KR20090064299A - Method for mapping control channels - Google Patents

Abstract

A control channel mapping method for improving the performance of a control channel is provided to reduce the resources and interference between adjacent cells and improve the performance of the control channel. A control channel mapping start time point of each cell is computed according to the group number of control channels allocated at a cell. The control channel mapping start time point of each cell is set by using maximum value among the group number of the control channel allocated to each cell. The repetition of the control channel is mapped with the interval predetermining for the diversity gain. The control channel of the multiple groups is transmitted inside the cell.

Description

Method for mapping control channels

The present invention relates to a mapping scheme for a frequency and an OFDM symbol region of a signal transmitted in a downlink in a cellular OFDM wireless packet communication system.

When transmitting and receiving a packet in the mobile communication system, the receiver should inform the transmitter whether the packet reception was successful. If the packet reception is successful, the transmitter transmits an ACK to transmit a new packet. If the packet reception fails, the transmitter transmits a NACK to retransmit the packet. This operation is called an automatic request (ARQ). Hybrid ARQ (HARQ) has been proposed by combining ARQ operation with channel coding. In HARQ, retransmitted packets can be combined with previously received packets to lower the error rate and increase the efficiency of the entire system. In order to increase the throughput of the system, the HARQ requires a fast ACK / NACK response from the receiver, compared to the conventional ARQ operation. Therefore, in HARQ, ACK / NACK is transmitted by physical channel signaling. There are two ways of implementing HARQ. First is CC (Chase combining), which has the same modulation scheme and coding rate as a conventionally transmitted packet when retransmitted. Second, when retransmitting with incremental redundancy (IR), it has a modulation scheme and a coding rate different from that of a conventionally transmitted packet. In this case, the receiver may increase the performance of the system through coding diversity.

In a multi-carrier cellular mobile communication system, terminals belonging to one or more cells perform uplink data packet transmission to a base station. Since a plurality of terminals can transmit an uplink data packet in one subframe, the base station must also be able to transmit ACK / NACK signals to the plurality of terminals in one subframe. When the base station multiplexes a plurality of ACK / NACK signals transmitted to terminals in one subframe by CDMA within a partial time-frequency region of a downlink transmission band of a multicarrier system, ACK / NACK signals for other terminals. Are separated by orthogonal or quasi-orthogonal codes that are multiplied through the time-frequency domain. In addition, when performing QPSK transmission, it may be divided into two different orthogonal phase components.

When multiplexing each ACK / NACK signal by CDMA to transmit a plurality of ACK / NACK signals in one subframe, the downlink radio channel response characteristic in the time-frequency domain in which the ACK / NACK signal is transmitted is greatly increased. Should not change. Because orthogonality between different CDMA multiplexed ACK / NACK signals is preserved, satisfactory reception performance can be obtained at the receiving end without applying a special reception algorithm such as a channel equalizer. Therefore, CDMA multiplexing of ACK / NACK signals should be performed in the time-frequency domain where the radio channel response does not change significantly. However, if the radio channel quality for a particular terminal is poor in the time-frequency domain in which the ACK / NACK signal is transmitted, the ACK / NACK reception performance of the terminal may also be greatly degraded.

Accordingly, the ACK / NACK signal transmitted to any terminal in one subframe is repeatedly transmitted over time-frequency regions distributed on a plurality of time-frequency axes, and transmitted to other terminals in each time-frequency region. By multiplexing the ACK / NACK signal with the CDMA scheme, the receiver may obtain a time-frequency diversity gain in receiving the ACK / NACK signal.

An object of the present invention is to provide a control channel mapping method that can reduce interference between adjacent cells by improving a resource allocation method in control channel transmission.

In order to achieve the above technical problem, the control channel mapping method according to an embodiment of the present invention calculates the control channel mapping start time of each cell according to the number of groups of control channels allocated to each cell, and the control channel mapping start time Starting from and mapping the repetition of the control channel at predetermined intervals for diversity gain. Here, a plurality of groups of control channels are transmitted in each cell.

Preferably, in the process of calculating the control channel mapping start time, the control channel mapping start time of each cell may be determined using the maximum value of the number of groups of control channels allocated to each cell.

Preferably, in the process of calculating the control channel mapping start time, the control channel mapping start time of each cell may be determined using an average value of the number of groups of control channels allocated to each cell.

Preferably, in the process of calculating the control channel mapping start time, the channel allocation start time may be determined according to the number of groups of control channels of an adjacent cell.

의 수학식으로 결정할 수 있다. 여기서, N은 제어 채널 전송을 위해 할당할 수 있는 단위 자원의 수, N_cell은 간섭을 최소로 하는 셀의 수, N_rep는 제어 채널을 전송시의 반복 횟수를 나타내고,

은 물리계층 셀 아이디를 나타낸다. 이 경우, 상기 제어 채널의 반복을 매핑하는 과정에서, 상기 제어 채널의 i번째 반복 위치를

,

의 수학식으로 결정할 수 있다. 또는, 상기 제어 채널의 반복을 매핑하는 과정에서, 상기 제어 채널의 i번째 반복 위치를

,

의 수학식으로 결정할 수 있다.Preferably, in the process of calculating the control channel mapping start time, the control channel mapping start time

It can be determined by the following equation. Here, N is the number of unit resources that can be allocated for control channel transmission, N _cell is the number of cells to minimize interference, N _rep represents the number of repetitions when transmitting the control channel,

Indicates a physical layer cell ID. In this case, in the process of mapping the repetition of the control channel, the i-th repetition position of the control channel is determined.

,

It can be determined by the following equation. Alternatively, in the process of mapping the repetition of the control channel, the i-th repetition position of the control channel is determined.

,

It can be determined by the following equation.

Preferably, in the process of mapping the repetition of the control channel, the repetition of the control channel may be mapped to the remaining resource elements except for the positions of the resource elements allocated to the reference signal and the physical control format indication channel (PCFICH).

Preferably, in the process of mapping the repetition of the control channel, the plurality of groups of control channels in each cell may be mapped to positions adjacent to each other.

Preferably, the control channel may be a physical HARQ indication channel (PHICH).

Preferably, the control channel may be a physical control format indication channel (PCFICH) for each downlink control channel when a plurality of downlinks exist.

According to embodiments of the present invention, in the control channel transmission such as PHICH, PCFICH, etc., the interference allocation between neighboring cells can be reduced by improving the resource allocation method and the performance of the control channel can be improved.

Hereinafter, with reference to the drawings will be described a preferred embodiment of the present invention. However, embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below.

Hereinafter, a method in which a control channel transmitted through one OFDM symbol is spread evenly over all frequency bands, and at the same time, allows each control channel to be repeatedly transmitted through different frequency domains. In particular, a transmission scheme of a PHICH (Physical Hybrid ARQ Indicator Channel) channel used for ACK / NACK transmission in a 3GPP LTE system will be described as an example. However, the present invention is not limited thereto and may be applied to any control channel as well as the PHICH.

In a cellular communication system, when there are a plurality of cells, these cells are distinguished by their unique numbers, for example, cell IDs. Since the PHICH channel is an important channel for transmitting ACK / NACK information, it is important to improve the performance of PHICH channel transmission by minimizing the interference by PHICH transmission between cells in performing PHICH transmission. In this case, if the time-frequency resource for PHICH transmission is allocated differently according to the cell ID using the cell ID, interference between these cells can be reduced.

는 다음의 수학식 1과 같이 정의된다.In the 3GPP LTE system, physical-layer cell-identity

Is defined as in Equation 1 below.

는 물리계층 셀 아이디 그룹 (physical-layer cell-identity group)을 나타내며 0~167의 값을 갖는다.

는 각 셀 그룹안에 속해있는 물리계층 아이디 (physical-layer identity)를 나타내며 0~2의 값을 갖는다. 물리계층 아이디

에 따라 레퍼런스 신호 (reference signal)의 서로 다른 직교코드 및 PSCH (Primary synchronization signal)의 서로 다른 루트 시퀀스 인덱스를 할당하게 된다. 따라서, 일반적으로 인접한 셀 간에는 동일한 물리계층 셀 아이디 그룹

내의 서로 다른 물리계층 아이디

가 할당된다. 수학식 1에서와 같이

는

와

의 조합으로 표현되므로 0~503의 값을 가지게 된다. 따라서 인접 셀 간에 PHICH 전송에 의한 간섭을 줄이는 방법으로, 인접 셀 간에 PHICH 전송을 위한 시간-주파수 자원을 서로 다르게 할당할 수 있다. 그 중 하나의 방법이 셀 아이디에 따라 PHICH 전송을 위한 시간-주파수 자원을 서로 다르게 할당하는 것이다.In Equation 1 above

Indicates a physical-layer cell-identity group and has a value of 0 to 167.

Indicates a physical-layer identity belonging to each cell group and has a value of 0 to 2. Physical Layer ID

Accordingly, different orthogonal codes of reference signals and different root sequence indexes of primary synchronization signals (PSCHs) are allocated. Therefore, in general, the same physical layer cell ID group among adjacent cells

Different physical layer IDs within

Is assigned. As in Equation 1

Is

Wow

It is expressed as a combination of 0 to 503. Therefore, in a method of reducing interference due to PHICH transmission between neighboring cells, time-frequency resources for PHICH transmission between neighboring cells may be differently allocated. One method is to allocate time-frequency resources for PHICH transmission differently according to cell ID.

FIG. 1A illustrates an example of increasing resources for PHICH transmission one by one according to an increase of a cell ID.

In FIG. 1A, as cell IDs are increased by one, resources for PHICH transmission are increased by one to allocate resources for PHICH differently for each cell. A small square with a pattern represents a CDM multiplexed resource unit after several PHICHs are spread to several Resource Elements (REs) by orthogonal or quasi-orthogonal codes. That is, it indicates a resource unit used for transmission of the PHICH group. In FIG. 1A, the PHICH group is repeated at some interval in the entire system frequency band to obtain frequency diversity. The example of FIG. 1A is a case where each PHICH group is repeatedly transmitted three times. As described above, if resources for PHICH transmission are allocated differently according to cell IDs, interference between cells can be reduced, thereby improving PHICH transmission performance. However, in general, if there are a plurality of terminals in each cell, there may be several PHICH groups to be transmitted in each cell.

Figure 1b shows the case of three PHICH groups in each cell.

Within a particular cell, PHICH groups can be allocated contiguously adjacent to resources used by the first PHICH group for transmission. According to this method, resources of several PHICH groups can be easily allocated. However, in this case, interference between several PHICH groups between adjacent cells occurs.

FIG. 2 illustrates an example in which resources for PHICH transmission overlap between cells when multiple PHICH groups are sequentially allocated to each cell, thereby causing interference between cells.

내의 서로 다른 물리계층 아이디

를 할당하므로, 인접 셀간의 셀 아이디는 위 수학식 1 에 의해서 연속적으로 할당될 수 있다. 일반적으로 인접한 셀 간의 간섭이 가장 크므로 이 경우, PHICH 전송 성능의 열화가 발생할 수 있다.Typically, the same physical layer cell ID group between adjacent cells

Different physical layer IDs within

Since the IDs are allocated, cell IDs between adjacent cells may be continuously allocated by Equation 1 above. In general, since interference between adjacent cells is greatest, in this case, degradation of PHICH transmission performance may occur.

Hereinafter, in order to solve the problem, a method of adaptively adjusting a resource allocation interval for transmitting PHICH between consecutive cell IDs can reduce interference between cells even when several PHICH groups are allocated as consecutive resources in each cell. Explain.

3 illustrates a method of allocating resources for PHICH transmission to each cell according to an embodiment of the present invention.

Each cell (cell ID 0, 1, 2) repeatedly transmits each PHICH group three times. The frequency interval to repeat in each cell is set to 9 (Interval 2), and the resource interval for PHICH transmission between each cell is set to 3 (Interval 1), and then resources are allocated. In this case, even when several PHICH groups are transmitted in each cell, the interference problem as shown in FIG. 2 is not generated.

4 illustrates an example of transmitting several PHICH groups for each cell in the allocation result of FIG. 3.

The simplest method of transmitting several PHICH groups in the same cell is to transmit another PHICH group to a resource immediately adjacent to a resource used for transmission of a previous PHICH group. Unlike FIG. 2, in FIG. 4, no interference between cells occurs. If the number of PHICH groups to be transmitted in each cell is greater than 3, interference occurs, but it is clear that interference can be reduced even in this case than in FIG. In other words, the PHICH transmission performance can be improved.

The above description is expressed as a mathematical expression as follows. Equation 2 shows a method of allocating resources for PHICH transmission while maintaining a predetermined interval between adjacent cells.

, N_cell, 그리고 N_rep에 따라 제어 채널 매핑 시작 시점 k₀의 값이 결정된다.In Equation 2, N denotes the number of unit resources that can be allocated for PHICH transmission, N _cell denotes the number of cells that can reduce the amount of interference to a minimum, and N _rep repeatedly transmits the PHICH to obtain diversity gain Indicate the number of repetitions to be performed. First, cell ID

The value of control channel mapping start time k ₀ is determined according to, N _cell , and N _rep .

The location p _i of the unit resource in which the actual PHICH group is transmitted is determined by Equation 3 based on the k ₀ value.

or

or

=0, 1, 2 인 경우에 해당한다. 즉, 도 3은 3개의 셀 간에 PHICH 자원만을 고려해서 할당한 경우이다. 셀 아이디가 3보다 많은 경우 셀 아이디가 증 가함에 따라 이전 셀의 마지막 그룹에 할당했던 자원과 인접해서 PHICH 자원을 할당할 수 있다. In the case of allocating resources for PHICH transmission according to Equation 3, FIG. 3 shows N = 27, N _cell = 3, N _rep = 3,

This is the case when = 0, 1, 2. That is, FIG. 3 illustrates a case where only PHICH resources are allocated among three cells. If the cell ID is greater than 3, as the cell ID increases, the PHICH resource may be allocated adjacent to the resource allocated to the last group of the previous cell.

5 shows an example of allocating resources between four cells when the number of cells with the minimum interference amount is three.

The PHICH group of the cell having the cell ID of 4 is allocated a resource adjacent to the resource allocated to the cell having the cell ID of 0. When N _cell = 4, resources are allocated at intervals that minimize interference between four cells. 4 and 5 is only one example to help the understanding of the present invention, and the present invention may be applied to any N, N _cell , or N _rep values. Also, the parameters shown in Equations 2 and 3 are just examples to help explain the present invention, and any parameters having the same concept may be used.

FIG. 6 illustrates an example of differently applying intervals between control channel mapping start points for each cell.

6 assumes that the number of PHICH groups transmitted for each cell is different. The method shown in FIG. 2 does not maintain the same allocation intervals (Interval 2_1, Interval 2_2, Interval 2_3) of resources for PHICH transmission between neighboring cells, and considers the number of PHICH groups transmitted from each cell between neighboring cells. Control channel mapping start time is adjusted. As shown in FIG. 6, when the interval between cells is adjusted in consideration of the number of groups actually transmitted by each cell, resources can be used more efficiently than when the same interval is applied to all cells.

의 값은 인접 셀 간의 PHICH 전송을 위한 자원의 할당 간격을 조절하는 값으로, 이 값은 상황에 따라 각 셀에서 전송하는 PHICH 그룹의 개수, 혹은 각 셀에서 전송 가능한 최대 PHICH 그룹의 개수 등의 값으로 대체될 수 있다.In particular, in equation (2)

Is a value that adjusts the allocation interval of resources for PHICH transmission between neighbor cells, and this value is the number of PHICH groups transmitted by each cell or the maximum number of PHICH groups that can be transmitted by each cell according to circumstances. Can be replaced with

The above description is shown using the parameters used in the 3GPP LTE system.

에 따라 이웃 셀간의 관계를 고려하여 PHICH의 매핑 위치를 결정한다. PHICH는 기준 심볼(reference symbols) 및 PCFICH (Physical Control Format Indicator Channel)에 매핑되지 않은 4개의 연속적인 자원요소

에 i와 k가 증가하는 순서대로 매핑될 수 있다.

In accordance with the relation between neighboring cells, the PHICH mapping position is determined. PHICH consists of four consecutive resource elements that are not mapped to reference symbols and to the Physical Control Format Indicator Channel (PCFICH).

Can be mapped in increasing order of i and k.

In the following, y (0), ..., y (3), y (4), ..., y (7), y (8), ..., y (11) are diffusion ratios (SF: It is assumed that after spreading with spreading factor 4, the CDM multiplexed PHICH group represents a symbol transmitted three times.

는 전체 시스템에서 자원이 매핑될 수 있는 다운링크의 자원 블록 개수,

는 자원 블록당 자원요소의 개수를 나타낸다.In the following,

Is the number of resource blocks in the downlink to which resources can be mapped across the entire system,

Represents the number of resource elements per resource block.

인 위치의 자원요소부터 매핑된다. y(4), ... , y(7)는

인 위치의 자원요소부터 매핑될 수 있다. 또한, y(8), ... , y(11)는

인 위치의 자원요소부터 매핑될 수 있다.Y (0), ..., y (3) to be mapped to four consecutive resource elements

Maps from the resource element at the location. y (4), ..., y (7)

It can be mapped from the resource element of the location. Also, y (8), ..., y (11)

It can be mapped from the resource element of the location.

인 위치의 자원요소부터 매핑된다. y(4), ... , y(7)는

인 위치의 자원요소부터 매핑될 수 있다. 또한, y(8), ... , y(11)는

인 위치의 자원요소부터 매핑될 수 있다.As another example, y (0), ..., y (3) to be mapped to four consecutive resource elements

Maps from the resource element at the location. y (4), ..., y (7)

It can be mapped from the resource element of the location. Also, y (8), ..., y (11)

It can be mapped from the resource element of the location.

The above-described control channel mapping start time k ₀ may be expressed as Equation 4, 5 or 6.

or

or

는 각 셀에서 PHICH 전송에 필요한 자원요소의 최대 개수를 나타내며, 이는 시스템 정보를 통해서 있다.In Equation 5,

Denotes the maximum number of resource elements required for PHICH transmission in each cell, which is through system information.

or

에 대한 모듈라 연산이다.

는 시스템에서 실제 매핑할 수 있는 전체 위치의 개수를 나타낸다. 수학식 6에서

,i는 각 셀 i에서 PHICH 전송을 위해 실제 사용하는 자원요소의 개수를 나타내며, 이는 각 셀 마다 다를 수 있다. 사용되는 자원요소의 개수는 각 기지국이 판단하여 결정할 수 있다.Additions in Equations 4 to 6 are such that the value continues to increase as the cell ID increases. However, since the resources that can be mapped are limited to the frequency band of the system, the values that can be mapped by the above equation do not depart from the mappable positions of the frequency band of the system.

Modular operation on.

Represents the total number of locations that can be actually mapped in the system. In equation (6)

, i represents the number of resource elements actually used for PHICH transmission in each cell i, which may be different for each cell. The number of resource elements used may be determined and determined by each base station.

The symbols of y (0), ..., y (11) start from the resource element index determined by k, and other signals such as reference signal (RS) and physical control format indicator channel (PCFICH) are used for transmission. It is mapped to four consecutive resource elements that are not used.

에 따라 결정된다. 이때, k₀가 가리키는 인덱스가 기준 신호 및 PCFICH를 사용하는 자원요소의 인덱스와 충돌될 경우, k₀가 기준 신호 및 PCFICH 전송을 위해 사용되지 않는 자원요소 인덱스를 만날 때까지 1씩 증가된 인덱스가 적용된다. 또한 하나의 PHICH 그룹의 인덱스가 결정되면, 그 다음 PHICH 그룹은 이전 PHICH 그룹에 사용된 인덱스에 인접하고, 기준 신호 및 PCFICH에 사용되지 않는 연속된 4개의 자원요소에 할당된다.In Equations 4 to 6, the value of k ₀ is

It depends on. In this case, k If _0, the index collides with an index of a resource element using a reference signal and PCFICH points, the increased index to the one by one when they meet the resource element index k ₀ is not used for a reference signal and PCFICH transmission Apply. In addition, when the index of one PHICH group is determined, the next PHICH group is allocated to four consecutive resource elements that are adjacent to the index used in the previous PHICH group and not used in the reference signal and the PCFICH.

The present invention can be applied to other control channels as well as the above-described PHICH.

7 shows an example of transmitting a plurality of PCFICH in one cell.

When multiple downlinks exist in a cell, a PCFICH indicating the number of OFDM symbols used for a control channel transmitted for each downlink should be transmitted. In case of transmitting only the PCFICH corresponding to each downlink, the UE must receive PCFICH information transmitted by accessing all downlinks in order to know PCFICH information of each downlink. However, in this case, since the power consumption of the terminal can be increased, the terminal can be designated to receive only one specific downlink control channel before receiving data. For convenience, such a downlink is called a primary component carrier. In this case, the terminal may receive only a control channel in the first component carrier and determine which downlink data to receive according to the information of the control channel. Such a first component carrier may be designated differently according to a terminal, so that even if a specific component carrier is not the first component carrier of one terminal, it may be a first component carrier of another terminal. Control channels are transmitted on all downlinks, and this is why PCFICH information is needed to inform the number of OFDM symbols transmitting such control channels.

If one UE tries to receive data transmitted through multiple downlinks using only control channel information of a specific first component carrier, the PCFICH information of each downlink must be known to transmit data (not a control channel) for each downlink. The number of OFDM symbols can be known. Therefore, another embodiment of the present invention proposes a method of transmitting PCDICH information of another downlink to one first component carrier together.

In FIG. 7, if the component carrier C is the first component carrier, the component carrier may transmit PCFICH information of the remaining A, B, D, and E together. As described above, when a plurality of component carriers exist in one cell, a plurality of PCFICH information may be transmitted. In this case, the above-described mapping method may be applied. The PCFICH has been described as an example, but the present invention can be applied to other control channels.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and variations may be made therefrom. And, such modifications should be considered to be within the technical protection scope of the present invention. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

The present invention relates to a mapping scheme for a frequency and an OFDM symbol region of a signal transmitted in a downlink in a cellular OFDM wireless packet communication system, and can be applied to a system such as 3GPP LTE.

FIG. 1A illustrates an example of increasing resources for PHICH transmission one by one according to an increase of a cell ID.

Figure 1b shows the case of three PHICH groups in each cell.

FIG. 2 illustrates an example in which interference between cells occurs when successively assigning a plurality of PHICH groups to each cell.

3 illustrates a method of allocating resources for PHICH transmission to each cell according to an embodiment of the present invention.

4 illustrates an example of transmitting several PHICH groups for each cell in the allocation result of FIG. 3.

5 shows an example of allocating resources between four cells when the number of cells with the minimum interference amount is three.

FIG. 6 illustrates an example of differently applying intervals between control channel mapping start points for each cell.

7 shows an example of transmitting a plurality of PCFICH in one cell.

Claims (11)

In the method of mapping the control channel by repeating at regular intervals on the frequency axis, Calculating a control channel mapping start time of each cell according to the number of groups of control channels allocated to each cell; And Mapping the repetition of the control channel at predetermined intervals for diversity gain starting from the start of the control channel mapping And a plurality of groups of control channels in each cell. The method of claim 1, Computing the control channel mapping start time point, And determining a control channel mapping start time of each cell by using a maximum value of the number of groups of control channels allocated to each cell. The method of claim 1, Computing the control channel mapping start time point, And determining a control channel mapping start time of each cell by using an average value of group numbers of control channels allocated to each cell. The method of claim 1, Computing the control channel mapping start time point, And determining the channel allocation start time according to the number of groups of control channels of an adjacent cell. The method of claim 1, Computing the control channel mapping start time point, Starting time of the control channel mapping

Where N is the number of unit resources that can be allocated for control channel transmission, N _cell is the number of cells that minimize interference, and N _rep represents the number of repetitions when transmitting the control channel. ,

Is a physical layer cell ID, characterized in that the control channel mapping method. The method of claim 5, wherein Mapping the repetition of the control channel, I-th repeating position of the control channel

,

The control channel mapping method, characterized in that the step of determining. The method of claim 5, wherein Mapping the repetition of the control channel, I-th repeating position of the control channel

,

The control channel mapping method, characterized in that the step of determining. The method of claim 1, Mapping the repetition of the control channel, And mapping the repetition of the control channel to the remaining resource elements except for positions of resource elements allocated to a reference signal and a physical control format indication channel (PCFICH). The method of claim 1, Mapping the repetition of the control channel, And mapping the plurality of groups of control channels to positions adjacent to each other in each cell. The method of claim 1, The control channel, And a physical HARQ indication channel (PHICH). The method of claim 1, The control channel, If there is a plurality of downlinks, characterized in that the physical control format indication channel (PCFICH) for the control channel of each downlink, control channel mapping method.

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