JP2006157666A - Mobile communication terminal and network control method - Google Patents

Abstract

In a wireless communication network composed of a communication terminal as a master and a plurality of communication terminals as slaves, a plurality of masters are set and the network is maintained.
A line status measuring unit 32 of a communication terminal 30 measures a line status with another communication terminal, and aggregates information on the line status measured at each communication terminal in a master, and a master / slave determination unit. 33 determines the roles of the master and slave. If it is difficult to configure a network with one master according to the line status, and it is determined that a network can be configured by providing multiple masters and multiple networks composed of masters and slaves, the master and slaves A new network is provided, and a plurality of newly provided networks are connected to each other via terminals having the roles of master and slave.
[Selection] Figure 1

Description

  The present invention relates to a mobile communication terminal and a network control method, and more particularly to a mobile communication terminal and a network control method that constitute a wireless communication ad hoc network composed of a master and a slave.

  In recent years, instant messaging services and online games at short distances have been realized using portable wireless terminals having local communication functions. Some network-compatible home appliances establish a home network by wireless local communication. Such communication forms an ad hoc network by performing wireless communication between a plurality of terminals at a short distance, and IEEE802.11, Bluetooth (registered trademark) or the like is used as a communication means for configuring the ad hoc network. ing.

  Bluetooth (registered trademark) is a communication standard using a 2.4 GHz frequency band, and constructs a minimum unit network called a piconet when an ad hoc network is constructed by a plurality of communication terminals. In this case, as shown in FIG. 12, among the plurality of communication terminals that construct the piconet, one communication terminal that first started communication operates as a master terminal, and the remaining communication terminals serve as slave terminals. By operating, communication is performed between the plurality of communication control devices. FIG. 12 is a diagram showing a network configuration suitable for each embodiment of the present invention. The figure shows a state in which the piconet 1 is composed of wireless communication terminals 30A to 30G that comply with the specification of Bluetooth (registered trademark). In the piconet 1, the communication terminal 30G is a master serving as a communication hub, and the wireless communication terminals 30A to 30F are slaves. The communication terminal 30G that is the master of the piconet 1 relays signals from the communication terminals 30A to 30F that are slaves, and realizes communication between the communication terminals in the network.

  Since a Bluetooth (registered trademark) piconet is configured by communication between a master terminal and a slave terminal, a range of a distance that can be communicated with a slave around the master terminal is an area of the piconet. The number of slave stations that can simultaneously participate in one piconet is limited to 7 units in the current standard. However, it is possible to connect a plurality of piconets via a common node, thereby realizing a network configuration with an infinite number of devices. A form in which a plurality of piconets are connected in this way is called a scatternet.

As a method for assigning masters and slaves in an ad hoc network consisting of a master and slaves in the past, the method of selecting the first terminal that started communication as the master terminal, the remaining battery capacity of each communication terminal, the amount of communication, etc. A selection method has been proposed on the basis (see, for example, Patent Document 1 and Patent Document 2).
However, depending on the configuration of the master terminal and the slave terminal, the area that can be covered by the piconet may be narrow. For example, as shown in FIG. 13, even if a communication terminal participating in an ad hoc network is in a range where communication with other slave communication terminals is possible, the communication terminal is located away from the master terminal, When communication is not possible, there arises a problem that the ad hoc network cannot be joined. In this case, it is not possible to cover the same area as the area that can be covered by the piconet shown in FIG.

  In order to solve this, a method of changing the roles of the master and the slave can be considered. For example, in Patent Document 3, when the slave calculates the capability value as a performance parameter and transmits it to the master, the master selects as the next master candidate based on the performance parameter from each slave, and the master leaves Determines the next master based on the backup master information.

Moreover, in patent document 4, it aims at detecting the state of an unsuitable cluster head (equivalent to a master), and re-selecting a better cluster head, and in order to make it function as a temporary cluster head, The reception level (connection radio wave situation) with the temporary cluster member that is configured when becomes the cluster head is acquired, and when the radio wave situation is improved, the cluster head is replaced.
JP2002-164901 Japanese Patent No. 2924828 JP 2004-129042 A JP 2002-44003 A

However, in the above-described conventional technology, there is a problem that the network cannot be maintained even if the roles of the master and the slave are changed when the moving distance of the terminal is long.
The present invention has been made to solve the above-described problems of the prior art, and its purpose is to set a plurality of masters so that even when the moving distance of the terminal is long or the communication status of the line is deteriorated. To provide a mobile communication terminal and a network control method capable of maintaining a network.

  According to a first aspect of the present invention, there is provided a mobile communication terminal for determining a line status measuring unit for measuring a channel status with another communication terminal, and determining a master and a slave in the network based on a measurement result by the channel status measuring unit. And a master / slave determination unit that configures a network together with other communication terminals, and cannot be configured as one network due to at least one of movement of the terminal and deterioration of communication status In addition, it further includes determination means for determining whether a plurality of networks can be configured as a connected network, and when the master / slave determination means can be configured as a network in which a plurality of networks are connected according to the determination result of the determination means, A plurality of masters are determined. According to this configuration, the network can be maintained by appropriately changing the configuration of the network according to the communication status between the master and the slave, and setting a plurality of masters even when the moving distance of the terminal is long.

  The network control method according to claim 2 of the present invention is configured as a network by at least one of a line status measurement step for measuring a line status with another communication terminal, movement of the terminal, and deterioration of the communication status. A first determination step for determining whether or not the second network can be configured; and a second determination for determining whether or not the first network can be configured as a network in which a plurality of networks are connected in the first determination step. And determining the plurality of masters and slaves in the network based on the measurement result in the line status measurement step when it is determined in the second determination step that the network can be configured as a network in which a plurality of networks are connected. Including a master / slave determination step And wherein the door. In this way, the network can be maintained by appropriately changing the configuration of the network according to the communication status between the master and the slave, and setting a plurality of masters even when the moving distance of the terminal is long.

  As described above, according to the present invention, in an ad hoc network composed of a master and a slave, the network configuration is appropriately changed according to the communication status between the master and the slave. By setting a plurality, there is an effect that the network can be maintained.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings referred to in the following description, the same parts as those in the other drawings are denoted by the same reference numerals.
(Configuration of mobile communication terminal)
FIG. 1 is a block diagram showing a functional configuration of a mobile communication terminal according to an embodiment of the present invention. In the figure, a mobile communication terminal 30 according to an embodiment of the present invention is a mobile communication terminal that forms a network together with other communication terminals, and a communication unit 31 having a function of connecting to and communicating with other communication terminals, A line status measuring unit 32 for measuring a line status with another communication terminal, a master / slave determining unit 33 for determining a master and a slave in the network based on a measurement result by the line status measuring unit 32, It is configured to include a determination unit 34 that determines whether a network can be configured as a network in which a plurality of networks can be configured when the network cannot be configured as a result of movement or deterioration in communication status. The master / slave determination unit 33 determines a plurality of masters when it can be configured as a network in which a plurality of networks are connected based on the determination result of the determination unit 34.

  In a network in which a plurality of mobile communication terminals are connected, the master is replaced when a slave that is out of the communication range from the master due to movement of the terminal or the communication line is deteriorated, and further configured as one network. A description will be given of the control for configuring a network in which a plurality of networks are connected by setting a plurality of masters when it becomes impossible.

(Master change due to out-of-service slave generation)
A case will be described in which the position of each communication terminal moves as shown in FIG. 13 and communication from the communication terminal 30G as a master to the communication terminal 30B becomes impossible. In this case, processing is performed according to the processing flow of FIG.
That is, as shown in the figure, when the master detects that the communication terminal 30B is out of the communication range (step S501), the master communicates with the slave communication terminals 30A and 30C to 30F that are currently communicable. A communication status notification request is transmitted (step S502). Each communication terminal that has received this communication status notification request transmits a measurement signal to the other terminals, and the communication status is measured (step S503). Each communication terminal receives a measurement signal from another terminal, and transmits a measurement result to the master communication terminal after a predetermined time has elapsed (step S504).

The master totals the measurement results received from each communication terminal and creates a table of the total results (step S505).
FIG. 3 shows an example of the tabulation result table. In the figure, an example is shown in which received power with other terminals is expressed as an evaluation value from “0” to “10” at each terminal as a measured value of the communication state.

  As a determination criterion, it is conceivable to select a master having the highest received power value after changing the master, to increase the average value, or to apply them in combination. If the case where the reception power is the lowest is selected in the example of the figure, when the communication terminal 30C is selected as the master, it is possible to secure a communication power of “5” or more, and it is outside the communication range of the piconet. Communication with the communication terminal 30B is also possible. The communication terminal 30G, which is the current master terminal, determines the master change to the communication terminal 30C by the above-described determination method, and changes the master from the communication terminal 30G to the communication terminal 30C for each of the communication terminals 30A and 30C to 30F. Is transmitted to each slave communication terminal as a change request (step S506). Thereafter, the master is changed at each communication terminal (step S507).

  In this case, the communication terminals 30A, 30D, 30E, and 30F that serve as slaves reset the relationship between the communication terminal 30G and the master / slave and enter a standby state, and the communication terminal 30C that newly becomes the master sequentially receives the communication terminals 30A, 30B, Connect to 30D to 30G. As a result, as shown in FIG. 4, the master communication terminal is changed from communication terminal 30G to 30C, and the network configuration is changed from piconet 1 to piconet 2.

(Master change due to communication line deterioration)
A case will be described in which the position of each communication terminal moves as shown in FIG. 13 to move away from the range of the piconet 1, which is the communication area of the master, and the communication status of the communication terminal 30B is significantly deteriorated. In this case, processing is performed according to the processing flow of FIG.
That is, as shown in the figure, the communication terminal 30B that has detected that the communication status with the master has deteriorated (step S601) is reconfigured to change the master / slave assignment to the master. A request is transmitted (step S602).

Thereafter, as in the case of FIG. 2, the master transmits a communication status notification request to the slave communication terminals 30A and 30B to 30F (step S502). Furthermore, each communication terminal transmits a measurement signal to the other terminals, and the communication status is measured (step S503). Each communication terminal receives a power measurement signal from another terminal, and transmits a measurement result to the master communication terminal after a predetermined time has elapsed (step S504).
The master totals the measurement results received from each communication terminal and creates a table of the total results (step S505).

FIG. 6 shows an example of the tabulation result table. In the figure, an example is shown in which received power with other terminals is expressed as an evaluation value from “0” to “10” at each terminal as a measured value of the communication state.
In the example of FIG. 6, when the communication terminal 30C is selected as the master, it is possible to secure communication power of “7” or more. When the communication terminal 30C is selected, changing the master from the communication terminal 30G to the communication terminal 30C is transmitted to each communication terminal 30A to 30F from the current master terminal 30G to the communication terminal of each slave as a change request ( Step S506). Thereafter, the master is changed at each communication terminal (step S507).

In this case, the communication terminals 30A, 30B, 30D, 30E, and 30F that serve as slaves reset the relationship between 30G and the master / slave, and enter the standby state. Connection is made to 30D to 30G and the master communication terminal is changed from 30G to 30C as shown in FIG. 4, and the network configuration is changed from piconet 1 to piconet 2.
In the above, the re-request for the master / slave assignment was started by the communication terminal 30B that detected the deterioration of the communication status. However, each communication terminal periodically measures the status with other communication terminals. It is also conceivable that the master communication terminal 30G judges the situation and performs reassignment.

(Multiple master settings)
Each communication terminal moves from the configuration shown in FIG. 12 to the configuration shown in FIG. 7, and the communication terminals 30E and 30F described above (change of the master due to the occurrence of a slave out of communication range) and ( A case will be described in which it is not possible to participate in the network in the communication area of the piconet 2 as in the case of master change due to communication line deterioration. In this case, another piconet 3 constituted by a master-slave relationship is newly provided.
In FIG. 7, the communication terminal 30D serves as a slave in the piconet 2 and a master in the piconet 3, and relays signals between the respective piconets. A technique for connecting a plurality of piconets to each other to form one network is called a scatternet in the Bluetooth (registered trademark) standard.

  In this case, processing is performed according to the processing flow of FIG. That is, as shown in the figure, the communication terminal 30G that has played the role of the master in the piconet 1 counts the line status as in the case of FIG. 2 (steps S501 to S505). Thereafter, when selecting a new master, the communication terminal 30G determines whether a network can be configured with one piconet by changing the master (step S701). As a result of this determination, if it is determined that a network can be configured with one piconet, a process of selecting a new master and changing the master is performed as in the case of FIG. 2 (steps S506 and S507). ).

On the other hand, when it is determined that the configuration with one piconet is difficult, it is determined whether or not communication is possible by dividing into a plurality of piconets (step S702).
Here, FIG. 9 shows an example of a result obtained by tabulating with the communication terminal 30G. In the table of FIG. 9, the minimum value when selected as the master in all communication terminals is “0”, that is, there is a situation where communication is impossible.

  Therefore, here, if the determination is made in the case where one piconet is configured without the lowest value of “0”, the communication terminals 30A and 30C are selected. When it is determined that a piconet including the communication terminals 30D, 30E, and 30F that cannot communicate with the communication terminal 30A when the communication terminal 30A is selected is generated, the communication terminal 30B that is a slave of the communication terminal 30A, In any of 30C and 30D, the minimum value of the communication terminals 30D, 30E, and 30F is “0”, and communication with these communication terminals is impossible.

On the other hand, when it is determined that the communication terminal 30C is selected as the piconet master, there is a communication terminal 30D that can communicate with the communication terminals 30E and 30F among the communication terminals 30A, 30B, 30D, and 30G that are slaves of the communication terminal 30C. I understand that. Therefore, it can be determined that the scatternet can be configured with the communication terminal 30D as a slave of the communication terminal 30C and a master of the new piconet 3.
In this way, if it is determined that a piconet having the communication terminal 30D as a master and the communication terminal 30E as a slave can be connected to each other as a scatternet using a plurality of piconets, an instruction is given. Send a message to each terminal.

  Returning to FIG. 8, if the network can be configured by generating a plurality of piconets, the configuration of the scatternet described above is determined (steps S702 → S703). Thereafter, similarly to the case of FIG. 2, processing for changing the master is performed (steps S506 and S507). That is, each terminal receives a message transmitted from a communication terminal that is the original master (communication terminal 30G in the above example), changes the roles of the master and slave, and constructs a network with a new configuration. That is, a plurality of masters are set, a network in which slaves exist for each master is configured, and they are connected to each other.

Note that if a network cannot be configured even if a plurality of piconets are generated, the processing ends.
As described above, by generating a plurality of piconets and exchanging the roles of master and slave, slave terminals that could not communicate with the configuration before the exchange can communicate with each other in a network with a new configuration. .

(Master hierarchy)
Each communication terminal moves from the configuration shown in FIG. 7 to the configuration shown in FIG. 10, and is connected to the network in the communication area of the piconet 3 with the communication terminal 30D newly set as described above as a master. Describe the cases where you cannot participate. In this case, another piconet 4 constituted by a master-slave relationship is newly provided. In this case, the communication terminal 30D that is the master of the piconet 3 measures the communication line status with the communication terminal 30F, and if it detects that communication is impossible, the communication status notification request is sent to the slave terminal 30E of the piconet 3 of the communication status. A request is made and the communication information acquired from 30E is added up again at the communication terminal 30C which is the master of the piconet 1. FIG. 11 shows an example of the result of aggregation by the communication terminal 30C. As in the above example, the connection status of each terminal is checked, and it is determined that communication with the communication terminal 30F is possible by configuring the piconet 4 by newly setting the communication terminal 30E as a master, and changing the configuration. Instruct.

(Network control method)
In the above description, the following network control method is realized. That is, a line status measuring step for measuring a line status with another communication terminal, and a first determination step for determining whether or not a network can be configured by at least one of terminal movement and communication status degradation And a second determination step for determining whether or not it can be configured as a network in which a plurality of networks are connected when it is determined in the first determination step that the network cannot be configured as one network, and the second determination. A network including a master / slave determination step for determining a plurality of masters and slaves in a network based on a measurement result in the line status measurement step when it is determined in the step that the network can be configured as a connected network Control method is realized In this way, the network can be maintained by appropriately changing the configuration of the network according to the communication status between the master and the slave, and setting a plurality of masters even when the moving distance of the terminal is long.

  The present invention can be used in an ad hoc network for wireless communication including a master and a slave.

It is a functional block diagram which shows the structure of the mobile communication terminal by embodiment of this invention. It is a flowchart which shows the content of the process performed in the case of FIG. It is a figure which shows the example of the total table in the process of FIG. It is a figure which shows the state of the network after a master is changed by the process of FIG. It is a flowchart which shows the content of the process when a communication condition with a master deteriorates remarkably. It is a figure which shows the example of the total table in the process of FIG. It is a figure which shows the state of the network which the terminal moved from the state of FIG. 12 and set several masters. It is a flowchart which shows the content of the process performed in the case of FIG. It is a figure which shows the example of the total table in the process of FIG. It is a figure which shows the state of the network after a terminal moves from the state of FIG. It is a figure which shows the example of the total table in the process of FIG. It is a figure which shows the example of the ad hoc network comprised by a master and a slave. It is a figure which shows the state of the network after a terminal moves from the state of FIG.

Explanation of symbols

1 to 3 piconet 30, 30A to 30G communication terminal 31 communication unit 32 line status measurement unit 33 master / slave determination unit 34 determination unit

Claims (2)

  Line status measuring means for measuring the status of a line between other communication terminals, and master / slave determining means for determining a master and a slave in the network based on a measurement result by the line status measuring means, A mobile communication terminal that constitutes a network together with a communication terminal, and can be configured as a network in which a plurality of networks are connected when it cannot be configured as one network due to at least one of movement of the terminal and deterioration of communication status A determination unit for determining whether or not the master / slave determination unit determines a plurality of masters when a plurality of networks can be connected according to a determination result of the determination unit. Communication terminal.   A line status measurement step for measuring a line status with another communication terminal, a first determination step for determining whether or not a network can be configured by at least one of terminal movement and communication status degradation; In the first determination step, when it is determined that the network cannot be configured as one network, the second determination step that determines whether the network can be configured as a connected network, and the second determination step A master / slave determination step of determining a plurality of masters and slaves in the network based on a measurement result in the line status measurement step when it is determined that the network can be configured as a connected network. Network control method.

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