KR20180013650A - Method and apparatus for csi reporting in wireless communication system - Google Patents

Abstract

The present disclosure relates to a communication technique for combining IoT technology with a 5G communication system for supporting a higher data transmission rate after a 4G system and a system thereof. The present disclosure can be applied to an intelligent service (for example, a smart home, a smart building, a smart city, a smart car or a connected car, a health care, a digital education, a retail, a security and safety-related service, etc.) based on 5G communication technology and IoT-related technology. The present invention discloses a method for measuring a channel and interference of a base station and a terminal for efficiently measuring a channel characteristic and an interference characteristic varied according to a support service, a method for processing channel state information, and a method and apparatus for reporting the channel state information. A method for processing a control signal according to the present invention includes the steps of: receiving a first control signal; processing the received first control signal; and transmitting a second control signal to the base station.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for reporting channel state information in a mobile communication system,

The present invention relates to a wireless communication system, and more particularly, to a method and apparatus for measuring channel and interference of a base station and a terminal for efficiently measuring a channel characteristic and an interference characteristic depending on a support service, Reporting method and apparatus.

Efforts are underway to develop an improved 5G or pre-5G communication system to meet the growing demand for wireless data traffic after commercialization of the 4G communication system. For this reason, a 5G communication system or a pre-5G communication system is called a system after a 4G network (Beyond 4G network) communication system or after a LTE system (Post LTE). To achieve a high data rate, 5G communication systems are being considered for implementation in very high frequency (mmWave) bands (e.g., 60 gigahertz (60GHz) bands). In order to mitigate the path loss of the radio wave in the very high frequency band and to increase the propagation distance of the radio wave, in the 5G communication system, beamforming, massive MIMO, full-dimension MIMO (FD-MIMO ), Array antennas, analog beam-forming, and large scale antenna technologies are being discussed. In order to improve the network of the system, the 5G communication system has developed an advanced small cell, an advanced small cell, a cloud radio access network (cloud RAN), an ultra-dense network, (D2D), a wireless backhaul, a moving network, cooperative communication, Coordinated Multi-Points (CoMP), and interference cancellation Have been developed. In addition, in the 5G system, the Advanced Coding Modulation (ACM) scheme, Hybrid FSK and QAM Modulation (FQAM) and Sliding Window Superposition Coding (SWSC), the advanced connection technology, Filter Bank Multi Carrier (FBMC) (non-orthogonal multiple access), and SCMA (sparse code multiple access).

On the other hand, the Internet is evolving into an Internet of Things (IoT) network in which information is exchanged between distributed components such as objects in a human-centered connection network where humans generate and consume information. IoE (Internet of Everything) technology, which combines IoT technology with big data processing technology through connection with cloud servers, is also emerging. In order to implement IoT, technology elements such as sensing technology, wired / wireless communication, network infrastructure, service interface technology and security technology are required. In recent years, sensor network, machine to machine , M2M), and MTC (Machine Type Communication). In the IoT environment, an intelligent IT (Internet Technology) service can be provided that collects and analyzes data generated from connected objects to create new value in human life. IoT is a field of smart home, smart building, smart city, smart car or connected car, smart grid, health care, smart home appliance, and advanced medical service through fusion of existing information technology . ≪ / RTI >

Accordingly, various attempts have been made to apply the 5G communication system to the IoT network. For example, technologies such as a sensor network, a machine to machine (M2M), and a machine type communication (MTC) are implemented by techniques such as beamforming, MIMO, and array antennas It is. The application of the cloud RAN as the big data processing technology described above is an example of the convergence of 5G technology and IoT technology.

On the other hand, NR (New Radio Access Technology), a new 5G communication, is designed to freely multiplex various services in time and frequency resources. Accordingly, waveform / numerology and reference signals are dynamic Or can be freely assigned. In order to provide optimal service to the terminal in wireless communication, it is important to optimize the data transmission by measuring the quality of the channel and the interference amount, and accordingly, accurate channel state measurement is essential. However, unlike 4G communication, in which the channel and interference characteristics do not change significantly according to frequency resources, the channel and interference characteristics of the 5G channel vary greatly depending on the service. Therefore, the VRG (Vertical Resource Group) It is necessary to support the subset of.

It is an object of the present invention to provide a method and apparatus for providing data transmission and reception for a 5G communication service. In particular, the present invention provides a method for operating a transmission time interval of various lengths in order to satisfy a 5G communication service having various requirements, and a method for transmitting and receiving data of a base station and a terminal, and an apparatus therefor.

Still another object of the present invention is to provide various services such as Enhanced Mobile Broadband (eMBB), Massive Machine Type Communications (mMTC), URLLC (Ultra-Reliable and Low Latency Communications), and FCR (Forward Compatiable Resource) A channel state information subset according to a frequency unit and a channel state information reporting method optimized for a service in order to measure and report channel state information and interference characteristics depending on characteristics of a corresponding service.

Another object of the present invention is to describe a method of operating a delay-reduced mode of a base station and a terminal when a time required for signal processing between the base station and the terminal can be reduced in an LTE system using FDD or TDD.

It is still another object of the present invention to provide a control channel structure that can be flexibly set to satisfy 5G wireless communication requirements.

According to an aspect of the present invention, there is provided a method of processing a control signal in a wireless communication system, the method comprising: receiving a first control signal transmitted from a base station; Processing the received first control signal; And transmitting the second control signal generated based on the process to the base station.

According to an embodiment of the present invention, there is provided a method and apparatus for providing data transmission / reception for a 5G communication service. In particular, the present invention provides a method for operating transmission time intervals of various lengths to satisfy a 5G communication service having various requirements, and a method for transmitting and receiving data of a base station and a terminal, and an apparatus therefor. Meanwhile, various other effects will be directly or implicitly disclosed in the detailed description according to the embodiment of the present invention to be described later.

According to another embodiment of the present invention, when another service is supported according to time and frequency resources, a subsystem for reporting channel state information can be divided and set according to a frequency resource according to the service, And to report different channel conditions according to the type of service causing the interference. In addition, when reporting the channel status, different types of channel status reports may be performed according to services supported by the terminal.

According to another embodiment of the present invention, a method for operating a delay-reduced mode of a base station and a terminal is provided to reduce a delay time during uplink and downlink data transmission.

According to another embodiment of the present invention, a control channel structure having a flexible structure for transmitting a downlink control signal is provided, so that a 5G wireless communication system supporting various services having different requirements can be effectively operated .

1A is a diagram illustrating a basic structure of a time-frequency domain in an LTE system.
1B is a diagram illustrating an example in which 5G services are multiplexed and transmitted in one system.
FIG. 1C is a diagram showing a 1-1th embodiment of a communication system to which the present invention is applied.
FIG. 1D is a diagram showing a first-second embodiment of a communication system to which the present invention is applied.
FIG. 1E is a diagram illustrating subframe structures proposed in the present invention.
1F is a diagram showing a situation to be solved by the present invention.
FIG. 1G is a view showing the 1-1th embodiment proposed by the present invention.
FIG. 1H is a view showing the first and second embodiments proposed by the present invention.
FIG. 1I is a view showing the first to third embodiments proposed by the present invention.
1J is a diagram illustrating a base station apparatus according to the present invention.
1K is a diagram illustrating a terminal device according to the present invention.
2A is a diagram illustrating a radio resource configuration of an LTE system.
2B is a diagram illustrating a radio resource configuration of data such as eMBB, URLLC, and mMTC in the NR system.
2C is a diagram illustrating URLLC data and CSI-RS transmission in an NR system.
FIG. 2D is a diagram illustrating that other services such as URLLC and FCR in the NR system cause interference in eMBB transmission.
FIG. 2E is a diagram illustrating that a TRP (Transmission Reception Point) in a NR system transmits different beams for respective subbands at the time of CSI-RS transmission, or TRPs located at geographically different locations at different frequencies at the same time.
2F is a diagram illustrating downlink resource allocation type 0 of the LTE system.
2G is a diagram illustrating downlink resource allocation type 1 of the LTE system.
2H is a diagram illustrating downlink resource allocation type 2 of the LTE system.
2I is a flowchart showing an operation of a terminal in the present invention.
2J is a flowchart showing the operation of the base station in the present invention.
2K is a block diagram illustrating an internal structure of a terminal according to an embodiment of the present invention
FIG. 21 is a block diagram illustrating an internal structure of a base station according to an embodiment of the present invention.
3A is a diagram illustrating a downlink time-frequency domain transmission structure of an LTE or LTE-A system.
3B is a diagram illustrating an uplink time-frequency domain transmission structure of an LTE or LTE-A system.
3C is a diagram showing data allocated for eMBB, URLLC, and mMTC in frequency-time resources in the communication system.
FIG. 3D is a diagram showing data allocated for eMBB, URLLC, and mMTC in frequency-time resources in a communication system.
3E is a diagram illustrating a structure in which one transport block according to the embodiment is divided into several code blocks and CRC is added.
FIG. 3F is a diagram illustrating a structure in which an outer code according to the embodiment is applied and coded.
FIG. 3G is a block diagram of the outer code according to the embodiment of the present invention.
3H is a diagram illustrating a terminal operation according to the embodiment 3-1.
3I is a diagram illustrating a terminal operation according to the embodiment 3-2.
3J is a diagram illustrating a terminal operation according to the third to third embodiments.
3K is a diagram illustrating a terminal operation according to the 3-5 embodiment.
FIG. 31 is a block diagram illustrating the structure of a terminal according to embodiments.
3M is a block diagram showing the structure of a base station according to the embodiments.
4A is a diagram illustrating an example in which 5G services are multiplexed and transmitted in one system.
4B is a diagram illustrating PDCCH and EPDCCH, which are downlink control channels of LTE.
4C is a diagram illustrating an example of a downlink control channel basic unit considered by the present invention.
4D is a diagram illustrating an example of downlink control channel setting in the 4-1 embodiment of the present invention.
4E is a diagram illustrating an example of downlink control channel resource allocation in the 4-1 embodiment of the present invention.
4F is a diagram illustrating an example of downlink transmission according to the embodiment 4-1 of the present invention.
4G is a diagram illustrating a procedure of a base station and a terminal according to embodiment 4-1-1 of the present invention.
4H is a diagram illustrating a base station and a terminal procedure according to embodiment 4-1-2 of the present invention.
4I and 4A are diagrams illustrating a base station and a terminal procedure according to Embodiment 4-1-3 of the present invention.
4J is a diagram illustrating an example of downlink transmission according to the embodiment 4-1 of the present invention.
4K is a diagram illustrating a base station and a terminal procedure according to embodiment 4-1-4 of the present invention.
4L is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-1-5 of the present invention.
4M is a view showing the fourth embodiment of the present invention.
4n is a diagram illustrating an example of resource allocation for the control channel of the fourth embodiment of the present invention.
4O is a diagram showing an example of DCI division according to the embodiment 4-2-1.
FIG. 4P is a diagram illustrating a base station and a terminal procedure according to the embodiment 4-2-1. FIG.
FIG. 4Q is a diagram showing an example of the DCI division according to the embodiment 4-2-2. FIG.
4R is a diagram illustrating a base station and a terminal procedure according to the embodiment 4-2-2.
FIG. 4S is a diagram showing an example of DCI division according to the embodiment 4-2-3. FIG.
4T is a diagram showing an example of the frame structure according to the embodiment 4-2-3.
4U is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-2-3.
4V is a block diagram showing the internal structure of the UE according to the embodiment.
4W is a block diagram illustrating the internal structure of a base station according to an embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

≪ Embodiment 1 >

Generally, a mobile communication system has been developed to provide voice service while ensuring the user's activity. However, the mobile communication system is gradually expanding not only to voice but also to data service, and now it has developed to the extent of providing high-speed data service. However, in a mobile communication system in which a service is currently provided, a lack of resources and users demand higher speed services, and therefore, a more advanced mobile communication system is required.

As a system under development in the next generation mobile communication system in response to this demand, standard works for LTE (Long Term Evolution) are underway in the 3rd Generation Partnership Project (3GPP). LTE is a technology that implements high-speed packet-based communications with transmission rates of up to 100 Mbps. Various methods are discussed for this purpose. For example, there is a method of reducing the number of nodes located on a communication path by simplifying the structure of a network, and a method of approaching wireless protocols to a wireless channel as much as possible.

The LTE system adopts a Hybrid Automatic Repeat reQuest (HARQ) scheme in which a physical layer resends data when a decoding failure occurs in an initial transmission. In the HARQ scheme, when a receiver fails to correctly decode data, a receiver transmits information (NACK: Negative Acknowledgment) indicating decoding failure to the transmitter so that the transmitter can retransmit the corresponding data in the physical layer. The receiver combines the data retransmitted by the transmitter with data that has not been decoded previously, thereby improving data reception performance. In addition, when the receiver correctly decodes the data, an acknowledgment (ACK) indicating the decoding success is transmitted to the transmitter so that the transmitter can transmit new data.

FIG. 1A is a diagram illustrating a basic structure of a time-frequency domain, which is a radio resource region in which data or a control channel is transmitted in a downlink in an LTE system.

In Fig. 1A, the abscissa represents the time domain and the ordinate axis represents the frequency domain. The minimum transmission unit in the time domain is an OFDM symbol. Nsymb (1a-02) OFDM symbols are gathered to form one slot 1a-06, and two slots are gathered to form one subframe 1a-05 . The length of the slot is 0.5 ms and the length of the subframe is 1.0 ms. The radio frames 1a to 14 are time-domain units composed of 10 subframes. The minimum transmission unit in the frequency domain is a subcarrier, and the bandwidth of the total system transmission bandwidth is composed of a total of NBW (1a-04) subcarriers.

In a time-frequency domain, a basic unit of a resource can be represented by an OFDM symbol index and a subcarrier index as a resource element 1a-12. A resource block (RB or Physical Resource Block) (PRB) is defined as Nsymb (1a-02) consecutive OFDM symbols in the time domain and NRB (1a-10) consecutive subcarriers in the frequency domain do. Therefore, one RB 1a-08 is composed of Nsymb x NRB REs 1a-12. In general, the minimum transmission unit of data is the RB unit. In the LTE system, Nsymb = 7 and NRB = 12 in general, and NBW and NRB are proportional to the bandwidth of the system transmission band. The data rate increases in proportion to the number of RBs scheduled to the UE. The LTE system defines and operates six transmission bandwidths. In the case of an FDD system in which the downlink and the uplink are classified by frequency, the downlink transmission bandwidth and the uplink transmission bandwidth may be different from each other. The channel bandwidth represents the RF bandwidth corresponding to the system transmission bandwidth. Table 1a-01 shows the correspondence relationship between the system transmission bandwidth and the channel bandwidth defined in the LTE system. For example, an LTE system with a 10 MHz channel bandwidth has a transmission bandwidth of 50 RBs.

[Table 1a-01]

In the case of downlink control information, it is transmitted within the first N OFDM symbols in the subframe. In general, N = {1, 2, 3}. Therefore, the N value varies with each subframe according to the amount of control information to be transmitted in the current subframe. The control information includes a control channel transmission interval indicator indicating how many OFDM symbols control information is transmitted, scheduling information for downlink data or uplink data, and an HARQ ACK / NACK signal.

In the LTE system, scheduling information for downlink data or uplink data is transmitted from a base station to a mobile station through downlink control information (DCI). An uplink (UL) refers to a radio link through which a terminal transmits data or control signals to a base station, and a downlink (DL) refers to a radio link through which a base station transmits data or control signals to a terminal. The DCI defines various formats to determine whether it is scheduling information (uplink grant) for uplink data or scheduling information (DL (downlink) grant) for downlink data, a compact DCI Whether to apply spatial multiplexing using multiple antennas, whether DCI is used for power control, and the like. For example, DCI format 1, which is scheduling control information (DL grant) for downlink data, is configured to include at least the following control information.

- Resource allocation type 0/1 flag: Notifies whether the resource allocation method is Type 0 or Type 1. Type 0 allocates resources by resource block group (RBG) by applying bitmap method. In the LTE system, the basic unit of scheduling is an RB (resource block) represented by a time and frequency domain resource, and the RBG is composed of a plurality of RBs and serves as a basic unit of scheduling in the type 0 scheme. Type 1 allows a specific RB to be allocated within the RBG.

- Resource block assignment: Notifies the RB allocated to data transmission. The resources to be represented are determined according to the system bandwidth and the resource allocation method.

- Modulation and coding scheme (MCS): Notifies the modulation scheme used for data transmission and the size of the transport block, which is the data to be transmitted.

- HARQ process number: Notifies the HARQ process number.

- New data indicator: Notifies HARQ initial transmission or retransmission.

- Redundancy version: Notifies redundancy version of HARQ.

- Transmit power control command for PUCCH (Physical Uplink Control CHannel): Notifies a transmission power control command for PUCCH, which is an uplink control channel.

The DCI is transmitted through a Physical Downlink Control Channel (PDCCH) or an Enhanced PDCCH (EPDCCH) through a channel coding and modulation process.

Generally, the DCI is independently channel-coded for each UE, and then is composed of independent PDCCHs and transmitted. In the time domain, the PDCCH is mapped and transmitted during the control channel transmission period. The frequency domain mapping position of the PDCCH is determined by the identifier (ID) of each terminal and spread over the entire system transmission band.

The downlink data is transmitted through a Physical Downlink Shared Channel (PDSCH), which is a physical channel for downlink data transmission. The PDSCH is transmitted after the control channel transmission interval. The scheduling information such as the specific mapping position in the frequency domain, the modulation scheme, and the like is notified by the DCI transmitted through the PDCCH.

The base station notifies the UE of a modulation scheme applied to a PDSCH to be transmitted and a transport block size (TBS) to be transmitted through an MCS having 5 bits among the control information constituting the DCI. The TBS corresponds to a size before channel coding for error correction is applied to data (transport block, TB) to be transmitted by the base station.

The modulation schemes supported by the LTE system are QPSK (Quadrature Phase Shift Keying), 16QAM (Quadrature Amplitude Modulation), and 64QAM, and the respective modulation order (Qm) corresponds to 2, 4, and 6. That is, 2 bits per symbol for QPSK modulation, 4 bits per symbol for 16QAM modulation, and 6 bits per symbol for 64QAM modulation.

In 3GPP LTE Rel-10, bandwidth expansion technology was adopted to support higher data transmission compared with LTE Rel-8. The above technique called Bandwidth extension or Carrier Aggregation (CA) can increase the amount of data transmission by an extended band compared to the LTE Rel-8 terminal that transmits data in one band by extending the band . Each of the above-mentioned bands is referred to as a constituent carrier (CC), and the LTE Rel-8 terminal is defined to have one constituent carrier wave for each of the downward and upward directions. Also, the downlink carrier wave and the uplink carrier wave that are connected to the SIB-2 are bundled and called a cell. The SIB-2 connection relationship between the downlink carrier and the uplink carrier is transmitted as a system signal or an upper signal. A terminal supporting a CA can receive downlink data through a plurality of serving cells and transmit uplink data.

In the Rel-10, when it is difficult for a base station to transmit a Physical Downlink Control Channel (PDCCH) in a specific serving cell to a specific UE, a PDCCH is transmitted in another serving cell and the corresponding PDCCH is allocated to a Physical Downlink Shared Channel (PDSCH) A Carrier Indicator Field (CIF) can be set as a field for indicating that a Physical Uplink Shared Channel (PUSCH) is indicated. The CIF may be set to a terminal supporting CA. The CIF is determined to be able to indicate another serving cell by adding 3 bits to the PDCCH information in a specific serving cell. CIF is included only when performing cross carrier scheduling, and when the CIF is not included, cross carrier scheduling . When the CIF is included in the DL assignment, the CIF indicates a serving cell to which a PDSCH scheduled to be scheduled by the DL assignment is to be transmitted, and the CIF is included in uplink resource allocation information (UL grant) , The CIF is defined to point to the serving cell to which the PUSCH scheduled to be transmitted by the UL grant is to be transmitted.

As described above, Carrier Aggregation (CA), which is a bandwidth extension technique, is defined in the LTE-10, and a plurality of serving cells can be set to the UE. The UE periodically or non-periodically transmits channel information on the plurality of serving cells to the base station for data scheduling of the base station. The base station schedules data for each carrier and transmits the data, and the terminal transmits A / N feedback on the data transmitted for each carrier. The LTE Rel-10 is designed to transmit up to 21 bits of A / N feedback. When the A / N feedback and channel information transmission overlap in one subframe, the A / N feedback is transmitted and the channel information is discarded . LTE Rel-11 is designed to transmit A / N feedback of up to 22 bits and channel information of one cell to PUCCH format 3 in transmission resources of PUCCH format 3 by multiplexing channel information of one cell together with A / N feedback Respectively.

In LTE-13, a maximum of 32 serving cell configuration scenarios are assumed. The concept of extending the number of serving cells up to 32 using unlicensed band, which is a license-exempt band as well as license band, is completed. Also, considering the limited number of license bands, such as LTE frequencies, we have completed providing LTE services in unlicensed bands such as the 5GHz band, which we call Licensed Assisted Access (LAA). In LAA, we applied carrier-aggregation technology in LTE to support operation of P cell for licensed LTE cell and S cell for LAA cell that is license-exempted. Therefore, the feedback generated in the LAA cell, which is an S cell as in LTE, should be transmitted only in the P cell, and the downlink subframe and the uplink subframe can be freely applied to the LAA cell. Unless otherwise stated herein, LTE refers to all of the evolutionary technologies of LTE, such as LTE-A and LAA.

Meanwhile, New Radio Access Technology (NR), a fifth generation wireless cellular communication system (hereinafter referred to as 5G in the present specification), which is a communication system after LTE, freely reflects various requirements of users and service providers Services that satisfy various requirements can be supported.

Therefore, 5G is an example of an enhanced mobile broadband (eMBB) (hereinafter referred to as eMBB), massive machine type communication (hereinafter referred to as mMTC) A variety of 5G services such as Ultra Low Reliability and Low Latency Communications (hereinafter referred to as " URLLC ") will be referred to as a terminal maximum transmission rate of 20Gbps, a terminal maximum rate of 500km / , Terminal connection density of 1,000,000 terminals / km2, etc., can be defined as a technique for satisfying the requirements selected for each 5G service.

For example, in order to provide eMBB at 5G, it is required to provide a maximum terminal transmission rate of 20Gbps in the downlink and a maximum terminal transmission rate of 10Gbps in the uplink from the viewpoint of one base station. At the same time, it is necessary to increase the average transmission speed that the terminal actually senses. In order to meet such requirements, improvement of transmission / reception technology including a further improved multiple-input multiple output transmission technique is required.

At the same time, mMTC is being considered to support application services such as the Internet of Thing (IoT) in 5G. In order to efficiently provide Internet of things, mMTC needs to support the connection of large terminals in a cell, enhancement of terminal coverage, improved battery time, and cost reduction of terminals. Object The Internet must be able to support a large number of terminals (for example, 1,000,000 terminals / km2) in a cell because it is attached to various sensors and various devices and provides communication functions. In addition, mMTC is required to have a wider coverage than eMBB because it is likely to be located in a shadow area such as an area where a terminal can not cover a cell or a building. The mMTC is likely to be configured as a low-cost terminal and requires a very long battery life time because it is difficult to frequently replace the battery of the terminal.

Finally, in the case of URLLC, cellular-based wireless communication used for a specific purpose is a service used for remote control, industrial automation, unmanned aerial vehicle, remote health control, emergency notification of robots or machinery , Ultra-low latency, and ultra-high reliability. For example, URLLC has a requirement to satisfy a maximum delay time of less than 0.5 ms and at the same time to provide a packet error rate of 10 -5 or less. Therefore, a transmission time interval (TTI) that is smaller than a 5G service such as an eMBB is required for URLLC, and a design requirement for allocating a wide resource in the frequency band is required.

The services considered in the above-mentioned fifth generation wireless cellular communication system should be provided as one framework. That is, for efficient resource management and control, it is preferable that each service is integrated into one system and controlled and transmitted rather than operated independently.

1B is a diagram showing an example in which services to be considered in 5G are multiplexed and transmitted in one system.

In FIG. 1B, a frequency-time resource 1b-01 used by 5G may be composed of a frequency axis 1b-02 and a time axis 1b-03. In FIG. 1B, 5G illustrates that eMBB (1b-05), mMTC (1b-06), and URLLC (1b-07) are operated by a 5G base station in one framework. Also, as an additional service that can be considered in 5G, an enhanced Mobile Broadcast / Multicast Service (eMBMS, 1b-08) for providing a broadcasting service on a cellular basis may be considered. Services considered in 5G such as eMBB (1b-05), mMTC (1b-06), URLLC (1b-07) and eMBMS (1b-08) (TDM) or Frequency Division Multiplexing (FDM), and spatial division multiplexing may also be considered. In the case of the eMBB 1b-05, it is preferable to occupy and transmit the maximum frequency bandwidth at a specific arbitrary time in order to provide the above-mentioned increased data transmission rate. Therefore, in case of eMBB (1b-05) service, it is preferable to transmit TDM within other service and system transmission bandwidth (1b-01). However, according to the needs of other services, .

In the case of mMTC (1b-06), unlike other services, an increased transmission interval is required in order to secure a wide coverage, and coverage can be ensured by repetitively transmitting the same packet within a transmission interval. At the same time, in order to reduce the complexity of the terminal and the terminal price, the transmission bandwidth that the terminal can receive is limited. Considering these requirements, it is desirable that mMTC (1b-06) be transmitted in FDM with other services within 5G transmission system bandwidth (1b-01).

It is preferable that the URLLC (1b-07) has a short Transmit Time Interval (TTI) when compared with other services in order to satisfy the second delay requirement required by the service. At the same time, since it is necessary to have a low coding rate in order to satisfy the second reliability requirement, it is preferable to have a wide bandwidth on the frequency side. Considering the requirements of such URLLC (1b-07), it is desirable that URLLC (1b-07) is TDM with other services within the transmission system bandwidth (1b-01) of 5G.

In this paper, we describe the necessity of various services in order to satisfy various requirements in 5G, and describe the requirements for services that are considered as typical ones.

On the other hand, in the future, if 5G phase 2 or beyond 5G services and technologies are multiplexed on the 5G operating frequency, 5G phase 2 or beyond 5G technologies and services will be provided so that there is no backward compatibility problem in operation of the previous 5G technologies There are requirements to be made. These requirements are referred to as forward compatibility in the future, and technologies for satisfying compatibility in the future should be considered when designing the initial 5G. The lack of consideration of future compatibility in the initial LTE standardization phase can create constraints in providing new services within the LTE framework. For example, in the case of eMTC (Enhanced Machine Type Communication) applied in LTE release-13, in order to reduce the terminal cost by reducing the complexity of the terminal, the system transmission bandwidth provided by the serving cell Regardless, it is possible to communicate only at frequencies corresponding to 1.4MHz. Therefore, the UE supporting the eMTC can not receive the physical downlink control channel (PDCCH) transmitted in the entire bandwidth of the system transmission bandwidth. Therefore, in the time interval during which the PDCCH is transmitted, Constraints that can not be received occurred. Therefore, a 5G communication system must be designed so that the services under consideration after the 5G communication system operate with efficient coexistence with the 5G communication system. For future compatibility in the 5G communication system, it is necessary to freely allocate and transmit resource resources so that services to be considered in future can be freely transmitted in the time-frequency resource region supported by the 5G communication system.

Each of the services described above may have different transmission / reception techniques and transmission / reception parameters to satisfy the requirements of the respective services. For example, each service can have a different numerology depending on each service requirement. Numerology refers to a method of calculating a Cyclic Prefix (CP) length, a subcarrier interval, and a subcarrier spacing in a communication system based on Orthogonal Frequency Division Multiplexing (OFDM) or Orthogonal Frequency Division Multiple Access (OFDMA) spacing, OFDM symbol length, transmission time interval length (TTI), and the like. As an example having a different numerology between the above services, the eMBMS 1b-08 may have a longer CP length than other services. Since the eMBMS 1b-08 transmits the broadcast-based upper traffic, the same data can be transmitted from all the cells. At this time, if a signal received from a plurality of cells arrives within a CP length, the UE can receive and decode all of these signals, thereby obtaining a single frequency network (SFN) gain, Therefore, a terminal located at a cell boundary is also advantageous in that broadcasting information can be received without restriction of coverage. However, if the CP length is relatively long for supporting eMBMS in 5G, the CP overhead will cause waste, and at the same time, a longer OFDM symbol length is required compared to other services. A narrow subcarrier interval is required.

Also, as an example in which different Numerologies are used between services in 5G, in the case of URLLC, a shorter OFDM symbol length may be required as a smaller TTI is required compared to other services, and at the same time a wider subcarrier interval may be required.

On the other hand, frequencies considered to operate the 5G range from several GHz to tens of GHz, frequency division duplex (FDD) rather than TDD (Time Division Duplex) is preferred in a few GHz band with a low frequency, TDD is considered to be more suitable than FDD. When multiplexing various 5G services within a TDD carrier, services with different transmission time intervals (Transmission Time Intervals) may require different frame structures (i.e., uplink or downlink frames) The base station multiplexes the services of the different transmission time intervals, and the terminal needs a method for decoding the services transmitted to the terminal in each transmission time interval.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

The embodiments of the present invention will be described in detail with reference to LTE and 5G systems. However, the present invention is also applicable to other communication systems having a similar technical background and channel form. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

The following will describe a 5G communication system in which 5G cells operate in a stand-alone 5G communication system or in a non-stand alone mode combined with dual connectivity or carrier aggregation with other stand-alone 5G cells.

1C and 1D are views showing a 1-1 and 1-2 embodiment of a communication system to which the present invention is applied. The measures proposed by the present invention are applicable to both the system of FIG. 1C and the system of FIG. 1D.

Referring to FIG. 1C, the upper diagram of FIG. 1C illustrates a case where a 5G cell 1c-02 operates in stand-alone mode within one base station 1c-01 in the network. The terminal 1c-04 is a 5G capable terminal having a 5G transmission / reception module. The terminal 1c-04 acquires synchronization through a synchronization signal transmitted from the 5G stand-alone cell 1c-01, and attempts to perform random access to the 5G base station 1c-01 after receiving the system information. The terminal 1c-04 transmits and receives data through the 5G cell 1c-02 after the RRC connection with the 5G base station 1c-01 is completed. In this case, there is no restriction on the duplex method of the 5G cell (1c-02). In the system of FIG. 1C, the 5G cell may have a plurality of serving cells.

1C, the 5G stand-alone base station 1c-11 and the 5G non-stand alone base station 1c-12 for increasing data transmission amount are installed. The terminal 1c-14 is a 5G capable terminal having a 5G transmission / reception module for performing 5G communication in a plurality of base stations. The 5G capable terminal may be a terminal supporting only one 5G service or a terminal supporting a plurality of 5G services. A terminal supporting only one 5G service can support one numerology, and a terminal supporting a plurality of 5G services can support a plurality of numerology. The terminal 1c-14 acquires synchronization through the synchronization signal transmitted from the 5G stand-alone base station 1c-11, and receives random access to the 5G stand-alone base station 1c-11 after receiving the system information Try it. The terminal 1c-14 additionally sets up a 5G non-stand alone cell 1c-15 after the RRC connection with the 5G stand-alone base station 1c-11 is completed and the 5G stand-alone base station 1c- 11) or 5G non-stand alone base station 1c-12. In this case, there is no restriction on the duplex method of the 5G stand-alone base station 1c-11 or the 5G non-stand alone base station 1c-12. It is assumed that the base station 1c-12 is connected to an ideal backhaul network or a non-ideal backhaul network. Therefore, fast base station X2 communication (1c-13) is possible with the ideal backhaul network 1c-13. In the system shown in the bottom view of FIG. 1C, the 5G cell may have a plurality of serving cells.

1D, an upper diagram of FIG. 1D shows a case where LTE cells 1d-02 and 5G cells 1d-03 coexist in one base station 1d-01 in the network . The terminal 1d-04 may be an LTE capable terminal having an LTE transmission / reception module, a 5G capable terminal having a 5G transmission / reception module, or a terminal having an LTE transmission / reception module / 5G transmission / reception module at the same time. The 5G capable terminal having the 5G transmission / reception module may be a terminal supporting only one 5G service or a terminal supporting a plurality of 5G services. A terminal supporting only one 5G service can support one numerology, and a terminal supporting a plurality of 5G services can support a plurality of numerology. The terminal 1d-04 acquires synchronization through the synchronization signal transmitted from the LTE cell 1d-02 or the 5G cell 1d-03 and receives the system information, (1d-02) or the 5G cell (1d-03). In this case, there is no restriction on the duplex scheme of the LTE cell (1d-02) or the 5G cell (1d-03). The uplink control transmission is performed through the LTE cell 1d-02 when the LTE cell is a P cell and through the 5G cell 1d-03 when the 5G cell is a P cell. In the system shown in the upper diagram of FIG. 1D, the LTE cell and the 5G cell can have a plurality of serving cells, and can support a total of 32 serving cells. It is assumed that the base station 1d-01 has both an LTE transmission / reception module (system) and a 5G transmission / reception module (system) in the network. The base station 1d-01 controls the LTE system and the 5G system in real time It is possible to operate. For example, if the LTE system and the 5G system are operated at different times by dividing resources in time, it is possible to dynamically select the allocation of time resources of the LTE system and the 5G system. The terminal 1d-04 transmits a resource (a time resource or a frequency resource or an antenna resource or a space resource) divided and operated by the LTE cell and the 5G cell from the LTE cell 1d-02 or the 5G cell 1d- By receiving a signal indicating the allocation, it is possible to know through which resource the data reception from the LTE cell 1d-02 and the 5G cell 1d-03 is performed, respectively.

1D, the LTE macro base station 1d-11 for wide coverage in the network and the 5G small base station 1d-12 for increasing the data transmission amount are installed. The terminal 1d-14 may be an LTE capable terminal having an LTE transmission / reception module, a 5G capable terminal having a 5G transmission / reception module, or a terminal having an LTE transmission / reception module / 5G transmission / reception module at the same time. The 5G capable terminal having the 5G transmission / reception module may be a terminal supporting only one 5G service or a terminal supporting a plurality of 5G services. A terminal supporting only one 5G service can support one numerology, and a terminal supporting a plurality of 5G services can support a plurality of numerology. The terminal 1d-14 acquires synchronization through a synchronization signal transmitted from the LTE base station 1d-11 or the 5G base station 1d-12 and transmits the synchronization information to the LTE base station 1d- And transmits and receives data through the base station 1d-12. In this case, there is no restriction on the duplex scheme of the LTE macro base station 1d-11 or the 5G small base station 1d-12. The uplink control transmission is performed through the LTE cell 1d-11 when the LTE cell is a P-cell and the 5G cell 1d-12 when the 5G cell is a P-cell. At this time, it is assumed that the LTE base station 1d-11 and the 5G base station 1d-12 have an ideal backhaul network or a non-ideal backhaul network. Therefore, even when the uplink transmission is transmitted only to the LTE base station 1d-11, it is possible to perform the fast inter-base-station X2 communication 1d-13 with the ideal backhaul network 1d-13, It is possible for the 5G base station 1d-12 to receive the relevant control information from the LTE base station 1d-11 in real time. In the system shown in the lower diagram of FIG. 1D, the LTE cell and the 5G cell may have a plurality of serving cells, and may support a total of 32 serving cells. The base station 1d-11 or 1d-12 can manage the LTE system and the 5G system in real time. For example, when the base station 1d-11 divides resources on time and operates the LTE system and the 5G system at different times, it dynamically selects allocation of time resources of the LTE system and the 5G system, and transmits the signal to another base station 1 d-12. The terminal 1d-14 transmits a resource (a time resource or a frequency resource or an antenna resource or a space resource) divided and operated by the LTE cell and the 5G cell from the LTE base station 1d-11 or the 5G base station 1d- By receiving the signal indicating the allocation, it is possible to know through which resource the data transmission / reception from the LTE cell 1d-11 and the 5G cell 1d-12 takes place.

On the other hand, when the LTE base station 1d-11 and the 5G base station 1d-12 have non-ideal backhaul networks 1d-13, fast inter-base-station X2 communication 1d-13 is impossible. Therefore, the base station 1d-11 or 1d-12 can operate the LTE system and the 5G system semi-statically. For example, when the base station 1d-11 divides resources on time and operates the LTE system and the 5G system at different times, it selects the time resource allocation of the LTE system and the 5G system, and transmits the signal to the other base station base station 1d-12), it is possible to distinguish resources between the LTE system and the 5G system. The terminal 1d-14 transmits a resource (a time resource or a frequency resource or an antenna resource or a space resource) divided and operated by the LTE cell and the 5G cell from the LTE base station 1d-11 or the 5G base station 1d- By receiving the signal indicating the allocation, it is possible to know through which resource the data transmission / reception from the LTE cell 1d-11 and the 5G cell 1d-12 takes place.

Next, FIG. 1E is a diagram illustrating subframe structures proposed in the present invention. The subframe structures in the transmission time interval that various services can have in the 5G communication system through the upper and lower diagrams of FIG. 1E will be described.

X1 (1e-11) and X2 (1e-21) in the upper and lower diagrams of FIG. 1E show various transmission time intervals that a terminal of a specific service or a specific service can use, Frame structures 1e-12 to 1e-17 and 1e-22 to 1e-27. For example, X1 may be 1 ms and X2 may be 0.5 ms. X1 and X2 are used to describe a relative transmission time interval. In the 5G communication system, only one transmission time interval may be used or at least one (X1, X2, X3 , ...) may be multiplexed and used. In the present invention, a unit of signals transmitted in one transmission time interval is referred to as a subframe, and a subframe includes at least one downlink symbol 1e-01 or a protection symbol 1e-01 or uplink symbols 1e-03 . When OFDM of the symbol is used, the OFDM symbol may be defined as an OFDM symbol, and the length of the OFDM symbol may vary depending on the number of subcarriers, the CP length, and the size of the band wig.

The subframes 1e-12 to 1e-17 are indicated to the terminal by the base station and the terminal transmits information related to the subframes 1e-12 to 1e-17, that is, Frame is used. The position and the number of the sub-frames 1e-12 to 1e-17 are set by the upper signal in advance so that the terminal may obtain the related information, May be acquired by the terminal.

First, the downlink symbol (1e-01) or the protection symbol (1e-02) or the uplink symbol (1e-03) constituting each subframe will be described.

Each subframe consists of at least one downlink symbol (1e-01) or guard symbol (1e-02) or uplink symbol (1e-03) It is used for transmission. The protection symbol (1e-02) guarantees the RF switching time of the terminal or the base station when the symbols on both sides of the protection symbol are in different directions (i.e., upward and downward) in one subframe or two consecutive subframes , A delay time due to the distance between the terminal and the base station, and the like in the protection symbol 1e-02. And is used to guarantee the processing time of a terminal having a capability to receive downlink data and uplink control information on the downlink data in the subframe. The number of protection symbols (1e-02) in the subframe is preset by the base station in consideration of the RF switching times and the cell radius of the UE in the cell, and the UE transmits the protection symbols It is possible to obtain information on the number from the base station. The uplink symbol 1e-03 is used for uplink control information and uplink data transmission. The number of uplink symbols 1e-03 in one subframe is set in advance by the base station in consideration of uplink control information due to cell radius and coverage of uplink data transmission, etc., and the terminal transmits uplink symbols Can be obtained from the base station.

Next, each subframe structure corresponding to the transmission time interval X1 (1e-11) is as follows.

The subframe 1e-12 is composed only of the downlink symbol 1e-01.

The subframe 1e-13 is composed of a downlink symbol 1e-01 and a protection symbol 1e-02.

The subframe 1e-14 includes a downlink symbol 1e-01, a protection symbol 1e-02, and an uplink symbol 1e-03. The subframe 1e-14 has a subframe structure capable of transmitting downlink control information, downlink data reception, and uplink control information on the downlink data in the same subframe.

The subframe 1e-15 includes a downlink symbol 1e-01, a protection symbol 1e-02, and an uplink symbol 1e-03. The subframe 1e-15 has a subframe structure capable of receiving downlink control information and transmitting uplink data indicated by the downlink control information in the same subframe.

The subframe 1e-16 is composed of a protection symbol 1e-02 and an uplink symbol 1e-03.

The subframe 1e-17 is composed only of the upward symbol 1e-03.

Next, each subframe structure corresponding to the transmission time interval X2 (1e-21) is as follows.

The subframe 1e-22 is composed only of the downlink symbol 1e-01.

The subframe 1e-23 comprises a downlink symbol 1e-01 and a protection symbol 1e-02.

The subframe 1e-24 includes a downlink symbol 1e-01, a protection symbol 1e-02, and an uplink symbol 1e-03. The subframe 1e-24 has a subframe structure capable of transmitting downlink control information, downlink data reception, and uplink control information on the downlink data in the same subframe.

The subframe 1e-25 includes a downlink symbol 1e-01, a protection symbol 1e-02, and an uplink symbol 1e-03. The subframe 1e-25 has a subframe structure capable of receiving downlink control information and transmitting uplink data indicated by the downlink control information in the same subframe.

The subframe 1e-26 is composed of a protection symbol 1e-02 and an uplink symbol 1e-03.

The subframe 1e-27 is composed only of the upward symbol 1e-03.

Next, with reference to FIG. 1F, an issue that occurs when multiplexing various transmission time intervals within one carrier will be described.

1F is a diagram showing a situation to be solved by the present invention.

(1f-2) having a transmission time interval different from that of the subframe (1f-21) and the transmission time interval X1 (1f-11) by the transmission time interval X1 1f-22) are multiplexed and multiplexed in one carrier, especially in a TDD carrier.

The subframe according to the transmission time interval X1 (1f-11) consists of a downlink symbol, a protection symbol and an uplink symbol, and a subframe according to X2 (1f-11) also includes a downlink symbol, a protection symbol and an uplink symbol have. In the example of Fig. 1F, since X1 has a length twice as long as X2, it can be seen that the subframe length by X1 corresponds to two subframe lengths by X2.

At this time, the downward symbol of the subframe 1f-21 by X1 collides with the time (1f-23) like the uplink symbol in the subframes 1f-22 constituted by X2. That is, reception of downlink data of a terminal to be served by X1 and transmission of uplink data of a terminal to be served by X2 must be performed at the same time. In this case, the downlink data reception by the UE receiving the service by X1 may be interfered by the uplink data transmission by the UE receiving the service by X2, and the base station may transmit the uplink data by X2 and the downlink data by X1 It should be done at the same time. There is a need for a scheme to avoid such problems as the above-mentioned interference problem and hardware complexity for performing bidirectional simultaneous data transmission / reception of a base station. A method for solving the above problem and a method for multiplexing various transmission time intervals are proposed in the present invention.

FIG. 1G is a view showing the 1-1th embodiment proposed by the present invention.

First, a description will be given of a method of informing a subframe structure through a common transmission time interval and a dedicated transmission time interval through the upper and lower diagrams of FIG. 1G, and performing control information and data transmission according to the subframe structure in a dedicated transmission time interval do.

The common transmission time interval 1g-11 and the dedicated transmission time interval 1g-12 are set at the top of FIG. 1g. The common transmission time interval 1g-11 is for determining a subframe structure to be used by all the UEs in the BS and the cell within the common transmission time interval 1g-11. The subframe structure may be preset for a predetermined period of time, and the subframe structure may be transmitted through an upper signal including a system signal and an RRC signal. The subframe structure may be varied in every common transmission time interval and be directed to the terminal, in which case the subframe structure may be transmitted via a physical signal. When a physical signal is transmitted, a decoding operation of a terminal for searching for a subframe structure according to the common transmission time interval 1g-11 may be performed. For example, the subframe structure for the current subframe structure or the next common transmission time interval may be determined through the control information transmission in the first symbol in which the common transmission time interval 1g-11 starts, The sub-frame structure can be obtained through the decoding of the control information in the first symbol in which the first symbol (1g-11) starts. The subframe structure includes the subframe structure shown in FIG. 1E. The dedicated transmission time interval 1g-12 is a transmission time interval for transmitting control information and data information to the UE, and it is possible to set a dedicated transmission time interval 1g-12 having a different length for each service . For example, the dedicated transmission time interval 1g-12 in 1g-21 has a length corresponding to half of the common transmission time interval 1g-11, and the control information including the subframe structure information and the control information The scheduling data information is transmitted. Or 1g-22 has a length corresponding to the common transmission time interval (1g-11), and the dedicated transmission time interval (1g-13) has a length corresponding to the common transmission time interval Data information is transmitted.

1G, the common transmission time interval and the dedicated transmission time interval are defined differently from the upper part of FIG. 1G, and an example in which the base station and the terminal are operated will be described. In FIG. 1G, the common transmission time interval 1g-31 and the dedicated transmission time interval 1g-32 are set, respectively. 1G, the common transmission time interval 1g-31 may mean a period in which the UE should attempt decoding to find the position where the subframe structure used in the dedicated transmission time interval starts. The subframe structure may be varied in every dedicated transmission time interval and be directed to the terminal. In this case, the subframe structure may be transmitted through a physical signal. When a physical signal is transmitted, a decoding operation of the terminal for searching for a position where the subframe structure starts according to the common transmission time interval 1g-11 can be performed. For example, the start position of the subframe structure for the current subframe structure or the next common transmission time interval may be determined through the control information transmission in the first symbol in which the common transmission time interval 1g-32 starts, It is possible to acquire a position at which the subframe structure of the dedicated transmission time interval starts through the decoding of the control information in the first symbol in which the transmission time interval 1g-32 starts. The subframe structure includes the subframe structure shown in FIG. 1E. The dedicated transmission time interval 1g-31 is a transmission time interval for transmitting control information and data information to the UE, and it is possible to set a dedicated transmission time interval 1g-31 having a different length for each service . For example, the dedicated transmission time interval 1g-31 in the 1g-41 has a length corresponding to twice the common transmission time interval 1g-32, and the control information including the subframe structure information and the control information Data information scheduled by the information is transmitted.

The procedures of the base station and the terminal for the method described in the upper part of FIG. 1G will be described with reference to the flowchart at the bottom of FIG.

First, a base station procedure according to the first embodiment of the present invention will be described.

In step g-50, the base station transmits transmission time interval setting information to the mobile station. The transmission time interval setting information includes common transmission time interval and dedicated transmission time interval related information as described above at the upper part of FIG. 1G, and the setting information includes an upper signal or a physical signal including a system signal, an RRC signal, Lt; / RTI > In addition, the subframe structure may be predetermined for a predetermined time and transmitted to the UE through a higher signal or a physical signal including a system signal, an RRC signal, and the like.

In step 1g-51, the BS transmits control information including data scheduling information for the 5G service to the MS. The control information may include a subframe structure according to a common transmission time interval. The control information may be a subframe structure for a current common transmission time interval or a next common transmission time interval. The control information may be transmitted in the first symbol of the subframe. Also, the data scheduling information includes all services considered for 5G as described in the present invention, and the data scheduling information includes frequency resources or time resources for data transmission of the 5G service. The data scheduling information may be transmitted by an upper signal or a physical signal.

In step 1g-52, the base station transmits and receives data according to the control information for the 5G service to the terminal. The control information may include a subframe structure as described in step 1g-51, wherein the base station transmits and receives data according to the subframe structure.

Next, the terminal procedure according to the embodiment 1-1 of the present invention will be described.

In step lg-60, the terminal receives the transmission time interval setting information from the base station. The transmission time interval setting information includes common transmission time interval and dedicated transmission time interval related information as described above at the upper part of FIG. 1G, and the setting information includes an upper signal or a physical signal including a system signal, an RRC signal, Lt; / RTI > In addition, the subframe structure may be predetermined for a predetermined time and transmitted to the UE through a higher signal or a physical signal including a system signal, an RRC signal, and the like.

In step lg-61, the UE attempts to receive control information including data scheduling information for the 5G service from the BS. The control information may include a subframe structure according to a common transmission time interval. The control information may be a subframe structure for a current common transmission time interval or a next common transmission time interval. The control information may be transmitted in the first symbol of the subframe. Also, the data scheduling information includes all services considered for 5G as described in the present invention, and the data scheduling information includes frequency resources or time resources for data transmission of the 5G service. The data scheduling information may be transmitted by an upper signal or a physical signal.

In step 1g-62, the terminal transmits and receives data according to control information for the 5G service to the base station. The control information may include a subframe structure as described in step 1g-61, and in this case, the terminal transmits and receives data according to the subframe structure.

FIG. 1H is a view showing the first and second embodiments proposed by the present invention.

Referring to FIG. 1H, when a subframe structure is informed in a common transmission time interval, if a first symbol of a subframe has an uplink symbol to which downlink control information can not be transmitted, a next subframe structure based on the previous subframe structure Explain what you are looking for.

A common transmission time interval (1h-11 or 1h-12) is set at the top of FIG. 1h, and thus a subframe structure having a length of the common transmission time interval is determined. When a subframe structure starting from the downlink symbol is determined in the previous common transmission time interval 1h-11 and transmitted to the UE, if the subframe structure in the next common transmission time interval 1h-12 starts with the uplink symbol , The control information indicating the subframe structure starting with the uplink symbol can not be transmitted to the UE. In this case, the subframe structure transmitted in the next common transmission time interval (1h-12) can be determined based on the subframe structure transmitted in the previous common transmission time interval (1h-11).

For example, if the subframe structure transmitted in the previous common transmission time interval 1h-11 at 1h-21 is composed of only the downlink symbol, the subframe structure transmitted in the next common transmission time interval 1h-12 includes the downlink and uplink symbols With a protection symbol. Therefore, if the UE fails to acquire the downlink control information even if it attempts to decode the downlink control information including the subframe structure (1h-31), it can be seen that the UE has the uplink subframe structure including the protection symbol and the uplink symbol.

In the case where the subframe structure transmitted in the previous common transmission time interval 1h-11 in 1h-22 is composed of the downlink symbol and the protection symbol, the subframe structure transmitted in the next common transmission time interval 1h-12 is upward It should be a subframe structure starting with a symbol. Accordingly, when the UE fails to acquire the downlink control information even if the UE attempts to decode the downlink control information including the subframe structure (1h-32), it can be seen that the UE has an uplink subframe structure consisting only of uplink symbols.

If the subframe structure transmitted in the previous common transmission time interval 1h-11 in 1h-23 is composed of the downlink symbol, the protection symbol, and the uplink symbol, the subframe transmitted in the next common transmission time interval 1h- The structure must be a subframe structure starting with an upward symbol. Therefore, if the UE fails to acquire the downlink control information even though it attempts to decode the downlink control information including the subframe structure (1h-33), it can be seen that the UE has an uplink subframe structure consisting only of uplink symbols.

If the subframe structure transmitted in the previous common transmission time interval 1h-11 in 1h-24 is composed of the downlink symbol, the protection symbol, and the uplink symbol, the subframe transmitted in the next common transmission time interval 1h- The structure must be a subframe structure starting with an upward symbol. Therefore, if the UE fails to acquire the downlink control information even if it attempts to decode the downlink control information including the subframe structure (1h-34), it can be seen that the UE has an uplink subframe structure consisting only of uplink symbols.

The procedure of the terminal for the method described in the upper part of FIG. 1H will be described with reference to the flowchart at the bottom of FIG.

The terminal procedure according to the first and second embodiments of the present invention will be described.

In step 1h-60, the UE acquires the subframe structure starting from the downlink symbol from the base station in the transmission time interval n. The subframe structure starting with the downlink symbol includes the subframe structure shown in FIG. 1E. The transmission time interval setting information includes common transmission time interval and dedicated transmission time interval related information as described above at the upper part of FIG. 1G, and the setting information includes an upper signal or a physical signal including a system signal, an RRC signal, Lt; / RTI > In addition, the subframe structure may be predetermined for a predetermined time and transmitted to the UE through a higher signal or a physical signal including a system signal, an RRC signal, and the like.

In step 1h-61, the UE attempts to receive downlink control information including the subframe structure from the base station in the transmission time interval n + 1. The control information may include a subframe structure according to a common transmission time interval. The control information may be a subframe structure for a current common transmission time interval or a next common transmission time interval. The control information may be transmitted in the first symbol of the subframe. If the downlink control information is successfully received in step 1h-61, the UE acquires the subframe structure of the transmission time interval n + 1 included in the downlink control information in step 1h-62.

If the downlink control information is not successfully received in step 1h-61, the UE acquires the subframe structure of the transmission time interval n + 1 based on the subframe structure of the transmission time interval n in step 1h-63. A specific method follows the method described above with reference to the top view of FIG.

FIG. 1I is a view showing the first to third embodiments proposed by the present invention.

First, a subframe structure is informed through a common transmission time interval and a dedicated transmission time interval through the upper diagram of FIG. 1i, data transmission according to the subframe structure is performed in a dedicated transmission time interval, Transmission of uplink feedback information will be described.

The description of the common transmission time interval 1i-11 and the dedicated transmission time interval 1i-12 may be as described in the upper drawing and the interrupted drawing of FIG. 1g.

(1i-21) for data transmitted according to the subframe structure in the dedicated transmission time interval and uplink feedback information (1i-22) for the data transmitted according to the subframe structure according to the length of the common transmission time interval ) Can be multiplexed at the same time.

A specific method for multiplexing is to transmit each uplink control channel for feedback transmission of data transmitted in the different transmission time intervals. In this case, if the power of the UE is insufficient (power limited case), a method for protecting the feedback of the data to be transmitted in the common transmission time interval by first adjusting the power for the feedback to the data corresponding to the dedicated transmission time interval Can be applied.

Another method for multiplexing is to transmit one uplink control channel for feedback transmission of data transmitted in the different transmission time intervals, and to multiplex the information to a fixed length. If the terminal misses certain data, the base station does not know which data the terminal has sent feedback on. Accordingly, the above problem can be solved by fixing the payload size of the feedback for the data transmitted in the different transmission time intervals and fixing the position of the feedback.

The procedure of the base station and the terminal for the method described in the upper part of FIG. 1I will be described with reference to the flowchart at the bottom of FIG.

First, the base station procedure according to the first to third embodiments of the present invention will be described.

In step 1i-50, the base station transmits transmission time interval setting information to the mobile station. The transmission time interval setting information includes common transmission time interval and dedicated transmission time interval related information as described above at the upper part of FIG. 1G, and the setting information includes an upper signal or a physical signal including a system signal, an RRC signal, Lt; / RTI > In addition, the subframe structure may be predetermined for a predetermined time and transmitted to the UE through a higher signal or a physical signal including a system signal, an RRC signal, and the like.

In step 1i-51, the BS transmits control information and data including data scheduling information for the 5G service to the MS. The control information may include a subframe structure according to a common transmission time interval. The control information may be a subframe structure for a current common transmission time interval or a next common transmission time interval. The control information may be transmitted in the first symbol of the subframe. Also, the data scheduling information includes all services considered for 5G as described in the present invention, and the data scheduling information includes frequency resources or time resources for data transmission of the 5G service. The data scheduling information may be transmitted by an upper signal or a physical signal. The base station transmits and receives data according to the subframe structure of the control information.

In step 1i-52, the base station receives feedback on the data transmitted in step 1j-51. The feedback receiving method follows the method described above with reference to the upper drawing of Fig.

Next, the terminal procedure according to the first to third embodiments of the present invention will be described.

In step 1i-60, the terminal receives the transmission time interval setting information from the base station. The transmission time interval setting information includes common transmission time interval and dedicated transmission time interval related information as described above at the upper part of FIG. 1G, and the setting information includes an upper signal or a physical signal including a system signal, an RRC signal, Lt; / RTI > In addition, the subframe structure may be predetermined for a predetermined time and transmitted to the UE through a higher signal or a physical signal including a system signal, an RRC signal, and the like.

In step 1i-61, the UE receives control information and data including data scheduling information for the 5G service from the BS. The control information may include a subframe structure according to a common transmission time interval. The control information may be a subframe structure for a current common transmission time interval or a next common transmission time interval. The control information may be transmitted in the first symbol of the subframe. Also, the data scheduling information includes all services considered for 5G as described in the present invention, and the data scheduling information includes frequency resources or time resources for data transmission of the 5G service. The data scheduling information may be transmitted by an upper signal or a physical signal. The terminal transmits and receives data according to the subframe structure of the control information.

In step 1i-62, the terminal transmits feedback on the data received in step 1j-61. The feedback transmission method follows the method described in the upper part of Fig. 1I.

1J is a diagram illustrating a base station apparatus according to the present invention.

The controller 1j-01 transmits control information and controls data transmission / reception according to the subframe structure according to the present invention, the embodiments of the present invention according to Figs. 1g, 1h, 1i and the base station procedure, The scheduler 1j-03 schedules the 5G data in the 5G resource and transmits and receives the 5G data and the 5G terminal through the 5G data transceiver 1j-07 through the information transmission apparatus 1j-05 .

1K is a diagram illustrating a terminal device according to the present invention.

Control information and data are received from the base station through the 5G resource information receiving apparatus (1k-05) according to the subframe structure according to the present invention, the embodiments of the present invention according to Figs. 1g, 1h, And the controller 1k-01 transmits / receives 5G data scheduled with the allocated 5G resource to / from the 5G base station through the 5G data transceiver 1k-06.

≪ Embodiment 2 >

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates generally to a wireless mobile communication system, and more particularly, to a wireless mobile communication system using a multiple access scheme using multi-carriers such as OFDMA (Orthogonal Frequency Division Multiple Access) Signal).

The present mobile communication system is moving away from providing initial voice-oriented services and is developing a high-speed and high-quality wireless packet data communication system for providing data service and multimedia service. To this end, 3GPP, 3GPP2, IEEE, and other standardization organizations are working on a third generation evolved mobile communication system standard applying multi-carrier multiple access scheme. Recently, various mobile communication standards such as Long Term Evolution (LTE) of 3GPP, Ultra Mobile Broadband (UMB) of 3GPP2, and IEEE 802.16m have been proposed as a high speed and high quality wireless packet data transmission service Was developed to support.

The existing third generation mobile communication system such as LTE, UMB and 802.16m is based on multi-carrier multiple access scheme. In order to improve transmission efficiency, existing multiple-input multiple output (MIMO) (AMC), and channel sensitive (scheduling) channel scheduling methods, which are used in a wide variety of applications. Various techniques described above improve the transmission efficiency by adjusting the amount of data to be transmitted or transmitted from various antennas according to channel quality and selectively transmitting data to a user having good channel quality, Improves system capacity performance. Most of these schemes operate based on channel state information between an evolved Node B (eNB) and a base station (UE) and a user equipment (MS) It is necessary to measure the channel state between the CSI-RS and the channel status indication reference signal (CSI-RS). The above-mentioned eNB refers to a downlink transmission and uplink receiving apparatus located in a certain place, and an eNB performs transmission and reception for a plurality of cells. In one mobile communication system, a plurality of eNBs are geographically dispersed, and each eNB performs transmission and reception for a plurality of cells.

Existing third and fourth generation mobile communication systems such as LTE / LTE-A utilize MIMO technology for transmitting data using a plurality of transmission / reception antennas in order to increase data transmission rate and system capacity. The MIMO technique spatially separates and transmits a plurality of information streams by using a plurality of transmission / reception antennas. Spatial multiplexing is a method of spatially separating and transmitting a plurality of information streams. Generally, how many spatial multiplexing can be applied to several information streams depends on the number of antennas of the transmitter and the receiver. In general, the ability to apply spatial multiplexing to several information streams is called the rank of the transmission. The MIMO technology supported by the LTE / LTE-A Release 11 standards supports spatial multiplexing for up to 8 transmit antennas and 8 receive antennas, and supports up to 8 rank.

In the case of NR (New Radio Access Technology), a fifth generation mobile communication system currently being discussed, it is the design goal of the system to support various services such as eMBB, mMTC, and URLLC mentioned above. The reference signal is minimized and the reference signal transmission can be transmitted irregularly so that the time and frequency resources can be flexibly transmitted.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, some of the elements are exaggerated, omitted or schematically shown. Also, the size of each component does not entirely reflect the actual size. In the drawings, the same or corresponding components are denoted by the same reference numerals.

At this point, it will be appreciated that the combinations of blocks and flowchart illustrations in the process flow diagrams may be performed by computer program instructions. These computer program instructions may be loaded into a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus, so that those instructions, which are executed through a processor of a computer or other programmable data processing apparatus, Thereby creating means for performing functions. These computer program instructions may also be stored in a computer usable or computer readable memory capable of directing a computer or other programmable data processing apparatus to implement the functionality in a particular manner so that the computer usable or computer readable memory The instructions stored in the block diagram (s) are also capable of producing manufacturing items containing instruction means for performing the functions described in the flowchart block (s). Computer program instructions may also be stored on a computer or other programmable data processing equipment so that a series of operating steps may be performed on a computer or other programmable data processing equipment to create a computer- It is also possible for the instructions to perform the processing equipment to provide steps for executing the functions described in the flowchart block (s).

In addition, each block may represent a portion of a module, segment, or code that includes one or more executable instructions for executing the specified logical function (s). It should also be noted that in some alternative implementations, the functions mentioned in the blocks may occur out of order. For example, two blocks shown in succession may actually be executed substantially concurrently, or the blocks may sometimes be performed in reverse order according to the corresponding function.

Herein, the term " part " used in the present embodiment means a hardware component such as software or an FPGA or an ASIC, and 'part' performs certain roles. However, 'part' is not meant to be limited to software or hardware. &Quot; to " may be configured to reside on an addressable storage medium and may be configured to play one or more processors. Thus, by way of example, 'parts' may refer to components such as software components, object-oriented software components, class components and task components, and processes, functions, , Subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided in the components and components may be further combined with a smaller number of components and components or further components and components. In addition, the components and components may be implemented to play back one or more CPUs in a device or a secure multimedia card.

Hereinafter, the NR system and the LTE (Long Term Evolution) system and the LTE-A (LTE-Advanced) system are exemplified in the present specification. However, the present invention is applicable to other communication systems using licensed and unlicensed bands. .

FIG. 2A shows radio resources of 1 subframe and 1 RB, which are the minimum units that can be downlink-scheduled in the LTE / LTE-A system.

The radio resources shown in FIG. 2A consist of one subframe on the time axis and one RB on the frequency axis. The radio resources are composed of 12 subcarriers in the frequency domain and 14 OFDM symbols in the time domain, thereby providing a total of 168 natural frequencies and time positions. In LTE / LTE-A, the respective natural frequencies and time positions in FIG. 2A are referred to as RE (resource elements).

A plurality of different types of signals may be transmitted to the radio resource shown in FIG. 2A.

1. CRS (Cell Specific RS): A reference signal transmitted periodically for all UEs belonging to one cell and can be commonly used by a plurality of UEs.

2. Demodulation Reference Signal (DMRS): This is a reference signal transmitted for a specific terminal and is transmitted only when data is transmitted to the terminal. The DMRS can be composed of a total of 8 DMRS ports. In LTE / LTE-A, port 7 to port 14 correspond to the DMRS port, and ports maintain orthogonality so that they do not interfere with each other using CDM or FDM.

3. PDSCH (Physical Downlink Shared Channel): A data channel transmitted in the downlink, which is used by a base station to transmit traffic to a mobile station, and is transmitted using an RE in which a reference signal is not transmitted in the data region of FIG. 2

4. CSI-RS (Channel Status Information Reference Signal): Used to measure the channel status of a reference signal transmitted for UEs belonging to one cell. A plurality of CSI-RSs can be transmitted to one cell.

5. Other control channels (PHICH, PCFICH, PDCCH): ACK / NACK transmission for providing the control information necessary for the UE to receive PDSCH or HARQ for uplink data transmission

In the LTE-A system other than the above-mentioned signal, muting can be set so that the CSI-RS transmitted from another base station can be received without interference to the terminals of the corresponding cell. The muting can be applied at a position where the CSI-RS can be transmitted. Generally, the UE receives the traffic signal by skipping the corresponding radio resource. In LTE-A systems, muting is also referred to as zero-power CSI-RS. Because of the nature of the muting, it is applied to the location of the CSI-RS and the transmit power is not transmitted.

In FIG. 2A, the CSI-RS is transmitted using a part of the positions indicated by A, B, C, D, E, E, F, G, H, I and J according to the number of antennas transmitting CSI- . The muting can also be applied to a portion of the locations denoted by A, B, C, D, E, E, F, G, H, I, In particular, the CSI-RS can be transmitted in 2, 4, or 8 REs depending on the number of antenna ports to transmit. When the number of antenna ports is two, the CSI-RS is transmitted in half of the specific pattern in FIG. 2A. When the number of antenna ports is four, the CSI-RS is transmitted to all the specific patterns. CSI-RS is transmitted. On the other hand, muting is always done in one pattern unit. That is, although muting can be applied to a plurality of patterns, it can not be applied to only a part of one pattern when the position does not overlap with the CSI-RS. However, it can be applied only to a part of one pattern only when the position of CSI-RS overlaps with the position of muting. When CSI-RS is transmitted for two antenna ports, the CSI-RS transmits signals of the respective antenna ports in two REs connected in the time axis, and the signal of each antenna port is divided into orthogonal codes. In addition, when CSI-RS is transmitted for four antenna ports, two additional REs are added to the CSI-RS for two antenna ports to transmit signals for two antenna ports in the same manner. The same is true when the CSI-RS for eight antenna ports is transmitted. In case of CSI-RS supporting 12 and 16 antenna ports, 3 CSI-RS transmission positions for the existing 4 antenna ports are combined or 2 CSI-RS transmission positions for 8 antenna ports are combined.

In addition, the UE may be allocated CSI-IM (or IMR) with the CSI-RS. The CSI-IM resource has the same resource structure and location as the CSI-RS supporting the 4-port. CSI-IM is a resource for a terminal that receives data from one or more base stations to accurately measure interference from an adjacent base station. For example, if the adjacent base station wants to measure the amount of interference when transmitting data and the amount of interference when not transmitting, the base station constructs CSI-RS and two CSI-IM resources, and one CSI- The CSI-IM can always transmit a signal and the adjacent base station does not always transmit a signal, so that the interference amount of the adjacent base station can be effectively measured.

Table 2a below shows the RRC fields that make up the CSI-RS setting.

[Table 2a] RRC setup to support periodic CSI-RS in CSI process

The setup for channel status reporting based on periodic CSI-RS in the CSI process can be classified into 4 types as shown in Table 2a. The CSI-RS config is for setting the frequency and time location of the CSI-RS RE. Here, it is set how many ports the corresponding CSI-RS has through setting the number of antennas. The Resource config sets the RE position in the RB, and the Subframe config sets the period and offset of the subframe. Table 2b is a table for resource config and subframe config settings currently supported by LTE.

[Table 2b] Resource config and subframe config settings

(a) Resource config settings

(b) Subframe config settings

The terminal can check the frequency and time position, period and offset from Table 2b. Qcl-CRS-info sets quasi co-location information for CoMP. The CSI-IM config is for setting the frequency and time location of the CSI-IM to measure the interference. Since CSI-IM is always set based on 4 ports, it is not necessary to set the number of antenna ports, and Resource config and Subframe config are set in the same manner as CSI-RS. The CQI report config exists to configure how to report the channel status using the corresponding CSI process. In this setting, there are periodic channel status report setting, aperiodic channel status report setting, PMI / RI report setting, RI reference CSI process setting, and subframe pattern setting.

The subframe pattern is for setting a channel and a measurement subframe subset for supporting interferometry and a channel having characteristics different in time from each other in measuring a channel and an interference received by the terminal. The Measurement subframe subset was first introduced in eICIC (Enhanced Inter-Cell Interference Coordination) to estimate other interference characteristics of ABS (Almost Blank Subframe) and non-ABS general subframes. In order to measure the different channel characteristics between subframes that always operate in the DL and subframes that can be dynamically switched from the DL to the UL in eIMTA (Enhanced Interference Mitigation and Traffic Adaptation), two IMRs can be set and measured To a more advanced form. Tables 2c and 2d show the measurement subframe subsets for eICIC and eIMTA support.

[Table 2c] Measurement subframe subset setting for eICIC

[Table 2d] Measurement subframe subset setting for eIMTA

The eICIC measurement subframe subset supported by LTE is set using csi-MeasSubframeSet1-r10 and csi-MeasSubframeSet2-r10. MeasSubframePattern-r10 referred to by the corresponding field is shown in Table 2e below.

[Table 2e] MeasSubframePattern

The MSB in the left field indicates subframe # 0, and when it is 1, it indicates that it is included in the subframe of the measurement subframe. Unlike the eICIC measurement subframe subset, which sets each subframe set through each field, the eIMTA measurement subframe set uses one field to indicate 0 as the first subframe set and 1 as the second subframe set. Therefore, in eICIC, the subframe may not be included in two subframe sets. However, in the case of the eIMTA subframe set, the subframe should always be included in one of the two subframe sets.

In addition, there is a PC, which means a power ratio between a PDSCH and a CSI-RS RE required for a UE to generate a channel status report, and a Codebook subset restriction for setting which codebook to use. PC and codebook subset restriction are the settings for each subframe subset according to the p-C-AndCBSRList field including two P-C-AndCBSR fields in Table 2g.

[Table 2f] p-C-AndCBSRList

[Table 2g] P-C-AndCBSR

The PC can be defined as shown in Equation (2a), and a value between -8 and 15 dB can be specified.

&Quot; (2a) "

The BS can variably adjust the CSI-RS transmission power for various purposes such as improving the channel estimation accuracy. The UE can determine how much lower or higher the transmission power to be used for data transmission than the transmission power used for channel estimation Able to know. According to the above-described reason, even if the base station varies the CSI-RS transmission power, the terminal can calculate the correct CQI and report it to the base station.

Codebook subset restriction is a function that enables the base station to not report to codewords of codewords supported by the standard according to the number of CRS or CSI-RS ports of the base station. This codebook subset restriction can be set by the codebookSubsetRestriction field included in AntennaInfoDedicated in Table 2h below.

[Table 2h] AntennaInfoDedicated

The codebookSubsetRestriction field is composed of a bitmap, and the size of the bitmap is equal to the number of code points of the corresponding codebook. Therefore, each bit map represents each code point. When the corresponding value is 1, the UE can report the corresponding code point to the BS through the PMI. If the value is 0, the UE can report the corresponding code point as PMI none. For reference, the MSB represents a high precoder index and the LSB represents a low precoder index (eg, 0).

In a cellular system, a base station must transmit a reference signal to a mobile station in order to measure a downlink channel condition. In the LTE-A (Long Term Evolution Advanced) system of the 3GPP, the UE measures the channel state between the BS and the BS using the CRS or the CSI-RS, do. The channel state basically needs to consider several factors, including the amount of interference in the downlink. The amount of interference in the downlink includes an interference signal generated by an antenna belonging to an adjacent base station, thermal noise, and the like, and it is important for the terminal to determine the channel condition of the downlink. For example, when transmitting a signal from a base station with one transmit antenna to a terminal with a receive antenna, the terminal calculates energy per symbol that can be received in the downlink using the reference signal received from the base station, It is necessary to determine the interference amount to be received at the same time and determine Es / Io. The determined Es / Io is converted into a data transmission rate or a value corresponding thereto, and is notified to the base station in the form of a channel quality indicator (CQI), thereby enabling the base station to transmit to the terminal at a certain data transmission rate in the downlink To be able to judge whether or not.

In the case of the LTE-A system, the UE feeds back information on the channel status of the downlink to the base station so that it can be utilized for downlink scheduling of the base station. That is, the UE measures a reference signal transmitted from the base station in the downlink, and feeds back the extracted information to the base station in a form defined by the LTE / LTE-A standard. There are three main types of information that the UE feedbacks in LTE / LTE-A.

Rank Indicator (RI): The number of spatial layers that the UE can receive in the current channel state.

Precoder Matrix Indicator (PMI): Indicator for the precoding matrix preferred by the terminal in the current channel state

Channel Quality Indicator (CQI): The maximum data rate that the terminal can receive in the current channel state. The CQI can be replaced by a SINR that can be used similar to the maximum data rate, a maximum error correction coding rate and modulation scheme, and data efficiency per frequency.

The RI, PMI, and CQI are related to each other and have a meaning. For example, the precoding matrix supported by LTE / LTE-A is defined differently for each rank. Therefore, PMI values when RI has a value of 1 and PMI values when RI has a value of 2 are interpreted differently even if their values are the same. Also, when the UE determines the CQI, it is assumed that the rank value and the PMI value that the base station notified to the base station are applied to the base station. That is, when the UE reports RI_X, PMI_Y, and CQI_Z to the base station, it means that the UE can receive the data rate corresponding to CQI_Z when rank is RI_X and precoding is PMI_Y. In this way, when calculating the CQI, the MS assumes a transmission scheme to be performed by the BS so that optimized performance can be obtained when the transmission is performed according to the transmission scheme.

FIG. 2B is a diagram illustrating how data such as eMBB, URLLC, and mMTC, which are services considered in the NR system, are allocated in a frequency-time resource together with an FCR (Forward Compati- bility Resource).

When eMBB and mMTC are allocated and transmitted in a specific frequency band and URLLC data is generated and needs to be transmitted, eMBB and mMTC empt the previously allocated portion and transmit URLLC data. Among the above services, since the URLLC is particularly important for a short delay time, URLLC data can be allocated to a part of resources allocated to the eMBB, and the eMBB resource can be informed to the UE in advance. For this purpose, the eMBB data may not be transmitted in the frequency-time resource where the eMBB data and the URLLC data are overlapped, and thus the transmission performance of the eMBB data may be lowered. That is, in the above case, eMBB data transmission failure due to URLLC allocation may occur. At this time, the length of the transmission time interval (TTI) used for the URLLC transmission may be shorter than the TTI length used for the eMBB or mMTC transmission.

2C is a diagram illustrating the assumption that each service is multiplexed in time and frequency resources in the NR system. The BS may allocate the CSI-RS to all or multiple bands in order to secure initial channel state information, such as 2c-10. This full-band or multiple-band CSI-RS may be disadvantageous for optimizing system performance because it requires a large amount of reference signal overhead, but in the absence of prior information, such full-band or multiple-band CSI- It may be necessary. After the CSI-RS transmission in the full-band or the multiple-band, each service can be provided with different requirements for each service, and the accuracy and update necessity of necessary channel state information can be changed accordingly. Therefore, after securing the initial channel state information, the base station can trigger the sub-band CSI-RSs 2c-20, 2c-30, and 2c-40 for each service in the corresponding band according to the necessity of each service. Although FIG. 2C illustrates transmission of a CSI-RS for one service at one time, it is also possible that a CSI-RS for a plurality of services is transmitted as needed.

As described above with reference to FIGS. 2B and 2C, the service of the corresponding band may vary according to the change of the time and frequency resources of the base station, and various channels and interference conditions should be considered in view of the change. FIG. 2D illustrates the service of the interference cell and the change of the interference state according to the change of the time and frequency resources from the viewpoint of the eMBB.

In FIG. 2D, one square denotes a VRG (Vertical Resource Group) which is a basic unit of time and frequency resources set by the BS to the UE. In FIG. 2D, all the VRG resources of the cell # 1 are set as eMBB. At this time, the other cells operate the respective VRG resources using eMBB, FCR, URLLC candidate resources, and the like. The transmission method may be different depending on the needs of the service in the resource, and thus the characteristics of the interference may be changed. For example, since URLLC requires high reliability, a large number of resources can be used for the service compared to the amount of data to be transmitted. Since the URLLC data has a higher priority than other services, the resource of the corresponding terminal is preferentially occupied when the URLLC is to be transmitted. Therefore, in the corresponding VRG, the change of the frequency band may be relatively small as compared with the VRG in which the eMBB acts as the interference, so that the interference prediction of the base station may be relatively easy. In addition, if the service of the interference resource is mMTC, the interference power may be lower than the URLLC because the UE having a relatively low power is repeatedly transmitted for improving the coverage although it is not included in FIG. 2D. . In FIG. 2D, it is assumed that all the resources of the cell 1 are set for eMBB transmission. However, it is also necessary to measure the interference and interference signals assuming that the resources are set to FCR, URLLC, mMTC, A channel state measurement and reporting method is needed.

Also, for effective CoMP (Coordinated Multipoint) operation and sub-band BF (Beamformed) CSI-RS operation, it is necessary to measure signals and interference according to time and frequency resources. FIG. 2E illustrates that the base station transmits the CSI-RS in order to effectively measure and report channel state information in the NR.

The optimal beam direction may be different for each frequency band and accordingly it may be effective to transmit different analog and digital beams for each frequency band. In the case of an analog beam, it is not possible to transmit different signals for different frequency bands due to hardware limitations. However, in the case of a digital beam, it is sufficient to make the phase of the analog beam different. Therefore, as shown in FIGS. 2e-10 and 2e-20, And transmit the CSI-RS based on the CSI-RS. It is also possible to transmit from different transmission directions (TRPs) located not only in different beam directions but also in different geographical locations. In the case of the existing LTE CSI-RS, it is designed assuming that the same signal is transmitted in all the bands. In order to allow other service, beam and CoMP scenarios to be assumed for different time and frequency resources, .

The resource for supporting the eMBB / URLLC / mMTC resource for each service and the channel status measurement and reporting of other beam and CoMP scenarios may be a PRB (Physical Resource Block) or a plurality of PRB units. The plurality of PRB units include a service group (SG), a service resource group (SRG), a vertical group (VG), a vertical resource group (VRG), a frequency resource block group (FRG), a physical resource block group (PRG) Multiple PRB group). In addition, since the setting can be considered not only in frequency but also in time and frequency resources, the resource can be also referred to as a time and frequency resource block group (TFRG) or the like. Although the following description of the present specification is based on the VRG, the VRG in the following description can be replaced by all terms and similar terms mentioned above.

The above-mentioned VRG resource setting unit should be specified according to time and frequency resources. In this case, the unit of time resource can be defined as one value in the standard or can be set through RRC. If the service conversion unit of a plurality of cells is defined as one value in the standard, the service conversion unit of the base station transmitting the data is also coincident with the service conversion unit of the data transmitting unit. Therefore, Can be relatively easily predicted. However, unnecessary setup overhead can be increased if the base station is defined as one small time unit (e.g., one slot or subframe) when service conversion is not often needed in time resources. Also, in the opposite case, if it is set to a large time unit (e.g., several tens of ms), the service can not be flexibly switched over from time resources according to the need of the base station, May not be satisfied. Therefore, the corresponding time resource unit should be determined in consideration of this.

RRC, a plurality of base stations or TRPs can freely convert the corresponding time service unit. Accordingly, the corresponding time unit can be freely set and used according to the requirements of the corresponding system. However, in order to satisfy this requirement, the terminal implementation becomes complicated. In the terminal view, the interference of other cells may also be relatively difficult because the time unit is changed according to the request of the service. Therefore, it is preferable to limit the settable time unit to limit to only specific values. Table 2i below illustrates the service unit specification field in time for such VRG setting.

[Table 2i] Time resource granularity configuration for VRG

In the above example, the BS can set the size of the corresponding time resource to one of 5 ms, 10 ms, 20 ms, and 40 ms, and the terminal can recognize the size and number of the VRG time resource based on the size and number. In the above example, the number of time units settable by the base station can be changed. In the above example, the number is set in units of ms. However, the unit may be various units such as a TTI or a subframe. In the above example, a direct number is set. However, it is possible to indirectly set the number by type A, type B or the like instead of a direct number. In this case, such a time unit may be included in the type setting.

The size setting of the VRG at the frequency can also be defined as one value in the standard or set via RRC as mentioned above. If a single value is defined in the standard, since the service conversion unit of a plurality of cells can be set to one value in the frequency, the service conversion unit is also coincident with the signal of the base station transmitting the data, Can be relatively easily predicted. However, if the base station is defined as one small frequency unit (for example, one PRB) when service conversion is not frequently needed in frequency resources, unnecessary setup overhead can be increased. Also, in the opposite case, when a large frequency resource unit (for example, several tens of PRBs) is used, the service can not be flexibly switched over from time resources according to the needs of the base station. requirement may not be satisfied. Therefore, the corresponding frequency resource unit should be determined in consideration of this. As described above, when determining the frequency resource unit according to the standard, the effective frequency resource unit can be changed according to the size of the system band. In other words, when the system bandwidth is relatively small, it is important to efficiently multiplex the bandwidth by dividing the bandwidth efficiently. However, if the system bandwidth is sufficient, it may be preferable to divide the bandwidth efficiently and use it more effectively than to increase the setting overhead . Table 2j is a table illustrating the VRG size in the frequency band according to the size of the system band by illustrating the corresponding frequency resource with VRG.

[Table 2j] VRG Size in frequency with system bandwidth

In Table 2j, the size of the VRG changes according to the set system band. Based on the VRG having the service unit of this frequency band, the base station can set the terminal to support different services or verticals for each VRG. In this case, Table 2J is a table illustrating that the VRG size varies according to the system band setting, and the direct number of the system band range and the VRG size in the table may vary.

Also, it is possible to set the VRG service unit through the RRC in the frequency unit. In this case, a plurality of base stations or TRPs can freely convert the corresponding frequency service unit, and the corresponding frequency unit can be freely set and used according to the demand of the corresponding system. However, in order to satisfy this requirement, the terminal implementation becomes complicated. In the terminal view, the interference of other cells may also be relatively difficult because the frequency unit is changed according to the service request. Therefore, it is preferable to restrict the settable frequency unit to limit to only specific values. Table 2k below illustrates the service unit specification field in frequency for VRG setting.

[Table 2k] frequency resource granularity configuration for VRG

In this example, the BS can set the size of the corresponding time resource to one of 5 PRB, 10 PRB, 20 PRB, and 40 PRB. The terminal determines the size and number of the VRG time resource based on the size, . In the above example, the number of time units settable by the base station can be changed. In the above example, the number is set in units of PRB. However, the unit may be various units such as RBG or subband. In the above example, a direct number is set. However, it is possible to indirectly set a type A, a type B or the like instead of a direct number. In this case, such a frequency unit may be included in the type setting. In addition, when indirectly setting such as type A and type B, the indirect setting may include not only the frequency unit but also the time unit.

The number of VRGs supported by the corresponding system can be calculated based on the time and frequency resource size of the VRG mentioned above, which can be expressed by Equation 2b below.

(2b)

In the above equation, the number of VRGs is expressed by dividing the number of subframes in one frame unit into subframes in units of VRG time. However, the subframe as a unit can be expressed in various units such as ms or TTI. The number of VRGs in frequency is also expressed by dividing the system band represented by PRB number by PRB number in VRG unit in frequency, but the PRB can be represented by various numbers such as RBG or subband. Also, in the above example, when the number of VRGs in a time band is one, the number of VRG resources can be expressed by only the number of VRGs in a frequency resource.

Based on Equation (2b), the UE can directly or indirectly set the service or vertical of the corresponding VRG to the UE based on the calculated number of VRGs. These settings can be provided to all VRG resources individually, or to separate fields by time and frequency. Table II below is an example of providing the setting fields individually for all VRG resources.

[Table 2l] VRG type configuration field

The service type of the VRG resource can be calculated by multiplying the number of VRGs that can be calculated in Equation (2b) by the number of configurable bits per VRG to calculate the size of the corresponding bitmap. This method has the advantage that the VRG type can be set for each VRG setting so that it can be set for all possible combinations. However, a large size bitmap is required for setting the VRG type and the configuration overhead is increased accordingly. In addition, this disadvantage is further maximized when it is set for each band or band combination considering CA (Carrier Aggregation) or other band. Although the above method is illustrated assuming that the corresponding bitmap is set to all the VRGs of the corresponding system at once, such a setting field may be provided for each VRG.

In order to reduce the setting overhead, the service type setting of the VRG resource may be separately set for each VRG resource for each resource. In other words, the VRG of the time unit and the VRG of the frequency unit can be separately set. Table 2m below is an example of providing these time and frequency specific fields.

[Table 2m] VRG type configuration field

In Table 2m, each field indicates a setting field for a VRG resource for each time and frequency. This can reduce the overhead for VRG setup. For example, if there are 10 time- and frequency-specific VRG resources, there should be a configuration field for all VRG resources, and 200 bits of overhead is required if the corresponding configuration field is assumed to be 2 bits. However, when setting 1 bit for the time resource and 2 bits for the frequency resource, it is necessary to set 10 bits and 20 bits, respectively, so that it is possible to set the total by only 30 bits. When divided into time and frequency resources as described above, the corresponding time or frequency resource can be set such that one resource setting indicates whether to allow setting of another resource. Table 2n below illustrates this one bit setting.

[Table 2n] 1 bit VRG type configuration

For example, when 1 bit can be set using the field of Table 2n with respect to the time resource, it indicates whether the corresponding time resource is a resource that can be set as a variety of services. In this case, if the resource is not configurable, the resource may be attributed to a specific service, for example, a specific service such as an eMBB. If the service is not configurable in the standard, it is assumed that the resource corresponds to eMBB or eMBB . It is also possible to select one of 'eMBB', 'mMTC', and 'eMBMS' through the RRC field to notify the terminal of the basic service for the non-configurable value. In the above example, the time resource is set to 1 bit by using the table, and the individual service is set to the frequency resource. However, conversely, it is also possible to set the frequency resource to 1 bit and set the individual service to the time resource. In the above example, 'not configurable' is used. However, it is also possible to describe the description of the corresponding field as 'eMBB', 'mMTC', 'eMBMS' or the like, .

Tables 2o and 2p illustrate fields for directly setting VRG service setting or vertical according to 2-bit or 3-bit VRG setting fields.

[Table 2] 2 bit VRG type configuration

[Table 2p] 3 bit VRG type configuration

The service type can be directly set for each VRG using a predetermined table as shown in Table 2o and Table 2p. This setting method can be used for all the VRG setting fields and the VRG setting fields that are set according to the time / frequency resources mentioned above. As can be seen from Tables 2o and 2p, when the VRG type is set directly as described above, when a large number of bits are used, the corresponding service type can be informed in more detail, and the 'reserved' You can also prepare for that field. However, such an increase in the amount of the indication increases the corresponding overhead, so it should be determined by judging the utility of the service setting versus the overhead increase. In addition, in the case of directly setting the method as described above, since the type of the corresponding service is set in advance in the terminal, not only the channel state information is measured for each resource but also the terminal estimates the operation The operation of the terminal can be optimized. Also, as indicated for eMBMS in Table 2p, a plurality of types can be supported for one service. For example, in the case of eMBMS, a UE can be set up for two or more MBSFN areas. In this case, although two VRGs operate for the same eMBMS service, the MCS settings of the corresponding areas may be different, The setting can be used to support other settings.

In the case of the channel status information, the requirement for the operation of URLLC differs from that of the eMBB. In other words, eMBB operates with 10% BLER, but URLLC may require high reliability such as 1-10 ^ -5 due to its characteristics and can operate with an error probability of 10 ^ -5. However, the current CQI of LTE is required to report MCS capable of operating at 10% BLER and is not suitable for link adaptation for URLLC operation. Accordingly, when the corresponding VRG is set for the URLLC service, information such as a CQI, an MCS, and a coding rate suitable for the service can be reported.

In addition to the CQIs with different reliability for the URLLC, the CSI for URLLC may support CQI tables that support lower modulation and coding rates. The following Tables 2q, 2r and 2s are CQI tables for data transmission based on 64QAM in LTE, CQI tables for data transmission based on 256QAM, and CQI tables for NB-IOT support.

[Table 2q] CQI table for medium transmission rate

[Table 2] CQI table for high transmission rate

[Table 2] CQI table for low transmission rate and / or high reliability

The above table can be used as an example of a high data rate, an intermediate data rate and a data rate for a low data rate or a high reliability, respectively. Therefore, in the case of the channel state information set to the eMBB or used for the eMBB, the plurality of CQI tables can be all settable. However, in the case of channel state information used for URLLC, it may not be necessary to consider a high modulation or coding rate considering the high reliability required by URLLC. Therefore, the channel state information for the URLLC can be set only for a CQI table that supports the maximum (64QAM) or low (16QAM) data rate among the plurality of CQI tables. The setting of the CQI table can be supported by the following method.

Highly reliable CQI table setting method 1: Set directly by independent RRC field setting

Highly reliable CQI table setting method 2: Setting indirectly through RRC field setting which is set together with CQI of high reliability

Highly reliable CQI table setting method 3: Directly set through independent DCI field setting

Highly reliable CQI table setting method 4: Indirect setting through DCI field setting set with CQI of high reliability

CQI table setting method 1 is a method of setting directly by setting an independent RRC field. In this case, it can be set based on the setting field independent of the CQI considering the above-mentioned high reliability. In this method, the base station can freely set a CQI table necessary for the corresponding URLLC transmission according to the corresponding implementation. In addition, this method can report a channel status report based on a different CQI table according to the UE for URLLC transmission.

The CQI table setting method 2 is a method of setting indirectly through the setting of the RRC field to be set together with the CQI of high reliability. URLLC requires a low CQI with low modulation and coding rate at the same time. Therefore, if the corresponding channel state information is divided and set, the overhead for setting can be increased. Accordingly, the UE can support reporting of channel status information for the URLLC by allowing the methods to be set at the same time. In this case, unlike the CQI table setting method 1, the corresponding CQI table can support only one CQI table defined in the standard in the plurality of tables.

CQI table setting method 3 is a method of directly setting through independent DCI field setting. In this case, it can be set based on the setting field independent of the CQI considering the above-mentioned high reliability. This method has an advantage that the base station can freely set the CQI table necessary for the corresponding URLLC transmission according to the implementation. In addition, it is possible to dynamically change eMBB and URLLC dynamically according to the transmission, or to dynamically change the target data rate of the eMBB and report the channel status information.

CQI table setting method 4 is a method of setting indirectly through RRC field setting to be set together with CQI of high reliability. URLLC requires a low CQI with low modulation and coding rate at the same time. Therefore, if the corresponding channel state information is divided and set, the overhead for setting can be increased. Accordingly, the UE can support reporting of channel status information for the URLLC by allowing the methods to be set at the same time. In this case, it is possible to dynamically change the eMBB and URLLC dynamically according to the transmission, or dynamically change the target data rate of the eMBB and report the channel status information. In this case, unlike the CQI table setting method 1, the corresponding CQI table can support only one CQI table defined in the standard in the plurality of tables.

Although three CQI tables are illustrated in the above example, more CQI tables may exist. In the above example, the CQI table supporting the high data rate supports up to 256QAM, but in addition, it can support 1024QAM. In addition, in the above example, the CQI table for providing high reliability supports up to 16 QAM, but it may support a lower modulation, for example, QPSK only.

In addition, in the case of channel state information reporting for URLLC, the rank allowed for reporting may be limited. As with the modulation and coding rates, it is difficult to guarantee high reliability of data transmission based on a high rank. Therefore, by limiting the rank used for channel state information reporting for URLLC, the amount of information required for channel state information reporting can be reduced. Such a setting method is possible by the following method.

How to set the RI limit for URLLC Method 1: Set directly through the independent RRC field setting

Setting RI Limit for URLLC Method 2: Setting indirectly through RRC field setting with high reliability CQI

Setting RI restriction for URLLC Method 3: Codebook subset restriction Setting directly through RRC field setting

Setting the RI Limit for URLLC Method 4: Set Directly through Independent DCI Field Settings

Setting RI Limit for URLLC Method 5: Setting indirectly through DCI field setting with high reliability CQI

The method 1 for setting the RI restriction for URLLC is a method for setting directly by setting the independent RRC field. In this case, it can be set based on the CQI and CQI table setting considering the above-mentioned high reliability and the independent setting field. This method has an advantage that the base station can freely set the RI limit necessary for the corresponding URLLC transmission according to the implementation.

The RI restriction setting method 2 for the URLLC is a method of setting indirectly through the setting of the RRC field to be set together with the CQI and the CQI table of high reliability. URLLC may require both low modulation and coding rates and high reliability CQI and RI constraints at the same time. Therefore, if the corresponding channel state information is divided and set, the overhead for setting can be increased. Accordingly, the UE can support reporting of channel status information for the URLLC by allowing the methods to be set at the same time. In such a case, the corresponding RI restriction may support only one of the RI defined in the standard, for example, 2 or 3 in advance.

The method 3 for setting the RI restriction for URLLC is a method of setting indirectly through the RRC field setting of the codebook. PMI and RI limit settings can be supported using the same method as eMBB service.

The method 4 for setting the RI restriction for URLLC is a direct setting method through the setting of the independent DCI field. In this case, it can be set based on the setting field independent of the CQI considering the above-mentioned high reliability. In this method, the base station can freely set a CQI table necessary for the corresponding URLLC transmission according to the corresponding implementation. In addition, it is possible to dynamically change eMBB and URLLC dynamically according to the transmission, or to dynamically change the target data rate of the eMBB and report the channel status information.

The RI restriction setting method 5 for the URLLC is a method of setting indirectly through the setting of the RRC field to be set together with the CQI and the CQI table of high reliability. URLLC may require both low modulation and coding rates and high reliability CQI and RI constraints at the same time. Therefore, if the corresponding channel state information is divided and set, the overhead for setting can be increased. Accordingly, the UE can support reporting of channel status information for the URLLC by allowing the methods to be set at the same time. In this case, it is possible to dynamically change the eMBB and URLLC dynamically according to the transmission, or dynamically change the target data rate of the eMBB and report the channel status information. In such a case, the corresponding RI restriction may support only one of the RI defined in the standard, for example, 2 or 3 in advance.

In addition, a separate transport block size (TBS) table for supporting URLLC transmission can be supported. The UE can receive the modulation and coding rate for data transmission through the MCS together with the data scheduling resource information. The MCS information can be used for obtaining the TBS size information required for decoding the downlink transmission. The setting of the TBS table may be independently set through the DCI or RRC setting, and may be set together with the CQI, CQI table or RI restriction setting for the URLLC transmission having the above-mentioned high reliability.

In addition, the transmission scheme for the corresponding URLLC data transmission may be limited. As described above, since data transmission requires high transmission reliability, diversity-based transmission techniques such as transmit diversity or large delay CDD, or semi-open-loop or beam Based diversity transmission scheme can be advantageous. Similar to the TBS setting, the setting of this transmission scheme may be independently set through the DCI or RRC setting. In addition to the above-mentioned CRL, CQI table, RI restriction or TBS table setting for the highly reliable URLLC transmission Can be set.

In addition, the above-mentioned methods can also be used for other services. For example, a highly reliable CQI is not required for mMTC, but a CQI table with a low transmission rate, a TBS table setting, an RI restriction setting, and a transmission scheme restriction may be required. Therefore, the corresponding methods are applied to such terminals by using a CQI or CQI table having a higher transmission rate, an intermediate transmission rate, a lower transmission rate, a higher reliability, an intermediate reliability, and a lower reliability than a URLLC dedicated CQI table or a mMTC CQI table, TBS table, and the like. In addition, it can be expressed as an alternative CQI, an alternative CQI table, an alternative TBS table, or the like, and can also be expressed by CQI and CQI tables I, II, and III.

As another example, when the eMBMS is set, the channel state information reporting may be omitted. The eMBMS does not use link adaptation as a service specialized for broadcasting, and all terminals in the area should be able to receive the data. Therefore, an MCS suitable for a corresponding terminal is used so that a terminal having the lowest signal-to-interference ratio (SINR) can be received. Considering this, it may not be necessary to report the channel state information for the corresponding band. If the channel state information is not reported according to the service setting, information such as RI, PMI, and CQI may be excluded from the information transmission or may be fixed to a specific bit such as zero. By minimizing the amount of channel state information transmitted in the uplink using the above method, coverage and transmission performance of the information can be improved and system performance can be improved.

As described above, the direct service setting method has an advantage that the control signal, data, and channel state information can be transmitted in a method optimized for the service, and thus the system can be efficiently used. However, it may be necessary to reserve a large number of fields on the assumption that a service will be newly introduced for NR, and a sufficient number of reserve fields should be secured to prevent this. However, in this case, there is a disadvantage that the field setting overhead can be excessively increased. The above Table 2o and Table 2p are examples of direct service type setting for VRG, and the value and service of the corresponding field directly can be changed. In addition, although the field using 2 bits and 3 bits is illustrated in the above table, the number of bits in the actual field may be different from the above table.

Table 2 below is a table showing the setting of the indirect VRG set through the 2-bit VRG setting field.

[Table 2t] 2 bit VRG type configuration

Unlike the direct VRG service type configuration mentioned above, the method of Table 2t is a method of specifying and using an indirect service set. The base station does not need to support all service types, and only a few sets of services can be used as needed. When using the methods of Table 2o and Table 2p, all base stations must use a set bit according to all service types, thereby increasing setting overhead. Therefore, when the indirect service set is informed as described above, the setting overhead can be minimized, and the BS can enjoy the corresponding VRG effect by managing the VRGs as a set. However, in order to perform the service specific operation mentioned above, additional setting is necessary. For example, if the fields mentioned in Table 2o or Table 2p are set for each service set, the service type can be directly set for each service set without supporting all fields for all VRGs, and the setting overhead can be minimized have.

In addition to the above form, channel status information specialized for services such as URLLC can be used by using additional fields for the service. Table 2u illustrates these additional fields.

[Table 2] VRG type configuration field

As described above, the URLLC or FCR setting fields may be separately set in the VRG setting field, and the terminal may support the corresponding feedback or related operation through the setting of the corresponding field. At this time, the AdvancedCSI field may be set for eMBB operation as a field for providing improved channel status information, which uses more overhead but provides accurate information.

In addition, the above-mentioned direct VRG service type configuration and indirect type configuration can be used in combination. For example, eMBB is a service commonly used by all base stations and is frequently used. Therefore, field 00 can be directly set by eMBB, and the remaining three fields can be used as a service set. Table 2t is an example of an indirect service type setting for VRG, and the representation of the corresponding indirect field may be different. Also, although the field using 2 bits is illustrated in the above table, the number of bits in the actual field may be different from the above table.

In order to manage the above-mentioned VRG setting information, the base station may add an ID to the VRG setting information in the corresponding field. Table 2v illustrates these ID fields.

[Table 2v] VRG Info ID

The base station can easily set or trigger the corresponding VRG related information when using the periodic CSI-RS and channel state information reporting or non-periodic CSI-RS and non-periodic CSI-RS reporting through the non-periodic trigger through the VRG setting ID . The ID may be one of the maximum number of VRG information that can be set from 0.

As mentioned above, the service / vertical allocation in the frequency-time resource can be supported to set in VRG units, and this setting can be semi-static through RRC or simultaneously transmit control information to specific groups of terminals Can be set dynamically through the downlink control information (which can be illustrated as a group DCI / common DCI). If the semi-static setting is supported through the RRC, the service / vertical allocation in the time and frequency resources is constant over a long period of time, so that the change of the interference situation is small. Therefore, I can grasp well. However, in this method, performance for service / vertical support may be deteriorated due to a long adaptation period according to the change of traffic characteristics of the TRP. For example, in the case of a base station that does not require mMTC or URLLC transmission, it may cause deterioration of system performance if these resources are allocated in advance. Therefore, by setting all the resources as eMBB resources, it is possible to prevent the deterioration of the system performance. However, if the base station suddenly needs to transmit a URLLC or the like, it can not support the service before resetting the corresponding RRC. If there is such a possibility, the base station should set a certain amount of resources as a corresponding service resource in advance The performance of the corresponding base station may be degraded. If it can be set dynamically through the downlink control information, it is possible to cope with such traffic generation relatively quickly, so that the amount of time and frequency resources to be secured in advance can be small. Therefore, although the system performance can be relatively high, a control signal overhead due to DCI or the like is generated. The group DCI is transmitted at a predetermined time between the BS and the UE, and may be scrambled based on the set RNTI group.

In order to trigger the aperiodic CSI-RS transmission and channel state information reporting on the VRG, the BS may transmit information on the corresponding VRG set to the UE. Tables 2w and 2x illustrate fields for triggering aperiodic CSI-RS transmission and channel state information reporting on the VRG aggregate.

[Table 2w] Aperiodic CSI-RS and CSI reporting trigger via VRG

[Table 2x] Aperiodic CSI-RS and CSI reporting trigger via VRG

Table 2w is a method for triggering by Wideband CSI-RS or VRG ID based on preset VRG setting information and corresponding ID. This method has an advantage in that CSI-RS can be transmitted only to the corresponding VRG for each service that must be transmitted according to need, but there is a disadvantage that a plurality of downlink control information must be transmitted in order to trigger a plurality of VRGs.

Table 2x is a method of triggering CSI-RS and related channel state information based on a set of preset VRG setting information. Table 2y below illustrates these trigger field settings.

[Table 2y] VRG set configuration for CSI-RS and CSI reporting

In Table 2y, each trigger field indicates VRG information through which the CSI-RS and the channel status report will be performed. For example, if the first and second bits of trigger010 are set to 1 and the remaining bits are 0, the CSI-RS and channel status reports can be made in the VRG corresponding to VRG IDs 0 and 1. In this example, it is assumed that the number of bits and the number of bits of the trigger of Table 2x are the same. However, these fields may be different, and the downlink control information group DCI / common DCI < / RTI > or the like). Table 2z below illustrates the field.

[Table 2z] Aperiodic CSI-RS and CSI reporting trigger via VRG

As shown in Table 2z, the BS can transmit 2 bits through the downlink control information transmitted to the MS. The 2 bits indicate the lowest index and the highest index among the allowed VRG sets. In this case, the BS can inform the UE of a set of VRGs available through the group DCI, and the size of the corresponding bitmap may be equal to the number of VRG aggregation settings. For example, if the base station transmits 01001000 and 00110000 for the first set and the second set respectively through the group DCI, the terminal will trigger the VRG of ID 1 and the VRG of ID 4 for the first set, And the VRG of the ID number 3 is enabled. Accordingly, when trigger '10' is on, CSI-RS for VRG of ID # 2 and ID # 3 is received when VRG 1 and 4 are turned on and trigger 11 is turned on, and channel status information And reports.

As described above, a setting field as shown in Table 2aa may be used for CSI-RS transmission, IMR resource setting, and channel status report setting.

[Table 2aa] CSI-RS / CSI-IM / CSI reporting configs in VRG Info

As shown in Table 2aa, the corresponding field may include a CSI-RS setting and a CSI-IM setting. When the setting supports aperiodic CSI-RS, the number of ports for the NP CSI-RS, O1 and O2, which are dimension oversampling factors, one subframe config for transmitting a plurality of CSI-RSs, and a plurality of resource configs for setting a location, and the periodic CSI-RS If supported, the subframe config information may be included in addition to the information. The port number information of the CSI-IM can be fixed to the standard. Like the CSI-RS, if the resource is acyclic, only the resource config can be included. If the resource is periodically set, the subframe config information can be additionally included in the information .

In the above description, the CSI-RS and the channel status information are described for each VRG. However, in order to support the VRG described above, the corresponding configuration may be supported as a measurement subset. In the case of CSI-RS and channel state information report allocation according to the VRG mentioned above, the CSI-RS and the channel state information report can be allocated including the area where the base station does not transmit data although the terminal is set. It can be a waste. Therefore, CSI-RS setting and channel status information reporting setting can be separated from VRG setting for efficient resource use. In this case, the VRG setting can indirectly act as a measurement subset in the channel status report measurement. Table 2ab below illustrates VRG settings for the measurement subset operation.

[Table 2ab] VRG type configuration field

As mentioned in Table 2ab above, for the measurement subset operation, individual codebook subset restriction and PC settings are required. Therefore, when a measurement subset operation is performed for each VRG, the codebook subset restriction and the PC may be set in the individual VRG fields as in the above example. The UE can individually report CRI, PTI, RI, PMI, and CQI based on the measurement set. As described above, channel state information such as CRI, RI, PTI, PMI, It depends on the type setting and the feedback type setting. This method is advantageous in that it does not require additional overhead in addition to VRG setting for subset restriction. However, it has a disadvantage in that it can not reflect additional interference when the interference condition changes due to service change of another cell in the corresponding VRG.

The measurement subsets can be supported within the VRG for measurement of interference changes by other services, beam directions and CoMP scenarios in the above-mentioned VRG. For this support, the VRG specific CSI-RS and channel state information trigger mentioned in Table 2w-Table 2z may be preferable. The VRG sub-frame subset method may support independent fields for each VRG subset, or may support separate fields. Table 2ac below is an example of supporting independent fields for each measurement subset for a measurement subset within up to three allowed VRGs.

[Table 2ac] VRG Size with system bandwidth

Unlike the existing subframe subset, since there are two or more interference conditions in the frequency band, the corresponding subset setting may be more than two. In addition, a list of corresponding settings can be indicated for individual PC and codebook subset restriction settings, and the list of corresponding settings is equal to the number of VRG measurement subset. In the above example, a setting field is provided for each measurement set. However, unlike the above example, it is also possible to support two measurement sets with one field. However, in this case, since only two measurement sets can be supported, there is a limit to the measurable interference condition. In order to prevent this, it is also possible to provide additional setting fields to support four measurement sets.

Since it may be difficult for all terminals to support the plurality of VRG settings, the UE can inform the base station of the UE capability for the corresponding setting. Table 2ad below illustrates fields for such UE capability reporting.

[Table 2ad] UE capability on VRG

As described above, the UE can inform the BS of the number of VRGs supported by the UE and the measurement subframe set that can be supported by each VRG. Accordingly, it is possible to easily implement the UE and to support the corresponding service more flexibly. If the capability indication is not supported, the implementation of the NR UE can be complicated due to the difficulty of the implementation, and the unit price of the UE can be increased.

2C, CSI-RS transmission for an entire system band or an entire system band to which a terminal is allocated may be required for ensuring initial channel state and securing long-term information. In order to secure channel state information for each service, CSI-RS transmission may be required. Therefore, the CSI-RS type can be divided into two types, and it can be referred to as CSI-RS type A and CSI-RS type B.

CSI-RS type A supports CSI-RS transmission for the whole system band or the entire system band to which the terminal is allocated. Accordingly, the UE can acquire initial channel status and long-term information based on the CSI-RS type A information. Therefore, the CSI-RS type A requires the resource config described in Table 2a. In the case of the Aperiodic CSI-RS, the subframe configuring the period and the subframe offset information is not required. However, in the case of the semi-persistent CSI-RS, the subframe config can be maintained as it is. Etc. may be set.

On the other hand, CSI-RS type B requires partial band setting unlike CSI-RS type A. Therefore, in the case of CSI-RS type A, it is assumed that transmission is always performed for the whole system band. However, such CSI-RS type A may require a method for partial band setting. Therefore, it may be necessary to set the CSI-RS allocation to support a specific subband or a bandwidth part, a RBG, a discontinuous RB, and a continuous RB. This method may be applied to a bitmap And may be supported using LTE downlink resource allocation types 0, 1, 2, and so on. 2F, 2G and 2H illustrate such downlink resource allocation types 0, 1, and 2. It is also possible to support it using an uplink resource allocation method or the like.

크기의 비트맵을 이용하여 해당 RBG를 할당받고 해당 자원에서 하향 링크 데이터를 수신 받을 수 있다. 이와 마찬가지로 기지국이 단말에게 해당 RBG에 비주기적 CSI-RS를 전송 할 것인지를 알리기 위해서 해당 방법을 이용하여 RBG 별로 비주기적 CSI-RS를 할당 할 수 있다. The downlink resource allocation type 0 of LTE is a method of allocating resources in a predetermined RBG unit according to the system band. In order to allocate resources based on type 0, the BS first uses bits to inform the resource allocation type. Also, in order to allocate a substantial resource, the terminal uses the RBG size according to the system bandwidth size

Size bitmap and receive the downlink data from the corresponding resource. Likewise, in order to notify the UE whether the non-periodic CSI-RS is to be transmitted to the corresponding RBG, the non-periodic CSI-RS can be allocated to each RBG using the corresponding method.

크기의 비트맵에 서브셋 선택을 위한 [log₂(P)] 비트와 오프셋 선택을 위한 1비트를 제외한 양인

크기의 비트맵을 이용하여 해당 RB를 할당받고 해당 자원에서 하향 링크 데이터를 수신 받을 수 있다. 이러한 하향 링크 자원 할당 타입 1의 방법을 하여 기지국은 단말에게 비주기적 CSI-RS를 전송할 수 있다. 이 때, 방법은 RRC 또는 L1 시그널링 일 수 있다. 또한, 불연속적 RB를 할당함에 있어 해당 비주기적 CSI-RS 전송은 하향 링크 데이터 할당과 달리 코드워드 별 MCS와 같은 CSI-RS 전송에 필요하지 않은 오버헤드가 필요치 않으므로 이에 따라 하향 링크 자원 할당보다 더 많은 DCI 비트를 설정 가능할 수도 있다. 따라서, 이 때에는 오프셋을 제외하고 전체 크기의 비트맵을 사용하여 할당하는 것도 가능하다.The downlink resource allocation type 1 is a method of allocating and transmitting an aperiodic CSI-RS to a specific discontinuous RB. This method supports non-periodic CSI-RS transmission for each discontinuous RB, which increases the flexibility of resource use. In order to assign a resource to a type 1, a base station first uses a bit to inform the resource allocation type. In addition, since the signaling overhead increases excessively in order to allocate resources for all the RBs to all the bands at once, it is possible to transmit the resources in two by offset. In addition, type 1 uses the same signaling as type 0,

Size bitmap except for [log ₂ (P)] bits for subset selection and 1 bit for offset selection

Size bitmap and receive the downlink data from the corresponding resource. The BS can transmit the aperiodic CSI-RS to the UE by using the downlink resource allocation type 1 method. At this time, the method may be RRC or L1 signaling. In addition, in the non-periodic CSI-RS transmission in the discontinuous RB allocation, unlike the downlink data allocation, no unnecessary overhead is required for CSI-RS transmission such as MCS for each codeword, It may be possible to set many DCI bits. Therefore, at this time, it is also possible to allocate by using a bitmap of full size except offset.

In order to allocate resources based on the downlink resource allocation type 2, the base station first allocates 1 bit to indicate whether the resource allocation is allocated in the form of Localized Virtual Resource Block (LVRB) or Distributed Virtual Resource Block (DVRB) Lt; / RTI > Based on this, the RB location and length are informed through RIV (Resource Indication Value). At this time, the start position and length can be obtained according to the DCI format as shown in the following equation (2c).

(2c)

와

비트이다.The resource allocation bits used at this time are

Wow

Bit.

In addition, as in CSI-RS type A, CSI-RS type B also requires the resource config described in Table 2a. In the case of the Aperiodic CSI-RS, the subframe configuring the period and the subframe offset information is not required. However, in the case of the semi-persistent CSI-RS, the subframe config can be maintained as it is. Etc. may be set.

Therefore, if the corresponding CSI-RS setting is type A, the terminal assumes that the CSI-RS is transmitted in the entire system band to which the terminal is allocated, and receives the CSI-RS. If the CSI-RS setting is type B, the corresponding CSI-RS is assumed to receive the CSI-RS in the partial band of the system. The CSI-RS type setting may be indirectly set according to the existence of the subband transmission setting mentioned above.

The CSI-RS type A and the CSI-RS type B can have different QCL support for CoMP transmission according to their characteristics. As mentioned above, the CSI-RS type A is transmitted to the entire band. Therefore, it is very useful to estimate delay information (delay spread, average delay, etc.), but it is not suitable to estimate Doppler information (Doppler spread, Doppler shift, etc.) because the number of transmissions in the time resource of the transmission is insufficient. Therefore, CSI-RS type A may be used to estimate only delay information. Conversely, CSI-RS type B is suitable for Doppler information estimation considering a short transmission period but not for delay information estimation. Therefore, CSI-RS type B can be used only for Doppler information estimation.

In order to estimate the DMRS, the terminal needs both the above-mentioned delay information and Doppler information. In case of LTE, the BS provides the CRS and the CSI-RS information to the UE, and since the CRS and the CSI-RS are always transmitted using the short period and the full band, the delay information and the Doppler information are available . However, in the case of NR, CRS does not exist, and there are two types of CSI-RS as described above. Therefore, the CSI-RS type A and the CSI-RS type B are set in place of the CRS in the PQI (PDSCH RE mapping and quasi-colocation indicator) information, which previously provided CRS and CSI-RS information, Information can be estimated.

The channel state information provided for the CSI-RS type A and the CSI-RS type B may also vary. CSI-RS type A provides information on channels that change over a relatively long period. A method of channel status reporting in CSI-RS type A includes channel state reporting including only system band and long period information, channel state reporting including system band information, subband information, and long cycle and short cycle information simultaneously .

The first method is to allow the UE to report only the system band and long period information, and the UE may only include information such as RI / W1 / wideband W2 / wideband CQI. Based on this, the UE can report the allocated total system bandwidth and long-term channel status information. In addition, since the full-band channel state information can not satisfy the service of the allocated part, it can support only one representative type of CQI. Such a CQI can support only the CQI targeting the eMBB CQI, i.e., 10% BLER, rather than the CQI for each service to be described below.

The second method is for the UE to report the subband information at the same time. This method provides more information than the first method. Therefore, even if CSI-RS type B for subband information is not transmitted, it is possible to know subband information, thereby increasing transmission efficiency and information amount.

In addition, explicit CSI can be supported in CSI-RS type A. Explicit CSI means that the UE directly transmits the covariance matrix, which is long-term information of the channel, to the base station. Therefore, it is desirable that this information is supported through CSI-RS type A. In LTE, the above information is reported for each UE in the entire system band. However, in NR, a wider system band can be supported. Accordingly, it is also possible to report a plurality of RI / W1 / CQIs by dividing the entire system band into parts.

Compared with the above-mentioned CSI-RS type A, CSI-RS type B provides information on a channel changing in a relatively short period. Therefore, the corresponding CSI-RS type B must include W2 / and subband CQI information report. In addition, channel state information specific to a specific service to be described below may be supported. At this time, RI can also be included because the supportable rank of each service can be changed. For example, in the case of URLLC transmission or control channel, high reliability is required. In this case, the amount of information needed can be reduced and reliability can be improved by lowering the rank required for support. In the channel state report for CSI-RS type B, the UE can support RI and subband CQI by using relative values. For example, offset support may exist as shown in the following table. The following Tables 2ae, 2af, and Table 2ag are examples of tables for reporting RI and CQI at these relative values.

[Table 2ae] Relative CQI reporting for CSI-RS type B

[Table 2af] Relative RI reporting for CSI-RS type B

[Table 2] Relative RI reporting for CSI-RS type B

When reporting using this relative value, the bit amount can be reduced compared to reporting the total CQI or RI. In particular, Table 2af has the advantage of reporting RI with a small amount of bits for high reliability services.

In addition to the above-mentioned RI and CQI, W2 reported based on CSI-RS type B can be based on W1 reported based on CSI-RS type A. Also, when there are a plurality of W1 reported in the CSI-RS type A, the UE can report the subband W2 and the subband CQI based on W1 corresponding to the corresponding set and reported subband.

The CSI-RS type A may be represented by another name such as a coverage CSI-RS, a cell specific CSI-RS, a wideband CSI-RS, a full BW CSI- RS, UE specific beamformed CSI-RS, partial BW CSI-RS, and the like. Also, in the above-mentioned terminology, it is also possible to express in various terms such as a measurement RS, a beam RS, and a beam measurement RS instead of CSI-RS.

FIG. 2I is a flowchart showing an operation procedure of a terminal according to an embodiment of the present invention.

Referring to FIG. 2I, in step 1910, the terminal receives configuration information on the VRG configuration. At least one of a VRG ID, a time of each VRG, a frequency resource location, a service type, a service set, a support feedback type, and a VRG measurement subset may be set in this information. In addition, based on the received setting information, the UE transmits the number of ports for each NP CSI-RS, N1 and N2, which are the number of antennas for each dimension, O1 and O2, which are oversampling factors for each dimension, At least one of a plurality of resource configs for configuring a subframe and a location, codebook subset restriction related information, CSI report related information, CSI-process index, and transmission power information (PC). Thereafter, in step 1920, the UE configures one feedback configuration information based on the CSI-RS location. The information may include PMI / CQI period and offset, RI period and offset, CRI period and offset, wideband / subband availability, submode, and the like. Upon receiving the CSI-RS based on the information in step 1940, the terminal estimates a channel between the base station antenna and the reception antenna of the terminal based on the CSI-RS. In step 1940, the UE generates the feedback information rank, PMI, and CQI based on the received feedback based on the estimated channel, and selects an optimal CRI based on the feedback information. In step 1950, the terminal transmits the feedback information to the base station at a predetermined feedback timing according to the feedback setting of the base station or the aperiodic channel status report trigger, thereby completing the channel feedback generating and reporting process.

FIG. 2J is a flowchart showing an operation procedure of the base station according to the embodiment of the present invention.

 Referring to FIG. 2J, in step 2010, the BS transmits configuration information on a VRG for measuring a channel to a UE. At least one of a time, a frequency resource location, a service type, a support feedback type, and a VRG measurement subset of each VRG can be set. The number of ports for the NP CSI-RS to transmit the CSI- A plurality of resource configs for setting a subframe config and a location for transmitting a plurality of CSI-RSs, codebook subset restriction related information, CSI Report related information, a CSI-process index, and transmission power information (PC). In step 2020, the BS transmits feedback configuration information based on at least one CSI-RS to the UE. The information may include PMI / CQI period and offset, RI period and offset, CRI period and offset, wideband / subband availability, submode, and the like. The base station then transmits the configured CSI-RS to the terminal. The terminal estimates a channel for each antenna port and estimates an additional channel for a virtual resource based on the estimated channel. The UE determines the feedback and generates CRI, PMI, RI, and CQI corresponding to the feedback, and transmits the CRI, PMI, RI, and CQI to the base station. Accordingly, the BS receives the feedback information from the UE at a predetermined timing in step 2030 and uses it to determine the channel state between the UE and the BS.

2K is a block diagram illustrating an internal structure of a terminal according to an embodiment of the present invention.

Referring to FIG. 2K, the terminal includes a communication unit 2110 and a control unit 2120. The communication unit 2110 performs a function of transmitting or receiving data from outside (for example, a base station). Here, the communication unit 2110 can transmit feedback information to the base station under the control of the control unit 2120. [ The controller 2120 controls the states and operations of all the components constituting the terminal. Specifically, the control unit 2120 generates feedback information according to information allocated from the base station. In addition, the controller 2120 controls the communication unit 2110 to feedback the generated channel information to the base station according to the timing information allocated from the base station. For this, the control unit 2120 may include a channel estimation unit 2130. The channel estimation unit 2130 determines the position of the corresponding VRG in the time and frequency resources through the VRG service and the feedback information received from the base station and confirms necessary feedback information through the CSI-RS and the feedback allocation information related thereto . And estimates the channel using the received CSI-RS based on the feedback information. In FIG. 2h, the terminal is configured to include the communication unit 2110 and the control unit 2120, but the present invention is not limited thereto. Various configurations may be further provided according to functions performed in the terminal. For example, the terminal may further include a display unit for displaying a current state of the terminal, an input unit for inputting a signal such as a function execution from the user, a storage unit for storing data generated in the terminal, and the like. Although the channel estimation unit 2130 is illustrated as being included in the control unit 2120 in the above description, the present invention is not limited thereto. The control unit 2120 may control the communication unit 2110 to receive configuration information for each of the at least one reference signal resource from the base station. The control unit 2120 may control the communication unit 2110 to measure the at least one reference signal and to receive feedback setting information for generating feedback information according to the measurement result from the base station.

The control unit 2120 may measure at least one reference signal received through the communication unit 2110 and generate feedback information according to the feedback setting information. The control unit 2120 may control the communication unit 2110 to transmit the generated feedback information to the base station at a feedback timing according to the feedback setting information. The controller 2120 also receives CSI-RS (Channel Status Indication-Reference Signal) from the base station, generates feedback information based on the received CSI-RS, and transmits the generated feedback information to the base station . At this time, the controller 2120 may select a precoding matrix for each antenna port group of the base station and select one additional precoding matrix based on the relationship between the antenna port groups of the base station have.

Also, the controller 2120 receives the CSI-RS from the base station, generates feedback information based on the received CSI-RS, and transmits the generated feedback information to the base station. At this time, the controller 2120 may select one precoding matrix for all antenna port groups of the base station. The control unit 2120 also receives feedback setting information from the base station, receives the CSI-RS from the base station, generates feedback information based on the received feedback setting information and the received CSI-RS, Feedback information to the base station. At this time, the control unit 2120 can receive additional feedback setting information based on the feedback setting information corresponding to each antenna port group of the base station and the relationship between the antenna port groups.

FIG. 21 is a block diagram illustrating an internal structure of a base station according to an embodiment of the present invention.

Referring to FIG. 21, the base station includes a control unit 2210 and a communication unit 2220. The control unit 2210 controls states and operations of all the constituent elements of the base station. Specifically, the control unit 2210 assigns a CSI-RS resource for channel establishment and related settings for acquiring VRG information to the UE, and allocates a feedback resource and a feedback timing to the UE. For this, the control unit 2210 may further include a resource allocation unit 2230. Also, feedback setting and feedback timing are assigned so that feedback from the plurality of terminals do not collide, and feedback information set at the corresponding timing is received and analyzed. The communication unit 2220 transmits and receives data, a reference signal, and feedback information to the terminal. Here, the communication unit 2220 transmits the CSI-RS to the UE through the resources allocated under the control of the controller 2210, and receives feedback on the channel information from the UE. Also, the reference signal is transmitted based on the CRI, rank, partial PMI information, and CQI obtained from the channel state information transmitted from the UE.

Although the resource allocation unit 2230 is illustrated as being included in the control unit 2210 in the above description, the resource allocation unit 2230 is not limited thereto. The control unit 2210 may control the communication unit 2220 to transmit the setting information for each of the at least one reference signal to the terminal, or may generate the at least one reference signal. In addition, the control unit 2210 may control the communication unit 2220 to transmit feedback setting information for generating feedback information according to the measurement result to the terminal. The control unit 2210 may transmit the at least one reference signal to the terminal and may control the communication unit 2220 to receive the feedback information transmitted from the terminal at the feedback timing according to the feedback setting information. In addition, the controller 2210 may transmit feedback setting information to the terminal, transmit the CSI-RS to the terminal, and receive the feedback setting information and feedback information generated based on the CSI-RS from the terminal . At this time, the control unit 2210 may transmit additional feedback setting information based on the feedback setting information corresponding to each antenna port group of the base station and the relation between the antenna port groups. Also, the control unit 2210 may transmit the beamformed CSI-RS to the terminal based on the feedback information, and may receive feedback information generated based on the CSI-RS from the terminal. According to the embodiment of the present invention described above, it is possible to prevent excessive allocation of feedback resources to transmit CSI-RSs in a base station having a large number of two-dimensional antenna array structures and increase in channel estimation complexity The UE can effectively measure all the channels for a large number of Tx antennas and form feedback information to notify the BS.

≪ Third Embodiment >

Efforts are underway to develop an improved 5G or pre-5G communication system to meet the growing demand for wireless data traffic after commercialization of the 4G communication system. For this reason, a 5G communication system or a pre-5G communication system is called a system after a 4G network (Beyond 4G network) communication system or after a LTE system (Post LTE). To achieve a high data rate, 5G communication systems are being considered for implementation in very high frequency (mmWave) bands (e.g., 60 gigahertz (60GHz) bands). In order to mitigate the path loss of the radio wave in the very high frequency band and to increase the propagation distance of the radio wave, in the 5G communication system, beamforming, massive MIMO, full-dimension MIMO (FD-MIMO ), Array antennas, analog beam-forming, and large scale antenna technologies are being discussed. In order to improve the network of the system, the 5G communication system has developed an advanced small cell, an advanced small cell, a cloud radio access network (cloud RAN), an ultra-dense network, (D2D), a wireless backhaul, a moving network, cooperative communication, Coordinated Multi-Points (CoMP), and interference cancellation Have been developed. In addition, in the 5G system, the Advanced Coding Modulation (ACM) scheme, Hybrid FSK and QAM Modulation (FQAM) and Sliding Window Superposition Coding (SWSC), the advanced connection technology, Filter Bank Multi Carrier (FBMC) (non-orthogonal multiple access), and SCMA (sparse code multiple access).

On the other hand, the Internet is evolving into an Internet of Things (IoT) network in which information is exchanged between distributed components such as objects in a human-centered connection network where humans generate and consume information. IoE (Internet of Everything) technology, which combines IoT technology with big data processing technology through connection with cloud servers, is also emerging. In order to implement IoT, technology elements such as sensing technology, wired / wireless communication, network infrastructure, service interface technology and security technology are required. In recent years, sensor network, machine to machine , M2M), and MTC (Machine Type Communication). In the IoT environment, an intelligent IT (Internet Technology) service can be provided that collects and analyzes data generated from connected objects to create new value in human life. IoT is a field of smart home, smart building, smart city, smart car or connected car, smart grid, health care, smart home appliance, and advanced medical service through fusion of existing information technology . ≪ / RTI >

Accordingly, various attempts have been made to apply the 5G communication system to the IoT network. For example, technologies such as sensor network, machine to machine (M2M), and machine type communication (MTC) are implemented by techniques such as beamforming, MIMO, and array antennas, which are 5G communication technologies will be. The application of the cloud RAN as the big data processing technology described above is an example of the convergence of 5G technology and IoT technology.

As described above, a plurality of services can be provided to a user in the communication system, and a method and a device using the method that can provide each service within the same time interval in accordance with the characteristics to provide the plurality of services to the user are required .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, some of the elements are exaggerated, omitted or schematically shown. Also, the size of each component does not entirely reflect the actual size. In the drawings, the same or corresponding components are denoted by the same reference numerals.

At this point, it will be appreciated that the combinations of blocks and flowchart illustrations in the process flow diagrams may be performed by computer program instructions. These computer program instructions may be loaded into a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus, so that those instructions, which are executed through a processor of a computer or other programmable data processing apparatus, Thereby creating means for performing functions. These computer program instructions may also be stored in a computer usable or computer readable memory capable of directing a computer or other programmable data processing apparatus to implement the functionality in a particular manner so that the computer usable or computer readable memory The instructions stored in the block diagram (s) are also capable of producing manufacturing items containing instruction means for performing the functions described in the flowchart block (s). Computer program instructions may also be stored on a computer or other programmable data processing equipment so that a series of operating steps may be performed on a computer or other programmable data processing equipment to create a computer- It is also possible for the instructions to perform the processing equipment to provide steps for executing the functions described in the flowchart block (s).

In addition, each block may represent a portion of a module, segment, or code that includes one or more executable instructions for executing the specified logical function (s). It should also be noted that in some alternative implementations, the functions mentioned in the blocks may occur out of order. For example, two blocks shown in succession may actually be executed substantially concurrently, or the blocks may sometimes be performed in reverse order according to the corresponding function.

Herein, the term " part " used in the present embodiment means a hardware component such as software or an FPGA or an ASIC, and 'part' performs certain roles. However, 'part' is not meant to be limited to software or hardware. &Quot; to " may be configured to reside on an addressable storage medium and may be configured to play one or more processors. Thus, by way of example, 'parts' may refer to components such as software components, object-oriented software components, class components and task components, and processes, functions, , Subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided in the components and components may be further combined with a smaller number of components and components or further components and components. In addition, the components and components may be implemented to play back one or more CPUs in a device or a secure multimedia card. Also, in an embodiment, 'to' may include one or more processors.

For example, 3GPP's High Speed Packet Access (HSPA), LTE (Long Term Evolution or Evolved Universal Terrestrial Radio Access (E-UTRA)), LTE-Advanced To a broadband wireless communication system that provides high-speed, high-quality packet data services such as the LTE-A, 3GPP2 high rate packet data (HRPD), UMB (Ultra Mobile Broadband), and IEEE 802.16e communication standards. . In addition, a 5G or NR (new radio) communication standard is being produced with the fifth generation wireless communication system.

In this way, at least one service of Enhanced Mobile Broadband (eMBB), Massive Machine Type Communications (mMTC), and URLLC (Ultra-Reliable and Low-latency Communications) can be provided to the terminal in a wireless communication system including the fifth generation have. The services can be provided to the same terminal during the same time period. In the embodiment, the eMBB may be a high-speed transmission of high-capacity data, the mMTC may be a terminal power minimization and a connection of a plurality of terminals, and the URLLC may be a service aiming at high reliability and low latency. The above three services may be a major scenario in a LTE system or a system such as 5G / NR (new radio, next radio) after LTE. In the embodiment, coexistence of eMBB and URLLC, coexistence of mMTC and URLLC, and apparatus using the same will be described.

When a base station has scheduled a data corresponding to an eMBB service in a specific transmission time interval (TTI) to a UE, when a situation is required to transmit URLLC data in the TTI, the eMBB data is already scheduled It is possible to transmit the generated URLLC data in the frequency band without transmitting a part of the eMBB data in the frequency band to which the data is transmitted. The UEs scheduled for the eMBB and the UEs scheduled for the URLLC may be the same UE or may be different UEs. In such a case, there is a possibility that eMBB data is damaged because a portion of the eMBB data that has already been scheduled and transmitted is generated. Therefore, in the above case, it is necessary to determine a method of processing a signal received from a terminal that is scheduled for eMBB or a terminal that is scheduled for URLLC and a signal receiving method. Therefore, when the information according to eMBB and URLLC is scheduled, or information according to mMTC and URLLC are scheduled simultaneously, or information according to mMTC and eMBB is scheduled simultaneously, sharing the part or whole frequency band, or The coexistence method between heterogeneous services that can transmit information according to each service when the information according to eMBB, URLLC and mMTC are scheduled simultaneously is described.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification. Hereinafter, the base station may be at least one of an eNode B, a Node B, a base station (BS), a wireless access unit, a base station controller, or a node on a network. The terminal may include a user equipment (UE), a mobile station (MS), a cellular phone, a smart phone, a computer, or a multimedia system capable of performing communication functions. In the present invention, a downlink (DL) is a wireless transmission path of a signal transmitted from a base station to a mobile station, and an uplink (UL) is a wireless transmission path of a signal transmitted from a mobile station to a base station. In the following, embodiments of the present invention will be described as an example of an LTE or LTE-A system, but embodiments of the present invention may be applied to other communication systems having a similar technical background or channel form. For example, 5G mobile communication technology developed after LTE-A (5G, new radio, NR) could be included. In addition, embodiments of the present invention may be applied to other communication systems by a person skilled in the art without departing from the scope of the present invention.

In the LTE system, an OFDM (Orthogonal Frequency Division Multiplexing) scheme is used in a downlink (DL) and a Single Carrier Frequency Division Multiple (SC-FDMA) scheme is used in an uplink Access) method. The uplink refers to a wireless link that transmits data or control signals to a terminal (User Equipment, UE) or a mobile station (MS) to a base station (eNode B or base station (BS) In the above multiple access scheme, time / frequency resources to transmit data or control information for each user are not overlapped with each other, that is, orthogonality So that data or control information of each user can be distinguished.

The LTE system adopts a Hybrid Automatic Repeat reQuest (HARQ) scheme in which a physical layer resends data when a decoding failure occurs in an initial transmission. In the HARQ scheme, if a receiver fails to correctly decode (decode) data, the receiver transmits information indicating a decoding failure (NACK: Negative Acknowledgment) to the transmitter so that the transmitter can retransmit the corresponding data in the physical layer. The receiver combines the data retransmitted by the transmitter with the previously decoded data to improve data reception performance. In addition, when the receiver correctly decodes the data, an acknowledgment (ACK) indicating the decoding success is transmitted to the transmitter so that the transmitter can transmit new data.

FIG. 3A is a diagram illustrating a basic structure of a time-frequency domain, which is a radio resource region in which the data or control channel is transmitted in the downlink in an LTE system or a similar system.

(3a02)개의 OFDM 심벌이 모여 하나의 슬롯(3a06)을 구성하고, 2개의 슬롯이 모여 하나의 서브프레임(3a05)을 구성한다. 상기 슬롯의 길이는 0.5ms이고, 서브프레임의 길이는 1.0ms이다. 그리고 라디오 프레임(3a14)은 10개의 서브프레임으로 구성되는 시간영역구간이다. 주파수영역에서의 최소 전송단위는 서브캐리어(subcarrier)로서, 전체 시스템 전송 대역 (Transmission bandwidth)의 대역폭은 총

(3a04)개의 서브캐리어로 구성된다. 다만 이와 같은 구체적인 수치는 가변적으로 적용될 수 있다. Referring to FIG. 3A, the horizontal axis indicates time domain and the vertical axis indicates frequency domain. The minimum transmission unit in the time domain is an OFDM symbol,

(3a02) OFDM symbols are gathered to form one slot 3a06, and two slots are gathered to constitute one subframe 3a05. The length of the slot is 0.5 ms and the length of the subframe is 1.0 ms. And the radio frame 3a14 is a time domain including 10 subframes. The minimum transmission unit in the frequency domain is a subcarrier, and the bandwidth of the entire system transmission bandwidth is a total

(3a04) subcarriers. However, such specific values can be applied variably.

(3a02)개의 연속된 OFDM 심벌과 주파수 영역에서

(3a10)개의 연속된 서브캐리어로 정의될 수 있다. 따라서, 한 슬롯에서 하나의 RB(3a08)는

개의 RE(3a12)를 포함할 수 있다. 일반적으로 데이터의 주파수 영역 최소 할당단위는 상기 RB. LTE 시스템에서 일반적으로 상기

= 7,

=12 이고,

및

는 시스템 전송 대역의 대역폭에 비례할 수 있다. 단말에게 스케줄링 되는 RB 개수에 비례하여 데이터 레이트가 증가하게 된다. LTE 시스템은 6개의 전송 대역폭을 정의하여 운영할 수 있다. 하향링크와 상향링크를 주파수로 구분하여 운영하는 FDD 시스템의 경우, 하향링크 전송 대역폭과 상향링크 전송 대역폭이 서로 다를 수 있다. 채널 대역폭은 시스템 전송 대역폭에 대응되는 RF 대역폭을 나타낸다. 아래의 표 3a는 LTE 시스템에 정의된 시스템 전송 대역폭과 채널 대역폭 (Channel bandwidth)의 대응관계를 나타낸다. 예를 들어, 10MHz 채널 대역폭을 갖는 LTE 시스템은 전송 대역폭이 50개의 RB로 구성될 수 있다. In a time-frequency domain, a basic unit of a resource can be represented by an OFDM symbol index and a subcarrier index as a resource element (RE). A resource block (RB or Physical Resource Block (PRB)

(3a02) consecutive OFDM symbols in the frequency domain

May be defined as (3a10) consecutive subcarriers. Therefore, one RB 3a08 in one slot

RE < / RTI > In general, the minimum frequency-domain allocation unit of data is the RB. In an LTE system,

= 7,

= 12,

And

Can be proportional to the bandwidth of the system transmission band. The data rate increases in proportion to the number of RBs scheduled to the UE. The LTE system can define and operate six transmission bandwidths. In the case of an FDD system in which the downlink and the uplink are classified by frequency, the downlink transmission bandwidth and the uplink transmission bandwidth may be different from each other. The channel bandwidth represents the RF bandwidth corresponding to the system transmission bandwidth. Table 3a below shows the correspondence between the system transmission bandwidth and the channel bandwidth defined in the LTE system. For example, an LTE system with a 10 MHz channel bandwidth can have a transmission bandwidth of 50 RBs.

[Table 3a]

The downlink control information may be transmitted within the first N OFDM symbols in the subframe. In the embodiment, N = {1, 2, 3} in general. Therefore, the N value can be variably applied to each subframe according to the amount of control information to be transmitted in the current subframe. The transmitted control information may include a control channel transmission period indicator indicating how many OFDM symbols control information is transmitted, scheduling information for downlink data or uplink data, and HARQ ACK / NACK information.

In the LTE system, scheduling information for downlink data or uplink data is transmitted from a base station to a mobile station through downlink control information (DCI). The DCI is defined according to various formats, and it is determined according to each format whether the scheduling information (UL grant) for the uplink data or the scheduling information (DL grant) for the downlink data, whether the size of the control information is compact DCI , Whether to apply spatial multiplexing using multiple antennas, whether or not DCI is used for power control, and the like. For example, DCI format 1, which is scheduling control information (DL grant) for downlink data, may include at least one of the following control information.

- Resource allocation type 0/1 flag: Indicates whether the resource allocation scheme is Type 0 or Type 1. Type 0 allocates resources by resource block group (RBG) by applying bitmap method. In the LTE system, the basic unit of scheduling is an RB represented by time and frequency domain resources, and the RBG is composed of a plurality of RBs and becomes a basic unit of scheduling in the type 0 scheme. Type 1 allows a specific RB to be allocated within the RBG.

- Resource block assignment: Indicates the RB allocated to the data transmission. The resources to be represented are determined according to the system bandwidth and the resource allocation method.

- Modulation and coding scheme (MCS): Indicates the modulation scheme used for data transmission and the size of the transport block, which is the data to be transmitted.

- HARQ process number: Indicates the HARQ process number.

- New data indicator: Indicates whether HARQ is initial transmission or retransmission.

- Redundancy version: Indicates the redundancy version of HARQ.

- Transmit Power Control (TPC) command for PUCCH for Physical Uplink Control CHannel: Indicates a transmission power control command for the uplink control channel PUCCH.

The DCI is a physical downlink control channel (PDCCH) (or control information), or an Enhanced PDCCH (Enhanced PDCCH) (or enhanced control information, hereinafter referred to as " It may be used on a mixed basis).

Generally, the DCI is scrambled with a specific Radio Network Temporary Identifier (RNTI) (or a mobile station identifier) independently of each mobile station, and a cyclic redundancy check (CRC) is added, channel-coded and then composed of independent PDCCHs . In the time domain, the PDCCH is mapped and transmitted during the control channel transmission period. The frequency domain mapping position of the PDCCH is determined by the identifier (ID) of each terminal, and can be transmitted over the entire system transmission band.

The downlink data may be transmitted on a physical downlink shared channel (PDSCH), which is a physical channel for downlink data transmission. PDSCH may be transmitted after the control channel transmission interval, and scheduling information such as a specific mapping position and a modulation scheme in the frequency domain is determined based on the DCI transmitted through the PDCCH.

Through the MCS among the control information constituting the DCI, the BS notifies the MS of the modulation scheme applied to the PDSCH to be transmitted and the transport block size (TBS) to be transmitted. In an embodiment, the MCS may be composed of 5 bits or more or fewer bits. The TBS corresponds to a size before channel coding for error correction is applied to data (transport block, TB) to be transmitted by the base station.

The modulation schemes supported by the LTE system are QPSK (Quadrature Phase Shift Keying), 16QAM (Quadrature Amplitude Modulation), and 64QAM, and the respective modulation order (Qm) corresponds to 2, 4, and 6. That is, 2 bits per symbol for QPSK modulation, 4 bits per symbol for 16QAM modulation, and 6 bits per symbol for 64QAM modulation. In addition, 256QAM or more modulation method can be used according to the system modification.

3B is a diagram illustrating a basic structure of a time-frequency domain, which is a radio resource region in which an uplink data or control channel is transmitted in an LTE-A system.

개의 SC-FDMA 심벌이 모여 하나의 슬롯(3b06)을 구성할 수 있다. 그리고 2개의 슬롯이 모여 하나의 서브프레임(3b05)을 구성한다. 주파수영역에서의 최소 전송단위는 서브캐리어로서, 전체 시스템 전송 대역(transmission bandwidth; 3b04)은 총

개의 서브캐리어로 구성된다.

는 시스템 전송 대역에 비례하는 값을 가질 수 있다. Referring to FIG. 3B, the horizontal axis represents the time domain and the vertical axis represents the frequency domain. The minimum transmission unit in the time domain is the SC-FDMA symbol 3b02,

SC-FDMA symbols can be gathered to form one slot 3b06. Then, two slots form one subframe 3b05. The minimum transmission unit in the frequency domain is the subcarrier, and the total system transmission bandwidth (3b04)

Lt; / RTI > subcarriers.

May have a value proportional to the system transmission band.

개의 연속된 SC-FDMA 심벌과 주파수 영역에서

개의 연속된 서브캐리어로 정의될 수 있다. 따라서, 하나의 RB는

개의 RE로 구성된다. 일반적으로 데이터 혹은 제어정보의 최소 전송단위는 RB 단위이다. PUCCH의 경우 1 RB에 해당하는 주파수 영역에 매핑되어 1 서브프레임 동안 전송된다. The basic unit of resources in the time-frequency domain is a resource element (RE, 3b12), which can be defined as an SC-FDMA symbol index and a subcarrier index. The resource block pair (3b08, RB pair)

Lt; RTI ID = 0.0 > SC-FDMA < / RTI &

Can be defined as consecutive subcarriers. Therefore, one RB

Of REs. In general, the minimum transmission unit of data or control information is RB unit. In case of PUCCH, it is mapped to a frequency region corresponding to 1 RB and transmitted for 1 sub-frame.

In the LTE system, an uplink physical channel PUCCH or PUSCH, to which HARQ ACK / NACK corresponding to a PDCCH / EPDDCH including a physical channel for downlink data transmission or a semi-persistent scheduling release (SPS release) Can be defined. For example, in an LTE system operating in a frequency division duplex (FDD), a HARQ ACK / NACK corresponding to a PDCCH / EPDCCH including PDSCH or SPS release transmitted in an n-4th subframe is transmitted as a PUCCH or a PUSCH Lt; / RTI >

In the LTE system, the downlink HARQ employs an asynchronous HARQ scheme in which the data retransmission time is not fixed. That is, when HARQ NACK is fed back from the UE to the initial transmission data transmitted from the BS, the BS freely determines the transmission time point of the retransmission data by the scheduling operation. The UE may perform buffering on the data determined to be an error as a result of decoding the received data for HARQ operation, and then perform the combining with the next retransmission data.

When the UE receives the PDSCH including the downlink data transmitted from the base station in the subframe n, the UE transmits the uplink control information including the HARQ ACK or NACK of the downlink data to the subframe n + k through the PUCCH or PUSCH, Lt; / RTI > Here, k may be defined differently according to FDD or TDD (time division duplex) of the LTE system and its subframe setting. For example, in the case of the FDD LTE system, the k is fixed at 4. On the other hand, in case of the TDD LTE system, k may be changed according to the subframe setting and the subframe number. Also, the value of k may be differently applied according to the TDD setting of each carrier at the time of data transmission through a plurality of carriers. In the case of the TDD, the k value is determined according to the TDD UL / DL setting as shown in Table 3b below.

[Table 3b]

Unlike the downlink HARQ in the LTE system, the uplink HARQ adopts a synchronous HARQ scheme in which the data transmission time is fixed. That is, a physical uplink shared channel (PUSCH), a downlink control channel (PDCCH), and a physical hybrid (PHICH) physical channel, in which a downlink HARQ ACK / NACK corresponding to the PUSCH is transmitted, Indicator Channel) can be transmitted and received according to the following rule.

When the UE receives the PDCCH including the uplink scheduling control information transmitted from the base station in the subframe n or the PHICH in which the downlink HARQ ACK / NACK is transmitted, the UE transmits uplink data corresponding to the control information in the subframe n + k PUSCH. Here, k may be defined differently according to the FDD or TDD (time division duplex) of the LTE system and its setting. For example, in the case of the FDD LTE system, the k can be fixed to 4. On the other hand, in case of the TDD LTE system, k may be changed according to the subframe setting and the subframe number. Also, the value of k may be differently applied according to the TDD setting of each carrier at the time of data transmission through a plurality of carriers. In the TDD case, the k value is determined according to the TDD UL / DL setting as shown in Table 3c below.

[Table 3c]

The HARQ ACK / NACK information of the PUSCH transmitted by the UE in the subframe n is transmitted through the PHICH from the BS to the MS in the subframe n + k. Here, k may be defined differently depending on the FDD or TDD of the LTE system and its setting. For example, in the case of the FDD LTE system, the k is fixed at 4. On the other hand, in case of the TDD LTE system, k may be changed according to the subframe setting and the subframe number. Also, the value of k may be differently applied according to the TDD setting of each carrier at the time of data transmission through a plurality of carriers. In the case of the TDD, the k value is determined according to the TDD UL / DL setting as shown in Table 3d below.

[Table 3d]

The description of the wireless communication system is based on the LTE system, and the contents of the present invention are not limited to the LTE system but can be applied to various wireless communication systems such as NR and 5G. Also, in a case where the present invention is applied to another wireless communication system, the k value may be changed and applied to a system using a modulation scheme corresponding to the FDD.

FIGS. 3C and 3D show data allocated for eMBB, URLLC, and mMTC, which are services to be considered in a 5G or NR system, in frequency-time resources.

Referring to FIGS. 3C and 3D, it is possible to see how frequency and time resources are allocated for information transmission in each system.

In FIG. 3C, data for eMBB, URLLC, and mMTC are allocated in the entire system frequency band 3c00. When the URLLC data 3c03, 3c05, 3c07 is generated while the eMBB 3c01 and the mMTC 3c09 are allocated and transmitted in a specific frequency band and transmission is required, the eMBB 3c01 and the mMTC 3c09 The URLLC data (3c03, 3c05, 3c07) can be transmitted without transmitting or transmitting the URLLC data (3c03, 3c05, 3c07). Among the above services, since the URLLC needs to reduce the delay time, the URLLC data can be allocated (3c03, 3c05, 3c07) to a part of the resource 3c01 allocated to the eMBB. Of course, when URLLC is further allocated and transmitted in the resource to which the eMBB is allocated, the eMBB data may not be transmitted in the overlapping frequency-time resources, and thus the transmission performance of the eMBB data may be lowered. That is, in the above case, eMBB data transmission failure due to URLLC allocation may occur.

In FIG. 3D, the entire system frequency band 3d00 may be divided and used to transmit services and data in the respective subbands 3d02, 3d04, and 3d06. The information related to the subband setting can be predetermined, and the information can be transmitted to the base station through the upper signaling. Alternatively, information related to the subbands may be provided by the base station or the network node without any separate subband configuration information being transmitted to the terminal. In FIG. 3D, subband 3d02 is used for eMBB data transmission, subband 404 is used for URLLC data transmission, and subband 3d06 is used for mMTC data transmission.

The length of the transmission time interval (TTI) used in the URLLC transmission in the first embodiment may be shorter than the TTI length used in the eMBB or mMTC transmission. Also, the response of the information related to the URLLC can be transmitted faster than the eMBB or mMTC, so that information can be transmitted and received with a low delay.

3E is a diagram illustrating a process in which one transport block is divided into a plurality of code blocks and a CRC is added.

Referring to FIG. 3E, a CRC (3e03) may be added to the last or first part of one transport block (3e01) to be transmitted in the uplink or the downlink. The CRC may have 16 bits or 24 bits or a predetermined number of bits or a variable number of bits depending on a channel condition or the like and may be used to determine whether channel coding is successful or not. The blocks (3e01, 3e03) to which TB and CRC are added can be divided into code blocks (3e07, 3e09, 3e11, 3e13) (3e05). In this case, the last code block 3e13 may be smaller than other code blocks, or may be set to 0, a random value or 1 to equalize the length with other code blocks. You can tailor it. CRCs 3e17, 3e19, 3e21, and 3e23 may be added to the divided code blocks, respectively (3e15). The CRC may have 16 bits or 24 bits, or a predetermined number of bits, and may be used to determine whether channel coding is successful. However, the CRC (3e03) added to the TB and the CRCs (3e17, 3e19, 3e21, 3e23) added to the code block may be omitted depending on the kind of the channel code to be applied to the code block. For example, when an LDPC code, not a turbo code, is applied to a code block, the CRCs 3e17, 3e19, 3e21, and 3e23 to be inserted for each code block may be omitted. However, even when the LDPC is applied, the CRCs 3e17, 3e19, 3e21, and 3e23 can be directly added to the code block. Also, CRC can be added or omitted even when polar codes are used.

FIG. 3F is a diagram illustrating a manner in which an outer code is used and transmitted. FIG. 3G is a block diagram illustrating a structure of a communication system in which the outer code is used.

Referring to FIGS. 3F and 3G, a method of transmitting a signal using an outer code can be described.

In FIG. 3F, one transport block is divided into a plurality of code blocks, and bits or symbols 3f04 at the same position in each code block are encoded with a second channel code to generate parity bits or symbols 3f06 (3f02). Thereafter, CRCs may be added to the respective code blocks and the parity code blocks generated by the second channel code encoding, respectively (3f08, 3f10). The addition of the CRC may vary depending on the type of the channel code. For example, when the turbo code is used as the first channel code, the CRCs (3f08, 3f10) are added, but then the respective code blocks and parity code blocks can be encoded by the first channel code encoding.

When the outer code is used, the data to be transmitted passes through the second channel coding encoder 3g09. The channel code used for the second channel coding may be, for example, a Reed-Solomon code, a BCH code, a Raptor code, a parity bit generation code, or the like. The bits or symbols thus passed through the second channel coding encoder 3g09 pass through the first channel coding encoder 3g11. The channel code used for the first channel coding includes a convolutional code, an LDPC code, a turbo code, and a polar code. When the channel coded symbols are received by the receiver through the channel 3g13, the receiver side can sequentially operate the first channel coding decoder 3g15 and the second channel coding decoder 3g17 based on the received signal . The first channel coding decoder 3g15 and the second channel coding decoder 3g17 may perform operations corresponding to the first channel coding encoder 3g11 and the second channel coding encoder 3g09, respectively.

On the other hand, in the channel coding block diagram in which no outer code is used, only the first channel coding encoder 3g11 and the first channel coding decoder 3g05 are used in the transceiver, and the second channel coding encoder and the second channel coding decoder are not used Do not. Even when the outer code is not used, the first channel coding encoder 3g11 and the first channel coding decoder 3g05 may be configured in the same way as the outer code is used.

The eMBB service described below will be referred to as a first type service and the eMBB data will be referred to as first type data. The first type service or the first type data is not limited to the eMBB, but may be applied to a case where high-speed data transmission is required or a broadband transmission is performed. The URLLC service is referred to as a second type service, and the URLLC data is referred to as second type data. The second type service or second type data is not limited to URLLC, but may be applicable to other systems requiring a low delay time, requiring high reliability transmission, or requiring low latency and high reliability at the same time. The mMTC service is called a third type service, and the mMTC data is called a third type data. The third type service or the third type data is not limited to mMTC but may be applied to a case where a low speed, wide coverage, or low power is required. Also, in describing the embodiment, it can be understood that the first type service includes or does not include the third type service.

The structure of the physical layer channel used for each type may be different in order to transmit the three services or data. For example, at least one of a transmission time interval (TTI) length, a frequency resource allocation unit, a control channel structure, and a data mapping method may be different.

Although three services and three pieces of data have been described above, there are more kinds of services and corresponding data. In this case, the contents of the present invention can be applied.

The terms physical channel and signal in a conventional LTE or LTE-A system may be used to describe the method and apparatus proposed in the embodiment. However, the present invention can be applied to wireless communication systems other than LTE and LTE-A systems.

As described above, the embodiment defines transmission and reception operations of a first type, a second type, a third type service, and a terminal and a base station for data transmission, and transmits terminals having different types of services or data scheduling to the same system We suggest a concrete method to operate together. In the present invention, the first type, the second type and the third type terminals are respectively referred to as terminals of type 1, type 2, type 3, or data scheduling. In an embodiment, the first type terminal, the second type terminal and the third type terminal may be the same terminal or may be different terminals.

Hereinafter, at least one of the PHICH, the uplink scheduling grant signal and the downlink data signal is referred to as a first signal. Also, in the present invention, at least one of an uplink data signal for uplink scheduling grant and an HARQ ACK / NACK for a downlink data signal is referred to as a second signal. In an exemplary embodiment, a signal transmitted from a base station to a mobile station may be a first signal if it is a signal expecting a response from the mobile station, and a response signal from a mobile station corresponding to the first signal may be a second signal. Also, in the embodiment, the service type of the first signal may be at least one of eMBB, URLLC, and mMTC, and the second signal may also correspond to at least one of the services. For example, in LTE and LTE-A systems, PUCCH format 0 or 4 and PHICH may be the first signal, and the corresponding second signal may be PUSCH. For example, in the LTE and LTE-A systems, the PDSCH may be the first signal, and the PUCCH or PUSCH including the HARQ ACK / NACK information of the PDSCH may be the second signal.

In the following embodiments, the TTI length of the first signal may indicate the length of time during which the first signal is transmitted with a time value related to the first signal transmission. Also, in the present invention, the TTI length of the second signal may indicate the length of time that the second signal is transmitted with a time value related to the second signal transmission, and the TTI length of the third signal may be shorter than the time related to the third signal transmission Value may represent the length of time the third signal is transmitted. In the present invention, the second signal transmission timing is information on when the terminal transmits the second signal and when the base station receives the second signal, and may be referred to as a second signal transmission / reception timing.

Further, in the following embodiments, when the base station transmits the first signal in the n < th > TTI, it is assumed that the terminal transmits the second signal in the (n + k) th TTI. It is like telling k value. Assuming that the base station transmits the first signal in the n-th TTI and the terminal transmits the second signal in the n + 4 + a-th TTI, when the base station informs the terminal of the timing to transmit the second signal, It is like telling the value a. An offset can be defined by various methods such as n + 3 + a and n + 5 + a in place of the n + 4 + a. Hereinafter, the n + 4 + It can be defined.

Although the contents of the present invention are described on the basis of the FDD LTE system, the present invention is also applicable to the TDD system and the NR system.

In the present invention, upper signaling is a signal transmission method that is transmitted from a base station to a mobile station using a downlink data channel of a physical layer or from a mobile station to a base station using an uplink data channel of a physical layer, and includes RRC signaling or PDCP signaling , Or a MAC control element (MAC CE).

In the present invention, a method of determining the timing of transmitting the second signal after the terminal or the base station receives the first signal has been described. However, the method of sending the second signal can be performed by various methods. For example, after receiving the PDSCH, which is the downlink data, the timing of sending the HARQ ACK / NACK information corresponding to the PDSCH to the BS follows the method of the present invention. However, the timing of selecting the PUCCH format, And a method of mapping HARQ ACK / NACK information to the PUSCH can be performed according to the conventional LTE method.

In the present invention, a normal mode refers to a mode using a first signal and a second signal transmission timing used in the conventional LTE and LTE-A systems. In the normal mode, a signal of about 3 ms It is possible to secure processing time. For example, in the FDD LTE system operating in the normal mode, the transmission of the second signal to the first signal received by the terminal in the subframe n is transmitted by the terminal in the subframe n + 4.

Meanwhile, in the present invention, the latency reduction mode is a mode that enables the transmission timing of the second signal for the first signal to be faster or equal to that of the normal mode, and can reduce the delay time. In the delay reduction mode, the timing can be controlled in various ways.

The present invention will be described based on the case where the transmission time intervals (TTI) used in the normal mode and the delay reduction mode are the same. However, the present invention can be applied to a case where the length of the TTI in the normal mode is different from the length of the TTI in the delay reduction mode.

[Example 3-1]

The embodiment 3-1 discloses a method in which a base station informs a mobile station that it operates in a delay reduction mode through a higher signaling and accordingly a mobile station determines a second signal transmission and resource and power control timing according to the setting of upper signaling Will be described with reference to FIG. 3H.

The base station sets the delay reduction mode to the mobile station by higher signaling (3h02). The higher signaling may be an RRC signaling or may be set via a MAC control element. The base station may transmit the transmission timing information of the second signal corresponding to the first signal to the terminal in the higher signaling (3h04). Thereafter, the terminal transmits a second signal at a predetermined timing, and the base station receives and decodes the second signal at the second signal transmission timing of the terminal (3h06). Assuming that the terminal transmits the second signal in the n + k-th TTI when the base station transmits the first signal in the n-th TTI, as described above, the timing at which the base station transmits the second signal to the terminal Telling k is like telling k value. Assuming that the base station transmits the first signal in the n-th TTI and the terminal transmits the second signal in the n + 4 + a-th TTI, when the base station informs the terminal of the timing to transmit the second signal, It is like telling the value a. An offset can be defined by various methods such as n + 3 + a, n + 5 + a instead of n + 4 + a.

The terminal receives the k value or the offset value a for the second signal transmission timing from the base station through higher signaling (3h04). Thereafter, when the UE receives the first signal in the n-th TTI, it transmits the corresponding second signal to the base station in the n + k-th TTI or the n + 4 + a-th TTI (3h06).

When the base station determines the k value or the offset value a for the second signal transmission timing, the terminal may determine the value based on the terminal capability indicating the base station.

The k or the offset a notified by the upper signaling may be a set of several values rather than one value. The UE can use the k value transmitted in the upper signaling or one of the sets of the offset a to determine the second signal transmission timing. A method of selecting one value from the set may be selected according to a specific bit of the control information DCI transmitted together with the first signal from the base station, or the terminal may arbitrarily select the value.

In addition, it is also possible to transmit a set of k values or offsets a according to a specific TDD UL / DL setting and a TTI index value in consideration of the TDD system.

For example, if the upper delay signal for setting the delay reduction mode and transmitting the parameter to the MAC Control Element (MAC CE) is transmitted, the Node B and the UE will know when the upper signaling is applied. Therefore, if the base station sets the delay reduction mode as a MAC control element in the subframe n, for example, it may be possible to apply the delay reduction mode from the subframe n + 6.

[Example 3-2]

3-2 is a flowchart illustrating a method of determining a timing at which a base station transmits a second signal from a terminal or a timing at which power control starts at a downlink control information (DCI) to provide.

The base station sets the delay reduction mode to the upper signaling (3i01). The base station determines the timing at which the terminal transmits the second signal, and transmits the timing using the specific x bits in the DCI transmitted when the first signal is transmitted to the terminal (3i05). The number of bits x can be set to 1, 2, or 3. The transmission timing indicated by the x bits of information may be preallocated in the upper signaling setting (3i03). The base station receives and decodes the second signal at the determined second signal transmission timing.

After decoding the downlink control signal, the terminal checks a specific x bit in the DCI and finds the k value or the offset value a for the second signal transmission timing from the specified x bit value. When the UE receives the first signal in the n-th TTI, it transmits the corresponding second signal to the base station in the n + k-th TTI or the n + 4 + a-th TTI (3i05, 3i07).

For example, when x is 2, that is, when 2 bits of the DCI are information for the second signal transmission timing, the value k for the second signal transmission timing can be indicated as follows.

Alternatively, the offset value a for the second signal transmission timing may be informed as follows.

When the base station determines the k value or the offset value a for the second signal transmission timing, the terminal may determine the value based on the terminal capability indicating the base station.

[Example 3-3]

The third to third embodiments of the present invention will be described with reference to FIG. 3J, in which HARQ ACK / NACK information for downlink data transmitted in a plurality of TTIs is transmitted from one TTI to the uplink according to HARQ timing.

In a situation where downlink data is delivered to a UE with a delay reduction mode set to (3j02) as in (3-1) or (3-2), a downlink corresponding to a HARQ ACK / NACK to be transmitted to a base station in a specific TTIn It is possible to differently transmit the uplink control signal when the number of link data is one or a plurality of link data. For example, when using the delay reduction mode in the LTE system, when the number of PDSCHs corresponding to the HARQ ACK / NACK to be transmitted in the subframe n is one, the PUCCH format 1a or the format 1b is used and two or more PDSCHs When HARQ ACK / NACK is transmitted, it may be changed depending on whether HARQ-ACK bundling or HARQ-ACK multiplexing is set. The HARQ-ACK bundling and multiplexing setting or the PUCCH format selection may be set from the base station to the UE as higher signaling (3j04).

If HARQ-ACK bundling is set when transmitting HARQ ACK / NACK corresponding to two or more PDSCHs, ACK is set only when all the codewords of the two PDSCHs are ACKs, and NACK is set in other cases, And generates two HARQ ACK / NACK information. The generated HARQ ACK / NACK information may be transmitted using the PUCCH format 1a or 1b. For example, if the PDSCHs transmitted in two or more subframes contain only one codeword, the HARQ ACK / NACK information generated through HARQ-ACK bundling will be one bit, . Also, for example, if PDSCHs transmitted in two or more TTIs contain only two codewords in a PDSCH, the HARQ ACK / NACK information generated through HARQ-ACK bundling will be two bits, PUCCH format 1b.

와 PUCCH 포맷 1b에 사용되는 2비트 b(0) 및 b(1)이 결정될 수 있다. 상기 i는 0 또는 1 또는 2 또는 3인 정수가 될 수 있다. 상기 단말이 보내야하는 HARQ ACK 정보 비트수는 본 발명의 제3-4실시예 등에서 설명하는 방법과 같이 DCI 등에서, 예를 들어 DAI 값으로, 전달될 수 있을 것이다 (3j06). If HARQ-ACK multiplexing is set when transmitting HARQ ACK / NACK corresponding to two or more PDSCHs, ACK information is generated only for ACKs for all codewords in each PDSCH, and NACK is generated in other cases. Therefore, for example, when the PDSCH transmitted in the maximum M TTIs is considered, M-bit HARQ ACK / NACK information is generated. The generated M bits of HARQ ACK / NACK information may be transmitted to the base station using the PUCCH format 1b with channel selection method or PUCCH format 3. [ The PUCCH format 1b and the channel selection are performed in the same manner as Tables 3e to 3j, using the PUCCH transmission resources

And 2 bits b (0) and b (1) used in the PUCCH format 1b can be determined. I may be 0 or an integer of 1, 2, or 3. The number of HARQ ACK information bits to be transmitted by the UE may be transmitted in a DCI or the like, for example, as a DAI value as described in the third to fourth embodiments of the present invention (3j06).

[Table 3e] PUCCH format with M = 2 1b with channel selection method

[Table 3f] PUCCH format with M = 3 1b with channel selection method

[Table 3g] PUCCH format with M = 4 1b with channel selection method

[Table 3h] PUCCH format with M = 2 1b with channel selection method

[Table 3i] PUCCH format when M = 3 1b with channel selection method

[Table 3j] PUCCH format with M = 4 1b with channel selection method

를 결정하는 방법은 다양한 방법으로 가능할 것이다. 예를 들어, TTI n에 전송될 PUCCH는 n-1, n-2, n-3, n-4 TTI에서 전송된 PDSCH의 HARQ-ACK을 포함해야 한다면, M=4가 될 것이며, k1=4, k2=3, k3=2, k4=1이라고 하기로 하자.

는 TTI n-ki에서 전송된 PDSCH의 제어채널이 매핑된 첫번째 CCE의 번호이다.

라고 할 때, c는 0, 1, 2, 3 중에서

를 만족하는 수이다. 이 때, PUCCH 자원

은 하기와 같이 정해질 수 있다.In the above,

Can be determined in various ways. For example, if the PUCCH to be transmitted in TTI n should include HARQ-ACK of the PDSCH transmitted in n-1, n-2, n-3 and n-4 TTI, M = 4 and k1 = 4 , k2 = 3, k3 = 2, and k4 = 1.

Is the number of the first CCE to which the control channel of the PDSCH transmitted in the TTI n-ki is mapped.

, C is 0, 1, 2, or 3

Lt; / RTI > At this time, the PUCCH resource

Can be determined as follows.

는 상위 시그널링으로 단말에게 설정될 수 있다. In the above,

May be set to the terminal by higher signaling.

In the above example, a PUCCH format 1a, 1b or 1b with channel selection method is described for transmitting HARQ ACK / NACK information for downlink data transmitted in a plurality of TTIs in one TTI in an uplink. 4 or 5 will be described. When transmitting the uplink PUCCH or PUSCH, the UE determines the number of HARQ ACK information to be transmitted. The determination may be based on the DAI value transmitted from the control information in the previous downlink data transmission or PUSCH scheduling. Assuming that the HARQ ACK / NACK information is configured from the HARQ-ACK information of the PDSCH first transmitted to the HARQ-ACK information of the most recently transmitted PDSCK, it is assumed that the number of HARQ ACK / NACK bits is determined from the DAI value And can transmit the information using PUCCH format 3 or 4 or 5. Using the PUCCH format 3 or 4 or 5 may be set to upper signaling to the UE in delay decrease mode (3j04). Also, the PUCCH format 3, 4, or 5 may be one defined in the conventional LTE-A or LTE-A pro. When the HARQ ACK / NACK information is configured from the HARQ-ACK information of the PDSCH first transmitted to the HARQ-ACK information of the most recently transmitted PDSCK, if HARQ-ACK bundling is set, the codewords of the PDSCH It can be set to ACK only when all are ACK.

[Example 3-4]

In the third to fourth embodiments, a method of setting a downlink assignment index (DAI) value for allowing a base station and a mobile station to know the amount of HARQ ACK / NACK information to be transmitted by a delay decreasing mode terminal is equal to each other.

값으로 상기 제어정보에 포함하여 단말에게 전송한다. When transmitting control information for uplink scheduling such as DCI format 0 or 4 for uplink scheduling to the UE, the Node B calculates the amount of HARQ ACK / NACK information to be transmitted at the same time when the uplink transmission is performed

And transmits the control information to the terminal.

값을 상기 제어정보에 포함하여 단말에게 전송한다. 일례로 TTI n에서 HARQ ACK/NACK을 전송해야하는 PDSCH가 처음 전송하는 경우의 제어신호에서는 1에 해당하는

값을 포함하는 것이 가능하며, TTI n에서 HARQ ACK/NACK을 전송해야하는 PDSCH가 두 번째에 해당하는 경우의 제어신호에서는 2에 해당하는

값을 포함하는 것이 가능할 것이다. In addition, when the BS transmits control information for downlink data transmission, the BS transmits to the serving cell c the number of HARQ ACK / NACK to be transmitted by the UE in the serving cell c,

And transmits the control information to the terminal. For example, in a control signal when a PDSCH to transmit HARQ ACK / NACK is first transmitted in TTI n,

, And in the control signal when the PDSCH to transmit the HARQ ACK / NACK in the TTI n corresponds to the second time,

It will be possible to include a value.

값과

값이 가리키는 하향링크 데이터 전송의 수는 하기 표와 같이 정해질 수 있다. 상기 표와 같이 정해지는 값은 하나의 일례일 뿐이며, 2비트 이상의

값과

값에 대해서도 쉬운 변형으로 적용하는 것이 가능할 것이다. 예를 들어, DAI 정보를 위해 DCI에서 2비트가 아닌 3비트 혹은 4비트를 사용하는 것도 가능할 수 있을 것이다.remind

Value and

The number of downlink data transfers indicated by the value can be determined as shown in the following table. The values determined as shown in the above table are only one example,

Value and

It will be possible to apply an easy variation to the value. For example, it may be possible to use 3 bits or 4 bits instead of 2 bits in DCI for DAI information.

[Example 3-5]

The third to fifth embodiments will be described with reference to FIG. 3K by way of a method for determining the timing at which the second signal is transmitted from the terminal to the base station using the absolute value of the TA of the terminal set in the delay reduction mode.

The BS sets the delay reduction mode for the MS (3k02) and calculates the absolute value of the TA for the MS (3k04). The BS can calculate the absolute value of the TA by adding or subtracting the variation of the TA value that has been transmitted to the first TA from the first signaling in the random access phase. The terminal can calculate the absolute value of TA similarly to the method of the base station. Alternatively, the terminal can calculate the absolute value of TA by subtracting the start time of the n-th TTI received by the terminal from the start time of the n-th TTI to be transmitted. In the present invention, the absolute value of TA may be referred to as NTA.

As described above, the Node B and the UE can know the NTA and can connect the NTA to the second signal transmission timing using an arbitrary mapping. Therefore, the base station and the terminal can determine the second signal transmission timing using the NTA (3k06) using the mapping relationship, and the terminal transmits the second signal at the second signal transmission timing (3k08) Can receive and decode (3k08) the transmitted second signal. For example, the NTA and the second signal transmission timing k can be found by the method shown in Table 3 below.

[Table 3k]

In Equation 3, the equality of inequality may be excluded or added, and x and y, which are k values according to NTA, can be set to the UE by the base station in the delay reduction mode setting or x is fixed to 4 and y is 2 or 3 Or may be different depending on the setting. The above example is merely an example, and the k value according to the NTA value may be determined by various methods. It is obvious that the offset a can be determined instead of the k value for informing the second signal transmission timing. It may also be based on the absolute time length instead of the standard NTA. Also, it is possible to easily determine that the value of k or a is changed according to the amount of change of the TA value for a predetermined time instead of using the NTA as a reference.

[Example 3-6]

The third to sixth embodiments describe a delay reduction mode and a method of operating a terminal in which a CA is set to one or more carriers.

A UE with a delay reduction mode and a CA with one or more carriers or a UE with a delay reduction mode performs blind decoding of PDCCH or EPDCCH only in the primary cell. Or in the delay reduction mode, HARQ ACK / NACK information of the PDSCH transmitted in the subframe n is transmitted in the subframe n + 2, the UE may restrict the blind decoding of the PDCCH or the EPDCCH to be performed only in the primary cell have.

In order to perform the above-described embodiments of the present invention, the transmitter, the receiver and the processor of the terminal and the base station are shown in Figs. 3I and 3M, respectively. In order to determine the transmission and reception timing of the second signal and the terminal transmission power from the above-mentioned 3-1 to 3-6 embodiments, the transmission and reception method of the base station and the terminal are shown in order to perform the operation. And the receiving unit, the processing unit, and the transmitting unit of the terminal must operate according to the embodiment, respectively.

Specifically, FIG. 31 is a block diagram illustrating an internal structure of a terminal according to an embodiment of the present invention. As shown in FIG. 31, the terminal of the present invention may include a terminal receiving unit 3100, a terminal transmitting unit 3100, and a terminal processing unit 3120. The terminal receiving unit 3100 and the terminal may be collectively referred to as a transmitting unit 3100 in the embodiment of the present invention. The transmitting and receiving unit can transmit and receive signals to and from the base station. The signal may include control information and data. To this end, the transmitting and receiving unit may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, an RF receiver for low-noise amplifying the received signal and down-converting the frequency. The transceiving unit may receive a signal through a wireless channel, output the signal to the terminal processing unit 3120, and transmit the signal output from the terminal processing unit 3120 through a wireless channel. The terminal processing unit 3102 can control a series of processes so that the terminal can operate according to the embodiment of the present invention described above. For example, the terminal receiving unit 3100 may receive a signal including the second signal transmission timing information from the base station, and the terminal processing unit 3120 may control to interpret the second signal transmission timing. After that, the terminal transmitting unit 31 04 transmits the second signal at the above timing.

3M is a block diagram illustrating an internal structure of a base station according to an embodiment of the present invention. As shown in FIG. 3M, the base station of the present invention may include a base station receiving unit 3m01, a base station transmitting unit 3m05, and a base station processing unit 3m03. The base station receiving unit 3m01 and the base station transmitting unit 3m05 may collectively be referred to as a transmitting and receiving unit in the embodiment of the present invention. The transmitting and receiving unit can transmit and receive signals to and from the terminal. The signal may include control information and data. To this end, the transmitting and receiving unit may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, an RF receiver for low-noise amplifying the received signal and down-converting the frequency. In addition, the transceiving unit may receive a signal through a wireless channel, output the signal to the base station processing unit 3m03, and transmit the signal output from the terminal processing unit 3m03 through a wireless channel. The base station processor 3m03 may control a series of processes so that the base station can operate according to the above-described embodiment of the present invention. For example, the base station processing unit 3m03 may determine the second signal transmission timing and control to generate the second signal transmission timing information to be transmitted to the terminal. Then, the base station transmitting unit 3m05 transmits the timing information to the terminal, and the base station receiving unit 3m01 receives the second signal at the timing.

Also, according to an embodiment of the present invention, the base station processor 3m03 may control to generate downlink control information (DCI) including the second signal transmission timing information. In this case, the DCI may indicate the second signal transmission timing information.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate the understanding of the present invention and are not intended to limit the scope of the present invention. That is, it will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible. Further, each of the above embodiments can be combined with each other as needed. For example, the base station and the terminal can be operated by combining the embodiments 3-1, 3-2, and 3-3 of the present invention with each other. Also, although the above embodiments are presented on the basis of the LTE / LTE-A system, other systems based on the technical idea of the above embodiment may be applicable to other systems such as 5G and NR systems.

<Fourth Embodiment>

Background Art [0002] Conventional wireless communication systems have evolved mainly to improve transmission speed and transmission efficiency. In contrast, the 5G mobile communication requirements proposed by the ITU-R include not only enhanced Mobile Broadband (eMBB), which requires a high transmission rate, but also Ultra Reliability and Low Latency (URLLC) Communication and Massive Machine Type Communication (mMTC), a service that requires a high connection density. To this end, various technologies such as signal transmission technology using a new waveform, non-orthogonal multiple access technology, and large-scale multi-antenna technology using a very high frequency band are being discussed.

4A is a diagram illustrating an example in which three services of 5G, i.e., eMBBs 4a-01, URLLCs 4a-02, and mMTCs 4a-03 are multiplexed and transmitted in one system.

5G is aiming at a single wireless access technology that accommodates all three defined service scenarios, thus making it a philosophy to build a flexible system that is different from the conventional one. For example, in order to satisfy different frequency bands and requirements, scalability can be given to numerology such as a subcarrier interval when an OFDM signal is generated, and services can be simultaneously performed. Alternatively, you can tailor the latency and requirements to suit each service by tailoring the TTI to your situation. In FIG. 4A, the eMBB 4a-01, the URLLC 4a-02, and the mMTC 4a-03 are set to different TTIs 4a-04, respectively. Also, considering compatibility in the future, it is aimed to design so that there will be no restriction that the service to be designed later is limited by the current system. In order to construct such a flexible system, a technical approach to 5G is required in order to maximally exclude various always-on signals existing in the conventional LTE or fixed signals transmitted over the entire system band.

In the LTE, the PDCCH, which is one of the physical channels for transmitting the downlink control signal, i.e., DCI (Downlink Control Information), is transmitted every subframe over the entire system band. A CRS (Cell-Specific Reference Signal) is used as a reference signal for decoding the PDCCH. CRS is a typical always-on signal transmitted regardless of existence of downlink traffic. In other words, since the structure of the PDCCH currently used in LTE can not be flexibly set, if the existing PDCCH is directly used in the 5G system, it will be difficult to support various services according to requirements or secure compatibility in the future.

The downlink control channel existing in the LTE will be described in more detail. 4B is a diagram illustrating a PDCCH (4b-01) and an EPDCCH (Enhanced PDCCH, 4b-02) which are downlink physical channels through which the DCI of the LTE is transmitted. According to Fig. 4B, the PDCCH 4b-01 is time-multiplexed with the PDSCH 4b-03, which is a data transmission channel, and is transmitted over the entire system bandwidth. The area of the PDCCH 4b-01 is represented by the number of OFDM symbols, which is indicated to the UE by the CFI transmitted through the Physical Control Format Indicator Channel (PCFICH). PDCCH (4b-01) to an OFDM symbol that is located in a front part of a subframe, the UE can decode the downlink scheduling assignment as soon as possible, and thereby, a decoding delay for a DL-SCH (Downlink Shared Channel) There is an advantage that the overall downlink transmission delay can be reduced.

The DCI transmitted on the PDCCH (4b-01) includes the following.

- Downlink scheduling assignment: PDSCH resource assignment, transmission format, HARQ information, spatial multiplexing control information

- Uplink scheduling grant: PUSCH resource assignment, transmission format, HARQ information, PUSCH power control

- Power control command for terminal set

Different control information typically have different DCI message sizes, which are classified in different DCI formats. DCI format, the downlink scheduling assignment information is transmitted in DCI format 1 / 1A / 1B / 1C / 1D / 2 / 2A / 2B / 2C and the uplink scheduling grant is transmitted in DCI format 0/4 And the power control command is transmitted in DCI format 3 / 3A. One PDCCH (4b-01) carries one message having one form of DCI format. Generally, since a plurality of UEs are simultaneously scheduled on the downlink and uplink, each scheduling message is transmitted on each PDCCH (4b-01), so that a plurality of PDCCHs (4b-01) are simultaneously transmitted.

A CRC (Cyclic Redundancy Check) is attached to the DCI message payload, and the CRC is scrambled into a Radio Network Temporary Identifier (RNTI) corresponding to the identity of the UE. Different RNTIs are used depending on the purpose of the DCI message, e.g., UE-specific data transmission, power control command or random access response. Soon, the RNTI is not explicitly transmitted but is included in the CRC computation and transmitted. Upon receiving the DCI message transmitted on the PDCCH, the UE checks the CRC using the allocated RNTI, and if the CRC check result is correct, the UE can know that the corresponding message is transmitted to the UE.

The resource allocation of the PDCCH 4b-01 is based on a CCE (Control-Channel Element), and one CCE is composed of nine RE (Resource Element Groups), that is, a total of 36 Resource Elements (REs). The number of CCEs required for a particular PDCCH (4b-01) may be 1, 2, 4, or 8, depending on the channel coding rate of the DCI message payload. Thus, different CCE numbers are used to implement the link adaptation of the PDCCH (4b-01). The UE must detect a signal without knowing information about the PDCCH (4b-01). In LTE, a search space representing a set of CCEs for blind decoding is defined. The search space is composed of a plurality of aggregates at the aggregation level of each CCE, which is not explicitly signaled but implicitly defined by function and subframe number by the terminal identity. In each subframe, the UE performs decoding on all possible PDCCHs (4b-01) that can be generated from the CCEs in the set search space, and processes the information declared valid to the UE through the CRC check. The search space is classified into a UE-specific search space and a common search space. The UEs of a certain group or all the UEs can check the common search space of the PDCCH 4b-01 to receive control information common to cells such as dynamic scheduling or paging message for the system information. For example, the scheduling assignment information of the DL-SCH for transmission of the SIB (system information block) -1 including the cell operator information can be received by checking the common search space of the PDCCH 4b-01. Because system messages typically must reach the edge of the cell, the common search space is defined only for DCI formats such as aggregation levels of 4 and 8, and the smallest 0 / 1A / 3 / 3A / 1C of the DCI format.

As described above, CRS (4b-04) is used as a reference signal for decoding the PDCCH (4b-01). The CRS 4b-04 is transmitted every subframe over the entire band, and the scrambling and resource mapping are changed according to the cell ID (Identity). The multi-antenna transmission scheme for PDCCH (4b-01) is limited to open-loop transmit diversity.

Various technologies such as Carrier Aggregation (CA) and Coordinated MultiPoint (CoMP) are supported in the conventional LTE, and it is difficult to secure a sufficient transmission capacity for transmitting the downlink control signal only with the PDCCH (4b-01) . In LTE Release 11, EPDCCH (4b-02) is added as a physical channel for transmitting downlink DCI. EPDCCH (4b-02) is designed to meet the following requirements.

- Increase control channel transmission capacity

- Frequency axis adjacent cell interference control

- frequency-selective scheduling

- MBSFN sub-frame support

- Coexistence with existing LTE terminal

As shown in FIG. 4B, the EPDCCH (4b-02) is frequency-multiplexed with the PDSCH (4b-03) and transmitted. The base station can appropriately allocate the resources of the EPDCCH (4b-02) and the PDSCH (4b-03) through the scheduling, thereby effectively supporting the coexistence with the data transmission for the existing LTE terminal. However, since the EPDCCH (4b-02) is allocated and transmitted over one subframe in the time domain, there is a problem in terms of transmission delay time. A plurality of EPDCCHs 4b-02 constitute one EPDCCH (4b-02) set and EPDCCH (4b-02) sets are allocated to a PRB (physical resource block) pair. The location information for the EPDCCH set is set UE-specific and is signaled via RRC (Remote Radio Control). A maximum of two EPDCCH (4b-02) sets can be set for each UE, and one EPDCCH (4b-02) set can be simultaneously multiplexed to different UEs.

The resource allocation of EPDCCH (4b-02) is based on ECCE (Enhanced CCE), one ECCE can be composed of four or eight EREGs (Enhanced REG) It depends on the setup information. One EREG is composed of 9 REs, so there can be 16 EREGs per PRB pair. The EPDCCH transmission scheme is classified into localized / distributed transmission according to the RE mapping scheme of EREG. The aggregation level of the ECCE can be 1, 2, 4, 8, 16, 32, which is determined by the CP length, subframe setting, EPDCCH format and transmission mode.

EPDCCH (4b-02) supports only the UE-specific search space. Therefore, the UE desiring to receive the system message must examine the common search space on the existing PDCCH (4b-01). DMRS (Demodulation Reference Signal, 4b-05) is used as a reference signal for decoding the EPDCCH (4b-02). EPDCCH (4b-02) supports transmission using up to four antenna ports. Because the DMRS 4b-05 is used, precoding for the EPDCCH (4b-02) can be set by the base station, and the terminals can perform decoding on the EPDCCH (4b-02) without knowing what precoding is used have.

The downlink control channel in the existing LTE has been described above. In 5G, the downlink control channel should be designed differently from the downlink control channel in LTE. As described above, the 5G control channel shall meet the following requirements.

- Meets requirements of eMBB, URLLC, mMTC

- Supports multiple TTIs at the same time

Support simultaneous service of different numerology

- Ensure future compatibility

The above requirements are difficult to satisfy with the existing control channel structure. For example, PDCCH is not suitable for mMTC which mainly supports narrow band because it is transmitted in full band. Since EPDCCH is transmitted during one subframe, it is not suitable for URLLC requiring very low latency. In order to support various numerology and TTI, and to ensure future compatibility, it is necessary to flexibly allocate control channels in time and frequency domains. However, it is difficult to flexibly allocate existing PDCCHs and EPDCCHs. Therefore, it is essential to design a new structure of control channel for 5G.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

The embodiments of the present invention will be described in detail with reference to LTE and 5G systems. However, the present invention is also applicable to other communication systems having a similar technical background and channel form. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

First, a description will be made of a fourth embodiment of the downlink control channel structure proposed in the present invention.

[Example 4-1]

4C is a diagram illustrating an example of preferred basic units of time and frequency resources constituting the downlink control channel proposed in the present invention. Referring to FIG. 4C, the basic unit of the time and frequency resources constituting the control channel is composed of one OFDM symbol 4c-01 in the time axis and one FU (Frequency Unit) 4c-02 in the frequency axis Consists of. At this time, 1 FU is defined as a basic unit of frequency resource for performing scheduling from the base station to the mobile station. The downlink control channel to be provided in the present invention can be flexibly allocated according to the requirements of the services requested by the respective terminals. By connecting the basic units of the control channel shown in FIG. 4C, control channel regions of various sizes can be set. The data channel and the control channel can be time multiplexed within one subframe by assuming that the basic unit of time axis is one OFDM symbol in constituting the basic unit of the control channel. By placing the control channel ahead of the data channel, the processing time of the user can be reduced and it is easy to satisfy the delay time requirement. By setting the basic unit of the frequency axis of the control channel to 1 FU, frequency multiplexing between the control channel and the data channel can be performed more efficiently. If the basic unit of the frequency axis is composed of arbitrary subcarriers smaller than 1FU, there is a disadvantage that the starting point for the scheduled data must be indicated in units of subcarriers.

On the other hand, the basic unit of the downlink control channel shown in FIG. 4C may be an area to which a DCI-mapped area 4c-03 and a reference signal for decoding it are mapped to a DMRS 4c-04.

4D is a diagram illustrating an example of a downlink control channel setting according to the fourth embodiment of the present invention. FIG. 4D shows an example in which downlink control channels are set differently for subframes for supporting services having three different TTIs. Referring to FIG. 4D, TTI ₁ (4d-01) is composed of 14 OFDM symbols, TTI ₂ (4d-02) is composed of 7 OFDM symbols, and TTI ₃ (4d-03) is composed of 2 OFDM symbols. According to Figure 4d a terminal having a _{TTI 1 (User Equipment, UE)} # 1 , the downlink control channel (Control Channel, CCH) to a total of three OFDM symbols (4d-04), UE # 2 has a TTI ₂ has a total of 2 A total of one OFDM symbol 4d-06 is set in each OFDM symbol (4d-05) and a terminal # 3 having TTI ₃ , respectively. Although FIG. 4D shows an example set differently for each terminal, it is noted that it can be set for each terminal or terminal group in consideration of the complexity and efficiency of the control channel setting. In other words, it should be noted that the term terminal used in the present invention may be interpreted as a terminal group or a term having a similar meaning.

The TU (Time Unit, 4d-07) indicated in 4d indicates a basic time unit for scheduling. In the example of FIG. 4D, 1 TU is assumed to be 14 OFDM symbols. When serving a terminal # 1 / # 2 / # 3 with OFDMA, the base station allocates a subframe corresponding to 1 TTI ₁ for terminal # 1 and 2 TTI ₂ for terminal # 2 And a subframe corresponding to 7 TTI3 for the terminal # 3 can be scheduled. In addition, according to FIG. 4D, one control channel is set per TTI in the case of the terminal # 1 and the terminal # 2, but one control channel is set per a plurality of TTIs for the terminal # 3. In this case, in the control channel allocated to the terminal # 3, the control information for a plurality of TTIs is bundled and can be indicated at one time in the previously received control channel.

Note that the setting of the control channel region in Fig. 4D is only one example, and the control channel region may be set differently according to the TTI and various other system parameters.

4E is a diagram illustrating an example of a time / frequency axis setting for a downlink control channel according to the 4-1 embodiment of the present invention. In FIG. 4E, the time axis resources are represented by OFDM symbols and are shown by 1 TU (4e-01), and the frequency axis resources are shown by one subband 4e-03 in units of 1 FU (4e-02) . In the example of FIG. 4E, it is assumed that the subframes of the terminal # 1 (4e-04), the terminal # 2 (4e-05), and the terminal # 3 (4e-06) in FIG. The control channels (CCH # 1 and 4e-07) of the terminal # 1, the control channels (CCH # 2 and 4e-08) of the terminal # 2 and the control channel 4e-09 of the terminal # The control channel can be set differently not only in the time resource but also in the frequency resource. The assignment of control channels is accomplished through the concatenation of the basic units depicted in Figure 4c. As a result, the control channel region is provided in a specific pattern in the time and frequency axes. The base station can indicate information on the set control channel pattern to each terminal through RRC signaling. Or through a function using various system parameters such as RNTI, TTI length, service type, and the like.

In the case of using the downlink control channel structure according to the above-described and the 4-1th embodiment, the control channel region is variably allocated according to the service situation for each terminal, so that resources can be effectively utilized for each service requirement. In this case, if the control information message to be transmitted does not exist, the resources set as the control channel can be utilized for data transmission, thereby further increasing the resource efficiency. In this case, more specific operation of the base station and the terminal is required, which will be described below in consideration of various embodiments.

4F is a diagram illustrating an example of downlink transmission according to the embodiment 4-1 of the present invention.

In FIG. 4F, transmission examples of the terminal # 1 (4f-01) and the terminal # 2 (4f-02) having different TTI lengths are shown. The TTI lengths of the terminal # 1 (4f-01) and the terminal # 2 (4f-02) are set to TTI ₁ (4f-03) and TTI ₂ (4f-04), respectively. In the example of FIG. 4F, the PDSCH # 1 (4f-05) of the terminal # 1 (4f-01) is allocated to a part of the subbands. At this time, as shown in FIG. 4F, a part of the resources allocated to the PDSCH # 1 (4f-05) is the control channel CCH # 2 (4f-06) existing in the second TTI of the UE # 2 Some of the predetermined resources may overlap. If there is no control information to be transmitted through CCH # 2 (4f-06), CCH # 2 (4f-06) is deactivated and PDSCH # 1 (4f-05) Lt; / RTI &gt; However, if there is control information to be transmitted through the CCH # 2 (4f-06), there may occur interference between the PDSCH # 1 (4f-05) and the CCH # 2 (4f-06) Terminal operation is required.

(Example 4-1-1)

The PDSCH # 1 (4f-05) and the CCH # 2 (4f-06) collide with each other as shown in FIG. 4F, 2 (4f-06) can be protected by puncturing a part of the PDSCH # 1 (4f-05) with respect to the resources overlapping the CCH # 2 (4f-06).

FIG. 4G is a diagram illustrating a base station and a terminal procedure according to embodiment 4-1-1 of the present invention.

First, the base station procedure of the present invention will be described. In step 4g-01, the base station performs setting for each control channel region, and transmits information on the set control channel pattern to each terminal through RRC signaling or an implicit method. In step 4g-02, when the BS performs scheduling for the PDSCH, it determines whether a preset control channel exists in the resource to which the PDSCH is allocated. If there is no control channel region, the PDSCH is directly allocated (4g-05). If there is a control channel area, it is determined again whether the control channel of the corresponding area is used in step 4g-03. If the control channel of the corresponding area is activated, the PDSCH of the corresponding area is punctured and scheduled in step 4g-04. Even if the control channel is set, if the control channel of the corresponding area is not used, the PDSCH can be directly scheduled to the corresponding resource (4g-05).

Next, the terminal procedure of the present invention will be described. In step 4g-06, the terminal receives the control channel area setting information from the base station. In step 4g-07, the UE decodes its control channel to obtain scheduling information for the PDSCH. In step 4g-08, the UE can perform decoding on the PDSCH.

(Example 4-1-2)

4f, when the data channel (PDSCH # 1 (4f-05)) and the control channel (CCH # 2 (4f-06)) collide with each other, the base station performs scheduling for PDSCH # 1 The collision with the control channel can be avoided. The base station can allocate the PDSCH # 1 (4f-05) only to the area that avoids the control channel of the active terminal in the process of performing the resource allocation of the PDSCH # 1 (4f-05).

4H is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-1-2 of the present invention.

First, the base station procedure of the present invention will be described. The base station performs the setting for the control channel region in step 4h-01 and transmits it to the terminal. In step 4h-02, the BS examines whether the PDSCH is overlapped with a predetermined control channel region, and if not overlapping, the PDSCH can be scheduled (4h-05). If overlapping resources exist, it is determined whether the control channel of the corresponding area is used (4h-03). If the control channel of the corresponding region is in use, the PDSCH allocation unit searches for another resource for PDSCH allocation in Step 4h-04, and if the control channel of the corresponding region is not in use, PDSCH allocation is performed in Step 4h-05.

Next, the terminal procedure of the present invention will be described. The UE receives the setting information for the control channel region in step 4h-06 and acquires the scheduling information for its own PDSCH from the downlink control information obtained by decoding the control channel in step 4h-07. In step 4h-08, the UE performs decoding on the PDSCH.

(Example 4-1-3)

The PDSCH # 1 (4f-05) and the CCH # 2 (4f-06) collide with each other as shown in FIG. 4F, (4f-06) are allocated to PDSCH # 1 (4f-05) so as not to use resources allocated to CCH # 2 (4f-06) by performing rate matching on PDSCH # 1 0.0 &gt; 4f-05). &Lt; / RTI &gt; In this case, for successful decoding of PDSCH # 1 (4f-05), additional signaling is required to indicate that some of the resources are not used because of the rate matching. Each user can know information on the control channel pattern set in the current subframe from the RRC signaling of the base station. In this case, the base station can transmit to the DCI of the terminal # 1 an indicator indicating whether or not to use the control channel of another terminal, for example, CCH # 2 (4f-06) existing in the area allocated to the PDSCH of the terminal # 1. The UE can know where resources are not used in the area to which the PDSCH is allocated through a predetermined control channel pattern and an indicator indicating whether the control channel is used by the other UEs received in the DCI. Therefore, the UE can perform decoding based on the assumption that the PDSCH is allocated to the remaining part except for the corresponding area.

4I and 4A are diagrams illustrating base station and terminal procedures according to embodiment 4-1-3 of the present invention.

First, the base station procedure of the present invention will be described. The base station performs setting for the control channel region and transmits it to the terminal (4i-01). (4i-02) whether a control channel is set in an area for scheduling the PDSCH, and determines whether the corresponding control channel is used (4i-03). If the PDSCH does not collide with the control channel of another UE, the PDSCH is directly scheduled (4i-05). If the control channel of the corresponding area is being used, the base station schedules the PDSCH by performing rate matching except for the corresponding area in step 4i-04. In step 4i-06, the base station further transmits an indication of whether the control channel is used for an area where the PDSCH overlaps with the control channel. In the case where there is no area where the PDSCH overlaps with the control channel, since there is no active control channel, an indicator of whether to use the control channel can be used as it is.

Next, the terminal procedure of the present invention will be described. The UE receives (4i-07) the setup information for the control channel region and acquires (4i-08) the scheduling information for the PDSCH from its control channel. In step 4i-09, the UE determines whether its PDSCH is set to a control channel of another UE among the scheduled resources based on the setting information for the control channel region. If there is no control channel of another UE, the PDSCH is directly decoded (4i-13). If there is a control channel of another UE, information on whether to use the corresponding control channel is obtained in step 4i-10. In step 4i-11, if the UE receives an indication that the control channel of the corresponding area is in use, the UE decodes the PDSCH except for the corresponding area (4i-12). If an indicator indicating that the control channel of the corresponding area is not in use is received, PDSCH decoding (4i-13) is performed as it is.

4J is a diagram illustrating an example of downlink transmission according to the embodiment 4-1 of the present invention.

In Fig. 4J, an example of PDSCH transmission of the terminal 4j-02 having a length of TTI ₁ (4j-01) is shown. In the same manner as described above, when there is no control message to be transmitted to the control channel for the resource set to the control channel, the resource can be used to transmit the PDSCH. Therefore, as shown in FIG. 4J, the start point 4j-02 of the PDSCH can be changed according to the position of the frequency resource to which the PDSCH is allocated. More specifically, if the PDSCH1 (4j-04) is scheduled for the PDSCH1 (4j-02), the starting point of the PDSCH1 (4j-04) becomes the fourth OFDM symbol. Similarly, the PDSCH2 (4j-05) has the third OFDM symbol and the PDSCH3 (4j-06) has the second OFDM symbol as the start points. Although the control channels 4j-07 are allocated to three OFDM symbols when viewed from the time axis, in the case of the downlink control channel according to the 4-1 embodiment of the present invention, since it supports frequency axis multiplexing with the PDSCH, A control channel and a data channel may exist simultaneously in a symbol. Therefore, the point at which the PDSCH can start in the example shown in FIG. 4J may be a 1/2/3/4th OFDM symbol point. In order for the UE to successfully decode the PDSCH, it is required to know where the PDSCH of its own is to be started, so that additional base station and terminal operations are required.

(Example 4-1-4)

When the BS schedules the PDSCH, the PDSCH resource may be allocated to the OFDM symbol following the control channel of the corresponding MS. In this case, since the UE can always assume that its PDSCH is next to the control channel, the UE can perform decoding on the PDSCH without signaling to an additional PDSCH start point.

4K is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-1-4 of the present invention.

First, the base station procedure of the present invention will be described. In step 4k-01, the base station sets up a control channel region and transmits information on the control channel region to the UE. In step 4k-02, when scheduling a PDSCH of a UE, the BS schedules the PDSCH to the next symbol of the OFDM symbol to which the control channel is allocated considering the time domain in which the control channel of the UE is set. For example, when the control channel of the UE is set to n OFDM symbols, the PDSCH may be allocated to the (n + 1) th symbol.

Next, the terminal procedure of the present invention will be described. In step 4k-04, the UE receives the control channel area setting information. The UE can acquire the frequency-axis scheduling information for the PDSCH from its control channel (4k-05) and decode the PDSCH (4k-06) after assuming that the start point of the PDSCH is the next OFDM symbol of its control channel.

(Example 4-1-5)

When the BS schedules the PDSCH, the BS can add an indication of the start point of the PDSCH to the DCI message providing the PDSCH scheduling information and transmit the PDSCH. In this case, the candidate group of the start point of the PDSCH is determined by the size of the control channel time domain of the corresponding user. For example, if the control channel is assigned to n OFDM symbols, the PDSCH is 1, 2, ... , &lt; / RTI &gt; the (n + 1) th OFDM symbol. As a result, each user can have an indication of the PDSCH start point of a different size. In this case, the DCI format may be newly defined to add message bits having different sizes to the PDSCH start point. Alternatively, the number of message bits for the PDSCH start point may be fixed and no extra bits may be used. In this case, the number of message bits for the PDSCH start point may be log2 (nmax + 1), where nmax represents the maximum number of OFDM symbols that can be allocated to the control channel. In this case, you can use the existing DCI format without any additional DCI format.

4L is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-1-5 of the present invention.

First, the base station procedure of the present invention will be described. After setting the control channel region, the base station transmits the corresponding information to the mobile station (4l-01). In step 4l-02, the base station performs scheduling for the PDSCH, and in step 4l-03, the indicator for the PDSCH start point is added to the DCI and transmitted.

Next, the terminal procedure of the present invention will be described. The UE receives (4l-05) the control channel region setup information and acquires (4l-06) frequency-axis scheduling information for the PDSCH from its control channel. In step 4l-07, the UE may additionally obtain information on a start point, which is time-axis scheduling information for the PDSCH, and perform decoding (4l-08) on the PDSCH based on the preamble information.

Next, a fourth embodiment of the downlink control channel proposed in the present invention will be described.

[Example 4-2]

Prior to describing the embodiment 4-2, a more detailed description of the DCI message will be given. As described above, there are various DCI formats according to a data transmission scheme and an objective. Among them, the DCI format 2C, which is one of the DCI formats for transmitting the downlink scheduling assignment, will be described as an example. DCI format 2C contains scheduling assignment information for a PDSCH that supports closed-loop multi-antenna transmission for up to 8 layers. More specifically, the DCI format 2C includes the following message.

- carrier indicator

- Resource allocation header

- Resource block allocation

- Power control command for PUCCH

- Downlink allocation index (index)

- HARQ process number

- RS setting information: antenna port, scrambling sequence, number of layers

- SRS (Sounding Reference Signal) request

- MCS for transport block 1, new data indicator, Redundancy version

- MCS for transport block 2, new data indicator, Redundancy version

- The resource offset for HARQ-ACK (if transmitted on EPDCCH)

During downlink data transmission, the UE first decodes the control channel to obtain the control information. From the resource block allocation information, the location where the PDSCH is allocated can be known, and data can be decoded based on the MCS and other multi-antenna setting information.

4M is a view showing a fourth embodiment of the present invention.

FIG. 4M shows the subframe structure of the terminal # 1 (4m-02) having the TTI length of TTI ₁ (4m-01) and the terminal # 2 (4m-04) having the TTI ₂ of (4m-03). Referring to FIG. 4M, the downlink control channel according to the fourth embodiment of the present invention includes a pre-CCH and a post-CCH. The subframe structure of the UE # 1 (4m-02) shows an example in which the proposed control channel is allocated when the length of the TTI ₁ (4m-01) is equal to 1 TU (4m-10). According to the example of FIG. 4M, the Pre-CCH # 1 (4m-05) of the terminal # 1 (4m-02) can be assigned to the first OFDM symbol and the Post- OFDM symbols. In case of the terminal # 1 (4m-02), one control channel can be set for 1 TU since the length of the TTI and the length of the TU are the same. The subframe structure of the UE # 2 (4m-04) shows an example in which a control channel is proposed for a case where the length of (4m-03) TTI ₂ is smaller than 1TU. In this case, the Pre-CCH # 2 (4m-07) of the UE # 2 (4m-04) is allocated to the first OFDM symbol of the first TTI and not allocated to the second TTI. As a result, in the case of the Pre-CCH # 2 (4m-07) of the terminal # 2 (4m-04), it has one setting for one TU like the terminal # 1 (4m-04). On the other hand, the post-control channel of the UE # 2 (4m-04) can be set for each TTI, and in the example of Figure 4m, the Post-CCH ₁ # 2 (4m-08) is allocated to the second OFDM symbol of the first TTI, Post-CCH ₂ # 2 (4m-09) is allocated to the first and second OFDM symbols of the second TTI, respectively. As a result, when the terminal # 1 4m-02 and the terminal # 2 4m-04 are frequency multiplexed and transmitted, the pre-control channel can be similarly transmitted through the first OFDM symbol.

4n is a diagram illustrating an example of time / frequency assignment for a control channel according to embodiment 4-2 of the present invention.

4n shows an example of the time and frequency allocation of the control channel for the terminal # 1 (4n-01) and the terminal # 2 (4n-02) considered in FIG. 4m. (4n-04), which is the line control channel of the terminal # 1 (4n-01) and the pre-CCH # 2 (4n-03) of the terminal # 2 May be allocated to a sub-band of a sub-band of the first OFDM symbol. The line control channels 4n-03 and 4n-04 shown in FIG. 4n have basically the same structure as the control channels in the 4-1 embodiment of the present invention. The preamble control channel may be set to a different size considering the various system parameters corresponding to each terminal or terminal group with the same basic unit of resource allocation as described in FIG. 4C. At this time, a preferable form in the time-axis resource allocation of the pre-control channel is to be allocated to the minimum OFDM symbol. This is advantageous in that it is possible to reduce the delay time until the control channel decoding by making it possible to receive the line control channel in a short time as possible and reduce the complexity by reducing the size of the area to be examined for blind decoding of the terminal have. In the example of FIG. 4n, the line control channels 4n-03 and 4n-04 of the terminal # 1 (4n-01) and the terminal # 2 (4n-02) are all allocated to one OFDM symbol. The frequency axis assignment of the pre-transmission control channels 4n-03 and 4n-04 may be set to be different in a certain region of the sub-bands according to the requirements of the terminal as in the 4-1 embodiment.

In the embodiment 4-2 of the present invention, the pre-control channel can be allocated independent resources while the post-control channel is transmitted through the PDSCH. In FIG. 4n, the Post-CCH # 1 (4n-05) of the terminal # 1 (4n-01) is allocated to the same frequency resource as the PDSCH # 1 (4n-06). Similarly, when the terminal # 2 (4n-02), Post-CCH 1 # 2 (4n-07) has been assigned to the same frequency resources and PDSCH1 # 2 (4n-08) , Post-CCH 2 # 2 (4n- 09) is allocated to the same frequency resource as the PDSCH2 # 2 (4n-10). In other words, the post-control channel can be mapped and transmitted to a partial area of the PDSCH, which is a data channel.

The control channel according to the fourth embodiment of the present invention is composed of two control channels, and the mapping methods of the control channels are also different from each other. In the case of the embodiment 4-2, it is possible to allocate the control channels variably according to the service requirements of each terminal, as in the case of the embodiment 4-1. In addition, in the case of the post-control channel resource allocation, it is not preset in a specific time and frequency resource, such as a pre-control channel, but may exist in various positions depending on whether the PDSCH is allocated or not. Thereby, there is an advantage that the scheduling for the PDSCH can be freely allocated without any restriction in the remaining part except for the resource to which the pre-control channel is allocated. Therefore, it is possible to operate the system more flexibly than in the embodiment 4-1.

In the case of the preamble control channel, each UE can determine the location of its control region by setting a control region and signaling it to the UE, while in the case of the post-control channel, it is mapped to a part of the resource region of the scheduled PDSCH This may require instructions. Therefore, specific base station and terminal operations for setting the pre-control channel and the post-control channel are required.

(Example 4-2-1)

4O is an illustration of an example of DCI partitioning according to embodiment 4-2-1 of the present invention.

According to FIG. 4o, the entire DCI message 4o-01 can be divided into DCI ₀ (4o-02) and DCI ₁ (4o-03). Fig. In the example of 4o DCI0 (4o-02) comprises a message to the resource block allocation information (4o-04) for the PDSCH and, DCI ₁ (4o-03) are other MCS, New data indicator, Redundancy version, etc. Data decoding, and various downlink control information for terminal operation. The DCI ₀ (4o-02) message can be transmitted on the line control channel 4o-05 and the DCI ₁ (4o-03) can be transmitted on the post control channel 4o-06.

According to the embodiment 4-2-1 shown in FIG. 4O, the line control channel 4o-05 includes the resource allocation information 4o-04 for the PDSCH. Therefore, the UE can know the position of the PDSCH by decoding the preamble control channel, which is the same as the position of the control channel 4o-06 transmitted through the PDSCH. As a result, since the UE receives the resource allocation information for the post-control channel 4o-06 from the pre-control channel 4o-05, it does not need to be transmitted in a predetermined area differently from the pre-control channel. Therefore, a more flexible control channel can be set.

4P is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-2-1 of the present invention.

First, the base station procedure of the present invention will be described. In step 4p-01, the base station performs area setting and information transmission for the line control channel. In step 4p-02, the base station can generate DCI ₀ and DCI ₁ messages through DCI division. In step 4p-03, the base station transmits a DCI ₀ message to the UE through the pre-control channel. In step 4p-04, the base station transmits the DCI ₁ message to the UE through the control channel after being mapped to the scheduled PDSCH.

Next, the terminal procedure of the present invention will be described. In step 4p-05, the terminal receives setting information for the line control channel region. In step 4p-06, the UE receives the DCI ₀ message and decodes the preamble control channel, and obtains the scheduling information for the PDSCH from the DCI ₀ message. In step 4p-07, the UE can decode the control channel allocated to some of the scheduled PDSCHs, receive the DCI ₁ message, and obtain the remaining downlink control information therefrom. And decodes the PDSCH according to the downlink control information (4p-08).

(Example 4-2-2)

Figure 4Q is an illustration of an example of DCI partitioning according to embodiment 4-2-2 of the present invention.

FIG. 4q shows an example in which a total of four DCIs (4q-01, 4q-02, 4q-03, 4q-03) are divided. The example of FIG. 4q is an example of a case where a service corresponding to 4 TTIs is to be transmitted for 1 TU, and a necessary control channel is transmitted four times in total. According to FIG. 4q, the four DCIs can be divided into one DCI ₀ (4q-09) and a total of four DCI ₁ (4q-10, 4q-11, 4q-12, 4q-13). The PDSCH resource allocation information 4q-05 in the first DCI 4q-01 and the PDSCH resource allocation information 4q-06 in the second DCI 4q-02 can all be divided into the DCI ₀ (4q-09) message . Similarly, PDSCH resource allocation information (4q-07) in the third DCI (4q-03) and PDSCH resource allocation information (4q-08) in the fourth DCI (4q- . And the total remaining DCI information other than the resource allocation information for four PDSCH are each _{DCI 1, 1 (4q-10} ), DCI 1, 2 (4q-11), DCI 1, 3 (4q-12), DCI 1, ₄ (4q-13). According to FIG. 4q, DCI ₀ (4q-09) is mapped to the line control channel 4q-14 transmitted in the first TTI and DCI _{1 , 1} (4q-10) ). Similarly, DCI _{1 , 2} (4q-11), DCI _{1 , 3} (4q-12) and DCI _1,4 (4q-13) correspond to the post-CCH ₂ ), Post-CCH ₃ (4q-17), and Post-CCH ₄ (4q-18). The important point here is that both the pre-control channel and the post-control channel are transmitted only in the first TTI and only the post-control channel is transmitted in the subsequent TTI. This can be considered as a case of the case of the terminal # 2 (4m-04, 4n-02) in Figs. 4M and 4N already described above.

In the case of the embodiment 4-2-2 shown in FIG. 4q, it is considered that a plurality of control channels can be transmitted in 1TU unlike the embodiment 4-2-1 described above. In this case, it is important to appropriately divide a plurality of DCIs transmitted during 1TU. In Embodiment 4-2-2, the resource allocation information for the PDSCH can be mapped not only to DCI ₀ but also DCI ₁ . A plurality of if both the resource allocation information for all the PDSCH that follows in the service transmission for the TTI mapped to DCI ₀ can overhead (overhead) that are weighted for DCI ₀ is too large exceeds the transmission capacity of the DCI ₀ provided have. In consideration of this, in FIG. 4q, the PDSCH resource allocation information corresponding to the third and fourth TTIs is divided into DCI _{1 , 2} (4q-11) and transmitted. When the UE operates according to the example shown in FIG. 4Q, the UE knows the positions of Post-CCH ₁ (4q-15) and Post-CCH ₂ (4q-16) from the line control channel 4q- and, it can be seen that the resource area of the Post-CCH2 from (4q-16) Post-CCH3 (4q-17) and _{Post-CCH 4 (4q-18} ). Decoding of a total of four PDSCHs can be successfully performed through other control signals.

4R is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-2-2 of the present invention. In FIG. 4R, it is assumed that K PDSCHs transmitted for 1TU are transmitted.

First, the base station procedure of the present invention will be described. In step 4r-01, the base station sets up the area for the line control channel and transmits information on the area to the terminal. In step 4r-02, the base station generates one DCI ₀ and K DCI ₁ messages through DCI division. In this case, DCI ₀ is set to k = 1, ... , &lt; / RTI &gt; n of the PDSCH _k are included. The DCI ₀ message is transmitted (4r-03) through the pre-set line control channel and mapped to the K PDSCH _k , and DCI _{1, k} can be transmitted (4r-04) through the control channel, respectively.

Next, the terminal procedure of the present invention will be described. In step 4r-05, the UE receives area setting information for the line control channel. From the DCI ₀ of the line control channel, the terminal calculates k = 1, ..., corresponding to n may obtain the scheduling information for the PDSCH _k (4r-06). In step 4r-07 UE PDSCH using the terminal control information in obtaining the rest of the control information and the step 4r-08 for each PDSCH _k receives the DCI _{1, k} message therefrom from the rear control channel of each PDSCH _{k k} Lt; / RTI &gt; Last PDSCH _k known scheduling information, or can obtain the scheduling information for the PDSCH _k out thereafter from DCI _{1, m} existing in the PDSCH _m (4r-10). The above procedure is repeated until decoding of all PDSCHs is completed (4r-09).

The embodiment 4-2-2 described above is merely a specific example for the purpose of easily explaining the technical contents of the present invention and helping understanding of the present invention, and it is also possible to use other variants based on the technical idea of the present invention Note that it is possible to perform as many as possible.

(Example 4-2-3)

FIG. 4S is a diagram illustrating an example of DCI partitioning according to embodiment 4-2-3 of the present invention. FIG.

According to the example shown in FIG. 4S, the resource allocation information 4s-02 and the RS setting information 4s-03 for the PDSCH in the entire DCI message 4s-01 can be divided. PDSCH and the multiple antenna setting information 4s-03 are divided into DCI ₀ (4s-04) messages and the remaining control information is divided into DCI ₁ (4s-05) Show. DCI ₀ (4s-04) is mapped to the line control channel 4s-06 and transmitted, and DCI ₁ (4s-05) is mapped to the post control channel 4s-07 and transmitted. According to the example shown in FIG. 4S, not only the resource allocation information for the PDSCH but also the RS setup information are separated by the DCI ₀ message, unlike the embodiment 4-2-1 or the embodiment 4-2-2. The RS setup information may include information such as an antenna port, a scrambling sequence, and the number of layers as described above.

4T is a diagram showing an example of a frame structure according to Embodiment 4-2-3 of the present invention.

In FIG. 4T, the PDSCH 4t-02 to which the post-control channel is transmitted and the reference signal DMRS (4t-03) to decode the post-control channel 4t-01 are shown. As shown in FIG. 4C, the downlink control channel described in the present invention can basically support decoding based on the DMRS. For example, in the case of linear control channels, separate RSs are required for decoding of the linear control channel since they are set to independent time / frequency resources. If a post-control channel 4t-01 is transmitted in the same way as a pre-control channel, a separate DMRS for the post-control channel 4t-01 is required. However, in the embodiment 4-2 of the present invention, since the post-control channel is mapped to a partial region of the PDSCH, the post-control channel can be transmitted in the same transmission scheme as the PDSCH. In this case, the DMRS 4t-03 of the PDSCH 4t-02 can be shared and used for decoding the post-control channel 4t-01 without setting an individual DMRS in the post-control channel 4t-01. In this case, since there is no need for an additional RS for the post-control channel, RS overhead can be reduced. In order to use the DMRS (4t-03) of the PDSCH (4t-02) in the post-control channel (4t-01), the setting information for the DMRS (4t-03) must be received first. Therefore, as shown in FIG. 4S, the RS setup information is divided into DCI ₀ , and is transmitted through the line control channel, and the UE can acquire the DMRS setup information for decoding the pre-control channel by decoding the pre-control channel.

4U is a diagram illustrating a base station and a terminal procedure according to Embodiment 4-2-3 of the present invention.

First, the base station procedure of the present invention will be described. In step 4u-01, the BS performs area setting for the line control channel and transmits information to the MS. In step 4u-02, DCI is divided to generate DCI ₀ and DCI ₁ messages. The base station transmits (4u-03) the DCI ₀ through the line control channel and transmits (4u-04) the DCI ₁ through the scheduled control channel of the PDSCH.

Next, the terminal procedure of the present invention will be described. In step 4u-05, the terminal receives the line control channel area setting information. The UE receives the DCI ₀ message from its own Line Control Channel and acquires the scheduling information and RS setup information for its PDSCH from the DCI ₀ message (4u-06). In step 4u-07, the UE can perform decoding on the post-control channel using the RS setup information acquired from the DCI1. (4u-08) the remaining control information for the PDSCH by acquiring the DCI ₁ message from the control channel, and then performing the decoding on the PDSCH (4u-09).

In order to perform the above-described embodiments of the present invention, the transmitter, the receiver and the controller of the terminal and the base station are shown in FIGS. 4V and 4W, respectively. The above-mentioned Example 4-1, Example 4-1-1, Example 4-1-2, Example 4-1-3, Example 4-1-4, Example 4-1-5, Example 4 The base station and the terminal transmit / receive method for setting up the downlink control channel and transmitting / receiving operation corresponding to Embodiment 4-2-1, Embodiment 4-2-2 and Embodiment 4-2-3, In order to accomplish this, the base station and the transmitter, receiver, and processing unit of the terminal must operate according to the embodiments.

4v is a block diagram illustrating an internal structure of a terminal according to an embodiment of the present invention. As shown in FIG. 4V, the terminal of the present invention may include a terminal processing unit 4v-01, a receiving unit 4v-02, and a transmitting unit 4v-03.

The terminal processor 4v-01 may control a series of processes that the terminal can operate according to the embodiment of the present invention described above. For example, the terminal operation can be controlled differently according to the setting items of the downlink control channel according to the embodiment of the present invention.

The terminal receiver 4v-02 and the terminal 4v-03 may collectively be referred to as a transmitter / receiver in the embodiment of the present invention. The transmitting and receiving unit can transmit and receive signals to and from the base station. The signal may include control information and data. To this end, the transmitting and receiving unit may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, an RF receiver for low-noise amplifying the received signal and down-converting the frequency. In addition, the transmitter / receiver may receive the signal through the wireless channel, output it to the terminal processor 4v-01, and transmit the signal output from the terminal processor 4v-01 through the wireless channel.

4w is a block diagram illustrating an internal structure of a base station according to an embodiment of the present invention. As shown in FIG. 4w, the base station of the present invention may include a base station processing unit 4w-01, a receiving unit 4w-02, and a transmitting unit 4w-03.

The base station processing unit 4w-01 may control a series of processes so that the base station can operate according to the above-described embodiment of the present invention. For example, the BS operation can be controlled differently according to the downlink control channel setup according to the embodiment of the present invention. In addition, scheduling for the downlink control channel and the data channel of the present invention can be performed, and the setup information for the downlink control channel can be instructed to the terminal.

The base station receiving unit 4w-02 and the base station transmitting unit 4w-03 may be collectively referred to as a transmitting / receiving unit in the embodiment of the present invention. The transmitting and receiving unit can transmit and receive signals to and from the terminal. The signal may include control information and data. To this end, the transmitting and receiving unit may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, an RF receiver for low-noise amplifying the received signal and down-converting the frequency. In addition, the transmitting and receiving unit may receive a signal through a wireless channel, output it to the base station processing unit 4w-01, and transmit the signal output from the terminal processing unit 4v-01 through a wireless channel.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate the understanding of the present invention and are not intended to limit the scope of the present invention. That is, it will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible. Further, each of the above embodiments can be combined with each other as needed.

Claims (1)

A method for processing a control signal in a wireless communication system,
Receiving a first control signal transmitted from a base station;
Processing the received first control signal; And
And transmitting the second control signal generated based on the process to the base station.

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