KR20060079555A - Method for removing the strongest interferer in the synchronized tdma network environment - Google Patents

Abstract

The present invention relates to a method for removing maximum interference elements in a synchronized TDMA network environment. The method for canceling maximum interference elements in a synchronized TDMA network environment according to the present invention is directed to adjacent cells periodically reported from a mobile station. Receiving power information on the BSC, analyzing and storing power information on the adjacent cells received by the BSC, and having a base station to which the BSC starts data transmission and reception using the same carrier frequency in the BSS; Determining, and if there is a base station to perform data transmission and reception using the same carrier frequency in the BSS, the BSC notifies the current mobile station of information of the TSC used by the base station; and Currently, the mobile station transmits to the base station using the TSC from the entire received signal. That comprises the step of removing the signal transmitted from the features.

According to the configuration of the present invention as described above it provides an advantage that can increase the reception performance and subscription capacity by finding and removing the interference signal of the other user most strongly affected.

Synchronized TDMA Network, Interference Cancellation, Receive Performance

Description

Method for removing the strongest interferer in the synchronized TDMA network environment             

1 is a diagram illustrating a model of a received signal transmitted from N base stations in a mobile communication environment and received at a receiving apparatus.

2 illustrates a burst structure transmitted in a GSM mobile communication system

3 is a diagram illustrating a configuration of a BSS for explaining a method of removing a maximum interference element in a synchronized TDMA network environment according to the present invention.

4 is a flowchart illustrating a method of canceling maximum interference elements in a synchronized TDMA network environment according to the present invention.

<Explanation of symbols for the main parts of the drawings>

300: BSS 301: mobile station

311 to 317: base station 320: BSC

The present invention relates to a method of maximizing interference cancellation in a synchronized TDMA network environment.

Several user signals exist in the mobile communication environment, and signals other than the desired signals act as interference, which is a major factor in deteriorating reception performance.

In the case of time division multiple access (TDMA) or frequency division multiple access (FDMA) systems, time or frequency is used separately from other users. Although separated from the desired signal, when the base station is densely installed to increase the capacity of the system, the frequency reuse factor is increased, so that multiple user signals exist in the same frequency or time slot and act as interference.

As methods used for interference cancellation, techniques such as joint demodulation (JD) and smart antennas are used.

The JD is known to have a large amount of computation as a method of increasing performance by simultaneously detecting signals of other users in addition to a desired signal. In addition, the smart antenna technology is a method for attenuating the signal to other users by spatially changing the radiation pattern of the radio wave with multiple antennas, or because multiple antennas must be mounted in the receiver, it is used in a mobile station sensitive to size and power consumption. Is not suitable.

Recently, an antipodal type signal such as Binary Phase Shift Keying (BPSK) has been proposed to remove interference using only one antenna. This technique is called Single Antenna Interference Cancellation (SAIC).

A method of extracting a necessary signal by removing an interference signal from a signal received in a mobile communication system will be briefly described with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a model of a received signal transmitted from N base stations in a mobile communication environment.

Referring to FIG. 1, a ₁ (k) to a _N (k) represent each received signal transmitted from N base stations and received at a receiver. In addition, n (k) represents a noise signal received at the receiver.

h _i (k) is the channel characteristic value for each transmission signal, and r (k) represents the signal received from the N co-channel signal components.

As can be seen in FIG. 1, a signal received at any time is modeled as a signal component to be detected, a signal received from another base station, and a noise component.

In this case, the JD method that detects N received signals simultaneously and detects a desired signal is the most ideal, but the signal power having the largest signal power among the received signals transmitted from the N-1 users is required because of the complexity that cannot be implemented in an actual system. Only considering JD method is used                         

2 is a diagram illustrating a burst structure transmitted in a GSM mobile communication system.

In the GSM mobile communication system, as shown in FIG. 2, the TSC allocated among eight Training Sequence Codes (TSCs) is used in the center of the transmitted bursts.

The receiving side uses the TSC to calculate the channel estimate for detecting the signal via the equalizer. In order to use the JD equalizer, it is necessary to know not only an estimate of a desired signal but also a channel estimate of an interference signal, and thus a process of obtaining a TSC of the interference signal is required. Therefore, the channel estimates are obtained for all combinations of eight TSCs, and then the powers of the respective estimates are compared or the desired signal and the interference signal are estimated using MSE (Mean Square Error) thresholds.

However, the method of obtaining a channel estimate for the equalizer of the conventional JD method as described above requires a channel detection process 7 times higher in complexity than the method considering only a single user. For example, even if the TSC of a desired signal is 0, the channel detector performs a channel estimation process on a combination of TSC 0 and TSCs from 1 to 7, and thus requires a long processing time. There is a problem such as complicated device configuration.

According to the present invention, when a signal is detected by applying a JD method in a GSM (Global System for Mobile Telecommunication) mobile communication system having a synchronized TDMA network environment, the present invention has the strongest influence to improve the complexity of a receiver. The object of the present invention is to provide a method of removing maximum interference elements in a TDMA network environment that is synchronized to increase reception performance and subscription capacity by finding and removing interference signals of a user.

In the synchronized TDMA network environment according to the present invention for achieving the above object, the method for removing the maximum interference element, the base station controller (BSC) receiving the power information for the neighbor cells periodically reported from the mobile station and And analyzing and storing power information of the neighbor cells received by the BSC, and whether there is a base station to which the BSC transmits and receives data using the same carrier frequency in a base station system (BSS). If the base station is to perform data transmission and reception using the same carrier frequency in the BSS as a result of the determination and the determination, the BSC is information to the current mobile station of the TSC used by the base transceiver station (BTS) Notifying the base station and the current mobile station uses the TSC from the entire received signal. That comprises the step of removing the signal transmitted from the features.

In addition, when the base station does not exist to perform data transmission and reception using the same carrier frequency in the BSS, the BSC performs the step of receiving power information on neighbor cells reported from the mobile station again. It is characterized by.

Hereinafter, a method of removing the maximum interference element in a synchronized TDMA network environment according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram illustrating a configuration of a BSS for explaining a method of removing a maximum interference element in a synchronized TDMA network environment according to the present invention.

As shown in FIG. 3, a BSS for controlling data transmission with a mobile station in a TDMA network environment is located in each cell C1 to C7 for data transmission and reception with a mobile station 301. It includes a plurality of base stations BTS1 to BTS7 (311 to 317), and the BSC 320 for controlling the plurality of BTS (311 to 317). For convenience of description of the method of canceling the maximum interference element in the synchronized TDMA network environment according to the present invention, it is assumed that the mobile station 301 is located in a cell covered by the BTS1 311.

In the above configuration, assuming that the BTS acting as an interference factor is six corresponding to BTS2 to BTS7, the signal received by the mobile station 301 is expressed by Equation 1 below.

(Equation 1)                     

Y = H ₁ X ₁ + H ₂ X ₂ + H ₃ X ₃ + H ₄ X ₄ + H ₅ X ₅ + H ₆ X ₆ + H ₇ X ₇ + n _t

Herein, it is assumed that the signal corresponding to the current mobile station 301 is X ₁ , and the remaining signals, i.e., X _i , i = 2, 3, 4, 4, 5, 6, and 7 are interference signals. N _t is thermal noise.

Assuming an interference signal having the largest power among the interference signals as X ₇ , Equation 1 is summarized as Equation 2 below.

(Equation 2)

Y = H ₁ X ₁ + H ₇ X ₇ + n _I + n _t

= H ₁ X ₁ + H ₇ X ₇ + n

In Equation (n), n _I represents the sum of signal components excluding an interference signal having the largest power, and n is a random variable representing the total noise component.

In order to detect a received signal by applying the JD method in Equation 2, X ₁ and X ₇ may be known. And in order to know this value in current GSM mobile communication system, it is necessary to know which TSC is used.

In the current GSM mobile communication system, the mobile station 301 periodically reports the power size of the neighbor cells C2 to C7 to the BSS 300 through a MEASUREMENT REPORT message. At this time, the mobile station 301 reports to the BSS 300 for each BCCH carrier frequency. The message is an operation currently used in the GSM mobile communication system for the current cell reselection procedure.

The BSS 300 instructs the mobile station 301 to change the cell when the power transmitted from the neighboring cell is larger than the current cell based on the content of the measurement report message received from the mobile station 301. It is supposed to be. Hence, the BSS 300 may know which cell serves as the largest interference factor for the current mobile station 301, although not enough to command a cell change.

4 is a flowchart illustrating a method of removing maximum interference elements in a synchronized TDMA network environment according to the present invention.

Referring to FIG. 4, in order to remove the maximum interference factor in the synchronized TDMA network environment, first, the BSC 320 receives power information about neighbor cells periodically reported from the mobile station (S410).

In a synchronized TDMA network environment, the mobile station periodically transmits power information about neighbor cells to the base station (BTS1) 311 through a measurement report message for each BCCH carrier frequency, and the BSC 320 of the BSS 300. ) Receives all power information of neighbor cells C2 to C7 reported to the base station (BTS1) 311.                     

According to the process (S410), the BSC 320 that receives all the power information of the adjacent cells C2 to C7 analyzes and stores the power information of the received neighboring cells C2 to C7. (S420). Accordingly, the powers of the adjacent cells C2 to C7 using the same carrier frequency as the current mobile station 301 are arranged in order of magnitude and stored.

Single antenna when the BTS1 311 of the cell to which the current mobile station belongs has data to be transmitted to the mobile station 301, i.e., when the mobile station is in dedicated channel mode or packet transfer mode. Perform an operation for interference cancellation (SAIC).

On the other hand, in the synchronized network, the synchronization of time slots used by the cells is synchronized with each other. In such a situation, an interference factor occurs in the current mobile station 301 when data is transmitted to another mobile station during the time slot while accidentally using the same frequency in other cells C2 to C6 during the time slot to which the mobile station 301 intends to send. to be. That is, among the other BTS2 to BTS7 312 to 317 managed by the BSC 320 to which the current BTS1 311 belongs to the same time slot, in the same time slot time zone while using the same carrier frequency as the current mobile station 301. The transmission of data to another mobile station now serves as an interference factor for the mobile station 301.

Since the BSC 320 controls all of the base stations BTS1 to BTS7 located in the BSS 300, it is possible to observe whether different BTSs using the same carrier frequency start transmission while using the same time slot.

Accordingly, the BSC 320 determines whether there is a base station that starts transmitting and receiving data using the same carrier frequency in the BSS 300 (S430). To this end, we continue to monitor whether there is a need to transmit data using the same carrier frequency.

As a result of the determination (S430), when there is no base station performing data transmission and reception using the same carrier frequency in the BSS 300, the BSC 320 is a neighbor cell (C2 to the reported from the mobile station 301) Receiving the power information for the C7) is performed again (S410).

Meanwhile, as a result of the determination (S430), there is another BTS (assuming one or more of BTS2 to BTS7, for example, BTS2) that performs data transmission and reception using the same carrier frequency in the BSS 300. In this case, the BSC 320 notifies the current mobile station 301 of the information of the TSC used by the BTS2 (S440).

In the current GSM mobile communication system, a traffic channel for transmitting user data and a slow associated control channel (SACCH) are allocated together to transmit signaling information between the mobile station and the BSS 300 associated with the traffic channel. do. Accordingly, in one embodiment of the present invention, the TSC information of the neighboring cell C2 operating as the largest interference factor to be informed to the current mobile station 301 is in a 26-multiframe or 51-multiframe structure. The mobile station 301 is informed by using a frame period allocated to the SACCH in the channel.                     

According to the process S440, the mobile station 301 that has received the information of the TSC of the neighboring cell C2 operating as the largest interference factor receives the signal transmitted from the BTS2 311 using the TSC. The remaining signal is removed from the process (S450).

That is, by detecting the TSC, the previously mentioned (Equation 2), a total received signal _{Y = H 1 X 1 + H} 7 X 7 + n X ₇ of the large interfering signal from the expression becomes to be specific. Therefore, it is possible to obtain a received signal from which X ₇ , which is the largest interference signal, is removed.

To do this, Equation 3 below is used to detect the value of X ₁ 'that satisfies the minimum value.

(Equation 3)

min (Y-H ₁ X ₁ '-H ₇ X ₇ )

As described above, in the present invention, the current mobile station can inform the current mobile station of the TSC used in an adjacent cell that transmits data in the same time slot while using the same carrier frequency as the current mobile station. By using the TSC of the most influential interference factor known from the present invention, the signal can be detected by the JD method.

In the above, the method of canceling the maximum interference element in the synchronized TDMA network environment according to the present invention has been described in detail. However, the present invention is not limited thereto, but the present invention may be included in the present invention even if the present invention is carried out without change and modification without departing from the spirit of the present invention, and the fact will be apparent to those skilled in the art.

According to the method of maximizing interference cancellation in a synchronized TDMA network environment according to the present invention, a current mobile station is informed of a TSC used by an adjacent cell transmitting data using the same time slot while using the same carrier frequency as the mobile station. In this case, the current mobile station can detect the signal by JD method by removing the interference signal by the most influential interference factor known from the BSC among the received signal components, thereby reducing the complexity significantly compared to the conventional method. It provides an advantage.

Claims (2)

Receiving, by the BSC, power information for neighboring cells periodically reported from the mobile station; Analyzing and storing power information of the adjacent cells received by the BSC; Determining, by the BSC, whether there is a base station which starts data transmission and reception using the same carrier frequency in the BSS; If there is a base station to perform data transmission / reception using the same carrier frequency in the BSS, the BSC notifying the current mobile station of information of the TSC used by the base station; And And wherein said current mobile station is configured to remove a signal transmitted from a base station using said TSC from the total received signal. The method of claim 1, wherein when there is no base station performing data transmission / reception using the same carrier frequency in the BSS, the BSC receives the step of receiving power information on neighbor cells reported from the mobile station. Maximum interference elimination method in a synchronized TDMA network environment, characterized in that to perform again.

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