WO2015165026A1 - 用于实现跨站点灵活配比的方法和基站 - Google Patents
用于实现跨站点灵活配比的方法和基站 Download PDFInfo
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- WO2015165026A1 WO2015165026A1 PCT/CN2014/076432 CN2014076432W WO2015165026A1 WO 2015165026 A1 WO2015165026 A1 WO 2015165026A1 CN 2014076432 W CN2014076432 W CN 2014076432W WO 2015165026 A1 WO2015165026 A1 WO 2015165026A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/02—Selection of wireless resources by user or terminal
Definitions
- Embodiments of the present invention relate to the field of communications, and, more particularly, to a method and base station for implementing cross-site flexible rationing. Background technique
- the LTE (Long Term Evolution) system supports two frames, a FDD (Frequency Division Duplex) frame and a TDD (Time Division Duplex) frame.
- a 10 ms radio frame is divided into two half frames of 5 ms in length, each half frame consisting of 5 subframes of length 1 ms, 4 normal subframes and 1 special subframe.
- a normal subframe consists of two 0.5ms time slots, and a special subframe consists of three special time slots.
- the three special time slots are an UpPTS time slot for uplink signal transmission, a guard interval GP time slot for TDD uplink and downlink conversion, and a DwPTS time slot for transmission of downlink signals.
- An uplink and downlink transition protection interval is set between the uplink and downlink subframes to implement uplink and downlink conversion.
- the base station can flexibly configure the TDD uplink and downlink ratio.
- the TDD uplink and downlink ratio can be dynamically changed according to the traffic volume. For example, the base station configures the TDD uplink-downlink ratio in the broadcast message, and the UE (User Equipment) in the coverage area reads the message to obtain the latest TDD uplink-down ratio.
- each base station independently configures the TDD uplink-downlink ratio of the local cell, and the flexible ratios used between different base stations are often different. In this way, cross-slot interference may occur between adjacent base stations, which in turn affects communication efficiency.
- the embodiments of the present invention provide a method and a base station for implementing a cross-site flexible ratio, which can improve communication efficiency.
- an embodiment of the present invention provides a base station, including: a generating unit, configured to generate a time division duplex TDD flexible proportion configuration message, and the TDD flexible ratio configuration message includes a TDD flexible proportioning parameter, and a TDD flexible proportioning parameter.
- the sending unit is configured to send a TDD flexible proportion configuration message to the second base station, so that the second base station is configured according to the TDD
- the flexible matching ratio configuration message sets the TDD flexible matching parameter;
- the obtaining unit is configured to obtain, according to the TDD flexible matching parameter, the TDD flexible allocation of the second base station to the user equipment UE in the coverage of the second base station based on the TDD flexible matching parameter
- the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the second base station.
- the base station further includes a receiving unit, where the receiving unit is configured to receive a TDD flexible matching request message from the second base station, where the TDD flexible matching request message is used for the request.
- the base station configures a desired TDD flexible proportioning parameter for the second base station, and the generating unit is configured to generate a TDD flexible proportioning configuration message according to the TDD flexible matching request message.
- the acquiring unit is specifically configured to send, according to the TDD flexible proportioning parameter, the second base station to send the second according to the TDD flexible ratio parameter TDD flexible proportioning signaling of UEs within the coverage of the base station.
- the sending unit is further configured to send a TDD flexible proportioning parameter to the UE in the coverage of the base station, so as to facilitate the UE in the coverage of the base station.
- the second base station is configured to send TDD flexible proportioning signaling to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter;
- the acquiring unit is specifically configured to receive from the UE in the coverage of the base station. TDD flexible rationing signaling.
- the sending unit is further configured to send a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes the current use of the base station.
- the TDD flexible matching parameters are further configured to send a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes the current use of the base station.
- the TDD flexible matching parameters also include carrier information supporting TDD flexible matching characteristics, TDD flexible matching wireless network temporary identification, TDD flexible ratio signaling transmission time offset, TDD flexible ratio uplink reference ratio, TDD One or more of the mapping relationship between the downlink reference ratio and the location of the TDD proportioning configuration signaling in the downlink physical layer signaling.
- an embodiment of the present invention provides a base station, including: a receiving unit, configured to receive a time division duplex TDD flexible proportion configuration message from a first base station, where the TDD flexible ratio configuration message includes a TDD flexible ratio parameter, TDD
- the flexible matching parameter includes a transmission period of flexible proportioning signaling; a setting unit, configured to configure a TDD flexible proportioning parameter according to a TDD flexible ratio configuration message; and a sending unit, configured to cover the base station based on the TDD flexible proportioning parameter
- the user equipment UE in the UE sends TDD flexible proportioning signaling, and the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the base station.
- the sending unit is further configured to send a TDD flexible matching request message to the first base station, where the TDD flexible matching request message is used to request the first base station to configure the base station for the base station.
- the TDD flexible matching parameters are further configured to send a TDD flexible matching request message to the first base station, where the TDD flexible matching request message is used to request the first base station to configure the base station for the base station.
- the receiving unit is further configured to receive a TDD flexible matching reference message from the first base station, where the TDD flexible matching reference message includes the current current location of the first base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio wireless network temporary identifier, and TDD flexibility.
- carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio wireless network temporary identifier, and TDD flexibility.
- the mapping between the transmission time offset of the proportioning signaling, the uplink reference ratio of the TDD flexible ratio, the downlink reference ratio of the TDD flexible ratio, and the position of the TDD ratio configuration signaling in the downlink physical layer signaling One or more.
- an embodiment of the present invention provides a method for implementing a cross-site flexible ratio, which includes: a first base station generates a time division duplex TDD flexible proportion configuration message, and a TDD flexible ratio configuration message includes a TDD flexible ratio.
- the parameter, the TDD flexible matching parameter includes a transmission period of the TDD flexible proportioning signaling; the first base station sends a TDD flexible proportion configuration message to the second base station, so that the second base station sets the TDD flexible ratio according to the TDD flexible ratio configuration message.
- the first base station obtains TDD flexible proportioning signaling sent by the second base station to the user equipment UE in the coverage of the second base station according to the TDD flexible proportioning parameter, and the TDD flexible ratio signaling includes The index of the TDD flexible ratio currently used by the second base station.
- the method before the first base station generates the time division duplex TDD flexible proportion configuration message, the method further includes: the first base station receiving the TDD flexible ratio from the second base station The request message, the TDD flexible matching request message is used to request the first base station to configure the desired TDD flexible proportioning parameter for the second base station; the first base station generates the time division duplex TDD flexible proportioning configuration message, including: the first base station is flexible according to the TDD The matching request message generates a TDD flexible matching configuration message.
- the first base station acquires, according to the TDD flexible ratio parameter, the second base station sends the coverage ratio to the second base station based on the TDD flexible ratio parameter.
- the TDD flexible proportioning signaling of the user equipment UE includes: the first base station, according to the TDD flexible proportioning parameter, intercepting the TDD flexible ratio of the second base station to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter Signaling.
- a base station obtains TDD flexible proportioning signaling that is sent by the second base station to the user equipment UE in the coverage of the second base station according to the TDD flexible proportioning parameter, and includes: the coverage of the first base station to the first base station
- the UE in the UE sends the TDD flexible proportioning parameter, so that the UE in the coverage of the first base station, according to the TDD flexible proportioning parameter, listens to the TDD of the UE that is sent by the second base station to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter.
- Flexible proportioning signaling the first base station receives TDD flexible proportioning signaling from UEs within the coverage of the first base station.
- the method further includes: the first base station sends a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes The TDD flexible matching parameter currently used by a base station.
- the TDD flexible matching parameters also include carrier information supporting TDD flexible matching characteristics, TDD flexible matching wireless network temporary identification, TDD flexible ratio signaling transmission time offset, TDD flexible ratio uplink reference ratio, TDD One or more of the mapping relationship between the downlink reference ratio and the location of the TDD proportioning configuration signaling in the downlink physical layer signaling.
- an embodiment of the present invention provides a method for implementing a cross-site flexible ratio, including: receiving, by a second base station, a time division duplex TDD flexible proportion configuration message from a first base station, where the TDD flexible ratio configuration message includes The TDD flexible matching parameter, the TDD flexible matching parameter includes the transmission period of the flexible ratio signaling; the second base station sets the TDD flexible proportioning parameter according to the TDD flexible ratio configuration message; the second base station is based on the TDD flexible ratio parameter, The user equipment UE in the coverage of the second base station sends TDD flexible proportioning signaling, and the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the second base station.
- the method before the second base station receives the time division duplex TDD flexible proportion configuration message from the first base station, the method further includes: the second base station to the first base station The TDD flexible matching request message is sent, and the TDD flexible matching request message is used to request the first base station to configure the expected TDD flexible matching parameter for the second base station.
- the method further includes: receiving, by the second base station, a TDD flexible matching reference message from the first base station, where the TDD flexible proportion reference message includes the first The TDD flexible matching parameter currently used by the base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio wireless network temporary identifier, and TDD flexible
- the transmission time offset of the proportioning signaling and the TDD are flexibly matched.
- the first base station configures a TDD flexible proportioning parameter for the second base station.
- the first base station can obtain the flexible ratio signaling sent by the second base station to the UE based on the TDD flexible proportioning parameter, and can further know the flexible ratio currently used by the second base station.
- the first base station can flexibly adjust information such as the flexible ratio of the first base station or the uplink and downlink scheduling according to the flexible ratio used by the second base station, so as to avoid mutual interference between the first base station and the second base station. Thereby improving communication efficiency.
- Figure 1 is a schematic flow diagram of a method for implementing cross-site flexible ratioing in accordance with one embodiment of the present invention.
- FIG. 2 is a schematic flow diagram of a method for implementing cross-site flexible ratioing according to another embodiment of the present invention.
- FIG. 3 is a schematic flow diagram of a method for implementing cross-site flexible ratioing in accordance with another embodiment of the present invention.
- FIG. 4 is a schematic block diagram of a base station according to an embodiment of the present invention.
- FIG. 5 is a schematic block diagram of a base station according to another embodiment of the present invention.
- FIG. 6 is a schematic block diagram of a base station according to another embodiment of the present invention.
- FIG. 7 is a schematic block diagram of a base station according to another embodiment of the present invention. detailed description
- GSM Global System of Mobile communication
- CDMA Code Division Multiple Access
- WCDMA Wideband Code Division Multiple Access
- GPRS General Packet Radio Service
- LTE Long Term Evolution
- FDD Frequency Division Duplex
- TDD Time Division Duplex
- UMTS Universal Mobile Telecommunication System
- WiMAX Worldwide Interoperability for Microwave Access
- a user equipment may be referred to as a terminal, a mobile station (Mobile Station, referred to as “MS”), and a mobile terminal (Mobile Terminal).
- the user equipment can communicate with one or more core networks via a Radio Access Network (“RAN"), for example, the user equipment can be a mobile phone (or “cellular” phone)
- RAN Radio Access Network
- the user equipment can be a mobile phone (or “cellular” phone)
- Computers with mobile terminals, etc. for example, the user devices can also be portable, pocket-sized, handheld, computer-integrated or in-vehicle mobile devices that exchange voice and/or data with the wireless access network.
- the base station may be a base station (Base Transceiver Station, referred to as "BTS") in GSM or CDMA, or may be a base station (NodeB, referred to as "NB") in WCDMA, or may be in LTE.
- BTS Base Transceiver Station
- NodeB NodeB
- the present invention is not limited to the evolved Node B (abbreviated as ' ⁇ or e-NodeB'). However, for convenience of description, the following embodiments will be described by taking the base station ENB and the user equipment UE as an example.
- Figure 1 is a schematic flow diagram of a method for implementing cross-site flexible ratioing in accordance with one embodiment of the present invention.
- the method 10 shown in Figure 1 can be performed by a base station, which can be a macro base station, a micro base station, or other type of base station in a cellular network.
- the first base station generates a time division duplex TDD flexible proportion configuration message, the TDD flexible proportion configuration message includes a TDD flexible proportioning parameter, and the TDD flexible proportioning parameter includes a TDD flexible ratio signaling sending period.
- the first base station may generate a TDD flexible proportion configuration message of the second base station according to information such as service characteristics and load of the first base station.
- the first base station sends a TDD flexible proportion configuration message to the second base station, so that the second base station sets the TDD flexible proportioning parameter according to the TDD flexible proportion configuration message.
- the first base station sends a TDD flexible proportion configuration message to the second base station.
- the second base station sends the TDD flexible proportioning parameter to the UE according to the TDD flexible proportioning parameter in the TDD flexible ratio configuration message, to complete setting the TDD flexible proportioning parameter.
- the first base station may transmit the configuration message ratio TDD flexible interface or through X n X 2 interface to a second base station.
- the first base station acquires, according to the TDD flexible proportioning parameter, the TDD flexible proportioning signaling that is sent by the second base station to the user equipment UE in the coverage of the second base station according to the TDD flexible proportioning parameter, where the TDD flexible ratio signaling includes The index of the TDD flexible ratio currently used by the second base station.
- the first base station may perform other TDD flexible matching parameters, such as a TDD flexible ratio signaling transmission period in the TDD flexible ratio parameter, and a preset TDD flexible ratio signaling transmission time offset.
- TDD flexible proportioning signaling sent by the second base station to the UE is monitored.
- the first base station configures a TDD flexible proportioning parameter for the second base station.
- the first base station can obtain the flexible ratio signaling sent by the second base station to the UE based on the TDD flexible proportioning parameter, and can further know the flexible ratio currently used by the second base station.
- the first base station can flexibly adjust information such as the flexible ratio of the first base station or the uplink and downlink scheduling according to the flexible ratio used by the second base station, so as to avoid mutual interference between the first base station and the second base station. Thereby improving communication efficiency.
- the flexible ratio currently used by each cell covered by the second base station may be referred to as the flexible ratio currently used by the second base station.
- the first base station determines the flexible ratio of the current use of the second base station according to the TDD flexible proportioning signaling sent by the second base station that is detected, which is often a flexible ratio used by the cell adjacent to the first base station.
- the first base station learns the flexible ratio currently used by the second base station, according to the method of the embodiment of the present invention, if the flexible ratio used by the second base station is different from the flexible ratio used by the first base station, The first base station can adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station.
- the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious.
- the downlink to uplink transition interval is included every 5ms.
- the downlink to uplink transition interval is included every 10ms. It is assumed that the first base station uses the ratio 0, and the second base station uses the ratio 5, so that in the subframes with the subframe numbers 4, 7, 8, and 9, the first base station schedules uplink data transmission, and the second base station schedules downlink. Data is sent. In other words, the first base station is in these subframes When scheduling and receiving data transmitted by the UE, the second base station transmits data to the UE just in these subframes.
- the transmit power of the second base station is much larger than the transmit power used by the UE to transmit data to the first base station.
- the signal sent by the UE to the first base station may be flooded by the signal transmitted by the first base station, thereby affecting the normal communication between the first base station and the UE. That is to say, when the first base station and the second base station use different flexible ratios, cross-slot interference may be caused.
- the first base station may not schedule UEs adjacent to the second base station in the subframes, or let the scheduled users increase the transmission power.
- the first base station may change the flexible ratio of one or more cells of the coverage of the base station to avoid cross-slot interference.
- the first base station may further receive a TDD flexible proportion request message from the second base station, where the TDD flexible ratio request message is used to request the first The base station configures the desired TDD flexible proportioning parameter for the second base station.
- the TDD flexible proportion configuration request message can be generated according to the TDD flexible ratio request message.
- the TDD flexible matching configuration message may be It does not include some or all of the accepted TDD flexible matching parameters, but only the modified TDD flexible matching configuration parameters of the first base station.
- the second base station may send a TDD flexible proportioning request message to the first base station in advance, where
- the TDD flexible proportioning request message may include a TDD flexible proportioning parameter desired by the second base station.
- the second base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the first base station may generate an appropriate TDD flexible proportion configuration message according to the TDD flexible matching request message.
- the first base station may further send a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes a TDD flexible proportion parameter currently used by the first base station.
- the first base station sends a TDD flexible proportion reference message to the second base station, and the second base station may determine, according to the TDD flexible proportion reference message, the TDD flexible proportion parameter currently used by the first base station.
- the second base station can listen to the TDD flexible proportioning signaling sent by the first base station to the UE according to the TDD flexible proportioning parameter of the first base station, and further determine the flexible ratio currently used by the second base station.
- the second base station may also adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station. In this way, mutual interference between the first base station and the second base station can be further reduced.
- the TDD flexible proportion reference message received by the second base station from the first base station may further include TDD flexible proportioning parameters of other base stations.
- the first base station can comprehensively consider the TDD flexible proportioning parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the first base station may, according to the TDD flexible proportioning parameter, listen to the TDD flexibility of the second base station to send to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter. Proportional signaling.
- the first base station may send a TDD flexible proportioning parameter to the UE in the coverage of the first base station, so that the UE in the coverage of the first base station has a flexible ratio according to the TDD.
- the parameter the second base station sends the TDD flexible proportioning signaling to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter. Then, the first base station receives TDD flexible proportioning signaling from UEs within the coverage of the first base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio radio network temporary identifier, TDD flexible ratio signaling transmission time offset, TDD One or more of a mapping relationship of a flexible ratio of an uplink reference ratio, a TDD flexible ratio downlink reference ratio, and a position of a TDD ratio configuration signaling in downlink physical layer signaling.
- FIG. 2 is a schematic flowchart of a method for implementing cross-site flexible proportioning according to another embodiment of the present invention.
- the method 20 shown in Figure 2 can be performed by a base station, which can be a macro base station, a micro base station, or other type of base station in a cellular network.
- the second base station receives the time division duplex TDD flexible proportion configuration message from the first base station, the TDD flexible proportion configuration message includes a TDD flexible proportioning parameter, and the TDD flexible proportioning parameter includes a transmission period of the flexible ratio signaling.
- the ratio of the second base station may flexibly configure the message interface or through X n X 2 interface receives from the first base station TDD.
- the second base station sets a TDD flexible proportioning parameter according to the TDD flexible ratio configuration message. For example, the second base station sends the TDD flexible ratio parameter to the UE according to the TDD flexible ratio configuration message to complete the setting of the TDD flexible proportioning parameter. If the TDD flexible proportioning parameter is successfully set, the second base station may send a response message that the setting is successful to the first base station. If the TDD flexible matching parameter is not successfully set, the second base station may send a response message indicating that the setting is failed to the first base station.
- the second base station sends TDD flexible proportioning signaling to the user equipment UE in the coverage of the second base station based on the TDD flexible proportioning parameter, where the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the second base station. .
- the second base station may send TDD flexible proportioning signaling to the UE according to the newly set TDD flexible proportioning parameter, so as to meet the flexible matching ratio of the service characteristic in real time. demand.
- the first base station configures a TDD flexible proportioning parameter for the second base station.
- the first base station can obtain the flexible ratio signaling sent by the second base station to the UE based on the TDD flexible proportioning parameter, and can further know the flexible ratio currently used by the second base station.
- the first base station can flexibly adjust information such as the flexible ratio of the first base station or the uplink and downlink scheduling according to the flexible ratio used by the second base station, so as to avoid mutual interference between the first base station and the second base station. Thereby improving communication efficiency.
- the first base station learns the flexible ratio currently used by the second base station, according to the method of the embodiment of the present invention, if the flexible ratio used by the second base station is different from the flexible ratio used by the first base station, The first base station can adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station.
- the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious. In this way, the first base station may not schedule the UE adjacent to the second base station in the clipped subframe, or let the scheduled user increase the transmission power.
- the first base station may change the flexible ratio of one or more cells in the coverage of the base station to avoid cross-slot interference.
- the second base station may further send a TDD flexible matching request message to the first base station, where the TDD flexible matching request message is used. The first base station is requested to configure a desired TDD flexible proportioning parameter for the second base station.
- the second base station may send a TDD flexible proportioning request message to the first base station in advance, where
- the TDD flexible proportioning request message may include a TDD flexible proportioning parameter desired by the second base station.
- the second base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the first base station may generate an appropriate TDD flexible proportion configuration message according to the TDD flexible matching request message.
- the second base station may further receive a TDD flexible matching reference message from the first base station, where the TDD flexible matching reference message includes a TDD flexible matching parameter currently used by the first base station.
- the first base station sends a TDD flexible proportion reference message to the second base station, and the second base station may determine, according to the TDD flexible proportion reference message, the TDD flexible proportion parameter currently used by the first base station.
- the second base station can listen to the TDD flexible proportioning signaling sent by the first base station to the UE according to the TDD flexible proportioning parameter of the first base station, and further determine the flexible ratio currently used by the second base station.
- the second base station may also adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station. In this way, mutual interference between the first base station and the second base station can be further reduced.
- the TDD flexible proportion reference message received by the second base station from the first base station may further include TDD flexible proportioning parameters of other base stations.
- the first base station can comprehensively consider the TDD flexible proportioning parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio radio network temporary identifier, TDD flexible ratio signaling transmission time offset, TDD One or more of a mapping relationship of a flexible ratio of an uplink reference ratio, a TDD flexible ratio downlink reference ratio, and a position of a TDD ratio configuration signaling in downlink physical layer signaling.
- FIG. 3 is a schematic flow diagram of a method for implementing cross-site flexible ratioing in accordance with another embodiment of the present invention. As shown in FIG. 3, a description will be given by taking a first base station as a macro base station and a second base station as a micro base station.
- the micro base station sends a TDD flexible matching request message to the macro base station.
- the micro base station can determine a desired TDD flexible proportioning parameter according to information such as service characteristics. Then, the desired TDD flexible matching parameter is sent to the macro base station through the TDD flexible matching request message, so that the macro base station configures the appropriate TDD flexible matching parameter.
- the macro base station generates a TDD flexible proportion configuration message.
- the macro base station generates a TDD flexible proportion configuration message according to the TDD flexible proportioning request message received in step 701.
- the TDD flexible matching configuration message includes the TDD flexible matching parameter, and the TDD flexible matching parameter includes the sending period of the TDD flexible matching signaling.
- the macro base station sends a TDD flexible proportion configuration message to the micro base station.
- the macro base station sends a TDD flexible proportion configuration message to the micro base station, and the TDD flexible proportion configuration message may include a TDD flexible proportioning parameter.
- the macro base station may transmit a configuration message ratio TDD flexible interface or through X n ⁇ 2 interface to a micro base station.
- the micro base station sets the TDD flexible proportioning parameter.
- the micro base station sends the TDD flexible proportioning parameter to the UE according to the TDD flexible proportion configuration message received in step 303 to complete the setting of the TDD flexible proportioning parameter.
- the micro base station sends TDD flexible proportioning signaling to the UE.
- step 304 the setting of the TDD flexible proportioning parameter is completed.
- the micro base station sends TDD flexible proportioning signaling to the user equipment UE based on the TDD flexible proportioning parameter.
- the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the second base station.
- the macro base station listens to TDD flexible proportioning signaling.
- the macro base station may be based on a TDD flexible proportioning signaling transmission period in the TDD flexible ratio parameter, and a preset TDD flexible ratio signaling transmission time offset and other related TDD flexible matching parameters, and the detection Listening to the TDD flexible proportioning signaling sent by the micro base station to the UE in step 305. In this way, the macro base station can learn the TDD flexible proportioning signaling currently used by the micro base station.
- the first base station configures a TDD flexible proportioning parameter for the second base station.
- the first base station can obtain the flexible ratio signaling sent by the second base station to the UE based on the TDD flexible proportioning parameter, and can further know the flexible ratio currently used by the second base station.
- the first base station can flexibly adjust information such as the flexible ratio of the first base station or the uplink and downlink scheduling according to the flexible ratio used by the second base station, so as to avoid mutual interference between the first base station and the second base station. Thereby improving communication efficiency.
- the first base station may configure the UE in its coverage to report the index of the TDD flexible ratio currently used by the first base station to the second base station.
- the first base station and the second base station are adjacent base stations.
- the first base station sends a first configuration message to the UE, and configures the UE to report the index of the TDD flexible ratio currently used by the first base station to the second base station.
- the TDD flexible ratio currently used by the first base station may be a flexible ratio currently used by one or more cells controlled by the first base station.
- the first base station may configure the UE by using L1 layer signaling, L2 layer signaling, or L3 layer signaling. For example, a dedicated RRC (Radio Resource Control) message or a system broadcast message in L3 layer signaling.
- the UE reports the index of the flexible ratio currently used by the first base station to the second base station according to the first configuration message.
- the second base station can adjust the flexible ratio of the base station or the uplink and downlink scheduling to avoid cross-slot interference, thereby improving communication efficiency.
- the base station 40 shown in FIG. 4 includes a generating unit 401, a transmitting unit 402, and an obtaining unit 403.
- the generating unit 401 is configured to generate a time division duplex TDD flexible proportioning configuration message, the TDD flexible proportioning configuration message includes a TDD flexible proportioning parameter, and the TDD flexible proportioning parameter includes a sending period of the TDD flexible proportioning signaling.
- the generating unit 401 may generate a TDD flexible proportion configuration message of the second base station according to information such as service characteristics and load of the first base station.
- the sending unit 402 is configured to send a TDD flexible proportion configuration message to the second base station, so that the second base station sets the TDD flexible proportioning parameter according to the TDD flexible ratio configuration message.
- the sending unit 402 sends a TDD flexible proportion configuration message to the second base station. Then, the second base station sends the TDD flexible proportioning parameter to the UE according to the TDD flexible proportioning parameter in the TDD flexible ratio configuration message, to complete setting the TDD flexible proportioning parameter.
- the transmission unit 402 may transmit a configuration message ratio TDD flexible interface or through X n X 2 interface to a second base station.
- the obtaining unit 403 is configured to obtain, according to the TDD flexible proportioning parameter, a TDD flexible ratio that is sent by the second base station to the user equipment UE in the coverage of the second base station based on the TDD flexible proportioning parameter.
- Signaling, TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the second base station. For example, according to the TDD flexible ratio signaling transmission period in the TDD flexible proportioning parameter, and the preset TDD flexible ratio signaling transmission time offset and other related TDD flexible matching parameters, the interception parameter can be used to listen.
- the TDD flexible proportioning signaling sent by the second base station to the UE according to the TDD flexible ratio signaling transmission period in the TDD flexible proportioning parameter, and the preset TDD flexible ratio signaling transmission time offset and other related TDD flexible matching parameters.
- the base station configures a TDD active ratio parameter for the second base station.
- the base station can obtain the flexible proportioning signaling sent by the second base station to the UE based on the TDD flexible matching parameter, and can further know the flexible ratio currently used by the second base station.
- the base station can flexibly adjust the flexible ratio of the first base station or the uplink and downlink scheduling information according to the flexible ratio used by the second base station, so as to avoid mutual interference between the base station and the second base station, thereby improving communication. effectiveness.
- the flexible ratio currently used by each cell covered by the second base station may be referred to as the flexible ratio currently used by the second base station.
- the base station determines the flexible ratio of the current use of the second base station according to the TDD flexible proportioning signaling sent by the second base station that is detected, which is often a flexible ratio of the cell used by the neighboring base station.
- the base station can adjust the base to avoid cross-slot interference.
- the flexible ratio used by the base station or the uplink and downlink scheduling of the base station Especially in the application scenario of cross-site carrier aggregation, the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious. In this way, the base station can not schedule the UE adjacent to the second base station in the clipped subframe, or let the scheduled user increase the transmission power. Alternatively, the base station can change the flexible ratio of one or more cells in the coverage of the base station to avoid cross-slot interference.
- the base station further includes a receiving unit 404, where the receiving unit 404 is configured to receive a TDD flexible proportioning request message from the second base station, where the TDD flexible matching request message is used to request the base station to configure the desired requirement for the second base station.
- the TDD flexible matching parameters In this case, the generating unit 401 is specifically configured to generate a TDD flexible matching configuration message according to the TDD flexible matching request message.
- the TDD flexible matching configuration message may not include Some or all of the TDD flexible matching parameters are accepted, and only the TDD flexible matching configuration parameters modified by the first base station are included.
- the second base station may send a TDD flexible proportioning request message to the base station in advance, the TDD
- the flexible proportioning request message may include a TDD flexible proportioning parameter desired by the second base station.
- the second base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the base station can generate an appropriate TDD flexible proportion configuration message according to the TDD flexible ratio request message.
- the sending unit 402 is further configured to send a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes a TDD flexible proportion parameter currently used by the base station.
- the base station sends a TDD flexible proportion reference message to the second base station, and the second base station can determine the TDD flexible proportion parameter currently used by the base station according to the TDD flexible ratio reference message.
- the second base station can detect the TDD flexible proportioning signaling sent by the base station to the UE according to the TDD flexible proportioning parameter of the base station, and then determine the flexible ratio currently used by the second base station.
- the second base station may also adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station. In this way, mutual interference between the base station and the second base station can be further reduced.
- the TDD flexible proportion reference message received by the second base station from the base station may further include TDD flexible proportioning parameters of other base stations.
- the base station can comprehensively consider the TDD flexible ratio parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the acquiring unit 403 is specifically configured to: according to the TDD flexible proportioning parameter, listen to the TDD flexible ratio of the second base station to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter. Signaling.
- the sending unit 402 is further configured to send a TDD flexible proportioning parameter to the UE in the coverage of the base station, so that the UE in the coverage of the base station can listen to the second according to the TDD flexible proportioning parameter.
- the base station sends the TDD flexible proportioning signaling to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter.
- the obtaining unit 403 is specifically configured to receive TDD flexible proportioning signaling from UEs in the coverage of the base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio radio network temporary identifier, TDD flexible ratio signaling transmission time offset, TDD One or more of a mapping relationship of a flexible ratio of an uplink reference ratio, a TDD flexible ratio downlink reference ratio, and a position of a TDD ratio configuration signaling in downlink physical layer signaling.
- FIG. 5 is a schematic block diagram of a base station according to another embodiment of the present invention.
- the base station 50 in FIG. 5 includes a receiving unit 501, a setting unit 502, and a transmitting unit 503.
- the receiving unit 501 is configured to receive a time division duplex TDD flexible proportion configuration message from the first base station, where the TDD flexible proportion configuration message includes a TDD flexible proportioning parameter, and the TDD flexible proportioning parameter includes a sending period of the flexible ratio signaling.
- the setting unit 502 is configured to set a TDD flexible proportioning parameter according to the TDD flexible ratio configuration message.
- the setting unit 502 may send the TDD flexible proportioning parameter to the UE according to the TDD flexible proportion configuration message to complete the setting of the TDD flexible proportioning parameter.
- the sending unit 503 is configured to send TDD flexible proportioning signaling to the user equipment UE in the coverage of the base station according to the TDD flexible proportioning parameter, where the TDD flexible proportioning signaling includes an index of the TDD flexible ratio currently used by the base station.
- the sending unit 503 can send TDD flexible proportioning signaling to the UE based on the newly set TDD flexible proportioning parameter, so as to meet the requirement of flexible matching of the service characteristics in real time. If the TDD flexible matching parameter is successfully set, the base station may send a response message that the setting is successful to the first base station. If the TDD flexible matching parameter is not successfully set, the base station may send a response message of setting failure to the first base station.
- the first base station configures a TDD active ratio parameter for the base station.
- the first base station can obtain the flexible proportioning signaling sent by the base station to the UE based on the TDD flexible proportioning parameter, and can further know the flexible ratio currently used by the base station.
- the first base station can flexibly adjust the flexible ratio of the first base station or the uplink and downlink scheduling information according to the flexible ratio used by the base station, so as to avoid mutual interference between the first base station and the base station, thereby improving communication. effectiveness.
- the first base station may Adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station.
- the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious.
- the first base station may not schedule the UE adjacent to the base station in the clipped subframe, or let the scheduled user increase the transmission power.
- the first base station may change the flexible ratio of one or more cells of the coverage of the base station to avoid cross-slot interference.
- the sending unit 503 is further configured to send a TDD flexible matching request message to the first base station, where the TDD flexible matching request message is used to request the first base station to configure a desired TDD flexible matching parameter for the base station.
- the base station may send a TDD flexible proportioning request message to the first base station in advance, and the TDD flexible proportioning request message may include a TDD flexible proportioning parameter desired by the base station.
- the base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the first base station may generate an appropriate TDD flexible proportion configuration message according to the TDD flexible matching request message.
- the receiving unit 501 is further configured to receive a TDD flexible matching reference message from the first base station, where the TDD flexible matching reference message includes a TDD flexible proportioning parameter currently used by the first base station.
- the first base station sends a TDD flexible proportion reference message to the base station, and the base station may determine, according to the TDD flexible proportion reference message, the TDD flexible proportion parameter currently used by the first base station.
- the base station can listen to the TDD flexible proportioning signaling sent by the first base station to the UE according to the TDD flexible proportioning parameter of the first base station, and then determine the flexible ratio currently used by the base station.
- the base station can also adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station. In this way, mutual interference between the first base station and the base station can be further reduced.
- the TDD flexible proportion reference message received by the base station from the first base station may further include TDD flexible proportioning parameters of other base stations.
- the first base station can comprehensively consider the TDD flexible proportioning parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the TDD flexible proportioning parameter further includes carrier information that supports TDD flexible proportioning characteristics, TDD flexible ratio radio network temporary identifier, TDD flexible ratio signaling transmission time offset, TDD One or more of a mapping relationship of a flexible ratio of an uplink reference ratio, a TDD flexible ratio downlink reference ratio, and a position of a TDD ratio configuration signaling in downlink physical layer signaling.
- FIG. 6 is a schematic block diagram of a base station according to another embodiment of the present invention.
- the base station 60 of FIG. 6 can be used to implement the steps and methods in the foregoing method embodiments.
- base station 60 includes an antenna 601, a transmitter 602, a receiver 603, a processor 604, and a memory.
- Processor 604 controls the operation of base station 60 and can be used to process signals.
- Memory 605 can include read only memory and random access memory and provides instructions and data to processor 604.
- Transmitter 602 and receiver 603 can be coupled to antenna 601.
- the various components of base station 60 are coupled together by a bus system 606, which in addition to the data bus includes a power bus, a control bus, and a status signal bus. However, for clarity of description, various buses are labeled as bus system 606 in the figure.
- the memory 605 can store instructions to perform the following process:
- the time-division duplex TDD flexible matching configuration message is generated, the TDD flexible matching configuration message includes the TDD flexible matching parameter, the TDD flexible matching parameter includes the transmission period of the TDD flexible proportioning signaling, and the TDD flexible matching configuration is sent to the second base station. a message, so that the second base station sets the TDD flexible proportioning parameter according to the TDD flexible ratio configuration message; and obtains, according to the TDD flexible proportioning parameter, the second base station, based on the TDD flexible proportioning parameter, to the user equipment UE in the coverage of the second base station
- the TDD flexible proportioning signaling includes the index of the TDD flexible ratio currently used by the second base station.
- the base station configures a TDD active ratio parameter for the second base station.
- the base station can obtain the flexible proportioning signaling sent by the second base station to the UE based on the TDD flexible matching parameter, and can further know the flexible ratio currently used by the second base station.
- the base station can flexibly adjust the flexible ratio of the first base station or the uplink and downlink scheduling information according to the flexible ratio used by the second base station, so as to avoid mutual interference between the base station and the second base station, thereby improving communication. effectiveness.
- the flexible ratio currently used by each cell covered by the second base station may be referred to as the flexible ratio currently used by the second base station.
- the base station determines the flexible ratio of the current use of the second base station according to the TDD flexible proportioning signaling sent by the second base station that is detected, which is often a flexible ratio of the cell used by the neighboring base station.
- the base station can adjust the base to avoid cross-slot interference.
- the flexible ratio used by the base station or the uplink and downlink scheduling of the base station Especially in the application scenario of cross-site carrier aggregation, the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious. In this way, the base station can not schedule the UE adjacent to the second base station in the clipped subframe, or let the scheduled user increase the transmission power. Alternatively, the base station may change the flexible ratio of one or more cells in the coverage of the base station to avoid cross-slot interference.
- the memory 605 may further store an instruction to: receive a TDD flexible matching request message, a TDD flexible matching request from the second base station before generating the time division duplex TDD flexible matching configuration message
- the message is used to request the base station to configure the desired TDD flexible proportioning parameter for the second base station.
- a TDD flexible proportion configuration message is generated according to the TDD flexible ratio request message.
- the TDD flexible matching configuration message may not include Some or all of the TDD flexible matching parameters are accepted, and only the TDD flexible matching configuration parameters modified by the first base station are included.
- the second base station may send a TDD flexible proportioning request message to the base station in advance, and the TDD flexible proportioning request message may include a TDD flexible proportioning parameter desired by the second base station.
- the second base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the base station can generate a suitable TDD flexible configuration configuration message according to the TDD flexible matching request message.
- the memory 605 may further store an instruction to: send a TDD flexible proportion reference message to the second base station, where the TDD flexible proportion reference message includes a TDD flexible ratio currently used by the first base station parameter.
- the base station sends a TDD flexible proportion reference message to the second base station, and the second base station can determine the TDD flexible proportion parameter currently used by the base station according to the TDD flexible ratio reference message.
- the second base station can detect the TDD flexible proportioning signaling sent by the base station to the UE according to the TDD flexible proportioning parameter of the base station, and then determine the flexible ratio currently used by the second base station.
- the second base station may also adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station. In this way, mutual interference between the base station and the second base station can be further reduced.
- the TDD flexible proportion reference message received by the second base station from the base station may further include TDD flexible proportioning parameters of other base stations.
- the base station can comprehensively consider the TDD flexible ratio parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the memory 605 may further store an instruction to: send, according to the TDD flexible proportion parameter, the second base station to send the user equipment in the coverage of the second base station according to the TDD flexible proportioning parameter.
- the UE's TDD flexible ratio signaling it can be based on
- the TDD flexible proportioning parameter is used to intercept the TDD flexible proportioning signaling sent by the second base station to the UE in the coverage of the second base station based on the TDD flexible proportioning parameter.
- the memory 605 may further store an instruction to: send, according to the TDD flexible proportion parameter, the second base station to send the user equipment in the coverage of the second base station according to the TDD flexible proportioning parameter.
- the TDD flexible proportioning signaling of the UE is used, the TDD flexible matching parameter can be sent to the UE in the coverage of the base station, so that the UE in the coverage of the base station can listen to the flexible ratio of the second base station based on the TDD according to the TDD flexible ratio parameter.
- the parameter is sent to the TDD flexible proportioning signaling of the UE within the coverage of the second base station. Then, TDD flexible proportioning signaling can be received from UEs within the coverage area of the base station.
- the memory 605 may also store instructions to perform the following process:
- the TDD flexible matching parameters also include carrier information supporting TDD flexible matching characteristics, TDD flexible matching wireless network temporary identification, TDD flexible ratio signaling transmission time offset, TDD flexible ratio uplink reference ratio, TDD One or more of the mapping relationship between the downlink reference ratio and the location of the TDD proportioning configuration signaling in the downlink physical layer signaling.
- FIG. 7 is a schematic block diagram of a base station according to another embodiment of the present invention.
- the base station 70 of FIG. 7 can be used to implement the steps and methods in the foregoing method embodiments.
- base station 70 includes an antenna 701, a transmitter 702, a receiver 703, a processor 704, and a memory 705.
- Processor 704 controls the operation of access point 70 and can be used to process signals.
- Memory 705 can include read only memory and random access memory and provides instructions and data to processor 704.
- Transmitter 702 and receiver 703 can be coupled to antenna 701.
- the various components of base station 70 are coupled together by a bus system 706, which in addition to the data bus includes a power bus, a control bus, and a status signal bus. However, for clarity of description, various buses are labeled as bus system 706 in the figure.
- the memory 705 can store instructions to perform the following process:
- the TDD flexible matching configuration message includes a TDD flexible matching parameter, and the TDD flexible matching parameter includes a flexible matching signaling sending period; according to the TDD flexible matching configuration message
- the TDD flexible proportioning parameter is set; the TDD flexible proportioning signaling is sent to the user equipment UE in the coverage of the base station based on the TDD flexible proportioning parameter, and the TDD flexible proportioning signaling includes the index of the TDD flexible ratio currently used by the base station.
- the first base station configures a TDD flexible proportioning parameter for the base station.
- the first base station can acquire the base station to send based on the TDD flexible ratio parameter.
- the flexible proportioning signaling to the UE can be used to know the flexible ratio currently used by the base station.
- the first base station can flexibly adjust the flexible ratio of the first base station or the uplink and downlink scheduling information according to the flexible ratio used by the base station, so as to avoid mutual interference between the first base station and the base station, thereby improving communication. effectiveness.
- the first base station may Adjust the flexible ratio used by the base station or the uplink and downlink scheduling of the base station.
- the carrier frequencies used by different base stations are the same or similar, and the problem of cross-slot interference is particularly obvious.
- the first base station may not adjust the UE with the neighboring cell of the base station in the clipped subframe, or let the scheduled user increase the transmission power.
- the first base station may change the flexible ratio of one or more cells covered by the base station to avoid cross-slot interference.
- the memory 705 may further store an instruction to: send a TDD flexible matching request message to the first base station before receiving the time division duplex TDD flexible matching configuration message from the first base station, and the TDD is flexible.
- the proportion request message is used to request the first base station to configure the desired TDD flexible proportioning parameter for the second base station.
- the base station may send a TDD flexible proportioning request message to the first base station in advance, and the TDD flexible proportioning request message may include a TDD flexible proportioning parameter desired by the base station.
- the base station may determine the expected TDD flexible proportioning parameter according to information such as service characteristics.
- the first base station can generate an appropriate TDD flexible proportion configuration message according to the TDD flexible proportioning request message.
- the memory 705 may further store an instruction to: receive a TDD flexible matching reference message from the first base station, where the TDD flexible matching reference message includes a TDD flexible matching parameter currently used by the first base station .
- the first base station sends a TDD flexible proportion reference message to the base station, and the base station may determine, according to the TDD flexible proportion reference message, the TDD flexible proportion parameter currently used by the first base station.
- the base station can listen to the TDD flexible proportioning signaling sent by the first base station to the UE according to the TDD flexible proportioning parameter of the first base station, and then determine the flexible ratio currently used by the base station.
- the base station may also adjust the flexible ratio used by the base station or the uplink and downlink adjustment of the base station. Degree. In this way, mutual interference between the first base station and the base station can be further reduced.
- the TDD flexible proportion reference message received by the base station from the first base station may further include TDD flexible proportioning parameters of other base stations.
- the first base station can comprehensively consider the TDD flexible proportioning parameters of all base stations to adjust the flexible ratio or uplink and downlink scheduling of the base station.
- the memory 705 may further store instructions for performing the following process:
- the TDD flexible matching parameter further includes carrier information supporting TDD flexible matching characteristics, TDD flexible matching wireless network temporary identification, and TDD flexible matching.
- the mapping relationship between the transmission time offset of the signaling, the uplink reference ratio of the TDD flexible ratio, the downlink reference ratio of the TDD flexible ratio, and the position of the TDD proportioning configuration signaling in the downlink physical layer signaling One or more.
- the size of the sequence numbers of the above processes does not mean the order of execution, and the order of execution of each process should be determined by its function and internal logic, and should not be taken to the embodiments of the present invention.
- the implementation process constitutes any limitation.
- the disclosed systems, devices, and methods may be implemented in other ways.
- the device embodiments described above are merely illustrative.
- the division of the unit is only a logical function division.
- there may be another division manner for example, multiple units or components may be combined or Can be integrated into another system, or some features can be ignored, or not executed.
- the mutual coupling or direct connection or communication connection shown or discussed may be an indirect connection or communication connection through some interface, device or unit, or may be an electrical, mechanical or other form. connection.
- the components displayed for the unit may or may not be physical units, ie may be located in one place, or may be distributed over multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the embodiments of the present invention.
- each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
- the above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
- the integrated unit if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable storage medium.
- the technical solution of the present invention contributes in essence or to the prior art, or all or part of the technical solution may be embodied in the form of a software product stored in a storage medium.
- a number of instructions are included to cause a computer device (which may be a personal computer, server, or network device, etc.) to perform all or part of the steps of the methods described in various embodiments of the present invention.
- the foregoing storage medium includes: a USB flash drive, a removable hard disk, a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disk, and the like. .
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Abstract
本发明公开了一种用于实现跨站点灵活配比的方法和基站。该基站包括:生成单元,用于生成时分双工TDD灵活配比配置消息,TDD灵活配比配置消息包括TDD灵活配比参数,TDD灵活配比参数包括TDD灵活配比信令的发送周期;发送单元,用于向第二基站发送TDD灵活配比配置消息,以便于第二基站根据TDD灵活配比配置消息设置TDD灵活配比参数;获取单元,用于根据TDD灵活配比参数,获取第二基站基于TDD灵活配比参数发送给第二基站覆盖范围内的用户设备UE的TDD灵活配比信令,TDD灵活配比信令包括第二基站当前使用的TDD灵活配比的索引。本发明实施例能够提高通信效率。
Description
用于实现跨站点灵活配比的方法和基站 技术领域
本发明实施例涉及通信领域, 并且更具体地, 涉及一种用于实现跨站点 灵活配比的方法和基站。 背景技术
LTE( Long Term Evolution,长期演进 )系统支持两种帧, FDD( Frequency Division Duplex, 频分双工) 帧和 TDD ( Time Division Duplex, 时分双工) 帧。 在 TDD帧中, 10ms的无线帧分为两个长度为 5ms的半帧, 每个半帧由 5个长为 1ms的子帧构成, 4个普通子帧和 1个特殊子帧。 普通子帧由两个 0.5ms的时隙组成, 而特殊子帧由 3个特殊时隙组成。 这 3个特殊时隙分别 为用于上行信号发送的 UpPTS时隙、 TDD上下行转换的保护间隔 GP时隙 和用于下行信号的发送的 DwPTS时隙。 上下行子帧之间会设置一个上下行 转换保护间隔, 以实现上下行转换。
在 TDD系统中, 时间资源在上下行方向上进行分配。 为了更好地适应 不同业务的变化, 基站可以灵活地配置 TDD上下行配比。 换句话说, TDD 上下行配比可以根据业务量动态改变。 例如, 基站在广播消息中配置 TDD 上下行配比, 其覆盖范围内的 UE ( User Equipment, 用户设备)都通过读取 此消息, 来获得最新的 TDD上下行配比。
目前, 每个基站独立配置本小区的 TDD上下行配比, 不同基站之间使 用的灵活配比往往不同。 这样, 相邻基站之间可能会发生交叉时隙干扰, 进 而影响了通信效率。 发明内容
本发明实施例提供了一种用于实现跨站点灵活配比的方法和基站, 能够 提高通信效率。
第一方面, 本发明实施例提供了一种基站, 包括: 生成单元, 用于生成 时分双工 TDD灵活配比配置消息, TDD灵活配比配置消息包括 TDD灵活 配比参数, TDD灵活配比参数包括 TDD灵活配比信令的发送周期; 发送单 元,用于向第二基站发送 TDD灵活配比配置消息,以便于第二基站根据 TDD
灵活配比配置消息设置 TDD灵活配比参数; 获取单元, 用于根据 TDD灵活 配比参数, 获取第二基站基于 TDD灵活配比参数发送给第二基站覆盖范围 内的用户设备 UE的 TDD灵活配比信令, TDD灵活配比信令包括第二基站 当前使用的 TDD灵活配比的索引。
结合第一方面, 在第一方面的第一种实现方式中, 该基站还包括接收单 元, 接收单元, 用于从第二基站接收 TDD灵活配比请求消息, TDD灵活配 比请求消息用于请求基站为第二基站配置期望的 TDD灵活配比参数; 生成 单元,具体用于根据 TDD灵活配比请求消息,生成 TDD灵活配比配置消息。
结合第一方面及其上述实现方式, 在第一方面的第二种实现方式中, 获 取单元, 具体用于根据 TDD灵活配比参数, 侦听第二基站基于 TDD灵活配 比参数发送给第二基站覆盖范围内的 UE的 TDD灵活配比信令。
结合第一方面及其上述实现方式, 在第一方面的第三种实现方式中, 发 送单元, 还用于向基站覆盖范围内的 UE发送 TDD灵活配比参数, 以便于 基站覆盖范围内的 UE根据 TDD灵活配比参数, 侦听第二基站基于 TDD灵 活配比参数发送给第二基站覆盖范围内的 UE的 TDD灵活配比信令; 获取 单元, 具体用于从基站覆盖范围内的 UE接收 TDD灵活配比信令。
结合第一方面及其上述实现方式, 在第一方面的第四种实现方式中, 发 送单元, 还用于向第二基站发送 TDD灵活配比参考消息, TDD灵活配比参 考消息包括基站当前使用的 TDD灵活配比参数。
结合第一方面及其上述实现方式, 在第一方面的第五种实现方式中,
TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配 比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
第二方面, 本发明实施例提供了一种基站, 包括: 接收单元, 用于从第 一基站接收时分双工 TDD灵活配比配置消息, TDD灵活配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括灵活配比信令的发送周期; 设 置单元, 用于根据 TDD灵活配比配置消息, 设置 TDD灵活配比参数; 发送 单元, 用于基于 TDD灵活配比参数, 向基站覆盖范围内的用户设备 UE发 送 TDD灵活配比信令, TDD灵活配比信令包括基站当前使用的 TDD灵活 配比的索引。
结合第二方面, 在第二方面的第一种实现方式中, 发送单元, 还用于向 第一基站发送 TDD灵活匹配请求消息, TDD灵活配比请求消息用于请求第 一基站为基站配置期望的 TDD灵活配比参数。
结合第二方面及其上述实现方式, 在第二方面的第二种实现方式中, 接 收单元, 还用于从第一基站接收 TDD灵活匹配参考消息, TDD灵活配比参 考消息包括第一基站当前使用的 TDD灵活配比参数。
结合第二方面及其上述实现方式, 在第二方面的第三种实现方式中, TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配 比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
第三方面, 本发明实施例提供了一种用于实现跨站点灵活配比的方法, 包括: 第一基站生成时分双工 TDD灵活配比配置消息, TDD灵活配比配置 消息包括 TDD灵活配比参数, TDD灵活配比参数包括 TDD灵活配比信令 的发送周期; 第一基站向第二基站发送 TDD灵活配比配置消息, 以便于第 二基站根据 TDD灵活配比配置消息设置 TDD灵活配比参数;第一基站根据 TDD灵活配比参数, 获取第二基站基于 TDD灵活配比参数发送给第二基站 覆盖范围内的用户设备 UE的 TDD灵活配比信令, TDD灵活配比信令包括 第二基站当前使用的 TDD灵活配比的索引。
结合第三方面, 在第三方面的第一种实现方式中, 在第一基站生成时分 双工 TDD灵活配比配置消息之前, 该方法还包括: 第一基站从第二基站接 收 TDD灵活配比请求消息, TDD灵活配比请求消息用于请求第一基站为第 二基站配置期望的 TDD灵活配比参数;第一基站生成时分双工 TDD灵活配 比配置消息, 包括: 第一基站根据 TDD灵活配比请求消息, 生成 TDD灵活 配比配置消息。
结合第三方面及其上述实现方式, 在第三方面的第二种实现方式中, 第 一基站根据 TDD灵活配比参数,获取第二基站基于 TDD灵活配比参数发送 给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, 包括: 第一 基站根据 TDD灵活配比参数,侦听第二基站基于 TDD灵活配比参数发送给 第二基站覆盖范围内的 UE的 TDD灵活配比信令。
结合第三方面及其上述实现方式, 在第三方面的第三种实现方式中, 第
一基站根据 TDD灵活配比参数,获取第二基站基于 TDD灵活配比参数发送 给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, 包括: 第一 基站向第一基站覆盖范围内的 UE发送 TDD灵活配比参数, 以便于第一基 站覆盖范围内的 UE根据 TDD灵活配比参数, 侦听第二基站基于 TDD灵活 配比参数发送给第二基站覆盖范围内的 UE的 TDD灵活配比信令; 第一基 站从第一基站覆盖范围内的 UE接收 TDD灵活配比信令。
结合第三方面及其上述实现方式, 在第三方面的第四种实现方式中, 该 方法还包括: 第一基站向第二基站发送 TDD灵活配比参考消息, TDD灵活 配比参考消息包括第一基站当前使用的 TDD灵活配比参数。
结合第三方面及其上述实现方式, 在第三方面的第五种实现方式中,
TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配 比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
第四方面, 本发明实施例提供了一种用于实现跨站点灵活配比的方法, 包括: 第二基站从第一基站接收时分双工 TDD灵活配比配置消息, TDD灵 活配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括灵活配比 信令的发送周期; 第二基站根据 TDD灵活配比配置消息,设置 TDD灵活配 比参数; 第二基站基于 TDD灵活配比参数, 向第二基站覆盖范围内的用户 设备 UE发送 TDD灵活配比信令, TDD灵活配比信令包括第二基站当前使 用的 TDD灵活配比的索引。
结合第四方面, 在第四方面的的第一种实现方式中, 在第二基站从第一 基站接收时分双工 TDD灵活配比配置消息之前, 该方法还包括: 第二基站 向第一基站发送 TDD灵活匹配请求消息, TDD灵活配比请求消息用于请求 第一基站为第二基站配置期望的 TDD灵活配比参数。
结合第四方面及其上述实现方式, 在第四方面的第二种实现方式中, 该 方法还包括: 第二基站从第一基站接收 TDD灵活匹配参考消息, TDD灵活 配比参考消息包括第一基站当前使用的 TDD灵活配比参数。
结合第四方面及其上述实现方式, 在第四方面的第三种实现方式中, TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配
比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
基于上述技术方案,在本发明实施例中,第一基站为第二基站配置 TDD 灵活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取第二基 站发送给 UE的灵活配比信令,进而可以获知第二基站当前使用的灵活配比。 这种情况下, 第一基站可以根据第二基站使用的灵活配比, 灵活地调整第一 基站的灵活配比或上下行调度等信息, 以避免第一基站与第二基站之间相互 干扰, 进而提高了通信效率。 附图说明
为了更清楚地说明本发明实施例的技术方案, 下面将对本发明实施例中 所需要使用的附图作简单地介绍, 显而易见地, 下面描述中的附图仅仅是本 发明的一些实施例, 对于本领域普通技术人员来讲, 在不付出创造性劳动的 前提下, 还可以根据这些附图获得其他的附图。
图 1是本发明一个实施例的用于实现跨站点灵活配比的方法的示意性流 程图。
图 2是本发明另一实施例的用于实现跨站点灵活配比的方法的示意性流 程图。
图 3是本发明另一实施例的用于实现跨站点灵活配比的方法的示意性流 程图。
图 4是本发明一个实施例的基站的示意性框图。
图 5是本发明另一实施例的基站的示意性框图。
图 6是本发明另一实施例的基站的示意性框图。
图 7是本发明另一实施例的基站的示意性框图。 具体实施方式
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行 清楚、 完整地描述, 显然, 所描述的实施例是本发明的一部分实施例, 而不 是全部实施例。 基于本发明中的实施例, 本领域普通技术人员在没有作出创 造性劳动的前提下所获得的所有其他实施例, 都应属于本发明保护的范围。
应理解, 本发明实施例的技术方案可以应用于各种通信系统, 例如: 全
球移动通讯 ( Global System of Mobile communication, 简称为 "GSM" )系统、 码分多址(Code Division Multiple Access, 简称为 "CDMA" ) 系统、 宽带码 分多址( Wideband Code Division Multiple Access, 简称为 "WCDMA" )系统、 通用分组无线业务(General Packet Radio Service, 简称为 "GPRS" )、 长期 演进( Long Term Evolution, 简称为 "LTE" )系统、 LTE频分双工 ( Frequency Division Duplex,简称为 "FDD" )系统、 LTE 时分双工( Time Division Duplex, 简称为 "TDD" )、 通用移动通信系统(Universal Mobile Telecommunication System,简称为 "UMTS" )、全球互联微波接入( Worldwide Interoperability for Microwave Access, 简称为 "WiMAX" )通信系统等。
还应理解,在本发明实施例中,用户设备( User Equipment,简称为 "UE" ) 可称之为终端 ( Terminal ), 移动台 ( Mobile Station, 简称为 "MS" )、 移动 终端 (Mobile Terminal )等, 该用户设备可以经无线接入网 (Radio Access Network, 简称为 "RAN" )与一个或多个核心网进行通信, 例如, 用户设备 可以是移动电话(或称为 "蜂窝" 电话)、 具有移动终端的计算机等, 例如, 用户设备还可以是便携式、 袖珍式、 手持式、 计算机内置的或者车载的移动 装置, 它们与无线接入网交换语音和 /或数据。
在本发明实施例中, 基站可以是 GSM 或 CDMA 中的基站 (Base Transceiver Station, 简称为 "BTS" ), 也可以是 WCDMA中的基站( NodeB, 简称为 "NB " ), 还可以是 LTE中的演进型基站 ( Evolutional Node B , 简称 为 'ΈΝΒ或 e-NodeB" ), 本发明并不限定。 但为描述方便, 下述实施例将以 基站 ENB和用户设备 UE为例进行说明。
图 1是本发明一个实施例的用于实现跨站点灵活配比的方法的示意性流 程图。 图 1所示的方法 10可以由基站执行, 该基站可以为宏基站、 微基站 或者蜂窝网络中的其它类型的基站。
101 , 第一基站生成时分双工 TDD灵活配比配置消息, TDD灵活配比 配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括 TDD灵活配比 信令的发送周期。
例如, 第一基站可以根据第一基站的业务特性和负载等信息, 生成第二 基站的 TDD灵活配比配置消息。
102, 第一基站向第二基站发送 TDD灵活配比配置消息, 以便于第二基 站根据 TDD灵活配比配置消息设置 TDD灵活配比参数。
例如, 第一基站向第二基站发送 TDD灵活配比配置消息。 然后, 第二 基站根据该 TDD灵活配比配置消息中的 TDD灵活配比参数, 向 UE发送该 TDD灵活配比参数, 以完成对该 TDD灵活配比参数的设置。 具体地, 第一 基站可以通过 Xn接口或 X2接口向第二基站发送 TDD灵活配比配置消息。
103 , 第一基站根据 TDD灵活配比参数, 获取第二基站基于 TDD灵活 配比参数发送给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, TDD灵活配比信令包括第二基站当前使用的 TDD灵活配比的索引。
例如,第一基站可以根据 TDD灵活配比参数中的 TDD灵活配比信令的 发送周期, 和预设的 TDD 灵活配比信令的发送时间偏移量等其它相关的 TDD灵活配比参数, 来侦听第二基站发送给 UE的 TDD灵活配比信令。
基于上述技术方案,在本发明实施例中,第一基站为第二基站配置 TDD 灵活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取第二基 站发送给 UE的灵活配比信令,进而可以获知第二基站当前使用的灵活配比。 这种情况下, 第一基站可以根据第二基站使用的灵活配比, 灵活地调整第一 基站的灵活配比或上下行调度等信息, 以避免第一基站与第二基站之间相互 干扰, 进而提高了通信效率。
应理解,第二基站所覆盖的各个小区当前使用的灵活配比都可以称为第 二基站当前使用的灵活配比。 这里, 第一基站根据侦听到的第二基站发送的 TDD 灵活配比信令, 确定的第二基站当前使用的灵活配比, 往往是与第一 基站邻近的小区使用的灵活配比。
例如, 基于本发明实施例的方法, 第一基站获知第二基站当前使用的灵 活配比后, 如果第二基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉时隙干扰, 第一基站可以调整本基站使用的灵活配比或者本基站 的上下行调度。 尤其在跨站点载波聚合的应用场景下, 不同基站使用的载波 频率相同或相近, 交叉时隙干扰的问题尤为明显。
如表一所示, 在 TDD系统中, 支持 7中不同的上下行比例分配, 分别 包括 4种 5ms周期的情况和 3种 10ms周期的情况。 在 5ms周期的配置中, 每 5ms包含一次下行到上行的转换间隔, 在 10ms的周期配置中, 每 10ms 包含一次下行到上行的转换间隔。 假设第一基站使用配比 0, 第二基站使用 配比 5, 这样, 在子帧序号分别为 4、 7、 8和 9的子帧上, 第一基站调度上 行数据发送, 第二基站调度下行数据发送。 换句话说, 第一基站在这些子帧
上调度和接收 UE发送的数据时, 第二基站正好在这些子帧上向 UE发送数 据。
然而, 第二基站的发射功率远大于 UE向第一基站发送数据时使用的发 射功率。 这样, UE发送给第一基站的信号可能会被第一基站发射的信号淹 没, 进而影响了第一基站与 UE之间的正常通信。 也就是说, 在第一基站与 第二基站使用不同的灵活配比时, 可能会造成交叉时隙干扰。
根据本发明实施例, 第一基站可以在这些子帧不调度与第二基站邻近小 区的 UE, 或者让调度的用户提升发射功率。 或者, 第一基站可以改变本基 站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙干扰。
表一
可选地, 作为一个实施例, 在生成时分双工 TDD灵活配比配置消息之 前, 第一基站还可以从第二基站接收 TDD灵活配比请求消息, TDD灵活配 比请求消息用于请求第一基站为第二基站配置期望的 TDD灵活配比参数。 这种情况下, 在第一基站生成时分双工 TDD灵活配比配置消息时, 可以根 据 TDD灵活配比请求消息, 生成 TDD灵活配比配置消息。
可选地, 如果第一基站接受 TDD灵活配比请求消息中包含的部分或者 全部 TDD灵活配比配置参数,在向第二基站发送 TDD灵活配比配置消息时, 该 TDD灵活配比配置消息可以不包括接受的部分或全部 TDD灵活配比参 数, 而只包括第一基站修改的 TDD灵活配比配置参数。
例如, 第二基站可以预先向第一基站发送 TDD灵活配比请求消息, 该
TDD灵活配比请求消息可以包括第二基站期望的 TDD灵活配比参数。 具体 地, 第二基站可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种情况下,第一基站可以根据该 TDD灵活配比请求消息,生成合适的 TDD 灵活配比配置消息。
这样, 可以更好地满足第二基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 第一基站还可以向第二基站发送 TDD灵活 配比参考消息, TDD灵活配比参考消息包括第一基站当前使用的 TDD灵活 配比参数。
例如, 第一基站向第二基站发送 TDD灵活配比参考消息, 第二基站可 以根据该 TDD灵活配比参考消息确定第一基站当前使用的 TDD灵活配比参 数。 这种情况下, 第二基站可以根据第一基站的 TDD灵活配比参数, 侦听 第一基站发送给 UE的 TDD灵活配比信令, 进而确定第二基站当前使用的 灵活配比。
如果第二基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免 交叉时隙干扰, 第二基站也可以调整本基站使用的灵活配比或者本基站的上 下行调度。 这样, 可以进一步降低第一基站与第二基站之间的相互干扰。
另外, 可选地, 第二基站从第一基站接收到的 TDD灵活配比参考消息 中还可以包括其它基站的 TDD灵活配比参数。 这种情况下, 第一基站可以 综合考虑所有基站的 TDD灵活配比参数, 来调整本基站的灵活配比或者上 下行调度。
可选地, 作为另一实施例, 在步骤 103中, 第一基站可以根据 TDD灵 活配比参数, 侦听第二基站基于 TDD灵活配比参数发送给第二基站覆盖范 围内的 UE的 TDD灵活配比信令。
可选地, 作为另一实施例, 在步骤 103中, 第一基站可以向第一基站覆 盖范围内的 UE发送 TDD灵活配比参数, 以便于第一基站覆盖范围内的 UE 根据 TDD灵活配比参数,侦听第二基站基于 TDD灵活配比参数发送给第二 基站覆盖范围内的 UE的 TDD灵活配比信令。 然后, 第一基站从第一基站 覆盖范围内的 UE接收 TDD灵活配比信令。
可选地, 作为另一实施例, TDD灵活配比参数还包括支持 TDD灵活配 比特性的载波信息、 TDD灵活配比无线网络临时标识、 TDD灵活配比信令 的发送时间偏移量、 TDD灵活配比的上行参考配比、 TDD灵活配比的下行 参考配比和 TDD配比配置信令在下行物理层信令中的位置的映射关系中的 一种或多种。
图 2是本发明另一实施例的用于实现跨站点灵活配比的方法的示意性流 程图。 图 2所示的方法 20可以由基站执行, 该基站可以为宏基站、 微基站 或者蜂窝网络中的其它类型的基站。
201, 第二基站从第一基站接收时分双工 TDD灵活配比配置消息, TDD 灵活配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括灵活配 比信令的发送周期。
例如, 第二基站可以通过 Xn接口或 X2接口从第一基站接收 TDD灵活 配比配置消息。
202, 第二基站根据 TDD灵活配比配置消息, 设置 TDD灵活配比参数。 例如, 第二基站根据该 TDD灵活配比配置消息, 向 UE发送该 TDD灵 活配比参数, 以完成该 TDD灵活配比参数的设置。 如果成功设置了该 TDD 灵活配比参数, 第二基站可以向第一基站发送设置成功的响应消息。 如果, 没有成功设置该 TDD灵活配比参数, 第二基站可以向第一基站发送设置失 败的响应消息。
203 , 第二基站基于 TDD灵活配比参数, 向第二基站覆盖范围内的用户 设备 UE发送 TDD灵活配比信令, TDD灵活配比信令包括第二基站当前使 用的 TDD灵活配比的索引。
例如, 在根据步骤 202设置了 TDD灵活配比参数之后, 第二基站可以 基于该新设置的 TDD灵活配比参数向 UE发送 TDD灵活配比信令, 以实时 满足业务特性的对灵活配比的需求。
基于上述技术方案,在本发明实施例中,第一基站为第二基站配置 TDD 灵活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取第二基 站发送给 UE的灵活配比信令,进而可以获知第二基站当前使用的灵活配比。 这种情况下, 第一基站可以根据第二基站使用的灵活配比, 灵活地调整第一 基站的灵活配比或上下行调度等信息, 以避免第一基站与第二基站之间相互 干扰, 进而提高了通信效率。
例如, 基于本发明实施例的方法, 第一基站获知第二基站当前使用的灵 活配比后, 如果第二基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉时隙干扰, 第一基站可以调整本基站使用的灵活配比或者本基站 的上下行调度。 尤其在跨站点载波聚合的应用场景下, 不同基站使用的载波 频率相同或相近, 交叉时隙干扰的问题尤为明显。 这样, 第一基站可以在夹 叉的子帧不调度与第二基站邻近小区的 UE, 或者让调度的用户提升发射功 率。或者,第一基站可以改变本基站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙干扰。
可选地, 作为一个实施例, 在从第一基站接收时分双工 TDD灵活配比 配置消息之前, 第二基站还可以向第一基站发送 TDD灵活匹配请求消息, TDD灵活配比请求消息用于请求第一基站为第二基站配置期望的 TDD灵活 配比参数。
例如, 第二基站可以预先向第一基站发送 TDD灵活配比请求消息, 该
TDD灵活配比请求消息可以包括第二基站期望的 TDD灵活配比参数。 具体 地, 第二基站可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种情况下,第一基站可以根据该 TDD灵活配比请求消息,生成合适的 TDD 灵活配比配置消息。
这样, 可以更好地满足第二基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 第二基站还可以从第一基站接收 TDD灵活 匹配参考消息, TDD灵活配比参考消息包括第一基站当前使用的 TDD灵活 配比参数。
例如, 第一基站向第二基站发送 TDD灵活配比参考消息, 第二基站可 以根据该 TDD灵活配比参考消息确定第一基站当前使用的 TDD灵活配比参 数。 这种情况下, 第二基站可以根据第一基站的 TDD灵活配比参数, 侦听 第一基站发送给 UE的 TDD灵活配比信令, 进而确定第二基站当前使用的 灵活配比。
如果第二基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免 交叉时隙干扰, 第二基站也可以调整本基站使用的灵活配比或者本基站的上 下行调度。 这样, 可以进一步降低第一基站与第二基站之间的相互干扰。
另外, 可选地, 第二基站从第一基站接收到的 TDD灵活配比参考消息 中还可以包括其它基站的 TDD灵活配比参数。 这种情况下, 第一基站可以 综合考虑所有基站的 TDD灵活配比参数, 来调整本基站的灵活配比或者上 下行调度。
可选地, 作为另一实施例, TDD灵活配比参数还包括支持 TDD灵活配 比特性的载波信息、 TDD灵活配比无线网络临时标识、 TDD灵活配比信令 的发送时间偏移量、 TDD灵活配比的上行参考配比、 TDD灵活配比的下行 参考配比和 TDD配比配置信令在下行物理层信令中的位置的映射关系中的 一种或多种。
下面将结合具体的例子详细描述本发明实施例。 应注意, 这些例子只是
为了帮助本领域技术人员更好地理解本发明实施例, 而非限制本发明实施例 的范围。
图 3是本发明另一实施例的用于实现跨站点灵活配比的方法的示意性流 程图。如图 3所示, 以第一基站为宏基站、第二基站为微基站为例进行说明。
301, 微基站向宏基站发送 TDD灵活配比请求消息。
例如,微基站可以根据业务特性等信息确定期望的 TDD灵活配比参数。 然后,通过 TDD灵活配比请求消息将该期望的 TDD灵活配比参数发送给宏 基站, 以便于宏基站为其配置合适的 TDD灵活配比参数。
302, 宏基站生成 TDD灵活配比配置消息。
例如, 宏基站根据在步骤 701中接收到的 TDD灵活配比请求消息, 生 成 TDD灵活配比配置消息。 TDD灵活配比配置消息包括 TDD灵活配比参 数, TDD灵活配比参数包括 TDD灵活配比信令的发送周期。
303, 宏基站向微基站发送 TDD灵活配比配置消息。
例如,宏基站向微基站发送 TDD灵活配比配置消息, 该 TDD灵活配比 配置消息可以包括 TDD灵活配比参数。 具体地, 宏基站可以通过 Xn接口或 χ2接口向微基站发送 TDD灵活配比配置消息。
304, 微基站设置 TDD灵活配比参数。
例如, 微基站根据在步骤 303中接收到的 TDD灵活配比配置消息, 向 UE发送该 TDD灵活配比参数, 以完成该 TDD灵活配比参数的设置。
305, 微基站向 UE发送 TDD灵活配比信令。
例如, 在步骤 304中, 完了对 TDD灵活配比参数的设置。 微基站基于 该 TDD灵活配比参数, 向用户设备 UE发送 TDD灵活配比信令。 TDD灵活 配比信令包括第二基站当前使用的 TDD灵活配比的索引。
306, 宏基站侦听 TDD灵活配比信令。
例如,宏基站可以基于 TDD灵活配比参数中的 TDD灵活配比信令的发 送周期, 和预设的 TDD灵活配比信令的发送时间偏移量等其它相关的 TDD 灵活配比参数, 侦听步骤 305中微基站发送给 UE的 TDD灵活配比信令。 这样, 宏基站可以获知微基站当前使用的 TDD灵活配比信令。
基于上述技术方案,在本发明实施例中,第一基站为第二基站配置 TDD 灵活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取第二基 站发送给 UE的灵活配比信令,进而可以获知第二基站当前使用的灵活配比。
这种情况下, 第一基站可以根据第二基站使用的灵活配比, 灵活地调整第一 基站的灵活配比或上下行调度等信息, 以避免第一基站与第二基站之间相互 干扰, 进而提高了通信效率。
可选地, 作为一个实施例, 第一基站可以配置其覆盖范围内的 UE向第 二基站上报第一基站当前使用的 TDD灵活配比的索引。 其中, 第一基站和 第二基站为相邻的基站。
例如, 第一基站向 UE发送第一配置消息, 配置该 UE向第二基站上报 第一基站当前使用的 TDD灵活配比的索引。其中,第一基站当前使用的 TDD 灵活配比可以是第一基站控制的一个或多个小区当前使用的灵活配比。具体 地, 第一基站可以通过 L1层信令、 L2层信令或者 L3层信令对 UE进行配 置。 如 L3层信令中专用 RRC ( Radio Resource Control, 无线资源控制协议) 消息或者系统广播消息。 UE根据第一配置消息向第二基站上报第一基站当 前使用的灵活配比的索引。
这样, 第二基站在获知第一基站当前使用的灵活配比后, 可以调整本基 站的灵活配比或者上下行调度,以避免交叉时隙干扰,进而提高了通信效率。
图 4是本发明一个实施例的基站的示意性框图。 图 4中示出的基站 40 包括生成单元 401、 发送单元 402和获取单元 403。
生成单元 401, 用于生成时分双工 TDD灵活配比配置消息, TDD灵活 配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括 TDD灵活 配比信令的发送周期。
例如, 生成单元 401可以根据第一基站的业务特性和负载等信息, 生成 第二基站的 TDD灵活配比配置消息。
发送单元 402, 用于向第二基站发送 TDD灵活配比配置消息, 以便于 第二基站根据 TDD灵活配比配置消息设置 TDD灵活配比参数;
例如, 发送单元 402向第二基站发送 TDD灵活配比配置消息。 然后, 第二基站根据该 TDD灵活配比配置消息中的 TDD灵活配比参数, 向 UE发 送该 TDD灵活配比参数, 以完成对该 TDD灵活配比参数的设置。 具体地, 发送单元 402可以通过 Xn接口或 X2接口向第二基站发送 TDD灵活配比配 置消息。
获取单元 403, 用于根据 TDD灵活配比参数, 获取第二基站基于 TDD 灵活配比参数发送给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比
信令, TDD灵活配比信令包括第二基站当前使用的 TDD灵活配比的索引。 例如,可以根据 TDD灵活配比参数中的 TDD灵活配比信令的发送周期, 和预设的 TDD灵活配比信令的发送时间偏移量等其它相关的 TDD灵活配比 参数, 来侦听第二基站发送给 UE的 TDD灵活配比信令。
基于上述技术方案, 在本发明实施例中, 基站为第二基站配置 TDD灵 活配比参数。 这样, 基站可以基于该 TDD灵活配比参数获取第二基站发送 给 UE的灵活配比信令, 进而可以获知第二基站当前使用的灵活配比。 这种 情况下, 基站可以根据第二基站使用的灵活配比, 灵活地调整第一基站的灵 活配比或上下行调度等信息, 以避免基站与第二基站之间相互干扰, 进而提 高了通信效率。
应理解, 第二基站所覆盖的各个小区当前使用的灵活配比都可以称为第 二基站当前使用的灵活配比。这里,基站根据侦听到的第二基站发送的 TDD 灵活配比信令, 确定的第二基站当前使用的灵活配比, 往往是与基站邻近的 小区使用的灵活配比。
例如, 基于本发明实施例, 基站获知第二基站当前使用的灵活配比后, 如果第二基站使用的灵活配比与基站使用的灵活配比不同, 为避免交叉时隙 干扰, 基站可以调整本基站使用的灵活配比或者本基站的上下行调度。 尤其 在跨站点载波聚合的应用场景下, 不同基站使用的载波频率相同或相近, 交 叉时隙干扰的问题尤为明显。 这样, 基站可以在夹叉的子帧不调度与第二基 站邻近小区的 UE, 或者让调度的用户提升发射功率。 或者, 基站可以改变 本基站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙干扰。
可选地, 作为一个实施例, 基站还包括接收单元 404, 接收单元 404, 用于从第二基站接收 TDD灵活配比请求消息, TDD灵活配比请求消息用于 请求基站为第二基站配置期望的 TDD灵活配比参数。 这种情况下, 生成单 元 401, 具体用于才艮据 TDD灵活配比请求消息, 生成 TDD灵活配比配置消 息。
可选地, 如果基站接受 TDD灵活配比请求消息中包含的部分或者全部 TDD灵活配比配置参数, 在向第二基站发送 TDD灵活配比配置消息时, 该 TDD灵活配比配置消息可以不包括接受的部分或全部 TDD灵活配比参数, 而只包括第一基站修改的 TDD灵活配比配置参数。
例如, 第二基站可以预先向基站发送 TDD灵活配比请求消息, 该 TDD
灵活配比请求消息可以包括第二基站期望的 TDD灵活配比参数。 具体地, 第二基站可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种 情况下,基站可以根据该 TDD灵活配比请求消息, 生成合适的 TDD灵活配 比配置消息。
这样, 可以更好地满足第二基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 发送单元 402, 还用于向第二基站发送 TDD 灵活配比参考消息, TDD灵活配比参考消息包括基站当前使用的 TDD灵活 配比参数。
例如, 基站向第二基站发送 TDD灵活配比参考消息, 第二基站可以根 据该 TDD灵活配比参考消息确定基站当前使用的 TDD灵活配比参数。这种 情况下, 第二基站可以根据基站的 TDD灵活配比参数, 侦听基站发送给 UE 的 TDD灵活配比信令, 进而确定第二基站当前使用的灵活配比。
如果第二基站使用的灵活配比与基站使用的灵活配比不同, 为避免交叉 时隙干扰, 第二基站也可以调整本基站使用的灵活配比或者本基站的上下行 调度。 这样, 可以进一步降低基站与第二基站之间的相互干扰。
另外, 可选地, 第二基站从基站接收到的 TDD灵活配比参考消息中还 可以包括其它基站的 TDD灵活配比参数。 这种情况下, 基站可以综合考虑 所有基站的 TDD灵活配比参数,来调整本基站的灵活配比或者上下行调度。
可选地, 作为另一实施例, 获取单元 403, 具体用于根据 TDD灵活配 比参数, 侦听第二基站基于 TDD灵活配比参数发送给第二基站覆盖范围内 的 UE的 TDD灵活配比信令。
可选地, 作为另一实施例, 发送单元 402, 还用于向基站覆盖范围内的 UE发送 TDD灵活配比参数, 以便于基站覆盖范围内的 UE根据 TDD灵活 配比参数, 侦听第二基站基于 TDD灵活配比参数发送给第二基站覆盖范围 内的 UE的 TDD灵活配比信令。 这种情况下, 获取单元 403, 具体用于从基 站覆盖范围内的 UE接收 TDD灵活配比信令。
可选地, 作为另一实施例, TDD灵活配比参数还包括支持 TDD灵活配 比特性的载波信息、 TDD灵活配比无线网络临时标识、 TDD灵活配比信令 的发送时间偏移量、 TDD灵活配比的上行参考配比、 TDD灵活配比的下行 参考配比和 TDD配比配置信令在下行物理层信令中的位置的映射关系中的 一种或多种。
图 5是本发明另一实施例的基站的示意性框图。 图 5中的基站 50包括 接收单元 501、 设置单元 502和发送单元 503。
接收单元 501, 用于从第一基站接收时分双工 TDD灵活配比配置消息, TDD灵活配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括灵 活配比信令的发送周期。
设置单元 502, 用于根据 TDD灵活配比配置消息, 设置 TDD灵活配比 参数。
例如, 设置单元 502可以根据该 TDD灵活配比配置消息, 向 UE发送 该 TDD灵活配比参数, 以完成该 TDD灵活配比参数的设置。
发送单元 503, 用于基于 TDD灵活配比参数, 向基站覆盖范围内的用 户设备 UE发送 TDD灵活配比信令, TDD灵活配比信令包括基站当前使用 的 TDD灵活配比的索引。
例如, 在设置了 TDD灵活配比参数之后, 发送单元 503可以基于该新 设置的 TDD灵活配比参数向 UE发送 TDD灵活配比信令, 以实时满足业务 特性的对灵活配比的需求。 如果成功设置了该 TDD灵活配比参数, 基站可 以向第一基站发送设置成功的响应消息。 如果, 没有成功设置该 TDD灵活 配比参数, 基站可以向第一基站发送设置失败的响应消息。
基于上述技术方案, 在本发明实施例中, 第一基站为基站配置 TDD灵 活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取基站发送 给 UE的灵活配比信令, 进而可以获知基站当前使用的灵活配比。 这种情况 下, 第一基站可以根据基站使用的灵活配比, 灵活地调整第一基站的灵活配 比或上下行调度等信息, 以避免第一基站与基站之间相互干扰, 进而提高了 通信效率。
例如, 基于本发明实施例, 第一基站获知基站当前使用的灵活配比后, 如果基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉时隙 干扰, 第一基站可以调整本基站使用的灵活配比或者本基站的上下行调度。 尤其在跨站点载波聚合的应用场景下, 不同基站使用的载波频率相同或相 近, 交叉时隙干扰的问题尤为明显。 这样, 第一基站可以在夹叉的子帧不调 度与基站邻近小区的 UE, 或者让调度的用户提升发射功率。 或者, 第一基 站可以改变本基站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙 干扰。
可选地, 作为一个实施例, 发送单元 503, 还用于向第一基站发送 TDD 灵活匹配请求消息, TDD 灵活配比请求消息用于请求第一基站为基站配置 期望的 TDD灵活配比参数。
例如, 基站可以预先向第一基站发送 TDD灵活配比请求消息, 该 TDD 灵活配比请求消息可以包括基站期望的 TDD灵活配比参数。 具体地, 基站 可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种情况下, 第一基站可以根据该 TDD灵活配比请求消息,生成合适的 TDD灵活配比配 置消息。
这样, 可以更好地满足基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 接收单元 501, 还用于从第一基站接收 TDD 灵活匹配参考消息, TDD灵活配比参考消息包括第一基站当前使用的 TDD 灵活配比参数。
例如, 第一基站向基站发送 TDD灵活配比参考消息, 基站可以根据该 TDD灵活配比参考消息确定第一基站当前使用的 TDD灵活配比参数。 这种 情况下, 基站可以根据第一基站的 TDD灵活配比参数, 侦听第一基站发送 给 UE的 TDD灵活配比信令, 进而确定基站当前使用的灵活配比。
如果基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉 时隙干扰, 基站也可以调整本基站使用的灵活配比或者本基站的上下行调 度。 这样, 可以进一步降低第一基站与基站之间的相互干扰。
另外, 可选地, 基站从第一基站接收到的 TDD灵活配比参考消息中还 可以包括其它基站的 TDD灵活配比参数。 这种情况下, 第一基站可以综合 考虑所有基站的 TDD灵活配比参数, 来调整本基站的灵活配比或者上下行 调度。
可选地, 作为另一实施例, TDD灵活配比参数还包括支持 TDD灵活配 比特性的载波信息、 TDD灵活配比无线网络临时标识、 TDD灵活配比信令 的发送时间偏移量、 TDD灵活配比的上行参考配比、 TDD灵活配比的下行 参考配比和 TDD配比配置信令在下行物理层信令中的位置的映射关系中的 一种或多种。
图 6是本发明另一实施例的基站的示意性框图。
图 6的基站 60可用于实现上述方法实施例中各步骤及方法。 图 6的实 施例中, 基站 60包括天线 601、 发射机 602、 接收机 603、 处理器 604和存
储器 605。 处理器 604控制基站 60的操作, 并可用于处理信号。 存储器 605 可以包括只读存储器和随机存取存储器, 并向处理器 604提供指令和数据。 发射机 602和接收机 603可以耦合到天线 601。基站 60的各个组件通过总线 系统 606耦合在一起, 其中总线系统 606除包括数据总线之外, 还包括电源 总线、 控制总线和状态信号总线。 但是为了清楚说明起见, 在图中将各种总 线都标为总线系统 606。
具体地, 存储器 605可存储执行以下过程的指令:
生成时分双工 TDD 灵活配比配置消息, TDD 灵活配比配置消息包括 TDD灵活配比参数, TDD灵活配比参数包括 TDD灵活配比信令的发送周期; 向第二基站发送 TDD灵活配比配置消息,以便于第二基站根据 TDD灵活配 比配置消息设置 TDD灵活配比参数; 根据 TDD灵活配比参数, 获取第二基 站基于 TDD 灵活配比参数发送给第二基站覆盖范围内的用户设备 UE 的 TDD灵活配比信令, TDD灵活配比信令包括第二基站当前使用的 TDD灵活 配比的索引。
基于上述技术方案, 在本发明实施例中, 基站为第二基站配置 TDD灵 活配比参数。 这样, 基站可以基于该 TDD灵活配比参数获取第二基站发送 给 UE的灵活配比信令, 进而可以获知第二基站当前使用的灵活配比。 这种 情况下, 基站可以根据第二基站使用的灵活配比, 灵活地调整第一基站的灵 活配比或上下行调度等信息, 以避免基站与第二基站之间相互干扰, 进而提 高了通信效率。
应理解, 第二基站所覆盖的各个小区当前使用的灵活配比都可以称为第 二基站当前使用的灵活配比。这里,基站根据侦听到的第二基站发送的 TDD 灵活配比信令, 确定的第二基站当前使用的灵活配比, 往往是与基站邻近的 小区使用的灵活配比。
例如, 基于本发明实施例, 基站获知第二基站当前使用的灵活配比后, 如果第二基站使用的灵活配比与基站使用的灵活配比不同, 为避免交叉时隙 干扰, 基站可以调整本基站使用的灵活配比或者本基站的上下行调度。 尤其 在跨站点载波聚合的应用场景下, 不同基站使用的载波频率相同或相近, 交 叉时隙干扰的问题尤为明显。 这样, 基站可以在夹叉的子帧不调度与第二基 站邻近小区的 UE, 或者让调度的用户提升发射功率。 或者, 基站可以改变 本基站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙干扰。
可选地, 作为一个实施例, 存储器 605还可存储执行以下过程的指令: 在生成时分双工 TDD灵活配比配置消息之前,从第二基站接收 TDD灵 活配比请求消息, TDD 灵活配比请求消息用于请求基站为第二基站配置期 望的 TDD灵活配比参数。 这种情况下, 根据 TDD灵活配比请求消息, 生成 TDD灵活配比配置消息。
可选地, 如果基站接受 TDD灵活配比请求消息中包含的部分或者全部 TDD灵活配比配置参数, 在向第二基站发送 TDD灵活配比配置消息时, 该 TDD灵活配比配置消息可以不包括接受的部分或全部 TDD灵活配比参数, 而只包括第一基站修改的 TDD灵活配比配置参数。
例如, 第二基站可以预先向基站发送 TDD灵活配比请求消息, 该 TDD 灵活配比请求消息可以包括第二基站期望的 TDD灵活配比参数。 具体地, 第二基站可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种 情况下,基站可以根据该 TDD灵活配比请求消息, 生成合适的 TDD灵活配 比配置消息。
这样, 可以更好地满足第二基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 存储器 605还可存储执行以下过程的指令: 向第二基站发送 TDD灵活配比参考消息, TDD灵活配比参考消息包括 第一基站当前使用的 TDD灵活配比参数。
例如, 基站向第二基站发送 TDD灵活配比参考消息, 第二基站可以根 据该 TDD灵活配比参考消息确定基站当前使用的 TDD灵活配比参数。这种 情况下, 第二基站可以根据基站的 TDD灵活配比参数, 侦听基站发送给 UE 的 TDD灵活配比信令, 进而确定第二基站当前使用的灵活配比。
如果第二基站使用的灵活配比与基站使用的灵活配比不同, 为避免交叉 时隙干扰, 第二基站也可以调整本基站使用的灵活配比或者本基站的上下行 调度。 这样, 可以进一步降低基站与第二基站之间的相互干扰。
另外, 可选地, 第二基站从基站接收到的 TDD灵活配比参考消息中还 可以包括其它基站的 TDD灵活配比参数。 这种情况下, 基站可以综合考虑 所有基站的 TDD灵活配比参数,来调整本基站的灵活配比或者上下行调度。
可选地, 作为另一实施例, 存储器 605还可存储执行以下过程的指令: 在根据 TDD灵活配比参数,获取第二基站基于 TDD灵活配比参数发送 给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令时, 可以根据
TDD灵活配比参数, 侦听第二基站基于 TDD灵活配比参数发送给第二基站 覆盖范围内的 UE的 TDD灵活配比信令。
可选地, 作为另一实施例, 存储器 605还可存储执行以下过程的指令: 在根据 TDD灵活配比参数,获取第二基站基于 TDD灵活配比参数发送 给第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令时, 可以向基 站覆盖范围内的 UE发送 TDD灵活配比参数, 以便于基站覆盖范围内的 UE 根据 TDD灵活配比参数,侦听第二基站基于 TDD灵活配比参数发送给第二 基站覆盖范围内的 UE的 TDD灵活配比信令。 然后, 可以从该基站覆盖范 围内的 UE接收 TDD灵活配比信令。
可选地, 作为另一实施例, 存储器 605还可存储执行以下过程的指令:
TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵 活配比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵 活配比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信 令在下行物理层信令中的位置的映射关系中的一种或多种。
图 7是本发明另一实施例的基站的示意性框图。
图 7的基站 70可用于实现上述方法实施例中各步骤及方法。 图 7的实 施例中, 基站 70包括天线 701、 发射机 702、 接收机 703、 处理器 704和存 储器 705。 处理器 704控制接入点 70的操作, 并可用于处理信号。 存储器 705可以包括只读存储器和随机存取存储器, 并向处理器 704提供指令和数 据。发射机 702和接收机 703可以耦合到天线 701。基站 70的各个组件通过 总线系统 706耦合在一起, 其中总线系统 706除包括数据总线之外, 还包括 电源总线、 控制总线和状态信号总线。 但是为了清楚说明起见, 在图中将各 种总线都标为总线系统 706。
具体地, 存储器 705可存储执行以下过程的指令:
从第一基站接收时分双工 TDD灵活配比配置消息, TDD灵活配比配置 消息包括 TDD灵活配比参数, TDD灵活配比参数包括灵活配比信令的发送 周期; 根据 TDD灵活配比配置消息, 设置 TDD灵活配比参数; 基于 TDD 灵活配比参数, 向基站覆盖范围内的用户设备 UE发送 TDD灵活配比信令, TDD灵活配比信令包括基站当前使用的 TDD灵活配比的索引。
基于上述技术方案, 在本发明实施例中, 第一基站为基站配置 TDD灵 活配比参数。 这样, 第一基站可以基于该 TDD灵活配比参数获取基站发送
给 UE的灵活配比信令, 进而可以获知基站当前使用的灵活配比。 这种情况 下, 第一基站可以根据基站使用的灵活配比, 灵活地调整第一基站的灵活配 比或上下行调度等信息, 以避免第一基站与基站之间相互干扰, 进而提高了 通信效率。
例如, 基于本发明实施例, 第一基站获知基站当前使用的灵活配比后, 如果基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉时隙 干扰, 第一基站可以调整本基站使用的灵活配比或者本基站的上下行调度。 尤其在跨站点载波聚合的应用场景下, 不同基站使用的载波频率相同或相 近, 交叉时隙干扰的问题尤为明显。 这样, 第一基站可以在夹叉的子帧不调 度与基站邻近小区的 UE, 或者让调度的用户提升发射功率。 或者, 第一基 站可以改变本基站覆盖范围的一个或多个小区的灵活配比, 以避免交叉时隙 干扰。
可选地, 作为一个实施例, 存储器 705还可存储执行以下过程的指令: 在从第一基站接收时分双工 TDD灵活配比配置消息之前, 向第一基站 发送 TDD灵活匹配请求消息, TDD灵活配比请求消息用于请求第一基站为 第二基站配置期望的 TDD灵活配比参数。
例如, 基站可以预先向第一基站发送 TDD灵活配比请求消息, 该 TDD 灵活配比请求消息可以包括基站期望的 TDD灵活配比参数。 具体地, 基站 可以根据业务特性等信息确定该期望的 TDD灵活配比参数。 这种情况下, 第一基站可以才艮据该 TDD灵活配比请求消息,生成合适的 TDD灵活配比配 置消息。
这样, 可以更好地满足基站的业务需求, 提升了用户体验。
可选地, 作为另一实施例, 存储器 705还可存储执行以下过程的指令: 从第一基站接收 TDD灵活匹配参考消息, TDD灵活配比参考消息包括 第一基站当前使用的 TDD灵活配比参数。
例如, 第一基站向基站发送 TDD灵活配比参考消息, 基站可以根据该 TDD灵活配比参考消息确定第一基站当前使用的 TDD灵活配比参数。 这种 情况下, 基站可以根据第一基站的 TDD灵活配比参数, 侦听第一基站发送 给 UE的 TDD灵活配比信令, 进而确定基站当前使用的灵活配比。
如果基站使用的灵活配比与第一基站使用的灵活配比不同, 为避免交叉 时隙干扰, 基站也可以调整本基站使用的灵活配比或者本基站的上下行调
度。 这样, 可以进一步降低第一基站与基站之间的相互干扰。
另外, 可选地, 基站从第一基站接收到的 TDD灵活配比参考消息中还 可以包括其它基站的 TDD灵活配比参数。 这种情况下, 第一基站可以综合 考虑所有基站的 TDD灵活配比参数, 来调整本基站的灵活配比或者上下行 调度。
可选地, 作为另一实施例, 存储器 705还可存储执行以下过程的指令: TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵 活配比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵 活配比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信 令在下行物理层信令中的位置的映射关系中的一种或多种。
应理解, 在本发明的各种实施例中, 上述各过程的序号的大小并不意味 着执行顺序的先后, 各过程的执行顺序应以其功能和内在逻辑确定, 而不应 对本发明实施例的实施过程构成任何限定。
本领域普通技术人员可以意识到, 结合本文中所公开的实施例描述的各 示例的单元及算法步骤, 能够以电子硬件、 计算机软件或者二者的结合来实 现, 为了清楚地说明硬件和软件的可互换性, 在上述说明中已经按照功能一 般性地描述了各示例的组成及步骤。这些功能究竟以硬件还是软件方式来执 行, 取决于技术方案的特定应用和设计约束条件。 专业技术人员可以对每个 特定的应用来使用不同方法来实现所描述的功能,但是这种实现不应认为超 出本发明的范围。
所属领域的技术人员可以清楚地了解到, 为了描述的方便和简洁, 上述 描述的系统、 装置和单元的具体工作过程, 可以参考前述方法实施例中的对 应过程, 在此不再赘述。
在本申请所提供的几个实施例中, 应该理解到, 所揭露的系统、 装置和 方法, 可以通过其它的方式实现。 例如, 以上所描述的装置实施例仅仅是示 意性的, 例如, 所述单元的划分, 仅仅为一种逻辑功能划分, 实际实现时可 以有另外的划分方式, 例如多个单元或组件可以结合或者可以集成到另一个 系统, 或一些特征可以忽略, 或不执行。 另夕卜, 所显示或讨论的相互之间的 耦合或直接辆合或通信连接可以是通过一些接口、装置或单元的间接辆合或 通信连接, 也可以是电的, 机械的或其它的形式连接。
为单元显示的部件可以是或者也可以不是物理单元, 即可以位于一个地方, 或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或 者全部单元来实现本发明实施例方案的目的。
另外, 在本发明各个实施例中的各功能单元可以集成在一个处理单元 中, 也可以是各个单元单独物理存在, 也可以是两个或两个以上单元集成在 一个单元中。 上述集成的单元既可以釆用硬件的形式实现, 也可以釆用软件 功能单元的形式实现。
所述集成的单元如果以软件功能单元的形式实现并作为独立的产品销 售或使用时, 可以存储在一个计算机可读取存储介质中。 基于这样的理解, 本发明的技术方案本质上或者说对现有技术做出贡献的部分,或者该技术方 案的全部或部分可以以软件产品的形式体现出来, 该计算机软件产品存储在 一个存储介质中, 包括若干指令用以使得一台计算机设备(可以是个人计算 机, 服务器, 或者网络设备等)执行本发明各个实施例所述方法的全部或部 分步骤。 而前述的存储介质包括: U盘、 移动硬盘、 只读存储器 (ROM, Read-Only Memory ). 随机存取存储器 ( RAM, Random Access Memory )、 磁碟或者光盘等各种可以存储程序代码的介质。
以上所述, 仅为本发明的具体实施方式, 但本发明的保护范围并不局限 于此, 任何熟悉本技术领域的技术人员在本发明揭露的技术范围内, 可轻易 想到各种等效的修改或替换, 这些修改或替换都应涵盖在本发明的保护范围 之内。 因此, 本发明的保护范围应以权利要求的保护范围为准。
Claims
1、 一种基站, 其特征在于, 包括:
生成单元, 用于生成时分双工 TDD灵活配比配置消息, 所述 TDD灵活 配比配置消息包括 TDD灵活配比参数, 所述 TDD灵活配比参数包括 TDD 灵活配比信令的发送周期;
发送单元, 用于向第二基站发送所述 TDD灵活配比配置消息, 以便于 所述第二基站根据所述 TDD灵活配比配置消息设置所述 TDD灵活配比参 数;
获取单元, 用于根据所述 TDD灵活配比参数, 获取所述第二基站基于 所述 TDD灵活配比参数发送给所述第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, 所述 TDD灵活配比信令包括所述第二基站当前使用的 TDD灵活配比的索引。
2、 根据权利要求 1 所述的基站, 其特征在于, 所述基站还包括接收单 元,
所述接收单元, 用于从所述第二基站接收 TDD灵活配比请求消息, 所 述 TDD 灵活配比请求消息用于请求所述基站为所述第二基站配置期望的 TDD灵活配比参数;
所述生成单元, 具体用于根据所述 TDD灵活配比请求消息, 生成所述 TDD灵活配比配置消息。
3、 根据权利要求 1或 2所述的基站, 其特征在于, 所述获取单元, 具 体用于根据所述 TDD灵活配比参数,侦听所述第二基站基于所述 TDD灵活 配比参数发送给所述第二基站覆盖范围内的 UE的 TDD灵活配比信令。
4、 根据权利要求 1或 2所述的基站, 其特征在于, 所述发送单元, 还 用于向所述基站覆盖范围内的 UE发送所述 TDD灵活配比参数, 以便于所 述基站覆盖范围内的 UE根据所述 TDD灵活配比参数, 侦听所述第二基站 基于所述 TDD灵活配比参数发送给所述第二基站覆盖范围内的 UE的 TDD 灵活配比信令; 所述获取单元, 具体用于从所述基站覆盖范围内的 UE接收 所述 TDD灵活配比信令。
5、 根据权利要求 1至 4中任一项所述的基站, 其特征在于, 所述发送 单元, 还用于向所述第二基站发送 TDD灵活配比参考消息, 所述 TDD灵活 配比参考消息包括所述基站当前使用的 TDD灵活配比参数。
6、 根据权利要求 1至 5中任一项所述的基站, 其特征在于, 所述 TDD 灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配比无 线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配比的 上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在下行 物理层信令中的位置的映射关系中的一种或多种。
7、 一种基站, 其特征在于, 包括:
接收单元, 用于从第一基站接收时分双工 TDD灵活配比配置消息, 所 述 TDD灵活配比配置消息包括 TDD灵活配比参数, 所述 TDD灵活配比参 数包括灵活配比信令的发送周期;
设置单元, 用于根据所述 TDD灵活配比配置消息, 设置所述 TDD灵活 配比参数;
发送单元, 用于基于所述 TDD灵活配比参数, 向所述基站覆盖范围内 的用户设备 UE发送 TDD灵活配比信令, 所述 TDD灵活配比信令包括所述 基站当前使用的 TDD灵活配比的索引。
8、 根据权利要求 7所述的基站, 其特征在于, 所述发送单元, 还用于 向所述第一基站发送 TDD灵活匹配请求消息,所述 TDD灵活配比请求消息 用于请求所述第一基站为所述基站配置期望的 TDD灵活配比参数。
9、 根据权利要求 7或 8所述的基站, 其特征在于, 所述接收单元, 还 用于从所述第一基站接收 TDD灵活匹配参考消息,所述 TDD灵活配比参考 消息包括所述第一基站当前使用的 TDD灵活配比参数。
10、根据权利要求 7至 9中任一项所述的基站, 其特征在于, 所述 TDD 灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配比无 线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配比的 上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在下行 物理层信令中的位置的映射关系中的一种或多种。
11、 一种用于实现跨站点灵活配比的方法, 其特征在于, 包括: 第一基站生成时分双工 TDD灵活配比配置消息,所述 TDD灵活配比配 置消息包括 TDD灵活配比参数, 所述 TDD灵活配比参数包括 TDD灵活配 比信令的发送周期;
所述第一基站向第二基站发送所述 TDD灵活配比配置消息, 以便于所 述第二基站根据所述 TDD灵活配比配置消息设置所述 TDD灵活配比参数;
所述第一基站根据所述 TDD灵活配比参数, 获取所述第二基站基于所 述 TDD 灵活配比参数发送给所述第二基站覆盖范围内的用户设备 UE 的 TDD灵活配比信令, 所述 TDD灵活配比信令包括所述第二基站当前使用的 TDD灵活配比的索引。
12、 根据权利要求 11 所述的方法, 其特征在于, 在所述第一基站生成 时分双工 TDD灵活配比配置消息之前, 还包括:
所述第一基站从所述第二基站接收 TDD灵活配比请求消息, 所述 TDD 灵活配比请求消息用于请求所述第一基站为所述第二基站配置期望的 TDD 灵活配比参数;
所述第一基站生成时分双工 TDD灵活配比配置消息, 包括:
所述第一基站根据所述 TDD灵活配比请求消息,生成所述 TDD灵活配 比配置消息。
13、 根据权利要求 11或 12所述的方法, 其特征在于, 所述第一基站根 据所述 TDD灵活配比参数,获取所述第二基站基于所述 TDD灵活配比参数 发送给所述第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, 包 括:
所述第一基站根据所述 TDD灵活配比参数, 侦听所述第二基站基于所 述 TDD灵活配比参数发送给所述第二基站覆盖范围内的 UE的 TDD灵活配 比信令。
14、 根据权利要求 11或 12所述的方法, 其特征在于, 所述第一基站根 据所述 TDD灵活配比参数,获取所述第二基站基于所述 TDD灵活配比参数 发送给所述第二基站覆盖范围内的用户设备 UE的 TDD灵活配比信令, 包 括:
所述第一基站向所述第一基站覆盖范围内的 UE发送所述 TDD灵活配 比参数, 以便于所述第一基站覆盖范围内的 UE根据所述 TDD灵活配比参 数, 侦听所述第二基站基于所述 TDD灵活配比参数发送给所述第二基站覆 盖范围内的 UE的 TDD灵活配比信令;
所述第一基站从所述第一基站覆盖范围内的 UE接收所述 TDD灵活配 比信令。
15、根据权利要求 11至 14中任一项所述的方法,其特征在于,还包括: 所述第一基站向所述第二基站发送 TDD灵活配比参考消息, 所述 TDD
灵活配比参考消息包括所述第一基站当前使用的 TDD灵活配比参数。
16、 根据权利要求 11 至 15 中任一项所述的方法, 其特征在于, 所述 TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配 比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
17、 一种用于实现跨站点灵活配比的方法, 其特征在于, 包括: 第二基站从第一基站接收时分双工 TDD灵活配比配置消息, 所述 TDD 灵活配比配置消息包括 TDD灵活配比参数,所述 TDD灵活配比参数包括灵 活配比信令的发送周期;
所述第二基站根据所述 TDD灵活配比配置消息,设置所述 TDD灵活配 比参数;
所述第二基站基于所述 TDD灵活配比参数, 向所述第二基站覆盖范围 内的用户设备 UE发送 TDD灵活配比信令, 所述 TDD灵活配比信令包括所 述第二基站当前使用的 TDD灵活配比的索引。
18、 根据权利要求 17所述的方法, 其特征在于, 在所述第二基站从第 一基站接收时分双工 TDD灵活配比配置消息之前, 还包括:
所述第二基站向所述第一基站发送 TDD灵活匹配请求消息, 所述 TDD 灵活配比请求消息用于请求所述第一基站为所述第二基站配置期望的 TDD 灵活配比参数。
19、 根据权利要求 17或 18所述的方法, 其特征在于, 还包括: 所述第二基站从所述第一基站接收 TDD灵活匹配参考消息, 所述 TDD 灵活配比参考消息包括所述第一基站当前使用的 TDD灵活配比参数。
20、 根据权利要求 17 至 19 中任一项所述的方法, 其特征在于, 所述 TDD灵活配比参数还包括支持 TDD灵活配比特性的载波信息、 TDD灵活配 比无线网络临时标识、 TDD灵活配比信令的发送时间偏移量、 TDD灵活配 比的上行参考配比、 TDD灵活配比的下行参考配比和 TDD配比配置信令在 下行物理层信令中的位置的映射关系中的一种或多种。
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