WO2010081412A1 - Method, system, user equipment and base station for pre-coding feedback - Google Patents
Method, system, user equipment and base station for pre-coding feedback Download PDFInfo
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- WO2010081412A1 WO2010081412A1 PCT/CN2010/070146 CN2010070146W WO2010081412A1 WO 2010081412 A1 WO2010081412 A1 WO 2010081412A1 CN 2010070146 W CN2010070146 W CN 2010070146W WO 2010081412 A1 WO2010081412 A1 WO 2010081412A1
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- noise ratio
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/0413—MIMO systems
- H04B7/0417—Feedback systems
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
- H04B7/04—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
- H04B7/06—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
- H04B7/0613—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission
- H04B7/0615—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal
- H04B7/0619—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station using simultaneous transmission of weighted versions of same signal using feedback from receiving side
- H04B7/0621—Feedback content
- H04B7/0634—Antenna weights or vector/matrix coefficients
Definitions
- the present invention relates to mobile communication technologies, and in particular, to a precoding feedback method and system, a user equipment, and a base station. Background technique
- MIMO Multiple Input Multiple Output
- the precoding technique is based on the assumption that the transmitting end knows all or part of the channel state information. Therefore, in many cases, the receiving end needs to feed back the channel state information to the transmitting end.
- random beamforming is a possible solution to reduce the amount of feedback.
- random scheduling can make full use of multi-user diversity to improve system throughput.
- the optimal and capacity expansion law is A ⁇ loglog, where ⁇ is the number of transmitting antennas on the base station side, which is the number of users.
- ZF Zero Forcing
- ORB Opportunistic Orthogonal Random Beamforming
- the invention provides a precoding feedback method and system, a user equipment and a base station, which solve the problem of large feedback overhead.
- An embodiment of the present invention provides a precoding feedback method, including:
- the feedback optimal beam sets information of at least one beam having a signal to interference and noise ratio higher than the feedback threshold.
- the embodiment of the invention provides a user equipment, including:
- a receiving module configured to receive a random beam information stream, and determine an optimal beam set according to a signal to interference and noise ratio of the random beam information stream;
- An obtaining module configured to obtain a feedback threshold
- the feedback module is connected to the receiving module and the acquiring module, and is configured to feed back information of at least one beam whose signal to interference and noise ratio is higher than the feedback threshold.
- An embodiment of the present invention provides a base station, including:
- a calculation module configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, a feedback threshold value for each user equipment; or a user according to a signal to interference and noise ratio distribution function, a user At least one of the total number of devices and the environmental factors corresponding to each user equipment obtains a feedback threshold for each user equipment; and obtains a common feedback threshold according to a predetermined policy and a feedback threshold for each user equipment;
- the sending module is connected to the computing module, and is configured to send the feedback threshold of each user equipment or the common feedback threshold to the user equipment.
- An embodiment of the present invention provides a precoding feedback system, including:
- a base station configured to send a random beam information flow and threshold information to the user equipment
- a user equipment connected to the base station, configured to acquire an optimal beam according to the random beam information And collecting, according to the threshold information, a feedback threshold, and feeding back information of at least one beam whose signal to interference and noise ratio is higher than a feedback threshold in the optimal beam set.
- the threshold of the present invention can reduce the feedback overhead in the random beamforming scheme by setting the threshold value and feeding back the corresponding information when the signal to interference and noise ratio of the optimal beam exceeds the threshold.
- FIG. 1 is a schematic flow chart of a method according to a first embodiment of the present invention
- FIG. 2 is a schematic structural view of a first embodiment of the present invention
- Embodiment 3 is a schematic flow chart of Embodiment 1 of a method for obtaining a feedback threshold in the first embodiment of the present invention
- Embodiment 4 is a schematic flow chart of Embodiment 2 of a method for obtaining a feedback threshold in the first embodiment of the present invention
- FIG. 5 is a schematic flow chart of Embodiment 3 of a method for obtaining a feedback threshold in the first embodiment of the present invention
- FIG. 6 is a simulation relationship diagram of the total number of users and the capacity in the first embodiment of the present invention
- FIG. 7 is a graph showing the relationship between the signal-to-noise ratio and the capacity in the first embodiment of the present invention
- FIG. 9 is a schematic structural diagram of a user equipment according to a second embodiment of the present invention.
- FIG. 10 is a schematic structural diagram of a base station according to a third embodiment of the present invention.
- FIG. 11 is a schematic structural diagram of a precoding feedback system according to a fourth embodiment of the present invention. detailed description
- an embodiment of the present invention includes: Step 11: The user equipment receives the random beam information stream, and determines an optimal beam set according to the signal to interference and noise ratio of the random beam information stream.
- Step 12 The user equipment obtains the feedback threshold.
- Steps 11, 12 have no timing constraints.
- Step 13 The user equipment feeds back, to the base station, information about at least one beam whose signal to interference and noise ratio is higher than the feedback threshold in the optimal beam set.
- the feedback threshold is obtained, and the feedback overhead is reduced when the signal to interference and noise ratio of the optimal beam of the user equipment is higher than the feedback threshold.
- the base station has N, the root transmitting antenna, and there are a total of user equipments in the system, and each user equipment is equipped with N receiving antennas.
- the base station is distributed according to isotropic
- the information flow is statistically independent, and assume that the average transmit power of the daily lines is equal: E[
- the Gaussian white noise of each user equipment is represented by G C xl , z k ⁇ C 0, I N ), and the received signal vector of each user equipment is , ⁇
- the channel block H k is independent, and H t e CN(0, 1).
- the signal-to-interference ratio 8 ⁇ und 1 of the mth information stream received by the first user equipment is expressed as follows: SINR t , K, w- ⁇ , ⁇ , N t
- the optimal beam set is composed of a beam with the largest signal to interference and noise ratio; when the number of receiving antennas of the user equipment is greater than one, the signal is dry and noise according to the signal to interference and noise ratio from large to small.
- the relatively large N beams constitute an optimal beam set, where N ⁇ Nr, Nr is the number of receiving antennas of each user equipment.
- the feedback threshold is determined according to one or more of a signal to interference and noise ratio distribution function, a total number of user equipments, and environmental factors corresponding to each user equipment, or further determined according to a predetermined policy.
- a signal to interference and noise ratio distribution function a total number of user equipments, and environmental factors corresponding to each user equipment, or further determined according to a predetermined policy.
- FIG. 3 is a schematic flowchart of Embodiment 1 of a method for obtaining a feedback threshold in the first embodiment of the present invention.
- a base station generates a threshold value corresponding to each user equipment for each user equipment.
- this embodiment includes:
- Step 301 The base station obtains a feedback threshold O t for each user equipment according to the total number of user equipments and different environmental factors of each user equipment (for example, path loss and shadow) and a signal to interference and noise ratio distribution function. .
- the principle that the base station determines the threshold p( k ,f) according to the total number of user equipments K and y k is as follows:
- the design is different for user equipments with different path loss and shadow.
- Feedback thresholds can improve fairness, such as user equipment with more shadows and path loss, and feedback thresholds should be allocated lower, which can improve the fairness of the system.
- the formula is determined according to the total number of user equipments, environmental factors, and the signal-to-noise ratio distribution function. In practical applications, the calculation formulas may be different, for example, only related to one or more of the above parameters.
- Step 302 The base station sends the feedback threshold to the corresponding user equipment, and each user equipment obtains the feedback threshold for itself.
- the feedback threshold value for each user equipment is calculated by the base station, and an appropriate threshold value may be determined according to different conditions of each user equipment.
- FIG. 4 is a schematic flowchart of Embodiment 2 of a method for obtaining a feedback threshold in the first embodiment of the present invention.
- a base station generates a common feedback threshold for each user equipment. Referring to Figure 4, this embodiment includes:
- Step 401 The same as step 301 of the third embodiment, and details are not described herein again.
- Step 402 The base station processes the feedback threshold for each user equipment according to a preset policy to obtain a common feedback threshold. For example, the feedback thresholds are averaged to obtain an average value.
- Step 403 The base station sends a common feedback threshold to each user equipment, and each user equipment obtains the common feedback threshold.
- the base station calculates the same feedback threshold for each user equipment, so that each user equipment can obtain an appropriate common threshold.
- FIG. 5 is a schematic flowchart of Embodiment 3 of a method for obtaining a feedback threshold in the first embodiment of the present invention.
- each user equipment pin generates a feedback threshold corresponding to itself.
- this embodiment includes:
- Step 501 The base station sends the total number of user equipments K and different environmental factors of each user equipment to each corresponding user equipment.
- Step 502 Each user equipment obtains its own feedback threshold according to the foregoing information sent by the base station and the signal to interference and noise ratio distribution function. That is, each user equipment determines the threshold according to the total number of user equipments and ⁇
- the information of the optimal beam is fed back (for example, the beam number); when the number of receiving antennas of the user equipment is greater than 1 Comparing the signal-to-noise ratio and the feedback threshold of the beam in the optimal beam set composed of the N beams, and feeding back the information of the beam in the N beams with the signal-to-noise ratio higher than the feedback threshold, where
- the base station may further randomly select a user equipment from each user set, and schedule the user equipment to receive the information stream x m corresponding to the beam. Since they are mutually disjoint, this ensures that one user equipment is not allocated more than one beam.
- the feedback amount can be reduced on the basis of obtaining the optimal and capacity expansion laws.
- the effect is illustrated below in a simulation diagram.
- the simulation basis of this embodiment is that the number of transmitting antennas is 4, and the number of receiving antennas of each user equipment is 1, the signal to noise ratio p It is 10dB.
- the Dirty-Paper Coding (DPC) method is the optimal precoding method.
- the other precoding methods are the optimal optimal zero-pre-coding method (Optim ZF) and the opportunity orthogonality.
- Precoding method Opportunistic ORB
- 1-bit feedback pre- A coding method (1-Bit Feedback
- a 1-Bit ORB method based on an embodiment of the present invention. It can be seen from FIG.
- the pre-coding method based on the present embodiment can achieve an optimal and capacity expansion law. It can be seen from FIG. 6 that when the total number of user equipments is small, the precoding method and the optimal precoding curve according to the embodiment of the present invention are also similar, that is, when the total number of user equipments is small, based on the embodiment of the present invention.
- the precoding method can also have some better performance.
- FIG. 7 is a simulation relationship diagram of signal-to-noise ratio and sum capacity in the first embodiment of the present invention.
- the simulation basis of this embodiment is that the number of transmitting antennas is 4, and the number of receiving antennas N of each user equipment is 1, user equipment. The total is 100. It can be seen from Fig. 7 that the trend of each curve is also that the optimum and capacity law can be achieved in this embodiment when the signal-to-noise ratio changes.
- FIG. 8 is a graph showing a simulation relationship between the total number of users and the feedback amount in the first embodiment of the present invention.
- the curve from top to bottom shows the relationship between the total number of user equipments and the feedback amount when the number of transmitting antennas is 6, 5, 4, and 3 respectively.
- the limit values at infinity are 61og6, 51og5, 41og4, 31og3, respectively, that is, the average feedback rate of this embodiment will be N t ⁇ o g N t .
- the threshold-based feedback mechanism is not used in the prior art, and for each user, there is a maximum of min A ⁇ NJlogN, bit feedback, and the feedback bits of the entire system may reach Bit, so its feedback overhead is too large.
- the average total feedback overhead is A ⁇ logN, bit. Compared with the feedback amount of the existing 1 ⁇ , ⁇ )1 0 ⁇ , the feedback amount can be greatly reduced.
- FIG. 9 is a schematic structural diagram of a user equipment according to a second embodiment of the present invention, including a receiving module 91, an obtaining module 92, and a feedback module 93.
- the receiving module 91 is configured to receive a random beam information stream, and determine an optimal beam set according to a signal to interference and noise ratio of each random beam information stream;
- the obtaining module 92 is configured to obtain a feedback threshold value;
- the feedback module 93 is configured to feedback the receiving module 91.
- the optimal beam sets information of at least one beam whose signal to interference and noise ratio is higher than the feedback threshold obtained by the obtaining module 92.
- the obtaining module 92 is specifically configured to receive a feedback threshold corresponding to the user equipment sent by the base station, and the feedback threshold corresponding to the user equipment is used by the base station according to a signal to interference and noise ratio distribution function, and the total user equipment. And determining at least one of an environmental factor corresponding to the user equipment; or, acquiring a module
- the specific feedback threshold value is the same for each user equipment sent by the base station, and the common feedback threshold value for each user equipment is determined by the base station according to the signal to interference and noise ratio distribution function, the total number of user equipments, At least one of the environmental factors corresponding to the user equipment and the predetermined policy is determined; or the acquiring module 92 is specifically configured to receive the total number of user equipments and environmental factors sent by the base station, and the user equipment according to the signal to interference and noise ratio distribution function and the user equipment One of the total and environmental factors determines the feedback threshold.
- the information of the optimal beam is fed back, and the feedback amount can be reduced.
- FIG. 10 is a schematic structural diagram of a base station according to a third embodiment of the present invention, which includes a calculation module 101 and a sending module 102.
- the calculation module 101 is configured to calculate a feedback threshold.
- the sending module 102 is configured to send the feedback threshold obtained by the calculation module 101 to the user equipment, where the user equipment has at least one signal to interference and noise ratio higher than the feedback threshold. The information of the beam of values is fed back to the base station.
- the calculation module 101 is specifically configured to determine a feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment; or, the calculation module 101 is specifically used. Obtaining a feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment; and according to a predetermined policy and a feedback threshold value for each user equipment Get a common feedback threshold.
- the embodiment may further include a selection module, configured to receive beam information sent by each user equipment, to form a user set for each beam, and randomly select a user equipment in the user set corresponding to the same beam information, and the beam is selected. The data is sent to a randomly selected user device.
- a selection module configured to receive beam information sent by each user equipment, to form a user set for each beam, and randomly select a user equipment in the user set corresponding to the same beam information, and the beam is selected. The data is sent to a randomly selected user device.
- the feedback threshold is obtained by the calculation, and the feedback threshold is sent to the user equipment, so that the user equipment feedbacks when the signal to interference and noise ratio of the optimal beam is higher than the threshold, and the feedback amount can be reduced.
- FIG. 11 is a schematic structural diagram of a precoding feedback system according to a fourth embodiment of the present invention, including a base station 111 and a user equipment 112.
- the base station 111 is configured to send the beam information stream and the threshold information; the user equipment
- the algorithm is configured to obtain an optimal beam set according to the random beam information sent by the base station 111, obtain a feedback threshold according to the threshold information sent by the base station 111, and feed back at least one signal to interference and noise ratio in the optimal beam set is higher than a feedback threshold.
- the value of the beam information is configured to obtain an optimal beam set according to the random beam information sent by the base station 111, obtain a feedback threshold according to the threshold information sent by the base station 111, and feed back at least one signal to interference and noise ratio in the optimal beam set is higher than a feedback threshold.
- the threshold information may be specifically a feedback threshold corresponding to each user equipment, and the base station 111 is specifically configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, The feedback threshold is used by the user equipment 112 to receive the feedback threshold corresponding to the base station 111.
- the threshold information may be specifically a feedback threshold value common to each user equipment
- the base station 111 is specifically configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, for each user.
- a feedback threshold of the device, and a common feedback threshold is obtained according to a predetermined policy and a feedback threshold for each user equipment.
- the user equipment 112 is specifically configured to receive the common publicity of each user equipment obtained by the base station 111. Feedback threshold.
- the base station 111 is specifically configured to send the total number of user equipments and the environmental factors corresponding to the user equipments to the corresponding user equipments; the user equipment 112 according to the signal to interference and noise ratio distribution function, the total number of user equipments, and environmental factors sent by the base station 111 At least one of the determinations determines a respective feedback threshold.
- the base station 111 is further configured to receive the beam information sent by each user equipment, and form a user set for each beam; and randomly select a user equipment in the user set corresponding to the same beam information, and send the data of the beam to the random Selected user device.
- the feedback threshold is obtained in different manners.
- the feedback of the optimal beam information can reduce the feedback amount.
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Abstract
A method, system, user equipment and base station for pre-coding feedback are provided. The method includes the following steps: receiving random beam information flows; determining the optimal beam set according to the signal to interference-plus-noise ratio (SINR) of the random beam information flows; getting the feedback threshold value; feeding back the information of at least one beam, of which the SINR is larger than the feedback threshold value, in the optimal beam set. The method can decrease the pre-coding feedback quantity.
Description
预编码反馈方法及系统、 用户设备和基站 Precoding feedback method and system, user equipment and base station
本申请要求于 2009年 1月 15日提交中国专利局、 申请号 200910076683.8、 发明名称为 "预编码反馈方法及系统、 用户设备和基站" 的中国专利申请的 优先权, 其全部内容通过引用结合在本申请中。 技术领域 This application claims priority to Chinese Patent Application No. 200910076683.8, entitled "Pre-coded Feedback Method and System, User Equipment and Base Station" on January 15, 2009, the entire contents of which are incorporated by reference. In this application. Technical field
本发明涉及移动通信技术, 特别涉及一种预编码反馈方法及系统、 用户 设备和基站。 背景技术 The present invention relates to mobile communication technologies, and in particular, to a precoding feedback method and system, a user equipment, and a base station. Background technique
多输入多输出 ( Multiple Input Multiple Output, MIMO )技术可以在不增 加带宽的基础上极大地提高无线通信系统的传输速率, 满足了高速率数据传 输业务的要求。 在 MIMO系统中, 利用预编码技术同时对多个数据流进行传 输, 可以提高传输链路的可靠性和传输速率。 而预编码技术是基于发射端知 道全部或部分信道状态信息这样的假设而执行的, 因此, 在很多情况下接收 端需要将信道状态信息反馈到发射端。 在多用户环境中, 为了减小反馈量, 随机波束成形是一种可能的解决方案。 在多用户环境下, 随机调度能充分利 用多用户分集而提高系统吞吐量, 通常是用户数目越多吞吐量越大, 在用户 数目趋于无穷大时, 系统吞吐量和用户数目之间的函数关系为最优和容量扩 展律, 最优和容量扩展律为 A^ loglog , 其中 ^为基站侧的发射天线的数目, 为用户的数目。 随机波束成形方案中的迫零波束成形技术( Zero Forcing, ZF ) 和机会正交随机波束成形技术 ( Opportunistic Orthogonal Random Beamforming, ORB )都可以达到最优和容量扩展律。 Multiple Input Multiple Output (MIMO) technology can greatly improve the transmission rate of wireless communication systems without increasing the bandwidth, and meet the requirements of high-speed data transmission services. In a MIMO system, the use of precoding techniques to simultaneously transmit multiple data streams can improve the reliability and transmission rate of the transmission link. The precoding technique is based on the assumption that the transmitting end knows all or part of the channel state information. Therefore, in many cases, the receiving end needs to feed back the channel state information to the transmitting end. In a multi-user environment, random beamforming is a possible solution to reduce the amount of feedback. In a multi-user environment, random scheduling can make full use of multi-user diversity to improve system throughput. Usually, the more users, the greater the throughput, and the functional relationship between system throughput and number of users when the number of users tends to infinity. For the optimal and capacity expansion law, the optimal and capacity expansion law is A^loglog, where ^ is the number of transmitting antennas on the base station side, which is the number of users. Both Zero Forcing (ZF) and Opportunistic Orthogonal Random Beamforming (ORB) in the random beamforming scheme can achieve optimal and capacity expansion laws.
发明人发现现有技术至少存在如下问题: 现有技术中若需要达到最优和 容量扩展律, 用户向基站的反馈开销较大。
发明内容 The inventors have found that the prior art has at least the following problems: In the prior art, if the optimal and capacity expansion laws need to be achieved, the feedback overhead of the user to the base station is large. Summary of the invention
本发明提供一种预编码反馈方法及系统、 用户设备和基站, 解决反馈开 销较大的问题。 The invention provides a precoding feedback method and system, a user equipment and a base station, which solve the problem of large feedback overhead.
本发明实施例提供了一种预编码反馈方法, 包括: An embodiment of the present invention provides a precoding feedback method, including:
接收随机波束信息流, 根据所述随机波束信息流的信干噪比确定最优波 束集; Receiving a random beam information stream, and determining an optimal beam set according to a signal to interference and noise ratio of the random beam information stream;
获取反馈门限值; Obtain a feedback threshold;
反馈最优波束集中至少一个信干噪比高于所述反馈门限值的波束的信 息。 The feedback optimal beam sets information of at least one beam having a signal to interference and noise ratio higher than the feedback threshold.
本发明实施例提供了一种用户设备, 包括: The embodiment of the invention provides a user equipment, including:
接收模块, 用于接收随机波束信息流, 根据所述随机波束信息流的信干 噪比确定最优波束集; a receiving module, configured to receive a random beam information stream, and determine an optimal beam set according to a signal to interference and noise ratio of the random beam information stream;
获取模块, 用于获取反馈门限值; An obtaining module, configured to obtain a feedback threshold;
反馈模块, 与所述接收模块和获取模块连接, 用于反馈最优波束集中至 少一个信干噪比高于所述反馈门限值的波束的信息。 The feedback module is connected to the receiving module and the acquiring module, and is configured to feed back information of at least one beam whose signal to interference and noise ratio is higher than the feedback threshold.
本发明实施例提供了一种基站, 包括: An embodiment of the present invention provides a base station, including:
计算模块, 用于根据信干噪比分布函数、 用户设备总数和各用户设备对 应的环境因素中的至少一个参数确定针对各用户设备的反馈门限值; 或者根 据信干噪比分布函数、 用户设备总数、 各用户设备对应的环境因素中的至少 一个参数得到针对各用户设备的反馈门限值; 并根据预定策略及针对各用户 设备的反馈门限值得到公共的反馈门限值; a calculation module, configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, a feedback threshold value for each user equipment; or a user according to a signal to interference and noise ratio distribution function, a user At least one of the total number of devices and the environmental factors corresponding to each user equipment obtains a feedback threshold for each user equipment; and obtains a common feedback threshold according to a predetermined policy and a feedback threshold for each user equipment;
发送模块, 与所述计算模块连接, 用于将所述各用户设备的反馈门限值 或者所述公共的反馈门限值发送给用户设备。 The sending module is connected to the computing module, and is configured to send the feedback threshold of each user equipment or the common feedback threshold to the user equipment.
本发明实施例提供了一种预编码反馈系统, 包括: An embodiment of the present invention provides a precoding feedback system, including:
基站, 用于发送随机波束信息流及门限信息给用户设备; a base station, configured to send a random beam information flow and threshold information to the user equipment;
用户设备, 与所述基站连接, 用于根据所述随机波束信息获取最优波束
集, 根据所述门限信息获取反馈门限值, 反馈最优波束集中至少一个信干噪 比高于反馈门限值的波束的信息。 a user equipment, connected to the base station, configured to acquire an optimal beam according to the random beam information And collecting, according to the threshold information, a feedback threshold, and feeding back information of at least one beam whose signal to interference and noise ratio is higher than a feedback threshold in the optimal beam set.
由上述技术方案可知, 本发明实施例通过设定门限值, 在最优波束的信 干噪比超过门限值时反馈相应的信息, 可以减小随机波束成形方案中的反馈 开销。 附图说明 It can be seen from the above technical solution that the threshold of the present invention can reduce the feedback overhead in the random beamforming scheme by setting the threshold value and feeding back the corresponding information when the signal to interference and noise ratio of the optimal beam exceeds the threshold. DRAWINGS
图 1为本发明第一实施例的方法流程示意图; 1 is a schematic flow chart of a method according to a first embodiment of the present invention;
图 2为本发明第一实施例对应的结构示意图; 2 is a schematic structural view of a first embodiment of the present invention;
图 3为本发明第一实施例中获取反馈门限值的方法实施例一的流程示意 图; 3 is a schematic flow chart of Embodiment 1 of a method for obtaining a feedback threshold in the first embodiment of the present invention;
图 4为本发明第一实施例中获取反馈门限值的方法实施例二的流程示意 图; 4 is a schematic flow chart of Embodiment 2 of a method for obtaining a feedback threshold in the first embodiment of the present invention;
图 5为本发明第一实施例中获取反馈门限值的方法实施例三的流程示意 图; FIG. 5 is a schematic flow chart of Embodiment 3 of a method for obtaining a feedback threshold in the first embodiment of the present invention;
图 6为本发明第一实施例中用户总数与和容量的仿真关系曲线图; 图 7为本发明第一实施例中信噪比与和容量的仿真关系曲线图; 图 8为本发明第一实施例中用户总数与反馈量的仿真关系曲线图; 图 9为本发明第二实施例的用户设备的结构示意图; 6 is a simulation relationship diagram of the total number of users and the capacity in the first embodiment of the present invention; FIG. 7 is a graph showing the relationship between the signal-to-noise ratio and the capacity in the first embodiment of the present invention; FIG. 9 is a schematic structural diagram of a user equipment according to a second embodiment of the present invention; FIG.
图 10为本发明第三实施例的基站的结构示意图; FIG. 10 is a schematic structural diagram of a base station according to a third embodiment of the present invention; FIG.
图 11为本发明第四实施例的预编码反馈系统的结构示意图。 具体实施方式 FIG. 11 is a schematic structural diagram of a precoding feedback system according to a fourth embodiment of the present invention. detailed description
下面通过附图和实施例, 对本发明的技术方案做进一步的详细描述。 图 1为本发明第一实施例的方法流程示意图, 图 2为本发明第一实施例 对应的结构示意图。 参见图 1 , 本发明实施例包括:
步骤 11: 用户设备接收随机波束信息流, 根据该随机波束信息流的信干 噪比确定最优波束集。 The technical solution of the present invention will be further described in detail below through the accompanying drawings and embodiments. 1 is a schematic flow chart of a method according to a first embodiment of the present invention, and FIG. 2 is a schematic structural diagram of a first embodiment of the present invention. Referring to FIG. 1, an embodiment of the present invention includes: Step 11: The user equipment receives the random beam information stream, and determines an optimal beam set according to the signal to interference and noise ratio of the random beam information stream.
步骤 12: 用户设备获取反馈门限值。 Step 12: The user equipment obtains the feedback threshold.
步骤 11、 12无时序限制关系。 Steps 11, 12 have no timing constraints.
步骤 13: 用户设备向基站反馈最优波束集中至少一个信干噪比高于该反 馈门限值的波束的信息。 Step 13: The user equipment feeds back, to the base station, information about at least one beam whose signal to interference and noise ratio is higher than the feedback threshold in the optimal beam set.
本实施例通过获取反馈门限值, 在用户设备的最优波束的信干噪比高于 反馈门限值时再反馈, 可以降低反馈开销。 In this embodiment, the feedback threshold is obtained, and the feedback overhead is reduced when the signal to interference and noise ratio of the optimal beam of the user equipment is higher than the feedback threshold.
下面分别对各步骤进行较为详细地说明: The steps are described in more detail below:
关于步骤 11: About step 11:
以下行多用户 MIMO系统为例, 基站有 N,根发射天线, 系统中共有 个 用户设备, 每个用户设备装有 N根接收天线。 For example, in the following multi-user MIMO system, the base station has N, the root transmitting antenna, and there are a total of user equipments in the system, and each user equipment is equipped with N receiving antennas.
如图 2所示, 若采用随机正交波束成形方案, 则基站根据各向同性分布
, 在时刻 t, 第 个信息流 xm(t)乘以 φΜ(ί) , 并且 N,个累加得到发射信号 "^)=∑^^^^),假设发射机满足平均 功率约束
假设信息流是统计独立, 且假设每天线的平均发射 功率相等: E[|xm(t)|2] = , 令 P = 为每流的发射 SNR。 每个用户设备的高斯白噪声用 GC xl表示, zk ~ C 0,IN), 则每 个用户设备的接收信号向量为
,Κ 对于不同的用户设备经历不同的路损和阴影衰落的情况用 表示, 信道 块 Hk是独立的, 且 Ht e CN(0,1)。 As shown in FIG. 2, if a random orthogonal beamforming scheme is adopted, the base station is distributed according to isotropic At time t, the first information stream x m (t) is multiplied by φ Μ (ί) , and N, accumulate to obtain the transmitted signal "^) = ∑ ^ ^ ^ ^), assuming that the transmitter satisfies the average power constraint Suppose the information flow is statistically independent, and assume that the average transmit power of the daily lines is equal: E[|x m (t)| 2 ] = , let P = be the transmit SNR per stream. The Gaussian white noise of each user equipment is represented by G C xl , z k ~ C 0, I N ), and the received signal vector of each user equipment is , Κ For the case where different user equipments experience different path loss and shadow fading, the channel block H k is independent, and H t e CN(0, 1).
第 个用户设备接收的第 m个信息流的信干噪比 8^ „1表示如下:
SINRt ,K, w-Ι,Λ ,Nt
The signal-to-interference ratio 8^ „ 1 of the mth information stream received by the first user equipment is expressed as follows: SINR t , K, w-Ι, Λ , N t
其中, 接收天线的数目为 1个时, 最优波束集由信干噪比最大的波束组 成; 当用户设备的接收天线的数目大于 1个时, 按照信干噪比从大到小将信 干噪比较大的 N个波束组成最优波束集, 其中, N≤Nr, Nr为每个用户设备 的接收天线的数目。 下述以选取一个最优波束为例, 即第 A个用户设备的最 优波束 的计算公式为: m = arg max SINRkm。 Wherein, when the number of receiving antennas is one, the optimal beam set is composed of a beam with the largest signal to interference and noise ratio; when the number of receiving antennas of the user equipment is greater than one, the signal is dry and noise according to the signal to interference and noise ratio from large to small. The relatively large N beams constitute an optimal beam set, where N≤Nr, Nr is the number of receiving antennas of each user equipment. The following is an example of selecting an optimal beam, that is, the optimal beam of the Ath user equipment is calculated as: m = arg max SINR km .
K l≤m≤N, ' K l≤m≤N, '
关于步骤 12: About step 12:
反馈门限值是根据信干噪比分布函数、 用户设备总数、 各用户设备对应 的环境因素中的一个或多个确定, 或者进一步再根据预定策略确定。 具体获 取门限值的方法可参见图 3-5所示的实施例。 The feedback threshold is determined according to one or more of a signal to interference and noise ratio distribution function, a total number of user equipments, and environmental factors corresponding to each user equipment, or further determined according to a predetermined policy. For the method of obtaining the threshold value, refer to the embodiment shown in Figure 3-5.
图 3为本发明第一实施例中获取反馈门限值的方法实施例一的流程示意 图, 本实施例是基站针对各用户设备产生对应各用户设备的门限值。 参见图 3, 本实施例包括: FIG. 3 is a schematic flowchart of Embodiment 1 of a method for obtaining a feedback threshold in the first embodiment of the present invention. In this embodiment, a base station generates a threshold value corresponding to each user equipment for each user equipment. Referring to FIG. 3, this embodiment includes:
步骤 301:基站根据用户设备总数 和各用户设备不同的环境因素 ^ (例 如, 路损和阴影) 的估计及信干噪比分布函数, 得到针对每个用户设备的反 馈门限值 Ot, )。 Step 301: The base station obtains a feedback threshold O t for each user equipment according to the total number of user equipments and different environmental factors of each user equipment (for example, path loss and shadow) and a signal to interference and noise ratio distribution function. .
基站根据用户设备总数 K和 yk确定门限 p( k,f )的原则如下: The principle that the base station determines the threshold p( k ,f) according to the total number of user equipments K and y k is as follows:
ΡΜ ,κ)) = ι-^, 其中, (Α^, ))是 w 的累积分布函数, 在前述假 ΡΜ , κ)) = ι-^, where (Α^, )) is the cumulative distribution function of w, in the above-mentioned false
设条件下, ^的累积分布函数为: F x) = 1_(x + 1)w「i 。 根据反馈 门限值的计算公式可知, 对于不同的路损和阴影的用户设备, 设计不同的反 馈门限值可以提高公平性, 如阴影和路损更严重的用户设备, 反馈门限值 应该分配更低, 这样能够提高系统的公平性。 上述计算反馈门限值的
公式是根据用户设备总数、 环境因素和信干噪比分布函数共同确定的, 在实 际应用时, 计算公式可以不同, 例如, 只与上述参数中的一个或多个有关。 Under the condition, the cumulative distribution function of ^ is: F x ) = 1 _( x + 1) w “i . According to the calculation formula of the feedback threshold value, the design is different for user equipments with different path loss and shadow. Feedback thresholds can improve fairness, such as user equipment with more shadows and path loss, and feedback thresholds should be allocated lower, which can improve the fairness of the system. The formula is determined according to the total number of user equipments, environmental factors, and the signal-to-noise ratio distribution function. In practical applications, the calculation formulas may be different, for example, only related to one or more of the above parameters.
步骤 302: 基站将该反馈门限值发送给对应的用户设备, 各用户设备获 取该针对自身的反馈门限值。 Step 302: The base station sends the feedback threshold to the corresponding user equipment, and each user equipment obtains the feedback threshold for itself.
本实施例由基站计算得到针对各用户设备的反馈门限值, 可以根据各用 户设备不同的情况确定合适的门限值。 In this embodiment, the feedback threshold value for each user equipment is calculated by the base station, and an appropriate threshold value may be determined according to different conditions of each user equipment.
图 4为本发明第一实施例中获取反馈门限值的方法实施例二的流程示意 图, 本实施例是基站针对各用户设备产生公共的反馈门限值。 参见图 4, 本 实施例包括: FIG. 4 is a schematic flowchart of Embodiment 2 of a method for obtaining a feedback threshold in the first embodiment of the present invention. In this embodiment, a base station generates a common feedback threshold for each user equipment. Referring to Figure 4, this embodiment includes:
步骤 401: 同实施例三的步骤 301 , 不再贅述。 Step 401: The same as step 301 of the third embodiment, and details are not described herein again.
步骤 402: 基站根据预设的策略将针对各用户设备的反馈门限值进行处 理得到一个公共的反馈门限值,例如将各反馈门限值平均后得到一个平均值。 Step 402: The base station processes the feedback threshold for each user equipment according to a preset policy to obtain a common feedback threshold. For example, the feedback thresholds are averaged to obtain an average value.
步骤 403: 基站将公共的反馈门限值发送给各用户设备, 各用户设备获 取该公共的反馈门限值。 Step 403: The base station sends a common feedback threshold to each user equipment, and each user equipment obtains the common feedback threshold.
本实施例由基站计算得到针对各用户设备的相同的反馈门限值, 可以使 各用户设备获取合适的共性门限值。 In this embodiment, the base station calculates the same feedback threshold for each user equipment, so that each user equipment can obtain an appropriate common threshold.
图 5为本发明第一实施例中获取反馈门限值的方法实施例三的流程示意 图, 本实施例是各用户设备针产生对应自身的反馈门限值。 参见图 5, 本实 施例包括: FIG. 5 is a schematic flowchart of Embodiment 3 of a method for obtaining a feedback threshold in the first embodiment of the present invention. In this embodiment, each user equipment pin generates a feedback threshold corresponding to itself. Referring to Figure 5, this embodiment includes:
步骤 501:基站将用户设备总数 K和各用户设备不同的环境因素 ^发送给 各对应的用户设备。 Step 501: The base station sends the total number of user equipments K and different environmental factors of each user equipment to each corresponding user equipment.
步骤 502: 各用户设备根据基站发送的上述信息及信干噪比分布函数得 到自身的反馈门限值。 即各用户设备根据用户设备总数 和 ^确定门限 Step 502: Each user equipment obtains its own feedback threshold according to the foregoing information sent by the base station and the signal to interference and noise ratio distribution function. That is, each user equipment determines the threshold according to the total number of user equipments and ^
Α^, )的原则如下: Fk 3(jk , Ky) = —^^ , 其中, F yk ,K SINR k,m 的 累积分布函数, 在前述假设条件下, sn t 的累积分布函数为:
e PYk 本实施例由用户设备计算自身的反馈门限值, 可以减轻基站的负担。 关于步骤 13: The principle of Α^, ) is as follows: F k 3(j k , Ky) = —^^ , where F y k , K SINR k , m cumulative distribution function, under the above assumptions, the cumulative distribution function of sn t for: e PYk In this embodiment, the user equipment calculates its own feedback threshold, which can reduce the burden on the base station. About step 13:
例如, 接收天线的数目为 1个时, 当最优波束的信噪比高于反馈门限值 时, 反馈该最优波束的信息 (例如波束序号) ; 当用户设备的接收天线的数 目大于 1个时, 比较由 N个波束组成的最优波束集中的波束的信干噪比与反 馈门限值, 反馈 N个波束中信干噪比高于反馈门限值的波束的信息, 其中, For example, when the number of receiving antennas is one, when the signal to noise ratio of the optimal beam is higher than the feedback threshold, the information of the optimal beam is fed back (for example, the beam number); when the number of receiving antennas of the user equipment is greater than 1 Comparing the signal-to-noise ratio and the feedback threshold of the beam in the optimal beam set composed of the N beams, and feeding back the information of the beam in the N beams with the signal-to-noise ratio higher than the feedback threshold, where
Ν≤ΝΓ , 为每个用户的接收天线的数目。 Ν ≤ Ν Γ , the number of receiving antennas for each user.
具体地, 每个用户设备 k比较 57M?t ,和此门限, 如 SINRt , > β(γ, , Κ) , 用户设备 反馈其最合适的波束 (这要求 log N,个比特),否则用户设备 不 反馈任何信息。 In particular, each user equipment k comparator 57M? T, and the threshold, such as SINR t,> β (γ, , Κ), user equipment feedback the most appropriate beam (which requires log N, bits), otherwise the user The device does not feed back any information.
之后, 对应于每个波束 , 基站接收到的所有反馈了波束序号 的用户 集 Sm为: Bm = {k m = Mg max SINRk landSINRk m > (yk ,K),k = Ι,Λ , K}。 基站获得这些用户集合后, 可以进一步地从每个用户集 中随机的选择 一个用户设备, 并且调度这个用户设备接收此波束对应的信息流 xm。 由于 是互不相交的, 这保证了一个用户设备不被分配多于一个波束。 Then, corresponding to each beam, the user set S m of all the beam numbers that are received by the base station is: B m = {km = Mg max SINR kl and SINR km > (y k , K), k = Ι, Λ, K}. After obtaining the set of users, the base station may further randomly select a user equipment from each user set, and schedule the user equipment to receive the information stream x m corresponding to the beam. Since they are mutually disjoint, this ensures that one user equipment is not allocated more than one beam.
采用上述基于门限的反馈方法后, 在获取最优的和容量扩展律基础上可 以减小反馈量。 下面以仿真图说明该效果。 After adopting the above threshold-based feedback method, the feedback amount can be reduced on the basis of obtaining the optimal and capacity expansion laws. The effect is illustrated below in a simulation diagram.
图 6为本发明第一实施例中用户总数与和容量的仿真关系曲线图, 本实 施例的仿真基础是发射天线数 为 4, 每个用户设备的接收天线数 ^为 1 , 信噪比 p为 10dB。 其中脏纸预编码( Dirty-Paper Coding, DPC )方法是最优的 预编码方法, 其余的几种预编码方法分别是现有的最优的迫零预编码方法 ( Optimal ZF ) 、 机会正交预编码方法( Opportunistic ORB ) 、 1比特反馈预
编码方法( 1 -Bit Feedback ) , 及基于本发明实施例的 1 -Bit ORB方法。 从图 6 可以看出在用户设备总数趋于无穷大时, 各曲线的走向的趋于一致的, 即 基于本实施例的预编码方法可以达到最优的和容量扩展律。 从图 6中还可以 看出当用户设备总数较少时, 基于本发明实施例的预编码方法与最优预编码 的曲线也较为相似, 即在用户设备总数较少时, 基于本发明实施例的预编码 方法也可以具有一定的较好性能。 6 is a simulation relationship diagram of the total number of users and the capacity in the first embodiment of the present invention. The simulation basis of this embodiment is that the number of transmitting antennas is 4, and the number of receiving antennas of each user equipment is 1, the signal to noise ratio p It is 10dB. The Dirty-Paper Coding (DPC) method is the optimal precoding method. The other precoding methods are the optimal optimal zero-pre-coding method (Optim ZF) and the opportunity orthogonality. Precoding method (Opportunistic ORB), 1-bit feedback pre- A coding method (1-Bit Feedback), and a 1-Bit ORB method based on an embodiment of the present invention. It can be seen from FIG. 6 that when the total number of user equipments tends to infinity, the trend of the curves tends to be uniform, that is, the pre-coding method based on the present embodiment can achieve an optimal and capacity expansion law. It can be seen from FIG. 6 that when the total number of user equipments is small, the precoding method and the optimal precoding curve according to the embodiment of the present invention are also similar, that is, when the total number of user equipments is small, based on the embodiment of the present invention. The precoding method can also have some better performance.
图 7为本发明第一实施例中信噪比与和容量的仿真关系曲线图, 本实施 例的仿真基础是发射天线数 ^为 4, 每个用户设备的接收天线数 N为 1 , 用 户设备总数 为 100。从图 7中可以看出各曲线的走向趋势是也可以看出当信 噪比变化时, 本实施例也可以达到最优的和容量律。 7 is a simulation relationship diagram of signal-to-noise ratio and sum capacity in the first embodiment of the present invention. The simulation basis of this embodiment is that the number of transmitting antennas is 4, and the number of receiving antennas N of each user equipment is 1, user equipment. The total is 100. It can be seen from Fig. 7 that the trend of each curve is also that the optimum and capacity law can be achieved in this embodiment when the signal-to-noise ratio changes.
图 8为本发明第一实施例中用户总数与反馈量的仿真关系曲线图。 其中 从上至下的曲线表示的是发射天线数目分别为 6、 5、 4、 3时, 用户设备总数 与反馈量的关系图, 从图 8中可以看出, 各曲线在用户设备总数趋于无穷大 时的极限值分别为 61og6、 51og5、 41og4、 31og3 , 即本实施例的平均反馈率将 Nt \ogNt。 而现有技术中的不采用基于门限的反馈机制, 对于每个用户最多 有 min A^NJlogN, 比特的反馈, 整个系统的反馈比特可能达到
比特, 这样其反馈开销太大。 采用本方案后, 其平均总反馈 开销是 A^ logN,比特。 相比于现有 1^^ ,^)10§ 的反馈量, 可以大大减小 反馈量。 FIG. 8 is a graph showing a simulation relationship between the total number of users and the feedback amount in the first embodiment of the present invention. The curve from top to bottom shows the relationship between the total number of user equipments and the feedback amount when the number of transmitting antennas is 6, 5, 4, and 3 respectively. As can be seen from Figure 8, the total number of user equipments tends to be different. The limit values at infinity are 61og6, 51og5, 41og4, 31og3, respectively, that is, the average feedback rate of this embodiment will be N t \o g N t . However, the threshold-based feedback mechanism is not used in the prior art, and for each user, there is a maximum of min A^NJlogN, bit feedback, and the feedback bits of the entire system may reach Bit, so its feedback overhead is too large. After adopting this scheme, the average total feedback overhead is A^logN, bit. Compared with the feedback amount of the existing 1^^, ^)1 0 § , the feedback amount can be greatly reduced.
图 9为本发明第二实施例的用户设备的结构示意图, 包括接收模块 91、 获取模块 92和反馈模块 93。 接收模块 91用于接收随机波束信息流, 根据各 随机波束信息流的信干噪比确定最优波束集;获取模块 92用于获取反馈门限 值; 反馈模块 93用于反馈接收模块 91得到的最优波束集中至少一个信干噪 比高于获取模块 92得到的反馈门限值的波束的信息。 FIG. 9 is a schematic structural diagram of a user equipment according to a second embodiment of the present invention, including a receiving module 91, an obtaining module 92, and a feedback module 93. The receiving module 91 is configured to receive a random beam information stream, and determine an optimal beam set according to a signal to interference and noise ratio of each random beam information stream; the obtaining module 92 is configured to obtain a feedback threshold value; and the feedback module 93 is configured to feedback the receiving module 91. The optimal beam sets information of at least one beam whose signal to interference and noise ratio is higher than the feedback threshold obtained by the obtaining module 92.
获取模块 92具体用于接收基站发送的与该用户设备对应的反馈门限值, 与该用户设备对应的反馈门限值由基站根据信干噪比分布函数、 用户设备总
数和与该用户设备对应的环境因素中的至少一个参数确定; 或者, 获取模块The obtaining module 92 is specifically configured to receive a feedback threshold corresponding to the user equipment sent by the base station, and the feedback threshold corresponding to the user equipment is used by the base station according to a signal to interference and noise ratio distribution function, and the total user equipment. And determining at least one of an environmental factor corresponding to the user equipment; or, acquiring a module
92具体用于接收基站发送的对各个用户设备均相同的公共的反馈门限值, 该 对各个用户设备均相同的公共的反馈门限值由基站根据信干噪比分布函数、 用户设备总数、 各用户设备对应的环境因素中的至少一个参数及预定策略确 定; 或者, 获取模块 92具体用于接收基站发送的用户设备总数和环境因素, 用户设备根据信干噪比分布函数和所述用户设备总数及环境因素中的一个参 数确定反馈门限值。 The specific feedback threshold value is the same for each user equipment sent by the base station, and the common feedback threshold value for each user equipment is determined by the base station according to the signal to interference and noise ratio distribution function, the total number of user equipments, At least one of the environmental factors corresponding to the user equipment and the predetermined policy is determined; or the acquiring module 92 is specifically configured to receive the total number of user equipments and environmental factors sent by the base station, and the user equipment according to the signal to interference and noise ratio distribution function and the user equipment One of the total and environmental factors determines the feedback threshold.
本实施例通过获取门限值, 在最优波束的信干噪比高于门限值时反馈最 优波束的信息, 可以降低反馈量。 In this embodiment, by acquiring the threshold value, when the signal to interference and noise ratio of the optimal beam is higher than the threshold value, the information of the optimal beam is fed back, and the feedback amount can be reduced.
图 10为本发明第三实施例的基站的结构示意图, 包括计算模块 101和发 送模块 102。 计算模块 101用于计算反馈门限值; 发送模块 102用于将计算 模块 101得到的该反馈门限值发送给用户设备, 所述用户设备将至少一个信 干噪比高于所述反馈门限值的波束的信息反馈给所述基站。 FIG. 10 is a schematic structural diagram of a base station according to a third embodiment of the present invention, which includes a calculation module 101 and a sending module 102. The calculation module 101 is configured to calculate a feedback threshold. The sending module 102 is configured to send the feedback threshold obtained by the calculation module 101 to the user equipment, where the user equipment has at least one signal to interference and noise ratio higher than the feedback threshold. The information of the beam of values is fed back to the base station.
其中, 计算模块 101具体用于根据信干噪比分布函数、 用户设备总数和 各用户设备对应的环境因素中的至少一个参数确定针对各用户设备的反馈门 限值; 或者, 计算模块 101具体用于根据信干噪比分布函数、 用户设备总数、 各用户设备对应的环境因素中的至少一个参数得到针对各用户设备的反馈门 限值; 并根据预定策略及针对各用户设备的反馈门限值得到公共的反馈门限 值。 The calculation module 101 is specifically configured to determine a feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment; or, the calculation module 101 is specifically used. Obtaining a feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment; and according to a predetermined policy and a feedback threshold value for each user equipment Get a common feedback threshold.
进一步地, 本实施例还可以包括选择模块, 用于接收各用户设备发送的 波束信息, 形成针对各波束的用户集; 并在同一个波束信息对应的用户集中 随机选择一个用户设备, 将该波束的数据发送给随机选择的用户设备。 Further, the embodiment may further include a selection module, configured to receive beam information sent by each user equipment, to form a user set for each beam, and randomly select a user equipment in the user set corresponding to the same beam information, and the beam is selected. The data is sent to a randomly selected user device.
本实施例通过计算得到反馈门限值, 将该反馈门限值发送给用户设备, 使用户设备在最优波束的信干噪比高于门限值时反馈, 可以降低反馈量。 In this embodiment, the feedback threshold is obtained by the calculation, and the feedback threshold is sent to the user equipment, so that the user equipment feedbacks when the signal to interference and noise ratio of the optimal beam is higher than the threshold, and the feedback amount can be reduced.
图 11 为本发明第四实施例的预编码反馈系统的结构示意图, 包括基站 111和用户设备 112。基站 111用于发送随波束信息流及门限信息; 用户设备
112用于根据基站 111发送的所述随机波束信息获取最优波束集, 根据基站 111 发送的所述门限信息获取反馈门限值, 反馈最优波束集中至少一个信干 噪比高于反馈门限值的波束的信息。 FIG. 11 is a schematic structural diagram of a precoding feedback system according to a fourth embodiment of the present invention, including a base station 111 and a user equipment 112. The base station 111 is configured to send the beam information stream and the threshold information; the user equipment The algorithm is configured to obtain an optimal beam set according to the random beam information sent by the base station 111, obtain a feedback threshold according to the threshold information sent by the base station 111, and feed back at least one signal to interference and noise ratio in the optimal beam set is higher than a feedback threshold. The value of the beam information.
其中, 门限信息可以具体为各用户设备对应的反馈门限值, 基站 111具 体用于根据信干噪比分布函数、 用户设备总数和各用户设备对应的环境因素 中的至少一个参数确定针对各用户的反馈门限值; 用户设备 112具体用于接 收所述基站 111得到的与自身对应的反馈门限值。 The threshold information may be specifically a feedback threshold corresponding to each user equipment, and the base station 111 is specifically configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, The feedback threshold is used by the user equipment 112 to receive the feedback threshold corresponding to the base station 111.
或者, 门限信息可以具体为各用户设备公共的反馈门限值, 基站 111具 体用于根据信干噪比分布函数、 用户设备总数和各用户设备对应的环境因素 中的至少一个参数确定针对各用户设备的反馈门限值, 并根据预定策略及针 对各用户设备的反馈门限值得到公共的反馈门限值; 用户设备 112具体用于 接收所述基站 111得到的各用户设备均相同的公共的反馈门限值。 Alternatively, the threshold information may be specifically a feedback threshold value common to each user equipment, and the base station 111 is specifically configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, for each user. a feedback threshold of the device, and a common feedback threshold is obtained according to a predetermined policy and a feedback threshold for each user equipment. The user equipment 112 is specifically configured to receive the common publicity of each user equipment obtained by the base station 111. Feedback threshold.
或者, 基站 111具体用于将用户设备总数和与各用户设备对应的环境因 素发给对应的用户设备; 用户设备 112根据所述基站 111发送的信干噪比分 布函数、 用户设备总数及环境因素中的至少一个确定各自的反馈门限值。 Or the base station 111 is specifically configured to send the total number of user equipments and the environmental factors corresponding to the user equipments to the corresponding user equipments; the user equipment 112 according to the signal to interference and noise ratio distribution function, the total number of user equipments, and environmental factors sent by the base station 111 At least one of the determinations determines a respective feedback threshold.
进一步地, 基站 111还可以用于接收各用户设备发送的波束信息, 形成 针对各波束的用户集; 并在同一个波束信息对应的用户集中随机选择一个用 户设备, 将该波束的数据发送给随机选择的用户设备。 Further, the base station 111 is further configured to receive the beam information sent by each user equipment, and form a user set for each beam; and randomly select a user equipment in the user set corresponding to the same beam information, and send the data of the beam to the random Selected user device.
本实施例通过不同的方式得到反馈门限值, 在最优波束的信干噪比高于 反馈门限值时反馈最优波束的信息, 可以降低反馈量。 In this embodiment, the feedback threshold is obtained in different manners. When the signal to interference and noise ratio of the optimal beam is higher than the feedback threshold, the feedback of the optimal beam information can reduce the feedback amount.
本领域普通技术人员可以理解: 实现上述方法实施例的全部或部分步 骤可以通过程序指令相关的硬件来完成, 前述的程序可以存储于一计算机 可读取存储介质中, 该程序在执行时, 执行包括上述方法实施例的步骤; 而前述的存储介质包括: ROM、 RAM, 磁碟或者光盘等各种可以存储程 序代码的介质。 A person skilled in the art can understand that all or part of the steps of implementing the above method embodiments may be completed by using hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, and the program is executed when executed. The foregoing steps include the steps of the foregoing method embodiments; and the foregoing storage medium includes: a medium that can store program codes, such as a ROM, a RAM, a magnetic disk, or an optical disk.
最后应说明的是: 以上实施例仅用以说明本发明的技术方案而非对其进
行限制, 尽管参照较佳实施例对本发明进行了详细的说明, 本领域的普通技 术人员应当理解: 其依然可以对本发明的技术方案进行修改或者等同替换, 而这些修改或者等同替换亦不能使修改后的技术方案脱离本发明技术方案的 ^"神和范围。
Finally, it should be noted that the above embodiments are only used to illustrate the technical solution of the present invention, rather than The present invention has been described in detail with reference to the preferred embodiments. It will be understood by those skilled in the art that the invention may still be modified or substituted, and the modifications or equivalents may not be modified. The latter technical solution departs from the "God and scope" of the technical solution of the present invention.
Claims
1、 一种预编码反馈方法, 其特征在于, 包括: A precoding feedback method, comprising:
接收随机波束信息流, 根据所述随机波束信息流的信干噪比确定最优波 获取反馈门限值; Receiving a random beam information stream, and determining an optimal wave acquisition feedback threshold according to a signal to interference and noise ratio of the random beam information stream;
反馈最优波束集中至少一个信干噪比高于所述反馈门限值的波束的信 Feeding at least one letter of the beam with a signal to interference and noise ratio higher than the feedback threshold in the optimal beam set
2、根据权利要求 1所述的方法,其特征在于,所述获取反馈门限值包括: 接收基站发送的与每个用户设备对应的反馈门限值, 所述与每个用户设 备对应的反馈门限值由基站根据信干噪比分布函数、 用户设备总数和各用户 设备对应的环境因素中的至少一个参数确定; 或者, The method according to claim 1, wherein the obtaining the feedback threshold comprises: receiving a feedback threshold corresponding to each user equipment sent by the base station, and the feedback corresponding to each user equipment The threshold value is determined by the base station according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment; or
接收基站发送的对各个用户设备均相同的公共的反馈门限值, 所述公共 的反馈门限值由基站根据信干噪比分布函数、 用户设备总数、 各用户设备对 应的环境因素中的至少一个参数及预定策略确定; 或者, And receiving, by the base station, a common feedback threshold that is the same for each user equipment, where the common feedback threshold is determined by the base station according to a signal to interference and noise ratio distribution function, a total number of user equipments, and environmental factors corresponding to each user equipment. a parameter and a predetermined policy determination; or,
接收基站发送的用户设备总数和环境因素, 用户设备根据信干噪比分布 函数和所述用户设备总数和环境因素中的至少一个参数确定反馈门限值。 The user equipment receives the total number of user equipments and environmental factors, and the user equipment determines the feedback threshold according to at least one of a signal to interference and noise ratio distribution function and the total number of user equipments and environmental factors.
3、 根据权利要求 2所述的方法, 其特征在于, 所述根据信干噪比分布 函数、用户设备总数和环境因素中的至少一个参数确定反馈门限值的计算公 式为: The method according to claim 2, wherein the calculation formula for determining the feedback threshold according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor is:
其中, ( 为第 k个用户设备的反馈门限值, K为用户设备总数, 为用户设备的接收天线的数目; e PYk Where is (the feedback threshold of the kth user equipment, K is the total number of user equipments, and is the number of receiving antennas of the user equipment; e PYk
函数 Fk的表达式为: ^( ) = 1 - ( + 1)^-ΐ , 其中, Nt为基站的发射 天线的数目, p为每个发射天线的信噪比, ^为第 k个用户设备对应的环
境因素。 The expression of the function F k is: ^( ) = 1 - ( + 1) ^-ΐ , where N t is the number of transmitting antennas of the base station, p is the signal-to-noise ratio of each transmitting antenna, and ^ is the kth User equipment corresponding ring Circumstances.
4、 根据权利要求 2所述的方法, 其特征在于, 所述根据信干噪比分布 函数、 用户设备总数、 各用户设备对应的环境因素中的至少一个参数及预定 策略确定公共的反馈门限值包括: The method according to claim 2, wherein the determining a common feedback threshold according to a signal to interference and noise ratio distribution function, a total number of user equipments, at least one of environmental factors corresponding to each user equipment, and a predetermined policy Values include:
根据信干噪比分布函数、 用户设备总数、 各用户设备对应的环境因素中 的至少一个参数得到针对各用户设备的反馈门限值; And obtaining a feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment;
根据预定策略及针对各用户设备的反馈门限值得到公共的反馈门限值。 A common feedback threshold is obtained according to a predetermined policy and a feedback threshold for each user equipment.
5、 根据权利要求 1所述的方法, 其特征在于, 所述根据所述随机波束信 息流的信干噪比确定最优波束集包括: 当用户设备的接收天线的数目为 1个 时, 将信干噪比最大的波束组成最优波束集; 当用户设备的接收天线的数目 大于 1个时,将信干噪比较大的 N个波束组成最优波束集,其中, N≤Nr , ΝΓ 为每个用户的接收天线的数目。 The method according to claim 1, wherein the determining the optimal beam set according to the signal to interference and noise ratio of the random beam information stream comprises: when the number of receiving antennas of the user equipment is one, The beam with the largest signal-to-noise ratio constitutes the optimal beam set. When the number of receiving antennas of the user equipment is greater than one, the N beams with relatively large dry-noise signals form an optimal beam set, where N≤Nr , Ν Γ The number of receiving antennas for each user.
6、 一种用户设备, 其特征在于, 包括: 6. A user equipment, comprising:
接收模块, 用于接收随机波束信息流, 根据所述随机波束信息流的信干 噪比确定最优波束集; a receiving module, configured to receive a random beam information stream, and determine an optimal beam set according to a signal to interference and noise ratio of the random beam information stream;
获取模块, 用于获取反馈门限值; An obtaining module, configured to obtain a feedback threshold;
反馈模块, 与所述接收模块和获取模块连接, 用于反馈最优波束集中至 少一个信干噪比高于所述反馈门限值的波束的信息。 The feedback module is connected to the receiving module and the acquiring module, and is configured to feed back information of at least one beam whose signal to interference and noise ratio is higher than the feedback threshold.
7、 根据权利要求 6所述的用户设备, 其特征在于: 7. The user equipment according to claim 6, wherein:
所述获取模块具体用于接收基站发送的与所述用户设备对应的反馈门限 值, 该与所述用户设备对应的反馈门限值由基站根据信干噪比分布函数、 用 户设备总数和与所述用户设备对应的环境因素中的至少一个参数确定;或者, 所述获取模块具体用于接收基站发送的对各个用户设备均相同的公共的 反馈门限值, 所述公共的反馈门限值由基站根据信干噪比分布函数、 用户设 备总数、 各用户设备对应的环境因素中的至少一个参数及预定策略确定; 或 者,
所述获取模块具体用于接收基站发送的用户设备总数和环境因素, 所述 用户设备根据信干噪比分布函数和所述用户设备总数及环境因素中的至少一 个参数确定反馈门限值。 The acquiring module is specifically configured to receive a feedback threshold corresponding to the user equipment sent by the base station, where the feedback threshold corresponding to the user equipment is determined by the base station according to a signal to interference and noise ratio distribution function, a total number of user equipments, and At least one of the environmental factors corresponding to the user equipment is determined; or the acquiring module is specifically configured to receive a common feedback threshold that is sent by the base station and is the same for each user equipment, where the common feedback threshold is Determined by the base station according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and environmental factors corresponding to each user equipment; and a predetermined policy; or The acquiring module is specifically configured to receive a total number of user equipments and environmental factors sent by the base station, where the user equipment determines a feedback threshold according to at least one of a signal to interference and noise ratio distribution function and the total number of user equipments and environmental factors.
8、 一种基站, 其特征在于, 包括: 8. A base station, comprising:
计算模块, 用于根据信干噪比分布函数、 用户设备总数和各用户设备对 应的环境因素中的至少一个参数确定针对各用户设备的反馈门限值; 或者根 据信干噪比分布函数、 用户设备总数、 各用户设备对应的环境因素中的至少 一个参数得到针对各用户设备的反馈门限值, 并根据预定策略及针对各用户 设备的反馈门限值得到公共的反馈门限值; a calculation module, configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment, a feedback threshold value for each user equipment; or a user according to a signal to interference and noise ratio distribution function, a user At least one of the total number of devices and the environmental factors corresponding to each user equipment obtains a feedback threshold for each user equipment, and obtains a common feedback threshold according to a predetermined policy and a feedback threshold for each user equipment;
发送模块, 与所述计算模块连接, 用于将所述各用户设备的反馈门限值 或者所述公共的反馈门限值发送给用户设备。 The sending module is connected to the computing module, and is configured to send the feedback threshold of each user equipment or the common feedback threshold to the user equipment.
9、 根据权利要求 8 所述的方法, 其特征在于, 所述计算模块根据信 干噪比分布函数、 用户设备总数和环境因素中的至少一个参数确定针对各用 户设备的反馈门限值的计算公式为: The method according to claim 8, wherein the calculating module determines the calculation of the feedback threshold value for each user equipment according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor. The formula is:
其中, ( 为第 k个用户设备的反馈门限值, K为用户设备总数, 为用户设备的接收天线的数目; e P Where is (the feedback threshold of the kth user equipment, K is the total number of user equipments, and is the number of receiving antennas of the user equipment; e P
函数 Fk的表达式为: ^ ( ) = 1 ~ ( + 1) ^ -1 , 其中, Nt为基站的发射 天线的数目, p为每个发射天线的信噪比, ^为第 k个用户设备对应的环 境因素。 The expression of the function F k is: ^ ( ) = 1 ~ ( + 1 ) ^ -1 , where N t is the number of transmitting antennas of the base station, p is the signal-to-noise ratio of each transmitting antenna, and ^ is the kth The environmental factor corresponding to the user equipment.
10、 根据权利要求 8所述的基站, 其特征在于, 还包括: The base station according to claim 8, further comprising:
选择模块, 用于接收各用户设备发送的波束信息, 形成针对各波束的用 户集; 并在同一个波束信息对应的用户集中随机选择一个用户设备, 将该波 束的数据发送给随机选择的用户设备。
a selection module, configured to receive beam information sent by each user equipment, to form a user set for each beam; and randomly select a user equipment in a user set corresponding to the same beam information, and send the data of the beam to the randomly selected user equipment .
11、 一种预编码反馈系统, 其特征在于, 包括: 11. A precoding feedback system, comprising:
基站, 用于发送随机波束信息流及门限信息给用户设备; a base station, configured to send a random beam information flow and threshold information to the user equipment;
用户设备, 与所述基站连接, 用于根据所述随机波束信息获取最优波束 集, 根据所述门限信息获取反馈门限值, 反馈最优波束集中至少一个信干噪 比高于反馈门限值的波束的信息。 The user equipment is connected to the base station, configured to obtain an optimal beam set according to the random beam information, obtain a feedback threshold according to the threshold information, and feed back at least one signal to interference and noise ratio in the optimal beam set is higher than a feedback threshold. The value of the beam information.
12、 根据权利要求 11所述的系统, 其特征在于: 12. The system of claim 11 wherein:
所述基站发送的门限信息具体为针对各用户的反馈门限值, 所述基站具 体用于根据信干噪比分布函数、 用户设备总数和各用户设备对应的环境因素 中的至少一个参数确定针对各用户设备的反馈门限值; The threshold information sent by the base station is specifically a feedback threshold for each user, and the base station is specifically configured to determine, according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor corresponding to each user equipment. Feedback threshold of each user equipment;
所述用户设备具体用于接收所述基站得到的与自身对应的反馈门限值。 The user equipment is specifically configured to receive a feedback threshold that is obtained by the base station and corresponds to itself.
13、 根据权利要求 11所述的系统, 其特征在于: 13. The system of claim 11 wherein:
所述基站发送的门限信息具体为公共的反馈门限值, 所述基站具体用于 根据信干噪比分布函数、 用户设备总数和各用户设备对应的环境因素中的至 少一个参数确定针对各用户设备的反馈门限值, 并根据预定策略及针对各用 户设备的反馈门限值得到公共的反馈门限值; The threshold information sent by the base station is specifically a common feedback threshold, and the base station is specifically configured to determine, according to at least one parameter of a signal to interference and noise ratio distribution function, a total number of user equipments, and environmental factors corresponding to each user equipment, a feedback threshold of the device, and obtaining a common feedback threshold according to a predetermined policy and a feedback threshold for each user equipment;
所述用户设备具体用于接收所述公共的反馈门限值。 The user equipment is specifically configured to receive the common feedback threshold.
14、 根据权利要求 11所述的系统, 其特征在于: 14. The system of claim 11 wherein:
所述基站发送的门限信息具体为用户设备总数和与各用户设备对应的环 境因素, 所述基站具体用于将用户设备总数和与各用户设备对应的环境因素 发给对应的用户设备; The threshold information sent by the base station is specifically the total number of the user equipments and the environmental factors corresponding to the user equipments, and the base station is specifically configured to send the total number of the user equipments and the environmental factors corresponding to the user equipments to the corresponding user equipments;
所述用户设备根据所述基站发送的信干噪比分布函数、 用户设备总数及 环境因素中的至少一个参数确定各自的反馈门限值。 The user equipment determines a respective feedback threshold according to at least one of a signal to interference and noise ratio distribution function, a total number of user equipments, and an environmental factor sent by the base station.
15、 根据权利要求 11所述的系统, 其特征在于: 15. The system of claim 11 wherein:
所述基站还用于接收各用户设备发送的波束信息, 形成针对各波束的用 户集; 并在同一个波束信息对应的用户集中随机选择一个用户设备, 将该波 束的数据发送给随机选择的用户设备。
The base station is further configured to receive beam information sent by each user equipment, form a user set for each beam, and randomly select a user equipment in a user set corresponding to the same beam information, and send the data of the beam to the randomly selected user. device.
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CN103795491B (en) * | 2012-11-01 | 2019-01-15 | 中兴通讯股份有限公司 | Processing method, base station and the terminal of channel state information |
CN107370525B (en) | 2016-05-12 | 2021-03-30 | 华为技术有限公司 | Method, base station, terminal equipment and system for channel state information feedback |
WO2017193366A1 (en) * | 2016-05-13 | 2017-11-16 | 华为技术有限公司 | Information feedback method and station |
WO2017195183A1 (en) | 2016-05-13 | 2017-11-16 | Huawei Technologies Co., Ltd. | Precoding and channel state information acquisition for multi-stream transmissions in massive mimo systems |
CN107342836B (en) * | 2017-03-17 | 2019-04-23 | 深圳大学 | Weighting sparse constraint robust ada- ptive beamformer method and device under impulsive noise |
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CN113300989A (en) * | 2021-07-28 | 2021-08-24 | 四川创智联恒科技有限公司 | Method for rapidly realizing NR-5G physical downlink shared channel |
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