KR20010109061A - Signal processing method and apparatus of smart antenna system - Google Patents

Abstract

The present invention relates to a signal processing method and apparatus for a smart antenna system for calculating an optimal weight vector in which the reception power of a receiving terminal is maximized using the Lagrange multiplier method. Weight vector to be used by the base station to maximize received signal strength Provides a method and apparatus for obtaining the optimal value of. Weight vector Although is used at the transmitting base station, information for calculating this optimal weight vector is calculated at the receiving terminal and provided to the transmitting base station. In some cases, the optimal weight vector value calculated by the receiving terminal itself may be provided to the base station, and instead of sending the weight value itself, the receiving terminal may update the current weight value to approach the optimal weight value. There are two cases of sending bays to a base station. The present invention proposes a technique that enables the transmitting base station to apply an optimal weight vector in either of these two cases.

Description

SIGNAL PROCESSING METHOD AND APPARATUS OF SMART ANTENNA SYSTEM} for calculating an optimal weight vector that maximizes the receiving power of a receiving terminal using the Lagrange multiplier method

The present invention relates to a signal processing method, apparatus, and a recording medium of a smart antenna system for calculating an optimal weight vector in which the reception power of a receiving terminal is maximized using the Lagrange multiplier method.

The present invention uses the Lagrange multiplier method to calculate the optimal weight vector that maximizes the reception power of the receiving terminal. An object of the present invention is to provide a signal processing method, apparatus, and a recording medium of a smart antenna system for obtaining an optimal value.

1 is a view for explaining the concept of the present invention,

2 is a conceptual diagram of an arrangement system for transmitting a signal s ( t ) to a target terminal in the present invention;

3 is an explanatory diagram of a channelization distributor according to the present invention;

4 is a diagram illustrating a signal environment applied to a multipath channel of each of a plurality of subscribers according to the present invention;

FIG. 5 illustrates an embodiment for applying the technology provided herein to actual mobile communication to make an optimal transmission beam. FIG.

6 is an exemplary block diagram of a system for calculating an optimal weight vector at a receiving terminal using the technique provided by the present invention.

7 is a flow chart according to an embodiment of the present invention;

1 is a diagram illustrating the concept of the present invention, FIG. 2 is a conceptual diagram of an arrangement system for transmitting a signal s ( t ) to a target terminal, and FIG. 3 is an explanatory diagram of a channelization distributor according to the present invention.

Suppose signal s ( t ) is a signal to be transmitted from a base station to a mobile terminal.

First, consider the case where there is a single propagation path between the target terminal and each antenna. Application of the proposed technique to a channel with a large number of subscribers and multiple paths for each subscriber will be described after considering a single propagation path of a single subscriber first.

As shown in FIG. 3, the signal s ( t ) passing through the distributor is distributed to the transmission signal of each antenna channel. As one of methods to separate and extract a signal transmitted from each antenna in a receiving terminal, a signal s ( t ) may be processed in a splitter so that signals transmitted from each antenna are orthogonal to each other. Although not mentioned in detail about the orthogonalization scheme, it is apparent to those skilled in the art that the orthogonalization of the transmitted signal s ( t ) can be performed by arbitrarily selecting a known method.

In the present invention, although the signal to be transmitted is processing the transmission signal in each antenna channel between the splitter, it is also possible to orthogonalize each antenna signal in another concept. In any case, as a result of the orthogonalization process, signals transmitted from each antenna are orthogonal to each other, and the orthogonal interval P is defined in advance.

In other words, this is expressed as a formula below.

In Figure 2, s ( t ) is a signal sent to the target terminal, Is Channel between antenna element and target terminal (including attenuation and phase delay), Is The weights (complex conjugates) to be applied to the antenna elements are respectively shown.

3 is an explanatory diagram of a channelization divider according to the present invention, in which the signals transmitted to each antenna { s ₁ ( t ),... , s _N ( t )} is orthogonal to the interval. In this case, since the array system uses the same weight vector for the period P , P is the channel characteristic { h ₁ ( t ),. , h _N ( t )} should be short enough to ignore the change.

However, like all because it must be the same weight vector applied during the orthogonal interval of P periods, and should not P is too long, so the propagation channel characteristic discard too significantly changed. The strength of the signal transmitted by each antenna for convenience of description below ( In other words, Let's assume.

The signal transmitted from each antenna is a pattern s ₁ ( t ), s ₂ ( t ),... By correlating s _N ( t ) with the received signal, the signal for each antenna channel can be separated separately. As such, it can be seen that the procedure for calculating the optimal weight vector is applied to the pilot signal. Of course, the computed weight vector is used for the data sequence during each corresponding time slot. As mentioned above, assuming a channel of each antenna having only one path, the signal y received from the terminal is as follows.

here Is Weight applied to the first antenna channel (complex conjugate), Is Propagation path characteristics (attenuation and phase delay) between the first antenna and the receiving terminal. In the proposed technique, s ( t ) and Wow All use complex numbered phasor notation. Separation of each antenna channel of the received signal y is performed through the following correlation procedure at the receiving terminal.

According to Equations (1) and (2), the output z _j of the correlator correlating the received signal y with the signal s _j ( t ) transmitted from the j- th antenna can be written as follows. (However, for convenience of explanation, the following equations omit interference and noise from the received signal.)

That is, the channel characteristic h _j between each antenna and the receiving terminal is included from the received signal y. Can be obtained from the receiving terminal for j = 1, 2, ..., N , respectively. New variable To When defined as follows, the power of the received signal To maximize Is the same as maximizing The weight vector for maximizing can be obtained by the maximal inherent vector method known in the art.

That is, if the signal transmission signal can be distinguished by each antenna or signal as shown in Equation (3) in the receiving terminal, a known eigenvector method, for example, [1] "Signal Processing Apparatus and Method for Reducing the Effects of Interference and Noise in Wireless Communications Utilizing Antenna Array ", US patent (5,808,913), September 15, 1998, [2]" Design Technique of an Array Antenna and Telecommunication System and Method Utilizing the Array Antenna ", US patent (5,999,800), 1999 12. 7, [3] "Signal Processing Unit for Minimizing Interference and Reducing the Effects of Noise in Wireless Communication Systems", Korean Patent Registration (0197794), Feb. 25, 1999, [4] Signal Processing Method of Array Antenna Using Eigenvectors Corresponding to Maximum Eigenvalue of Autocorrelation Matrix ", Korean Patent Registration (0229094), Aug. 31, 1999, [5]" Adaptive Array Antenna for Code Division Multiple Access Mobile Network Signal processing method of system and its device Using a Media ", Korean Patent Application (99-3115), 1999. 1. 30) or the like, it is possible to calculate a weight vector that maximizes the reception power.

That is, the received power at each snapshot Weight vector to maximize To solve the problem It is obtained by using the above-mentioned well-known technique [1]-[5] by substituting the problem of maximizing. In this specification, a technique for calculating an optimal weight vector at which a reception power is maximized at a reception terminal is introduced by using a Lagrange multiplier method, which is one of known technologies.

Receive Power at Receiving Terminal Can be written as

only, ego, Is, Wow Are each and A column vector defined by. (In this specification, vectors are represented by underlined lowercase letters and matrices are shown in bold capital letters.)

However, in a situation where interference and noise are excluded The weight vector to obtain because the rank of is 1 for each snapshot. Is the propagation path vector It becomes itself. However, considering interference and noise (including multipath interference and other signal interference) Has a rank of N for each snapshot.

Since each antenna channel can be separated as shown in equation (3), Each entry value of can be obtained from the receiving terminal. As also mentioned above, it can be seen that the optimal weight vector maximizing the power of the received signal results in a maximum ratio combining (MRC) of the desired signal.

In other words, (only, Is a real constant).

The optimal weight vector that maximizes the received power of equation (4) above is provided from the solution of the maximal eigenvalue problem as shown in [1]-[5]. That is, the problem of finding the optimal weight vector is a problem of finding the eigenvector corresponding to the maximum eigenvalue in the eigen problem of Equation (5)

here Is a matrix Is the maximum eigenvalue of.

So far, a single path has been considered, but it can be applied to the case of multipath considering each weight vector for each path.

4 is an exemplary view illustrating a signal environment applied to a multipath channel of each of a plurality of subscribers in the present invention.

In the figure, s ( t ) is a signal to the target terminal, Is Terminal and Between antenna elements Route channel, Is Terminal and For route channel Weight vector (complex conjugate) of the antenna element.

As shown in FIG. 4, the technique proposed in the present invention may be applied to a signal environment having a plurality of terminals in which multiple paths exist for each terminal. In this case, as shown in FIG. 4, an optimal weight vector is separately calculated for each propagation path for each terminal.

5 is a block diagram of a system using the present technology using a pilot channel and a traffic channel as an example for applying the technology provided herein to actual mobile communication to create an optimal transmission beam. . When the pilot channel signal is transmitted without being orthogonalized for each antenna and weighted, a weight vector having a maximum reception power at the receiver can be calculated by the corresponding terminal using the technique of the present invention. When the signal is transmitted using the calculated weight vector in the traffic channel, the optimal beam can be transmitted. In this case, the pilot signal may also be transmitted by applying the calculated weight vector to the pilot signal in order to transmit the optimal beam.

6 is a block diagram of an example of a system for calculating an optimal weight vector at a receiving terminal using the techniques provided by the present invention.

In a closed loop scheme in which a weight value to be used by a transmitting base station is calculated by a receiving terminal and sent to a transmitting base station, it is important to calculate a weight vector value to a base station. That is, although the weight value itself calculated by the receiving terminal may be sent to the base station, a separate channel must be used to send the weight vector. In order to update the weight vector to an optimal value without occupying a separate channel in this way, only the amount of change or the direction of change of the phase value of the weight vector may be sent to the base station.

That is, in order to displace the beam at the transmitter station by + △ or-△, the current weight vector To Should be updated to This is to inform the transmitting base station only of the direction of updating the weight vector itself, which is determined to be not transmitted from the receiving terminal to the transmitter station.

Using this method, the weight vector can be updated in the + or-direction by a predetermined Δ even with only one digit.

From now on, according to the technique of obtaining the eigenvectors corresponding to the maximum eigenvalues, embodiments of the present invention will be constructed and described in detail for each embodiment.

In other words, it can be used to solve the maximum eigenvalue problem shown in Eq. (5) by modifying the known Lignan multiplier method, and by configuring the embodiments for each method to calculate the optimal weight vector and efficiently calculate the weight vector It will be described in detail how to transmit to the base station.

Example: Optimal Using Lagrange Method How to get

In the present embodiment, as described above, a known Lagrange method is employed to obtain a eigenvector corresponding to a maximum eigen value while considering a signal environment in which a signal is processed after transmission to be orthogonal to each antenna as described above. use. Since the Lagrange method is described in detail in [1], the present invention introduces a procedure of applying the Lagrange method to calculate an optimal weight vector at a transmitter station at a receiving terminal and returning it to a transmitting base station.

First, the weight vector and Lagrange multiplier λ are initialized.

Second, the current weight vector at the base station The signal is transmitted by weighting. In other words, The transmission signal from the first antenna As it is the current weight If you use Will be sent out. Therefore, the signal transmitted in the array antenna system consisting of N antenna elements is received at the terminal as follows.

Third, the received signal in a pattern transmitted from each antenna to separately classify the signals transmitted from each antenna. Signal classified by each antenna channel by correlating To calculate.

Fourth, the Lagrange multiplier λ is calculated by the receiving terminal as follows.

here The value of μ is a predetermined adaptive gain. only, ego, being.

At this time, Fixed to a constant value (for example, = 1), it is also suggested in the present invention that the Lagrange multiplier λ can be simply calculated as follows.

Fifth, the weight vector is updated in the receiving terminal by using the Lagrange multiplier λ obtained in the fourth step as follows.

In the present invention, it is possible to use four different calculation methods applied as follows in the above formula.

First, in the above formula To a constant value (e.g. = 1) normalized To You can calculate it alone.

second, Instead of using the value of itself, use only the sign of that value, i.e. ), By introducing the method You can also calculate here ] Shows the sign of a value.

third, Is Applies only the sign of each element of ie Can be calculated by replacing it with a value. only, Is the value of each element Represents a vector determined by +1 or -1 by the sign of the corresponding element in.

Fourthly, in the same principle The value is To calculate the weight vector. Therefore, the weight vector updating method in this step can be calculated by dividing into five types.

Sixth, the weight vector updated at the receiving terminal is transmitted to the base station, and the weight vector is transmitted to the second step and repeated from the second. In this case, instead of sending the weight vector value calculated by the receiving terminal to the transmitting base station, only the difference with the current weight value may be sent. By using only one bit, the current weight value is transmitted by transmitting only the displacement code of the weight vector to the base station. It can also displace by △ or-△. That is, since the receiving terminal sends a digital value of 0 or 1 to the transmitting base station, the transmitting base station updates the current weight vector value so that the beam is displaced by + Δ or -Δ.

The adaptation procedure is As a process to maximize It is the process of calculating the weight vector for maximizing. The flowchart for the above procedure is shown in Figure 7.

According to the present invention using the Lagrangian multiplier method as described above, it is possible to calculate the optimal weight vector that maximizes the reception power of the receiving terminal with a small amount of calculation, which is excellent in terms of performance and the beamforming process per snapshot. Since the calculation amount is significantly reduced, it is possible to actually apply to a mobile communication system requiring a quick response.

In addition, by providing the optimum beam pattern to each subscriber to minimize the influence of the interference signal has a very excellent effect of improving the communication quality while significantly increasing the communication capacity per cell within a given bandwidth.

Claims (1)

In order to calculate the optimal weight vector with the maximum reception power of the receiving terminal, the weight vector to be used in the base station to maximize the received signal strength at each terminal using the Lagrange multiplier method Signal processing method of smart antenna system to find the optimal value of.