JP6012401B2 - COMMUNICATION SYSTEM, BASE STATION, AND BASE STATION CONTROL METHOD - Google Patents

Description

The present invention relates to a communication system, a base station, and a base station control method .

  LTE (Long Term Evolution) systems, XGP (eXtended Global Platform) systems, and the like are attracting attention as next-generation communication systems that realize improved communication performance. These systems can employ TDMA / TDD (Time Division Multiple Access / Time Divisional Duplex). In a system employing TDMA / TDD, an upstream frame including a plurality of upstream time slots and a downstream frame including a plurality of downstream time slots are alternately arranged on the time axis. A plurality of uplink time slots and downlink time slots are allocated to each communication terminal communicating with the base station.

  In a system employing TDMA / TDD, the reception timing of the base station and the transmission timing of the communication terminal are determined based on the synchronization timing of the common clock. The signal (transmission signal) transmitted from the communication terminal is delayed according to the communication distance between the communication terminal and the base station. Therefore, when the communication terminal transmits a signal at the same timing as the reception timing of the base station, this signal reaches the base station later than the reception timing. Therefore, the communication terminal sets the transmission timing earlier than the synchronization timing in consideration of the propagation delay so that the transmission signal reaches the reception timing set as the synchronization timing.

  A communication terminal that is farther away from the base station has a longer propagation delay, so that the transmission timing is advanced. For this reason, the time (shift time) between the synchronization timing and the transmission timing becomes long. If the shift time exceeds the guard time between uplink time slots, the communication terminal may transmit a signal within the uplink time slot of another communication terminal. In this case, interference between communication terminals occurs.

  Therefore, a technique has been proposed in which uplink time slots are assigned to communication terminals so as to suppress interference between communication terminals (see, for example, Patent Document 1). The technique described in Patent Literature 1 determines an uplink time slot to be assigned to a communication terminal according to the distance between the base station and the communication terminal. In order from the communication terminal far from the base station (communication terminal having a long propagation delay), allocation is performed from the upstream uplink time slot of the upstream frame. As a result, the upstream time slot shift time before (the leading side) shifts longer than the shift time of a certain upstream time slot, so that the upstream time slots do not overlap each other. Therefore, interference between communication terminals can be suppressed.

JP 2008-167010 A

  However, although the technique of Cited Document 1 suppresses interference between communication terminals, no consideration is given to interference between adjacent base stations.

  It is assumed that a certain base station 501a communicates with the communication terminals 503a and 503b, and another base station 501b adjacent to the base station 501a communicates with the communication terminals 503c and 503d. As shown in FIG. 10, it is assumed that the reception period 531a of the communication terminal 503a and the reception period 531c of the communication terminal 503c are common. Further, it is assumed that the reception period 531b of the communication terminal 503b and the reception timing 531d of the communication terminal 503d are common.

  It is assumed that the distance between the base station 501a and the communication terminals 503a and 503b is longer than the distance between the base station 501b and the communication terminals 503c and 503d. In this case, the base station 501a transmits a signal earlier than the base station 501b in consideration of the propagation delay. That is, the base station 501a sets the downlink time slots 533a and 533b assigned to the communication terminals 503a and 503b as shown in FIG. Also, downlink time slots 533c and 533d assigned to the communication terminals 503c and 503d are set as shown in FIG.

  Then, as shown in FIG. 10, the downlink time slot 533b for the communication terminal 503b of the base station 501a may overlap with the downlink time slot 533c for the communication terminal 503c of the base station 501b. In this case, the base stations interfere with each other.

  Therefore, an object of the present invention made in view of the above problems is to provide a communication system, a base station, an adjacent base station, and a communication control method that can efficiently reduce the possibility of interference between base stations. It is in.

In order to solve the above-described problems, the invention of the communication system according to the first aspect is as follows:
In a communication system including a base station that determines a time slot assigned to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the range of the delay time .
The base station
When the delay time of the signal from the communication terminal communicating with the base station in a certain time slot is outside the range of the delay time associated with the time slot, the allowable delay time of the signal of the communication terminal If the delay time can be increased based on the communication terminal, a time slot corresponding to the increased delay time is reassigned to the communication terminal .

The invention according to the second aspect is the communication system according to the first aspect,
The base station
When the delay time cannot be increased based on the allowable delay time of the signal of the communication terminal, the delay time range corresponding to the time slot is changed so as to include the delay time. It is.

The invention according to the third aspect is the communication system according to the first or second aspect,
Further comprising an adjacent base station adjacent to the base station;
The correspondence between the time slot and the delay time range is the same between the respective base stations,
The base station
When the delay time range corresponding to the time slot is changed, the changed association between the time slot and the delay time range is transmitted to the adjacent base station,
The adjacent base station is
Based on the changed association, the association between the time slot and the delay time range in the own station is changed .

The invention according to a fourth aspect is a communication system according to a third aspect, the adjacent base station, in response to the correspondence of the change of the local station, the time slots to the communication terminal in communication before change Is reassigned.

The invention according to the fifth aspect is
In a base station including a control unit that determines a time slot assigned to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the delay time range .
The control unit, when a delay time of a signal from a communication terminal communicating with the base station in a certain time slot is out of a delay time range associated with the time slot, the signal of the communication terminal If the delay time can be increased based on the permissible delay time, the base station reassigns the time slot corresponding to the increased delay time to the communication terminal .

  As described above, the solution of the present invention has been described as an apparatus. However, the present invention can be realized as a method, a program, and a storage medium storing the program, which are substantially equivalent thereto, and the scope of the present invention. It should be understood that these are also included.

For example, the base station control method according to the sixth aspect of the present invention implemented as a method is as follows:
In a control method of a base station comprising a control unit that determines a time slot allocated to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the range of the delay time.
When the delay time of the signal from the communication terminal communicating with the base station in a certain time slot is outside the range of the delay time associated with the time slot, the allowable delay time of the signal of the communication terminal If the delay time can be increased based on, the step of increasing the delay time;
The time slot corresponding to the increased delay time which is a control method of a base station including <br/> the step of re-allocated to the communication terminal.

  According to the communication system, the base station, the adjacent base station, and the communication control method according to the present invention configured as described above, the possibility that the base stations interfere with each other can be efficiently reduced.

FIG. 1 is a schematic configuration diagram of a communication system according to an embodiment of the present invention. FIG. 2 is a functional block diagram showing a schematic configuration of the base station according to the embodiment of the present invention. FIG. 3 is a flowchart showing processing of the base station according to the embodiment of the present invention. FIG. 4 is a flowchart showing processing of an adjacent base station according to an embodiment of the present invention. FIG. 5 is an explanatory diagram showing associations between time slots and delay time ranges according to an embodiment of the present invention. FIG. 6 is an explanatory diagram showing allocation of time slots to communication terminals according to an embodiment of the present invention. FIG. 7 is an explanatory diagram showing allocation of time slots to communication terminals according to an embodiment of the present invention. FIG. 8 is an explanatory diagram showing allocation of time slots to communication terminals according to an embodiment of the present invention. FIG. 9 is an explanatory diagram showing allocation of time slots to communication terminals according to an embodiment of the present invention. FIG. 10 is an explanatory diagram showing conventional interference between base stations.

  FIG. 1 is a schematic configuration diagram of a communication system according to an embodiment of the present invention. The communication system 100 includes a base station 101 (base stations 101a and 101b) and a communication terminal 103 (communication terminals 103a, 103b, 103c and 103d). The communication system 100 is a system that employs TDMA / TDD, such as an LTE system or an XGP system. The base station 101 assigns an uplink time slot and a downlink time slot to the communication terminal 103 and performs wireless communication with the communication terminal 103. The uplink time slot is a time interval for the base station 101 to receive a signal from the communication terminal 103, and the downlink time slot is a time interval for the base station 101 to transmit a signal to the communication terminal 103. There are a plurality of uplink time slots and downlink time slots, and the base station 101 allocates one or more uplink time slots and one or more downlink time slots to one communication terminal 103 that requests communication connection. .

  Base stations 101a and 101b are adjacent to each other. Adjacent means that the cell (service area) of the base station 101a and the cell of the base station 101b overlap. Hereinafter, the base station 101a is referred to as a base station, and the base station 101b adjacent to the base station 101a is referred to as an adjacent base station. In the description of matters common to the base station 101a and the adjacent base station 101b, the base station 101a and the adjacent base station 101b are expressed as the base station 101 without distinction.

  FIG. 2 is a functional block diagram showing a schematic configuration of the base station according to the embodiment of the present invention. The base station 101 of this embodiment includes a communication unit 111, a baseband unit 113, and a control unit 117. The communication unit 111 and the baseband unit 113 are connected to the control unit 117.

  The communication unit 111 transmits and receives data (wireless signal) to and from the communication terminal 103 via wireless communication. The communication unit 111 performs amplification and down-conversion with low noise on the received signal (reception signal) and sends the signal to the baseband unit 113. In addition, the communication unit 111 performs up-conversion and amplification on the signal from the baseband unit 113 to generate a transmission signal. Then, the communication unit 111 transmits the transmission signal to the communication terminal 103 via the antenna.

  The communication unit 111 can also communicate with other base stations 101 via a wired network between base stations to transmit and receive signals. In this case, the communication unit 111 is realized by, for example, an X2 interface. The X2 interface is an interface between base stations defined by 3GPP (3rd Generation Partnership Project). In FIG. 2, the communication unit 111 is expressed as one functional block, but the present invention is limited to realizing the communication unit 111 with one piece of hardware having both wired communication and wireless communication functions. It is not a thing. For example, the communication unit 111 can be realized by separate hardware corresponding to the use of wired communication and wireless communication.

  The baseband unit 113 demodulates the received signal and extracts the baseband signal by performing AD conversion, fast Fourier transform, and the like on the received signal from the communication unit 111. Then, the baseband unit 113 sends a baseband signal to the control unit 117. The baseband unit 113 modulates the baseband signal by performing inverse fast Fourier transform, DA conversion, or the like on the baseband signal from the control unit 117. Then, the baseband unit 113 sends the modulated baseband signal to the communication unit 111.

  The control unit 117 controls and manages the entire base station 101 including each functional block of the base station 101. The control unit 117 is configured as software executed on an arbitrary suitable processor such as a CPU (central processing unit) or a dedicated processor (for example, DSP (digital signal processor)) specialized for each process. You can also. The processing performed by the control unit 117 will be described in detail with reference to FIGS. 3 and 4 to be described later.

  Subsequently, processing of the base station 101a and the adjacent base station 101b will be described with reference to FIGS. FIG. 3 is a flowchart showing processing of the base station according to the embodiment of the present invention. FIG. 4 is a flowchart showing processing of an adjacent base station according to an embodiment of the present invention. As reference numerals for the functional blocks of the base station 101 shown in FIG. 2, the reference numerals of the functional blocks for the base station 101a are a, and the reference numerals of the functional blocks for the adjacent base station 101b are b. explain.

  The control unit 117a of the base station 101a determines the downlink time slot 121a assigned to the communication terminal according to the delay time of the signal from the communication terminal 103. That is, the control unit 117a sets a delay time range (delay time range) corresponding to each of the plurality of downlink time slots 121a (step S101). The delay time of the signal from the communication terminal 103 is a propagation delay that is required until the base station 101a receives the signal after the communication terminal 103 transmits the signal. The delay time range is an item that is arbitrarily set according to the length of the guard time between adjacent downlink time slots, the allowable interference time between base stations, and the like.

  For example, as shown in FIG. 5, the control unit 117a sets a delay time range in four downlink time slots 121a-1 to 121a-4. The control unit 117a sets a delay time range of 0 [ms] to less than 50 [ms] (0 to 50 [ms]) in the time slot 121a-1, and 50 [ms] to 100 [100] in the time slot 121a-2. ms]] to the time slot 121a-3, a delay time range of 100 [ms] to less than 150 [ms] (100 to 150 [ms]) is assigned to the time slot 121a-3. 121a-4 is associated with a delay time range of 150 [ms] or more and less than 200 [ms] (150 to 200 [ms]).

  Then, the control unit 117a controls the communication unit 111a to transmit the association between the downlink time slot of the base station 101a and the delay time range to the adjacent base station 101b (step S102).

  Then, the communication unit 111b of the adjacent base station 101b receives the association between the downlink time slot and the delay time range of the base station 101a (step S201), and sends the association to the control unit 117b. Based on the received association of the base station 101a, the control unit 117b determines the association between the downlink time slot 121b and the delay time range in the adjacent base station 101b (step S202). That is, the control unit 117b sets the same delay time range as that of the downlink time slot 121a in the downlink time slot 121b having the same time position as the downlink time slot 121a of the base station 101a. Thereby, the association between the time slot and the delay time range in the base station 101a and the association between the time slot and the delay time range in the adjacent base station 101b are the same between the base stations.

  For example, as illustrated in FIG. 5, the control unit 117b sets a delay time range in the four downlink time slots 121b-1 to 121b-4 based on the association of the base station 101a. The control unit 117b sets a delay time range of 0 [ms] to less than 50 [ms] (0 to 50 [ms]) in the time slot 121b-1, and 50 [ms] to 100 [100] in the time slot 121b-2. ms] (50 to 100 [ms]) in the time slot 121b-3, a delay time range from 100 [ms] to less than 150 [ms] (100 to 150 [ms]) in the time slot 121b-4 is associated with a delay time range of 150 [ms] or more and less than 200 [ms] (150 to 200 [ms]).

  Here, it is assumed that the communication terminals 103a and 103b request communication connection from the base station 101a. Then, the control unit 117a of the base station 101a calculates the delay time of signals from the communication terminals 103a and 103b (step S103). The control unit 117a calculates a delay time, for example, a conventionally known calculation method such as a correlation calculation between a reference symbol (pilot signal) included in the connection request signal and an ideal reference symbol stored in the base station 101a in advance. It can ask for. In addition, when the communication terminals 103a and 103b add information (time stamp) indicating the transmission time to the connection request signal, the control unit 117a measures the reception time of the time stamp, and transmits the transmission time from the reception time. The delay time can also be obtained by subtracting. The time measurement can be realized, for example, when the base station 101a and the communication terminals 103a and 103b include an RTC (Real Time Clock). The delay time is not limited to the calculation based on one received signal, and the control unit 117a may specify the delay time by, for example, averaging the calculation results of the received signals over a plurality of times. it can.

  Then, the control unit 117a assigns the downlink time slot 121a associated with the delay time range including the calculated delay time to the communication terminals 103a and 103b (step S104). For example, when the delay times of the signals from the communication terminals 103a and 103b are 75 [ms] and 135 [ms], respectively, the control unit 117a sends the downlink time slot 121a to the communication terminals 103a and 103b as shown in FIG. -2 and 121a-3 are assigned respectively. In the downlink time slots 121a-1 and 121a-4, no communication terminal is allocated, and the downlink time slots are not used.

  Here, it is assumed that the communication terminals 103c and 103d request communication connection from the adjacent base station 101b. Then, the control unit 117b of the adjacent base station 101b calculates the delay time of signals from the communication terminals 103c and 103d (step S203).

  Then, the control unit 117b assigns the downlink time slot 121b associated with the delay time range including the calculated delay time to the communication terminals 103c and 103d (step S204). For example, when the delay times of the signals from the communication terminals 103c and 103d are 80 [ms] and 140 [ms], respectively, the control unit 117b sends the downlink time slot 121b to the communication terminals 103c and 103d as shown in FIG. -2 and 121b-3 are assigned respectively. Thus, the transmission timing of the adjacent base station 101b in the downlink time slot 121b-2 is 5 [ms] (= 80-75) earlier than the transmission timing of the base station 101a in the downlink time slot 121a-2. Become.

  If the processing of step S201 and step S202 is not performed in the adjacent base station 101b, the adjacent base station 101b arbitrarily assigns the downlink time slot 121b to the communication terminals 103c and 103d. For example, the adjacent base station 101b may assign the downlink time slot 121b-2 to the communication terminal 103d with a delay time of 140 [ms]. In this case, the transmission timing of the adjacent base station 101b in the downlink time slot 121b-2 is 65 [ms] (= 140-75) earlier than the transmission timing of the base station 101a in the downlink time slot 121a-2. Become. Then, compared with the case where the communication terminal 103c is assigned to the downlink time slot 121b-2, the possibility that the downlink time slot 121b-2 of the adjacent base station 101b overlaps with the downlink time slot 121a-1 of the base station 101a is increased. Will end up.

  After step S104, the control unit 117a of the base station 101a calculates the delay time of the signal from the communication terminal 103a during communication regularly or irregularly. Then, each time the delay time is calculated, the control unit 117a determines whether or not the delay time is included in the delay time range associated with the downlink time slot 121a-2 (step S105).

  When the calculated delay time is out of the delay time range associated with the downlink time slot 121a-2 (Yes in step S105), that is, when the delay time is less than 50 [ms] or 100 [ms] or more, The control unit 117a determines whether or not the downlink time slot associated with the delay time range including this delay time is free (step S106).

  When the downlink time slot corresponding to the delay time is vacant (Yes in step S106), the control unit 117a reassigns the downlink time slot to the communication terminal 103a (step S107). For example, when the delay time of the signal from the communication terminal 103a is 130 [ms] (Yes in Step S105) and the downlink time slot 121a-3 is not assigned to another communication terminal (Yes in Step S106), the control is performed. The unit 117a can reassign the downlink time slot 121a-3 to the communication terminal 103a (step S107).

  In the present embodiment, since the downlink time slot 121a-3 is assigned to the communication terminal 103b (No in step S106), the control unit 117a determines whether or not the delay time can be increased (step S108). Here, the control unit 117a can use a parameter called QCI (QoS Class Identifier) added to the signal in LTE QoS (Quality of Service) control for the determination in step S108. QCI defines communication quality required by a signal having QCI, and takes a value of 1 to 9. Each value defines a corresponding allowable delay time, an allowable data loss rate, and the like. Therefore, the control unit 117a can identify the allowable delay time of the signal from the QCI value added to the signal from the communication terminal 103a. Note that the communication terminal 103a may transmit a signal indicating the allowable delay time, not the QCI, to the base station 101a.

  If the quality required by the signal is satisfied even if the delay time is increased (Yes in step S108), the control unit 117a can simulate the transmission timing by delaying the transmission timing or temporarily storing the transmission signal in the buffer. Thus, a delay time is generated and the delay time is increased (step S109). Then, the control unit 117a reassigns a downlink time slot corresponding to the increased delay time (step S107).

  For example, it is assumed that the delay time of the signal from the communication terminal 103a is 130 [ms] and the allowable delay time of the signal is 300 [ms]. In this case, the control unit 117a can increase the delay time up to 300 [ms] (Yes in step S108).

  In this embodiment, since the downlink time slot 121a-4 is vacant, the control unit 117a increases the delay time to 150 [ms], for example (step S109). Then, as shown in FIG. 7, the control unit 117a can reassign the downlink time slot 121a-4 to the communication terminal 103a (step S107).

  In step S108, when the delay time cannot be increased (No in step S108), the control unit 117a changes the association between the downlink time slot and the delay time range set in the process of step S101 (step S110). That is, the control unit 117a changes the delay time range corresponding to the downlink time slot 121a-2 assigned to the communicating communication terminal 103a so as to include the calculated delay time.

  For example, when the delay time of the signal from the communication terminal 103a is 130 [ms], the control unit 117a sets the delay time range corresponding to the downlink time slot 121a-2 to 50 [ms] or more as shown in FIG. The range is changed from a range of less than 100 [ms] to a range of 100 [ms] or more and less than 150 [ms].

  Then, the control unit 117a controls the communication unit 111a to transmit the changed association between the downlink time slot and the delay time range to the adjacent base station 101b (step S111).

  Then, the communication unit 111b of the adjacent base station 101b receives the changed association (Yes in Step S205), and sends the changed association to the control unit 117b. Based on the changed association of the base station 101a, the control unit 117b changes the association between the downlink time slot and the delay time range in the adjacent base station 101b (step S206). That is, the control unit 117b changes the delay time range of the downlink time slot 121b-2 to the same range of 100 [ms] to less than 150 [ms] as the delay time range corresponding to the downlink time slot 121a-2.

  Here, the adjacent base station 101b assigns the downlink time slot 121b-2 to the communication terminal 103c with a delay time of 80 [ms] by the process of step S204. As the association is changed, the delay time of the communication terminal 103c is not included in the delay time range corresponding to the downlink time slot 121b-2. Therefore, the adjacent base station 101b reassigns downlink time slots (step S207).

  For example, when the delay time related to the communication terminal 103c can be increased, the control unit 117b increases the delay time related to the communication terminal 103c to the delay time included in the changed delay time range of the downlink time slot 121b-2. In this case, the downlink time slot assigned to the communication terminal 103c is not changed by the reassignment of the downlink time slot.

  When the delay time related to the communication terminal 103c cannot be increased, the control unit 117b changes the delay time range corresponding to another available downlink time slot. For example, in this embodiment, since the downlink time slot 121b-4 is vacant, the delay time range of the downlink time slot 121b-4 is set to be 50 [ms] or more from a range of 150 [ms] or more and less than 200 [ms]. Change to a range of less than 100 [ms]. Thereby, the control part 117b allocates the downlink time slot 121b-4 to the communication terminal 103c as shown in FIG.

  When the association is further changed in the adjacent base station 101b, the adjacent base station 101b transmits the changed association between the downlink time slot and the delay time range to the base station 101a, and the base station 101a As shown in FIG. 9, the delay time range corresponding to the free downlink time slot 121a-4 is changed to a range of 50 [ms] or more and less than 100 [ms].

  As described above, in this embodiment, the base station 101a and the adjacent base station 101b determine the downlink time slot assigned to the communication terminal 103 according to the delay time of the signal from the communication terminal 103, and determine the downlink time slot and the delay time. The correspondence with the range is made the same between the base stations. As a result, the communication terminals 103a and 103c having a short delay time are allocated to the downlink time slots 121a-1 and 121b-1 having the same time position between the adjacent base stations. Therefore, even when the base stations 101a and 101b advance the transmission timing in consideration of the delay time, the transmission timing shift time interval does not differ extremely between the base stations 101a and 101b. Therefore, it is difficult for the downlink time slot 121a-2 of the base station 101a to overlap the downlink time slot 121b-1 of the adjacent base station 101b that is temporally before the downlink time slot. Similarly, the downlink time slot 121b-2 of the adjacent base station 101b is unlikely to overlap the downlink time slot 121a-1 of the base station 101a that is temporally prior to the downlink time slot. As a result, it is possible to reduce the possibility of interference occurring due to overlapping of downlink time slots having different time positions in adjacent base stations.

  Further, in the present embodiment, the base station 101a and the adjacent base station 101b are connected to each other for communication, and the base station 101a transmits the correspondence between the downlink time slot and the delay time range in the own station to the adjacent base station 101b. The adjacent base station 101b can determine the association between the downlink time slot and the delay time range in the own station based on the association of the received base station 101a. When the base station 101a and the adjacent base station 101b exchange information related to the correspondence between the downlink time slot and the delay time range by communication, it is possible to change and determine the same correspondence in real time.

  In the present embodiment, when the delay time of the signal from the communication terminal 103a communicating with the base station 101a in the downlink time slot 121a-2 is outside the delay time range associated with the downlink time slot 121a-2. The base station 101a can reassign the downlink time slot corresponding to the delay time outside the delay time range to the communication terminal 103a. Thereby, even when the delay time of the communication terminal 103a is out of the delay time range, the base station 101a can continue the communication of the communication terminal 103a without destroying the correspondence between adjacent base stations. Can do.

  Further, in the present embodiment, the base station 101a determines whether or not the delay time of the signal can be increased based on the allowable delay time of the signal of the communication terminal 103a whose delay time is outside the delay time range, and the delay If the time can be increased, the downlink time slot 121a-4 corresponding to the increased delay time can be reassigned to the communication terminal 103a. As a result, even when the downlink time slot corresponding to the delay time exceeding the delay time range is not empty, the base station 101a can connect the communication terminals 103a without destroying the correspondence between adjacent base stations. Communication can be continued.

  Further, in this embodiment, the base station 101a changes the delay time range corresponding to the downlink time slot 121a-2 assigned to the communication terminal 103a whose delay time is outside the delay time range, so that the downlink time slot and the delay are changed. The changed association with the time range is transmitted to the adjacent base station 101b, and the adjacent base station 101b changes the association between the downlink time slot and the delay time range in the own station based on the changed association. be able to. Thereby, even when the base station 101a changes the association between the downlink time slot and the delay time range, the adjacent base station 101b changes the association of the own station to reflect the change of the base station 101a. it can. Therefore, the correspondence identity between adjacent base stations is maintained.

  Further, in the present embodiment, the adjacent base station 101b reassigns the downlink time slot to the communication terminal 103c that is in communication from before the change according to the change of the association between the downlink time slot of the own station and the delay time range. Can do. Thereby, the adjacent base station 101b can continue the communication of the communication terminal 103c even when the association of the own station is changed.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various modifications and corrections based on the present disclosure. Therefore, it should be noted that these variations and modifications are included in the scope of the present invention.

  For example, functions included in each member, each means, each step, etc. can be rearranged so as not to be logically contradictory, and a plurality of means, steps, etc. can be combined or divided into one. Is possible.

  In the above-described embodiment of the present invention, in order to make the correspondence between the downlink time slot and the delay time range in the adjacent base stations the same, the adjacent base stations are connected to each other and exchange association information. However, the present invention is not limited to this embodiment. For example, base stations adjacent to each other can store the same association between the downlink time slot and the delay time range, and can fix the association. The base stations adjacent to each other assign the downlink time slot to the communication terminal based on the stored association, thereby maintaining the identity of the association between the adjacent base stations. In this case, since the association is fixed and does not change, adjacent base stations do not need to perform communication connection for transmitting the association change.

  Further, in the above-described embodiment of the present invention, it has been described on the premise that there is a downlink time slot corresponding to the calculated delay time in the processing of step S103 and step S104, but the present invention is limited to this mode. It is not something. For example, when there is no downlink time slot corresponding to the delay time calculated in the process of step S103, the base station 101a can move to the process of step S110.

  Further, in the description of the embodiment of the present invention described above, the meaning of the technical idea such as “more than” or “less than” that defines the range of the delay time is not necessarily a strict meaning. Depending on the case, the meaning when the reference value is included or not included is included. For example, “more than 50 ms” can be implied not only when the delay time reaches 50 ms but also when it exceeds 50 ms. Further, for example, “less than 100 ms” may imply not only when the delay time is less than 100 ms, but also when it reaches 100 ms, that is, when it is 100 ms or less.

DESCRIPTION OF SYMBOLS 100 Communication system 101a Base station 101b Adjacent base station 103a-103d Communication terminal 111 Communication part 113 Baseband part 117 Control part 121a-1 to 121a-4 Downlink time slot 121b-1 to 121b-4 of base station 101a Adjacent base station 101b Downtime time slot

Claims (6)

In a communication system including a base station that determines a time slot assigned to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the range of the delay time .
The base station
When the delay time of the signal from the communication terminal communicating with the base station in a certain time slot is outside the range of the delay time associated with the time slot, the allowable delay time of the signal of the communication terminal If the delay time can be increased based on the communication terminal, a time slot corresponding to the increased delay time is reassigned to the communication terminal . The communication system according to claim 1,
The base station
When the delay time cannot be increased based on the allowable delay time of the signal of the communication terminal, the range of the delay time corresponding to the time slot is changed so as to include the delay time. system. The communication system according to claim 1 or 2,
Further comprising an adjacent base station adjacent to the base station;
The correspondence between the time slot and the delay time range is the same between the respective base stations,
The base station
When the delay time range corresponding to the time slot is changed, the changed association between the time slot and the delay time range is transmitted to the adjacent base station,
The adjacent base station is
The communication system , wherein the association between the time slot and the delay time range in the own station is changed based on the changed association . 4. The communication system according to claim 3 , wherein the adjacent base station reassigns a time slot to a communication terminal in communication from before the change according to the change of the association of the own station. In a base station including a control unit that determines a time slot assigned to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the delay time range .
The control unit, when a delay time of a signal from a communication terminal communicating with the base station in a certain time slot is out of a delay time range associated with the time slot, the signal of the communication terminal If the delay time can be increased based on the permissible delay time, a time slot corresponding to the increased delay time is reassigned to the communication terminal . In a control method of a base station comprising a control unit that determines a time slot allocated to a communication terminal according to a delay time of a signal from the communication terminal and associates the time slot with the range of the delay time.
When the delay time of the signal from the communication terminal communicating with the base station in a certain time slot is outside the range of the delay time associated with the time slot, the allowable delay time of the signal of the communication terminal If the delay time can be increased based on, the step of increasing the delay time;
Control method for a base station, including the step of reassigning the time slot corresponding to the increased delay time to the communication terminal <br/>.

Images