JP2018019235A - Base station, communication system, and synchronization signal transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a base station, a communication system, and a synchronization signal transmission device that can protect a control channel on which a pilot signal is transmitted if plural types of TDD communication systems are used together in the same frequency band.SOLUTION: A base station capable of radio communication with a mobile station includes: radio communication means for wirelessly communicating with the mobile station by using a first TDD (Time Division Duplex) system; and control means for performing control to stop transmission to the mobile station in a downlink time slot in the first TDD system corresponding to the downlink time slot in the second TDD system when a pilot signal is transmitted in a prescribed downlink time slot from another base station that wirelessly communicates with the mobile station by the second TDD system different from the first TDD system.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a base station, a communication system, and a synchronization signal transmission apparatus that perform radio communication with a mobile station using a time division duplex method.

  Conventionally, as a communication system for performing wireless communication between a mobile station and a base station, a PHS (Personal Handy Phone System) system, a DECT (Digital Enhanced Cordless Communications) system, a TD-LTE (Time Division Long Term Elevation Term Emission Term System, etc. One using a time division duplex (TDD) method is known (see, for example, Patent Document 1 and Non-Patent Document 1).

  There are cases where it is desired to use the above-described multiple types of TDD communication systems in the same frequency band. For example, in Japan, a PHS communication system (hereinafter referred to as “PHS” or “PHS system” as appropriate) is allocated to a band 39 or a frequency band (1880 MHz to 1920 MHz) called a 1.9 MHz band. There are cases where it is desired to use a TD-LTE communication system (hereinafter referred to as “TD-LTE system” as appropriate) in the frequency band to which the existing PHS is allocated. However, a plurality of types of TDD communication systems such as the PHS system and the TD-LTE system have different radio frame structures and may not be able to protect a control channel through which a pilot signal is transmitted.

A base station according to an aspect of the present invention is a base station capable of wireless communication with a mobile station, and wireless communication means for performing wireless communication with the mobile station using a first TDD (time division duplex) method, When a pilot signal is transmitted in a predetermined downlink time slot from another base station that performs radio communication with a mobile station using a second TDD method different from the first TDD method, the second TDD method is Control means for controlling to stop transmission to the mobile station in the first TDD downlink time slot corresponding to the link time slot.
In the base station, the wireless communication means is configured to perform wireless communication with a mobile station using the first TDD scheme for each of a plurality of frequencies in a predetermined communication band, and the control means includes the mobile station The transmission stop may be performed simultaneously for the plurality of frequencies.
The base station further includes receiving means for receiving a pilot signal of a second TDD scheme transmitted from the other base station, and the control means is configured to receive the pilot signal based on a reception result of the pilot signal. A downlink time slot in which a signal is transmitted is determined, and transmission to the mobile station is stopped in the first TDD downlink time slot corresponding to the second TDD downlink time slot. You may control as follows.
In addition, the base station receives the second TDD pilot signal transmitted from the other base station and transmits a synchronization signal including the pilot signal or a synchronization signal including timing information of the pilot signal. Receiving means for receiving the synchronization signal from a signal transmission device; the control means determines a downlink time slot in which the pilot signal is transmitted based on a reception result of the synchronization signal; It may be controlled to stop transmission to the mobile station in the first TDD downlink time slot corresponding to two TDD downlink time slots.
In the base station, the first TDD scheme is a TD-LTE scheme compliant with the LTE / LTE-Advanced standard, and the second TDD scheme is a PHS (Personal Handy Phone System) system. The TDD scheme used, and when the pilot signal is transmitted in a predetermined downlink time slot from the other base station in the second TDD scheme, the control means uses the second TDD scheme in the downlink. In the first TDD downlink subframe corresponding to the communication time slot, control may be performed to stop transmission to the mobile station.

A communication system according to another aspect of the present invention includes any one of the base stations and another base station that performs radio communication with a mobile station using a second TDD scheme different from the first TDD scheme used in the base station. With.
A synchronization signal transmission apparatus according to still another aspect of the present invention is a synchronization signal transmission apparatus that transmits a synchronization signal toward a base station that uses any of the first TDD schemes. Means for receiving a pilot signal of the second TDD scheme transmitted from a base station, and means for transmitting a synchronization signal including the pilot signal or a synchronization signal including timing information of the pilot signal.

  According to the present invention, when a plurality of types of TDD communication systems coexist in the same frequency band, it is possible to protect a control channel through which a pilot signal is transmitted.

(A) And (b) is explanatory drawing which shows an example of schematic structure of the mobile communication system containing the base station which concerns on embodiment of this invention, respectively. (A) is explanatory drawing which shows the structural example of the LTE radio | wireless frame used for the radio | wireless communication of the TD-LTE system between a LTE base station and a LTE mobile station. (B) is explanatory drawing which shows the example of arrangement | positioning of the downlink in a LTE radio frame, and an uplink. (C) is explanatory drawing which shows the structural example of the special sub-frame S in a LTE radio frame. Explanatory drawing which shows the structural example of the PHS radio | wireless frame used for the radio | wireless communication of a PHS system between a PHS base station and a PHS mobile station. Explanatory drawing which shows an example of the mutual interference between the communication system of a TD-LTE system and the communication system of a PHS system. Explanatory drawing which shows an example of the synchronization of the LTE radio frame with respect to the PHS radio frame in this embodiment. Explanatory drawing which shows an example of the transmission stop control in the LTE base station of this embodiment. The block diagram which shows the example of 1 structure of the principal part of the LTE base station which concerns on this embodiment. The block diagram which shows the other structural example of the principal part of the LTE base station which concerns on this embodiment. The block diagram which shows the further another structural example of the principal part of the LTE base station which concerns on this embodiment. The block diagram which shows the structural example of the principal part of the LTE base station and synchronous signal transmission apparatus which concern on this embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIGS. 1A and 1B are each an explanatory diagram showing an example of a schematic configuration of a mobile communication system including the base station 100 according to the embodiment of the present invention.
FIG. 1A shows a macro cell in which a first base station (hereinafter also referred to as “LTE base station”) 100 using a TD-LTE scheme as a first TDD (time division duplex) scheme in a cellular mobile communication system. The example of a structure which is a base station is shown. A cell (hereinafter also referred to as “LTE cell”) 100A, which is a radio communication area of LTE base station 100, is a macro cell, and a second TDD scheme different from the first TDD scheme is included in LTE cell 100A. A cell (hereinafter also referred to as “PHS cell”) 200 </ b> A that is a radio communication area of a second base station (hereinafter also referred to as “PHS base station”) 200 using the PHS system is located.

  FIG. 1B shows a configuration example in which the LTE base station (also referred to as “eNodeB”) 100 using the TD-LTE scheme in the cellular mobile communication system is a small cell base station. The LTE cell 100A, which is a radio communication area of the LTE base station 100 in this case, is a small cell that is narrower than the macro cell, and the LTE cell 100A uses a PHS scheme (hereinafter also referred to as “PHS base station”). It is located in 200 PHS cells 200A.

  The LTE base station 100 of the present embodiment is a mobile station (hereinafter referred to as “LTE mobile station”) in a 1.9 GHz band frequency band (1880 MHz to 1920 MHz) according to the TD-LTE scheme compliant with the LTE / LTE-Advanced standard. , Also referred to as “user equipment” or “UE”) 11. Bidirectional wireless communication between the uplink (UL) and the downlink (DL) is performed.

  Also, the PHS base station 200, which is a second base station located around the LTE base station 100, is mobile station (hereinafter referred to as "PHS mobile") in the frequency band of 1.9 GHz band as in the LTE base station 100. (Also referred to as a “station”, “user equipment” or “UE”) 12 performs uplink (UL) and downlink (DL) bidirectional wireless communication.

FIG. 2A is an explanatory diagram illustrating a configuration example of an LTE radio frame used for TD-LTE radio communication between an LTE base station and an LTE mobile station.
As shown in FIG. 2A, an LTE radio frame (RF) 150 having a predetermined period (Tf = 10 ms), which is a unit on the time axis in TD-LTE radio communication, is divided into 10 sub-frames of 1 ms. It consists of a frame (SF). One subframe (SF) can be further divided into two time slots (TS). That is, one LTE radio frame is composed of 10 subframes (20 time slots).

  FIG. 2B is an explanatory diagram showing an example of arrangement of the downlink and uplink of the TD-LTE scheme in the LTE radio frame, and FIG. 2C shows a configuration example of the special subframe S in the LTE radio frame. It is explanatory drawing. As shown in FIG. 2 (b), an LTE radio frame of the TD-LTE scheme is a downlink frame used for transmission from the LTE base station 100 to the LTE mobile station 11 with a subframe consisting of two time slots as one unit. A subframe (hereinafter also referred to as “downlink subframe”) D, and an uplink subframe (hereinafter also referred to as “uplink subframe”) U used for transmission from the LTE mobile station 11 to the LTE base station 100. Are allocated in time division. Note that the subframe indicated by the symbol “S” in FIG. 2B is a special subframe used for the purpose described later.

  In the present embodiment, as shown in the example of the UL / DL configuration of the LTE radio frame in FIG. 2B, the uplink subframe U, the downlink subframe D, and the special subframe S are the top of the LTE radio frame. To D, S, U, U, D, D, S, U, U, D. That is, two consecutive uplink subframes U (four time slots) are followed by two downlink subframes D (four time slots) and one special subframe S. Note that the UL / DL configuration of the LTE radio frame is not limited to the configuration example shown in FIG. 2B, and may be another configuration example as disclosed in Non-Patent Document 1. .

  The special subframe S shown in FIG. 2 (c) is a subframe arranged at a position where the downlink is switched to the uplink. In the example of FIG. 2 (b), the special subframe S is shown in the second and seventh subframes. Assigned. The special subframe S includes a downlink pilot time slot (DwPTS), a guard period (GP), and an uplink pilot time slot (UpPTS). The ratio of the time lengths of DwPTS, GP and UpPTS can be changed. In this embodiment, mutual interference between the TD-LTE communication system and the PHS communication system is more reliably suppressed by adjusting the time length of the guard period (GP) as described later. .

FIG. 3 is an explanatory diagram showing a configuration example of a PHS radio frame used for PHS radio communication between the PHS base station 200 and the PHS mobile station 12.
As shown in FIG. 3, a PHS radio frame (RF) 250 having a predetermined period (Tf = 5 ms), which is one unit on the time axis in PHS radio communication, is divided into eight time slots (TSs) of 0.625 ms. ). The first four time slots R1 to R4 of the PHS radio frame (RF) 250 are used for reception (R) channels in the PHS base station 200, that is, uplink radio communication from the PHS mobile station 12 to the PHS base station 200. . Further, the latter four time slots T1 to T4 of the PHS radio frame (RF) 250 are used for transmission (T) channels in the PHS base station 200, that is, downlink radio communication from the PHS base station 200 to the PHS mobile station 12. Used. Of the four transmission (T) channel time slots T1 to T4, the first time slot T1 is a control signal from the PHS base station 200 to the PHS mobile station 12 every 125 ms (every 200 times). Used for transmission of pilot signals.

  As described above, the LTE radio frame 150 and the PHS radio frame 250 have different frame structures. Therefore, in an area where the TD-LTE communication system and the PHS communication system are used together (for example, the area of the PHS cell 200A in which the LTE cells 100A in FIG. 1 overlap), the LTE on the time axis is used. Depending on the positional relationship between the radio frame 150 and the PHS radio frame 250, mutual interference may occur as described below.

FIG. 4 is an explanatory diagram showing an example of mutual interference between a TD-LTE communication system and a PHS communication system each having the above-described radio frame configuration.
For example, in the time zone of Ti1 and Ti3 in FIG. 4, when a downlink radio signal is transmitted from the PHS base station 200 to the PHS mobile station 12, the LTE base station 100 increases from the LTE mobile station 11. Since the radio signal of the link is received, the radio signal transmitted from the PHS base station 200 is received by the LTE base station 100 and may interfere with the uplink desired signal from the LTE mobile station 11.

  Further, in the time period of Ti2 and Ti4 in FIG. 4, when a downlink radio signal is transmitted from the LTE base station 100 to the LTE mobile station 11, the PHS base station 200 is updated from the PHS mobile station 12. Since the radio signal of the link is received, the radio signal transmitted from the LTE base station 100 is received by the PHS base station 200, which may cause interference with the uplink desired signal from the PHS mobile station 12.

  Therefore, in the present embodiment, the transmission timing of the radio signal to the mobile stations 11 and 12 and the reception timing of the radio signal from the mobile stations 11 and 12 do not overlap between the LTE radio frame 150 and the PHS radio frame 250. In addition, the transmission / reception timing in the LTE radio frame 150 is set. In the present embodiment, the LTE radio frame 150 is synchronized with the PHS radio frame 250 as described below so that the transmission / reception timing in the LTE radio frame 150 is set.

FIG. 5 is an explanatory diagram showing an example of synchronization of the LTE radio frame 150 with the PHS radio frame 250 in the present embodiment.
In the example of FIG. 5, the first subframe (time slot) D of the LTE radio frame 150 is switched from the downlink subframe (time slot) D to the uplink subframe (time slot) U at the position on the time axis indicated by T1 in the drawing. The LTE radio frame 150 is synchronized with the PHS radio frame 250 so that the timing coincides with the second timing when the PHS radio frame 250 switches from the downlink time slot T4 to the uplink time slot R1. By synchronizing in this way, the transmission timing of the radio signal to the mobile stations 11 and 12 and the reception timing of the radio signal from the mobile stations 11 and 12 do not overlap between the LTE radio frame 150 and the PHS radio frame 250. Can be.

  Also, a first timing at which the uplink subframe (time slot) U of the LTE radio frame 150 is switched to the downlink subframe (time slot) D at a position on the time axis indicated by T2 in FIG. 5; The LTE radio frame 150 may be synchronized with the PHS radio frame 250 so that the second timing of switching from the uplink time slot R4 to the downlink time slot T1 of the PHS radio frame 250 coincides. By synchronizing in this way, the transmission timing of the radio signal to the mobile stations 11 and 12 and the reception timing of the radio signal from the mobile stations 11 and 12 do not overlap between the LTE radio frame 150 and the PHS radio frame 250. Can be.

  In the example of FIG. 5, the timing T1 at which the downlink subframe (time slot) D of the LTE radio frame 150 synchronized with the PHS radio frame 250 is switched from the uplink subframe (time slot) U is the above-described timing. Located in special subframe S. Therefore, the length of the guard period GP is adjusted so that the timing T1 is located within the guard period GP that is not used for signal transmission / reception of the special subframe S. As a result, between the LTE radio frame 150 and the PHS radio frame 250, it is ensured that the radio signal transmission timing to the mobile stations 11 and 12 and the radio signal reception timing from the mobile stations 11 and 12 do not overlap. be able to.

  The length of the guard period GP may be changed according to the change of the UL / DL configuration of the LTE radio frame 150. For example, when the ratio between the number of downlink subframes (time slots) D and the number of uplink subframes (time slots) U in the LTE radio frame 150 is changed, the guard period is based on the changed ratio. You may change the length of GP. Accordingly, when the UL / DL configuration of the LTE radio frame 150 is changed, the transmission timing of the radio signal to the mobile stations 11 and 12 between the LTE radio frame 150 and the PHS radio frame 250 and the mobile station 11 are changed. , 12 can be reliably prevented from overlapping with the reception timing of the radio signals from.

  In addition, as described with reference to FIG. 3 above, in the first time slot T1 among the time slots T1 to T4 of the four transmission (T) channels, the PHS base station 200 changes the PHS every 125 ms (every 200 times). A pilot signal that is a control signal is transmitted to the mobile station 12. The pilot signal from the PHS base station 200 to the PHS mobile station 12 may be interfered by the downlink transmission signal from the LTE base station 100.

  Therefore, in the present embodiment, when a pilot signal is transmitted from the PHS base station 200 in a predetermined downlink time slot T1, in the downlink subframe corresponding to the downlink time slot T1, the LTE mobile station 11 Controls to stop transmission for. With this transmission stop control, the interference that the pilot signal from the PHS base station 200 to the PHS mobile station 12 receives from the downlink transmission signal from the LTE base station 100 is suppressed, and the pilot signal in the PHS radio frame 250 is transmitted. The control channel can be protected.

FIG. 6 is an explanatory diagram illustrating an example of transmission stop control in the LTE base station 100 of the present embodiment.
In the example of FIG. 6, a pilot signal is transmitted from the PHS base station 200 at a predetermined downlink time slot (T1) 255 every 125 ms (every 200 times). The LTE base station 100 stops transmission to the LTE mobile station 11 in the downlink subframe (D) 155 corresponding to the downlink time slot (T1) 255 in which the pilot signal is transmitted from the PHS base station 200. So that it is controlled. This control suppresses interference that the pilot signal from the PHS base station 200 to the PHS mobile station 12 receives from the downlink transmission signal from the LTE base station 100, and the control channel through which the pilot signal in the PHS radio frame 250 is transmitted. Can be protected.

  Note that the transmission stop for the LTE mobile station 11 may be performed simultaneously for all of a plurality of frequencies in a predetermined PHS communication band allocated to wireless communication by the PHS base station 200 such as a 1.9 GHz band. Good. In this case, the control channel through which the pilot signal in the PHS radio frame 250 is transmitted can be reliably protected over the entire PHS communication band.

  FIG. 7 is a block diagram illustrating a configuration example of a main part of the LTE base station 100 according to the present embodiment. Note that the LTE base station 100 has a general configuration as an LTE base station, a signal processing function, and a control function in addition to the illustrated configuration.

  In FIG. 7, the LTE base station 100 includes a control unit 101, an antenna 102, an LTE radio transmission / reception unit 103, an LTE uplink signal processing unit 104, and a downlink signal processing unit 105.

  The control unit 101 includes, for example, a CPU, storage means such as storage means (for example, RAM, ROM, HDD, SSD), a clock, and the like. The control unit 101 may include a GPS receiver used for time synchronization with other devices such as the PHS base station 200.

The control unit 101 functions as means for performing various signal processing and control by executing a predetermined control program. For example, the control unit 101 functions as the following means (1) to (5).
(1) Means for setting transmission / reception timing in a TD-LTE radio frame of the local station.
(2) Means for setting the length of the guard period GP of the TD-LTE radio frame of the local station.
(3) Means for changing the length of the guard period GP of the TD-LTE radio frame of the local station.
(4) Means for synchronizing the TD-LTE radio frame of the local station with the PHS radio frame of the PHS base station 200.
(5) When a pilot signal is transmitted from the PHS base station 200 in a predetermined downlink time slot T1, transmission to the LTE mobile station 100 is performed in the downlink subframe D corresponding to the downlink time slot T1. Means to control to stop.

  The transmission / reception timing is set, the guard period GP is set and changed, the PHS base station 200 is synchronized with the PHS radio frame, the transmission stop control for the LTE mobile station 100, and the PHS base station 200 The time synchronization may be performed based on the synchronization signal received from the server or the like by the network communication unit 106, or may be performed based on the GPS signal received by the GPS receiver of the control unit 101.

  The antenna 102 and the LTE wireless transmission / reception unit 103 function as a first wireless communication unit that performs wireless communication with the LTE mobile station 11 using the FD-LTE scheme. The LTE wireless transmission / reception unit 103 amplifies a transmission signal or reception signal of a predetermined frequency transmitted / received to / from the LTE mobile station 11, for example, or an antenna at a timing of a predetermined subframe D based on the control signal from the control unit 101. A radio signal is transmitted from 102 to the LTE mobile station 11, or a radio signal from the LTE mobile station 11 is received from the antenna 102 at a predetermined subframe U timing based on a control signal from the control unit 101.

  The LTE uplink signal processing unit 104 performs, for example, predetermined transmission target data and control information encoding processing and modulation processing, generates a transmission signal, and outputs the transmission signal to the LTE wireless transmission / reception unit 103. In addition, the LTE downlink signal processing unit 105 performs demodulation processing and decoding processing on the reception signal output from the LTE wireless transmission / reception unit 103, for example.

  The network communication unit 106 communicates with various servers and node devices on the network side such as a communication carrier via, for example, a wired or wireless communication link, and downloads various data, information, and signals used for control, etc. Or upload. For example, the network communication unit 106 can download or upload various data, information, and signals used for control such as time synchronization with the PHS base station 200.

  The LTE base station 100 having the configuration shown in FIG. 7 executes, for example, LTE movement at a predetermined transmission / reception timing set in advance in the radio frame described in FIG. 5 by executing a predetermined control program in the control unit 101. A radio signal can be transmitted / received to / from the station 11, and transmission to the LTE mobile station 11 can be stopped in the predetermined downlink subframe 155.

  FIG. 8 is a block diagram showing another configuration example of the main part of the LTE base station 100 according to the present embodiment. In addition, the same code | symbol is attached | subjected about the part similar to the structural example of above-mentioned FIG. 7, and those description is abbreviate | omitted.

  In FIG. 8, the LTE base station 100 further includes an antenna 107 and a PHS signal receiving unit 108 as receiving means for receiving a PHS radio signal transmitted from a neighboring PHS base station 200. Note that the antenna 107 may be used as the antenna 107.

  The PHS signal reception unit 108 is configured by, for example, a PHS reception unit (PHS reception module) that can be incorporated in the LTE base station 100, and can output a reception result of a radio signal from the PHS base station 200 to the control unit 101. . The PHS signal reception unit 108 also functions as a signal detection unit that detects a pilot signal transmitted from the PHS base station 200. For example, the PHS signal reception unit 108 receives a pilot signal transmitted from the PHS base station 200 and detects the pilot signal. The result can be output to the control unit 101.

  Based on the reception result of the radio signal from the PHS base station 200 output from the PHS signal receiving unit 108, the control unit 101 converts the TD-LTE LTE radio frame 150 of the local station into the PHS PHS radio frame 250. Perform synchronization processing to synchronize with. In this case, even if at least one of the LTE radio frame and the PHS radio frame fluctuates with time, the radio signal for the mobile station 11 in the LTE radio frame is between the LTE radio frame 150 and the PHS radio frame 250. The radio signal reception timing from the mobile station 11 in the LTE radio frame and the radio signal to the mobile station 12 in the PHS radio frame so that the transmission timing of the radio signal does not overlap with the reception timing of the radio signal from the mobile station 12 in the PHS radio frame Therefore, it is possible to more reliably suppress mutual interference when a TD-LTE communication system and a PHS communication system coexist in the same frequency band.

  Further, the control unit 101 determines a downlink time slot T1 in which the pilot signal is transmitted based on the detection result of the pilot signal output from the PHS signal receiving unit 108, and corresponds to the downlink time slot T1. In the downlink subframe D to be transmitted, control is performed so as to stop transmission to the LTE mobile station 11. In this case, even if the timing of the pilot signal output from the PHS signal receiving unit 108 fluctuates, the downlink time slot T1 in which the pilot signal is transmitted is accurately determined, and the pilot signal in the PHS radio frame 250 is transmitted. The control channel can be reliably protected.

  FIG. 9 is a block diagram showing still another configuration example of the main part of the LTE base station 100 according to the present embodiment. The LTE base station 100 in FIG. 9 is a configuration example in which the function of the PHS base station is built. In addition, the same code | symbol is attached | subjected about the part similar to the structural example of above-mentioned FIG. 7, and those description is abbreviate | omitted.

  In FIG. 9, the LTE base station 100 includes an antenna 107 and a PHS wireless transmission / reception unit 109 as a second wireless communication unit that performs wireless communication with the PHS mobile station 12 using the PHS method, and a PHS uplink signal processing unit 110. The PHS downlink signal processing unit 111 is further provided. Note that the antenna 107 may be used as the antenna 107.

  The PHS wireless transmission / reception unit 109 is configured by, for example, a PHS base station unit or a PHS base station module that can be incorporated in the LTE base station 100, and amplifies transmission signals and reception signals of a predetermined frequency transmitted to and received from the PHS mobile station 12. Or a radio signal is transmitted from the antenna 107 to the PHS mobile station 12 at timings of predetermined transmission time slots T1 to T4 based on a control signal from the control unit 101, or predetermined based on a control signal from the control unit 101 The radio signal from the PHS mobile station 12 is received from the antenna 107 at the timing of the reception time slots R1 to R4.

  The PHS uplink signal processing unit 110 performs, for example, predetermined transmission target data and control information encoding processing and modulation processing, generates a transmission signal, and outputs the transmission signal to the PHS wireless transmission / reception unit 109. Also, the PHS downlink signal processing unit 111 performs demodulation processing and decoding processing on the reception signal output from the PHS wireless transmission / reception unit 109, for example.

  In the LTE base station 100 of FIG. 9, the PHS radio transmission / reception unit 109 can output the reception result of the radio signal from the PHS base station 200 to the control unit 101. The PHS wireless transmission / reception unit 109 also functions as a signal detection unit that detects a pilot signal transmitted from the PHS base station 200. For example, the PHS wireless transmission / reception unit 109 receives a pilot signal transmitted from the PHS base station 200 and detects the pilot signal. The result can be output to the control unit 101.

  Based on the reception result of the radio signal from the PHS base station 200 output from the PHS radio transmission / reception unit 109, the control unit 101 converts the TD-LTE LTE radio frame 150 of the local station into the PHS PHS radio frame 250. Perform synchronization processing to synchronize with. In this case, even if at least one of the LTE radio frame and the PHS radio frame varies with time, the radio signal is transmitted between the LTE radio frame 150 and the PHS radio frame 250 to the mobile stations 11 and 12. When the timing and the reception timing of the radio signal from the mobile stations 11 and 12 do not overlap, the TD-LTE communication system and the PHS communication system coexist in the same frequency band. Mutual interference can be suppressed more reliably.

  Further, the control unit 101 determines a downlink time slot T1 in which the pilot signal is transmitted based on the detection result of the pilot signal output from the PHS wireless transmission / reception unit 109, and corresponds to the downlink time slot T1. In the downlink subframe D to be transmitted, control is performed so as to stop transmission to the LTE mobile station 11. In this case, even if the timing of the pilot signal output from the PHS signal receiving unit 108 fluctuates, the downlink time slot T1 in which the pilot signal is transmitted is accurately determined, and the pilot signal in the PHS radio frame 250 is transmitted. The control channel can be reliably protected.

  FIG. 10 is a block diagram illustrating a configuration example of main parts of the LTE base station 100 and the synchronization signal transmission unit 300 according to the present embodiment. In addition, the same code | symbol is attached | subjected about the part similar to the structural example of above-mentioned FIG. 7, and those description is abbreviate | omitted.

  In FIG. 10, the LTE base station 100 includes an antenna 112 as a reception unit for receiving a synchronization signal including a PHS pilot signal transmitted from the synchronization signal transmission apparatus 300 or a synchronization signal including timing information of the pilot signal. And a synchronization signal receiving unit 113. Note that the antenna 112 may be used as the antenna 112.

  The synchronization signal transmission apparatus 300 includes an antenna 301 and a PHS signal receiving unit 302 as means for receiving a PHS pilot signal transmitted from the PHS base station 200, and a timing of the synchronization signal or pilot signal including the pilot signal of the PHS. A synchronization signal transmission unit 303 and an antenna 304 as means for transmitting a synchronization signal including information; Note that the antenna 304 may be used as the antenna 304.

  The synchronization signal transmission device 300 is installed, for example, in the following place where the LTE base station 100 cannot directly receive a signal from the PHS base station 200 or is difficult to receive. For example, when the LTE base station 100 is installed in a building such as a femto base station and the PHS base station 200 is installed outside the building, the LTE base station 100 transmits a signal from the PHS base station 200. Cannot be received directly or is difficult to receive. In this case, a location where the LTE base station 100 can receive the synchronization signal from the synchronization signal transmission device 300 and the synchronization signal transmission device 300 can receive the signal from the PHS base station 200 (for example, in the window of the building). The synchronization signal transmission device 300 is installed in a nearby location.

  The PHS signal reception unit 302 includes, for example, a PHS signal reception unit (PHS reception module), and can output a reception result of a radio signal from the PHS base station 200 to the synchronization signal transmission unit 303 via the antenna 301. The PHS signal receiving unit 302 also functions as a signal detection unit that detects a pilot signal transmitted from the PHS base station 200. For example, the PHS signal receiving unit 302 receives a pilot signal transmitted from the PHS base station 200 and detects the pilot signal. The result can be output to the synchronization signal transmission unit 303. The synchronization signal transmission unit 303 transmits a synchronization signal including the pilot signal received by the PHS signal reception unit 302 or a synchronization signal including pilot signal timing information to the LTE base station 100.

  The synchronization signal receiving unit 113 of the LTE base station 100 includes, for example, a synchronization signal receiving unit (synchronous reception module) that can be incorporated in the LTE base station 100, and controls the reception result of the synchronization signal received from the synchronization signal transmission device 300. The data can be output to the unit 101.

  Based on the reception result of the synchronization signal from the synchronization signal transmission device 300 output from the synchronization signal receiver 113, the control unit 101 converts the TD-LTE LTE radio frame 150 of the local station into the PHS PHS radio frame. The synchronization processing to synchronize with 250 is performed. In this case, even if at least one of the LTE radio frame and the PHS radio frame fluctuates with time, the radio signal for the mobile station 11 in the LTE radio frame is between the LTE radio frame 150 and the PHS radio frame 250. The radio signal reception timing from the mobile station 11 in the LTE radio frame and the radio signal to the mobile station 12 in the PHS radio frame so that the transmission timing of the radio signal does not overlap with the reception timing of the radio signal from the mobile station 12 in the PHS radio frame Therefore, it is possible to more reliably suppress mutual interference when a TD-LTE communication system and a PHS communication system coexist in the same frequency band.

  Further, the control unit 101 determines the downlink time slot T1 in which the pilot signal is transmitted from the PHS base station 200 based on the detection result of the synchronization signal output from the synchronization signal receiving unit 113, and the downlink time slot T1 is transmitted. Control is performed to stop transmission to the LTE mobile station 11 in the downlink subframe D corresponding to the time slot T1. In this case, even if the timing of the pilot signal corresponding to the synchronization signal output from the synchronization signal receiving unit 113 fluctuates, the downlink time slot T1 in which the pilot signal is transmitted is accurately determined, and the PHS radio frame 250 The control channel through which the pilot signal is transmitted can be reliably protected.

  In particular, even if the LTE base station 100 in FIG. 10 cannot directly receive the radio signal from the PHS base station 200, the LTE base station 100 in the radio frame described in FIG. 5 described above based on the synchronization signal received from the synchronization signal transmission device 300. A radio signal can be transmitted / received to / from the LTE mobile station 11 at a predetermined transmission / reception timing set in advance, or transmission to the LTE mobile station 11 can be stopped in the predetermined downlink subframe 155.

  As described above, according to the present embodiment, the transmission timing of the radio signal to the mobile station 11 in the LTE radio frame 150 and the radio signal from the mobile station 12 in the PHS radio frame 250 between the LTE radio frame 150 and the PHS radio frame 250. The reception timing of the radio signal from the mobile station 11 in the LTE radio frame 150 does not overlap with the transmission timing of the radio signal to the mobile station 12 in the PHS radio frame 250. Thereby, when the downlink radio signal is transmitted from the PHS base station 200 to the PHS mobile station 12, the LTE base station 100 does not receive the uplink radio signal from the LTE mobile station 11. Therefore, the radio signal transmitted from the PHS base station 200 is not received by the LTE base station 100, and interference with the uplink desired signal from the LTE mobile station 11 can be prevented. Further, when a downlink radio signal is transmitted from the LTE base station 100 to the LTE mobile station 11, the PHS base station 200 does not receive an uplink radio signal from the PHS mobile station 12. Therefore, the radio signal transmitted from the LTE base station 100 is not received by the PHS base station 200, and interference with the desired uplink signal from the PHS mobile station 12 can be prevented. Therefore, mutual interference can be suppressed when a TD-LTE communication system and a PHS communication system are used in the same frequency band.

  Further, according to the present embodiment, control is performed to stop transmission to the LTE mobile station 11 in the downlink subframe D corresponding to the downlink time slot T1 in which the pilot signal is transmitted from the PHS base station 200. ing. By this control, the interference that the pilot signal from the PHS base station 200 to the PHS mobile station 12 receives by the downlink transmission signal from the LTE base station 100 is suppressed, and the control channel through which the pilot signal in the PHS radio frame 250 is transmitted is controlled. Can protect. In this way, when the TD-LTE communication system and the PHS communication system are used in the same frequency band, the control channel through which the pilot signal is transmitted from the PHS base station 200 can be protected.

11 LTE mobile station (UE)
12 PHS mobile station (UE)
100 LTE base station (first base station)
100A LTE cell (macro cell, small cell)
DESCRIPTION OF SYMBOLS 101 Control part 102 Antenna 103 LTE radio | wireless transmission / reception part 104 LTE uplink signal processing part 105 LTE downlink signal processing part 106 Network communication part 107 Antenna 108 PHS signal receiving part 109 PHS radio | wireless transmission / reception part 110 PHS uplink signal processing part 111 PHS down Link signal processing unit 112 Antenna 113 Synchronization signal receiving unit 200 PHS base station (second base station)
200A PHS cell 300 Synchronization signal transmission device 301 Antenna 302 PHS signal reception unit 303 Synchronization signal transmission unit 304 Antenna

JP 2013-219918 A

3GPP TS 36.211 V13.1.0 (2016-04), Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Channels and Modulation, Release 13

The control unit 101 functions as means for performing various signal processing and control by executing a predetermined control program. For example, the control unit 101 functions as the following means (1) to (5).
(1) Means for setting transmission / reception timing in a TD-LTE radio frame of the local station.
(2) Means for setting the length of the guard period GP of the TD-LTE radio frame of the local station.
(3) Means for changing the length of the guard period GP of the TD-LTE radio frame of the local station.
(4) Means for synchronizing the TD-LTE radio frame of the local station with the PHS radio frame of the PHS base station 200.
(5) When the pilot signal from the PHS base station 200 at a predetermined downlink time slot T1 is transmitted in sub-frame D for the downlink corresponding to the downlink time slot T1, transmission to the LTE mobile station 1 1 Means to control to stop.

The setting of the transmission and reception timings, setting the length of the guard period GP and change, the synchronization with the radio frame of the PHS system of the PHS base station 200, the stop control of the transmission to LTE mobile stations 1 1, as well as, PHS base station 200 May be performed based on a synchronization signal received from the server or the like by the network communication unit 106, or may be performed based on a GPS signal received by the GPS receiver of the control unit 101.

FIG. 10 is a block diagram illustrating a configuration example of main parts of the LTE base station 100 and the synchronization signal transmission device 300 according to the present embodiment. In addition, the same code | symbol is attached | subjected about the part similar to the structural example of above-mentioned FIG. 7, and those description is abbreviate | omitted.

Claims (7)

A base station capable of wireless communication with a mobile station,
Wireless communication means for performing wireless communication with a mobile station using a first TDD (time division duplex) method;
When a pilot signal is transmitted in a predetermined downlink time slot from another base station that performs radio communication with a mobile station in a second TDD scheme different from the first TDD scheme, the second TDD scheme And a control means for controlling to stop transmission to the mobile station in the downlink time slot of the first TDD scheme corresponding to the downlink time slot. In the base station of claim 1,
The wireless communication means is configured to perform wireless communication with a mobile station using the first TDD scheme for each of a plurality of frequencies in a predetermined communication band,
The base station is characterized in that the control means simultaneously stops transmission to the mobile station for the plurality of frequencies. In the base station according to claim 1 or 2,
Receiving means for receiving a pilot signal of the second TDD scheme transmitted from the other base station;
The control means determines a downlink time slot in which the pilot signal is transmitted based on a reception result of the pilot signal, and the first TDD corresponding to the second TDD downlink time slot A base station that controls to stop transmission to a mobile station in a TDD downlink time slot. In the base station according to claim 1 or 2,
From the synchronization signal transmitting apparatus that receives the pilot signal of the second TDD scheme transmitted from the other base station and transmits a synchronization signal including the pilot signal or a synchronization signal including timing information of the pilot signal, Receiving means for receiving a signal;
The control means determines a downlink time slot to which the pilot signal is transmitted based on a reception result of the synchronization signal, and the first TDD corresponding to the second TDD downlink time slot A base station that controls to stop transmission to a mobile station in a TDD downlink time slot. In the base station according to any one of claims 1 to 4,
The first TDD scheme is a TD-LTE scheme compliant with the LTE / LTE-Advanced standard,
The second TDD system is a TDD system used in a PHS (Personal Handy Phone System) system,
When the pilot signal is transmitted in the predetermined downlink time slot from the other base station in the second TDD scheme, the control means corresponds to the downlink time slot in the second TDD scheme. A base station that performs control so as to stop transmission to a mobile station in a downlink subframe of the first TDD scheme.   A communication system comprising: the base station according to any one of claims 1 to 5; and another base station that performs radio communication with a mobile station using a second TDD method different from the first TDD method used by the base station. A synchronization signal transmission device for transmitting a synchronization signal toward a base station using the first TDD system according to any one of claims 1 to 5,
Means for receiving a pilot signal of the second TDD scheme transmitted from the other base station;
And a means for transmitting a synchronization signal including the pilot signal or a synchronization signal including timing information of the pilot signal.

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