JP2022544728A - HARQ transmission apparatus and transmission method based on shared buffer - Google Patents

Abstract

The present invention discloses a HARQ transmission apparatus and transmission method based on a shared buffer, in which the scheduling module performs one retransmission or a new transmission according to the current feedback information and the buffer of service data waiting to be transmitted. a transmission module transmitting data according to instructions of the scheduling module; a demodulation module decoding the received transmission data and buffering the soft bits in a soft bit buffer module; step S3, the soft bit buffer module sending the soft bits corresponding to new transmissions and retransmissions received so far in the HARQ process to the decoding module for decoding, step S4; The module notifies the decoding result to the feedback module, and when the decoding module successfully decodes, notifies the soft bit buffer module to clear all the buffer bits of the corresponding HARQ Process, and the soft bit buffer module notifies the current buffer status information to the feedback module, step S5; and the feedback module builds feedback information according to the input of the decoding module and the softbit buffer module and feeds back to the scheduling module, step S6. and including. The method can effectively save hardware costs, match different service data models, and adapt to different non-ideal retransmission delays. [Selection drawing] Fig. 2

Description

TECHNICAL FIELD The present invention relates to the field of communication technology, and in particular to a shared buffer-based HARQ transmission apparatus and transmission method.

Distributed wireless communication systems are a major trend and trend in current wireless communication technology development. Especially in 5G communication systems, a distributed solution with different split ports is adopted to save hardware cost and increase software flexibility. The basic processing unit (BBU) of 5G access network is divided into three functional entities such as Centralized Unit (CU), Distributed Unit (DU) and Remote/Radio Unit (RU). Rebuilt. In the current mainstream segmentation scheme Option7.2, the CU equipment handles wireless high-level protocol stack functions such as RRC layer, PDCP layer, and also supports some core network functions to sink into the access network. It can also meet the higher requirements of future communication networks on network latency for new services such as video, online shopping, virtual/augmented reality. The DU equipment mainly handles some physical layer functions and real-time demanding Layer 2 functions, such as the scheduler, while the RU contains radio frequency modules and some physical layer functions.

The DU and RU are connected via a Front Haul (FH). Different FH schemes lead to different delays between DU and RU. In certain cases, these erratic and potentially very significant delays have a considerable impact on the scheduler located at the DU, especially for Hybrid Automatic Repeat reQuest (HARQ). poses an even greater challenge. After adopting HARQ technology, if a particular transmission fails, the receiving side will buffer the soft bit information transmitted this time, wait for the next retransmission of the same data, and merge it with the received retransmission data. , you need to run the decryption again. In a non-ideal FH, the delay between the scheduler and the RU is so large that it takes a long time to wait between new transmissions of data and retransmissions, and the receiver cannot process the received data bits. Requires a large amount of memory to buffer. If the receiver is a terminal device and adopts a chip design, its memory capacity is limited by the cost, area and power consumption of the chip and cannot grow infinitely.

The current HARQ strategy for 4G and 5G is to split the memory into different HARQ Processes of the same size. Each data transmission occupies an idle HARQ process, if the receiver fails to decode, the soft bits awaiting merging are stored in the buffer corresponding to that HARQ process, and when the retransmission arrives, the decoding are merged until successful or HARQ times out.

Such a method is simple and has a low signaling overhead, but for distributed systems, the increase in FH delay leads to a sharp increase in the requirement for the number of HARQ processes, especially for 5G radio frequency systems with short transmission intervals. With a subcarrier spacing of 120 KHz, the transmission time interval is 0.125 ms, where a delay of 3 ms corresponds to 24 transmission intervals. For FDD system, 24 HARQ processes need to be added.

Each HARQ Process's buffer should be reserved according to the maximum possible transmission data block size, so if a huge amount of HARQ Processes is required, divide the buffers evenly according to different HARQ Processes. method is very inefficient. Especially when a user has a series of small packets to send, such a splitting scheme results in a large amount of buffer waste. This leads to a sharp increase in chip cost and design complexity on the terminal side.

In order to solve the above technical problems, the present invention provides an apparatus and method for performing HARQ transmission using shared buffer technology between HARQ processes, effectively saving hardware costs, and providing different services It can match the data model and accommodate different non-ideal retransmission delays.

To achieve the above objects, the technical solutions adopted by the present invention are as follows.
1. A HARQ transmission apparatus based on shared buffers, comprising a receive module and a transmit module, comprising:
the receiving module includes a demodulation module, a decoding module, a soft bit buffer module and a feedback module;
the demodulation module is configured to demodulate a received signal into softbit information and output the demodulated softbit information to a decoding module;
The decoding module decodes all softbit information of the currently received HARQ process, including newly transmitted softbits and merged softbits received for each retransmission; outputting an indication of successful decoding or unsuccessful decoding, upon successful decoding, instructing the soft bit buffer module to release all soft bits corresponding to the HARQ process, and simultaneously decoding; configured to output the decoding result to a feedback module,
The soft bit buffer module buffers the soft bit information received during the current transmission according to the HARQ process number transmitted this time, and all HARQ processes share all storage space and transmit at this time. is a retransmission, merge and update the repeated bits, store those bits that were originally transmitted, and when the decoding module decodes a particular HARQ Process, all corresponding to that HARQ Process. of the soft bits to the decoding module for decoding, and at the same time outputting the current buffer occupancy to the feedback module;
the feedback module is configured to feed back to the transmitting module the decoding result and the number of remaining available buffer bits according to the current received decoding result of the decoding module and the buffer occupancy status;
the transmission module includes a transmission module and a scheduling module;
the transmission module is configured to perform transmission of signals according to HARQ information scheduled by a scheduling module;
The scheduling module performs HARQ scheduling according to the received feedback information, and when receiving the information that the decoding result of a specific HARQ process is successful, the number Q of free bits available in the buffer of the receiving module , calculating the bit size B of the data buffer awaiting transmission in the transmitting module, and the number of bits C that can be carried by the air interface in the above transmission interval, let N be the minimum value of Q, B, C and schedules a new transmission HARQ process containing N information bits, and the number of free bits available in the buffer of the receiving module when receiving information that the decoding result of a particular HARQ process is in a failed state Calculate Q, the number of check bits P required to meet the target bit error rate, and the number of bits C that can be carried by the air interface in the above transmission interval, and calculate the minimum of Q, P, and C. , as N, to schedule a retransmission HARQ process containing N check bits.

A transmission method based on the above transmission device includes the following steps S1 to S6.
In step S1, a scheduling module schedules a retransmission or a new transmission according to current feedback information and a buffer of service data waiting to be transmitted.
At step S2, the transmitting module transmits data according to the instructions of the scheduling module.
At step S3, the demodulation module decodes the received transmission data and buffers the soft bits into the soft bit buffer module.
In step S4, the soft bit buffer module sends the soft bits corresponding to new transmissions and retransmissions received so far in the HARQ process to the decoding module for decoding.
In step S5, the decoding module notifies the feedback module of the decoding result, and when the decoding module succeeds in decoding, notifies the soft bit buffer module to clear all buffer bits of the corresponding HARQ process. and the softbit buffer module notifies the feedback module of the current buffer status information.
In step S6, the feedback module builds feedback information according to the input of the decoding module and the soft bit buffer module and feeds it back to the scheduling module.

As a further technical solution, when step S1 specifically receives the information that the decoding result of a particular HARQ Process is in a successful state, the number Q of free bits available in the buffer of the receiving module, the transmission in the transmitting module Calculate the bit size B of the waiting data buffer and the number C of bits that can be carried by the air interface in the above transmission interval, taking the minimum value of Q, B, and C as N, N When a new transmission HARQ Process containing information bits of Calculate the number of check bits P required to satisfy the rate and the number of bits C that can be carried by the air interface in the above transmission interval, taking the minimum of Q, P, C as N , scheduling a retransmission HARQ process including N check bits.

Compared with the prior art, the present invention has the following beneficial effects. The method can effectively save hardware cost, match different service data models, and adapt to different non-ideal retransmission delays.

1 is a schematic diagram of a distributed 5G base station; FIG. 1 is a schematic diagram of a HARQ transmission apparatus based on shared buffers of the present invention; FIG. It is a processing flowchart between each module of the present invention. 10 is a processing flowchart of a scheduling module;

Embodiments of the present invention will now be described in greater detail with reference to the accompanying drawings and examples. The following examples are used to illustrate the invention, but cannot be used to limit the scope of the invention.

Referring to FIG. 1, FIG. 1 is a schematic diagram of a distributed 5G base station, consisting of 1 central unit, 4 extension units and 32 remote units. Four expansion units are connected to the central unit, while each expansion unit is connected to eight remote units. All remote units are configured in one cell. The fronthaul uses a passive fiber optic network (PON) network, with a delay of 1.5ms to 2ms for commutation.

Referring to FIG. 2, FIG. 2 is a schematic diagram of the shared buffer-based HARQ transmission device of the present invention, wherein the shared buffer-based HARQ transmission device includes a receiving module and a transmitting module,
the receiving module includes a demodulation module, a decoding module, a soft bit buffer module and a feedback module;
the demodulation module is configured to demodulate a received signal into softbit information and output the demodulated softbit information to a decoding module;
The decoding module decodes all softbit information of the currently received HARQ process, including newly transmitted softbits and merged softbits received for each retransmission; outputting an indication of decoding success or decoding failure; if decoding succeeds, instruct the soft bit buffer module to release all the soft bits corresponding to the HARQ process; configured to output the decoding result to a feedback module,
The soft bit buffer module buffers the soft bit information received during the current transmission according to the HARQ process number transmitted this time, and all HARQ processes share all storage space and transmit at this time. is a retransmission, merge and update the repeated bits, store those bits that were originally transmitted, and when the decoding module decodes a particular HARQ Process, all corresponding to that HARQ Process. of the soft bits to the decoding module for decoding, and at the same time outputting the current buffer occupancy to the feedback module;
the feedback module is configured to feed back the decoding result and the number of remaining available buffer bits to the transmitting module according to the currently received decoding result of the decoding module and the buffer occupancy status;
the transmission module includes a transmission module and a scheduling module;
the transmission module is configured to perform transmission of signals according to HARQ information scheduled by a scheduling module;
The scheduling module performs HARQ scheduling according to the received feedback information, and when receiving the information that the decoding result of a specific HARQ process is successful, the number Q of free bits available in the buffer of the receiving module , calculating the bit size B of the data buffer awaiting transmission in the transmitting module, and the number of bits C that can be carried by the air interface in the above transmission interval, let N be the minimum value of Q, B, C and schedules a new transmission HARQ process containing N information bits, and the number of free bits available in the buffer of the receiving module when receiving information that the decoding result of a particular HARQ process is in a failed state Calculate Q, the number of check bits P required to meet the target bit error rate, and the number of bits C that can be carried by the air interface in the above transmission interval, and calculate the minimum of Q, P, and C. , as N, to schedule a retransmission HARQ process containing N check bits.

The transmit module can transmit OFDM (Orthogonal Frequency Division Multiplexing) waveforms and can use those that use LDPC (Low Density Check Code) coding and phase-amplitude quadrature modulation.

The demodulation module is a reception module that receives an OFDM (Orthogonal Frequency Division Multiplex) waveform and has a function of determining a phase-amplitude quadrature modulated signal into soft bits.

The softbit buffer module can be a software-based memory management system that stores and manages different softbits according to different HARQ processes, and can output statistically currently occupied or available free buffers. The buffer can then be freed as instructed by the decoding module.

The decoding module can complete the decoding of the LDPC, perform a CRC (Cyclic Redundancy Check), and output whether the current decoding was successful or unsuccessful.

The feedback module determines feedback information according to the current number of free bits that can be buffered by the soft bit buffer module and the output of the decoding module.

A scheduling module receives feedback information and performs HARQ scheduling according to the received feedback information. Instruct the sending module to perform a resend.

A transmission method based on the above transmission device includes the following steps S1 to S6.
In step S1, a scheduling module schedules a retransmission or a new transmission according to current feedback information and a buffer of service data waiting to be transmitted.
At step S2, the transmitting module transmits data according to the instructions of the scheduling module.
At step S3, the demodulation module decodes the received transmission data and buffers the soft bits into the soft bit buffer module.
In step S4, the soft bit buffer module sends the soft bits corresponding to new transmissions and retransmissions received so far in the HARQ process to the decoding module for decoding.
In step S5, the decoding module notifies the feedback module of the decoding result, and when the decoding module succeeds in decoding, notifies the soft bit buffer module to clear all buffer bits of the corresponding HARQ process. and the softbit buffer module notifies the feedback module of the current buffer status information.
In step S6, the feedback module builds feedback information according to the input of the decoding module and the soft bit buffer module and feeds it back to the scheduling module.

As shown in FIG. 4, step S1 specifically includes, when receiving information that the decoding result of a specific HARQ process is successful, the number Q of free bits available in the buffer of the receiving module, the transmission Calculate the bit size B of the data buffer awaiting transmission in the module and the number of bits C that can be carried by the air interface in the above transmission interval, taking the minimum of Q, B, C as N , the number Q of free bits available in the buffer of the receiving module when scheduling a new transmission HARQ process containing N information bits and receiving information that the decoding result of a particular HARQ process is in a failed state, Calculate the number of check bits P required to meet the target bit error rate and the number of bits C that can be carried by the air interface in the above transmission interval, and set the minimum value of Q, P, C to N and scheduling a retransmission HARQ Process containing N check bits.
Finally, it should be noted that the above examples are only used to describe the technical solutions of the present invention and not to limit them. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or part of the technical features therein. Although equivalently interchangeable, these modifications or replacements do not cause the essence of the corresponding technical solutions to depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (3)

1. A shared buffer based HARQ transmission apparatus comprising a receive module and a transmit module,
the receiving module includes a demodulation module, a decoding module, a soft bit buffer module and a feedback module;
the demodulation module is configured to demodulate a received signal into softbit information and output the demodulated softbit information to a decoding module;
The decoding module decodes all softbit information of the currently received HARQ process, including newly transmitted softbits and merged softbits received for each retransmission; outputting an indication of decoding success or decoding failure; if decoding succeeds, instruct the soft bit buffer module to release all the soft bits corresponding to the HARQ process; configured to output the decoding result to a feedback module,
The soft bit buffer module buffers the soft bit information received during the current transmission according to the HARQ process number transmitted this time, and all HARQ processes share all storage space and transmit at this time. is a retransmission, merge and update the repeated bits, store those bits that were originally transmitted, and when the decoding module decodes a particular HARQ Process, all corresponding to that HARQ Process. of the soft bits to the decoding module for decoding, and at the same time outputting the current buffer occupancy to the feedback module;
the feedback module is configured to feed back the decoding result and the number of remaining available buffer bits to the transmitting module according to the currently received decoding result of the decoding module and the buffer occupancy status;
the transmission module includes a transmission module and a scheduling module;
the transmission module is configured to perform transmission of signals according to HARQ information scheduled by a scheduling module;
The scheduling module performs HARQ scheduling according to the received feedback information, and when receiving the information that the decoding result of a specific HARQ process is successful, the number Q of free bits available in the buffer of the receiving module , calculating the bit size B of the data buffer awaiting transmission in the transmitting module, and the number of bits C that can be carried by the air interface in the above transmission interval, let N be the minimum value of Q, B, C to schedule a new transmission HARQ process containing N information bits, and the number of free bits available in the buffer of the receiving module when receiving information that the decoding result of a particular HARQ process is in a failed state Calculate Q, the number of check bits P required to meet the target bit error rate, and the number of bits C that can be carried by the air interface in the above transmission interval, and calculate the minimum of Q, P, and C. taking N as N, the HARQ transmission apparatus based on the shared buffer is configured to schedule a retransmission HARQ process containing N check bits. A transmission method based on the transmission device of claim 1, comprising:
a scheduling module scheduling one retransmission or new transmission according to current feedback information and a buffer of service data waiting to be transmitted, step S1;
step S2, wherein the sending module sends data according to the instructions of the scheduling module;
the demodulation module decoding the received transmission data and buffering the softbits in the softbit buffer module, step S3;
step S4, wherein the soft bit buffer module sends the soft bits corresponding to new transmissions and retransmissions received so far in the HARQ process to the decoding module for decoding;
The decoding module notifies the feedback module of the decoding result, and when the decoding module successfully decodes, notifies the softbit buffer module to clear all the buffer bits of the corresponding HARQ Process, and the softbit the buffer module notifying the feedback module of the current buffer status information, step S5;
Transmission according to claim 1, characterized in that the feedback module comprises a decoding module and a step S6 of building feedback information according to the input of the soft bit buffer module and feeding it back to the scheduling module. Device-based transmission method. Specifically, the step S1 is
When receiving information indicating that the decoding result of a specific HARQ process is in a successful state, the number Q of free bits available in the buffer of the receiving module, the bit size B of the data buffer waiting for transmission in the transmitting module, and the above transmission interval Calculate the number of bits C that can be carried by the air interface at , and schedule the HARQ Process for a new transmission containing N information bits, taking the minimum value of Q, B, and C as N. , the number of free bits Q available in the buffer of the receiving module when receiving information indicating that the decoding result of a particular HARQ Process is in a failed state, the number of check bits P required to satisfy the target bit error rate, and the above Calculate the number of bits C that can be carried by the air interface in a transmission interval of , and take the minimum value of Q, P, and C as N to define the retransmission HARQ process containing N check bits as scheduling, characterized by comprising a step of
Transmission method according to claim 2, based on the transmission device according to claim 1.

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