WO2012149683A1 - 功率补偿的方法、用户设备及基站 - Google Patents

功率补偿的方法、用户设备及基站 Download PDF

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Publication number
WO2012149683A1
WO2012149683A1 PCT/CN2011/073679 CN2011073679W WO2012149683A1 WO 2012149683 A1 WO2012149683 A1 WO 2012149683A1 CN 2011073679 W CN2011073679 W CN 2011073679W WO 2012149683 A1 WO2012149683 A1 WO 2012149683A1
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WO
WIPO (PCT)
Prior art keywords
base station
user equipment
path loss
value
loss value
Prior art date
Application number
PCT/CN2011/073679
Other languages
English (en)
French (fr)
Inventor
李宏超
张元涛
王轶
周华
吴建明
Original Assignee
富士通株式会社
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 富士通株式会社 filed Critical 富士通株式会社
Priority to PCT/CN2011/073679 priority Critical patent/WO2012149683A1/zh
Priority to JP2014508667A priority patent/JP2014517579A/ja
Priority to CN201180070471.4A priority patent/CN103493548A/zh
Priority to KR1020137031702A priority patent/KR20140016363A/ko
Priority to EP11864761.9A priority patent/EP2706791A4/en
Publication of WO2012149683A1 publication Critical patent/WO2012149683A1/zh
Priority to US14/071,226 priority patent/US20140056267A1/en

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/06TPC algorithms
    • H04W52/14Separate analysis of uplink or downlink
    • H04W52/143Downlink power control
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/06TPC algorithms
    • H04W52/10Open loop power control
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/18TPC being performed according to specific parameters
    • H04W52/24TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters
    • H04W52/242TPC being performed according to specific parameters using SIR [Signal to Interference Ratio] or other wireless path parameters taking into account path loss
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/08Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the receiving station
    • H04B7/0837Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the receiving station using pre-detection combining
    • H04B7/0842Weighted combining
    • H04B7/086Weighted combining using weights depending on external parameters, e.g. direction of arrival [DOA], predetermined weights or beamforming
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/06TPC algorithms
    • H04W52/14Separate analysis of uplink or downlink
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/18TPC being performed according to specific parameters
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/022Site diversity; Macro-diversity
    • H04B7/024Co-operative use of antennas of several sites, e.g. in co-ordinated multipoint or co-operative multiple-input multiple-output [MIMO] systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W52/00Power management, e.g. TPC [Transmission Power Control], power saving or power classes
    • H04W52/04TPC
    • H04W52/38TPC being performed in particular situations
    • H04W52/40TPC being performed in particular situations during macro-diversity or soft handoff

Definitions

  • the present invention relates to the field of wireless communications, and in particular, to a power compensation method, a user equipment, and a base station. Background technique
  • LTE-A enhanced long term evaluation
  • CoMP Coordinated Multi-points
  • Transmission or reception technology This technology enables multiple geographically dispersed transmission points to collaborate as a single user to improve the user's performance experience.
  • heterogeneous network nodes that are different from the traditional cellular network are introduced.
  • These heterogeneous network nodes such as a home base station (HeNB, Home eNodeB), a hotspot coverage cell Pico-cell, a remote radio head (RRH, Radio Remote Head), etc., use a lower transmit power for a specific area or user.
  • the coverage is relatively flexible. If the deployment is reasonable, the user experience will be greatly improved.
  • CoMP's working modes can be divided into two types: CS/CB (Coordinated scheduling and/or beamforming) and JP (Joint processing/transmission).
  • CS/CB Coordinatd scheduling and/or beamforming
  • JP Joint processing/transmission
  • the type of the transmission point may be a conventional macrocell base station, or a heterogeneous network node such as an RRH or a Pico base station, and may be a high power node or a low power node.
  • CoMP works in the JP mode. If a geographically distributed antenna of multiple transmission points is utilized, the combined multi-antenna can be used to increase the channel capacity of the user.
  • the existing codebook is designed according to the default multiple antennas in the same geographical position, that is, the traditional codebook is designed under the assumption that the amplitudes of the elements of the channel matrix H are the same.
  • the traditional codebook is designed under the assumption that the amplitudes of the elements of the channel matrix H are the same.
  • the distance between each antenna port and the UE is different.
  • the power of each antenna port at the receiving end of the receiving end will be different, which will cause the amplitude of each element of the channel matrix H to be different.
  • Existing codebooks will not adapt to such channel characteristics and will not achieve the desired results.
  • Embodiments of the present invention provide a method, a user equipment, and a base station for power compensation.
  • the purpose is to compensate for the power of the downlink signal or the uplink signal.
  • a method for power compensation is provided, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the method includes: a first value obtaining step, the base station receiving the report reported by the user equipment a path loss value, or calculating a path loss value according to the reference signal received power value reported by the user equipment; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side;
  • the base station performs power compensation on the uplink signal from the user equipment according to the path loss value.
  • a method for power compensation comprising:
  • the user equipment measures a reference signal received power value
  • the first value reporting step reports the path loss value or the reference signal received power value to the base station.
  • a method for power compensation is provided, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the method includes: a second value obtaining step, the base station receives the path loss value reported by the user equipment, or calculates a path loss value according to the reference signal received power value reported by the user equipment; the path loss value is used to indicate the user equipment and the base station Power loss of the signal between the sides;
  • the base station performs power compensation on the downlink signal transmitted to the user equipment according to the path loss value.
  • a method for power compensation is provided, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the method includes: a second numerical measurement step, the user equipment measures the reference signal Received power value;
  • the user equipment performs power compensation on the downlink signal from the base station side according to the path loss value.
  • a base station is provided, where the base station is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the base station includes:
  • the first value acquirer receives the path loss value reported by the user equipment, or calculates a path loss value according to the reference signal received power value reported by the user equipment; the path loss value is used to indicate between the user equipment and the base station side. Power loss of the signal;
  • the first power compensator performs power compensation on the uplink signal from the user equipment according to the path loss value.
  • a user equipment is provided, where the user equipment includes:
  • a first value measurer that measures a reference signal received power value
  • a first value calculator calculating a path loss value according to the measured reference signal received power value; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side; the first value reporter And reporting the path loss value or the reference signal receiving power value to the base station.
  • a base station is provided, where the base station is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the base station includes:
  • a second value acquirer receiving a path loss value reported by the user equipment, or according to the user Calculating a path loss value by using a reference signal received power value reported by the device; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side;
  • the second power compensator performs power compensation on the downlink signal transmitted to the user equipment according to the path loss value.
  • a user equipment which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment, where the user equipment includes: a second value measurer, measuring a reference signal received power value. ;
  • a second value calculator calculating a path loss value according to the measured reference signal received power value; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side; the third power compensator And performing power compensation on the downlink signal from the base station side according to the path loss value or the reference signal received power value.
  • a computer readable program wherein when the program is executed in a base station, the program causes a computer to perform a method of power compensation as described above in the base station.
  • a storage medium storing a computer readable program, wherein the computer readable program causes a computer to perform a power compensation method as described above in a base station.
  • a computer readable program wherein when the program is executed in a user equipment, the program causes a computer to perform a power compensation method as described above in the user equipment .
  • a storage medium storing a computer readable program, wherein the computer readable program causes a computer to perform a power compensation method as described above in a base station.
  • the beneficial effects of the embodiment of the present invention are: according to the path loss value or the reference signal receiving power value, the base station side or the user equipment side can compensate the power of the signal, so that the power of each receiving end is the same in the uplink transmission or the downlink transmission, so that Reuse codebook based transmission.
  • 1 is a schematic diagram of precoding processing on the downlink
  • 2 is a schematic diagram of decoding processing on the uplink
  • FIG. 3 is a flowchart of a method of power compensation according to Embodiment 1 of the present invention.
  • FIG. 5 is still another flowchart of the method of power compensation according to Embodiment 1 of the present invention.
  • FIG. 6 is a schematic structural diagram of a base station according to Embodiment 1 of the present invention.
  • FIG. 7 is still another schematic structural diagram of a base station according to Embodiment 1 of the present invention.
  • FIG. 8 is a schematic structural diagram of a user equipment according to Embodiment 1 of the present invention.
  • FIG. 9 is a flowchart of a method of power compensation according to Embodiment 2 of the present invention.
  • FIG. 10 is still another flowchart of a method for power compensation according to Embodiment 2 of the present invention
  • FIG. 11 is a schematic structural diagram of a base station according to Embodiment 2 of the present invention.
  • FIG. 12 is still another schematic structural diagram of a base station according to Embodiment 2 of the present invention.
  • Figure 13 is a flowchart of a method of power compensation according to Embodiment 3 of the present invention.
  • FIG. 16 is another schematic structural diagram of a user equipment according to Embodiment 3 of the present invention.
  • 17 is a system configuration diagram of a user equipment according to an embodiment of the present invention.
  • Figure 18 is a block diagram showing still another system configuration of the user equipment according to the embodiment of the present invention.
  • the embodiment of the present invention introduces an LTE-A system as an example, and relates to a multi-antenna enhancement technology, a measurement mechanism, and a signaling interaction in a multi-point coordinated transmission and reception of a heterogeneous network.
  • LTE-A Long Term Evolution
  • the present invention is not limited to this system and can be applied to any system employing multipoint cooperation techniques.
  • the base station side may include a geographically distributed base station A and a cooperative node B, and provide services for the user equipment through the base station A and the cooperative node B.
  • the base station A may be a macro base station, and may include multiple antennas;
  • the cooperative node B may be a Pico base station, an RRH, or the like, or may include multiple antennas.
  • the base station side of the present invention may include a base station and a cooperative node only with respect to the user equipment.
  • Embodiments of the present invention provide a method for power compensation, which is applied to compensate power of an uplink signal.
  • the embodiment of the present invention compensates the power at the base station side.
  • FIG. 3 is a flowchart of a method for power compensation according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment.
  • the method includes: Step 301: A base station receives a path loss value reported by a user equipment, or calculates a path loss value according to a reference signal received by a user equipment, where the path loss value is used to indicate a user equipment and a base station. Power loss of the signal between the sides;
  • Step 302 The base station performs power compensation on the uplink signal from the user equipment according to the path loss value.
  • Reference Signal Receiving Power is a key parameter that can represent the strength of the wireless signal in the LTE-A network.
  • the user equipment can obtain the RSRP value according to the existing standard, and the existing technology can be used, and details are not described herein again.
  • the user equipment may estimate a path loss value (Pathloss) according to the RSRP value, where the path loss value is used to indicate the power loss of the signal between the user equipment and the base station side.
  • the path loss value is used to indicate the power loss of the signal between the user equipment and the base station side.
  • the RSRP value is -60dBm and the power of the base station to the user equipment can be preset to 30dBm
  • the user equipment can estimate the Pathloss value as 90dB.
  • the above is only a schematic description of the estimated Pathloss value, but it is not limited to this, and the specific calculation method can be determined according to the actual situation.
  • the user equipment may report the Pathloss value to the base station. After receiving the Pathloss value, the base station can compensate for the received power according to the Pathloss value. Alternatively, the user equipment may report the RSRP value to the base station. After receiving the RSRP value, the base station may estimate the Pathloss value according to the RSRP value, and then perform compensation of the received power according to the Pathloss value.
  • the system structure may be as shown in FIG. 2, and the base station side includes a geographically distributed base station A and a cooperative node B.
  • FIG. 4 is still another flowchart of a method for power compensation according to an embodiment of the present invention. As shown in FIG. 4, the method includes:
  • Step 401 The base station receives the Pathloss value reported by the user equipment, or calculates a Pathloss value according to the RSRP value reported by the user equipment.
  • the Pathloss value may include a path loss value of the signal from the user equipment to the base station, and a path loss value of the signal from the user equipment to the cooperative node, and the base station may receive a plurality of Pathloss values.
  • the base station A can receive the Pathloss value of the user equipment reported by the user equipment to the base station A, and the Pathloss value of the user equipment to the cooperative node B.
  • the base station A is required to notify the user equipment of the transmission power of the cooperative node B, and the user equipment estimates the user equipment to the cooperation according to the transmission power of the cooperative node B and the RSRP value of the cooperative node B.
  • the Pathloss value of Node B the user equipment may report the RSRP value of the cooperative node B to the base station A, and the base station A estimates the user equipment to the cooperative node B according to the RSRP value of the cooperative node B and the transmit power of the cooperative node B. Pathloss value.
  • Step 402 The base station interacts with the collaboration node according to the difference between the Pathloss value or the Pathloss value.
  • the base station may interact with the cooperation node according to the Pathloss value; the content of the interaction may include: a Pathloss value of the user equipment to the base station, a Pathloss value of the user equipment to the cooperation node, or the difference between the two, etc. . It can be implemented by upper layer signaling, and existing technology can be used, and details are not described herein again.
  • Step 403 The base station adjusts the amplifier of the receiver according to the interaction result or notifies the amplifier of the coordinated node adjustment receiver to perform power compensation on the uplink signal.
  • the power of the uplink signal sent by the user equipment to the base station A and the cooperative node B is 24 dBm.
  • the existing Codebook can be used.
  • the base station and the cooperating node have the same cell identity and have multiple antenna ports respectively;
  • the base station A may be a macro base station, and the cooperative node B may be an RRH.
  • multiple antennas of the cooperative node B can be regarded as an extension of the base station A, and the base station A can control the antenna of the cooperative node B, that is, the base station A can have multiple geographically distributed different antenna ports.
  • the specific control can be implemented by using the prior art, and details are not described herein again.
  • the step 301 is specifically: the base station receives multiple antenna ends reported by the user equipment.
  • the path loss value of the port, or the path loss value of multiple antenna ports is calculated according to the RSRP value of multiple antenna ports reported by the user equipment;
  • step 302 is specifically as follows: The base station adjusts amplifiers of different antenna ports according to the Pathloss values of the multiple antenna ports to perform power compensation on the uplink signals from the user equipment.
  • the power of the uplink signal sent by the user equipment to the base station A and the cooperative node B is 24 dBm.
  • the base station A adjusts the amplifiers of the different antenna ports of the base station A and the cooperative node B according to the above Pathloss_l to Pathloss_8, and amplifies the uplink signal from the user equipment; so that the power of the uplink signal received by the antenna port 1 in the base station A is -66dBm becomes -56dBm, the power of the uplink signal received by antenna port 2 is changed from -66.01dBm to -56dBm, and the power of the uplink signal received by antenna port 3 is changed from -66.02dBm to -56dBm, and antenna port 4 receives The power of the uplink signal is changed from -66.03dBm to -56dBm ;
  • the antenna port 5 in the cooperative node B is not adjusted, the power of the received uplink signal is still -56 dBm, and the power of the uplink signal received by the antenna port 6 is changed from -56.51 dBm to -56 dBm, and the antenna port 7 is received.
  • the power of the uplink signal is changed from -56.52dBm to -56dBm, and the power of the uplink signal received by the antenna port 8 is changed from -56.53dBm to -56dBm.
  • the power of each antenna port at the receiving end can be made the same when the uplink is transmitted, and the existing Codebook can be used.
  • FIG. 5 is still another flowchart of a method for power compensation according to an embodiment of the present invention. As shown in FIG. 5, the method includes:
  • Step 501 The user equipment measures a reference signal received power value.
  • Step 502 Calculate a path loss value according to the measured reference signal received power value, where the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side;
  • Step 503 The user equipment reports a path loss value or a reference signal received power value to the base station.
  • the base station side can compensate the power of the uplink signal according to the path loss value reported by the user equipment or the reference signal received power value, so that the power of the receiving end is the same when the uplink transmission is performed, so that the codebook-based codebook can be reused. transfer method.
  • FIG. 6 is a schematic structural diagram of a base station according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment.
  • the base station includes: a first value acquirer 601 and a first power compensator 602;
  • the first value acquirer 601 receives the path loss value reported by the user equipment, or the first value acquirer 601 calculates the path loss value according to the reference signal received power value reported by the user equipment; the path loss value is used to indicate the user equipment and the base station side. Power loss of the signal;
  • the first power compensator 602 performs power compensation on the uplink signal from the user equipment based on the path loss value.
  • FIG. 7 is still another schematic structural diagram of a base station according to an embodiment of the present invention. As shown in FIG. 7, the base station includes: a first value acquirer 601 and a first power compensator 602, as described above.
  • the path loss value includes the path loss value of the signal from the user equipment to the base station, and the path loss value of the signal from the user equipment to the cooperative node.
  • the base station may further include: a first information interactor 701;
  • the first information interactor 701 interacts with the cooperative node according to a path loss value from the user equipment to the base station, and a path loss value from the user equipment to the cooperative node, or a difference between the two;
  • the first power compensator 602 is specifically configured to: adjust an amplifier of the receiver according to the interaction result, or notify the cooperative node to adjust an amplifier of the receiver to perform power compensation on the uplink signal.
  • the base station and the cooperative node have the same cell identity and each have a plurality of different antenna ports;
  • the first value acquirer 601 is specifically configured to: receive a path loss value of the multiple antenna ports reported by the user equipment, or calculate a path loss value of the multiple antenna ports according to the reference signal received power value of the multiple antenna ports reported by the user equipment;
  • the first power compensator 602 is specifically configured to: adjust amplifiers of different antenna ports according to path loss values of multiple antenna ports to perform power compensation on the uplink signals.
  • FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention. As shown in FIG. 8, the user equipment includes: a first value measurer 801, a first value calculator 802, and a first value report 803;
  • the first value measurer 801 is configured to measure a reference signal received power value
  • the first value calculator 802 is configured to calculate a path loss value according to the measured reference signal received power value; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side; the first value report 803 to the base station Report the path loss value or the reference signal received power value.
  • the base station side can compensate the power of the uplink signal from the user equipment according to the path loss value or the reference signal received power value reported by the user equipment, so that the power of each receiving end is the same in the uplink transmission, so that the power can be recovered.
  • Use codebook-based transmission is configured to calculate a path loss value according to the measured reference signal received power value; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side; the first value report 803 to the base station Report the path loss value or the reference signal received power value.
  • FIG. 9 is a flowchart of a method for power compensation according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment.
  • the method includes:
  • Step 901 The base station receives the path loss value reported by the user equipment, or calculates a path loss value according to the received power value of the reference signal reported by the user equipment; the path loss value is used to indicate the power loss of the signal between the user equipment and the base station side;
  • Step 902 The base station performs power compensation on the downlink signal transmitted to the user equipment according to the path loss value.
  • the user equipment may report the Pathloss value to the base station. After receiving the Pathloss value, the base station may perform compensation of the transmit power according to the Pathloss value. Alternatively, the user equipment may report the RSRP value to the base station, and after receiving the RSRP value, the base station may estimate the Pathloss value according to the RSRP value, and then perform the receiving power supplement according to the Pathloss value. Reimbursement.
  • the system structure may be as shown in FIG. 1, and the base station side includes a geographically distributed base station A and a cooperative node B.
  • FIG. 10 is still another flowchart of a method for power compensation according to an embodiment of the present invention. As shown in FIG. 10, the method includes:
  • Step 1001 The base station receives the Pathloss value reported by the user equipment, or calculates a Pathloss value according to the RSRP value reported by the user equipment.
  • the Pathloss value may include a path loss value of the signal from the base station to the user equipment, and a path loss value of the signal from the cooperative node to the user equipment, and the base station may receive a plurality of Pathloss values.
  • the base station A can receive the Pathloss value of the base station A to the user equipment reported by the user equipment, and the Pathloss value of the cooperative node B to the user equipment. It should be noted that, in this case, the base station A is required to notify the user equipment of the transmission power of the cooperative node B, and the user equipment estimates that the cooperative node B is based on the transmission power of the cooperative node B and the RSRP value of the cooperative node B. The Pathloss value of the user device.
  • the user equipment may report the RSRP value of the coordinated Node B to the base station A, and the base station A estimates the coordinated Node B to the user equipment according to the RSRP value of the cooperative Node B and the transmit power of the cooperative Node B. Pathloss value.
  • Step 1002 The base station interacts with the collaboration node according to the difference between the Pathloss value or the Pathloss value.
  • the base station may interact with the collaboration node according to the Pathloss value; the content of the interaction may include: a Pathloss value of the base station to the user equipment, a Pathloss value of the collaboration node to the user equipment, or the like, or a difference between the two. It can be implemented by the upper layer signaling through the X2 port, and the existing technology can be used, and details are not described herein again.
  • Step 1003 The base station adjusts the amplifier of the transmitter according to the interaction result, or notifies the cooperative node to adjust the amplifier of the transmitter to perform power compensation on the downlink signal.
  • the power of the downlink signal sent by the base station A to the user equipment is 45 dBm
  • the power of the downlink signal sent by the cooperative node B to the user equipment is 30 dBm.
  • base station A interacts with the cooperative node B according to ?&1(1 ⁇ 28_ ⁇ ?&1088_6; finally, base station A adjusts the amplifier of the transmitter according to the interaction result.
  • the signal power received by the user equipment from the base station and the cooperative node is the same when the downlink transmission is performed, and the existing Codeb 00 k can be used.
  • the base station A and the cooperative node B have the same cell identifier and each have multiple antenna ports; the base station A may be a macro base station, and the cooperative node B may be multiple of the coordinated node B in a specific implementation.
  • the antenna can be regarded as an extension of the base station A, and the base station A can control the antenna of the cooperative Node B, that is, the base station A can have a plurality of geographically distributed different antenna ports. The specific control can be implemented by using the prior art, and details are not described herein again.
  • step 901 is specifically: the base station receives the path loss value of the multiple antenna ports reported by the user equipment, or calculates the path loss value of the multiple antenna ports according to the reference power receiving power values of the multiple antenna ports reported by the user equipment;
  • step 902 is specifically as follows: The base station allocates different transmit powers for different antenna ports according to path loss values of multiple antenna ports.
  • the power of the downlink signals sent by the antenna ports of the base station A to the user equipment is 45 dBm
  • the power of the downlink signals transmitted by the antenna ports of the cooperative node B to the user equipment is 30 dBm.
  • the base station A adjusts the base station A and the cooperation according to the above Pathloss_l to Pathloss_8.
  • the amplifier of the different antenna ports of the transmitter in the node B is such that the antenna port 1 is unchanged, and the power of the downlink signal transmitted by the antenna port 1 to the user equipment is 45 dBm, and the power of the downlink signal received by the user equipment is -45 dBm;
  • the power of the downlink signal transmitted from the antenna port 2 to the user equipment is changed from 45 dBm to 45.01 dBm, and the power of the downlink signal transmitted from the antenna port 3 to the user equipment is changed from 45 dBm to 45.02 dBm, and the antenna port 4 is directed to the user equipment.
  • the power of the transmitted downlink signal is changed from 45dBm to 45.03dBm, the power of the downlink signal transmitted from the antenna port 5 to the user equipment is changed from 30dBm to 35dBm, and the power of the downlink signal transmitted from the antenna port 6 to the user equipment is changed from 30dBm.
  • the power of the downlink signal transmitted from the antenna port 7 to the user equipment is changed from 30 dBm to 35.52 dBm, and the power of the downlink signal transmitted from the antenna port 8 to the user equipment is changed from 30 dBm to 35.53 dBm ;
  • the downlink signals received by the user equipment from the respective antenna ports have a power of -45 dBm. It is possible to make the signal power received by the user equipment from each antenna port the same when transmitting in the downlink, and the existing Codebook can be used.
  • FIG. 11 is a schematic structural diagram of a base station according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment.
  • the base station includes: a second value acquirer 1101 and a second power compensator 1102;
  • the second value acquirer 1101 is configured to receive a path loss value reported by the user equipment, or the second value acquirer 1101 is configured to calculate a path loss value according to the reference signal received power value reported by the user equipment; the path loss value is used to indicate the user equipment. Power loss of the signal between the base station side and the base station side;
  • the second power compensator 1102 performs power compensation on the downlink signal transmitted to the user equipment based on the path loss value.
  • FIG. 12 is still another schematic structural diagram of a base station according to an embodiment of the present invention. As shown in FIG. 12, the base station includes: a second value acquirer 1101 and a second power compensator 1102, as described above.
  • the path loss value includes a path loss value of the signal from the base station to the user equipment, and The path loss value of the signal from the cooperating node to the user equipment.
  • the base station further includes: a second information interactor 1201;
  • the second information interactor 1201 interacts with the cooperative node according to a path loss value from the base station to the user equipment, and a path loss value from the cooperation node to the user equipment, or a difference between the two;
  • the second power compensator 1102 is specifically configured to: adjust an amplifier of the transmitter according to the interaction result, or notify the cooperative node to adjust an amplifier of the transmitter to perform power compensation on the downlink signal.
  • the base station and the cooperative node have the same cell identifier, and each has multiple antenna ports, that is, the base station side has a plurality of geographically distributed different antenna ports.
  • the second value acquirer 1101 is specifically configured to: Receiving path loss values of multiple antenna ports reported by the user equipment, or calculating path loss values of multiple antenna ports according to reference signal received power values of multiple antenna ports reported by the user equipment;
  • the second power compensator 1102 is specifically configured to: allocate different transmit powers to different antenna ports according to path loss values of multiple antenna ports.
  • the base station side can compensate the power of the downlink signal according to the path loss value reported by the user equipment or the reference signal received power value. Therefore, when the downlink transmission is performed, the signal power received by the user equipment from each transmitting end is the same, so that the codebook-based transmission mode can be multiplexed.
  • the embodiment of the invention provides a method for power compensation, which is used for compensating the power of the downlink signal from the user equipment side.
  • FIG. 13 is a flowchart of a method for power compensation according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment. As shown in FIG. 13, the method includes: Step 1301: A user equipment measures a reference signal received power value;
  • Step 1302 The user equipment calculates a path loss value according to the measured reference signal received power value, where the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side.
  • Step 1303 The user equipment performs power compensation on the downlink signal from the base station side according to the path loss value.
  • the user equipment may obtain an RSRP value according to an existing standard, and may adopt The prior art is not described here.
  • the Pathloss value can be estimated from the RSRP value, as described in Embodiment 1. Then, the user equipment can perform power compensation on the downlink signal according to the Pathloss value.
  • the system structure may be as shown in FIG. 1, and the base station side includes a geographically distributed base station A and a cooperative node B.
  • FIG. 14 is still another flowchart of a method for power compensation according to an embodiment of the present invention. As shown in FIG. 14, the method includes:
  • Step 1401 The user equipment measures an RSRP value.
  • Step 1402 The user equipment calculates a Pathloss value according to the measured RSRP value.
  • the Pathloss value may include a path loss value of the signal from the base station to the user equipment, and a path loss value of the signal from the cooperation node to the user equipment.
  • Step 1403 The user equipment interacts with the base station according to the difference between the Pathloss value or the Pathloss value.
  • the base station may configure a measurement event for the user equipment, so that when the serving cell signal and the coordinated cell signal measured by the user equipment meet certain conditions, the measurement report is reported to the base station of the serving cell. It can be implemented by the upper layer signaling, and the prior art can be used, and details are not described herein again.
  • Step 1404 The user equipment adjusts the amplifier according to the interaction result, and performs power compensation on the downlink signal from the base station or the downlink signal from the cooperative node.
  • the power of the downlink signal sent by the base station A to the user equipment is 45 dBm
  • the power of the downlink signal sent by the cooperative node B to the user equipment is 30 dBm.
  • the user equipment interacts with the base station A according to the Pathloss_A and the Pathl 0SS_B ; Finally, the user equipment adjusts the amplifier according to the interaction result, so that the power of the downlink signal sent by the base station A to the user equipment is changed from -45 dBm to -50 dBm ; and the power of the downlink signal sent by the cooperative node B to the user equipment remains unchanged. -50dBm.
  • the signal power received by the user equipment from each transmitting end can be made the same when the downlink transmission is performed, and the existing Codeb 00 k can be used.
  • the above is only a schematic description of the power compensation of the downlink signal from the user equipment side, but is not limited thereto, and a specific implementation manner may be determined according to actual conditions.
  • the base station A and the cooperative node B have the same cell identifier and each have multiple antenna ports; the base station A may be a macro base station, and the cooperative node B may be multiple of the coordinated node B in a specific implementation.
  • the antenna can be regarded as an extension of the base station A, and the base station A can control the antenna of the cooperative Node B, that is, the base station A can have a plurality of geographically distributed different antenna ports. The specific control can be implemented by using the prior art, and details are not described herein again.
  • step 1301 is specifically: the user equipment measures a reference signal received power value of the multiple antenna ports;
  • step 1302 is specifically: the user equipment calculates a path loss value of the multiple antenna ports according to the measured reference signal received power values of the multiple antenna ports;
  • step 1303 is specifically as follows: The user equipment adjusts the amplifier according to the path loss value of the multiple antenna ports, and performs power compensation on the downlink signals from different antenna ports.
  • the method may further include: receiving, by the user equipment, a notification that the reference signal received power value of the multiple antenna ports sent by the base station is measured, or the path loss value of the multiple antenna ports is calculated. According to the notification, the user equipment measures the reference signal received power value of the plurality of antenna ports or calculates the path loss values of the plurality of antenna ports.
  • the power of the downlink signals sent by the antenna ports of the base station A to the user equipment is 45 dBm
  • the power of the downlink signals sent by the antenna ports of the cooperative node B to the user equipment is 30 dBm.
  • path loss device Pathloss_5 80dB
  • Pathloss_6 80.51dB
  • Pathloss_7 80.52dB
  • Pathloss_8 80.53dB;
  • the user equipment adjusts the amplifier according to the above Pathloss_l to Pathloss_8, so that the power of the downlink signals received by the user equipment from the respective antenna ports is -45 dBm.
  • the signals received by the user equipment from the respective antenna ports during downlink transmission can be made With the same power, you can use your existing Codebook.
  • FIG. 15 is a schematic structural diagram of a base station according to an embodiment of the present invention, which is applied to a communication system in which a base station and a cooperative node jointly serve a user equipment.
  • the user equipment includes: a second numerical measurer 1501, a second numerical calculator 1502, and a third power compensator 1503; wherein
  • the second value measurer 1501 measures the reference signal received power value
  • the second value calculator 1502 is configured to calculate a path loss value according to the measured reference signal received power value; the path loss value is used to indicate a power loss of a signal between the user equipment and the base station side; the third power compensator 1503 is based on the road The loss value or the reference signal received power value performs power compensation on the downlink signal from the base station side.
  • FIG. 16 is still another schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • the user equipment includes: a second value measurer 1501, a second value calculator 1502, and a third power compensator 1503, as shown in FIG. Said.
  • the path loss value includes the path loss value of the signal from the base station to the user equipment, and the path loss value of the signal from the cooperative node to the user equipment.
  • the user equipment may further include: a third information interactor 1601;
  • the third information interactor 1601 is configured to interact with the base station according to a path loss value from the base station to the user equipment, and a path loss value from the cooperative node to the user equipment, or a difference between the two; further, the third The power compensator 1502 is specifically configured to: adjust the amplifier according to the interaction result to perform power compensation on the downlink signal from the base station or the downlink signal from the cooperative node.
  • the base station and the cooperative node have the same cell identifier, and each has multiple antenna ports, that is, the base station side has a plurality of geographically distributed different antenna ports;
  • the second value measurer 1501 is specifically configured to: Obtaining reference signal received power values of multiple antenna ports;
  • the second numerical calculator 1502 is specifically configured to: refer to the plurality of antenna ports according to the measurement Signal receiving power value, calculating path loss values of multiple antenna ports;
  • the third power compensator 1503 is specifically configured to: adjust an amplifier according to a path loss value of multiple antenna ports, and perform power compensation on downlink signals from different antenna ports.
  • the user equipment may further include: a notification receiver, configured to receive a notification sent by the base station to measure a reference signal received power value of the multiple antenna ports, or calculate a path loss value of the multiple antenna ports.
  • a notification receiver configured to receive a notification sent by the base station to measure a reference signal received power value of the multiple antenna ports, or calculate a path loss value of the multiple antenna ports.
  • Figure 17 is a schematic block diagram showing the system configuration of the user equipment 1700 according to the embodiment of the present invention, which includes the first numerical value measuring unit 801, the first numerical value calculator 802 and the first numerical value reporting unit 803 described in the first embodiment.
  • Figure 18 is a schematic block diagram showing the system configuration of the user equipment 1800 according to the embodiment of the present invention, which includes the second numerical value measuring unit 1501, the second numerical value calculator 1502 and the third power compensator 1503 according to the third embodiment.
  • 17 through 18 are exemplary; other types of structures may be used in addition to or in place of the structure to implement telecommunications functions or other functions.
  • the user equipment 1700, 1800 further includes a central processing unit 100, a communication module 110, an input unit 120, an audio processing unit 130, a memory 140, a camera 150, a display 160, and a power supply 170.
  • the central processing unit 100 receives input and controls various portions and operations of the user equipment.
  • Input unit 120 provides input to central processor 100.
  • the input unit 120 is, for example, a button or a touch input device.
  • the camera 150 is for taking in image data, and supplies the taken image data to the central processing unit 100 for use in a conventional manner, for example, for storage, transfer, and the like.
  • Power source 170 is used to provide power to the user equipment.
  • the display 160 is used to display a display object such as an image and a text.
  • the display may be, for example, an LCD display, but is not limited thereto.
  • Memory 140 is coupled to central processor 100.
  • the memory 140 can be a solid state memory such as a read only memory (ROM), a random access memory (RAM), a SIM card, and the like. It may also be a memory that saves information even when the power is turned off, and can be selectively erased and More data is provided, and an example of this memory is sometimes referred to as an EPROM or the like. Memory 140 can also be some other type of device.
  • Memory 140 includes a buffer memory 141 (sometimes referred to as a buffer).
  • the memory 140 may include an application/function storage section 142 for storing an application and a function program or a flow for executing an operation of the user device by the central processing unit 100.
  • the memory 140 can also include a data storage portion 143 for storing data such as contacts, digital data, pictures, sounds, and/or any other data used by the user device.
  • the driver storage portion 144 of the memory 140 may include various drivers for the communication functions of the user device and/or for performing other functions of the user device (e.g., messaging applications, address book applications, etc.).
  • the communication module 110 is a transmitter/receiver 110 that transmits and receives signals via the antenna 111.
  • a communication module (transmitter/receiver) 110 is coupled to the central processing unit 100 to provide an input signal and receive an output signal, which can be the same as in the case of a conventional mobile phone.
  • a plurality of communication modules 110 may be provided in the same user equipment.
  • a communication module (transmitter/receiver) 110 is also coupled via audio processor 130 to speaker 131 and microphone 132 to provide an audio output via speaker 131 and to receive audio input from microphone 132 to effect the usual telecommunications functions.
  • Audio processor 130 may include any suitable buffer, decoder, amplifier, or the like.
  • the audio processor 130 is also coupled to the central processing unit 100 so that it is possible to record on the local unit through the microphone 132, and it is possible to play the sound stored on the unit through the speaker 131.
  • the embodiment of the present invention further provides a computer readable program, wherein when the program is executed in the user equipment, the program causes the computer to perform the method of power compensation as described in Embodiments 1 to 3 in the user equipment.
  • the embodiment of the present invention further provides a storage medium storing a computer readable program, wherein the computer readable program causes the computer to perform the power compensation method as described in Embodiments 1 to 3 in the user equipment.
  • the embodiment of the present invention further provides a computer readable program, wherein when the program is executed in a base station, the program causes the computer to perform the method of power compensation as described in Embodiments 1 to 3 in the base station.
  • the embodiment of the invention further provides a storage medium storing a computer readable program, wherein the computer readable program causes the computer to perform the method of power compensation as described in Embodiments 1 to 3 in a base station.
  • the above apparatus and method of the present invention may be implemented by hardware or by hardware in combination with software.
  • the present invention relates to a computer readable program that, when executed by a logic component, enables the logic component to implement the apparatus or components described above, or to cause the logic component to implement the various methods described above Or steps.
  • the present invention also relates to a storage medium for storing the above program, such as a hard disk, a magnetic disk, an optical disk, a DVD, a flash memory, or the like.

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Description

功率补偿的方法、 用户设备及基站 技术领域
本发明涉及无线通信领域, 特别涉及一种功率补偿的方法、 用户设 备及基站。 背景技术
为了改善增强的长期演进 (LTE-A, long term evaluation advanced) 系统下的小区覆盖和用户体验, 提高系统的吞吐量和用户的数据传输速 率, 目前引入了多点协作(CoMP, Coordinated Multi-points )传输或接收 技术。 这种技术可以使得多个地理位置上分散的传输点, 协作为一个用 户服务, 提高用户的性能体验。
并且, 在 LTE-A系统中, 引入了区别于传统的蜂窝网络的某些异构 网络结点。 这些异构网络结点, 例如家庭基站 (HeNB , Home eNodeB)、 热点覆盖小区 Pico-cell、 远端无线头 (RRH, Radio Remote Head) 等, 使用较低的发射功率, 对特定的区域或者用户进行覆盖, 组网方式相对 灵活, 如果部署合理, 用户体验会有较大幅度的提高。
CoMP 的工作模式可以分为两种: CS/CB ( Coordinated scheduling and/or beamforming )禾口 JP (Joint processing/transmission)。 CS/CB表不同 时只有一个传输点为 UE发送数据, JP表示同时可以有多个传输点为 UE 发送数据。 传输点的类型可以是传统的宏蜂窝基站、 或者是 RRH、 还可 以是 Pico基站等异构网络结点,可能是高功率节点也可能是低功率节点。 CoMP工作在 JP模式下, 如果利用地理上分布式的多个传输点的天线, 可以作为联合的多天线来增加用户的信道容量。
但是, 在实施本发明的过程中, 发明人发现如果上述的 CoMP联合 多天线技术采用现有标准中的基于码本(codebook)的传输模式, 将会出 现如下的问题:
现有的 codebook 是根据默认的多天线处于相同的地理位置来设计 的, 也就是说, 传统的 codebook是在信道矩阵 H的各个元素的幅值是一 致的假设条件下设计的。 但是在 CoMP联合多天线技术的应用场景中, 由于协作的传输点分散, 各天线端口和 UE的距离有差异。
尤其是在各个传输点发射功率不同的异构网络中, 接收端的各天线 端口接收发射端的各天线端口的功率会有差异, 这样将导致信道矩阵 H 的各个元素的幅值有所不同。 现有的 codebook将不会适应这样的信道特 性, 无法达到预期的效果。
应该注意, 上面对技术背景的介绍只是为了方便对本发明的技术方 案进行清楚、 完整的说明, 并方便本领域技术人员的理解而阐述的。 不 能仅仅因为这些方案在本发明的背景技术部分进行了阐述而认为上述技 术方案为本领域技术人员所公知。 发明内容
本发明实施例提供一种功率补偿的方法、 用户设备及基站。 目的在 于对下行信号或者上行信号的功率进行补偿。
根据本发明实施例的一个方面, 提供一种功率补偿的方法, 应用于 基站与协作节点联合为用户设备服务的通信系统中, 所述方法包括: 第一数值获取步骤, 基站接收用户设备上报的路损值, 或者根据所 述用户设备上报的参考信号接收功率值计算路损值; 所述路损值用于指 示所述用户设备与基站侧之间的信号的功率损耗;
第一功率补偿步骤, 所述基站根据所述路损值对来自所述用户设备 的上行信号进行功率补偿。
根据本发明实施例的又一个方面, 提供一种功率补偿的方法, 所述 方法包括:
第一数值测量步骤, 用户设备测量参考信号接收功率值;
第一数值计算步骤, 根据测量到的所述参考信号接收功率值计算路 损值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损 耗;
第一数值上报步骤, 向所述基站上报所述路损值或者参考信号接收 功率值。
根据本发明实施例的又一个方面, 提供一种功率补偿的方法, 应用 于基站与协作节点联合为用户设备服务的通信系统中, 所述方法包括: 第二数值获取步骤, 基站接收用户设备上报的路损值, 或者根据所 述用户设备上报的参考信号接收功率值计算路损值; 所述路损值用于指 示所述用户设备与所述基站侧之间的信号的功率损耗;
第二功率补偿步骤, 所述基站根据所述路损值对向所述用户设备发 射的下行信号进行功率补偿。
根据本发明实施例的又一个方面, 提供一种功率补偿的方法, 应用 于基站与协作节点联合为用户设备服务的通信系统中, 所述方法包括: 第二数值测量步骤, 用户设备测量参考信号接收功率值;
第二数值计算步骤, 根据测量到的所述参考信号接收功率值计算路 损值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损 耗;
第三功率补偿步骤, 所述用户设备根据所述路损值对来自基站侧的 下行信号进行功率补偿。
根据本发明实施例的又一个方面, 提供一种基站, 应用于基站与协 作节点联合为用户设备服务的通信系统中, 所述基站包括:
第一数值获取器, 接收用户设备上报的路损值, 或者根据所述用户 设备上报的参考信号接收功率值计算路损值; 所述路损值用于指示所述 用户设备与基站侧之间的信号的功率损耗;
第一功率补偿器, 根据所述路损值对来自所述用户设备的上行信号 进行功率补偿。
根据本发明实施例的又一个方面, 提供一种用户设备, 所述用户设 备包括:
第一数值测量器, 测量参考信号接收功率值;
第一数值计算器, 根据测量到的所述参考信号接收功率值计算路损 值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损耗; 第一数值上报器, 向所述基站上报所述路损值或者参考信号接收功 率值。
根据本发明实施例的又一个方面, 提供一种基站, 应用于基站与协 作节点联合为用户设备服务的通信系统中, 所述基站包括:
第二数值获取器, 接收用户设备上报的路损值, 或者根据所述用户 设备上报的参考信号接收功率值计算路损值; 所述路损值用于指示所述 用户设备与基站侧之间的信号的功率损耗;
第二功率补偿器, 根据所述路损值对向所述用户设备发射的下行信 号进行功率补偿。
根据本发明实施例的又一个方面, 提供一种用户设备, 应用于基站 与协作节点联合为用户设备服务的通信系统中, 所述用户设备包括: 第二数值测量器, 测量参考信号接收功率值;
第二数值计算器, 根据测量到的所述参考信号接收功率值计算路损 值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损耗; 第三功率补偿器, 根据所述路损值或者参考信号接收功率值, 对来 自基站侧的下行信号进行功率补偿。
根据本发明实施例的又一个方面, 提供一种计算机可读程序, 其中 当在基站中执行所述程序时, 所述程序使得计算机在所述基站中执行如 上所述的功率补偿的方法。
根据本发明实施例的又一个方面, 提供一种存储有计算机可读程序 的存储介质, 其中所述计算机可读程序使得计算机在基站中执行如上所 述的功率补偿的方法。
根据本发明实施例的又一个方面, 提供一种计算机可读程序, 其中 当在用户设备中执行所述程序时, 所述程序使得计算机在所述用户设备 中执行如上所述的功率补偿的方法。
根据本发明实施例的又一个方面, 提供一种存储有计算机可读程序 的存储介质, 其中所述计算机可读程序使得计算机在基站中执行如上所 述的功率补偿的方法。
本发明实施例的有益效果在于, 根据路损值或者参考信号接收功率 值, 基站侧或者用户设备侧可以对信号的功率进行补偿, 使得在上行传 输或者下行传输时各接收端的功率相同, 从而可复用基于码本的传输方 式。
参照后文的说明和附图, 详细公开了本发明的特定实施方式, 指明 了本发明的原理可以被采用的方式。 应该理解, 本发明的实施方式在范 围上并不因而受到限制。 在所附权利要求的精神和条款的范围内, 本发 明的实施方式包括许多改变、 修改和等同。
针对一种实施方式描述和 /或示出的特征可以以相同或类似的方式在 一个或更多个其它实施方式中使用, 与其它实施方式中的特征相组合, 或替代其它实施方式中的特征。
应该强调, 术语"包括 /包含"在本文使用时指特征、 整件、 步骤或组 件的存在, 但并不排除一个或更多个其它特征、 整件、 步骤或组件的存 在或附加。 附图说明
参照以下的附图可以更好地理解本发明的很多方面。 附图中的部件 不是成比例绘制的, 而只是为了示出本发明的原理。 为了便于示出和描 述本发明的一些部分, 附图中对应部分可能被放大或缩小。
在本发明的一个附图或一种实施方式中描述的元素和特征可以与一 个或更多个其它附图或实施方式中示出的元素和特征相结合。 此外, 在 附图中, 类似的标号表示几个附图中对应的部件, 并可用于指示多于一 种实施方式中使用的对应部件。
图 1是在下行链路上预编码处理的示意图;
图 2是在上行链路上解码处理的示意图;
图 3是本发明实施例 1的功率补偿的方法的流程图;
图 4是本发明实施例 1的功率补偿的方法的又一流程图;
图 5是本发明实施例 1的功率补偿的方法的又一流程图;
图 6是本发明实施例 1的基站的结构示意图;
图 7是本发明实施例 1的基站的又一结构示意图;
图 8是本发明实施例 1的用户设备的结构示意图;
图 9是本发明实施例 2的功率补偿的方法的流程图;
图 10是本发明实施例 2的功率补偿的方法的又一流程图; 图 11是本发明实施例 2的基站的结构示意图;
图 12是本发明实施例 2的基站的又一结构示意图;
图 13是本发明实施例 3的功率补偿的方法的流程图;
图 14是本发明实施例 3的功率补偿的方法的又一流程图; 图 15是本发明实施例 3的基站的结构示意图;
图 16是本发明实施例 3的用户设备的又一结构示意图;
图 17是本发明实施例的用户设备的系统构成图;
图 18是本发明实施例的用户设备的又一系统构成图。
具体实施方式
参照附图, 通过下面的说明书, 本发明的前述以及其它特征将变得 明显。 在说明书和附图中, 具体公开了本发明的特定实施方式, 其表明 了其中可以采用本发明的原则的部分实施方式, 应了解的是, 本发明不 限于所描述的实施方式, 相反, 本发明包括落入所附权利要求的范围内 的全部修改、 变型以及等同物。
本发明的实施方式以 LTE-A系统为例进行介绍, 涉及异构网络多点 协同传输和接收中的多天线增强技术、 测量机制和信令交互。 但是应该 理解, 本发明不限于该系统, 可用于任何采用多点协作技术的系统。
图 1是在下行链路上预编码处理的示意图, 图 2是在上行链路上解 码处理的示意图。如图 1和 2所示,基站侧可以包括地理上分布的基站 A 和协作节点 B, 通过基站 A和协作节点 B为用户设备提供服务。 其中, 基站 A可以为宏基站,可以包括多个天线;协作节点 B可以为 Pico基站、 RRH等, 也可以包括多个天线。
图 1和图 2仅为示意性说明, 本发明的系统结构不限于此, 例如还 可以包括更多的传输点。 值得注意的是, 本发明所述的基站侧仅相对于 用户设备而言, 可以包括基站以及协作节点。
实施例 1
本发明实施例提供一种功率补偿的方法, 应用于对上行信号的功率 进行补偿。 为了保持用户设备的向后兼容性, 本发明实施例在基站侧对 功率进行补偿。
图 3 是本发明实施例的功率补偿的方法的流程图, 应用于基站与协 作节点联合为用户设备服务的通信系统中。 如图 3所示, 该方法包括: 步骤 301,基站接收用户设备上报的路损值,或者根据用户设备上报 的参考信号接收功率值计算路损值; 该路损值用于指示用户设备与基站 侧之间的信号的功率损耗;
步骤 302,基站根据该路损值对来自用户设备的上行信号进行功率补 偿。
在本实施例中,参考信号接收功率(RSRP, Reference Signal Receiving Power)是 LTE-A网络中可以代表无线信号强度的关键参数。用户设备可 以根据现有标准获取 RSRP值, 可采用现有技术, 此处不再赘述。
在本实施例中, 用户设备可以根据 RSRP值估算路损值 (Pathloss ) , 该路损值用于指示用户设备与基站侧之间的信号的功率损耗。例如, RSRP 值为 -60dBm, 基站到用户设备的功率可预先设定为 30dBm, 则用户设备 可估算该 Pathloss值为 90dB。 以上仅为对估算 Pathloss值的示意性说明, 但不限于此, 可根据实际情况确定具体的计算方式。
在本实施例中, 用户设备可将 Pathloss值上报给基站。 基站接收到 该 Pathloss值之后, 可以根据该 Pathloss值进行接收功率的补偿。 或者, 用户设备也可将 RSRP值上报给基站,基站接收到该 RSRP值之后,可根 据该 RSRP值估算 Pathloss值, 然后根据该 Pathloss值进行接收功率的补 偿。
在具体实施时, 系统结构可如图 2所示, 基站侧包括地理上分布的 基站 A和协作节点 B。
在一个实施方式中, 基站和协作节点具有不同的小区标识, 基站 A 可以为宏基站, 协作节点 B可以为 Pico基站。 图 4是本发明实施例的功 率补偿的方法的又一流程图, 如图 4所示, 该方法包括:
步骤 401, 基站接收用户设备上报的 Pathloss值, 或者根据用户设备 上报的 RSRP值计算 Pathloss值。
具体地, Pathloss值可以包括信号从用户设备到基站的路损值、 以及 信号从用户设备到协作节点的路损值, 基站可以接收到多个 Pathloss值。
例如,基站 A可接收到用户设备上报的用户设备到基站 A的 Pathloss 值、 以及用户设备到协作节点 B的 Pathloss值。 值得注意的是, 这种情 况下, 需要基站 A将协作节点 B的发送功率通知给用户设备, 用户设备 根据该协作节点 B的发送功率和协作节点 B的 RSRP值, 估计出用户设 备到该协作节点 B的 Pathloss值。 此外, 也可以是用户设备上报协作节点 B的 RSRP值给基站 A, 由 该基站 A根据该协作节点 B的 RSRP值、以及该协作节点 B的发送功率, 来估计用户设备到该协作节点 B的 Pathloss值。
步骤 402, 基站根据 Pathloss值或者 Pathloss值的差值, 与协作节点 进行交互。
在本实施例中, 基站可以根据 Pathloss值与协作节点进行交互; 交 互的内容可包括: 用户设备到基站的 Pathloss值、用户设备到协作节点的 Pathloss值等, 或者二者之间的差值等。 可通过上层信令实现, 可采用现 有技术, 此处不再赘述。
步骤 403,基站根据交互结果调节接收机的放大器、或者通知协作节 点调节接收机的放大器, 以对上行信号进行功率补偿。
以下通过具体例子对上述方法进行说明。
例如, 用户设备向基站 A和协作节点 B发送的上行信号的功率均为 24dBm。 首先, 基站 A接收到用户设备上报的用户设备到基站 A的路损 值 Pathloss_A=90dB、 以及用户设备到协作节点 B的路损值 Pathloss_B= 80dB; 其次, 基站 A根据?& 1(^_八和?& 1(^_:8, 与协作节点 B进行 交互, 交互的内容可包括 80dB和 90dB、 或者二者的差值 10; 最后, 基 站 A根据交互结果调节放大器, 对来自用户设备的上行信号进行放大, 使得该上行信号的功率由 24-90=-66dBm变为 -56dBm, 而协作节点 B接 收到的来自用户设备的上行信号的功率不变,仍为 24-80=-56dBm。 由此, 可以使得在上行传输时, 各接收端的功率相同, 可以使用现有的 Codebook。
以上仅为对从基站侧进行上行信号的功率补偿的示意性说明, 但不 限于此, 可根据实际情况确定具体的实施方式。
在另一个实施方式中, 基站和协作节点具有相同的小区标识、 且分 别具有多个天线端口; 基站 A可以为宏基站, 协作节点 B可以为 RRH。
在具体实施时, 协作节点 B的多个天线可以看做是基站 A的延伸, 基站 A可以控制协作节点 B的天线, 即基站 A可以具有多个地理上分布 的不同的天线端口。 具体如何控制可采用现有技术实现, 此处不再赘述。
进一步地, 步骤 301具体为: 基站接收用户设备上报的多个天线端 口的 Pathloss值,或者根据用户设备上报的多个天线端口的 RSRP值计算 多个天线端口的路损值;
进一步地, 步骤 302具体为: 基站根据多个天线端口的 Pathloss值, 调节不同的天线端口的放大器, 以对来自用户设备的上行信号进行功率 补偿。
以下通过具体例子对上述方法进行说明。 例如, 用户设备向基站 A 和协作节点 B发送的上行信号的功率均为 24dBm。
首先, 基站 A接收到用户设备上报的用户设备到基站 A中 4个天线 端口的路损值 Pathloss_l=90dB、 Pathloss_2=90.01dB、 Pathloss_3= 90.02dB、 Pathloss_4=90.03dB; 以及用户设备到协作节点 B中 4个天线端 口的路损值 Pathloss_5=80dB、 Pathloss_6=80.51dB、 Pathloss_7= 80.52dB、 Pathloss_8= 80.53dB;
其次, 基站 A根据上述 Pathloss_l至 Pathloss_8, 调节基站 A和协作 节点 B的不同天线端口的放大器,对来自用户设备的上行信号进行放大; 使得基站 A 中的天线端口 1 接收到的上行信号的功率由 -66dBm 变为 -56dBm、天线端口 2接收到得上行信号的功率由 -66.01dBm变为 -56dBm、 天线端口 3接收到得上行信号的功率由 -66.02dBm变为 -56dBm、 天线端 口 4接收到得上行信号的功率由 -66.03dBm变为 -56dBm;
而协作节点 B中的天线端口 5不进行调整、 接收到得上行信号的功 率仍为 -56dBm, 天线端口 6接收到得上行信号的功率由 -56.51dBm变为 -56dBm,天线端口 7接收到得上行信号的功率由 -56.52dBm变为 -56dBm, 天线端口 8接收到得上行信号的功率由 -56.53dBm变为 -56dBm。 由此, 可以使得在上行传输时, 接收端各个天线端口的功率相同, 可以使用现 有的 Codebook。
以上仅为对从基站侧进行上行信号的功率补偿的示意性说明, 但不 限于此, 可根据实际情况确定具体的实施方式。
本发明实施例还提供一种功率补偿的方法,应用于用户设备侧。图 5 是本发明实施例的功率补偿的方法的又一流程图, 如图 5 所示, 该方法 包括:
步骤 501, 用户设备测量参考信号接收功率值; 步骤 502,根据测量到的参考信号接收功率值计算路损值,该路损值 用于指示用户设备与基站侧之间的信号的功率损耗;
步骤 503, 用户设备向基站上报路损值或者参考信号接收功率值。 由上述实施例可知, 根据用户设备上报的路损值或者参考信号接收 功率值, 基站侧可以对上行信号的功率进行补偿, 使得在上行传输时接 收端的功率相同, 从而可复用基于码本的传输方式。
本发明实施例还提供一种基站, 用于对上行信号的功率进行补偿。 图 6 是本发明实施例的基站的结构示意图, 应用于基站与协作节点联合 为用户设备服务的通信系统中。
如图 6所示, 该基站包括: 第一数值获取器 601和第一功率补偿器 602; 其中,
第一数值获取器 601接收用户设备上报的路损值, 或者第一数值获 取器 601 根据用户设备上报的参考信号接收功率值计算路损值; 路损值 用于指示用户设备与基站侧之间的信号的功率损耗;
第一功率补偿器 602根据路损值对来自用户设备的上行信号进行功 率补偿。
在一个实施方式中, 基站和协作节点具有不同的小区标识。 图 7是 本发明实施例的基站的又一结构示意图, 如图 7所示, 该基站包括: 第 一数值获取器 601和第一功率补偿器 602, 如上所述。
在本实施例中, 路损值包括信号从用户设备到基站的路损值、 以及 信号从用户设备到协作节点的路损值。 如图 7所示, 该基站还可以包括: 第一信息交互器 701 ;
第一信息交互器 701根据从用户设备到基站的路损值、 以及从用户 设备到协作节点的路损值, 或者二者之间的差值, 与该协作节点进行交 互;
进一步地, 第一功率补偿器 602具体用于: 根据交互结果调节接收 机的放大器、 或者通知协作节点调节接收机的放大器, 以对上行信号进 行功率补偿。
在另一个实施方式中, 基站和协作节点具有相同的小区标识、 且分 别具有多个不同的天线端口; 第一数值获取器 601具体用于: 接收用户设备上报的多个天线端口 的路损值, 或者根据用户设备上报的多个天线端口的参考信号接收功率 值计算多个天线端口的路损值;
第一功率补偿器 602具体用于: 根据多个天线端口的路损值, 调节 不同的天线端口的放大器, 以对上行信号进行功率补偿。
本发明实施例还提供一种用户设备, 用于对上行信号的功率进行补 偿。 图 8是本发明实施例的用户设备的结构示意图, 如图 8所示, 该用 户设备包括: 第一数值测量器 801、第一数值计算器 802和第一数值上报 器 803 ; 其中,
第一数值测量器 801用于测量参考信号接收功率值;
第一数值计算器 802用于根据测量到的参考信号接收功率值计算路 损值; 该路损值用于指示用户设备与基站侧之间的信号的功率损耗; 第一数值上报器 803向基站上报路损值或者参考信号接收功率值。 由上述实施例可知, 根据用户设备上报的路损值或者参考信号接收 功率值, 基站侧可以对来自用户设备的上行信号的功率进行补偿, 使得 在上行传输时各个接收端的功率相同, 从而可复用基于码本的传输方式。
实施例 2
本发明实施例提供一种功率补偿的方法, 用于从基站侧对下行信号 的功率进行补偿。 图 9 是本发明实施例的功率补偿的方法的流程图, 应 用于基站与协作节点联合为用户设备服务的通信系统中。
如图 9所示, 该方法包括:
步骤 901,基站接收用户设备上报的路损值,或者根据用户设备上报 的参考信号接收功率值计算路损值; 该路损值用于指示用户设备与基站 侧之间的信号的功率损耗;
步骤 902,基站根据路损值对向该用户设备发射的下行信号进行功率 补偿。
在本实施例中, 用户设备可将 Pathloss值上报给基站。 基站接收到 该 Pathloss值之后, 可以根据该 Pathloss值进行发射功率的补偿。 或者, 用户设备也可将 RSRP值上报给基站,基站接收到该 RSRP值之后,可根 据该 RSRP值估算 Pathloss值, 然后根据该 Pathloss值进行接收功率的补 偿。
在具体实施时, 系统结构可如图 1所示, 基站侧包括地理上分布的 基站 A和协作节点 B。
在一个实施方式中, 基站 A和协作节点 B具有不同的小区标识; 基 站 A可以为宏基站, 协作节点 B可以为 Pico基站。 图 10是本发明实施 例的功率补偿的方法的又一流程图, 如图 10所示, 该方法包括:
步骤 1001, 基站接收用户设备上报的 Pathloss值, 或者根据用户设 备上报的 RSRP值计算 Pathloss值;
具体地, Pathloss值可以包括信号从基站到用户设备的路损值、 以及 信号从协作节点到用户设备的路损值, 基站可以接收到多个 Pathloss值。
例如,基站 A可接收到用户设备上报的基站 A到用户设备的 Pathloss 值、 以及协作节点 B到用户设备的 Pathloss值。 值得注意的是, 这种情 况下, 需要基站 A将协作节点 B的发送功率通知给用户设备, 用户设备 根据该协作节点 B的发送功率和协作节点 B的 RSRP值, 估计出该协作 节点 B到用户设备的 Pathloss值。
此外, 也可以是用户设备上报协作节点 B的 RSRP值给基站 A, 由 该基站 A根据该协作节点 B的 RSRP值、以及该协作节点 B的发送功率, 来估计该协作节点 B到用户设备的 Pathloss值。
步骤 1002, 基站根据 Pathloss值或者 Pathloss值的差值, 与协作节 点进行交互;
具体地, 基站可以根据 Pathloss值与协作节点进行交互; 交互的内 容可包括:基站到用户设备的 Pathloss值、协作节点到用户设备的 Pathloss 值等, 或者二者之间的差值等。 可通过 X2口由上层信令实现, 可采用现 有技术, 此处不再赘述。
步骤 1003, 基站根据交互结果调节发射机的放大器、 或者通知协作 节点调节发射机的放大器, 以对下行信号进行功率补偿。
以下通过具体例子对上述方法进行说明。
例如, 基站 A向用户设备发送的下行信号的功率均为 45dBm, 协作 节点 B向用户设备发送的下行信号的功率为 30dBm。 首先, 基站 A接收 到用户设备上报的基站 A到用户设备的路损值 PathlOSS_A=90dB、以及协 作节点 B 到用户设备的路损值 Pathloss_B=80dB ; 其次, 基站 A 根据 ?& 1(½8_八和?& 1088_6, 与协作节点 B进行交互; 最后, 基站 A根据交 互结果调节发射机的放大器, 将发射功率由 45dBm调整为 40dBm, 使得 发送至该用户设备的下行信号的功率由 -45dBm变为 -50dBm;而不调整协 作节点 B , 协作节点 B发送至该用户设备的下行信号的功率不变, 仍为 -50dBm。 由此, 可以使得在下行传输时, 用户设备从基站和协作节点接 收到的信号功率相同, 可以使用现有的 Codeb00k。
以上仅为对从基站侧进行下行信号的功率补偿的示意性说明, 但不 限于此, 可根据实际情况确定具体的实施方式。
在另一个实施方式中, 基站 A和协作节点 B具有相同的小区标识、 且分别具有多个天线端口; 基站 A可以为宏基站, 协作节点 B 可以为 在具体实施时, 协作节点 B的多个天线可以看做是基站 A的延伸, 基站 A可以控制协作节点 B的天线, 即基站 A可以具有多个地理上分布 的不同的天线端口。 具体如何控制可采用现有技术实现, 此处不再赘述。
进一步地, 步骤 901具体为: 基站接收用户设备上报的多个天线端 口的路损值, 或者根据用户设备上报的多个天线端口的参考信号接收功 率值计算多个天线端口的路损值;
进一步地, 步骤 902具体为: 基站根据多个天线端口的路损值, 为 不同的天线端口分配不同的发射功率。
以下通过具体例子对上述方法进行说明。例如, 假定功率补偿之前, 基站 A的各个天线端口向用户设备发送的下行信号的功率均为 45dBm, 协作节点 B 的各个天线端口向用户设备发射的下行信号的功率均为 30dBm。
首先, 基站 A接收到用户设备上报的基站 A中 4个天线端口到用户 设备的路损值 Pathloss_l=90dB、Pathloss_2=90.01dB、Pathloss_3=90.02dB、 Pathloss_4=90.03dB; 以及协作节点 B中 4个天线端口到用户设备的路损 值 Pathloss_5=80dB、 Pathloss_6=80.51dB、 Pathloss_7=80.52dB、 Pathloss_8= 80.53dB;
其次, 基站 A根据上述 Pathloss_l至 Pathloss_8, 调节基站 A和协作 节点 B中发射机的不同天线端口的放大器, 使得天线端口 1不变, 该天 线端口 1 向该用户设备发射的下行信号的功率为 45dBm, 则用户设备接 收到的下行信号的功率为 -45dBm;
将天线端口 2 向该用户设备发射的下行信号的功率由 45dBm变为 45.01dBm、 将天线端口 3向该用户设备发射的下行信号的功率由 45dBm 变为 45.02dBm、 将天线端口 4 向该用户设备发射的下行信号的功率由 45dBm变为 45.03dBm、将天线端口 5向该用户设备发射的下行信号的功 率由 30dBm变为 35dBm、将天线端口 6向该用户设备发射的下行信号的 功率由 30dBm变为 35.51dBm、将天线端口 7向该用户设备发射的下行信 号的功率由 30dBm变为 35.52dBm、将天线端口 8向该用户设备发射的下 行信号的功率由 30dBm变为 35.53dBm; 由此, 该用户设备接收到的来自 各个天线端口的下行信号的功率均为 -45dBm。 可以使得在下行传输时, 用户设备从各个天线端口接收到的信号功率均相同, 可以使用现有的 Codebook。
以上仅为对从基站侧进行下行信号的功率补偿的示意性说明, 但不 限于此, 可根据实际情况确定具体的实施方式。
本发明实施例还提供一种基站, 用于对下行信号的功率进行补偿。 图 11是本发明实施例的基站的结构示意图, 应用于基站与协作节点联合 为用户设备服务的通信系统中。
如图 11所示, 该基站包括: 第二数值获取器 1101和第二功率补偿 器 1102; 其中,
第二数值获取器 1101用于接收用户设备上报的路损值, 或者第二数 值获取器 1101 用于根据用户设备上报的参考信号接收功率值计算路损 值; 该路损值用于指示用户设备与基站侧之间的信号的功率损耗;
第二功率补偿器 1102根据路损值对向该用户设备发射的下行信号进 行功率补偿。
在一个实施方式中, 基站和协作节点具有不同的小区标识。 图 12是 本发明实施例的基站的又一结构示意图, 如图 12所示, 该基站包括: 第 二数值获取器 1101和第二功率补偿器 1102, 如上所述。
在本实施例中, 路损值包括信号从基站到用户设备的路损值、 以及 信号从协作节点到用户设备的路损值。 如图 12所示, 该基站还包括: 第 二信息交互器 1201 ;
第二信息交互器 1201根据从基站到用户设备的路损值、 以及从协作 节点到用户设备的路损值, 或者二者之间的差值, 与该协作节点进行交 互;
进一步地, 第二功率补偿器 1102具体用于: 根据交互结果调节发射 机的放大器、 或者通知协作节点调节发射机的放大器, 以对下行信号进 行功率补偿。
在另一个实施方式中, 基站和协作节点具有相同的小区标识、 且分 别具有多个天线端口, 即基站侧具有多个地理上分布的不同的天线端口; 第二数值获取器 1101具体用于: 接收用户设备上报的多个天线端口 的路损值, 或者根据用户设备上报的多个天线端口的参考信号接收功率 值计算多个天线端口的路损值;
第二功率补偿器 1102具体用于: 根据多个天线端口的路损值, 为不 同的天线端口分配不同的发射功率。
由上述实施例可知, 根据用户设备上报的路损值或者参考信号接收 功率值, 基站侧可以对下行信号的功率进行补偿。 使得在下行传输时, 用户设备从各个发射端接收到的信号功率相同, 从而可复用基于码本的 传输方式。
实施例 3
本发明实施例提供一种功率补偿的方法, 用于从用户设备侧对下行 信号的功率进行补偿。
图 13是本发明实施例的功率补偿的方法的流程图, 应用于基站与协 作节点联合为用户设备服务的通信系统中。 如图 13所示, 该方法包括: 步骤 1301, 用户设备测量参考信号接收功率值;
步骤 1302,用户设备根据测量到的参考信号接收功率值计算路损值, 该路损值用于指示用户设备与基站侧之间的信号的功率损耗;
步骤 1303, 用户设备根据路损值对来自基站侧的下行信号进行功率 补偿。
在本实施例中, 用户设备可以根据现有标准获取 RSRP值, 可采用 现有技术, 此处不再赘述。 并且, 可以根据 RSRP值估算 Pathloss值, 可 如实施例 1所述。然后, 用户设备可以根据该 Pathloss值对下行信号进行 功率补偿。
在具体实施时, 系统结构可如图 1所示, 基站侧包括地理上分布的 基站 A和协作节点 B。
在一个实施方式中, 基站 A和协作节点 B具有不同的小区标识; 基 站 A可以为宏基站, 协作节点 B可以为 Pico基站。 图 14是本发明实施 例的功率补偿的方法的又一流程图, 如图 14所示, 该方法包括:
步骤 1401, 用户设备测量 RSRP值;
步骤 1402, 用户设备根据测量到的 RSRP值计算 Pathloss值; 具体地, Pathloss值可以包括信号从基站到用户设备的路损值、 以及 信号从协作节点到用户设备的路损值。
步骤 1403, 用户设备根据 Pathloss值或者 Pathloss值的差值, 与基 站进行交互;
具体地, 基站可以给用户设备配置测量事件 (measurement event) , 使得用户设备测量的服务小区信号和协作小区信号满足一定的条件的时 候, 就向服务小区的基站上报 measurement report。可通过上层信令实现, 可采用现有技术, 此处不再赘述。
步骤 1404, 用户设备根据交互结果调整放大器, 对来自基站的下行 信号、 或者来自协作节点的下行信号进行功率补偿。
以下通过具体例子对上述方法进行说明。
例如, 基站 A向用户设备发送的下行信号的功率为 45dBm, 协作节 点 B向用户设备发送的下行信号的功率为 30dBm。 首先, 用户设备得到 基站 A到用户设备的路损值 Pathloss_A=90dB、以及协作节点 B到用户设 备的路损值 Pathloss_B=80dB ; 其次, 用户设备根据 Pathloss_A 和 Pathl0SS_B, 与基站 A进行交互; 最后, 用户设备根据交互结果调节放大 器, 使得基站 A 发送至该用户设备的下行信号的功率由 -45dBm 变为 -50dBm; 而协作节点 B发送至该用户设备的下行信号的功率不变, 仍为 -50dBm。 由此, 可以使得在下行传输时, 用户设备从各个发射端接收到 的信号功率相同, 可以使用现有的 Codeb00k。 以上仅为对从用户设备侧进行下行信号的功率补偿的示意性说明, 但不限于此, 可根据实际情况确定具体的实施方式。
在另一个实施方式中, 基站 A和协作节点 B具有相同的小区标识、 且分别具有多个天线端口; 基站 A可以为宏基站, 协作节点 B 可以为 在具体实施时, 协作节点 B的多个天线可以看做是基站 A的延伸, 基站 A可以控制协作节点 B的天线, 即基站 A可以具有多个地理上分布 的不同的天线端口。 具体如何控制可采用现有技术实现, 此处不再赘述。
进一步地, 步骤 1301具体为: 用户设备测量多个天线端口的参考信 号接收功率值;
进一步地, 步骤 1302具体为: 用户设备根据测量到的多个天线端口 的参考信号接收功率值, 计算多个天线端口的路损值;
进一步地, 步骤 1303具体为: 用户设备根据多个天线端口的路损值 调整放大器, 对来自不同的天线端口的下行信号进行功率补偿。
在本实施例中, 在步骤 1301之前, 所述方法还可以包括: 用户设备 接收基站发送的测量多个天线端口的参考信号接收功率值、 或者计算多 个天线端口的路损值的通知。 根据该通知, 用户设备测量多个天线端口 的参考信号接收功率值、 或者计算多个天线端口的路损值。
以下通过具体例子对上述方法进行说明。例如, 假定功率补偿之前, 基站 A的各个天线端口向用户设备发送的下行信号的功率均为 45dBm, 而协作节点 B 的各个天线端口向用户设备发送的下行信号的功率均为 30dBm。
首先, 用户设备获取到基站 A中 4个天线端口到用户设备的路损值 Pathloss_l=90dB、 Pathloss_2=90.01dB、 Pathloss_3=90.02dB、 Pathloss_4= 90.03dB; 以及协作节点 B 中 4 个天线端口到用户设备的路损值 Pathloss_5=80dB、 Pathloss_6=80.51dB、 Pathloss_7=80.52dB、 Pathloss_8= 80.53dB;
其次, 用户设备根据上述 Pathloss_l至 Pathloss_8调节放大器, 使得 该用户设备接收到的来自各个天线端口的下行信号的功率均为 -45dBm。 由此, 可以使得在下行传输时, 用户设备从各个天线端口接收到的信号 功率相同, 可以使用现有的 Codebook。
以上仅为对从用户设备侧进行下行信号的功率补偿的示意性说明, 但不限于此, 可根据实际情况确定具体的实施方式。
本发明实施例还提供一种用户设备, 用于对下行信号的功率进行补 偿。 图 15是本发明实施例的基站的结构示意图, 应用于基站与协作节点 联合为用户设备服务的通信系统中。
如图 15所示, 该用户设备包括: 第二数值测量器 1501、第二数值计 算器 1502和第三功率补偿器 1503 ; 其中,
第二数值测量器 1501测量参考信号接收功率值;
第二数值计算器 1502用于根据测量到的参考信号接收功率值计算路 损值; 该路损值用于指示用户设备与基站侧之间的信号的功率损耗; 第三功率补偿器 1503根据路损值或者参考信号接收功率值,对来自 基站侧的下行信号进行功率补偿。
在一个实施方式中, 基站和协作节点具有不同的小区标识。 图 16是 本发明实施例的用户设备的又一结构示意图, 如图 16所示, 该用户设备 包括: 第二数值测量器 1501、 第二数值计算器 1502和第三功率补偿器 1503, 如上所述。
在本实施例中, 路损值包括信号从基站到用户设备的路损值、 以及 信号从协作节点到用户设备的路损值。 如图 16所示, 该用户设备还可以 包括: 第三信息交互器 1601 ;
第三信息交互器 1601用于根据从基站到用户设备的路损值、 以及从 协作节点到用户设备的路损值, 或者二者之间的差值, 与基站进行交互; 进一步地, 第三功率补偿器 1502具体用于: 根据交互结果调整放大 器, 以对来自基站的下行信号、 或者来自协作节点的下行信号进行功率 补偿。
在另一个实施方式中, 基站和协作节点具有相同的小区标识、 且分 别具有多个天线端口, 即基站侧具有多个地理上分布的不同的天线端口; 第二数值测量器 1501具体用于: 获取多个天线端口的参考信号接收 功率值;
第二数值计算器 1502具体用于: 根据测量到的多个天线端口的参考 信号接收功率值, 计算多个天线端口的路损值;
第三功率补偿器 1503具体用于: 根据多个天线端口的路损值调整放 大器, 对来自不同的天线端口的下行信号进行功率补偿。
在本实施例中, 用户设备还可以包括: 通知接收器, 接收基站发送 的测量多个天线端口的参考信号接收功率值、 或者计算多个天线端口的 路损值的通知。
由上述实施例可知, 用户设备获取路损值或者参考信号接收功率值 后, 对下行信号的功率进行补偿。 使得在下行传输时, 用户设备从各个 发射端接收到的信号功率相同, 从而可复用基于码本的传输方式。
图 17是本发明实施例的用户设备 1700的系统构成的示意框图, 其 中包括了实施例 1所述的第一数值测量器 801、第一数值计算器 802和第 一数值上报器 803。图 18是本发明实施例的用户设备 1800的系统构成的 示意框图, 其中包括了实施例 3所述的第二数值测量器 1501、 第二数值 计算器 1502和第三功率补偿器 1503。
图 17至图 18是示例性的; 还可以使用其他类型的结构, 来补充或 代替该结构, 以实现电信功能或其他功能。
如图 17至图 18所示,用户设备 1700、 1800还包括中央处理器 100、 通信模块 110、 输入单元 120、 音频处理单元 130、 存储器 140、 照相机 150、 显示器 160、 电源 170。
该中央处理器 100 (有时也称为控制器或操作控件,可以包括微处理 器或其他处理器装置和 /或逻辑装置) 接收输入并控制用户设备的各个部 分和操作。 输入单元 120 向中央处理器 100提供输入。 该输入单元 120 例如为按键或触摸输入装置。 照相机 150用于摄取图像数据, 并将摄取 的图像数据提供给中央处理器 100, 以按常规方式使用,例如,进行存储、 传送等。
电源 170用于向用户设备提供电力。 显示器 160用于进行图像和文 字等显示对象的显示。 该显示器例如可为 LCD显示器, 但并不限于此。
存储器 140耦合到中央处理器 100。该存储器 140可以是固态存储器, 例如, 只读存储器 (ROM)、 随机存取存储器 (RAM)、 SIM卡等。 还可 以是这样的存储器, 其即使在断电时也保存信息, 可被选择性地擦除且 设有更多数据,该存储器的示例有时被称为 EPROM等。存储器 140还可 以是某种其它类型的装置。存储器 140包括缓冲存储器 141 (有时被称为 缓冲器)。存储器 140可以包括应用 /功能存储部 142, 该应用 /功能存储部 142用于存储应用程序和功能程序或用于通过中央处理器 100执行用户设 备的操作的流程。
存储器 140还可以包括数据存储部 143,该数据存储部 143用于存储 数据, 例如联系人、 数字数据、 图片、 声音和 /或任何其他由用户设备使 用的数据。 存储器 140的驱动程序存储部 144可以包括用户设备的用于 通信功能和 /或用于执行用户设备的其他功能 (如消息传送应用、 通讯录 应用等) 的各种驱动程序。
通信模块 110 即为经由天线 111 发送和接收信号的发送机 /接收机 110。 通信模块 (发送机 /接收机) 110耦合到中央处理器 100, 以提供输 入信号和接收输出信号, 这可以和常规手机的情况相同。
基于不同的通信技术, 在同一用户设备中, 可以设置有多个通信模 块 110, 如蜂窝网络模块、 蓝牙模块和 /或无线局域网模块等。 通信模块 (发送机 /接收机) 110还经由音频处理器 130耦合到扬声器 131和麦克 风 132, 以经由扬声器 131提供音频输出, 并接收来自麦克风 132的音频 输入, 从而实现通常的电信功能。 音频处理器 130可以包括任何合适的 缓冲器、 解码器、 放大器等。 另外, 音频处理器 130还耦合到中央处理 器 100, 从而使得可以通过麦克风 132能够在本机上录音, 且使得可以通 过扬声器 131来播放本机上存储的声音。
本发明实施例还提供一种计算机可读程序, 其中当在用户设备中执 行该程序时, 该程序使得计算机在该用户设备中执行如实施例 1 至实施 例 3所述的功率补偿的方法。
本发明实施例还提供一种存储有计算机可读程序的存储介质, 其中 该计算机可读程序使得计算机在用户设备中执行如实施例 1 至实施例 3 所述的功率补偿的方法。
本发明实施例还提供一种计算机可读程序, 其中当在基站中执行该 程序时, 该程序使得计算机在该基站中执行如实施例 1至实施例 3所述 的功率补偿的方法。 本发明实施例还提供一种存储有计算机可读程序的存储介质, 其中 该计算机可读程序使得计算机在基站中执行如实施例 1至实施例 3所述 的功率补偿的方法。
本发明以上的装置和方法可以由硬件实现, 也可以由硬件结合软件 实现。 本发明涉及这样的计算机可读程序, 当该程序被逻辑部件所执行 时, 能够使该逻辑部件实现上文所述的装置或构成部件, 或使该逻辑部 件实现上文所述的各种方法或步骤。 本发明还涉及用于存储以上程序的 存储介质, 如硬盘、 磁盘、 光盘、 DVD、 flash存储器等。
以上结合具体的实施方式对本发明进行了描述, 但本领域技术人员 应该清楚, 这些描述都是示例性的, 并不是对本发明保护范围的限制。 本领域技术人员可以根据本发明的精神和原理对本发明做出各种变型和 修改, 这些变型和修改也在本发明的范围内。

Claims

权 利 要 求 书
1、 一种功率补偿的方法, 应用于基站与协作节点联合为用户设备服 务的通信系统中, 所述方法包括:
第一数值获取步骤, 所述基站接收用户设备上报的路损值, 或者根 据所述用户设备上报的参考信号接收功率值计算路损值; 所述路损值用 于指示所述用户设备与基站侧之间的信号的功率损耗;
第一功率补偿步骤, 所述基站根据所述路损值对来自所述用户设备 的上行信号进行功率补偿。
2、 根据权利要求 1所述的方法, 所述基站与协作节点具有不同的小 区标识, 所述路损值包括信号从用户设备到基站的路损值、 以及信号从 用户设备到协作节点的路损值;
在所述第一功率补偿步骤之前, 所述方法还包括:
第一信息交互步骤,所述基站根据所述从用户设备到基站的路损值、 以及所述从用户设备到协作节点的路损值, 或者二者之间的差值, 与所 述协作节点进行交互;
并且, 所述第一功率补偿步骤具体为: 所述基站根据交互结果调节 接收机的放大器、 或者通知所述协作节点调节接收机的放大器, 以对上 行信号进行功率补偿。
3、 根据权利要求 1所述的方法, 所述基站和协作节点具有相同的小 区标识、 且分别具有多个不同的天线端口;
所述第一数值获取步骤具体为: 所述基站接收所述用户设备上报的 多个天线端口的路损值, 或者根据所述用户设备上报的多个天线端口的 参考信号接收功率值计算所述多个天线端口的路损值;
所述第一功率补偿步骤具体为: 所述基站根据所述多个天线端口的 路损值, 调节不同的天线端口的放大器, 以对上行信号进行功率补偿。
4、 一种功率补偿的方法, 所述方法包括:
第一数值测量步骤, 用户设备测量参考信号接收功率值;
第一数值计算步骤, 根据测量到的所述参考信号接收功率值计算路 损值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损 耗;
第一数值上报步骤, 向所述基站上报所述路损值或者所述参考信号 接收功率值。
5、 一种功率补偿的方法, 应用于基站与协作节点联合为用户设备服 务的通信系统中, 所述方法包括:
第二数值获取步骤, 所述基站接收用户设备上报的路损值, 或者根 据所述用户设备上报的参考信号接收功率值计算路损值; 所述路损值用 于指示所述用户设备与基站侧之间的信号的功率损耗;
第二功率补偿步骤, 所述基站根据所述路损值对向所述用户设备发 射的下行信号进行功率补偿。
6、 根据权利要求 5所述的方法, 所述基站和协作节点具有不同的小 区标识, 所述路损值包括信号从基站到用户设备的路损值、 以及信号从 协作节点到用户设备的路损值;
在所述第二功率补偿步骤之前, 所述方法还包括:
第二信息交互步骤,所述基站根据所述从基站到用户设备的路损值、 以及所述从协作节点到用户设备的路损值, 或者二者之间的差值, 与所 述协作节点进行交互;
并且, 所述第二功率补偿步骤具体为: 所述基站根据交互结果调节 发射机的放大器、 或者通知所述协作节点调节发射机的放大器, 以对下 行信号进行功率补偿。
7、 根据权利要求 5所述的方法, 所述基站和协作节点具有相同的小 区标识, 且分别具有多个不同的天线端口;
所述第二数值获取步骤具体为: 所述基站接收所述用户设备上报的 多个天线端口的路损值, 或者根据所述用户设备上报的多个天线端口的 参考信号接收功率值计算所述多个天线端口的路损值;
所述第二功率补偿步骤具体为: 所述基站根据所述多个天线端口的 路损值, 为不同的天线端口分配不同的发射功率。
8、 一种功率补偿的方法, 应用于基站与协作节点联合为用户设备服 务的通信系统中, 所述方法包括:
第二数值测量步骤, 所述用户设备测量参考信号接收功率值; 第二数值计算步骤, 根据测量到的所述参考信号接收功率值计算路 损值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损 耗;
第三功率补偿步骤, 所述用户设备根据所述路损值对来自基站侧的 下行信号进行功率补偿。
9、 根据权利要求 8所述的方法, 所述基站和协作节点具有不同的小 区标识, 所述路损值包括信号从基站到用户设备的路损值、 以及信号从 协作节点到用户设备的路损值;
在所述第三功率补偿步骤之前, 所述方法还包括:
第三信息交互步骤, 所述用户设备根据所述从基站到用户设备的路 损值、 以及从协作节点到用户设备的路损值, 或者二者之间的差值, 与 所述基站进行交互;
并且, 所述第三功率补偿步骤具体为: 所述用户设备根据交互结果 调整放大器, 对来自所述基站的下行信号、 或者来自所述协作节点的下 行信号进行功率补偿。
10、 根据权利要求 8所述的方法, 所述基站与协作节点具有相同的 小区标识、 且分别具有多个不同的天线端口;
所述第二数值测量步骤具体为: 所述用户设备测量多个天线端口的 参考信号接收功率值;
所述第二数值计算步骤具体为: 根据测量到的所述多个天线端口的 参考信号接收功率值, 计算所述多个天线端口的路损值;
所述第三功率补偿步骤具体为: 所述用户设备根据所述多个天线端 口的路损值调整放大器, 对来自不同天线端口的下行信号进行功率补偿。
11、 根据权利要求 10所述的方法, 在所述第二数值测量步骤之前, 所述方法还包括:
通知接收步骤, 所述用户设备接收所述基站发送的测量所述多个天 线端口的参考信号接收功率值、 或者计算所述多个天线端口的路损值的 通知。
12、 一种基站, 应用于所述基站与协作节点联合为用户设备服务的 通信系统中, 所述基站包括: 第一数值获取器, 接收用户设备上报的路损值, 或者根据所述用户 设备上报的参考信号接收功率值计算路损值; 所述路损值用于指示所述 用户设备与基站侧之间的信号的功率损耗;
第一功率补偿器, 根据所述路损值对来自所述用户设备的上行信号 进行功率补偿。
13、 根据权利要求 12所述的基站, 所述基站与协作节点具有不同的 小区标识; 所述路损值包括信号从用户设备到基站的路损值、 以及信号 从用户设备到协作节点的路损值; 所述基站还包括:
第一信息交互器, 根据所述从用户设备到基站的路损值、 以及所述 从用户设备到协作节点的路损值, 或者二者之间的差值, 与所述协作节 点进行交互;
并且, 所述第一功率补偿器具体用于: 根据交互结果调节接收机的 放大器、 或者通知所述协作节点调节接收机的放大器, 以对上行信号进 行功率补偿。
14、 根据权利要求 12所述的基站, 所述基站与协作节点具有相同的 小区标识、 且分别具有多个不同的天线端口;
所述第一数值获取器具体用于: 接收所述用户设备上报的多个天线 端口的路损值, 或者根据所述用户设备上报的多个天线端口的参考信号 接收功率值计算所述多个天线端口的路损值;
所述第一功率补偿器具体用于: 根据所述多个天线端口的路损值, 调节不同的天线端口的放大器, 以对上行信号进行功率补偿。
15、 一种用户设备, 所述用户设备包括:
第一数值测量器, 测量参考信号接收功率值;
第一数值计算器, 根据测量到的所述参考信号接收功率值计算路损 值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损耗; 第一数值上报器, 向所述基站上报所述路损值或者所述参考信号接 收功率值。
16、 一种基站, 应用于所述基站与协作节点联合为用户设备服务的 通信系统中, 所述基站包括:
第二数值获取器, 接收用户设备上报的路损值, 或者根据所述用户 设备上报的参考信号接收功率值计算路损值; 所述路损值用于指示所述 用户设备与基站侧之间的信号的功率损耗;
第二功率补偿器, 根据所述路损值对向所述用户设备发射的下行信 号进行功率补偿。
17、 根据权利要求 16所述的基站, 所述基站和协作节点具有不同的 小区标识, 所述路损值包括信号从基站到用户设备的路损值、 以及信号 从协作节点到用户设备的路损值; 所述基站还包括:
第二信息交互器, 根据所述从基站到用户设备的路损值、 以及所述 从协作节点到用户设备的路损值, 或者二者之间的差值, 与所述协作节 点进行交互;
并且, 所述第二功率补偿器具体用于: 根据交互结果调节发射机的 放大器、 或者通知所述协作节点调节发射机的放大器, 以对下行信号进 行功率补偿。
18、 根据权利要求 16所述的基站, 所述基站和协作节点具有相同的 小区标识、 且分别具有多个不同的天线端口;
所述第二数值获取器具体用于: 接收所述用户设备上报的多个天线 端口的路损值, 或者根据所述用户设备上报的多个天线端口的参考信号 接收功率值计算所述多个天线端口的路损值;
所述第二功率补偿器具体用于: 根据所述多个天线端口的路损值, 为不同的天线端口分配不同的发射功率。
19、 一种用户设备, 应用于基站与协作节点联合为所述用户设备服 务的通信系统中, 所述用户设备包括:
第二数值测量器, 测量参考信号接收功率值;
第二数值计算器, 根据测量到的所述参考信号接收功率值计算路损 值; 所述路损值用于指示所述用户设备与基站侧之间的信号的功率损耗; 第三功率补偿器, 根据所述路损值对来自基站侧的下行信号进行功 率补偿。
20、 根据权利要求 19所述的用户设备, 所述基站和协作节点具有不 同的小区标识, 所述路损值包括信号从基站到用户设备的路损值、 以及 信号从协作节点到用户设备的路损值; 所述用户设备还包括: 第三信息交互器, 根据所述从基站到用户设备的路损值、 以及从协 作节点到用户设备的路损值, 或者二者之间的差值, 与所述基站进行交 互;
并且, 所述第三功率补偿器具体用于: 根据交互结果调整放大器, 以对来自所述基站的下行信号、 或者来自所述协作节点的下行信号进行 功率补偿。
21、 根据权利要求 19所述的用户设备, 所述基站和协作节点具有相 同的小区标识、 且分别具有多个不同的天线端口;
所述第二数值测量器具体用于: 获取多个天线端口的参考信号接收 功率值;
所述第二数值计算器具体用于: 根据测量到的所述多个天线端口的 参考信号接收功率值, 计算所述多个天线端口的路损值;
所述第三功率补偿器具体用于: 根据所述多个天线端口的路损值调 整放大器, 对来自不同天线端口的下行信号进行功率补偿。
22、 根据权利要求 21所述的用户设备, 所述用户设备还包括: 通知接收器, 接收所述基站发送的测量所述多个天线端口的参考信 号接收功率值、 或者计算所述多个天线端口的路损值的通知。
23、 一种计算机可读程序, 其中当在基站中执行所述程序时, 所述 程序使得计算机在所述基站中执行如权利要求 1至 3、或 5至 7的任意一 项权利要求所述的功率补偿的方法。
24、 一种存储有计算机可读程序的存储介质, 其中所述计算机可读 程序使得计算机在基站中执行如权利要求 1至 3、或 5至 7的任意一项权 利要求所述的功率补偿的方法。
25、 一种计算机可读程序, 其中当在用户设备中执行所述程序时, 所述程序使得计算机在所述用户设备中执行如权利要求 4、 或 8至 11的 任意一项权利要求所述的功率补偿的方法。
26、 一种存储有计算机可读程序的存储介质, 其中所述计算机可读 程序使得计算机在基站中执行如权利要求 4、 或 8至 11的任意一项权利 要求所述的功率补偿的方法。
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