JP2013539312A - Efficient feedback method and apparatus in multi-antenna assisted wireless communication system - Google Patents

Abstract

The present invention relates to a wireless communication system, and more particularly, to provide an efficient feedback method and apparatus in a multi-antenna assisted wireless communication system. A method for transmitting CSI for downlink multi-carrier transmission according to an embodiment of the present invention includes a rank indicator (RI), a first precoding matrix index (PMI), a second PMI, and one or more downlink carriers. Generating a CSI including one or more channel quality indicators (CQIs) calculated based on precoding information determined by a combination of the first and second PMIs, and one on one uplink carrier When two or more CSIs collide with each other in an uplink subframe, the method includes a step of determining CSI to be transmitted based on the priority order and a step of transmitting the determined CSI using an uplink channel.
[Selection] Figure 34

Description

  The following description relates to a wireless communication system, and more particularly, to an efficient feedback method and apparatus in a multiple antenna assisted wireless communication system.

  MIMO (Multiple-Input Multiple-Output) technology has been used since one transmission antenna and one reception antenna so far, and adopted multiple transmission antennas and multiple reception antennas to improve transmission and reception data efficiency. It refers to a method that can be improved. That is, it is a technique for increasing capacity or improving performance by using multiple antennas at a transmitting end or a receiving end of a wireless communication system. MIMO technology can also be referred to as multiple antenna technology. In order to accurately perform multi-antenna transmission, it is necessary to feed back information about the channel from the receiving end that receives the multi-antenna channel.

  Information that is fed back from the receiving end to the transmitting end in an existing multi-antenna wireless communication system includes a rank indicator (RI), a precoding matrix index (PMI), and channel quality information (Channel Quality Information); CQI) and the like are defined. The feedback information is configured as information suitable for existing multi-antenna transmission.

  However, the introduction of a new system having an extended antenna configuration compared to existing multi-antenna wireless communication systems has been discussed. For example, the existing system only supported up to 4 transmission antennas, but a new system with an extended antenna configuration can support MIMO transmission through 8 transmission antennas and provide increased system capacity. .

  In a new system that supports an extended antenna configuration, more complex MIMO transmission is performed compared to the existing MIMO transmission operation. Therefore, only the feedback information defined for the existing MIMO transmission operation is used in the new system. It cannot accurately support the MIMO operation.

  An object of the present invention is to provide a method and apparatus for configuring and transmitting feedback information for accurately and efficiently supporting MIMO operation with an extended antenna configuration.

  The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned are described below. Those with ordinary knowledge in the field will be clearly understood.

In order to solve the above technical problem, a method for transmitting channel state information (CSI) for downlink multi-carrier transmission according to an embodiment of the present invention includes a rank indicator (RI) for one or more downlink carriers. ), One or more of a first precoding matrix index (PMI), a second PMI, and a channel quality indicator (CQI) calculated based on precoding information determined by a combination of the first and second PMIs. Generating the CSI, including determining CSI to be transmitted based on priority when two or more CSIs collide in one uplink subframe on one uplink carrier;
Transmitting the determined CSI using an uplink channel, wherein the CSI includes a first group including an RI, a second group including a broadband first PMI, a third group including a broadband CQI, and It is classified into a fourth group including sub-band CQI, and the priority is assigned to CSI belonging to the first group or CSI belonging to the second group belonging to the third group CSI or the fourth group. In case of collision with the CSI, the CSI belonging to the third group or the fourth group has a low priority and is set to drop.

  In order to solve the above technical problem, a terminal that transmits channel state information (CSI) for downlink multi-carrier transmission according to another embodiment of the present invention includes a receiving module that receives a downlink signal from a base station, and A transmission module for transmitting an uplink signal to the base station; and a processor for controlling the terminal including the reception module and the transmission module, wherein the processor is a rank indicator for one or more downlink carriers. (RI), a first precoding matrix index (PMI), a second PMI, and a channel quality indicator (CQI) calculated based on precoding information determined by a combination of the first and second PMIs The CSI including the above is generated, and one uplink subcarrier on one uplink carrier is generated. When two or more CSIs collide with each other in a frame, the CSI to be transmitted is determined based on priority, and the determined CSI is transmitted using an uplink channel via the transmission module. The CSI is classified into a first group including RI, a second group including a wideband first PMI, a third group including a wideband CQI, and a fourth group including a subband CQI. When CSI belonging to one group or CSI belonging to the second group collides with CSI belonging to the third group or CSI belonging to the fourth group, it belongs to the third group or the fourth group. The CSI has a low priority and is set to drop.

  The following matters can be commonly applied to the above-described embodiments of the present invention.

  The CSI belonging to the first group and the CSI belonging to the second group may have the same priority.

  When the CSI related to the downlink transmission mode using the 8 transmission antennas collides with the CSI related to the other downlink transmission mode, the priority order of the CSI related to the other downlink transmission mode is low. Have and fall off.

  When the priorities are the same, a CSI related to a downlink carrier having a high priority set by an upper layer for each of the one or more downlink carriers is transmitted using the uplink channel. Also good.

  When the CSI belonging to the third group and the CSI belonging to the fourth group collide, the CSI belonging to the fourth group has a low priority and may fall.

  When the first PMI falls, the channel state information subsequent to the dropped first PMI may be generated based on the predefined first PMI.

  The uplink channel may be a physical uplink control channel (PUCCH).

  The uplink channel is a physical uplink shared channel (PUSCH), and the priority order may be applied when CSI for different carriers collides.

  The foregoing general description and the following detailed description of the invention are exemplary and are for the purpose of further explanation of the claimed invention.

  According to the present invention, it is possible to provide a method and apparatus for configuring and transmitting feedback information for accurately and efficiently supporting MIMO operation with an extended antenna configuration.

  The effects obtained from the present invention are not limited to the effects mentioned above, and other effects that are not mentioned are clearly apparent to those having ordinary knowledge in the technical field to which the present invention belongs from the following description. Will be understood.

The drawings attached hereto are provided to provide an understanding of the invention, illustrate various embodiments of the invention, and together with the description serve to explain the principles of the invention. is there.
It is a figure which shows the structure of a radio | wireless frame. FIG. 6 is a diagram illustrating a resource grid in a downlink slot. It is a figure which shows the structure of a downlink sub-frame. It is a figure which shows the structure of an uplink sub-frame. It is a figure for demonstrating the structure of the physical layer (L1) and MAC layer (L2) of a multicarrier support system. It is a figure which shows notionally the component carrier wave (CC) with respect to each of a downlink and an uplink. It is a figure which shows an example of DL / UL CC cooperation. It is a figure for demonstrating a SC-FDMA transmission system and an OFDMA transmission system. It is a figure for demonstrating the maximum transmission power in the case of single antenna transmission and multiple antenna transmission. It is a figure which shows the structure of a multiple antenna (MIMO) communication system. It is a figure which shows the general CDD structure in a multi-antenna system. It is a figure for demonstrating the codebook based precoding. It is a figure which shows the resource mapping structure of PUCCH. It is a figure which shows the channel structure of a CQI information bit. It is a figure for demonstrating transmission of CQI and ACK / NACK information. It is a figure for demonstrating the feedback of channel state information. It is a figure for demonstrating an example of CQI report mode. It is a figure which shows an example of the system with which a terminal transmits channel information periodically. It is a figure for demonstrating transmission of SB CQI. It is a figure for demonstrating transmission of WB CQI and SB CQI. It is a figure for demonstrating transmission of WB CQI, SB CQI, and RI. It is a figure for demonstrating the illustration of the PMI / CQI transmission timing and offset of a restricted rank. It is a figure for demonstrating the illustration of the PMI / CQI transmission timing and offset of a restricted rank. It is a figure for demonstrating the reporting period of the PMI / CQI of the restricted rank. It is a figure for demonstrating the reporting period of the PMI / CQI of the restricted rank. It is a figure for demonstrating the reporting period of the PMI / CQI of the restricted rank. It is a figure for demonstrating the channel information transmission plan by PUCCH report mode 2-1. It is a figure for demonstrating the channel information transmission plan by PUCCH report mode 2-1 when a part of channel information falls. It is a figure which shows an example of the timing by which channel information is reported through an uplink. It is a figure which shows the channel information report timing by PUCCH report mode 2-1 based on a PTI value. It is a figure for demonstrating the channel information transmission plan by PUCCH report mode 2-1 in the case of the fall of some channel information. It is a figure for demonstrating the channel information transmission plan by PUCCH report mode 2-1 in the case of the fall of some channel information. It is a figure for demonstrating the report period of WB CQI / WB W2 and SB CQI / SB W2. It is a figure which shows the reporting period of periodic PUCCH report mode 2-1 with respect to the downlink transmission mode 9. FIG. 3 is a flowchart illustrating a channel state information transmission method according to the present invention. It is a figure which shows the structure of the base station apparatus and terminal device which concern on this invention.

  In the following examples, the constituent elements and features of the present invention are combined in a predetermined form. Each component or feature must be considered optional unless explicitly stated otherwise. Each component or feature may be implemented in a form that is not combined with other components or features, or some components and / or features may be combined to constitute an embodiment of the present invention. The order of operations described in the embodiments of the present invention may be changed. Some configurations and features of an embodiment may be included in other embodiments, and may be replaced with corresponding configurations or features of other embodiments.

  In the present specification, an embodiment of the present invention will be described focusing on the data transmission / reception relationship between the base station and the terminal. Here, the base station has a meaning as a terminal node of a network that directly communicates with a terminal. In this document, the specific operation that is performed by the base station may be performed by an upper node of the base station in some cases.

  That is, in a network composed of a large number of network nodes including a base station, various operations performed for communication with a terminal can be performed by the base station or another network node other than the base station. That is obvious. The “base station (BS)” may be replaced with a fixed station (fixed station), a node B, an eNode B (eNB), an access point (AP), or the like. Also, in this document, the term base station can be used as a concept including a cell or a sector. On the other hand, the repeater may be replaced with terms such as Relay Node (RN) and Relay Station (RS). “Terminal” may be replaced with terms such as UE (User Equipment), MS (Mobile Station), MSS (Mobile Subscriber Station), SS (Subscriber Station), and the like.

  The specific terms used in the following description are provided to assist the understanding of the present invention, and the use of these specific terms can be changed to other forms without departing from the technical idea of the present invention. is there.

  In some instances, well-known structures and devices may be omitted or may be shown in block diagram form with the core functions of each structure and device being centered to avoid obscuring the concepts of the present invention. In addition, throughout the present specification, the same constituent elements will be described with the same reference numerals.

  Is the embodiment of the present invention supported by a standard document disclosed in at least one of the wireless connection systems IEEE 802 system, 3GPP system, 3GPP LTE and LTE-A (LTE-Advanced) system, and 3GPP2 system? it can. That is, in the embodiment of the present invention, stages or portions not described for clarifying the technical idea of the present invention can be supported by the standard document. It should be noted that all terms disclosed in this document can be explained by the above standard documents.

  The following technology, CDMA (Code Division Multiple Access), FDMA (Frequency Division Multiple Access), TDMA (Time Division Multiple Access), OFDMA (Orthogonal Frequency Division Multiple Access), SC-FDMA (Single Carrier Frequency Division Multiple Access), etc. It can be used for various wireless connection systems. CDMA may be a radio technology such as UTRA (Universal Terrestrial Radio Access) or CDMA2000. TDMA may be GSM (Global System for Mobile communications) / GPRS (General Packet Radio Service) / EDGE (Enhanced Data Rates for GSM (registered trademark) Evolution). OFDMA may be a wireless technology such as IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802-20, E-UTRA (Evolved UTRA), and the like. UTRA is a part of UMTS (Universal Mobile Telecommunication Systems). 3GPP (3rd Generation Partnership Project) LTE (long term evolution) is part of E-UMTS (Evolved UMTS) using E-UTRA, adopts OFDMA on the downlink, and SC-FDMA on the uplink . LTE-A (Advanced) is a development of 3GPP LTE. WiMAX can be described by the IEEE 802.16e standard (WirelessMAN-OFDMA Reference System) and the advanced IEEE 802.16m standard (WirelessMAN-OFDMA Advanced system). For clarity, the following description focuses on 3GPP LTE and LTE-A systems, but the technical idea of the present invention is not limited thereto.

  The structure of the downlink radio frame will be described with reference to FIG.

  In the cellular OFDM wireless packet communication system, uplink / downlink data packet transmission is performed in units of subframes, and one subframe is defined as a certain time interval including a number of OFDM symbols. The 3GPP LTE standard supports a type 1 radio frame structure applicable to FDD (Frequency Division Duplex), and a type 2 radio frame structure applicable to TDD (Time Division Duplex).

  FIG. 1A is a diagram illustrating the structure of a type 1 radio frame. The downlink radio frame is composed of 10 subframes, and one subframe is composed of 2 slots in a time domain. The time taken to transmit one subframe is called TTI (transmission time interval). For example, the length of one subframe is 1 ms, and the length of one slot is 0.5 ms. One slot has a plurality of OFDM symbols in the time domain, and has a number of resource blocks (RBs) in the frequency domain. In the 3GPP LTE system, since OFDMA is used in the downlink, an OFDM symbol indicates one symbol period. An OFDM symbol can also be called an SC-FDMA symbol or a symbol interval. A resource block (RB) is a resource allocation unit, and can have a plurality of continuous subcarriers in one slot.

  The number of OFDM symbols included in one slot may differ depending on the configuration of a CP (Cyclic Prefix). The CP includes an extended CP (extended CP) and a general CP (normal CP). For example, when the OFDM symbol is configured by a general CP, the number of OFDM symbols included in one slot may be seven. When an OFDM symbol is configured by an extended CP, the length of one OFDM symbol increases, so that the number of OFDM symbols included in one slot is smaller than that in the case of a general CP. In the case of the extended CP, for example, the number of OFDM symbols included in one slot may be six. An extended CP can be used to further reduce intersymbol interference when the channel condition is unstable, such as when the terminal moves at a high speed.

  When a general CP is used, one slot has 7 OFDM symbols, so one subframe has 14 OFDM symbols. In this case, the first two or three OFDM symbols in each subframe may be allocated to PDCCH (physical downlink control channel), and the remaining OFDM symbols may be allocated to PDSCH (physical downlink shared channel).

  FIG. 1B is a diagram illustrating the structure of a type 2 radio frame. A type 2 radio frame is composed of two half frames. Each half frame includes five subframes, a DwPTS (Downlink Pilot Time Slot), a guard period (GP), and an UpPTS (Uplink). (Pilot Time Slot), and one subframe is composed of two slots. DwPTS is used for initial cell search, synchronization or channel estimation at the terminal. UpPTS is used to match channel estimation at the base station and uplink transmission synchronization of the terminal. The protection section is a section for removing interference generated in the uplink due to multipath delay of the downlink signal between the uplink and the downlink. On the other hand, regardless of the type of radio frame, one subframe is composed of two slots.

  The structure of the radio frame is merely an example, and the number of subframes included in the radio frame, the number of slots included in the subframe, and the number of symbols included in the slots can be variously changed.

FIG. 2 is a diagram illustrating a resource grid in one downlink slot. Although one downlink slot includes 7 OFDM symbols in the time domain and one resource block (RB) includes 12 subcarriers in the frequency domain, the present invention is not limited thereto. For example, in the case of a general CP (Cyclic Prefix), one slot includes 7 OFDM symbols, but in the case of an extended CP (Extended-CP), one slot can include 6 OFDM symbols. Each element on the resource grid is called a resource element (RE). One resource block includes 12 × 7 resource elements. The number N ^{DL of} resource blocks included in the downlink slot follows the downlink transmission bandwidth. The structure of the uplink slot may be the same as the structure of the downlink slot.

  FIG. 3 is a diagram illustrating a structure of a downlink subframe. Within one subframe, a maximum of 3 OFDM symbols at the beginning of the first slot correspond to a control region to which a control channel is allocated, and the remaining OFDM symbols are physical downlink shared channels (PDSCH). Corresponds to the data area to be allocated. The downlink control channel used in the 3GPP LTE system includes, for example, a physical control format indicator channel (Physical Control Indicator Channel; PCFICH), a physical downlink control channel (Physical Downlink Control Channel; PDCCH indicator channel), and a physical HAR channel. (Physical Hybrid automatic repeat request Indicator Channel; PHICH). PCFICH is transmitted in the first OFDM symbol of the subframe, and includes information on the number of OFDM symbols used for control channel transmission in the subframe. The PHICH includes a HARQ ACK / NACK signal as a response to the uplink transmission. Control information transmitted through the PDCCH is referred to as downlink control information (DCI). The DCI includes uplink or downlink scheduling information and includes an uplink transmission power control command for an arbitrary terminal group. PDCCH includes downlink shared channel (DL-SCH) resource allocation and transmission format, uplink shared channel (UL-SCH) resource allocation information, paging channel (PCH) paging information, system information on DL-SCH, Resource allocation of higher layer control messages such as random access response transmitted on PDSCH, set of transmission power control commands to individual terminals in an arbitrary terminal group, transmission power control information, VoIP (Voice over) IP) activation and the like. A plurality of PDCCHs are transmitted in the control region, and the terminal can monitor the plurality of PDCCHs. The PDCCH is transmitted in a combination of one or more consecutive control channel elements (CCE). CCE is a logical allocation unit used to provide PDCCH at a coding rate based on the state of a radio channel. The CCE corresponds to a plurality of resource element groups. The format of the PDCCH and the number of available bits are determined by the correlation between the number of CCEs and the coding rate provided by the CCE. The base station determines the PDCCH format based on the DCI transmitted to the terminal, and adds a cyclic redundancy check (CRC) to the control information. The CRC is masked by an identifier called a radio network temporary identifier (RNTI) depending on the owner or use of the PDCCH. If the PDCCH is for a specific terminal, the cell-RNTI (C-RNTI) of the terminal can be masked to the CRC. Alternatively, if the PDCCH is for a paging message, a paging indicator identifier (P-RNTI) can be masked in the CRC. If the PDCCH is for system information (particularly, system information block (SIB)), the system information identifier and system information RNTI (SI-RNTI) can be masked in the CRC. Random access-RNTI (RA-RNTI) can be masked to the CRC to represent a random access response, which is a response to the terminal's random access preamble transmission.

  FIG. 4 is a diagram illustrating a structure of an uplink subframe. The uplink subframe can be distinguished into a control region and a data region in the frequency domain. A physical uplink control channel (Physical Uplink Control Channel; PUCCH) including uplink control information is allocated to the control region. A physical uplink shared channel (PUSCH) including user data is allocated to the data area. In order to maintain the single carrier characteristic, one terminal does not transmit PUCCH and PUSCH at the same time. The PUCCH for one terminal is allocated to a resource block pair (RB pair) in a subframe. Resource blocks belonging to a resource block pair occupy different subcarriers for two slots. This is referred to as frequency-hopping a resource block pair allocated to the PUCCH at slot boundaries.

(Carrier Aggregation)
In a general wireless communication system, even if the bandwidths between the uplink and the downlink are set to be different from each other, only one carrier is mainly considered. For example, based on a single carrier, there is provided a wireless communication system in which the number of carriers constituting the uplink and the downlink is one each, and the uplink bandwidth and the downlink bandwidth are mainly symmetrical with each other can do.

  In ITU (International Telecommunication Union), IMT-Advanced candidate technology is required to support an extended bandwidth compared to existing wireless communication systems. However, frequency allocation of a large bandwidth is not easy except in some regions worldwide. Therefore, as a technique for efficiently using a small band of fragments, a combination of carriers for achieving an effect of using a band of a logically large band by combining a plurality of bands physically in the frequency domain ( Carrier Aggregation: Bandwidth Aggregation or Spectral Aggregation (also referred to as Spectrum Aggregation) technology has been developed.

  Carrier combinations are introduced to support increasing throughput, to prevent cost increases due to the introduction of broadband RF elements, and to ensure compatibility with existing systems. The carrier combination is between a terminal and a base station through a plurality of bundles of bandwidth units defined in an existing wireless communication system (for example, 3GPP LTE Release 8 or 9 system in the case of 3GPP LTE-Advanced system). It is a technology that allows data to be exchanged. Here, a carrier in a bandwidth unit defined in an existing wireless communication system can be referred to as a component carrier (CC). A carrier combination technique using one or more constituent carriers in each of the uplink and the downlink can be applied. The carrier combination technology may include a technology that supports a system bandwidth of up to 100 MHz by combining up to five component carriers even if one component carrier supports a bandwidth of 5 MHz, 10 MHz, or 20 MHz.

  The downlink constituent carrier can be expressed as DL CC, and the uplink constituent carrier can be expressed as UL CC. A carrier wave or a component carrier wave may be expressed as a cell by a method described and expressed in terms of a functional configuration in the 3GPP standard. Therefore, DL CC may be expressed as DL cell, and UL CC may be expressed as UL cell. Hereinafter, in the present invention, a plurality of carriers to which a combination of carriers is applied are expressed using terms of a carrier, a constituent carrier, CC, or a cell.

  In the following description, the downlink transmission entity will be described mainly with a base station (or cell), and the uplink transmission entity will mainly be described with a terminal, but this is not a limitation. Absent. In other words, when the repeater is the downlink transmission subject to the terminal or the uplink reception subject from the terminal, or the repeater is the uplink transmission subject to the base station, or the downlink reception from the base station The contents of the present invention can also be applied to the main body.

  In the downlink carrier combination, a base station transmits a downlink to a terminal using a frequency domain resource (subcarrier or PRB (Physical Resource Block)) on one or more carrier bands in a certain time domain resource (subframe unit). It can be said that it supports. In the uplink carrier combination, the terminal supports the uplink transmission using the frequency domain resource (subcarrier or PRB) on one or more carrier bands in a certain time domain resource (subframe unit) to the base station, It can be said.

  The configuration of the physical layer (first layer, L1) and the MAC layer (second layer, L2) of the multi-carrier support system will be described with reference to FIG. In a base station in an existing wireless communication system that supports a single carrier, there is one physical layer (PHY) individual that supports one carrier, and one MAC (Medium Access Control) individual that controls one PHY individual. Can be provided. In the PHY layer, for example, a baseband processing operation can be performed. In the MAC layer, for example, the transmission unit can perform MAC PDU (Protocol Data Unit) generation and L1 / L2 scheduler operation including the MAC / RLC sublayer. The MAC PDU packet block in the MAC layer is converted into a transport block through a logical transport layer and mapped to a physical layer input information block. The MAC layer in the figure represents the entire L2 layer, and can be applied to include the MAC / RLC / PDCP sublayer. Such application can be applied by replacing any of them in the description of the MAC layer of the present invention as a whole.

  On the other hand, a plurality of MAC-PHY individuals can be provided in the multi-carrier support system. That is, as shown in FIG. 5A, the transmission unit and the reception unit of the multi-carrier support system can be configured in a form in which one MAC-PHY individual corresponds to each of the n constituent carriers. . Since an independent PHY layer and a MAC layer are configured for each constituent carrier, a PDSCH is generated for each constituent carrier in the physical layer from the MAC PDU.

  Alternatively, one common MAC entity and a plurality of PHY entities can be provided in the multi-carrier support system. That is, as shown in FIG. 5B, n PHY individuals corresponding to each of the n constituent carriers are provided, and there is one common MAC individual that controls the n PHY individuals. The transmission unit and the reception unit of the multi-carrier support system can also be configured. In this case, a MAC PDU from one MAC layer may be divided into a plurality of transmission blocks corresponding to each of a plurality of constituent carriers on the transmission layer, or when generating a MAC PDU in the MAC layer Or, when RLC PDUs are generated in the RLC layer, they may be branched for each constituent carrier. Thereby, PDSCH is generated for each constituent carrier wave in the physical layer.

  The PDCCH that transmits the control information of the L1 / L2 control signaling generated from the packet scheduler in the MAC layer can be mapped to the physical resource for each dedicated carrier and transmitted. Here, the PDCCH including control information (downlink assignment or uplink grant) for PDSCH or PUSCH transmission to a specific terminal can be encoded separately for each component carrier on which the PDSCH / PUSCH is transmitted. Such a PDCCH may be referred to as a separately coded PDCCH. Meanwhile, control information for PDSCH / PUSCH transmission of a plurality of constituent carriers can be transmitted as one PDCCH, which can be referred to as a joint-coded PDCCH.

  In order to support the carrier combination, the connection between the base station and the terminal (or repeater) is configured so that the control channel (PDCCH or PUCCH) and / or the shared channel (PDSCH or PUSCH) can be transmitted, or the connection Preparation for setting is required. For such a connection / connection setting for each specific terminal (or relay station), measurement and / or reporting for the carrier is required for such connection / connection setting, and a constituent carrier to be subjected to such measurement and / or reporting Can be assigned. That is, constituent carrier allocation refers to downlink / uplink transmission in consideration of the performance (capability) of a specific terminal (or relay station) and system environment among downlink / uplink constituent carriers configured by a base station. This means setting the constituent carrier to be used (specifying the number and index of constituent carriers).

  At this time, when the configuration carrier allocation is controlled by the third layer (L3) RRM (Radio Resource Management), terminal-specific (UE-specific) or relay-specific (RN-specific) RRC signaling may be used. it can. Alternatively, cell-specific or cell cluster-specific RRC signaling may be used. When dynamic control such as a series of configuration carrier activation / deactivation settings is required for configuration carrier allocation, a predetermined PDCCH is used as L1 / L2 control signaling, It is also possible to use a dedicated physical control channel dedicated to configuration carrier allocation control information or a PDSCH in the form of an L2 MAC message. On the other hand, when the component carrier allocation is controlled by the packet scheduler, a predetermined PDCCH is used as the L1 / L2 control signaling, a physical control channel dedicated to the component carrier allocation control information is used, or a PDSCH in the L2 MAC message form Can be used.

  FIG. 6 is a diagram conceptually illustrating constituent carriers (CC) for each of the downlink and the uplink. The downlink (DL) and uplink (UL) CC of FIG. 6 can be allocated by a base station (cell) or a relay station. For example, the number of DL CCs is set to N, and the number of UL CCs is set to M. Is set.

  A stage of establishing RRC connection based on a single arbitrary CC for each of DL and UL through initial access or initial deployment process of a terminal (cell search, system information ( After performing system information acquisition / reception, initial random access process, etc., a carrier configuration specific to each terminal is determined through dedicated signaling (terminal-specific RRC signaling or terminal-specific L1 / L2 PDCCH signaling). Provided by the bureau. Alternatively, when the carrier setting for the terminal is made common for each base station (cell or cell cluster), it may be provided through cell-specific RRC signaling or cell-specific terminal-common L1 / L2 PDCCH signaling. Alternatively, the carrier configuration information configured in the base station may be signaled to the terminal through system information for RRC connection setup, or to the terminal through separate system information after cell RRC connection setup or cell-specific RRC signaling. Signaling may be performed.

  In this document, the DL / UL CC setting will be described focusing on the relationship between the base station and the terminal, but is not limited to this. For example, the present invention is equally applicable to the case where a relay station provides the DL / UL CC setting of the corresponding terminal to a terminal in the relay station area. Further, the present invention is equally applicable to the case where the base station provides the DL / UL CC setting of the corresponding relay station to the relay station in the base station area. Hereinafter, for the sake of clarity, the DL / UL CC configuration will be described focusing on the relationship between the base station and the terminal. However, the same content may be applied between the relay station and the terminal (access uplink and downlink) or the base station− It is clear that it can be applied between repeaters (backhaul uplink and downlink).

  Setting DL / UL CC associations implicitly in the process of assigning DL / UL CCs uniquely to individual terminals or explicitly through the definition of arbitrary signaling parameters Can do.

  FIG. 7 is a diagram illustrating an example of DL / UL CC linkage. When a base station configures a CC with two downlink CCs (DL CC # a and DL CC # b) and two uplink CCs (UL CC # i and UL CC # j), an arbitrary terminal Exemplifies DL / UL CC linkage defined by assigning two downlink CCs (DL CC # a and DL CC # b) and one uplink CC (UL CC # i). In the DL / UL CC linkage setting of FIG. 7, what is indicated by a solid line basically indicates the linkage setting of the DL CC and UL CC configured by the base station. This can be defined in SIB2. The DL / UL CC link setting shown in FIG. 7 is indicated by a dotted line, indicating the link setting between DL CC and UL CC set for a specific terminal. The link setting of DL CC and UL CC in FIG. 7 is merely an example, and is not limited to this. That is, in various embodiments of the present invention, the number of DL CCs and UL CCs configured by a base station may be set to an arbitrary value, and according to this, the configured DL CCs and UL CCs The number of DL CCs and UL CCs that are specifically set or assigned to the terminal can also be set to an arbitrary value, and the DL / UL CC association associated therewith may be defined in a manner different from the scheme of FIG. is there.

  Also, the DL and UL constituent carriers configured or set in the terminal are a primary constituent carrier (primary CC; PCC) (or primary cell; P-cell) or an anchor constituent carrier (anchor CC) (or anchor cell). Can be set. For example, in order to always set DL PCC (or DL P-cell) for the purpose of transmission of configuration / reconfiguration information on RRC connection setup, or to transmit UCI that an arbitrary terminal should transmit on the uplink The UL CC that transmits the PUCCH of the PC can be set as UL PCC (or UL P-cell). The DL PCC (P-cell) and the UL PCC (P-cell) can be basically identified and set for each terminal. Alternatively, in a case where a large number of CCs are set in a terminal or in a situation where CCs can be set from a plurality of base stations, one or a plurality of DL PCCs from one or more base stations to any terminal (P-cell) and / or UL PCC (P-cell) may be set. For the link between DL PCC (P-cell) and UL PCC (P-cell), it is possible to consider a method in which the base station can arbitrarily configure the terminal. Alternatively, as a simpler method, DL PCC (P-P) is defined based on the basic linkage relationship already defined in LTE Release-8 (Rel-8) and signaled in SIB (System Information Block (or Base)) 2. cell) and UL PCC (P-cell) may be configured. The DL PCC (P-cell) and UL PCC (P-cell) for which the above linkage is set can be collectively expressed as a P-cell for terminal identification.

(SC-FDMA transmission and OFDMA transmission)
FIG. 8 is a diagram for explaining an SC-FDMA transmission scheme and an OFDMA transmission scheme in a mobile communication system. An SC-FDMA transmission scheme can be used for uplink transmission, and an OFDMA transmission scheme can be used for downlink transmission.

  An uplink signal transmission entity (for example, a terminal) and a downlink signal transmission entity (for example, a base station) are a serial-to-parallel converter (801), a subcarrier mapper 803, an M-point IDFT (Inverse). It is the same in that a Discrete Fourier Transform module 804 and a Parallel-to-Serial Converter 805 are provided. The input signal input to the serial-to-parallel converter 801 is data symbols that have been channel coded and modulated. However, the user equipment for transmitting a signal by the SC-FDMA system further includes an N-point DFT (Discrete Fourier Transform) module 802, which cancels the influence of the IDFT processing of the M-point IDFT module 804 to some extent. Can have a single carrier characteristic. That is, the DFT module 802 can satisfy the single carrier property required for uplink transmission by DFT spreading the input data symbols. Such an SC-FDMA transmission scheme basically provides good PAPR (Peak to Average Power Ratio) or CM (Cubic Metric), and is more efficient even when the uplink transmitter is in a power limited situation. It can be transmitted and the user yield can be improved.

FIG. 9 is a diagram for explaining the maximum transmission power in the case of single antenna transmission and multiple antenna transmission. FIG. 9A shows the case of single antenna transmission. One power amplifier (PA) can be provided for one antenna. In FIG. 9A, the output (P _max ) of the power amplifier can have a specific value, for example, a value of 23 dBm. On the other hand, FIGS. 9B and 9C show the case of multiple antenna transmission. 9B and 9C, a plurality of PAs can be mapped to each of a plurality of transmission antennas. For example, when the number of transmission antennas is 2, two PAs are mapped to the transmission antennas. The settings of the output values (that is, the maximum transmission power) of the two PAs may be configured to be different as shown in FIGS. 9B and 9C.

FIG. 9B shows an example in which the maximum transmission power value (P _max ) in the case of single antenna transmission is applied separately for PA1 and PA2. That is, when a transmission power value of x [dBm] is set in PA1, a transmission power value of (P _max -x) [dBm] can be applied to PA2. In this way, since the total transmission power is maintained at Pmax, the transmitter can have a stronger characteristic against an increase in PAPR in a power limited situation.

On the other hand, in FIG. 9C, only one transmission antenna (ANT1) has the maximum transmission power value (P _max ), and the transmission power value of the remaining one transmission antenna (ANT2) is half (P _max / 2). ) Is set as an example. In this case, only one transmission antenna can have a characteristic strong against PAPR increase.

(Multiple antenna system)
Multiple antenna (MIMO) technology is an application of technology that collects and completes data fragments received from multiple antennas without relying on a single antenna path to receive a message. Multi-antenna technology is a next-generation mobile communication technology that can be widely used for mobile communication terminals and repeaters, because it can improve the data transmission rate in a specific range or increase the system range for a specific data transmission rate. It is attracting interest as a next-generation technology that can overcome the limit of mobile communication transmission that has reached its limit due to the expansion of data communication.

FIG. 10A is a configuration diagram of a general multiple antenna (MIMO) communication system. Figure 10 (a), the number of the N _T transmit antennas, increasing the number of receive antennas N _R number simultaneously, when using multiple antennas only at either the transmitter or receiver Unlike this, the channel transmission capacity theoretically increases in proportion to the number of antennas. Therefore, the transmission rate can be improved and the frequency efficiency can be dramatically improved. The transmission rate due to the increase in channel transmission capacity can be increased by multiplying the maximum transmission rate (R ₀ ) theoretically when one antenna is used by the increase rate (R _i ) of the following mathematical formula 1. is there.

例えば、４個の伝送アンテナと４個の受信アンテナを用いるＭＩＭＯ通信システムでは、単一アンテナシステムに比べて理論上４倍の伝送率を獲得することができる。このような多重アンテナシステムの理論的容量増加が９０年代の半ばに証明されて以来、実質的なデータ伝送率の向上につなかせるめめに様々な技術が現在まで活発に研究されており、それらのいくつかの技術は既に３世代移動通信と次世代無線ＬＡＮなどの様々な無線通信の標準に反映されている。

For example, a MIMO communication system using four transmission antennas and four reception antennas can theoretically obtain a transmission rate four times that of a single antenna system. Since the theoretical capacity increase of such a multi-antenna system was proved in the mid-1990s, various technologies have been actively researched to date to lead to a substantial improvement in data transmission rate. Some of these technologies are already reflected in various wireless communication standards such as 3rd generation mobile communication and next generation wireless LAN.

  Looking at trends in multi-antenna related research to date, research on information theory related to multi-antenna communication capacity calculation in various channel environments and multi-connection environments, research on radio channel measurement and model derivation of multi-antenna systems In addition, active research is being conducted from various viewpoints, such as research on spatio-temporal signal processing techniques for improving transmission reliability and transmission rate.

To mathematically model a communication method in a multi-antenna system in order to explain it in a more specific way, it can be shown as follows. As shown in FIG. 10 (a), suppose the N _T transmit and N _R receive antennas are present. First, the transmission signal will be described. When there are _NT transmission antennas, the maximum transmittable information is _{NT, and} therefore the transmission information can be represented by a vector such as Equation 2 below.

一方、それぞれの伝送情報

Meanwhile, each transmission information

において伝送電力を異ならせることができ、この時、それぞれの伝送電力を

In this case, the transmission power can be varied.

とすれば、伝送電力の調整された伝送情報をヘクトルで示すと、下記の数学式３のようになる。

Then, when transmission information whose transmission power is adjusted is indicated by a vector, the following mathematical formula 3 is obtained.

また、

Also,

を伝送電力の対角行列Ｐを用いて表すと、下記の数学式４のようになる。

Is expressed using the diagonal matrix P of the transmission power, the following mathematical formula 4 is obtained.

一方、伝送電力の調整された情報ヘクトル

On the other hand, the transmission power adjusted information vector

に重み行列Ｗが適用されて、実際に伝送されるＮ_Ｔ個の伝送信号（ｔｒａｎｓｍｉｔｔｅｄ ｓｉｇｎａｌ）

Weight matrix W is applied to, it is actually transmitted the _{N T} transmission signal (Transmitted The Signal)

が構成される場合を考慮してみよう。ここで、重み行列は、伝送情報を伝送チャネル状況などに応じて各アンテナに適宜分配する役割を果たす。このような伝送信号

Consider the case where is configured. Here, the weight matrix plays a role of appropriately distributing transmission information to each antenna according to a transmission channel condition or the like. Such transmission signal

はヘクトルＸを用いて下記の数学式５のように表すことができる。ここで、Ｗ_ｉｊは、ｉ番目の伝送アンテナとｊ番目の情報間の重み値を意味する。Ｗは、重み行列（Ｗｅｉｇｈｔ Ｍａｔｒｉｘ）またはプリコーディング行列（Ｐｒｅｃｏｄｉｎｇ Ｍａｔｒｉｘ）と呼ばれる。

Can be expressed as in Equation 5 below using vector X. Here, W _ij means a weight value between the i-th transmission antenna and the j-th information. W is called a weighting matrix (Weight Matrix) or a precoding matrix (Precoding Matrix).

Ｎ_Ｒ個の受信アンテナがある場合に、各アンテナの受信信号

When there are N _R receiving antennas, the received signal of each antenna

をヘクトルで表すと、下記の数学式６のようになる。

Is represented by a vector, as shown in Equation 6 below.

一方、多重アンテナ通信システムにおけるチャネルをモデリングする場合に、チャネルを送受信アンテナインデックスによって区別でき、伝送アンテナｊから受信アンテナｉを経るチャネルをｈ_ｉｊと表示するとする。ここで、ｈ_ｉｊのインデックスの順序は、受信アンテナインデックスが先で、伝送アンテナのインデックスが後であることに留意されたい。

On the other hand, when modeling a channel in a multi-antenna communication system, the channel can be distinguished by a transmission / reception antenna index, and a channel passing from the transmission antenna j to the reception antenna i is denoted as _hij . Here, it should be noted that the index order of h _ij is the reception antenna index first and the transmission antenna index later.

A plurality of such channels can be displayed together in a vector and matrix form. The following is a description of the vector display. FIG. 10B is a diagram illustrating channels from the _NT transmission antennas to the reception antenna i.

As shown in FIG. 10 (b), the channel arriving at the receive antenna i from the total the N _T transmit antennas, can be expressed as follows.

また、上記の数学式７のような行列表現を用いてＮ_Ｔ個の伝送アンテナからＮ_Ｒ個の受信アンテナを経るチャネルを全て表すと、下記の数学式８のようになる。

Also, when representing all channels through the N _R receive antennas from the N _T transmit antennas using a matrix expression as the above Equation 7 is as Equation 8 below.

実のチャネルは上のようなチャネル行列Ｈを経た後に白色雑音（ＡＷＧＮ；Ａｄｄｉｔｉｖｅ Ｗｈｉｔｅ Ｇａｕｓｓｉａｎ Ｎｏｉｓｅ）が加えられるので、Ｎ_Ｒ個の受信アンテナのそれぞれに加えられる白色雑音

Since the actual channel is subjected to the white noise (AWGN) after passing through the channel matrix H as described above, the white noise added to each of the _NR receiving antennas.

をヘクトルで表現すると、下記の数学式９のようになる。

Is expressed as a vector, as shown in Equation 9 below.

これらの数学式を用いて求めた受信信号は、下記の数学式１０の通りである。

The received signal obtained using these mathematical formulas is as shown in the following mathematical formula 10.

一方、チャネル状況を表すチャネル行列Ｈの行と列の数は、伝送アンテナと受信アンテナの個数によって決定される。チャネル行列Ｈにおいて、行の数は受信アンテナの個数（Ｎ_Ｒ）と同一であり、列の数は伝送アンテナの個数（Ｎ_Ｔ）と同一である。すなわち、チャネル行列Ｈは、Ｎ_Ｒ×Ｎ_Ｔ行列で表示することができる。一般に、行列のランクは、互いに独立した行の数と列の数のうち、より小さい数によって定義される。そのため、行列のランクは、行列の行の数や列の数よりも大きい値を有することができない。チャネル行列Ｈのランクは、下記の数学式１１で表現することができる。

On the other hand, the number of rows and columns of the channel matrix H representing the channel status is determined by the number of transmission antennas and reception antennas. In the channel matrix H, the number of rows is the same as the number of receiving antennas (N _R ), and the number of columns is the same as the number of transmitting antennas (N _T ). That is, the channel matrix H can be displayed as an N _R × _NT matrix. In general, the rank of a matrix is defined by the smaller of the number of independent rows and the number of columns. Therefore, the rank of the matrix cannot have a value larger than the number of rows or columns of the matrix. The rank of the channel matrix H can be expressed by the following mathematical formula 11.

多重アンテナシステムの運営（ｏｐｅｒａｔｉｏｎ）のために用いられる多重アンテナ送受信手法（ｓｃｈｅｍｅ）は、ＦＳＴＤ（ｆｒｅｑｕｅｎｃｙ ｓｗｉｔｃｈｅｄ ｔｒａｎｓｍｉｔ ｄｉｖｅｒｓｉｔｙ）、ＳＦＢＣ（Ｓｐａｃｅ Ｆｒｅｑｕｅｎｃｙ Ｂｌｏｃｋ Ｃｏｄｅ）、ＳＴＢＣ（Ｓｐａｃｅ Ｔｉｍｅ Ｂｌｏｃｋ Ｃｏｄｅ）、ＣＤＤ（Ｃｙｃｌｉｃ Ｄｅｌａｙ Ｄｉｖｅｒｓｉｔｙ）、ＴＳＴＤ（ｔｉｍｅ ｓｗｉｔｃｈｅｄ ｔｒａｎｓｍｉｔ ｄｉｖｅｒｓｉｔｙ）などにすることができる。ランク２以上では、空間多重化（Ｓｐａｔｉａｌ Ｍｕｌｔｉｐｌｅｘｉｎｇ；ＳＭ）、ＧＣＤＤ（Ｇｅｎｅｒａｌｉｚｅｄ Ｃｙｃｌｉｃ Ｄｅｌａｙ Ｄｉｖｅｒｓｉｔｙ）、Ｓ−ＶＡＰ（Ｓｅｌｅｃｔｉｖｅ Ｖｉｒｔｕａｌ Ａｎｔｅｎｎａ Ｐｅｒｍｕｔａｔｉｏｎ）などを用いることができる。

The multi-antenna transmission / reception technique (scheme) used for the operation of the multi-antenna system is FSTD (frequency switched transversity diversity), SFBC (Space Frequency Block Code), STBC (Space CD C). Diversity), TSTD (time switched transmission diversity), and the like. For rank 2 or higher, spatial multiplexing (SM), GCDD (Generalized Cyclic Delay Diversity), S-VAP (Selective Virtual Antenna Permutation), or the like can be used.

  FSTD is a scheme for obtaining diversity gain by assigning subcarriers of different frequencies for each signal transmitted to each multiple antenna. SFBC is a technique that can secure both diversity gain and multi-user scheduling gain in a corresponding dimension by efficiently applying selectivity in a spatial domain and a frequency domain. STBC is a technique for applying selectivity in the space domain and the time domain. CDD is a technique for obtaining a diversity gain by using a path delay between transmitting antennas. TSTD is a technique for distinguishing signals transmitted by multiple antennas according to time. Spatial multiplexing is a technique for increasing the transmission rate by transmitting different data for each antenna. GCDD is a technique that applies selectivity in the time domain and frequency domain. S-VAP is a technique that uses a single precoding matrix, and MCW (Multi Codeword) S-VAP that mixes multiple codewords between antennas in spatial diversity or spatial multiplexing and SCW (Single) that uses a single codeword. Codeword) S-VAP.

  Among these MIMO transmission methods, the STBC method is a method of acquiring time diversity by repeating the same data symbol in a method supporting orthogonality in the time domain. Similarly, the SFBC method is a method of acquiring frequency diversity by repeating the same data symbol in a method supporting orthogonality in the frequency domain. Examples of time block codes used for STBC and frequency block codes used for SFBC are as shown in Equations 12 and 13 below. Equation 12 represents a block code in the case of two transmission antennas, and Equation 13 represents a block code in the case of four transmission antennas.

数学式１２及び１３で、Ｓ_ｉ（ｉ＝１，２，３，４）は、変調されたデータシンボルを表す。また、数学式１２及び１３の行列において、行（ｒｏｗ）はアンテナポートを表し、列（ｃｏｌｕｍｎ）は時間（ＳＴＢＣの場合）または周波数（ＳＦＢＣの場合）を表す。

In equations 12 and 13, S _i (i = 1, 2, 3, 4) represents a modulated data symbol. In the matrixes of mathematical expressions 12 and 13, row represents an antenna port, and column represents time (in the case of STBC) or frequency (in the case of SFBC).

  On the other hand, among the above-mentioned MIMO transmission methods, the CDD method is a method of increasing frequency diversity by artificially increasing delay spread. FIG. 11 shows an example of a typical CDD structure in a multiple antenna system. FIG. 11A shows a scheme for applying a cyclic delay in the time domain. The CDD method applying the cyclic delay in FIG. 11A can also apply phase-shift diversity as shown in FIG.

  On the other hand, a codebook based precoding method will be described in relation to the MIMO transmission method described above. FIG. 12 is a diagram for explaining the basic concept of codebook-based precoding.

  According to the codebook-based precoding scheme, the transmitting and receiving ends share codebook information including a predetermined number of precoding matrices determined in advance by the transmission rank, the number of antennas, and the like. That is, when the feedback information is finite, a precoding-based codebook method can be used. The receiving end measures the channel state through the received signal and feeds back a finite number of preferred precoding matrix information (that is, the index of the corresponding precoding matrix) to the transmitting end based on the above-described codebook information. For example, the receiving end can measure a received signal by an ML (Maximum Likelihood) or MMSE (Minimum Mean Square Error) method and select an optimal precoding matrix. Although FIG. 12 shows an example in which the receiving end transmits precoding matrix information to the transmitting end for each codeword, the present invention is not limited to this.

  The transmitting end that has received the feedback information from the receiving end can select a specific precoding matrix from the codebook based on the received information. The transmitting end that has selected the precoding matrix performs precoding by multiplying the number of layer signals corresponding to the transmission rank by the selected precoding matrix, and transmits the precoded transmission signals from multiple antennas. can do.

A receiving end that has received a signal that has been precoded and transmitted at the transmitting end can restore the received signal by performing reverse processing of precoding performed at the transmitting end. In general, since the precoding matrix satisfies the unitary matrix (U) condition such as U * U ^H = I, the precoding inverse process described above is performed by using the precoding matrix (P) used for precoding at the transmission end. The Hermit matrix (P ^H ) can be multiplied by the received signal.

(Physical uplink control channel (PUCCH))
A physical uplink control channel (PUCCH) including uplink control information will be described.

  Control information of a plurality of terminals can be transmitted through the PUCCH, and CAZAC (Constant Amplitude Zero Autocorrelation) having a length of 12 is used when code division multiplexing (CDM) is performed to distinguish the signals of each terminal. ) Sequence is mainly used. Since the CAZAC sequence has a characteristic of maintaining a constant magnitude in the time domain and the frequency domain, the PAPR (Peak-to-Average Power Ratio) or CM (CubiC Metric) of the terminal is lowered to increase the coverage. It has properties suitable for In addition, ACK / NACK information for downlink data transmission transmitted through the PUCCH is covered using an orthogonal sequence.

  Also, control information transmitted on the PUCCH can be distinguished using cyclically shifted sequences having different cyclic shift values (cyclically shifted sequences). The cyclically shifted sequence can be generated by cyclically shifting the basic sequence (base sequence) by a specific CS amount (cyclic shift amount). The specific CS amount is indicated by a cyclic shift index (CS index). The number of available cyclic shifts may differ depending on the delay spread of the channel. Various sequences can be used for the basic sequence, an example of which is the aforementioned CAZAC sequence.

  The PUCCH may include control information such as a scheduling request (SR), downlink channel measurement information, and ACK / NACK information for downlink data transmission. The channel measurement information may include a channel quality indicator (CQI), a precoding matrix index (PMI), and a rank indicator (RI).

  The PUCCH format is defined by the type of control information included in the PUCCH, the modulation scheme, and the like. That is, PUCCH format 1 is used for transmission of SR, PUCCH format 1a or format 1b is used for transmission of HARQ ACK / NACK, PUCCH format 2 is used for transmission of CQI, PUCCH format 2a / 2b is used for CQI and Used for transmission of HARQ ACK / NACK.

  When HARQ ACK / NACK is transmitted independently in an arbitrary subframe, PUCCH format 1a or format 1b is used. When SR is transmitted independently, PUCCH format 1 is used. The terminal can also transmit HARQ ACK / NACK and SR in the same subframe, which will be described later.

  The PUCCH format can be summarized as shown in Table 1.

図１３は、アップリンク物理リソースブロックでＰＵＣＣＨのリソースマッピング構造を示す。

は、アップリンクでのリソースブロックの個数を表し、ｎ_ＰＲＢは、物理リソースブロック番号を意味する。ＰＵＣＣＨは、アップリンク周波数ブロックの両端（ｅｄｇｅ）にマッピングされる。ＣＱＩリソースは、周波数帯域末端に続く物理リソースブロックにマッピングし、これに続いてＡＣＫ／ＮＡＣＫをマッピングできる。

FIG. 13 shows a PUCCH resource mapping structure in an uplink physical resource block.

_Represents the number of resource blocks in the uplink, and n _PRB represents a physical resource block number. The PUCCH is mapped to both ends (edges) of the uplink frequency block. The CQI resource can be mapped to a physical resource block that follows the end of the frequency band, followed by ACK / NACK.

  PUCCH format 1 is a control channel used for SR transmission. The scheduling request (SR) can be transmitted in a manner in which the terminal requests or does not request scheduling.

  PUCCH format 1a / 1b is a control channel used for ACK / NACK transmission. A symbol modulated using the BPSK or QPSK modulation scheme in the PUCCH format 1a / 1b is multiplied by a CAZAC sequence having a length of 12 (multiple). After the CAZAC sequence multiplication, it is spread in the block direction (block-wise) as an orthogonal sequence. For general ACK / NACK information, a Hadamard sequence having a length of 4 is used. For short ACK / NACK information and a reference signal (Reference Signal), a length 3 DFT (Discrete Fourier) is used. Transform) sequence can be used. For the reference signal in the extended CP case, a Hadamard sequence of length 2 can be used.

  The terminal can also transmit HARQ ACK / NACK and SR in the same subframe. For positive SR transmission, the UE may transmit HARQ ACK / NACK through resources allocated for SR. For negative SR transmission, the UE can transmit HARQ ACK / NACK through resources allocated for ACK / NACK.

  Next, PUCCH format 2 / 2a / 2b will be described. PUCCH format 2 / 2a / 2b is a control channel for transmitting channel measurement feedback (CQI, PMI, RI).

  The PUCCH format 2 / 2a / 2b supports modulation by a CAZAC sequence and can multiply a CAZAC sequence of length 12 by a QPSK modulated symbol. The cyclic shift of the sequence can be changed between symbols and slots. Orthogonal covering can be used for the reference signal (RS).

  FIG. 14 is a diagram illustrating a channel structure of CQI information bits. The CQI information bit may include one or more fields. For example, the CQI information bits may include a CQI field indicating a CQI index for determining an MCS, a PMI field indicating an index of a precoding matrix on a codebook, an RI field indicating a rank, and the like.

  Referring to FIG. 14 (a), of the seven SC-FDMA symbols included in one slot, two SC-FDMA symbols separated by three SC-FDMA symbol intervals are used as reference signals (RS). CQI information can be carried on the remaining five SC-FDMA symbols. The reason why two RSs are used in one slot is to support high-speed terminals. Moreover, each terminal can be distinguished using a sequence. The CQI information symbol is modulated and transmitted over the entire SC-FDMA symbol, and the SC-FDMA symbol is composed of one sequence. That is, the terminal can modulate and transmit CQI for each sequence.

  The number of symbols that can be transmitted in 1 TTI is 10, and the modulation of CQI information is defined up to QPSK. When QPSK mapping is used for an SC-FDMA symbol, a 2-bit CQI value can be placed, so a 10-bit CQI value can be placed in one slot. Therefore, a CQI value of a maximum of 20 bits can be placed in one subframe. A frequency domain spreading code can be used to spread CQI information in the frequency domain.

  A CAZAC sequence (for example, a ZC sequence) can be used for the frequency domain spreading code. Also, other sequences having excellent correlation characteristics can be applied to the frequency domain spreading code. In particular, each control channel can be distinguished by applying a CAZAC sequence having a different cyclic shift value. IFFT is performed on the frequency-domain spread CQI information.

  FIG. 14B shows an example of PUCCH format 2 / 2a / 2b transmission in the case of an extended CP. One slot contains 6 SC-FDMA symbols. Of the 6 OFDM symbols in each slot, 1 OFDM symbol can carry RS, and the remaining 5 OFDM symbols can carry CQI information bits. Other than this, the example of the general CP in FIG. 14A can be applied as it is.

  Table 2 shows the orthogonal covering used for the RSs in FIGS. 14 (a) and 14 (b).

図１５を参照してＣＱＩ情報とＡＣＫ／ＮＡＣＫ情報の同時伝送について説明する。

The simultaneous transmission of CQI information and ACK / NACK information will be described with reference to FIG.

  In the case of a general CP, CQI information and ACK / NACK information can be transmitted simultaneously using PUCCH format 2a / 2b. ACK / NACK information can be transmitted through a symbol in which CQI RS is transmitted. That is, in the case of a general CP, the second RS can be modulated into an ACK / NACK symbol. When the ACK / NACK symbol is modulated by the BPSK method as in the PUCCH format 1a, the CQI RS is modulated into the ACK / NACK symbol by the BPSK method, and the ACK / NACK symbol is modulated by the QPSK method as in the PUCCH format 1b. In this case, the CQI RS can be modulated to an ACK / NACK symbol by a QPSK scheme. On the other hand, in the case of an extended CP, CQI information and ACK / NACK information can be transmitted simultaneously using PUCCH format 2, and therefore, CQI information and ACK / NACK information can be jointly coded. .

  In addition to the above-mentioned matters, a description on the PUCCH may be made by referring to a 3GPP standard document (for example, 3GPP TS 36.2115.4), and a specific content thereof is omitted for clarity of description. However, the contents disclosed in the standard document regarding the PUCCH can be applied to the PUCCH used in various embodiments of the present invention described below.

(Channel state information feedback)
In order to perform the MIMO technique accurately, the receiving end may feed back a rank indicator (RI), a precoding matrix index (PMI), and a channel quality indicator (CQI) to the transmitting end. These RI, PMI, and CQI can be collectively referred to as channel status information (CSI). Alternatively, the term CQI can be used as a concept of channel information including RI, PMI, and CQI.

  FIG. 16 is a diagram for explaining feedback of channel state information.

Referring to FIG. 16, a MIMO transmission from a transmitter can be received by a receiver through channel (H). The receiver can select a preferred precoding matrix from the codebook based on the received signal and feed back the selected precoding matrix index (PMI) to the transmitter. In addition, the receiver measures the signal-to-interference plus noise ratio (SINR) of the received signal, calculates channel quality information (CQI), and feeds it back to the transmitter. can do. The receiver can also feed back a rank indicator (RI) for the received signal to the transmitter. The transmitter uses the RI and CQI information fed back from the receiver to determine the appropriate number of layers, time / frequency resources, and modulation and coding scheme (MCS) for data transmission to the receiver. ) Etc. can be defined. Also, the transmitter can transmit the transmission signal that has been precoded using the precoding matrix (W _l ) indicated by the PMI fed back from the receiver through a plurality of antennas.

  Below, the specific content of channel state information is demonstrated.

  The RI is information related to the channel rank (the number of layers used for transmission from the transmitter). The RI can be determined from the number of assigned transmission layers and obtained from the associated downlink control information (DCI).

  PMI is information related to a precoding matrix used for transmission from a transmitter. The precoding matrix fed back from the receiver is determined in consideration of the number of layers indicated by the RI. The PMI can be fed back in case of closed-loop spatial multiplexing (SM) and long delay CDD (long delay CDD) transmission. For open-loop transmission, the transmitter can select a precoding matrix according to a predetermined rule. The process in which the receiver selects the PMI for each rank (ranks 1 to 4) is as follows. The receiver calculates a post processing SINR for each PMI, converts the calculated SINR into a sum capacity, and selects the best PMI based on the total capacity. be able to. That is, it can be said that the receiver calculates the PMI is a process of searching for the optimum PMI based on the total capacity. The transmitter to which PMI is fed back from the receiver can use the precoding matrix recommended by the receiver as it is, and include this fact as a 1-bit indicator in the data transmission scheduling assignment information to the receiver. Can do. Alternatively, the transmitter may not use the precoding matrix indicated by the PMI fed back from the receiver as it is. In such a case, the precoding matrix information used by the transmitter for data transmission to the receiver can be explicitly included in the scheduling assignment information. For specific matters regarding PMI, a 3GPP standard document (for example, 3GPPTS 36.211) may be referred to.

  CQI is information indicating channel quality. The CQI can be expressed by a predetermined MCS combination. The CQI index can be given as shown in Table 3 below.

上記の表３で示すように、ＣＱＩインデックスは４ビット（すなわち、ＣＱＩインデックス０乃至１５）で表現され、それぞれのＣＱＩインデックスは、該当する変調手法（ｍｏｄｕｌａｔｉｏｎ ｓｃｈｅｍｅ）及びコードレート（ｃｏｄｅ ｒａｔｅ）を示す。

As shown in Table 3 above, the CQI index is expressed by 4 bits (that is, CQI indexes 0 to 15), and each CQI index indicates a corresponding modulation scheme and code rate. .

  A CQI calculation method will be described. A 3GPP standard document (eg, 3GPP TS36.213) defines that the terminal considers the following assumptions when calculating the CQI index.

(1) The first three OFDM symbols of one subframe are occupied by control signaling. (2) Resources used by a primary synchronization signal, a secondary synchronization signal, or a physical broadcast channel (PBCH). No elements (3) CP length of non-MBSFN subframe (4) Redundancy version is 0 (5) PDSCH transmission method is a transmission mode currently set for a terminal (may be default mode) . according to) (6) PDSCH EPRE (Energy Per Resource Element) versus cell - the ratio of the specific reference signal EPRE (ratio) are as given with the exception of [rho _a [rho _A may follow on the following assumptions terminal, for any modulation scheme, four cells -. or is set to the transmission mode 2 of a particular antenna port configurations, or four cells - specific When the antenna mode is set and the transmission mode 3 in which the related RI is 1 is set, ρ _A = P _A + Δ _offset +10 log ₁₀ (2) [dB]. against modulation techniques and any layer _{number, ρ a = P a + Δ} offset [dB] at a .Deruta _offset is given by nomPDSCH-RS-EPRE-offset parameters set by higher layer signaling.)
Defining such an assumption means that the CQI includes not only information on the channel quality but also various information on the terminal. That is, different CQI indexes may be fed back depending on the performance of the terminal even with the same channel quality, so a certain standard is defined.

  The terminal receives the downlink reference signal (RS) from the base station, and can grasp the channel state through the received reference signal. Here, the reference signal may be a common reference signal (CRS) defined in an existing 3GPP LTE system, and a channel state defined in a system having an extended antenna configuration (for example, a 3GPP LTE-A system). It may be an information-reference signal (Channel Status Reference Signal; CSI-RS). The terminal can calculate a CQI index with a block error rate (BLER) not exceeding 10% while satisfying the assumption given for the CQI calculation on the channel obtained from the reference signal. The terminal can transmit the calculated CQI index to the base station. The terminal does not apply a method for improving interference estimation when calculating the CQI index.

  The process in which the terminal grasps the channel state and obtains an appropriate MCS can be designed in various ways in terms of terminal implementation. For example, the UE can calculate a channel state or an effective SINR (Signal-to-Interference plus Noise Ratio) using the reference signal. Also, channel conditions or effective SINR can be measured on the overall system bandwidth (which can be referred to as set S), or can be measured on a partial bandwidth (specific subband or specific RB). The CQI for the entire system bandwidth (set S) can be a wideband (WB) CQI, and the CQI for a partial band can be a subband (SB) CQI. The terminal can determine the highest MCS based on the calculated channel condition or effective SINR. The highest MCS means an MCS in which a transmission block error rate does not exceed 10% at the time of decoding and satisfies an assumption for CQI calculation. The terminal may determine a CQI index associated with the determined MCS and report the determined CQI index to the base station.

Moreover, the case where a terminal transmits only CQI (CQI-only transmission) can be considered. This corresponds to a case where the CQI is transmitted aperiodically without data on the PUSCH. Aperiodic CQI transmission can be performed in an event-triggered manner in response to a request from a base station. The request from the base station may be a CQI request (CQI request) defined by 1 bit on the downlink control information (DCI) format 0. Also, for transmission of only CQI, the MCS index (I _MCS ) 29 can be signaled in Table 4 below. In this case, the DCI format 0 CQI request bit is set to 1, transmission of 4 RBs or less is set, redundancy version 1 (RV1) in PUSCH data retransmission is indicated, and the modulation order Q _m is 2 Can be set. That is, when only CQI is transmitted, only QPSK can be used as a modulation method.

以下では、チャネル品質情報の報告動作について具体的に説明する。

Hereinafter, the report operation of the channel quality information will be specifically described.

  In the 3GPP LTE system, when a downlink receiving entity (for example, a terminal) is connected to a downlink transmitting entity (for example, a base station), the reception strength (RSRP: reference signal received power) of a reference signal transmitted on the downlink. ), Reference signal quality (RSRQ: reference signal received quality), etc. can be measured at an arbitrary time, and the measurement result can be reported to the base station periodically or event-triggered.

  In the cellular OFDM wireless packet communication system, each terminal reports downlink channel information according to the downlink channel status through the uplink, and the base station uses the downlink channel information received from each terminal, for each terminal. Time / frequency resources and modulation and coding scheme (MCS) suitable for data transmission can be determined.

  In the existing 3GPP LTE system (for example, 3GPP LTE Release-8 system), such channel information can be composed of CQI (Channel Quality Indicator), PMI (Precoding Matrix Indicator) and RI (Rank Indication). Depending on the transmission mode of the terminal, all of CQI, PMI and RI may be transmitted, or only part of them may be transmitted. The CQI is determined by the received signal quality of the terminal, which is mainly determined based on the measurement of the downlink reference signal. At this time, the CQI value actually transmitted to the base station corresponds to the MCS that exhibits the maximum performance while maintaining the block error rate (BLER) at 10% or less in the received signal quality measured by the terminal. .

  Also, the channel information reporting method is divided into a periodic report transmitted periodically and an aperiodic report transmitted in response to a request from the base station.

  The aperiodic report is set in each terminal by a 1-bit request bit (CQI request bit) included in the uplink scheduling information transmitted from the base station to the terminal. Can be transmitted to the base station through a physical uplink shared channel (PUSCH). It can be set so that RI and CQI / PMI are not transmitted on the same PUSCH.

  In the periodic report, a cycle in which channel information is transmitted through an upper layer signal and an offset in the corresponding cycle are signaled to each terminal in subframe units, and transmission of each terminal is performed at a predetermined cycle. The channel information considering the mode is transmitted to the base station through the physical uplink control channel (PUCCH). When data transmitted in the uplink is simultaneously present in subframes in which channel information is transmitted at a predetermined period, the channel information is physically transmitted together with the data instead of the physical uplink control channel (PUCCH). It can be transmitted through an uplink shared channel (PUSCH). Periodic reporting over PUCCH may use limited bits compared to PUSCH. RI and CQI / PMI can be transmitted on the same PUSCH.

  If the periodic report and the aperiodic report collide with each other in the same subframe, only the aperiodic report can be performed.

  In calculating the WB CQI / PMI, the most recently transmitted RI can be used. The RI in the PUCCH reporting mode is independent of the RI in the PUSCH reporting mode, and the RI in the PUSCH reporting mode is valid only for CQI / PMI in the PUSCH reporting mode ( valid).

  CQI / PMI / RI feedback types for the PUCCH reporting mode can be classified into four types. Type 1 is CQI feedback for the subband selected by the terminal. Type 2 is WB CQI feedback and WB PMI feedback. Type 3 is RI feedback. Type 4 is WB CQI feedback.

  Referring to Table 5, in periodic reporting of channel information, four reporting modes (reporting modes) of modes 1-0, 1-1, 2-0, and 2-1, depending on CQI and PMI feedback types. ).

ＣＱＩフィードバックタイプによって、ＷＢ（ｗｉｄｅｂａｎｄ）ＣＱＩとＳＢ（ｓｕｂｂａｎｄ）ＣＱＩとに分けられ、ＰＭＩ伝送の有無によって、Ｎｏ ＰＭＩと単一（ｓｉｎｇｌｅ）ＰＭＩとに分けられる。表５では、Ｎｏ ＰＭＩが開−ループ（Ｏｐｅｎ−ｌｏｏｐ；ＯＬ）、伝送ダイバーシティ（Ｔｒａｎｓｍｉｔ Ｄｉｖｅｒｓｉｔｙ；ＴＤ）及び単一−アンテナ（ｓｉｎｇｌｅ−ａｎｔｅｎｎａ）の場合に該当し、単一ＰＭＩは閉−ループ（ｃｌｏｓｅｄ−ｌｏｏｐ；ＣＬ）に該当することを表す。

It is divided into WB (wideband) CQI and SB (subband) CQI according to the CQI feedback type, and is divided into No PMI and single PMI according to the presence / absence of PMI transmission. In Table 5, No PMI corresponds to open-loop (OL), transmit diversity (TD), and single-antenna, and single PMI is closed-loop ( closed-loop (CL).

  Mode 1-0 is a case where WB CQI is transmitted without PMI transmission. In this case, the RI is transmitted only in the case of open-loop (OL) spatial multiplexing (SM), and one WB CQI represented by 4 bits can be transmitted. If RI exceeds 1, the CQI for the first codeword can be transmitted. In mode 1-0, the above-mentioned feedback type 3 and feedback type 4 can be multiplexed and transmitted at different timings within a set reporting period (channel information of a time division multiplexing (TDM) system). Transmission).

  Mode 1-1 is a case where a single PMI and WB CQI are transmitted. In this case, 4-bit WB CQI and 4-bit WB PMI can be transmitted together with the RI transmission. Further, when RI exceeds 1, a 3-bit WB spatial differential CQI (Wideband Spatial Differential CQI) can be transmitted. In 2-codeword transmission, the WB spatial difference CQI can represent the difference between the WB CQI index for codeword 1 and the WB CQI index for codeword 2. These difference values have any one value of the set {-4, -3, -2, -1, 0, 1, 2, 3} and can be expressed by 3 bits. In mode 1-1, the above-described feedback type 2 and feedback type 3 can be multiplexed and transmitted at different timings within a set reporting period.

  Mode 2-0 is a case where there is no PMI transmission and CQI of a band selected by the terminal (UE selected) is transmitted. In this case, RI can be transmitted only in the case of open-loop spatial multiplexing (OL SM), and WB CQI expressed by 4 bits can be transmitted. Also, the optimal (Best-1) CQI is transmitted in each bandwidth part (Bandwidth Part; BP), and the Best-1 CQI can be expressed by 4 bits. Also, an L-bit indicator that indicates Best-1 can be transmitted together. If RI exceeds 1, the CQI for the first codeword can be transmitted. In mode 2-0, the above-described feedback type 1, feedback type 3, and feedback type 4 can be multiplexed and transmitted at different timings within the set reporting period.

  Mode 2-1 is a case where a single PMI and a CQI of a band selected by the terminal (UE selected) are transmitted. In this case, 4-bit WB CQI, 3-bit WB spatial difference CQI, and 4-bit WB PMI can be transmitted together with the RI transmission. Furthermore, a 4-bit Best-1 CQI can be transmitted in each bandwidth part (BP), and an L-bit Best-1 indicator can be transmitted together. Furthermore, when RI exceeds 1, 3-bit Best-1 spatial difference CQI can be transmitted. This can represent a difference value between the Best-1 CQI index of codeword 1 and the Best-1 CQI index of codeword 2 in 2-codeword transmission. In mode 2-1, the above-mentioned feedback type 1, feedback type 2, and feedback type 3 can be multiplexed and transmitted at different timings within the set reporting period.

  In the SB CQI reporting mode selected by the UE (UE selected), the subband size of the bandwidth part (BP) can be defined as shown in Table 6.

上記の表６では、システム帯域幅のサイズによる帯域幅部分（ＢＰ）の設定、及びそれぞれのＢＰ内のサブバンドのサイズを表す。端末は、それぞれのＢＰから好む（ｐｒｅｆｅｒｒｅｄ）サブバンドを選択し、当該サブバンドに対するＣＱＩを計算することができる。表６で、システム帯域幅のサイズが６または７の場合は、サブバンドサイズ及び帯域幅部分（ＢＰ）個数の適用がないと示されており、これは、ＷＢ ＣＱＩのみを適用でき、サブバンドは存在しなく、ＢＰは１であることを意味できる。

In Table 6 above, the setting of the bandwidth portion (BP) according to the size of the system bandwidth and the size of the subband in each BP are shown. The UE can select a preferred subband from each BP and calculate a CQI for the subband. Table 6 shows that when the system bandwidth size is 6 or 7, there is no application of the subband size and the number of bandwidth parts (BP), which can apply only WB CQI, Can be implied and BP is 1.

  FIG. 17 is a diagram for explaining a CQI report mode selected by a terminal (UE selected).

は、全体帯域幅のＲＢの個数を表す。全体帯域幅を、Ｎ（１，２，３，…，Ｎ）個のＣＱＩサブバンドに分けることができる。１ ＣＱＩサブバンドは、表６で定義するｋ個のＲＢを含むことができる。全体帯域幅のＲＢ個数がｋの整数倍でない場合に、最後（Ｎ番目）のＣＱＩサブバンドを構成するＲＢの個数を、数学式１４により決定することができる。

Represents the number of RBs of the entire bandwidth. The total bandwidth can be divided into N (1, 2, 3,..., N) CQI subbands. One CQI subband may include k RBs as defined in Table 6. When the number of RBs of the total bandwidth is not an integer multiple of k, the number of RBs constituting the last (Nth) CQI subband can be determined by Equation 14.

数学式１４で、

In Equation 14,

は、床（ｆｌｏｏｒ）演算を表し、

Represents the floor operation,

またはｆｌｏｏｒ（ｘ）は、ｘを超えない最大の整数を意味する。

Or floor (x) means the largest integer not exceeding x.

Also, the N of _J CQI subbands, constitute one bandwidth portion (BP), the entire bandwidth can be divided into J BP. The UE can calculate a CQI index for the best (Best-1) CQI subband of the BP and transmit the CQI index through the PUCCH. At this time, the Best-1 indicator indicating the Best-1 CQI subband selected from one BP can be transmitted together. The Best-1 indicator can be composed of L bits, where L is as in Equation 15.

数学式１５で、

In mathematical formula 15,

は天井（ｃｅｉｌｉｎｇ）演算を表し、

Represents the ceiling operation,

またはｃｅｉｌｉｎｇ（ｘ）は、ｘより小さくない最小の整数を意味する。

Or ceiling (x) means the smallest integer not smaller than x.

  In the above-described manner, the frequency band in which the CQI index is calculated in the CQI reporting mode selected by the UE (UE selected) can be determined. Hereinafter, the CQI transmission cycle will be described.

  Each terminal can receive information composed of a combination of a transmission cycle of channel information and an offset through RRC signaling in the upper layer. The terminal can transmit the channel information to the base station based on the received information on the channel information transmission period.

FIG. 18 shows an example of a scheme in which a terminal periodically transmits channel information. For example, when the terminal receives the information of the combination in which the transmission cycle of the channel information is “5” and the offset is “1”, the terminal transmits the channel information in units of five subframes. Channel information can be transmitted through the PUCCH with a 1 subframe offset in a direction in which the subframe index increases with the 0th subframe as a reference. At this time, the index of the sub-frame, 20-slot index (n _s, 0 to 19) with the system frame system frame number (n _f) can be configured in combination with. Since one subframe is composed of two slots, the subframe index can be expressed as 10 × n _f + floor (n _s / 2).

  Depending on the CQI feedback type, there are a type that transmits only WB CQI and a type that transmits both WB CQI and SB CQI. In the case of a type that transmits only WB CQI, WB CQI information for the entire band is transmitted in a subframe corresponding to each CQI transmission period. The transmission period of WB periodic CQI feedback can be set to {2, 5, 10, 16, 20, 32, 40, 64, 80, 160} ms or no transmission. At this time, if the PMI must be transmitted according to the PMI feedback type in Table 5, the PMI information is transmitted together with the CQI information. In the type in which both WB CQI and SB CQI are transmitted, WB CQI and SB CQI can be transmitted alternately.

  FIG. 19 is a diagram illustrating an example of a scheme for transmitting both WB CQI and SB CQI. In FIG. 19, for example, a system composed of 16 resource blocks (RBs) is shown. When the frequency band of the system has 16 RBs, for example, it can be composed of two bandwidth parts (BP) (BP0 and BP1), and each BP can be composed of two subbands (SB) (SB0 and SB1). ), Each SB is composed of four RBs. At this time, as described in connection with Table 6, the number of BPs and the size of each SB are determined depending on how many RBs the entire system band is configured. , It is possible to determine how many SB each BP is composed of.

  In the type in which both WB CQI and SB CQI are transmitted, after transmitting WB CQI to the CQI transmission subframe, in the next transmission subframe, SB0 and SB1 in BP0 having the good channel state (that is, Best -1) and the index of the SB (that is, the Best-1 indicator) are transmitted, and in the next transmission subframe, SB0 and SB1 in BP1 having a good channel state (that is, Best- The CQI for 1) and the index of the SB (that is, the Best-1 indicator) are transmitted. After transmitting the WB CQI in this way, the CQI information for each BP is sequentially transmitted. At this time, between the WB CQI transmitted once and the WB CQI transmitted next, the BP CQI is transmitted. The CQI information can be sequentially transmitted up to 1 to 4 times. For example, when CQI information for BP is transmitted once during 2 WB CQI, it can be transmitted in the order of WB CQI → BP0 CQI → BP1 CQI → WB CQI. As another example, when CQI information for BP is transmitted four times during 2 WB CQI, WB CQI → BP0 CQI → BP1 CQI → BP0 CQI → BP1 CQI → BP0 CQI → BP1 CQI → BP0 CQI → BP1 CQI → WB CQI can be transmitted in this order. 2 Information regarding how many times the CQI for the BP is sequentially transmitted during the WB CQI is signaled in the upper layer, and the channel information signaled in the upper layer illustrated in FIG. 18 regardless of the WB CQI or the SB CQI. It can be transmitted through PUCCH in a subframe corresponding to information of a combination of a transmission period and an offset.

  At this time, when the PMI also needs to be transmitted according to the PMI feedback type, the PMI information is transmitted together with the CQI information. However, if the PUSCH for uplink data transmission exists in the corresponding subframe, the PMI information is not transmitted. CQI and PMI can be transmitted along with data through PUSCH.

  FIG. 20 is a diagram illustrating an example of a CQI transmission scheme when both WB CQI and SB CQI are transmitted. In FIG. 20, the information of the combination of the channel information transmission period “5” and the offset “1” as shown in FIG. 18 is signaled, and information about BP is transmitted once during 2 WB CQI / PMI. An example of the channel information transmission operation of the terminal in the case of sequential transmission will be shown.

  On the other hand, in the RI transmission, it is possible to signal the RI by a combination of how many times the WB CQI / PMI transmission period is transmitted and an offset in the transmission period. The offset at this time is defined as a relative offset with respect to the CQI / PMI transmission offset. For example, if the CQI / PMI transmission cycle offset is “1” and the RI transmission cycle offset is “0”, the RI transmission cycle offset is the same as the CQI / PMI transmission cycle offset. means. The offset of the RI transmission period can be defined by 0 and a negative value.

  FIG. 21 exemplifies a case where the CQI / PMI transmission is set as shown in FIG. 20, the RI transmission cycle is one time the WB CQI / PMI transmission cycle, and the RI transmission cycle offset is “−1”. Indicate. Since the RI transmission period is one time the WB CQI / PMI transmission period, the RI transmission period has the same period, and the RI offset value “−1” is relatively “relative to the CQI offset“ 1 ”in FIG. Since it means having a “−1” value, the RI can be transmitted with reference to subframe index number 0.

  In addition, when RI transmission and WB CQI / PMI or SB CQI / PMI transmission overlap, WB CQI / PMI or SB CQI / PMI can be dropped. For example, if the RI offset is “0” instead of “−1”, the WB CQI / PMI and the RI transmission subframe overlap each other. In this case, the WB CQI / PMI is dropped, and the RI Can be transmitted.

  By such a combination, CQI, PMI, and RI can be transmitted, and these pieces of information can be transmitted to each terminal by higher-layer RRC signaling. The base station can transmit information suitable for each terminal in consideration of the channel status of each terminal, the terminal distribution status in the base station, and the like.

  Meanwhile, the payload size for SB CQI, WB CQI / PMI, RI, and WB CQI for the report type on PUCCH can be set as shown in Table 7.

次に、ＰＵＳＣＨを用いた非周期的ＣＱＩ、ＰＭＩ、ＲＩ伝送について説明する。

Next, aperiodic CQI, PMI, and RI transmission using PUSCH will be described.

  In the case of aperiodic reporting, RI and CQI / PMI can be transmitted on the same PUSCH. In the aperiodic reporting mode, RI reporting is valid only for CQI / PMI reporting in the aperiodic reporting mode. The CQI-PMI combinations supported for all rank values are as shown in Table 8 below.

表８のモード１−２は、ＷＢフィードバックに関するものである。モード１−２で、それぞれのサブバンドに対して好むプリコーディング行列は、当該サブバンドのみでの伝送を仮定してコードブックサブセット（ｓｕｂｓｅｔ）から選択することができる。端末は、コードワードごとに一つのＷＢ ＣＱＩを報告でき、ＷＢ ＣＱＩは、全体システム帯域幅（ｓｅｔ Ｓ）のサブバンド上での伝送及びそれぞれのサブバンドでの対応する選択されたプリコーディング行列を用いることを仮定して計算することができる。端末は、サブバンドのそれぞれに対して選択されたＰＭＩを報告することができる。ここで、サブバンドサイズは、下記の表９のように与えることができる。表９で、システム帯域幅のサイズが６または７の場合は、サブバンドサイズの適用がないと示しており、これは、ＷＢ ＣＱＩのみを適用可能であり、サブバンドは存在しないことを意味することができる。

Mode 1-2 in Table 8 relates to WB feedback. In mode 1-2, the preferred precoding matrix for each subband can be selected from the codebook subset assuming transmission in that subband only. The terminal can report one WB CQI per codeword, which is transmitted over subbands of the total system bandwidth (set S) and the corresponding selected precoding matrix in each subband. It can be calculated assuming use. The terminal can report the selected PMI for each of the subbands. Here, the subband size can be given as shown in Table 9 below. Table 9 shows that when the system bandwidth size is 6 or 7, there is no application of subband size, which means that only WB CQI can be applied and there is no subband. be able to.

表８のモード３−０及び３−１は、上位層により構成される（ｃｏｎｆｉｇｕｒｅｄ）サブバンドフィードバックに関するものである。

Modes 3-0 and 3-1 in Table 8 relate to subband feedback configured by higher layers.

  In mode 3-0, the terminal may report a WB CQI value calculated assuming transmission on the entire system bandwidth (set S) subband. The terminal can also report one subband CQI value for each subband. The subband CQI value may be calculated assuming transmission in only the subband. Both WB CQI and SB CQI can indicate the channel quality for codeword 1 even when RI> 1.

  In mode 3-1, a single precoding matrix may be selected from the codebook subset assuming transmission over the entire system bandwidth (set S) subband. The terminal can report one SB CQI value per codeword for each subband. The SB CQI value may be calculated assuming a single precoding matrix is used in all subbands and assuming transmission in the corresponding subband. The terminal can report the WB CQI value for each codeword. The WB CQI value can be calculated assuming a single precoding matrix is used in all subbands and assuming transmission in the overall system bandwidth (set S) subband. The terminal can report the selected single precoding matrix indicator. The SB CQI value for each codeword can be expressed as a difference value with respect to the WB CQI using a 2-bit subband differential CQI offset (subband differential CQI offset). That is, the subband differential CQI offset is defined as a difference value between the SB CQI index and the WB CQI index. The subband differential CQI offset value may have any one of {−2, 0, +1, +2}. The subband size can be given as shown in Table 9.

  Modes 2-0 and 2-2 in Table 8 relate to UE-selected subband feedback. Modes 2-0 and 2-2 can be briefly described as reporting the optimal M (Best-M) average.

  In mode 2-0, the terminal can select a set of M preferred subbands (ie, Best-M) from the total system bandwidth (set S). One subband size is k, and the values of k and M for each system bandwidth range can be given as in Table 10 below. Table 10 shows that when the system bandwidth size is 6 or 7, there is no application of the subband size and M value, which is applicable only to WB CQI, and there is no subband. Can mean.

  The terminal may report one CQI value reflecting transmission on only the M selected (best-M) subbands determined above. This CQI value can indicate the channel quality for codeword 1 even when RI> 1. Also, the UE can report a WB CQI value calculated assuming transmission on the entire system bandwidth (set S) subband. The WB CQI can indicate the channel quality for codeword 1 even when RI> 1.

モード２−２で、端末は、全体システム帯域幅（ｓｅｔ Ｓ）サブバンドからＭ個の好むサブバンドの集合（すなわち、Ｂｅｓｔ−Ｍ）を選択し（一つのサブバンドサイズはｋである。）、これに加えて、当該選択されたＭ個のサブバンド上で伝送に用いられるコードブックサブセットから、好む単一プリコーディング行列を選択することができる。端末は、選択されたＭ個のサブバンド上のみでの伝送、及びＭ個のサブバンドのそれぞれにおいて同一の選択された単一プリコーディング行列が用いられることを反映して、コードワード当たり一つのＣＱＩ値を報告することができる。端末は、当該Ｍ個のサブバンドに対して選択された単一のプリコーディング行列の指示子を報告することができる。また、一つのプリコーディング行列（前述したＭ個の選択されたサブバンドに対するプリコーディング行列と別個のプリコーディング行列）を、全体システム帯域幅（ｓｅｔ Ｓ）のサブバンド上での伝送を仮定してコードブックサブセットから選択することができる。端末は、全体システム帯域幅（ｓｅｔ Ｓ）のサブバンドでの伝送及び全サブバンドで上記一つのプリコーディング行列を用いることを仮定して計算されたＷＢ ＣＱＩを、コードワードごとに報告することができる。端末は、全サブバンドに対して選択された一つのプリコーディング行列の指示子を報告することができる。

In mode 2-2, the terminal selects a set of M preferred subbands (ie, Best-M) from the overall system bandwidth (set S) subband (one subband size is k). In addition, a preferred single precoding matrix can be selected from the codebook subset used for transmission on the selected M subbands. The terminal transmits one on each codeword, reflecting transmission on only the selected M subbands and the same selected single precoding matrix being used in each of the M subbands. CQI values can be reported. The terminal may report a single precoding matrix indicator selected for the M subbands. Also, assuming that one precoding matrix (precoding matrix separate from the precoding matrix for the M selected subbands described above) is transmitted on the subband of the total system bandwidth (set S). You can choose from a codebook subset. The UE may report the WB CQI calculated for each codeword on the assumption that transmission in the subband of the total system bandwidth (set S) and use of the one precoding matrix in all the subbands. it can. The terminal can report the indicator of one precoding matrix selected for all subbands.

  For both the UE-selected subband feedback modes (modes 2-0 and 2-2), the terminal determines the position of the M selected subbands in combination index (combinatorial index). can be reported using r. r can be defined as in Equation 16.

集合

set

は、Ｍ個の整列された（ｓｏｒｔｅｄ）サブバンドインデックスを含むことができる。数学式１６で、

May include M sorted subband indices. In Equation 16,

であり、ｘ＜ｙの場合に０である拡張された二項係数（ｅｘｔｅｎｄｅｄ ｂｉｎｏｍｉａｌ ｃｏｅｆｆｉｃｉｅｎｔ）を意味する。これにより、ｒは唯一のラベル（ｕｎｉｑｕｅ ｌａｂｅｌ）を有するようになり、

And an extended binomial coefficient that is 0 when x <y. This ensures that r has a unique label,

である。

It is.

  Also, the CQI values for the M selected subbands for each codeword can be expressed as a difference value relative to the WB CQI. This relative difference value can be expressed by a differential CQI offset level of 2 bits, and can have a value of CQI index-WB CQI index of M selected subbands. . The possible differential CQI value may be any one of {+1, +2, +3, +4}.

  Further, the supported subband size k and the value of M can be given as shown in Table 10 above. As shown in Table 10, the values of k and M are given as a function of system bandwidth.

  The label indicating the position of the selected M (Best-M) subbands can be expressed by L bits,

である。

It is.

(Feedback information for multiple MIMO transmission mode)
As described above, channel state information (CSI: Channel State Information) is required for transmission using multiple antennas. The CSI can be fed back from the receiving end to the transmitting end. The transmitting end can obtain a precoding weight that can be used adaptively according to the channel state from the CSI. Also, the transmission end can acquire information for signal transmission from the channel state information converted by the precoding weight determined to be used for multi-antenna transmission. The information for signal transmission may include, for example, a modulation order, a coding rate, a transmission block size, a scheduled band, and the like.

  The receiving end acquires information on the channel state between the transmitting end and the receiving end using the reference signal (RS) transmitted by the transmitting end, and reports (feeds back) the acquired channel state information (CSI) to the transmitting end. be able to. At this time, various methods can be used to reduce the amount of CSI information to be fed back. For example, by expressing information such as channel quality information (Channel Quality Information / Index; CQI), precoding matrix index (Precoding Matrix Index; PMI), rank indicator (Rank Indicator; RI) by quantized bits, The amount of information to be fed back can be reduced and efficient transmission can be performed.

  In particular, in multi-antenna transmission, information about a rank suitable for transmission varies depending on long-term fading, and therefore has characteristics that do not change for a relatively long time compared to other channel state information. On the other hand, PMI and CQI are information reflecting a channel state that changes suddenly due to short-term fading, and thus have characteristics that change in a relatively short time. For this reason, RI is preferably reported in a longer cycle than PMI / CQI, and PMI / CQI is preferably reported in a shorter cycle than RI. Since PMI and CQI are information determined by the rank used for transmission, PMI and CQI are calculated based on the previously determined RI until the next RI reporting period.

  Thus, when calculating the channel state information, the rank value needs to be determined first, and the rank value can be determined in consideration of the multiple antenna (or MIMO) transmission scheme. The MIMO transmission method can be classified into a multi-user MIMO (MU-MIMO) transmission method and a single-user MIMO (SU-MIMO) transmission method. A case where spatial channels that can be generated using multiple antennas are assigned to multiple users is called MU-MIMO, and a case where all spatial channels are assigned to a single user is called SU-MIMO.

  The MU-MIMO transmission method includes a transmission method using a non-unitary matrix such as DPC (Dirty Paper Coding) and zero focusing, and a PU2RC (Per-User Unitary Rate Control). And a transmission method using unitary precoding weights as in the above method. Both transmission systems are characterized in that a single user reports a precoding weight calculated based on a limited transmission rank to the transmission end. For example, a multi-antenna transmitter having M transmit antennas can generate a maximum of M spatial channels and transmit a signal, but the number of spatial channels allocated to receiving ends participating in MU-MIMO transmission is , Limited to fewer than M spatial channels. At this time, it is possible to consider a method in which the number of maximum spatial channels allocated to each user is limited to N (N <M) spatial channels so that each user receives N or fewer spatial channels. In such a situation, the terminal, under the assumption that a maximum of N transmission spatial channels can be allocated, the most suitable rank for transmission, that is, the optimal rank among the ranks (1 to N) of N or less. The precoding weight and channel quality information are calculated according to the selected rank value.

For example, if the number of spatial channels allocated to one receiving end is limited to two, the receiving end may measure channel state information under the assumption that one or a maximum of two spatial channels are allocated to itself. it can. This can reduce the amount of channel state information that the receiving end should measure and report. That is, information about the rank order is limited to 2 to N, the bits required to represent the rank information reduced to _log 2 (2) from the _log 2 (N).

  The amount of PMI is determined by a defined codebook set (codebook set), but L codebook sets are defined from rank-1 to rank-N, and rank-1 to rank-2. If (K <L) codebook sets are defined, the amount of feedback information required for PMI reporting is also reduced when the maximum rank is limited from N to 2.

  A CQI must be calculated for each codeword (CW). If a system with multiple codewords (MCW) has a maximum of two CWs in a rank-2 transmission, two CQIs must be reported for a rank-2 or higher transmission, The CQI can be reported in the same amount (ie, two CQIs) when restricting that a maximum of two spatial channels are allocated.

  The transmitting end calculates CQI in consideration of the number of layers to be transmitted. If the transmission with MCW is rank-2 transmission, the CNR of the CW transmitted through the first layer is calculated as SINR considering the signal transmitted through the second layer as interference. be able to. Similarly, when the receiving end knows the number of spatial channels that the transmitting end generates at one time, the receiving end can measure channel state information suitable for the maximum number of spatial channels generated by the transmitting end. , The accuracy for CQI can be increased. For example, if a maximum of two spatial channels are formed at the transmitting end and each spatial channel is assigned to two users, the receiving end assumes that there is an interference layer when calculating the CQI. Can be used to calculate the CQI.

  On the other hand, SU-MIMO transmission is characterized in that one user uses all the spatial channels generated by the transmitting end. The receiving end reports rank information suitable for transmission to the transmitting end, and can report PMI and CQI calculated based on the rank information to the transmitting end. For example, if the maximum number of spatial channels that can be generated by the transmitting end is M, the receiving end may select a transmission rank that maximizes transmission efficiency from 1 to M ranks and report it to the transmitting end. it can.

  The transmitting end can simultaneously support SU-MIMO transmission and MU-MIMO transmission. A special control signal may be required for each of SU-MIMO transmission and MU-MIMO transmission. For example, in SU-MIMO, it is possible to receive up to M ranks. In MU-MIMO, the transmitting end can generate up to M spatial channels, but the receiving end can generate up to N spatial channels for each user. It is also possible to transmit a control signal optimized for each transmission mode when it is regarded as an effective spatial channel corresponding to. In this case, the transmitting end notifies the receiving end about the transmission mode, thereby informing in advance in which transmission mode the receiving end will receive the signal, and transmits a control signal corresponding thereto. Can simultaneously support SU-MIMO and MU-MIMO transmission.

  Alternatively, the transmitting end does not give an instruction (indication) that enables the receiving end to distinguish between the SU-MIMO transmission mode and the MU-MIMO transmission mode, and the receiving end recognizes one of the transmission modes and decodes the data. You can also consider how to do it. In this case, the transmitting end may consider a method of simply instructing the receiving end of the number of layers that the terminal should currently receive. Then, there is no distinction between the SU-MIMO mode / MU-MIMO mode for the terminal. This makes it possible to support MIMO transmission using the same control signal. However, also in this case, in order to support SU-MIMO and MU-MIMO, different feedback information must be reported from the receiving end to the transmitting end. For example, in order to support SU-MIMO transmission, an optimal transmission rank for transmission may be reported in consideration of the maximum spatial channel that can be generated by the transmitting end. In order to support MU-MIMO transmission, the receiving end may receive a limited number of layers and select and report an optimal rank for transmission from the limited ranks. .

(Multiple-rank PMI feedback)
Multi-rank PMI feedback can be considered in a feedback scheme to smoothly support multiple MIMO modes in a system that supports extended antenna configurations.

  For example, in SU-MIMO rank-r transmission, the receiving end can receive r layers from the base station and determine the PMI on the assumption that it is transmitted in rank-rSU-MIMO. On the other hand, in MU-MIMO transmission, even if one layer is received from the viewpoint of one receiving end, it is possible to actually transmit multiple layers at the transmitting end.

  Multi-rank PMI feedback means that rank-r PMI is used in SU-MIMO mode transmission, and limited rank (eg, rank-1 or 2) PMI is used in MU-MIMO mode transmission. means. For example, for rank-r SU-MIMO transmission, rank-r PMI is fed back under the assumption of SU-MIMO. Alternatively, for MU-MIMO pairing, PMI / CQI of a limited rank (for example, rank-1 or 2) based on the assumption of SU-MIMO is fed back. The use of restricted rank (or lower rank) PMI is described in detail below.

  A restricted PMI with a lower rank value (eg, rank-1 or 2) is appended to the general rank-r PMI to allow dynamic switching between SU-MIMO and MU-MIMO modes. It can be made easier. In order to support dynamic SU-MIMO / MU-MIMO switching in rank-1 to rank-8 overall-rank, one transmission mode for each rank-1 to rank-8 is assigned to each sub-mode. There is a need to support dynamic SU-MIMO / MU-MIMO switching in frames. That is, the same terminal feedback (PMI / CQI for rank-1 to rank-8) is used for both SU-MIMO scheduling and MU-MIMO scheduling.

  When the terminal does not know the actual transmission mode or the actual rank, and the terminal reports PMI / CQI of a high rank (for example, ranks 3 to 8), a low rank (for example, rank-1) is reported to the terminal. Or, the problem is how to schedule the MU-MIMO transmission mode of 2). As one solution to solve this, it is considered to extract and use the first two columns (columns) from the higher rank (ranks 3 to 8) PMI fed back by the terminal for MU-MIMO scheduling. can do. However, the “truncated PMI” is thus the optimal lower rank (rank-1 or 2) PMI calculated under the assumption of lower rank (rank-1 or 2). There is a case that cannot be. Of course, such suboptimal “truncated PMI” may be used, although it may adversely affect MU-MIMO performance. Also, in general, once a terminal reports rank-r PMI according to a low mobility setting in a situation suitable for the MU-MIMO transmission mode (that is, a setting suitable for a low rank), the terminal rank- Without reporting 1 PMI, rank-r PMI may be continuously reported in a long cycle. Thus, with multi-rank PMI, the terminal can additionally provide an optimal low-rank PMI that can achieve sufficient CSI accuracy for rank-1 or 2 MU-MIMO pairing. .

  Therefore, using multi-rank PMI facilitates dynamic SU-MIMO / MU-MIMO switching and also improves CSI accuracy.

(Precoder for 8 transmission antennas)
In a system that supports an extended antenna configuration (for example, 3GPP LTE Release-10 system), for example, MIMO transmission using eight transmission antennas can be performed, and a codebook design to support this is required. Is done.

  It may be considered to use a codebook as shown in Table 11 to Table 18 for CSI reporting for channels transmitted through 8 antenna ports. Eight CSI antenna ports can be expressed by indexes of antenna ports 15 to 22. Table 11 is an example of a codebook for 1-layer CSI reporting using antenna ports 15-22. Table 12 is an example of a codebook for 2-layer CSI reporting using antenna ports 15-22. Table 13 is an example of a codebook for 3-layer CSI reporting using antenna ports 15-22. Table 14 is an example of a codebook for 4-layer CSI reporting using antenna ports 15-22. Table 15 is an example of a codebook for 5-layer CSI reporting using antenna ports 15-22. Table 16 is an example of a codebook for 6-layer CSI reporting using antenna ports 15-22. Table 17 is an example of a codebook for 7-layer CSI reporting using antenna ports 15-22. Table 18 is an example of a codebook for 8-layer CSI reporting using antenna ports 15-22.

  In Table 11 to Table 18,

は、数学式１７のように与えることができる。

Can be given as in Equation 17.

（ＤＣＩフォーマット０）
ＤＣＩフォーマット０は、ＰＵＳＣＨ伝送をスケジューリングするために用いられる。ＤＣＩフォーマット０により伝送される制御情報について説明する。

(DCI format 0)
DCI format 0 is used to schedule PUSCH transmission. Control information transmitted in the DCI format 0 will be described.

  The “Flag for format 0 / format 1A differentiation” (flag for distinguishing format 0 / format 1A) field is given by 1 bit, and is a field for distinguishing between DCI format 0 and DCI format 1A. The DCI format 1A is a DCI format for scheduling downlink transmission, and has the same payload size as that of the DCI format 0. Therefore, the DCI format 0 and the DCI format 1A are included in a field that can distinguish between them while having the same format. If the “Flag for format 0 / format 1A differentiation” field has a value of 0, it indicates DCI format 0, and if it has a value of 1, it indicates DCI format 1A.

  The “Frequency hopping flag” (frequency hopping flag) field is given as 1 bit and represents whether or not PUSCH frequency hopping is applied. When the “Frequency hopping flag” field has a value of 0, it indicates that PUSCH frequency hopping is not applied, and when it has a value of 1, it indicates that PUSCH frequency hopping is applied.

  The “Resource block assignment and hopping resource allocation” (resource block allocation and hopping resource allocation) field represents resource block allocation information in an uplink subframe depending on presence / absence of PUSCH frequency hopping. The “Resource block assignment and hopping resource allocation” field

ビットで構成される。

Consists of bits.

は、上りリンク帯域幅設定（ｃｏｎｆｉｇｕｒａｔｉｏｎ）値であり、リソースブロックの個数で表現される。ＰＵＳＣＨホッピングが適用される場合に、

Is an uplink bandwidth configuration value and is represented by the number of resource blocks. When PUSCH hopping is applied,

（物理リソースブロックのインデックス）を獲得するために、

To get (index of physical resource block)

のＭＳＢ（Ｍｏｓｔ Ｓｉｇｎｉｆｉｃａｎｔ Ｂｉｔ）ビットが用いられ、

MSB (Most Significant Bit) bits are used,

ビットが上りリンクサブフレームの第１スロットのリソース割当を提供する。ここで、

Bits provide resource allocation for the first slot of the uplink subframe. here,

は、システム帯域幅のサイズによって１または２ビットを有するホッピング情報を表す。一方、ＰＵＳＣＨホッピングが適用されない場合には、

Represents hopping information having 1 or 2 bits depending on the size of the system bandwidth. On the other hand, when PUSCH hopping is not applied,

ビットが上りリンクサブフレームのリソース割当を提供する。

Bits provide resource allocation for uplink subframes.

  The “Modulation and coding scheme and redundancy version” (modulation and coding scheme and redundancy version) field is given as 5 bits, and represents the modulation order and redundancy version (RV) for PUSCH. RV represents information on which subpacket is retransmitted in the case of retransmission. Of the 32 states represented by 5 bits, 0 to 28 can represent modulation orders, and 29 to 31 can represent RV indexes (1, 2, and 3).

  The “New data indicator” (new data indicator) field is given as 1 bit and indicates whether the uplink scheduling information is related to new data or retransmission. When toggled compared to the NDI value of the previous transmission, it represents a new data transmission, and when not toggled, it represents a retransmission.

  The “TPC command for scheduled PUSCH” (transmission power control command for scheduled PUSCH) field is given as 2 bits and represents a value that can determine the transmission power for PUSCH transmission.

  The “Cyclic shift for DMRS” (cyclic shift for demodulated reference signal) field is given as 3 bits, and a cyclic shift (Cyclic Shift) value used for sequence generation for an uplink demodulated reference signal (DeModulation Reference Signal; DMRS) is set. Represent. DMRS is a reference signal used for uplink channel estimation by antenna port or layer.

  The “UL index (for TDD)” (uplink index (in the case of TDD)) field is given as 2 bits, and when a radio frame is configured in a time division duplex (TDD) scheme, a specific uplink-downlink A subframe index set as uplink transmission in the configuration can be represented.

  The “Downlink Assignment Index (for TDD)” (downlink assignment index (in the case of TDD)) field is given as 2 bits, and when a radio frame is configured in the TDD scheme, PDSCH transmission in a specific uplink-downlink configuration And the total number of subframes set.

  The “CQI request” (channel quality indicator request) field is given as 1 bit, and a non-periodic CQI (Channel Quality Information), PMI (Precoding Matrix Indicator) and RI (Rank Indicator) reports are made using PUSCH. Represents a request. When the “CQI request” field is set to 1, the terminal transmits aperiodic CQI, PMI and RI reports using PUSCH.

According to “Modulation and coding scheme and redundancy version”, it is possible to signal an MCS index (I _MCS ) expressing 32 states in 5 bits as shown in Table 4 above.

に対して、

Against

をシグナリングすると、ＤＣＩフォーマット０の「ＣＱＩ ｒｅｑｕｅｓｔ」ビットは１に設定され、４ＲＢ以下

The "CQI request" bit in DCI format 0 is set to 1, and 4RB or less

の伝送が設定され、ＰＵＳＣＨデータ再伝送におけるリダンダンシバージョン１（ＲＶ１）が指示され、変調次数

Transmission is set, redundancy version 1 (RV1) in PUSCH data retransmission is instructed, and the modulation order

に設定される。すなわち、ＣＱＩのみを伝送する場合には変調手法としてＱＰＳＫのみを用いることができる。

Set to That is, when only CQI is transmitted, only QPSK can be used as a modulation method.

  In 3GPP LTE-A system, SU-MIMO can transmit signals using up to 8 layers, and MU-MIMO can transmit signals using up to 2 layers. The receiving end demodulates the signal with the same operation regardless of the transmission method of SU-MIMO and MU-MIMO.

  The receiving end provides information (CSI and the like) for signal transmission to the transmitting end, but generally, SU-MIMO transmission is assumed when reporting CSI information. In general, since SU-MIMO-based CSI information is calculated without considering intra-cell interference, when MU-MIMO transmission is attempted using SU-MIMO-based CSI information, CQI mismatch (Mismatch) can cause performance degradation. Therefore, in order to improve the performance of MU-MIMO transmission, it is necessary to consider a method for reporting a precoder suitable for MU-MIMO transmission.

  When the terminal reports a transmission rank that provides the maximum efficiency in SU-MIMO transmission to the base station, for example, when a rank-8 based codebook index and CQI are calculated and reported, the feedback information is Although it is suitable for rank-8 transmission, it may not be suitable for MU-MIMO transmission in which terminals having rank-1 / 2 are multiplexed and transmitted. Therefore, in order to prevent performance degradation, CSI information for MU-MIMO transmission as well as CSI information for SU-MIMO transmission must be reported.

  On the other hand, two methods can be considered as a method in which the receiving end reports CSI information to the transmitting end. One is a method for reporting CSI information using a resource promised at a promised time, and the other is a method for reporting CSI information at a specific time in accordance with an instruction from the transmitting end. In the method of reporting CSI information at a promised time, a periodic CQI report can be transmitted through PUCCH as in the 3GPP LTE Release-8 system (PUSCH data is transmitted at the timing when periodic CSI is reported). The CSI can be multiplexed with the data and transmitted). On the other hand, in the method of reporting CSI information at a specific time according to an instruction from the transmitting end, an aperiodic CSI report request is included in control information (eg, DCI format 0) for uplink transmission included in the downlink control channel. By setting the field, CSI can be reported through PUSCH.

Example 1
In the first embodiment, a CSI information reporting method that can effectively support SU-MIMO and MU-MIMO transmission by an aperiodic CSI reporting method reported through PUSCH will be described. In the first embodiment, the UE recommends (UE recommended) CSI and the CSI related to the restricted rank (Example 1-A), and the CSI recommended by the terminal and the CSI related to the restricted rank. It is roughly divided into a method for reporting one (Example 1-B).

Example 1-A
Example 1-A relates to a method for simultaneously reporting CSI recommended by a terminal and CSI related to a limited rank.

  Assuming the rank range that the receiving end (ie, the terminal) can measure is rank-N, the receiving end calculates the CQI for rank-1 to rank-N and selects the rank that provides the maximum yield. . Here, when the receiving end selects a rank of rank-M (for example, M = 3) or higher, information on ranks (for example, rank-1 and rank-2) smaller than rank-M (this is MU-MIMO transmission). Can be reported additionally). At this time, when a restricted rank is set and rank adaptation is possible within the maximum rank, a rank indicator is required. If the limited rank is determined to be a limited value such as 1 or 2, only the PMI and CQI values need be reported without a rank indicator.

  On the other hand, if the rank recommended by the terminal is a value less than or equal to M (for example, M = 2), only the CSI recommended by the terminal is reported. If the rank recommended by the terminal is larger than M (for example, M = 2), in addition to the CSI related to the rank recommended by the terminal, the CSI related to the restricted rank is also reported.

(Example 1-B)
Example 1-B relates to a method for reporting one of CSI recommended by a terminal and CSI related to a restricted rank.

  When it is assumed that the range of ranks that can be measured by the receiving end is rank-N, the receiving end generally calculates the CQI for rank-1 to rank-N and selects the rank that provides the maximum yield. Here, when the receiving end reports a rank of rank-M or higher (for example, M = 3), the transmitting end requires CSI information of a rank lower than M in order to perform MU-MIMO transmission. In this case, the transmitting end can request to report rank information in a range lower than the range that the receiving end can calculate and report. Various embodiments of the invention in this regard are described below.

(Example 1-B-1)
By defining an indicator in the DCI format of the PDCCH, a method for instructing the base station to report rank information in a desired range can be considered.

  By defining an indicator indicating the CQI attribute in the control information for uplink transmission, the receiving end can be instructed to report CQIs of ranks in the range specified by the transmitting end.

  For example, “CQI request field” is defined in DCI format 0 defined in 3GPP LTE Release-8. When the CQI request field has a value of 1, the terminal transmits CSI information. At this time, the transmitted CSI information includes RI, PMI, and CQI. In general, the rank information is selected by a value preferred by the terminal.

  In a DCI format newly defined for uplink transmission according to the present invention (eg, referred to as DCI format 4) in a system having an extended antenna configuration (eg, 3GPP LTE Release-10 system), the base station uses CQI. When making a request, it is possible to preferentially report the preferred rank of the terminal, and if the base station indicates the rank, the terminal can report the CSI based on the (eNB configured) rank set by the base station. . Here, the rank indicated by the base station may designate a specific rank value, may designate a maximum rank value, may designate an index for the maximum rank value, and is promised (predetermined It may be an indicator that uses a rank value, or an indicator that uses a promised maximum rank value.

  An indicator indicating that the rank set by the base station (or a restricted rank) is used can be included in the DCI format. For example, when the CQI request field is activated among the fields defined in the DCI format, other fields that are not used in the DCI format are changed to an indicator for using the rank set by the base station. (Ie, can be reused). Or you may use the combination with another field for the use of the indicator with respect to the rank which the base station set.

  For example, a bit field of DCI format 4 can be defined as shown in Table 19.

表１９で、ＣＱＩ要請フィールドが活性化されると、第２伝送ブロック（ＴＢ）に対するＭＣＳ及びＲＶフィールドは使用されない。この場合、第２ＴＢに対するＭＣＳ及びＲＶフィールドを、基地局が設定するランク（または、制限されたランク）を指示する用途に再使用することができる。

In Table 19, if the CQI request field is activated, the MCS and RV fields for the second transport block (TB) are not used. In this case, the MCS and RV fields for the second TB can be reused for indicating the rank (or restricted rank) set by the base station.

(Example 1-B-2)
Depending on the type of the DCI format of the PDCCH, a method for setting the reporting rank range can be considered.

  Control information for uplink transmission can be classified into a DCI format for supporting single layer transmission and a DCI format for supporting multi-layer transmission. For example, single antenna transmission is single layer transmission and for this purpose DCI format 0 is defined. Also, a new DCI format (for example, referred to as DCI format 0A) may be defined to support a specific allocation method although it is a single layer, and is a single layer, but a single layer precoder indication A new DCI format that includes children (eg, referred to as DCI format 0B) may be defined. Also, a DCI format for multi-antenna transmission can be defined. For example, a new DCI format (for example, referred to as DCI format 4) can be defined for transmission of a multi-transmission block. A CQI request field can be defined for each DCI format. Here, when the CQI request field of the DCI format for supporting a single transport block is activated, the UE may calculate and report the CQI with a “restricted rank”. When the CQI request field of the DCI format for supporting the multi-transmission block is activated, the UE can calculate and report the CQI with a rank within a range in which measurement and reception are possible. .

  In other words, when a CQI request is indicated from a DCI format that supports a single transmission block such as DCI format 0, 0A, 0B, the terminal calculates a CQI within a limited rank, When a CQI request is instructed from a DCI format that supports multiple transmission blocks, a CQI may be calculated and reported in a rank within a range in which the terminal can measure and receive.

  Here, the restricted rank can be set to a value independent of the rank of the range that can be measured by the terminal. The restricted rank may be indicated by RRC signaling and may be determined to a fixed value. For example, the restricted rank may be set to the maximum rank 2.

(Example 1-B-3)
A method of setting different types of information to be reported depending on the number of PUSCH to be transmitted can be considered.

  In the existing 3GPP LTE release-8, when the CQI request field of DCI format 0 is set to 1, at the time when k subframes have elapsed from the time of receiving DCI through the PDCCH (the nth subframe). The PUSCH is transmitted in a certain n + kth subframe. In the case of FDD, k = 4 is set.

  Temporarily, the CSI information to be reported varies depending on whether n is an even number or an odd number, based on the nth subframe at the time of receiving the DCI format in which the CQI request field for requesting the aperiodic CQI is activated. can do. For example, if the n-th subframe is an even-numbered subframe, the CSI of the rank recommended by the UE is reported, and if it is an odd-numbered subframe, the CSI of a limited rank is reported. it can. Or, if the nth subframe is an odd subframe, the CSI of the rank recommended by the terminal may be reported, and if the nth subframe is an even subframe, the CSI of a limited rank may be reported.

  On the other hand, if the DCI format in which the CQI request field for requesting the aperiodic CQI is activated is received in the nth subframe and the CSI is reported, n + k is an even number based on the n + kth subframe. The CSI information to be reported may be different depending on whether it is odd or odd. For example, if the n + k-th subframe is an even-numbered subframe, the CSI of the rank recommended by the terminal may be reported, and if it is an odd-numbered subframe, the CSI of a limited rank may be reported. Or, if the n + k-th subframe is an odd-numbered subframe, the CSI of the rank recommended by the terminal may be reported, and if it is an even-numbered subframe, the CSI of a limited rank may be reported.

  SU-MIMO and MU-MIMO transmission as proposed in the first embodiment can be effectively supported in a transmission mode newly defined in a system that supports an extended antenna configuration (eg, 3GPP LTE-A system). CSI reporting scheme can be applied.

(Example 2)
In the second embodiment, when the rank recommended by the terminal (UE recommended) is higher than the restricted rank (restricted rank), the restricted rank is determined using the precoder selected based on the rank recommended by the terminal. A method for selecting a precoder that meets the requirements will be described.

  A precoder having rank -N is composed of a combination of N precoding vectors. Using a partial vector out of N vectors enables low rank transmission. The use of the partial vector of the precoder in this way can be referred to as “subset selection”.

  The base station may perform subset selection on the precoder reported from the terminal by randomly selecting an arbitrary vector, by selecting a subset according to a predetermined (ie, promised) rule, It is possible to consider a method of reporting a preferred vector on the reporting side (terminal). Here, a method of selecting an arbitrary vector or a method of selecting a subset according to a promised rule can be performed without additional signaling. On the other hand, in the method of reporting a preferred vector on the reporting side, the reporting side (terminal) must provide information on subset selection to the receiving side (base station).

  Examples of rules that can be applied in the method of selecting a subset according to promised rules are described below.

  As an example, a rule for selecting in order from the first column of the precoder can be applied. For example, in the case of rank-1, one of the first columns can be selected, and in the case of rank-2, the first column and the second column can be selected.

  As another example, a rule for selecting a subset in consideration of a layer to which a transmission block (TB) is mapped may be applied. For example, a precoder corresponding to the M-th layer can be selected from the layers to which the TB is mapped. For example, if two TBs (TB1 and TB2) are mapped to four layers (Layer 1, Layer 2, Layer 3, Layer 4), TB1 is mapped to Layer 1 and Layer 2, and TB2 is a layer Assume 3 and 4 are mapped. At this time, if M = 1 is given in the precoder subset selection, it corresponds to the first layer to which TB1 is mapped (ie, layer 1) and the first layer to which TB2 is mapped (ie, layer 3). The subset can be selected as two precoders.

  Meanwhile, an example of a signaling scheme that can be applied in a method of reporting a vector preferred by a reporter will be described below.

  As an example, a subset of precoders can be reported in bitmap format. For example, in the case of rank-N, a precoder vector preferred by the terminal can be reported to the base station using a bitmap made up of N bits of N vectors.

As another example, if reporting a preference for one of a subset of precoders, log ₂ (N) bits (where N = rank) are used to base the terminal's preferred precoder vector. You can report to the station.

  When a precoder is selected according to various methods as described above, a CQI corresponding to the selected precoder can be calculated and reported. A rank-N precoder is selected for SU-MIMO transmission, and a CQI can be calculated for the selected precoder. At this time, when a partial precoder vector is selected from the rank-N precoder, the CQI corresponding to the selected subset can be calculated again. For example, if a precoder for rank-4 is selected, the CQI for rank-4 can be calculated by this precoder. Also, if two precoder vectors are selected based on the rank-4 precoder, the CQI for rank-2 can be calculated.

  An example of a feedback scheme applicable when precoder selection is made in this way will be described below.

  First, a method of feeding back RI-PMI1-CQI1-PMI2-CQI2 can be considered. Here, RI is rank information corresponding to PMI1 (or Precoder 1), and CQI1 is a value calculated based on PMI1. PMI2 (or Precoder 2) is a precoder selected from PMI1, and CQI2 is a value calculated based on PMI2. Here, one or more of each of PMI1, PMI2, CQI1, and CQI2 can be transmitted.

  Secondly, a method of feeding back RI-PMI1-CQI1-CQI2 can be considered. Here, RI is rank information corresponding to PMI1 (or Precoder 1), and CQI1 is a value calculated based on PMI1. CQI2 is a value calculated based on PMI2 (or Precoder 2). PMI2 is a precoder selected from PMI1, and PMI2 is not reported when PMI2 is selected according to a promised rule. That is, only CQI2 can be reported without reporting PMI2. Here, one or more of each of PMI1, CQI1, and CQI2 may be transmitted.

  Third, a method of feeding back RI-PMI1-CQI1-PSI (Precoder Selection Indicator) -CQI2 can be considered. Here, RI is rank information corresponding to PMI1 (or Precoder 1), and CQI1 is a value calculated based on PMI1. PMI2 (or Precoder 2) is a precoder selected from PMI1, and can report PSI to inform the value of the selected PMI2. CQI2 is a value calculated based on PMI2. Here, one or more of each of PMI1, CQI1, and CQI2 may be transmitted.

  In the application of the feedback scheme as described above, feedback information may be reported simultaneously by a reported channel (ie, PUSCH or PUCCH), or may be reported at different periods. For example, in the feedback report using PUSCH, RI, PMI and CQI are reported through one channel, and when PMI2 selected as a partial subset of PMI1 as described above is reported, PMI2 and CQI2 are one. It may be reported simultaneously through two channels. Alternatively, in the feedback report using PUCCH, 'RI' and 'PMI and CQI' may be reported in different periods, and PMI2 selected as a partial subset of PMI1 as described above is reported. May report 'PMI2 and CQI2' in different periods.

(Example 3)
In the third embodiment, a method for determining the transmission timing of feedback information when precoder information related to a restricted rank is transmitted will be described.

  In general, for MU-MIMO transmission, it is preferable to use a low-rank precoder from the viewpoint of one user, and multiplex and transmit users with little spatial correlation. Also in the case of MU-MIMO transmission, the terminal determines and reports a rank value at which the maximum yield is expected, assuming SU-MIMO without distinguishing between MU-MIMO and SU-MIMO. be able to. When a UE recommended rank (UE recommended) and a precoder based on the rank are selected and reported, a higher rank precoder and a CQI based on the precoder may be calculated and reported. When high rank precoders are reported in this way, in order to perform MU-MIMO transmission, a lower rank precoder is configured using a subset of the reported precoders, or low rank precoders are additionally reported. A plan can be considered.

  First, the case where the base station selects a subset of the precoder reported from the terminal and performs MU-MIMO transmission will be described. When a subset of precoders according to the rank recommended by the terminal is used as a precoder for MU-MIMO transmission, the base station needs CQI for MU-MIMO transmission. Since the base station reports the CQI calculated based on the precoder according to the rank recommended by the terminal, the base station can consider using this CQI as the CQI for MU-MIMO. However, the channel state indicated by the CQI calculated based on the precoder according to the rank recommended by the terminal may be different from the channel state in the case of transmitting using a subset of the precoder. Therefore, when the base station uses the CQI calculated based on the precoder according to the rank recommended by the terminal as the CQI for MU-MIMO, a CQI mismatch may occur. Therefore, for improved MU-MIMO performance, CQI calculated based on a subset of precoders is preferably reported.

  Next, a case where the terminal additionally reports a lower rank precoder will be described. When a precoder having a lower rank is reported, it is preferred that the CQI calculated based on the precoder is also reported.

  The resources of the uplink control channel (PUCCH) allocated to the terminal by the base station for channel information reporting according to existing schemes are constrained, and using the PUCCH, the precoder for the rank recommended by the terminal and the calculation based on it are calculated. CQI information can be reported. Therefore, in order to report the precoder subset and the CQI calculated based on it as proposed in this embodiment, or to report the precoder and the CQI calculated based on it for a limited rank, these additional New timing and / or resources at which specific feedback information is reported needs to be defined.

Example 3-A
A method of setting an offset for reporting a precoder based on a limited rank and a CQI calculated based on the precoder will be described below.

  In the case of periodic PUCCH feedback reporting, timing for RI and PMI / CQI transmission is defined. In general, RI and PMI / CQI information are reported in different subframes. In particular, RI is reported with a longer period than PMI / CQI. When a rank is reported, PMI / CQI information corresponding to the previously reported rank is reported in accordance with the transmission period until the next rank is reported.

  As described above, if a high rank is reported, a PMI having a low rank and a CQI calculated based thereon are reported, or a subset of precoders having a high rank and a CQI calculated based on the subset. Need to be reported. The PMI / CQI information having such a low rank can be expressed as PMI / CQI information having a limited rank.

  The timing at which the restricted rank PMI / CQI is reported may be part of the timing at which the higher rank PMI / CQI is reported. That is, in a period in which ranks are reported, a part of time points when high-rank PMI / CQIs are reported can be used as time points for reporting PMI / CQIs with limited ranks. The PMI / CQI of the restricted rank is reported in a period longer than the PMI / CQI reporting period of the rank recommended by the terminal (that is, frequently lower), and the timing of reporting the PMI / CQI of the rank recommended by the terminal Can be reported with a predetermined offset. In particular, the offset with respect to the timing at which the PMI / CQI of the restricted rank is transmitted is set so that the PMI / CQI of the restricted rank is later than the timing at which the PMI / CQI recommended by the terminal is transmitted. can do.

  On the other hand, the timing offset of the subframe in which the rank information is transmitted is set to be the same subframe or the previous subframe based on the subframe in which the PMI / CQI of the rank recommended by the terminal is transmitted. Can do. Therefore, in order to prevent the transmission of restricted rank PMI / CQI from colliding with the transmission of rank information (ie, not transmitted in the same subframe), the restricted rank PMI / CQI is Based on the subframe in which PMI / CQI of the recommended rank is transmitted, it can be set to be reported in a subsequent subframe. The offset to the transmission timing of the limited rank PMI / CQI may be set to an integer other than 0 (ie, a positive integer or a negative integer).

  An example of PMI / CQI transmission timing and offset of a limited rank will be described with reference to FIGS. 22 and 23, Ns represents a slot index and has values of 0, 1,..., Ns. That is, in the examples of FIG. 22 and FIG. 23, one radio frame composed of 10 subframes is shown.

は、サブフレームインデックスに対応する。

Corresponds to the subframe index.

In FIG. 22, CQI / PMI according to the rank recommended by the terminal is transmitted with a period of Np, and RI is transmitted with a period (N _p × M _RI ) that is an integral multiple of the CQI / PMI period according to the rank recommended by the terminal. This shows that _RI is transmitted at a timing earlier by a predetermined offset (N _{offset, RI} ) than the CQI / PMI transmission timing according to the rank recommended by the terminal. As in the above-described embodiment of the present invention, the PMI / CQI of the limited rank is transmitted at a timing that is later than the CQI / PMI transmission timing by the rank recommended by the terminal by a predetermined offset (N _{offset, CQI} ). The terminal is transmitted in a longer cycle than the CQI / PMI transmission cycle according to the rank recommended by the terminal.

FIG. 23 shows that WB CQI / PMI and SB CQI are transmitted as CQI / PMI according to the rank recommended by the terminal. WB CQI / PMI and SB CQI are alternately transmitted with a period of Np, and the transmission period of WB CQI / PMI can be H × Np. The RI is transmitted in a cycle (H × Np × M _RI ) that is an integral multiple of the WB CQI / PMI cycle according to the rank recommended by the terminal, and the RI is a predetermined value compared to the CQI / PMI transmission timing according to the rank recommended by the terminal. It is transmitted at an earlier timing by an offset (N _{offset, RI} ). Further, as in the above-described embodiment of the present invention, the PMI / CQI of the limited rank is delayed by a predetermined offset (N _{offset, CQI} ) compared to the CQI / PMI transmission timing based on the rank recommended by the terminal. It is shown that the data is transmitted at a longer cycle than the CQI / PMI transmission cycle according to the rank recommended by the terminal.

(Example 3-A-1)
An example of feedback mode for PMI / CQI based on restricted rank is described below.

  According to the present embodiment, the feedback mode for reporting the PMI / CQI of the restricted rank may follow the PMI / CQI feedback mode of the rank recommended by the terminal. For example, when the PMI / CQI feedback mode of the rank recommended by the terminal is a mode transmitted by WB PMI / WB CQI, the limited rank of PMI / CQI may be transmitted by WB PMI / WB CQI. . Alternatively, when the PMI / CQI feedback mode of the rank recommended by the terminal is a mode transmitted by WB PMI / SB CQI, the limited rank of PMI / CQI may be transmitted by WB PMI / SB CQI. .

  In addition, when SB CQI is reported by a method such as band cycling, WB CQI is reported, and one cycle in which all SB CQI related to each BP (Bandwidth Part) is reported. Can be considered. In this case, the PMI / CQI of a limited rank can be reported in one cycle in which the WB CQI and the SB CQI for each BP are reported. That is, during the RI reporting period, at least one period of a band cyclic reporting period having a period of one period or more is set as a period for reporting PMI / CQI of a limited rank. Can do.

With reference to FIG. 24, an example of PMI / CQI reporting periods with limited ranks will be described. In FIG. 24, one of the bandwidth cycle reporting periods in which the WB CQI and the CQI for each BP are reported during the RI reporting period (H × N _p × M _RI ) is:

値１乃至４に該当する。図２４の例示では、前述した本発明の実施例のように、帯域循環報告周期のうち一つで、制限されたランクのＰＭＩ／ＣＱＩを伝送することができる。

Corresponds to values 1 to 4. In the example of FIG. 24, as in the above-described embodiment of the present invention, PMI / CQI of a limited rank can be transmitted in one of the band circulation report periods.

(Example 3-A-2)
Another example of PMI / CQI feedback mode based on restricted rank is described below.

  According to the present embodiment, the PMI / CQI feedback mode of the restricted rank can be set to always have a constant feedback mode regardless of the PMI / CQI feedback mode of the rank recommended by the terminal. . For example, a limited rank PMI / CQI may be configured to always have a feedback mode that reports WB PMI and WB CQI.

(Example 3-B-1)
An embodiment of the present invention relating to a feedback scheme when a multiple-granular precoder is defined will be described.

  The multi-unit precoder can be composed of a combination of two different codebooks (W1 and W2). W1 and W2 can be composed of various codebooks. As a result, the base station can receive different types of feedback indicators (W1 and W2) regarding the precoder and select the entire precoder. Different information about the precoder (W1 and W2) may be reported at different times. For example, W1 may be reported in a long-term and W2 may be reported in a short-term. When W1 is reported in long-period, it may be reported with rank information. Alternatively, W1 may be reported along with W2. That is, when a multi-unit precoder is applied, the transmission timing of feedback information can be set as shown in Table 20.

表２０のモード（１）のように、ランク情報（ＲＩ）及びＷＢ Ｗ１が同一の時点（Ｔ１）で伝送され、その後の任意の時点（Ｔ２）でＷＢ Ｗ２及びＷＢ ＣＱＩが伝送されうる。または、表２０のモード（２）のように、ランク情報（ＲＩ）がＴ１で伝送され、その後の任意の時点（Ｔ２）でＷＢ Ｗ１、ＷＢ Ｗ２及びＷＢ ＣＱＩが伝送されてもよい。

As in mode (1) of Table 20, rank information (RI) and WB W1 may be transmitted at the same time (T1), and WB W2 and WB CQI may be transmitted at any subsequent time (T2). Alternatively, as in mode (2) in Table 20, rank information (RI) may be transmitted at T1, and WB W1, WB W2, and WB CQI may be transmitted at an arbitrary time point (T2) thereafter.

  In this way, it is possible to consider a case where PMI / CQI of a limited rank is fed back in a situation where the indicators W1 and W2 regarding the precoder are reported at different timings or at the same timing. If PMI / CQI with a limited rank is reported, W1 and W2 that match the limited rank can be selected and fed back. Also, the CQI calculated based on the selected W1 and W2 can be fed back. Here, W1, W2, and CQI can be reported at the same time point (one subframe).

  With reference to FIGS. 25 and 26, a feedback scheme including PMI / CQI with a limited rank when a multi-unit precoder is applied will be described.

FIG. 25 shows that RI and PMI1 (that is, WB W1) are transmitted at the same time, and WB PMI2 (that is, WB W2) and WB CQI are transmitted at a later time. The PMI1, PMI2 and CQI transmitted here are feedback information selected and calculated according to the rank recommended by the terminal. Further, the PMI / CQI of the restricted rank is transmitted at a timing that is later than the CQI / PMI transmission timing by the rank recommended by the terminal by a predetermined offset (N _{offset, CQI} ). In FIG. 25, PMI1, PMI2 and CQI with restricted rank are

のインタイミングで伝送されている。

Is transmitted in-timing.

FIG. 26 shows that RI is transmitted and WB PMI1 (that is, WB W1), WB PMI2 (that is, WB W2), and WB CQI are transmitted at the same time thereafter. Here, the transmitted PMI1, PMI2, and CQI are feedback information selected and calculated according to the rank recommended by the terminal. Further, the PMI / CQI of the restricted rank is transmitted at a timing that is later than the CQI / PMI transmission timing by the rank recommended by the terminal by a predetermined offset (N _{offset, CQI} ). In FIG. 26, PMI1, PMI2 and CQI with restricted rank are

のタイミングで伝送されている。

It is transmitted at the timing.

(Example 3-B-2)
Another embodiment of the present invention relating to a feedback scheme when a multiple-granular precoder is defined will be described.

  When the base station receives the multi-unit precoder indicator (ie, W1 and W2), a different feedback mode may be indicated using a precoder type indication (PTI) bit.

  One feedback mode is a mode in which RI, W1, and W2 / CQI are transmitted in different subframes, and W1, W2, and CQI are set in WB information. Another feedback mode is a mode in which W2 and CQI are reported in the same subframe, and the W2 / CQI frequency unit is WB or SB depending on the reported subframe. That is, the feedback mode can be defined as shown in Table 21.

表２１で、ＰＴＩが０の値を有する場合には、Ｔ１でＲＩが伝送され、その後の任意の時点（Ｔ２）でＷＢ Ｗ１が伝送され、その後の任意の時点（Ｔ３）でＷＢ Ｗ２及びＷＢ ＣＱＩが伝送されるモードによってフィードバックが行われる。表２１で、ＰＴＩが１の値を有する場合には、Ｔ１でＲＩが伝送され、その後任意の時点（Ｔ２）でＷＢ Ｗ１及びＷＢ ＣＱＩが伝送され、その後の任意の時点（Ｔ３）でＳＢ Ｗ２及びＳＢ ＣＱＩが伝送されるモードによってフィードバックが行われる。

In Table 21, when PTI has a value of 0, RI is transmitted at T1, WB W1 is transmitted at an arbitrary time point (T2), and WB W2 and WB are transmitted at an arbitrary time point (T3) thereafter. Feedback is performed according to the mode in which CQI is transmitted. In Table 21, when PTI has a value of 1, RI is transmitted at T1, and then WB W1 and WB CQI are transmitted at an arbitrary time (T2), and SB W2 at an arbitrary subsequent time (T3). And feedback is performed according to the mode in which the SB CQI is transmitted.

  The mode (1) or mode (2) shown in Table 21 can be determined in accordance with the feedback period of the rank information. When mode (1) or mode (2) is determined by PTI, WB W1, WB W2 / WB CQI is reported in accordance with the CQI period (mode (1)), or WB W2 / WB CQI, SB W2 / SB CQI can be reported (mode (2)). The reported period reference may be the transmission timing of WB W2 / WB CQI. The transmission timing of other feedback information can be determined by an offset with respect to the transmission timing of the WB W2 / WB CQI.

  In the feedback method according to the present embodiment, a method for setting the period and offset in which WB W1 is fed back will be described below.

  As a first solution, the transmission period of WB W1 can be set to a period longer (that is, lower frequently) than the period in which the PTI / RI is transmitted. Further, the cycle of WB W1 can be set to an integral multiple of the cycle in which WB W2 / WB CQI is transmitted. Also, the WB W1 transmission timing can be set as an offset value with respect to the reference timing (that is, the transmission subframe of WB W2 / WB CQI).

  As a second method, the transmission timing of WB W1 can be set as an offset value with respect to the reference timing (that is, the transmission subframe of WB W2 / WB CQI). Then, when the PTI is set to a predetermined value (0 or 1) in the PTI / RI feedback information, it can be set that WB W1 is transmitted once immediately after the PTI / RI transmission timing.

  In the feedback scheme according to the present embodiment, a scheme in which PMI / CQI of a limited rank is fed back will be described below. The WB W1, WB W2, WB CQI, SB W2 and SB CQI are feedback information selected and calculated according to a rank recommended by the UE, and additionally, a PMI / CQI of a limited rank is transmitted. be able to. If PTI reported with RI is set to 0, WB PMI / WB CQI can be reported as PMI / CQI with limited rank. The restricted ranks WB W1, WB W2 and WB CQI report at the same timing. In some subframes in which WB W2 + WB CQIs according to ranks recommended by the terminal are reported, WB W1, WB W2, and WB CQIs of limited ranks can be reported simultaneously.

  Alternatively, a PMI / CQI with a limited rank can be reported when the PTI reported with the RI is set to 1. At this time, two methods can be considered as a method for reporting PMI / CQI of a restricted rank.

  One approach may be to report only the restricted rank WB W1, WB W2 and WB CQI as the restricted rank PMI / CQI.

  Another method is to report limited rank WB W1, WB W2 and WB CQI in one subframe, and report limited rank SB W2 and SB CQI in another subframe, Can be set according to the band cycle reporting period.

Example 4
In the fourth embodiment, a method for determining the number of bits of different precoder indexes constituting the entire precoder will be described.

  Tables 11 to 18 above define a codebook defined for CSI reporting in a base station having 8 transmission antennas in a 3GPP LTE system. In the codebook for CSI reporting as shown in Table 11 to Table 18, codebook elements can be determined by two feedback reports. In Tables 11 to 18, these two feedback report values are expressed by i1 and i2, which are concepts corresponding to the above-described precoder indexes W1 (or PMI1) and W2 (or PMI2), respectively. . The two report values may be set to have different timings and different frequency units. The number of elements constituting the code book (# of elements) is set to have different values depending on the number of ranks recommended by the terminal for transmission, and can be expressed as shown in Table 22 below. .

表２２によれば、ｉ１は、ランクによって１６、４または１の要素（ｅｌｅｍｅｎｔ）を有するように定義され、ｉ２は、ランクによって１６、８または１の要素を有するように定義される。そして、フィードバックのためにｉ１を０乃至４ビットで表現し、ｉ２を０乃至４ビットで表現することができる。ランクによるｉ１及びｉ２の表現可能な最大ビット数（Ｍａｘｉｍｕｍ ｂｉｔｓ）は、表２３のように表すことができる。

According to Table 22, i1 is defined to have 16, 4 or 1 elements by rank, and i2 is defined to have 16, 8 or 1 elements by rank. For feedback, i1 can be represented by 0 to 4 bits, and i2 can be represented by 0 to 4 bits. The maximum number of bits (Maximum bits) that can be represented by i1 and i2 by rank can be expressed as shown in Table 23.

フィードバック情報を報告するために定義される制御チャネルの容量の限界により、ＣＳＩ報告のためのｉ１及びｉ２を表現できるビットに制約が適用されることがある。すなわち、ＣＳＩ報告のためにはｉ１及びｉ２の両方を伝送しなければならないが、ｉ１のための指示子（ｉｎｄｉｃａｔｏｒ）及び／またはｉ２のための指示子がＲＩまたはＣＱＩと同時に伝送される場合には、既存の３ＧＰＰ ＬＴＥリリース−８またはリリース−９で定義しているＲＩまたはＣＱＩを報告するチャネルのエラー率（ｅｒｒｏｒ ｒａｔｅ）並みのエラー率を有するようにしながらフィードバック情報を送ることを考慮することができる。

Due to the limited capacity of the control channel defined to report feedback information, constraints may be applied to the bits that can represent i1 and i2 for CSI reporting. That is, both i1 and i2 must be transmitted for CSI reporting, but an indicator for i1 and / or an indicator for i2 is transmitted simultaneously with RI or CQI. Consider sending feedback information with an error rate comparable to the error rate of the channel reporting RI or CQI defined in the existing 3GPP LTE Release-8 or Release-9 Can do.

  For example, when the indicator for i1 and / or the indicator for i2 is transmitted simultaneously with the RI or CQI, the RI is reported in one subframe and the indication for i1 in the other subframe. Consider the case where the child, the indicator for i2, and the CQI are reported simultaneously. As another example, a case where an indicator for RI and i1 is simultaneously reported in one subframe and an indicator and CQI for i2 are simultaneously transmitted in another subframe may be considered.

  In existing 3GPP LTE Release-8 or Release-9, transmission of up to 2 bits is assumed for RI, and the same coding method as ACK / NACK can be used for RI transmission using PUCCH. In addition, in order to report CQI / PMI, transmission of a maximum of 11 bits is assumed. Therefore, coding can be performed using an RM (Reed-Muller) code that can support up to 13 bits.

  Assuming i1 / i2 / CQI is reported simultaneously in systems supporting extended antenna configurations (eg, 3GPP LTE Release-10 systems), a maximum of 15 (= 4 + 4 + 7) bits for rank-1 or 2 Is required. For 15-bit transmission, it is possible to consider applying a coding method for extending an existing RM code or reporting a control signal using a convolutional code defined in the existing. It can also be considered to reduce the size of the indicator bits for i1 and i2 to have the same level as the maximum bit size defined in the existing system.

  Table 24 summarizes the number of bits required when i1 / i2 / CQI is reported at the same time. When the indicator bits for i1 and i2 are 0 to 4, one subframe is used. Represents the number of bits transmitted. Also, depending on the rank, the number of indicator bits for i1 or i2 may be a full set (full set) or a subset (subset). For example, if the indicator bit for i1 is 4 and the indicator bit for i2 is 4, the full set of codebooks can be used for both rank-1 and rank-2 transmissions. Or, if 2 bits are used for i1 (or W1) and 4 bits are used for i2 (or W2), then in rank-1 or 2, use a subset of i1, a full set of i2 In rank-3, both i1 and i2 can use the full set. In Table 24, F represents a full set and S represents a subset. In addition, in the expression F / F, F / S, S / F or S / S in Table 24, the one displayed before “/” indicates the bit for i1, and the one displayed after “/” Means the bit for i2.

ＰＵＣＣＨを用いたフィードバック伝送において既存のコーディング方法を適用したり、既存のフィードバックチャネル並みのエラー率を得るために、一つのサブフレームで１３ビット以下のビットを伝送することが考えられる。ここで、少なすぎる個数のコードブック要素を含むサブセットを用いる場合は、実際のチャネル状態に適合したＣＳＩを表現するためのコードブック要素が当該サブセットに含まれる確率が低くなるため、伝送の収率が低下することがある。そのため、フィードバックビットの数を減少させながらも適度レベルのサブセットを用いなければならない。

In order to apply an existing coding method in feedback transmission using PUCCH or to obtain an error rate similar to that of an existing feedback channel, it is conceivable to transmit 13 bits or less in one subframe. Here, if a subset including an excessively small number of codebook elements is used, the probability that the codebook elements for expressing CSI adapted to the actual channel state are included in the subset is low, and therefore the transmission yield. May decrease. Therefore, a moderate level subset must be used while reducing the number of feedback bits.

  For example, for rank-1 and rank-2, i1 and i2 each require a maximum of 4 bits, but (bit for i1 indicator / bit for i2 indicator) is (4/3), It can be considered to use a subset of indices such as (4/2), (3/3), (3/2), (2/3), (2/2).

  Also, a subset of indexes may be used according to rank, or a full set may be used. For example, in order to adjust the level to a maximum of 11 bits, it can be considered to use 2 bits / 2 bits for i1 / i2. At this time, consider that 2 bits / 2 bits are used in ranks 1 to 4, 2 bits / 0 bits are used in ranks 5 to 7, and 0 bits / 0 bits are used in rank-8. Can do. Alternatively, it can be considered to use 3 bits / 2 bits for i1 / i2 in order to match a level of up to 13 bits. At this time, 3 bits / 2 bits are used in ranks 1 to 2, 2 bits / 4 bits are used in rank-3, 2 bits / 3 bits are used in rank-4, and ranks 5-5 are used. It can be considered that 2 bits / 0 bits are used and 0 bits / 0 bits are used in rank-8. Table 25 illustrates the number of bits available for i1 / i2 by rank.

表２６は、表２５におけるｉ１／ｉ２ビット数の好適な組み合わせを表すものである。

Table 26 shows suitable combinations of the number of i1 / i2 bits in Table 25.

表２７は、は、ＲＩとｉ１インデックスとが一つのサブフレームで同時に伝送され、他のサブフレームでｉ２インデックスとＣＱＩとが同時に伝送される場合に必要とされるビットを示すものである。

Table 27 shows bits required when the RI and the i1 index are simultaneously transmitted in one subframe and the i2 index and the CQI are simultaneously transmitted in another subframe.

端末が受信し得る最大ランクまたは基地局が伝送しようとする最大ランクによって、端末が報告する最大ランク数が決定されると、ランクを指示するためのビットを決定することができる。ＲＩとｉ１とが結合して同時に伝送される場合には、フィードバックに必要な最大ビットは７（＝３＋４）ビットになり、最小ビットは５（＝１＋４）ビットになり得る。

When the maximum rank that can be received by the terminal or the maximum rank that the base station intends to transmit is determined and the maximum number of ranks reported by the terminal is determined, the bit for indicating the rank can be determined. When RI and i1 are combined and transmitted simultaneously, the maximum bit required for feedback can be 7 (= 3 + 4) bits and the minimum bit can be 5 (= 1 + 4) bits.

  Since rank information is a basis for selecting and calculating other feedback information, it needs to be transmitted robustly, and therefore, the number of bits included in a subframe in which rank is transmitted is reduced as much as possible. It is preferable. A scheme for reducing the bits of the i1 indicator for such transmission can be considered. Table 28 illustrates the number of bits that can be used for i1 / i2 by rank in consideration of such matters.

ｉ１／ｉ２のための指示子のサブセットの設定において、例えば、好むランクによってｉ１及びｉ２のサブセットのサイズが異なるように設定されてもよい。他の例として、端末のカテゴリー（ＵＥ ｃａｔｅｇｏｒｙ）によってｉ１及びｉ２のサブセットのサイズが異なるように設定されてもよい。端末のカテゴリーは端末の性能（ｃａｐａｂｉｌｉｔｙ）によって区別すればよい。

In the setting of the subset of indicators for i1 / i2, for example, the sizes of the subsets of i1 and i2 may be set to be different depending on the preferred rank. As another example, the subsets of i1 and i2 may be set differently depending on a UE category. The category of the terminal may be distinguished according to the capability of the terminal.

(Example 5)
A method for setting a codebook subset using different precoder indexes (i1 / i2) according to the present invention will be described.

  Table 29 represents a codebook suitable for the rank-1 CSI report of Table 11 described above in another manner. Rank-1 codebook is a 4 Tx DFT vector

を基本にして構成され、位相

Configured on the basis of phase

との組み合わせで表すことができる。ｉ１のインデックスが０乃至１５と定義され、ｉ２のインデックスが０乃至１５と定義される場合に、３２ＰＳＫ（Ｐｈａｓｅ Ｓｈｉｆｔ Ｋｅｙｉｎｇ）の位相を有する

Can be expressed in combination. When the index of i1 is defined as 0 to 15 and the index of i2 is defined as 0 to 15, it has a phase of 32 PSK (Phase Shift Keying)

とＱＰＳＫ（Ｑｕａｄｒａｔｕｒｅ ＰＳＫ）の位相を有する

And QPSK (Quadrature PSK) phase

とによってコードブックを構成することができる。ここで、ｉ１の隣接したインデックス同士間では同一要素（ｅｌｅｍｅｎｔ）が反復して配置されうる。

The code book can be configured with Here, the same element can be repeatedly arranged between adjacent indexes of i1.

したがって、コードブックのサブセットを構成するときは、

So when configuring a subset of the codebook,

を構成するＤＦＴ行列の位相または

The phase of the DFT matrix comprising

の位相に制限をおく方法、一つのｉ１に含まれるコードブック要素の互いに異なったｉ１のインデックスでは互いに異なったコードブック要素でｉ１を構成する方法などを考慮することができる。このような方法によってコードブックサブセットを構成することができる。

For example, a method of limiting the phase of the codebook element, a method of configuring i1 with different codebook elements at different i1 indexes of codebook elements included in one i1, and the like can be considered. A codebook subset can be constructed by such a method.

  According to using a subset of i1 and i2

が有する位相が決定される。例えば、ｉ１の指示（ｉｎｄｉｃａｔｉｏｎ）のために３ビットが用いられ、インデックスは偶数（０，２，４，６，８，１０，１２，１４）の８個が用いられ、且つｉ２の指示のために３ビットが用いられ、インデックスは０，１，２，３，８，９，１０，１１の８個が用いられるとき、

Is determined. For example, 3 bits are used for indication of i1, 8 indexes (even number (0, 2, 4, 6, 8, 10, 12, 14)) are used for indication of i1, and for indication of i2 When 3 bits are used and 8 indexes 0, 1, 2, 3, 8, 9, 10, and 11 are used,

のために１６ＰＳＫの位相を有する４Ｔｘ ＤＦＴベクトルと

4Tx DFT vector with 16PSK phase for

のためにＱＰＳＫを有するように構成することができる。

Can be configured to have QPSK.

  Thus, when the instruction bit for i1 and the instruction bit for i2 are determined, the combination of indices suitable for each bit

を構成する４Ｔｘ ＤＦＴベクトルの位相と

And the phase of the 4Tx DFT vector comprising

を構成する位相を表３０のように示すことができる。

Table 30 can show the phases that constitute.

下記の表３１は、上記の表１２のランク−２ ＣＳＩ報告に適したコードブックを、別の方式で表現したものである。ランク−２ ＣＳＩ報告ではｉ１及びｉ２のためにそれぞれ１６個のインデックス（０乃至１５）を定義する。

Table 31 below is a representation of the codebook suitable for the rank-2 CSI report of Table 12 above in another manner. Rank-2 CSI reports define 16 indices (0-15) for i1 and i2, respectively.

コードブックサブセットを構成するに当たり、このようにｉ１のための指示ビットとｉ２のための指示ビットが決定されるとき、各ビットに合うインデックスの組み合わせによって、

In constructing the codebook subset, when the indicator bit for i1 and the indicator bit for i2 are determined in this way, the combination of indices suitable for each bit is:

を構成する４ Ｔｘ ＤＦＴベクトルの位相と

4 Tx DFT vector phases constituting

を構成する位相を、表３０のように示すことができる。

Table 30 can indicate the phases that constitute.

  According to using a subset of i1 and i2

が有する位相が決定される。表３１のようにｉ１のための指示ビットとｉ２のための指示ビットが決定されるとき、各ビットに合うインデックスの組み合わせによって、

Is determined. When the indication bit for i1 and the indication bit for i2 are determined as shown in Table 31, the combination of indices suitable for each bit

を構成する４ Ｔｘ ＤＦＴベクトルの位相と

4 Tx DFT vector phases constituting

を構成する位相を、表３２のように示すことができる。

Table 32 can show the phases that constitute.

これと類似の方式により、上記の表１３乃至表１８のランク−３乃至ランク−８に適したコードブックに対して、ｉ１／ｉ２で表現されるコードブックのサブセットを選択する方案を適用することができる。

Applying a method of selecting a subset of codebooks expressed by i1 / i2 to codebooks suitable for ranks 3 to 8 in Tables 13 to 18 in a similar manner. Can do.

  For example, i2 of the rank-3 codebook of Table 13 above is composed of 16 elements from 0 to 15, each of which uses 3 vectors and 3 orthogonal beams (orthogonal beams). It consists of a matrix that generates Two types of rank-3 codebooks can be constructed using two vectors.

  For example, when i2 is 0, 1, 2, and 3, four types (type-A, type-B, type-C, and type-D) of rank-3 codebooks can be expressed as follows: it can.

Type-A has a common-phase (co-phase) with the first column (1 ^st column) being '+'

で構成され、第２列（２^ｎｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

In the configuration, the second column ⁽² nd column) has a phase - - common ''

で構成され、第３列（３^ｒｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

And the third column (3 ^rd column) has a common phase of '-'

で構成されるタイプを指す

Points to a type consisting of

。

.

Type-B has a common-phase (co-phase) where the first column (1 ^st column) is '+'

で構成され、第２列（２^ｎｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

In the configuration, the second column ⁽² nd column) has a phase - - common ''

で構成され、第３列（３^ｒｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

And the third column (3 ^rd column) has a common phase of '-'

で構成されるタイプを指す

Points to a type consisting of

。

.

Type-C has a common-phase (co-phase) where the first column (1 ^st column) is '+'

で構成され、第２列（２^ｎｄ ｃｏｌｕｍｎ）が‘＋’の共通−位相を有する

In the configuration, a common second column ⁽² nd column) is '+' - having a phase

で構成され、第３列（３^ｒｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

And the third column (3 ^rd column) has a common phase of '-'

で構成されるタイプを指す

Points to a type consisting of

。

.

Type-D has a common-phase (co-phase) where the first column (1 ^st column) is '+'

で構成され、第２列（２^ｎｄ ｃｏｌｕｍｎ）が‘＋’の共通−位相を有する

In the configuration, a common second column ⁽² nd column) is '+' - having a phase

で構成され、第３列（３^ｒｄ ｃｏｌｕｍｎ）が‘−’の共通−位相を有する

And the third column (3 ^rd column) has a common phase of '-'

で構成されるタイプを指す

Points to a type consisting of

。

.

  In the above example, the two vectors used in the codebook are

である。ｉ２＝０とｉ２＝２に対しては、第１列のためにベクトル

It is. For i2 = 0 and i2 = 2, the vector for the first column

が用いられ、ｉ２＝１とｉ２＝３に対しては、第１列のためにベクトル

For i2 = 1 and i2 = 3, the vector for the first column

が用いられる。また、ｉ２＝０とｉ２＝１に対しては、第２列及び第３列に２個の互いに異なったベクトル、すなわち、

Is used. Also, for i2 = 0 and i2 = 1, two different vectors in the second and third columns, ie,

を用いることで２列間に直交性を持たせることができる。一方、ｉ２＝２とｉ２＝３に対しては、第２列及び第３列の両方に一つのベクトル、すなわち、

Can be used to provide orthogonality between two columns. On the other hand, for i2 = 2 and i2 = 3, one vector in both the second and third columns, ie,

を用いながら、異なった共通−位相成分（‘＋’及び‘−’）を用いることで直交性を持たせることができる。

By using different common-phase components ('+' and '-'), the orthogonality can be provided.

  Next, when the case of i2 = 0, 1, 2, 3 and the case of i2 = 4, 5, 6, 7 in the rank-3 codebook of Table 13 are compared, the vectors constituting the codebook are different. You can see that That is, for i2 = 0, 1, 2, 3,

ベクトルが用いられるが、ｉ２＝４，５，６，７に対しては

A vector is used, but for i2 = 4, 5, 6, 7

ベクトルが用いられる。

A vector is used.

  Using the types A to D defined above, the rank-3 codebook generator matrix can also be expressed as in Table 33 below.

コードブック指示に必要なビットサイズを減らすための方法にサブ−サンプリング（ｓｕｂ−ｓａｍｐｌｉｎｇ）を適用することを考慮することができる。

It can be considered to apply sub-sampling to the method for reducing the bit size required for codebook indication.

  For example, it can be considered to reduce the size of the two instruction bits constituting the rank-3 codebook to the bits shown in Table 34.

コードブック指示のための全体ビットサイズを４ビットにする３つの方案（すなわち、ｉ１＋ｉ２＝０＋４、１＋３または２＋２）を考慮することができる。このうち、ｉ１を０ビットにすると、すなわち、１個の要素で構成するようになると、ビームの解像度（ｂｅａｍ ｒｅｓｏｌｕｔｉｏｎ）が低下して性能が大幅に低くなることがある。以下では、ｉ１を０ビットにする方案以外の方案について説明する。

Three schemes (ie, i1 + i2 = 0 + 4, 1 + 3 or 2 + 2) in which the total bit size for codebook indication is 4 bits can be considered. Among these, if i1 is 0 bits, that is, if it is configured by one element, the beam resolution may be lowered and the performance may be significantly lowered. Hereinafter, a method other than the method of setting i1 to 0 bits will be described.

  First, a method of configuring a subset of i1 and a subset of i2 when 1 bit is allocated for i1 and 3 bits are allocated for i2 will be described.

  When a subset is selected and used from the overall indexes of i1 and i2, the codebook elements that can be generated differ depending on which index is selected. Appropriate selection is required.

  When i1 is assigned with 1 bit, two indexes can be selected from the indexes (0, 1, 2, 3) of i1. The number of vectors that can be used for the material constituting the codebook is 12 or 16 depending on which one is selected from the indices (0, 1, 2, 3) of i1. For example, if (0, 1) is selected from the indexes (0, 1, 2, 3) of i1,

（ｍ＝０，２，４，６，８，１０，１２，１４，１６，１８，２０，２２）の１２個のベクトルが使用可能である。他の例として、ｉ１のインデックス（０，１，２，３）の中から（０，２）を選択すると、

Twelve vectors (m = 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22) can be used. As another example, when (0, 2) is selected from the indexes (0, 1, 2, 3) of i1,

（ｍ＝０，２，４，６，８，１０，１２，１４，１６，１８，２０，２２，２４，２６，２８，３０）の１６個のベクトルが使用可能である。すなわち、ｉ１＝（０，１）のとき、ｉ１＝０とｉ１＝１に対して重複したベクトルを用いる場合があり、Ｉ１＝（０，２）のときは、ｉ１＝０とｉ１＝２に対して互いに異なったベクトルを用いることとなる。したがって、ビーム解像度（ｂｅａｍ ｒｅｓｏｌｕｔｉｏｎ）の観点ではＩ１＝（０，２）を用いることが好ましい。

Sixteen vectors (m = 0, 2, 4, 6, 8, 10, 12, 14, 16, 18, 20, 22, 24, 26, 28, 30) can be used. That is, when i1 = (0,1), there are cases where overlapping vectors are used for i1 = 0 and i1 = 1, and when I1 = (0,2), i1 = 0 and i1 = 2. On the other hand, different vectors are used. Therefore, it is preferable to use I1 = (0, 2) from the viewpoint of beam resolution.

  On the other hand, when i2 is assigned with 3 bits, eight indexes can be selected from the 16 i2 indexes from 0 to 15. The first way to select the 8 indexes is to select the i2 index to include various vectors to increase the beam resolution, the second method generates rank-3 elements Select to include all four types (type-A, B, C, D).

  The first method is, for example, (0, 1, 2, 3), (4, 5, 6, 7), (8, 9, 10, 11), (12, 13, 14, 15) of the index of i2. ), Two of the four groups are selected and eight indexes are taken. For example, if eight of (0, 2), (4, 6), (8, 10), (12, 14) are selected as i2 indexes, type-A / type-C using eight vectors. A rank-3 codebook element to which the above method is applied can be generated. As another example, if eight of (1, 3), (5, 7), (9, 11), and (13, 15) are selected as indices of i2, type-B / A rank-3 codebook element applying the type-D method can be generated.

  The second method includes, for example, (0, 1, 2, 3), (4, 5, 6, 7), (8, 9, 10, 11), and (12, 13, 14, 15). It is possible to select two groups from these groups and take eight indexes. Looking at the matrix making up the rank-3 codebook, it can be seen that +1 and -1 are used as the common-phase (co-phase) components. There are also vectors that can form an 8 Tx DFT vector with common-phase components. For example, in the case of vectors 0, 8, 16, and 24, an 8 Tx DFT vector can be formed by using +1 as the common-phase component. As another example, in the case of vectors Nos. 4, 14, 20, and 28, if -1 is used as the common-phase component, an 8 Tx DFT vector can be formed. Considering a co-polarized antenna configuration, higher performance can be achieved using 8 Tx DFT vectors.

  Since the common-phase components used in the matrix constituting the rank-3 codebook are +1 and -1, 0, 8, 16, 24, 4 which can form an 8 Tx DFT vector using this common-phase component. , 14, 20 and 28 are preferably selected to include the i2 index. For example, (0, 1, 2, 3), (8, 9, 10, 11) can be selected as the index of i2.

  Next, a method of configuring a subset of i2 when 2 bits are allocated for i1 and 2 bits are allocated for i2 will be described below. Since i1 has indexes 0, 1, 2, and 3, all indexes can be expressed using 2 bits.

  For example, the index 0 to 15 of i2 is set to 4 of (0, 1, 2, 3), (4, 5, 6, 7), (8, 9, 10, 11), (12, 13, 14, 15). As a method of selecting a subset of the index of i2 when dividing into groups, one group is selected and all four elements of the group are used, or one from each of the four groups. Select an index to configure 4 elements, or select 2 groups from 4 groups and select 2 indexes from each of the selected groups to configure 4 elements Can be considered.

  The number of cases in which two of the four types-A / B / C / D constituting the rank-3 codebook element can be used selectively is 6, and in each case (A, B), (A, C), (A, D), (B, C), (B, D), (C, D).

  The number in the case of selecting two groups from the four groups of the index of i2 is six. When the corresponding group is indicated by the number of the first vector of the index group of i2, each group can be expressed as the 0th, 4th, 8th, and 12th groups. In each case of selecting 2 groups from 4 groups Are (0,4), (0,8), (0,12), (4,8), (4,12), (8,12).

  Therefore, the combination of the six cases for the rank-3 codebook element construction method and the six cases for selecting the vector group generates a method for constructing a total of 36 i2 index subsets.

  By way of example of the present invention described above, a rank-3 codebook is assigned 1 bit for i1, 3 bits for i2, and 2 bits for i1, i2 An example of configuring a subset of i1 and a subset of i2 when 2 bits are allocated for can be shown as Table 35 below.

ランク４に対するコードブックを構成する場合にも、次のような方法のサブサンプリングを考慮することができる。例えば、前述したランク−３コードブックを構成する２個の指示子（ｉ１及びｉ２）のビットサイズを、下の表３６のように減らすことを考慮することができる。

Even when a code book for rank 4 is constructed, subsampling of the following method can be considered. For example, it can be considered to reduce the bit sizes of the two indicators (i1 and i2) constituting the rank-3 codebook as shown in Table 36 below.

ランク−４コードブックについても、前述したランク−３コードブックでサブセットを選択するのと類似の原理によって、ｉ１及びｉ２のインデックスのサブセットを選択することができる。重複する説明は明瞭性のために省略する。

For the rank-4 codebook, a subset of the indices of i1 and i2 can be selected by a similar principle to selecting a subset in the rank-3 codebook described above. Duplicate descriptions are omitted for clarity.

  For a rank-4 codebook, 1 bit is allocated for i1, 3 bits are allocated for i2, and 2 bits are allocated for i1 and 2 bits are allocated for i2. In this case, an example of configuring a subset of i1 and a subset of i2 can be shown as in Table 37 below.

一方、上記のように選択されたコードブックサブセットは、ＰＵＳＣＨ報告において用いられてもよい。例えば、ＰＵＳＣＨ報告モード１−２のように各サブ帯域別にＰＭＩを報告するモードにおいて、ＰＭＩに対するフィードバックオーバーヘッドを減らすための方法にｉ１／ｉ２のサブセットを用いることができる。このとき、ｉ１に対してはＷＢで一つのインデックスが報告され、ｉ２に対してはＳＢ別にインデックスが報告されるとよい。

Meanwhile, the codebook subset selected as described above may be used in PUSCH reporting. For example, in a mode in which PMI is reported for each subband, such as PUSCH reporting mode 1-2, a subset of i1 / i2 can be used as a method for reducing feedback overhead for PMI. At this time, one index may be reported by WB for i1, and an index may be reported by SB for i2.

  In the 3GPP LTE Release-10 system, a mode in which SB CQI and SB PMI are reported can be considered as a new PUSCH reporting mode. Even in such a reporting mode, the codebook subset can be used as a method for reducing the reporting bits for representing the codebook. At this time, one index may be reported by WB for i1, and an index may be reported by SB for i2.

(Example 6)
In the sixth embodiment, a method for defining a PUCCH periodic report mode of multiplex control information and determining a transmission priority (priority) applicable when reporting control information will be described.

  As described in connection with Table 5 above, the terminal transmits various control information (RI, PMI, CQI) according to the PUCCH reporting mode (modes 1-0, 1-1, 2-0, 2-1). Periodic feedback can be performed using the PUCCH, and the periodic feedback of the UE can be semi-statically set by an upper layer. Depending on whether the downlink transmission is a single antenna transmission, a transmission diversity transmission, a closed-loop spatial multiplexing transmission, a dual layer transmission, or the like, an appropriate PUCCH reporting mode is determined for the downlink transmission. It should be applied. Also, there are four CQI / PMI / RI feedback types related to the PUCCH reporting mode. Type 1 is CQI feedback for the subband selected by the terminal. Type 2 is WB CQI feedback and WB PMI feedback. Type 3 is RI feedback. Type 4 is WB CQI feedback.

  On the other hand, in the existing 3GPP LTE Release-8 or Release-9 system, it is dropped when various control information collides in uplink transmission (that is, when the control information is set to be transmitted in the same subframe). (Drop) Defines possible control information.

  Specifically, in the feedback using PUCCH, when RI transmission and WB CQI / PMI collide (that is, set to be transmitted in the same subframe), WB CQI / PMI. Can be dropped. Alternatively, in the feedback using PUCCH, when RI transmission and SB CQI collide, SB CQI may be dropped. Further, when positive SR and RI / PMI / CQI collide, RI / PMI / CQI may be dropped. In addition, when an uplink-shared channel (UL-SCH) to which a subframe bundling operation is applied and a periodic RI / PMI / CQI report collide with each other, the periodic CQI / PMI / RI reports can be dropped, and periodic CQI / PMI and / or RI need not be multiplexed with the PUSCH transmission of the corresponding subframe. In addition, when HARQ-ACK and RI / PMI / CQI collide with each other in a subframe in which PUSCH is not transmitted and the predetermined parameter (simultaneousAckNackAndCQI) value provided by the higher layer is 1, CQI / PMI on PUCCH / RI is multiplexed with HARQ-ACK, otherwise CQI / PMI / RI may be dropped.

  As described above, 3GPP LTE Release-8 / 9 defines that limited control information is reported when multiple control information must be simultaneously transmitted in the time of one subframe. Transmission priorities applied in the event of a collision of control information and the like can be summarized as SR, HARQ-ACK, UL-SCH (in the case of subframe bundling operation)> RI> WB CQI / PMI, WB CQI, SB CQI. it can.

  In a system supporting an extended antenna configuration, it can be considered that two different indices (i1 and i2) for the precoder are fed back. Accordingly, it is necessary to determine the transmission priority when the RI, I1, I2, and CQI collide. Prior to determining the transmission priority of these control information, it is necessary to define a report mode that defines the timing for reporting these control information.

(Example of PUCCH report mode)
First, in periodic CQI / PMI / RI transmission, CQI, CQI / PMI, preferred subband selection and CQI information can be calculated based on the last reported periodic RI, subband selection and The CQI value can be calculated based on the last reported periodic WB PMI and RI. The two precoder indexes (I1 and I2) may be reported at different timings or may be reported at the same timing. In consideration of such matters, for example, a reporting mode as shown in Table 38 can be considered in transmission of feedback information.

表３８で、Ｉ１とＩ２は、プリコーダ要素（ｐｒｅｃｏｄｅｒ ｅｌｅｍｅｎｔ）で構成されたコードブックのインデックスを意味する。また、ＰＴＩは、プリコーダ種類指示（Ｐｒｅｃｏｄｅｒ Ｔｙｐｅ Ｉｎｄｉｃａｔｉｏｎ）ビットを意味する。

In Table 38, I1 and I2 represent codebook indexes composed of precoder elements. Also, PTI means a precoder type indication (Precoder Type Indication) bit.

  In Mode 1-1-1 of Table 38, the precoder index I1 represents the index of the precoder calculated and selected based on the RI transmitted in the current subframe. The precoder index I2 represents the index of the precoder calculated and selected based on the last reported RI and the last reported I1. The CQI represents a value calculated based on the last reported RI, the last reported I1, and the current reported I2.

  In Mode 1-1-2 in Table 38, precoder indexes I1 and I2 represent precoder indexes calculated and selected based on the last reported RI. CQI represents a value calculated based on the last reported RI, currently reported I1 and I2.

  In Mode 2-1 (1) of Table 38, the precoder index I1 represents the precoder index calculated and selected based on the last reported RI. The precoder index I2 represents the precoder index calculated and selected based on the last reported RI and the last reported I1. The CQI represents a value calculated based on the last reported RI, the last reported I1, and the current reported I2. When (I1) and (I2 + CQI) are reported during a transmission period of (RI + PTI), (I1) can be reported once and (I2 + CQI) can be reported multiple times. Alternatively, when (I1) and (I2 + CQI) are reported during a transmission period of (RI + PTI), (I1) can be reported twice and (I2 + CQI) can be reported multiple times. Alternatively, (I1) may be reported continuously. Alternatively, (I1) may be reported alternately with (I2 + CQI). Alternatively, (I1) may be reported immediately after (RI + PTI) is reported, and may be reported before the next (RI + PTI) is reported.

  In Mode 2-1 (2) of Table 38, the precoder index I2 represents the precoder index calculated and selected based on the last reported RI. The precoder index I2 represents the precoder index calculated and selected based on the last reported RI and the last reported I1. The CQI represents a value calculated based on the last reported RI, the last reported I1, and the current reported I2. SB CQI and SB I2 represent values and indices calculated and selected based on the last reported RI and the last reported I1.

  Hereinafter, Mode 2-1 in Table 38 will be specifically described.

  Mode 2-1 in Table 38 above (Mode 2-1 (1) and 2-1 (2)) may correspond to a report mode in an expanded form of PUCCH report mode 2-1 in Table 5 above. PUCCH reporting mode 2-1 in Table 5 above is a PUCCH reporting mode defined in the 3GPP LTE Release-8 / 9 system, and is defined as a mode for reporting WB PMI / CQI and SB CQI. Here, SB CQI means CQI of SB selected from BP. Since the BP is a subset of the system bandwidth and the BP that can be defined within the system bandwidth is cyclically selected in time order to report the CQI of the BP, a large number of SB CQIs can be reported. That is, (RI)-(WB PMI / CQI)-(SB CQI at the first BP)-(SB CQI at the second 2 BP) -...- (SB CQI at the nth BP) RI / PMI / CQI can be reported in chronological order. At this time, if the PMI / CQI reporting period and offset are determined through RRC signaling, the WB PMI / CQI and SB CQI can be reported in accordance with the set reporting period. Then, the RI is set to have an integer multiple period based on the period in which the WB PMI / CQI is reported, and an offset indicator is used to compare the set offset with the WB PMI / CQI transmission timing. Can be set to be reported before a subframe.

  For a PUCCH reporting mode in a system supporting an extended antenna configuration (for example, 3GPP LTE Release-10 system), a reporting mode is defined by extending the PUCCH reporting mode 2-1 in Table 5 as described above. be able to.

  In 3GPP LTE Release-8 / 9 system, there are four feedback types as CQI / PMI / RI feedback types for PUCCH reporting mode (ie, type 1 is CQI feedback for selected subband of terminal and type 2 is WB CGPI feedback and WB PMI feedback, type 3 is RI feedback, and type 4 is WB CQI feedback.) Is defined for PUCCH reporting mode in 3GPP LTE Release-10 systems as well. For example, four CQI / PMI / RI feedback types can be defined. For example, report type 1 is RI / PTI feedback, report type 2 is WB I1 feedback, report type 3 is WB I2 / CQI feedback, and report type 4 is defined as SB I2 / CQI feedback. can do. The type used for reporting can be determined according to the type 1 PTI setting. For example, if type 1 PTI = 0, type 1 -type 2 -type 3 are used for reporting, and if type 1 PTI = 1, type 1 -type 3 -type 4 are used for reporting. Can be defined. Thereby, Mode 2-1 (1) and Mode 2-1 (2) in Table 38 above can be defined.

  As in the case of transmission of two transmission antennas or transmission of four transmission antennas, when indicating a precoder element using one precoder index, the PTI is always set to 1 (setting) Type 1 -type 3 -type 4 can be defined to be used for reporting. The difference between this method and the reporting method in the 3GPP LTE Release-8 / 9 system is that SB PMI / CQI is transmitted in type 4. In order to ensure that Type 4 transmissions in 3GPP LTE Release-10 systems operate similarly to 3GPP LTE Release-8 / 9 systems, they are reported cyclically to one or more BPs within the system bandwidth. Can be defined as reporting PMI / CQI for the preferred SB within the BP. In such a case, the type 3 or type 4 reporting period may be determined in the same manner as the PMI / CQI period setting in the 3GPP LTE Release-8 / 9 system. For example, type 3 and type 4 can be reported according to the period set for PMI / CQI. The period for type 1 can also be determined in the same manner as the period setting of RI in the 3GPP LTE Release-8 / 9 system. For example, the type 1 reporting period can be set to have an integer multiple relationship with respect to the type 3 reporting period. Then, an offset value can be set so that type 1 is transmitted in a specific number of previous subframes based on a subframe in which type 3 is reported.

  On the other hand, when the precoder element is indicated using two different precoder indexes as in the case of eight transmission antenna transmissions, (type 1 -type 2 -type 3) or (type 1 -type 3) depending on the PTI value. Type 3-Type 4) can be reported. When selecting two different sets of feedback types by PTI, the reporting period for each feedback type must be determined. A specific method for notifying the reporting period applied to each feedback type is described below.

  As a first plan, when the period of type 1 (RI + PTI) is set regardless of the indication of PTI, the period of type 1 (RI + PTI) is type 3 when PTI = 1 (ie, It can be set based on type 3) in the reporting mode of type 1-type 3-type 4 order.

  As a second method, when the period of type 1 (RI + PTI) is set regardless of the indication of PTI, the period of type 1 (RI + PTI) is type 3 when PTI = 0 (ie, It can be set based on type 3) in the reporting mode of type 1-type 2-type 3 order.

  As a third method, when the type 1 (RI + PTI) cycle is set without an instruction from the PTI, the type 1 (RI + PTI) cycle is type 2 when PTI = 0 (ie, type 1− It can be set based on type 2) in the report mode of type 2-type 3 order.

  As a fourth method, the type 1 (RI + PTI) cycle can be set differently depending on the PTI instruction. For example, when PTI = 1, one cycle for transmission of one type 3 (WB I2 / CQI) and one or more types 4 (SB I2 / CQI) is set. Sometimes, the period of type 1 (RI + PTI (= 1)) can be set to an integral multiple of the one cycle. On the other hand, when one cycle for transmission of one type 2 (WB I1) and one type 3 (WB I2 / CQI) is set when PTI = 0, type 1 (RI + PTI (= 0) ) Can be set to an integral multiple of the one cycle. In this way, the minimum circulation required when PTI = 0 and PTI = 1 can be set to be different from each other.

  As a fifth method, when the interval required for CQI / PMI transmission when PTI = 1 is different from the interval required for CQI / PMI transmission when PTI = 0, The repetitive transmission of feedback information may be performed in the shorter section with the longer section as a reference. For example, transmission of one type 2 (WB I1) and one type 3 (WB I2 / CQI) is required when PTI = 0, and one type 3 (WB I2 /) when PTI = 1. If transmission of CQI) and a plurality of type 4 (SB I2 / CQI) is required, the case of PTI = 0 corresponds to a short interval, and the case of PTI = 1 corresponds to a long interval. In this case, a short section can be repeated by an amount corresponding to the length of the long section. That is, it is possible to repeatedly transmit type 2 and / or type 3 in the case of PTI = 0. Here, after type 2 is reported, type 3 may be reported repeatedly, and both type 2 and type 3 may be reported repeatedly.

  As a sixth method, when the interval required for CQI / PMI transmission when PTI = 1 is different from the interval required for CQI / PMI transmission when PTI = 0, A part of the report content of the longer section may be dropped or transmitted in the next type 1 transmission section based on the section having the shorter section. For example, transmission of one type 2 (WB I1) and one type 3 (WB I2 / CQI) is required when PTI = 0, and one type 3 (WB I2 /) when PTI = 1. When transmission of CQI) and a plurality of type 4 (SB I2 / CQI) is required, the case of PTI = 0 corresponds to a short section, and the case of PTI = 1 corresponds to a long section. In this case, one type 3 and one type 4 can be reported by dropping some information (for example, type 4) in the case of PTI = 1 having a longer interval. In addition, when Type 4 reports CQI / PMI in the band circulation method, CQI / PMI of BP different depending on the Type 1 transmission section may be transmitted.

  Meanwhile, an example of the PUCCH report mode applicable in the 3GPP LTE Release-10 system described above will be described more specifically.

  In response to various downlink transmission modes being defined in the 3GPP LTE Release-10 system, various PUCCH feedback reporting modes may be defined for transmitting CSI for downlink transmission using PUCCH. . At this time, two different precoder indexes (I1 and I2) (in this specification, I1 and I2 may be referred to as PMI1 and PMI2, respectively, and may be referred to as W1 and W2, respectively). It can be considered to use and basically use the PUCCH reporting mode defined in the existing 3GPP LTE Release-8 / 9. Since PUCCH transmission resources are limited, it is required to design a PUCCH reporting mode that takes into account reporting bit width optimization using codebook subsampling (sub-sampling) or the like. Hereinafter, an example proposed in the present invention for the PUCCH feedback report mode applicable to the 3GPP LTE Release-10 system will be described.

  First, the size of the PUCCH report bit can be set not to exceed 11 bits (as in 3GPP LTE Release-8). Considering this, the bit size of each PUCCH reporting mode must be set appropriately. Also, the PUCCH report applied to the 3GPP LTE Release-10 system as an extension of the PUCCH report mode (PUCCH report modes 1-1 and 2-1 in Table 5 above) regarding PMI transmission in the 3GPP LTE Release-8 system A mode can be defined. This allows three new PUCCH reporting modes to be defined.

  PUCCH mode-A is defined as one extended form of PUCCH report mode 1-1 in Table 5, PUCCH mode-B is defined as another extended form of PUCCH report mode 1-1 in Table 5, and the above table PUCCH mode-C can be defined as an extension of 5 PUCCH reporting modes 2-1. Modes A, B, and C correspond to Modes 1-1-1, 1-1-2, and 2-1 in Table 38, respectively. In these three PUCCH report modes, control information transmitted at one timing (subframe) can be expressed by a report type. Hereinafter, report types transmitted in each of PUCCH report modes-A, B, and C will be described.

  In PUCCH reporting mode-A, two reporting types (type-5 and type-2a) can be used. Type-5 is joint-coded RI and W1 feedback, and type-2a is WB CQI and W2 feedback.

  In PUCCH reporting mode-B, two report types (type-3 and type-2b) can be used. Type-3 is RI feedback and type-2b is WB CQI, W1 and W2 feedback.

  In PUCCH reporting mode-C, four reporting types (type-6, type-2a, type-7 and type-8) can be used. Type-6 is joint-coded RI and PTI feedback, type-2a is WB CQI and W2 feedback, type-7 is WB W1 feedback, and type-8 is the selected band. SB CQI and W2 feedback including an indicator.

  Since these various report types are reported in different subframes, in PUCCH reporting modes-A and C where precoder indexes W1 and W2 are reported at different timings, the total precoding matrix and calculation based on it are performed. Multiple subframes (TTIs) are required to determine the CQI to be performed.

  Hereinafter, sub-sampling in the PUCCH report mode will be described. First, PUCCH reporting modes-A and B corresponding to the extension of the existing PUCCH reporting mode 1-1 will be described.

  PUCCH reporting mode-When codebook subsampling is not applied to A and B, the feedback overhead for the report type (ie, the number of bits required) is organized by rank value and expressed as in Table 39 below Can do.

表３９で、ＰＵＣＣＨモード−Ｂにおける一部のタイプ−２報告は１１ビットを超えるので、ＰＵＣＣＨ伝送ビットの制限を越えることになる。したがって、下の表４０のように、ＰＵＣＣＨモード−Ｂにおいてタイプ−２報告に対してコードブックサブサンプリングを適用することができる。

In Table 39, some Type-2 reports in PUCCH mode-B exceed 11 bits, thus exceeding the PUCCH transmission bit limit. Accordingly, as shown in Table 40 below, codebook subsampling can be applied to Type-2 reports in PUCCH mode-B.

表３９の例示で、タイプ−２ａ報告は１１ビットを超えず、サブサンプリングを必要としないが、タイプ−５報告は、タイプ−３報告に比べて２倍のビットを必要とする。タイプ−５及びタイプ−３報告がランク情報を運ぶ（ｃａｒｒｙ）ので、これらの報告タイプはロバストな信頼性（ｒｏｂｕｓｔ ｒｅｌｉａｂｉｌｉｔｙ）を有しなければならない。ランク情報はＰＵＣＣＨ報告において高い優先順位を有し、同じサブフレームで複数個のタイプが報告されなければならない場合に、ＲＩ伝送サブフレームでＣＱＩ及びＰＭＩは落ちる（ｄｒｏｐ）ことがある。このような点を考慮すると、ランクフィードバックの信頼性を高めるためにタイプ−５報告にもコードブックサブサンプリングが適用されるとよい。

In the illustration of Table 39, Type-2a reports do not exceed 11 bits and do not require subsampling, but Type-5 reports require twice as many bits as Type-3 reports. Since type-5 and type-3 reports carry rank information, these report types must have robust reliability. Rank information has a high priority in PUCCH reporting, and CQI and PMI may drop in RI transmission subframes when multiple types have to be reported in the same subframe. In view of these points, codebook subsampling may be applied to type-5 reports in order to increase the reliability of rank feedback.

  The application of subsampling to Type-5 reports can be shown, for example, in Table 41 to Table 44. Table 41 and Table 42 are examples regarding the case of maximum rank 2, Table 43 is an example regarding the case of maximum rank 4, and Table 44 is an example regarding the case of maximum rank 8.

表４１の例示は、ＲＩに対するタイプ−５のビットを５ビットに固定し、Ｗ１はフルセットとして用い得るため、システム性能を向上させることができる。

In the example of Table 41, since the type-5 bit for RI is fixed to 5 bits and W1 can be used as a full set, the system performance can be improved.

  Since the example in Table 42 uses 4 bits as the type-5 bits for the RI, the RI can be transmitted more robustly than the example in Table 36. On the other hand, since the subsampled W1 is used instead of using the full set of W1, the performance of the system may be lower than the example of Table 40. On the other hand, in the case of being configured according to the examples in Table 42, Table 43, and Table 44, since W1 and W2 of ranks 1 and 2 are configured in the same set regardless of the maximum rank, the nested characteristic is Can have.

  When the above-described PUCCH mode-A and mode-B are compared, the codebook sub-sampling for the PUCCH mode-A may reduce the beam granularity while maintaining the common-phase characteristic (co-phase property). it can. On the other hand, codebook subsampling for PUCCH mode-B provides a more precise beam unit compared to PUCCH mode-A, but lowers the common-phase characteristics.

  Next, PUCCH reporting mode-C corresponding to the extension of existing PUCCH reporting mode 2-1 will be described.

  The feedback overhead (number of feedback bits) required for PUCCH mode-C can be expressed as shown in Table 41.

表４５で示すように、タイプ−６の報告において、ＰＴＩ＝１のランク２乃至４ではタイプ−８報告のために要求されるビットが１１ビットを超えるので、これに対してコードブックサブサンプリングを適用することができる。前述のＰＵＣＣＨモード−Ｂに用いられたコードブックサブサンプリングと類似の原理をタイプ−８のＷ２に適用することができる。また、表４５に示すように、ＰＵＣＣＨモード−ＣのＲＩフィードバック信頼性は、１ビットのＰＴＩ指示によって前述のＰＵＣＣＨモード−Ｂに比べて低くなる。また、Ｗ１報告の動作周期（ｄｕｔｙ ｃｙｃｌｅ）はＲＩの動作周期に比べて長くなる。このような点を考慮して、報告されるタイプに対する報告タイミング及び優先順位を決定することができる。

As shown in Table 45, in the type-6 report, the rank 2 to 4 with PTI = 1 requires more than 11 bits for the type-8 report. Can be applied. A principle similar to the codebook subsampling used for the PUCCH mode-B described above can be applied to Type-8 W2. Further, as shown in Table 45, the RI feedback reliability of PUCCH mode-C is lower than that of PUCCH mode-B described above due to the 1-bit PTI instruction. Also, the operation cycle (duty cycle) of the W1 report is longer than the operation cycle of RI. In view of these points, the report timing and priority for the type to be reported can be determined.

(Priority of feedback information)
Control information that can be dropped when control information collides in each mode when a report mode related to transmission timing of feedback information is defined as described above will be described below.

  CQI / PMI / RI information regarding the downlink channel can be reported through the uplink channel. Since the transmission priority of each control information may be determined by the attribute of each control information (reporting period, applied bandwidth, whether to be the basis for selection / calculation of other control information, etc.) First, the attribute of the control information will be described.

  The RI bit is determined by the maximum number of layers that can be reported. RI is generally reported in a long-term compared to CQI / PMI, and can be applied in units of system bandwidth (WB) from the viewpoint of one carrier.

  The PMI may be transmitted as a codebook indicator that is a set of precoding matrices applied to downlink transmission. The codebook may be represented by a single index or may be represented by two different indexes (ie, I1 and I2). For example, in codebooks defined for 2 or 4 transmit antennas in 3GPP LTE Release-8 / 9, the precoder elements can be determined with a single index. In the codebook defined for 8 transmit antenna transmissions newly defined in 3GPP LTE Release-10 to support extended antenna configurations, the precoder element is used with two different indicators (I1, I2). Can be determined. When using I1 and I2, the period in which each index is reported and the applied frequency bandwidth can be defined differently. I1 can also be described as representing a row index of a codebook, for example. I1 is reported in a relatively long-period period or short-term period and can be applied to the system bandwidth (WB) defined in terms of one carrier. On the other hand, I2 can also be described as representing a column index of a codebook, for example. I2 is reported in a relatively short-period period, and may be applied to a system bandwidth (WB) defined in terms of one carrier wave, or may be applied in units of subbands (SB).

  If the I1 indicator is reported in a longer-period period than the I2 indicator in terms of the transmission cycle, the I1 indicator must be reported with a higher priority than the I2 indicator. In other words, if the I1 and I2 reports are set in the same subframe, I1 can be transmitted and I2 can be dropped.

  The CQI information is a value calculated based on the determined precoder and may be reported together with the I2 indicator.

  Hereinafter, the transmission priority order of feedback information will be specifically described by taking up the PUCCH reporting mode of Table 38 above.

  Mode 1-1-1 in Table 38 above defines that RI and I1 applied to WB are reported in long-period, and I2 and CQI applied to WB are reported in short-period. it can. Therefore, in Mode 1-1-1 of Table 38 above, when transmission timings of (RI + I1) and (I2 + CQI) collide, (I2 + CQI) can be lowered. That is, RI and I1 reported in the long-period can be reported with higher priority than I2 and CQI reported in the short-period.

  Mode 1-1-2 in Table 38 above can be defined as RI applied to WB is reported in long-period and I1, I2 and CQI applied to WB are reported in short-period. . In Mode 1-1-2 in Table 38 above, when the reporting periods of (RI) and (I1 + I2 + CQI) collide, (I1 + I2 + CQI) can be dropped. That is, the RI reported in the long-period can be reported with higher priority than the I1, I2 and CQI information reported in the short-period.

  In Mode 2-1 in Table 38, it can be considered that the RI has a higher priority than the PMI / CQI. That is, in Mode 2-1 (1) in Table 38 above, when (RI + PTI) and (I1) or (I2 + CQI) reporting periods collide, (I1) or (I2 + CQI) can be dropped. Also, in Mode 2-1 (2) in Table 38 above, when (RI + PTI) and (I2 + CQI) _WB or (I2 + CQI) _SB collide, (I2 + CQI) _WB or (I2 + CQI) _SB can be dropped.

  Further, in Mode 2-1 in Table 38, the attribute of information to be subsequently reported can be determined according to the indication (indication) of the PTI. When the PTI indicates 0 (that is, Mode 2-1 (1)), I1 applied to the WB is reported, and I2 and CQI applied to the WB are reported. At this time, I1 may be reported in a longer period than I2 and CQI, or may be reported in the same period. On the other hand, when PTI indicates 1 (that is, Mode 2-1 (2)), I2 and CQI applied to WB are reported, and I2 and CQI applied to SB are reported. At this time, I2 and CQI applied to WB are reported in a longer period than I2 and CQI applied to SB. In Mode 2-1, the PTI is reported along with the RI and is reported in long-period.

  In Mode 2-1, when (RI, PTI), (I1) _WB, (I2, CQI) _WB and (I2, CQI) _SB transmission cycles are viewed, (I1) _WB is longer than (RI, PTI). May be reported in Therefore, in the case of Mode 2-1, it is preferable that information on (I1) _WB is reported with higher priority than (RI, PTI) _WB. That is, when (I1) _WB and (RI, PTI) _WB collide, (RI, PTI) _WB can be dropped.

(Example 7)
In the seventh embodiment, a method for determining transmission priorities that can be applied when multiple control information is reported when multiple carriers (or carrier aggregation) is applied will be described. In the following description, the meaning that multi-carrier or carrier aggregation is applied indicates that more than one carrier (or serving cell) is configured. That is, this embodiment is applicable when a plurality of carriers (or cells) are set in the terminal.

  In multi-carrier transmission, when control information on a plurality of carriers set in the downlink is reported from the terminal to the base station using the uplink carrier, one carrier set for a specific purpose (for example, UL P -Cell) can be used to report control information. In this case, the transmission period of control information for each downlink carrier wave can be set independently for each carrier wave. That is, positive SR / HARQ-ACK / CQI / PMI / RI and the like can be reported using an uplink carrier in an independent transmission period for each carrier. If control information is carried by one uplink carrier wave, different types of control information may collide with each other. In such a case, it is determined which control information is given transmission priority. There is a need. Hereinafter, a control information transmission method of the present invention for effectively supporting downlink multiplex-carrier transmission will be described.

  As a first plan, when the timing at which HARQ-ACK information for positive SR or downlink multiplex-carrier wave is reported matches the timing at which CQI / PMI / RI is reported, CQI / PMI / You can drop the RI.

  As a second method, the CQI / PMI / RI information of the downlink dedicated carrier is set to be reported in an independent transmission period, and the priority of CQI / PMI / RI reporting is determined by the priority of the downlink carrier. be able to. For example, if carrier-A has a higher priority for reporting than carrier-B, when CQI / PMI / RI for carrier-B and CQI / PMI / RI for carrier-B collide, CQI / PMI / RI for carrier-B can be dropped.

  As a third method, when CQI / PMI / RI collides with each other in a period in which CQI / PMI / RI for downlink multi-carrier is reported in multi-carrier transmission, it is determined which information is dropped. can do. Regardless of which downlink carrier is used, priority can be given based on attributes of feedback information. CQI / PMI may be calculated and selected based on the last reported RI. When reporting multiple indexes to the precoder (eg, I1 and I2), each precoder is calculated and selected based on the last reported RI, and the CQI transmitted with I2 is reported last. It can be calculated based on RI, last reported I1 and currently transmitted I2. Alternatively, the CQI reported with I1 / I2 can be calculated based on the last reported RI and the current reported I1 / I2. Considering this, it is possible to give a relatively high priority to control information reported in a longer-period cycle. For example, it can be set that I1 has the highest priority, RI has the next priority, and I2 and CQI have the next priority. When the low priority control information is set to be transmitted at the same timing as the high priority control information, the low priority control information can be dropped and the high priority control information can be transmitted.

  The above-mentioned method regarding the priority of periodic CSI reporting using PUCCH when multiple carriers are set is as follows.

  First, when more than one serving cell (more than one serving cell) is configured in a terminal, the terminal transmits channel state information (CSI) for only one serving cell in an arbitrary subframe (in any given subframe). can do.

  If the feedback information of the first serving cell has a higher priority than the feedback information of the second serving cell according to the attribute of the feedback information in an arbitrary subframe, the feedback information of the second serving cell having a lower priority can be dropped. For example, CSI including PMI (or broadband PMI (W1 or I1)) having RI or a long-period reporting period may have higher priority than other CSIs. In other CSIs, PMI and / or CQI with long-period reporting period (or wideband attribute) is higher priority than PMI and / or CQI with short-period reporting period (or subband attribute) Can have.

(Example 8)
In the eighth embodiment, when multiple control information is reported, a reporting method for a case where certain control information is dropped will be described, and a specific reporting method for a case where RI or I1 (PMI or W1) is dropped will be described.

  In the eighth embodiment, a reporting method in the case of RI or I1 drop on the side of one carrier wave will be described as an example. However, the present invention is not limited to this. For example, the content of the eighth embodiment is based on a predetermined feedback based on the priority when a feedback information (eg, CSI) collides with a terminal in which a multi-carrier (or more than one serving cell) described in this document is set. The present invention can also be applied to examples in which information falls. For example, as a specific CSI reporting method in the case where the priority based on the attribute of the CSI information or the information that falls according to the priority already defined for the serving cell is RI or I1 (PMI or W1 of the long-period broadband attribute), The illustrations described below can be applied.

  In the following, assuming that CQI / PMI / RI is periodically reported through PUCCH by Mode 2-1 (ie, Mode 2-1 (1) and Mode 2-1 (2)) of Table 38 above, control information is assumed. Explain the reporting method when the omission applies.

  With reference to FIG. 27 and Table 46, the control information transmission scheme in Mode 2-1 will be specifically described. FIG. 27 is an example showing the timing at which RI / PMI / CQI is reported in the case of Mode 2-1. Table 46 is for explaining the timing and attributes of the RI / PMI / CQI report in the case of Mode 2-1.

Ｉ１、Ｉ２及びＣＱＩは、報告されるＲＩの指示（ｉｎｄｉｃａｔｉｏｎ）にしたがって決定されうる。表４６のＣａｓｅ １では、ランク−Ｎという情報が報告されると、これに基づいてランク−ＮのためのコードブックからＩ１が選択されて報告される。その後、選択されたＩ１に基づいてＩ２が選択され、ＣＱＩが計算されて報告される。その後、ランク値が変わってＲＩ値がランク−Ｍと報告されると、以降はランク−Ｍに基づいてＩ１、Ｉ２が選択されてＣＱＩが計算される。

I1, I2 and CQI may be determined according to the indication of the reported RI. In Case 1 of Table 46, when information of rank-N is reported, I1 is selected and reported from the codebook for rank-N based on this information. Thereafter, I2 is selected based on the selected I1, and the CQI is calculated and reported. Thereafter, when the rank value changes and the RI value is reported as rank-M, thereafter, I1 and I2 are selected based on rank-M, and CQI is calculated.

  On the other hand, Case 2-1 and Case 2-2 in Table 46 show control feedback information attributes when RI falls. Cases 2-1 and 2-2 in Table 46 represent RI information referred to by I1, I2, and CQI when the RI is dropped. If I1, I2, and CQI are defined to be selected / calculated based on the most recently reported RI rank value, there is no problem in selecting / calculating I1, I2, and CQI even in a situation where RI falls. That is, when the RI representing rank-M falls in Case 2-1, the terminal may select / calculate I1, I2, and CQI based on the last reported RI rank value (ie, N). Also, even if PTI is set to 0 or 1 as in Case 2-2, I1, I2 and CQI can be selected / calculated based on the last reported rank value. Here, the RI in the case of PTI 1 preferably reports the same rank information as the rank information reported in the RI in the case of PTI 0.

  On the other hand, the case where I1 falls can be considered. The I1 information is used as information for I2 selection and CQI calculation. If I1 falls at the moment when rank information changes, I2 selection and CQI calculation will be confused. For example, when rank-M-based I1 drops in the situation where rank information is changed from N to M as in Case 3-1 and Case 3-2 in Table 46, I2 and CQI information to be selected / calculated thereafter Since there is no rank-M based I1 information, a problem occurs in selection / calculation. Therefore, it is required to eliminate ambiguity in I1 selection and CQI calculation for the case where I1 falls.

  In the following, an illustration of the present invention for I2 and CQI selection / calculation when I1 falls will be described.

(Example 8-A)
If I2 / CQI calculation is to be performed based on rank M, calculate I2 and CQI based on the most recently reported I1 (for rank-M) of I1 for previously reported rank M be able to. Alternatively, if the I2 / CQI calculation is to be performed based on rank M, rank-M based I1 may be pre-defined. In other words, if the most recently reported I1 (first PMI) was calculated assuming a different RI than the most recently reported RI, or there was no (or dropped) the most recently reported I1 ), I2 (second PMI) or CQI may be selected / calculated based on I1 (first PMI) defined in advance. For example, the predefined I1 (first PMI) is I1 (first PMI) with the smallest index allowed by the codebook subset restriction bitmap parameter subject to the most recently reported RI. ) Can be defined. This allows selection / calculation of I2 and CQI for rank-M even when there is no previously reported I1 for rank M. This can be organized as shown in Table 47.

（実施例８−Ｂ）
ランクがＮからＭに変更されるとき、ランク−Ｍに対するＩ１が落ちる場合には、最も最近に報告されたＩ１のランクの情報をオーバーライド（ｏｖｅｒｒｉｄｅ）することができる。

(Example 8-B)
When the rank is changed from N to M, if the I1 for rank-M falls, the most recently reported I1 rank information can be overridden.

  For example, the most recently reported when an RI indicating rank-M is transmitted, the I1 report for rank-M is dropped, and an I2 / CQI based on rank-M has to be selected / calculated subsequently. It can be assumed that I1 is an indicator selected based on rank-N. In this case, the rank information based on the most recently reported RI (ie, rank-M) is ignored, and I2 // based on the most recently reported I1 and the rank value of the I1 (rank-N). CQI can be calculated. Also selected based on rank-M if WB I2, CQI and SB I2 / CQI must be reported by PTI indications reported in the next RI (still representing rank-M) transmission period Since I1 has fallen, I2 / CQI may be calculated based on the most recently reported I1 and its rank. This is organized as shown in Table 48.

（実施例８−Ｃ）
Ｉ１が落ちる場合には、その次のＲＩ報告周期にはＰＴＩ＝０を指示してＩ１が報告されるようにすることができる。これを整理すると、表４９のようになる。

(Example 8-C)
If I1 falls, it is possible to indicate P1 = 0 by reporting PTI = 0 in the next RI reporting period. This is organized as shown in Table 49.

（実施例８−Ｄ）
Ｉ１が落ちる場合に、Ｉ１の報告をずらしてＩ１を報告するようにすることができる。例えば、Ｉ１の報告タイミングに続くＮ番目のサブフレームでＩ１を報告するようにすることができる。

(Example 8-D)
When I1 falls, I1 can be reported by shifting the report of I1. For example, it is possible to report I1 in the Nth subframe following the reporting timing of I1.

  For example, the N-th subframe may be set to an N value such that it is one of the CQI report timings after the original I1 report timing. The dropped I1 may be reported instead of the control information to be transmitted in the first place at an arbitrary timing in the period in which the CQI is promised to be reported. For example, as shown in FIG. 28A, if I2 / CQI is to be reported after I1 is reported, I1 can be reported instead of reporting I2 / CQI. Alternatively, the dropped I1 may be reported at the CQI reporting timing immediately after I1 falls. Alternatively, as shown in FIG. 28 (b), the N value may be set so that the dropped I1 is reported in the subframe immediately after the original I1 report timing. This is shown in Table 50.

（実施例９）
本実施例９では、多重の制御情報が報告される場合における制御情報伝送の優先順位について説明し、且つ多重−搬送波伝送の場合における制御情報伝送の優先順位の具体的な設定方案について説明する。以下の説明において、多重搬送波またはキャリアアグリゲーションが適用されるという意味は、１個より多い搬送波（またはサービングセル）が設定（ｃｏｎｆｉｇｕｒｅ）されることを指す。すなわち、本実施例は、端末に複数個の搬送波（またはセル）が設定される場合に適用可能である。

Example 9
In the ninth embodiment, priority of control information transmission when multiple control information is reported will be described, and a specific setting method of priority of control information transmission in the case of multiplex-carrier transmission will be described. In the following description, the meaning that multi-carrier or carrier aggregation is applied means that more than one carrier (or serving cell) is configured. That is, this embodiment is applicable when a plurality of carriers (or cells) are set in the terminal.

  When the downlink channel is measured and reported using the uplink channel in the 3GPP LTE system, RI / PMI / CQI or the like can be reported as information on the downlink channel. Here, when the downlink channel information is reported using PUCCH, two modes can be used depending on the frequency unit to which CQI / PMI is applied. A mode for reporting CQI / PMI applied to WB can be called a PUCCH report mode 1-1 sequence, and a mode for reporting SB CQI together with WB CQI / PMI can be called a PUCCH report mode 2-1 sequence. Since PUCCH has restrictions on the channel capacity that can be transmitted at a time, rank, WB CQI / PMI, and SB CQI may be defined to be reported at different timings. FIG. 29 shows an example of the timing at which each channel information is reported. Comparing the period in which each channel information is reported, RI is reported in a relatively long-period period, and SB CQI / PMI and SB CQI are reported in a relatively short-period.

  Considering that multi-carrier (carrier aggregation) transmission is applied, information on each downlink carrier must be measured and reported. The downlink channel information can be reported using one uplink carrier (for example, UL P-cell), and the timing for reporting information on each downlink carrier is set to have an independent transmission period for each DL carrier. be able to. In such a case, there is a case where the reporting timing of information on DL carriers that must be reported on one uplink carrier overlaps (that is, information on different DL carriers is reported at the same time).

  In order to solve this problem, priority can be set for each CSI (RI / PMI / CQI), information with high priority can be transmitted, and channel information with low priority can be dropped. As shown in FIG. 29, rank information is reported in a relatively long-period cycle and CQI / PMI information is reported in a relatively short-period information. Transmission priorities can be given so that the latest channel information is reported.

  In the 3GPP LTE-A system, a codebook is defined that uses two indexes (I1 and I2 (or PMI1 (W1) and PMI2 (W2))) to represent precoding information related to eight transmission antenna transmissions. In order to unambiguously determine information about an element, all two indices must be reported: I1 is reported as relatively long-period / WB information and I2 is as relatively short-period / SB information. Compared with CSI reporting in the existing 3GPP LTE Release-8 / 9 system, it is necessary to additionally define how to report the two codebook indicators. For reporting RI, I1, I2 and CQI information, Mode2-1 (1) in Table 38 above is as follows: And the same PUCCH reporting mode as in Mode 2-1 (2) can be applied.

  As described in Mode 2-1 in Table 38 above, the attribute of the next reported information is determined by the PTI. That is, when the PTI transmitted with the RI is set to 0, W1 is transmitted, and then WB W2 and CQI are transmitted. At this time, W2 and CQI are selected / calculated based on previously reported W1. When PTI is set to 1, WB W2 / CQI is transmitted, and then SB W2 / CQI is transmitted. FIG. 30 is a diagram illustrating CSI report timings when PTI = 0 and PTI = 1 according to Mode 2-1.

  Looking at the reporting period of CSI, as shown in FIG. 30, W1 is reported relatively less frequently and RI + PTI is reported more frequently than W1. And WB W2 / CQI and SB W2 / CQI are reported frequently. Therefore, as described above, when CSI information transmitted at a specific timing in multi-carrier transmission must be selected, the transmission priority of each CSI information may be defined as W1> RI + PTI> W2 = CQI. it can.

  Meanwhile, PUCCH reporting modes such as Mode 1-1-1 and Mode 1-1-2 in Table 38 may be applied. In such a PUCCH reporting mode, the transmission priority of each CSI information of each CSI can be determined based on the reporting period. That is, the priority of (RI + I1) _WB> (I2 + CQI) _WB is defined in Mode 1-1-1 in Table 38, and (RI) _WB> (I1 + I2 + CQI) _WB is defined in Mode 1-1-2 in Table 38. A priority is defined.

  Here, when multi-carrier transmission is applied, (RI + I1) _WB for the first DL carrier may collide with (RI) _WB transmission for the second carrier. Considering the fact that I1 is reported in a longer-period period than RI, in some cases, I1 may be more affected by the drop in I1, so I1 can be set to a higher priority. . That is, it can be set to have a priority order of (RI + I1)> (RI).

  Considering the three feedback modes (Mode 1-1-1, Mode 1-1-2 and Mode 2-1) as shown in Table 38 above, I1) _WB is set to have the highest priority. do it.

  The above-mentioned scheme regarding the priority of periodic CSI reporting using PUCCH when multiple carriers are set up is as follows.

  First, when more than one serving cell (more than one serving cell) is set in a terminal, the terminal transmits channel state information (CSI) related to only one serving cell in an arbitrary subframe (in any given subframe). be able to.

  If the feedback information of the first serving cell has a higher priority than the feedback information of the second serving cell due to the attribute of the feedback information in an arbitrary subframe, the feedback information of the second serving cell can be dropped with a lower priority. For example, RI, (RI + I1) _WB, (RI + PTI), or I1_WB may have a higher priority than other CSIs.

(Example 10)
In the tenth embodiment, the priority of control information transmission when multiple control information is reported will be described, and the following embodiments 10-A and 10-B will be used as a feedback method when RI and PTI drop. I will explain.

(Example 10-A)
When a PUCCH reporting mode such as Mode 2-1 in Table 38 is applied, RI + PTI may be dropped for various reasons. In this case, the next reported information can be determined according to the most recently reported RI + PTI indication.

  For example, when RI + PTI (= 0) is reported, (W1) _WB is subsequently reported, and (W2 + CQI) _WB is reported. In this case, if RI + PTI (= 0) falls, subsequently reported information can be determined by the last reported PTI value. FIG. 31 shows an example in which, when RI + PTI (= 0) falls, the last reported PTI indicates 1, so that (W2 + CQI) _WB is reported and (W2 + CQI) _SB is reported.

(Example 10-B)
When a PUCCH reporting mode such as Mode 2-1 in Table 38 is applied, if RI + PTI falls, the information reported subsequently is calculated according to the rank value indicated by the most recently reported RI. / Can be selected.

  For example, when RI (= M) + PTI is reported, W1, W2, and CQI transmitted subsequently should be selected / calculated based on rank-M and reported. In this case, if RI (= M) + PTI falls, subsequently reported information can be selected / calculated based on the rank value of the last reported RI. FIG. 32 shows that when RI (= M) + PTI falls, W1_WB is selected and reported based on rank-N by the last reported RI (= N) instead of rank-M. In this case, the subsequent W1 / CQI is selected / calculated based on rank-N and W1 based on rank-N. If the PTI instruction timing is determined, the PTI instruction may be reported at the determined timing.

(Example 11)
In the eleventh embodiment, a codebook subsampling scheme applicable to the PUCCH reporting mode, and the definition of the MU-MIMO case and the PUSCH reporting mode will be described.

(Example 11-A)
In a system supporting an extended antenna configuration (for example, 3GPP LTE Release-10 system), as an extension of the existing PUCCH reporting mode, three PUCCH reporting modes (Mode 1-1-1, Mode 1-1-2, Mode 2-1) (or Mode-A, Mode-B, Mode-C) can be applied.

  Mode 1-1-1 is a mode that reports joint-coded RI and I1, and reports wideband CQI and wideband I2. Mode 1-1-2 is a mode for transmitting (RI) _WB and (I1 + I2 + CQI) _WB. Mode 2-1 can transmit different feedback information depending on the PTI. When PTI = 0, (RI + PTI (0)), (I1) _WB, and (I2 + CQI) _WB can be transmitted. In the case of PTI = 1, (RI + PTI (1)), (I2 + CQI) _WB, and (I2 + CQI) _SB can be transmitted. On the other hand, in the present specification, the two precoder indexes I1 and I2 may be expressed as W1 and W2, respectively.

  In the following, the codebook subsampling is applied to each PUCCH reporting mode to achieve the reporting bandwidth optimization while maintaining the same PUCCH feedback coverage as the existing 3GPP LTE release-8 / 9. The method will be explained.

  The signaling overhead required for PUCCH reporting modes 1-1-1 and 1-1-2 is the same as in Table 39 above (in Table 39, Mode-A corresponds to PUCCH reporting mode 1-1-1). Mode-B corresponds to PUCCH reporting mode 1-1-2).

  As can be seen from Table 39 above, 6 bits are required for type-5 (join-coded RI and W1) reporting in PUCCH reporting mode 1-1-1. Since 6 bits are allocated for RI and W1 while RI is jointly coded with W1, the coverage of RI transmission is significantly lower than that of the existing 3GPP LTE Release-8 system, resulting in RI detection failure or performance degradation. May be connected. Therefore, sub-sampling of W1 to increase RI coverage can be considered. On the other hand, in Mode 1-1-1, since type-2a (W2 and CQI) reports are updated more frequently than type-5 reports, it is not necessary to protect type-2a (W2 and CQI). It can be said. Therefore, subsampling for W2 is not required unless the reported bandwidth exceeds 1 bit size.

  In PUCCH reporting mode 1-1-2, RI is not jointly coded with other CSI information, so RI coverage can be kept the same as the existing 3GPP LTE Release-8 system. However, as shown in Table 39 above, in ranks 1, 2, 3, and 4, signaling overhead exceeding 11 bits is required for type-2b (W1 + W2 + CQI) reports. Therefore, codebook subsampling is required to reuse the PUCCH format 2 of 3GPP LTE Release-8.

  First, a subsampling scheme applicable to the PUCCH reporting mode 1-1-1 will be described.

  The number of W1 candidates can be different depending on the transmission rank. That is, as shown in Tables 11 to 18, the numbers of W1 candidates are 16, 16, 4, 4, 4, 4, 4, 1 for ranks 1 to 8, respectively. Can be individual. When RI and W1 are reported jointly, the required signaling overhead is 6 (= ceiling (log2 (53))) bits. To extend the RI coverage, it can be considered to reduce the signaling overhead to 5 or 4 bits using W1 subsampling. An example of W1 subsampling is shown in Table 51 below.

二重−段階（ｄｕａｌ−ｓｔａｇｅ）コードブック構造ではビームグループ間に重なる（ｏｖｅｒｌａｐｐｅｄ）ビームが存在するので、表５１のＡｌｔ−１方案のように、コードブックから奇数番のＷ１のみを除外する方式でＷ１に対してサブサンプリングを適用しても、コードブックの全てのビームを維持することができる。しかし、全体コードブックを構成するためのＷ１及びＷ２が異なったサブフレームで伝送されるため、サブサンプリングの適用されない全体コードブックを用いる場合に比べて性能低下が発生することはある。一方、上記の表５１のＡｌｔ−２方案のように、より多いビームを除外するサブサンプリングが適用される場合には、コードブックの全てのビームを維持する上記Ａｌｔ−１方案と違い、コードブックにおいていくつかのビームが用いられないことがあり、性能低下が発生する。

In the dual-stage codebook structure, since there is an overlapped beam between beam groups, a method of excluding only odd-numbered W1 from the codebook as in the Alt-1 scheme in Table 51 Even if subsampling is applied to W1, all the beams of the codebook can be maintained. However, since W1 and W2 for configuring the entire codebook are transmitted in different subframes, performance degradation may occur compared to the case of using the entire codebook to which subsampling is not applied. On the other hand, when sub-sampling that excludes more beams is applied as in the Alt-2 scheme of Table 51 above, unlike the Alt-1 scheme that maintains all the beams in the codebook, the codebook In some cases, some beams may not be used, resulting in performance degradation.

  Table 52 shows the system level performance of PUCCH reporting mode 1-1-1 by applying codebook subsampling in transmission of 8 × 2 SU-MIMO scheme. In Table 52, cross-polarized and common when the Alt-1 and Alt-2 schemes are applied, based on the use of 4 + 4 as W1 and W2 bits for ranks -1 and 2. -Represents the average spectral efficiency (SE) and the cell-edge SE in the case of a co-polarized antenna configuration. The Alt-1 scheme of Table 52 causes a slight performance degradation at both the average SE and the cell-boundary SE, while the Alt-2 scheme results in a relatively large performance degradation at the cell-boundary SE.

表５２からわかるように、５ビットにサブサンプリングされたコードブックはシステム性能を維持するが、４ビットにサブサンプリングされたコードブックは、最大７％だけシステム性能を減少させる。したがって、Ａｌｔ−１方案は、Ａｌｔ−２方案に比べて、ＲＩカバレッジは相対的に小さくなるが、システム性能の観点でより好ましい。

As can be seen from Table 52, a codebook subsampled to 5 bits maintains system performance, whereas a codebook subsampled to 4 bits reduces system performance by up to 7%. Therefore, the Alt-1 method has a relatively smaller RI coverage than the Alt-2 method, but is more preferable from the viewpoint of system performance.

  Next, a subsampling scheme applicable to the PUCCH reporting mode 1-1-2 will be described.

  In W1 + W2 + CQI reporting in PUCCH reporting mode 1-1-2, W1 and W2 are reported in the same subframe. Therefore, subsampling can be applied to keep the reporting bandwidth below 11 bits. As described above, when subsampling is applied to W1, which reduces by 1 bit (for example, when 8 index subsets are selected from 16 indexes), all the beams of the codebook can be maintained. , System performance degradation is minimized. However, when sub-sampling W1 having more than 1 bit, a beam group in a specific direction is excluded from the codebook, so that the system performance is greatly deteriorated. Therefore, for ranks 1 to 4, it is preferable to subsample only one bit from W1 and exclude more bits from W2. Table 53 below is an example of a subsampling scheme that can be applied to the PUCCH reporting mode 1-1-2.

表５３で、Ａｌｔ−１及びＡｌｔ−２方案の両方とも、全てのビームグループを失わないように、ランク１乃至４に対してＷ１に１ビットのみ減少される。これにより、Ｗ２は、要求される帯域幅によってサブサンプリングされる。

In Table 53, both Alt-1 and Alt-2 schemes are reduced by only 1 bit in W1 for ranks 1 through 4 so as not to lose all beam groups. Thus, W2 is subsampled according to the required bandwidth.

  Table 54 shows the system level performance of the PUCCH reporting mode 1-1-2 when the Alt-1 and Alt-2 schemes of Table 42 are applied in the transmission of the 8 × 2 SU-MIMO scheme. In Table 54, cross-polarized and common when the Alt-1 and Alt-2 schemes are applied, based on the use of 4 + 4 as W1 and W2 bits for ranks -1 and 2 -Represents the average spectral efficiency (SE) and cell-edge SE for the case of a co-polarized antenna configuration.

表５４に示すように、８伝送アンテナでのいくつかのビームステアリング（ｓｔｅｅｒｉｎｇ）ベクトルがＷ２サブサンプリングから除外されるため、交差−極性アンテナ構成に比べて共通−極性アンテナ構成で性能低下が相対的に大きく現れる。一方、交差−極性アンテナ構成に対してはわずかな（ｍａｒｇｉｎａｌ）性能低下が現れる。

As shown in Table 54, some beam steering vectors with 8 transmit antennas are excluded from W2 sub-sampling, so there is a relative performance degradation in common-polar antenna configurations compared to cross-polar antenna configurations. Appear greatly in On the other hand, marginal performance degradation appears for cross-polar antenna configurations.

  Thus, when W1 subsampled to 3 bits is used, the performance degradation caused by using the subsampled codebook is considered acceptable. Therefore, it is preferable to apply the Alt-1 scheme to the PUCCH reporting mode 1-1-2.

  Next, a subsampling scheme applicable to the PUCCH report mode 2-1 will be described.

  In the PUCCH report mode 2-1, four different report types ((RI + PTI), (W1) _WB, (W2 + CQI) _WB, (W2 + CQI) _SB) can be fed back. The report type may vary depending on the PTI selection. Table 45 above shows signaling overhead required for each report type in the case of PUCCH mode 2-1 (represented as Mode-C in Table 41). Table 45 assumes that the (W2 + CQI) _SB report with PTI = 1 includes an L-bit indicator for the subband selected by the terminal.

  As shown in Table 45, for ranks 2, 3 and 4 where 1 is indicated as the PTI, the overhead required to report the L-bit indicator for (W2 + CQI) _SB and SB is 11 bits. Will be exceeded. Without reducing the signaling overhead in this regard, 3GPP LTE Release-8 PUCCH format 2 cannot be reused. Therefore, the following two methods can be considered for reducing signaling overhead. The first strategy (option 1) is to newly define a pre-promised SB cycling without using the L-bit selected band indicator. The second strategy (option 2) is to reuse the selected band indicator of L-bits by subsampling W2.

  In scheme 1, SB CQI and SB W2 can be reported using PUCCH format 2. However, according to Method 1, since the CQI reporting period in each subband may be increased, the performance is more sensitive in time-selective channel because it uses a predefined SB circulation. A decrease can occur. In addition, WB CQI and WB W2 must be reported during the bandwidth part (BP) reporting interval, which may further increase the CQI reporting period in each subband. Greater performance degradation can occur.

  In plan 2, SB CQI and SB W2 are reported with a selected band indicator of L-bits, so that ranks 2, 3 and 4 require that the number of bits required for reporting exceed 11. Thus, W2 subsampling can be applied. An example of W2 subsampling is shown in Table 46 below.

表５６は、８×２ ＳＵ−ＭＩＭＯ方式の伝送において、前述した２個の方案（ｏｐｔｉｏｎ １及びｏｐｔｉｏｎ ２）が適用される場合にＰＵＣＣＨ報告モード２−１のシステムレベル性能を表すものである。表５６では、２個の方案が適用されるとき、交差−極性（ｃｒｏｓｓ−ｐｏｌａｒｉｚｅｄ）及び共通−極性（ｃｏ−ｐｏｌａｒｉｚｅｄ）アンテナ構成の場合に対する平均スペクトル効率（Ｓｐｅｃｔｒａｌ Ｅｆｆｉｃｉｅｎｃｙ；ＳＥ）及びセル−境界（ｃｅｌｌ−ｅｄｇｅ）ＳＥを表す。システム性能の測定のために、ＳＢ ＣＱＩ及びＳＢ Ｗ２が５ｍｓ報告周期で報告され、ＷＢ Ｗ１は、４５ｍｓごとに更新されると仮定する。また、方案２に対しては２ビットにサブサンプリングされたＷ２が用いられると仮定する。

Table 56 shows the system level performance of the PUCCH reporting mode 2-1 when the above-described two methods (option 1 and option 2) are applied in the transmission of the 8 × 2 SU-MIMO scheme. In Table 56, when two schemes are applied, the average spectral efficiency (SE) and cell-boundary (SE) for the case of cross-polarized and co-polarized antenna configurations. cell-edge) SE. For measurement of system performance, assume that SB CQI and SB W2 are reported in a 5 ms reporting period, and WB W1 is updated every 45 ms. Also, for method 2, it is assumed that W2 subsampled to 2 bits is used.

表５６のように、方案１は方案２に比べて平均ＳＥにおいて３乃至４％のシステム性能低下を示す。これは、方案１におけるＷＢ ＣＱＩ／ＷＢ Ｗ２報告動作周期が方案２における報告周期に比べてより長くなるためである。例えば、システム帯域幅が５ＭＨｚの場合にあらかじめ定義されたＳＢ循環が適用される場合の報告区間を示す図３３と同様に、方案１では、全てのサブ帯域に対するＣＳＩを報告するから、方案１におけるＷＢ ＣＱＩ／ＷＢ Ｗ２報告周期が方案２の周期に比べて長くなる。

As shown in Table 56, Method 1 shows a 3 to 4% reduction in system performance in average SE compared to Method 2. This is because the WB CQI / WB W2 reporting operation cycle in the plan 1 is longer than the reporting cycle in the plan 2. For example, as in FIG. 33, which shows a report interval when a predefined SB circulation is applied when the system bandwidth is 5 MHz, in the plan 1, CSI for all subbands is reported. The WB CQI / WB W2 reporting period becomes longer than the period of the plan 2.

  As described above, since method 2 exhibits higher performance than method 1, it is more preferable in terms of performance to include an L-bit indicator for the band selected by the terminal and apply W2 subsampling. Further, since the band selection function of the terminal is used in the existing system (3GPP LTE Release-8 system), the complexity of implementation of Method 2 is also reduced.

  Therefore, according to the codebook subsampling scheme proposed in the present invention applied to each of the PUCCH modes, it is possible to minimize the decrease in system performance while reusing the existing PUCCH format 2.

  On the other hand, Table 57 below shows parameters applied to the simulation of the system performance in Tables 52, 54 and 56 described above. Table 58, Table 59, and Table 60 show parameters applied to system performance simulations of PUCCH formats 1-1-1, 1-1-2, and 2-1.

（実施例１１−Ｂ）
ＭＵ−ＭＩＭＯ伝送においては、送信端で送信するレイヤーの個数と受信端で受信するレイヤーの個数とに相違がある。また、受信端ではＳＵ−ＭＩＭＯと仮定してＣＳＩを報告するので、受信端が報告するチャネル情報が実際チャネル情報と整合しない（ｍｉｓｍａｔｃｈ）こともある。例えば、既存のＰＵＳＣＨ報告モード３−１を用いる場合にＭＵ−ＭＩＭＯでのチャネル状態情報を正確にフィードバックすることができず、ＣＱＩ報告を改善するための方案が要求される。

(Example 11-B)
In MU-MIMO transmission, there is a difference between the number of layers transmitted at the transmitting end and the number of layers received at the receiving end. Further, since CSI is reported at the receiving end assuming SU-MIMO, the channel information reported by the receiving end may not match the actual channel information (missmatch). For example, when the existing PUSCH report mode 3-1 is used, channel state information in MU-MIMO cannot be accurately fed back, and a method for improving CQI reporting is required.

  In order to solve this, it is possible to consider a method of additionally reporting CQI related to MU-MIMO in the existing PUSCH reporting mode 3-1. As a result, flexible scheduling between the SU-MIMO mode and the MU-MIMO mode is allowed, and the system performance can be optimized. However, in order to support dynamic switching between the SU-MIMO mode and the MU-MIMO mode, the MU-MIMO CQI must be fed back and added to the SU-MIMO CQI. Additional overhead for feedback is required.

  As another solution, a new PUSCH reporting mode can be applied. For example, the PUSCH report mode 3-2 for transmitting RI, WB CQI related to the first codeword (CW), WB CQI related to the second CW, WB W1, and SB W2 can be applied. The PUSCH reporting mode 3-2 can feed back the PMI for a more precise frequency feedback unit (granularity), thereby improving the accuracy of the feedback information. In PUSCH reporting mode 3-2, no additional MU-MIMO CQI feedback is required, but the feedback overhead increases to improve the finer PMI feedback frequency unit.

  Table 61 below shows the case of applying PUSCH reporting mode 3-1 with additional MU-MIMOCSI when applying PUSCH reporting mode 3-1, and applying PUSCH reporting mode 3-2 in 4-transmit antenna transmission This represents the feedback overhead required when In Table 61, N represents the number of subbands, and L represents the number of bits required to indicate the selected band.

上記表６１に示すように、２つのＣＱＩ報告方案（ＭＵ−ＭＩＭＯ ＣＱＩを伝送する方案とＰＵＳＣＨ報告モード３−２を用いる方案）とも、ＰＵＳＣＨ報告モード３−１に比べてフィードバックオーバーヘッドが大きく増加する。フィードバックオーバーヘッドはシステム帯域幅が広くなるほど一層増加する。したがって、上記のようなＣＱＩ報告方案を適用するためには充分の性能利得が存在しなければならない。

As shown in Table 61 above, the feedback overhead is greatly increased in both of the two CQI reporting schemes (the scheme for transmitting MU-MIMO CQI and the scheme using PUSCH reporting mode 3-2) as compared with PUSCH reporting mode 3-1. . The feedback overhead increases as the system bandwidth increases. Therefore, there must be a sufficient performance gain in order to apply the CQI reporting scheme as described above.

  Tables 62 to 64 below show the system level performance according to each CQI improvement method in the case of 4 × 2 MU-MIMO transmission. In Tables 62 to 64, it is assumed that only one layer is allocated to one terminal. Tables 62 and 63 relate to the case where the maximum number of terminals subjected to MU-MIMO scheduling is two, and Table 64 relates to the case where the maximum number of terminals subjected to MU-MIMO scheduling is four. For the MU-MIMO CQI calculation, the terminal searches for a preferred beam vector similar to the SU-MIMO scheme, and other interference beam vectors are defined in advance. Accordingly, a precoder is formed by one preferred beam vector and another interference beam vector in consideration of common-channel (co-channel) interference, and MU-MIMO CQI calculation is performed based on the precoder thus formed. be able to.

上記表６２乃至６４から、既存のＰＵＳＣＨ報告モード３−１に比べて上記のＣＱＩ改善方案が提供する性能利得が存在することがわかる。場合によっては、ＣＱＩ改善方案による性能利得が大きくないので、シグナリングオーバーヘッドを増加させるＣＱＩ改善方案を適用する代わりに既存のＰＵＳＣＨ報告モード３−１を用いることを考慮することもできる。

From Tables 62 to 64, it can be seen that there is a performance gain provided by the CQI improvement method compared to the existing PUSCH reporting mode 3-1. In some cases, since the performance gain due to the CQI improvement plan is not large, it may be considered to use the existing PUSCH reporting mode 3-1 instead of applying the CQI improvement plan that increases the signaling overhead.

  Table 65 below shows the number of subbands and the number of bits required for subband indication.

下の表６６は、上記表６２乃至表６４のシステム性能のシミュレーションに適用されたパラメータを整理したものである。

Table 66 below summarizes the parameters applied to the system performance simulations of Tables 62 to 64 above.

（実施例１２）
本実施例１２では、Ｗ１及びＷ２がジョイントコーディングされる場合に適用可能なＷ１及びＷ２のサブサンプリング方案について説明する。

(Example 12)
In the twelfth embodiment, a subsampling scheme for W1 and W2 that can be applied when W1 and W2 are jointly coded will be described.

  In the case of PUCCH reporting mode 1-1-2 in Table 38 above, W1 and W2 are transmitted together with WB CQI (in Table 38, W1 and W2 are represented as I1 and I2). In order to set the feedback mode to have the same level as the error occurrence probability in the existing 3GPP LTE Release-8 PUCCH reporting scheme, the bits for each rank precoder may be designed to have a 4-bit size. it can.

  For example, as shown in Table 67, the number of bits of W1 and W2 according to each rank can be set. The indexes for W1 and W2 described in Table 52 correspond to the indexes (i1, i2) for the codebooks shown in Tables 11 to 14 above.

（実施例１３）
本実施例１３では、ＰＵＣＣＨ報告モード２−１に適用可能なＷ２サブサンプリング方案について説明する。

(Example 13)
In the thirteenth embodiment, a W2 subsampling scheme applicable to the PUCCH report mode 2-1 will be described.

  In the PUCCH reporting mode 2-1 described in Table 38 above, when SB CQI is transmitted when PTI = 1, the SB CQI may be selected in the bandwidth portion (BP). That is, WB CQI and WB W2 are reported at the first reporting time, and SB CQI selected within a certain BP, selected band index and SB W2 are reported at the second reporting time (in Table 38, W1 And W2 are represented as I1 and I2.) In the third reporting time, the SB CQI selected in the BP different from the BP considered in the second reporting time, the selected band index, and SB W2 are reported.

  Here, the SB CQI is expressed by 4 bits or 7 bits. The selected band index is expressed by 2 bits, and SB W2 is expressed by 4 bits. Considering this, 10 or 13 bits are required as a total of bits to be transmitted in one reporting time (that is, one subframe). However, as described above, considering that the number of bits of feedback information that can be transmitted using PUCCH (for example, when using PUCCH format 2) is limited to 11 bits, 2 bits are reduced in rank-2 or higher. There must be.

  As a method of reducing 2 bits in W2, a W2 subband report as shown in Table 67 below can be applied. Table 68 shows an example in which W2 subsampling is applied in ranks-2, 3 and 4 in the case of 8-transmit antenna transmission.

また、Ｗ２のサブサンプリングを適用する場合に、Ｗ１及びＷ２によってプリコーダが特定されるので、プリコーダ要素の落ちを避けるためにＷ１に対してはサブサンプリングを適用しないことを考慮することができる。またはフィードバックオーバーヘッドをさらに軽減するために、Ｗ１が最大３ビットを有するように設定することもできる。表６９は、Ｗ２のサブサンプリングが適用される場合にＷ１のビット数設定の一例を表すものである。

Further, when the sub-sampling of W2 is applied, the precoder is specified by W1 and W2. Therefore, it can be considered that the sub-sampling is not applied to W1 in order to avoid the drop of the precoder element. Alternatively, W1 can be set to have a maximum of 3 bits to further reduce feedback overhead. Table 69 shows an example of setting the number of bits of W1 when W2 subsampling is applied.

本実施例１３において、Ｗ２を２ビットにサブサンプリングする具体的な方案として、上記の本発明の種々の実施例で説明した方案を適用することができる。

In the thirteenth embodiment, as a specific scheme for sub-sampling W2 into 2 bits, the scheme described in the various embodiments of the present invention can be applied.

(Example 14)
In the fourteenth embodiment, a specific method for channel state reporting for multi-carrier transmission will be described, and different feedback information may collide by setting the transmission information transmission priority in the case of multi-carrier transmission. Which feedback information to drop when doing so. In the following description, the meaning that multi-carrier or carrier aggregation is applied means that more than one carrier cell (or more than one serving cell) is configured. That is, this embodiment is applicable when a plurality of carriers (or cells) are set in the terminal.

  In the periodic CQI / PMI / RI report for downlink multiplex-carrier transmission, as defined in the existing 3GPP LTE Release-8, the period is independently determined for each downlink carrier using higher layer configuration parameters. A dynamic feedback scheme can be set.

  When PUCCH and PUSCH are not set simultaneously, periodic CQI / PMI / RI for only one DL carrier can be reported in one subframe. A priority can be set as to which DL carrier is to report periodic CQI / PMI / RI. In the priority setting, priority between carriers can be set based on the report mode or type. If the report mode / type matches, the priority order between the carriers may be set by an upper layer (for example, RRC). Such priority setting of feedback transmission is applicable both when feedback is transmitted without PUSCH and when feedback is transmitted together with PUSCH. Since CQI / PMI / RI for only one DL carrier is reported in one subframe, CQI / PMI / RI for other DL carriers can be dropped. Prioritization in case of collision of RI, WB CQI / PMI, and SB CQI as defined in 3GPP LTE Release-8 for one DL carrier determined to be fed back (ie, RI> WB CQI) / PMI, WB CQI, SB CQI), feedback information can be transmitted.

  When PUCCH and PUSCH are not set at the same time, when only periodic CQI / PMI / RI is transmitted without HARQA / N information, CQI / PMI / RI may be transmitted using PUCCH if PUSCH is not available. it can. On the other hand, if the PUSCH is available, CQI / PMI / RI can be transmitted using the PUSCH.

  In periodic CQI / PMI / RI report using PUCCH, various PUCCH report modes and report types as described above can be set.

  As the PUCCH reporting mode, mode 1-0, mode 1-1, mode 2-0, and mode 2-1 are set for 2 or 4 transmission antenna transmission, and mode 1 is set for 8 transmission antenna transmission. 1-1, mode 1-1-2, and mode 2-1 can be set.

  In the contents described throughout this specification, the feedback mode for 8 transmission antenna transmission can be expressed as the feedback mode for the downlink transmission mode 9 defined in 3GPP LTE Release-10. The downlink transmission mode 9 is a downlink transmission mode that supports 8-layer transmission. Also, the feedback mode for 2 or 4 transmission antenna transmission can be expressed as a feedback mode used for transmission modes other than the downlink transmission mode 9. For example, the report mode 2-1 for 8-transmit antenna transmission can be expressed as being used for the transmission mode 9. Further, as described above, the report mode 1-1-1 means the sub-mode 1 of the report mode 1-1 set for the transmission mode 9, and the report mode 1-1- 2 means sub-mode 2 of report mode 1-1 set for transmission mode 9.

  The PUCCH report type can be set as shown in Table 70.

このようなＰＵＣＣＨ報告タイプに対して適用可能な優先順位について説明する。単一搬送波上での周期的ＣＳＩ報告においては、ＰＵＣＣＨ報告タイプ３、５または６が最も長い報告周期を有する。また、ＰＵＣＣＨ報告タイプ１、１ａ、２、２ａ、２ｂ及び４のフィードバック情報は、報告されたＲＩ、ｗｂ １^ｓｔ ＰＭＩまたはＰＴＩに基づいて決定される。したがって、ＰＵＣＣＨ報告タイプ３、５または６がＰＵＣＣＨ報告タイプ１、１ａ、２、２ａ、２ｂ、２ｃまたは４と衝突する場合は、ＰＵＣＣＨ報告タイプ１、１ａ、２、２ａ、２ｂ、２ｃを低い優先順位により落とすことができる。一方、上記の実施例６で説明した通り、多重の制御情報の衝突時に適用される伝送優先順位は、ＳＲ、ＨＡＲＱ−ＡＣＫ、ＵＬ−ＳＣＨ（サブフレームバンドリング動作の場合）＞ＲＩ＞ＷＢ ＣＱＩ／ＰＭＩ、ＷＢ ＣＱＩ、ＳＢ ＣＱＩを適用することができる。例えば、ＳＲ制御情報とＣＱＩ／ＰＭＩ／ＲＩとが同一のサブフレームで衝突する場合には、ＣＱＩ／ＰＭＩ／ＲＩが落ち、ＳＲが伝送される。

Priorities applicable to such PUCCH report types will be described. For periodic CSI reporting on a single carrier, PUCCH report type 3, 5 or 6 has the longest reporting period. Also, the feedback information of PUCCH report types 1, 1a, 2, 2a, 2b and 4 is determined based on the reported RI, wb 1 ^st PMI or PTI. Therefore, when PUCCH report type 3, 5 or 6 collides with PUCCH report type 1, 1a, 2, 2a, 2b, 2c or 4, PUCCH report type 1, 1a, 2, 2a, 2b, 2c has lower priority. It can be dropped by rank. On the other hand, as described in the sixth embodiment, the transmission priority applied when multiple control information collides is SR, HARQ-ACK, UL-SCH (in the case of subframe bundling operation)>RI> WB CQI. / PMI, WB CQI, and SB CQI can be applied. For example, when SR control information and CQI / PMI / RI collide in the same subframe, CQI / PMI / RI falls and SR is transmitted.

  Based on the above matters, an embodiment proposed in the present invention for setting feedback priority will be described.

  As method 1, the feedback priority order can be determined based on the report type.

  As method 2, when the same report type collides when performing feedback for different DL carriers, the feedback priority can be determined according to the report mode.

  As method 3, the report types can be grouped and the feedback priority order can be determined based on the report type group.

  As a method 4, when the same report type group collides when performing feedback on different DL carriers, the feedback priority can be determined according to the report mode.

The PUCCH report mode as described above is composed of a combination of a plurality of report types. This is organized as shown in Table 71. In Table 71, wb represents feedback information for a wideband, sb represents feedback information for a subband, and 1 ^st PMI is a precoder index 1 (that is, i1 or W2 in the above description). 2 ^nd PMI represents the precoder index 2 (that is, corresponding to i2 or W2 in the above description).

次に、伝送周期及びフィードバック情報の属性に基づいて報告タイプを下記表７２のようにグループ化できる。

Next, report types can be grouped as shown in Table 72 below based on the attributes of the transmission period and feedback information.

上記表７１で、報告タイプグループＡは、ＲＩを含むフィードバック情報の集合で構成され、報告タイプグループＢは、ｗｂ １^ｓｔ ＰＭＩを含むフィードバック情報の集合で構成され、報告タイプグループＣは、ｗｂ ＣＱＩを含むフィードバック情報の集合で構成され、報告タイプグループＤは、ＳＢ ＣＱＩを含むフィードバック情報の集合で構成される。

In Table 71 above, report type group A is configured with a set of feedback information including RI, report type group B is configured with a set of feedback information including wb 1 ^st PMI, and report type group C is configured with wb CQI. The report type group D is composed of a set of feedback information including SB CQI.

  Thereby, as proposed in the above-described method 3, the feedback priority order can be set by the report type group. An example of the present invention in which the priority order is set based on the attribute of each feedback information will be specifically described.

  RI information is information reported intermittently. If the RI information is not reported, the RI has a considerably long reporting period. Therefore, the old (or incorrect) rank information is applied until the next RI report, which may lead to performance degradation. Therefore, when comparing with other feedback information, the RI may be set to have a high priority. As in report types 3, 5 and 6, group A containing RI (ie, RI report group) may have a higher feedback priority than groups containing CQI / PMI.

Next, wb 1 ^st PMI is information serving as a basis for selecting / calculating WB CQI / wb 2 ^nd PMI / sb CQI / sb 2nd PMI and the like. If wb 1 ^st PMI is not reported, it is difficult to select / calculate CQI / PMI information reported thereafter. Therefore, wb 1 ^st PMI may have a higher feedback priority than wb CQI / wb 2 ^nd PMI / sb CQI / sb 2 ^nd PMI. wb is 1 report period of ^st PMI can be determined by the RRC signaling, it may be determined reporting cycle of wb ¹ st PMI to be repeatedly reported in the period in which RI information is reported.

  Next, when determining the priority order of WB CQI and SB CQI information, the frequency of reporting and dependency may be taken into consideration. After the WB CQI + WB PMI information is transmitted in the PUCCH feedback mode 2-1 for 2 and 4 transmission antenna transmissions, the SB CQI is calculated based on the reported WB PMI. Therefore, it can be said that SB CQI has dependency on WB CQI + wbPMI. Also, the SB CQI information is recognized as auxiliary information for improving performance, and is transmitted more frequently than the WB CQI information. Therefore, wb CQI information can be set to have a higher priority than SB CQI information. Group C containing wb CQI as in report types 4, 2, 2b, 2c (ie, wb CQI report group) is group D containing SB CQI as in report type 1, 1a (ie, sb CQI report group) It can be set to have a higher feedback priority than

  Based on the foregoing, priority settings can be defined in various ways when different report type groups A, B, C, D collide in the same subframe. Table 73 below shows examples of priority setting.

表７３で、例示１は、ＲＩを含むグループが最も高い優先順位を有し、続いてｗｂ １^ｓｔ ＰＭＩを含むグループ、ＷＢ ＣＱＩを含むグループ、ＳＢ ＣＱＩを含むグループの順に優先順位を設定する例示である。例示２は、ＲＩを含むグループとｗｂ １^ｓｔ ＰＭＩを含むグループとが同じ優先順位を有し、続いてＷＢ ＣＱＩを含むグループ、ＳＢ ＣＱＩを含むグループの順に優先順位を設定する例示である。例示３は、ＲＩを含むグループが最も高い優先順位を有し、続いてｗｂ １^ｓｔ ＰＭＩを含むグループとＷＢ ＣＱＩを含むグループが同じ優先順位を有し、ｓｂ ＣＱＩを含むグループが最も低い優先順位を有する例示である。例示４は、ｗｂ １^ｓｔ ＰＭＩを含むグループが最も高い優先順位を有し、続いてＲＩを含むグループ、ＷＢ ＣＱＩを含むグループ、ＳＢ ＣＱＩを含むグループの順に優先順位を設定する例示である。

In Table 73, Example 1 is an example in which a group including RI has the highest priority, followed by a group including wb 1 ^st PMI, a group including WB CQI, and a group including SB CQI. It is. In the example 2, the group including the RI and the group including the wb 1 ^st PMI have the same priority, and subsequently, the priority is set in the order of the group including the WB CQI and the group including the SB CQI. Example 3 shows that the group containing RI has the highest priority, followed by the group containing wb 1 ^st PMI and the group containing WB CQI have the same priority, and the group containing sb CQI has the lowest priority. It is an example which has. Example 4 is an example in which a group including wb 1 ^st PMI has the highest priority, followed by setting a priority in the order of a group including RI, a group including WB CQI, and a group including SB CQI.

  On the other hand, as in the above-described method 4, the feedback priority order can be set for the feedback information belonging to the same report type group by the report mode. For example, the reporting mode 2-1 for 8 transmission antenna transmission is the reporting mode 1-0, 1-1, 2-0 or 2-1, for 2 or 4 transmission antenna transmission, and the reporting mode 1-1 for 8 transmission antenna transmission. -1 or 1-1-2 can be set to have a higher priority. Thereby, the priority of each report type can be determined within one report type group.

  For example, report types 3, 5 and 6 belong to group A (report type group including RI). Report type 6 is used to configure feedback mode 2-1 for 8-transmit antenna transmission. Report type 3 is used to configure reporting modes 1-0, 1-1, 2-0, 2-1 for 2 or 4 transmit antenna transmissions. Report type 5 is used to configure reporting modes 1-1-1 and 1-1-2 for 8 transmit antenna transmissions. Here, in the report mode 2-1 for 8-transmit antenna transmission, the precoding type to be subsequently reported is determined by the PTI value transmitted together with the RI. Therefore, RI + PTI can have a higher importance than RI-only transmission or RI + PMI transmission.

  In addition, report types 4, 2, 2b and 2c belong to group C (a group of report types including wb CQI). Report types 4, 2, 2b are used for SB CQI reporting modes 2-0, 2-1 and reporting mode 2-1 for 8 transmit antenna transmissions. Also, report types 4, 2, and 2b are used for WB CQI report modes 1-0, 1-1, and report mode 1-1-1 for 8 transmit antenna transmissions. Here, in the SB CQI report, the report types 4, 2, and 2b are information that should always be used for feedback information to be reported next, and thus can be set to have high importance. Therefore, the importance of the feedback information of the same report type can be determined depending on which feedback mode is transmitted.

  Accordingly, the priority setting of each report type in the report type group is illustrated in Table 74 below.

フィードバック優先順位設定について本発明で提案するさらなる実施例を以下に説明する。

A further embodiment proposed in the present invention for feedback priority setting is described below.

  As method 5, priority is given to each report type or report type group, and for report types belonging to the same report type group, the priority of the report type is set according to the priority given by the RRC setting for each downlink carrier. can do.

  As a method 6, priority can be given to each report type or report type group, and priority can be set between report types belonging to the same report type group by RRC setting.

  When a report type group is set as shown in Table 72 and priority among report type groups is set as shown in Example 1 of Table 73 (ie, A> B> C> D), multiple- The priority for each report type in the feedback report for each downlink carrier in the situation of carrier transmission may be set according to the priority of the report type group.

  For example, if report type 3, 5 or 6 collides with report type 1, 1a, 2, 2a, 2b, 2c or 4, low priority report type 1, 1a, 2, 2a, 2b, 2c or 4 Can be dropped. If report type 2a collides with report type 1, 1a, 2, 2b, 2c or 4, the lower priority report type 1, 1a, 2, 2b, 2c or 4 can be dropped. If report type 2, 2b, 2c or 4 collides with report type 1 or 1a, the lower priority report type 1, 1a can be dropped.

  Next, when a report type group is set as shown in Table 72 and priority among report type groups is set as shown in Example 2 of Table 73 (that is, A = B> C> D), The priority for each report type in the feedback report for each downlink carrier in the multi-carrier transmission situation can be set according to the priority of the report type group.

  For example, if report type 3, 5, 6 or 2a collides with report type 4, 2, 2b, 2c, 1 or 1a, the lower priority report type 4, 2, 2b, 2c, 1 or 1a Can be dropped. Also, if report type 4, 2, 2b or 2c collides with report type 1 or 1a, lower priority report type 1 or 1a can be dropped.

  Next, when a report type group is set as shown in Table 72 and priority among report type groups is set as shown in Example 3 of Table 73 (that is, A> B = C> D). In the multi-carrier transmission situation, the priority for each report type in the feedback report for each downlink carrier can be set according to the priority of the report type group.

  For example, if report type 3, 5 or 6 collides with report type 2a, 4, 2, 2b, 2c, 1 or 1a, low priority report type 2a, 4, 2, 2b, 2c, 1 or 1a Can be dropped. Also, if the report type 2a, 4, 2, 2b or 2c collides with the report type 1 or 1a, the lower priority report type 1 or 1a can be dropped.

  Hereinafter, whether to give priority to the periodic CSI report for which carrier in the case of multi-carrier transmission will be described more specifically based on the above-described matters. In the case of multi-carrier transmission, in the periodic CSI report, higher layer configuration parameters related to the periodic PUCCH report are determined independently for each downlink carrier, so that reporting is performed compared to the case of single-carrier transmission. Various types of collisions occur between types.

  Assume that the PUCCH report mode and report type for the downlink transmission mode 9 and other transmission modes are set as shown in Table 71 above. For example, PUCCH report types 1 and 2 do not collide in periodic CSI reporting for single carrier transmission, but they may collide in multi-carrier transmission. Therefore, a solution for that is required.

  In periodic CSI reporting for multi-carrier transmission, as described above, downlink carrier (or DL cell) selection by priority based on the report mode is possible. However, it is essential for an activated DL carrier if it is applied as a prerequisite to apply DL carrier selection priority for periodic CQI / PMI / RI reporting based on the reporting mode. Report information may be frequently dropped. It should also be considered that the DL carrier selection priority can be applied according to the RRC configured rules for periodic CQI / PMI / RI reporting as in the case of report type collisions. Therefore, there is ambiguity when applying DL carrier selection priority based on report mode in a situation where multiple carriers are set. On the other hand, determining the report priority only based on the report type has an advantage that it can be implemented simply by preventing important feedback information from dropping.

  Therefore, the report types can be grouped as shown in Table 72, and the feedback priority by the report type group can be applied as A> B = C> D. As an alternative, in the case of carrier aggregation, the report type with the highest priority (report type 3, 5 or 6) maintains that priority, and the DL carrier is determined according to the priority based on the report type. Can do.

Next, determination of the priority order of the PUCCH report type 2a including wb 1 ^st PMI will be specifically described.

  FIG. 34 is a diagram illustrating a reporting period in the periodic PUCCH reporting mode 2-1 regarding the transmission mode 9 described in Table 71 above. The reporting period of periodic PUCCH reporting mode 2-1 for transmission mode 9 can be determined according to the reporting type and PTI configuration. Referring to FIG. 34, report type 6 (RI + PTI) is

の報告周期を有することができる。図３４（ａ）に示すように、ＰＴＩ＝０の場合には、報告タイプ２ａ（ｗｂ １^ｓｔ ＰＭＩ）が

Reporting period. As shown in FIG. 34 (a), when PTI = 0, the report type 2a (wb 1 ^st PMI) is

の報告周期を有し、報告タイプ２ｂ（ｗｂ ２^ｎｄ ＰＭＩ及びＷＢ ＣＱＩ）が報告タイプ２ａ伝送以降の

Report type 2b (wb 2 ^nd PMI and WB CQI) after report type 2a transmission

タイミングで報告されうる。また、ＰＴＩ＝１の場合には、報告タイプ２ｂが

Can be reported at timing. If PTI = 1, report type 2b is

の報告周期を有し、報告タイプ１ａ（ｓｂ ２^ｎｄ ＰＭＩ及びＳＢ ＣＱＩ）が報告タイプ２ｂ伝送以降の

Report type 1a (sb 2 ^nd PMI and SB CQI) after report type 2b transmission

タイミングで報告されうる。図３４では、Ｍ＝２の場合に対する８アンテナポートのＣＳＩ−ＲＳを用いた下りリンク伝送モード９に関するＰＵＣＣＨ報告モード２−１の報告周期の一例を示している。

Can be reported at timing. FIG. 34 shows an example of the reporting period of PUCCH reporting mode 2-1 for downlink transmission mode 9 using CSI-RS of 8 antenna ports for the case of M = 2.

  As shown in FIG. 34 (a), when PTI = 0, the report type 2a can have the same period as the report type 2b. Also, as shown in FIG. 34 (b), when PTI = 1, the reporting period of report type 2a may be much shorter than the reporting period of report type 2b.

If we simply apply a priority rule that causes a report type with a longer reporting period to have a higher priority, report type 2b should have a higher priority than report type 2a. . However, in the codebook structure for 8-transmit antenna transmission, report type 2a (wb 1 ^st PMI) contains long-term spatial channel information, and report type 2b (wb 2 ^nd PMI and WB CQI) Are further related to short-term spatial channel information. Therefore, it is preferable that report type 2a has a higher priority than other report types except report type 6 (RI + PTI). Therefore, for the PUCCH reporting mode 2-1 for the transmission mode 9 in the multi-carrier situation, the reporting type 2a has higher priority than the reporting types 1, 1a, 2, 2b, 2c and 4. Can do.

  Based on the above, general rules regarding the priorities of DL carrier (or DL cell) selection for periodic CQI / PMI / RI reports in the case of multi-carrier transmission are summarized as follows.

As a priority order for which DL carrier CSI is fed back, a priority order between DL carriers activated based on a CSI feedback report type can be determined. Therefore, as shown in Table 72 above, group A including RI (report types 3, 5, and 6), group B including wb 1 ^st PMI without CQI (report type 2a), and group C including WB CQI (report) Type 2, 2b, 2c, 4) and group D (report type 1, 1a) including SB CQI, and define the priority of each report type group as A>B>C> D Can do. If the report types have the same priority, it is only necessary to determine which DL carrier CSI is to be fed back according to the priority set in the RRC between the activated DL carriers. The CQI / PMI / RI for the DL carrier thus determined can be transmitted, and the CQI / PMI / RI for the other DL carrier can be dropped.

  If the same PUCCH report type collides, the PUCCH report type of the DL carrier with the highest priority is reported among the DL carriers activated by higher layers (DL cell), and other DL carriers are reported. CQI / PMI / RI for can be dropped. For example, when the PUCCH report type 6 is set to be transmitted at the specific timing x as the CSI for the DL carrier # 1, the PUCCH report type 6 is set as the CSI for the other DL carrier # 2. Can be assumed to be transmitted at the same timing x. In this case, when the priority set in the RRC-set for the DL carrier # 1 is higher than the DL carrier # 2, the PUCCH report type 6 for the DL carrier # 1 is transmitted, and the PUCCH report type for the other DL carrier # 2 is transmitted. 6 can be dropped.

  Based on the proposal of the present invention as described above, if the priority between report type groups is set as A> B> C> D, any one for one or more DL carriers (or DL cells) A priority setting method regarding whether to transmit CSI of a DL carrier can be expressed as follows.

  When PUCCH report type 3, 5 or 6 collides with PUCCH report type 1, 1a, 2, 2a, 2b, 2c or 4, the latter PUCCH report type (1, 1a, 2, 2a, 2b, 2c or 4 ) Has a low priority and can be dropped.

  When PUCCH report type 2a collides with PUCCH report type 1, 1a, 2, 2b, 2c or 4, the latter PUCCH report type (1, 1a, 2, 2b, 2c or 4) has lower priority Can be dropped.

  If PUCCH report type 2, 2b, 2c or 4 collides with PUCCH report type 1 or 1a, the latter PUCCH report type (1, 1a) has a lower priority and can be dropped.

  If the same PUCCH report type collides, it reports the PUCCH report type with the highest priority set by higher layers between activated DL carriers (DL cells) and CQI / PMI for other DL carriers. / RI can be dropped.

On the other hand, as shown in Table 72 above, group A including RI (report types 3, 5, and 6), group B including wb 1 ^st PMI without CQI (report type 2a), and group C including WB CQI (report type) 2, 2b, 2c, 4), and group D (report type 1, 1a) including SB CQI, and determining priorities among activated DL carriers based on the report type. Embodiments of the present invention with other settings of report type group priorities are described below.

  As an example, if the priority between the report type groups is set as A = B> C = D, the report type 3, 5, 6 or 2a is changed to report type 4, 2, 2b, 2c, Upon collision with 1 or 1a, report type 4, 2, 2b, 2c, 1 or 1a has a lower priority and can be dropped. If the priority order of the PUCCH report type is the same, the feedback priority order may be determined according to the priority order RRC-set between the activated DL carriers (DL cells). CQI / PMI / RI for other DL carriers can be dropped.

  As another example, if the priority between report type groups is set as A> B> C = D, PUCCH report types 3, 5 or 6 are PUCCH report types 2, 2a, 2b, 2c, In the event of a collision with 4, 1 or 1a, PUCCH report types 2, 2a, 2b, 2c, 4, 1 or 1a have lower priority and can be dropped. Also, when PUCCH report type 2a collides with PUCCH report type 2, 2b, 2c, 4, 1 or 1a, PUCCH report type 2, 2b, 2c, 4, 1 or 1a has lower priority and drops. be able to. When the priority order of the PUCCH report type is the same, the feedback priority order may be determined according to the priority order RRC-set between the activated DL carriers (DL cells). CQI / PMI / RI for other DL carriers can be dropped.

  In the above-mentioned 14th Example, when the upper plan regarding the priority of the periodic CSI report using PUCCH when a multicarrier is set up, it will become as follows.

  First, when more than one serving cell (more than one serving cell) is configured in a terminal, the terminal transmits channel state information (CSI) for only one serving cell in an arbitrary subframe (in any given subframe). can do.

  If the feedback information of the first serving cell has a higher priority than the feedback information of the second serving cell according to the attribute of the feedback information in an arbitrary subframe, the feedback information of the second serving cell having a lower priority can be dropped.

  For example, Example 2 in Table 73 will be described based on the report type (or PUCCH report type) in Table 70 as the priority of feedback information for CSI as follows.

  If the PUCCH report type 3, 5, 6 or 2a of one serving cell collides with the PUCCH report types 1, 1a, 2, 2b, 2 or 4 of another serving cell in any subframe, the latter CSI (ie, PUCCH report types 1, 1a, 2, 2b, 2 or 4) have lower priority and can be dropped.

  If PUCCH report type 2, 2b, 2c or 4 of one serving cell collides with PUCCH report type 1 or 1a of another serving cell in any subframe, the latter CSI (ie PUCCH report type 1 or 1a) is Has lower priority and can be dropped.

  When CSI reports of different serving cells having PUCCH report types having the same priority in any subframe collide with each other, a specific serving cell (serving cell having a higher priority according to RRC configuration, e.g., most CSI for a serving cell with a low serving cell index) is reported, and the CSI for the remaining serving cells may drop.

  With reference to FIG. 35, a channel state information reporting method according to a preferred embodiment of the present invention will be described.

  For downlink transmission from the base station to the terminal, the terminal can measure the downlink channel state and feed back the result to the base station through the uplink. For example, when 8 transmission antennas are used for downlink transmission of a base station, the base station transmits channel state information-reference signal (CSI-RS) through 8 antenna ports (antenna port indexes 15 to 22). Can do. The terminal can transmit the result of measuring the downlink channel state (RI, PMI, CQI, etc.) from the CSI-RS. The above-described various examples of the present invention can be applied to a specific method for selecting / calculating RI / PMI / CQI. The base station can determine the number of downlink transmission layers, precoder, modulation and coding technique (MCS) level, etc. based on the received channel state information (RI / PMI / CQI), and transmits the downlink signal accordingly. be able to.

  In step S3510 of FIG. 35, the UE may generate channel state information (CSI) for each of one or more downlink carriers (DL cells). The CSI may include one or more CQIs calculated based on precoding information determined by RI, first PMI, second PMI, and first and second PMI for one or more downlink carriers. it can.

  In step S3520, the UE may determine whether two or more CSIs collide in one uplink subframe on one uplink carrier.

  When two or more CSIs collide, in step S3530, the CSI to be transmitted can be determined based on the priority order. Here, in order to determine the priority order, CSI is classified into a first group including RI, a second group including broadband first PMI, a third group including broadband CQI, and a fourth group including subband CQI. Can do. As a result, when CSI belonging to the first group or CSI belonging to the second group collides with CSI belonging to the third group or CSI belonging to the fourth group, it belongs to the third group or the fourth group. CSI has a low priority and can be dropped. Also, the CSI belonging to the first group and the CSI belonging to the second group may have the same priority. When the CSI belonging to the third group and the CSI belonging to the fourth group collide, the CSI belonging to the fourth group has a low priority and can be dropped.

  Also, if the priority given by the group is the same, when the CSI related to the downlink transmission mode using 8 transmission antennas collides with the CSI related to the other downlink transmission mode, the CSI related to the other downlink transmission mode. Has a low priority and can be dropped. In addition or separately, the CSI for a downlink carrier having a higher priority set by a higher layer for each of one or more downlink carriers may have a higher priority. Or the priority setting of the various systems demonstrated by this invention mentioned above may be applied.

  In step S3540, the UE can transmit the CSI determined to be transmitted using the uplink channel. The uplink channel may be PUCCH. Alternatively, the uplink channel is PUSCH, and the above-described priority order may be applied when CSI for different carriers collides.

  In the channel state information transmission method of the present invention described with reference to FIG. 35, the matters described in the various embodiments of the present invention described above may be applied independently, and two or more embodiments may be applied simultaneously. May be. Here, overlapping contents will be omitted for clarity.

  In addition, channel state information feedback for MIMO transmission (in the backhaul uplink and backhaul downlink) between the base station and the relay and MIMO transmission (in the access uplink and access downlink) between the relay and the terminal. Also, the principle proposed in the present invention can be similarly applied.

  FIG. 36 is a diagram showing the configurations of the base station apparatus and terminal apparatus according to the present invention.

  Referring to FIG. 36, a base station device 3610 according to the present invention may include a reception module 3611, a transmission module 3612, a processor 3613, a memory 3614, and a plurality of antennas 3615. The plurality of antennas 3615 means a base station apparatus that supports MIMO transmission / reception. The reception module 3611 can receive various signals, data, and information on the uplink from the terminal. The transmission module 3612 can transmit various signals, data, and information on the downlink to the terminal. The processor 3613 can control the overall operation of the base station device 3610.

  The base station apparatus 3610 according to an embodiment of the present invention may be configured to perform downlink transmission using a maximum of 8 transmission antennas and receive channel state information for downlink transmission from the terminal apparatus 3620. Also, the base station apparatus can receive channel state information for one or more downlink carriers from the terminal. When the base station receives channel state information for one or more downlink carriers through the PUCCH of one uplink carrier, the channel state information received by the base station is channel state information determined according to priority by the terminal. There may be.

  Further, the processor 3613 of the base station apparatus 3610 also performs a function of calculating information received by the base station apparatus 3610 and information transmitted to the outside, and the memory 3614 stores the calculated information and the like for a predetermined time. And may replace components such as a buffer (not shown).

  Referring to FIG. 36, a terminal device 3620 according to the present invention may include a reception module 3621, a transmission module 3622, a processor 3623, a memory 3624, and a plurality of antennas 3625. The plurality of antennas 3625 means a terminal device that supports MIMO transmission / reception. The reception module 3621 can receive various signals, data, and information on the downlink from the base station. The transmission module 3622 can transmit various signals, data, and information on the uplink to the base station. The processor 3623 can control the overall operation of the terminal device 3620.

  A terminal device 3620 according to an embodiment of the present invention receives downlink transmissions via a maximum of 8 transmission antennas from the base station device 3610, and feeds back channel state information for these downlink transmissions to the base station. can do. The processor 3623 of the terminal apparatus may use one or more CQIs calculated based on precoding information determined by RI, the first PMI, the second PMI, and the combination of the first and second PMIs for one or more downlink carriers. Can be configured to generate CSI. Further, the processor 3623 may be configured to determine the CSI to be transmitted based on the priority order when two or more CSIs collide in one uplink subframe on one uplink carrier. . Further, the processor 3623 may be configured to transmit the determined CSI using the uplink channel via the transmission module 3622. Here, the CSI can be classified into a first group including RI, a second group including a wideband first PMI, a third group including a wideband CQI, and a fourth group including a subband CQI. In addition, when the CSI belonging to the first group or the CSI belonging to the second group collides with the CSI belonging to the third group or the CSI belonging to the fourth group, the priority order is the third group or the fourth group. CSIs that belong to have a low priority and can be set to drop.

  Further, the processor 3623 of the terminal device 3620 performs a function of calculating information received by the terminal device 3620, information transmitted to the outside, and the like, and the memory 3624 can store the calculated information and the like for a predetermined time. Alternatively, a component such as a buffer (not shown) may be substituted.

  The specific configurations of such base station apparatuses and terminal apparatuses are such that the matters described in the various embodiments of the present invention are applied independently, or two or more embodiments are applied simultaneously. The description can be omitted for the sake of clarity.

  In the description of FIG. 36, the description regarding the base station device 3610 can also be applied to the repeater device as the downlink transmission subject or the uplink reception subject, and the description regarding the terminal device 3620 is related to the downlink reception. The same application is also possible for a repeater device as a main body or an uplink transmission main body.

  The above-described embodiments of the present invention can be implemented through various means. For example, the embodiments of the present invention may be implemented by hardware, firmware, software, or a combination thereof.

  In the case of implementation by hardware, the method according to an embodiment of the present invention may include one or more ASICs (application specific integrated circuits), DSPs (digital signal processing), DSPSs (digital signal coding), DSPDs (digital signal processing). logic devices), FPGAs (field programmable gate arrays), a processor, a controller, a microcontroller, a microprocessor, and the like.

  When implemented by firmware or software, a method according to an embodiment of the present invention may be in the form of a module, procedure, function, or the like that performs the functions or operations described above. The software code can be stored in a memory unit and driven by a processor. The memory unit is provided inside or outside the processor, and can exchange data with the processor by various known means.

  The detailed description of the preferred embodiments of the present invention disclosed above is provided to enable any person skilled in the art to implement and practice the present invention. Although the foregoing has been described with reference to the preferred embodiments of the present invention, it will be understood by those skilled in the art that the present invention can be variously modified and changed without departing from the scope of the present invention. Will be understood. For example, those skilled in the art can use the configurations described in the above embodiments in a combination manner. Accordingly, the present invention is not intended to be limited to the embodiments disclosed herein, but is to provide the widest scope consistent with the principles and novel features disclosed herein.

  The present invention may be embodied in other specific forms without departing from the spirit and essential characteristics of the invention. As such, the above detailed description should not be construed as limiting in any respect, but should be considered as exemplary. The scope of the invention should be determined by reasonable interpretation of the appended claims and any changes that come within the equivalent scope of the invention are included in the scope of the invention. The present invention is not limited to the embodiments disclosed herein, but has the widest scope consistent with the principles and novel features disclosed herein. In addition, claims which do not have an explicit citation relationship in the claims can be combined to constitute an embodiment, or can be included as a new claim by amendment after application.

  In the system using multiple antennas as described above, various embodiments of the present invention related to a method for effectively reporting feedback information may include various mobile communication systems (OFDMA, SC-FDMA, CDMA, TDMA, etc.) using multiple antennas. It can be applied to all communication systems based on the multiple connection technology.

Claims (16)

A method for transmitting channel state information (CSI) for downlink multi-carrier transmission, comprising:
Calculated based on rank indicator (RI) for one or more downlink carriers, first precoding matrix index (PMI), second PMI, and precoding information determined by a combination of the first and second PMI. Generating the CSI including one or more of a channel quality indicator (CQI);
Determining two CSIs to be transmitted based on priority when two or more CSIs collide in one uplink subframe on one uplink carrier; and
Transmitting the determined CSI using an uplink channel;
Have
The CSI is classified into a first group including RI, a second group including a broadband first PMI, a third group including a broadband CQI, and a fourth group including a subband CQI.
The priority is determined when the CSI belonging to the first group or the CSI belonging to the second group collides with the CSI belonging to the third group or the CSI belonging to the fourth group. Alternatively, the CSI belonging to the fourth group has a low priority and is set to drop.   The channel state information transmission method according to claim 1, wherein CSI belonging to the first group and CSI belonging to the second group have the same priority.   When the CSI related to the downlink transmission mode using the 8 transmission antennas collides with the CSI related to the other downlink transmission mode, the priority order of the CSI related to the other downlink transmission mode is low. The channel state information transmission method according to claim 1, which has and falls.   When the priorities are the same, CSI related to a downlink carrier having a high priority set by an upper layer for each of the one or more downlink carriers is transmitted using the uplink channel. The channel state information transmission method according to claim 1.   The channel state according to claim 1, wherein when a CSI belonging to the third group collides with a CSI belonging to the fourth group, the CSI belonging to the fourth group has a low priority and falls. Information transmission method.   2. The channel state information transmission method according to claim 1, wherein, when the first PMI falls, channel state information following the dropped first PMI is generated based on a first PMI defined in advance.   The channel state information transmission method according to claim 1, wherein the uplink channel is a physical uplink control channel (PUCCH).   The channel state information transmission method according to claim 1, wherein the uplink channel is a physical uplink shared channel (PUSCH), and the priority is applied when CSIs for different carriers collide. A terminal that transmits channel state information (CSI) for downlink multi-carrier transmission,
A receiving module for receiving a downlink signal from the base station;
A transmission module for transmitting an uplink signal to the base station;
A processor for controlling the terminal including the receiving module and the transmission module,
The processor is based on precoding information determined by a rank indicator (RI), a first precoding matrix index (PMI), a second PMI, and a combination of the first and second PMIs for one or more downlink carriers. Generating the CSI including one or more of the channel quality indicators (CQI) calculated by:
When two or more CSIs collide in one uplink subframe on one uplink carrier, determine the CSI to be transmitted based on the priority,
Via the transmission module, configured to transmit the determined CSI using an uplink channel;
The CSI is classified into a first group including RI, a second group including a broadband first PMI, a third group including a broadband CQI, and a fourth group including a subband CQI.
The priority is determined when the CSI belonging to the first group or the CSI belonging to the second group collides with the CSI belonging to the third group or the CSI belonging to the fourth group. Or, the CSI belonging to the fourth group has a low priority and is set to drop.   The channel state information transmission terminal according to claim 9, wherein the CSI belonging to the first group and the CSI belonging to the second group have the same priority.   When the CSI related to the downlink transmission mode using the 8 transmission antennas collides with the CSI related to the other downlink transmission mode, the priority order of the CSI related to the other downlink transmission mode is low. The channel state information transmission terminal according to claim 9, which has and falls.   When the priorities are the same, CSI related to a downlink carrier having a high priority set by an upper layer for each of the one or more downlink carriers is transmitted using the uplink channel. The channel state information transmission terminal according to claim 9.   The channel state according to claim 9, wherein when a CSI belonging to the third group collides with a CSI belonging to the fourth group, the CSI belonging to the fourth group has a low priority and falls. Information transmission terminal.   The channel state information transmission terminal according to claim 9, wherein when the first PMI falls, channel state information subsequent to the dropped first PMI is generated based on the first PMI defined in advance.   The channel state information transmission terminal according to claim 9, wherein the uplink channel is a physical uplink control channel (PUCCH).   The channel state information transmission terminal according to claim 9, wherein the uplink channel is a physical uplink shared channel (PUSCH), and the priority is applied when CSIs for different carriers collide.

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