KR20110065396A - Communication method - Google Patents

Abstract

PURPOSE: A communication method is provided to embody high-speed packet transmission by preventing packet transmit delay. CONSTITUTION: A BS(Base Station) transfers DL(DownLink) resource allocation information to an MS(Mobile Station) in the I-numbered sub frame of an i-numbered frame(S110). The BS starts to transmit DL data burst such as a sub packet with DL resources allocated according to the DL resource allocation information in the m-numbered sub frame of the i-numbered frame(S130). The MS decodes the received DL data burst. According to the success of decoding, the MS transmits ACK or NACK feedback to the BS(S150).

Description

Communication method {COMMUNICATION METHOD}

The present invention relates to a communication method. In particular, the present invention relates to transmission timing of packets or messages.

In a wireless mobile communication system, a duplexing method divides uplink and downlink transmission / reception resources into frequencies to perform frequency division duplexing for bidirectional communication of uplink (UL) and downlink (DL). (FDD) transmission mode and uplink and downlink transmission / reception resources are distinguished by a time division duplex (TDD) transmission mode scheme for bidirectional communication of uplink and downlink.

The wireless mobile communication system mainly performs communication using a communication frame.

Next, a communication frame will be described with reference to FIGS. 1 and 2.

1 illustrates a communication frame of a conventional frequency division duplex (FDD).

As shown in FIG. 1, a frequency division duplex communication frame includes F downlink subframes and F uplink subframes. F corresponds to the number of subframes constituting one communication frame.

F downlink subframe indexes corresponding to F-1 are allocated to the F downlink subframes, and uplink subframe indexes corresponding to F-1 from 0 to F-1 are allocated to the F uplink subframes.

2 illustrates a communication frame of a conventional time division duplex (TDD).

As shown in FIG. 2, the time division duplex communication frame includes D downlink subframes and U uplink subframes.

D downlink subframe indexes corresponding to D-1 are allocated to D downlink subframes, and uplink subframe indexes corresponding to 0 to U-1 are allocated to U uplink subframes.

On the other hand, in the mobile communication system, a hybrid AQ that combines a forward error correction (FEC) method and an automatic repeat request (ARQ) method in order to secure high-speed data packet transmission, low delay, and communication reliability. Hybrid ARQ, HARQ) is used a lot.

The retransmission method is to correct an error by retransmitting a data packet, and there are SAW (stop and wait), GBN (Go-back-N), SR (selective repeat) method, and especially SAW (stop and wait) method. After checking whether the received frame is correctly received, the next frame is transmitted.

According to the HARQ method, a receiver decodes a data packet received by a physical layer to determine whether an error is detected, and if an error does not occur, transmits an acknowledgment signal as a response signal to successfully receive the data packet. Inform the transmitter. However, when an error is detected in the received data packet, the receiver transmits a negative acknowledgment (NACK) signal as a response signal to inform the transmitter that the error is detected. The transmitter may retransmit the data packet when the NACK signal is received.

The HARQ protocol is classified into a synchronous HARQ technique and an asynchronous HARQ technique according to transmission timing of a retransmitted packet. A synchronous HARQ technique is a method in which a transmission time of a retransmission packet is constant for an initial transmission packet. In the asynchronous HARQ scheme, a scheduler of a base station determines a transmission time of a retransmission packet for an initial transmission packet.

In addition, the HARQ scheme is classified into an adaptive HARQ scheme and a non-adaptive HARQ scheme according to a change in the amount and location of allocated resources. The adaptive HARQ scheme is used to determine the amount and location of allocated resources. The non-adaptive HARQ scheme is to fix the amount and location of allocated resources.

High scheduling gains and high data rates can be achieved by properly mixing synchronous and asynchronous HARQ and adaptive and non-adaptive HARQ techniques and using less signaling overhead. For example, the mobile communication system may apply adaptive asynchronous HARQ for downlink data transmission and synchronous HARQ for uplink data transmission.

In order to reduce signaling overhead according to control signals such as resource allocation information, it may be effective to use a synchronous and non-adaptive HARQ technique that does not change the retransmission timing and the amount and location of allocated resources. However, without considering signaling overhead, it may be rather effective to use an asynchronous and adaptive HARQ technique with scheduling gains.

High scheduling gains and high data rates can be achieved by properly mixing synchronous and asynchronous HARQ and adaptive and non-adaptive HARQ techniques and using less signaling overhead.

When the terminal uses the synchronous HARQ scheme for the uplink, in order to transmit the HARQ packet in the uplink, resources must be allocated from the downlink control signal from the base station. That is, uplink transmission resources are allocated as a downlink control signal, and the HARQ packet is transmitted to a designated position (slot or subframe). In addition, the base station transmits an ACK as a HARQ feedback signal in downlink if the HARQ packet is successfully received without error, and transmits a NACK if the HARQ packet fails. At this time, when the terminal receives the NACK as a HARQ feedback signal, the terminal retransmits a packet previously transmitted at a designated time.

In particular, in the TDD transmission mode in which the transmission / reception method is divided into uplink and downlink, a more efficient gain can be obtained if the time-based transmission segment and the efficient timing of resource allocation are considered according to the ratio of uplink and downlink frequency and transmission channel. have.

In the TDD transmission mode, one frame may consist of one or more subframes for DL and UL, and the ratio of the number of subframes (hereinafter referred to as subframes) allocated to the DL and UL may vary according to the type of the frame structure. have. For example, if the number of subframes constituting one frame is six, seven, or eight, 3: 3, 4: 2, 2: 4, 5: 2, 3: 4, 4: 3, 2: 5 , 6: 2, 5: 3, 4: 4, 3: 5, 2: 6,... One of a variety of frame structures may be selected.

Meanwhile, the wireless mobile communication system may use a transmission time interval (TTI) as a transmission time unit. TTI corresponds to the transmission duration of a physical layer for a packet encoded on a radio air interface, and corresponds to a subframe or an advanced air interface subframe. It is expressed as an integer number. That is, one TTI is a transmission duration of a packet (subpacket or data burst) occupying one subframe length, and n TTI represents a transmission duration of a packet by n subframe lengths.

In addition, a data burst may be transmitted over one subframe or over a plurality of consecutive subframes. If a data burst is transmitted in one subframe, the duration for that data burst is called one TTI or default TTI.If the data burst is transmitted over multiple consecutive subframes, the duration for that data burst is Long. It is called TTI. For example, in the case of Long TTI transmission in the FDD transmission mode, the data burst may be defined as occupying a length corresponding to four subframes. In case of the Long TTI transmission in the TDD mode, the data burst may be defined as DL or UL in one frame. Can be defined as occupying all DL or all UL subframes of the corresponding frame.

Depending on the system, the required length of subframe occupancy of the transmitted data burst is 1 TTI, 2 TTI, 3 TTI,... This may be variously determined according to the characteristics of the data.

According to the conventional synchronous HARQ method, the transmission of the control signal, the HARQ packet, and the corresponding HARQ feedback signal for resource allocation are configured to follow a predefined timing. In particular, for uplink (UL), the HARQ packet is retransmitted at the same subframe position as the subframe in which the previous data burst was transmitted.

However, according to the conventional synchronous HARQ method, in the TDD mode, the following problems may occur in the HARQ transmission / reception procedure of DL and UL data bursts allocated to subframes close to the switching points of the DL and UL.

That is, the HARQ reference timing is not considered to be variously applied according to the processing time of various data bursts and control signals, which may be different or the same, depending on the packet capability of the base station and the plurality of terminals. have. In addition, since transmission occupancy time for data bursts of various sizes is not considered, there is no flexibility in processing capacity and processing time. In addition, one-way access delay for DL and UL may occur because packet transmission and feedback signals may be delayed and transmitted late in the HARQ transmission / reception procedure. As a result, high-speed packet transmission is impossible, and a buffer waiting time may be increased during operation due to a delay of the HARQ procedure, and the HARQ timing procedure is complicated.

The technical problem to be achieved by the present invention is to provide a flexible HARQ timing procedure in consideration of the radio signal processing time, the structure of the frame, the occupied transmission time of the data burst.

A communication method according to an embodiment of the present invention is a method in which a mobile station communicates with a base station using a frame including one or more downlink subframes and one or more uplink subframes, and includes data in a frame corresponding to a first frame index. Receiving a burst from the base station, determining a first parameter value using a difference in radio signal processing time and the number of one or more uplink subframes, and using the first parameter value to determine a frame offset. Determining, and transmitting feedback for the data burst to the base station in a frame corresponding to a second frame index determined according to the first frame index and the frame offset.

The determining of the frame offset may include determining the frame offset based on a difference between the number of the one or more downlink subframes and the first parameter value.

Receiving the data burst may include receiving the data burst in a subframe corresponding to a downlink subframe index of a frame corresponding to the first frame index.

The transmitting of the feedback may include determining an uplink subframe index using the downlink subframe index and the first parameter value, and the uplink subframe index of the frame corresponding to the second frame index. The method may include transmitting the feedback in a subframe corresponding to the subframe.

The determining of the uplink subframe index may include setting the uplink subframe index to 0 when the downlink subframe index is greater than or equal to a value obtained by subtracting the first parameter value from the number of the one or more downlink subframes. It may include the step of determining.

The determining of the uplink subframe index may include determining a second parameter value by using a difference between the number of one or more downlink subframes and a radio signal processing time, the downlink subframe index, and the first The method may include determining the uplink subframe index using a parameter value, the second parameter value, and the number of subframes occupied by the data burst.

The uplink subframe index may be determined by the following equation when the first parameter value is less than or equal to zero.

Herein, n corresponds to the uplink subframe index, m corresponds to the downlink subframe index, N _TTI corresponds to the number of subframes occupied by the data burst, and X is the second parameter value. D corresponds to the number of one or more downlink subframes.

The uplink subframe index may be determined by the following equation when the first parameter value is greater than zero.

Here, K 'corresponds to the first parameter value.

A communication method according to another embodiment of the present invention is a method in which a base station communicates with a mobile station using a frame including one or more downlink subframes and one or more uplink subframes, and includes data in a frame corresponding to a first frame index. Sending a burst to the mobile station; Receiving feedback from the mobile station for the data burst in a frame corresponding to a second frame index. The second frame index is determined according to the first frame index and the frame offset, and the frame offset is determined using a parameter value determined through a difference between a radio signal processing time and the number of the one or more uplink subframes. .

The frame offset may be determined based on a difference between the number of one or more downlink subframes and the parameter value.

The data burst is transmitted in a subframe corresponding to a downlink subframe index, the feedback is received in a subframe corresponding to an uplink subframe index, and the downlink subframe index is defined in the one or more downlink subframes. If the number is greater than or equal to the value obtained by subtracting the parameter value, the uplink subframe index may be determined to be zero.

A communication method according to another embodiment of the present invention is a method in which a mobile station communicates with a base station using a frame including one or more downlink subframes and one or more uplink subframes, in a frame corresponding to a first frame index. Receiving resource allocation information from the base station; Determining a first parameter value using a difference between a radio signal processing time and the number of the one or more uplink subframes; Determining a first frame offset using the first parameter value; And transmitting a data burst to the base station in a frame corresponding to a second frame index determined according to the first frame index and the first frame offset.

The communication method may further include receiving feedback for the data burst in a frame corresponding to a third frame index. The third frame index may be determined according to the second frame index and the second frame offset, and the second frame offset may be determined using the first parameter value.

The communication method may further include determining a third frame offset using the first parameter value when the feedback is negative; And retransmitting the data burst to the base station in a frame corresponding to a fourth frame index determined according to the third frame index and the third frame offset.

The second frame offset is determined by comparing the number of the one or more downlink subframes, the difference between the first parameter value, and the second frame index, and the third frame offset is the one or more downlink subframes. The number of times and a difference between the first parameter value and the third frame index may be determined through comparison.

The resource allocation information is received in a subframe corresponding to a first downlink subframe index, the data burst is transmitted in a subframe corresponding to a first uplink subframe index, and the first uplink subframe index is It may be determined using the first parameter value.

The first uplink subframe index is a number of subframes occupied by the data burst, a comparison of the number of the one or more downlink subframes with the number of the one or more uplink subframes, the first parameter value, and the The second parameter may be determined by using a difference between the number of one or more downlink subframes and the radio signal processing time.

The feedback is received in a subframe corresponding to a second downlink subframe index, the data burst is retransmitted in a subframe corresponding to a second uplink subframe index, and the second downlink subframe index is the data. The number of subframes occupied by the burst may be determined by using the first parameter value, and the second uplink subframe index may be the same as the first uplink subframe index.

A communication method according to another embodiment of the present invention is a method in which a base station communicates with a mobile station using a frame including one or more downlink subframes and one or more uplink subframes, in a frame corresponding to a first frame index. Transmitting resource allocation information to the mobile station; Receiving a data burst from the mobile station in a frame corresponding to a second frame index.

The second frame index may be determined according to the first frame index and the frame offset, and the frame offset may be determined using a parameter value determined through a difference between a radio signal processing time and the number of the at least one uplink subframe. have.

The communication method includes transmitting feedback on the data burst in a frame corresponding to a third frame index; And re-receiving the data burst to the base station in a frame corresponding to a fourth frame index, wherein the third frame index is determined using the first parameter value, and the fourth frame index is the It may be determined using the first parameter value.

The resource allocation information is transmitted in a subframe corresponding to a first downlink subframe index, the data burst is received in a subframe corresponding to a first uplink subframe index, and the first uplink subframe index is It may be determined using the first downlink subframe index and the first parameter value.

According to a feature of the present invention, packet transmission delay is prevented to enable high speed packet transmission. In addition, a sequential HARQ timing procedure for each channel is provided, and a flexible HARQ timing procedure in consideration of radio signal processing time, frame structure, and occupied transmission time of a data burst is provided.

1 illustrates a communication frame of a conventional frequency division duplex (FDD).
2 illustrates a communication frame of a conventional time division duplex (TDD).
3 is a flowchart illustrating a downlink data communication method according to an embodiment of the present invention.
4 is a flowchart illustrating an uplink data communication method according to an embodiment of the present invention.
5 shows TDD DL HARQ timing according to an embodiment of the present invention.
6 shows TDD UL HARQ timing according to an embodiment of the present invention.
7 shows TDD DL HARQ timing according to another embodiment of the present invention.
8 shows TDD UL HARQ timing according to another embodiment of the present invention.
9 shows TDD DL HARQ timing according to another embodiment of the present invention.
10 shows TDD DL HARQ timing according to another embodiment of the present invention.
11 shows TDD UL HARQ timing according to another embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

In this specification, a mobile station (MS) includes a terminal, a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS), and a user equipment. It may also refer to a user equipment (UE), an access terminal (AT), and the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

In the present specification, a base station (BS) is an access point (AP), a radio access station (Radio Access Station, RAS), a Node B (Node B), a base transceiver station (Base Transceiver Station, BTS), MMR ( Mobile Multihop Relay) -BS and the like, and may include all or part of functions such as an access point, a radio access station, a Node B, a base transceiver station, and an MMR-BS.

Next, a downlink data communication method according to an embodiment of the present invention will be described with reference to FIG. 3.

3 is a flowchart illustrating a downlink data communication method according to an embodiment of the present invention.

First, the base station 100 transmits downlink resource allocation information to the mobile station 200 in the l-th subframe of the i-th frame (S110). The downlink resource allocation information may be a control signal such as A-MAP (Advanced MAP).

Next, the base station 100 starts transmission of a downlink data burst such as a sub packet through downlink resources allocated according to downlink resource allocation information in the mth subframe of the i th frame (S130).

The mobile station 200 decodes the received downlink data burst, and if successful, transmits an ACK feedback corresponding to a positive response to the base station 100, and fails to decode a NACK feedback corresponding to a negative response. (S150). The mobile station 200 uses the n th subframe of the j th frame for feedback transmission.

In the exemplary embodiment of the present invention, when one super frame is composed of four frames, the frame index may have a range of 0 to 3.

According to an embodiment of the present invention, the frame index i and j, the subframe index l, m, n may be determined as shown in Table 1 in the case of TDD.

Table 1 shows TDD DL HARQ timing according to an embodiment of the present invention.

In Table 1, A mod B returns the remainder of A divided by B.

On the other hand, the parameter K is a parameter determined according to system capability such as channel bandwidth, number of subframes, etc. in the time division duplex method, and is used to obtain a HARQ reference timing interval. The downlink HARQ reference timing interval means an interval between a downlink subframe in which a downlink data burst is transmitted and a downlink subframe in which HARQ feedback is transmitted. The uplink HARQ reference timing interval means an interval between a downlink subframe in which uplink resource allocation information is transmitted and an uplink subframe in which an uplink data burst is transmitted.

The parameter K may be determined according to Equation 1 or Equation 2.

ceil (x) returns the smallest integer greater than or equal to the parameter x, and floor (x) returns the largest integer less than or equal to the parameter x. Equation 1 is equivalent to Equation 2 since K = 0 when D = U.

In Table 1, the downlink feedback frame offset z of the TDD transmission mode may be determined according to Equation 3.

In Equation 3, N _TTI is a value of TTI, which is a transmission time unit, and indicates the number of subframes occupied during transmission of a data burst, that is, the number of subframes over which an HARQ packet spans. N _TTI = 1 for One TTI transmission and N _TTI = D for Long TTI transmission. T _proc represents radio signal processing time, that is, processing time of data burst.

Next, an uplink data communication method according to an embodiment of the present invention will be described with reference to FIG. 4.

4 is a flowchart illustrating an uplink data communication method according to an embodiment of the present invention.

First, the base station 100 transmits uplink resource allocation information to the mobile station 200 in the l-th subframe of the i-th frame (S210). The uplink resource allocation information may be a control signal such as A-MAP (Advanced MAP).

Next, the mobile station 200 starts transmission of an uplink data burst such as a subpacket through the uplink resource allocated according to the uplink resource allocation information in the mth subframe of the jth frame (S230).

The base station 100 transmits the feedback for the received uplink data burst to the mobile station 200 in the l-th subframe of the k-th frame (S250). The base station 100 decodes the received uplink data burst, and if successful, transmits an ACK feedback corresponding to a positive response to the mobile station 200. If the decoding fails, the base station 100 transmits a NACK feedback corresponding to a negative response. To be sent).

If this feedback is a negative response, the mobile station 200 retransmits the uplink data burst in the mth subframe of the pth frame (S270).

According to an embodiment of the present invention, the frame indexes i, j, k, and p, and the subframe indexes l and m may be determined as shown in Table 2 in the case of TDD.

Table 2 shows the TDD UL HARQ timing according to an embodiment of the present invention.

In Table 2, the parameter K may be determined according to Equation 1 or Equation 2.

In Table 2, the uplink data packet transmission frame offset v and the uplink feedback frame offset w of the FDD transmission mode may be determined according to Equation 4.

In Equation 4, N _TTI = 1 for one TTI transmission and N _TTI = U for long TTI transmission.

Next, the TDD HARQ timing according to Table 1 or Table 2 will be described with reference to FIGS. 5 to 9.

5 shows TDD DL HARQ timing according to an embodiment of the present invention.

In particular, FIG. 5 shows TDD DL HARQ timing according to Table 1 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 5 is based on the adaptive asynchronous HARQ method, and resource allocation and transmission format for HARQ retransmission may be different from resource allocation and transmission format for initial transmission.

5 illustrates an example in which the base station 100 transmits downlink resource allocation information and a downlink data burst to the mobile station 200 in a subframe corresponding to downlink subframe index 1 of the i-th frame. In this case, the mobile station 200 decodes the received downlink data burst, and if successful, transmits an ACK feedback corresponding to a positive response to the base station 100, and fails to decode the NACK feedback corresponding to a negative response. To 100. The mobile station 200 uses a subframe corresponding to the uplink subframe index 0 of the i-th frame for feedback transmission. If the feedback is positive, the base station 100 transmits a new data burst and resource allocation information therefor to the mobile station 200 in a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame. On the other hand, if the feedback is negative, the base station 100 transmits the previously transmitted data burst to the mobile station 200 in a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame with resource allocation information therefor. Resend.

6 shows TDD UL HARQ timing according to an embodiment of the present invention.

In particular, FIG. 6 shows TDD UL HARQ timing according to Table 2 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 6 is in accordance with the synchronous HARQ method, where the location of resources for HARQ retransmission is allocated to be the same as the location of resources for initial transmission.

6 shows an example in which the base station 100 transmits uplink resource allocation information to the mobile station 200 in a subframe corresponding to downlink subframe index 1 of the i-th frame. In this case, the mobile station 200 transmits an uplink data burst through uplink resources allocated according to uplink resource allocation information in a subframe corresponding to uplink subframe index 0 of the i-th frame. The base station 100 transmits the feedback for the received uplink data burst to the mobile station 200 in the subframe corresponding to the downlink subframe index 1 of the (i + 1) th frame. In this case, the base station 100 may transmit uplink resource allocation information to the mobile station 200 together with the feedback when there is a new uplink data burst to be transmitted. If this feedback is a negative response, the mobile station 200 retransmits the previously transmitted uplink data burst in a subframe corresponding to uplink subframe index 0 of the (i + 1) th frame. On the other hand, if the feedback is a positive response, a new uplink data burst is transmitted in a subframe corresponding to the uplink subframe index 0 of the (i + 1) th frame.

7 shows TDD DL HARQ timing according to another embodiment of the present invention.

In particular, FIG. 7 shows TDD DL HARQ timing according to Table 1 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 7 is based on the adaptive asynchronous HARQ method, and resource allocation and transmission format for HARQ retransmission may be different from resource allocation and transmission format for initial transmission.

7 shows that the base station 100 has a subframe corresponding to downlink subframe index 4 of the i-th frame, a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame, and (i + 1) An example of transmitting downlink data bursts for channels A, B, and C to the mobile station 200 in a subframe corresponding to downlink subframe index 2 of the first frame, respectively. According to Table 1, the mobile station 200 receives feedback on downlink data bursts for channels A, B, and C and subframes corresponding to uplink subframe indexes 2, 0, and 1 of the (i + 1) th frame. Are transmitted to the base station 100, respectively. As a result, when the feedback is negative, the base station 100 sets downlink data bursts for channels B, C, and A in subframes corresponding to downlink subframe indexes 1, 2, and 3 of the (i + 2) th frame. Resend. As such, a problem may occur in which the HARQ procedure for channels B and C precedes the HARQ procedure for channel A.

8 shows TDD UL HARQ timing according to another embodiment of the present invention.

In particular, FIG. 8 shows TDD UL HARQ timing according to Table 2 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 8 is according to the synchronous HARQ method, and the location of resources for HARQ retransmission is allocated to be the same as the location of resources for initial transmission.

8 shows a subframe corresponding to downlink subframe index 4 of the i-th frame, a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame, and (i + 1) An example of transmitting uplink resource allocation information for channels A, B, and C to the mobile station 200 in a subframe corresponding to downlink subframe index 2 of the first frame is shown. According to Table 2, the mobile station 200 transmits uplink data bursts for channels B, C, and A, respectively, in subframes corresponding to uplink subframe indexes 0, 1, and 2 of the (i + 1) th frame. do. The base station 100 provides feedback on uplink data bursts for channels B, C, and A to the mobile station 200 in subframes corresponding to downlink subframe indexes 1, 2, and 4 of the (i + 2) th frame. send. If this feedback is a negative response, the mobile station 200 uses the uplink data bursts for channels B, C, and A as subframes corresponding to uplink subframe indexes 0 and 1 of the (i + 2) th frame, and (i It is retransmitted in the subframe corresponding to the uplink subframe index 2 of the +3) th frame. As such, a problem may occur in which the HARQ procedure for channels B and C precedes the HARQ procedure for channel A.

9 shows TDD DL HARQ timing according to another embodiment of the present invention.

In particular, FIG. 9 shows TDD DL HARQ timing according to Table 1 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 9 shows an adaptive asynchronous HARQ method, and resource allocation and transmission format for HARQ retransmission may be different from resource allocation and transmission format for initial transmission.

9 illustrates an example in which the base station 100 transmits downlink resource allocation information and a downlink data burst to the mobile station 200 in a subframe corresponding to downlink subframe index 4 of the i-th frame. According to Table 1, the mobile station 200 transmits the feedback for the downlink data burst to the base station 100 in the subframe corresponding to the uplink subframe index 2 of the (i + 1) th frame. If the feedback is positive, the base station 100 transmits a new data burst and resource allocation information therefor to the mobile station 200 in a subframe corresponding to downlink subframe index 3 of the (i + 2) th frame. On the other hand, if the feedback is negative, the base station 100 transmits the previously transmitted data burst to the mobile station 200 in a subframe corresponding to downlink subframe index 3 of the (i + 2) th frame with resource allocation information therefor. Resend. If the resource is not allocated at the location of the appropriate subframe in the (i + 2) th frame as shown in the downlink packet transmission shown in FIG. 9, only two HARQ packets are transmitted over four frames, and thus a packet delay may occur. .

On the other hand, the processing capability (capability) of the base station and the mobile station may vary depending on the implemented system and the frame configuration ratio of the DL and UL may vary, such as 6: 2 or 3: 5, so that data bursts of uplink and downlink It is also necessary to consider a situation in which the processing time and the processing time of the control signal are different and the ratio of the DL and UL subframes varies. In addition, considering that the TTI unit is not 3 subframes but 2 or 4 subframes, it is difficult to obtain a good HARQ performance due to an inefficient HARQ transmission process due to a timing misalignment, so that various types of TTI transmissions can be applied. A timing determination method is required.

HARQ timing determination method for this will be described with reference to Table 3 and Table 4.

Table 3 shows TDD DL HARQ timing according to another embodiment of the present invention.

In Table 3, the parameter K 'for resource allocation of the HARQ packet and for determining the HARQ feedback signal position is determined according to Equation 5.

In Equation 5, 1 is added to the difference between Tproc and U to determine whether resources can be allocated after an index corresponding to the size of Tproc.

In the case of determining K as shown in Equation 5, the number of Tproc and uplink subframes affects the time for transmitting the HARQ packet, the feedback signal, and the retransmission packet for the data burst.

That is, if K 'is positive, the value of one subframe size added to Tproc exceeds the number of subframes in one frame, and thus the next HARQ signal processing (HARQ packet transmission or HARQ feedback signal transmission) is performed in the current frame. It means that a situation can arise where the procedure cannot be performed.

Therefore, when K 'is a positive number, processing of the HARQ signal that cannot be accepted in the current frame, that is, the next process of the HARQ signal corresponding to the DK' subframe index is all performed in the next frame, especially in the first subframe of the next frame. Is processed. That is, when K 'is a positive number, HARQ signals (HARQ packets and HARQ feedback signals) that can be transmitted in the next frame based on D-K' are processed before the newly allocated HARQ packets (data burst) in the next frame to delay the delay. prevent.

On the other hand, if K 'is less than or equal to 0, since the number U of subframes of one frame is greater than or equal to the value of one subframe size added to Tproc, HARQ signal processing in all UL subframes of the current frame (HARQ packet Transmission or HARQ feedback signal transmission) may be performed. In particular, if K '<0, this means that there are | K' | UL subframes available for HARQ signal processing. That is, K 'less than or equal to 0 means that the following HARQ signal processing for all HARQ signal processing (HARQ packet transmission or HARQ feedback signal transmission) occurring in the previous subframe can be accommodated in the current frame. .

In other words, when transmitting DL and UL HARQ packets, if the size of K 'is positive, the next HARQ signal for the previous HARQ signal is not processed in the current frame but is processed in the next frame, and if K' is less than or equal to 0, the previous The next HARQ signal for the HARQ signal is processed in the current frame rather than the next frame.

Hereinafter, a case in which DL HARQ packet is transmitted to one TTI according to Table 3 will be described.

When K '≦ 0, the subframe index n for transmitting the HARQ feedback signal for the HARQ packet transmitted in the m = l th subframe is determined according to Equation 6.

X represents a range of DL subframe index m of the HARQ packet in which the HARQ feedback signal for the HARQ packet may be transmitted in the first UL subframe in the current frame, and is calculated according to Equation 7.

According to equations (6) and (7), the number of downlink subframes belonging to one frame and the value of Tproc affect the resource allocation positions and ranges of data and control signals to be transmitted.

Meanwhile, the determination of the subframe index for transmission of the HARQ feedback signal for the HARQ packet when K 'is positive is performed as follows.

If K 'is a positive number, the processing of the HARQ signal that cannot be accepted in the current frame, that is, the next process of the HARQ signal corresponding to the DK' subframe index is all performed in the next frame, and is processed in particular in the first subframe of the next frame. do. That is, when K 'is a positive number, HARQ signals (HARQ packets and HARQ feedback signals) that can be transmitted in the next frame based on D-K' are processed before the newly allocated HARQ packets (data burst) in the next frame to delay the delay. prevent.

To this end, when K '> 0, the subframe index n for transmitting the HARQ feedback signal for the HARQ packet transmitted in the m = l th subframe is determined according to Equation (8).

As shown in Equation 8, when 0 ≦ m <X, HARQ feedback is allocated to the first subframe of the current frame. When X ≦ m <D-K ', HARQ feedback is allocated to a subframe corresponding to the UL subframe index (m-X) of the current frame. When D-K '≦ m <D, HARQ feedback is allocated to the first subframe of the next frame and processed before the feedback signal for the HARQ packet to be newly allocated in the next frame.

To this end, the index j of the frame to which the HARQ feedback is allocated is determined by (i + z) mod (f). f indicates a limit range of a frame to which a feedback signal can be transmitted, and i indicates an index of a current frame. The frame offset z is determined according to Equation 9 when K '≧ 0.

On the other hand, when the HARQ packet is transmitted in Long TTI, m indicates a subframe index which is a time point at which the transmission of the last part of the HARQ packet is completed. For example, when the HARQ packet is transmitted by occupying all downlink subframes, m becomes the last subframe index D-1.

If the resource allocation position for retransmission of the DL HARQ packet is determined to be the same as the resource allocation position of the previously transmitted HARQ packet, a synchronous HARQ scheme is employed. When the base station changes the resource allocation location for the retransmission packet in order to more effectively obtain the scheduling gain when the resource allocation, it becomes an asynchronous HARQ transmission scheme.

Table 4 shows TDD UL HARQ timing according to another embodiment of the present invention.

First, a case in which a UL HARQ packet is transmitted to one TTI will be described according to Table 4.

In Table 4, K 'is determined according to Equation 5. As shown in Table 4, the subframe index m for the UL HARQ packet transmission, the subframe index n for the transmission of the HARQ feedback signal, and the retransmission of the HARQ packet according to the case of K'≤0 and K '> 0. The subframe index m is determined differently.

As described above, in the case of K '≤ 0, since the number U of uplink subframes belonging to one frame is greater than or equal to the value of one subframe size added to Tproc, HARQ signals in all uplink subframes of the current frame. Processing (HARQ packet transmission and HARQ feedback signal transmission) may be performed.

On the other hand, unlike the DL packet transmission scheme, UL packet transmission is affected by the configuration ratio of the downlink subframe and the uplink subframe. In particular, when U is larger than D, the limit of the subframe position for UL packet transmission is reduced, and thus the base station can allocate resources to the appropriate UL region.

First, in the case of D> U, a method of determining a subframe position for transmission of a UL HARQ packet is as follows. If the frame configuration ratio is D≥U and K'≤0, the subframe index m for the transmission of the UL HARQ packet is determined as follows.

In equation (10), X is determined according to equation (7).

As shown in Equation 10, when 0 ≦ l <X, the uplink subframe index m for transmitting the UL HARQ packet is 0. When X≤l <D, the uplink subframe index m for transmitting the UL HARQ packet becomes l-X.

If the frame configuration is D> U and K '> 0, the subframe index m for transmitting the UL HARQ packet is determined as follows.

As shown in Equation 11, when 0 ≦ l <X, the UL HARQ packet is allocated to a subframe corresponding to the uplink subframe index 0 of the current frame. When X≤l <D-K ', the UL HARQ packet is allocated to a subframe corresponding to the uplink subframe index l-X of the current frame. If D-K'≤l <D, the UL HARQ packet is allocated to a subframe corresponding to one of lX in uplink subframe index 0 of the next frame and precedes the feedback signal for the HARQ packet to be newly allocated in the next frame. Is processed.

The frame index j for the UL HARQ packet is determined by (i + v _d ) mod (f), f indicates a limit range of a frame in which the HARQ packet can be transmitted, and i indicates an index of the current frame. v _d indicates whether to allocate the UL HARQ packet to the next frame as 0 and 1, and if the frame configuration is D> U, v _d is determined according to Equation 12.

In case of D≤U, a method of determining a location of a subframe for transmitting a UL HARQ packet is as follows.

If the frame configuration is D≤U and K'≤0, the subframe index m for transmitting the UL HARQ packet is determined differently for X≥0 and X <0, as shown in Equations 13 and 14 do.

If the frame configuration is D≤U and K '> 0, it is arithmetically generated only if X <0. At this time, the subframe index m for transmitting the UL HARQ packet is determined as follows.

When D≤U, the position j of the frame for transmitting the UL HARQ packet is determined by (i + v _u ) mod (f), and v _u is determined according to Equation 16.

Hereinafter, the transmission of the UL HARQ feedback signal according to Table 4 will be described.

Unlike the transmission of the UL HARQ packet, the transmission of the UL HARQ feedback signal is different from the transmission of the UL HARQ packet. The subframe index for the transmission of the DL HARQ feedback signal according to a case in which a value is negative and a positive value including 0 is calculated using K '. The position of n is determined differently. The subframe index n for transmitting the DL HARQ feedback signal is determined according to Equation 17.

When K'≤0, since the number U of uplink subframes belonging to one frame is greater than or equal to the value of one subframe size added to Tproc, HARQ feedback signal transmission may be performed in all uplink subframes of the current frame. . That is, the corresponding HARQ feedback signal may be transmitted at the same position as the subframe position in which the UL resource allocation control signal in the previously transmitted DL frame is transmitted. That is, n = l.

If K '> 0 and the HARQ feedback signal is the first feedback signal for the UL HARQ packet, n = l if it is in the range of m≥D-K', otherwise, the subframe of the UL HARQ packet previously transmitted The index obtained by adding K 'to the index m becomes the transmission position of the HARQ feedback signal for the HARQ packet.

The position k of the frame for transmission of the HARQ feedback signal is determined by (i + 1 + w) mod (f), f denotes a limit of a frame to which HARQ feedback can be transmitted, and i denotes an index of the current frame. Indicates. w indicates whether 0 or 1 is allocated to the next frame and is determined according to Equation 18.

According to Table 4, the subframe position for retransmission of the UL HARQ packet is the same as the subframe position m for the transmission of the initial UL HARQ packet. In addition, the position k of the frame for retransmission of the UL HARQ packet is represented by (k + v _r ) mod (f), f represents a limit range of the frame that can be retransmitted UL HARQ packet, i i Represents an index. v _r indicates whether or not to allocate the UL HARQ packet to be retransmitted to the next frame as 0 and 1, and is determined according to Equation 19

Meanwhile, TDD DL when N _TTI = any TTI, that is, data burst is transmitted by occupying a subframe according to an arbitrary TTI value, and when N _TTI = long TTI, that is, data burst is transmitted by occupying all subframes. UL HARQ timing is similar to that of one TTI, where HARQ timing is shown in Tables 3 and 4.

In this case, the frame offset z is determined according to Equation 20 and Equation 21.

Meanwhile, in the UL HARQ timing calculation method, when N _TTI = long TTI, the frame offset v _long is determined by Equation 22 as follows.

Next, the TDD HARQ timing according to Table 3 or Table 4 will be described with reference to FIGS. 10 and 11.

10 shows TDD DL HARQ timing according to another embodiment of the present invention.

In particular, FIG. 10 shows TDD DL HARQ timing according to Table 3 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 10 is according to the adaptive asynchronous HARQ method, and the resource allocation and transmission format for HARQ retransmission may be different from the resource allocation and transmission format for initial transmission.

10 shows that the base station 100 has a subframe corresponding to downlink subframe index 4 of the i-th frame, a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame, and (i + 1) An example of transmitting downlink data bursts for channels A, B, and C to the mobile station 200 in a subframe corresponding to downlink subframe index 2 of the first frame, respectively. According to Table 3, the mobile station 200 receives feedback on downlink data bursts for channels A, B, and C and corresponds to uplink subframe indexes 0, 0, and 1 of the (i + 1) th frame. Are transmitted to the base station 100, respectively. As a result, when the feedback is negative, the base station 100 sets the downlink data bursts for the channels A, B, and C in the subframes corresponding to the downlink subframe indexes 1, 1, and 2 of the (i + 2) th frame. Resend. As such, when the HARQ timing of Table 3 is used, HARQ procedures for channels A, B, and C are sequential and packet transmission delays can be prevented.

11 shows TDD UL HARQ timing according to another embodiment of the present invention.

In particular, FIG. 11 shows TDD UL HARQ timing according to Table 4 in one TTI transmission where Tproc = 3 and D: U = 5: 3. 11 is in accordance with the synchronous HARQ method, and the location of resources for HARQ retransmission is allocated to be the same as the location of resources for initial transmission.

11 shows a subframe corresponding to downlink subframe index 4 of the i-th frame, a subframe corresponding to downlink subframe index 1 of the (i + 1) th frame, and (i + 1). An example of transmitting uplink resource allocation information for channels A, B, and C to the mobile station 200 in a subframe corresponding to downlink subframe index 2 of the first frame is shown. According to Table 4, the mobile station 200 transmits uplink data bursts for channels A, B, and C, respectively, in subframes corresponding to uplink subframe indexes 0, 0, and 1 of the (i + 1) th frame. do. The base station 100 transmits feedback on uplink data bursts for channels A, B, and C in the subframes corresponding to downlink subframe indexes 1, 1, and 2 of the (i + 2) th frame, respectively. To transmit. If this feedback is a negative response, the mobile station 200 sets uplink data bursts for channels A, B, and C in subframes corresponding to uplink subframe indexes 0, 0, 1 of the (i + 2) th frame. Resend each. As such, according to the HARQ timing of Table 4, the HARQ procedure for channels A, B, and C is sequential and packet transmission delay can be prevented.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Base station 100, mobile station 200

Claims (20)

A method for a mobile station to communicate with a base station using a frame including at least one downlink subframe and at least one uplink subframe,
Receiving a data burst from the base station in a frame corresponding to a first frame index;
Determining a first parameter value using a difference between a radio signal processing time and the number of the one or more uplink subframes;
Determining a frame offset using the first parameter value; And
And transmitting feedback for the data burst to the base station in a frame corresponding to a second frame index determined according to the first frame index and the frame offset. The method of claim 1,
Determining the frame offset
And determining the frame offset based on a difference between the number of the one or more downlink subframes and the first parameter value. The method of claim 2,
Receiving the data burst
Receiving the data burst in a subframe corresponding to a downlink subframe index of the frame corresponding to the first frame index;
The step of transmitting the feedback is
Determining an uplink subframe index using the downlink subframe index and the first parameter value;
And transmitting the feedback in a subframe corresponding to the uplink subframe index of the frame corresponding to the second frame index. The method of claim 3,
The determining of the uplink subframe index
And determining the uplink subframe index as 0 when the downlink subframe index is greater than or equal to the number of the one or more downlink subframes minus the first parameter value. The method of claim 3,
The determining of the uplink subframe index
Determining a second parameter value by using a difference between the number of one or more downlink subframes and a radio signal processing time;
And determining the uplink subframe index using the downlink subframe index, the first parameter value, the second parameter value, and the number of subframes occupied by the data burst. The method of claim 5,
The uplink subframe index is determined by the following equation when the first parameter value is less than or equal to zero.

Herein, n corresponds to the uplink subframe index, m corresponds to the downlink subframe index, N _TTI corresponds to the number of subframes occupied by the data burst, and X is the second parameter value. D corresponds to the number of the one or more downlink subframes. The method of claim 6,
The uplink subframe index is determined by the following equation when the first parameter value is greater than zero.

Here, K 'corresponds to the first parameter value. A method of communicating with a mobile station by a base station using a frame including at least one downlink subframe and at least one uplink subframe,
Transmitting a data burst to the mobile station in a frame corresponding to a first frame index;
Receiving feedback from the mobile station for the data burst in a frame corresponding to a second frame index,
The second frame index is determined according to the first frame index and the frame offset;
The frame offset is determined using a parameter value determined through a difference between a radio signal processing time and the number of one or more uplink subframes. The method of claim 8,
The frame offset is determined based on the difference between the number of the one or more downlink subframes and the parameter value. 10. The method of claim 9,
The data burst is transmitted in a subframe corresponding to a downlink subframe index,
The feedback is received in a subframe corresponding to an uplink subframe index,
And if the downlink subframe index is greater than or equal to the number of the one or more downlink subframes minus the parameter value, the uplink subframe index is determined to be zero. A method for a mobile station to communicate with a base station using a frame including at least one downlink subframe and at least one uplink subframe,
Receiving resource allocation information from the base station in a frame corresponding to a first frame index;
Determining a first parameter value using a difference between a radio signal processing time and the number of the one or more uplink subframes;
Determining a first frame offset using the first parameter value; And
And transmitting a data burst to the base station in a frame corresponding to a second frame index determined according to the first frame index and the first frame offset. The method of claim 11,
Receiving feedback for the data burst in a frame corresponding to a third frame index,
The third frame index is determined according to the second frame index and the second frame offset,
And the second frame offset is determined using the first parameter value. The method of claim 12,
Determining a third frame offset using the first parameter value if the feedback is negative; And
Retransmitting the data burst to the base station in a frame corresponding to a fourth frame index determined according to the third frame index and the third frame offset. The method of claim 13,
The second frame offset is determined by comparing the number of the one or more downlink subframes, the difference between the first parameter value and the second frame index,
The third frame offset is determined by comparing the number of the one or more downlink subframes, the difference between the first parameter value and the third frame index. The method of claim 13,
The resource allocation information is received in a subframe corresponding to the first downlink subframe index,
The data burst is transmitted in a subframe corresponding to the first uplink subframe index,
The first uplink subframe index is determined using the first parameter value. 16. The method of claim 15,
The first uplink subframe index is
The number of subframes occupied by the data burst,
Comparing the number of the one or more downlink subframes with the number of the one or more uplink subframes,
The first parameter value, and
And a second parameter value determined by using a difference between the number of the one or more downlink subframes and the radio signal processing time. The method of claim 16,
The feedback is received in a subframe corresponding to the second downlink subframe index,
The data burst is retransmitted in a subframe corresponding to a second uplink subframe index,
The second downlink subframe index is determined using the number of subframes occupied by the data burst and the first parameter value.
The second uplink subframe index is the same as the first uplink subframe index. A method of communicating with a mobile station by a base station using a frame including at least one downlink subframe and at least one uplink subframe,
Transmitting resource allocation information to the mobile station in a frame corresponding to a first frame index;
Receiving a data burst from the mobile station in a frame corresponding to a second frame index.
The second frame index is determined according to the first frame index and the frame offset;
The frame offset is determined using a parameter value determined through a difference between a radio signal processing time and the number of one or more uplink subframes. The method of claim 18,
Transmitting feedback for the data burst in a frame corresponding to a third frame index; And
Re-receiving the data burst to the base station in a frame corresponding to a fourth frame index,
The third frame index is determined using the first parameter value,
And the fourth frame index is determined using the first parameter value. The method of claim 19,
The resource allocation information is transmitted in a subframe corresponding to the first downlink subframe index,
The data burst is received in a subframe corresponding to a first uplink subframe index,
The first uplink subframe index is determined using the first downlink subframe index and the first parameter value.

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