JP2017184221A - Management device, terminal device, management method, resource selection method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique which executes efficient resource selection in consideration of easiness to establish communication.SOLUTION: An acquisition unit 40 acquires a parameter which is a parameter for each of a plurality of base station devices using a resource to communicate with a terminal device and which enables a resource shortage of each base station device to be forecasted. According to the parameter acquired by the acquisition unit 40, a generation unit 32 generates information on resource priority desired to be used in a terminal device which is connected to one of the plurality of base station devices. A transmitter unit 38 transmits the information generated in the generation unit 32.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a selection technique, and more particularly, to a management device, a terminal device, a management method, a resource selection method, and a program that execute a process for selecting a radio channel resource.

  A mobile station in a wireless communication system performs an operation called channel scan. For example, the mobile station moves to another location from a state where it is communicating with a base station operated on a predetermined channel, and enters the area of the base station operated on another channel. In this case, the mobile station searches for a base station by searching for a base station channel by attempting to receive a signal while changing the channel. Under such circumstances, it takes time if the number of channels to be scanned is large. In order to cope with this, the mobile station calculates the distance between the mobile station and the base station, and determines the order of scanning the channel of the base station according to the distance (see, for example, Patent Document 1).

JP2013- 211803 A

  When the mobile station determines the scan order based on the distance to the base station, it takes into account the case where the base station's channel shortage occurs when the number of mobile stations using the base station increases. Absent. In addition, the mobile station must store the location information and channel information of the base station in advance. Under such circumstances, when the location of the base station changes or the channel operated by the base station changes, the information stored in the mobile station needs to be updated. In other words, the probability that communication between the mobile station and the base station is established dynamically changes depending on the situation, but until now, an efficient channel scan that fully considers the ease of establishment of communication has been performed. Not.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a technique for executing efficient resource selection in consideration of ease of establishment of communication.

  In order to solve the above problems, a management device according to an aspect of the present invention is a parameter for each of a plurality of base station devices that use resources for communication with a terminal device, and the resource shortage of each base station device is reduced. An acquisition unit that acquires a predictable parameter, and generates information related to the priority of a resource that is to be used by a terminal device connected to one of a plurality of base station devices, according to the parameter acquired by the acquisition unit A generation unit; and a transmission unit that transmits information generated by the generation unit.

  Another aspect of the present invention is a terminal device. This apparatus is a terminal apparatus that communicates with one base station apparatus using a resource among a plurality of base station apparatuses, and is a parameter for each of the plurality of base station apparatuses. A receiving unit that receives information from a management device that generates information about the priority of a resource to be used by the terminal device according to a parameter that can predict a resource shortage, and a receiving unit; And a selection unit that selects a resource based on the information received at.

  Yet another embodiment of the present invention is a management method. In this method, a parameter for each of a plurality of base station devices that use resources for communication with a terminal device and a parameter that can predict a shortage of resources of each base station device is obtained. In response, the method includes a step of generating information on the priority of a resource to be used by a terminal device connected to one of a plurality of base station devices, and a step of transmitting the generated information.

  Yet another aspect of the present invention is a resource selection method. This method is a method for selecting a resource in a terminal apparatus that communicates with one base station apparatus among a plurality of base station apparatuses, and is a parameter for each of the plurality of base station apparatuses, and A step of receiving information from a management device that generates information about the priority of a resource to be used by the terminal device according to a parameter that can predict resource shortage of each base station device via one base station device And selecting a resource based on the received information.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  According to the present invention, it is possible to execute efficient resource selection in consideration of ease of establishment of communication.

It is a figure which shows the structure of the communication system which concerns on Example 1 of this invention. It is a figure which shows the structure of the management apparatus of FIG. 3A to 3C are diagrams showing the data structure of the database stored in the storage unit of FIG. 4A to 4C are diagrams showing the format of signals transmitted and received in the communication system of FIG. It is a figure which shows the structure of the terminal device of FIG. 6A to 6D are diagrams showing the data structure of the scan channel list stored in the control unit of FIG. It is a sequence diagram which shows the update procedure of the scan channel list | wrist in the communication system of FIG. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 2 of this invention. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 3 of this invention. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 4 of this invention. It is a figure which shows the structure of the management apparatus which concerns on Example 5 of this invention. It is a sequence diagram which shows the update procedure of the scan channel list | wrist in the communication system which concerns on Example 6 of this invention. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 6 of this invention. It is a figure which shows the structure of the area defined in the management apparatus which concerns on Example 6 of this invention. FIGS. 15A and 15B are diagrams illustrating a format of signals transmitted and received in the communication system according to the sixth embodiment of the present invention. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 7 of this invention. FIGS. 17A to 17C are diagrams illustrating a format of signals transmitted and received in the communication system according to the seventh embodiment of the present invention. It is a figure which shows the data structure of the database memorize | stored in the memory | storage part which concerns on Example 8 of this invention.

Example 1
Before describing the present invention specifically, an outline will be given first. Embodiment 1 of the present invention relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of them to execute wireless communication. Resources are used for communication between the base station apparatus and the terminal apparatus in the communication system. An example of a resource is a channel. The channel is a communication path for forming communication between the base station apparatus and the terminal apparatus, and is specified by the center frequency, time, and code. In this embodiment, the channel is specified by the center frequency. A plurality of channels are defined in the communication system, and the center frequencies of the channels are different from each other.

  Each base station apparatus is operated on one of the channels, and performs communication with the terminal apparatus while using the channel. The terminal device measures the status of each channel, regardless of which channel is used to connect to the base station device. This measurement process is also called a channel scan, and the presence of a base station apparatus operated in each channel is searched by the channel scan. The channel scan result is used, for example, to select a base station apparatus to which the terminal apparatus should be connected. Note that “scan” corresponds to “selection” when channels are collectively referred to as resources. Here, in order to execute an efficient channel scan considering the ease of establishment of communication, the present embodiment executes the following processing.

  A management apparatus is connected to the base station apparatus via a network. The management device stores a database in which the relationship between the base station device and the channel is indicated. The management apparatus generates information on the priority of the channel that the terminal apparatus wants to use when executing the channel scan (hereinafter referred to as “channel instruction command”), and transmits the information from the base station apparatus. At that time, the management apparatus generates a channel instruction command according to the number of terminal apparatuses whose location is registered in each of the plurality of base station apparatuses. The terminal device performs a channel scan according to the channel instruction command.

  FIG. 1 shows a configuration of the communication system 100. The communication system 100 includes a first terminal device 10a, a second terminal device 10b, a third terminal device 10c, and a first base station device 12a and a second base station device, which are collectively referred to as a terminal device 10. 12b, a third base station device 12c, a network 14, and a management device 16. Here, the number of terminal apparatuses 10 and the number of base station apparatuses 12 are both “3”, but are not limited thereto.

  As illustrated, an area in which communication with the first base station apparatus 12a, that is, an area in which a signal from the first base station apparatus 12a can be received is indicated as a first communicable area 20a. Further, the second communicable area 20b and the third communicable area 20c are similarly shown for the second base station apparatus 12b and the third base station apparatus 12c. Here, the first communicable area 20a, the second communicable area 20b, and the third communicable area 20c are collectively referred to as a communicable area 20.

  The terminal device 10 corresponds to a wireless communication system and is connected to the base station device 12. An example of the wireless communication system is a commercial wireless system, a mobile phone system, and the like. However, since these are well-known techniques, description thereof is omitted here. When the terminal device 10 enters the communicable area 20 and receives a signal in the channel of the base station device 12 that forms the communicable area 20, the terminal device 10 requests the base station device 12 to register a location (Registration). Execute.

  Each of the plurality of base station devices 12 corresponds to the same radio communication system as the terminal device 10 on one end side, and the terminal device 10 can be connected thereto. Moreover, each base station apparatus 12 connects the network 14 in the other end side. Here, each base station apparatus 12 is operated by one of a plurality of channels defined in the communication system 100. For example, different channels are set in two or more base station apparatuses 12 arranged close to each other. When receiving the location registration request from the terminal device 10, the base station device 12 transmits a use permission to the terminal device 10 and holds the number of location registrations (the number of location-registered terminal devices 10). The base station apparatus 12 transmits the number of location registrations to the management apparatus 16 via the network 14. As a result of such processing, as shown in the figure, the first terminal device 10a and the first base station device 12a are connected, and the channel set in the first base station device 12a is the first terminal device 10a and the first base station. Used with the device 12a.

  The base station device 12 is connected to the management device 16 via the network 14. The network 14 transmits and receives data between various devices. The network 14 may be any network, for example, a wired network, a wireless network, or a combination thereof. With such a configuration, the terminal device 10 can communicate with a communication device (not shown) via the base station device 12 and the network 14. The communication device (not shown) may be a device directly connected to the network 14 or may be another terminal device 10 connected to any one of the base station devices 12. The communication is a telephone call or data communication.

  The management device 16 communicates with the terminal device 10 via the network 14 and the base station device 12. The management device 16 may be included in any of the base station devices 12. The management device 16 holds the number of terminal devices 10 connected to each base station device 12 by receiving the number of location registrations from the base station device 12 via the network 14. The number of location registrations to be held changes as the terminal device 10 using each base station device 12 moves. In addition, the management device 16 holds an allowable value of the number of registered positions of each base station device 12 and holds information on adjacent base station devices 12 and channel information for each base station device 12.

  The management device 16 does not exceed the allowable value of the number of position registrations among the other base station devices 12 adjacent to the base station device 12 with respect to the base station device 12 that has exceeded the allowable value of the number of position registrations. And the channel of the other base station apparatus 12 with the smallest number of location registrations is selected. In addition, the management device 16 causes the base station device 12 to transmit a channel instruction command for changing the channel of the terminal device 10 to the selected channel. The terminal apparatus 10 that has received the channel instruction command executes a channel scan in accordance with the channel instruction command.

  FIG. 2 shows the configuration of the management device 16. The management device 16 includes a communication unit 30, a generation unit 32, and a storage unit 34. The communication unit 30 includes a reception unit 36 and a transmission unit 38, and the generation unit 32 includes an acquisition unit 40. The communication unit 30 is connected to the base station apparatus 12 via the network 14. The receiving unit 36 receives the number of location registrations from each base station device 12. The receiving unit 36 stores the number of position registrations in the storage unit 34.

  The memory | storage part 34 memorize | stores the database shown to Fig.3 (a)-(c). 3A to 3C show the data structure of the database stored in the storage unit 34. FIG. FIG. 3A is a database showing the number of location registrations and allowable values for each base station apparatus 12. The number of location registrations is written by the receiving unit 36. On the other hand, the allowable value may be input in advance. FIG. 3B is a database in which base station apparatuses 12 adjacent to each base station apparatus 12 are shown. For example, the second base station apparatus 12b and the third base station apparatus 12c are adjacent to the first base station apparatus 12a. FIG. 3C is a database in which channels in each base station apparatus 12 are shown. For example, channel A is used in the first base station apparatus 12a. Returning to FIG.

  The acquisition unit 40 acquires the number of position registrations of each base station apparatus 12, that is, the number of terminal apparatuses 10 registered in each base station apparatus 12, from the database shown in FIG. The number of location registrations is a parameter that can predict the channel shortage of the base station device 12 for each of the plurality of base station devices 12. As shown in FIG. 3 (a), since the number of registered positions “140” of the first base station apparatus 12a exceeds the allowable value “100”, the generation unit 32 runs out of channels in the first base station apparatus 12a. Recognize that there is a high probability that Further, the generation unit 32 determines, based on the database shown in FIG. 3B, the second base station apparatus 12b (position registration number “50”), which is the base station apparatus 12 adjacent to the first base station apparatus 12a, The second base station apparatus 12b having the smallest number of position registrations is selected from the three base station apparatuses 12c (position registration number “70”). Further, the generation unit 32 selects the channel B of the selected second base station apparatus 12b from the database shown in FIG. Following this, the generation unit 32 generates a channel instruction command including the selected channel.

  4A to 4C show the format of signals transmitted and received in the communication system 100. FIG. As shown in these, the signal is configured in the order of “command”, “parameter 1”, and “parameter 2”. “Command” includes information indicating the type of signal, and “Parameter 1” and “Parameter 2” include values corresponding to the respective commands. FIG. 4A shows the format of the channel instruction command. “Command” includes “priority channel designation”, and “parameter 1” includes “priority”. Here, the priority is set to “1”, that is, “high”. “Parameter 2” includes “Channel B”. As shown in FIG. 4A, when only one channel is specified, “parameter 1 (priority)” may be omitted. In that case, the designated channel is interpreted as having a high priority.

  FIG. 4B shows another format of the channel instruction command. This is a case where the third base station apparatus 12c can also be used as the base station apparatus 12 adjacent to the first base station apparatus 12a in the above-described example, and this is also added. In FIG. 4B, “parameter 3” and “parameter 4” are added as compared to FIG. 4A. “Parameter 3” includes “priority”. Here, the priority is set to “2”, that is, “medium”. “Parameter 4” includes “Channel C”.

  FIG. 4C shows another format of the channel instruction command. This is because, in the above-described example, when the terminal device 10 connected to the first base station device 12a is located in an area where the terminal device 10 cannot be connected to the second base station device 12b and the third base station device 12c, This is for continuously using the station apparatus 12a. For this purpose, the channel of the first base station apparatus 12a is added. In FIG. 4C, “parameter 5” and “parameter 6” are added as compared to FIG. 4B. “Parameter 5” includes “priority”. Here, the priority is set to “3”, that is, “low”. “Parameter 6” includes “Channel A”. Returning to FIG.

  As described above, the generation unit 32 prioritizes the channel to be used by the terminal device 10 connected to one of the plurality of base station devices 12 according to the number of location registrations that are parameters acquired by the acquisition unit 40. Generate information about degrees. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of location registrations is greater than the allowable value.

  The transmission unit 38 transmits the channel instruction command generated by the generation unit 32 to the base station apparatus 12. In the above example, the channel instruction command is transmitted to the first base station apparatus 12a. The first base station apparatus 12a transmits a channel instruction command. As a result, the terminal apparatus 10 connected to the first base station apparatus 12a receives the channel instruction command.

  When the management device 16 detects a failure in the first base station device 12a, the channel instruction command shown in FIG. 4B is transmitted from the second base station device 12b and the third base station device 12c. Also good. By performing such processing, scanning of the terminal apparatus 10 with respect to the channel of the first base station apparatus 12a in which a failure has occurred is avoided, so that channel scanning efficiency is improved. Further, when the number of position registrations of the second base station apparatus 12b or the third base station apparatus 12c also exceeds the allowable value, or when the number of position registrations of all the base station apparatuses 12 exceeds the allowable value, FIG. Are transmitted from each base station apparatus 12. Even after the base station apparatus 12 used by each terminal apparatus 10 is changed, the base station apparatus 12 can be used continuously, so that the communication of the terminal apparatus 10 is not hindered.

  In the description so far, the base station apparatus 12 having a smaller number of location registrations has a higher priority, but another method may be used. For example, the generation unit 32 increases the priority as the base station apparatus 12 has a smaller value obtained by subtracting the allowable value from the number of position registrations, that is, a difference value between the number of position registrations and the allowable value (position registration number−allowable value). May be. If the number of registered positions is smaller than the allowable value, the difference value is a negative value. In addition, the generation unit 32 may increase the priority of the base station device 12 as a value obtained by dividing the number of position registrations by the allowable value, that is, the ratio of the number of position registrations to the allowable value (position registration number / allowable value) is small. Good. For example, the number of position registrations of the first base station apparatus 12a is “140”, the number of position registrations of the second base station apparatus 12b is “50”, and the number of position registrations of the third base station apparatus 12c is “70”. Assume that the allowable values are “100”, “60”, and “100”. The ratio of the number of location registrations to the allowable value is “1.4”, “0.83”, and “0.7”, respectively, and the priority of the channel of the third base station apparatus 12c is “1”, which is the highest, The priority of the second base station apparatus 12b is “2”, and the priority of the first base station apparatus 12a is “3”.

  The configuration of the management device 16 shown in FIG. 2 can be realized in hardware by a CPU, memory, or other LSI of an arbitrary computer, and is realized in software by a program loaded in the memory. Here, functional blocks realized by the cooperation are depicted. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms by hardware only, software only, or a combination thereof.

  FIG. 5 shows the configuration of the terminal device 10. The terminal device 10 includes a positioning unit 50, a selection unit 52, a microphone 54, a speaker 56, a processing unit 58, a control unit 60, and a communication unit 62. The communication unit 62 includes a reception unit 64 and a transmission unit 66. As described above, the terminal apparatus 10 communicates with one base station apparatus 12 among the plurality of base station apparatuses 12 using a channel.

  The positioning unit 50 has a GPS (Global Positioning System) positioning function, and measures the position of the terminal device 10. Position information that is a result of positioning is indicated by latitude and longitude. The positioning unit 50 outputs position information to the control unit 60. The control unit 60 causes the communication unit 62 to transmit a location registration request to the base station device 12. At that time, the control unit 60 may include the position information input from the positioning unit 50 in the position registration request.

  The microphone 54 receives the voice from the user and outputs the voice to the processing unit 58 as an electric signal (hereinafter referred to as “voice signal”). The speaker 56 inputs an electrical signal indicating sound (hereinafter also referred to as “sound signal”) from the processing unit 58 and outputs the sound. For this reason, the microphone 54 and the speaker 56 correspond to an interface when the user talks. In addition, although a button for receiving an operation from the user may be included as an interface with the user, description thereof is omitted here.

  The processing unit 58 inputs the audio signal from the microphone 54 and outputs the audio signal to the speaker 56. The processing unit 58 performs audio signal processing on the audio signal. Since a known technique may be used for the audio signal processing, the description is omitted here. The processing unit 58 performs wireless communication for a call together with the control unit 60 and the communication unit 62. Therefore, the communication unit 62 transmits or receives a signal to the base station apparatus 12 (not shown).

  The receiving unit 64 receives a channel instruction command from the management device 16 via the network 14 and the base station device 12 (not shown). As described above, the channel instruction command is generated in the management device 16 and can be said to be information on the priority of the channel desired to be used by the terminal device 10. This is a parameter for each of the plurality of base station apparatuses 12 and is generated according to a parameter that can predict a shortage of channels of each base station apparatus 12. The receiving unit 64 outputs a channel instruction command to the control unit 60.

  The control unit 60 inputs a channel instruction command from the receiving unit 64. In addition, the control unit 60 stores a list (hereinafter referred to as “scan channel list”) indicating the priority of the channels that cause the selection unit 52 to perform scanning, and scans according to the input channel instruction command. Update the channel list. 6A to 6D show the data structure of the scan channel list stored in the control unit 60. FIG. FIG. 6A shows a scan channel list when the terminal apparatus 10 is connected to the first base station apparatus 12a. Here, only “channel A”, which is the channel of the first base station apparatus 12a, is shown.

  FIG. 6B shows a scan channel list updated in accordance with the channel instruction command shown in FIG. “Channel A” in FIG. 6A is updated to “Channel B”. Note that “channel A” may be retained as a priority (medium) without deleting the originally stored “channel A” but with a lower priority than the newly designated “channel B”. . FIG. 6C shows a scan channel list updated in response to the channel instruction command shown in FIG. “Channel C” of “priority (medium)” is added to FIG. 6B. FIG. 6D shows a scan channel list updated in response to the channel instruction command shown in FIG. “Channel A” of “priority (low)” is added to FIG. Returning to FIG.

  The selection unit 52 executes channel scan processing based on the scan channel list stored in the control unit 60. Specifically, the selection unit 52 preferentially sets a channel with a higher priority in the scan channel list. When the selection unit 52 receives a signal from the base station device 12, for example, the second base station device 12 b, on the set channel, the selection unit 52 selects the channel at that time and reports it to the control unit 60. When receiving the report, the control unit 60 transmits a location registration request to the second base station device 12b. Thereafter, the terminal device 10 performs communication with the second base station device 12b while using the channel of the second base station device 12b. As a result, among the plurality of terminal devices 10 using the first base station device 12a, the terminal device 10 that has succeeded in scanning uses the second base station device 12b instead of the first base station device 12a. connect. Therefore, the possibility that the first base station apparatus 12a will run out of channels is reduced.

  When the terminal device 10 receives the channel instruction command shown in FIGS. 4B to 4C, the terminal device 10 measures the reception state together with the execution of the channel scan, and selects the most from the updated scan channel list. A channel with good reception may be selected. Alternatively, the terminal device 10 may scan in order from the highest priority and select the first channel in which the reception state is equal to or higher than a predetermined threshold value. By such processing, the reception state of the terminal apparatus 10 that has used the first base station apparatus 12a is improved, and the call quality is also improved. The terminal device 10 determines whether or not a resource with a high priority can really be used based on information on the priority of the resource (channel instruction command), and performs an operation of selecting a resource to be used according to the determination result. Do. When a resource with a high priority cannot be actually used, the same process is repeated for a resource with a lower priority than that to select a resource to be used.

  The operation of the communication system 100 configured as above will be described. FIG. 7 is a sequence diagram showing a procedure for updating the scan channel list in the communication system 100. The first terminal apparatus 10a transmits a location registration request to the first base station apparatus 12a (S10), and the first base station apparatus 12a transmits Ack to the first terminal apparatus 10a (S12). The first base station device 12a adds the number of location registrations to the management device 16 (S14). In the management apparatus 16, the number of location registrations in the first base station apparatus 12a becomes larger than the allowable value (S16).

  The management device 16 transmits a channel instruction command to the first base station device 12a (S18), and the first base station device 12a transmits Ack to the management device 16 (S20). The first base station apparatus 12a transmits a channel instruction command to the first terminal apparatus 10a (S22). The first terminal apparatus 10a updates the scan channel list (S24). The first terminal apparatus 10a transmits Ack to the first base station apparatus 12a (S26).

  According to the present embodiment, since information on the priority of the channel desired to be used by the terminal device is generated based on the parameter that can predict the channel shortage of each base station device, the priority of the channel that is easy to establish communication. Can be high. In addition, since the terminal device is notified of information about the priority of the channel desired to be used by the terminal device, it is possible to perform efficient channel scanning considering the ease of establishment of communication. In addition, since efficient channel scanning is performed in consideration of ease of establishment of communication, the time required for channel scanning can be shortened. In addition, since parameters that can predict the channel shortage of each base station apparatus are acquired as appropriate, it is possible to generate information related to the priority level of the channel that the terminal apparatus wants to use according to environmental changes.

  In addition, since the number of location registrations in each base station apparatus is used to generate information on the channel priority, the processing can be simplified. In addition, since information on the channel priority is generated for the base station apparatus whose number of location registrations is larger than the allowable value, the base station apparatus that is likely to cause a channel shortage is different from another base station. Can be moved to the device. In addition, since information regarding the priority of the channel is generated according to the difference between the number of registered locations and the allowable value, the degree of freedom in configuration can be improved. In addition, since the information on the channel priority is generated according to the ratio of the number of location registrations to the allowable value, the degree of freedom in configuration can be improved.

  Further, when the terminal device receives information on the priority of the channel, the terminal device scans the channel based on the information, so that it is possible to perform efficient channel scanning considering the ease of establishment of communication. In addition, since channel scanning is performed in consideration of actual communication conditions and the like, communication can be easily established. Further, since it is sufficient to set only the management device side, the operation of collecting the terminal device and rewriting the data can be made unnecessary. Also, it can be operated according to the actual situation. In addition, the environment and data can be maintained without affecting the communication protocol of the terminal device and the communication system.

(Example 2)
Next, Example 2 will be described. As in the first embodiment, the second embodiment also relates to a communication system in which a plurality of base station devices are installed and a terminal device is connected to one of them to execute wireless communication. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. In the first embodiment, a channel instruction command is generated according to the number of location registrations. On the other hand, in the second embodiment, a channel instruction command is generated according to the number of location registrations per channel of the base station device. The communication system 100, the management device 16, and the terminal device 10 according to the second embodiment are the same types as those in FIGS. Here, it demonstrates centering on the difference with Example 1. FIG.

  The storage unit 34 in FIG. 2 stores the database shown in FIG. FIG. 8 shows the data structure of the database stored in the storage unit 34. The number of location registrations is written by the receiving unit 36. In addition, the number of channels and the allowable value of the base station device 12 may be input in advance. Therefore, the number of location registrations per channel is derived by dividing the number of location registrations by the number of channels of the base station apparatus 12. Returning to FIG.

  The acquisition unit 40 acquires the number of position registrations per channel in each base station apparatus 12 from the database shown in FIG. The number of location registrations per channel is also a parameter that can predict the channel shortage of the base station device 12 for each of the plurality of base station devices 12. As shown in FIG. 8, since the number of position registrations per channel with respect to the second base station apparatus 12b exceeds the allowable value, the generation unit 32 causes a shortage of channels in the second base station apparatus 12b. Recognize that the likelihood is high. Therefore, the generation unit 32 causes the second base station apparatus 12b to transmit the channel instruction command to the terminal apparatus 10 by generating a channel instruction command, as in the first embodiment.

  In that case, the production | generation part 32 selects the 1st base station apparatus 12a with the fewest number of position registrations per channel in the base station apparatuses 12 adjacent to the 2nd base station apparatus 12b. Moreover, the production | generation part 32 makes the priority of the channel of the 1st base station apparatus 12a the highest. Thereby, the terminal device 10 connected to the second base station device 12b scans the channel of the first base station device 12a with priority. As a result, the load on the second base station apparatus 12b is reduced. Note that the number of location registrations per channel calculated for the entire communication system 100 may be used as an allowable value. Thereby, the degree of load in each base station apparatus 12 becomes nearly uniform.

  As described above, the generation unit 32 generates information on the channel priority according to the number of position registrations per channel acquired by the acquisition unit 40. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of position registrations per channel acquired by the acquisition unit 40 is greater than the allowable value.

  Up to now, the base station apparatus 12 having a smaller number of location registrations per channel has a higher priority, but another method may be used. For example, the generation unit 32 increases the priority as the base station device 12 has a smaller value obtained by subtracting an allowable value from the number of position registrations per channel, that is, a difference value between the number of position registrations per channel and the allowable value. May be. Further, the generation unit 32 may increase the priority of the base station apparatus 12 as a value obtained by dividing the number of position registrations per channel by the allowable value, that is, the ratio of the number of position registrations per channel to the allowable value is small. Good.

  According to the present embodiment, since the information on the channel priority is generated using the number of position registrations per channel in each base station apparatus, the prediction accuracy of channel shortage can be improved. In addition, since information on the channel priority is generated for the base station apparatus in which the number of location registrations per channel is greater than the allowable value, the base station apparatus is likely to cause a channel shortage. Movement to another base station apparatus can be enabled. In addition, since the information on the channel priority is generated according to the difference between the number of registered locations per channel and the allowable value, the degree of freedom in configuration can be improved. In addition, since the information on the channel priority is generated according to the ratio of the number of position registrations per channel to the allowable value, the degree of freedom of configuration can be improved.

(Example 3)
Next, Example 3 will be described. The third embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. In the first embodiment, a channel instruction command is generated according to the number of location registrations. On the other hand, in the third embodiment, a channel instruction command is generated according to the number of group registrations on the premise of a group call by a terminal device. The communication system 100, the management device 16, and the terminal device 10 according to the third embodiment are the same types as those in FIGS. Here, it demonstrates centering on the difference from before.

  In FIG. 1, when the communication system 100 corresponds to a business wireless system, a group call that is one-to-many communication in the terminal device 10 is widely used. When the terminal device 10 receives a signal from the base station device 12 by the channel scan process, the terminal device 10 transmits a location registration request to the base station device 12 and transmits a group registration request. When receiving the location registration request and the group registration request, the base station device 12 transmits a use permission including a group call to the terminal device 10 and holds the number of location registrations and the number of group registrations. The base station device 12 transmits the number of location registrations and the number of group registrations to the management device 16 via the network 14.

  A feature of the group call is that one channel is used by the terminal devices 10 in the same group in one base station device 12. Therefore, if there is only one group registration using the base station device 12, only one channel is used. In addition, when the number of group registrations in the base station apparatus 12 is equal to or less than the number of channels of the base station apparatus 12, even if the number of location registrations of the terminal apparatuses 10 included in each group increases, The load should not be so high. On the other hand, when the number of group registrations in the base station device 12 is larger than the number of channels in the base station device 12, there is a possibility that a shortage of channels may occur as the number of location registrations of the terminal devices 10 included in each group increases. Get higher. Furthermore, if the number of group registrations in the base station apparatus 12 increases, the possibility of a shortage of channels in the base station apparatus 12 increases. Therefore, the management device 16 holds the number of group registrations and uses this to generate information regarding the priority of the channel.

  The storage unit 34 in FIG. 2 stores the database shown in FIG. FIG. 9 shows the data structure of the database stored in the storage unit 34. The number of group registrations is written by the receiving unit 36. Further, the allowable value may be input in advance. Returning to FIG. The acquisition unit 40 acquires the number of group registrations from the database shown in FIG. The number of group registrations is also a parameter that can predict the channel shortage of the base station apparatus 12 for each of the plurality of base station apparatuses 12.

  As shown in FIG. 9, since the number of group registrations of the first base station apparatus 12a exceeds the allowable value, the generation unit 32 is highly likely to cause a channel shortage in the first base station apparatus 12a. Recognize that Therefore, the generation unit 32 causes the first base station apparatus 12a to transmit the channel instruction command to the terminal apparatus 10 by generating the channel instruction command as before.

  In that case, the production | generation part 32 selects the 2nd base station apparatus 12b with the fewest number of group registrations among the base station apparatuses 12 adjacent to the 1st base station apparatus 12a. Moreover, the production | generation part 32 makes the priority of the channel of the 2nd base station apparatus 12b the highest. Thereby, the terminal device 10 connected to the first base station device 12a scans the channel of the second base station device 12b with priority. As a result, the load on the first base station apparatus 12a is reduced. The allowable values shown in FIG. 9 may be arbitrarily determined and input by the system administrator, or may be automatically changed according to the number of group registrations that change.

  As described above, the generation unit 32 generates information on the channel priority according to the number of group registrations acquired by the acquisition unit 40. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of group registrations acquired by the acquisition unit 40 is greater than the allowable value.

  Up to now, the base station apparatus 12 having a smaller number of group registrations has a higher priority, but another method may be used. For example, the generation unit 32 may increase the priority as the base station apparatus 12 has a smaller value obtained by subtracting an allowable value from the number of group registrations, that is, a difference value between the number of group registrations and the allowable value. In addition, the generation unit 32 may increase the priority of the base station apparatus 12 that is a value obtained by dividing the number of group registrations by the allowable value, that is, the ratio of the number of group registrations to the allowable value is small.

  According to the present embodiment, information on the channel priority is generated using the number of group registrations in each base station apparatus, so that it is possible to improve the prediction accuracy of the channel shortage in the group call. That is, it is possible to improve the accuracy of prediction regarding the ease of establishment of communication. In addition, since information on the channel priority is generated for the base station apparatus whose group registration number is larger than the allowable value, the base station apparatus that is likely to cause a channel shortage is different from another base station. Can be moved to the device. In addition, since the information on the channel priority is generated according to the difference between the number of group registrations and the allowable value, the degree of freedom of configuration can be improved. In addition, since the information on the channel priority is generated according to the ratio of the number of registered groups to the allowable value, the degree of freedom in configuration can be improved.

Example 4
Next, Example 4 will be described. The fourth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. In the third embodiment, a channel instruction command is generated according to the number of group registrations. On the other hand, in the fourth embodiment, a channel instruction command is generated according to the number of group registrations per channel of the base station device. The communication system 100, the management device 16, and the terminal device 10 according to the third embodiment are the same types as those in FIGS. Here, it demonstrates centering on the difference from before.

  The storage unit 34 in FIG. 2 stores the database shown in FIG. FIG. 10 shows the data structure of the database stored in the storage unit 34. The number of group registrations is written by the receiving unit 36. In addition, the number of channels and the allowable value of the base station device 12 may be input in advance. Here, the allowable value is “7” for the communication system 100 as a whole. The number of group registrations per channel is derived by dividing the number of group registrations by the number of channels of the base station apparatus 12. Returning to FIG.

  The acquisition unit 40 acquires the number of group registrations per channel in each base station apparatus 12 from the database shown in FIG. The number of group registrations per channel is also a parameter that allows the channel shortage of the base station apparatus 12 to be predicted for each of the plurality of base station apparatuses 12. As shown in FIG. 10, since the number of group registrations per channel for the second base station apparatus 12b exceeds the allowable value, the generation unit 32 causes a channel shortage in the second base station apparatus 12b. Recognize that the likelihood is high. Therefore, the generation unit 32 causes the second base station apparatus 12b to transmit the channel instruction command to the terminal apparatus 10 by generating a channel instruction command as before.

  In that case, the production | generation part 32 selects the 1st base station apparatus 12a with the fewest number of group registrations per channel in the base station apparatuses 12 adjacent to the 2nd base station apparatus 12b. Moreover, the production | generation part 32 makes the priority of the channel of the 1st base station apparatus 12a the highest. Thereby, the terminal device 10 connected to the second base station device 12b scans the channel of the first base station device 12a with priority. As a result, the load on the second base station apparatus 12b is reduced. Note that the number of group registrations per channel calculated for the entire communication system 100 may be used as an allowable value. Thereby, the degree of load in each base station apparatus 12 becomes nearly uniform.

  Furthermore, when the number of group registrations per channel of each terminal device 10 or the entire communication system 100 shown in FIG. 10 is equal to “1”, the number of group registrations and the number of usable channels are equal. Therefore, the base station apparatus 12 or the communication system 100 does not cause channel shortage. When the number of group registrations per channel of the entire communication system 100 is “1” or less, the allowable value of each base station apparatus 12 is set to “1”, or is automatically changed to “1”. May be. As a result, the base station apparatus 12 whose number of group registrations per channel exceeds the allowable value receives the channel instruction command from the management apparatus 16, so that the communication system 100 as a whole does not have a shortage of channels. Operate.

  As described above, the generation unit 32 generates information on the channel priority according to the number of group registrations per channel acquired by the acquisition unit 40. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of group registrations per channel acquired by the acquisition unit 40 is greater than the allowable value.

  So far, the base station apparatus 12 having a smaller number of group registrations per channel has a higher priority, but another method may be used. For example, the generation unit 32 increases the priority as the base station device 12 has a smaller value obtained by subtracting the allowable value from the number of group registrations per channel, that is, the difference value between the number of group registrations per channel and the allowable value. May be. Further, the generation unit 32 may increase the priority of the base station device 12 as a value obtained by dividing the number of group registrations per channel by the allowable value, that is, the ratio of the number of group registrations per channel to the allowable value is small. Good.

  According to the present embodiment, since the information on the channel priority is generated using the number of group registrations per channel in each base station apparatus, the prediction accuracy of the channel shortage in the group call can be further improved. In addition, since information on the channel priority is generated for the base station apparatus in which the number of group registrations per channel is larger than the allowable value, the base station apparatus is likely to cause a channel shortage. Movement to another base station apparatus can be enabled. In addition, since the information on the channel priority is generated according to the difference between the number of group registrations per channel and the allowable value, the degree of freedom in configuration can be improved. In addition, since the information on the channel priority is generated according to the ratio of the number of registered groups per channel to the allowable value, the degree of freedom in configuration can be improved.

(Example 5)
Next, Example 5 will be described. The fifth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. Until now, channel instruction commands are generated according to the number of location registrations, the number of group registrations, and the like. On the other hand, in the fifth embodiment, an index indicating the degree of congestion of the base station device is calculated, and a channel instruction command is generated according to the index. The communication system 100 and the terminal device 10 according to the fifth embodiment are the same type as those in FIGS. Here, it demonstrates centering on the difference from before.

FIG. 11 shows the configuration of the management device 16 according to the fifth embodiment of the present invention. In the management device 16, the index calculation unit 42 is further included in the generation unit 32 in the configuration of FIG. 2. The acquisition unit 40 acquires the number of position registrations of the base station apparatus 12, the number of group registrations of the base station apparatus 12, and the number of channels of the base station apparatus 12 from the respective databases shown in FIGS. The index calculation unit 42 derives an index indicating the degree of congestion for each base station apparatus 12 based on the acquired data. The index calculation unit 42 calculates an index Z [i] indicating the congestion degree of the i-th base station apparatus 12i according to the formula (1) or the formula (2).

  In Equation (1), N [i] is the number of location registrations in the i-th base station device 12i, G [i] is the number of group registrations in the i-th base station device 12i, and C [i] is the i-th base station. This is the number of channels of the station device 12i. Α1 and α2 are constants equal to or greater than “0”, and at least one is greater than “0”. γ1 and γ2 are constants larger than zero. Equation (1) can be said to be a weighted average of the number of position registrations per channel and the number of group registrations per channel using α1 and α2 as weighting factors. The greater the number of location registrations per channel and the greater the number of group registrations per channel, the greater the congestion degree Z [i]. In the case of a group call, basically, the greater the number of group registrations, the higher the possibility of channel shortage. However, when comparing the base station devices 12 having the same number of group registrations, the greater the number of location registrations, It can be said that the possibility of channel shortage increases. Therefore, by calculating the degree of congestion Z [i], channel shortage can be predicted with high accuracy. Further, by adjusting γ1 and γ2, it is possible to adjust the influence exerted on the degree of congestion by the two elements of the number of location registrations and the number of group registrations. Further, it is possible to set γ1 = γ2 = 1 and not to perform the power operation.

  In Expression (2), μ1 and μ2 are constants of “0” or more, and at least one of them is larger than “0”. Further, by adjusting μ 1 and μ 2, it is possible to adjust the influence exerted on the degree of congestion by the two elements of the number of registered positions and the number of registered groups. Further, it is possible to set μ1 = μ2 = 1 and not to perform the power operation.

  If the value of the congestion degree Z [i] is large, for example, when the terminal device 10 makes a call, there is a possibility that communication between the terminal device 10 and the base station device 12 may not be established due to a lack of an empty channel. high. On the other hand, it can be said that the possibility of establishment of communication between the terminal device 10 and the base station device 12 is higher as the base station device 12 has a smaller value of the degree of congestion Z [i]. For this reason, the smaller the degree of congestion Z [i], the higher the channel scan priority for the channel of the i-th base station apparatus 12i may be set. Therefore, the generation unit 32 generates information on the channel priority according to the index calculated by the index calculation unit 42. In the present embodiment, the index calculation unit 42 calculates the index, but other methods may be used. For example, each base station apparatus 12 or another apparatus may calculate an index indicating the degree of congestion of each base station apparatus 12, and the acquisition unit 40 may acquire the index. In that case, the index calculation unit 42 of the management device 16 can be omitted.

  According to the present embodiment, since the index indicating the degree of congestion of each base station device is generated, the channel shortage prediction accuracy can be further improved. That is, it is possible to further improve the prediction accuracy regarding the ease of establishment of communication. In addition, since information on the channel priority is generated according to the index indicating the degree of congestion of each base station apparatus, it is possible to provide a communication system in which channels of the entire system can be used effectively and communication is easily established.

(Example 6)
Next, Example 6 will be described. The sixth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. In the fifth embodiment, an index indicating the degree of congestion of the base station apparatus is calculated, and a channel instruction command is generated according to the index. In the sixth embodiment, a channel instruction command is generated using data related to the reception power of the terminal device 10. The communication system 100, the management device 16, and the terminal device 10 according to the sixth embodiment are the same types as those in FIGS. Here, it demonstrates centering on the difference from before.

  Since the processing sequences of the terminal device 10, the base station device 12, and the management device 16 in the sixth embodiment are different from those in the past, here, the operation will be described before the configuration. FIG. 12 is a sequence diagram showing a procedure for updating the scan channel list in the communication system 100. The management device 16 transmits an area acquisition request to the first base station device 12a (S50), and the first base station device 12a transmits an area acquisition request to the first terminal device 10a (S52). The area is an area defined so as to be smaller than the communicable area 20 so far, and details will be described later.

  The first terminal apparatus 10a transmits position information to the first base station apparatus 12a (S54), and the first base station apparatus 12a transmits area information update to the management apparatus 16 (S56). The management device 16 transmits an area information storage request to the first base station device 12a in order to cause the first terminal device 10a to store information related to the area where the first terminal device 10a exists (S58). The device 12a transmits an area information storage request to the first terminal device 10a (S60). The first terminal device 10a stores the area information (S62).

  The management device 16 transmits a channel instruction command to the first base station device 12a (S64), and the first base station device 12a transmits Ack to the management device 16 (S66). The first base station apparatus 12a transmits a channel instruction command to the first terminal apparatus 10a (S68). The first terminal apparatus 10a determines the area (S70), and updates the scan channel list (S72). The first terminal apparatus 10a transmits Ack to the first base station apparatus 12a (S74).

  In such an operation, when transmitting the position information, the terminal apparatus 10 transmits the received channel and the reception state (field strength, received power, etc.) to the base station apparatus 12 together. The base station apparatus 12 or the management apparatus 16 stores the position information, channel, and reception state from the terminal apparatus 10 in a database. FIG. 13 shows the data structure of the database stored in the storage unit 34. As shown in the figure, the position information, channel, and reception state are stored in association with the date / time and the area code. Instead of creating a database based on information received from the terminal device 10, the database may be created by measuring in advance. Further, the database may be created by estimating the electric field strength or received power at each point not by actual measurement but by simulation such as ray tracing in consideration of the distance from the base station apparatus 12 and topography.

  The area code shown in FIG. 13 is a code for identifying the aforementioned area. FIG. 14 shows a configuration of areas defined in the management device 16. An area such as “area A-1” is defined in the first communicable area 20a to the third communicable area 20c. That is, it can be said that the area is an area obtained by subdividing the communicable area 20. Here, “A-1” in “Area A-1” corresponds to an area code.

  In FIG. 12, the first terminal apparatus 10 a transmits position information to the first base station apparatus 12 a, and the first base station apparatus 12 a transmits position information and area information (area code) to the management apparatus 16. The index calculation unit 42 of the management device 16 refers to the database shown in FIG. 13, selects a row whose area code matches the received area code, and averages the received power for each channel for those data. Calculate the value. Furthermore, the generation unit 32 sets channel priorities in descending order of the average received power. That is, the priority of the channel with the highest average received power is “1”, and the priority of the second largest channel is “2”.

  Here, such processing will be described in more detail with reference to FIG. In FIG. 14, the terminal device 10 is located in the area C-1, and can use three base station devices 12. In addition, the database shown in FIG. 13 stores three pieces of data regarding the area C-1. In this case, since there is only one data for each of channels A, B, and C, the average value of the received power is the value itself included in the database, and channel A is “−115” and channel B is “−120” and channel C becomes “−100”. The generation unit 32 selects the channel C having the maximum received power as the first priority channel, and generates a channel instruction command storing this. Alternatively, channel A with the next highest received power may be selected as the second priority channel, and a channel instruction command storing the first priority channel and the second priority channel may be generated. FIGS. 15A and 15B show the format of signals transmitted and received in the communication system 100. FIG. 15 (a)-(b) are shown corresponding to FIGS. 4 (a)-(b).

In the following, a method for determining channel priority using received power and the degree of congestion in the fifth embodiment will be described. For example, when the terminal device 10 is located in the area C-1, the index calculating unit 42 is the congestion degree Z [i] of the first base station device 12a to the third base station device 12c corresponding to the channels A, B, and C. (I = 1 to 3) is calculated by the method described in the fifth embodiment. Next, as in the above description, the index calculation unit 42 calculates an average value of received power for each channel. In the present embodiment, for simplicity of explanation, one channel corresponds to one base station apparatus 12, and the average received power of the channel of the i-th base station apparatus 12i is P [i]. The value of P [i] is always negative, and the smaller the absolute value is, the higher the received power is. The index calculation unit 42 calculates an index S [i] related to the i-th base station apparatus 12i (channel i) according to Expression (3) or Expression (4) using the congestion degree and the received power.

  That is, the index calculated by the index calculation unit 42 is an index that reflects the received power in the terminal device 10. Here, in Expression (3), β1 and β2 are constants of “0” or more, and at least one is larger than “0”. λ1 and λ2 are constants larger than “0”. According to Expression (3), the smaller the degree of congestion and the larger the received power, the smaller the index S [i]. In the formula (4), θ1 and θ2 are constants of “0” or more, and at least one of them is larger than “0”. According to Expression (4), the index S [i] becomes a smaller value as the congestion degree is smaller and the received power is larger. Also, the channel priority is increased in ascending order of the index S [i]. That is, the priority of the channel with the smallest index S [i] is “1”, and the priority of the second smallest channel is “2”. In the present embodiment, the index calculation unit 42 calculates the index, but other methods may be used. For example, each base station device or another device may calculate an index indicating the degree of congestion of each base station device, and the acquisition unit 40 may acquire the index. In that case, the index calculation unit 42 of the management device 16 can be omitted.

  According to the present embodiment, since the received power in the terminal device is also reflected in the index, the prediction accuracy regarding the ease of establishment of communication can be further improved. In addition, since information on the channel priority is generated according to the index reflecting the received power, it is possible to provide a communication system in which channels of the entire system can be used effectively and communication is easily established.

(Example 7)
Next, Example 7 will be described. The seventh embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. The seventh embodiment corresponds to a modification of the first embodiment. In the first embodiment, a channel instruction command is generated according to the number of location registrations. On the other hand, in the seventh embodiment, a channel instruction command is generated according to the busy number.

  The problem of the seventh embodiment is shown as follows. In channel allocation by distance, it is not possible to consider a case where a shortage of channels of the base station apparatus occurs due to an increase in the number of terminal apparatuses using the base station apparatus. On the other hand, when the terminal device has the information, it is necessary to update the data of the terminal device when the arrangement of the base station device or the like changes. In other words, the probability of establishment of communication between the terminal device and the base station apparatus dynamically changes depending on the situation at the time, but conventionally, an efficient channel scan that fully considers the ease of establishment of communication is performed. Not. In addition, when there is a lot of calls in a base station device and many channels of the base station device are used, if there is a call request from another terminal device, the call channel Is not assigned (hereinafter referred to as “busy”). In such a case, there is a case in which the terminal device can use an adjacent base station device, but an efficient channel scan that fully considers the ease of establishment of communication is not performed, and thus a call cannot be made. Fall into. In the seventh embodiment, the difference from the first embodiment will be mainly described.

  A communication system 100 according to the seventh embodiment is illustrated as in FIG. When receiving the location registration request from the terminal device 10, the base station device 12 transmits a use permission to the terminal device 10. Thereby, for example, the first terminal apparatus 10a and the first base station apparatus 12a are connected, and the channel set in the first base station apparatus 12a is used for the first terminal apparatus 10a and the first base station apparatus 12a. The On the other hand, even if the base station device 12 receives a call request from the terminal device 10, if the channel used by the terminal device 10 for the call is insufficient, the base station device 12 transmits a use disapproval to the terminal device 10. At that time, the base station apparatus 12 counts a shortage of channels as a busy occurrence. The number of busy occurrences (hereinafter referred to as “the number of busy occurrences”) may be held by the management device 16.

  In response to the base station apparatus 12 that has exceeded the allowable number of busy occurrences per unit time, the management apparatus 16 generates a busy occurrence per unit time among other base station apparatuses 12 adjacent to the base station apparatus 12. A channel of another base station apparatus 12 that does not exceed the allowable value of the number and has the smallest number of busy occurrences per unit time is selected. In addition, the management device 16 causes the base station device 12 to transmit a channel instruction command for changing the channel of the terminal device 10 to the selected channel. The terminal apparatus 10 that has received the channel instruction command executes a channel scan in accordance with the channel instruction command.

  The management apparatus 16 according to the seventh embodiment is shown in the same manner as in FIG. The receiving unit 36 receives the number of busy occurrences from each base station device 12. The receiving unit 36 stores the busy occurrence number in the storage unit 34. The storage unit 34 stores a database shown in FIG. 16 instead of FIG. The storage unit 34 also stores a database shown in FIGS. FIG. 16 shows a data structure of a database stored in the storage unit 34 according to the seventh embodiment of the present invention. FIG. 16 is a database showing the number of busy occurrences per unit time (for example, one hour) and allowable values for each base station apparatus 12. The number of busy occurrences per unit time varies with the number of channels of each base station device 12 and the frequency of communication of the terminal device 10 that uses each base station device 12. The number of busy occurrences per unit time is written by the receiving unit 36. On the other hand, the allowable value corresponds to an upper limit threshold for occurrence of busy per unit time. Returning to FIG.

  The acquisition unit 40 acquires the number of busy occurrences of each base station apparatus 12 from the database shown in FIG. As illustrated in FIG. 16, since the number of busy occurrences “10” of the first base station apparatus 12 a exceeds the allowable value “5”, the generation unit 32 recognizes a channel shortage in the first base station apparatus 12 a. . Further, the generation unit 32 determines, based on the database shown in FIG. 3B, the second base station device 12b (busy occurrence number “2”), which is the base station device 12 adjacent to the first base station device 12a, Among the three base station apparatuses 12c (the number of busy occurrences “5”), the second base station apparatus 12b having the smallest number of busy occurrences is selected. Further, the generation unit 32 selects the channel B of the selected second base station apparatus 12b from the database shown in FIG. Following this, the generation unit 32 generates a channel instruction command including the selected channel.

  As described above, the generation unit 32 prioritizes the channel to be used by the terminal device 10 connected to one of the plurality of base station devices 12 according to the number of busy occurrences that is the parameter acquired by the acquisition unit 40. Generate information about degrees. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of location registrations is greater than the allowable value. Here, the number of busy occurrences is also called a busy number, and corresponds to the number of times communication has not been established in each base station apparatus 12.

  In the description so far, the base station apparatus 12 having the smaller number of busy occurrences has a higher priority, but another method may be used. For example, the generation unit 32 increases the priority as the base station apparatus 12 has a smaller difference value (busy occurrence number−allowable value) between the busy occurrence number and the allowable value, that is, the difference between the busy occurrence number and the allowable value. May be. If the number of busy occurrences is smaller than the allowable value, the difference value becomes a negative value. Further, the generation unit 32 may increase the priority of the base station device 12 as a value obtained by dividing the number of busy occurrences by the allowable value, that is, the ratio of the number of busy occurrences to the allowable value (busy occurrence number / allowable value). Good. For example, the number of busy occurrences of the first base station apparatus 12a is 10, the number of busy occurrences of the second base station apparatus 12b is 5, and the number of busy occurrences of the third base station apparatus 12c is 7, and each allowable value is 5 3 and 6, the ratios of the number of busy occurrences to the allowable value of the number of busy occurrences are “2”, “1.67”, and “1.17”, respectively. As a result, the channel priority of the third base station apparatus 12c is the highest at “1”, the priority of the second base station apparatus 12b is “2”, and the priority of the first base station apparatus 12a is “3”. Become.

  Further, when the number of busy occurrences exceeds the allowable value not only in the first base station apparatus 12a but also in the second base station apparatus 12b or the third base station apparatus 12c, most of the base station apparatuses 12 or all of The channel shortage has occurred in the base station apparatus 12. Even when all the base station devices 12 exceed the allowable value, a shortage of channels has occurred in most of the base station devices 12 or all of the base station devices 12. An instruction command corresponding to the channel instruction command as shown in FIG. 4C indicates the priority channel of each base station apparatus 12 selected by the difference value between the number of busy occurrences and the allowable value or the ratio of the number of busy occurrences to the allowable value. May be notified.

  In the above description, the channel instruction command in the format for specifying the priority for each channel is used. However, other types of channel instruction commands may be used. For example, a channel instruction command for designating a relative change in priority based on a scan channel list set in the terminal device 10 may be used. FIGS. 17A to 17C show formats of signals transmitted and received in the communication system 100 according to the seventh embodiment of the present invention.

  For example, in the state where the scan channel list set in the terminal apparatus 10 is “first priority = channel B, second priority = channel C, third priority = channel A”, the command shown in FIG. Assume a case of reception. In this case, the order of the third priority channel A is increased by one in the direction of higher priority, and “first priority = channel B, second priority = channel A, third priority = channel C” is set. When two channels (second priority = channel A, channel C) are arranged in the same order, the channel (channel A) specified by the channel instruction command is adopted, and the order of other channels is lowered.

  In the above state, when the command shown in FIG. 17B is received, the channel of the first priority channel B is lowered by one in the direction of lower priority, and the channel designated as the second priority of the movement destination C is incremented by 1 and “first priority = channel C, second priority = channel B, third priority = channel A” is set. When the command shown in FIG. 17C is received in the above state, the rank of the first priority channel B is lowered by two, the rank of the third priority channel A is raised by two, and “first priority = Channel A, second priority = channel C, third priority = channel B ”. That is, a channel instruction command for instructing a relative change with respect to a channel scan priority set in the terminal device 10 is used.

  According to the present embodiment, the information on the channel priority is generated using the number of busy occurrences in each base station apparatus, so the accuracy of the information on the channel priority can be improved. In addition, since the number of busy occurrences in each base station apparatus is used to generate information on channel priority, the processing can be simplified. In addition, since information on the channel priority is generated for the base station apparatus in which the number of busy occurrences is larger than the allowable value, the base station apparatus that is likely to cause a channel shortage is different from another base station. Can be moved to the device. In addition, since information on the channel priority is generated according to the difference between the number of busy occurrences and the allowable value, the degree of freedom in configuration can be improved. Further, since the information on the channel priority is generated according to the ratio of the number of busy occurrences to the allowable value, the degree of freedom in configuration can be improved. Further, since the channel instruction command for instructing a relative change with respect to the channel scan priority set in the terminal device is used, the degree of freedom in configuration can be improved.

(Example 8)
Next, Example 8 will be described. The eighth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. The eighth embodiment corresponds to a modification of the second embodiment. In the second embodiment, a channel instruction command is generated according to the number of location registrations per channel of the base station device. On the other hand, in the eighth embodiment, a channel instruction command is generated according to the average number of busy occurrences per channel per unit time. In the eighth embodiment, the difference from the second embodiment will be mainly described.

  The storage unit 34 in FIG. 2 stores the database shown in FIG. FIG. 18 shows a data structure of a database stored in the storage unit 34 according to the eighth embodiment of the present invention. The number of busy occurrences per unit time is written by the receiving unit 36. In addition, the number of channels and the allowable value of the base station device 12 may be input in advance. The average number of busy occurrences per channel is derived by dividing the number of busy occurrences per unit time by the number of channels of the base station apparatus 12. Note that the allowable value that is the busy occurrence upper limit threshold per unit time may be arbitrarily determined and input by the system administrator, or may be automatically changed according to the changing number of busy occurrences. Returning to FIG.

  The acquisition unit 40 acquires the average number of busy occurrences per channel in each base station apparatus 12 from the database shown in FIG. As shown in FIG. 18, since the average number of busy occurrences per channel with respect to the second base station apparatus 12b exceeds the allowable value, the generation unit 32 generates a channel shortage in the second base station apparatus 12b. Recognize that there is a high possibility that Therefore, the generation unit 32 causes the second base station apparatus 12b to transmit the channel instruction command to the terminal apparatus 10 by generating a channel instruction command.

  In that case, the production | generation part 32 selects the 1st base station apparatus 12a with the fewest number of average busy generation per channel in the base station apparatuses 12 adjacent to the 2nd base station apparatus 12b. Moreover, the production | generation part 32 makes the priority of the channel of the 1st base station apparatus 12a the highest. Thereby, the terminal device 10 connected to the second base station device 12b scans the channel of the first base station device 12a with priority. As a result, the load on the second base station apparatus 12b is reduced. Note that the average number of busy occurrences per channel calculated for the entire communication system 100 may be used as an allowable value. Thereby, the degree of load in each base station apparatus 12 becomes nearly uniform.

  As described above, the generation unit 32 generates information on the channel priority according to the number of busy occurrences per channel acquired by the acquisition unit 40. In particular, the generation unit 32 generates information on the channel priority for the base station apparatus 12 in which the number of busy occurrences per channel acquired by the acquisition unit 40 is greater than the allowable value.

  Up to now, the base station apparatus 12 having a lower average number of busy occurrences per channel has a higher priority, but another method may be used. For example, the generation unit 32 sets the priority to a value obtained by subtracting the allowable value from the average number of busy occurrences per channel, that is, the base station apparatus 12 having a smaller difference value between the average busy occurrence number per channel and the allowable value. May be high. In addition, the generation unit 32 increases the priority as the base station apparatus 12 has a value obtained by dividing the average busy occurrence number per channel by the allowable value, that is, the ratio of the average busy occurrence number per channel to the allowable value is smaller. May be.

  According to the present embodiment, since the information on the channel priority is generated using the average number of busy occurrences per channel in each base station apparatus, the prediction accuracy of the channel shortage can be improved. In addition, since information on the channel priority is generated for the base station apparatus in which the average number of busy occurrences per channel is greater than the allowable value, the base station apparatus is likely to cause a channel shortage. It is possible to move from one to another base station apparatus. In addition, since the information on the channel priority is generated according to the difference between the average number of busy occurrences per channel and the allowable value, the degree of freedom in configuration can be improved. In addition, since information on the channel priority is generated according to the ratio of the average number of busy occurrences per channel to the allowable value, the degree of freedom in configuration can be improved.

Example 9
Next, Example 9 will be described. The ninth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of the base station apparatuses to perform wireless communication as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. The ninth embodiment corresponds to a modification of the fifth embodiment. In the fifth embodiment, an index indicating the degree of congestion of the base station apparatus is calculated using the number of position registrations, and a channel instruction command is generated according to the index. On the other hand, in the ninth embodiment, an index indicating the degree of congestion of the base station apparatus is calculated using the number of busy occurrences, and a channel instruction command is generated according to the index. In the ninth embodiment, the difference from the fifth embodiment will be mainly described.

The management apparatus 16 according to the ninth embodiment is illustrated in the same manner as in FIG. The acquisition unit 40 acquires the number of busy occurrences of the base station apparatus 12, the number of registered positions of the base station apparatus 12, and the number of channels of the base station apparatus 12 from the respective databases shown in FIGS. The index calculation unit 42 derives an index indicating the degree of congestion for each base station apparatus 12 based on the acquired data. The index calculation unit 42 calculates an index Z [i] indicating the degree of congestion of the i-th base station device 12i according to Expression (5) or Expression (6).

  In Expression (5), B [i] is the number of busy occurrences per unit time in the i-th base station apparatus 12i, and D [i] is the number of terminal apparatuses 10 registered in the i-th base station apparatus 12i. , C [i] is the number of channels of the i-th base station apparatus 12i. Equation (5) can be said to be a weighted average of the number of busy occurrences per channel and the number of location registrations per channel using α1 and α2 as weighting factors. As the number of busy occurrences per channel increases and the number of location registrations per channel increases, the degree of congestion Z [i] increases. Further, by adjusting γ1 and γ2, it is possible to adjust the influence exerted on the degree of congestion by the two factors of the number of busy occurrences and the number of location registrations. Expression (6) is shown in the same manner as Expression (5).

  Further, in the equations (5) and (6), instead of the number D [i] of the terminal devices 10 registered in the i-th base station device 12i, the number of groups G [ i] may be used. In this case, the greater the number of busy occurrences per channel and the greater the number of groups per channel, the greater the degree of congestion Z [i]. In a wireless system with many group calls, the number of groups G [i] should be used. Alternatively, the degree of congestion may be calculated using three factors: the number of busy occurrences per channel, the number of location registrations per channel, and the number of groups per channel. Similar to Equation (5), a weighted addition value of three elements may be calculated. Further, similarly to Expression (6), a multiplication value of three elements may be calculated.

  Further, the priority of the channel may be determined in consideration of the electric field strength at the position of the terminal device 10 or the received power of the terminal device 10. For example, as the electric field strength at the position of the candidate terminal apparatus 10 to which the base station apparatus 12 is moved increases, an index that becomes a larger value is calculated for each base station apparatus 12, and the higher the index, the higher the channel priority. To do. For example, it is assumed that the first terminal device 10a and the second terminal device 10b registered in the first base station device 12a are moved to the second base station device 12b or the third base station device 12c. For the sake of clarity, the first terminal device 10a is referred to as a terminal device A and the second terminal device 10b is referred to as a terminal device B here.

  The electric field strength of the second base station device 12b at the position of the terminal device A is E (2, A), and the electric field strength of the third base station device 12c is E (3, A). Further, the electric field strength of the second base station device 12b at the position of the terminal device B is E (2, B), and the electric field strength of the third base station device 12c is E (3, B). For each base station apparatus 12, the sum of the electric field strengths of the movement candidate terminal apparatuses 10 is calculated and used as an index. The index S [2] of the second base station apparatus 12b is S [2] = E (2, A) + E (2, B), and the index S [3] of the third base station apparatus 12c is S [ 3] = E (3, A) + E (3, B). In addition to calculating the total electric field strength (reception power) at the position of each terminal device 10, a representative value such as an average value or a median value may be calculated, and an index may be calculated using the calculated value. That is, a value obtained by collecting electric field strengths (reception power) at positions of a plurality of terminal devices 10 may be calculated, and an index may be calculated using the calculated value. In addition, a value corresponding to the minimum value or the lower X% of the electric field strength (reception power) of the terminal apparatus 10 that is a movement candidate may be calculated for each base station apparatus 12, and the index may be calculated using the value.

  Here, the value corresponding to the lower X% is the electric field strength of the terminal device 10 corresponding to the lower X% rank when the terminal devices 10 are arranged in descending order of the electric field strength. When using the minimum value, assuming that E (2, A) <E (2, B), S [2] = E (2, A). If E (3, A)> E (3, B), then S [3] = E (3, B). If S [2]> S [3], the channel scan priority of the second base station apparatus 12b is set higher than that of the third base station apparatus 12c. The electric field strength (reception power) data at each position may be received by sequentially receiving position information and reception power information from the terminal device 10. Or you may accumulate | store the information received from measuring devices, such as the terminal device 10, in the past, create the database which shows the electric field strength of each point, and use it. Further, the database indicating the radio wave condition at each point may be created by estimating the electric field strength or the received power at each point by a simulation that considers the distance from the base station apparatus 12 and the topography, instead of actual measurement.

  Also, an index that considers both the degree of congestion and the electric field strength may be calculated, and the channel priority may be determined accordingly. For example, the smaller the congestion degree Z [i] and the higher the electric field strength at the position of the terminal device 10 that is the movement candidate, the larger the index S [i] that is the movement destination candidate that moves the terminal device 10. Calculation is performed for each base station apparatus 12. Furthermore, the higher the index S [i], the higher the channel priority.

  According to the present embodiment, since the index indicating the degree of congestion of each base station apparatus is generated using the number of busy occurrences, the channel shortage prediction accuracy can be further improved. That is, it is possible to further improve the prediction accuracy regarding the ease of establishment of communication. In addition, since information on the channel priority is generated according to the index indicating the degree of congestion of each base station apparatus, it is possible to provide a communication system in which channels of the entire system can be used effectively and communication is easily established.

(Example 10)
Next, Example 10 will be described. The tenth embodiment also relates to a communication system in which a plurality of base station apparatuses are installed and a terminal apparatus is connected to one of them to execute wireless communication, as in the past. Further, the management device generates a channel instruction command and transmits it to the terminal device via the base station device. The tenth embodiment corresponds to a modification of the sixth embodiment. In the sixth embodiment, a channel instruction command is generated using an index indicating the degree of congestion using the number of location registrations and received power. On the other hand, in the tenth embodiment, a channel instruction command is generated using an index indicating the degree of congestion using the number of occurrences of busy and the received power. In the tenth embodiment, the difference from the sixth embodiment will be mainly described.

  Similar to the sixth embodiment, the index calculation unit 42 uses the congestion degree and the received power, and the index S [i] related to the i-th base station apparatus 12i (channel i) according to Expression (3) or Expression (4). Is calculated. Here, the number of busy occurrences is reflected on the degree of congestion as in the ninth embodiment.

  According to the present embodiment, since information on the channel priority is generated according to the index reflecting the received power, it is possible to provide a communication system that can effectively use the channels of the entire system and can easily establish communication.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to the combination of each component and each processing process, and such modifications are also within the scope of the present invention. .

  In the first to tenth embodiments, a channel is used as a resource. However, the present invention is not limited to this, and for example, the resource may be hardware or software for configuring and operating a computer system. According to this modification, the degree of freedom of configuration can be improved.

  10 terminal devices, 12 base station devices, 14 networks, 16 management devices, 30 communication units, 32 generation units, 34 storage units, 36 reception units, 38 transmission units, 40 acquisition units, 42 index calculation units, 50 positioning units, 52 Selection unit, 54 microphone, 56 speaker, 58 processing unit, 60 control unit, 62 communication unit, 64 reception unit, 66 transmission unit, 100 communication system.

Claims (26)

An acquisition unit that acquires parameters for each of a plurality of base station devices that use resources for communication with a terminal device, and that can predict a shortage of resources of each base station device;
According to the parameter acquired in the acquisition unit, a generation unit that generates information related to the priority of a resource to be used by a terminal device connected to one of the plurality of base station devices;
A transmission unit for transmitting the information generated in the generation unit;
A management apparatus comprising: The parameter acquired in the acquisition unit is the number of terminal devices registered in each base station device,
The management device according to claim 1, wherein the generation unit generates information related to resource priorities according to the number of terminal devices acquired by the acquisition unit.   The said generation part produces | generates the information regarding the priority of a resource with respect to the base station apparatus with which the number of the terminal devices acquired in the said acquisition part became larger than the allowable value. Management device.   The generation unit generates information on resource priorities according to a difference between the number of terminal devices acquired by the acquisition unit and an allowable value, or a ratio of the number of terminal devices to the allowable value. The management device according to claim 2 or 3. The parameter acquired in the acquisition unit is the number of terminal devices per resource in each base station device,
The management device according to claim 1, wherein the generation unit generates information related to resource priorities according to the number of terminal devices per resource acquired by the acquisition unit.   The said generation part produces | generates the information regarding the priority of a resource with respect to the base station apparatus in which the number of the terminal devices per resource acquired in the said acquisition part became larger than the allowable value. 5. The management device according to 5.   The generation unit is configured to provide information on resource priorities according to a difference between the number of terminal devices per resource acquired by the acquisition unit and an allowable value, or a ratio of the number of terminal devices per resource to the allowable value. The management apparatus according to claim 5, wherein the management apparatus generates the management information. The parameter acquired in the acquisition unit is the number of groups registered in each base station device, and the number of groups formed by a plurality of terminal devices,
The management apparatus according to claim 1, wherein the generation unit generates information related to resource priorities according to the number of groups acquired by the acquisition unit.   The management according to claim 8, wherein the generation unit generates information on resource priority for a base station apparatus in which the number of groups acquired by the acquisition unit is greater than an allowable value. apparatus.   The said generation part produces | generates the information regarding the priority of a resource according to the difference between the number of groups acquired in the said acquisition part, and an allowable value, or the ratio of the number of groups with respect to an allowable value. The management device according to 8 or 9. The parameter acquired in the acquisition unit is the number of groups per resource in each base station device, and the number of groups formed by a plurality of terminal devices,
The management apparatus according to claim 1, wherein the generation unit generates information related to resource priorities according to the number of groups per resource acquired by the acquisition unit.   The generation unit generates information related to resource priority for a base station apparatus in which the number of groups per resource acquired in the acquisition unit is greater than an allowable value. The management apparatus as described in.   The generation unit generates information related to resource priority according to a difference between the number of groups per resource acquired by the acquisition unit and a permissible value, or a ratio of the number of groups per resource to the permissible value. The management apparatus according to claim 11 or 12, characterized in that: The parameter acquired in the acquisition unit is a busy number related to the number of times communication has not been established in each base station device,
The management apparatus according to claim 1, wherein the generation unit generates information related to resource priority according to the number of busys acquired by the acquisition unit.   15. The management apparatus according to claim 14, wherein the generation unit generates information related to resource priority for a base station apparatus in which the number of busys acquired by the acquisition unit is greater than an allowable value. .   The said generation part produces | generates the information regarding the priority of a resource according to the difference of the busy number acquired in the said acquisition part, and an allowable value, or the ratio of the busy number with respect to an allowable value. 15. The management device according to 15. The parameter acquired in the acquisition unit is a busy number per resource of the base station device,
The management device according to claim 1, wherein the generation unit generates information related to resource priority according to the number of busys per resource of the base station device acquired by the acquisition unit.   The generation unit generates information on resource priority for a base station device in which the number of busys per resource of the base station device acquired by the acquisition unit is greater than an allowable value. The management device according to claim 17.   The generation unit generates information related to resource priorities according to a difference between a busy number per resource of the base station apparatus acquired by the acquisition unit and a permissible value, or a ratio of the busy number to the permissible value. The management apparatus according to claim 17 or 18, characterized in that: An index calculation unit that calculates an index indicating the degree of congestion of each base station device based on the parameter acquired by the acquisition unit;
The management device according to any one of claims 1 to 19, wherein the generation unit generates information related to resource priority in accordance with the index calculated by the index calculation unit.   21. The management apparatus according to claim 20, wherein the index calculated by the index calculation unit is an index reflecting reception power in a terminal device. A terminal device that communicates with one of a plurality of base station devices using resources,
A management device that generates information on the priority of a resource to be used by the terminal device according to a parameter for each of the plurality of base station devices and a parameter that can predict a resource shortage of each base station device Receiving unit for receiving information from the one base station device;
A selection unit that selects a resource based on information received by the reception unit;
A terminal device comprising: Obtaining parameters that are parameters for each of a plurality of base station devices that use resources for communication with a terminal device and that can predict resource shortage of each base station device; and
Generating information related to the priority of a resource to be used by a terminal device connected to one of the plurality of base station devices according to the acquired parameters;
Sending the generated information;
A management method comprising: A resource selection method in a terminal apparatus that communicates with a base station apparatus among a plurality of base station apparatuses using a resource,
A management device that generates information on the priority of a resource to be used by the terminal device according to a parameter for each of the plurality of base station devices and a parameter that can predict a resource shortage of each base station device Receiving information from the one base station device;
Selecting a resource based on the received information;
A resource selection method comprising: Obtaining parameters that are parameters for each of a plurality of base station devices that use resources for communication with a terminal device and that can predict resource shortage of each base station device; and
Generating information related to the priority of a resource to be used by a terminal device connected to one of the plurality of base station devices according to the acquired parameters;
Sending the generated information;
A program that causes a computer to execute. A program in a terminal device that communicates with one base station device among a plurality of base station devices using a resource,
A management device that generates information on the priority of a resource to be used by the terminal device according to a parameter for each of the plurality of base station devices and a parameter that can predict a resource shortage of each base station device Receiving information from the one base station device;
Selecting a resource based on the received information;
A program that causes a computer to execute.

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