherein the first radiation pattern is determined dynamically according to properties of previous signals received.

13. The method of claim 8, wherein the second radiation pattern is predetermined statically.

14. The method of claim 8, wherein the obtaining further includes obtaining predetermined first and second input weights for providing one or more selected outputs coupled to one or more predetermined antenna with at least one antenna not receiving any output.

15. An antenna system comprising: an antenna array having one or more antennas for providing a first radiation pattern for carrying a predetermined traffic channel associated with a predetermined mobile terminal and a second radiation pattern for carrying a control channel associated with one or more mobile terminals; a transform matrix for transforming one or more inputs into one or more outputs according to a transform function, wherein the outputs of the transform matrix provide signals to the antennas with predetermined phases and magnitudes for generating the first and second radiation patterns; and a transmitter for providing a first set of signals corresponding to the first radiation pattern and a second set of signals corresponding to the second radiation pattern to inputs of the transform matrix.

16. The antenna system of claim 15, further comprising a Tx/Rx duplexer array coupled to the transform matrix and the antennas having one or more duplexers for duplexing a predetermined number of transmission ends with a predetermined receiving ends into a predetermined duplexer ends.

17. The antenna system of claim 16, wherein the transmission ends couple to the outputs of the transform matrix and the duplexer ends couple to the antenna array.

18. The antenna system of claim 16, wherein the transmission ends couple to the transmitter and the duplexer ends couple to inputs of the transform matrix.

19. The antenna system of claim 15, wherein the transmission matrix is an N×N Butler matrix composed by a predetermined 90 degree hybrids.

20. The antenna system of claim 15, wherein the magnitudes and phases of the first or second radiation pattern is determined dynamically according to predetermined properties of previous signals received.

21. The antenna systems of claim 15, wherein the magnitudes and phases are programmed by applying predetermined vectored signal weights corresponding to the first and second radiation patterns.