JP7009597B2 - Terminal and communication method - Google Patents

Description

The present disclosure relates to terminals and communication methods.

A communication system called a 5th generation mobile communication system (5G) is being studied. In 5G, it is being considered to flexibly provide functions for each use case that requires an increase in communication traffic, an increase in the number of connected terminals, high reliability, and low latency. Typical use cases include Enhanced Mobile Broadband (eMBB), Massive Machine Type Communications (mMTC), and Ultra Reliable and Low Latency Communications (URLLC). There are three. The 3GPP (3rd Generation Partnership Project), an international standardization organization, is considering the sophistication of communication systems from the perspectives of both the sophistication of LTE systems and New RAT (Radio Access Technology) (see, for example, Non-Patent Document 1). ing.

As a DL (Downlink) control signal (DCI: Downlink Control Information) for New RAT, a two-step DCI (referred to as two step DCI or two stage DCI) is being studied (see, for example, Non-Patent Document 2). The two-stage DCI is a method of dividing the information contained in the DCI into a first DCI and a second DCI.

RP-161596, "Revision of SI: Study on New Radio Access Technology", "NTT DOCOMO, September 2016 R1-1613668, "WF on two stage DCI design," Huawei, HiSilicon, Qualcomm, OPPO, Convida, ZTE, Fujitsu, Mediatek, InterDigital, Intel, November 2016 3GPP TS 36.213 V13.3.0, “Physical procedures (Release 13),” September 2016

In the two-stage DCI, it is necessary to consider how to determine the resource to which the DCI (particularly the second DCI) is placed.

One aspect of the present disclosure contributes to the provision of a terminal and a communication method capable of appropriately determining the resource in which the DCI (particularly, the second DCI) is arranged.

The terminal according to one aspect of the present disclosure uses a receiver that receives the first downlink control signal and the second downlink control signal, and the first downlink control signal and the second downlink control signal, and download data from the received signal. The receiver includes a circuit for separating signals, and the receiver controls the second downlink based on the information regarding the first downlink control signal or the information regarding the downlink data signal indicated by the first downlink control signal. Identify signal resources.

The base station according to one aspect of the present disclosure includes a circuit that generates a first downlink control signal and a second downlink control signal, and a transmitter that transmits the first downlink control signal, the second downlink control signal, and the downlink data signal. And, the transmitter is a resource set based on the information about the first downlink control signal or the information about the downlink data signal indicated by the first downlink control signal, and the second downlink control signal. To send.

The communication method according to one aspect of the present disclosure receives a first downlink control signal and a second downlink control signal, and uses the first downlink control signal and the second downlink control signal to obtain a downlink data signal from the received signal. Separated, the resource of the second downlink control signal is specified based on the information regarding the first downlink control signal or the information regarding the downlink data signal indicated by the first downlink control signal.

In the communication method according to one aspect of the present disclosure, the first downlink control signal and the second downlink control signal are generated, the first downlink control signal, the second downlink control signal, and the downlink data signal are transmitted, and the second downlink control signal is transmitted. The downlink control signal is transmitted by a resource set based on the information regarding the first downlink control signal or the information regarding the downlink data signal included in the first downlink control signal.

It should be noted that these comprehensive or specific embodiments may be realized in a system, an apparatus, a method, an integrated circuit, a computer program, or a recording medium, and the system, an apparatus, a method, an integrated circuit, a computer program, and a recording medium may be realized. It may be realized by any combination of.

According to one aspect of the present disclosure, the resource in which the DCI (particularly the second DCI) is located can be appropriately specified.

Further advantages and effects in one aspect of the present disclosure will be apparent from the specification and drawings. Such advantages and / or effects are provided by some embodiments and the features described in the specification and drawings, respectively, but not all need to be provided in order to obtain one or more identical features. There is no.

Block diagram showing the configuration of the base station according to the first embodiment Block diagram showing the configuration of the terminal according to the first embodiment Block diagram showing the configuration of the base station according to the first embodiment Block diagram showing the configuration of the terminal according to the first embodiment A flowchart showing an operation example of the base station according to the first embodiment. A flowchart showing an operation example of the terminal according to the first embodiment. The figure which shows an example of the correspondence between the size of the 1st DCI and the size of the 2nd DCI which concerns on Embodiment 1. The figure which shows an example of the correspondence between the size of the 1st DCI and the size of the 2nd DCI which concerns on Embodiment 1. The figure which shows an example of the correspondence between the MCS and the size of the 2nd DCI of the data which concerns on Embodiment 1. The figure which shows an example of the correspondence between the data modulation method and the size of 2nd DCI which concerns on Embodiment 1. The figure which shows an example of the correspondence between the MCS and the size of the 2nd DCI of the data which concerns on Embodiment 1. The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2. Figure to be used for explanation of subject of Embodiment 2 The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2 (operation example 2-1) The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2 (operation example 2-2) The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2 (operation example 2-2) The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2 (operation example 2-3) The figure which shows the arrangement example of the 2nd DCI which concerns on Embodiment 2 (operation example 2-4)

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the drawings.

In the two-stage DCI, the first DCI including the resource area (channel estimation area) for channel estimation is transmitted from the base station (sometimes called eNB) to the terminal (UE: User Equipment). The terminal has the advantage of being able to initiate channel estimation prior to decoding the second DCI. Further, in the two-stage DCI, the code length of the first DCI can be shortened by dividing the information contained in the DCI into the first DCI and the second DCI, so that the search space of the first DCI can be reduced. be.

Here, it is conceivable that the resource to which the first DCI is allocated is determined in the same manner as the DCI in LTE / LTE-Advance. On the other hand, as a method of specifying the resource to which the second DCI is assigned, for example, a method of using a defined resource or a method of notifying the resource by the first DCI is being studied.

However, in the method of allocating the specified resource to the second DCI, it is necessary to set the resource of the second DCI so as not to interfere with the resource allocation of other terminals, which complicates the process. In addition, in the method of notifying the resource to which the second DCI is assigned by the first DCI, it is necessary to add the information for identifying the resource of the second DCI to the first DCI, and the length of the first DCI becomes long.

Therefore, in the following, a method for efficiently identifying the resource of the second DCI will be described.

[Premise]
The base station places the first DCI in any of the areas called the search space. In addition, one of a plurality of Aggregation levels is set in the first DCI. Aggregation level is a value indicating the amount of resources of the first DCI.

The terminal monitors (blindly decodes) the 1st DCI for multiple Aggregation levels in the search space, and if reception is successful, it determines that the resource allocation of the 1st DCI is assigned to the own machine. By monitoring multiple Aggregation levels by the terminal, the redundancy of the 1st DCI can be adjusted according to the line quality between the base station and the terminal.

[Overview of communication system]
The communication system according to each embodiment of the present disclosure includes a base station 100 and a terminal 200.

FIG. 1 is a block diagram showing a configuration of a base station 100 according to an embodiment of the present disclosure. In the base station 100 shown in FIG. 1, the DCI generation unit 101 generates the first downlink control information (first DCI) and the second downlink control information (second DCI), and the transmission unit 105 generates the first DCI, the second DCI, and the DL. Send a data signal. The transmission unit 105 transmits the second DCI with a resource set based on the information regarding the first DCI or the information regarding the DL data signal specified by the first DCI.

FIG. 2 is a block diagram showing a configuration of the terminal 200 according to the embodiment of the present disclosure. In the terminal 200 shown in FIG. 2, the DCI receiving unit 203 receives the first DCI and the second DCI, and the signal separation unit 202 separates the DL data signal using the first DCI and the second DCI. The DCI receiving unit 203 identifies the resource of the second DCI based on the information about the first DCI or the information about the DL data signal specified by the first DCI.

(Embodiment 1)
[Base station configuration]
FIG. 3 is a block diagram showing the configuration of the base station 100 according to the present embodiment. In FIG. 3, the base station 100 includes a DCI generation unit 101, an error correction coding unit 102, a modulation unit 103, a signal allocation unit 104, a transmission unit 105, a reception unit 106, and a signal separation unit 107. It has a demodulation unit 108 and an error correction / decoding unit 109.

The DCI generation unit 101 generates a DL data signal or a DL control signal (DCI) to which a UL data signal is assigned. The DCI generation unit 101 includes a first DCI generation unit 1011 and a second DCI generation unit 1012. For example, when the generated control signal is long (for example, when it is longer than a set threshold value), the DCI generation unit 101 divides the generated control signal into a first DCI and a second DCI.

The first DCI generation unit 1011 generates the first DCI. The first DCI includes, for example, information indicating whether or not the data signal assigned by the control signal is a retransmission signal, a HARQ process number (process ID), an SRS (Sounding Reference Signal) request, and a data MCS (Modulation and Coding Scheme). ) Etc. may be included. Here, the SRS request may be included in the first DCI in order to secure the time for generating the reference signal on the transmitting side (terminal 200). Further, the information indicating whether or not the signal is a retransmission signal and the control signal indicating the HARQ process number are used for determining whether or not to delete the buffer at the terminal 200 and preparing for the allocation of the DL data signal. It may be arranged in the first DCI to secure the time, and may be included in the first DCI in the case of allocation of the uplink data signal in order to secure the time for preparing the transmission signal in the terminal 200. Further, in the case of allocation of DL data signals, the first DCI may include a control signal or the like for specifying a region (channel estimation region) in which the terminal 200 performs channel estimation.

The second DCI generation unit 1012 generates the second DCI. The second DCI contains, for example, the remaining information of the generated control signal that is not included in the first DCI.

In the DCI generation unit 101, which information is to be arranged in each of the first DCI and the second DCI may be variably determined, and the information that cannot be arranged in the first DCI may be arranged in the second DCI. Further, when the amount of information of the generated control signal is small, the DCI generation unit 101 may generate the first DCI and may not generate the second DCI.

The DCI generation unit 101 outputs the generated DCI (first DCI, or first DCI and second DCI) to the signal allocation unit 104. Further, the DCI generation unit 101 outputs the DL allocation information of the generated DCI to the signal allocation unit 104, and outputs the UL allocation information to the signal separation unit 107.

The error correction coding unit 102 error-corrects and encodes the transmission data signal (DL data signal), and outputs the coded signal to the modulation unit 103.

The modulation unit 103 performs modulation processing on the signal received from the error correction coding unit 102, and outputs the modulated signal to the signal allocation unit 104.

The signal allocation unit 104 is a DL data signal received from the modulation unit 103 and a DCI (first DCI and second DCI) which is a control signal received from the DCI generation unit 101 based on the DL allocation information input from the DCI generation unit 101. Is assigned to the downlink resource. Specifically, the signal allocation unit 104 allocates the DL data signal to the data area based on the DL allocation information included in the first DCI or the second DCI.

Further, the signal allocation unit 104 arranges the first DCI in the search space of the first DCI. Here, the Aggregation level of the 1st DCI is determined from the line quality and the amount of information of the 1st DCI. In addition, the resource to which the second DCI is assigned (resource size and resource area (location)) is specified from the signal included in the first DCI for a different purpose from the signal related to the second DCI, or the information specifying the first DCI (). Details will be described later). In this way, the transmission signal is formed. The formed transmission signal is output to the transmission unit 105.

The transmission unit 105 performs wireless transmission processing such as up-conversion on the transmission signal input from the signal allocation unit 104, and transmits the transmission signal to the terminal 200 via the antenna.

The receiving unit 106 receives the signal transmitted from the terminal 200 via the antenna, performs wireless reception processing such as down-conversion on the received signal, and outputs the received signal to the signal separation unit 107.

The signal separation unit 107 separates the UL data signal from the received signal received from the reception unit 106 based on the UL allocation information input from the DCI generation unit 101, and outputs the UL data signal to the demodulation unit 108.

The demodulation unit 108 performs demodulation processing on the signal input from the signal separation unit 107, and outputs the obtained signal to the error correction decoding unit 109.

The error correction decoding unit 109 decodes the signal input from the demodulation unit 108 and obtains the received data signal (UL data signal) from the terminal 200.

[Terminal configuration]
FIG. 4 is a block diagram showing the configuration of the terminal 200 according to the present embodiment. In FIG. 4, the terminal 200 includes a receiving unit 201, a signal separating unit 202, a DCI receiving unit 203, a channel estimation unit 204, a demodulation unit 205, an error correction decoding unit 206, and an error correction coding unit 207. , A modulation unit 208, a signal allocation unit 209, and a transmission unit 210.

The receiving unit 201 receives the received signal via the antenna, performs reception processing such as down-conversion on the received signal, and then outputs the received signal to the signal separation unit 202.

The signal separation unit 202 separates the signal arranged in the resource (search space area) to which the first DCI may be allocated from the reception signal received from the reception unit 201, and separates the signal arranged in the DCI reception unit 203 (the first DCI reception described later). Output to unit 2031). Further, the signal separation unit 202 identifies the resource of the second DCI based on the information input from the DCI reception unit 203 (information used for specifying the resource of the second DCI), and separates the second DCI from the received signal. Then, it is output to the DCI receiving unit 203 (the second DCI receiving unit 2032 described later).

Further, the signal separation unit 202 outputs the signal in the DL data area of the received signals to the channel estimation unit 204 based on the DL allocation information input from the DCI reception unit 203 or the information indicating the channel estimation area. Further, the signal separation unit 202 separates the DL data signal from the reception signal and outputs it to the demodulation unit 205 based on the DL allocation information input from the DCI reception unit 203.

The DCI receiving unit 203 receives a control signal (DCI) indicating the allocation of the DL data signal or the UL data signal. The DCI receiving unit 203 includes a first DCI receiving unit 2031 and a second DCI receiving unit 2032. When the DCI receiving unit 203 receives the DCI including the DL resource allocation information, the DCI receiving unit 203 outputs the DCI to the signal separation unit 202, and when receiving the DCI including the UL resource allocation information, the DCI receiving unit 203 outputs the DCI to the signal allocation unit 209. do.

Specifically, the first DCI receiving unit 2031 attempts to decode the signal of the resource to which the first DCI may be assigned (that is, the search space signal) received from the signal separation unit 202, and detects the first DCI. And receive. Further, the first DCI receiving unit 2031 outputs information used for specifying the resource to which the second DCI is allocated to the signal separation unit 202. The information used to identify the resource to which the second DCI is assigned is not the information notified to identify the resource of the second DCI itself, but information for other purposes, such as the aggregation level of the first DCI. Code rate, channel estimation area, etc.

The second DCI receiving unit 2032 receives the signal in the resource area to which the second DCI is assigned received from the signal separating unit 202.

The channel estimation unit 204 performs channel estimation for the signal in the DL data area (that is, the channel estimation area) received from the signal separation unit 202. The channel estimation unit 204 outputs channel estimation information indicating the channel estimation result to the demodulation unit 205.

The demodulation unit 205 demodulates the signal received from the signal separation unit 202 based on the channel estimation information received from the channel estimation unit 204, and outputs the demodulated signal to the error correction decoding unit 206.

The error correction decoding unit 206 decodes the demodulation signal received from the demodulation unit 205 and outputs the obtained received data signal.

The error correction coding unit 207 performs error correction coding of the transmission data signal (UL data signal) and outputs the encoded data signal to the modulation unit 208.

The modulation unit 208 modulates the data signal received from the error correction coding unit 207, and outputs the modulated data signal to the signal allocation unit 209.

The signal allocation unit 209 allocates the data signal input from the modulation unit 208 to the resource based on the UL allocation information received from the DCI reception unit 203, and outputs the data signal to the transmission unit 210.

The transmission unit 210 performs transmission processing such as up-conversion on the signal input from the signal allocation unit 209, and transmits the signal via the antenna.

[Operation of base station 100 and terminal 200]
The operation of the base station 100 and the terminal 200 having the above configuration will be described in detail.

FIG. 5 is a flowchart showing the operation of the base station 100, and FIG. 6 is a flowchart showing the operation of the terminal 200.

When the base station 100 generates the first DCI and the second DCI (ST101), the base station 100 determines the resource (resource size) of the second DCI based on the information contained in the first DCI (information about the DL data signal, etc.) or the information about the first DCI. (ST102). The details of the method for determining the resource of the second DCI will be described later. Then, the base station 100 transmits the first DCI and the second DCI to the terminal 200 (ST103), and transmits the DL data signal indicated by the first DCI and the second DCI to the terminal 200 (ST104).

On the other hand, when the terminal 200 receives the first DCI from the base station 100 (ST201), the terminal 200 obtains the resource (resource size) of the second DCI based on the information contained in the first DCI (information about the DL data signal, etc.) or the information about the first DCI. Identify (ST202). The details of the method for specifying the resource of the second DCI will be described later. Then, the terminal 200 receives the second DCI based on the specified resource of the second DCI (ST203), and receives the DL data signal based on the received first DCI and the second DCI (ST204).

That is, the resource to which the second DCI is assigned is implicitly notified to the terminal 200 by the information included in the first DCI and used for other purposes or the information set in the first DCI. As a result, the information for notifying the resource of the second DCI itself becomes unnecessary, and it is possible to prevent the amount of information of the first DCI from increasing.

In this embodiment, a method of determining / specifying the size (resource size) of the second DCI from the first DCI will be described.

Here, the size of the second DCI indicates the Aggregation level or the coding rate of the DCI.

Aggregation level is used as a value indicating the amount of DCI resources in LTE / LTE-Advance. The higher the Aggregation level, the greater the amount of DCI resources. In LTE, when DCI is transmitted in the PDCCH (Physical Downlink Control Channel) area, Aggregation level 1 is 1CCE (Control Channel Element). Note that 1CCE is composed of 36RE (Resource Element). Similarly, Aggregation level 1 is 2CCE (72REs), Aggregation level 4 is 4CCE (144REs), and Aggregation level 8 is 8CCE (288REs).

The coding rate indicates the ratio of redundant bits added to the information bits. For example, when two redundant bits are added to one information bit, the coding rate is 1/3. That is, the lower the coding rate, the higher the redundancy, and when sending the same information bit, a large amount of resources is required.

Hereinafter, operation example 1-1 and operation example 1-2 according to the present embodiment will be described.

<Operation example 1-1>
In operation example 1-1, the size of the second DCI is determined according to the Aggregation level of the first DCI.

The Aggregation level of the first DCI is the Aggregation level at the time when the first DCI is blindly decoded in the terminal 200 and the first DCI addressed to the terminal 200 is detected. That is, since the terminal 200 specifies the size of the second DCI according to the Aggregation level of the first DCI specified by the blind decoding, signaling for notifying the terminal 200 of the size of the second DCI becomes unnecessary.

For example, it is assumed that the first DCI and the second DCI are transmitted from the same base station 100 and received by the same terminal 200. In this case, it can be assumed that the reception quality of the first DCI (for example, SINR (Signal to Interference and Noise Ratio)) and the reception quality of the second DCI are equivalent.

Here, when the amount of information (the number of information bits) is the same between the 1st DCI and the 2nd DCI and the target error rate is also the same, as shown in FIG. 7, the Aggregation level of the 2nd DCI is the 1st DCI. The same value as the Aggregation level of may be set. The values of the Aggregation level of the first DCI and the Aggregation level of the second DCI are not limited to the cases shown in FIG. 7.

That is, the base station 100 allocates and transmits the second DCI according to the Aggregation level associated with the Aggregation level of the first DCI. Further, the terminal 200 identifies and receives the detected Aggregation level associated with the Aggregation level of the first DCI as the Aggregation level of the second DCI.

Further, when the amount of information (number of information bits) differs between the first DCI and the second DCI, the Aggregation level of the second DCI may be determined using the following (Equation 1).
2nd DCI Aggregation level = 2nd DCI information bits / 1st DCI information bits * 1st DCI Aggregation level (Equation 1)

In (Equation 1), the ratio of the number of information bits between the first DCI and the second DCI is obtained by (the number of information bits of the second DCI / the number of information bits of the first DCI). That is, if the number of information bits of the second DCI is twice the number of information bits of the first DCI, the Aggregation level of the second DCI is also twice the Aggregation level of the first DCI.

If the result of (Equation 1) is not an integer, it may be rounded, rounded down, or rounded up to an integer. Further, when a defined value such as 1,2,4,8,16 is used as the Aggregation level, the result of (Equation 1) may be converged to the defined value.

Next, a case where the size of the second DCI is defined not by the Aggregation level but by the coding rate will be described.

As shown in FIG. 8, the coding rate of the second DCI is determined according to the Aggregation level of the first DCI.

That is, the base station 100 sets the coding rate associated with the Aggregation level of the first DCI to the second DCI and transmits the code. Further, the terminal 200 specifies the code rate associated with the detected Aggregation level of the first DCI as the code rate of the second DCI.

In FIG. 8, the coding rate of the second DCI associated with the Aggregation level 1 of the first DCI is set to 4/5, and when the Aggregation level of the first DCI becomes X times (X = 2, 4, 8 in FIG. 8), The code rate of the second DCI is 1 / X. That is, the larger the Aggregation level of the 1st DCI (the larger the resource amount of the 1st DCI), the lower the coding rate of the 2nd DCI. In other words, the larger the Aggregation level of the 1st DCI, the larger the resource amount of the 2nd DCI. The correspondence between the Aggregation level of the first DCI and the coding rate of the second DCI is not limited to the case shown in FIG.

Further, the following (Equation 2) may be used to obtain the code rate of the second DCI so that the code rate of the first DCI and the code rate of the second DCI are equal to each other.
2nd DCI code rate = 1st DCI information bit number / (Number of REs that transmitted 1st DCI * 2) (Equation 2)

In (Equation 2), (number of first DCI information bits / (number of REs transmitted the first DCI * 2)) indicates the coding rate when the first DCI is QPSK-modulated (number of modulation multi-values = 2).

As described above, Operation Example 1-1 pays attention to the relationship between the reception quality of the first DCI and the reception quality of the second DCI. Therefore, in the operation example 1-1, when the first DCI and the second DCI are arranged in the same or close symbols or PRB (Physical Resource Block), or when the same antenna port and the same transmission scheme are used. It is valid.

When the Aggregation level is used as the size of the 2nd DCI, it is possible that the resource amount (RE number) of the Aggregation level 1 of the 1st DCI is not equal to the resource amount of the Aggregation level 1 of the 2nd DCI. For example, the number of REs per CCE differs between the 1st DCI and the 2nd DCI. In this case, the base station 100 and the terminal 200 may perform operations using additional variables for achieving the same coding rate (resource amount) between the first DCI and the second DCI.

<Operation example 1-2>
In operation example 1-2, the size of the second DCI is determined according to the MCS of PDSCH (Physical Downlink Shared Channel) which is the data (DL data signal) indicated by the first DCI.

The data MCS represents the data reception quality predicted by the base station 100.

When the second DCI is placed in the resource area of the data (PDSCH), it can be assumed that the reception quality of the second DCI (for example, SINR) is equivalent to the reception quality of the PDSCH.

Therefore, when the size of the second DCI is determined by the Aggregation level, as shown in FIG. 9, the Aggregation level of the second DCI is determined according to the MCS of the data (PDSCH). In FIG. 9, the modulation method of the second DCI is QPSK. The association between the MCS of the data and the Aggregation level of the second DCI is not limited to the case shown in FIG.

The base station 100 assigns and transmits the second DCI according to the Aggregation level associated with the MCS of the data specified by the first DCI. Further, the terminal 200 identifies and receives the Aggregation level associated with the MCS of the detected data specified by the first DCI as the Aggregation level of the second DCI.

As shown in FIG. 9, when the MCS Index (I _MCS ) is small, assuming that the reception quality is poor, the modulation order is also low at QPSK (Q _m = 2), and the coding rate is low. Will also be low. Also, the smaller the MCS Index, the smaller the TBS Index (I _TBS ). The smaller the TBS Index, the smaller the allocated TBS (Transport block size) (see, for example, Non-Patent Document 3). That is, the smaller the MCS Index, the smaller the TBS Index, the smaller the number of information bits, and the larger the number of redundant bits, so the coding rate becomes lower. That is, in FIG. 9, assuming that the smaller the MCS Index, the larger the amount of information in the second DCI, a large value is associated with the Aggregation level of the second DCI.

In addition, in FIG. 9, the case where the MCS Index and the Aggregation level of the second DCI are associated with each other has been described. However, as shown in FIG. 10, the data modulation method (Modulation order Q _m ) and the Aggregation level of the second DCI are associated with each other. You may.

Next, a case where the size of the second DCI is defined by the coding rate instead of the Aggregation level will be described.

The coding rate of the second DCI may be determined from the MCS of the data indicated by the first DCI based on the following (Equation 3).
Code rate of 2nd DCI = Transport block size / (N_PRB * Number of REs per PRB * Modulation order * Number of layers) (Equation 3)

In (Equation 3), N_PRB indicates the number of PRBs to which data is assigned. Further, the denominator in (Equation 3) indicates the number of bits that can be transmitted in the allocated data area. For example, the larger the Modulation order, the more bits can be sent per PRB. Also, as the number of layers of spatial multiplexing increases, the number of bits that can be transmitted per PRB also increases. Further, the numerator in (Equation 3) indicates the number of information bits.

The resource amount (number of REs) of the second DCI is obtained from the following (Equation 4).
Amount of resources in the 2nd DCI = Number of information bits in the 2nd DCI / (Code rate of the 2nd DCI * Modulation order of the 2nd DCI * Number of layers in the 2nd DCI) (Equation 4)

If the resource amount of the 2nd DCI is expressed for each unit consisting of multiple REs such as CCE unit, PRB unit, mini-slot unit, etc., rounding, rounding up, rounding down, etc. should be adjusted to match that unit. Then, the resource amount of the second DCI may be determined.

Further, in the above, the case where the coding rate is the same for the data and the second DCI has been described, but the desired error rate required for the second DCI is the desired error rate required for the second DCI in the desired error rate required for the data and the desired error rate required for the second DCI. Is considered to be low. Therefore, the code rate of the second DCI obtained by (Equation 3) may be multiplied by 1 / N to make the code rate of the second DCI lower than the code rate of the data.

Further, as shown in FIG. 11, the base station 100 and the terminal 200 include a table in which the MCS of the data and the code rate or the amount of resources of the second DCI are associated with each other, and the MCS of the data is referred to by referring to the table. The code rate of the second DCI or the amount of resources may be determined from.

The desired coding rate of the second DCI shown in FIG. 11 is obtained by the following (Equation 5).
Desired code rate of 2nd DCI = 1/2 * Transport block size / (N_PRB * Number of REs per PRB * Modulation order * Number of layers) (Equation 5)

In FIG. 11, the N_PRB of the data in (Equation 5) is 8, the number of REs per PRB is 138, the number of layers is 1, and the second DCI is multiplied by 1/2 in order to make the coding rate of the second DCI lower than that of the data. There is.

Further, the number of CCEs (number of 40bit CCEs, number of 20bit CCEs) when the number of information bits of the second DCI shown in FIG. 11 is 40 bits and 20 bits is the number of CCEs required when the number of REs per CCE is assumed to be 36. I'm calculating. Moreover, the modulation multivalue number of the second DCI was assumed to be 2 (QPSK). In this case, the number of CCEs of the second DCI is calculated by the following (Equation 6).
Number of CCE = ceiling (number of information bits / desired code rate / 2/36) (Equation 6)

The operation examples 1-1 and 1-2 for determining the size of the second DCI have been described above.

Thus, in this embodiment, the size of the second DCI is determined according to the information about the first DCI (here Aggregation level) or the information indicated by the first DCI (here the MCS of the data). As a result, the base station 100 can implicitly notify the size of the second DCI using the first DCI, and the terminal 200 can specify the size of the second DCI using the first DCI. That is, according to the present embodiment, the size of the second DCI can be notified to the terminal 200 without increasing the number of information bits of the first DCI. Therefore, according to the present embodiment, the terminal 200 can appropriately specify the resource in which the second DCI is arranged.

(Embodiment 2)
In order to perform data channel estimation in the UE at an early stage, it is conceivable that the base station notifies the resource area (channel estimation area) for channel estimation in the first DCI and notifies the detailed resource allocation in the second DCI. .. In this case, the first DCI is arranged in front of the transmission unit (subframe / slot / mini-slot / sub-slot) on the time axis. After receiving the first DCI, the UE starts channel estimation and then receives the second DCI.

[Task]
In the above operation, for example, as shown in FIG. 12A, the data area (channel estimation area) notified by the first DCI is a range in which the UE performs channel estimation, and the actually allocated data notified by the second DCI. It may be larger than the area (PDSCH resource area; area shown by UE1 data in FIG. 12A). Further, as shown in FIG. 12A, it is conceivable that the second DCI is arranged in the data area.

As shown in FIG. 12A, when the frequency resource in which the second DCI is arranged is included in the frequency resource to which the data (UE1 data) is assigned, UE1 receives the second DCI and then the second DCI is assigned which frequency resource. Since it can be specified, it is possible to recognize that the area other than the area where the second DCI is arranged is the resource in which the data is arranged.

However, as shown in FIG. 12B, when the frequency resource in which the second DCI for UE1 is placed is placed in the frequency resource to which the data of UE1 is not assigned (the resource surrounded by the dotted line in FIG. 12B), the base is used. The problem is that it is difficult for the station to assign the symbol behind the frequency resource to which the data of UE1 is not assigned to UE2. Since UE2 cannot detect the second DCI other than the one addressed to UE2, it cannot identify in which area the second DCI addressed to UE1 is located. Therefore, when allocating the data of the UE, the base station has a problem that the data of the UE cannot be allocated to the frequency resource in which the second DCI of the other UE is arranged. Further, for example, in FIG. 12B, when the base station allocates a frequency resource in which the second DCI of UE1 is arranged to UE2, the symbol # excluding the symbol # 1 in which the second DCI of UE1 is arranged # 1. It is necessary to allocate frequency resources of 2 or higher, which complicates the process.

Therefore, in the present embodiment, a method of appropriately specifying the frequency resource (resource position) in which the second DCI is arranged will be described.

Since the base station and the terminal according to the present embodiment have the same basic configuration as the base station 100 and the terminal 200 according to the first embodiment, FIGS. 3 and 4 will be referred to for description.

Specifically, the base station 100 determines the resource (resource area) of the second DCI based on the information indicating the channel estimation area included in the first DCI (ST102 shown in FIG. 5). On the other hand, the terminal 200 identifies the resource (resource area) of the second DCI based on the information indicating the channel estimation area included in the first DCI notified from the base station 100 (ST202 shown in FIG. 6).

That is, as in the first embodiment, the resource to which the second DCI is assigned is implicitly notified to the terminal 200 by the information contained in the first DCI and used for other purposes. As a result, the information for notifying the resource of the second DCI itself becomes unnecessary, and it is possible to prevent the amount of information of the first DCI from increasing.

Hereinafter, the method of specifying the frequency domain of the second DCI from the information contained in the first DCI will be described in detail.

[Operation example 2-1]
In operation example 2-1 as shown in FIG. 13, the second DCI is arranged in the frequency domain at the center of the channel estimation region indicated by the first DCI.

That is, the base station 100 arranges the second DCI in the frequency domain at the center of the channel estimation region designated by the first DCI, and transmits the second DCI. Further, the terminal 200 specifies the frequency domain at the center of the channel estimation region designated by the first DCI as the region in which the second DCI is arranged, and receives the second DCI.

In this case, as shown in FIG. 13, the base station 100 may allocate data to the terminal 200 so as to include the frequency domain in which the second DCI is arranged. Further, when the base station 100 indicates the channel estimation area by the first DCI, it is assumed that the data of UE1 is allocated to the frequency domain at the center of the channel estimation area, and the data between UE1 and another user (UE2). The amount of resources in the allocation is adjusted mainly at the edge of the channel estimation area.

For example, in FIG. 13, the second DCI of UE1 and the second DCI of UE2 are arranged in the frequency domain at the center of each channel estimation region. In this case, the base station 100 adjusts the amount of resources between UE1 and UE2 in the section where the channel estimation areas overlap between the UEs.

As a result, as shown in FIG. 13, as a result of the resource amount adjustment between the UEs in the base station 100, the possibility that the second DCI for the terminal 200 is allocated outside the range of the data area for the terminal 200 is reduced. Therefore, in the base station 100, it is possible to prevent the data of other UEs from being unassigned by the frequency resource in which the second DCI for the terminal 200 is arranged. After receiving the second DCI, the terminal 200 can recognize the area other than the area where the second DCI is arranged as a resource in which the data is arranged.

The method of operation example 2-1 (FIG. 13) is particularly suitable when it is assumed that data of a plurality of terminals 200 are continuously allocated in the frequency direction. For example, in FIG. 13, data is allocated to UE1 and UE2 at the same time, and there is an overlapping portion in the channel estimation area indicated by the first DCI for UE1 and UE2, respectively.

[Operation example 2-2]
In operation example 2-2, as shown in FIG. 14, the second DCI is arranged in the frequency domain at the end of the channel estimation region indicated by the first DCI. As the frequency domain in which the second DCI is arranged, there are cases where one end of the channel estimation area is used and cases where both ends are used.

That is, the base station 100 arranges the second DCI in the frequency domain at the end of the channel estimation region designated by the first DCI, and transmits the second DCI. Further, the terminal 200 specifies the frequency domain at the end of the channel estimation region designated by the first DCI as the region in which the second DCI is arranged, and receives the second DCI.

In this case, as shown in FIG. 14, the base station 100 may allocate data to the terminal 200 so as to include the frequency domain in which the second DCI is arranged. Further, when the base station 100 indicates the channel estimation area by the first DCI, it is assumed that the data of UE1 is allocated to the frequency domain at the end of the channel estimation area, and the data between the UE and another user (UE2). The amount of resources in the allocation is adjusted mainly outside the edge of the channel estimation area.

For example, in FIG. 14, data is assigned to UE1 and UE2 at the same time. In FIG. 14, the second DCI of each UE is located at one end of the channel estimation region of each UE. In this case, the base station 100 may arrange the data for each UE at one end of the channel estimation area in which the second DCI is arranged.

Further, in FIG. 14, the frequency domain in which the second DCI of UE1 is arranged is included in the channel estimation region of UE2. In this case, the base station 100 may arrange the data of UE2 while avoiding the frequency domain in which the second DCI of UE1 is arranged. For example, when the base station 100 indicates the channel estimation area by the first DCI, the base station 100 determines the data allocation in the frequency domain (that is, the area in which the second DCI is arranged) at both ends of the channel estimation area, and allocates the data in the other areas. Adjust the amount of resources in. That is, in FIG. 14, the base station 100 is a resource between UE1 and UE2 in a region other than the frequency domain in which the second DCI of UE1 is arranged in the section where the channel estimation regions overlap between the UEs. You can adjust the amount.

As a result, as shown in FIG. 14, as a result of the resource amount adjustment between the UEs in the base station 100, the possibility that the second DCI for the terminal 200 is allocated outside the range of the data area for the terminal 200 is reduced. Therefore, in the base station 100, it is possible to prevent the data of other UEs from being unassigned by the frequency resource in which the second DCI for the terminal 200 is arranged. After receiving the second DCI, the terminal 200 can recognize the area other than the area where the second DCI is arranged as a resource in which the data is arranged.

Further, in FIG. 15, data is assigned to UE1 and UE2 at the same time. In FIG. 15, the second DCI of each UE is arranged at both ends of the channel estimation area of each UE. In this case, the base station 100 may arrange data at both ends of the channel estimation area in which the second DCI is arranged for each UE.

As shown in FIG. 15, when the second DCI is arranged at both ends of the channel estimation region, the second DCI is arranged at a position separated in the frequency domain, so that the frequency diversity effect can be obtained. FIG. 15 is particularly suitable when data is allocated discontinuously.

[Operation example 2-3]
In Operation Example 2-3, as shown in FIG. 16, the second DCI is arranged in a region adjacent to the frequency domain in which the first DCI is arranged.

In this case, that is, the base station 100 arranges the second DCI in the frequency domain adjacent to the frequency domain to which the first DCI is allocated, and transmits the second DCI. Further, the terminal 200 specifies a frequency domain adjacent to the frequency domain in which the first DCI is detected as a region in which the second DCI is arranged, and receives the second DCI. The terminal 200 determines the placement of the second DCI based on the region where the first DCI is detected for the terminal 200, not the search space of the first DCI.

It should be noted that the adjacent regions include that they are adjacent in the frequency domain and that they are logically adjacent (for example, the CCE numbers are continuous). Further, the adjacent region may include a region to which a certain offset is added.

It is conceivable that the base station 100 allocates data to the terminal 200 so as to include the frequency domain in which the first DCI is arranged when the channel estimation region is indicated by the first DCI. Therefore, as shown in FIG. 16, by allocating data to the area adjacent to the area where the first DCI is arranged and allocating the second DCI, the second DCI for the terminal 200 becomes the data area for the terminal 200. It is less likely to be assigned out of range. Therefore, in the base station 100, it is possible to prevent the data of other UEs from being unassigned by the frequency resource in which the second DCI for the terminal 200 is arranged.

Further, as shown in FIG. 16, by allocating the data to the area adjacent to the area where the first DCI is arranged, the allocation becomes continuous, so that the channel estimation area can be limited.

Further, in the operation example 2-3, by excluding the area where the terminal 200 has detected the first DCI and the second DCI (symbol # 0 in FIG. 16) from the data allocation area, the base station 100 has the first DCI and the second DCI. Data can be placed from the first symbol in the frequency domain that is not placed (symbol # 1 or later).

[Operation example 2-4]
In operation example 2-4, as shown in FIG. 17, the second DCI is distributed in the frequency domain at each X interval from the start position determined based on the channel estimation region specified by the first DCI.

In FIG. 17, the start position of the region where the second DCI is arranged is one end of the channel estimation region indicated by the first DCI, and the second DCI is divided into four and distributed in the frequency domain. Further, in FIG. 17, the frequency interval (interval) in which the second DCI of each UE is arranged is set as a common value among the UEs. The interval may differ between UEs.

In this case, the base station 100 may allocate data to the terminal 200 so as to include a frequency domain in which the second DCI is arranged. Further, when the base station 100 indicates the channel estimation area by the first DCI, it is assumed that the data is allocated to the frequency domain at the end of the channel estimation area and the frequency domain in which the second DCI determined from the interval is arranged. Adjust the amount of resources in data allocation with other users in the area where the second DCI is not placed.

As a result, as shown in FIG. 17, as a result of the resource amount adjustment between the UEs in the base station 100, the possibility that the second DCI for the terminal 200 is allocated outside the range of the data area for the terminal 200 is reduced. Therefore, in the base station 100, it is possible to prevent the data of other UEs from being unassigned by the frequency resource in which the second DCI for the terminal 200 is arranged.

In addition, by setting the interval to a predetermined value, there is an advantage that if the start position of the frequency domain in which the second DCI is arranged is different between the UEs, the possibility of the second DCI colliding between different UEs is reduced. .. It is also conceivable to make the interval variable according to the size of the channel estimation area, such as setting a large interval when the channel estimation area is large. Determining the interval according to the size of the channel estimation area has the advantage that the frequency diversity effect is higher because the second DCI is placed over the entire channel estimation area.

Further, here, the case where the start position of the frequency domain in which the second DCI is arranged is the end of the channel estimation region has been described, but the present invention is not limited to this, and UEID, cell ID, group ID, subcell ID, etc. The position determined from the information of may be set as the start position.

Also, the interval may be set within the channel estimation area. If the channel estimation regions are not continuous on the frequency axis, the PRBs in the channel estimation region may be logically arranged and intervals may be set. In this case, the interval may not be physically constant.

Also, the interval does not have to be constant. An interval may be set between the base station 100 and the terminal 200, and the interval of each DCI distributed may be determined according to the interval.

The method of specifying the frequency domain of the second DCI according to the present embodiment has been described above.

As described above, according to the present embodiment, the frequency domain in which the second DCI for the terminal 200 is arranged is determined based on the information (channel estimation region) instructed by the first DCI. At this time, resources are allocated to the data so that the second DCI is placed in the area where the data (PDSCH) is placed. As a result, the base station 100 can prevent the data of the other terminal 200 from being unable to be allocated by the frequency resource in which the second DCI for the certain terminal 200 is arranged among the plurality of terminals 200. That is, the base station 100 can easily allocate resources in data allocation among a plurality of terminals 200.

Further, the base station 100 can implicitly notify the frequency domain of the second DCI by using the first DCI, and the terminal 200 can specify the frequency domain of the second DCI by using the first DCI. That is, according to the present embodiment, the frequency domain of the second DCI can be notified to the terminal 200 without increasing the number of information bits of the first DCI. Therefore, according to the present embodiment, the terminal 200 can appropriately specify the resource in which the second DCI is arranged.

[Modified Example of Embodiment 2]
Although the case where the data is allocated to the area where the second DCI is arranged in the present embodiment has been described, the data may not be allocated to the area where the second DCI is arranged. In particular, if data with a short number of symbols such as URLLC is expected to be inserted, if a reference signal is placed, or if other services such as MBMS are inserted, DCI is placed in front of the symbol. In that case, it is also effective not to allocate data in the symbol behind.

Further, although the physical mapping is shown as an example of the frequency domain, a logical mapping may be used. In the case of logical mapping, the mapping is changed from logical mapping to physical mapping, so even if the frequency domain is continuous when FIGS. 13 to 17 are regarded as logical mapping, it is physical. Since it can be placed at a remote position, a frequency diversity effect can be obtained.

Further, in the above embodiment, the case where the channel estimation area is a continuous resource is shown, but the present invention is not limited to this, and the channel estimation area may be a discontinuous resource.

Further, in addition to the above, the offset of the area where the second DCI is arranged may be determined from the parameters such as cell ID, sub-cell ID, group ID, and UE ID.

Further, the data assigned by the second DCI is received by the terminal 200 when the error detection of the second DCI, for example, CRC becomes OK. Therefore, if the reception of the second DCI fails, the terminal 200 does not receive the data. Therefore, when the data allocation is specified to include the area of the second DCI, the terminal 200 determines that the data is not arranged in the area (RE) where the second DCI is arranged. That is, the area (RE) where the second DCI was placed is rate-matched.

It can also be assumed that the subcarrier spacing of the symbol in which the first DCI is placed is narrow (the symbol spacing is wide), and the subcarrier spacing of the symbol in which the second DCI and the data symbol are placed is wide (the symbol spacing is short). In such a case, the terminal 200 that uses different subcarrier intervals for the first DCI and the data transmission receives the first DCI, recognizes the data allocation and the data subcarrier interval, and makes the second DCI wider than the first DCI. It can be received at subcarrier intervals. In such a case, the symbol spacing of the second DCI can be shortened, so that the time required for transmitting the DCI can be shortened. Therefore, the effect of reducing the overhead of the control signal by dividing into the first DCI and the second DCI is high.

(Embodiment 3)
Since the base station and the terminal according to the present embodiment have the same basic configuration as the base station 100 and the terminal 200 according to the first embodiment, FIGS. 3 and 4 will be referred to and described.

In the present embodiment, the case where the terminal 200 receives both the first DCI and the second DCI and the case where the terminal 200 receives the first DCI without receiving the second DCI are defined.

Specifically, the base station 100 determines the resource (whether or not resource allocation is performed) of the second DCI based on the information set in the terminal 200 or the information included in the first DCI (ST102 shown in FIG. 5). On the other hand, the terminal 200 determines whether or not the second DCI is transmitted from the base station 100 based on the information set in the terminal 200 or the information included in the first DCI notified from the base station 100, and determines whether or not the second DCI is transmitted from the base station 100. The presence or absence of resource allocation is specified (ST202 shown in FIG. 6).

That is, the base station 100 determines the DCI to be used based on the information for the terminal 200, so that when the second DCI is unnecessary, the resource can be allocated using the first DCI. Further, as in the first embodiment, the resource to which the second DCI is assigned is implicitly notified to the terminal 200 by the information included in the first DCI and used for other purposes. As a result, the information for notifying the resource of the second DCI itself becomes unnecessary, and it is possible to prevent the amount of information of the first DCI from increasing.

The method for specifying the resource allocation of the second DCI will be described below.

[Operation example 3-1]
In operation example 3-1 the second DCI is used when the amount of resources allocated to the terminal 200 is large.

Here, the amount of resources allocated to the terminal 200 is (1) when the carrier bandwidth is wide (for example, when the bandwidth is equal to or greater than the threshold value), and (2) the bandwidth to be monitored individually specified for each UE is wide. When (for example, when the bandwidth is above the threshold value), (3) when the channel estimation area notified by the first DCI is wide (when the channel estimation area is above the threshold value), (4) the amount of resources allocated by the first DCI. (When the amount of resources is equal to or greater than the threshold value), etc. may be considered.

When the amount of resources allocated to the terminal 200 is large, the number of bits required for notification of allocation to the terminal 200 also increases. Therefore, it is effective to use the second DCI for the terminal 200. On the other hand, when the amount of resources allocated to the terminal 200 is small, using the second DCI to allocate the resources to the terminal 200 increases the overhead by adding CRC to both the first DCI and the second DCI, and the overhead is increased with respect to the amount of data. The overhead ratio of the control signal is high, which is inefficient.

[Operation example 3-2]
In operation example 3-2, the second DCI is used when the resource allocation method is significantly changed at the time of initial transmission or retransmission of HARQ.

When the HARQ is instructed to be retransmitted, the parameter used for the initial transmission may be diverted to the terminal 200. For example, for the channel estimation area, MCS, resource allocation, number of MIMO layers, etc., the parameters used in the initial transmission are used at the time of retransmission.

In this way, when there is a lot of information that can be diverted at the time of retransmission, the DCI length at the time of retransmission may be shorter than the DCI length at the time of initial transmission. Therefore, the base station 100 can suppress the overhead amount of DCI low by instructing using the first DCI instead of using the second DCI at the time of retransmission.

The terminal 200 can determine whether it is the first transmission or the retransmission based on whether or not the NDI (New data indicator) included in the first DCI is toggled.

In addition, it is effective to use the second DCI when resource allocation and MIMO-related information are renewed at the time of retransmission and the amount of information to be instructed using DCI is large.

[Operation example 3-3]
In operation example 3-3, it is determined whether or not the second DCI is used depending on the transmission mode or the transmission method (scheme).

For example, if spatial multiplexing sets a transmission mode or transmission method that supports multiple codewords, multiple layers, a second DCI may be used. Alternatively, if a transmission mode or transmission method using a large number of layers or a large number of antenna ports is set (for example, when the number of layers or the number of antenna ports is equal to or greater than the threshold value), the second DCI may be used.

When the number of codewords and layers is large, the amount of DCI information tends to be small. Therefore, when using a transmission mode or transmission method with a large amount of DCI information, the second DCI is used, and when using a transmission mode or transmission method with a small amount of DCI information, the second DCI is not used. , 1st DCI may be used. The parameter associated with the amount of DCI information is not limited to the codeword, layer, and antenna port, and may be other parameters.

The transmission mode or transmission method can also be specified from the DCI format of the first DCI. That is, the terminal 200 may determine whether or not the second DCI is used from the detected DCI format of the first DCI.

[Operation example 3-4]
In operation example 3-4, when the use of a narrow beam is assumed, the second DCI is used.

The case where a narrow beam is expected to be used is when a high band such as 6 GHz or higher is allocated. In this case, the use of both wide and narrow beams is envisioned. Further, when an analog beam is assumed, the beam is different for each symbol.

For example, a first DCI may be placed on a symbol transmitted by a wide beam and a second DCI may be placed on a rear symbol transmitted by a narrow beam. The search space of the first DCI transmitted by a wide beam is monitored by many terminals 200.

When each terminal 200 detects the first DCI destined for the own machine transmitted by the wide beam, it receives the UE-individual second DCI transmitted by the narrow beam according to the detected first DCI.

By doing so, the terminal 200 does not have to monitor the first DCI with all the symbols, so that the power consumption can be suppressed.

The terminal 200 may determine whether or not a narrow beam is used according to the frequency band to be set, or may determine whether or not a narrow beam is used, depending on the transmission method.

[Operation example 3-5]
In operation example 3-5, the second DCI is used when the symbol length of the DL data is long.

For example, the symbol length of the DL data may be notified by the first DCI, or may be notified by a control signal such as PCFICH (Physical Control Format Indicator Channel) which is notified separately from the DCI.

The terminal 200 determines that the second DCI is used when the symbol length of the DL data is long (when the symbol length is equal to or greater than the threshold value), and when the symbol length of the DL data is short (when the symbol length is less than the threshold value). It is determined that the 1st DCI is used instead of the 2nd DCI.

If the symbol length of the DL data is long, it can be assumed that the amount of resources allocated to the terminal 200 will be large. Therefore, it is effective to use the second DCI when the symbol length of DL data is long. On the other hand, when the symbol length of the DL data is short, it is assumed that the amount of resources allocated to the terminal 200 becomes small. When the amount of resources allocated to the terminal 200 is small, using the second DCI to allocate the resources to the terminal 200 increases the overhead by adding CRC to both the first DCI and the second DCI, and is a control signal for the amount of data. Overhead ratio is high, which is inefficient.

The method of specifying the resource allocation of the second DCI has been described above.

As described above, according to the present embodiment, the base station 100 and the terminal 200 have the second DCI as the base station based on the information regarding the DL data signal (or the information set in the terminal 200) instructed by the first DCI. It is determined whether or not the data is transmitted from 100 to the terminal 200. Specifically, the second DCI is transmitted when the resource amount (information amount) of DCI is large, and is not transmitted when the resource amount of DCI is small. That is, the ratio of the DCI overhead to the amount of data can be suppressed according to the amount of DCI resources.

Further, the base station 100 can implicitly notify the resource allocation of the second DCI (whether or not the resource is allocated) by using the first DCI, and the terminal 200 can implicitly notify the resource allocation of the second DCI by using the first DCI. Can be identified. That is, according to the present embodiment, it is possible to notify the terminal 200 of the resource allocation of the second DCI without increasing the number of information bits of the first DCI. Therefore, according to the present embodiment, the terminal 200 can appropriately specify the resource in which the second DCI is arranged.

The embodiments of the present disclosure have been described above.

In addition, at least two of the above-mentioned embodiments 1 to 3 may be combined. That is, the base station 100 and the terminal 200 have at least two of the first embodiment (setting the size of the second DCI), the second embodiment (frequency domain of the second DCI), and the third embodiment (presence / absence of the second DCI). May work in combination.

The present disclosure can be realized by software, hardware, or software linked with hardware. Each functional block used in the description of the above embodiment is partially or wholly realized as an LSI which is an integrated circuit, and each process described in the above embodiment is partially or wholly. It may be controlled by one LSI or a combination of LSIs. The LSI may be composed of individual chips, or may be composed of one chip so as to include a part or all of functional blocks. The LSI may include data input and output. LSIs may be referred to as ICs, system LSIs, super LSIs, and ultra LSIs depending on the degree of integration. The method of making an integrated circuit is not limited to LSI, and may be realized by a dedicated circuit, a general-purpose processor, or a dedicated processor. Further, an FPGA (Field Programmable Gate Array) that can be programmed after the LSI is manufactured, or a reconfigurable processor that can reconfigure the connection and settings of the circuit cells inside the LSI may be used. The present disclosure may be realized as digital processing or analog processing. Furthermore, if an integrated circuit technology that replaces an LSI appears due to advances in semiconductor technology or another technology derived from it, it is naturally possible to integrate functional blocks using that technology. The application of biotechnology may be possible.

The terminal of the present disclosure separates a downlink data signal from a received signal by using a receiver that receives a first downlink control signal and a second downlink control signal, and the first downlink control signal and the second downlink control signal. The receiver comprises a circuit, and the receiver obtains the resource of the second downlink control signal based on the information regarding the first downlink control signal or the information regarding the downlink data signal indicated by the first downlink control signal. Identify.

In the terminal of the present disclosure, the receiver specifies the resource size of the second downlink control signal according to the aggregation level of the first downlink control signal.

In the terminal of the present disclosure, the receiver specifies the resource size of the second downlink control signal according to the MCS (Modulation and Coding Scheme) of the downlink data signal indicated by the first downlink control signal.

In the terminal of the present disclosure, the second downlink control signal is arranged in the frequency domain in which the downlink data signal is arranged.

In the terminal of the present disclosure, the receiver specifies a frequency domain at the center of the channel estimation region indicated by the first downlink control signal as a region in which the second downlink control signal is arranged.

In the terminal of the present disclosure, the receiver specifies the frequency domain at the end of the channel estimation region indicated by the first downlink control signal as the region in which the second downlink control signal is arranged.

In the terminal of the present disclosure, the receiver specifies a frequency domain adjacent to the frequency domain in which the first downlink control signal is arranged as a region in which the second downlink control signal is arranged.

In the terminal of the present disclosure, the receiver determines whether or not the second downlink control information is transmitted based on the information regarding the downlink data signal indicated by the first downlink control signal.

The base station of the present disclosure includes a circuit that generates a first downlink control signal and a second downlink control signal, and a transmitter that transmits the first downlink control signal, the second downlink control signal, and the downlink data signal. Then, the transmitter transmits the second downlink control signal with a resource set based on the information regarding the first downlink control signal or the information regarding the downlink data signal indicated by the first downlink control signal.

In the communication method of the present disclosure, a first downlink control signal and a second downlink control signal are received, and the downlink data signal is separated from the received signal by using the first downlink control signal and the second downlink control signal. The resource of the second downlink control signal is specified based on the information regarding the first downlink control signal or the information regarding the downlink data signal indicated by the first downlink control signal.

The communication method of the present disclosure generates a first downlink control signal and a second downlink control signal, transmits the first downlink control signal, the second downlink control signal, and the downlink data signal, and the second downlink control signal is , Is transmitted by a resource set based on the information regarding the first downlink control signal or the information regarding the downlink data signal included in the first downlink control signal.

One aspect of the present disclosure is useful for mobile communication systems.

100 Base station 101 DCI generation unit 102, 207 Error correction coding unit 103, 208 Modulation unit 104, 209 Signal allocation unit 105, 210 Transmission unit 106, 201 Reception unit 107, 202 Signal separation unit 108, 205 Demodulation unit 109, 206 Error correction Decoding unit 200 Terminal 203 DCI receiving unit 204 Channel estimation unit

Claims (5)

A receiver that receives the first control signal and the second control signal,
A circuit that separates a data signal from a received signal using the first control signal and the second control signal.
Equipped with
The receiver identifies the resource of the second control signal based on the information about the data signal indicated by the first control signal, and corresponds to the MCS (Modulation and Coding Scheme) of the data signal. Specifying the resource size of the second control signal,
Terminal. The second control signal is arranged in the frequency domain in which the data signal is arranged.
The terminal according to claim 1. The receiver specifies a frequency domain at the center of the channel estimation region indicated by the first control signal as a region in which the second control signal is arranged.
The terminal according to claim 1. The receiver identifies the frequency domain at the end of the channel estimation region indicated by the first control signal as a region in which the second control signal is arranged.
The terminal according to claim 1. Receives the first control signal and the second control signal,
The data signal is separated from the received signal by using the first control signal and the second control signal.
The resource of the second control signal is specified based on the information about the data signal indicated by the first control signal, and the resource size of the second control signal is MCS (Modulation and Coding) of the data signal. Specified according to Scheme),
Communication method.

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