KR100690326B1 - Apparatus for softhandover in cellular ofdma - Google Patents

Abstract

In the present invention, a soft handover device is disclosed in an OFDMA system.

According to the present invention, in a communication system for soft handover in an OFDMA system, a preamble signal of a neighbor base station to be soft handed over with a base station through at least two antennas Are respectively received, estimate a Signal to Interference plus Noise Ratio (SINR) for each signal based on preamble signals of the base station and the neighbor base station, and transmits the estimation result to the base station, And a mobile station whose soft handover is determined based on a base station control signal notified from the base station, wherein the base station receives an SINR estimation result from the mobile station and the SINR estimation result is less than or equal to a threshold. And generating and transmitting the base station control signal to perform soft handover in the next frame. The base station transmits a base station transmission signal of the base station to the adjacent base station.

The mobile station may further include an inverse matrix unit for extracting preamble signals of the two base stations and classifying the base station signal and the adjacent base station signal; A signal ratio estimator for estimating a Signal to Interference plus Noise Ratio (SINR) of signals transmitted by each base station classified by the inverse matrix unit, and transmitting an estimation result to the base station; An optional interference canceller for distinguishing a signal to be selected and a signal to be removed by receiving the base station control signal; And an optimum synthesizer for performing soft handover by combining a maximum ratio of the signal to be selected and the signal to be removed in response to the base station control signal.

According to the present invention configured as described above, the optimum signal is selected through the maximum non-combination of the base station signal and the adjacent base station signal, thereby easily eliminating the interference signal, thereby maximizing the reception rate and soft handover of the mobile communication terminal. Provide effect.

Handover, Softhandover, SINR, MRC, Maximum Ratio Combination, Preamble

Description

Soft handover device in cellular OSDM system {APPARATUS FOR SOFTHANDOVER IN CELLULAR OFDMA}

1 compares the differences of multiple access schemes.

2 is a diagram illustrating a downlink reception model for transmitting a base station signal from two adjacent base stations to a mobile station equipped with a reception apparatus according to the present invention.

3 is a view for explaining a channel estimation method according to the present invention.

4 is an overall configuration diagram according to the present invention.

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

10, 20: antenna 30, 40: FFT unit

50: channel estimation 60: reverse matrix part

70: selective interference cancellation unit 80: maximum ratio coupling unit

90: SINR estimator

The present invention relates to a soft handover of a wireless communication system. More specifically, after calculating a signal ratio for interference and noise of a received signal using two antennas, the soft handover of the mobile communication terminal ( A soft handover device in a cellular OS system capable of performing SHO: Shoft Hand Over.

In general, a communication system such as an OFDM scheme is known to have good characteristics in terms of robustness and frequency efficiency in a selective frequency fading environment, and has been actively studied recently in a method suitable for high-speed data transmission in a wired / wireless channel.

The OFDM scheme is a kind of multi-carrier transmission using multiple carriers. Recently, as shown in FIG. 1, multiple access methods (CDMA) and frequency division (FDMA), which are multiple access methods conventionally used for OFDM, are used. Multiple Access (TDMA) and Time Division Multiple Access (TDMA) are used together.

However, OFDM-CDMA has a problem of complexity of a receiver structure and a peak to average power ratio (PAPR). Recently, OFDM-CDMA employs OFDMA, which combines OFDM and FDMA.

The IEEE802.16 system uses a typical OFDMA.

The OFDMA is used without limitation in time by using some subcarriers among all subcarriers as shown in FIG. 1, and the assignment of subcarriers can be dynamically changed according to a user's request.

However, when OFDMA is designed in a multi-cell structure, the performance of the system may be affected by a method of allocating subcarriers to a user. In the case of configuring a system that satisfies the frequency reuse rate as "1", performance degradation occurs due to an increase in interference between adjacent cells at the cell edge in downlink. In the uplink, if the frequency synchronization is not perfectly matched, performance degradation of the entire system occurs. Therefore, a lot of overhead must be used for a perfect frequency synchronization and a separate control channel is required. .

For example, one of the key technologies required for imparting mobility of a terminal in a communication system is hand over. In particular, in order to smoothly perform the soft handover for simultaneously receiving the signals of the two base stations, it is necessary to distinguish the signals of the two received base stations. In the case of using OFDMA for mobile communication, signals capable of distinguishing between base stations in OFDMA are preambles and midambles, and different subcarriers are allocated to each base station and subcarriers allocated to different base stations are adjacent to each other. The base station is distinguished from the base station using an unused method (see IEEE802.16-REVd / D2-2003).

However, since all subcarriers are used simultaneously in all base stations, data symbols and pilot symbols need to be combined with other techniques to distinguish the two signals.

The present invention was created to solve the above problems, and an object of the present invention is to calculate a signal ratio for interference and noise of a received signal, and through combining the maximum ratio of two signals that are interfered based on the calculated signal ratio. The present invention provides a soft handover apparatus in a cellular OMD system capable of easily performing a soft handover of a mobile communication terminal.

Soft handover device in the ODMA system (OFDMA) system according to an embodiment of the present invention for achieving the above object, free of neighbor base stations to be soft handover with the base station through at least two antennas Receives a preamble signal and estimates a Signal to Interference plus Noise Ratio (SINR) for each signal based on preamble signals of the base station and the neighboring base station, and estimates an estimation result of the base station. And a mobile station for which a soft handover is determined based on a base station control signal notified from the base station, the base station receives an SINR estimation result from the mobile station, and the SINR estimation result is a threshold value. If less than (Threshold), the base station control signal to perform a soft handover in the next frame Generating and transmitting, and is characterized in that the base station transmits the transmission signal of the self base station to the neighbor base stations.

Preferably, the mobile station comprises: an inverse matrix unit for classifying the self base station signal and the neighbor base station signal by extracting preamble signals of the two base stations; A signal ratio estimator for estimating a Signal to Interference plus Noise Ratio (SINR) of signals transmitted by each base station classified by the inverse matrix unit, and transmitting an estimation result to the base station; An optional interference canceller for distinguishing a signal to be selected and a signal to be removed by receiving the base station control signal; And an optimum synthesizer for performing soft handover by combining a maximum ratio of the signal to be selected and the signal to be removed in response to the base station control signal.

On the other hand, in a soft handover apparatus in a cellular OS according to another embodiment of the present invention, the soft handover apparatus estimates the base station signal and the neighbor base station signal to be soft handover, based on the An inverse matrix unit for classifying a base station signal and an adjacent base station signal; A signal ratio estimator for estimating a Signal to Interference plus Noise Ratio (SINR) of signals transmitted by each base station classified by the inverse matrix unit, and transmitting an estimation result to the base station; An optional interference cancellation unit for receiving a base station control signal for controlling a soft handover corresponding to the SINR estimation result from the base station, and for distinguishing a signal to be selected from a signal to be removed based on the received signal; And after determining the soft handover in response to the base station control signal, an optimum synthesis unit configured to perform soft handover through maximum ratio combining of the same two signals.

Preferably, the selective interference cancellation unit removes the signal for the base station having a small SINR as an interference signal, and selects a signal for the base station having a large SINR as a signal of its own base station.

In addition, the optimal synthesis unit may give different weights to the selected signal and the removed signal to combine a portion corresponding to the subcarriers used by the base stations in the soft handover region at the best ratio.

In addition, the estimation of the SINR signal is characterized by the characteristics of each channel from the plurality of FFT unit and the demodulated signal of the plurality of FFT unit for receiving the self base station signal and the adjacent base station signal, respectively, performing Fast Fourier transform Characterized by the channel estimation to estimate the.

In addition, the self base station signal and the adjacent base station signal are received through a plurality of antennas, and the channel estimator performs a fast Fourier transform channel impulse response to a channel impulse response of a signal received from the base stations to the plurality of antennas. Is separated into parallel channels and output to the inverse matrix unit.

On the other hand, the soft handover method in the cellular OMD system according to another aspect of the present invention is a soft handover method of the mobile communication terminal for removing signal interference within the effective communication range of the wireless communication system A method comprising: a) receiving a self-base station signal using two antennas and a neighbor base station signal to perform soft handover; b) removing one base station signal of each signal estimated as an interference signal using a selective interference cancellation method; And c) performing soft handover based on signal-to-noise ratio (SINR) for interference and noise of the synthesized signal through a maximum-ratio combining (MRC), and combining the magnetic through the maximum ratio combination of the same two signals. And performing a soft handover for the base station signal.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. In addition, although the communication system described in the embodiment of the present invention uses an orthogonal frequency multiple access scheme (OFDMA) as an example, it can be used by integrating smart antenna and beauty technology.

First, FIG. 2 illustrates a downlink model of a self base station signal and a neighbor base station signal transmitted to a receiving apparatus to which the present invention is applied, that is, a mobile communication terminal having two antennas. The principle of the present invention will be described through the model. do.

As shown, a base station signal is received from its base station BS # A and the neighboring base station BS # B through two antennas of the mobile station (mobile communication terminal) SS # a. Here, signals transmitted from the base stations BS # A and BS # B are referred to as x _A and x _B , respectively.

In this case, when the signal x _A is the impulse response of the channel transmitted to the two antennas, respectively h ₀₀ , h ₁₀ and the signal x _B is the impulse response of the channel transmitted to the two antennas, respectively h ₀₁ , h ₁₁ , It may be modeled as in Equation 1.

Here, y _a0 is a signal received at the first antenna and y _a1 is a signal received at the second antenna.

The signals y _a0 and y _a1 received through the first antenna and the second antenna are Fast Fourier Transformed, respectively, and then detect a pilot signal from the Fast Fourier Transformed signal, based on the respective pilot signals. And estimating channel characteristics of signals transmitted from the neighbor base stations BS # B to the respective antennas. That is, as shown in FIG. 3, the transmission signal of each base station has a preamble structure assigned to different subcarriers for each sector, so that the sectors existing in one cell are preambled in the standard case. The subcarrier allocation method is used, and the structure of the midamble also allocates subcarriers for each of the preamble and each sector, and distinguishes the rest with variations of the Y _k signal, thereby distinguishing H ₀₀ , H ₁₀ , H ₀₁ , and H ₁₁ . Can be estimated. Equation 1 is expressed by Equation 2 through a fast Fourier transform.

H ₀₀ , H ₁₀ , H ₀₁ , and H ₁₁ are Fast Fourier transformed values for channel impulse responses h ₀₀ , h ₁₀ , h ₀₁ , and h ₁₁ .

Here, X _A is a fast Fourier transform of x _A , and X _B is a fast Fourier transform of x _B.

The inverse matrix unit 60 calculates an inverse matrix H ⁻¹ for the matrix H of the channel impulse response, and then multiplies them by both sides of Equation 2 to transmit the two matrices BS # A and BS # B as shown in Equation 3. An estimate of the base station signal received at the mobile station SS # a through two antennas is obtained.

Here, denotes an estimated value of a signal transmitted at the Mth base station and received at the mth mobile station.

Subsequently, the SINR of the signal transmitted from each of the base stations BS # A and BS # B is calculated based on the estimated value, and the signal to be selected and the signal to be removed are discriminated. That is, as in Equation 4, a signal for a base station with a small SINR becomes a signal to be canceled and a signal for a base station with a large SINR becomes a signal to be selected.

: m 이동국에서 선택된 신호From here,

m is the signal selected by the mobile station.

: m 이동국에서 제거된 신호

m signal removed from the mobile station

: M번째 기지국에서 m번째 이동국으로 전송된 신호의 SINR

: SINR of the signal transmitted from M base station to m mobile station

: m 이동국에서 M 기지국을 제외한 신호 즉, 간섭 신호

m signals other than M base stations, i.e., interference signals

)에 따라 수학식 5에서와 같이 선택된 신호와 삭제된 신호에 서로 다른 가중치(weighting ratio)를 주어 소프트 핸드오버 영역에서 두 기지국에서 사용하는 부 반송파에 해당하는 부분을 가장 좋은 비율로 결합하여 출력한다.Next, the soft handover command (

As shown in Equation 5, different weighting ratios are given to the selected signal and the deleted signal, and the portions corresponding to the subcarriers used by the two base stations in the soft handover region are combined and output at the best ratio. .

: M 기지국에서 최종 수신신호From here,

: Final received signal at M base station

: 선택된 신호의 부 반송파 할당 집합

: Subcarrier allocation set of the selected signal

: 제거된 신호의 부 반송파 할당 집합

: Subcarrier allocation set of removed signals

: SHO 계수

SHO coefficient

와

는 동일한 신호가 들어 있는 집합)(Where α is ε

Wow

Is a set containing the same signal)

Therefore, in the region where the SINR is greater than a preset threshold, the selected signal becomes a signal finally received at the mobile station SS # a, and in the soft handover region where the SINR is less than or equal to the threshold. The signal obtained by combining the selected signal with the removed signal using the handover coefficient ε at the best ratio becomes the signal finally received at the mobile station SS # a.

Figure 4 is a block diagram showing a soft handover system and a receiving device according to the present invention. According to the present invention, a mobile station includes a plurality of antennas 10 and 20 including a first antenna and a second antenna, a fast fourier transform (FFT) unit 30 and 40, a channel estimation unit 50, and an inverse matrix. an inverse matrix unit 60, a selective cancellation cancellation unit 70, an optimum ratio combining unit 80, and an SINR estimation unit 90. The plurality of antennas 10 and 20 receive a base station signal and an adjacent base station signal for soft handover.

Accordingly, the antennas 10 and 20 receive base station signals y _ao and y _a1 transmitted from adjacent base stations. The fast fourier transform (FFT) units 30 and 40 demodulate by performing fast Fourier transform on the base station signals y _ao and y _a1 received through the antennas 10 and 20, respectively, and then demodulate the signals Yao and Ya1. Is output to the inverse matrix unit 60. That is, the base station signals received through the antennas 10 and 20 are converted to baseband and then demodulated to a state before being modulated by an Inverse Fast Fourier Transform (FFT) after being fast Fourier transformed (FFT).

The channel estimator 50 detects preamble signals from the OFDMA signals demodulated by the FFT units 30 and 40, respectively, and estimates channel characteristics of the OFDMA signals received from two adjacent base stations at each antenna 10 and 20. FIG. . That is, when the channel estimation unit 50 denotes the channel impulse response of the signals received from the two base stations at each antenna 10 and 20, respectively, h ₀₀ , h ₁₀ , h ₀₁ , and h ₁₁ , The fast Fourier transform channel impulse response H = {H ₀₀ , H ₁₀ , H ₀₁ , H ₁₁ } is separated into parallel channels and output to the inverse matrix unit 60 in a matrix form. To this end, adjacent base stations should facilitate channel estimation using different subcarriers.

The inverse matrix unit 60 uses the output signals of the FFT units 30 and 40 and the channel estimator 50 to antennas 10 and 20 at two adjacent base stations, that is, adjacent base stations to perform soft handover with their base stations. Calculate an estimated value for the base station signal received at. Accordingly, the inverse matrix unit 60 obtains an output signal of the channel estimator 50, that is, an inverse matrix H ⁻¹ of the fast Fourier transformed channel impulse response H, and then outputs the signals of the FFT units 30 and 40. Multiply the fast Fourier transformed base station signals Y _ao and Y _a1 to obtain an estimate of the base station signal transmitted from each base station. In addition, an estimated value for each base station signal is input to the SINR estimator 90, and the SINR estimator 90 calculates an estimated value E {SINR} of SINR as shown in Equation 4 and according to the result. A base station control signal, i.e., a weight signal for SINR and a soft handover response signal for selecting a base station signal are generated.

The selective interference canceller 70 receives a weighted signal for the signal to interference plus noise ratio (SINR) of the signal transmitted from each base station by using the value estimated by the SINR estimator 90 and selects according to the SINR. Distinguish between a signal and a signal to remove. That is, the selective interference cancellation unit 70 compares the SINRs of the signals transmitted from each base station, cancels a signal for a base station having a small SINR as an interference signal, and cancels a signal for a base station having a large SINR. Select by signal. As such, after receiving signals from both base stations, soft handover is possible by selecting a signal having a large SINR.

The soft combiner 80 performs a soft handover based on the soft handover response signal provided from the SINR estimator 90, and when the command for performing the soft handover is received from the soft handover response signal. By giving different weighting ratios to the signal selected by the selective interference cancellation unit 70 and the removed signal, a maximum ratio of combining portions corresponding to the subcarriers used by the two base stations in the soft handover region at the best ratio. Perform non-coupling (MRC). As described in Equation 5, in the region where the SINR is larger than a predetermined threshold, the selected signal becomes a signal finally received at the mobile station SS # a, and the SINR is larger than the threshold. In the small or equal soft handover region, the signal that combines the selected signal with the removed signal using the soft handover coefficient ε at the best ratio becomes the signal finally received at the mobile station SS # a.

Meanwhile, according to another exemplary embodiment of the present invention, a soft handover of the receiving apparatus may be performed by receiving an SINR weight signal and a soft handover response signal from the base station based on the estimation result estimated by the SINR estimator 90. . That is, the SINR estimation signal SINR_REPORT of the self base station estimated by the SINR estimator 90 and the neighbor base station signal to perform soft handover, that is, the self base station signals SINR A and a and the neighbor base station signals SINR B and b ) Is transmitted to its own base station, which is represented by Equation 6 below;

: 이동국에서 선택할 신호,

: 이동국에서 제거할 신호)(

: Signal to select from mobile station,

: Signal to remove from mobile station)

Generate a signal to select from the mobile station and a signal to remove as shown in. In addition, a soft handover response signal for whether to perform soft handover in the next frame is generated and provided to the optimum combiner 80. The soft handover response signal SHO_ACK (α) is expressed by Equation 7 below;

(ε: SHO factor)

As in, it is determined whether the SINR signal is present in the soft handover region based on the threshold. Accordingly, the soft handover response signal SHO_ACK (α) provided from the base station is provided to the optimum combiner 80. The soft handover response signal is a threshold value of the SINR signal as shown in Equation 5, as shown in Equation (5). When it exceeds, α of the soft handover response signal SHO_ACK (α) is set to '1' so that the final received signal becomes a base station signal. When the SINR signal does not exceed or equals the threshold, the soft handover Α of the response signal SHO_ACK (α) is set to 'ε', and the soft handover response signal SHO_ACK (α) is applied to the optimum combiner 80. Accordingly, the optimum combiner 80 performs a combine on the same two signals (ks, kc) flowing through the selective interference canceller 70 to receive the final signal.

The base station signal provided from the base station to the mobile station is transmitted to the adjacent base station to perform soft handover, so that even if the mobile base station channel of the mobile station is changed to the adjacent base station channel, the mobile station can receive the same two signals provided from the base station and the adjacent base station. And receive the final signal by synthesizing through the optimal combiner MRC, the base station signal may be received consecutively.

As described above, the mobile communication terminal according to the present invention is equipped with at least two antennas to extract the respective signals for the self-base station signal and the neighbor base station signal, and based on this, the optimum synthesizer (MRC) By selecting the adjacent base station signal having the best signal ratio (SINR) for the interference and noise of the synthesized signal, it provides the effect of maximizing the reception rate and soft handover of the mobile communication terminal.

Claims (13)

A soft handover device of a mobile communication terminal for removing signal interference within an effective communication range of a wireless communication system, Receive a preamble signal of the neighbor base station to be soft handed over with the base station through at least two antennas, respectively, and based on the preamble signal of the base station and the neighbor base station, Signal to Interference plus Noise Ratio) is estimated, the SINR estimation result of the preamble signal of the base station and the neighboring base station SINR estimation result of the preamble signal is transmitted to the base station and notified from the base station. A mobile station for which soft handover is determined based on a base station control signal, the mobile station comprising: An inverse matrix unit for classifying the self base station signal and the adjacent base station signal by extracting preamble signals of the two base stations; A signal ratio estimator for estimating a Signal to Interference plus Noise Ratio (SINR) of signals transmitted by each base station classified by the inverse matrix unit, and transmitting an estimation result to the base station; An optional interference canceller for receiving the self base station control signal to distinguish between a signal to be selected and a signal to be removed; And And an optimum synthesizer for performing soft handover by combining a maximum ratio of the signal to be selected and the signal to be removed in response to the base station control signal. The base station receives the SINR estimation result from the mobile station, and if the SINR estimation result is less than or equal to the threshold, generates and transmits the base station control signal to perform soft handover in the next frame. And a base station transmit signal of the base station to the adjacent base station. delete delete delete delete A soft handover device of a mobile communication terminal for removing signal interference within an effective communication range of a wireless communication system, The soft handover apparatus includes an inverse matrix unit for estimating a base station signal and an adjacent base station signal for soft handover, and classifying the base station signal and the adjacent base station signal based on the base station signal; A signal ratio estimator for estimating a Signal to Interference plus Noise Ratio (SINR) of signals transmitted by each base station classified by the inverse matrix unit, and transmitting an estimation result to the base station; An optional interference cancellation unit for receiving a base station control signal for controlling a soft handover corresponding to the SINR estimation result from the base station, and for distinguishing a signal to be selected from a signal to be removed based on the received signal; And After determining the soft handover in response to the base station control signal, the soft handover of the cellular OMD system comprising an optimal synthesis unit for performing a soft handover through the maximum ratio combination of the same two signals Over device. The cellular interference control method of claim 6, wherein the selective interference canceling unit considers and removes a signal for a base station having a small SINR as an interference signal, and selects a signal for a base station having a large SINR as a signal of a base station. Soft Handover Device in FM System. 7. The method of claim 6, wherein the optimal combining unit combines the portions corresponding to the subcarriers used by the base stations in the soft handover region at the best ratio by giving different weights to the selected signal and the removed signal. A soft handover device in a cellular OS. 7. The method of claim 6, wherein the SINR signal is estimated from a plurality of FFT units for receiving the self base station signal and the adjacent base station signal, respectively, and performing a fast Fourier transform to demodulate the signals. A soft handover device in a cellular OS system, characterized in that it is made through channel estimation for estimating the characteristics of each channel. The soft handover apparatus of claim 9, wherein the reception of the base station signal and the adjacent base station signal are performed through a plurality of antennas. 10. The method of claim 9, wherein the channel estimator divides the channel impulse response of the fast Fourier transform of the channel impulse response of the signals received from the base stations into a parallel channel and outputs the parallel impulse to the inverse matrix unit. Soft Handover Device in Cellular OSDM System. delete delete

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