The invention relates to an array processing method and an array receiver in a wireless communication system, and more particularly, the invention relates to a spatial domain matched filtering method and an array receiver thereof
For a long time, wireless communication systems have been facing a conflict between the limited spectrum resources and the continuously and quickly increasing of the number of users. Although system capacity has been increased to a certain extent by technologies such as frequency division multiple access (FDMA), time division multiple access (TDMA), and code division multiple access (CDMA), these technologies are far from the demand of ever-increasing quantity of wireless traffic. Therefore, people begins to utilize the spatial domain characteristic of a data transmission channel, e.g. diversity, sectorization, and switching multi-beam and adaptive antenna array, etc., to increase the capacity of a receiving system. By using these methods, communication quality of a wireless communication system have been improved to some extent, and the capacity have been increased.
In the diversity technology, signals received by different antennas with a space larger than 10 carrier-wavelength are not correlated. The signals received by respective antennas are combined by using a maximum ratio to improve system performance such as multipath anti-fading.
In the sectorization technology, a cell is divided into 3, 6, 9, or 12 sectors, each sector being configured with an antenna and a predetermined spectrum range. The interference of the communication channels can be decreased to a certain extent by sectorization, thereby increasing communication quality of the system.
The switching multi-beam technology is to form fixed beams in a cell in different directions, wherein signal quality of an expected signal in each beam is detected by a base station, and the best beam is selected to be received. One of the main reasons for calling it switching multi-beam is that during a procedure that the system selects a beam, there are controlled switches on the channels between each beam and the respective channel receiver, that is, a “switch matrix”. After a certain beam is selected, a switch between the beam and the corresponding channel receiver is closed, while the switches of the other channels are open.
The signals received by respective antennas are weighted and combined adaptively by an adaptive antenna array based on maximum signal to noise ratio criterion, maximum likelihood criterion, and minimum mean square error criterion, etc. The interference and noise signals are suppressed effectively, thereby increasing the entire performance of the wireless system.
Because the diversity method requires a large distance between the antennas (normally, larger than 10 wavelengths), the more the antennas, the more the spaces are occupied. However, spaces used practically by a base station are limited. In addition, although the diversity method for combining by using the maximum signal to noise ratio has the effect of multipath anti-fading, it cannot suppress signal interference effectively.
The common sectorization methods have used 3 sectors or 6 sectors. The reason for not using more sectors is that the more the division of the sectors, the less the spectrum resources can be used by each sector, and signal relay efficiency will be decreased. Furthermore, the more the division of the sectors, the more the beams overlap between different sectors, interference between the channels will increase, and system performance will decrease.
It can be considered to some extent that switching multi-beam is a type of sectorization method, whereby the division of sectors is formed dynamically by a combination of different beams. Because “the best” beam is set for receiving signals, switching multi-beam differs from the sectorization method. The more the beams of the switching multi-beam overlap, the more gain loss at the boundary between the beams will be decreased. The field of a beam of a current switching multi-beam system is cohered and overlapped by a directional antenna or by using a radio frequency phase shift network (for example, Butler matrix) to form a plurality of narrow beams directing to different directions in the space for covering a cell. In theory, the narrower the beams are, the better the performance of spatial domain filtering a multi-beam antenna switched by beams will have, and the stronger the ability for suppressing the signal interference. However, because an aperture of a directional antenna is limited, and phase shift accuracy of a radio frequency phase shift network is limited, the width of a beam is limited, and the overlapping the beams is limited. As a result, the ability for improving communication capacity of the existing switching multi-beam systems is limited. Furthermore, since a switching matrix of the existing switching multi-beam systems is implemented by radio frequency switching devices, it makes the cost of system hardware increase. When beams are selected by switching beams, it is implemented normally based on power magnitude of an expected signal in a beam. When there is strong interference, and the time for evaluating expected power of a user is rather short, it will sometimes cause malfunction in selecting the beams.
An adaptive antenna array employs an adaptive algorithm based on different standards to obtain an array-weighting factor. Although optimum system performance can be achieved in some extent, a large amount of calculation will be required for the adaptive algorithm with excellent performance. The requirement for digital signal processing devices is rather high, and a number of algorithms cannot be implemented by using high speed processing chips that are currently used.
Based on the above reasons, and by incorporating the technology of switching multi-beam and adaptive antenna array, one of the objectives of the invention is to provide a digital baseband spatial domain matched filtering method for an array receiver in a radio communication system. The method allows simple and small amount of calculation. Therefore, the cost for implementing the hardware is low, while the system performance is better.
Based on the above objective of the invention, a digital baseband spatial domain matched filtering method provided by the invention comprises the steps of:
(a) receiving array digital signals;
(b) performing a weighting calculation for the array digital signals and weighting vectors of NB set to obtain a digital beam output signal SB
(c) evaluating the power value PS
PS
and normalizing the digital beam output signal SBi(n) to obtain a power normalized digital beam output signal
wherein, the prefix “*” indicates a complex conjugation calculation, αP is a constant, 0<αP<1;
(d) correlating the power normalized digital beam output signal {tilde over (S)}B
Coeffi(k)=Coeffi(k)+αCoeffi(k−1)
wherein, the prefix “*” indicates a complex conjugation calculation, s(n) is the reference signal; N is a total amount of sample points, a product of N with a sample time is smaller than coherent time; Coeffi(k) indicates the correlation coefficient reflecting the energy of the expected signal in an ith beam, obtained by accumulating a kth correlation parameter, and α is a constant, 0.5<α<1;
(e) comparing the correlation coefficients Coeffi(k) reflecting the energy of the expected signal in respective beams to obtain a maximum correlation coefficient Coeffmax, and the digital beam output signal SB
Based on another objective of the invention, an array receiver is provided by the invention, which comprises:
an antenna array composing of a plurality of antennas;
an array digital signal generation module connecting with the antenna array for transforming analog signals received by the antenna array into digital signals;
a digital baseband spatial domain matched filtering module, coupled to the array digital signal generation module, for forming at least one signal beam on each channel for the digital signal of the array digital signal generation module;
a digital receiver module, coupled to the digital baseband spatial domain matched filtering module, for receiving at least one signal beam formed on each channel by the digital baseband spatial domain matched filtering module, and combining the signal beam over a time domain; and
wherein the digital baseband spatial domain matched filtering module comprises:
As described above, a new and simple algorithm is used in the digital baseband spatial domain matched filtering module in the invention, thereby the hardware structure can be simplified, and a better system performance can be provided.
The embodiment of the invention will be described below in detail by incorporating the drawings.
The received signals are processed by the digital baseband spatial domain matched filtering module 104 shown in
The digital signals outputted by the array digital signal generation module 103 in the array receiver 100 shown in
wherein, l=1,2, . . . , L is the number of multipath; a(θl) is M*l−dimension vector, indicating an array response on M antenna elements produced by the first multipath signal relating to the direction θ; θi is an arriving direction of wave of the first multipath; hl(t) is the fading experienced by a signal of the first multipath; s(t) is a transmitted expectation signal; τl is a delay of the ith multipath signal; and n(t) is the interference and noise signal of the array.
Based on the types of the antenna array 102, such as a uniform straight line array, circular array, etc., it can be predetermined that the signals in the different direction have an array response a(θi)(i=1,2, . . . , NB) with the array. Wi=aH(θi) (the prefix H indicates conjugation rotator arithmetic which is used as the weight of a signal received by respective antenna elements of the array, corresponding to the beams being formed by the array in direction θi, and performing the spatial domain filtering for the received array digital signal X(t). In order to consider both the result of the spatial domain filtering and the process ability of the system digital signals, the value of NB is taken to allow the difference between the gain of an intersection point 201 of the beams formed by aH (θi), and the maximum gain among the entire beams is −3˜0 dB, i.e., a line 202 marked in
An internal function diagram of the spatial domain matched filtering module 104 is shown in
SBi(n)=Wi*X(t)=aH(θi)a(θd)hd(t)S(t)+aH(θi)n(t)i=1,2,3 . . . NB□ (2)
The NB digital beam output signals SB
In the multi-beam selection module 403, in a correlation time period, power value PS
PS
Power normalization is performed for the digital beam output signals SB
The normalization process significantly reduces the interference to beam selection correlation.
In most of the communication systems, transmitted signals often include information that have known to a receiving end in advance, such as known training sequences, pilot symbols, etc. For example, in a GSM system, 26 bits of known training sequences are included in each normal burst; in a WCDMA system, known pilot symbols are included in each slot of DPCCH. The reference signal s(t) can be obtained directly or indirectly at the receiving end by using these known information. Based on the correlation of reference signal s(t) and the digital beam output signal SB
Coeffi(k)=Coeffi(k)+αCoeffi(k−1)□6□
Coeffi(k) represents a correlation coefficient reflecting the energy of the expected signal in an ith beam obtained by accumulating a kth correlation parameter, a is a factor for accumulating non-correlation parameter, which relates to the factors, such as moving speed of a mobile station in a cell, and it is normally taken 0<α<1. It can be seen from the equations (1) to (5) easily that a direction θmax corresponding to the maximum coefficient Coeffmax among NB correlation coefficient is a direction approximate that of the expected signal. Therefore, the array weight can be selected as W=aH(θmax) for a digital beam output signal so as to obtain the maximum gain.
For the spatial domain matched filtering module 104 as shown in
Now refer to
The digital switching matrix 404 is mainly composed of an array of beam data lines 601, an array of output data lines 109, an array of digital switches 602, and an array of switch controlled signal lines 603. It can be seen from
It can be set that when element Cij in the matrix is 1, it indicates that the digital switch 602 is switched on, and the ith beam data line 601 is connected to the jth output data line 109; when Cij is 0, the ith beam data line 601 is disconnected with the jth output data line 109. In this way, the multi-beam selection module 403 controls the digital switching matrix 404 to easily select suitable beams for outputting to the prescribed output terminals.
The spatial domain matched filter set 401 is shown in
The construction structure and the operation principle of the array receiver in the invention have been described in detail herein above. Particularly, the construction and the operation principle of the digital baseband spatial domain matched filtering module 104, which is designed specially and uniquely by the invention, has been described. It can be seen from the above disclosure that a new spatial domain matched filtering method is used to implement the digital baseband spatial domain matched filtering module 104. In the method, in order to obtain the digital beams, the above equations (3), (4), (5) and (6) are used to obtain the correlation coefficient reflecting the expected signal energy in the respective beams. The digital beams are then selected and determined by the correlation coefficient. A flow chart of the spatial domain matched filtering method of the invention is shown in
As shown in
At step S2, the weighting calculation is performed for the array digital signals and NB sets of weighted vectors to obtain NB sets of the digital beam output signals SB
At step S3, based on the digital beam output signals SB
At step S4, the correlation coefficient Coeffi reflecting the expected signal energy in each beam is evaluated based on the equations (5) and (6).
In step S5, the obtained correlation coefficients Coeffi (k) reflecting the expected signal energy in the beams are compared and selected to obtain a maximum correlation coefficient Coeffmax, and the digital beam output signal SB
In the embodiment corresponding to the method described herein, steps S3 and S4 are implemented by the multi-beam selection module 403 of the digital baseband spatial domain matched filtering module 104 shown in
It can be seen that for a four-element array receiver, when an input signal to noise ratio is about 2.2 dB, a bit error rate (BER) of the signal outputting by the digital receiver module of the present invention is about 10−3, whereas for a digital receiver module with a single antenna, to reach the BER of 10−3, the signal to noise ratio of the antenna input signal is about 8.2 dB. Thus, by using the method provided by the invention, the system performance is improved significantly.
Number | Date | Country | Kind |
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00133919 A | Nov 2000 | CN | national |
This utility patent application is a continuation application and claims priority of the PCT International Patent Application, serial number PCT/CN01/00693, filed on May 8, 2001, which claims the priority of the Chinese patent application, serial number CN 00133919.2, filed on Nov. 15, 2000; subject matter of which are incorporated herewith by reference.
Number | Name | Date | Kind |
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5379046 | Tsujimoto | Jan 1995 | A |
5990831 | McDowell | Nov 1999 | A |
6188718 | Gitlin et al. | Feb 2001 | B1 |
Number | Date | Country |
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1261223 | Jul 2000 | CN |
2177207 | Dec 2001 | RU |
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Number | Date | Country | |
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20030236108 A1 | Dec 2003 | US |
Number | Date | Country | |
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Parent | PCT/CN01/00693 | May 2001 | US |
Child | 10439219 | US |