WO2019087228A1 - Base station device, terminal device, communication method and wireless communication system - Google Patents

Abstract

This base station device, which is capable of communicating with a terminal device in a first communication mode and a second communication mode, is provided with: a control unit which controls the transmission power of the terminal device; and a detection unit which detects that the terminal device is in a first state in which the terminal device cannot increase the transmission power of data to be transmitted in the first communication mode, wherein, when the terminal device is detected as being in the first state, the control unit stops controlling the transmission power of the data to be transmitted in the first communication mode.

Description

Base station apparatus, terminal apparatus, communication method, and wireless communication system

The present invention relates to a base station apparatus, a terminal apparatus, a communication method, and a wireless communication system.

In the 5th generation mobile communication system (hereinafter sometimes referred to as 5G), eMBB (enhanced mobile broad band) and URLLC (ultra-reliable and low latency communication) etc. are considered on the assumption of various use cases. There is.

The eMBB is communication that realizes continuous broadband at ultra high speed (for example, up to 20 Gigabits / second), and is communication that is an alternative to wired communication, for example, transmission of video.

The URLLC is communication that achieves high reliability (for example, BLER (Block Error Rate) of 10 or less to the power of 5 or less) and ultra-low delay (reciprocal delay of the wireless section of 1 ms or less). URLLC is used, for example, for more urgent data communication as compared to eMBB.

The terminal device in 5G may be required to execute eMBB and URLLC simultaneously or in parallel, for example. In this case, the terminal apparatus adjusts the transmission power of each of the eMBB and the URLLC so that the total value of the transmission power in the communication between the eMBB and the URLLC falls within the range of the transmittable power value that the terminal can transmit.

However, when communication between eMBB and URLLC is performed simultaneously or in parallel, the terminal device may adjust the transmission power with priority given to URLLC with high urgency. For example, the terminal device allocates sufficient transmission power to the URLLC, and allocates the remaining power to the eMBB. In this case, the transmission power of the eMBB may be insufficient, and the reception power of the eMBB may be reduced in the reception-side base station apparatus, and it may be determined that the reception quality is deteriorated. The base station apparatus may control the terminal apparatus to increase the transmission power of the eMBB communication when detecting a decrease in the reception quality of the eMBB, but since the terminal apparatus gives priority to the URLLC, the transmission power of the eMBB is I can not raise it. After that, the base station apparatus repeatedly controls the transmission power of the eMBB until the communication of the URLLC in the terminal apparatus is completed.

The power control of the eMBB of the base station apparatus in a state where the terminal apparatus can not increase the transmission power of the eMBB is, for example, a radio resource in the radio communication system by using a radio resource to transmit a power control message to the terminal apparatus. It can be a factor of shortage. In addition, the eMBB power control of the base station apparatus in the state where the terminal apparatus can not increase the eMBB transmission power performs processing such as measurement of eMBB reception quality and calculation of transmission power, so the processing load of the base station apparatus is It may be a factor to rise.

Therefore, one aspect of the disclosure is to provide a base station apparatus, a terminal apparatus, a communication method, and a wireless communication system that suppress transmission power control by the base station apparatus in a state where the terminal apparatus can not increase transmission power. is there.

A base station apparatus capable of communicating with a terminal device in a first communication mode and a second communication mode, the control unit controlling transmission power of the terminal device, and data transmitted by the terminal device in the first communication mode A detection unit that detects that the transmission power of the terminal can not be increased, and the control unit detects that the terminal device is in the first state; Control of transmission power for data to be transmitted in the first communication mode is stopped.

One aspect of the disclosure is to suppress transmission power control by the base station apparatus in a state where the terminal apparatus can not increase transmission power.

FIG. 1 is a diagram showing an example of the configuration of a wireless communication system 10. FIG. 2 is a diagram showing a configuration example of the base station apparatus 200. As shown in FIG. FIG. 3 is a diagram showing a configuration example of the terminal device 100. As shown in FIG. FIG. 4 is a diagram illustrating an example of a sequence of wireless communication in the comparison target method. FIG. 5 is a diagram showing an example of a sequence of wireless communication processing at the time of simultaneous execution of eMBB and URLLC. FIG. 6 is a diagram showing an example of a processing flowchart of transmission power calculation processing S105. FIG. 7 is a diagram illustrating an example of transmission power when communication of URLLC occurs during eMBB transmission. FIG. 8 is a diagram showing an example of a processing flowchart of eMBB data transmission processing S106. FIG. 9 is a diagram showing an example of a process flowchart of the eMBB data reception process S108. FIG. 10 is a diagram showing an example of the sequence of wireless communication after the end of the URLLC communication. FIG. 11 is a diagram showing an example of a processing flowchart of eMBB non-control flag control processing S202. FIG. 12 is a diagram illustrating an example of a sequence in which the base station device 200 detects that the terminal device 100 is in the eMBB transmission power increase disabling state. FIG. 13 is a diagram showing an example of a flowchart of the eMBB non-control flag control process S307. FIG. 14 is a diagram showing a configuration example of the base station apparatus 200. FIG. 15 is a diagram illustrating an example of a sequence of MCS communication processing. FIG. 16 is a diagram showing an example of a processing flowchart of eMBB data reception processing S400.

First Embodiment
The first embodiment will be described.

<Configuration Example of Communication System>
FIG. 1 is a diagram showing an example of the configuration of a wireless communication system 10. The wireless communication system 10 includes a terminal device 100 and a base station device 200.

The wireless communication system 10 is, for example, a wireless communication network conforming to the LTE (Long Term Evolution) or 5G standard. The wireless communication system 10 is a communication system that provides communication to the terminal device 100, for example, because the terminal device 100 receives a service of an external network such as the Internet. The terminal device 100 realizes communication by transmitting and receiving data to and from an external network via the base station device 200.

The terminal device 100 is a device that performs wireless connection with the base station device 200 and performs communication by transmitting and receiving packets with the base station device 200, and is, for example, a mobile communication device such as a smartphone. Although only one terminal device 100 is shown in FIG. 1, a plurality of terminal devices 100 may exist.

The base station apparatus 200 wirelessly connects to the terminal apparatus 100 and transmits / receives packets, and is, for example, an eNodeB (evolved Node B) in LTE or a gNodeB in 5G. The base station apparatus 200 has a communication area A200 indicating a range in which wireless communication is possible, and performs wireless communication with the terminal apparatus 100 located in the communication area A200. Although one base station apparatus 200 is shown in FIG. 1, a plurality of base station apparatuses 200 may exist.

The wireless communication system 10 is a communication system corresponding to, for example, a first communication mode (e.g., eMBB) and a second communication mode (e.g., URLLC) that requires lower delay than the first communication mode or higher reliability. . Hereinafter, the first communication mode will be described as eMBB, and the second communication mode will be described as URLLC. The terminal device 100 selectively uses eMBB and URLLC, for example, based on the service content realized by communication. For example, in the case of a service that requires high-speed and high-speed communication such as moving image distribution, the terminal device 100 transmits data by eMBB (C1). Further, for example, when high-speed and highly reliable communication such as a control signal is required, the terminal device 100 transmits data by the URLLC (C2). Also, the wireless communication system may support communication other than eMBB and URLLC.

When the terminal device 100 transmits eMBB and URLLC simultaneously or in parallel, the transmission power of URLLC with high urgency (for example, a lower delay is required) is preferentially allocated, and the remaining Allocate transmit power to eMBB. The eMBB allows for a delay greater than that allowed by URLLC.

<Example of Configuration of Base Station Device>
FIG. 2 is a diagram showing a configuration example of the base station apparatus 200. As shown in FIG. The base station apparatus 200 includes a central processing unit (CPU) 210, a storage 220, a memory 230, a network interface card (NIC) 240, a radio frequency (RF) circuit 250, and an antenna 251.

The CPU 210 is a processor that loads a program stored in the storage 220 into the memory 230, executes the loaded program, and implements each process.

The storage 220 is an auxiliary storage device such as a flash memory, a hard disk drive (HDD), or a solid state drive (SSD) that stores programs and data. The storage 220 stores a wireless communication control program 221, an eMBB data reception program 222, an eMBB non-control flag control program 223, and an eMBB non-control flag 224.

The eMBB non-control flag 224 is a flag indicating whether to control the transmission power of eMBB data for the terminal device 100, and if in the ON state, the transmission power control of the eMBB is performed for the terminal device 100. Indicates not to do. On the other hand, when the eMBB non-control flag 224 is in the OFF state, it indicates that the transmission power control of the eMBB is performed on the terminal device 100.

The memory 230 is an area for loading a program stored in the storage 220. The memory 230 is also used as an area for storing data in the program.

The NIC 240 is a device that connects to a control device or an external network and performs communication. The NIC 240 may be connected to a control device or an external network via a hub or a switch. Further, when there are a plurality of base station apparatuses 200, the NIC 240 may be used for connection between the base station apparatuses 200.

The RF circuit 250 is a device that realizes transmission and reception of data through the antenna 251. Transmission and reception of data is realized, for example, by transmitting and receiving a packet including data by a wireless signal. The RF circuit 250 wirelessly communicates with the terminal device 100 located in the communication area A 200 of the base station device 200, for example, by transmitting and receiving packets via wireless communication.

The CPU 210 executes the wireless communication control program 221 to perform wireless communication control processing. The wireless communication control process is a process of controlling wireless communication including eMBB and URLLC.

The CPU 210 executes the eMBB data reception program 222 to construct a detection unit and a control unit, and performs eMBB data reception processing. The eMBB data reception process is a process of receiving eMBB data and controlling the transmission power of the eMBB according to the state of the eMBB non-control flag.

In addition, the CPU 210 executes the eMBB reception quality calculation module 2221 included in the eMBB data reception program 222 to perform eMBB reception quality calculation processing. The eMBB reception quality calculation process is a process of calculating the reception quality of the received eMBB data, for example, calculating the radio quality such as the reception power and the frame error rate.

Further, the CPU 210 executes the eMBB transmission power control module 2222 of the eMBB data reception program 222 to perform eMBB transmission power control processing. The eMBB transmission power control process is a process of controlling the transmission power of eMBB data in the terminal device 100, and for example, transmits a message instructing the terminal device 100 to increase or decrease the transmission power of eMBB.

The CPU 210 executes the eMBB non-control flag control program 223 to perform eMBB non-control flag control processing. The eMBB non-control flag control process is a process of turning off the eMBB non-control flag when the base station apparatus 200 detects an opportunity to turn off the eMBB non-control flag. The trigger to turn off the eMBB non-control flag is, for example, when the communication of the URLLC in the terminal device 100 ends.

<Configuration Example of Terminal Device>
FIG. 3 is a diagram showing a configuration example of the terminal device 100. As shown in FIG. The terminal device 100 is, for example, a mobile communication terminal, and includes a CPU 110, a storage 120, a memory 130, and an RF circuit 150.

The CPU 110 is a processor that loads a program stored in the storage 120 into the memory 130, executes the loaded program, and implements each process.

The storage 120 is an auxiliary storage device such as a flash memory, an HDD, or an SSD that stores programs and data. The storage 120 includes a wireless communication program 121, a transmission power calculation program 122, an eMBB transmission power reduction flag 123, and an eMBB transmission power reduction notification completion flag 124.

The eMBB transmission power lowering flag 123 is a flag indicating whether or not the terminal device 100 can not increase the eMBB transmission power. If the terminal device 100 is in the ON state, the eMBB transmission power may be increased. Indicates that it can not be done.

The eMBB transmission power reduction notification completion flag 124 is a flag indicating whether the base station apparatus 200 has been notified that the transmission power of the eMBB can not be increased, and if it is in the ON state, Indicates that it has been notified.

The memory 130 is an area for loading a program stored in the storage 120. The memory 130 is also used as an area for storing data by the program.

The RF circuit 150 is wirelessly connected to the base station apparatus 200, for example, an apparatus that communicates with an external network. The RF circuit 150 transmits and receives packets using the antenna 151 to realize communication with other devices.

The CPU 110 executes the wireless communication program 121 to perform wireless communication processing. The wireless communication process is a process of performing wireless communication including eMBB and URLLC.

Further, the CPU 110 executes the eMBB data transmission module 1211 included in the wireless communication program 121 to construct a notification unit, and performs eMBB data transmission processing. The eMBB data transmission process is a process of determining whether an eMBB transmission power reduction notification for notifying a reduction in transmission power of the eMBB is to be added to eMBB data, and transmitting eMBB data.

The CPU 110 executes the URLLC data transmission module 1212 of the wireless communication program 121 to perform URLLC data transmission processing. The URLLC data transmission process is a process of transmitting URLLC data to the base station apparatus 200.

The CPU 110 executes the transmission power calculation program 122 to construct a first state detection unit and a transmission power control unit, and performs transmission power calculation processing. The transmission power calculation process is, for example, a process of calculating transmission power to be assigned to each communication when a plurality of communications such as eMBB and URLLC occur simultaneously or in parallel.

<Wireless communication in the comparison target method>
FIG. 4 is a diagram illustrating an example of a sequence of wireless communication in the comparison target method. The terminal device 100 and the base station device 200 establish a connection of the eMBB, and are in communication by the eMBB (S10).

Then, when an opportunity to perform communication by the URLLC occurs, the terminal device 100 transmits a URLLC operation mode setting request for requesting the base station device 200 to perform the communication by the URLLC (S11).

When the base station apparatus 200 receives the URLLC operation mode setting request, the base station apparatus 200 transmits, to the terminal apparatus 100, a URLLC operation mode setting that permits (or accepts) communication in the URLLC operation mode (S12).

When receiving the URLLC operation mode setting, the terminal device 100 transmits an SR (Scheduling Request) for requesting allocation of a radio resource for URLLC to the base station device 200 (S13). When receiving the SR, the base station apparatus 200 transmits, to the terminal apparatus 100, UL (UpLink) _Grant including information on the radio resource allocated to the data (URLLC data) to be transmitted by the URLLC (S14).

Then, when transmitting data (eMBB data) to be transmitted by the eMBB, the terminal device 100 calculates (acquires) the transmission power of the URLLC and the transmission power of the eMBB. Then, when the total of the transmission power of the URLLC and the eMBB exceeds the transmittable power, it is determined that the transmission power of the eMBB is to be reduced (S15). Then, the terminal apparatus 100 transmits the eMBB data to the base station apparatus 200 with the reduced transmission power (S16).

When receiving the eMBB data transmitted with the reduced transmission power, the base station apparatus 200 may determine that the reception quality of the eMBB data has deteriorated (S17). When the base station apparatus 200 determines that the reception quality of eMBB data has deteriorated, it requests the UL_Grant (allocation of radio resources for eMBB data transmission) to be transmitted next time to increase the transmission power of eMBB. Information is included (S18).

When the terminal device 100 receives the eMBB transmission power control information requesting to increase the transmission power of the eMBB, the terminal device 100 determines whether it is possible to increase the transmission power of the eMBB. However, in order to give priority to the transmission power of the URLLC, the terminal device 100 determines that the transmission power of the eMBB can not be increased (S19). Therefore, the terminal device 100 transmits the eMBB data to the base station device 200 with the transmission power as it is lowered (S20).

Then, the base station apparatus 200 determines that the reception quality of the eMBB data has deteriorated as in the reception of the eMBB data S16 (S21), and performs UL_Grant including information similar to the eMBB transmission power control information of UL_GrantS18, It transmits to the terminal device 100 (S22).

As described above, in the comparison target method, the terminal device 100 determines transmission power with priority given to URLLC when transmitting data simultaneously by the URLLC and the eMBB. The terminal device 100 may transmit eMBB data with reduced transmission power. Then, the base station apparatus 200 receives the reduced eMBB data of the transmission power, determines that the reception quality has deteriorated, and controls the terminal apparatus 100 to increase the transmission power of the eMBB. However, the terminal device 100 can not increase the transmission power of the eMBB because the transmission power is preferentially allocated to the URL LC, and transmits the eMBB data with the reduced transmission power again.

That is, in the comparison target method, detection of degradation in reception quality of eMBB data of base station apparatus 200, control of eMBB transmission power increase to terminal apparatus 100, and transmission of eMBB with reduced transmission power of terminal apparatus 100 are repeated. To be executed.

<Wireless communication processing at the time of simultaneous execution of eMBB and URLLC>
FIG. 5 is a diagram showing an example of a sequence of wireless communication processing at the time of simultaneous execution of eMBB and URLLC. In FIG. 5, the terminal device 100 executes eMBB and URLLC simultaneously (or in parallel).

The terminal device 100 and the base station device 200 establish an eMBB connection, and are in communication by the eMBB (S100). Then, the terminal device 100 transmits a URLLC operation mode setting request to the base station device 200 (S101).

When receiving the URLLC operation mode setting request, the base station apparatus 200 transmits the URLLC operation mode setting to the terminal device 100 (S102).

When receiving the URLLC operation mode setting, the terminal apparatus 100 transmits an SR for requesting allocation of a radio resource for URLLC to the base station apparatus 200 (S103). When receiving the SR, the base station apparatus 200 transmits, to the terminal apparatus 100, a UL_Grant including information on the radio resource allocated for transmission of the URLLC data (S104).

Then, when transmitting eMBB data, for example, the terminal device 100 executes transmission power calculation processing for calculating transmission power of the URLLC and transmission power of the eMBB (S105).

FIG. 6 is a diagram showing an example of a processing flowchart of transmission power calculation processing S105. The terminal device 100 acquires the provisional transmission power of the URLLC (S105-1). The provisional transmission power of the URLLC is transmission power by which the receiving side (base station apparatus 200) can receive the URLLC data without error, and is a numerical value calculated based on the state of the wireless section, for example. Also, the provisional transmission power of the URLLC may be, for example, a fixed value or a numerical value for each service stored in the internal memory.

The terminal device 100 acquires temporary transmission power of the eMBB (S105-2). The provisional transmission power of eMBB is a transmission power that can receive eMBB data without error on the receiving side. The provisional transmission power of the eMBB may be, for example, a numerical value calculated based on the state of the wireless section, a fixed value stored in the internal memory, or a numerical value for each service, similarly to the transmission power of the URLLC.

Then, the terminal device 100 determines whether the total value of the provisional transmission powers of the eMBB and the URLLC exceeds the transmittable power (S105-3). If the terminal device 100 determines that the total value does not exceed the transmittable power (No in S105-3), the eMBB transmission power reduction in progress flag 123 is turned OFF (S105-8), and the eMBB transmission power reduction notification end flag 124 Is turned off (S105-9). Then, the terminal device 100 determines the provisional transmission power as the transmission power of each of the eMBB and the URLLC (S105-7), and ends the processing.

On the other hand, when the terminal device 100 determines that the total value exceeds the transmittable power (Yes in S105-3), the eMBB is set such that the total value becomes the transmittable power (or, the transmittable power is less than). The provisional transmission power of the above is reduced (S105-4). Then, the terminal device 100 turns on the eMBB transmission power reduction flag 123 (S105-5), determines the provisional transmission power as the transmission power of each of the eMBB and the URL LC (S105-6), and ends the processing.

FIG. 7 is a diagram illustrating an example of transmission power when communication of URLLC occurs during eMBB transmission. For example, at time T1, communication of URLLC occurs. As shown in FIG. 7A, when the sum of the transmission power V1 required for transmission of URLLC data and the transmission power V2 required for transmission of eMBB data exceeds the transmittable power Vmax of the terminal device 100. The transmission of eMBB data can not transmit the URLLC data with the transmission power V1 while maintaining the transmission power V2. Therefore, as shown in FIG. 7B, the terminal device 100 reduces the eMBB data transmission to the transmission power V3 until the time T2 when the communication of the URLLC ends, and the sum of the transmission power V1 and the transmission power V3 is Control (adjustment) is performed so as not to exceed the transmittable power Vmax. Then, at time T2 when the communication of the URL LC ends, the terminal device 100 restores the transmission power of the eMBB from the transmission power V2 to the transmission power V2. That is, a period from time T1 to time T2 is a period in which the terminal device 100 can not increase the transmission power of the eMBB (hereinafter, it may be referred to as an eMBB transmission power increase non-permission period). The terminal device 100 in the eMBB transmission power increase disabling period is in a state in which the eMBB transmission power can not be increased (hereinafter, it may be referred to as an eMBB transmission power increase disabling state).

Returning to the sequence of FIG. 5, the terminal device 100 reduces the transmission power of the eMBB when the total of the provisional transmission powers of the URLLC and the eMBB exceeds the transmittable power (Yes in S105-3 of FIG. 6) ( At step S105-4) in FIG. 6, the eMBB transmission power lowering flag 123 is turned ON (S105-5 in FIG. 6). Then, the terminal device 100 performs eMBB data transmission processing when transmitting eMBB data (S106).

FIG. 8 is a diagram showing an example of a processing flowchart of eMBB data transmission processing S106. The terminal device 100 confirms whether the eMBB transmission power lowering flag 123 is ON or not (S106-1). If the eMBB transmission power lowering flag 123 is not ON (No in S106-1), the terminal device 100 transmits eMBB data to the base station device 200 (S106-5), and ends the process.

On the other hand, when the eMBB transmission power reduction flag 123 is ON (Yes in S106-1), the terminal device 100 checks whether the eMBB transmission power reduction notification completion flag 124 is ON (S106-2). . When the eMBB transmission power reduction notification completion flag 124 is ON (Yes in S106-2), the terminal device 100 transmits eMBB data to the base station device 200 (S106-5), and ends the process.

On the other hand, when the eMBB transmission power reduction notification completion flag 124 is not ON (No in S106-2), the terminal device 100 transmits a transmission power reduction notification indicating that the eMBB transmission power increase disabling state (first state) is eMBB data (S106-3), and the eMBB transmission power reduction notification completion flag 124 is turned ON (S106-4). Then, the terminal device 100 transmits the eMBB data to the base station device 200 (S106-5), and ends the process.

Returning to the sequence of FIG. 5, the terminal device 100 has the eMBB transmission power reduction flag 123 ON (Yes in S106-1 of FIG. 8) and the eMBB transmission power reduction notification completion flag 124 is OFF in the initial state. (No in S106-2 of FIG. 8), a transmission power reduction notification is added to eMBB data (S106-3 in FIG. 8), and the eMBB transmission power reduction notification completion flag 124 is turned ON (S106-4 in FIG. 8) . Then, the terminal device 100 transmits eMBB data including a transmission power reduction notification to the base station device 200 (S107, 106-5 in FIG. 8).

When receiving the eMBB data, the base station apparatus 200 performs eMBB data reception processing (S108).

FIG. 9 is a diagram showing an example of a process flowchart of the eMBB data reception process S108. The base station apparatus 200 waits to receive eMBB data (No in S108-1). When receiving the eMBB data (Yes in S108-1), the base station apparatus 200 checks whether the eMBB data includes a transmission power reduction notification (S108-2).

When the transmission power reduction notification is included (Yes in S108-2), the base station apparatus 200 sets the eMBB non-control flag 224 to ON (S108-3), and when the transmission power reduction notification is not included (S108-2). No), the eMBB non-control flag 224 is not updated.

Then, the base station apparatus 200 confirms whether the eMBB non-control flag 224 is ON (S108-4). When the eMBB non-control flag 224 is ON (Yes in S108-4), the base station apparatus 200 performs processing (for example, delivers to a target application) according to the received eMBB data, and waits for reception of eMBB data again. (S108-1). That is, when the eMBB non-control flag 224 is ON, the base station apparatus 200 does not perform the eMBB reception quality calculation process S108-5 and the eMBB transmission power control process S108-7, and stops the transmission power control for the eMBB.

On the other hand, when the eMBB non-control flag 224 is not ON (No in S108-4), the base station apparatus 200 performs eMBB reception quality calculation processing (S108-5). The eMBB reception quality calculation process S108-5 is, for example, a process of calculating a frame error rate and a bit error rate of the received eMBB data.

Then, the base station apparatus 200 confirms whether the reception quality of the eMBB is less than or equal to the quality threshold (S108-6). The base station apparatus 200 performs eMBB transmission power control processing (S108-7). The eMBB transmission power control process S108-7 is a process of instructing the terminal device 100 to increase or decrease the transmission power or the transmission power of the eMBB. For example, the instruction content is assigned to UL_Grant to which a radio resource for eMBB data is allocated. It is a process of including and transmitting, or transmitting a message for transmission power control.

That is, when the eMBB non-control flag 224 is OFF, the base station apparatus 200 performs eMBB reception quality calculation processing S108-5 and eMBB transmission power control processing S108-7, and starts (resumes) transmission power control for the eMBB. .

Then, after the end of the eMBB transmission power control process S108-7 and when the reception quality of the eMBB is not less than the quality threshold (No in S108-6), the base station apparatus 200 performs a process according to the received eMBB data, It waits for the reception of eMBB data again (S108-1).

Returning to the sequence of FIG. 5, the base station apparatus 200 determines in the eMBB data reception process S108 that a transmission power reduction notification is included (Yes in S108-2 of FIG. 9), and turns the eMBB non-control flag 224 ON. (S108-3 in FIG. 9). Then, since the eMBB non-control flag 224 is ON (Yes in S108-4 of FIG. 9), the base station apparatus 200 executes the eMBB reception quality calculation process S108-5 and the eMBB transmission power control process S108-7. Instead, processing according to the eMBB data is performed, and reception of eMBB data is awaited again (S108-1 in FIG. 9).

The base station apparatus 200 transmits UL_Grant not including the control message related to the transmission power of eMBB when transmitting UL_Grant to allocate the radio resource for eMBB data, because the eMBB transmission power control process S108-7 is not performed (S109) .

Then, the terminal device 100 performs eMBB data transmission processing when transmitting eMBB data (S106). At this time, although the terminal device 100 has the eMBB transmission power reduction flag 123 ON (Yes in S106-1 in FIG. 8), the eMBB transmission power reduction notification completion flag 124 is ON (S106 in FIG. 8). 2) eMBB data is transmitted without including the transmission power reduction notification (S110, S106-5 in FIG. 8).

The base station apparatus 200 receives eMBB data and performs eMBB data reception processing (S108). Since the eMBB non-control flag 224 is ON in the eMBB data reception process S108 in the eMBB data reception process S108 (Yes in S108-4 of FIG. 9), the eMBB reception quality calculation process S108-5 and the eMBB transmission power control process S108- 7 is not performed, processing according to the received eMBB data is performed, and reception of eMBB data is awaited again (S108-1 in FIG. 9).

Since the base station apparatus 200 does not perform the eMBB transmission power control process S108-7, it transmits a UL_Grant not including the control message related to the eMBB transmission power, as in the UL_Grant S109 (S111).

In the first embodiment, the terminal device 100 transmits, to the base station device 200, a notification that the eMBB transmission power can not be increased. The base station apparatus 200 recognizes that the terminal apparatus 100 is in the eMBB transmission power increase disabling state, and does not perform eMBB transmission power control. As a result, the processing load on the base station apparatus 200 is reduced, and the use of radio resources for transmission power control can be suppressed.

<Wireless communication processing after completion of URLLC>
FIG. 10 is a diagram showing an example of the sequence of wireless communication after the end of the URLLC communication. When the terminal device 100 detects that the communication of the URLLC has ended (S199), the terminal device 100 transmits, to the base station device 200, a request for releasing the URLLC communication mode to the base station device 200 (S200). When receiving the URLLC communication mode release request, the base station apparatus 200 releases, for example, the radio resource for the URLLC data, and transmits the URLLC communication mode release to the terminal apparatus 100 (S201).

Also, when receiving the URLLC communication mode release request, the base station apparatus 200 determines that the terminal apparatus 100 has ended the eMBB transmission power increase disable state, that is, detects an opportunity to turn off the eMBB non-control flag 224, An eMBB non-control flag control process is performed (S202).

FIG. 11 is a diagram showing an example of a processing flowchart of eMBB non-control flag control processing S202. The base station apparatus 200 waits to detect an opportunity to turn off the eMBB non-control flag 224 (No in S202-1). When the base station apparatus 200 detects a trigger to turn the eMBB non-control flag 224 off (Yes in S202-1), the eMBB non-control flag is turned off (S202-2), and the eMBB non-control flag 224 is turned off again. It waits to detect a trigger to turn on (S202-1).

The trigger to turn off the eMBB non-control flag is, for example, when it is detected that the communication of the URLLC ends. In addition, when the eMBB non-control flag is turned off, for example, the terminal device 100 is notified that the eMBB transmission power increase disable state has ended, that is, the eMBB transmission power can be increased. It may be

Returning to the sequence of FIG. 10, the base station apparatus 200 detects the trigger for turning the eMBB non-control flag 224 OFF by receiving the URLLC communication mode release request in the eMBB non-control flag control process S202 (FIG. In step S202-1, the eMBB non-control flag 224 is turned off (step S202-2 in FIG. 11).

On the other hand, when transmitting eMBB data, for example, the terminal device 100 performs transmission power calculation processing S105. Since the terminal device 100 has completed the URLLC communication, the provisional transmission power of the URLLC is 0 (S105-1 in FIG. 6), and the provisional sum does not exceed the transmittable power (S105 in FIG. 6). (No in -3), the eMBB transmission power reduction flag 123 and the eMBB transmission power reduction notification completion flag 124 are turned OFF (S105-8, 9 in FIG. 6). Then, the terminal device 100 restores the transmission power of the eMBB to the transmission power before the reduction, and transmits the eMBB data (S202).

When receiving the eMBB data, the base station apparatus 200 performs an eMBB data reception process S108. Since the eMBB non-control flag is OFF in eMBB data reception processing S108 (No in S108-4 of FIG. 9), the base station apparatus 200 performs eMBB reception quality calculation processing S108-5. Then, when the reception quality of the eMBB is less than or equal to the quality threshold (S203, Yes in S108-6 of FIG. 9), the base station apparatus 200 transmits eMBB transmission power, for example, to UL_Grant in eMBB transmission power control processing S108-7. Is added to the eMBB transmission power control information including an instruction to raise the e.g.

In the first embodiment, the base station apparatus 200 turns off the eMBB non-control flag 224 by detecting that the communication of the URLLC in the terminal apparatus 100 has ended. Thus, the base station apparatus 200 recognizes that the terminal apparatus 100 is in a state capable of increasing the transmission power of eMBB, and can control the transmission power of eMBB thereafter.

Second Embodiment
Next, a second embodiment will be described.

In the first embodiment, the terminal device 100 detects that the transmission power of the eMBB can not be increased, and notifies the base station device 200 of the fact. In the second embodiment, the base station apparatus 200 detects that the terminal apparatus 100 is in the eMBB transmission power increase impossible state.

<Detection of eMBB Transmission Power Rise Impossible State of Terminal Device in Base Station>
FIG. 12 is a diagram illustrating an example of a sequence in which the base station device 200 detects that the terminal device 100 is in the eMBB transmission power increase disabling state. The terminal device 100 is simultaneously (in parallel) executing communication between the eMBB and the URLLC.

The terminal device 100 transmits transmittable power information to the base station device 200 (S301). The transmittable power information includes, for example, the transmittable power value of the terminal device 100. The terminal device 100 transmits transmittable power information, for example, when establishing a connection with the base station device 200. Also, the terminal device 100 may transmit transmittable power information, for example, in response to a request from the base station device 200. Furthermore, the terminal device 100 may add transmittable power information to a message to be transmitted to the base station device 200, such as SR, URLLC data, eMBB data, for example.

The base station apparatus 200 acquires transmittable power information of the terminal apparatus 100 by receiving transmittable power information from the terminal apparatus 100 (S302). Then, the base station apparatus 200 receives the URLLC data (S303), and calculates the transmission power of the URLLC data in the terminal apparatus 100 (S304). Similarly, the base station apparatus 200 receives eMBB data (S305), and calculates transmission power of eMBB data in the terminal apparatus 100 (S306).

The base station apparatus 200 calculates the transmission power of the terminal apparatus 100 based on, for example, the transmittable power of the terminal apparatus 100 and the received power of data in processing S304 and processing S306. The base station apparatus 200 calculates the transmission power of the eMBB data in the terminal apparatus 100 based on, for example, the received power of the eMBB data and the path loss value in the wireless section. Similarly, the base station apparatus 200 calculates the transmission power of the URLLC data in the terminal apparatus 100.

The path loss value is a path loss, and is a value indicating the degree to which the transmitted signal (data) attenuates (losses) in the communication path (wireless section) until it reaches the receiving side. The base station apparatus 200 may, for example, obtain a path loss value in the downlink direction (from the base station apparatus 200 to the terminal apparatus 100) acquired from the terminal apparatus 100, and a path loss value in the downlink direction may indicate the uplink direction (from the terminal apparatus 100 to the base station apparatus The transmission power may be calculated using the path loss value in the downlink direction, assuming that it is the same as the path loss value in the 200 direction).

FIG. 13 is a diagram showing an example of a flowchart of the eMBB non-control flag control process S307. The base station apparatus 200 waits to detect an update trigger (ON or OFF) of the eMBB non-control flag 224 (No in S308-1). When the base station apparatus 200 detects an update trigger of the eMBB non-control flag 224 (Yes in S308-1), if the update trigger is an update trigger of ON (Yes in S308-2), the eMBB non-control flag 224 Is turned on (S308-3), and when the update trigger is an update trigger of OFF (No in S308-2), the eMBB non-control flag 224 is turned OFF (S308-4).

Returning to the sequence of FIG. 12, the base station apparatus 200 compares the calculated transmission power of URLLC and eMBB with the transmittable power of the terminal apparatus 100, and the difference between the total and the transmittable power is within the predetermined power range. If so, it is determined that the transmittable power of the terminal apparatus 100 has no surplus capacity, or that the terminal apparatus 100 is reducing the transmission power of eMBB, and determines that it is an opportunity to turn on the eMBB non-control flag 224 ( Yes in S308-1 and Yes in S308-2 of FIG. Then, the base station apparatus 200 sets the eMBB non-control flag 224 to ON (S308-4 in FIG. 13).

Then, the base station apparatus 200 transmits, for example, a UL_Grant to which a radio resource for eMBB data is allocated without adding the eMBB transmission power control information (S309).

The base station apparatus 200 may acquire, for example, Power Headroom (information related to the remaining transmission power of the terminal) from the terminal apparatus 100, and may determine the eMBB transmission power increase disabling state of the terminal apparatus 100.

In the second embodiment, the base station apparatus 200 detects the eMBB transmission power increase disabling state of the terminal apparatus 100. Accordingly, the terminal device 100 can suppress the use of radio resources, for example, without transmitting the eMBB transmission power reduction notification to the base station device 200.

Third Embodiment
Next, a third embodiment will be described. In the third embodiment, the base station apparatus 200 resets the MCS (Modulation and Coding Scheme) when detecting that the terminal apparatus 100 can not increase the transmission power of the eMBB.

<Example of Configuration of Base Station Device>
FIG. 14 is a diagram showing a configuration example of the base station apparatus 200. The eMBB data reception program 222 stored in the storage 220 further includes an MCS reset module 2223.

The CPU 210 constructs the control unit by executing the MCS reset module 2223 of the eMBB data reception program 222, and performs MCS reset processing. The MCS resetting process is, for example, a process of determining a modulation scheme and a coding rate based on the received power of eMBB data, and selecting an MCS according to the determined modulation scheme and the coding rate.

<MCS notification process>
FIG. 15 is a diagram illustrating an example of a sequence of MCS communication processing. The terminal device 100 performs transmission power calculation processing S105 and eMBB data transmission processing S106. The terminal device 100 is in the eMBB transmission power increase disabling state, adds a transmission power decrease notification to the eMBB data, and transmits the eMBB data to the base station device 200 (S400).

The base station apparatus 200 receives eMBB data and performs eMBB data reception processing (S401).

FIG. 16 is a diagram showing an example of a processing flowchart of eMBB data reception processing S400. The processes from step S108-1 to step S108-7 in FIG. 16 are similar to the steps from step S108-1 to step S108-7 in FIG.

When the eMBB non-control flag 224 is ON (Yes in S108-4), the base station apparatus 200 performs MCS reconfiguration processing (S402). The MCS reset process S402 is a process of determining a modulation scheme and a coding rate according to the received power of eMBB data, and selecting an MCS according to the determined modulation scheme and the coding rate.

Returning to the sequence of FIG. 15, the base station apparatus 200 resets the MCS in MCS reconfiguration processing S402, and transmits an MCS configuration notification to the terminal apparatus 100 using the reconfigured MCS as a designated MCS (S403). When the terminal device 100 receives the MCS setting notification, the terminal device 100 stores the designated MCS, and implements the subsequent eMBB communication with the modulation scheme and the coding rate of the designated MCS (S404).

In the third embodiment, when the eMBB non-control flag 224 is ON, the base station apparatus 200 executes MCS reconfiguration processing S402. As a result, even if the transmission power of eMBB is low, the probability that base station apparatus 200 can receive eMBB data with a predetermined reception quality or more is improved.

10: Wireless communication system 11: CPU
100: terminal device 110: CPU
120: storage 121: wireless communication program 122: transmission power calculation program 123: eMBB transmission power lowering flag 124: eMBB transmission power reduction notification completion flag 130: memory 150: RF circuit 151: antenna 200: base station apparatus 210: CPU
220: storage 221: wireless communication control program 222: eMBB data reception program 223: eMBB non-control flag control program 224: eMBB non-control flag 230: memory 250: RF circuit 251: antenna 1211: eMBB data transmission module 1212: URLLC data transmission Module 2221: eMBB reception quality calculation module 2222: eMBB transmission power control module 2223: MCS reset module

Claims (13)

1. A base station apparatus capable of communicating with a terminal apparatus in the first communication mode and the second communication mode, the base station apparatus comprising:
   A control unit that controls the transmission power of the terminal device;
   And a detection unit that detects that the terminal device is in a first state in which the transmission power of data transmitted in the first communication mode can not be increased.
   The control unit stops control of transmission power for data transmitted by the terminal device in the first communication mode when detecting that the terminal device is in the first state.
2. The base station apparatus according to claim 1, wherein the detection unit receives, from the terminal apparatus, a message including information indicating the first state, and detects that the terminal apparatus is in the first state.
3. The detection unit is configured to be in the first state based on the reception power of data transmitted in the first communication mode and the second communication mode, and transmittable power that can be transmitted by the terminal device. The base station apparatus according to claim 1,
4. The detection unit transmits in the first communication mode and the second communication mode based on the received power and a path loss indicating a degree of power loss on the communication path between the terminal apparatus and the base station apparatus. Calculating the transmission power of the transmitted data at the terminal device, and adding the calculated transmission power of the data transmitted in the first communication mode and the second communication mode, and the transmittable power of the terminal device The base station apparatus according to claim 3, wherein when the difference is within a predetermined power range, the terminal apparatus is determined to be in the first state.
5. The base station apparatus according to claim 1, wherein the control unit further determines a modulation scheme in the first communication mode based on received power of data transmitted in the first communication mode.
6. The detection unit determines that the terminal device is not in the first state when detecting that the communication in the second communication mode has ended.
   The base station apparatus according to claim 1, wherein the control unit starts control of transmission power for data to be transmitted in the first communication mode when it is determined that the terminal apparatus is not in the first state.
7. The base station apparatus according to claim 1, wherein the first communication mode allows a delay larger than a delay allowed for the second communication mode.
8. The base station apparatus according to claim 7, wherein the first communication mode is eMBB (enhanced Mobile Broad Band), and the second communication mode is URL LC (Ultra-Reliable and Low Latency Communications).
9. A terminal apparatus capable of communicating with a base station apparatus in a first communication mode and a second communication mode, the terminal apparatus comprising:
   A first state detection unit which detects that the transmission power of data to be transmitted in the first communication mode can not be increased;
   And a notification unit configured to notify the base station apparatus that the own apparatus is in the first state when detecting that the first state is the first state.
10. The terminal device according to claim 9, wherein the base station device stops transmission power control on data transmitted by the terminal device in the first communication mode in response to reception of the notification.
11. Furthermore, when the sum of the transmission power in the first communication mode and the transmission power in the second communication mode exceeds the transmittable transmittable power of the own apparatus, the transmission power in the first communication mode is reduced, A transmission power control unit configured to control that the total does not exceed the transmittable power;
    10. The terminal apparatus according to claim 9, wherein the first state detection unit detects that the first state is the first state when the transmission power control unit controls the sum not to exceed the transmittable power.
12. A communication method in a base station apparatus, which is wirelessly connected to a communicable terminal device in the first communication mode and the second communication mode, and controls transmission power of the terminal device,
    Detecting that the terminal device is in a first state in which the transmission power of data to be transmitted in the first communication mode can not be increased;
    A communication method comprising: stopping control of transmission power for data transmitted by the terminal device in the first communication mode when detecting that the terminal device is in the first state.
13. A terminal device capable of communicating in a first communication mode and a second communication mode; and a base station device performing transmission power control for controlling transmission power of data transmitted by the terminal device;
    The base station apparatus detects that the terminal apparatus can not increase the transmission power of data to be transmitted in the first communication mode, and the terminal apparatus transmits the data in the first communication mode. A wireless communication system that stops control of transmission power for data.

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