WO2019026990A1 - Wireless device and program - Google Patents

Abstract

A wireless device 10 is included in a mesh network for transferring a packet signal by a flooding scheme. A receiving unit 52 receives a packet signal. A control unit 24 controls the transfer of the packet signal received by the receiving unit 52. A transmission unit 50 transmits a packet signal in accordance with transfer control by the control unit 24. The control unit 24 causes the transfer of packet signals to a destination that corresponds to the same packet signal to be suppressed to a greater extent commensurately with an increase in the number of times the same packet signal is received by the receiving unit 52.

Description

Wireless device, program

The present disclosure relates to communication technology, and more particularly to a wireless apparatus and program for transferring a packet signal in a flooding mode.

In a multi-hop communication system constituted by a plurality of wireless devices, packet signals transmitted from one wireless device are transferred by another wireless device and received by a destination wireless device. The communication path of the multi-hop communication system is, for example, formed in a mesh shape in which a plurality of wireless devices are connected in a mesh. When transmitting a packet signal, the wireless device serving as the starting point of packet signal transfer sets an upper limit value of the number of times of relay transmission as the relay count value. When relay transmitting a packet signal, the other wireless device sets a value obtained by subtracting 1 from the relay count value as a new relay count value (for example, see Patent Document 1).

JP, 2016-012867, A

By setting the upper limit value of the number of times of relay transmission, repetition of transfer is suppressed and an increase in traffic is suppressed. Such control is uniformly performed on the entire network. On the other hand, a plurality of wireless devices are generally not distributed evenly, and some may be densely arranged, and some may be coarsely arranged. In such a case, the number of transfer paths in the former tends to be large in the number of transfer paths in the latter. Therefore, control of transfer in consideration of such a difference is required.

The present disclosure has been made in view of such circumstances, and an object thereof is to provide a technique for transferring a packet signal in consideration of the difference in the number of transfer paths.

In order to solve the above problems, a wireless device according to an aspect of the present disclosure is a wireless device included in a mesh network that transfers a packet signal by a flooding method, and a receiver that receives a packet signal and a receiver The control unit controls the transfer of the packet signal, and the transmission unit transmits the packet signal according to the control of the transfer by the control unit. The control unit suppresses the transfer of the packet signal of the destination corresponding to the same packet signal as the number of times of reception of the same packet signal in the receiving unit increases.

It is to be noted that any combination of the above-described components, and one obtained by converting the expression of the present disclosure among methods, apparatuses, systems, recording media, computer programs, and the like are also effective as aspects of the present disclosure.

According to the present disclosure, a packet signal can be transferred in consideration of the difference in the number of transfer paths.

It is a figure which shows the structure of the radio | wireless communications system which concerns on an Example. It is a figure which shows another structure of the radio | wireless communications system which concerns on an Example. It is a figure which shows the structure of the radio | wireless apparatus of FIG. 1 and FIG. FIG. 3 illustrates the format of a packet signal used in the wireless communication system of FIGS. 1 and 2; It is a figure which shows the data structure of the database memorize | stored in the memory | storage part of FIG. It is a flowchart which shows the measurement procedure of the packet signal number by the radio | wireless apparatus of FIG. It is a flowchart which shows the setting procedure of transfer of the packet signal by the radio | wireless apparatus of FIG.

Before specifically describing the present disclosure, an outline will be given. An embodiment relates to a wireless communication system of a mesh network configured by a plurality of wireless devices. Each wireless device is mounted on, for example, a control device and a plurality of controlled devices in a lighting system controlled by wireless communication. In the illumination system, when the communication distance from the control device to the controlled device is equal to or more than a predetermined amount, the packet signal is transmitted by multi-hop communication by the wireless device mounted on the controlled device disposed therebetween. When performing multi-hop communication in a mesh network, a flooding scheme is used. On the other hand, a plurality of wireless devices are generally not evenly distributed, and some may be densely arranged or some may be coarsely arranged depending on the position where the controlled device is to be installed. . When the flooding method is performed under such a situation, there are the following problems.

In portions where wireless devices are densely arranged, one packet signal is transferred by many routes because the number of transfer routes between wireless devices is large. As a result, the traffic volume increases, and congestion of the traffic tends to increase the collision of packet signals. On the other hand, in a portion where the wireless devices are arranged roughly, one packet signal is transferred by a limited route because the number of transfer routes between the wireless devices is small. Therefore, when the transfer of the packet signal is suppressed, the packet signal becomes difficult to reach due to an error of the packet signal. This is a decrease in the communication success rate, which leads to a decrease in communication reliability.

In order to cope with this, the wireless device included in the wireless communication system according to the present embodiment receives the number of receptions of the same packet signal received from the wireless device (hereinafter referred to as "starting wireless device") serving as the starting point of transfer. measure. It can be said that as the number of times of reception of the same packet signal increases, the number of routes to the wireless device increases. The wireless device measures the number of receptions of the same packet signal for various originating wireless devices. When such a measurement result is stored, when the wireless device receives a packet signal to be transferred, the same starting point as the wireless device (hereinafter referred to as “destination wireless device”) that is the destination of the packet signal Get the number of receptions for the wireless device. The wireless device suppresses transfer when the number of receptions is equal to or greater than the threshold, and increases transfer when the number of receptions is less than the threshold. Thereby, congestion reduction in the mesh network and improvement of communication reliability are realized.

FIG. 1 shows the configuration of a wireless communication system 100. The wireless communication system 100 includes first to twelfth wireless devices 10a to 10l collectively referred to as wireless devices 10. The number of wireless devices 10 is not limited to "12". When the wireless communication system 100 is used for a lighting system, one of the plurality of wireless devices 10 is mounted on the control device, and the remaining wireless devices 10 are mounted on the controlled device. The control device and at least a part of the controlled device are fixed to a ceiling or the like. The plurality of wireless devices 10 form a mesh network and execute multi-hop communication by the flooding method.

FIG. 2 shows another configuration of the wireless communication system 100. This shows the configuration of the wireless communication system 100 in which the wireless device 10 of FIG. 1 includes a portion closely arranged and a portion roughly disposed of the wireless device 10. For example, the fifth wireless device 10e and the sixth wireless device 10f are densely arranged, and the eighth wireless device 10h is coarsely arranged. Since processing in the wireless communication system 100 is common to FIGS. 1 and 2, (1) transmission of packet signal, (2) reception of packet signal, (3) using FIGS. 1 and 2 here. The measurement of the number of receptions and (4) transfer of packet signals will be described in this order.

(1) Transmission of Packet Signal When any data to be transmitted is generated, one of the wireless devices 10 generates a packet signal including the data. The wireless device 10 that generates a packet signal corresponds to the above-described source wireless device, and the wireless device 10 that is the destination of the packet signal corresponds to the above-described destination wireless device. The packet signal includes an ID (Identification) (hereinafter referred to as “starting point ID”) for identifying the wireless device 10 that is the starting point of the transfer of the packet signal and the wireless device 10 that is the destination of the packet signal. ID (hereinafter referred to as "destination ID") is included. The originating wireless device transmits a packet signal. Packet signals are forwarded by the flooding method in the mesh network. Here, the packet signal includes a TTL value which is a value indicating the number of times of transfer. When the destination ID included in the packet signal is different from the ID of the wireless device 10, the wireless device 10 receiving the packet signal transfers the packet signal if the TTL value is “1” or more, and the TTL value is “0”. If "", the packet signal is not transferred. The wireless device 10 reduces the TTL value by “1” at the time of transfer.

(2) Reception of Packet Signal The wireless device 10 that has received the packet signal executes reception processing on the packet signal when the destination ID included in the packet signal is the same as the ID of the wireless device 10 itself. Get the data contained in the packet signal. The wireless device 10 is the above-described destination wireless device, and the control device or the controlled device on which the destination wireless device is mounted may execute processing according to data.

(3) Measurement of the Number of Receptions When one radio apparatus 10 is connected to a plurality of other radio apparatuses 10, a plurality of routes for transferring packet signals are formed in the one radio apparatus 10. In such a case, the packet signal travels through each of the plurality of paths to reach one radio apparatus 10. One radio apparatus 10 receives the same packet signal that has passed through a plurality of paths a plurality of times. Therefore, one radio apparatus 10 measures the number of times of reception of the same packet signal for each starting point ID.

In FIG. 2, when the first wireless device 10a is an origin wireless device and the ninth wireless device 10i is a destination wireless device, the fifth wireless device 10e of the closely arranged portion is a second wireless device 10b, the fifth wireless device 10b. The third radio device 10c receives the same packet signal transferred from the fourth radio device 10d. The roughly arranged portion of the eighth radio apparatus 10h receives the same packet signal transferred from the seventh radio apparatus 10g. Therefore, the number of receptions in the fourth wireless device 10d is larger than the number of receptions in the eighth wireless device 10h.

From this, it can be said that the number of receptions indicates the number of paths input to one radio apparatus 10. One wireless device 10 performs the same process for various origin wireless devices. Furthermore, each of the plurality of wireless devices 10 performs the same process. As a result, each wireless device 10 stores a plurality of correspondence relationships between the originating wireless device and the number of receptions. This corresponds to each wireless device 10 acquiring a plurality of correspondence relationships between the originating wireless device and the number of routes.

(4) Transfer of Packet Signal As described above, when the destination ID included in the packet signal is different from the ID of the own wireless device 10, the wireless device 10 having received the packet signal has a TTL value of “1” or more. , And decrements the TTL value included in the packet signal by "1" before transferring the packet signal. At this time, the wireless device 10 refers to a plurality of correspondence relationships that have already been stored, and acquires the number of receptions for the originating wireless device having the same ID as the destination ID included in the packet signal. This corresponds to acquiring the number of paths output from the wireless device 10.

In FIG. 2, when the ninth wireless device 10i is a home wireless device and the first wireless device 10a is a destination wireless device, each wireless device 10 disposed between them is the number of times of reception for the first wireless device 10a. To get That is, these units acquire the number of receptions after replacing the originating wireless device in the stored correspondence with the destination wireless device. When the number of receptions is equal to or more than the threshold, the wireless device 10 suppresses the transfer because the number of routes is large and congestion is likely to occur. When the number of receptions is smaller than the threshold value, the wireless device 10 increases the number of transfers because the number of paths is small and packet signals are hard to reach. For example, the former corresponds to the process in the fifth wireless device 10e, and the latter corresponds to the process in the eighth wireless device 10h. Specific examples of transfer suppression and increase will be described later. On the other hand, when the destination ID included in the packet signal is different from the ID of the wireless device 10, the wireless device 10 that has received the packet signal discards the packet signal without transferring it if the TTL value is "0". .

FIG. 3 shows the configuration of the wireless device 10. The wireless device 10 includes a communication unit 20, a processing unit 22, a control unit 24, and a storage unit 26. The communication unit 20 includes a transmission unit 50 and a reception unit 52. The processing unit 22 includes a packet signal generation unit 30, a packet signal processing unit 32, and a transfer processing unit 34. The control unit 24 includes a measurement unit 40 and an extraction unit. 42 includes a setting unit 44. Also in this case, (1) transmission of packet signal, (2) reception of packet signal, (3) measurement of reception count, and (4) transfer of packet signal will be described in this order.

(1) Transmission of Packet Signal When the wireless device 10 is a starting point wireless device, the packet signal generation unit 30 of the wireless device 10 generates a packet signal. FIG. 4 shows the format of a packet signal used in the wireless communication system 100. The packet signal includes the source ID, the destination ID, the TTL value, and the data to be transmitted, which have already been described. Here, a predetermined initial value is set as the TTL value. Furthermore, the packet signal also includes an authentication code and a sequence number. The authentication code is short information for authenticating a message that is data, and is also called a MAC (Message Authentication Code). The sequence number is a serial number assigned to data in order to specify the order of the data. A known technique may be used for the authentication code and the sequence number, and thus the description thereof is omitted here. Return to FIG. The packet signal generator 30 outputs the packet signal to the transmitter 50. The transmitting unit 50 transmits the packet signal received from the packet signal generating unit 30. The transmission unit 50 transmits a packet signal by the flooding method. A known technique may be used for the communication unit 20, and thus the description thereof is omitted here.

(2) Reception of Packet Signal The receiving unit 52 in the wireless device 10 other than the origin wireless device receives a packet signal. The receiving unit 52 outputs the packet signal to the processing unit 22 and the control unit 24. The packet signal processing unit 32 extracts the destination ID included in the packet signal. If the extracted destination ID matches the ID of the own radio apparatus 10, the packet signal processing unit 32 processes the data contained in the packet signal while using the authentication code and the sequence number contained in the packet signal. Although the process includes decoding and the like, the description is omitted here. The packet signal processing unit 32 may output the processing result to a control device or a controlled device in which the wireless device 10 is mounted.

(3) Measurement of the Number of Receptions The measurement unit 40 receives a packet signal from the reception unit 52. The measuring unit 40 measures the number of times of reception of the same packet signal in the receiving unit 52. Here, the measuring unit 40 executes, for example, one of the following three measuring methods. In the first measurement method, all bits of the received packet signal and in the format of the packet signal shown in FIG. 4 are compared. The measuring unit 40 determines that the packet signal in which all the bits match each other is the same packet signal. That is, the measuring unit 40 measures the number of packet signals in which all bits match.

In the second eye measurement method, a plurality of parameters among the received packet signals and among the packet signals of the format shown in FIG. 4 are compared. The measuring unit 40 determines, for example, that a packet signal in which “start point ID”, “destination ID”, and “sequence number” all match is the same packet signal. The combination of the plurality of parameters is not limited to the “start point ID”, the “destination ID”, and the “sequence number”. That is, the measuring unit 40 measures the number of packet signals for which the plurality of parameters match. In the third eye measurement method, single parameters of received packet signals and among the packet signals of the format shown in FIG. 4 are compared. For example, the measuring unit 40 determines that the packet signal whose authentication code matches is the same packet signal. That is, the measuring unit 40 measures the number of packet signals for which the single parameter matches.

The measuring unit 40 measures the number of times of reception for each starting point ID, and stores the correspondence between the starting point ID and the number of times of reception in the storage unit 26. FIG. 5 shows the data structure of the database stored in the storage unit 26. As illustrated, the correspondence between the start point ID and the number of receptions is stored together with the measurement date and time. When the measuring unit 40 measures the number of times of reception based on a new packet signal with respect to the starting point ID whose correspondence is already stored in the storage unit 26, the number of times of reception already stored is the new number of times of reception It may be updated by Further, the measuring unit 40 may derive the number of receptions based on the number of receptions already stored and the number of new receptions, and may update the number of receptions already stored according to the derived number of receptions. Return to FIG.

(4) Transfer of Packet Signal The receiving unit 52 in the wireless device 10 other than the origin wireless device receives a packet signal. The receiving unit 52 outputs the packet signal to the processing unit 22 and the control unit 24. The transfer processing unit 34 extracts the destination ID included in the packet signal. If the extracted destination ID does not match the ID of the own radio apparatus 10, the transfer processing unit 34 extracts the TTL value from the packet signal. When the TTL value is “0”, the transfer processing unit 34 determines the end of the transfer. On the other hand, when the TTL value is “1” or more, the transfer processing unit 34 determines transfer. At this time, the transfer processing unit 34 outputs the destination ID to the control unit 24.

The extraction unit 42 receives the destination ID from the transfer processing unit 34. The extraction unit 42 extracts from the storage unit 26 the number of receptions corresponding to the starting point ID having the same value as the received destination ID. This corresponds to acquiring the number of receptions corresponding to the source wireless device in order to use it for transfer of the packet signal to the destination wireless device having the same ID as that of the source wireless device. The extraction unit 42 outputs the extracted number of receptions to the setting unit 44. The setting unit 44 receives the number of receptions from the extraction unit 42. The setting unit 44 compares the threshold value held in advance with the number of receptions. The setting unit 44 determines the suppression of transfer when the number of receptions is equal to or more than the threshold. A first example of transfer suppression is not to transfer packet signals. This corresponds to a transfer discard rate of 100%. A second example of transfer suppression is not to transfer packet signals stochastically. This corresponds to the transfer discard rate being set between 0% and 100%.

A third example of transfer suppression is to reduce the number of consecutive transmissions of the same packet signal. The continuous transmission of the same packet signal is to transmit the same packet signal again although the error of the packet signal is not notified from the wireless device 10 on the receiving side. For example, when the number of continuous transmissions is “3” at normal time, the number of continuous transmissions is set to “1” when the transfer is suppressed. On the other hand, the setting unit 44 increases the transfer of the packet signal when the number of receptions is smaller than the threshold. One example of increasing transmission is to increase the number of consecutive transmissions of the same packet signal.

This suppresses the transfer by the wireless device 10 when the number of receptions of the same packet signal in the reception unit 52 is equal to or greater than the threshold value, and transfers by the wireless device 10 when the number of receptions is smaller than the threshold value. It corresponds to increasing. That is, the setting unit 44 controls the transfer of the packet signal received by the receiving unit 52 so that the transfer of the packet signal is suppressed as the number of receptions in the receiving unit 52 increases. The setting unit 44 sets the determined content in the transfer processing unit 34.

The transfer processing unit 34 determines the transfer of the packet signal according to the content set by the setting unit 44. At this time, the transfer processing unit 34 includes the TTL value obtained by subtracting “1” from the TTL value in the packet signal. The transfer processing unit 34 outputs the packet signal to the transmission unit 50, and the transmission unit 50 transmits the packet signal.

The setting unit 44 may determine to reduce the TTL value by two or more at the time of transfer in order to suppress transfer. At this time, the transfer processing unit 34 includes the TTL value obtained by subtracting “2” from the TTL value in the packet signal. This corresponds to suppressing the transfer by the other wireless device 10 when the number of receptions is equal to or more than the threshold.

The subject matter of the apparatus, system or method in the present disclosure comprises a computer. The computer executes the program to implement the functions of the apparatus, system, or method in the present disclosure. The computer includes, as a main hardware configuration, a processor that operates according to a program. The processor may be of any type as long as the function can be realized by executing a program. The processor is configured of one or more electronic circuits including a semiconductor integrated circuit (IC) or an LSI (Large Scale Integration). The plurality of electronic circuits may be integrated on one chip or may be provided on a plurality of chips. The plurality of chips may be integrated into one device or may be provided to a plurality of devices. The program is recorded in a non-transitory recording medium such as a computer readable ROM, an optical disc, a hard disk drive and the like. The program may be stored in advance in a recording medium, or may be supplied to the recording medium via a wide area communication network including the Internet and the like.

The operation of the wireless communication system 100 having the above configuration will be described. FIG. 6 is a flowchart showing the procedure for measuring the number of packet signals by the wireless device 10. When the receiving unit 52 has already received the same packet signal (Y in S10), the measuring unit 40 increments the number of receptions (S12). On the other hand, when the receiving unit 52 has not already received the same packet signal (N in S10), the measuring unit 40 starts measuring the number of receptions (S14). If the receiver 52 receives a new packet signal (Y in S16), the process returns to step S10. If the receiving unit 52 does not receive a new packet signal (N in S16), the storage unit 26 stores the number of receptions (S18).

FIG. 7 is a flowchart showing a setting procedure of transfer of a packet signal by the wireless device 10. The extraction unit 42 extracts the number of receptions (S20). If the number of receptions is equal to or more than the threshold (Y in S22), the setting unit 44 determines the suppression setting of transfer (S24). On the other hand, if the number of receptions is not equal to or more than the threshold (N in S22), the setting unit 44 determines an increase setting of transfer (S26).

According to this embodiment, since the number of times of reception of the same packet signal is measured, the number of transfer paths can be estimated. In addition, since the transfer of the packet signal of the destination corresponding to the same packet signal is suppressed as the number of receptions of the same packet signal increases, the packet signal can be transferred in consideration of the difference in the number of transfer paths. In addition, as the number of times of reception of the same packet signal increases with respect to the packet signal for which another wireless device serving as the starting point of transfer of the same packet signal is set as the destination of transfer, the transfer is suppressed. It is possible to reflect the number of routes to be transferred to the transfer control.

In addition, since the transfer is suppressed when the number of receptions of the same packet signal is equal to or more than the threshold value, an increase in traffic can be suppressed even if the number of paths is large. In addition, since the increase in traffic volume is suppressed, the occurrence of congestion can be suppressed. Since the transfer is increased when the number of times of reception of the same packet signal is smaller than the threshold, even if the number of paths is small, it is possible to suppress that the packet signal becomes difficult to reach due to an error of the packet signal. In addition, since it is suppressed that the packet signal is difficult to reach, it is possible to suppress a decrease in the communication success rate. Moreover, since the fall of a communication success rate is suppressed, the fall of communication reliability can be suppressed.

Moreover, since the packet signal is not transferred when the number of times of reception of the same packet signal is equal to or more than the threshold value, transfer can be suppressed. In addition, when the number of receptions of the same packet signal is equal to or more than the threshold value, the number of continuous transmissions of the same packet signal is reduced, so that transfer can be suppressed. In addition, when the number of receptions of the same packet signal is smaller than the threshold value, the number of continuous transmissions of the same packet signal is increased, so that transfer can be increased. Further, since the TTL value is reduced by 2 or more at the time of transfer when the number of times of reception of the same packet signal is equal to or more than the threshold value, transfer can be suppressed.

The outline of one aspect of the present disclosure is as follows. The wireless device 10 according to an aspect of the present disclosure is a wireless device 10 included in a mesh network that transfers a packet signal by a flooding method, and includes a receiving unit 52 that receives the packet signal and a packet signal received by the receiving unit 52. The control unit 24 controls transfer, and the transmission unit 50 transmits a packet signal according to transfer control by the control unit 24. As the number of times of reception of the same packet signal in the reception unit 52 increases, the control unit 24 suppresses transfer of a packet signal of a destination corresponding to the same packet signal.

The control unit 24 transfers the packet signal set as the transfer destination by the other wireless device 10 serving as the start point of transfer of the same packet signal as the number of times the same packet signal is received by the reception unit 52 increases. It may be suppressed.

The control unit 24 may suppress the transfer when the number of receptions of the same packet signal in the reception unit 52 is equal to or greater than the threshold, and may increase the transfer when the number of receptions is smaller than the threshold.

The control unit 24 suppresses transfer by the wireless device 10 if the number of receptions of the same packet signal in the reception unit 52 is equal to or greater than the threshold, and the number of receptions is smaller than the threshold. Transfer may be increased.

The control unit 24 may suppress transfer by another wireless device 10 when the number of times of reception of the same packet signal in the reception unit 52 is equal to or greater than a threshold.

The present disclosure has been described above based on the examples. It is understood by those skilled in the art that this embodiment is an exemplification, and that various modifications can be made to their respective components or combinations of processing processes, and such modifications are also within the scope of the present disclosure. .

In the present embodiment, the setting unit 44 determines the suppression or increase of the transfer by comparing the number of receptions with one threshold value. However, the invention is not limited to this. For example, the setting unit 44 determines a plurality of threshold values, and compares the threshold values with the number of receptions to gradually suppress or gradually increase the transfer. You may decide. According to this modification, finer control can be performed.

In the present embodiment, the setting unit 44 uses the number of receptions with respect to the origin wireless device to determine control of transfer of a packet signal for which the origin wireless device is the destination wireless device. However, the present invention is not limited to this. For example, by transmitting the number of receptions for the originating wireless device to the wireless device 10 on the originating wireless device side, the number of receptions is used when determining control of packet signal transfer in the relevant wireless device 10 May be According to this modification, since the number of times of reception is used in the wireless device 10 on the side of the originating wireless device, the control accuracy in the wireless device 10 can be improved.

DESCRIPTION OF REFERENCE NUMERALS 10 radio apparatus 20 communication unit 22 processing unit 24 control unit 26 storage unit 30 packet signal generation unit 32 packet signal processing unit 34 transfer processing unit 40 measurement unit 42 extraction unit 44 setting unit 50 Transmitter, 52 Receiver, 100 Wireless communication system.

According to the present disclosure, a packet signal can be transferred in consideration of the difference in the number of transfer paths.

Claims (6)

1. A wireless device included in a mesh network that transfers packet signals by a flooding method,
   A receiver for receiving a packet signal;
   A control unit that controls transfer of the packet signal received by the receiving unit;
   And a transmitter configured to transmit the packet signal according to control of transfer by the controller.
   The wireless device, wherein the control unit suppresses transfer of a packet signal of a destination corresponding to the same packet signal as the number of times of reception of the same packet signal in the receiving unit increases.
2. The control unit transfers the packet signal set as the transfer destination by another wireless device serving as the starting point of transfer of the same packet signal as the number of times the same packet signal is received in the reception unit increases. The wireless device according to claim 1, wherein the wireless device is suppressed.
3. The control unit suppresses transfer when the number of receptions of the same packet signal in the reception unit is equal to or greater than a threshold, and increases transfer when the number of receptions is smaller than the threshold. The wireless device according to claim 1.
4. The control unit suppresses transfer by the wireless device when the number of receptions of the same packet signal in the reception unit is equal to or greater than a threshold, and transfers by the wireless device when the number of receptions is smaller than the threshold. The radio device according to claim 3, characterized in that
5. 4. The wireless device according to claim 3, wherein the control unit suppresses transfer by another wireless device when the number of times of reception of the same packet signal in the receiving unit is equal to or greater than a threshold.
6. A program in a wireless device included in a mesh network that transfers packet signals in a flooding method,
   Receiving a packet signal;
   Controlling transfer of the received packet signal;
   Sending the packet signal according to the control of transfer;
   The program for causing a computer to execute the control step to suppress transfer of a packet signal of a destination corresponding to the same packet signal as the number of times of reception of the same packet signal increases.

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