WO2011085514A1 - Method and equipment for inter-cell interference coordination in relay-assisted cellular system - Google Patents
Method and equipment for inter-cell interference coordination in relay-assisted cellular system Download PDFInfo
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W16/00—Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
- H04W16/24—Cell structures
- H04W16/26—Cell enhancers or enhancement, e.g. for tunnels, building shadow
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/14—Relay systems
- H04B7/15—Active relay systems
- H04B7/155—Ground-based stations
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B7/00—Radio transmission systems, i.e. using radiation field
- H04B7/24—Radio transmission systems, i.e. using radiation field for communication between two or more posts
- H04B7/26—Radio transmission systems, i.e. using radiation field for communication between two or more posts at least one of which is mobile
- H04B7/2603—Arrangements for wireless physical layer control
- H04B7/2606—Arrangements for base station coverage control, e.g. by using relays in tunnels
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J11/00—Orthogonal multiplex systems, e.g. using WALSH codes
- H04J11/0023—Interference mitigation or co-ordination
- H04J11/005—Interference mitigation or co-ordination of intercell interference
Definitions
- the present invention relates to interference coordination methods and apparatus in a cellular system, and more particularly to a method and apparatus for inter-cell interference coordination in a relay assisted cellular network. Background technique
- Orthogonal Frequency Division Multiple Access has been accepted by 3rd Generation Partnership Project Long Term Evolution (3GPP LTE) as a promising downlink air interface technology for next generation systems (see S. Sesia, I. Toufik) And M. Baker, "LTE - the UMTS long term evolution: from theory to practice,” Wiley Press, 2009, incorporated herein by reference.
- OFDMA provides inherent flexibility for radio resource allocation and avoiding intra-cell interference.
- strong inter-cell interference caused by dense resource multiplexing limits the possibility of making full use of the OFDMA scheme. Therefore, to reduce inter-cell interference, it is necessary to provide suitable radio resource management (RRM).
- RRM radio resource management
- inter-cell interference Currently, the following three techniques for reducing inter-cell interference (ICIM) are mainly considered: 1) interference randomization, 2) interference cancellation, and 3) interference coordination (see M. Rahman, H. Yanikomeroglu, and W. Wong, "Interference avoidance With dynamic inter-cell coordination for downlink LTE system, "Proc. IEEE WCNC 09, April 2009, incorporated herein by reference.
- interference randomization does not substantially reduce interference
- interference cancellation can only eliminate primary interference, so interference coordination that limits downlink resource management in a coordinated manner to achieve optimal network performance is considered 3GPP LTE.
- 3GPP LTE 3GPP LTE
- FFR Fractional Frequency Multiplexing
- each UE may actively or passively access an eNB or a relay node (RN).
- RN relay node
- the present invention proposes a method and apparatus for performing inter-cell interference coordination ICIC in a relay assisted network.
- a method of performing inter-cell interference coordination ICIC in a relay assistance network in which a user equipment UE is divided into macro UEs directly served by a base station and via The relay node is indirectly relayed by the base station, and the method includes the following steps: calculating an average relay UE ratio, wherein the average relay UE ratio is a number of relay UEs served by a single relay node in the cell. Average percentage of the number of all UEs; determining the system bandwidth to be allocated to the relay node based on the calculated average relay UE ratio, and allocating the remaining system bandwidth to the base station; and determining the relay node and the base station based on the scheduling algorithm Further scheduling of the allocated system bandwidth.
- the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on a buffer queue state factor.
- the system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal.
- the step of determining further scheduling includes: calculating, according to a first enhanced proportional fair scheduling algorithm, a first scheduling criterion for the relay node, to determine a scheduling priority that further allocates the allocated system bandwidth to the relaying UE.
- Scheduling Algorithm
- ⁇ ' ( ⁇ ) denotes an instantaneous supportable data rate of the relay UE m
- the step of determining further scheduling further includes: calculating a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm to determine to further allocate the allocated system bandwidth to the macro UE and the relay backhaul link.
- Scheduling Algorithm Where t represents the time index, (t) represents the instantaneous supportable data rate of the macro UE n, (t) represents the exponentially filtered average service rate of the macro UE n for a certain time constant ⁇ , and R) represents the relay The average rate of the backhaul link corresponding to UE m, and ⁇ (0 represents the improved backhaul link rate considering the state of the relay buffer queue) - the method further includes, according to the current UE association scheme and traffic load information, Determine if the UE is a relay UE or a macro UE.
- an apparatus for performing inter-cell interference coordination ICIC in a relay assistance network in which a user equipment UE is divided into macro UEs directly served by a base station and via The relay node is indirectly relayed by the base station, and the device includes: a computing device, configured to calculate an average relay UE ratio, where the average relay UE ratio is a relay served by a single relay node in the cell The number of UEs is an average percentage of the number of all UEs; the allocating means is configured to determine a system bandwidth to be allocated to the relay node according to the calculated average relay UE ratio, and allocate the remaining system bandwidth to the base station; and a scheduling device, A method for determining further scheduling of the allocated system bandwidth by the relay node and the base station based on the scheduling algorithm.
- the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on a buffer queue state factor.
- the system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal.
- the scheduling apparatus includes: a first scheduling apparatus, configured to calculate, according to a first enhanced proportional fair scheduling algorithm, a first scheduling criterion for a relay node, to determine a scheduling priority for further allocating the allocated system bandwidth to the relay UE level.
- the first enhanced proportional fair scheduling algorithm is implemented by the following formula,
- ⁇ 'W represents the instantaneous supportable data rate of the relay UE m
- ⁇ 'W represents the instantaneous supportable data rate of the relay UE m
- ⁇ 'W represents the exponentially filtered average service rate of the relay UE m for a certain time constant
- (0 represents the relay UE m Expected buffer rate
- the scheduling apparatus further includes: a second scheduling apparatus, configured to calculate a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm, to determine to further allocate the allocated system bandwidth to the macro UE and to implement the relay back Second enhanced proportional fair scheduling algorithm,
- t represents a time index, indicating that the instantaneous UE can support the data rate
- JO represents the exponentially filtered average service rate of the macro UE n for a certain time constant ⁇ , and represents the average rate of the path corresponding to the relay UE m
- ⁇ (0 represents an improved backhaul link considering the state of the relay buffer queue.
- the device further includes determining means for determining the current UE association scheme and traffic load information, Whether the UE is a relay UE or a macro UE.
- the present invention is directed to a LTE downlink transmission in a relay-assisted cellular network, and proposes a new FFR-based ICIC scheme that utilizes a corresponding enhanced PFS algorithm.
- the entire system bandwidth is divided into two orthogonal parts, one for macro UEs served directly by the eNB and the other for relay UEs served by the cell edge RN.
- the resources used to relay the UE may be multiplexed by all RNs because the RN has limited transmission power; similarly, resources for macro UEs may also be multiplexed by all eNBs because these resources are for cell center UEs. This spectral division does not require power control at the eNB, but is very easy to implement.
- the semi-static adjustment is performed by determining the number of relay UEs according to the current UE association and traffic load, and then determining the amount of relay UE resources according to the calculated average relay UE ratio.
- an enhanced PFS that considers the state of the relay buffer in the scheduling priority criterion is proposed to provide an equalization method for resource usage.
- the present invention can significantly improve the system performance of a cellular system in which a relay node is deployed.
- FIG. 1 illustrates a typical FFR configuration in accordance with an exemplary embodiment of the present invention
- FIG. 2 shows a schematic diagram of relay assisted transmission in accordance with an exemplary embodiment of the present invention
- FIG. 3 is a block diagram showing the structure of an inter-cell interference coordination apparatus according to an exemplary embodiment of the present invention
- FIG. 4 is a flowchart showing an inter-cell interference coordination method according to an exemplary embodiment of the present invention.
- FIG. 6 illustrates an LTE FDD downlink frame structure in accordance with an exemplary embodiment of the present invention
- FIG. 7 illustrates a semi-static resource allocation in accordance with an exemplary embodiment of the present invention
- Figure 8 illustrates the throughput gain of an FRR based ICIC scheme in accordance with an illustrative embodiment of the present invention. detailed description .
- the present invention proposes a new fractional frequency reuse FFR scheme for inter-cell interference coordination ICIC in a relay-assisted cellular network.
- the basic idea of the present invention is to avoid intra-cell and inter-cell interference from an eNB to an RN through semi-static orthogonal resource allocation based on a relay UE association ratio and dynamic resource scheduling via an enhanced proportional fair scheduling (PFS) algorithm.
- PFS proportional fair scheduling
- UEs directly accessed and served by the eNB are referred to as macro UEs; and UEs indirectly served by the eNB via RNs are referred to as relay UEs;
- Fe can be multiplexed by all donor eNBs
- Fr can be multiplexed by all RNs. Since Fe is used for cell center UEs, it is expected that the interference power from neighboring eNBs is much smaller than the signal power from the donor eNB. At the same time, it can also be assumed that the inter-cell RN interference is within an acceptable range because R has a very limited coverage (the transmission power of the RN is much lower than the transmission power of the eNB);
- Fr The width of Fr is proportional to the average relay UE ratio, and is adjusted in a semi-static manner to match the current network state;
- the average relay UE ratio is the average percentage of the number of relayed UEs served by a single RN to the average number of UEs in a single cell. Specifically, the total number of relayed UEs in the whole network is divided by the total number of UEs in the whole network. The total number of RNs in the whole network. Since each cell may have a different total number of UEs, it may also contain a different number of RNs, and each RN may also serve a different number of relay UEs.
- the number of relay UEs is reported from each lower RN to the donor eNB via the Un interface; on the other hand, the number of relay UEs is exchanged between different eNBs through the X2 interface.
- Un interface is an interface between the Rn and the eNB
- X2 interface is an interface between the eNB and the eNB
- resource allocation is based on the Enhanced PF Scheduling (PFS) algorithm.
- PFS Enhanced PF Scheduling
- FIG. 3 is a block diagram showing the structure of an inter-cell interference coordination apparatus 300 according to an exemplary embodiment of the present invention.
- the inter-cell interference coordination device 300 includes: a computing device 301, configured to calculate an average a relaying UE ratio, wherein the average relaying UE ratio is an average percentage of the number of relaying UEs served by a single RN in the cell, and an allocation device 303, configured to calculate, according to the calculated average relaying UE ratio, Determining the system bandwidth to be allocated to the RN and allocating the remaining system bandwidth to the eNB; scheduling means 305 for determining further scheduling of the allocated system bandwidth by the RN and the eNB based on the enhanced proportional fair scheduling algorithm.
- the scheduling apparatus 305 includes: a first scheduling apparatus (not shown) for calculating a first scheduling result at the RN based on the first enhanced PFS algorithm to determine a schedule for further allocating the allocated system bandwidth to the relaying UE a second scheduling device (not shown) for calculating a second scheduling result at the eNB based on the second enhanced PFS algorithm to determine to further allocate the allocated system bandwidth to the macro UE and the relay backhaul chain
- a first scheduling apparatus (not shown) for calculating a first scheduling result at the RN based on the first enhanced PFS algorithm to determine a schedule for further allocating the allocated system bandwidth to the relaying UE
- a second scheduling device (not shown) for calculating a second scheduling result at the eNB based on the second enhanced PFS algorithm to determine to further allocate the allocated system bandwidth to the macro UE and the relay backhaul chain
- the scheduling priority of the path, wherein the first and second enhanced PFS algorithms are dependent on a buffer queue state factor.
- the inter-cell interference coordination device 300 can also include a determining device disposed prior to the computing device 301.
- UE (not shown), configured to determine, according to the current UE association scheme and traffic load information, whether the UE is a relay UE or a macro UE, so as to determine the number of relay UEs.
- an inter-cell interference coordination method will be described below with reference to FIG. 4-7.
- an LTE FDD downlink transmission is taken as an example. It will be appreciated that the invention is not limited thereto but may be applied to other wireless fields.
- Fig. 5 schematically shows the layout of a multi-cell hexagon and the corresponding spectral division. As shown in Figure 5, it can be deployed at the edge of each cell, for example, two RNs.
- each downlink frame in the LTE FDD system is typically 10 ms long, including 20 time slots of 0.5 ms in length, labeled 0-19, as shown in FIG. 6.
- a subframe is defined as two consecutive time slots, where subframe i includes time slots 2i and 2i+1.
- a UE that is directly served by an eNB is called a macro UE
- a UE that is indirectly served by an eNB through an RN is called a relay UE.
- the determining apparatus determines whether the UE is a relay UE or a macro UE according to the current UE association scheme and traffic load information, so as to determine the number of relay UEs.
- each RN reports the number of relay UEs to the eNB through the Un interface, and exchanges the UE association information (that is, the number of relay UEs) in different eNBs through the X2 interface.
- step S403 the average relay UE ratio is calculated by the computing device 301.
- step S405 the allocating means 303 determines to allocate to the RN based on the calculated average relay UE ratio. System bandwidth, and allocate the remaining system bandwidth to the eNB.
- the present invention proposes an enhanced PFS, which is obtained by introducing factors related to the buffer queue state in the scheduling criteria, thereby achieving a more suitable resource allocation.
- step S407 the scheduling device 305 determines further scheduling of the Fr and Fe allocated by the RN and the eNB for the allocation device 303 based on the enhanced PFS algorithm.
- the first scheduling result at the RN is calculated by the first scheduling device based on the first enhanced PFS algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the relay UE.
- the second scheduling device calculates a second scheduling result at the eNB based on the second enhanced PFS algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the macro UE and the relay backhaul link. among them,
- the scheduling priority criterion is
- ⁇ (0 is the expected buffer rate of the relay UE m, defined as:
- t denotes a time index indicating that the instantaneous UE can support the data rate
- r (t) denotes the relay UE m
- the average rate of the corresponding backhaul link, and / ⁇ (0 represents the modified backhaul link rate considering the relay buffer queue state.
- the calculation of the PF priority of the macro UE n is Hf, lR a n v fy
- the average rate of the backhaul link corresponding to the relay UE m (4(0) is the same as in the prior art.
- R ⁇ (o denotes an improved backhaul link rate that takes into account the queue status of the relay buffer:
- R p (t) + ⁇ , if the buffer of the link / is empty, and the total RN buffer queue length is less than a certain threshold S2 ( 5 )
- (0 is the backhaul link /, mecanic instantaneous support channel rate.
- the relay backhaul link does not consume too much Fe-band resources, and can simultaneously provide a balanced data stream to the relay UE. Thus, it can be in the macro UE and the relay backhaul chain
- the Fe band is more appropriately used in the road.
- the present invention is directed to a LTE downlink transmission in a relay-assisted cellular network, and proposes a new FFR-based ICIC scheme that utilizes a corresponding enhanced PFS algorithm.
- the entire system bandwidth is divided into two orthogonal parts, one for macro UEs served directly by the eNB and the other for relay UEs served by the cell edge RN.
- the resources used to relay the UE may be multiplexed by all RNs because the RN has limited transmission power.
- resources for macro UEs can also be multiplexed by all eNBs because these resources are for cell center UEs. This spectral division does not require power control at the eNB, but is very easy to implement.
- the semi-static adjustment is performed by determining the number of relay UEs according to the current UE association and traffic load, and then determining the amount of relay UE resources according to the calculated average relay UE ratio.
- an enhanced PFS that considers the state of the relay buffer in the scheduling priority criterion is proposed to provide an equalization method for resource usage.
- the proposed method can be used for Type I and Type II relay nodes, which is very advantageous for applications in the 3GPP LTE-A standard.
- the FFR-based ICIC scheme according to the present invention can provide in terms of cell average and cell edge spectral efficiency For better system performance.
- Figure 8 shows a schematic diagram of the significant performance gain (normalized user throughput) of the proposed method.
- Table 1 below records the corresponding cell average and cell edge (5%) user throughput gains for each of the cases in Figure 8 (the throughput has been normalized in Table 1).
- RN multiplexing there are 9.4% and 4.0% increase in cell average and cell edge throughput respectively; by using orthogonal RN transmission in each cell, in cell average and cell edge There was an increase of 3.0% and 16.0% in throughput, respectively.
- Table 2 below gives the parameters used in the simulation of the wireless cellular system using the method and apparatus of the present invention.
- the present invention mainly relates to an FFR-based ICIC solution that satisfies the 3GPP LTE relay definition and thus can be implemented directly based on existing technologies.
- some embodiments also include a machine readable or computer readable program storage device (eg, a digital data storage medium) and encoding machine executable or computer executable program instructions, wherein the instructions perform some of the above methods or All steps.
- the program storage device can be a digital memory, a magnetic storage medium (such as a magnetic disk and magnetic tape), a hardware or an optically readable digital data storage medium.
- Embodiments also include a computer that executes a program recorded on a storage medium to perform the steps of the above method.
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Abstract
A method for inter-cell interference coordination (ICIC) in a relay-assisted network is provided in the present invention, and in the relay-assisted network, user equipments (UE) are divided into macro UEs which are directly serviced by base stations, and relay UEs which are indirectly serviced by the base stations through relay nodes. The method includes the following steps: calculating the mean percentage of relay UEs, wherein the mean percentage of relay UEs is the mean percentage of the number of relay UEs serviced by a single relay node in the cell to the total number of UEs; according to the calculated mean percentage of relay UEs, determining the system bandwidth to be distributed to the relay nodes, and distributing the rest system bandwidth to the base station; and determining the further scheduling of the relay nodes and base station to the distributed system bandwidth based on the scheduling algorithm. An equipment for inter-cell interference coordination ICIC in the relay-assisted network is also provided in the present invention.
Description
中继辅助蜂窝系统中用于小区间干扰协调的方法和设备 Method and apparatus for inter-cell interference coordination in a relay-assisted cellular system
技术领域 Technical field
本发明涉及蜂窝系统中的干扰协调方法和设备, 更具体地讲,涉及在中继辅助蜂 窝网络中进行小区间干扰协调的方法和设备。 背景技术 The present invention relates to interference coordination methods and apparatus in a cellular system, and more particularly to a method and apparatus for inter-cell interference coordination in a relay assisted cellular network. Background technique
正交频分多址接入 (OFDMA) 已被第三代伙伴计划长期演进 (3GPP LTE) 接受 为用于下一代系统的有前景的下行链路空中接口技术 (参见 S. Sesia, I. Toufik, and M. Baker, "LTE - the UMTS long term evolution: from theory to practice, " Wiley Press, 2009,在此一并引入作为参考)。 OFDMA为无线电资源分配和避免小区内干扰提供了 固有的灵活性。 然而, 由密集资源复用导致的强小区间干扰限制了充分利用 OFDMA 方案的可能。 因而, 为减小小区间干扰, 提供适合的无线电资源管理(RRM) 是十分 必要的。 Orthogonal Frequency Division Multiple Access (OFDMA) has been accepted by 3rd Generation Partnership Project Long Term Evolution (3GPP LTE) as a promising downlink air interface technology for next generation systems (see S. Sesia, I. Toufik) And M. Baker, "LTE - the UMTS long term evolution: from theory to practice," Wiley Press, 2009, incorporated herein by reference. OFDMA provides inherent flexibility for radio resource allocation and avoiding intra-cell interference. However, strong inter-cell interference caused by dense resource multiplexing limits the possibility of making full use of the OFDMA scheme. Therefore, to reduce inter-cell interference, it is necessary to provide suitable radio resource management (RRM).
目前, 主要考虑以下三种降低小区间干扰 (ICIM) 的技术: 1 ) 干扰随机化, 2) 干扰消除 , 3 )干扰协调(参见 M. Rahman, H. Yanikomeroglu, and W. Wong, " Interference avoidance with dynamic inter-cell coordination for downlink LTE system, " Proc. IEEE WCNC 09, April 2009, 在此一并引入作为参考)。, 然而, 干扰随机化并没有从本质 上降低干扰, 而干扰消除仅能够消除主要干扰, 因此以协调的方式对下行链路资源管 理进行限制以实现最佳网络性能的干扰协调被视为 3GPP LTE中最有前景的 ICIM方 式。 Currently, the following three techniques for reducing inter-cell interference (ICIM) are mainly considered: 1) interference randomization, 2) interference cancellation, and 3) interference coordination (see M. Rahman, H. Yanikomeroglu, and W. Wong, "Interference avoidance With dynamic inter-cell coordination for downlink LTE system, "Proc. IEEE WCNC 09, April 2009, incorporated herein by reference. However, interference randomization does not substantially reduce interference, and interference cancellation can only eliminate primary interference, so interference coordination that limits downlink resource management in a coordinated manner to achieve optimal network performance is considered 3GPP LTE. The most promising ICIM approach.
大量的可用小区间干扰协调(ICIC)技术基于如图 1所示的分数频率复用 (FFR) 原理。 FFR考虑复用分割, 其中向小区边缘用户设备 (UE) 分配具有比小区中心 UE 高的复用因子的资源(一部分频谱), 分配给小区中心 UE的资源(整个频带或一部分 频谱) 仅以比至小区边缘 UE的增强型节点 B (eNB ) 传输的功率低的受限功率进行 复用。 然而, 基于各种考虑 (尤其是下行链路功率控制可能使下行链路信道质量指示 符 (CQI) 测量混乱, 因而影响下行链路自适应和调度的有效性), 最终在 LTE 中的 数据信道上并不支持下行链路功率控制, 这使得 FFR对于 ICIC是无效或无意义的。 A large number of available Inter-Cell Interference Coordination (ICIC) techniques are based on the Fractional Frequency Multiplexing (FFR) principle shown in Figure 1. FFR considers multiplexing division, in which a cell edge user equipment (UE) is allocated a resource (a part of spectrum) having a higher multiplexing factor than a cell center UE, and a resource (entire frequency band or a part of spectrum) allocated to a cell center UE is only The limited power of low power transmitted by the enhanced Node B (eNB) to the cell edge UE is multiplexed. However, based on various considerations (especially downlink power control may confuse downlink channel quality indicator (CQI) measurements, thus affecting the effectiveness of downlink adaptation and scheduling), ultimately the data channel in LTE Downlink power control is not supported on top, which makes FFR ineffective or meaningless for ICIC.
近来,在 LTE和 LTE-A中广泛地对多跳中继技术进行了讨论,并将其引入了 3GPP
版本 9及更高版本(参见 3GPP TR 36.814, "Further Advancements for E-UTRA Physical Layer Aspects," vl.2.1, June 2009, 在此一并引入作为参考)。 在中继辅助系统中, 每 个 UE可以主动或被动地访问 eNB或中继节点 (RN)。 通过在小区边缘部署 RN, 小 区边缘 UE可以体验来自服务 RN的提高的接收信号功率。 这样, 使得在不降低小区 中心频率资源处的 eNB传输功率的情况下, FFR在 LTE中可用。 基于上述考虑完成 了本发明。 发明内容 Recently, multi-hop relay technology has been widely discussed in LTE and LTE-A, and it has been introduced into 3GPP. Version 9 and higher (see 3GPP TR 36.814, "Further Advancements for E-UTRA Physical Layer Aspects," vl.2.1, June 2009, incorporated herein by reference). In a relay assistance system, each UE may actively or passively access an eNB or a relay node (RN). By deploying the RN at the cell edge, the cell edge UE can experience increased received signal power from the serving RN. In this way, FFR is available in LTE without reducing the e NB transmission power at the cell center frequency resource. The present invention has been completed based on the above considerations. Summary of the invention
为了解决现有技术中存在的问题, 本发明提出了在中继辅助网络中进行小区间干 扰协调 ICIC的方法和设备。 In order to solve the problems in the prior art, the present invention proposes a method and apparatus for performing inter-cell interference coordination ICIC in a relay assisted network.
根据本发明的一方面, 提供了一种在中继辅助网络中进行小区间干扰协调 ICIC 的方法, 在所述中继辅助网络中, 用户设备 UE被划分为由基站直接服务的宏 UE和 经由中继节点间接由基站服务的中继 UE, 所述方法包括以下步骤: 计算平均中继 UE 比, 其中所述平均中继 UE比是小区中的单个中继节点所服务的中继 UE数目占所有 UE数目的平均百分比;根据所计算的平均中继 UE比,确定要分配给中继节点的系统 带宽, 并将剩余的系统带宽分配给基站; 以及基于调度算法来确定中继节点和基站对 于所分配的系统带宽的进一步调度。 According to an aspect of the present invention, there is provided a method of performing inter-cell interference coordination ICIC in a relay assistance network, in which a user equipment UE is divided into macro UEs directly served by a base station and via The relay node is indirectly relayed by the base station, and the method includes the following steps: calculating an average relay UE ratio, wherein the average relay UE ratio is a number of relay UEs served by a single relay node in the cell. Average percentage of the number of all UEs; determining the system bandwidth to be allocated to the relay node based on the calculated average relay UE ratio, and allocating the remaining system bandwidth to the base station; and determining the relay node and the base station based on the scheduling algorithm Further scheduling of the allocated system bandwidth.
优选地, 所述调度算法是依赖于缓冲器队列状态因素的增强比例公平调度算法。 其中, 分配给中继节点的系统带宽和分配给基站的系统带宽是相互正交的。 Preferably, the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on a buffer queue state factor. The system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal.
其中确定进一步调度的步骤包括: 基于第一增强比例公平调度算法来计算针对中 继节点的第一调度准则, 以确定将所分配的系统带宽进一步分配给中继 UE的调度优 先级 一增强比例公平调度算法,
The step of determining further scheduling includes: calculating, according to a first enhanced proportional fair scheduling algorithm, a first scheduling criterion for the relay node, to determine a scheduling priority that further allocates the allocated system bandwidth to the relaying UE. Scheduling Algorithm,
其中, t表示时间索引, ·、·'(ί)表示中继 UE m的瞬时可支持数据速率, 表示针 对某一时间常量 τ的中继 UE m的指数滤波平均服务速率,以及 i £,.(0表示中继 UE m 的期望缓冲速率。 Where t denotes a time index, ··· ' (ί ) denotes an instantaneous supportable data rate of the relay UE m, denotes an exponentially filtered average service rate of the relay UE m for a certain time constant τ, and i £ ,. (0 represents the expected buffer rate of the relay UE m.
其中确定进一步调度的步骤还包括: 基于第二增强比例公平调度算法来计算针对 基站的第二调度准则, 以确定将所分配的系统带宽进一步分配给宏 UE和中继回程链 路 二增强比例公平调度算法,
其中, t表示时间索引, , (t)表示宏 UE n的瞬时可支持数据速率, ,.(t)表示针对 某一时间常量 τ的宏 UE n的指数滤波平均服务速率, R )表示中继 UE m所对应的 回程链路的平均速率, 以及 ρ(0表示考虑了中继缓冲器队列状态的改进型回程链路 速率 - 该方法还包括, 根据当前的 UE关联方案和业务量负载信息, 确定 UE是中继 UE 还是宏 UE。 ― The step of determining further scheduling further includes: calculating a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm to determine to further allocate the allocated system bandwidth to the macro UE and the relay backhaul link. Scheduling Algorithm, Where t represents the time index, (t) represents the instantaneous supportable data rate of the macro UE n, (t) represents the exponentially filtered average service rate of the macro UE n for a certain time constant τ, and R) represents the relay The average rate of the backhaul link corresponding to UE m, and ρ (0 represents the improved backhaul link rate considering the state of the relay buffer queue) - the method further includes, according to the current UE association scheme and traffic load information, Determine if the UE is a relay UE or a macro UE.
根据本发明的另一方面, 提供了一种中继辅助网络中进行小区间干扰协调 ICIC 的设备, 在所述中继辅助网络中, 用户设备 UE被划分为由基站直接服务的宏 UE和 经由中继节点间接由基站服务的中继 UE, 所述设备包括: 计算装置, 用于计算平均 中继 UE比, 其中所述平均中继 UE比是小区中的单个中继节点所服务的中继 UE数 目占所有 UE数目的平均百分比; 分配装置, 用于根据所计算的平均中继 UE比, 确 定要分配给中继节点的系统带宽, 并将剩余的系统带宽分配给基站; 以及调度装置, 用于基于调度算法来确定中继节点和基站对于所分配的系统带宽的进一步调度。 According to another aspect of the present invention, there is provided an apparatus for performing inter-cell interference coordination ICIC in a relay assistance network, in which a user equipment UE is divided into macro UEs directly served by a base station and via The relay node is indirectly relayed by the base station, and the device includes: a computing device, configured to calculate an average relay UE ratio, where the average relay UE ratio is a relay served by a single relay node in the cell The number of UEs is an average percentage of the number of all UEs; the allocating means is configured to determine a system bandwidth to be allocated to the relay node according to the calculated average relay UE ratio, and allocate the remaining system bandwidth to the base station; and a scheduling device, A method for determining further scheduling of the allocated system bandwidth by the relay node and the base station based on the scheduling algorithm.
优选地, 所述调度算法是依赖于缓冲器队列状态因素的增强比例公平调度算法。 其中, 分配给中继节点的系统带宽和分配给基站的系统带宽是相互正交的。 所述调度装置包括: 第一调度装置, 用于基于第一增强比例公平调度算法来计算 针对中继节点的第一调度准则, 以确定将所分配的系统带宽进一步分配给中继 UE的 调度优先级。 通过下式实现第一增强比例公平调度算法, Preferably, the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on a buffer queue state factor. The system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal. The scheduling apparatus includes: a first scheduling apparatus, configured to calculate, according to a first enhanced proportional fair scheduling algorithm, a first scheduling criterion for a relay node, to determine a scheduling priority for further allocating the allocated system bandwidth to the relay UE level. The first enhanced proportional fair scheduling algorithm is implemented by the following formula,
其中, t表示时间索引, ^'W表示中继 UE m的瞬时可支持数据速率, 表示针 对某一时间常量 的中继 UE m的指数滤波平均服务速率,以及 ,.(0表示中继 UE m 的期望缓冲速率。 Where t represents the time index, ^'W represents the instantaneous supportable data rate of the relay UE m, represents the exponentially filtered average service rate of the relay UE m for a certain time constant, and, (0 represents the relay UE m Expected buffer rate.
所述调度装置还包括: 第二调度装置, 用于基于第二增强比例公平调度算法来计 算针对基站的第二调度准则, 以确定将所分配的系统带宽进一步分配给宏 UE和中继 回 实现第二增强比例公平调度算法,
The scheduling apparatus further includes: a second scheduling apparatus, configured to calculate a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm, to determine to further allocate the allocated system bandwidth to the macro UE and to implement the relay back Second enhanced proportional fair scheduling algorithm,
其中, t表示时间索引, 表示宏 UE n的瞬时可支持数据速率, JO表示针对 某一时间常量 τ的宏 UE n的指数滤波平均服务速率, )表示中继 UE m所对应的 路的平均速率, 以及 ^(0表示考虑了中继缓冲器队列状态的改进型回程链路 该设备还包括, 确定装置, 用于根据当前的 UE关联方案和业务量负载信息, 确
定 UE是中继 UE还是宏 UE。 Where t represents a time index, indicating that the instantaneous UE can support the data rate, JO represents the exponentially filtered average service rate of the macro UE n for a certain time constant τ, and represents the average rate of the path corresponding to the relay UE m And ^(0 represents an improved backhaul link considering the state of the relay buffer queue. The device further includes determining means for determining the current UE association scheme and traffic load information, Whether the UE is a relay UE or a macro UE.
本发明针对中继辅助蜂窝网络中的 LTE下行链路传输,提出了一种利用相应的增 强型 PFS算法的新的基于 FFR的 ICIC方案。在该 FFR模型中 , 将整个系统带宽分为 两个正交部分, 一个用于由 eNB直接服务的宏 UE, 另一个用于由小区边缘 RN服务 的中继 UE。用于中继 UE的资源可以由所有 RN复用,因为 RN具有有限的传输功率; 类似地, 用于宏 UE的资源也可以由所有 eNB复用, 因为这些资源是用于小区中心 UE的。 该频谱划分并不需要在 eNB处的功率控制功能, 而是非常容易实现的。 通过 根据当前的 UE关联和业务量负载确定中继 UE的数目, 继而根据所计算的平均中继 UE比确定中继 UE资源的量, 以进行半静态调整。 同时, 为了完全利用该 FFR模型, 提出了在调度优先级准则中考虑中继缓冲器状态的增强型 PFS, 以提供一种资源使用 的均衡方式。 本发明可以显著地提高部署了中继节点的蜂窝系统的系统性能。 附图说明 The present invention is directed to a LTE downlink transmission in a relay-assisted cellular network, and proposes a new FFR-based ICIC scheme that utilizes a corresponding enhanced PFS algorithm. In the FFR model, the entire system bandwidth is divided into two orthogonal parts, one for macro UEs served directly by the eNB and the other for relay UEs served by the cell edge RN. The resources used to relay the UE may be multiplexed by all RNs because the RN has limited transmission power; similarly, resources for macro UEs may also be multiplexed by all eNBs because these resources are for cell center UEs. This spectral division does not require power control at the eNB, but is very easy to implement. The semi-static adjustment is performed by determining the number of relay UEs according to the current UE association and traffic load, and then determining the amount of relay UE resources according to the calculated average relay UE ratio. At the same time, in order to fully utilize the FFR model, an enhanced PFS that considers the state of the relay buffer in the scheduling priority criterion is proposed to provide an equalization method for resource usage. The present invention can significantly improve the system performance of a cellular system in which a relay node is deployed. DRAWINGS
结合附图,本发明的上述和其它方面、特征和优点将从以下对于本发明的非限制 性实施例的详细描述中变得更加清楚, 其中: The above and other aspects, features, and advantages of the present invention will become more apparent from the detailed description of the appended claims.
图 1示出了根据本发明示意性实施例的典型的 FFR配置; FIG. 1 illustrates a typical FFR configuration in accordance with an exemplary embodiment of the present invention;
图 2示出了根据本发明示意性实施例的中继辅助传输示意图; 2 shows a schematic diagram of relay assisted transmission in accordance with an exemplary embodiment of the present invention;
图 3示出了根据本发明示意性实施例的小区间干扰协调设备的结构框图; 图 4示出了根据本发明示意性实施例的小区间干扰协调方法的流程图; 图 5 示出了根据本发明示意性实施例的多小区六边形的布局以及相应的频谱划 分; 3 is a block diagram showing the structure of an inter-cell interference coordination apparatus according to an exemplary embodiment of the present invention; FIG. 4 is a flowchart showing an inter-cell interference coordination method according to an exemplary embodiment of the present invention; The layout of the multi-cell hexagon of the exemplary embodiment of the present invention and the corresponding spectrum division;
图 6示出了根据本发明示意性实施例的 LTE FDD下行链路帧结构; FIG. 6 illustrates an LTE FDD downlink frame structure in accordance with an exemplary embodiment of the present invention; FIG.
图 7示出了根据本发明示意性实施例的半静态资源分配; 以及 FIG. 7 illustrates a semi-static resource allocation in accordance with an exemplary embodiment of the present invention;
图 8示出了根据本发明示意性实施例的基于 FRR的 ICIC方案的吞吐量增益。 具体实施方式 . Figure 8 illustrates the throughput gain of an FRR based ICIC scheme in accordance with an illustrative embodiment of the present invention. detailed description .
以下将结合附图, 对本发明的示意性实施例进行描述。在该示意性实施例中, 以 LTE系统为例。 但是本领域技术人员应当理解, 本发明的范围并不限于此, 该示意性 实施例仅用于描述目的, 应将其看作本发明的示例而非对本发明的任何限制, 任何利 用了本发明实施例的方案均落入本发明的保护范围内。
本发明提出了一种新的针对中继辅助蜂窝网络中的小区间干扰协调 ICIC 的分数 频率复用 FFR方案。 本发明的基本思想是, 通过基于中继 UE关联比的半静态正交资 源分配、和经由增强比例公平调度(PFS )算法的动态资源调度, 来避免从 eNB至 RN 的小区内和小区间干扰, 其包括以下主要的几点: Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings. In this illustrative embodiment, an LTE system is taken as an example. However, those skilled in the art should understand that the scope of the present invention is not limited thereto, and the exemplary embodiments are only for the purpose of description, and should be considered as an example of the invention, and no limitation of the invention, The solutions of the embodiments are all within the scope of the invention. The present invention proposes a new fractional frequency reuse FFR scheme for inter-cell interference coordination ICIC in a relay-assisted cellular network. The basic idea of the present invention is to avoid intra-cell and inter-cell interference from an eNB to an RN through semi-static orthogonal resource allocation based on a relay UE association ratio and dynamic resource scheduling via an enhanced proportional fair scheduling (PFS) algorithm. , which includes the following main points:
( 1 ) 在小区边缘部署中继节点; (1) deploying a relay node at the edge of the cell;
(2) 将每个小区中的所有 UE分为两类: 直接由 eNB访问和服务的 UE被称为 宏 UE; 以及经由 RN间接由 eNB服务的 UE被称为中继 UE; (2) classifying all UEs in each cell into two categories: UEs directly accessed and served by the eNB are referred to as macro UEs; and UEs indirectly served by the eNB via RNs are referred to as relay UEs;
(3 )将整个系统频谱分为两个正交子频带,例如 Fe和 Fr,其中 Fe被分配给 eNB, 并由 eNB最终利用 PFS分配给宏 UE和中继回程(backhaul)链路; 以及 Fr被相应地 分配给 RN, 并由 RN最终利用 PFS分配给中继 UE。这样的划分保证了在 eNB与 RN 之间没有干扰; (3) dividing the entire system spectrum into two orthogonal sub-bands, such as Fe and Fr, where Fe is allocated to the eNB, and the eNB finally allocates the macro UE and the relay backhaul link using the PFS; and Fr It is allocated to the RN accordingly, and is finally allocated by the RN to the relay UE using the PFS. Such division ensures that there is no interference between the eNB and the RN;
(4)网络中的所有小区遵循相同的频谱划分, 即, Fe可以由所有施主 eNB复用, 以及 Fr可以由所有 RN复用。 由于 Fe用于小区中心 UE, 因而期望来自相邻 eNB的 干扰功率远小于来自施主 eNB的信号功率。 同时, 也可以假设小区间 RN千扰处于可 以接受的范围内, 因为 R 具有非常有限的覆盖范围 (RN的传输功率比 eNB的传输 功率低得多); (4) All cells in the network follow the same spectrum partitioning, i.e., Fe can be multiplexed by all donor eNBs, and Fr can be multiplexed by all RNs. Since Fe is used for cell center UEs, it is expected that the interference power from neighboring eNBs is much smaller than the signal power from the donor eNB. At the same time, it can also be assumed that the inter-cell RN interference is within an acceptable range because R has a very limited coverage (the transmission power of the RN is much lower than the transmission power of the eNB);
(5 ) Fr的宽度与平均中继 UE比成正比, 并且以半静态方式进行调整以与当前 的网络状态相匹配; (5) The width of Fr is proportional to the average relay UE ratio, and is adjusted in a semi-static manner to match the current network state;
(6)平均中继 UE比是单个 RN所服务的中继 UE数目占单个小区平均 UE总数 目的平均百分比, 具体地, 是全网总的中继 UE数目除以全网总 UE数目后再除以全 网总的 RN数目。因为每个小区可能分布不同的 UE总数, 也可能包含不同数量的 RN 数目, 而每个 RN也可能服务不同数目的中继 UE。 为了计算该平均中继 UE比, 一方 面, 将中继 UE数目经由 Un接口从每个下级 RN报告给施主 eNB; 另一方面, 通过 X2接口, 在不同的 eNB中互相交换中继 UE数目。 本领域技术人员应当理解, Un接 口是 Rn与 eNB之间的接口; 以及 X2接口是 eNB与 eNB之间的接口; (6) The average relay UE ratio is the average percentage of the number of relayed UEs served by a single RN to the average number of UEs in a single cell. Specifically, the total number of relayed UEs in the whole network is divided by the total number of UEs in the whole network. The total number of RNs in the whole network. Since each cell may have a different total number of UEs, it may also contain a different number of RNs, and each RN may also serve a different number of relay UEs. In order to calculate the average relay UE ratio, the number of relay UEs is reported from each lower RN to the donor eNB via the Un interface; on the other hand, the number of relay UEs is exchanged between different eNBs through the X2 interface. It should be understood by those skilled in the art that the Un interface is an interface between the Rn and the eNB; and the X2 interface is an interface between the eNB and the eNB;
(7) 为了充分利用该 FFR方案, 资源分配是基于增强 PF调度 (PFS ) 算法的。 通过将缓冲器队列状态的因素引入调度准则来获得该增强, 从而实现更加适合的资源 分配。 (7) In order to make full use of the FFR scheme, resource allocation is based on the Enhanced PF Scheduling (PFS) algorithm. This enhancement is achieved by introducing the factors of the buffer queue state into the scheduling criteria, thereby achieving a more suitable resource allocation.
参见图 3, 图 3示出了根据本发明示意性实施例的小区间干扰协调设备 300的结 构框图。 如图 3所示, 小区间干扰协调设备 300包括: 计算装置 301、 用于计算平均
中继 UE比,其中所述平均中继 UE比是小区中的单个 RN所服务的中继 UE数目占所 有 UE数目的平均百分比; 分配装置 303, 用于根据所计算的平均中继 UE比, 确定要 分配给 RN的系统带宽, 并将剩余的系统带宽分配给 eNB; 调度装置 305, 用于基于 增强比例公平调度算法来确定 RN和 eNB对于所分配的系统带宽的进一步调度。 Referring to FIG. 3, FIG. 3 is a block diagram showing the structure of an inter-cell interference coordination apparatus 300 according to an exemplary embodiment of the present invention. As shown in FIG. 3, the inter-cell interference coordination device 300 includes: a computing device 301, configured to calculate an average a relaying UE ratio, wherein the average relaying UE ratio is an average percentage of the number of relaying UEs served by a single RN in the cell, and an allocation device 303, configured to calculate, according to the calculated average relaying UE ratio, Determining the system bandwidth to be allocated to the RN and allocating the remaining system bandwidth to the eNB; scheduling means 305 for determining further scheduling of the allocated system bandwidth by the RN and the eNB based on the enhanced proportional fair scheduling algorithm.
该调度装置 305包括: 第一调度装置 (未示出), 用于基于第一增强 PFS算法来 计算 RN处的第一调度结果, 以确定将所分配的系统带宽进一步分配给中继 UE的调 度优先级; 以及第二调度装置 (未示出), 用于基于第二增强 PFS算法来计算 eNB处 的第二调度结果, 以确定将所分配的系统带宽进一步分配给宏 UE和中继回程链路的 调度优先级, 其中, 所述第一和第二增强 PFS算法依赖于缓冲器队列状态因素。 The scheduling apparatus 305 includes: a first scheduling apparatus (not shown) for calculating a first scheduling result at the RN based on the first enhanced PFS algorithm to determine a schedule for further allocating the allocated system bandwidth to the relaying UE a second scheduling device (not shown) for calculating a second scheduling result at the eNB based on the second enhanced PFS algorithm to determine to further allocate the allocated system bandwidth to the macro UE and the relay backhaul chain The scheduling priority of the path, wherein the first and second enhanced PFS algorithms are dependent on a buffer queue state factor.
此外, 小区间干扰协调设备 300还可以包括设置在计算装置 301之前的确定装置 Moreover, the inter-cell interference coordination device 300 can also include a determining device disposed prior to the computing device 301.
(未示出), 用于根据当前的 UE关联方案和业务量负载信息, 确定 UE是中继 UE还 是宏 UE, 以便确定中继 UE的数目。 (not shown), configured to determine, according to the current UE association scheme and traffic load information, whether the UE is a relay UE or a macro UE, so as to determine the number of relay UEs.
以下参照图 4-7, 对根据本发明示意性实施例的小区间干扰协调方法进行描述, 在该示意性实施例中, 以 LTE FDD下行链路传输为例。 可以理解, 本发明不限于此, 而是可以应用于其它无线领域。 An inter-cell interference coordination method according to an exemplary embodiment of the present invention will be described below with reference to FIG. 4-7. In the exemplary embodiment, an LTE FDD downlink transmission is taken as an example. It will be appreciated that the invention is not limited thereto but may be applied to other wireless fields.
图 5示意性地示出了多小区六边形的布局以及相应的频谱划分。 如图 5所示, 在 每个小区边缘可以部署, 例如, 两个 RN。 以 LTE FDD系统为例, 典型地, LTE FDD 系统中的每个下行链路帧长 10ms, 包括 20个长度为 0.5ms的时隙, 标记为 0-19, 如 图 6所示。 将子帧定义为两个连续的时隙, 其中子帧 i包括时隙 2i和 2i+l。 Fig. 5 schematically shows the layout of a multi-cell hexagon and the corresponding spectral division. As shown in Figure 5, it can be deployed at the edge of each cell, for example, two RNs. Taking the LTE FDD system as an example, each downlink frame in the LTE FDD system is typically 10 ms long, including 20 time slots of 0.5 ms in length, labeled 0-19, as shown in FIG. 6. A subframe is defined as two consecutive time slots, where subframe i includes time slots 2i and 2i+1.
在 10MHz系统带宽的情况下,在每个子帧中存在总数为 50的物理资源块 (PRB )。 假设平均 25个 UE均匀地分布在每个小区中,并根据当前适合的 UE关联方案(例如, 考虑最大接收信号功率、 或最短距离等) 以及实际的业务量负载, 由 eNB或 RN之一 服务。 如前所述, 直接由 eNB服务的 UE称为宏 UE, 通过 RN间接由 eNB服务的 UE称为中继 UE。 In the case of a 10 MHz system bandwidth, there are a total of 50 physical resource blocks (PRBs) in each subframe. It is assumed that an average of 25 UEs are evenly distributed in each cell, and are served by one of the eNBs or RNs according to the currently suitable UE association scheme (for example, considering maximum received signal power, or shortest distance, etc.) and actual traffic load. . As mentioned before, a UE that is directly served by an eNB is called a macro UE, and a UE that is indirectly served by an eNB through an RN is called a relay UE.
在步骤 401 中, 确定装置根据当前的 UE关联方案和业务量负载信息, 确定 UE 是中继 UE还是宏 UE, 以便确定中继 UE的数目。 In step 401, the determining apparatus determines whether the UE is a relay UE or a macro UE according to the current UE association scheme and traffic load information, so as to determine the number of relay UEs.
然后, 每个 RN通过 Un接口向 eNB报告中继 UE数目, 并通过 X2接口在不同 的 eNB中互相交换该 UE关联信息 (即中继 UE数目)。 Then, each RN reports the number of relay UEs to the eNB through the Un interface, and exchanges the UE association information (that is, the number of relay UEs) in different eNBs through the X2 interface.
在步骤 S403中, 通过计算装置 301计算平均中继 UE比。 In step S403, the average relay UE ratio is calculated by the computing device 301.
在步骤 S405中, 分配装置 303根据所计算的平均中继 UE比, 确定要分配给 RN
的系统带宽, 并将剩余的系统带宽分配给 eNB。 In step S405, the allocating means 303 determines to allocate to the RN based on the calculated average relay UE ratio. System bandwidth, and allocate the remaining system bandwidth to the eNB.
例如, 假设在特定持续时间内, 平均地, 每个 RN间接地服务 3个 UE, gp, 中 继 UE, (由此可知平均中继 UE比为 3/25=12%), 以及施主 eNB直接服务 19个 UE。 因此, 可以根据平均中继 UE比 12%, 将整个系统带宽划分为以下两个部分: Fr, 1-6 个 PRB; 以及 Fe, 7-50个 PRB, BP,将前 12%的资源分配给 RN以便服务于中继 UE, 以及将剩余资源分配给 eNB以便服务于宏 UE和中继回程链路, 如图 7所示。 For example, assume that, for a specific duration, on average, each RN indirectly serves 3 UEs, gp, relay UEs (thus knowing that the average relay UE ratio is 3/25=12%), and the donor eNB directly Serves 19 UEs. Therefore, the entire system bandwidth can be divided into the following two parts according to the average relay UE ratio of 12%: Fr, 1-6 PRBs; and Fe, 7-50 PRBs, BP, which allocates the first 12% of resources to The RN serves to relay the UE, and allocates the remaining resources to the eNB to serve the macro UE and the relay backhaul link, as shown in FIG.
由于资源调度算法极大地影响着 FFR的性能, 为此, 本发明提出了增强 PFS, 通 过在调度准则中引入涉及缓冲器队列状态的因素来获得该增强, 从而实现更加适合的 资源分配。 Since the resource scheduling algorithm greatly affects the performance of the FFR, the present invention proposes an enhanced PFS, which is obtained by introducing factors related to the buffer queue state in the scheduling criteria, thereby achieving a more suitable resource allocation.
在步骤 S407中, 调度装置 305基于增强 PFS算法来确定 RN和 eNB对于分配装 置 303所分配的 Fr和 Fe的进一步调度。 In step S407, the scheduling device 305 determines further scheduling of the Fr and Fe allocated by the RN and the eNB for the allocation device 303 based on the enhanced PFS algorithm.
具体地讲, 在步骤 S407中, 由第一调度装置基于第一增强 PFS算法来计算 RN 处的第一调度结果,以确定将所分配的系统带宽进一步分配给中继 UE的调度优先级。 第二调度装置基于第二增强 PFS算法来计算 eNB处的第二调度结果, 以确定将所分 配的系统带宽进一步分配给宏 UE和中继回程链路的调度优先级。 其中, Specifically, in step S407, the first scheduling result at the RN is calculated by the first scheduling device based on the first enhanced PFS algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the relay UE. The second scheduling device calculates a second scheduling result at the eNB based on the second enhanced PFS algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the macro UE and the relay backhaul link. among them,
1 ) 实现第一增强 PFS算法如下面的表达式 (1 ) 一 (3 ) 给出: 1) Implement the first enhancement PFS algorithm as shown in the following expression (1) one (3) gives:
针对 Fr频带的每个 PRB的 RN PFS, 调度优先级准则为 For the RN PFS of each PRB in the Fr band, the scheduling priority criterion is
Mr{t) - arg max ϊ ) 其中, t是时间索引, 7C(0是中继 UE m的瞬时可支持数据速率, 以及 是根据 下式进行更新的针对某一时间常量 r的中继 UE m的指数滤波平均服务速率 M r {t) - arg max ϊ ) where t is the time index, 7C (0 is the instantaneous supportable data rate of the relay UE m, and is a relay UE for a certain time constant r updated according to the following formula Exponential filtering average service rate of m
f (1 - T)R'wi. (t) + T - min , (t), RB"„'FFER {t)} , 若^(,) = ,"f (1 - T)R' wi . (t) + T - min , (t), R B "„' FFER {t)} , if ^(,) = , "
(l- r)C( , 若 M )≠'" (l- r)C( , if M )≠'"
。 以及 ^ (0是中继 UE m的期望缓冲速率, 被定义为: . And ^ (0 is the expected buffer rate of the relay UE m, defined as:
R!„ _ UE OT的缓冲器队列总长度 (以比特为单位) ( 3 ) buffer ) TTI 其中, TTI等于 lms, 即, 一个子帧的传输时间间隔。 通过新到达的数据队列长度和 服务 RN处的重传数据队列长度二者来确定缓冲器队列的总长度。 与现有技术中的 PFS算法 M(0 = arg mmax^^相比, 本发明所提出的调度优先级 准则考虑了 UE的缓冲器状态, 从而避免了以空的缓冲器来调度 UE。 R! „ _ UE OT buffer queue total length (in bits) ( 3 ) buffer ) TTI where TTI is equal to lms, ie, the transmission time interval of one subframe. Through the newly arrived data queue length and service RN The retransmission data queue length at both ends to determine the total length of the buffer queue. Compared with the prior art PFS algorithm M (0 = ar gm max ^^, the proposed scheduling priority criterion considers the UE The buffer state, thereby avoiding scheduling the UE with an empty buffer.
2) 实现第二增强 PFS算法如下面的表达式 (4) 和 (5 ) 给出 -
假设 eNB处的业务量加载模型是无限负载模型(infmitely-backlogged model ) , 也 称为满负荷模型, 针对 Fe频带的每个 RPB处的 eNB PFS , 在每个时间步骤中, 调度 优先级准则为
2) Implement the second enhanced PFS algorithm as given by the following expressions (4) and (5) - Assuming that the traffic loading model at the eNB is an infmitely-backlogged model, also referred to as a full load model, for each eNB PFS at the RPB of the Fe band, in each time step, the scheduling priority criterion is
其中, t表示时间索引, 表示宏 UE n的瞬时可支持数据速率, ,.(0表示针对 某一时间常量 τ的宏 UE n的指数滤波平均服务速率, 4r(t)表示中继 UE m所对应的 回程链路的平均速率, 以及/ ^(0表示考虑了中继缓冲器队列状态的改迸型回程链路 速率。 其中宏 UE n的 PF优先级的计算 Hf、lRa n v fy、、 以及中继 UE m所对应的回 程链路的平均速率 ( 4(0 ) 的计算与现有技术中相同。 然而, 对于与中继 UE m对 应的中继回程链路 /„,, R^(o表示考虑了中继缓冲器队列状态的改进型回程链路速率: Where t denotes a time index indicating that the instantaneous UE can support the data rate, (0 represents the exponentially filtered average service rate of the macro UE n for a certain time constant τ, 4 r (t) denotes the relay UE m The average rate of the corresponding backhaul link, and / ^ (0 represents the modified backhaul link rate considering the relay buffer queue state. The calculation of the PF priority of the macro UE n is Hf, lR a n v fy And the average rate of the backhaul link corresponding to the relay UE m (4(0) is the same as in the prior art. However, for the relay backhaul link corresponding to the relay UE m/,, R ^ (o denotes an improved backhaul link rate that takes into account the queue status of the relay buffer:
0, 如果链路 /m的缓冲器队列长度大于特定阈值 si 0, if the link queue length of link / m is greater than a certain threshold si
R p (t) = +∞, 如果链路 /„的缓冲器为空,且总的 RN缓冲器队列长度小于特定阈值 S2 ( 5 ) R p (t) = +∞, if the buffer of the link / is empty, and the total RN buffer queue length is less than a certain threshold S2 ( 5 )
R; ),其它情况 R;), other situations
其中, ,(0是回程链路 /,„的瞬时可支持信道速率。 Among them, (0 is the backhaul link /, „ instantaneous support channel rate.
通过采用 R (0而非^ ,(0, 中继回程链路不会耗费过多的 Fe频带资源, 同时可 以向中继 UE提供均衡的数据流。 于是, 可以在宏 UE和中继回程链路中更恰当地使 用 Fe频带。 By using R (0 instead of ^, (0, the relay backhaul link does not consume too much Fe-band resources, and can simultaneously provide a balanced data stream to the relay UE. Thus, it can be in the macro UE and the relay backhaul chain The Fe band is more appropriately used in the road.
因而, 将半静态资源分配和增强 PFS相结合, 可以在中继辅助蜂窝网络中有效地 实现基于 FFR的 ICIC , 而不用限制 eNB处的功率控制。 Thus, combining semi-static resource allocation with enhanced PFS can effectively implement FFR-based ICIC in a relay-assisted cellular network without limiting power control at the eNB.
本发明针对中继辅助蜂窝网络中的 LTE下行链路传输,提出了一种利用相应的增 强 PFS算法的新的基于 FFR的 ICIC方案。在该 FFR模型中, 将整个系统带宽分为两 个正交部分, 一个用于由 eNB直接服务的宏 UE, 另一个用于由小区边缘 RN服务的 中继 UE。 用于中继 UE的资源可以由所有 RN复用, 因为 RN具有有限的传输功率。 类似地, 用于宏 UE 的资源也可以由所有 eNB复用, 因为这些资源是用于小区中心 UE的。 该频谱划分并不需要在 eNB处的功率控制功能, 而是非常容易实现的。 通过 根据当前的 UE关联和业务量负载确定中继 UE的数目, 继而根据所计算的平均中继 UE比确定中继 UE资源的量, 以进行半静态调整。 同时, 为了完全利用该 FFR模型, 提出了在调度优先级准则中考虑中继缓冲器状态的增强型 PFS , 以提供一种资源使用 的均衡方式。 The present invention is directed to a LTE downlink transmission in a relay-assisted cellular network, and proposes a new FFR-based ICIC scheme that utilizes a corresponding enhanced PFS algorithm. In the FFR model, the entire system bandwidth is divided into two orthogonal parts, one for macro UEs served directly by the eNB and the other for relay UEs served by the cell edge RN. The resources used to relay the UE may be multiplexed by all RNs because the RN has limited transmission power. Similarly, resources for macro UEs can also be multiplexed by all eNBs because these resources are for cell center UEs. This spectral division does not require power control at the eNB, but is very easy to implement. The semi-static adjustment is performed by determining the number of relay UEs according to the current UE association and traffic load, and then determining the amount of relay UE resources according to the calculated average relay UE ratio. At the same time, in order to fully utilize the FFR model, an enhanced PFS that considers the state of the relay buffer in the scheduling priority criterion is proposed to provide an equalization method for resource usage.
此外, 所提出的方法可以用于类型 I和类型 II 中继节点, 非常有利于在 3GPP LTE-A标准中的应用。 In addition, the proposed method can be used for Type I and Type II relay nodes, which is very advantageous for applications in the 3GPP LTE-A standard.
根据本发明的基于 FFR的 ICIC方案可以在小区平均和小区边缘频谱效率方面提
供更好的系统性能。 The FFR-based ICIC scheme according to the present invention can provide in terms of cell average and cell edge spectral efficiency For better system performance.
图 8示出了所提出的方法的显著性能增益 (归一 I化用户吞吐量) 示意图。 下面的 表 1记录了针对图 8中每种情况的相应小区平均和小区边缘 (5%)用户吞吐量增益 (表 1中已对吞吐量迸行了归一化)。 经过计算可以得知, 通过采用 RN复用, 在小区平均 和小区边缘吞吐量上分别有 9.4%和 4.0%的增加; 通过在每个小区内釆用正交 RN传 输, 在小区平均和小区边缘吞吐量上分别有 3.0%和 16.0%的增加。 Figure 8 shows a schematic diagram of the significant performance gain (normalized user throughput) of the proposed method. Table 1 below records the corresponding cell average and cell edge (5%) user throughput gains for each of the cases in Figure 8 (the throughput has been normalized in Table 1). After calculation, it can be known that by using RN multiplexing, there are 9.4% and 4.0% increase in cell average and cell edge throughput respectively; by using orthogonal RN transmission in each cell, in cell average and cell edge There was an increase of 3.0% and 16.0% in throughput, respectively.
表 1 Table 1
下面的表 2给出了在无线蜂窝系统中利用本发明的方法和设备进行仿真时所釆用 的参数。 Table 2 below gives the parameters used in the simulation of the wireless cellular system using the method and apparatus of the present invention.
表 2 Table 2
表 2. 系统级仿真参数
通过上面给出的数据可知, 本发明可以显著地改进部署了中继节点的蜂窝系统的 系统性能。 根据本发明的方案具有以下特性-Table 2. System level simulation parameters As can be seen from the data given above, the present invention can significantly improve the system performance of a cellular system in which a relay node is deployed. The solution according to the invention has the following characteristics -
- eNB和它的下级 R 使用正交频率资源; - the eNB and its subordinate R use orthogonal frequency resources;
- 以半静态方式执行小区内的资源分配; - performing resource allocation within the cell in a semi-static manner;
- 通过 Un接口, 将 UE关联信息从 RN报告给施主 eNB; - reporting UE association information from the RN to the donor eNB through the Un interface;
- 不同的 eNB彼此交互, 以通过 X2接口交换它们相应的 UE关联结果等。 本发明主要涉及基于 FFR的 ICIC解决方案, 满足 3GPP LTE中继定义, 因而可 以直接基于现有的技术来实现。 - Different eNBs interact with each other to exchange their respective UE association results and the like through the X2 interface. The present invention mainly relates to an FFR-based ICIC solution that satisfies the 3GPP LTE relay definition and thus can be implemented directly based on existing technologies.
本领域技术人员应该很容易认识到,可以通过编程,利用计算机来实现上述方法 的不同步骤。 在此, 一些实施方式同样包括机器可读或计算机可读的程序存储设备 (如, 数字数据存储介质) 以及编码机器可执行或计算机可执行的程序指令, 其中, 该指令执行上述方法的一些或全部步骤。 例如, 程序存储设备可以是数字存储器、 磁 存储介质 (如磁盘和磁带)、 硬件或光可读数字数据存储介质。 实施方式同样包括执 行存储介质上记录的程序以执行上述方法的所述步骤的计算机。 - 上面结和附图所做的描述只是为了说明本发明而示例性给出的。本领域技术人员 可以理解, 能够基于上面所描述的本发明的原理提出不同的结构, 虽然这些不同的结 构未在此处明确描述或示出, 但体现了本发明的原理并包括在其精神和范围之内。 此 夕卜, 所有此处提到的示例明确地主要只用于教学目的以帮助读者理解本发明的原理以 及发明人所贡献的促进本领域的构思, 并应被解释为不是对这些特定提到的示例和条 件的限制。 此外, 此处所有提到本发明的原则、 方面和实施方式的陈述及其特定的示 例包含其等同物在内。
Those skilled in the art will readily recognize that the various steps of the above methods can be implemented by programming using a computer. Herein, some embodiments also include a machine readable or computer readable program storage device (eg, a digital data storage medium) and encoding machine executable or computer executable program instructions, wherein the instructions perform some of the above methods or All steps. For example, the program storage device can be a digital memory, a magnetic storage medium (such as a magnetic disk and magnetic tape), a hardware or an optically readable digital data storage medium. Embodiments also include a computer that executes a program recorded on a storage medium to perform the steps of the above method. The descriptions of the above and the drawings are merely illustrative for the purpose of illustrating the invention. It will be appreciated by those skilled in the art that the present invention may be practiced in various embodiments, and the various structures are not described or illustrated herein. Within the scope. Furthermore, all of the examples mentioned herein are explicitly used primarily for teaching purposes to assist the reader in understanding the principles of the invention and the concepts promoted by the inventors, and should be construed as not The limitations of the examples and conditions. In addition, all statements herein reciting principles, aspects, and embodiments of the invention, as well as the specific examples thereof,
Claims
权 利 要 求 Rights request
1.一种在中继辅助网络中进行小区间干扰协调 ICIC的方法, 在所述中继辅助网 络中, 用户设备 UE被划分为由基站直接服务的宏 UE和经由中继节点间接由基站服 务的中继 UE, 所述方法包括以下步骤: A method for performing inter-cell interference coordination ICIC in a relay assistance network, in which a user equipment UE is divided into a macro UE directly served by a base station and indirectly served by a base station via a relay node Relay UE, the method includes the following steps:
计算平均中继 UE比, 其中所述平均中继 UE比是小区中的单个中继节点所服务 的中继 UE数目占所有 UE数目的平均百分比; Calculating an average relay UE ratio, wherein the average relay UE ratio is an average percentage of the number of relay UEs served by a single relay node in the cell, and the average percentage of all UEs;
根据所计算的平均中继 UE比, 确定要分配给中继节点的系统带宽, 并将剩余的 系统带宽分配给基站; 以及 Determining a system bandwidth to be allocated to the relay node based on the calculated average relay UE ratio, and allocating the remaining system bandwidth to the base station;
基于调度算法来确定中继节点和基站对于所分配的系统带宽的进一步调度。 Further scheduling of the allocated system bandwidth by the relay node and the base station is determined based on a scheduling algorithm.
2. 根据权利要求 1所述的方法, 其中, 所述调度算法是依赖于缓冲器队列状态因 素的增强比例公平调度算法。 2. The method of claim 1, wherein the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on buffer queue state factors.
3. 根据权利要求 1所述的方法, 其中, 分配给中继节点的系统带宽和分配给基站 的系统带宽是相互正交的。 3. The method of claim 1, wherein the system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal.
4. 根据权利要求 2所述的方法, 其中确定进一步调度的步骤包括: 4. The method of claim 2, wherein the step of determining further scheduling comprises:
基于第一增强比例公平调度算法来计算针对中继节点的第一调度准则, 以确定将 所分配的系统带宽进一步分配给中继 UE的调度优先级。 A first scheduling criterion for the relay node is calculated based on the first enhanced proportional fair scheduling algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the relaying UE.
其中通过下式实现第一增强比例公平调度算法,
The first enhanced proportional fair scheduling algorithm is implemented by the following formula.
其中, t表示时间索引, ((ί)表示中继 UE m的瞬时可支持数据速率, 0表示针 对某一时间常量 f 的中继 UE m的指数滤波平均服务速率,以及7¾^,.(0表示中继 UE m 的期望缓冲速率。 Where t denotes a time index, ( (ί) denotes the instantaneous supportable data rate of the relay UE m, 0 denotes the exponentially filtered average service rate of the relay UE m for a certain time constant f, and 73⁄4^,. Indicates the expected buffer rate of the relay UE m.
6. 根据权利要求 2所述的方法, 其中确定进一步调度的步骤还包括: 基于第二 增强比例公平调度算法来计算针对基站的第二调度准则, 以确定将所分配的系统带宽 进一步分配给宏 UE和中继回程链路的调度优先级。 6. The method of claim 2, wherein the determining the further scheduling further comprises: calculating a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm to determine to further allocate the allocated system bandwidth to the macro The scheduling priority of the UE and the relay backhaul link.
, 其中通过下式实现第二增强比例公平调度算法,
, wherein the second enhanced proportional fair scheduling algorithm is implemented by the following formula,
其中, t表示时间索引, ?^ (t)表示宏 UE n的瞬时可支持数据速率, , (t)表示针对 某一时间常量 r的宏 UE n的指数滤波平均服务速率, r(0表示中继 UE m所对应的 回程链路的平均速率, 以及/ ¾p(0表示考虑了中继缓冲器队列状态的改进型回程链路
Where t denotes the time index, ?^(t) denotes the instantaneous supportable data rate of the macro UE n, and (t) denotes the exponentially filtered average service rate of the macro UE n for a certain time constant r, r (0 means The average rate of the backhaul link corresponding to UE m, and / 3⁄4 p (0 represents an improved backhaul link considering the state of the relay buffer queue)
8. 根据权利要求 1所述的方法, 还包括, 根据当前的 UE关联方案和业务量负载 信息, 确定 UE是中继 UE还是宏 UE。 8. The method according to claim 1, further comprising determining whether the UE is a relay UE or a macro UE according to a current UE association scheme and traffic load information.
9. 一种中继辅助网络中进行小区间干扰协调 ICIC的设备, 在所述中继辅助网络 中, 用户设备 UE被划分为由基站直接服务的宏 UE和经由中继节点间接由基站服务 的中继 UE, 所述设备包括: 9. A device for inter-cell interference coordination ICIC in a relay assisted network, in which the user equipment UE is divided into macro UEs directly served by the base station and indirectly served by the base station via the relay node Relaying the UE, the device includes:
计算装置, 用于计算平均中继 UE比, 其中所述平均中继 UE比是小区中的单个 中继节点所服务的中继 UE数目占所有 UE数目的平均百分比; a computing device, configured to calculate an average relay UE ratio, where the average relay UE ratio is an average percentage of the number of relay UEs served by a single relay node in the cell, and the average percentage of all UEs;
分配装置, 用于根据所计算的平均中继 UE比, 确定要分配给中继节点的系统带 宽, 并将剩余的系统带宽分配给基站; 以及 And a means for determining, according to the calculated average relay UE ratio, determining a system bandwidth to be allocated to the relay node, and allocating the remaining system bandwidth to the base station;
调度装置, 用于基于调度算法来确定中继节点和基站对于所分配的系统带宽的进 一步调度。 And a scheduling apparatus, configured to determine, according to a scheduling algorithm, further scheduling of the allocated system bandwidth by the relay node and the base station.
10. 根据权利要求 9所述的设备, 其中, 所述调度算法是依赖于缓冲器队列状态 因素的增强比例公平调度算法。 10. The apparatus of claim 9, wherein the scheduling algorithm is an enhanced proportional fair scheduling algorithm that relies on a buffer queue state factor.
11. 根据权利要求 9所述的设备, 其中, 分配给中继节点的系统带宽和分配给基 站的系统带宽是相互正交的。 11. The apparatus of claim 9, wherein the system bandwidth allocated to the relay node and the system bandwidth allocated to the base station are mutually orthogonal.
12. 根据权利要求 10所述的设备, 其中所述调度装置包括: 12. The device of claim 10, wherein the scheduling device comprises:
第一调度装置, 用于基于第一增强比例公平调度算法来计算针对中继节点的第一 调度准则, 以确定将所分配的系统带宽进一步分配给中继 UE的调度优先级。 And a first scheduling apparatus, configured to calculate a first scheduling criterion for the relay node based on the first enhanced proportional fair scheduling algorithm to determine a scheduling priority for further allocating the allocated system bandwidth to the relay UE.
13. 根据权利要求 12 所述的设备, 其中通过下式实现第一增强比例公平调度算 法,
13. The apparatus according to claim 12, wherein the first enhanced proportional fair scheduling algorithm is implemented by:
其中, t表示时间索引, 表示中继 UE m的瞬时可支持数据速率, 表示针 对某一时间常量 的中继 UE m的指数滤波平均服务速率,以及 /¾ ,(0表示中继 UE m 的期望缓冲速率。 Where t denotes a time index, denotes an instantaneous supportable data rate of the relay UE m, denotes an exponentially filtered average service rate of the relay UE m for a certain time constant, and /3⁄4, (0 denotes the expectation of the relay UE m Buffer rate.
14. 根据权利要求 10所述的设备, 其中所述调度装置还包括: 第二调度装置, 用 于基于第二增强比例公平调度算法来计算针对基站的第二调度准则, 以确定将所分配 的系统带宽进一步分配给宏 UE和中继回程链路的调度优先级。 14. The apparatus according to claim 10, wherein the scheduling apparatus further comprises: second scheduling means, configured to calculate a second scheduling criterion for the base station based on the second enhanced proportional fair scheduling algorithm to determine the allocated The system bandwidth is further allocated to the scheduling priorities of the macro UE and the relay backhaul link.
15. 根据权利要求 14所述的设备, 其中通过下式实现第二增强比例公平调度算 法,
其中, t表示时间索引, i )表示宏 UEn的瞬时可支持数据速率, 2 .(0表示针对 某一时间常量 的宏 UE n的指数滤波平均服务速率, R (t)表示中继 UE m所对应的 回程链路的平均速率, 以及 表示考虑了中继缓冲器队列状态的改进型回程链路 速率。 15. The apparatus according to claim 14, wherein the second enhanced proportional fair scheduling algorithm is implemented by: Where t represents the time index, i) represents the instantaneous supportable data rate of the macro UEn, 2 (0 represents the exponentially filtered average service rate of the macro UE n for a certain time constant, and R (t) represents the relay UE m The average rate of the corresponding backhaul link, and the improved backhaul link rate that takes into account the state of the relay buffer queue.
16. 根据权利要求 9所述的设备, 还包括, 确定装置, 用于根据当前的 UE关联 方案和业务量负载信息, 确定 UE是中继 UE还是宏 UE。
The device according to claim 9, further comprising: determining means, determining, according to the current UE association scheme and traffic load information, whether the UE is a relay UE or a macro UE.
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US9986487B1 (en) | 2016-05-13 | 2018-05-29 | Sprint Communications Company L.P. | Relay control system notification of inter-cell interference coordination (ICIC) to a donor base station |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101009622A (en) * | 2006-01-05 | 2007-08-01 | 阿尔卡特朗讯公司 | Method of semidynamic centralized interference coordination for cellular systems |
CN101335971A (en) * | 2007-06-28 | 2008-12-31 | 联想(北京)有限公司 | Resource scheduling method of multi-hop wireless network based on relay station |
WO2009129413A2 (en) * | 2008-04-16 | 2009-10-22 | Qualcomm Incorporated | Methods and apparatus for uplink and downlink inter-cell interference coordination |
CN101610518A (en) * | 2008-03-14 | 2009-12-23 | 英特尔公司 | Resource management and interference mitigation technology based on the wireless network of relaying |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN101009622A (en) * | 2006-01-05 | 2007-08-01 | 阿尔卡特朗讯公司 | Method of semidynamic centralized interference coordination for cellular systems |
CN101335971A (en) * | 2007-06-28 | 2008-12-31 | 联想(北京)有限公司 | Resource scheduling method of multi-hop wireless network based on relay station |
CN101610518A (en) * | 2008-03-14 | 2009-12-23 | 英特尔公司 | Resource management and interference mitigation technology based on the wireless network of relaying |
WO2009129413A2 (en) * | 2008-04-16 | 2009-10-22 | Qualcomm Incorporated | Methods and apparatus for uplink and downlink inter-cell interference coordination |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP2880888A4 (en) * | 2012-07-31 | 2016-07-27 | Dali Systems Co Ltd | Optimization of traffic load in a distributed antenna system |
US10506454B2 (en) | 2012-07-31 | 2019-12-10 | Dali Systems Co., Ltd. | Optimization of traffic load in a distributed antenna system |
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