METHOD AND APPARATUS TO SELECT BEAM GROUP AND BEAM SUBSET IN COMMUNICATION SYSTEM AND COMPUTER-READA

专利摘要:
apparatus, computer program product and method. an apparatus and method for selecting a beam group and a subset of beams in a communication system are disclosed. the method includes: measuring channel state information (csi) on a downlink from a base station (920), identifying a beam group selected from a set of beam groups according to a broadband property of the csi (930), identify a subset of beams selected in the beam group selected according to at least one subband (940). wherein the characteristic of the set of beam groups depends on a transmission rating and the number of beams in the selected beam subset is equal to the transmission rating. the method further includes: generating coded feedback information to identify the selected beam group and selected subset of beams, for each subband in a dual codebook format (950), transmitting the coded feedback information to the station base. a computer program product which includes the computer program code which is configured to cause the apparatus to implement the above operations is also disclosed.
公开号:BR112012030434B1
申请号:R112012030434-8
申请日:2010-06-02
公开日:2021-06-22
发明作者:Tommi Koivisto；Timo Roman；Mihai Enescu；Shuang Tan；Helka-Liina MAATTANEN
申请人:Beijing Xiaomi Mobile Software Co., Ltd.；
IPC主号:

专利说明:

DESCRIPTION RELATED ORDERS
[0001] The present invention claims the priority of PCT patent application PCT/CN2010/073411 (attorney registration EIE100124PCT) filed at SIPO on June 1, 2010, entitled "Apparatus and method for selecting beam groups and beam subsets in a communication system," the entirety of which is incorporated herein by reference. TECHNICAL FIELD
[0002] The present invention is directed, generally, to communication systems and, in particular, to an apparatus, method and system for selecting a group of beams and a subset of beams in a communication system. BACKGROUND
[0003] The Long Term Evolution ("LTE") of the Third Generation Partnership Project ("3GPP"), also known as 3 GPP LTE, refers to research and development involving 3 GPP LTE Release 8 and beyond, which is the name commonly used to describe an ongoing industry-wide effort aimed at identifying technologies and capabilities that can improve systems, such as the universal mobile telecommunications system ("UMTS"). The notation "LTE-A" is commonly used in the industry to refer to further advances in LTE. The goals of this broadly based project include improving communication efficiency, reducing costs, improving services, making use of new spectrum opportunities, and achieving better integration with other open standards.
[0004] The evolved universal terrestrial radio access network ("E-UTRAN") in 3 GPP includes base stations that provide user plane (including packet data convergence protocol / radio link control / access control to the middle / physical sublayers ("PDCP RLC MAC / PHY")) and control plane (including the radio resource control sublayer ("RRC")) protocol terminations for wireless communication devices such as cell phones. A wireless communication device or terminal is generally known as user equipment (also referred to as "UE"). The base station is an entity of a communication network, often referred to as a node B or an NB. Particularly in E-UTRAN, an "evolved" base station is referred to as an eNodeB or an eNB. For details on the general architecture of E-UTRAN, see Technical Specification 3 GPP ("TS") 36,300 v8.7.0 (2008-12), which is incorporated herein by reference. For more details on radio resource control management, see 3 GPP TS 25.331 v.9.1.0 (2009-12) and 3 GPP TS 36.331 v.9.1.0 (2009-12), which are incorporated herein by reference.
[0005] As wireless communication systems such as cell phone, satellite and microwave communication systems become widespread and continue to attract an increasing number of users, there is an urgent need to accommodate large numbers. and variable communication devices that transmit an increasing amount of data within a fixed spectral allocation and limited transmission power. The increase in the amount of data is a consequence of wireless communication devices that transmit video information and surf the Internet, as well as carry out normal voice communication. To meet these ongoing needs, a current topic of general interest in 3GPP is the efficient use of spatially multiplexed cellular transmission. Efficient use of spatially multiplexed transmission can allow a higher data rate to be transmitted per hertz ("Hz") bandwidth at a limited transmission power level, which allows for a greater amount of data to be transmitted by one. wireless communication device in a short period of time, or, equivalently, the accommodation of substantially simultaneous operation of a greater number of wireless communication devices.
[0006] In order to meet peak spectral efficiency requirements (up to 30 bits / Hz), support of up to eight transmit antennas ("Tx") on a downlink ("DL") will be standardized on 3 GPP LTE Rel -10, allowing spatially multiplexed downlink transmission with up to eight spatial layers. Both eight stream downlink multiple inputs and multiple outputs ("MMO") and enhanced multiple user multiple inputs and multiple outputs ("MU-MIMO") are now agreed to be part of a Rel-10 work item in improved downlink MIMO transmission. Such processes will allow the highest data rate to be transmitted with a transmitter power level limited by hertz of bandwidth.
[0007] The processes, however, to allow a wireless communication device to communicate channel status and other related information back to the base station so that spatially multiplexed transmission on a downlink can be efficiently performed by the base station that presents a number of challenges. One of the most problematic issues is how to deal with the dimensionality of the larger communication channel and degrees of freedom associated with downlink antenna beamforming (also known as transmit precoding) without reporting communication channel information overload from the uplink communication channel to the wireless communication device. Another issue is to allow improved single-user multi-in/multi-out performance ("SU-MIMO") with large azimuthal propagation in the wireless communication channel in the transmit antenna array. It is generally recognized that coverage for wireless communication devices located at the crossover beams in the antenna beam space may be poor with current arrangements.
[0008] Taking into account the increasing distribution of communication systems such as cellular communication systems and these unresolved problems, it would be beneficial to employ an improved codebook format to allow a wireless communication device to efficiently determine and communicate the channel state and antenna beam characteristics of a base station that avoid the shortcomings of today's communication systems. SUMMARY OF THE INVENTION
[0009] These and other problems are generally solved or circumvented and technical advantages are generally achieved, by embodiments of the present invention, which include an apparatus, method and system for selecting a beam group and a subset of beams in a communication system. In one embodiment, an apparatus includes a processor and memory, including computer program code. The memory and computer program code are configured to, with the processor, cause the apparatus to measure downlink channel status information from a base station, and identify a selected beam group from a set of beam groups according to a broadband property of the channel state information. The characteristic of the set of beam groups depends on a transmission classification. The memory and the computer program code are configured to, with the processor, make the apparatus identify a selected subset of beams in the selected beam group according to at least one subband. The number of beams in the selected beam subset is equal to the transmission rating.
[00010] The following description has outlined quite broadly the technical characteristics and advantages of the present invention, so that the detailed description of the invention below can be better understood. Other features and advantages of the present invention will be described below, which are the subject of the claims of the invention. It should be appreciated by those skilled in the art that the specific design and embodiment disclosed can be readily used as a basis for modifying or designing other structures or processes to accomplish the same goals as the present invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as defined in the appended embodiments. BRIEF DESCRIPTION OF THE DRAWINGS
[00011] For a more complete understanding of the invention, and the advantages thereof, reference is now made to the following description taken in conjunction with the accompanying drawings, in which:
[00012] Figures 1 and 2 illustrate system level diagrams of embodiments of communication systems, including a base station and wireless communication devices that provide an environment for applying the principles of the present invention; Figures 3 and 4 illustrate system level diagrams of embodiments of wireless communication systems including communication systems that provide an environment for applying the principles of the present invention; Figure 5 illustrates a system level diagram of an embodiment of a communication element of a communication system for applying the principles of the present invention; Figures 7A 6A, 6B, and 7B illustrate graphical representations of embodiments of beam group formation in accordance with the principles of the present invention; Figure 8 illustrates a graphical representation of an embodiment of beam groups in accordance with the principles of the present invention; and Figure 9 illustrates a flow diagram of an embodiment of a method of operating a communication system in accordance with the principles of the present invention. DETAILED DESCRIPTION OF ILLUSTRATIVE ACHIEVEMENTS
[00013] The production and use of the presently preferred embodiments are discussed in detail below. It should be appreciated, however, that the present invention provides many applicable inventive concepts that can be incorporated in a wide variety of contexts. The specific embodiments discussed are merely illustrative of specific ways of making and using the invention, and do not limit the scope of the invention. In view of the foregoing, the present invention will be described with respect to exemplary embodiments, in a specific context of an apparatus and method for determining system and communication channel status and antenna beam characteristics of a wireless communication device. wire, such as user equipment to a base station in a communication system. The apparatus, method and system are applicable, without limitation, to any communication system that includes existing and future 3GPP technologies (ie, UMTS, LTE, and its variants such as 4th generation ("4G") communication systems ).
[00014] Turning now to Figure 1, illustrated is a system level diagram of an embodiment of a communication system that includes a base station 115 and wireless communication devices (e.g., user equipment), 135, 140 , 145, which provides an environment for applying the principles of the invention. Base station 115 is coupled to a public switched telephone network (not shown). Base station 115 is configured with a plurality of antennas to transmit and receive signals from a plurality of sectors, including a first sector 120, a second sector 125, and a third sector 130, each of which typically spans 120 degrees. Although Figure 1 illustrates a wireless communication device (for example, wireless communication device 140) in each of the sectors (for example, the first sector 120), one sector (for example, the first sector 120) can generally contain a plurality of wireless communication devices. In an alternative embodiment, a base station 115 may be formed with a single sector (e.g., the first sector 120), and multiple base stations may be constructed so as to transmit in accordance with cooperative multiple input/multiple output operation ( "C-MINO"), etc.
[00015] The sectors (for example, the first sector 120) are formed by concentrating and phasing out electromagnetic signals from the base station antennas and separate antennas can be employed, by sector (for example, the first sector 120). The plurality of sectors 120, 125, 130 increases the number of subscriber stations (e.g. wireless communication devices 135, 140, 145) that can simultaneously communicate with base station 115, without the need for increase the bandwidth used by reducing interference that results from focusing and phasing the base station antennas. While wireless communication devices 135, 140, 145 are part of a primary communication system, wireless communication devices 135, 140, 145 and other devices such as machines (not shown) can be a part of a system. secondary communication to participate, without limitation, in device-to-device and machine-to-machine communication or other communications.
[00016] Turning now to Figure 2, illustrated is a system level diagram of an embodiment of a communication system that includes a base station 210 and wireless communication devices (e.g., user equipment), 260, 270 , which provides an environment for applying the principles of the present invention. The communication system includes base station 210 coupled via communication or link 220 (e.g., via a fiber optic communication path) with a main telecommunications network, such as the public switched telephone network ("PSTN") 230. Base station 210 is coupled via wireless communication paths or links 240, 250 to wireless communication devices 260, 270, respectively, which are within its cellular area 290.
[00017] In the operation of the communication system illustrated in Figure 2, the base station 210 communicates with each of the wireless communication devices 260, 270 through a control and data communication resources assigned by the base station 210 to the along the communication paths 240, 250, respectively. Data communication and control features may include frequency and time band communication features in frequency division duplex ("FDD") and/or time division duplex ("TDD") communication modes. While wireless communication devices 260, 270 are part of a primary communication system, wireless communication devices 260, 270 and other devices such as machines (not shown) can be a part of a secondary communication system. to participate, without limitation, device-to-device and machine-to-machine communication or other communications.
[00018] Turning now to Figure 3, illustrated is a system level diagram of an embodiment of a communication system that includes a wireless communication system that provides an environment for applying the principles of the present invention. The wireless communication system can be configured to provide universal mobile telecommunications services ("E-UTRAN") of an evolved UMTS terrestrial radio access network. An entity architecture evolution portal / mobile management system ("MME / SAE GW," one of which is designated 310) provides the control functionality of an E-UTRAN B node (designated "eNB", a "B node" "evolved", also known as a "base station", one of which is designated 320) via a communication link S1 (one of which is designated as "link S1"). The base stations 320 communicate via X2 communication links (those of which are designated "X2 link"). The different communication links are typically fiber, microwave, or other high frequency communication paths, such as coaxial metallic links, or combinations thereof.
[00019] Base stations 320 communicate with wireless communication devices such as user equipment ("UE", which are designated 330), which is typically a cellular transceiver carried by a user. Thus, the communication links (called "Uu communication links", one of which are designated "Uu link") coupling base stations 320 to user equipment 330 are air links employing a wireless communication signal, such as by example, an orthogonal frequency division multiplexing ("OFDM") signal. Although user equipment 330 is part of a primary communication system, user equipment 330 and other devices such as machines (not shown) may be a part of a secondary communication system participating, without limitation, in the device-to-device and machine-to-machine communications or other communications.
[00020] Turning now to Figure 4, illustrated is a system level diagram of an embodiment of a communication system that includes a wireless communication system that provides an environment for applying the principles of the present invention. The wireless communication system provides an E-UTRAN architecture including base stations (one of which is designated 410) providing E-UTRAN (packet data convergence protocol / radio link control / access control) user plane to media / physical) and control plane protocol terminals (control of radio resources) for wireless communication devices such as 420 user equipment and other devices such as 425 machines (eg a set, television , meter, etc.) The 410 base stations are interconnected with X2 interfaces or communication links (designated "X2"). The base stations 410 are also connected by SI interfaces or communication links (designated "SI") to an evolved packet core ("EPC"), including a cellular management entity/system architecture evolution portal ("ME / SAE GW," one of which is designated 430), the SI interface supports a multi-entity relationship between the cellular management entity/system architecture evolution portal 430 and the base stations 410. For applications that support land mobile handoff inter-public, inter-eNB active mode mobility is supported by the 430 system architecture/cellular management entity evolution portal through the S1 interface.
[00021] The 410 base stations can host functions such as radio resource management. For example, base stations 410 may perform functions such as Internet Protocol ("IP") header compression and encryption of user data streams, encoding of user data streams, radio bearer control, data admission control. radio, connection mobility control, dynamic allocation of communication resources to user equipment, both uplink and downlink, selection of a mobility management entity in securing user equipment, user plan data routing to the user plan entity, and scheduling and transmitting paging messages (originating from the mobility management entity), scheduling and transmitting broadcast information (originating from the mobility management entity or operations and maintenance), and reporting configuration for mobility and programming. The system architecture evolution portal/mobile management entity 430 can host functions such as paging message distribution to base stations 410, security control, termination of U-plane packets for paging reasons, U switching -plan to support user equipment mobility, idle state mobility control, and a system architecture evolution carrier control. User equipment 420 and machines 425 receive an assignment of a group of information blocks from base stations 410.
[00022] In addition, one of the base stations 410 is coupled to a base station 440 (a device), which is coupled to devices such as user equipment 450 and/or machines (not shown) to a secondary communication system . Base station 410 may allocate resources from the secondary communication system directly to user equipment 420 and machines 425, or to source base station 440 for communication (e.g., local communications) within the secondary communication system. For a better understanding of source base stations (called "HeNB"), see 3 GPP TS 32.871 v.9.1.0 (2010-03), which is incorporated herein by reference. Although user equipment 420 and machines 425 are part of a primary communication system, user equipment 420, machines 425 and the source base station 440 (communicating with other user equipment 450 and machines (not shown) ) may be a part of a secondary communication system to participate, without limitation, in device-to-device and machine-to-machine communication or other communications.
[00023] Turning now to Figure 5, a system level diagram of an embodiment of a communication element 510 of a communication system for applying the principles of the present invention is illustrated. The communication element or device 510 may represent, without limitation, a base station, a wireless communication device (e.g., a subscriber station, terminal, mobile station, user equipment, machine), a network control element , a communication node, or the like.
[00024] The communication element 510 includes at least a processor 520, memory 550 that stores programs and data of a temporary or more permanent nature, an antenna 560 and a radio frequency transceiver 570 coupled to the antenna 560 and the processor 520 for bidirectional wireless communication. Communication element 510 may provide point-to-point and/or point-to-multipoint communication services.
[00025] The communication element 510, as a base station of a cellular network, can be coupled to a communication network element, such as a control element of the network 580 of a public switched telecommunications network ("PSTN") . The control element of the network 580 can, in turn, be formed with a processor, memory and other electronic elements (not shown). The 580 network control element generally provides access to a telecommunications network, such as a PSTN. Access can be provided via fiber optic, coax, twisted pair, microwave communication, or similar link coupled to a suitable link termination element. A communication element 510 formed as a wireless communication device is generally a self-contained device that is intended to be carried by an end user.
[00026] Processor 520 in communication element 10, which can be implemented with one or a plurality of processing devices, performs functions associated with its operation, including, without limitation, precoding antenna gain / phase parameters (precoder 521), encoding and decoding (encoder/decoder 523) of individual bits forming a communication message, information formatting and general control (controller 525) of the communication element, including processes related to the management of communication resources (manager of resource 528). Exemplary functions related to managing communication resources include, without limitation, hardware installation, traffic management, performance data analysis, end user and equipment tracking, configuration management, end user administration, communication device management wireless, rate management, subscriptions, security, billing and the like. For example, according to memory 550, resource manager 528 is configured to allocate primary and second communication resources (eg time and frequency communication resources) for the transmission of voice and data communications to/from the communication element 510 and for formatting messages including the respective communication resources in a primary and secondary communication system.
[00027] The execution of all or parts of specific functions or processes related to the management of communication resources can be performed in separate equipment and/or coupled to the communication element 510, with the results of such functions or processes communicated for execution to communication element 510. Processor 520 of communication element 10 may be of any type suitable for the local application environment, and may include one or more of the general purpose computers, special purpose computers, microprocessors, computer processors. digital signal ("DSP"), field-programmable array of gates ("FPGAs"), application-specific integrated circuits ("ASICs"), and processors based on a multi-core processor architecture, as non-limiting examples.
[00028] The transceiver 570 of the communication element 510 modulates the information on the carrier waveform for transmission through the communication element 10 through the antenna 560 to another communication element. Transceiver 570 demodulates information received through antenna 560 for further processing by other communication elements. Transceiver 570 is capable of supporting duplex operation for communication element 510.
[00029] The memory 550 of the communication element 510, as shown above, may be one or more memories and any type suitable for the local application environment, and may be implemented using any suitable non-volatile or volatile data storage technology , such as a semiconductor-based memory device, a magnetic memory device and system, an optical memory device and system, fixed memory, and removable memory. Programs stored in memory 550 may include program instructions or computer program code that, when executed by an associated processor, allow communication element 510 to perform tasks as described herein. Of course, memory 550 can form a temporary data storage for the data transmitted to and from the communication element 510, exemplary embodiments of the system, subsystems and modules as described herein can be implemented, at least in part, by the software of computer executable by processors, for example, of the wireless communication device and the base station, or by hardware, or a combination thereof. As will become more apparent, systems, subsystems and modules can be incorporated into communication element 510, as illustrated and described here.
[00030] Discussion at 3GPP recently focused on code table design for eight base station broadcast antennas and related precoding, which is missing in the new LTE Rel-10 standard. At RANI meeting n°59, it was agreed to expand the implied feedback framework for LTE Rel-10. This is based on a modular (or multi-granular) design, combining two components from separate feedback code tables representing different characteristics of channel state information. One feedback component targets broadband communication channel properties (also referred to as broadband properties) and/or long-term communication channel properties (also referred to as long-term properties), while the others target properties of the frequency selective communication channel (also referred to as frequency selective properties) and/or short term communication channel properties (also called short term properties). An example of a long-lasting property is the directional structure of optimal transmission beams. For example, the location of a user's equipment cannot change quickly and, consequently, its azimuthal direction can be substantially stationary. Therefore, the directional structure of the transmission beams can be represented with a long-term property, which becomes broadband in nature, especially in the presence of strong spatial correlation in the transmission antenna matrix, which is quite susceptible to be observed under the assumption of closely spaced antenna elements (eg, spaced by half wavelength). An example of a short-term property is rapid amplitude and phase fluctuations of the air communication path. Such rapid fluctuations can be represented with a short-term property, which are typically frequency selective in nature (eg, varying from one frequency subband to another).
[00031] This channel feedback communication structure is also referred to herein as a dual code table structure. While the missing standard LTE Rel-10 specifications relate to 1-8 transmit layers of a base station with an eight transmit antenna configuration, the principles of a dual codebook structure can be generalized to an arbitrary number of antennas of transmission. As presented here, a new codebook design and structure for channel state information feedback based on dual codebook ("CSI") in support of downlink SU-/MU-MIMO operation is described for application, without limitations, in LTE Rel-10 and beyond.
[00032] 3 GPP LTE downlink MIMO operation is one of several work items under consideration in LTE Rel-10. Two new enhancements to LTE Rel-8/-9 downlink MIMO are being considered. One improvement is the optimization of the MU-MIMO operation, which benefits from a new reference symbol ("RS") design package that employs reference symbols specified by pre-coded user equipment (referred to in the 3GPP community as UE -RS, or "dedicated reference symbols "DM-RS"), and periodic channel status information reference symbols ("CSI-RS"). A second improvement is the extension of the downlink transmission operation to up to eight SU-MIMO downlink layers.
[00033] These enhancements support a better feedback mode of user equipment, following the implicit feedback principles of LTE Rel-8. Accurate channel state information feedback plays an important role for reliable, interference-free (or substantially free) communication, especially for MU-MIMO. Furthermore, signaling aspects and code table sizes are important when considering the extension for SU-/MU-MIMO operation of eight transmissions because of the increased dimensionality of the communication channel and its degrees of freedom.
[00034] The feedback design of LTE Rel-10 user equipment is based on implicit feedback principles (channel quality indicator / matrix precoding / classification indicator), similar to LTE Rel-8, but with the difference that a dual codebook format is used instead of a single codebook format. However, single codebook feedback can still be seen as a special case by defining one of the codebook entries for the identity matrix. Rel-10 project decisions date back to 3GPP Workgroup RANI No.59, where in the slideshow represented in 3GPP Rl-101683, entitled "Way Forward for Rel-10 Feedback Framework", which is incorporated herein by reference, it was described that a precoder for a subband is composed of two matrices belonging to distinct code tables. A code table targets broadband communication channel properties and/or long term properties, the matrix denoted here as "W1". The other code tables target frequency selective properties and/or short term properties and the respective matrix denoted here as "W2". The resulting precoder for each subband can be constructed, for example, as matrix multiplication of two matrices.
[00035] At a recent 3GPP RAN1 meeting, code table design proposals and various ways to utilize the long/short term properties were presented. Several fundamental design aspects are included among these proposals: A feedback concept is envisioned to operate with cross polarization ("XP") and uniform linear array ("ULA") of array types of base station antenna configurations and therefore , code tables have to be designed and optimized accordingly. Long-term and short-term properties can be sampled with the same or different time periodicities and, consequently, reported (in cases of equal or different time). While considering a relatively fixed total feedback rate budget (that is, a fixed total number of bits over a given time span), one can try to find the best balance in investing the feedback bits between the tables of codes that characterize the long-term and short-term properties. The final precoder is the output of an operation (eg matrix multiplication) between the long-term and short-term precoders.
[00036] The order of the wideband / long-term precoder matrix W1 and the arrangement of the short-term precoder matrix W2 in such a product can further differentiate the concepts. If the broadband/long-term properties are handled on the communication channel side (ie the matrix of the "H" channel is multiplied by the right as H*W1), it can be seen as directing the main antenna beams towards the user equipment signal space, while further refinement may increase either co-phasing (transmission rating-1) or orthogonality (transmission rating >1) between the beams/precoders at a subband level. This can be seen as a W1 * W2 matrix multiplication operation. On the other hand, it is possible to create a larger beam space for matrix W1, which is further refined by matrix W2 multiplied by the left. The final precoder matrix is the output of a W1 * W2 matrix multiplication. Arguably these two ways of forming the product of the two code tables are almost the same. The main difference is how the beams and refinements of matrices W1 and W2 are defined. A common denominator is the construction of the W1 matrix using discrete Fourier transform ("DFT") (supersampling) vectors or matrices.
[00037] The way to select the W1 and W2 matrices in the communication channel user equipment is also important from the point of view of complexity, and this can affect the performance of the system itself. For example, a feedback proposal may best work under the assumption of exhaustive research on all possible combinations of long-term/broadband and short-term precoders (W1 and W2 arrays), while losing ground in more precoder selection. practical and less complex. While up to eight spatial layers (or streams) are considered, the dual codebook concept is primarily considered attractive to lower transmission layers, ie transmission ratings 1-2, and perhaps also transmission ratings 3-4, while that higher levels of transmission can operate counting only on a single feedback component (eg matrix of size W2 Nt times R, where Nt and R is the number of transmit antennas at the base station and the transmission rating, respectively) , with the other component being conceptually defined as the identity matrix (eg the matrix W1 = I of the size of Nt by Nt).
[00038] As presented in the points mentioned above, the concept of the dual code table can be reduced to the definition of beams and vectors or selection/combination precoders that are part of the two code tables. Since the construction of the W1 matrix can employ supersampled discrete Fourier transform matrices/vectors, the drawings effectively develop some form of the well-known beam grid concept, in which the user equipment effectively chooses a beam (a column of a discrete Fourier transform matrix) that provides better transmission performance.
[00039] The Rel-10 feedback concept should support both SU-MIMO and MU-MIMO, where SU-MIMO is typical and offers more performance gains for less correlated scenarios with higher azimuthal (angular) communication channel propagation. while MU-MIMO is typical and provides the most performance gains for scenarios highly correlated with small azimuthal spread. In case of higher azimuthal propagation and SU-MIMO operation, just selecting one beam (or multiple beams in case of l> transmission rating) for the whole band as usual in a beam grid is generally not sufficient for performance good communication, because frequency selective precoding and beam selection at a subband level is known to perform best in this situation. On the other hand, for very low azimuthal propagation and MU-MIMO operation, a beam grid is known to have a good performance as is, because in this case, frequency and wideband selective precoding reaches very close for the same performance. , and broadband precoding is more attractive because of the much lower overhead of associated channel state feedback information. Introduced here, the traditional beamgrid concept is reinforced so that it still supports low azimuth propagation scenarios well, but improves the performance of SU-/MU-MIMO operation in scenarios with high azimuthal propagation.
[00040] Major code table structures were introduced during the 61 RANI meeting in Montreal, Canada, May 10 - 14, 2010. However, parts of the concepts are even older. A codebook structure is described in 3GPP TSG-RAN WG1 #61 document Rl-102630 entitled "Codebook Design and Feedback Refinements", Montreal, Canada, May 10 - 14, 2010, which is incorporated herein by reference.
[00041] In a first codebook structure proposal, the precoder matrix W1 is mainly treated in the wideband sense, compressing the communication channel in the spatial dimension such that the resulting equivalent communication channel matrix H * W1 is of smaller dimensionality than physical transmit communication channel matrix H (eg of size Nr by Nt where Nt and Nr are the number of transmit and receive antennas, respectively). In addition, the combination (co-suppression) of the remaining two dimensions (or beams) (by cross polarized antennas) or orthogonalization between the flows is handled through the W2 matrix, which is applied in a frequency selective way at a level of sub-band. Precoder matrix W1 is the diagonal block, where each block includes columns of supersampled discrete Fourier transform matrices. The careful design of both W1 and W2 arrays can allow them to support both uniform linear and cross polarized antenna array configurations with the same code tables. This is achieved through four bits for matrix W1 and two bits for matrix W2. The four bits for matrix W1 essentially translate into an oversampling factor of four for discrete Fourier transform matrices in the case of four transmit antennas (eg corresponding to four uniform linear matrix configurations of four streams or for each block of four co-polarized transmit antenna elements assuming cross polarized eight transmit antenna configuration). The codebook entries for matrix W2 consist of the antenna code table of two Rel-8 transmissions, as the concept also addresses transmission rating operation 1-2 on Rel-10. The purpose of the W2 precoder matrix is to handle the combination of cross polarization (co-suppression and orthogonalization) after the matrix structure has been applied to the communication channel, and also to provide support for linear uniform matrix operation, all matrix W2 based operations being done in a frequency selective mode at a subband level.
[00042] Additionally / alternatively, some user equipment feedback reporting modes (for example, along a physical uplink control channel ("PUCCH")), may be designed under the very feedback overload constraint. low associated. In the latter case, it would not make sense, for example, to analyze the selection of matrix W1 and W2 and report both in a broadband mode. The main difference from the usual beam grid is that the feedback is based on the codebook format or dual structure, where the format is used to provide a beam-like operating grid for the linear uniform matrix and type matrices. polarization with the same feedback. The problem with this scheme is exactly the one mentioned here above (ie, the system does not allow for better SU-MIMO performance when the azimuth propagation is greater).
[00043] In a second proposal, the precoder matrix W1 selects a set of column vectors from the supersampled discrete Fourier transform matrices. For the case of cross polarized antennas, four antenna beams are created by polarization, while eight beams are used for the uniform linear array. Making use of a bit for the matrix W1 signaling, the code table that divides the codeword space (beam) into two non-overlapping parts and selects one of them to be further used for refinement or proper adjustment of the beam to a level of subband through the W2 precoder matrix. Note that, in the selected one-bit space, the beams are preset for further processing, so the size of the W1 matrix is a 16 x 8 matrix in the case of eight transmit antennas, as there are eight beams defined by an array W1. The codebook structure is described in 3GPP TSG-RAN WG1 #61 document R1-102823 entitled "8 Tx Codebook Design", Montreal, Canada, May 10 - 14, 2010, which is incorporated herein by reference.
[00044] It is also to be noted that the main difference with the previous proposal was to compress the communication channel in the spatial dimension with the matrix W1. Allowing a larger space (that is, with the dimensionality of the complete communication channel) to be processed at a subband level with matrix W2 which can be seen as an advantage of one of the concepts, especially in situations of greater azimuthal propagation and highest transmission rating SU-MIMO transmission. Precoder matrix W2 is signaled with four bits, and the associated code table consists of combiners and beam selectors.
[00045] The freedom of choice of multiple beams per subband, due to the main partition operated by matrix W1 can be seen as an advantage, especially in the SU-MIMO case described above. However, this flexibility brings its own disadvantage in that the Matrix W1 cannot be used alone, as the beam space defined by a matrix is thus too large. Furthermore, due to the two spaces created with the W1 matrix, coverage is poor for user equipment located at the intersection of spaces.
[00046] In a third proposal, multiple beams are allowed per subband, through matrix W1. The second matrix of precoder W2 refines the matrix W1 by multiplying to the left (ie, W2 * W1), thereby performing an initial beam rotation. The first code table (eg the one associated with matrix W1) also contains combiners along the longitudinal beams and has a larger size of 32 beams in total, while the second code table (ie the one associated with the matrix W2) can only have 2-3 bits, consisting of several rotation matrices. In fact, there are only two cross-pole combiners available for cross-polarization operation, which can be seen as a disadvantage. A codebook restriction for the W1 matrix subset is also possible. The structure of the code table is described in 3GPP TSG-RAN WGL No. 61 Rl-103026, entitled "Insights into the Assessment Framework for Rel 10,". Montreal, Canada, May 10 - 14, 2010, which is incorporated herein by reference.
[00047] A summary of the main proposed concepts is illustrated in Table 1 below:

[00048] TABLE II below illustrates the feedback rates of the main concepts proposed, considering the same time report for matrices W1 and W2 (which affects the use of the physical uplink shared channel ("Pusch")) and 50 blocks of physical resources ("PRBs") with six -PRB granularity of matrix W2 and periodicity of 10 milliseconds ("ms") to report.

[00049] As introduced here, a code table structure is described that provides improved support for scenarios with low spatial correlation / high azimuthal propagation, where frequency selective feedback is required for good performance. The codebook format or structure also provides improved support for higher levels of transmission, especially for the case of linear uniform arrays.
[00050] The codebook structure is based on similar beam grouping as in the second proposal as described above above (i.e. the first part of the feedback signal performs the selection of the beam group and the second part of the signal performs beam selection from the selected beam group). The first part of the feedback applies to the entire band or broadband properties, while the second part of the feedback is sub-band specific. As a special case, the second part of the feedback can also be applied in a broadband way. In this particular case, it is to be understood that there is a single subband for channel state information feedback, wherein the width is equal to the bandwidth of the wideband system. To allow beam group selection and beam selection from selected beam group with double codebook format or structure, there is a precoder matrix W1 which contains, for example, sub-based discrete Fourier transform. -matrices, and W2 precoder matrices that contain column selection and phase shift vectors such that the actual beams in the beam group are determined by matrix multiplications of the form:

[00051] As shown here, groups of beams can overlap. Overlapping beam groups are intended to cover cases with superior azimuthal propagation, where the enhanced / long-duration broadband transmission direction is on the "edges" or in other words, on the boundary of two beam groups. Without overlapping beam groups in such cases, part of the azimuthal propagation cannot be captured with precoding because it falls into the adjacent beam group. Overlap usually means that the total angular domain (or angular domain) generated by beam groups is overlapping. Angular domain can mean the angular range from the maximum matrix gain direction of a first beam to the maximum gain matrix direction of a last beam in a beam group or equivalently, the maximum possible angular range, in terms of direction of maximum matrix gains between any two beams within the beam group. A special case of beam group overlap is such that the beam groups partly contain the same beams. In this case, different W1 matrices could be partially constructed from the same column vectors.
[00052] Second, the number of beam groups and/or the beam group size (number of beams in the group) and/or total beam group angular domain (angular range generated by the beam group) depends on the transmission rating. Typical eight-stream antenna arrays have antennas physically spaced very closely together. Since higher levels of transmission of communication channels employ azimuthal propagation of highly correlated communication channels it has to be large to allow for higher rank transmission. With the codebook format or the dual structure, such high azimuth propagation can be properly captured if the beam group size and total angular domain is large enough to cover a wide range of azimuth angles. Hence for higher transmission ratings, the beam group size and total angular domain must be larger. The two aspects thus introduced can be combined. Overlapping groups of beams are constructed, in which the size, number, and angular domain of overlapping groups of beams can vary according to transmission classification.
[00053] As presented here in an exemplary embodiment, the description is given in terms of beam group selected from a set of beam groups and beam subset selection from the selected beam group as well as beam groups potentially overlapping. This can be equivalently translated in terms of matrix / vector description and codebook format or structure. A set of specific beam groups for a transmission rating translates into a set of specific W1 matrices or associated with a transmission rating in the code table that target broadband and/or long term properties. A certain number of beam groups in a set of beam groups depending on the transmission classification means that the number of W1 matrices in the set of matrices associated with a given position depends on the classification itself. Beams within a given beam group translate to specific column vectors within matrices W1 associated with the beam group or equivalently specific columns of the resulting precoder matrix W = W1 * W2. Consequently, a number of beams within a beam group translates to the number of columns within the associated precoder. The overlapping of beam groups within a set of beam groups can be described as precoders (eg W1 matrices) associated with one beam group, with a subset of column vectors located in the other precoder (eg another matrix W1 or matrices) associated with another beam group within the set of beam groups. Selecting a subset of the beams from the selected beam group translates, for example, to column selection vectors / matrices (eg matrix W2), which select the column subsets of the matrix associated with the selected beam group (eg the matrix W1). Furthermore, co-phasing or orthogonalizing beams at the sub-band level can be handled with additional vector or precoder matrix components (eg W2 consisting of phase shift in addition to column selection elements).
[00054] Hence, user equipment feedback, where it is employed where a user equipment first measures the channel state information and then selects the beam group from a set of beam groups according to the wideband or long-term information of the channel state, where the size of each beam group (i.e. a certain number of beams in each beam group of a set of beam groups) and/ or the number of beam groups (ie, a number of beam groups in a set of beam groups) and/or the total angular domain generated by each beam group (ie, a total angular domain extended from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each beam group in a set of beam groups) depend on the transmission classification and/or on which the beam groups different ones are superimposed. In other words, a characteristic of a set of beam groups includes at least one of a series of beams from each beam group in the set of beam groups, a number of beam groups in the set of beam groups, and a total angular domain extended from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each beam group in a set of beam groups. For each subband, the user equipment selects a subset of the beams in the selected group of beams, where the size of the subset is equal to the transmission rating. Furthermore, the selected subset of bundles can consist of bundles orthogonal to each other. The user equipment encodes the feedback information into a dual codebook or precoder format employing matrices W1 and W2 for transmission over an uplink communication channel, and transmits the dual codebook format to the base station.
[00055] The base station receives the feedback transmitted on an uplink communication channel, decodes the feedback information, and converts it into a double code table or precoder format or structure (for example, in matrices W1 and W2 ). The base station calculates the final precoder (ie antenna weights) to be used for transmission to user equipment, per frequency subband based on W1 and W2 matrices, eg matrix multiplication , like:

[00056] In the data transmission to the user equipment, the base station does the weighting of the antenna in the programmed sub-bands according to the weights of the matrix W.
[00057] To calculate feedback to the base station, the user equipment first measures the channel state information. In the case of a communication system based on LTE, this measurement can be done through reference signals, for example, the CSI-RS, in the case of eight transmission antennas, ie CSI-RS, in the case of four transmission antennas. transmission (or less). The user equipment then obtains the channel state information for the entire system bandwidth.
[00058] Once the user equipment has obtained channel status information, the feedback can be computed (ie, the user equipment determines the beam group, and selects a beam for each subband), with the format From the double codebook or structure, the user equipment selects a wideband / long-term precoder matrix and a precoder matrix W2 for each subband, conditioned on the chosen precoder matrix W1. In one aspect, the beam group is selected with matrix W1, while the precoder matrices W1 and W2 together form the final beams (precoders) within each beam group. The final precoders are then built employing matrix multiplication:

[00059] Turning now to Figures 6A and 6B, illustrated are graphical representations of embodiments of beam group formation in accordance with the principles of the present invention. It should be understood that the azimuthal gain characteristic of a particular transmission beam is not flat and is precisely in the limited angular domain as shown in the figures. In Figure 6A, illustrated there are four beam groups for the case of transmission rows 1-2, each beam group including, for example, four beams. As illustrated in Figure 6B for transmission rows 34, there are two groups of beams, but with greater angular domain of the beam group (azimuth), each group including, for example, eight beams. The sizes of the beam groups and/or the number of beam groups and/or global angular domain generated by the beam groups depend on the transmission classification. Exemplary codebook entries for matrix W1, W2 precoders that support this format or structure are shown below.
[00060] Turning now to Figures 7A and 7B, illustrated are graphical representations of embodiments of beam group formation in accordance with the principles of the present invention. In the illustrated embodiment, the groups of beams overlap. Note that the number of beam groups, sizes and angular domain occupied by each of the beam groups are dependent on the transmission classification. Exemplary codebook entries for a format or structure are shown below.
[00061] Both the base station and the user equipment know of the code table constructed using these principles. The user equipment can select codebook entries using, for example, the following exemplary matrix selection method. First, the user equipment calculates the spatial covariance matrix of the broadband communication channel R:
where E is the hope operator and the superscript operator "H" represents the Hermitian operator (ie conjugation and transposition of the respective matrix). Again, the H (not superscript) represents the communication channel matrix. The user equipment then uses, for example, and without limitation, one of the following ways to choose the matrix W1.
[00062] In an exemplary method, the user equipment makes all matrix combinations,
scanning (searching) all possible options for matrices W1 and W2. The search can be done across the bandwidth to the W2 matrix (ie, across the total system bandwidth) to limit computational complexity. The user equipment then finds the precoder matrix W which reduces (eg minimizes) a chord, Fubini-Study, or two-norm projection distance to V where the matrix S,
is the singular value decomposition of the matrix R. The matrices U and V are usual unit matrices associated with the transformation of the matrix R on the diagonal of the matrix S. The precoder matrix W1 is selected as the one corresponding to an improved W (for example, best).
[00063] In another exemplary method, the user's equipment makes all matrix combinations,
sweeping all possible choices for matrices W1 and W2 (eg in the broadband sense). The user equipment then finds the precoder matrix W which increases (eg maximize) capacity (eg maximizes expression):

[00064] The precoded matrix W1 is selected as the one corresponding to an improved (eg better) W.
[00065] To reduce the complexity of the above methods, the Combinations
could be subject to sampling such that, for example, a single beam from each beam group is selected as representative of the beam group, and the selection is made on the basis of which matrix subset W, matrix W1 is selected that increases (for example, maximizes),

[00066] A second option is to select the matrix W1 which increases (eg maximizes),

[00067] Once the wideband / long-term precoder matrix W1 has been selected, the precoder matrices W2 are selected by frequency subband, for example, by finding the increasing precoder matrix W2 (by example, maximizes) the transfer rate in a given subband conditioned on the choice of matrix W1.
[00068] Once the user equipment has determined the beam group and the beam selection within that group by subband beam, the user equipment encodes the selections for transmission over an uplink communication channel. Both W1 and W2 matrices are encoded as indices in code tables known to both the base station and the user equipment. The user equipment transmits the index of the selected matrix W1 as well as the index of the selected matrix W2 to the base station (eg the double codebook format). In the case of an LTE-based communication system, the uplink communication channel used for the feedback transmission can be a physical uplink control channel ("PUCCH") or Pusch. In case of PUCCH, at least two alternative signaling solutions are provided.
[00069] In a signaling solution, the W1 matrix index can be coded together with the transmission patent indicator in a first PUCCH report, and the W2 matrix index can be coded together with the channel quality indicators ("CQI(s)") in another PUCCH report. In the other signaling solution, the transmission classification indicator is transmitted separately in a first PUCCH report, and the matrix index W1 as well as the matrix index W2 and the CQI(s) are transmitted in another PUCCH report . In an exemplary embodiment, data for matrix W1 and data for matrix W2 may be reported at the same frequency, or data for matrix W2 may be reported at a higher frequency than data for matrix W1. In case of Pusch, including all information including transmission classification indicator, both codebook indexes (eg double codebook format) as well as CQI(s) would be transmitted in a Pusch report. Transmission of Pusch feedback reports is typically triggered by the base station rather than PUCCH, which occurs periodically according to some semi-static configurations.
[00070] The base station gets the final precoder matrix as a result of matrix multiplication,

[00071] Since none of the codebook matrices is self-contained, receiving both matrices in a report can be advantageous. However, as Matrix W1 explores the broadband/long-term properties of the communication channel, the Matrix W1 report can be done with a shorter periodicity, while the refinement of the W2 matrix can be sent with a longer periodicity. time. Once the matrix W1 is relatively constant over time and no erroneous transmission has been performed, decoupled signaling can be employed.
[00072] An exemplary codebook design for beam groups dependent on transmission classification with operation 1-4 of transmission classification is now described. In this exemplary drawing, there are four beam groups in the case of transmission ratings 1 and 2, and two beam groups covering a larger beam space in the case of transmission ratings 3 and 4. The four beam groups in the case of transmission ratings of 1 and 2 are described with diagonal matrices based on discrete Fourier transform as follows:


[00073] The two beam groups in the case of transmission ratings 3-4 can be described as follows:
Where

[00074] Corresponding W2 vectors/matrices are composed of beam selection vectors, multiplied by a complex number to shift the phase of the vectors. These are listed below in Table 3 for transmission rating 1 only, but transmission rating 2-4 designs follow the same way, having transmission rating 2-4 beam selection vectors with adequate phase shift. In Table III below, ei denotes a 4 x 1 vector that selects the ith beam, for example,

TABLE III
[00075] An exemplary code table design for overlapping beam groups operating 1-2 of transmission classification is now described. In this exemplary design, there are eight groups of beams that partially overlap. The overlap is visible in W1 matrices, giving some of the columns the same in two adjacent matrices.




[00076] The corresponding W2 vectors / matrices are similar as in the exemplary drawing of the first code table (ie these matrices are composed of beam selection column vectors).
[00077] Thus, improved support of larger azimuthal propagation scenarios can be achieved in the case of feedback type beam grating. The full signal space can be better captured in a frequency selective manner when there is less spatial correlation in the communication channel (ie there is a greater azimuth differential). The benefits of the beam grid for MUMIMO in highly correlated cases are also retained.
[00078] Turning to figure 8, illustrated is a graphical representation of an embodiment of beam groups for the case of 1-2 transmission ratings according to the principles of the present invention. A first beam group (designated beam group 1) includes four beams with a first beam 810 that has a maximum gain of six decibels ("DB") in the azimuth direction of zero degrees and a fourth beam 820 that has a maximum gain of six decibels ("dB") in the azimuthal direction of less than 22 degrees. A second beam group (referred to as beam group 2) includes four beams with a first beam 830 that has a maximum gain of six decibels ("DB") in the azimuth direction of 18 degrees, and a fourth beam 840 that has a maximum gain six decibels ("dB") in the azimuthal direction of less than 4 degrees. The angular range 850 from a first beam maximum matrix gain direction 810 to a fourth beam (last beam) maximum matrix gain direction 820 in the first beam group is 22 degrees and the angular domains overlap with an angular variation 860 from a maximum matrix gain direction of the first beam 830 to a maximum matrix gain direction of the fourth beam (the last beam) 840 in the second beam group (beam of an adjacent group).
[00079] Turning now to Figure 9, illustrated is a flow diagram of an embodiment of a method of operating a communication system in accordance with the principles of the present invention. After a start step or module 910, an element of a communication system (e.g., a user equipment and/or the base station thereon) measures the uplink channel status information from a station. based on a 920 step or module. In a step or module 930, a beam group selected from a set of beam groups is identified according to a wideband property of channel state information, on which one of the characteristics of the set of beam groups depends of a transmission classification, the characteristic of the beamgroup set can be a number of beams in each beamgroup of the beamgroup set, a number of beamgroups in the beamgroup set, and/or a domain full angle extended from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each beam group in the set of beam groups. In a step or module 940, a selected subset of beams in the selected beam group is identified according to at least one subband, where a series of beams in the selected subset of beams is equal to the transmission rating.
[00080] In a step or module 950, coded feedback information is generated to identify the selected beam group and the selected subset of beams, for each subband in a dual codebook format. The dual codebook format is structured as a first matrix representing the selected beam group and a second matrix representing a selected subset of beams, for each subband. The first matrix can be formed using the sets of columns taken from supersampled discrete Fourier transform matrices. Furthermore, an angular range from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in the selected beam group can overlap in the angular domain with an angular range from from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam part of an adjacent beam group. The selected beam group can be used to drive eight base station transmit antennas. According to the coded response information, a precoder is formed (eg at a base station) for transmitting a signal in the communication system using the double codebook format, in one step or module 960. method ends at step 970 or module.
[00081] Thus, an apparatus, method and system are introduced here to select a beam group and a subset of beams in a communication system. In one embodiment, an apparatus (e.g., incorporated in a user equipment) includes a processor and memory including computer program code. The memory and computer program code are configured to, with the processor, cause the apparatus to measure uplink channel status information from a base station, and identify a selected beam group from a set of beam groups according to a broadband property channel state information. The characteristic of the set of beam groups depends on a transmission classification. The memory and the computer program code are configured to, with the processor, cause the apparatus to identify a selected subset of beams in the selected beam group according to at least one subband. The number of beams in the selected subset of beams is equal to the transmission rating.
[00082] In addition, the memory and the computer program code are configured to, with the processor, cause the apparatus to generate coded feedback information to identify the selected beam group and the selected subset of beams, for each sub -band in a dual codebook format, and transmit the coded feedback information to the base station. The dual codebook format includes a first matrix representing the selected beam group and a second matrix representing a selected subset of beams, for each subband. The first matrix is formed using sets of columns taken from the supersampled discrete Fourier transform matrices. In addition, the feature of the set of beam groups includes at least one of a series of beams from each beam group of the set of beam groups, a number of beam groups in the set of beam groups, and a domain full angle extended from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each beam group in the set of beam groups. In addition, a selected beam group can overlap in the full angular domain (or angular domain) with an adjacent beam group. For example, an angular range from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in the selected beam group can overlap in the angular domain with an angular range from from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in an adjacent beam group. Furthermore, the selected beam group can feature eight transmit antennas.
[00083] In another embodiment, an apparatus (e.g. embedded in a base station) includes a processor and memory including computer program code. The memory and computer program code are configured to, with the processor, cause the apparatus to receive coded feedback information from user equipment that identifies a selected beam group and a selected subset of beams for at least a subband, in a dual codebook format. The selected beam group represents one of a set of beam groups according to a broadband property of channel state information measured by the user equipment and a characteristic of the set of beam groups is based on a transmission classification. Furthermore, the selected subset of beams in the selected beam group is selected according to the subband, at least one and a certain number of beams in the selected subset of beams is equal to the transmission classification. The computer program code and memory are configured to, with the processor, cause the device to form a precoder for transmitting a signal to the user equipment using the double codebook format. Although the apparatus, method and system described herein with respect to cellular-based communication systems, the apparatus and method are equally applicable to other types of communication systems, such as a WiMax ® communication system.
[00084] The program or code segments that form the various embodiments of the present invention may be stored on a computer readable medium or transmitted by a computer data signal embedded in a carrier wave, or a carrier-modulated signal, upon along a transmission medium. For example, a computer program product including a program code stored on a computer-readable medium can form various embodiments of the present invention. "Computer-readable medium" can include any medium that can store or transfer information. Examples of computer readable media include an electronic circuit, a semiconductor memory device, a read-only memory ("ROM"), a flash memory, an erasable ROM ("EROM"), a floppy disk, a compact disk (" CD-ROM"), an optical disk, a hard disk, a fiber optic medium, a radio frequency ("RF") link, and the like. The computer data signal can include any signal that can propagate more than one medium transmission channels, such as electronic communications network channels for communications, fiber optics, air, electromagnetic links, RF links, and the like. Code segments can be downloaded through computer networks such as the Internet, Intranet, and the like .
[00085] As described above, the exemplary embodiment provides both a method and a corresponding apparatus consisting of several modules that provide functionality to perform the steps of the method. Modules can be implemented as hardware (built into one or more chips, including an integrated circuit, such as an application-specific integrated circuit), or can be implemented as software or firmware for execution by a computer processor. In particular, in the case of firmware or software, the exemplary embodiment may be provided as a computer program product that includes a computer-readable storage structure that contains the computer program code (i.e., the software or firmware) in the even for execution by the computer's processor.
[00086] Although the present invention and its advantages have been described in detail, it is to be understood that various changes, substitutions and alterations can be made thereto without departing from the spirit and scope of the invention as defined by the appended embodiments. For example, many of the features and functions discussed above can be implemented in hardware, software or firmware, or a combination of these. Furthermore, many of the features, functions and operating steps thereof can be rearranged, omitted, added, etc., and still fall within the broad scope of the present invention.
[00087] Furthermore, the scope of this application is not intended to be limited to the particular embodiments of the process, machine, fabrication, composition of matter, means, methods and steps described in the specification. As a person skilled in the art will understand immediately from the disclosure of the present invention, the processes, machines, fabrication, compositions of matter, means, methods, or steps, currently existing or to be developed later, that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein can be used in accordance with the present invention. Therefore, the appended embodiments are intended to include within its scope such processes, machines, fabrication, compositions of matter, means, methods, or steps.

权利要求:
Claims (15)
[0001]
1. A method characterized in that it comprises the steps of: measuring (920) channel state information on a downlink of a base station; identifying (930) a beamgroup selected from a set of beamgroups according to a wideband property of the channel state information, wherein a characteristic of the beamgroup set depends on a transmission classification; and identifying (940) a selected beam subset in which the selected beam group in accordance with at least one subband, wherein a number of beams from the selected beam subset is equal to the transmission rating; wherein an angular range from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in the beam group overlaps in the angular domain with an angular range from a gain direction from maximum matrix of a first beam to a maximum matrix gain direction of a last beam in an adjacent beam group.
[0002]
2. Method according to claim 1, characterized in that it further comprises the steps of: generating (950) coded feedback information identifying the selected beam group and the selected beam subset for each subband in table format code, and transmit the coded feedback information to the base station.
[0003]
3. Method characterized in that it comprises the steps of: receiving coded feedback information from a user equipment identifying a selected beam group and a selected beam subset for at least one subband in a table format dual coding, wherein the selected beamgroup represents one of a set of beamgroups according to a wideband property of the channel state information measured by the user equipment and a characteristic of the set of beamgroups based on in a transmission classification, and wherein the selected subset of beams in the selected beam group is selected according to the at least one subband and a number of beams in the selected subset of beams is equal to the transmission classification; and forming (960) a precoder for transmitting a signal to user equipment using the dual format codebook; wherein an angular range from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in the beam overlaps selected from the group in the angular domain with an angular range from a gain direction of maximum matrix of a first beam to a maximum matrix gain direction of a last beam in an adjacent beam group.
[0004]
4. Method according to claim 2 or 3, characterized in that the dual codebook format comprises a first matrix representing the selected beam group and a second matrix representing a selected subset of the beams for each subband .
[0005]
5. Method according to claim 4, characterized in that the first matrix is formed using sets of columns taken from supersampled Discrete Fourier Transform (DFT) matrices.
[0006]
6. Method according to any one of claims 1 to 5, characterized in that the characteristic of the set of beam groups includes at least one of a number of beams from each beam group of the set of beam groups, a number of beam groups in the set of beam groups, and a total angular domain calibrated from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each group in the set of beam of beam groups.
[0007]
7. Method according to any one of claims 1 to 6, characterized in that the angular domain overlap occurs between groups of beams, in part, containing the same beams.
[0008]
8. Apparatus characterized in that it comprises: means for measuring downlink channel state information from a base station; means for identifying (520) a beam group selected from a set of beam groups according to a broadband property of the channel state information, wherein a characteristic of the beam group set depends on a classification of streaming; and means for identifying (520) a selected subset of beams in the selected beam group in accordance with at least one subband, wherein a number of beams in the selected subset of beams is equal to the transmission rating; wherein an angular range from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in the beam group overlaps in the angular domain with an angular range from a gain direction from maximum matrix of a first beam to a maximum matrix gain direction of a last beam in an adjacent beam group.
[0009]
9. Apparatus according to claim 8, further comprising: means for generating (520) coded feedback information identifying the selected beam and the selected subset of beams for each subband in a table format of double encoding; and means for transmitting (570) the encoded feedback information to the base station.
[0010]
10. Apparatus, characterized in that it comprises: means for receiving (570) coded feedback information from a user equipment identifying a selected beam group and a selected beam subset for at least one subband, in a dual codebook format, in which the selected beam group represents one of a set of beam groups according to a broadband property of the channel state information measured by the user equipment and a characteristic of the set of beam groups. beam based on a transmission rating, and wherein the selected beam subset in the selected beam group is selected according to at least one subband and a number of beams in the selected beam subset is equal to the transmission rating ; and means for forming (520) a precoder for transmitting a signal to the user equipment using the dual format codebook.
[0011]
11. Apparatus according to claim 9 or 10, characterized in that the dual codebook format comprises a first matrix representing the selected beam group and a second matrix representing a selected subset of the beams for each subband .
[0012]
12. Apparatus according to claim 11, characterized in that the first matrix is formed using sets of columns taken from supersampled Discrete Fourier Transform (DFT) matrices.
[0013]
13. Apparatus according to any one of claims 8 to 12, characterized in that the characteristic of the set of beam groups includes at least one of a number of beams from each beam group of the set of beam groups, a number of beam groups in the beam group set, and an angular domain calibrated from a maximum matrix gain direction of a first beam to a maximum matrix gain direction of a last beam in each group in the beam set of beam groups.
[0014]
14. Apparatus according to any one of claims 8 to 12, characterized in that the angular domain overlap occurs between groups of beams, in part, containing the same beams.
[0015]
15. Computer readable medium characterized in that it comprises a method as defined in any one of claims 1 to 7.

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同族专利:

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公开号 | 公开日

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WO2011150559A1|2011-12-08|

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RU2538735C2|2015-01-10|

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US8897254B2|2014-11-25|

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DK2577923T3|2020-05-18|

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US20130064129A1|2013-03-14|

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PL2577923T3|2020-09-07|

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EP2577923B1|2020-02-26|

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WO2011150549A1|2011-12-08|

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EP2577923A1|2013-04-10|

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HUE048959T2|2020-09-28|

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RU2012151961A|2014-07-20|

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ES2793699T3|2020-11-16|

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BR112012030434A2|2017-06-13|

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EP2577923A4|2017-02-01|

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法律状态:
2017-08-01| B25A| Requested transfer of rights approved|Owner name: NOKIA TECHNOLOGIES OY (FI) |

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2018-08-07| B25A| Requested transfer of rights approved|Owner name: BEIJING XIAOMI MOBILE SOFTWARE CO., LTD. (CN) |

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2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-02-11| B15K| Others concerning applications: alteration of classification|Free format text: A CLASSIFICACAO ANTERIOR ERA: H04L 25/03 Ipc: H04B 7/06 (2006.01) |

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2020-02-11| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-05-04| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-06-01| B350| Update of information on the portal [chapter 15.35 patent gazette]|

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2021-06-22| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 02/06/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, , QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |

优先权:

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申请号 | 申请日 | 专利标题

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PCT/CN2010/073411|WO2011150549A1|2010-06-01|2010-06-01|Apparatus and method for selection of beam groups and subset of beams in communication system|

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PCT/CN2010/073463|WO2011150559A1|2010-06-01|2010-06-02|Apparatus, method and computer program product for selecting beam group and subset of beams in communication system|

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