JP7441494B2 - Wireless communication method - Google Patents

Description

Embodiments of the present invention relate to a wireless communication method.

Full duplex wireless communication technology is one of the wireless multiplexing technologies. Since full-duplex wireless communication technology simultaneously transmits and receives wireless signals, it can, in principle, double the efficiency of frequency use. Therefore, it is highly useful in 5G and B5G wireless communication systems including IoT systems.

A base station that performs full-duplex wireless communication allocates individual wireless communication channels represented by time slots to a plurality of accommodated wireless terminals, and performs full-duplex wireless communication for each of them.

Bharadia, E. McMilin, and S. Katti, “Full duplex radios.” In Proceedings of the ACM SIGCOMM 2013 conference on SIGCOMM’13, pages 375-386, NewYork, NY, USA, 2013.

In Non-Patent Document 1, since full-duplex wireless communication is performed between a plurality of wireless terminals and a base station, effective use of frequency resources for expanding radio wave resources is achieved.

However, Non-Patent Document 1 does not take into account differences in operating conditions including service quality required for wireless communication. Therefore, there is room for improvement from the perspective of operational status, including required service quality.

One possible area for improvement in operational conditions, including service quality, is communication interference between wireless terminals that occurs at base stations due to full-duplex wireless communications.

Embodiments of the present invention provide a wireless communication method using full-duplex wireless communication that can suppress communication interference between wireless terminals occurring at a base station.

A wireless communication method according to a first aspect of the present invention is a wireless communication method in a 5G or B5G wireless communication system including an IoT system that wirelessly communicates between a plurality of wireless terminals and a base station, a first wireless terminal that performs full-duplex wireless communication of the wireless signal with the base station; a second wireless terminal that performs half-duplex wireless communication of the wireless signal with the base station; The base station allocates individual wireless communication channels to each of the plurality of wireless terminals, performs full-duplex wireless communication or half-duplex wireless communication with the plurality of wireless terminals , and further The individual wireless communication channel includes a time slot, and on the time slot, a time slot period for full-duplex wireless communication and a time slot period for half-duplex wireless communication are set regularly. , alternately, the separate wireless communication channels are full-duplex channels including uplinks transmitted from the first wireless terminal to the base station and downlinks transmitted from the base station to the first wireless terminal. an uplink channel including an uplink transmitted from the second wireless terminal to the base station, and a downlink channel including a downlink transmitted from the base station to the second wireless terminal, the base station (1) allocating a first wireless communication channel including the full duplex channel; (2) after allocating the first wireless communication channel, allocating a second wireless communication channel including the uplink channel; and (3) after allocating the second wireless communication channel, allocating the first wireless communication channel; (4) after allocating the first wireless communication channel, allocating a third wireless communication channel including the downlink channel; The wireless communication channel assignments described in 1) to (4) are repeated.

In the wireless communication method according to a second aspect of the present invention, in the first aspect, the individual wireless communication channels include an unused channel, an uplink transmitted from the first wireless terminal to the base station, and an uplink that is transmitted from the first wireless terminal to the base station. a full duplex channel comprising a downlink transmitted from the base station to the first wireless terminal; an uplink channel comprising an uplink transmitted from the second wireless terminal to the base station; and a full duplex channel comprising a downlink transmitted from the second wireless terminal to the base station; a downlink channel including a downlink transmitting to the base station, the base station (5) allocating a fourth wireless communication channel including the full duplex channel; and (6) after allocating the fourth wireless communication channel. , allocating a fifth wireless communication channel including one of the uplink channel and the downlink channel, (7) allocating the unused channel after allocating the fifth wireless communication channel, (8) allocating the unused channel. After allocating, a sixth wireless communication channel including the other of the uplink channel and the downlink channel is allocated, and the wireless communication channel allocation described in (5) to (8) above is repeated, and the unused channel is , a non-standby slot in which transmission and reception are not performed for each of the first wireless terminal and the second wireless terminal.

In the wireless communication method according to a third aspect of the present invention, in the first aspect or the second aspect, the individual wireless communication channels include an unused channel and an uplink transmitted from the first wireless terminal to the base station. , a full duplex channel including a downlink transmitted from the base station to the first wireless terminal; an uplink channel including an uplink transmitted from the second wireless terminal to the base station; a downlink channel including a downlink transmitted to a second wireless terminal, the base station alternately allocating the full duplex channel and one of the uplink channel and the downlink channel to the unused channel and the other of the uplink channel and the downlink channel, and the unused channel includes a non-standby slot in which no transmission or reception is performed for the first wireless terminal and the second wireless terminal, respectively. .

In a wireless communication method according to a fourth aspect of the present invention, in any one of the first to third aspects, the wireless terminal performs full-duplex wireless communication with the base station before a wireless communication channel is allocated. It is possible to notify whether a channel assignment or a half-duplex wireless communication channel assignment is desired.

In the wireless communication methods according to the first to fourth aspects, the base station allocates individual wireless communication channels to each of the plurality of wireless terminals, and performs full-duplex wireless communication or half-duplex wireless communication for the plurality of wireless terminals. Performs heavy radio communication. As a result, communication interference between wireless terminals occurring at the base station can be suppressed, compared to a case where the base station performs full-duplex wireless communication with all of a plurality of wireless terminals. Therefore, according to the wireless communication methods according to the first to fourth aspects, it is possible to provide a wireless communication method using full-duplex wireless communication that can suppress communication interference between wireless terminals occurring at a base station. .

FIGS. 1(a) to 1(c) are schematic diagrams illustrating an example of a wireless communication method according to an embodiment. FIG. 2 is a schematic time chart showing an example of time slots of a wireless communication method according to an embodiment. FIG. 3 is a schematic diagram illustrating an example of a wireless communication method according to a first modification of an embodiment. FIG. 4 is a schematic time chart showing an example of time slots of a wireless communication method according to a first modified example of an embodiment. FIGS. 5(a) to 5(d) are schematic diagrams illustrating an example of a wireless communication method according to a second modified example of an embodiment. FIG. 6 is a schematic time chart showing an example of time slots of a wireless communication method according to a second modified example of an embodiment.

Hereinafter, one embodiment of the present invention will be described with reference to the drawings. In each figure, common parts are given common reference numerals, and overlapping explanations will be omitted.

(One embodiment)
FIGS. 1(a) to 1(c) are schematic diagrams illustrating an example of a wireless communication method according to an embodiment. FIG. 2 is a schematic time chart showing an example of time slots of a wireless communication method according to an embodiment.

As shown in FIGS. 1(a) to 1(c), the wireless communication method according to one embodiment is a wireless communication method for wirelessly communicating between a plurality of wireless terminals and a base station 2. A first wireless terminal 1a (FIG. 1(a)) performs full-duplex wireless communication of wireless signals with the base station 2, and a first wireless terminal 1a (FIG. 1(a)) performs full-duplex wireless communication of wireless signals with the base station 2. It includes second wireless terminals 1b to 1d (FIGS. 1(b) and 1(c)) that perform heavy wireless communication.

As shown in FIG. 2, the base station 2 allocates individual wireless communication channels to each of the wireless terminals 1a to 1d. The base station 2 performs, for example, full-duplex wireless communication with the wireless terminal 1a and half-duplex wireless communication with the wireless terminals 1b to 1d. In one embodiment, the base station 2 performs full-duplex wireless communication with the first wireless terminal 1a, and performs half-duplex wireless communication with the second wireless terminal 1b to fourth wireless terminal 1d.

FIG. 2 also shows an example of a wireless communication channel including, for example, a time slot 100, as an example of individual wireless communication channels. The base station 2 divides the time slot 100 for the first wireless terminal 1a to the fourth wireless terminal 1d into a full-duplex wireless communication time slot period 200FD for full-duplex wireless communication and a half-duplex wireless communication time slot period 200FD for half-duplex wireless communication. The radio time slot period is divided into 200 HD. As a result, the base station 2 performs full-duplex wireless communication with the first wireless terminal 1a during the full-duplex wireless communication time slot period 200FD, and performs full-duplex wireless communication with the second wireless terminals 1b to 1d during the half-duplex wireless communication time slot period 200HD. , half-duplex wireless communication is performed.

Furthermore, in the wireless communication method according to one embodiment, the base station 2 periodically repeats the full-duplex wireless communication time slot period 200FD and the half-duplex wireless time slot period 200HD. For example, the base station 2 alternately repeats a full-duplex radio communication time slot period 200FD and a half-duplex radio time slot period 200HD.

Full-duplex wireless communication time slot period 200FD includes full-duplex slot 100FD. The full duplex slot 100FD includes an uplink that transmits uplink data from the first wireless terminal 1a to the base station 2, and a downlink that transmits downlink data from the base station 2 to the first wireless terminal 1a.

Half-duplex radio time slot period 200HD includes uplink slot 100UL and downlink slot 100DL. The uplink slot 100UL sequentially transmits uplink data from the second wireless terminal 1b to the fourth wireless terminal 1d to the base station 2. The downlink slot 100DL sequentially transmits downlink data from the base station 2 to the second wireless terminal 1b to the fourth wireless terminal 1d.

In the wireless communication method according to one embodiment, the base station 2 takes the following communication procedure.

(1) Allocate a first wireless communication channel including a full duplex channel (one example is full duplex slot 100FD).

(2) After allocating the first wireless communication channel, allocate a second wireless communication channel including an uplink channel (an example is uplink slot 100UL).

(3) After allocating the second wireless communication channel, allocating the first wireless communication channel.

(4) After allocating the first wireless communication channel, allocate a third wireless communication channel including a downlink channel (an example is downlink slot 100DL).

Then, the communication channel allocation described in (1) to (4) above is repeated.

According to the wireless communication method according to such an embodiment, full-duplex wireless communication and half-duplex wireless communication are possible between a plurality of wireless terminals, for example, the first wireless terminal 1a to the fourth wireless terminal 1d, and the base station 2. Performs heavy radio communication. Thereby, compared to the case where the base station 2 performs half-duplex wireless communication with all of a plurality of wireless terminals, for example, it is possible to effectively utilize frequency resources for expanding radio wave resources. Along with this, communication interference between wireless terminals occurring at the base station 2 can be suppressed compared to the case where the base station 2 performs full-duplex wireless communication with all of the plurality of wireless terminals.

Furthermore, the wireless communication method according to the embodiment includes a full-duplex wireless communication time slot period of 200FD and a half-duplex wireless time slot period of 200HD regarding differences in operational conditions including service quality required for wireless communication. Instead of being generated randomly, an attempt is made to repeat them alternately on the time slot 100 with regularity. With this device, communication interference between the first wireless terminal 1a to the fourth wireless terminal 1d that occurs at the base station 2 due to full-duplex wireless communication can be suppressed by randomizing the full-duplex wireless communication and half-duplex wireless communication. This makes it possible to reduce the amount of damage even more than when it occurs. In particular, interference between communication cells based on the downlink from the first wireless terminal 1a in full-duplex wireless communication can be suppressed.

An example of interference between communication cells is that, for example, a call or ambient environmental sound that enters the downlink data from the first wireless terminal 1a enters the downlink data of the wireless terminal 1b during transmission from the base station 2. It is. According to the communication method according to one embodiment, such interference between communication cells can be reduced compared to the case where the communication method according to one embodiment is not used.

Therefore, according to the wireless communication method according to one embodiment, full-duplex wireless communication is used that can suppress communication interference between the first wireless communication terminal 1a to the fourth wireless communication terminal 1d that occurs at the base station 2. A wireless communication method can be obtained.

Further, a wireless communication method according to an embodiment that uses both full-duplex wireless communication and half-duplex wireless communication is particularly useful in 5G and B5G wireless communication systems including IoT systems.

Note that although the case where there are four wireless terminals 1a to 1d is illustrated as an example, the number of wireless terminals is not limited to four and may be arbitrary. Moreover, although the case where there is one wireless terminal 1a that performs full-duplex wireless communication is illustrated, the number of wireless terminals that perform full-duplex wireless communication is not limited to one and may be arbitrary. These matters also apply to the modified examples described below.

(First modification)
FIG. 3 is a schematic diagram illustrating an example of a wireless communication method according to a first modified example of an embodiment. FIG. 4 is a schematic time chart showing an example of time slots of a wireless communication method according to a first modified example of an embodiment.

As shown in FIGS. 3 and 4, the wireless communication method according to the first modification differs from the wireless communication method according to the embodiment in that each wireless communication channel includes an unused channel. Unused channels include unused slots 300, for example. Examples of the unused slots 300 include non-standby slots that do not perform transmission or reception for each of the first wireless terminals 1a to 4th wireless terminals 1d. In such an unused slot 300, the base station 2 can reduce the power involved in transmitting downlink data and receiving uplink data to each of the first to fourth wireless terminals 1a to 1d.

According to the wireless communication method according to the first modification, compared to the communication method according to one embodiment, it is possible to reduce power consumption in the base station 2 while suppressing communication interference.

Furthermore, according to the first modification, the communication procedure performed next to the unused slot 300 is a downlink between the second wireless terminal 1b to the fourth wireless terminal 1d.

In this way, after allocating the unused slot 300, the base station 2 allocates the wireless communication channel including the downlink slot 100DL to the second wireless terminal 1b to the fourth wireless terminal 1d, thereby improving the communication between the communication cells. Interference can be reduced even better. Further, although not particularly illustrated, after allocating the unused slot 300, the base station 2 can also allocate a wireless communication channel including the uplink slot 100UL to the second wireless terminal 1b to the fourth wireless terminal 1d. . Therefore, the base station 2 allocates, for example, a fourth wireless communication channel including (5) full duplex slots (one example is full duplex slot 100FD). (6) After allocating the fourth wireless communication channel, allocate a fifth wireless communication channel including one of an uplink channel (one example is uplink slot 100UL) and a downlink channel (one example is downlink slot 100DL). (7) After allocating the fifth wireless communication channel, allocate an unused channel. (8) After allocating the unused channels, allocating a sixth wireless communication channel including the other of the uplink channel and the downlink channel. Then, the communication channel allocation described in (5) to (8) above may be repeated.

(Second modification)
FIGS. 5(a) to 5(d) are schematic diagrams illustrating an example of a wireless communication method according to a second modified example of an embodiment. FIG. 6 is a schematic time chart showing an example of time slots of a wireless communication method according to a second modified example of an embodiment.

As shown in FIGS. 5(a) to 6, the second modified example differs from the first modified example in that the base station 2 alternately allocates full duplex slots 100FD and uplink slots 100UL to unused slots. The slot 300 and the downlink slot 100DL are alternately allocated.

In this way, for example, by alternately using the unused slots 300 and the downlink slots 100DL, the interference between the communication cells can be further reduced compared to the first modification. Although not particularly shown, it is also possible to alternately allocate the full duplex slot 100FD and the downlink slot 100DL, and to alternately allocate the unused slot 300 and the uplink slot 100UL. In this way, the base station 2 alternates between a full duplex channel (one example is full duplex slot 100FD) and one of the uplink channel (one example is uplink slot 100UL) and the downlink channel (one example is downlink slot 100DL). Alternatively, the unused channel and the other of the uplink channel and the downlink channel may be allocated alternately.

An embodiment and some modifications of this invention have been described above, but the above embodiment and some modifications are presented as examples and are not intended to limit the scope of the invention. .

For example, information indicating whether the communication method is full-duplex wireless communication or half-duplex wireless communication is included in the uplink data from the wireless terminal, and based on this information, the base station 2 It is also possible to allocate either a full-duplex wireless communication channel or a half-duplex wireless communication channel as the wireless communication channel to the wireless terminals, for example, the wireless terminals 1a to 1d. In addition, the wireless terminals, for example, the wireless terminals 1a to 1d, determine whether to allocate a wireless communication channel using a full-duplex wireless communication method or a wireless communication channel using a half-duplex wireless communication method to downlink data from the base station 2. You may also inform them. Based on this information, the wireless terminal can know whether a wireless communication channel using full-duplex wireless communication or a wireless communication channel using half-duplex wireless communication has been allocated. In this way, the wireless terminal may be able to notify the base station 2 whether it wishes to allocate a full-duplex wireless communication channel or a half-duplex wireless communication channel, for example, before the wireless communication channel is allocated. good.

Furthermore, various omissions, substitutions, and changes can be made to the embodiments of the present invention without departing from the gist of the present invention. Such novel forms and modifications are included within the scope and gist of the present invention, as well as within the scope of the claimed inventions and equivalents of the claimed inventions.

1a: First wireless terminal 1b: Second wireless terminal 1c: Third wireless terminal 1d: Fourth wireless terminal 2: Base station 100: Time slot 100FD: Full duplex slot 100UL: Uplink slot 100DL: Downlink slot 200FD: Full Duplex communication time slot period 200HD: Half duplex communication time slot period 300: Unused slot

Claims (4)

A wireless communication method in a 5G or B5G wireless communication system including an IoT system that wirelessly communicates between a plurality of wireless terminals and a base station,
The plurality of wireless terminals are
a first wireless terminal that performs full-duplex wireless communication of the wireless signal with the base station;
a second wireless terminal that performs half-duplex wireless communication of the wireless signal with the base station;
including;
The base station is
Allocating individual wireless communication channels to each of the plurality of wireless terminals, performing full-duplex wireless communication or half-duplex wireless communication with the plurality of wireless terminals ,
Furthermore, the individual wireless communication channel includes a time slot, and on the time slot, a time slot period for full-duplex wireless communication and a time slot period for half-duplex wireless communication are made regular. Repeat alternately,
The separate wireless communication channels are:
a full duplex channel including an uplink transmitted from the first wireless terminal to the base station and a downlink transmitted from the base station to the first wireless terminal;
an uplink channel including an uplink transmitted from the second wireless terminal to the base station;
a downlink channel including a downlink transmitted from the base station to the second wireless terminal;
including;
The base station is
(1) allocating a first wireless communication channel including the full duplex channel;
(2) after assigning the first wireless communication channel, assigning a second wireless communication channel including the uplink channel;
(3) after assigning the second wireless communication channel, assigning the first wireless communication channel;
(4) after assigning the first wireless communication channel, assigning a third wireless communication channel including the downlink channel;
Repeating the wireless communication channel allocation described in (1) to (4) above.
A wireless communication method characterized by: The separate wireless communication channels are:
unused channels and
a full duplex channel including an uplink transmitted from the first wireless terminal to the base station and a downlink transmitted from the base station to the first wireless terminal;
an uplink channel including an uplink transmitted from the second wireless terminal to the base station;
a downlink channel including a downlink transmitted from the base station to the second wireless terminal;
including;
The base station is
(5) allocating a fourth wireless communication channel including the full duplex channel;
(6) after assigning the fourth wireless communication channel, assigning a fifth wireless communication channel including one of the uplink channel and the downlink channel;
(7) after assigning the fifth wireless communication channel, assigning the unused channel;
(8) after allocating the unused channel, allocating a sixth wireless communication channel including the other of the uplink channel and the downlink channel;
Repeating the wireless communication channel allocation described in (5) to (8) above,
2. The wireless communication method according to claim 1 , wherein the unused channel includes a non-standby slot in which no transmission or reception is performed for each of the first wireless terminal and the second wireless terminal . The separate wireless communication channels are:
unused channels and
a full duplex channel including an uplink transmitted from the first wireless terminal to the base station and a downlink transmitted from the base station to the first wireless terminal;
an uplink channel including an uplink transmitted from the second wireless terminal to the base station;
a downlink channel including a downlink transmitted from the base station to the second wireless terminal;
including;
The base station is
alternately allocating the full duplex channel and one of the uplink channel and the downlink channel;
Alternately allocating the unused channel and the other of the uplink channel and the downlink channel;
3. The wireless communication method according to claim 1, wherein the unused channel includes a non-standby slot in which neither transmission nor reception is performed for the first wireless terminal and the second wireless terminal. The wireless terminal is
2. The base station according to claim 1 , wherein, before a wireless communication channel is allocated, it is possible to notify the base station whether a full-duplex wireless communication channel or a half-duplex wireless communication channel is desired to be allocated. 3. The wireless communication method according to any one of 3 .

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