KR20210129615A - Data transmission device and data retransmission method - Google Patents

Abstract

The present invention proposes a new method (technology) for performing DL data retransmission without relying on a TDD slot structure (eg, a DDDSU structure) in which D slots and S slots are mixed in a 5G NR TDD system. A data transmission device includes a data transmission unit which transmits data based on a slot structure consisting of two or more slots having different configurations for data transmission; and a transmission control unit which uses a second slot to transmit new data, when transmission of different specific data fails in the first slot used at the time of previous transmission among the two or more slots and the second slot located at the time when retransmission is possible.

Description

DATA TRANSMISSION DEVICE AND DATA RETRANSMISSION METHOD

The present invention relates to a technique for retransmitting downlink (DL) data in a 5G NR TDD system.

In NR (New Radio), that is, 5G NR system using a high frequency band of 3.5 GHz or higher, when using the TDD transmission method, for high-speed DL transmission, Downlink) adopts a slot structure that allocates many DL slots for data transmission.

For example, the 5G NR TDD system may adopt a DDDSU structure, and each slot D (Downlink), S (Special), and U (Uplink) constituting the DDDSU structure has the following configuration.

D Slot: 14 DL Symbols

S Slot: 10 DL Symbols, 2 UL Symbols, 2 Guard Symbols

U Slot: 14 UL Symbols

In such a 5G NR TDD system, a hybrid-ARQ (HARQ) retransmission technique is used to cope with data transmission failure.

The HARQ retransmission scheme is performed in units of HARQ processes and operates asynchronously. The 5G NR TDD system assigns (assigns) a HARQ Process Number to DL data transmitted in every DL slot, and determines when the UE receives the DL data and when to transmit the HARQ Feedback (Ack or Nack) to the UL. is determined through

Accordingly, according to the HARQ retransmission technique, when the base station (gNB) receives an Ack (transmission success) to the UL determined through K1 for DL data, it maps new DL data to the corresponding HARQ process number, allocates it to the terminal, and assigns the NDI (New Data Indicator) value can be toggled (0->1, or 1->0) to transmit new DL data to which the corresponding HARQ Process Number is assigned (allocated) in the next DL slot.

Meanwhile, according to the HARQ retransmission technique, when the base station (gNB) receives a Nack (transmission failure) to the UL determined through K1 for DL data, it maps the same DL data to the corresponding HARQ process number, allocates it to the terminal, and assigns an NDI value. Without toggle, DL data can be retransmitted by allocating the same resources (number of DL physical resource blocks (DL PRBs), number of DL symbols, etc.) as those of previously failed transmission in order to obtain HARQ retransmission combining gain.

At this time, assuming the DDDSU structure in the 5G NR TDD system, since the number of DL symbols in the D slot is larger than the number of DL symbols in the S slot, in the case of DL data that has failed to be transmitted using 11 to 14 PDSCH symbols in the D slot Retransmission is not possible in the S slot, and in the case of DL data that has failed to be transmitted in the S slot, retransmission is performed in the S slot for the reason that it is difficult to provide the same slot configuration as that used for transmission in the S slot in the D slot.

Therefore, according to the existing HARQ retransmission technique, when D slots and S slots coexist in a TDD slot structure (eg, DDDSU structure) in a 5G NR TDD system, the configuration of the number of DL symbols is different between the D slots and the S slots. Retransmission can be performed only in a slot having the same configuration as that used for transmission, and this has a limitation in that a delay occurs when retransmitting DL data.

In the present invention, in a 5G NR TDD system, a new HARQ retransmission scheme capable of performing DL data retransmission without relying on a TDD slot structure (eg, a DDDSU structure) in which D slots and S slots are mixed is proposed.

The present invention was created in view of the above circumstances, and the object of the present invention is to achieve DL data without relying on a TDD slot structure (eg, DDDSU structure) in which D slots and S slots are mixed in a 5G NR TDD system. An attempt is made to provide a HARQ retransmission scheme (method) capable of performing retransmission.

According to a first aspect of the present invention, there is provided a data transmission apparatus comprising: a data transmission unit for transmitting data based on a slot structure including two or more slots having different configurations for data transmission; a check unit for confirming whether a first slot used at a previous transmission time point and a second slot located at a retransmission time point have the same configuration with respect to the specific data that has failed to be transmitted among the transmitted data; and a transmission control unit configured to transmit the specific data as new data using the second slot when the configuration of the check result is different.

In detail, the transmission control unit may allow the specific data to be transmitted as retransmission data using the second slot when the configuration of the check result is the same.

Specifically, the two or more slots may be slots having different configurations of down link (DL) symbols.

Specifically, the transmission control unit, when the confirmation result configuration is different, allocates HARQ (Hybrid Automatic Repeat Request) process and resource (Physical Resource) differently from the previous transmission using the first slot for the specific data transmission Thus, the specific data may be transmitted using the allocated HARQ process and resources in the second slot.

Specifically, the transmission control unit, when allocating the HARQ process for the specific data transmission, toggles a New Data Indicator (NDI) value other than the HARQ process in the previous transmission using the first slot or the same HARQ process ( Toggle) and can be assigned.

Specifically, the transmission control unit, when allocating the resource for the specific data transmission, may allocate the size of the transport block to be greater than or equal to the size of the transport block during the previous transmission using the first slot.

Specifically, the retransmission time point may be determined by a time point at which a transmission failure response for the specific data is received and a time point at which data processing for transmitting the data is completed.

In order to achieve the above object, there is provided a data retransmission method performed in a base station according to a second aspect of the present invention, comprising: a data transmission step of transmitting data based on a slot structure consisting of two or more slots having different configurations for data transmission; checking whether a first slot used at a previous transmission time point and a second slot located at a retransmission time point have the same configuration with respect to the specific data that has failed to be transmitted among the transmitted data; and a transmission control step of allowing the specific data to be transmitted as new data using the second slot when the configuration of the check result is different.

Specifically, the transmission control step may allow the specific data to be transmitted as retransmission data using the second slot when the configuration result is the same as the check result.

Specifically, in the transmission control step, when the confirmation result configuration is different, the HARQ (Hybrid Automatic Repeat Request) process and the resource (Physical Resource) are different from the previous transmission using the first slot for the specific data transmission. By allocating, the specific data may be transmitted using the allocated HARQ process and resources in the second slot.

Specifically, in the transmission control step, when the HARQ process for the specific data transmission is allocated, the HARQ process other than the HARQ process in the previous transmission using the first slot or the same HARQ process is toggled with a New Data Indicator (NDI) value It can be assigned after (Toggle).

Specifically, in the transmission control step, the size of the transport block when allocating the resource for the specific data transmission may be assigned to be greater than or equal to the transport block size during the previous transmission using the first slot.

Accordingly, according to the data transmission apparatus and data retransmission method of the present invention, HARQ capable of performing DL data retransmission without relying on a TDD slot structure (eg, DDDSU structure) in which D slots and S slots are mixed in a 5G NR TDD system The retransmission technique (plan) is realized.

Accordingly, according to the present invention, since it is possible to transmit in a slot of a different configuration from that of the prior (first) transmission of DL data in the 5G NR TDD system, additional delay time caused by the TDD slot structure (eg, DDDSU structure) is reduced. Minimize the effect.

1 is an exemplary diagram showing an example of DL data retransmission timing according to the conventional HARQ retransmission scheme.
2 is an exemplary diagram showing the configuration of a data transmission apparatus according to an embodiment of the present invention.
3 is an exemplary diagram illustrating a previous transmission/retransmission slot combination as a table according to an embodiment of the present invention.
4 is an exemplary diagram illustrating an example of DL data retransmission timing according to an embodiment of the present invention.
5 is a control flowchart illustrating a data retransmission method (method) according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The present invention relates to a technique for retransmitting downlink (DL) data in a 5G NR TDD system.

In NR (New Radio), that is, 5G NR system using a high frequency band of 3.5 GHz or higher, when using the TDD transmission method, for high-speed DL transmission, Downlink) adopts a slot structure that allocates many DL slots for data transmission.

For example, the 5G NR TDD system may adopt a DDDSU structure, and each slot D (Downlink), S (Special), and U (Uplink) constituting the DDDSU structure has the following configuration.

D Slot: 14 DL Symbols

S Slot: 10 DL Symbols, 2 UL Symbols, 2 Guard Symbols

U Slot: 14 UL Symbols

In such a 5G NR TDD system, a hybrid-ARQ (HARQ) retransmission technique is used to cope with data transmission failure.

The HARQ retransmission scheme is performed in units of HARQ processes and operates asynchronously. The 5G NR TDD system assigns (assigns) a HARQ Process Number to DL data transmitted in every DL slot, and determines when the UE receives the DL data and when to transmit the HARQ Feedback (Ack or Nack) to the UL. is determined through

Accordingly, according to the HARQ retransmission technique, when the base station (gNB) receives an Ack (transmission success) to the UL determined through K1 for DL data, it maps new DL data to the corresponding HARQ process number, allocates it to the terminal, and assigns the NDI (New Data Indicator) value can be toggled (0->1, or 1->0) to transmit new DL data to which the corresponding HARQ Process Number is assigned (allocated) in the next DL slot.

Meanwhile, according to the HARQ retransmission technique, when the base station (gNB) receives a Nack (transmission failure) to the UL determined through K1 for DL data, it maps the same DL data to the corresponding HARQ process number, allocates it to the terminal, and assigns an NDI value. It is not toggled, and in order to obtain the HARQ retransmission combining gain, the same resources (the number of DL PRBs, the number of DL symbols, etc.) as those of the previously failed transmission are allocated, and the DL data can be retransmitted.

At this time, assuming the DDDSU structure in the 5G NR TDD system, since the number of DL symbols in the D slot is larger than the number of DL symbols in the S slot, in the case of DL data that has failed to be transmitted using 11 to 14 PDSCH symbols in the D slot , retransmission is not possible in the S slot.

On the other hand, in the 5G NR TDD system, in the case of DL data that fails to be transmitted in the S slot, it is difficult to provide the same slot configuration as that used for transmission in the S slot in the D slot, signaling overhead increase, complexity increase, etc. It is implemented to perform retransmission in the S slot.

1 shows an example of DL data retransmission timing according to the conventional HARQ retransmission scheme set above.

In FIG. 1, it is assumed that the base station gNB receives a Nack (transmission failure) in Slot #9(U) of the UL determined through K1 (=6) after DL data transmission in Slot #3(S). have.

In this case, (A) assumes that the data processing (DL Data Processing) for this data transmission is completed before Slot #13.

As shown in (A), if DL Data Processing is completed before Slot #13, DL data that has failed to be transmitted can be retransmitted at the time of Slot #13. Since it is the same S slot as the used S slot, the base station (gNB) may retransmit the DL data that has failed to be transmitted in Slot #13 using the same HARQ Process Number/NDI (toggle X)/resource as in the previous (first) transmission.

(B) assumes that DL Data Processing for this time data transmission is completed after Slot #13.

As shown in (B), when DL Data Processing is completed after Slot #13, DL data that has failed to be transmitted can be retransmitted at a time point after Slot #13. ), since it is a D slot with a different configuration (number of DL symbols) from the S slot used for transmission, the base station (gNB) waits until Slot #18, which is the same S slot as in the previous (initial) transmission, for the DL data that has failed to transmit, and then waits for the same HARQ process as before. It can be retransmitted in Slot #18 using Number/NDI(Toggle X)/Resource.

As such, according to the existing HARQ retransmission technique, when D slots and S slots coexist in a TDD slot structure (eg, DDDSU structure) in a 5G NR TDD system, the configuration of the number of DL symbols is different between D slots and S slots. Retransmission can be performed only in a slot having the same configuration as that used for transmission, and this has a limitation in that a delay occurs when retransmitting DL data.

Accordingly, in the present invention, in a 5G NR TDD system, a new HARQ retransmission scheme capable of performing DL data retransmission without relying on a TDD slot structure (eg, a DDDSU structure) in which D slots and S slots coexist in a 5G NR TDD system is proposed. do.

Specifically, the HARQ retransmission scheme of the new method proposed in the present invention is to be realized through the data transmission apparatus described below.

2 shows the configuration of a data transmission apparatus according to an embodiment of the present invention.

As shown in FIG. 2 , the data transmission apparatus 100 according to an embodiment of the present invention may include a data transmission unit 110 , a check unit 120 , and a transmission control unit 130 .

Prior to a detailed description, the data transmission apparatus 100 of the present invention may be implemented in a gNB of a base station, that is, 5G, or may be a gNB.

Furthermore, the data transmission apparatus 100 of the present invention may further include a communication unit 140 .

Here, the communication unit 140 includes, but is not limited to, for example, an antenna system, an RF transceiver, one or more amplifiers, a tuner, one or more oscillators, a digital signal processor, a codec (CODEC) chipset, and a memory. All known circuits to perform may be included.

Accordingly, the data transmission device 100 connects/communicates with a receiving device 10 (eg, UE) that receives data based on the communication unit 140 , so that the UE 10 provides various types of data from the Core Network network. service can be used.

All or at least a part of the configuration of the data transmission apparatus 100 may be implemented in the form of a hardware module or a software module, or may be implemented in a form in which a hardware module and a software module are combined.

Here, the software module may be understood as, for example, a command executed by a processor that controls operations in the data transmission device 100 , and these commands may have a form mounted in a memory in the data transmission device 100 . There will be.

As a result, the data transmission apparatus 100 according to an embodiment of the present invention has a TDD slot structure in which D slots and S slots are mixed in a new scheme proposed by the present invention, that is, in a 5G NR TDD system (eg: A new HARQ retransmission scheme capable of performing DL data retransmission without relying on the DDDSU structure) is realized. Hereinafter, each configuration in the data transmission apparatus 100 for realizing this will be described in more detail.

The data transmission unit 110 is responsible for transmitting data based on a slot structure including two or more slots having different configurations for data transmission.

The present invention relates to a 5G NR TDD system, and more particularly to a technique for retransmitting downlink (DL) data in a 5G NR TDD system.

Accordingly, the data transmission unit 110 transmits data according to the TDD transmission method.

In addition, two or more slots having different configurations for DL transmission mean slots having different configurations of the number of DL symbols in the configuration of a down link (DL) symbol. For example, assuming the current standard, a D slot ( 14 DL symbols) and S slots (10 DL symbols, 2 UL symbols, 2 Guard symbols).

In this case, the data transmitter 110 may transmit DL data to the UE 10 based on a DL TDD slot structure including D slots and S slots having different DL symbol number configurations, for example, a DDDSU structure.

The confirmation unit 120, with respect to the specific data that has failed to be transmitted among the data transmitted by the data transmission unit 110, has the same configuration in which the first slot used at the time of previous transmission and the second slot located at the time when retransmission is possible are identical to each other. Responsible for checking whether

Here, the specific data that has failed to be transmitted means DL data that has received a Nack (transmission failure) from the UE 10 .

In the 5G NR TDD system, the HARQ retransmission technique is used to cope with data transmission failure.

Accordingly, the DL data transmitted from the data transmission unit 110, that is, the DL data transmitted in every DL slot (D slot or S slot), has an arbitrary order among HARQ Process #1, #2??#N(115). Selected (asynchronous)/allocated HARQ Process Number is given, and other information such as NDI and K1 is also transmitted.

The UE 10 decodes the DL data normally, and when reception succeeds, Ack (transmission success) is fed back to the base station (gNB) to the UL determined through K1, and when decoding fails, Nack (transmission failure) to the UL determined through K1 Feedback to the base station (gNB).

Accordingly, the checker 120 may check the DL data for which a Nack (transmission failure) is received among the DL data transmitted by the data transmitter 110 as specific data that has failed to be transmitted.

And, for the specific DL data that has failed to be transmitted, the check unit 120 may check whether the first slot used at the time of previous (first) transmission and the second slot located at the time when retransmission is possible have the same configuration. have.

Here, the retransmission time point may be determined by a time point at which a transmission failure response (Nack) for specific DL data that has failed to be transmitted is received (Feedback) and a time point at which data processing for transmitting the current data (DL Data Processing) is completed. have.

That is, the time point at which retransmission is possible means a time point at which resources (HARQ Process, resources, etc.) for (re)transmission can be allocated to specific data (=MAC PDU) of transmission failure requiring retransmission, which is the base station (gNB). It is determined according to the DL Data Processing Capability of the DL and the adopted slot structure (eg, DDDSU structure).

Accordingly, the retransmission is possible after the time when the data transmission failure is confirmed and the target of retransmission is confirmed, that is, after the Nack is feedback, and based on the time when the data processing for this data transmission (DL Data Processing) is completed. It may mean the earliest point in time.

In other words, for the specific DL data that has failed to be transmitted, the check unit 120 determines the first slot used at the time of previous (first) transmission, and the point at which retransmission is possible, that is, the earliest time based on the completion of this DL Data Processing. It can be checked whether the second slots located in , have the same configuration.

The transmission control unit 130 allows the specific data to be transmitted as new data using the second slot when the configuration of the verification result of the verification unit 120 is different.

On the other hand, when the confirmation result of the confirmation unit 120 has the same configuration, the transmission control unit 130 transmits specific data as retransmission data using the second slot.

If it is assumed that the first slot used at the time when the specific data that has failed to be transmitted, that is, the specific DL data previously (first) transmitted is the D slot, if the second slot is the D slot, the first and second It is confirmed that the configuration of the slot, that is, the configuration of the number of DL symbols is the same, and when the second slot is an S slot, the check unit 120 will check that the configuration of the first and second slots, that is, the configuration of the number of DL symbols is different.

In addition, if it is assumed that the first slot used at the time when the specific data that has failed to be transmitted, that is, the specific DL data previously (first) transmitted is an S slot, when the second slot is an S slot, the first and second It is confirmed that the configuration of the slot, that is, the configuration of the number of DL symbols is the same, and when the second slot is the D slot, the check unit 120 will check that the configuration of the first and second slots, that is, the configuration of the number of DL symbols is different.

That is, the transmission control unit 130 uses the second slot for specific DL data according to the existing HARQ retransmission scheme if the configuration as a result of the verification of the verification unit 120 is the same (D slot-D slot, or S slot-S slot). to be transmitted as retransmission DL data, but if the configuration is different as a result of checking by the checking unit 120 (D slot-S slot, or S slot-D slot), specific DL data according to the new HARQ retransmission scheme proposed in the present invention is transmitted as new DL data using the second slot.

Specifically, when the confirmation result configuration of the confirmation unit 120 is the same (D slot-D slot, or S-slot-S slot), the transmission control unit 130 controls the previous (first) transmission time for specific DL data transmission. The same specific DL data is mapped with the same HARQ process (HARQ Process Number) and assigned to the UE 10, the NDI value is not toggled, and the same resources (DL PRB number, DL Symbol number, DL MCS, number of layers, etc.) so that specific DL data is transmitted in the second slot using the same HARQ process and resources allocated as before (initial).

In this case, the base station gNB under the control of the transmission control unit 130 may transmit the specific DL data that has failed to be transmitted using the same HARQ Process Number/NDI (toggle X)/resource as in the previous (initial) transmission. The base station (gNB) may transmit specific DL data as retransmission DL data according to the existing HARQ retransmission scheme.

On the other hand, the transmission control unit 130, when the confirmation result of the confirmation unit 120 has a different configuration (D slot-S slot, or S slot-D slot), the transfer control unit 130 using the first slot for specific DL data transmission (first time). ) by allocating a HARQ process and a resource (Physical Resource) differently from the time of transmission, so that specific DL data is transmitted in the second slot using the HARQ process and resource allocated differently from before.

More specifically, when the transmission control unit 130 allocates a HARQ process number for transmission of specific DL data, a HARQ process other than the HARQ process in the previous (first) transmission using the previously failed first slot Alternatively, the same HARQ process is allocated after toggling the New Data Indicator (NDI) value.

That is, when the transmission control unit 130 allocates a HARQ process number for transmission of specific DL data, the same HARQ Process Number as in the previous (initial) transmission in the existing HARQ retransmission scheme is allocated without NDI value toggle, and the UE ( 10), unlike the previous (first) transmission time, different from the HARQ process (HARQ Process Number), for example, in any order among HARQ Process #1, #2??#N(115) (asynchronous) By assigning the HARQ process number selected as NDI value toggle (O->1, or 1->), it is possible to allow the UE 10 to recognize that specific DL data is newly transmitted new data.

Alternatively, when the transmission control unit 130 allocates a HARQ process number for transmission of specific DL data, the same HARQ Process Number as in the previous (initial) transmission in the existing HARQ retransmission scheme is allocated without toggle of the NDI value to the UE ( Unlike making the 10) recognize that it is retransmission data, the same HARQ process (HARQ Process Number) as in the previous (first) transmission is assigned after the NDI value toggle (O->1, or 1->) to the UE (10) It can also be made to recognize that the specific DL data is newly transmitted new data.

In addition, the transmission control unit 130, when allocating resources (eg, the number of DL PRBs, the number of DL symbols, the number of DL MCS, the number of layers, etc.) for specific DL data transmission, the size of the transport block (eg, Transport Block Size (TBS)) ) is allocated to be greater than or equal to the transport block size (TBS) of the previous (first) transmission using the previously failed first slot.

That is, the transmission control unit 130, the resource for transmission of specific DL data so as to have a size (TBS) of a transport block greater than or equal to a transport block size (TBS) at the time of previous (first) transmission using the previously failed first slot ( Example: The number of DL PRBs, the number of DL symbols, the number of DL MCSs, the number of layers, etc.) is allocated and set so that the same amount of DL data can be transmitted when the previous (first) failure occurs.

For example, it is assumed that the first slot used at the time when specific DL data was previously (first) transmitted is an S slot, and 9 DL symbols (one DL symbol is for PDCCH) during previous (first) transmission in the S slot. , it is assumed that specific DL data is transmitted by allocating/using 64 PRBs.

In this case, the total number of resource elements (REs) used is 9 x 64 x 12 (the number of subcarriers per PRB) = 6912 pieces. (※ TBS is determined by the total number of REs (determined by the number of DL PRBs and DL symbols), DL MCS, and the number of layers.)

And, assuming that the second slot for transmitting specific DL data is the D slot, 13 DL symbols (one DL symbol is for PDCCH) can be used in the D slot, so the transmission control unit 130 transmits the previous (first) In order to have a TBS greater than or equal to the previous (first) transmission (failure) by allocating REs greater than or equal to the (failure) time, a minimum of 45 PRBs may be allocated so that the REs are 6912 or more. (13 x 45 x 12 = 7020)

As such, in the present invention, when the DL slots of the initial (previous) transmission time and the retransmission possible time are different, the NDI value is toggled with a different or the same HARQ Process (HARQ Process Number) in the DL data to be retransmitted (= MAC PDU). By allocating and allocating a new resource (Physical Resource), retransmission may be performed as if transmission of new new DL data.

FIG. 3 shows the previous transmission/retransmission slot combination as a table when the present invention is applied.

As can be seen from the table of FIG. 3 , when the DL slots of the initial (previous) transmission timing (Timing) and the retransmission possible timing (Timing) are the same, that is, Case 1 is all D slots-D slots, and Case 1 is all S slots-S slots. In 4, the existing HARQ retransmission technique and the new HARQ retransmission technique of the present invention may perform DL data retransmission in the same manner.

On the other hand, when the DL slots of the initial (previous) transmission timing (Timing) and the retransmission possible timing (Timing) are different, that is, in Case 2 (D slot-S slot) and Case 3 (S slot-D slot), the existing HARQ retransmission scheme is the first Because retransmission is supported only in a slot having the same configuration (number of DL symbols) as the (previous) transmission slot, retransmission is impossible, and a slot having the same configuration (number of DL symbols) as the first (previous) transmission slot must be waited.

However, when the DL slots of the initial (previous) transmission timing and the retransmission possible timing are different, that is, in Cases 2 and 3, the new HARQ retransmission scheme of the present invention is different from the first (previous) transmission HARQ Process DL data retransmission can be performed by allocating /NDI (toggle) and allocating a new resource (Physical Resource).

As described above, in the new HARQ retransmission scheme proposed by the present invention, even when the DL slots of the initial (previous) transmission time and the retransmission possible time are different, the DL data to be retransmitted (= MAC PDU) is different or the same HARQ Process (HARQ). Process Number) after toggling the NDI value and allocating a new resource (Physical Resource), retransmission can be performed as if transmission of new new DL data.

Since the HARQ Process/NDI (toggle) is assigned to the DL data that is retransmitted as if it is the transmission of new DL data, differently from the previous (first) transmission, the UE 10 does not recognize it as a retransmission and sends new DL data. will be perceived as receiving.

However, since the actually transmitted DL data (= MAC PDU) is the same data as the previously (first) transmitted DL data, it can be seen as semantically retransmission, and as long as it is decoded and received normally in the UE 10, any HARQ Process Whether it is transmitted through (HARQ Process Number), there will be no problem with data processing according to the standard.

4 shows an example of DL data retransmission timing according to the HARQ retransmission scheme realized in the present invention.

In FIG. 4, it is assumed that the base station gNB receives a Nack (transmission failure) in Slot #9(U) of the UL determined through K1 (=6) after DL data transmission in Slot #3(S). have.

In this case, if DL Data Processing for this data transmission is completed after Slot #13, the existing HARQ retransmission scheme waits until Slot #18, which is the same S slot as in the previous (initial) transmission, for DL data that has failed to be transmitted, and then retransmits it ( As shown in (B) of FIG. 1 and FIG. 4, according to the present invention, the form of new data in the D slot (Slot #15) located at the earliest point based on the completion of this DL Data Processing for DL data that has failed to be transmitted according to the present invention can be retransmitted to

As described above, according to the present invention, even when the DL slots of the initial (previous) transmission time and the retransmission possible time are different in the 5G NR TDD system, the DL data to be retransmitted (= MAC PDU) is the transmission of new DL data. As a method of performing retransmission, the HARQ retransmission scheme (plan) is realized.

Accordingly, according to the present invention, in the 5G NR TDD system, the slot of the configuration different from that of the previous (first) transmission is not dependent on the TDD slot structure (eg, the DDDSU structure) in which the D slot and the S slot are mixed, and when DL data is retransmitted. Since it can also be transmitted in a TDD slot structure (eg, a DDDSU structure), an effect of minimizing the additional delay time caused by the structure is derived.

Hereinafter, a data retransmission method according to an embodiment of the present invention will be described with reference to FIG. 5 .

The data retransmission method of the present invention is the same as the HARQ retransmission method (method) realized in the data transmission apparatus 100 of the present invention.

In the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100 transmits the data to the UE 10 based on a DL TDD slot structure including D slots and S slots having different DL symbol number configurations, for example, a DDDSU structure. DL data may be transmitted (S10).

And, in the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100 checks the specific DL data that has failed to be transmitted among the DL data transmitted in step S10 ( S20 ).

Here, the specific DL data that has failed to be transmitted means DL data that has received a Nack (transmission failure) from the UE 10 .

In the 5G NR TDD system, the HARQ retransmission technique is used to cope with data transmission failure.

Accordingly, the DL data transmitted in step S10, that is, the DL data transmitted in every DL slot (D slot or S slot), is selected in any order among HARQ Process #1, #2??#N(115) (asynchronous type). )/allocated HARQ Process Number (or ID) is assigned, and other information such as NDI and K1 is also transmitted.

The UE 10 decodes the DL data normally, and when reception succeeds, Ack (transmission success) is fed back to the base station (gNB) to the UL determined through K1, and when decoding fails, Nack (transmission failure) to the UL determined through K1 Feedback to the base station (gNB).

Accordingly, in the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100 may identify DL data for which Nack (transmission failure) is received among the DL data transmitted in step S10 as specific data that has failed to be transmitted ( S20 Yes).

And, in the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100, for the specific DL data for which transmission failure is confirmed (S20 Yes), the first slot used at the previous (first) transmission time and It may be checked whether the second slots located at the time point at which retransmission is possible have the same configuration as each other (S30).

That is, the data transmission apparatus 100 is positioned at the first slot used at the time of previous (first) transmission for the specific DL data that has failed to be transmitted, and the point at which retransmission is possible, that is, the earliest time based on the completion of this DL Data Processing. It is checked whether the second slot to be used has the same configuration (number of DL symbols).

If it is assumed that the first slot used at the time when the specific DL data that has failed to be transmitted is an S slot, the configuration of the first and second slots, that is, the DL symbol in step S30, if the second slot is the S slot. It will be confirmed that the number configuration is the same (S30 Yes), and if the second slot is the D slot, it will be confirmed that the configuration of the first and second slots, that is, the configuration of the number of DL symbols, is different in step S30 (S30 No).

In the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100 determines that the configuration in step S30 is the same (D slot-D slot, or S slot-S slot) (S30 Yes), the existing HARQ According to the retransmission scheme, specific DL data is transmitted as retransmission DL data using the second slot (S60), and if the configuration is different as a result of checking in step S30 (D slot-S slot, or S slot-D slot) ( S30 No), specific DL data is transmitted as new DL data using the second slot according to the new HARQ retransmission scheme proposed by the present invention (S40 and S50).

Specifically, when the configuration as a result of checking in step S30 is the same (D slot-D slot, or S slot-S slot), the data transmission apparatus 100 performs the same HARQ as in the previous (first) transmission for specific DL data transmission. The same specific DL data is mapped to the process (HARQ Process Number) and allocated to the UE 10, the NDI value is not toggled, and the same resources (DL PRB number, DL Symbol number, DL MCS, number of layers, etc.), so that specific DL data is transmitted in the second slot using the HARQ process and resources allocated the same as before (initially) (S60).

In this case, the data transmission apparatus 100, that is, the base station (gNB), may transmit the specific DL data that has failed to be transmitted using the same HARQ Process Number/NDI (toggle X)/resource as in the previous (initial) transmission, and thus the base station The (gNB) may transmit specific DL data as retransmission DL data according to the existing HARQ retransmission scheme (S60).

On the other hand, if the data transmission apparatus 100 is different from the configuration as a result of checking in step S30 (D slot-S slot, or S slot-D slot), the previous (first) transmission using the first slot for specific DL data transmission By allocating a HARQ process and a resource (Physical Resource) differently from the time (S40), specific DL data is transmitted in the second slot using the HARQ process and resource allocated differently from before (S50).

According to a specific example, when allocating a HARQ process (HARQ Process Number) for transmission of specific DL data, the data transmission apparatus 100 performs a different HARQ process (HARQ Process Number) other than the HARQ process in the failed previous (first) transmission. can be assigned after toggling the New Data Indicator (NDI) value (S40).

That is, the data transmission apparatus 100 allocates the same HARQ Process Number/NDI (toggle X) as in the previous (first) transmission in the existing HARQ retransmission scheme when a HARQ process number for specific DL data transmission is allocated. In contrast to allowing the UE 10 to recognize that it is retransmission data, a different HARQ process (HARQ Process Number) from the previous (first) transmission, for example, an arbitrary sequence of HARQ Process #1, #2??#N (115) (asynchronous) to allocate the selected HARQ process (HARQ Process Number) after toggling the NDI value (O->1, or 1->) so that the UE 10 recognizes that the specific DL data is newly transmitted new data will be.

In addition, when allocating resources (eg, the number of DL PRBs, the number of DL symbols, the number of DL MCSs, the number of layers, etc.) for specific DL data transmission, the data transmission apparatus 100 is configured to perform a transport block size (eg, Transport Block Size (TBS)). )) is allocated to be greater than or equal to the transport block size (TBS) of the previous (first) transmission using the previously failed first slot (S40).

That is, the data transmission apparatus 100 sets a resource for transmitting specific DL data so as to have a size (TBS) of a transport block greater than or equal to a transport block size (TBS) at the time of previous (first) transmission using the previously failed first slot. (eg, the number of DL PRBs, the number of DL symbols, the number of DL MCSs, the number of layers, etc.) It is set to be able to send a larger or equal amount of DL data than the previous (first) failure.

As such, when the DL slot of the initial (previous) transmission time and the retransmission possible time are different (S30 No), the data transmission apparatus 100 performs HARQ differently from the first (previous) DL data (= MAC PDU) to be retransmitted. By allocating a process (by assigning a different or the same HARQ process number after toggling) and allocating a new physical resource, retransmission can be performed as if new new DL data was transmitted (S50).

In the data retransmission method according to an embodiment of the present invention, the data transmission apparatus 100 may repeatedly perform the above-described step S10 and subsequent processes until the DL data transmission is terminated (S70 No).

As described above, according to the data retransmission method of the present invention, even when the DL slots of the initial (previous) transmission time and the retransmission available time are different in the 5G NR TDD system, the DL data to be retransmitted (= MAC PDU) is newly DL HARQ retransmission technique (plan) is realized by performing retransmission as if data transmission.

Accordingly, according to the present invention, in the 5G NR TDD system, the slot of the configuration different from that of the previous (first) transmission is not dependent on the TDD slot structure (eg, the DDDSU structure) in which the D slot and the S slot are mixed, and when DL data is retransmitted. Since it can also be transmitted in a TDD slot structure (eg, a DDDSU structure), an effect of minimizing the additional delay time caused by the structure is derived.

The data retransmission method according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and carry out program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

Although the present invention has been described in detail with reference to preferred embodiments so far, the present invention is not limited to the above-described embodiments, and the technical field to which the present invention belongs without departing from the gist of the present invention as claimed in the following claims It will be said that the technical idea of the present invention extends to a range where various modifications or modifications can be made by anyone with ordinary knowledge.

According to the data transmission apparatus and data retransmission method according to the present invention, a new method for performing DL data retransmission without relying on a TDD slot structure (eg, DDDSU structure) in which D slots and S slots are mixed in a 5G NR TDD system In terms of realizing (technology), as it goes beyond the limits of existing technologies, the possibility of marketing or business of the applied device, not just the use of the related technology, is sufficient, as well as the extent to which it can be clearly implemented in reality. It's a potential invention.

100: data transmission device
110: data transmission unit 120: confirmation unit
130: transmission control unit

Claims (7)

a data transmission unit for transmitting data based on a slot structure composed of two or more slots having different configurations for data transmission; and
When specific data different from the first slot used at the time of previous transmission among the two or more slots and the second slot located at the time point at which retransmission is possible fails to be transmitted, transmission is performed as new data using the second slot A data transmission device comprising a control unit. The method of claim 1,
The two or more slots,
A data transmission apparatus, characterized in that the DL (Down Link) symbol configuration is a different slot. The method of claim 1,
The transmission control unit,
By allocating a Hybrid Automatic Repeat Request (HARQ) process and a physical resource differently from the previous transmission using the first slot for the transmission of the specific data, the specific data is transferred to the allocated HARQ in the second slot. A data transmission device, characterized in that it is transmitted using a process and a resource. 4. The method of claim 3,
The transmission control unit,
When allocating the HARQ process for transmission of the specific data, a HARQ process other than the HARQ process in the previous transmission using the first slot or the same HARQ process is allocated after toggling a New Data Indicator (NDI) value data transmission device. 4. The method of claim 3,
The transmission control unit,
The data transmission apparatus according to claim 1, wherein the size of the transport block is greater than or equal to the size of the transport block during the previous transmission using the first slot when the resource is allocated for transmission of the specific data. The method of claim 1,
When the retransmission is possible,
The data transmission apparatus characterized in that it is determined by a time when a transmission failure response for the specific data is received and a time when data processing for transmitting the data is completed. In the data retransmission method performed in the base station,
A data transmission step of transmitting data based on a slot structure consisting of two or more slots having different configurations for data transmission; and
When specific data different from the first slot used at the time of previous transmission among the two or more slots and the second slot located at the time point at which retransmission is possible fails to be transmitted, transmission is performed as new data using the second slot A data retransmission method comprising a control step.

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