 METHOD AND APPARATUS TO IMPLEMENT A USER CHANNEL AND EQUIPMENT MEASUREMENT
专利摘要:
method and apparatus for implementing a channel measurement and user equipment. the invention relates to a method and an apparatus for implementing a channel measurement. the method includes: determining an (s101) antenna port subset which is required for an UE according to the current status information of the UE user equipment; and informing (S102) that to perform the channel measurement for the antenna gate subset is required to be measured and return the channel state information. through the present invention, when the eu state information meets certain conditions. the eu measures only the reference signals from a part of antenna ports, and returns channel state information from this part of antenna ports. therefore, the excess generated by returning the ue to the channel state information is reduced. 公开号:BR112012010218B1 申请号:R112012010218-4 申请日:2010-10-28 公开日:2021-07-13 发明作者:Yajun Zhao;Jianguo Wang;Xingqing CHENG;Zuomin WU;Yan Cheng 申请人:Huawei Technologies Co., Ltd.; IPC主号:
专利说明:
FIELD OF THE INVENTION [0001] The present invention relates to the field of communications technologies, and specifically, to a method and an apparatus to implement channel measurement. BACKGROUND OF THE INVENTION [0002] OFDM (Orthogonal Frequency Division Multiplexing, orthogonal frequency division multiplexing) is a special multi-carrier transmission technology. This separates a large transmission bandwidth into multiple mutually orthogonal subcarriers to transmit data in parallel. [0003] In an OFDM system, to program the radio resources, the base station needs to obtain the downlink channel state information from the UE. Generally, the information is usually obtained after the UE (User Equipment, User Equipment) has measured and reported it. The measurement and reporting method mainly includes: The base station transmits a reference signal; and the UE uses the received reference signal to measure and obtain the downlink channel status information; and then the UE feeds back the downlink channel state information to the base station. The base station performs a radio resource scheduling for the received downlink channel status information that is fed back to the UE, and decides how to allocate a limited time and frequency resources for each UE, so as to maximize the usage of radio features. [0004] However, in the process of developing the present invention, it was discovered that in a MIMO system (Multiple Inputs Multiple Outputs), the base station has multiple antenna ports, and each antenna port has one reference signal to be sent. The UE needs to measure the channel state information of all antenna ports, and feed back the information to the base station. Therefore, the excess of measurement and feedback is enormous. SUMMARY OF THE INVENTION [0005] The present invention provides a method and an apparatus for implementing a channel measurement to reduce the excess generated by feedback from a UE to the channel state information. [0006] The present invention provides the following solutions: [0007] A method for implementing a channel measurement, which includes: determining an antenna gate subset, which is required to be measured, for a UE according to the current state information of the UE; and informing the UE to perform the channel measurement for the antenna gate subset that is required to be measured and feedback the channel state information. [0008] An apparatus for implementing a channel measurement, including: a determination unit, configured to determine an antenna gate subset, which is required to be measured, for a UE according to the current status information of the HUH; and an information unit, configured to inform the UE to perform the channel measurement for the antenna gate subset that is required to be measured and to feed back the channel state information. [0009] A user equipment, comprising: a notification receiving unit, configured to receive a notification sent by a base station and acquire an antenna gate subset that is required to be measured, wherein the antenna gate subset antenna that is required to be measured is determined by the base station according to the current status information of the UE; and a measurement and feedback unit, configured to perform a channel measurement for the antenna gate subset that is required to be measured and feedback the channel state information. [00010] A method for implementing a channel measurement, which includes: selecting an antenna gate subset that is required to be measured from pre-partitioned antenna gate subsets according to the current state information of a UE obtained from a base station; and performing a channel measurement for the antenna gate subset that is required to be measured and feedback channel state information. [00011] An apparatus for implementing a channel measurement, including: a selection unit, configured to select an antenna port subset that is required to be measured from pre-partitioned antenna port subsets according to the information of current state of a UE obtained from a base station; and a feedback unit, configured to perform a channel measurement for the antenna gate sub-assembly that is required to be measured and feedback the channel state information. [00012] According to the specific modalities of the present invention, the present invention describes the following technical effects: [00013] According to the embodiments of the present invention, the antenna port subset which is required to be measured can be selected for the UE according to the current status information of the UE and the UE is informed to perform the measurement from the channel to the antenna port subset that is required to be measured and the channel state information is fed back. By the present invention, when the UE status information meets certain conditions, the UE measures only the reference signals from an antenna ports part, and feeds back the channel status information to the antenna ports part. Therefore, the excess generated by the feedback from the UE to the channel state information is reduced. BRIEF DESCRIPTION OF THE DRAWINGS [00014] To make the technical solutions according to the embodiments of the present invention or prior art more clear, the following outlines the accompanying drawings to illustrate the embodiments. Of course, the accompanying drawings in the following description are merely about some embodiments of the present invention, and those skilled in the art can derive other drawings from such accompanying drawings without making any creative effort. [00015] Figure 1 is a flowchart of a method according to a first embodiment of the present invention; Figure 2 is a schematic diagram of a single-cell distributed antenna system in accordance with an embodiment of the present invention; Figure 3 is a flowchart of a method according to a second embodiment of the present invention; Figure 4 is a schematic diagram of an apparatus in accordance with an embodiment of the present invention; Figure 5 is a schematic diagram of another apparatus in accordance with an embodiment of the present invention; Figure 6 is a schematic diagram of a user equipment in accordance with an embodiment of the present invention; and Figure 7 is a schematic diagram of another apparatus in accordance with an embodiment of the present invention. DETAILED DESCRIPTION OF MODALITIES [00016] The technical solutions according to the embodiments of the present invention are clearly and completely described with reference to the accompanying drawings of the embodiments of the present invention. Of course, the embodiments to be described are merely some rather than all embodiments of the present invention. All other embodiments, which may be derived by those skilled in the art from the embodiments provided herein without making any creative effort, shall fall within the scope of protection of the present invention. [00017] Modality 1: As shown in Figure 1, a channel measurement method provided in Modality 1 of the present invention includes the following steps: [00018] S101: Select an antenna port subset which is required to be measured for a UE according to the current status information of the UE. [00019] S102: Inform UE to perform a channel measurement for the antenna gate subset that is required to be measured and feedback channel state information. [00020] The current status information of the UE can include the moving speed of the UE, the geographical location relationship between the UE and each antenna port, the path loss relationship information between the UE and each antenna port , and the current transmission mode of the UE. During selection, one or more antenna ports can be selected from all antenna ports of a base station according to the state information to form an antenna port subset that is required to be measured, and the UE is informed to measure and feed back only the channel state information between the UE and the antenna gate subset that is required to be measured. For example, the base station learns the geographic location relationship between the UE and each antenna port from information such as the signal strength reported by the UE, selects one or more antenna ports closest to the UE to form a subset of the UE ports. antenna that is required to be measured, and notifies the UE. After receiving the notification, the UE measures only the subset of antenna ports that is required to be measured, and does not measure antenna ports other than the subset of antenna ports. Thereafter, the UE feeds back the channel state information, which is obtained through the measurement and corresponds to the subset of the corresponding antenna ports, to the base station. [00021] In a practical application, for ease of selection, a set formed by the antenna ports on the base station can be partitioned into multiple antenna port subsets in advance. At the time of selecting the antenna gate subset which is required to be measured for the UE subsequently, the antenna gate subset can be selected for the UE from the partitioned antenna gate subsets according to the state information current of the EU. [00022] In this mode, the base station can notify the UE of all possible modes of sets in advance, and identify each set (for example, by numbering). When channel status information needs to be obtained, the identifier of one or more antenna gate subsets is notified to the UE according to the status of the UE. The UE performs a measurement and feedback for the channel state information based on a subset of a corresponding identifier. [00023] For example, N antenna ports are configured for base station A and the N antenna ports are partitioned into m antenna port subsets: N0, N1, N2, ..., and Nm. antennas may overlap each other. For example, N0 can include antenna port 1 and antenna port 2, and N1 can include antenna port 2 and antenna port 3, where antenna port 2 is on both N0 and N1. The specific partition can be determined according to actual conditions, which are not restricted here. Base station A can inform the UE to measure one or more or all of the antenna gate subsets among the m antenna gate subsets according to the UE status information, and then the UE feeds back the channel status information. measured for base station A. The following provides more details with reference to specific implementation modes. [00024] Implementation mode 1: In implementation mode 1, the set formed by all base station antenna ports can be partitioned into antenna port subsets, where the subsets are applicable at different UE movement speeds. That is, antenna gate subsets can be partitioned according to the time correlation of a channel. For example, the set of all antenna ports can be partitioned into two antenna port subsets. An antenna port subset is applicable to a high speed UE and sends a reference signal at a high frequency; and the other antenna port subset is applicable to a low speed UE and sends a reference signal at a relatively low frequency. [00025] When the UE is required to report the channel state information a high speed UE can be told to measure only the antenna gate subset which is applicable to the high speed UE and feed back the channel state information; and a low speed UE can be told to measure the antenna gate subset that is applicable to the low speed UE and feed back the channel state information. In this way, it can be ensured that the low-speed UE cannot waste resources and the high-speed UE can feed back the change of a channel state to the base station in time at a frequency that is high enough. Meanwhile, for both low speed UE and high speed UE it is not necessary to measure all antenna ports. Therefore, excess feedback is reduced, and overall system performance is improved. Definitely, for a low speed UE, both the high speed antenna gate subset and the low speed antenna gate subset can be measured. [00026] For example, all base station antenna ports can be grouped into antenna port subset A and antenna port subset B. A transmission period (high frequency) of antenna port subset A is short ; and a long transmission period of the antenna gate subset B is long (for example, the transmission period of the antenna gate subset A is 5 ms, and the transmission period of the antenna gate subset B is 10 ms). Furthermore, both UE1 and UE2 belong to the base station, where UE1 is a high-speed UE and UE2 is a low-speed UE. Therefore, the base station can inform UE1 to measure the antenna gate subset A and inform UE2 to measure the antenna gate subset; or tell UE2 to measure both antenna port A subset and antenna port subset B. [00027] In a practical application, the movement speeds of UEs can vary. For example, a user might be at a fixed location, a user might be walking, or a user might be on a means of transport that is moving quickly, and so on. The moving speed of a UE corresponds to the time correlation of a channel. For example, when UE1 moves at a low speed, the channel time correlation is stronger, and the channel state information obviously does not change with time, so the UE can feed back the channel state information to a lower frequency; conversely, when the UE moves at a high speed, the channel time correlation is weaker, and the channel state information can change very obviously over time, and therefore the UE may need to measure and feed back the channel information. channel state at a higher frequency to get the real-time channel state information more accurately. The frequency of the UE measuring and feedback channel status information is related to the frequency of the base station sending a reference signal. That is, when the base station sends the reference signal at a high frequency, the UE can measure and feed back the channel state information at a higher frequency; when the base station sends the reference signal at a low frequency, the UE needs to measure and feed back the channel state information at a low frequency. [00028] In the prior art, all base station antenna ports send reference signals on the same frequency. In fact, UEs under the same base station can be in different states, there is always a UE that is moving fast, and there is a UE that is moving slowly or even stationary. If all antenna ports send the reference signals at a higher frequency, as in relation to UEs that are slowly moving or even stationary, a waste of resources is inevitably caused because channel states change slowly and channel states do not need to be measured or fed back at a higher frequency. If all antenna ports send the reference signals at a lower frequency, as in relation to UEs that are rapidly moving the base station may be unable to obtain channel state information that is accurate enough. [00029] Through the method provided in implementation mode 1, each base station antenna port can send the reference signal at a different frequency. If a UE moves quickly, the UE can be told to measure the reference signal of the antenna gate subset which has a higher sending frequency; otherwise, the UE is told to measure the reference signal of the antenna gate subset which has a lower sending frequency. Therefore, implementation mode 1 has the following benefits: it can be ensured that a fast moving UE can feed back channel state information that is accurate enough and a slow moving UE can not cause a waste of resources. [00030] It should be noted that in a practical application, UE movement speeds may include more than high speed and low speed. For example, the moving speeds of the UE can be partitioned into several different ranges. Consequently, the antenna ports are partitioned into multiple antenna port subsets. When an antenna gate subset is specifically selected for the UE, at which interval the UE moving speed falls can be judged, and a corresponding antenna gate subset is selected. [00031] It should be noted that the base station can obtain the UE moving speed information through the UE uplink channel information, the specific method can be implemented in the prior art, and the details are not repeated here again . [00032] Implementation mode 2: In implementation mode 2, a set formed by all base station antenna ports can be partitioned into multiple antenna port subsets according to the geographic location of an antenna. For example, antenna ports geographically close to each other form an antenna port subset, and other antenna ports geographically close to each other form other antenna port subsets. When a UE is required to feed back channel state information, a subset of antenna ports whose distance to the UE meets a preset condition can be selected according to the current geographic location information of the UE; and/or, an antenna gate subset whose path loss to the UE meets a pre-set condition can be selected according to the path loss information between the current UE and each antenna gate subset (the information about path loss can be inferred according to the geographical location information of the UE or can be obtained from the uplink information of the UE). [00033] A single-cell distributed antenna system shown in Figure 2 is taken as an example. Both antenna gate subset N1 and antenna gate subset N2 which are geographically distributed at different locations belong to base station A; consequently, the reference signals used by base station A for channel measurement are partitioned into two antenna gate subsets A and B (the antenna gates are in a one-to-one mapping relationship with the reference signals), and these are transmitted by antenna gate subset N1 and antenna gate subset N2 respectively. PLij (i = 1, 2; j = 1, 2, 3) is the path loss of the antenna gate subset i for UEj. Considering the path loss difference of each antenna gate subset to the UE, the UE can use different antenna gate subsets. For example, a possible solution of allocating and measuring antenna ports is: UE1 measures a reference signal that corresponds to antenna port subset N1; UE3 measures a reference signal corresponding to antenna gate subset N2; and UE2 measures the reference signals corresponding to antenna gate subset N1 and antenna gate subset N2. [00034] In a practical application, multiple antenna ports of a base station can be distributed in multiple locations; and the relative relationship between the current location of the UE and the location of an antenna gate determines the quality of channel state information. [00035] For example, if the UE is close to an antenna port, the path loss of the UE receiving a signal may be less, and the signal received by the UE of the antenna port may be stronger, and therefore a channel status may be better; conversely, if the UE is too far away from an antenna port, the path loss of the UE receiving a signal may be greater, and the signal received by the UE of the antenna port may be much weaker, and therefore a state channel can be worse. In this case, the channel state information from the very distant antenna port may have little impact on the radio resource programming performed by the radio station, and finally, the service information created by the antenna port may be little or even the antenna port is not used to contain the UE service information. Therefore, in the case that all antenna ports are measured and channel state information is fed back, channel state measurement and feedback to the very distant antenna ports lead to a waste of resources. [00036] By the method provided in implementation mode 2, the UE can be informed not to measure the reference signal of the antenna gate subset too far from the UE, and not to feed back the corresponding channel state information. Therefore, over-measuring and feedback is reduced. [00037] It should be noted that the base station can obtain the geographical location information of the UE through the uplink channel information of the UE, the specific method can be implemented in the prior art, and the details are not repeated here again. [00038] Implementation mode 3: In a practical application, a base station can select a different transmission mode for a UE according to the status information of the UE, to ensure that the UE gets the best quality of service and ensures the better performance of a system. Transmission modes can include: CoMP mode (Coordinated Multiple Points Transmission, Coordinated Multiple Points Transmission), CBF mode (Coordinated beamforming, Coordinated beamforming), JP mode (Common Processing, common processing), CBF mode (Coordinate Beam Switching, coordinate beam switching), single cell service mode, multiple user mode, and so on. [00039] In implementation mode 3, a set of all base station antenna ports can be partitioned into antenna port subsets applicable to different transmission modes. For example, some antenna ports may be grouped as an antenna port subset applicable to a single-cell mode of service. Thus, when the UE is required to feed back the channel status information, an antenna port subset applicable to the transmission mode of the UE can be selected according to the current transmission mode used by the UE, and then the UE is informed to feed back the channel state information to the base station with respect to the antenna gate subset applicable to the transmission mode of the UE. For example, UE1 is in CoMP mode, and therefore, the base station informs UE1 to measure only the set of reference signals in CoMP mode and feed back the corresponding channel state information. [00040] In practical application, in different transmission modes, a special configuration may be required for sending the reference signal. For example, when a UE is in CoMP mode, a power boost (power boost) needs to be performed for the transmit power of the reference signal. In the prior art, the transmit power of the antenna ports needs to be stepped up. However, other UEs belonging to the base station may be in other modes such as single cell service mode. In such modes, a high transmit power is not required. Therefore, in this case, for the UEs that are not in CoMP mode, the high transmit power of the reference signal leads to a kind of waste obviously. [00041] In the method provided in implementation mode 3, as the antenna ports are partitioned in advance, only the reference signal sent by the antenna port subset applicable to the CoMP mode can be configured according to the characteristic of the mode. CoMP, and special processing may not be performed for another antenna port subset. Therefore, another merit of the implementation mode is: When CoMP mode exists, a special configuration performed for the reference signals of all antenna ports can be avoided, and resources are saved. [00042] For example, for the antenna gate subset reference signal applicable to CoMP mode, within a CoMP cell set, the data of a neighboring cell on an RE (resource element, resource element) which corresponds to the reference signal are not sent; for the reference signal of another antenna gate subset not applicable to CoMP mode, within the CoMP cell set, the data from the neighboring cell in the RE corresponding to the reference signal is still sent, namely, no special configuration is performed. [00043] Alternatively, power enhancement may be performed for the applicable antenna gate subset reference signal for CoMP mode, and power amplification may not be performed for the antenna gate subset reference signal not applicable to CoMP mode. [00044] Still, for example, for the reference signal of the antenna gate subset applicable to the CoMP mode, within the CoMP cell set, the reference signal corresponding to each cell is configured as code partition quadrature or frequency partition quadrature; for the reference signal of another antenna gate subset not applicable to CoMP mode, within the CoMP cell set, the reference signal corresponding to each cell may not be configured as code partition quadrature or partition quadrature frequency. [00045] It should be noted that after the antenna ports are grouped into subsets according to the transmission modes, only the reference signal sent by the antenna port subset applicable to the CoMP mode can be configured according to the characteristics of the CoMP mode; after completion of grouping and configuration, each subset of antenna ports can send the reference signal according to the configured mode, without being affected by the state of the UE. [00046] Further, it should be noted that because the UE can be in a standard transmission mode in an initial state, the base station needs to decide, according to the channel state information fed back by the UE, whether to change the mode of transmission from the UE. Therefore, in implementation mode 3, the UE can feed back the channel state information of all antenna ports first; and then, when the base station selects a new transmission mode for the UE according to the channel state information of the UE, the base station informs the UE to feed back the channel state information to only the antenna port applicable to the transmission mode. Definitely, after a transmission mode is selected for the UE, another transmission mode can be selected for the UE according to the new status information. In this case, a corresponding antenna gate subset can be selected again, and then the UE is told to measure the antenna gate subset and perform the feedback. [00047] Definitely, the above implementation modes can be combined to partition the base station antenna ports according to multiple partition factors. At the time of selecting an antenna gate subset for the UE, a subset can be selected from antenna gate subsets under a corresponding grouping mode according to any of the state information obtained from the UE. [00048] At the time of selecting a subset of antenna ports for the UE from the pre-partitioned antenna port subsets according to the current state information of the UE, the number of selected antenna port subsets required to be measured is one or more. [00049] When the number of antenna port subsets required to be measured is one, the UE can perform a channel measurement based on the notified reference signal of the antenna port subset, and obtain the channel status information that correspond to the antenna port subset. When the number of antenna port subsets required to be measured is more than one, the channel state information that can be fed back by the UE may include not only the channel state information of each antenna port subset, but also the channel state cross-correlation information between the subsets so as to reflect the channel state information more accurately. The combination modes involved by the cross-correlation information can be diverse. However, as it is required to make the base station know what kinds of information are fed back by the UE, the UE cannot feed back the cross-correlation information arbitrarily; otherwise, the base station is unable to identify the type of information. Therefore, in a practical application, a way that the base station notifies the UE about what information needs to be fed back, for example, the UE can be told to feed back the following information: (i) The UE can be told to perform the measurement of channel for the reference signal of each antenna gate subset that is required to be measured and fed back by the channel state information of each antenna gate subset that is required to be measured. For example, UE1 is notified that reference signals of antenna gate subsets N1, N2, and N3 are required to be measured, and then UE1 can obtain the channel state information CSI1/CQI1/PMI1/RI1 between UE1 and the antenna port subset N1, the channel state information CSI2/CQI2/PMI2/RI2 between UE1 and the antenna port subset N2, the channel state information CSI3/CQI3/PMI3/RI3 between UE1 and the N3 antenna port subset. Subsequently, UE1 feeds back CSI1/CQI1/PMI1/RI1, CSI2/CQI2/PMI2/RI2, and CSI3/CQI3/PMI3/RI3 obtained through measurement to the base station; and the base station performs a radio resource schedule for the UE1 and other UEs in accordance with the channel state information fed back by the UE1 and other UEs. (ii) The UE may be told to perform channel measurement for the reference signal of each antenna gate subset that is required to be measured and feed back the channel state information of each antenna gate subset that is required to be measured and the channel state cross correlation information between the antenna gate subsets required to be measured. For example, UE1 is notified that antenna gate subsets N1, N2, and N3 are required to be measured, and then UE1 obtains the CSI1 channel state information between UE1 and the antenna gate subset N1 , the channel state information CSI2 between UE1 and the antenna gate subset N2, and the channel state information CSI3 between UE1 and the antenna gate subset N3. Meanwhile, R12 information about channel state cross correlation between UE1 and N1 and N2, and/or R13 information about channel state cross correlation between UE1 and N1 and N3, and/or R23 information about cross correlation of channel state between UE1 and N2 and N3, and/or the information R123 about channel state cross correlation between UE1 and N1, N2 and N3 is obtained by measuring. Subsequently, UE1 feeds back CSI1, CSI2, CSI3, R12, R13, R23, and R123 to the base station; and the base station performs a radio resource scheduling for UE1 and another UE in accordance with the channel state information fed back by the UE1 and other UEs. [00050] Feedback from the channel state cross-correlation information, the base station can know not only the channel state information of each channel, but also the cross-correlation between the channels, in order to provide more effective information for scheduling. radio feature. It should be noted that, in theory, channel state cross-correlation information can be obtained by the base station through calculation after the base station receives the channel state information of each channel. However, the channel state cross-correlation information is obtained by the UE through calculation because the UE generally needs to process the channel state information to facilitate transmission on a channel before the UE feeds back the channel state information to the base station. Therefore, the channel state information obtained by the base station is processed by the UE. If the base station calculates the channel state cross correlation information between the channels after receiving the channel state information, the information is not accurate. However, the UE can obtain the channel state cross-correlation information by calculating according to the original channel measurement data, so as to ensure the accuracy of the channel state cross-correlation information. (iii) All antenna gate subsets required to be measured are combined, and the UE is informed to perform a channel measurement based on the reference signals of all antenna gate subsets required to be measured, and feedback the channel state information of all antenna port subsets combined. For example, UE1 is notified that antenna port subset N1 and antenna port subset N2 are required to be measured, where N1 includes antenna ports 1 and 2, and N2 includes antenna ports 3 and 4, and therefore, UE1 obtains the CSI12 channel state information between UE1 and all antenna ports (antenna ports 1, 2, 3, and 4) on N1 and N2 through calculation, and then feeds back CSI12 to the base station ; and the base station performs a radio resource schedule for the UE1 and another UE in accordance with the channel state information fed back by the UE1 and another UE. (iv) A part of the antenna gate subsets required to be measured is combined and the UE is told to perform the channel measurements based on the reference signals of the partially matched antenna gate subsets required to be measured, and to feed back the channel state information of each antenna gate subset combination, and/or channel state cross correlation information between each two antenna gate subset combinations. For example, UE1 is notified that antenna gate subsets N1, N2, N3, and N4 are required to be measured, and the base station can combine antenna gate subsets N1 with N2 and match N3 with N4; UE1 is told to measure the channel state information of N12 to obtain CSI12, where N12 is a combination of antenna gate subset N1 and antenna gate subset N2; and measuring the channel state information of N34 to obtain CSI34, where N34 is a combination of antenna gate subset N3 and antenna gate subset N4; meanwhile, R1234 information about channel state correlation between N12 and N34 can be obtained by calculation. Afterwards, CSI12, CSI34, and R1234 are fed back to base station A. [00051] Definitely, other partial combinations apply. For example, the base station can inform UE1 to measure channel state information N13 to obtain CSI13, where N13 is a combination of antenna gate subset N1 and antenna gate subset N3; and measuring the channel state information of N24 to obtain CSI24, where N24 is a combination of antenna gate subset N2 and antenna gate subset N4; meanwhile, R1324 information about channel state correlation between N13 and N24 can be obtained through measurement. Thereafter, UE1 feeds back CSI13, U2CSI24, and R1324 to base station A. The base station performs a radio resource scheduling for UE1 and other UEs in accordance with the channel state information fed back by UE1 and other UEs. Definitely, according to a different number of antenna gate subsets, the partial combination modes are diverse, and the details are not exhaustively illustrated here. [00052] It should be noted that the channel state information of an antenna port subset is obtained by measuring the reference signal of each antenna port in the antenna port subset. The channel state cross-correlation information between the antenna port subsets reflects the cross-correlation between the antenna port subsets. For example, with reference to the channel state cross correlation information between N1 and N2, the channel state information CSI1 of N1 and the channel state information CSI2 of N2 may need to be calculated first before the correlation between the two is calculated. However, the channel state information of N12 which is a combination of antenna gate subsets N1 and N2 is obtained by measuring the reference signal of each antenna gate on N1 and measuring the reference signal of each gate of antenna on N2. That is, the two antenna gate subsets are combined, and then the channel state information from the combination is obtained. For example, N1 includes antenna ports 1 and 2, N2 includes antenna ports 3 and 4, and the channel state information of the combined subset antenna port N12 is calculated according to the reference signals of ports of antenna 1, 2, 3, and 4 directly. [00053] Persons skilled in the art will understand that all or part of the steps of the method specified in the above modality can be implemented by a program that informs the relevant hardware. The program can be stored on a computer-readable medium. When the program executes, the following steps are included: determining an antenna port subset, which is required to be measured, for a UE according to the current state information of the UE user equipment; and informing the UE to perform the channel measurement for the antenna gate subset that is required to be measured and feedback the channel state information. The storage medium can be a ROM / RAM, magnetic disk, CD-ROM or others. [00054] Modality 2: As shown in Figure 3, a channel measurement method provided in Modality 2 includes the following steps: [00055] S301: Select an antenna gate subset, which is required to be measured from pre-partitioned antenna gate subsets according to the current state information of a UE obtained from a base station. [00056] It should be noted that a UE can obtain its own status information (including the current transmit status of the UE, geographic location, path loss, and movement speed) from the base station's downlink channel information. The downlink channel message may not exclusively be used as a channel measurement indication, but the UE may obtain the required status information from the message as long as the UE can receive the message. Furthermore, as the status information is obtained from the base station's downlink channel message, it can be ensured that the base station is also aware of the current status of the UE. In this way, the base station can precisely obtain the basis for the UE to select a subset of antenna gate, and can accurately analyze the information fed back by the UE. [00057] S302: Perform a channel measurement for the antenna port subset that is required to be measured and feedback channel status information. [00058] Specifically, when the UE selects an antenna gate subset that is required to be measured from pre-partitioned antenna gate subsets according to the UE current state information obtained by the base station, the UE can obtain the UE current state information of the base station first, and then selecting an antenna gate subset that is required to be measured from the pre-partitioned antenna gate subsets according to a mapping relationship between the UE current state information and the antenna gate subset, where the mapping relationship is pre-negotiated with the base station. In addition, the UE may feed back the antenna gate subset identification information to the base station while feeding back the channel state information to the base station. [00059] When the number of antenna gate subsets required to be measured is greater than one, the UE needs to feedback a channel state in a mode that can be identified by the base station. Specific implementation modes may include the following. Mode 1: The UE feeds back the channel state information in a pre-negotiated mode with the base station, for example, the base station notifies the UE in advance for information such as the channel state information feedback order and /or the way to combine the antenna port subsets (the information can be carried out in the notification to the UE indicating how the antenna ports are grouped), so that the base station identifies and analyzes the information correctly; Mode 2: The UE at will selects the feedback order of the channel status information and/or the mode of combining the antenna port subsets and so on. However, in mode 2, it is required to feedback the antenna port subset identification information and/or the antenna port subset combination identification information to the base station at the time of feedback channel state information. , so the base station can identify and analyze the information correctly. Specifically, information such as the antenna port subset identifier and/or the combination identifier is added in a message used to feed back the channel state information to notify the base station of the channel state information feedback order. selected and how to combine the antenna port subsets, and so on. [00060] Modality 2 differs from Modality 1 in that: In Modality 1, the base station selects the antenna gate subset, which is required to be measured, to the UE when the UE is required to feed back the status information of channel; in Modality 2, the result and grouping factors of the antenna ports are notified to the UE in advance, and the UE can automatically select a corresponding antenna port subset to perform the measurement according to the status information of the UE, and feedback channel status information. That is, the entity to perform each step in Modality 1 is the base station, and the entity to perform each step in Modality 2 is a UE. [00061] The specific method of grouping the antenna ports into subsets may be the same as that described in Modality 1, and the details are not further repeated here. [00062] The following describes Modality 2 in detail through a specific example. [00063] For example, when antenna ports are grouped into subsets according to the transmission mode of the UE, the base station can notify the UE of all possible modes of sets in advance, and identify a transmission mode that matches to each set. When the UE is in a certain transmission mode, the UE measures and feeds back the channel state information for a set of the corresponding mode. In addition, a mode switching identifier can be determined. If the switching identifier notified by the cell in advance to the UE refers to automatically switching according to the transmission mode, then the UE measures and feeds back the channel state information to the corresponding mode set when the UE is in a certain mode of transmission; otherwise, even if the UE is in a certain transmission mode the UE may not switch the automatically measured set. [00064] In this mode, as the base station is aware of the current transmission mode of the UE, the base station can learn the antenna gate subset whose channel state information is fed by the UE. It can be seen that, in the method provided in Modality 2, the example is a preferred implementation mode. [00065] Persons versed in the art understand that all or part of the steps of the method specified in the above modality can be implemented by a program informing a relevant hardware. The program can be stored on a computer-readable storage medium. When the program executes, the following steps are included: selecting an antenna gate subset, which is required to be measured from pre-partitioned antenna gate subsets according to the current state information of a UE obtained from a base station ; and performing channel measurement for the antenna gate subset that is required to be measured and feedback channel state information. The storage medium can be a ROM / RAM, magnetic disk, CD-ROM or others. [00066] Corresponding to the method provided in Embodiment 1 of the present invention, an embodiment of the present invention provides an apparatus for implementing channel measurement. As shown in Figure 4, the apparatus includes: a determination step U401, configured to determine an antenna gate subset which is required to be measured, for a UE according to the current status information of the UE equipment; and an information unit U402 configured to inform the UE to perform a channel measurement for the antenna gate subset that is required to be measured and feedback channel status information. [00067] Through the apparatus provided in the embodiment of the present invention, in view of the UE status information, the base station can inform the UE to measure and feedback only the channel status information of a part of antenna ports. Therefore, the excess generated by the feedback from the UE to the channel state information is reduced. [00068] In a practical implementation, an antenna port applicable to the current state of the UE can be determined from multiple base station antenna ports directly, and the antenna ports (may be one or more antenna ports) serve as a subset of antenna port that is required to be measured; or an antenna gate subset can be partitioned into multiple antenna gate subsets in advance, and then a gate antenna subset that is required to be measured is selected from the antenna gate subsets according to the current state information of the EU. In this case, as shown in Figure 5, the U402 determination unit may include: a U4021 selection sub-unit configured to select an antenna gate subset which is required to be measured from pre-partitioned antenna gate subsets, to the UE according to the current status information of the UE; or, a second selection sub-unit, configured to select one or more antenna ports from all base station antenna ports in accordance with the current state information of the UE to form an antenna port subset that is required to be measured . [00069] If an antenna port subset is partitioned into multiple antenna port subsets in advance, the partition can be based on multiple factors, for example, the partition can be performed according to a time correlation of one channel. In this case, the antenna gate subsets may include antenna gate subsets applicable to different UE moving speeds, the UE current state information includes the UE current moving speed; and the selection sub-unit U4021 may include: a first selection sub-unit, configured to select an antenna gate subset applicable to the moving speed of the UE according to the current moving speed of the UE. [00070] In a distributed antenna system, the antenna ports can be grouped into subsets according to the geographic locations of the antenna ports. In this case, the antenna gate subsets may include an antenna gate subset grouped according to geographic antenna locations; and the UE current state information includes the path loss information between the UE and each antenna port subset and/or the UE current geographic location information; and the selection sub-unit U4021 may include: a second selection sub-unit, configured to select an antenna gate sub-set whose path loss to the UE meets a preset condition, in accordance with the path loss information between the UE and each antenna port subset; and/or, a third selection sub-unit, configured to select an antenna gate subset whose distance to the UE meets a preset condition, in accordance with the current geographic location information of the UE. [00071] Antenna ports can also be grouped into subsets according to the transmission mode of the UE. In this case, the antenna gate subsets include an antenna gate subset applicable to different transmission modes; UE current state information includes the current transmission mode used by the UE; and the selection sub-unit U4021 may include: a fourth selection sub-unit, configured to select an antenna gate subset applicable to the transmission mode of the UE according to the current transmission mode used by the UE. [00072] Transmission modes may include a CoMP transmission mode. When the antenna ports are grouped according to a transmission mode possibly used by the UE, a special configuration can be performed for only the reference signal sent by an antenna port subset applicable to the CoMP mode, and the special configuration can not necessarily be performed for the reference signal from another antenna port. In this case, a system may further include: a configuration unit, configured to configure only the reference signal sent by the antenna port subset applicable to the CoMP transmission mode according to the characteristics of the CoMP transmission mode. [00073] If at least two antenna gate subsets required to be measured are selected from the pre-partitioned antenna gate subsets the information unit U402 may include: a first information sub-unit, configured to inform the UE to perform a channel measurement for the reference signal of each antenna gate subset that is required to be measured, and feedback channel state information of each antenna gate subset that is required to be measured; or, a second information sub-unit, configured to inform the UE to perform a channel measurement for the reference signal of each antenna gate subset that is required to be measured, and to feed back the channel status information of each subset of antennas. antenna gate that is required to be measured and information about a channel state cross correlation between each two antenna gate subsets required to be measured; or, a third information sub-unit, configured to combine all antenna gate subsets required to be measured, and inform the UE to perform channel measurement based on reference signals of all antenna gate subsets required to be measured. combined measured and feedback channel state information from each combination of all antenna port subsets; or, a fourth information sub-unit, configured to: combine a portion of antenna gate subsets required to be measured, and inform the UE to perform the channel measurement based on reference signals of the antenna gate subsets required to be measured. measured partially combined and feedback channel state information from each combination of the antenna gate subsets, and/or channel state cross correlation information between each two combinations of the antenna gate subsets. [00074] Corresponding to the method and apparatus provided in Modality 1, an embodiment of the present invention provides a user equipment. As shown in Figure 6, the user equipment includes: a notification receiving unit U601, configured to receive a notification sent by a base station and acquire an antenna gate subset that is required to be measured, where the gate subset of antenna that is required to be measured is determined by the base station according to the current state information of the user equipment; and a measurement and feedback unit U602, configured to perform a channel measurement for the antenna gate subset that is required to be measured and feedback channel state information. [00075] The content such as the base station specific method that determines a subset of antenna gate which is required to be measured, according to the current status information of the UE is the same as the above description, and the details are not repeated here again. [00076] Corresponding to the method provided in Modality 2, an embodiment of the present invention provides another apparatus for implementing the channel measurement. Referring to Figure 7, the apparatus includes: a selection unit U701, configured to select an antenna gate subset which is required to be measured from pre-partitioned antenna gate subsets according to the current state information of a UE obtained from a base station; and a feedback unit U702 configured to perform a channel measurement for the antenna gate subset that is required to be measured and feedback the channel status information. [00077] Through the apparatus provided in this modality, according to the status information of a UE obtained from the base station and partition of the antenna gate subsets which are acquired from the base station in advance, the UE can select a subset of the antenna gate. antenna that is required to be measured, in order to measure and feed back only the channel state information of a part of antenna ports. Therefore, the excess generated by the feedback from the UE to the channel state information is reduced. [00078] Specifically the U702 selection unit may include: an auto-state information obtaining sub-unit, configured to obtain the current state information of the base station UE; and a selection sub-unit configured to select an antenna gate subset that is required to be measured from the pre-partitioned antenna gate subsets according to a mapping relationship between the UE current state information and the gate subset antenna, where the mapping relationship is pre-negotiated with the base station. [00079] When feedback the channel state information to the base station, the UE can feedback the identification information of the actually measured antenna gate subset. In this case, the apparatus may further include: an identification information feedback unit, configured to feed back identification information from the antenna port sub-assembly to the base station. [00080] When the antenna port subsets required to be measured are at least two, the feedback unit U702 includes: a feedback subunit as stipulated, configured to: according to the feedback order of the channel status information and /or a combination mode of the antenna gate subsets, perform the channel measurement for the antenna gate subset that is required to be measured and feed back the channel state information, where the order and/or the combination mode are pre-negotiated with the base station; or [00081] a discretion feedback unit, configured to: select the feedback order of the channel state information and/or a combination mode of antenna port subsets automatically, perform a channel measurement for the antenna port subset antenna that is required to measure and feed back channel status information; and feeding back the antenna port sub-assembly identification information and/or the identification information of a combination of antenna port sub-assemblies. [00082] The above describes in detail a method and apparatus for implementing the channel measurement according to the present invention. Although the principle and implementation of the present invention are described through some specific examples, the descriptions of the modalities are merely for a better understanding of the method and core idea of the present invention, and based on the idea of the present invention, those versed in the art can make modifications to the specific implementation and scope of application of the present invention. In conclusion, the content of the specification should not be considered as a limitation on the present invention.
权利要求:
Claims (18) [0001] 1. Method for implementing a channel measurement, characterized in that it comprises the steps of: determining (S101) an antenna gate subset, which is required to be measured, for a user equipment (UE) in accordance with the current state information of the UE, where the antenna port subset consists of one or more antenna ports from all antenna ports; and informing (S102) the UE to perform the channel measurement for the antenna gate subset that is required to be measured and feedback channel state information; wherein: the step of determining (S101) the antenna gate subset which is required to be measured, for a UE according to the current status information of the UE comprises: selecting the antenna gate subset, which is required to be measured, from pre-partitioned antenna gate subsets, for the UE according to the current state information of the UE; and wherein: the antenna gate sub-assemblies comprise an antenna gate sub-assembly applicable to different speeds of movement of UEs; the current state information of the UE comprises a current moving speed of the UE; and selecting the antenna port subset, which is required to be measured, from the pre-partitioned antenna port subsets, for the UE according to the current state information of the UE comprises: selecting the port subset of antenna applicable to the moving speed of the UE according to the current moving speed of the UE. [0002] 2. Method according to claim 1, characterized in that: the antenna gate subassemblies comprise an antenna gate subassembly that is partitioned according to the antenna geographic locations; the UE current state information comprises at least one of path loss information between the UE and each antenna port subset and UE current geographic location information; selecting the antenna port subset, which is required to be measured, from pre-partitioned antenna port subsets, for the UE according to the current state information of the UE comprises at least one of: selecting the subset an antenna gate whose path loss to the UE meets a preset condition in accordance with the path loss information between the UE and each antenna gate subset; and selecting the antenna port subset whose distance to the UE meets a preset condition, according to the current geographic location information of the UE. [0003] 3. Method according to claim 1 or 2, characterized in that: the antenna gate subsets comprise an antenna gate subset applicable to different modes of transmission; the current status information of the UE comprises a transmission mode that is currently used by the UE; and selecting the antenna port subset, which is required to be measured, from pre-partitioned antenna port subsets, for the UE according to the current state information of the UE comprises: selecting a port subset of antenna applicable to the transmission mode of the UE according to the transmission mode that is currently used by the UE. [0004] 4. Method according to claim 3, characterized in that the transmission mode comprises a multiple coordinate point transmission (CoMP) transmission mode, the method further comprising: configuring only a reference signal sent by the subset of antenna port applicable to CoMP transmission mode according to a characteristic of CoMP transmission mode. [0005] 5. Method according to any one of claims 1 to 4, characterized in that: if at least two antenna gate subsets required to be measured are selected from the pre-partitioned antenna gate subsets , informing (S102) the UE to perform the channel measurement for the antenna gate subsets that are required to be measured and feedback the channel state information comprises one of: informing the UE to perform the channel measurement for a signal reference each antenna gate subset that is required to be measured, and feedback the channel state information of each antenna gate subset that is required to be measured; inform the UE to perform the channel measurement for a reference signal of each antenna gate subset that is required to be measured, and feedback the channel state information of each antenna gate subset that is required to be measured and information about a cross channel state correlation between each two antenna gate subsets required to be measured; combine all the antenna gate subsets required to be measured, and inform the UE to perform the channel measurement based on reference signals of all the combined antenna gate subsets required to be measured and feed back the channel status information of each combination of the antenna port subassemblies; and, combining a part of antenna gate subsets required to be measured, and informing the UE to perform the channel measurement based on reference signals of the partially matched antenna gate subsets required to be measured and feedback at least one of the channel state information of each combination of the antenna gate subsets, and information about the channel state cross correlation between each two combinations of the antenna gate subsets. [0006] 6. Apparatus for implementing a channel measurement, characterized in that it comprises: a determination unit (U401), configured to determine an antenna gate subset, which is required to be measured, for a user equipment (UE ) according to the current status information of the UE, wherein the antenna port subset is formed by one or more antenna ports from all antenna ports; an information unit (U402) configured to inform the UE to perform the channel measurement for the antenna gate subset that is required to be measured and feedback channel status information; and a selection sub-unit (U411) configured to select the antenna gate subset which is required to be measured, from pre-partitioned antenna gate subsets, for the UE according to the current state information. of the EU; wherein the antenna gate subsets comprise an antenna gate subset applicable to different speeds of movement of UEs; the current state information of the UE comprises a current moving speed of the UE; and the selection sub-unit (U411) comprises: a first selection sub-unit, configured to select an antenna gate subset applicable to the moving speed of the UE according to the current moving speed of the UE. [0007] 7. Apparatus according to claim 6, characterized in that: the antenna gate subassemblies comprise an antenna gate subassembly which is partitioned according to the antenna geographic locations; the UE current state information comprises at least one of path loss information between the UE and each antenna port subset, and UE current geographic location information; the selection sub-unit (U4011) comprises at least one of: a second selection sub-unit configured to select the antenna gate subset whose path loss to the UE meets a preset condition, according to the information on the loss of path between the UE and each antenna gate subset; and a third selection sub-unit, configured to select the antenna gate subset whose distance to the UE meets a preset condition, in accordance with the current geographic location information of the UE. [0008] 8. Apparatus according to claim 6 or 7, characterized in that: the antenna gate subsets comprise an antenna gate subassembly applicable to different modes of transmission; the current status information of the UE comprises a transmission mode that is currently used by the UE; and the selection sub-unit comprises: a fourth selection sub-unit, configured to select an antenna gate subset applicable to the transmission mode of the UE according to the transmission mode that is currently used by the UE. [0009] 9. Apparatus according to claim 8, characterized in that the transmission modes comprise a multi-coordinated point transmission (CoMP) transmission mode, and the apparatus further comprises: a configuration unit, configured to configure only a reference signal transmitted by an antenna gate subset applicable to the CoMP transmission mode according to a characteristic of the CoMP transmission mode. [0010] 10. Apparatus according to any one of claims 6 to 9, characterized in that: if at least two antenna port subsets required to be measured are selected from the pre-partitioned antenna port subsets, the The information unit comprises one of: a first information sub-unit, configured to inform the UE to perform a channel measurement for a reference signal of each antenna gate subset that is required to be measured, and to feed back the status information of channel of each antenna port subset that is required to be measured; a second information sub-unit, configured to inform the UE to perform a channel measurement for a reference signal of each antenna gate subset that is required to be measured, and to feed back the channel status information of each antenna gate subset. antenna that is required to be measured and information about a channel state cross correlation between each two antenna port subsets required to be measured; a third information sub-unit, configured to combine all antenna gate subsets required to be measured, and inform the UE to perform channel measurement based on reference signals of all antenna gate subsets combined required to be measured and feedback the channel state information of each combination of all antenna port subsets; and a fourth information sub-unit, configured to: combine a portion of antenna gate subsets required to be measured, and inform the UE to perform channel measurement based on reference signals of the partially matched antenna gate subsets required to at least one of the channel state information of each combination of the antenna gate subsets, and information on the channel state cross correlation between each two combinations of the antenna gate subsets are measured and fed back. [0011] 11. Method for implementing a channel measurement, the method characterized in that it comprises the steps of: selecting (S301), by a user equipment (UE), an antenna gate subset that is required to be measured from of pre-partitioned antenna port subsets according to the current state information of the UE; and performing (S302), by the UE, channel measurement for the antenna gate subset to obtain channel status information; and feed back (S302), by the UE, the channel status information and antenna port subset identification information to a base station. [0012] 12. Method according to claim 11, characterized in that: the step of selecting (S301) the antenna gate subset that is required to be measured from the pre-partitioned antenna gate subsets according to the UE current state information obtained from the base station, comprises: obtaining the UE current state information from the base station; and selecting the applicable antenna gate subset that is required to be measured from the pre-partitioned antenna gate subsets according to a mapping relationship between the UE current state information and the antenna gate subset, in that the mapping relationship is pre-negotiated with the base station. [0013] 13. Method according to claim 11 or 12, characterized in that: if the number of antenna port subsets required to be measured is at least two, the step of performing (S302), by the UE, the Channel measurement for the antenna gate subsets required to be measured comprises: performing, by the UE, in accordance with at least one of the feedback order of the channel state information, and a combination mode of the antenna gate subsets, the channel measurement for the antenna gate subsets required to be measured and feedback channel state information, at least one of the order and combination mode being pre-negotiated with the base station. [0014] 14. Method according to claim 11 or 12, characterized in that: if the number of antenna port subsets required to be measured is at least two, the step of performing (S302), by the UE, the Channel measurement for the antenna gate subsets required to be measured comprises: selecting, by the UE, at least one among the channel state information feedback order, and a combination mode of the antenna gate subsets, and performing , by the UE, the channel measurement for the antenna gate subsets required to be measured; the step of feedback (S302), by the UE, the channel status information to a base station comprises: feedback at least one of the channel status information, and the identification information of the antenna port subsets and the information of identifying a combination of the antenna port subassemblies. [0015] 15. Apparatus for implementing a channel measurement, characterized in that it comprises: means for selecting an antenna gate subset which is required to be measured from pre-partitioned antenna gate subsets according to the state information current of a user equipment (UE); means for performing channel measurement for the antenna gate sub-assembly to obtain channel state information; and means for feedback channel state information and antenna port sub-assembly identification information. [0016] 16. Apparatus according to claim 15, characterized in that: means for selecting an antenna port subset that is required to be measured comprises: means for obtaining the current state information of the UE from the base station; and means for selecting an antenna gate subset that is required to be measured from pre-partitioned antenna gate subsets according to a mapping relationship between the UE current state information and the antenna gate subset, where the mapping relationship is pre-negotiated with the base station. [0017] 17. Apparatus according to claim 15 or 16, characterized in that: when the number of antenna port subsets required to be measured is at least two, means to perform channel measurement for the antenna port subset to obtain channel state information comprises: means to perform: according to the feedback order of at least one of the channel state information, and a way of combining the antenna gate subsets, the channel measurement for the antenna port subsets required to be measured, at least one of the order and combination mode being pre-negotiated with the base station. [0018] 18. Apparatus according to claim 15 or 16, characterized in that: when the number of antenna port subsets required to be measured is at least two, means to perform channel measurement for the antenna port subset to obtain channel state information comprises: selecting the feedback order of at least one among the channel state information, and a mode of combining the antenna gate subsets, and performing the channel measurement for the antenna gate subsets. antenna required to measure and feed back channel status information; and means for feeding back the channel state information comprises: feeding back at least one of the channel state information, and identification information of the antenna gate subsets and identification information of a combination of the antenna gate subsets.
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2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]| 2020-02-04| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04W 24/10 Ipc: H04B 7/024 (2017.01), H04B 7/06 (2006.01), H04W 24 | 2020-02-11| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]| 2021-05-04| B09A| Decision: intention to grant [chapter 9.1 patent gazette]| 2021-07-13| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 28/10/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |
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申请号 | 申请日 | 专利标题 CN200910208525.3A|CN102056220B|2009-10-28|2009-10-28|Method and device for realizing channel measurement| CN200910208525.3|2009-10-28| PCT/CN2010/078181|WO2011050727A1|2009-10-28|2010-10-28|Method and device for enabling channel measurement|BR122018004895-6A| BR122018004895B1|2009-10-28|2010-10-28|METHOD TO IMPLEMENT CHANNEL MEASUREMENT AND USER EQUIPMENT TO IMPLEMENT CHANNEL MEASUREMENT| 相关专利
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