JP6802747B2 - Base station equipment, terminal equipment, control methods, and programs - Google Patents

Description

The present invention relates to a radio resource allocation technique for a wireless communication system.

In the 3rd Generation Partnership Project (3GPP), the standardization of the 5th generation cellular communication system called New Radio (NR) is currently underway. NR is expected to support not only high-speed, large-capacity communication (eMBB: enhanced Mobile Broadband) but also high-reliability, low-latency communication (URLLC: Ultra-Reliable and Low Latency Communications). In particular, in order to realize URLLC on the downlink, a mechanism called preemption in which URLLC interrupts during eMBB communication is being studied (see Non-Patent Documents 1 and 2).

Samsung, Preemption-based multiplexing between eMBB and URLLC for DL, 3GPP TSG-RAN WG1 NR Ad-Hoc Meeting, R1-1700966, January 16-20, 2017 Samsung, Evaluation Results of Superposition for Multiplexing eMBB and URLLC, 3GPP TSG-RAN WG1 NR Ad-Hoc Meeting, R1-1700969, January 16-20, 2017

Preemption can deteriorate the reception performance (for example, packet error rate) of the terminal device due to thinning out (puncture) of data transmitted to the terminal device for eMBB. In order to reduce such deterioration of reception performance, a mechanism called superposition in which data addressed to the terminal device for eMBB is superimposed on data addressed to the terminal device for URLLC is also being studied (non-superposition). See Patent Document 2). On the other hand, in the super position, advanced signal processing may be required for demodulation processing in the terminal device for URLLC. Therefore, in order to realize demodulation with low delay in the terminal device for URLLC, it may be desirable to apply preemption instead of super position.

The present invention has been made in view of the above-mentioned problems. The present invention can be applied by dynamically switching between preemption and super position when data is transmitted from a base station device to another terminal device using a part of radio resources already allocated to the terminal device. The purpose is to provide the technology to make.

The base station apparatus according to one aspect of the present invention uses a part of the radio resources in the radio resources already allocated to the first terminal equipment during communication with the first terminal equipment that communicates with the eMBB. , The first process of replacing the data addressed to the first terminal device in some of the radio resources with the data addressed to the second terminal device when the data is transmitted to the second terminal device that performs URLLC communication. A processing means for performing either the second processing of superimposing the data addressed to the second terminal device on the data addressed to the first terminal device in the part of the radio resources , and the second terminal device. When the reliability required for the communication is higher than the threshold value, the first process is performed, and when the reliability level is not higher than the threshold value, the second process is performed. Using the radio resources of the unit, the transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device and the control information related to the processing result by the processing means are controlled. It is characterized by having a notification means for notifying the first terminal device using a channel.
The base station apparatus according to another aspect of the present invention uses a part of the radio resources in the radio resources already allocated to the first terminal apparatus during communication with the first terminal apparatus that communicates with the eMBB. Then, when the data is transmitted to the second terminal device that performs URLLC communication, the data addressed to the first terminal device in the part of the radio resources is replaced with the data addressed to the second terminal device. A processing means for performing either one process or a second process of superimposing data addressed to the second terminal device on the data addressed to the first terminal device in the part of the radio resources, and the part of the radio resources. Using a control channel, a transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device and control information related to the processing result by the processing means are used. The notification means for notifying the first terminal device, the first distance which is the distance between the base station device and the first terminal device, and the distance between the base station device and the second terminal device. It has a determination means for determining a certain second distance, and the processing means performs the second processing when the second distance is longer than the first distance, and the second distance is the second. If it is not longer than one distance, the first process is performed.
The base station apparatus according to still another aspect of the present invention uses a part of the radio resources in the radio resources already allocated to the first terminal apparatus during communication with the first terminal apparatus that communicates with the eMBB. When data is transmitted to the second terminal device that performs URLLC communication, the data addressed to the first terminal device in the part of the wireless resources is replaced with the data addressed to the second terminal device. A processing means that performs either the first process or the second process of superimposing the data addressed to the second terminal device on the data addressed to the first terminal device in the partial radio resource, and the partial radio. Using resources, a transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device and control information related to the processing result by the processing means are transmitted using a control channel. The notification means for notifying the first terminal device, the first pass loss which is the path loss between the base station device and the first terminal device, and the path loss between the base station device and the second terminal device. The processing means has a determination means for determining the second pass loss, and when the second pass loss is larger than the first pass loss, the second process is performed and the second pass loss is the said. If it is not larger than the first pass loss, the first process is performed.
The base station apparatus according to still another aspect of the present invention uses a part of the radio resources in the radio resources already allocated to the first terminal apparatus during communication with the first terminal apparatus that communicates with the eMBB. When data is transmitted to the second terminal device that performs URLLC communication, the data addressed to the first terminal device in the part of the wireless resources is replaced with the data addressed to the second terminal device. A processing means that performs either the first process or the second process of superimposing the data addressed to the second terminal device on the data addressed to the first terminal device in the partial radio resource, and the partial radio. Using resources, a transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device and control information related to the processing result by the processing means are transmitted using a control channel. The notification means for notifying the first terminal device, the first pass loss which is the path loss between the base station device and the first terminal device, and the path loss between the base station device and the second terminal device. The processing means has a determination means for determining the second pass loss, and when the second pass loss is larger than the pass loss obtained by adding a predetermined margin to the first pass loss, the processing means performs the second process. When the second pass loss is not larger than the pass loss obtained by adding the predetermined margin to the first pass loss, the first process is performed.

The terminal device according to one aspect of the present invention is a terminal device that performs eMBB communication , receives data from the base station device using radio resources allocated from the base station device, and receives the received data. When data is transmitted to another terminal device that performs URLLC communication by using the storage means stored in the storage means and a part of the radio resources in the radio resources assigned to the terminal device, the said The first process of replacing the data addressed to the terminal device in the part of the radio resources with the data addressed to the other terminal device, which is the control information notified from the base station device, and the said in the part of the radio resources. A receiving means that receives the control information related to the processing result of any of the second processing of superimposing the data addressed to the other terminal device on the data addressed to the terminal device from the base station device using the control channel. If the reliability required for communication with the other terminal device is higher than the threshold value, the first process is performed, and if the reliability level is not higher than the threshold value, the second process is performed. The receiving means is provided with the receiving means, and the demodating means for performing the demodulating process of the data stored in the storage means according to the control information received by the receiving means.

According to the present invention, when data is transmitted from a base station device to another terminal device using a part of radio resources already allocated to the terminal device, preemption and super position are dynamically switched and applied. It becomes possible to do.

Diagram showing a configuration example of a wireless communication system The figure which shows the example of the interrupt for the communication with the terminal device for eMBB. Block diagram showing a hardware configuration example of a base station device and a terminal device Block diagram showing a functional configuration example of a base station device Block diagram showing a functional configuration example of a terminal device Flow chart showing the procedure of processing executed by the base station device Diagram showing an example of preemption or super position selection Flow chart showing the procedure of processing executed by the terminal device for eMBB Diagram showing an example of preemption or super position selection The figure which shows the example of the interrupt for the communication with the terminal device for eMBB. Diagram showing an example of preemption or super position selection

Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings. In each of the following figures, components not necessary for the description of the embodiment will be omitted from the drawings.

[First Embodiment]
<System configuration>
FIG. 1 is a diagram showing a configuration example of a wireless communication system according to the first embodiment. The wireless communication system of the present embodiment includes a base station device 10 forming a cell 100 and a plurality of terminal devices 11 to 13. In the example of FIG. 1, three terminal devices 11 to 13 exist in the cell 100 formed by the base station device 10, but an arbitrary number of terminal devices may exist in the cell 100.

Communication between the base station device 10 and the terminal devices 11 to 13 is performed using the radio resources allocated to the terminal devices 11 to 13 by the base station device 10. The base station device 10 allocates radio resources for each of the uplink communication in the direction from the terminal devices 11 to 13 to the base station device 10 and the downlink communication in the direction from the base station device 10 to the terminal devices 11 to 13. Do. The radio resources allocated may be specified, for example, by time and frequency, and may be further specified by space (spatial layer) when spatial multiplexing is used.

In the present embodiment, the terminal device 11 is an example of a terminal device (first terminal device) that performs high-speed, large-capacity communication (eMBB), and the terminal devices 12 and 13 are highly reliable and low-delay communication (URLLC). ) Is an example of a terminal device (second terminal device). The terminal devices 11 to 13 can be mobile devices such as smartphones and tablet terminals. Since services such as automatic driving and telemedicine can be assumed as the URLLC service, the terminal devices 12 and 13 may be, for example, an automobile (a communication device mounted on the automobile).

When the base station device 10 starts communication with the URLLC terminal device (for example, terminal devices 12 and 13) during communication with the eMBB terminal device (for example, the terminal device 11), the base station device 10 is already in the eMBB terminal device. In some cases, a part of the allocated radio resources is used to communicate with the URLLC terminal device (that is, the communication with the URLLC terminal device is interrupted with the communication with the eMBB terminal device).

Here, FIG. 2 is a diagram showing an example of an interrupt for communication with the terminal device for eMBB, and is a terminal device which is a terminal device for URLLC during communication with the terminal device 11 which is a terminal device for eMBB. An example in which an interrupt is performed by communication with 12 is shown. In the example of FIG. 2, the base station device 10 allocates the wireless resource 20 to the terminal device 11 by scheduling the data transmission to the terminal device 11, and uses the wireless resource 20 to generate data to the terminal device 11. Start sending. The result of the scheduling is notified from the base station device 10 to the terminal device 11 as scheduling information 21. The notification of the scheduling information 21 is not limited to the region shown in FIG. 2 in the time-frequency region, and may be performed using radio resources in other regions. After that, when a request for communication with the terminal device 12 occurs during communication with the terminal device 11, the base station device 10 uses a part of the radio resource 25 in the radio resource 20 allocated to the terminal device 11. , The data is transmitted to the terminal device 12. Before the start of data transmission, the base station device 10 notifies the terminal device 12 of the scheduling information 26 regarding the data transmission by using a radio resource having a frequency different from that of the radio resource 20. The notification of the scheduling information 26 is not limited to the region shown in FIG. 2 in the time-frequency region, and may be performed using radio resources in other regions.

The base station device 10 can start communication with the URLLC terminal device (terminal device 12) in a short time by the interrupt processing as described above for the communication with the eMBB terminal device (terminal device 11). In the present embodiment, the interrupt processing for communication with the terminal device (terminal device 11) for eMBB is realized by a mechanism called preemption or superposition. The preemption corresponds to a process (first process) of replacing the data addressed to the eMBB terminal device (first terminal device) with the data addressed to the URLLC terminal device (second terminal device). The super position corresponds to a process (second process) of superimposing the data addressed to the terminal device for URLLC (second terminal device) on the data addressed to the terminal device (first terminal device) for eMBB.

As described above, preemption may deteriorate the reception performance of the terminal device for eMBB due to thinning out (puncture) of data transmitted to the terminal device for eMBB. Therefore, by applying the super position instead of the preemption in the interrupt processing, the influence on the reception performance of the terminal device for eMBB can be reduced. On the other hand, in the super position, advanced signal processing (interference removal processing) such as SIC (sequential interference cancellation) may be required in the demodulation processing by the terminal device for URLLC. Therefore, in order to realize demodulation with low delay in the terminal device for URLLC, it may be desirable to apply preemption instead of the super position to the communication with the terminal device for URLLC.

Therefore, in the present embodiment, when data is transmitted from the base station device 10 to the URLLC terminal device by using a part of the radio resources already allocated to the eMBB terminal device, the preemption and the super position are set. Make it dynamically switchable and applicable. Specifically, the base station device 10 uses a part of the radio resources already allocated to the terminal device 11 during communication with the terminal device for eMBB (terminal device 11) to use the terminal device for URLLC. When transmitting data to (terminal device 12), either preemption (first process) or super position (second process) is performed on the part of the radio resource. The base station device 10 transfers the preempted or superpositioned data to the terminal device 12 by using a part of the radio resources (radio resource 25) in the radio resource (radio resource 20) assigned to the terminal device 11. Send. Further, the base station apparatus 10 notifies the terminal apparatus 11 of the control information related to the processing result by using the control channel.

The base station device 10 relates to the above processing result, for example, after the scheduled data transmission to the terminal device 11 during communication is completed (for example, after the packet (slot) transmission by one scheduling is completed). Notify the terminal device 11 of the control information to be performed. In the example of FIG. 2, the base station apparatus 10 notifies the control information 22 by using the radio resource (control channel) having the same frequency as the radio resource 20 immediately after the completion of the data transmission using the radio resource 20. .. As a result, the terminal device 11 can grasp whether the preemption or super position process has been performed based on the control information 22 notified from the base station device 10. As a result, the terminal device 11 can appropriately perform the demodulation process of the received data. The notification of the control information 22 is performed using a specific control channel (radio resource) predetermined for the notification of the control information 22. In the present embodiment, as described above, the radio resource having the same frequency as the radio resource 20 and immediately after the completion of data transmission is set as such a control channel. However, the notification of the control information 22 may be performed using a radio resource having a frequency different from that of the radio resource 20, or may be performed at a timing different from immediately after the completion of data transmission.

In this way, when interrupt processing is performed on the communication with the terminal device 11 for the communication with the terminal device 12, the preemption and the super position can be dynamically switched and applied. In the following, a configuration example of the base station device 10 and the terminal device 11 for realizing the above-mentioned processing, and an example of a specific procedure of the processing executed by each device will be described.

<Device configuration>
FIG. 3 is a block diagram showing a hardware configuration example of the base station device and the terminal device. The base station device 10 and the terminal device 11 have a hardware configuration as shown in FIG. 3, and include, for example, a CPU 31, a ROM 32, a RAM 33, an external storage device 34, and a communication device 35. The terminal devices 12 and 13 may have the same configuration as the terminal device 11.

In the base station device 10 and the terminal device 11, for example, the CPU 31 executes a program stored in any of the ROM 32, the RAM 33, and the external storage device 34 to realize the functions of the base station device 10 and the terminal device 11. The CPU 31 may be replaced by one or more processors such as an ASIC (application specific integrated circuit), an FPGA (field programmable gate array), and a DSP (digital signal processor).

The base station device 10 (terminal device 11) controls the communication device 35 by, for example, the CPU 31, and communicates with the terminal device 11 (base station device 10). In FIG. 2, the base station device 10 and the terminal device 11 are shown to have one communication device 35, but the present invention is not limited to this. For example, the terminal device 11 may have two or more communication devices 35 for communicating with two or more base station devices, and yet another communication device 35 for communication in another system. May have.

The base station device 10 and the terminal device 11 may be provided with dedicated hardware for executing each function, or a part of the base station device 10 and the terminal device 11 may be provided with the hardware, and the other parts may be executed by the computer running the program. May be good. Also, all functions may be performed by a computer and a program.

FIG. 4 is a block diagram showing a functional configuration example of the base station apparatus. Each function of the base station apparatus 10 is a logical function realized by the hardware of FIG. 3, for example, and can be realized by the CPU 31 executing a program stored in the ROM 32 or the like. In the present embodiment, the base station apparatus 10 includes a wireless communication unit 41, a scheduling unit 42, a data transmission unit 43, and a notification transmission unit 44.

The wireless communication unit 41 transmits and receives wireless signals to and from terminal devices such as terminal devices 11 to 13 by communication according to the cellular communication standard. The scheduling unit 42 schedules uplink communication and downlink communication with each terminal device. In the following, only downlink communication will be described. Scheduling may be done for each scheduling period (eg, TTI (Transmission Time Interval) in Long Term Evolution (LTE)). In addition, one or more slots (or subframes) may be transmitted within the corresponding scheduling period by one scheduling.

When the scheduling unit 42 transmits downlink data to the URLLC terminal device (terminal devices 12 and 13), the scheduling unit 42 uses a part of the radio resources already allocated to the eMBB terminal device (terminal device 11). It is possible to schedule the data transmission (interrupt processing) used. In that case, the scheduling unit 42 determines (selects) whether to perform preemption (first process) or super position (second process) in data transmission to the terminal device for URLLC. The preemption or superposition determination can be made based on, for example, the communication conditions of the terminal device for URLLC (for example, the required conditions for communication with the terminal device or the distance to the terminal device), as will be described later. ..

The data transmission unit 43 transmits data to each terminal device via the wireless communication unit 41 according to the scheduling result (and determination of preemption or super position) by the scheduling unit 42. The notification transmission unit 44 transmits control information (control information related to interrupt processing) related to the processing result of preemption or super position to the terminal device for eMBB affected by the interrupt processing via the wireless communication unit 41. To do. Notification of control information can be performed using a specific control channel (radio resource) as described above.

FIG. 5 is a block diagram showing a functional configuration example of the terminal device. Each function of the terminal device 11 is a logical function realized by the hardware of FIG. 3, for example, and can be realized by the CPU 31 executing a program stored in the ROM 32 or the like. In the present embodiment, the terminal device 11 has a wireless communication unit 51, a data receiving unit 52, a data storage unit 53, a notification receiving unit 54, and a demodulation processing unit 55.

The wireless communication unit 51 transmits and receives a wireless signal to and from a base station device such as the base station device 10 by communication according to the cellular communication standard. The data receiving unit 52 receives the scheduling information from the base station apparatus via the wireless communication unit 51, and uses the radio resources allocated by the base station apparatus according to the received scheduling information from the base station apparatus. Receive data. The data received by the data receiving unit 52 is stored in the data storage unit 53. When the data receiving unit 52 receives data from the base station apparatus for each scheduling period, the data receiving unit 52 stores the received data in the data storage unit 53.

The notification receiving unit 54 receives the control information notified from the base station device (notification transmitting unit 44) when the above-mentioned interrupt processing is performed from the base station device via the wireless communication unit 51. When the data is received from the base station apparatus, the notification receiving unit 54 monitors a specific control channel (radio resource) used for the notification of the control information so that the notification of the control information can be received. When the notification receiving unit 54 receives the control information, the demodulation processing unit 55 demodulates the data stored in the data storage unit 53 for each scheduling period according to the control information.

<Processing procedure for base station equipment>
FIG. 6 is a flowchart showing a procedure of processing executed by the base station apparatus. When the base station device 10 of the present embodiment is requested to transmit data to the URLLC terminal device (terminal device 12 in this example) during communication with the terminal device 11 which is a terminal device for eMBB, FIG. Execute the process according to the procedure of.

First, in S61, the base station apparatus 10 schedules data transmission to the terminal apparatus 12. In this example, as shown in FIG. 2, it is assumed that data transmission using a part of the radio resources 25 in the radio resources 20 assigned to the terminal device 11 is scheduled.

Next, in S62, the base station device 10 acquires the communication conditions of the terminal device 12. Further, in S63, the base station device 10 has either preemption (first process) or super position (second process) in data transmission to the terminal device 12 using the wireless resource 25 based on the acquired communication conditions. Decide (select) whether to do.

The preemption or superposition selection process can be performed, for example, based on the requirements for communication with the terminal device 12. As the requirement condition, the reliability required for communication with the terminal device 12 can be used. The base station apparatus 10 may select preemption when the reliability required for communication with the terminal apparatus 12 is higher than a predetermined threshold value, and select a super position when the reliability is not higher than the threshold value. As described above, when high reliability is required for communication with the terminal device 12, it is possible to improve the reception performance of the terminal device 12 by selecting the preemption. On the other hand, when high reliability is not required for communication with the terminal device 12, by selecting the super position, the reception performance of the terminal device 11 deteriorates due to the interrupt processing (for example, the packet error rate increases). ) Can be reduced.

Alternatively, the preemption or super position selection process may be performed based on the distance between the base station device 10 and the terminal device 12. In this case, the base station device 10 determines the distance between the base station device 10 and the terminal device 11 (first distance) and the distance between the base station device 10 and the terminal device 12 (second distance). To do. Further, as shown in FIG. 7, the base station apparatus 10 selects the super position when the second distance is longer than the first distance (in the case of FIG. 7A), and the second distance is the first distance. If it is not longer (in the case of FIG. 7B), select preemption.

In addition, path loss may be used as an index of distance. In this case, the base station device 10 determines the path loss between the base station device 10 and the terminal device 11 (first path loss) and the path loss between the base station device 10 and the terminal device 12 (second path loss). To do. Further, the base station apparatus 10 selects the super position when the second path loss is larger than the first path loss (in the case of FIG. 7A), and when the second path loss is not larger than the first path loss (FIG. 7). In the case of (B)), the preemption is selected.

Here, when the super position is performed as interrupt processing, the data transmission power to the terminal device far from the base station device 10 is set higher than the data transmission power to the terminal device close to the base station device 10. Will be done. Further, in a terminal device close to the base station device 10, demodulation processing is performed with interference removal processing such as SIC, and in a terminal device far from the base station device 10, normal demodulation processing is performed without requiring interference removal processing. Will be done.

According to the selection process based on the above-mentioned distance (path loss), the super position is applied only when the terminal device 12 which is the terminal device for URLLC is farther from the base station device 10 than the terminal device 11. In this case, even if the super position is applied, the demodulation process can be performed in the terminal device 12 without requiring the interference removal process, so that demodulation with low delay can be realized. Further, deterioration of reception performance of the terminal device 11 (for example, increase in packet error rate) due to interrupt processing can be reduced. On the other hand, when the terminal device 12 is closer to the base station device 10 than the terminal device 11, preemption is applied so that the interference elimination process in the terminal device 12 is not required. Thereby, it is possible to improve the reception performance of the terminal device 12.

When the super position is selected, there is an increased possibility that an error will occur in the receiving slot (packet) in both the terminal device 11 and the terminal device 12. In order to reduce the possibility of such an error, there is a sufficient difference between the path loss corresponding to the terminal device 11 and the path loss corresponding to the terminal device 12 in the selection process based on the above-mentioned distance (path loss). Superposition may be applied only if it is. Specifically, the base station apparatus 10 selects the super position when the second path loss is larger than the path loss obtained by adding a predetermined margin to the first path loss, and selects the preemption when it is not large. May be good.

Returning to the description of FIG. 6, then in S64, the base station apparatus 10 transmits data to the terminal apparatus 12 according to the scheduling result in S61 and the preemption or super position selection result in S63. When preemption is selected, the base station device 10 thins out the data addressed to the terminal device 11 and replaces the data addressed to the terminal device 12 with the data addressed to the terminal device 12 in the radio resource 25, and transmits the data addressed to the terminal device 12. On the other hand, when the super position is selected, the base station device 10 determines the transmission power and the modulation method for the data addressed to the terminal device 11 and the data addressed to the terminal device 12 based on, for example, the determination result of the path loss. Data addressed to each terminal device is superimposed and transmitted.

After that, when the data transmission to the terminal device 11 using the wireless resource 20 is completed, in S65, the base station device 10 identifies the control information (control information 22 in FIG. 2) related to the result of the selection process in S63. Notifies the terminal device 11 using the control channel of the above, and ends the process.

<Processing procedure of terminal device>
FIG. 8 is a flowchart showing a procedure of processing executed by the terminal device for eMBB. When the terminal device 11 receives the scheduling information (scheduling information 21 in FIG. 2) from the base station device 10, the terminal device 11 executes the process according to the procedure in FIG.

First, in S81, the terminal device 11 receives data from the base station device 10 using the radio resource 20 allocated by the base station device 10 according to the received scheduling information 21. Further, in S82, the terminal device 11 stores the received data in the scheduling period corresponding to the scheduling information 21 in the data storage unit 53.

After that, in S83, the terminal device 11 attempts to receive the control information by the specific control channel (radio resource) used for notifying the control information, and determines whether or not the control information is received from the base station device 10. .. When the control information is received, the terminal device 11 advances the process to S84, demodulates the data stored in the data storage unit 53 according to the received control information, and ends the process. On the other hand, when the control information is not received, the terminal device 11 advances the process to S85, performs a normal demodulation process on the data stored in the data storage unit 53, and ends the process.

The control information (control information 22) received in S83 may include, for example, information indicating the radio resource (radio resource 25) for which interrupt processing has been performed, and information indicating the selection result of preemption or super position. When the control information indicates the selection of preemption, the terminal device 11 may perform demodulation processing by thinning out the data received by the radio resource indicated by the control information in S84.

When the super position is selected as the interrupt processing, the control information further includes data addressed to the terminal device (terminal device 12) for URLLC from the data received by the terminal device 11 from the base station device 10. It may contain the information needed to cancel. Such information includes, for example, the ratio of the data transmission power to the terminal device 11 (terminal device for eMBB) to the data transmission power to the URLLC terminal device in the interrupt-processed radio resource. , And at least the modulation scheme used to transmit data to the terminal device for URLLC. When the control information indicates the selection of the super position, the terminal device 11 cancels the data addressed to the terminal device for URLLC from the data received by the radio resource indicated by the control information based on the control information. Interference removal processing (eg, SIC) for this can be performed. The terminal device 11 can perform a normal demodulation process on the data received by the radio resource other than the radio resource indicated by the control information.

As described above, according to the present embodiment, when data is transmitted from the base station device 10 to the terminal device 12 by using a part of the radio resources already allocated to the terminal device 11, the preemption and the super position are used. Can be dynamically switched and applied.

[Second Embodiment]
In the first embodiment, an example is shown in which the base station device 10 interrupts the communication with one URLLC terminal device 12 for the communication with the eMBB terminal device 11. In the second embodiment, an example of performing interrupt processing for communication with a plurality of terminal devices 12 and 13 for URLLC will be described. In the following, the parts common to the first embodiment will be omitted, and the parts different from each other will be described.

FIG. 9 shows a preemption or a case where the base station device 10 according to the present embodiment performs interrupt processing for communication with a plurality of terminal devices 12 and 13 for URLLC during communication with the terminal device 11 for eMBB. It is a figure which shows the selection example of a super position. Further, FIG. 10 shows an example of interrupting communication with the terminal devices 12 and 13 using the wireless resources 25 and 27, which are a part of the wireless resources 20 assigned to the terminal device 11, which corresponds to FIG. It is a figure which shows.

In the present embodiment, the base station device 10 uses a plurality of terminal devices 12 for URLLC by using some different radio resources 25 and 27 in the radio resources 20 already assigned to the terminal device 11 for eMBB. When transmitting data to and 13, it is selected whether to perform preemption or super position for each terminal device for URLLC. In the example of FIG. 9, in the base station device 10, since the terminal device 12 is located farther from the base station device 10 than the terminal device 11 (the path loss is large), the communication with the terminal device 12 is the first embodiment. Select a super position according to the same criteria as above. On the other hand, in the base station device 10, since the terminal device 13 is located closer to the base station device 10 than the terminal device 11 (path loss is small), the communication with the terminal device 13 is based on the same criteria as in the first embodiment. Selects the preemption by.

Before the start of data transmission to the terminal devices 12 and 13, the base station device 10 uses the scheduling information 26 and 28 related to the data transmission by using a radio resource having a frequency different from that of the radio resource 20. Notify the terminal devices 12 and 13. As in the first embodiment, the notification of the scheduling information 26 and 28 is not limited to the region shown in FIG. 10 in the time-frequency region, and may be performed using radio resources in other regions.

As described above, according to the present embodiment, even when data is transmitted to a plurality of terminal devices 12 and 13 using a part of the radio resources already allocated to the terminal device 11, the preemption and the super position are used. Can be dynamically switched and applied.

[Third Embodiment]
The third embodiment is different from the first embodiment when the base station device 10 interrupts the communication with one URLLC terminal device 12 for the communication with the eMBB terminal device 11. An example of selecting a preemption or a super position based on a selection criterion will be described. In the present embodiment, the base station device 10 is preempted or based on the ratio of the amount of radio resources allocated to the URLLC terminal device 12 to the amount of radio resources already allocated to the terminal device 11 for eMBB. Select a super position. In the following, the parts common to the first embodiment will be omitted, and the parts different from each other will be described.

FIG. 11 is a diagram showing an example of interrupting communication with the terminal device 12 using the wireless resource 25, which is a part of the wireless resource 20 assigned to the terminal device 11, according to the present embodiment. FIG. 11A shows that the ratio of the amount of the radio resource 25 allocated to the terminal device 12 to the amount of the radio resource 20 already allocated to the terminal device 11 in the base station device 10 is not more than a predetermined ratio. , Shows an example of selecting a super position. On the other hand, in FIG. 11B, in the base station device 10, the ratio of the amount of the radio resource 25 allocated to the terminal device 12 to the amount of the radio resource 20 already allocated to the terminal device 11 is equal to or higher than a predetermined ratio. Therefore, an example of selecting a preemption is shown.

As described above, in the present embodiment, if the ratio of the amount of wireless resources allocated to the URLLC terminal device 12 to the amount of wireless resources already allocated to the terminal device 11 for eMBB is equal to or more than a predetermined ratio. , Select the super position regardless of other selection conditions. As a result, it is possible to prevent the deterioration of the reception performance of the terminal device 11 (for example, an increase in the packet error rate) from becoming unnecessarily large due to the excessive amount of radio resources of the terminal device 11 used for preemption. Is possible. It should be noted that this embodiment can be combined with the first and second embodiments.

10: Base station device, 11-13: Terminal device 41: Wireless communication unit, 42: Scheduling unit, 43: Data transmission unit, 44: Notification transmission unit 51: Wireless communication unit, 52: Data reception unit, 53: Data storage Unit, 54: Notification receiving unit 55: Demodulation processing unit

Claims (13)

During communication with the first terminal device that performs eMBB communication, a part of the radio resources in the radio resources already allocated to the first terminal device is used to the second terminal device that performs URLLC communication . When data is transmitted, the first process of replacing the data addressed to the first terminal device in the part of the radio resources with the data addressed to the second terminal device, and the first process in the part of the radio resources. It is a processing means that performs either of the second processing of superimposing the data addressed to the second terminal device on the data addressed to the terminal device, and the reliability required for communication with the second terminal device is higher than the threshold value. In this case, the processing means and the processing means, in which the first processing is performed, and when the reliability is not higher than the threshold value, the second processing is performed .
A transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device by using some of the radio resources.
A notification means for notifying the first terminal device of control information related to a processing result by the processing means using a control channel.
A base station apparatus characterized by having. It ’s a base station device,
During communication with the first terminal device that performs eMBB communication, a part of the radio resources in the radio resources already allocated to the first terminal device is used to the second terminal device that performs URLLC communication . When data is transmitted, the first process of replacing the data addressed to the first terminal device in the part of the radio resources with the data addressed to the second terminal device, and the first process in the part of the radio resources. A processing means that performs either a second process of superimposing the data addressed to the second terminal device on the data addressed to the terminal device, and
A transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device by using some of the radio resources.
A notification means for notifying the first terminal device of control information related to a processing result by the processing means using a control channel.
A determination means for determining a first distance, which is the distance between the base station device and the first terminal device, and a second distance, which is the distance between the base station device and the second terminal device. Have,
The processing means performs the second processing when the second distance is longer than the first distance, and performs the first processing when the second distance is not longer than the first distance. A base station device characterized by. It ’s a base station device,
During communication with the first terminal device that performs eMBB communication, a part of the radio resources in the radio resources already allocated to the first terminal device is used to the second terminal device that performs URLLC communication . When data is transmitted, the first process of replacing the data addressed to the first terminal device in the part of the radio resources with the data addressed to the second terminal device, and the first process in the part of the radio resources. A processing means that performs either a second process of superimposing the data addressed to the second terminal device on the data addressed to the terminal device, and
A transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device by using some of the radio resources.
A notification means for notifying the first terminal device of control information related to a processing result by the processing means using a control channel.
A determination means for determining a first path loss, which is a path loss between the base station device and the first terminal device, and a second path loss, which is a path loss between the base station device and the second terminal device. Have,
The processing means performs the second process when the second path loss is larger than the first path loss, and performs the first process when the second path loss is not larger than the first path loss. A base station device characterized by. It ’s a base station device,
During communication with the first terminal device that performs eMBB communication, a part of the radio resources in the radio resources already allocated to the first terminal device is used to the second terminal device that performs URLLC communication . When data is transmitted, the first process of replacing the data addressed to the first terminal device in the part of the radio resources with the data addressed to the second terminal device, and the first process in the part of the radio resources. A processing means that performs either a second process of superimposing the data addressed to the second terminal device on the data addressed to the terminal device, and
A transmission means for transmitting the data obtained by the first processing or the second processing to the second terminal device by using some of the radio resources.
A notification means for notifying the first terminal device of control information related to a processing result by the processing means using a control channel.
A determination means for determining a first path loss, which is a path loss between the base station device and the first terminal device, and a second path loss, which is a path loss between the base station device and the second terminal device. Have,
When the second pass loss is larger than the path loss obtained by adding a predetermined margin to the first pass loss, the processing means performs the second process, and the second pass loss adds the predetermined margin to the first pass loss. A base station apparatus characterized in that the first process is performed when the path loss is not larger than the added path loss . The base station apparatus according to any one of claims 1 to 4, wherein the control information includes a part of the radio resources and information indicating the processing result. When the processing means performs the second process, the control information is information necessary for canceling the data addressed to the second terminal device from the data received by the first terminal device from the base station device. The base station apparatus according to any one of claims 1 to 5, wherein the base station apparatus includes the device. When the processing means performs the second processing, the control information includes the data transmission power of the part of the radio resources to the first terminal device and the data transmission power to the second terminal device. The base station apparatus according to claim 6 , wherein the ratio and the modulation method used for transmitting data to the second terminal apparatus are included at least. The processing means is used when data is transmitted to a plurality of second terminal devices by using some different radio resources in the radio resources already allocated to the first terminal device. For each terminal device, either the first process or the second process is performed,
The method according to any one of claims 1 to 7 , wherein the transmitting means transmits data to each of the plurality of second terminal devices according to the processing result of each second terminal device by the processing means. Base station equipment. If the ratio of the amount of wireless resources allocated to the second terminal device to the amount of wireless resources allocated to the first terminal device is equal to or greater than a predetermined ratio, the processing means is subject to other processing conditions. The base station apparatus according to any one of claims 1 to 8 , wherein the second process is performed instead. It is a terminal device that communicates with eMBB .
A storage means that receives data from the base station device using the radio resources allocated from the base station device and stores the received data in the storage means.
Control information notified from the base station device when data is transmitted to another terminal device that communicates with URLLC using some of the radio resources in the radio resources assigned to the terminal device. The first process of replacing the data addressed to the terminal device in the part of the radio resources with the data addressed to the other terminal device, and the other data in the part of the radio resources destined for the terminal device. A receiving means for receiving the control information related to the processing result of any of the second processing for superimposing the data addressed to the terminal device from the base station device using the control channel, and the other terminal device. When the reliability required for the communication is higher than the threshold value, the first process is performed, and when the reliability level is not higher than the threshold value, the second process is performed .
A demodulation means that demodulates the data stored in the storage means according to the control information received by the receiving means, and
A terminal device characterized by having. It is a control method for base station equipment.
During communication with the first terminal device that performs eMBB communication, a part of the radio resources in the radio resources already allocated to the first terminal device is used to the second terminal device that performs URLLC communication . When data is transmitted, the first process of replacing the data addressed to the first terminal device in the part of the radio resources with the data addressed to the second terminal device, and the first process in the part of the radio resources. This is a processing step of performing either the second process of superimposing the data addressed to the second terminal device on the data addressed to the terminal device, and the reliability required for communication with the second terminal device. When is higher than the threshold value, the first process is performed, and when the reliability is not higher than the threshold value, the second process is performed .
A transmission step of transmitting the data obtained by the first processing or the second processing to the second terminal device by using some of the radio resources.
A notification step of notifying the first terminal device of control information related to the processing result in the processing step using a control channel.
A control method characterized by having. It is a control method of a terminal device that communicates with eMBB .
A storage step of receiving data from the base station device using the radio resources allocated from the base station device and accumulating the received data in the storage means.
Control information notified from the base station device when data is transmitted to another terminal device that communicates with URLLC using some of the radio resources in the radio resources assigned to the terminal device. The first process of replacing the data addressed to the terminal device in the part of the radio resources with the data addressed to the other terminal device, and the other data in the part of the radio resources destined for the terminal device. This is a receiving step of receiving the control information related to the processing result of any of the second processing for superimposing the data addressed to the terminal device from the base station device using the control channel, and the other terminal device. When the reliability required for the communication is higher than the threshold value, the first process is performed, and when the reliability level is not higher than the threshold value, the second process is performed .
A demodulation step of demodulating the data stored in the storage means according to the control information received in the receiving step, and a demodulation step.
A control method characterized by having. A program for causing a computer to execute each step of the control method according to claim 11 or 12 .

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