KR20170019701A - Method And Apparatus For Transmitting Adaptive CRS For Interference Mitigation - Google Patents

Abstract

A method and apparatus for transmitting an adaptive common reference signal (CRS) for interference mitigation are disclosed. The present invention relates to a technique for controlling the transmission of a common reference signal (CRS) transmitted from a terminal for interference mitigation at a base station. The transmission mode of the common reference signal (CRS) according to the traffic condition of a cell at the base station is changed, thereby mitigating unnecessary interference and improving a downlink transmission rate. A method and apparatus for transmitting an adaptive common reference signal (CRS) for interference mitigation are provided.

Description

[0001] The present invention relates to an adaptive common reference signal (CRS) transmission method and apparatus for suppressing interference,

This embodiment relates to an adaptive common reference signal (CRS) transmission method and apparatus for interference suppression.

The contents described below merely provide background information related to the present embodiment and do not constitute the prior art.

LTE (Long Term Evolution) is a mobile communication technology based on an OFDM (Orthogonal Frequency Division Multiplexing) technique in which an entire frequency band is divided into a plurality of sub-carriers having a narrow bandwidth. The frame structure of an FDD (Frequency Division Duplex) LTE system is composed of a repetition of a 'Radio Frame' having a length of 10 ms. The '1 radio frame' consists of 10 sub-frames each having a length of 1 ms. One 'subframe' is composed of two 'time slots' each having a length of 0.5 ms. One 'time slot' consists of a collection of N ^DL _symb (6 or 7) OFDM symbols.

The minimum unit of the LTE physical resource having the above-described frame structure is a 'Resource Element' (RE) which means that one 'subcarrier' is used during one OFDM symbol duration time . Resource elements RE of adjacent N ^RB _SC 'subcarriers' for a '1 time slot' (0.5 ms) (eg, total N ^DL _symb × N ^RB _SC 'resource elements RE' ) Is called a 'resource block' (RB).

A 'Cell-Specific Reference Signal' (CRS) is a signal transmitted by a base station to support a channel estimation and demodulation operation in a terminal. The 'Common Reference Signal (CRS)' is used to indicate that two adjacent adjacent cells on the time axis according to the 'Physical Cell ID' (PCI) of the cell and the number of the base station antenna port in the 3GPP standard document 'TS 36.211' The location of the 'resource element RE' to be used in the resource block 'RB' is defined.

FIG. 1A is a diagram showing the location of a 'resource element (RE)' generally occupied by a 'common reference signal (CRS)'. FIG. 1A shows an example of the location of a 'RE' to which a 'common reference signal (CRS)' should be transmitted when there are two base station antennas according to the number of antennas. As shown in Fig. 1A, the same pattern is repeatedly applied over the entire system bandwidth even on the frequency axis.

In other words, in the current LTE standard, the 'common reference signal (CRS)' is set to repeatedly transmit continuously for every 'subframe' over the entire system bandwidth (eg 20 MHz). However, in LTE, a system is used in which a single user is allocated only a part ('resource block (RB)') at a whole frequency, and a specific resource block (RB) There is a problem that an unnecessary 'common reference signal (CRS)' signal is continuously transmitted. In particular, even if there is no 'Active User' in the cell, the 'Common Reference Signal (CRS)' signal continues to be transmitted from the base station to the terminal. When the load of the cell is small due to the transmission of the common reference signal (CRS), the common reference signal (CRS) is a main cause of the inter-cell interference, causing a problem of causing LTE downlink rate degradation .

This embodiment is a technology for controlling transmission of a common reference signal (CRS) transmitted from a mobile station in order to suppress interference in a base station. The base station switches a transmission mode of a common reference signal (CRS) And to provide an adaptive common reference signal (CRS) transmission method and apparatus for interference suppression that can suppress unnecessary interference and improve a downlink transmission rate.

According to an aspect of the present invention, there is provided a subframe identification unit for identifying a current subframe; A status checking unit for checking whether the terminal in the cell is in a wakeup state in the current subframe; And transmitting, when the terminal is in the wakeup state, a common reference signal (CRS) in a full-band mode to the terminal, and when the terminal is not in the wake-up state, And a mode determination unit for causing the common reference signal (CRS) to be transmitted in the narrowband mode.

According to another aspect of the present invention, there is provided a method of adaptively transmitting a common reference signal (CRS) for interference suppression by a base station, comprising: a frame checking step of checking a current subframe; A state checking step of checking whether the terminal in the cell is in a wakeup state in the current subframe; And transmitting a common reference signal (CRS) in a full-band mode to the terminal when the terminal is in a wake-up state based on a result of the checking of the status checking process, And transmitting the reference signal (CRS) in a narrowband mode.

As described above, according to the present embodiment, a base station controls transmission of a common reference signal (CRS) transmitted to a mobile station in order to suppress interference, and a base station transmits a common reference signal (CRS) It is possible to suppress unnecessary interference and improve the downlink transmission rate by switching the transmission mode.

According to the present embodiment, the adaptive common reference signal (CRS) transmission scheme changes the transmission mode of the common reference signal (CRS) according to the traffic load of the cell, thereby eliminating unnecessary common reference signal transmission Thereby reducing the interference between adjacent cells, thereby increasing the downlink speed.

Particularly, according to this embodiment, in the case of a new transmission mode (Transmission Mode) using a channel state reference signal (CSI-RS) and a demodulation reference signal (DM-RS) standardized in 3GPP, It is necessary to introduce a terminal and there are restrictions that all users must change to a new terminal. However, the common reference signal (CRS) transmission control technique according to the present embodiment can obtain a similar effect not only in the current network in which existing terminals exist but also in the current commercial network immediately.

1A is a diagram showing a location of a resource element RE occupied by a general common reference signal CRS.
1B is a diagram illustrating a technique for transmitting a common reference signal (CRS).
2A is a diagram illustrating an adaptive common reference signal (CRS) transmission scheme according to the present embodiment.
FIG. 2B is a diagram showing the location of a resource element RE occupied by the common reference signal CRS when the adaptive common reference signal (CRS) transmission scheme according to the present embodiment is used.
3 is a diagram illustrating a monitoring band setting for measuring radio wave quality in a terminal according to the present embodiment.
4 is a diagram illustrating operation of an adaptive common reference signal (CRS) transmission scheme in the RRC idle state according to the present embodiment.
5 is a diagram illustrating a random access procedure in the case of switching from the RRC idle state to the RRC connected state according to the present embodiment.
6 is a diagram illustrating operation of an adaptive common reference signal (CRS) transmission scheme in an RRC connected state according to the present embodiment.
7 is a diagram illustrating subframe locations where MIB and SIB are transmitted according to the present embodiment.
8 is a block diagram schematically showing a base station according to the present embodiment.
9 is a flowchart for explaining a transmission mode selection algorithm of the common reference signal (CRS) in the base station according to the present embodiment.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings.

1B is a diagram illustrating a technique for transmitting a common reference signal (CRS) in general.

In the current LTE standard, the 'common reference signal (CRS)' is set to repeatedly transmit continuously for every 'subframe' for each antenna over the entire system bandwidth (for example, 20 MHz). Repeated transmission of 'Common Reference Signal (CRS)' is not related to the use of the corresponding 'Resource Block (RB)'.

1B shows a 'common reference signal (CRS) transmission method' of an existing LTE base station. As shown in FIG. 1B, 'common reference signal (CRS)' is transmitted to all bands in all 'subframes' irrespective of the traffic state of the cell.

As described above, the 'common reference signal (CRS)', which is always transmitted irrespective of the load of the cell, is a main cause of unnecessary interference between adjacent cells. As a result of discussing by the 3rd Generation Partnership Project (3GPP) to solve the repeated transmission of the 'common reference signal (CRS)', the channel measurement and demodulation functions in the terminal responsible for the 'common reference signal (CRS) (CSI-RS) and a demodulation-reference signal (DM-RS), which are new reference signals to be transmitted to the base station. Unlike the conventional 'common reference signal (CRS)' transmitted every 'subframe', the 'CSI-RS' is only responsible for channel measurement, and therefore, 10 ms, 20 ms, 40 ms, and 80 ms It is transmitted only once every long time. 'Demodulation reference signal (DM-RS)' is transmitted only in a 'resource block (RB)' actually used as a reference signal allocated to each terminal and does not cause unnecessary interference.

In particular, LTE Rel. 8 to support up to 4 base station antennas, LTE-Advanced Rel. (CRS) for the added antennas based on the above description has not been determined, and the channel estimation for the eight antennas is defined as a newly defined ' Channel state reference signal (CSI-RS) '. Therefore, in the future, the 'CSI-RS' completely replaces the 'CRS', the channel estimation function is replaced by the CSI-RS, and the demodulation function is set to 'DM-RS' New LTE base stations are expected to be introduced.

However, in reality, the current LTE base station can not but maintain the conventional scheme of transmitting 'common reference signal (CRS)' for a considerable period of time. The terminal supporting the channel state reference signal (CSI-RS) and the demodulation reference signal (DM-RS) is not yet present in the commercial network, and even if a new terminal is introduced and distributed, This is because a common reference signal (CRS) must be maintained for backward compatibility until the terminal is replaced.

In this embodiment, while maintaining compatibility with existing terminals, a 'common reference signal (CRS)' signal, which is always transmitted regardless of the presence or absence of an 'active user' in a general cell, A common reference signal (CRS) is adaptively transmitted to reduce unnecessary inter-cell interference.

The 'common reference signal (CRS)' signal is not used only for users in a cell but terminals belonging to a neighbor cell measure the quality of radio waves of the corresponding cell and use it when the MME (Mobility Management Entity) do. Therefore, it is necessary to ensure that there is no abnormality in the measurement of the radio wave quality of the adjacent cell terminal although the transmission of the 'common reference signal (CRS)' signal is controlled depending on the presence or absence of the 'active user' in the cell.

In this embodiment, in order to ensure that there is no abnormality in the measurement of the radio wave quality, the band that the terminal measures the radio wave quality is limited to a specific band (for example, 1.4 MHz) which is the smallest among the LTE system bandwidths. (20 MHz for example) in which the transmission mode of the 'common reference signal (CRS)' is transmitted over the entire band and a common reference signal (CRS) for transmitting only the specific band of the system bandwidth Band mode (for example, 1.4 MHz). In this embodiment, the transmission mode of the 'common reference signal (CRS)' is divided into a full-band mode and a narrow-band mode. In any case, a common reference signal (CRS) (CRS) " transmission control.

2A is a diagram illustrating an adaptive common reference signal (CRS) transmission scheme according to the present embodiment.

A scheme for adaptively transmitting a new 'common reference signal (CRS)' proposed in the present embodiment reduces the unnecessary inter-cell interference by switching the transmission mode of the common reference signal (CRS) according to the traffic condition of the cell, The link speed can be improved.

In the method of adaptively transmitting the 'common reference signal (CRS)' according to the present embodiment shown in FIG. 2A, a base station transmits a 'common reference signal (CRS)' to a system overall bandwidth (for example, 20 MHz) (For example, 1.4 MHz) in which only a specific band of the system bandwidth is transmitted and a 'common reference signal (CRS)' is transmitted. send. Hereinafter, the present embodiment will be described on the basis of an embodiment in which only the center 1.4 MHz band is used in the narrowband mode for the convenience of explanation.

FIG. 2B is a diagram showing a location of a 'RE' occupied by a 'common reference signal (CRS)' when a technique of adaptively transmitting a 'common reference signal (CRS)' according to the present embodiment is used.

FIG. 2B is an embodiment showing the 'RE' position used by the 'common reference signal (CRS)' in the 'resource block (RB)' excluding the center 1.4 MHz band in the narrowband mode. The important point is that since the first three OFDM symbols of the 'subframe' are used as a physical downlink control channel (PDCCH), 'common reference signal (CRS)' is always transmitted even in the narrowband mode, The common reference signal CRS is not transmitted in the remaining part.

A 3GPP standard document 'TS 36.331' defining a Radio Resource Control (RRC) procedure for controlling a radio channel between a terminal 310 and a base station includes a terminal 310 that transmits the quality of service , 'AllowedMeasBandwidth' field for setting a reference bandwidth to be used when measuring RSRP (Reference Signal Received Received Power) and RSRQ (Reference Signal Received Received Quality) is the same as the SIB (System Information Block) SIB 3 containing information for selection (Intra-Frequency Cell Reselection) and SIB 5 containing information for other band-cell selection (Inter-Frequency Cell Reselection). The related contents are defined as <Table 1>.

3 is a diagram illustrating a monitoring band setting for measuring radio wave quality in a terminal according to the present embodiment.

In order to ensure that the cell and the neighboring cell 310 do not have any abnormality in the radio quality measurement of the corresponding cell even if the narrowband mode is used according to the traffic condition of the cell, 'AllowedMeasBandwidth = mbw6 'so that the terminal 310 observes only 1.4 MHz (6 RBs) at the time of measuring the RSRP and RSRQ values. The terminal 310 refers to an electronic device that performs voice or data communication via the base station 320 according to a user's key operation. The terminal 310 according to the present embodiment means an LTE terminal.

The terminal 310 may have two states: an RRC Connected state and an RRC Idle state with the base station 320. The detailed operation of the scheme of adaptively transmitting the 'Common Reference Signal (CRS)' will be described according to whether the terminal 310 is in the RRC idle state, in the RRC idle state, or in the RRC connection state.

First, in the RRC idle state, the terminal 310 basically performs a discontinuous reception (DRX) operation for power saving. However, the terminal 310 may turn off the reception circuit of the terminal 310 except for a 'paging occasion' in which the base station 320 periodically wakes up (wake up state) to check whether there is a paging signal. do. Therefore, it is apparent that the base station 320 will not use the 'common reference signal (CRS)' in the entire band in the period in which the terminal 310 turns off the receiver. Therefore, Reference signal CRS '. Table 3 &gt; &lt; EMI ID = 16.1 &gt; &lt; tb &gt; &lt; tb &gt; &lt; TABLE &gt; Id = Table 3 Columns = 2 & As shown in Fig.

4 is a diagram illustrating operation of an adaptive common reference signal (CRS) transmission scheme in the RRC idle state according to the present embodiment.

The BS 320 can estimate a 'paging time' for each MS from the value of the International Mobile Subscriber Identity (IMSI), which is a unique ID value for each MS, and the default DRX Cycle T and nB, which are base station configuration parameters. Accordingly, in the 'subframe' in which there is a 'paging timing' of the terminals in the cell, the base station 320 allows paging reception in the terminal 310 to be normally performed using the entire band mode. In order to compensate for a malfunction due to terminal implementation, a paging margin can be set before and after the paging timing, and a common reference signal CRS (paging margin) ) '. 4 illustrates one embodiment (T = 128, nB = 1 / 8T) of adaptively transmitting a 'common reference signal (CRS)' at a base station 320 for a terminal in the RRC idle state as described above , &Quot; paging margin &quot; = 2ms before / 1ms after). As shown in FIG. 4, a paging frame of a specific terminal exists every 8 SFN (System Frame Number), and uses the same paging frame for every 16 UE_IDs.

5 is a diagram illustrating a random access procedure in the case of switching from the RRC idle state to the RRC connected state according to the present embodiment.

The terminal 310 transmits an uplink scheduling request (SR) to the base station 320 in the case of using the upload traffic when the RRC idle terminal 310 switches to the RRC connected state. The terminal 310 switches from the RRC idle state to the RRC connected state under the control of the base station 320.

Similarly, when there is downlink traffic to be transmitted from the outside to the terminal 310, the base station 320 transmits a paging signal to the terminal 310 in 'paging timing' for each terminal in the cell, and transmits the paging signal to the terminal 310 in the RRC idle state To the RRC connection state. The transition from the RRC idle state to the RRC connected state is performed using a random access procedure and starts from the transmission of the random access preamble at the terminal 310, (RRC), which is a radio control channel of the base station 310, is connected and is terminated. The entire process of the random access (LTE) is as shown in FIG.

The base station 320 transmits a random access preamble (Random Access Preamble) from the terminal 310 in order to receive normal data from the terminal 310 during the random access procedure, Margin) is set. The base station 320 transmits a 'common reference signal (CRS)' in a full band transmission mode for a set 'random access margin' period. The time taken for the random access procedure to be completed may vary depending on the distance between the terminal and the base station and the number of terminals attempting RRC connection at the same time. The random access procedure is not problematic in that it is possible to adaptively transmit the 'common reference signal (CRS)' by setting a sufficiently long value based on the actual random access time-required statistics in the commercial network.

6 is a diagram illustrating operation of an adaptive common reference signal (CRS) transmission scheme in an RRC connected state according to the present embodiment.

The base station 320 may adjust the transmission mode of the 'common reference signal (CRS)' in conjunction with the Connected Mode DRX (CDRX) operation for a terminal in the Connected state with the RRC. The base station 320 uses only 'long CDRX' (Long CDRX) without using 'short CDRX'. The terminal awakes (wakeup state) every 'Long DRX Cycle' and receives and monitors a signal from the base station 320 by an 'On Duration Timer'. The terminal can turn off the RX of the terminal from the end of the 'on-interval timer' until the next 'long-duration DRX cycle', thereby saving power. The terminal extends the duration of the 'On Duration' as much as the Inactivity Timer (DRX) if there is traffic from the base station 320 in a specific 'on interval timer'. Similar to the RRC idle mode, it is apparent that the base station 320 will not be used even if it transmits 'common reference signal (CRS)' to the entire band in the period when the terminal is turned off. Therefore, Common reference signal (CRS) '. In order to correct a malfunction due to terminal implementation, the base station 320 may set 'On Duration Margin' before and after 'On Duration', respectively, Common reference signal (CRS) '. 5 illustrates an embodiment of a scheme for adaptively transmitting a 'common reference signal (CRS)' in a base station 320 for a terminal in connection with an RRC (Long CDRX Cycle ) = 40 ms, On Duration Timer = 2 ms, CDRX Inactivity Timer = 10 ms). Of course, it is similarly scalable when additional Short CDRX Cycle is used.

7 is a diagram illustrating subframe locations where MIB and SIB are transmitted according to the present embodiment.

The base station 320 transmits a master information block (MIB) and a system information block (SIB) to transmit cell configuration information to the terminal 310. (SIB 1 to SIB 13) is not related to the control of the transmission mode of the 'common reference signal (CRS)' because the MIB exists only at 1.4 MHz when the MIB is transmitted. Since the 'subframe' for transmitting the SIB can be correctly confirmed, the 'common reference signal (CRS)' is transmitted in the entire band mode in the 'subframe' in which the corresponding SIB exists. FIG. 7 is a diagram showing locations of a 'radio frame' and a 'subframe' in which MIBs and SIBs exist according to a SFN (System Frame Number).

As shown in FIG. 7, the MIB is transmitted every '0' subframe of every 'radio frame' starting from 'SFN 0'. SIB 1 transmits 5 'subframes' of every 8 'radio frames' (SFN Mod 8 = 0) starting from 'SFN 0', and the same SIB 1 has different RV (Redundancy Value) every SFN Mode 2 = 0 . All other SIBs are transmitted in cycles and locations determined from SIB 1.

8 is a block diagram schematically showing a base station according to the present embodiment.

The base station 320 according to the present embodiment includes a frame checking unit 810, a status checking unit 820, and a mode determining unit 830. The constituent elements included in the base station 320 are not necessarily limited thereto.

Each component included in the base station 320 may be connected to a communication path connecting a software module or a hardware module in the apparatus and operate organically with each other. These components communicate using one or more communication buses or signal lines. Each element of the base station 320 shown in FIG. 8 means a unit for processing at least one function or operation, and may be implemented by a software module, a hardware module, or a combination of software and hardware.

The frame check unit 810 checks the current subframe. The frame check unit 810 checks the number of the subframe. The frame check unit 810 checks the number of each subframe. When the mode determination unit 830 transmits the common reference signal CRS to the terminal in the cell in the full-band mode or the narrow-band mode by the mode determination unit 830, the frame check unit 810 determines whether the current sub- Increase the value by 1 (F = F + 1).

The state checking unit 820 checks whether the terminal in the cell is woken up (wakeup state) in the current subframe.

Hereinafter, the operation of the state checking unit 820 will be described in detail. If the SIB exists in the current subframe, the state checking unit 820 confirms that the terminal is awake (wakeup state). If the SIB does not exist in the current subframe F, the state checking unit 820 sets the number of terminals in the cell to N (N = number of terminals in the cell) and sets the terminal I in the cell to 1 (I = 1). The state checking unit 820 confirms whether the number N of cells in the cell and the cell I in the cell are the same value (I = N). The state checking unit 820 confirms that the terminal is awake (wakeup state) when the number N of terminals in the cell and the terminal I in the cell are the same value (I = N) .

When the paging timing or the paging margin for the terminal 310 is confirmed in the current subframe, the state checking unit 820 confirms that the terminal 310 wakes up (wakeup state). In other words, when the number N of cells in the cell and the cell I in the cell are not equal to each other (I? N), the state checking unit 820 determines whether the current state of the terminal I It is confirmed whether or not the paging timing or the paging margin is confirmed. The state checking unit 820 confirms that the terminal in the cell wakes up (wakeup state) when the paging timing or paging margin for the terminal I is confirmed in the current subframe F. [

The state checking unit 820 confirms that the terminal 310 is awake (wakeup state) when the random access process for the terminal 310 is in progress or the random access margin is confirmed in the current subframe. In other words, if the number N of cells in the cell and the cell I in the cell are not equal to each other (I? N), the state checking unit 720 checks whether the current state of the terminal I Check whether random access process is in progress or random access margin is confirmed. If the random access procedure for the terminal I is in progress or the random access margin is confirmed in the current subframe F, the state checking unit 820 confirms that the terminal in the cell wakes up (wakeup state) .

The state checking unit 820 determines that the terminal 310 is woken up (in a wakeup state) when the ON period or the ON period margin is detected in the DRX cycle for the terminal 310 in the current subframe Check. In other words, when the paging timing or the paging margin for the terminal I in the current subframe F is not confirmed, the state checking unit 820 determines whether the paging time or the paging margin for the terminal I in the current subframe F is non- Check whether the ON or ON interval margin is confirmed in the receiving cycle (DRX Cycle).

The state checking unit 820 determines that the on period or the on period margin in the discontinuous reception cycle for the terminal I is within the current subframe F. In this case, State).

If the ON period or the ON period margin in the discontinuous reception cycle for the terminal I in the current subframe F is not confirmed, the state checking unit 820 determines that the terminal I value in the cell is 1 (I = I + 1). The state checking unit 820 increments or decrements the I value by 1 and checks whether the number N of cells in the cell and the cell I in the cell are the same value (I = N). The state checking unit 820 confirms that the terminal is awake (wakeup state) when the number N of terminals in the cell and the terminal I in the cell are the same value (I = N) .

The mode determination unit 830 transmits the common reference signal CRS to the terminal 310 in the full band mode at the time when the terminal 310 awakes (wakeup state).

Hereinafter, the operation of the mode determination unit 830 in the full-band mode will be described in detail. When the state checking unit 820 confirms that the SIB exists in the current subframe, the mode determining unit 830 determines that the terminal is woken up (wakeup state), and outputs a common reference signal CRS in the entire band mode To the terminal within the cell. The mode determination unit 830 determines whether the paging timing or the paging margin for the terminal I in the current subframe F is equal to the common reference signal CRS in the full band mode, To the terminal within the network. The mode determining unit 830 may determine that the random access margin for the terminal I is currently being processed or the random access margin for the terminal I is currently in the subframe F, (CRS) to a terminal in the cell. When the state checking unit 820 checks the ON period or the ON period margin in the non-continuous receiving cycle for the terminal I in the current subframe F, the mode determining unit 830 determines that the common reference And transmits the signal (CRS) to the terminal in the cell.

The mode determination unit 830 transmits the common reference signal CRS in the narrowband mode to the terminal 310 at a time other than the time when the terminal 310 wakes up (wakeup state).

Hereinafter, the operation of the mode determination unit 830 in the narrowband mode will be described in detail. The mode determination unit 830 determines that the state reference unit 820 has received the common reference signal CRS (I) from the terminal 310 when the number N of cells in the cell and the intra- ) In the narrowband mode. The number N of cells in the cell increases when a new terminal accesses the corresponding base station and decreases when moving to a neighboring cell (i.e., handover).

The mode determination unit 830 improves the downlink transmission rate by matching the connection mode discontinuous reception period between the terminals in the cell.

9 is a flowchart for explaining a transmission mode selection algorithm of the common reference signal (CRS) in the base station according to the present embodiment.

Since the RRC access terminal and the RRC idle terminal coexist in the actual cell, the base station 320 examines all the conditions described above for the existence of the SIB for each 'subframe' and the RRC state of each terminal, Mode, &quot; common reference signal (CRS) &quot; is transmitted. When all the conditions are satisfied, the base station 320 selects a narrowband mode and transmits a 'common reference signal (CRS)'. 9 is a flowchart of a transmission mode selection algorithm of the 'common reference signal (CRS)' in the base station 320 as described above.

Further, in order to improve the performance of the base station 320 that adaptively transmits the 'common reference signal (CRS)' that performs the operation described in FIG. 9, the following considerations may be considered. Since the CDRX function can operate separately for each mobile station, there is a problem that the efficiency of the transmission mode adjustment of the 'common reference signal (CRS)' is lowered when the CDRX period is different for each mobile station. Accordingly, it is possible to consider a CDRX alignment function that drives traffic when a plurality of terminals exist in accordance with the CDRX cycle for each terminal in the cell, and simultaneously turns off the RX of the terminal.

The base station 320 identifies the current subframe (S910). In step S910, the base station 320 confirms the number (F) of the subframe. As a result, the base station 320 confirms the number F every subframe.

The base station 320 determines whether an SIB exists in the current subframe (S920). If it is determined in step S920 that the SIB exists in the current subframe F, the base station 320 confirms that the terminal in the cell is woken up (wakeup state), and transmits the common reference signal CRS to the cell (S922). After performing step S922, the base station 320 increments or decrements 1 (F = F + 1) to the current subframe number F (S924) to check the next subframe. The base station 320 returns to step S910 after performing step S924.

If it is determined in step S920 that the SIB does not exist in the current subframe F, the base station 320 sets the number of terminals in the cell to N (N = the number of terminals in the cell) (I = 1) (S930). The base station 320 determines whether the number N of cells in the cell and the cell I in the cell are the same value (I = N) (S932).

If it is determined in step S932 that the number N of terminals in the cell and the terminal I in the cell have the same value (I = N), the base station 320 confirms that the terminal is awake (wakeup state) The terminal 310 transmits the common reference signal CRS in the narrowband mode (S934). After performing step S934, the base station 320 increments or decrements 1 (F = F + 1) to the current subframe number F (S924) to check the next subframe.

If it is determined in step S932 that the number N of in-cells and the number I in the cell are equal to each other (I? N), the base station 320 transmits It is checked whether the paging timing or the paging margin is confirmed (S940).

If it is determined in step S940 that the paging timing or the paging margin for the terminal I in the current subframe F is confirmed, the base station 320 confirms that the terminal in the cell wakes up (wakeup state) In the band mode, the common reference signal CRS is transmitted to the terminal in the cell (S922).

If it is determined in step S940 that the paging timing or the paging margin for the terminal I in the current subframe F is not yet confirmed, It is checked whether the access process is in progress or a random access margin is confirmed (S950). If it is determined in step S950 that the random access process for the terminal I is in progress or the random X margin is not confirmed in the current subframe F, the base station 320 determines that the terminal I (S960) whether or not the ON period or the ON period margin is confirmed in the DRX Cycle for the non-continuous receiving cycle (DRX Cycle).

As a result of checking in step S960, if an ON period or ON period margin in the discontinuous reception cycle for the terminal I in the current subframe F is confirmed, the BS 320 awakes ), And transmits the common reference signal CRS to the terminal in the cell in the full-band mode (S922). If it is determined in step S650 that the ON period or the ON period margin in the discontinuous reception cycle for the terminal I in the current subframe F is not confirmed, the base station 320 increments or decrements the terminal I value in the cell (I = I + 1) (S962). The base station 320 returns to step S932 after performing step S962.

Although it is described in Fig. 9 that steps S910 to S962 are sequentially executed, the present invention is not limited thereto. In other words, Fig. 9 is not limited to the time-series order, since it would be applicable to changing or executing the steps described in Fig. 9 or executing one or more steps in parallel.

As described above, the method of selecting the transmission mode of the common reference signal (CRS) in the base station according to the present embodiment described in FIG. 9 can be implemented by a program and recorded in a computer-readable recording medium. A program for implementing a method of selecting a transmission mode of a common reference signal (CRS) in a base station according to the present embodiment is recorded, and a computer-readable recording medium includes a computer readable medium having stored therein data that can be read by a computer system Type recording apparatus.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

As described above, the present embodiment is applied to a field for controlling the transmission of a common reference signal (CRS) transmitted from a mobile station for interference suppression, so that a transmission mode of a common reference signal (CRS) Thereby reducing the unnecessary interference and improving the downlink transmission rate.

310: terminal 320: base station
810: Frame check unit 820: Status check unit
830:

Claims (7)

A sub-frame checking unit for checking a current sub-frame;
A status checking unit for checking whether the terminal in the cell is in a wakeup state in the current subframe; And
Specific reference signal (CRS) in a full-band mode when the terminal is in a wake-up state, and when the terminal is in a wake-up state, transmitting a common reference signal (CRS) A mode decision unit (not shown) for transmitting the reference signal CRS in the narrow-
And a base station. The method according to claim 1,
Wherein the state checking unit comprises:
And if the SIB (System Information Block) exists in the current subframe, the base station confirms that the terminal is in a wakeup state. The method according to claim 1,
Wherein the state checking unit comprises:
Wherein the base station confirms that the terminal is in a wakeup state when a paging occasion or a paging margin for the terminal is confirmed in the current subframe. The method according to claim 1,
Wherein the state checking unit comprises:
Wherein the base station confirms that the terminal is in a wakeup state when a random access procedure for the terminal is performed or a random access margin is confirmed in the current subframe. The method according to claim 1,
Wherein the state checking unit comprises:
If it is determined that the terminal is in the wakeup state in the On Period or On Duration Margin in the DRX Cycle for the terminal in the current subframe, Characterized in that the base station. The method according to claim 1,
Wherein the mode determination unit determines,
Wherein a Connected Mode DRX period is matched between the terminals in the cell to improve a downlink transmission rate. A method for adaptively transmitting a common reference signal (CRS) for interference suppression by a base station,
A frame confirmation process of confirming a current subframe;
A state checking step of checking whether the terminal in the cell is in a wakeup state in the current subframe; And
And transmits a common reference signal (CRS) in a full-band mode to the terminal when the terminal is in a wake-up state based on a result of the checking of the status check process, Mode determination process for transmitting the signal (CRS) in narrowband mode
(CRS) transmission method.

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