JP2013026822A - Base station device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a femtocell base station device that can access a macrocell base station by setting means of synchronous signal power in a femtocell base station so that a base station positioned at a femtocell area can detect a macrocell synchronous signal.SOLUTION: When the number of users under communication in a cell reaches a certain threshold value, transmission power of a synchronous signal in the cell is suppressed.

Description

  The present invention relates to a radio communication system, and more particularly to a synchronization signal transmission method in a cellular radio communication system and a radio base station apparatus that implements the method.

  In a wireless communication system, a plurality of base stations called macro cell base stations having high transmission power and a coverage area per base station ranging from several hundred meters to several kilometers are installed. Thereby, the mobile station can perform wireless communication in a wide range. However, radio waves used for wireless communication are shielded or attenuated by buildings or the like. For this reason, the place where the electric wave from a macrocell base station weakens arises indoors.

  In order to perform stable communication even in a place where radio waves from such a macro cell base station weaken, a base station called a femto cell base station with low transmission power and a narrow cover area per base station may be installed. By installing the femtocell base station, the mobile station can perform communication even in a place where the radio wave from the macrocell base station is weakened.

  On the other hand, in the cellular radio communication system, since the same radio resource is shared by a plurality of cells, communication in one cell works as interference for communication in different cells. For example, downlink communication from a base station to a mobile station in a certain cell results in interference of downlink communication in a nearby cell. For this reason, the signal reception quality of the mobile station near the cell boundary is lowered. Further, uplink communication from a mobile station to a base station in a certain cell results in interference of uplink communication in a nearby cell. For this reason, in order to ensure sufficient communication quality, the mobile station needs to increase the power for uplink transmission, and the power consumption of the mobile station increases. In addition, when the uplink transmission power of the mobile station is not increased so as to cancel the influence of the uplink interference, the uplink reception quality at the base station deteriorates.

  In order to reduce the influence of these interferences, Patent Document 1 discloses a technique for reducing interference that occurs between a macrocell base station apparatus and a femtocell base station apparatus. Patent Document 2 discloses a technique for reducing interference with other cells even when the installation location is changed in a small radio base station apparatus.

JP 2009-253569 A JP 2007-243505 A

  When a power supply is turned on, a mobile station in a wireless communication system first performs a process of finding and synchronizing a cell in the network called cell search. A base station apparatus in a wireless communication system always transmits a synchronization signal. The mobile station can detect a cell in the network by receiving a synchronization signal transmitted from the base station, and can transmit / receive various data to / from the network by synchronizing the timing with the cell. At this time, when the mobile station detects a plurality of cells, the mobile station evaluates the received quality of each detected cell and performs communication with the cell having the highest received quality.

  On the other hand, femtocell base stations are installed in such a manner that cells overlap within the coverage area of a macrocell base station. At this time, the mobile station in the femtocell base station area detects both femtocell and macrocell cells, and accesses a cell with higher reception quality.

  When the femtocell base station is installed at a position away from the macrocell base station, the mobile station in the femtocell area has a very small reception power from the macrocell base station. Further, the signal power from the femtocell base station becomes a large interference source, and the macrocell cannot be detected.

  Since the femtocell base station covers a relatively small area, the number of users that can be connected simultaneously is relatively small. When a femtocell base station is installed in the above situation, there may be a situation in which no cell can be accessed in the femtocell area that has already reached the upper limit of the number of simultaneously connected users.

  The present invention provides a femtocell base station apparatus that enables a mobile station in a femtocell area to detect a macrocell synchronization signal and to access the macrocell base station even in the above situation. .

  In order to solve the above problem, the femtocell base station apparatus reduces the transmission power of the synchronization signal according to the number of simultaneously connected users in the cell.

  In the case of a femtocell base station apparatus, the coverage area of the cell is relatively narrow, and accordingly, the number of users who can simultaneously communicate is often set to a relatively small number of 4 to 8 users in a home femtocell. Therefore, when the number of users in communication in the cell reaches a certain threshold, the transmission power of the synchronization signal in the cell is reduced. In addition to the number of simultaneously connected users, for example, an upper limit is set according to, for example, the usage rate of radio resources, the amount of communication with the network, the usage rate of HW resources such as CPU and memory in the base station device, and the like. When it reaches, the transmission power of the synchronization signal in the cell may be reduced.

  Further, when the transmission power of the synchronization signal is decreased, for example, the transmission power of another data transmission channel can be increased by the amount of the decrease of the transmission power of the synchronization signal. The transmission power may be increased for data transmission and certain service data.

  The above-described problem is that, in a base station apparatus that performs radio communication with a terminal device, a synchronization signal transmission unit, a transmission power setting unit, and a threshold determination unit based on the number of connected users, When the determination is made, the setting means can be achieved by the base station apparatus that reduces the transmission power of the synchronization signal.

  According to the present invention, interference of a synchronization signal between a macro cell and a femto cell can be reduced, and a mobile station in the femto cell area can connect to the femto cell due to some restrictions in the femto cell base station. Even when it is not possible, it is possible to detect a synchronization signal in the macro cell area and connect to the macro cell base station.

It is a block diagram explaining the structure of a cellular radio | wireless communications system. It is a flowchart explaining the process of a femtocell base station. It is a block diagram explaining the structure of a cellular radio | wireless communications system. It is a figure explaining the structure of the synchronizing signal in a LTE system. It is a figure explaining the allocation of the synchronizing signal in the LTE system seen on the frequency axis. It is a figure explaining the Example which changed the transmission power of the synchronizing signal. It is a figure explaining the Example which changed the transmission power of the downstream signal and the synchronizing signal.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings using examples. The same reference numerals are assigned to substantially the same parts, and the description will not be repeated. The following description will be made using an LTE (Long Term Evolution) system standardized by 3GPP (3rd Generation Partnership Project) as a wireless communication system. However, the wireless communication system is not limited to this.

  In the following, the sequence and the flow of processing may be described in a specific order. However, the order of processing is changed unless there is a dependency on the order in which the result of one processing is used in the next processing. Alternatively, processing may be performed in parallel.

  Further, in the following, for the explanation of the transmission power setting method, a base station to be focused on is a femtocell base station, and base stations around the femtocell base station are macro cell base stations. However, the neighboring base stations may apply the transmission power setting method of this embodiment. In the following description, the femtocell base station to which the transmission power setting method according to the present embodiment is applied and the macrocell base station in the vicinity thereof are simply referred to as a base station.

  The configuration of the cellular radio communication system will be described with reference to FIG. In FIG. 1, a cellular radio communication system 1000 includes a macro cell base station (MeNB: Macro evolved Node B) 100, a femto cell base station (HeNB: Home evolved Node B) 500, a mobile station 600, and a network 700 connected to the base station. The core network 800 is connected to the base station via the network 700.

  Hereinafter, a signal or communication from the macrocell base station 100 or the femtocell base station 500 to the mobile station 600 is referred to as a downlink signal or downlink communication. Conversely, a signal or communication from the mobile station 600 toward the macro cell 100 or the femtocell base station 500 is referred to as an uplink signal or uplink communication.

  Macrocell base station 100 is connected to core network 800 via network 700. The macrocell base station 100 transmits a downlink signal to the mobile station 600 and receives an uplink signal transmitted by the mobile station 600-5. The femtocell base station 500 is connected to the core network 104 via the network 110 in the same manner as the macrocell base station 100. The femtocell base station 500 transmits a downlink signal to the mobile station 600 and receives an uplink signal transmitted by the mobile station 600.

  The network 700 to which the macrocell base station 100 is connected and the network 700 to which the femtocell base station 500 is connected may be the same network or may be different networks connected via a gateway. . The core network 800 has mobility management and a gateway function with other networks.

  The mobile station 600 determines whether to communicate with the macrocell base station 100 or to communicate with the femtocell base station 500 based on the reception quality or propagation loss of the downlink signal or uplink signal. When the propagation environment changes due to movement of the mobile station 600 or the like, a handover process for changing a base station that performs communication via the core network 800 is performed.

  In FIG. 1, a femtocell area 510 that is a range in which the femtocell base station 500 communicates with a terminal is arranged in a macrocell area 110 that is a range in which the macrocell base station 100 communicates with a terminal. Further, the position of the femtocell base station 500 is near the boundary of the macrocell area 110.

  The femtocell base station 500 is communicating with the four mobile stations 600-1 to 600-4. Here, the femtocell base station 500 can communicate with four users at the same time, and the new mobile station 600-5 receives the synchronization signal of the femtocell base station 500 and connects to the femtocell base station 500. Even if it is decided to do so, access to the femtocell base station 500 fails.

  On the other hand, the synchronization signal of the femtocell base station 500 indicated by the arrow B becomes an interference wave with respect to the synchronization signal of the macrocell base station 100 indicated by the arrow A, and the mobile station 600-5 receives the synchronization signal of the macrocell base station 100. Can not. That is, the mobile station 600-5 cannot access the femtocell base station 500 or the macrocell base station 100.

  With reference to FIG. 2, the process of the synchronous signal power setting in a femtocell base station is demonstrated. In FIG. 2, the femtocell base station 500A performs base station activation processing including initial setting of various parameters when the power is turned on (S201). By this base station activation process, the femtocell base station 500A starts transmission of a downlink signal, and data communication with the mobile station 600 becomes possible.

  Thereafter, the femtocell base station 500A performs a threshold determination process (S202). Here, the femtocell base station 500A detects the number of connected users currently in communication. Femtocell base station 500A compares with a preset threshold value (S203). When YES, the femtocell base station 500A sets the synchronization signal power (S204) and returns to step 202. Here, the synchronization signal power setting is to reduce the power of the synchronization signal to a preset power. When step 203 is NO, the femtocell base station 500A resets the synchronization signal power (S205), and returns to step 202. Here, the reset of the sync signal power is to restore the power of the sync signal that has been reduced to a preset power. Note that step 204 and step 205 include performing nothing when it has already been set.

  Here, threshold determination is performed based on the number of connected users. In addition to the number of connected users, the usage rate of radio resources, the usage rate of the backhaul line, the number of connection bearers, and hardware (HW) such as CPU and memory You may use the threshold value criterion by the utilization rate of resources, and these combination.

  With reference to FIG. 3, the case where the synchronizing signal power from the femtocell base station 500A in which the number of connections exceeds the threshold value is reduced will be described. In FIG. 3, a cellular radio communication system 1000A includes a macrocell base station 100, a femtocell base station 500A, a mobile station 600, a network 700 connected to the base station, and a core network 800 connected to the base station via the network 700. It is configured.

  Femtocell base station 500A is communicating with four mobile stations 600-1 to 600-4. Here, the femtocell base station 500A can communicate with 4 users at the same time, and the new mobile station 600-5 receives the synchronization signal of the femtocell base station 500A and connects to the femtocell base station 500A. Even if it is decided to do so, access to the femtocell base station 500A fails.

  On the other hand, the synchronization signal of the femtocell base station 500 </ b> A indicated by the arrow B ′ becomes an interference wave with respect to the synchronization signal of the macrocell base station 100 indicated by the arrow A. However, since the synchronization signal power of the femtocell base station 500A has decreased to a preset power, the mobile station 600-5 can receive the synchronization signal of the macrocell base station 100. That is, the mobile station 600-5 can access the macro cell base station 100.

  A synchronization signal in the LTE system will be described with reference to FIG. In FIG. 4, the downlink transmission frame of the LTE system is based on a 10 ms frame 301 and includes 10 subframes 302 in one frame 301. The downlink transmission frame 301 has a hierarchical frame structure having 14 OFDM (Orthogonal Frequency Division Multiplexing) symbols in one subframe 302.

  In the LTE system, the base station and the mobile station are synchronized by two types of synchronization signals called PSS (Primary Synchronization Signal) 303 and SSS (Secondary Synchronization Signal) 304.

  The PSS 303 is transmitted in the seventh symbol in the 0th and 5th subframes 302 in each frame. The SSS 304 is transmitted using the sixth symbol in the same subframe 302 as the PSS 303.

  With reference to FIG. 5, the assignment of PSS 303 and SSS 304 viewed on the frequency axis will be described. In FIG. 5, transmission bands 402 of PSS 303 and SSS 304 are mapped to the central 73 subcarriers with respect to the entire LTE downlink transmission band. The remaining bandwidth 401 other than the PSS 303 and the SSS 304 is used for other channels such as for user data transmission.

  With reference to FIG. 6, a decrease in transmission power of PSS 303 and SSS 304 will be described. In a normal radio communication system, a minimum reception sensitivity as low as possible is required in order to correctly detect a cell when a mobile station first performs a cell search. For this reason, the base station sets the highest possible transmission power. On the other hand, it is possible to reduce the transmission power required for maintaining synchronization to a mobile station once connected.

  In FIG. 6, the femtocell base station 500A exceeding the threshold suppresses only the transmission power of the band 402 of the PSS 303 and SSS 304 to the transmission power necessary for maintaining synchronization of the connected mobile stations. Thereby, the femtocell base station 500A exceeding the threshold enables the mobile station 600 in the femtocell 510 to receive the synchronization signal from the macrocell base station 100.

  With reference to FIG. 7, a decrease in transmission power of PSS 303 and SSS 304 and an increase in transmission power of other bands will be described. In FIG. 7, similarly to FIG. 6, the transmission power of PSS 303 and SSS 304 is decreased, and the transmission power of other channels is increased by the amount of decrease of the transmission power of PSS 303 and SSS 304.

  Also, instead of increasing the transmission power of all the other channels uniformly, the transmission power is allocated to a resource allocated to a specific mobile station or a resource allocated to a specific service that requires high reception power. May be increased.

  According to the present embodiment, the interference of the synchronization signal between the macro cell and the femto cell can be reduced. In addition, even when a mobile station in the femtocell area cannot connect to the femtocell due to some restrictions in the femtocell base station, it can detect the synchronization signal in the macrocell area and connect to the macrocell base station. Become.

  DESCRIPTION OF SYMBOLS 100 ... Macro cell base station, 110 ... Macro cell area, 301 ... LTE downlink transmission frame, 302 ... LTE downlink transmission subframe, 303 ... PSS (Primary Synchronization Signal), 304 ... SSS (Secondary Synchronization Signal), 401 ... LTE downlink transmission power 402 ... PSS / SSS downlink transmission power, 500 ... femtocell base station, 510 ... femtocell area, 600 ... mobile station, 700 ... network, 800 ... core network, 1000 ... cellular radio communication system.

Claims (8)

In a base station device that performs wireless communication with a terminal device,
A synchronization signal transmission means, a transmission power setting means, and a threshold determination means based on the number of connected users;
The base station apparatus according to claim 1, wherein when the threshold determination unit determines that the threshold is exceeded, the setting unit reduces transmission power of the synchronization signal. The base station apparatus according to claim 1,
Furthermore, it has a 2nd threshold value determination means based on the utilization rate of a radio | wireless resource, The base station apparatus characterized by the above-mentioned. The base station apparatus according to claim 1,
The base station apparatus further comprises second threshold determination means based on a backhaul line usage rate. The base station apparatus according to claim 1,
Furthermore, it has a 2nd threshold value determination means based on the number of connection bearers, The base station apparatus characterized by the above-mentioned. The base station apparatus according to claim 1,
Furthermore, the base station apparatus characterized by having a 2nd threshold value determination means based on the utilization rate of a hardware resource. A base station apparatus according to any one of claims 1 to 5,
The base station apparatus characterized by increasing the transmission power of channels other than the synchronization signal when the transmission power of the synchronization signal is decreased. A base station apparatus according to any one of claims 1 to 5,
A base station apparatus that increases the transmission power of a channel assigned to a specific terminal apparatus when the transmission power of the synchronization signal is decreased. A base station apparatus according to any one of claims 1 to 5,
A base station apparatus that increases the transmission power of a channel assigned to a specific service when the transmission power of the synchronization signal is decreased.

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