JP2014116714A - Data transmission terminal, communication quality control system, communication quality control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data transmission terminal, a communication quality control system, a communication quality control method and a program, enhancing a data arrival rate with the reduction of an increase amount of network use bands by the enhanced data arrival rate.SOLUTION: A data transmission terminal 10 includes: acquisition means 110 for acquiring reliability information indicative of the communication quality of transmission data transmitted to a data reception terminal; data adjustment means 120 for adding, to the transmission data, adjustment data excluding a part capable of being common with the transmission data among transmission completion data which is transmission data already transmitted to the data reception terminal, based on the acquired reliability information; and data transmission means 130 for transmitting the transmission data having the added adjustment data, to the data reception terminal.

Description

  The present invention relates to a data transmission terminal, a communication quality control system, a communication quality control method, and a program for controlling communication quality.

  In data communication, there may occur a situation in which transmission data is discarded midway due to a communication environment or the like and does not reach the receiving side. In order to solve this, various techniques for improving communication quality are provided.

  The following Patent Document 1 and Patent Document 2 disclose an example of a system that improves the data arrival rate (communication quality). Each patent document discloses a method of retransmitting a packet in response to a transmission request for a discarded packet.

JP 2011-259183 A JP 2001-268134 A

  However, in the methods described in the above-described patent documents, it is necessary to transmit the same packet a plurality of times in order to improve the data arrival rate. That is, according to the methods described in the above-mentioned patent documents, the use bandwidth of the network increases in proportion to the number of times the same packet is transmitted.

  The present invention has been made in view of such circumstances, and improves the data arrival rate while reducing the amount of increase in the bandwidth used by the network, a data transmission terminal, a communication quality control system, and communication quality A control method and a program are provided.

According to the present invention,
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A data transmission terminal is provided.

According to the present invention,
Comprising at least one data transmitting terminal and at least one data receiving terminal;
The data transmission terminal is
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
Have
The data receiving terminal is
Data receiving means for receiving the transmission data;
Reliability calculation means for calculating the reliability information based on the reception status of the transmission data;
Reliability transmission means for transmitting the reliability information calculated by the reliability calculation means to the data transmission terminal;
A communication quality control system is provided.

According to the present invention,
The data sending terminal
Obtain reliability information indicating the communication quality of the transmission data to be transmitted to the data receiving terminal,
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. To
Transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A communication quality control method including the above is provided.

According to the present invention,
Computer
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A program for functioning as a server is provided.

  According to the present invention, it is possible to improve the data arrival rate and reduce the amount of increase in the bandwidth used by the network.

It is a block diagram which shows the structure of the data transmission terminal which concerns on 1st Embodiment. It is a figure which shows an example of the transmission data to which adjustment data was added. It is a block diagram which shows the structure of the communication quality control system which concerns on 1st Embodiment. It is a sequence diagram which shows the flow of a process of the communication quality control system which concerns on 1st Embodiment. It is a sequence diagram which shows the flow of a process of the communication quality control system which concerns on 2nd Embodiment. It is a figure which shows the operation | movement concept of the communication quality control system which concerns on 3rd Embodiment. It is a figure which shows the header format of ECHONET Lite.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In all the drawings, the same reference numerals are given to the same components, and the description will be omitted as appropriate.

  Each component of the data transmission terminal and the data reception terminal shown in each figure is not a hardware unit configuration but a functional unit block. Each component of the data transmission terminal and the data reception terminal includes a CPU, a memory of any computer, a program that realizes the components of this figure loaded in the memory, a storage medium such as a hard disk that stores the program, and a network connection It is realized by any combination of hardware and software, with a focus on the interface. There are various modifications of the implementation method and apparatus.

(First embodiment)
FIG. 1 is a block diagram illustrating a configuration of a data transmission terminal 10 according to the first embodiment. For example, the data transmission terminal 10 of the present embodiment acquires data at a predetermined interval, and transmits a packet including the acquired data to a data reception terminal (not shown). The data transmission terminal 10 includes an acquisition unit 110, a data adjustment unit 120, and a data transmission unit 130.

  The acquisition unit 110 acquires reliability information indicating communication quality of transmission data included in a packet transmitted from the data transmission terminal 10. For example, the acquisition unit 110 acquires reliability information from another device located outside. Here, the reliability information is, for example, transmission data redundancy, information generated based on the redundancy, and the like. The information generated based on the redundancy is, for example, information for notifying transmission timing such as a transmission interval of packets transmitted from the data transmission terminal 10. In the present embodiment, a case where the acquisition unit 110 acquires redundancy as reliability information will be described as an example.

  The data adjustment unit 120 adds adjustment data for improving communication quality to transmission data based on the reliability information acquired by the acquisition unit 110. This adjustment data is, for example, information included in the payload of transmission data (transmitted data) that has already been transmitted. This transmitted data may be stored in a memory or storage built in the data transmission terminal 10. Further, devices other than the data transmission terminal 10 store the transmitted data transmitted from the data transmission terminal 10, and the data adjustment unit 120 transmits the transmitted data or the transmitted data from the other devices. Information included in the data payload may be acquired. Here, FIG. 2 shows an example of transmission data to which adjustment data is added. FIG. 2 shows an example in which reliability information with redundancy n is acquired. As shown in FIG. 2, the transmission data includes a header portion and a payload. Data acquired by the data transmission terminal 10 is stored in the payload. Then, adjustment data corresponding to the reliability information is added to the transmission data. Here, since the redundancy is n, data acquired up to n-1 times before the previously acquired data is added as adjustment data. Furthermore, the data acquired n-2 times before the data acquired this time becomes adjustment data added to the next transmission data. In this way, each data is transmitted n times to the data receiving terminal.

  The data transmission unit 130 generates a packet including the transmission data to which the adjustment data is added by the data adjustment unit 120, and transmits the packet to the data reception terminal that is the transmission destination.

  As described above, only the portion of the transmitted data that can be shared with the transmission data is added to the transmission data as adjustment data. As a result, it is possible to reduce the network bandwidth that can be shared while improving the data arrival rate.

  In addition, the data transmission terminal 10 according to the present embodiment transmits a packet including transmission data using a predetermined interval, a predetermined time, and a command from an external device as a trigger. The data transmission terminal 10 of the present embodiment is a smart meter that measures the flow rate of electricity, gas, water, and the like, for example, and the amount of power, gas amount, water flow rate, and the like acquired by the smart meter are the transmission data. Included in the payload. However, the information included in the payload of the transmission data transmitted by the data transmission terminal 10 is not limited to this. The data transmission terminal 10 may include various information acquired or stored by the data transmission terminal 10 in the payload.

  Hereinafter, the first embodiment will be described in more detail.

The data adjustment unit 120 determines adjustment data to be added to the transmission data using, for example, the following Equation 1. Here, m is the number of data included in one packet, t ₁ is the data acquisition interval, n is the redundancy, and t ₂ is the packet transmission interval.

The data adjustment unit 120 determines adjustment data to be added to the transmission data so as to satisfy the redundancy obtained from the data receiving terminal. Here, it is assumed that the data acquisition interval t ₁ is “30 minutes”, the redundancy n acquired by the acquisition unit 110 is “4”, and the packet transmission interval t ₂ is “30 minutes”. In this case, Equation 1 is “(m × 30) / 4 = 30”, and the number m of data included in one packet is calculated as 4. In this case, the number of adjustment data to be added is “3”.

The data adjustment unit 120 may determine adjustment data to be added to the transmission data by adjusting the packet transmission interval based on the redundancy obtained from the data receiving terminal. Here, it is assumed that the number m of data included in one packet is “48”, the data acquisition interval t ₁ is “30 minutes”, and the redundancy n acquired by the acquisition unit 110 is “6”. In this case, Equation 1 is “(48 × 30) / 6 = t ₂ ”, and the packet transmission interval t ₂ is calculated as “360 minutes = 6 hours”. In this case, since 12 pieces of new data are acquired during 6 hours, 36 pieces of data among the 48 pieces of data included in one packet become adjustment data.

  If the redundancy is n, the same data only needs to be transmitted n times from the data transmission terminal 10 to the data reception terminal. Therefore, various methods other than the above example can be employed. . For example, in the above, an example in which past data that is continuous in time series is inserted has been described, but discontinuous data in time series may be inserted.

  FIG. 3 is a block diagram illustrating a configuration of the communication quality control system 1 according to the first embodiment. In FIG. 3, the communication quality control system 1 includes a data transmission terminal 10 and a data reception terminal 20. The data transmission terminal 10 and the data reception terminal 20 are connected to each other via a wireless or wired network 30. In FIG. 3, the data transmission terminal 10 acquires reliability information from the data reception terminal 20. The data receiving terminal 20 receives a packet generated by the data transmitting terminal 10 based on the reliability information. Although not shown, the communication quality control system 1 may include a plurality of data transmission terminals 10 and a plurality of data reception terminals 20.

  The data receiving terminal 20 includes a data receiving unit 210, a reliability calculating unit 220, and a reliability transmitting unit 230.

  The data reception unit 210 receives a packet transmitted from the data transmission terminal 10. Furthermore, the data reception unit 210 monitors the reception status of packets transmitted from the data transmission terminal 10. For example, the data receiving unit 210 monitors the arrival time of the packet, the sequence number of the packet, the bandwidth used for the network interface, the MTU (Maximum Transmission Unit) size, the packet length, the number of arrival packets, and the like as the reception status. The data reception unit 210 transmits the reception status acquired as a result of monitoring to the reliability calculation unit 220. It should be noted that which information the data reception unit 210 handles as the reception status depends on the reliability information calculation method of the reliability calculation unit 220 described later.

  The reliability calculation unit 220 calculates reliability information based on the reception status acquired by the data reception unit 210. In the present embodiment, an example in which redundancy of transmission data is used as reliability information will be described. For example, the reliability calculation unit 220 calculates the redundancy of transmission data by the following method.

Based on the reception status acquired by the data reception unit 210, the reliability calculation unit 220 satisfies the data arrival rate (target data arrival rate) of the target transmission data and has a redundancy that minimizes the network load. It can be calculated. The target data arrival rate is set in advance in the data receiving terminal 20 for each data transmitting terminal 10, for example. First, the reliability calculation unit 220 calculates a packet arrival rate based on the reception status acquired by the data reception unit 210. Then, the reliability calculation unit 220 calculates the redundancy of the transmission data that satisfies the preset target data arrival rate based on the packet arrival rate. If the target data arrival rate is α, the packet arrival rate is β, and the transmission data redundancy is n, the transmission data redundancy n can be calculated using, for example, Equation 2 below. Assume that the target data arrival rate α is “0.95” and the packet arrival rate β is “0.6”. In this case, the redundancy n that minimizes the network load is calculated as “4” using the following equation (2).

  Here, the packet arrival rate in the present specification indicates a ratio of packets reaching the data receiving terminal 20 among packets transmitted from the data transmitting terminal 10 to the data receiving terminal 20. In addition, the data arrival rate in this specification indicates a ratio of data that has reached the data receiving terminal 20 among data included in a payload of a packet transmitted from the data transmitting terminal 10 to the data receiving terminal. For example, when a packet including the same data in the payload is transmitted twice from the data transmission terminal 10 to the data reception terminal 20, and only one of the packets reaches the data reception terminal 20, the packet arrival rate is 50%, the data The arrival rate is 100%.

  Further, the reliability calculation unit 220 may calculate a packet arrival rate for each set of the data transmission terminal 10 and the data reception terminal 20. Further, the reliability calculation unit 220 may calculate the packet arrival rate over the entire network in which one or several data receiving terminals 20 communicate with a plurality of data transmitting terminals 10. Further, the reliability calculation unit 220 may calculate the packet arrival rate for each group by grouping the data transmission terminals 10 with the same number of hops of the wireless when going through the wireless network.

  In addition, the reliability calculation unit 220 may calculate a packet arrival rate for each time period, and may calculate the redundancy including the past packet arrival rate in addition to the current (immediately previous) packet arrival rate. For example, the reliability calculation unit 220 may calculate the redundancy using an average value or an intermediate value of each packet arrival rate calculated within a predetermined time. In addition, when the future network status can be predicted, such as data to be transmitted periodically or a data backup event, the reliability calculation unit 220 may calculate the redundancy based on the future packet arrival rate.

  In the above description, the redundancy of the transmission data is calculated based on the packet arrival rate. Alternatively, the redundancy of the transmission data may be calculated based on the data arrival rate.

Further, the reliability calculation unit 220 can calculate the redundancy that maximizes the communication quality by using the MTU size of the data receiving terminal 20. For example, if the size of the payload of the transmission data is ε, the packet size increases by ε as the redundancy increases by one. Therefore, assuming that the MTU size of the data receiving terminal 20 is γ, the size of the header portion of the transmission data is δ, and the redundancy is m, the reliability calculation unit 220 uses the following Equation 3 to set the redundancy that maximizes the communication quality. The degree can be calculated. For example, it is assumed that the MTU size γ is “256 bytes”, the size δ of the header portion of the transmission data is “39 bytes”, and the size ε of the payload of the transmission data is “6 bytes”. In this case, the redundancy for maximizing the communication quality is calculated as “36” using the following Equation 2. In this case, the maximum number of payloads of transmitted data added as adjustment data is “35”.

  In the above, the redundancy is calculated based on the MTU size. However, the network bandwidth setting value based on the bottleneck bandwidth of the network bandwidth, the bandwidth of the network interface, the usage rate of the network interface, Alternatively, the redundancy may be calculated based on the available network bandwidth.

  In addition, the reliability calculation unit 220 can employ the redundancy within a range determined by the value calculated from Expression 2 and the value calculated from Expression 3. For example, the redundancy may be a value calculated by Expression 2 or a value calculated by Expression 3. Further, the redundancy may be an average value or an intermediate value of these values.

  The reliability transmission unit 230 transmits the redundancy (reliability information) calculated by the reliability calculation unit 220 to the data transmission terminal 10.

  The processing flow of the communication quality control system 1 in this embodiment will be described with reference to FIG. FIG. 4 is a sequence diagram illustrating a processing flow of the communication quality control system 1 according to the first embodiment.

  First, the data transmission terminal 10 acquires reliability information (S102). The data transmitting terminal 10 adds adjustment data to the transmission data based on the reliability information acquired in S102, and generates a packet to be transmitted to the data receiving terminal 20 (S104). Then, the data transmitting terminal 10 transmits the packet generated in S104 to the data receiving terminal 20 (S106).

  The data receiving terminal 20 monitors the reception status of packets transmitted from the data transmitting terminal 10 (S108). The data receiving terminal 20 acquires the packet from the data transmitting terminal 10 or monitors the arrival of the packet from the data transmitting terminal 10 until a predetermined time elapses (S108: NO). On the other hand, when the data receiving terminal 20 acquires a packet from the data transmitting terminal 10 or when a predetermined time elapses (S108: YES), the data receiving terminal 20 determines the reception status (S110). Here, the data receiving terminal 20 determines the reception status based on, for example, packet arrival time, packet sequence number, network interface bandwidth, MTU (Maximum Transmission Unit) size, packet length, number of packets arriving, etc. To do. Which information is actually used to determine the reception status depends on the reliability information calculation method described later. The data receiving terminal 20 calculates reliability information based on the reception status determined in S110 (S112). The data receiving terminal 20 calculates reliability information using, for example, the above Equation 2 or Equation 3. Then, the data receiving terminal 20 transmits the reliability information calculated in S112 to the data transmitting terminal 10 (S114).

  The data transmitting terminal 10 updates the reliability information with the reliability information received from the data receiving terminal 20 (S116). The next time the data transmission terminal 10 transmits a packet, the data transmission terminal 10 generates a packet based on the reliability information updated in S116. In this way, the data transmission terminal 10 can appropriately add adjustment data that satisfies the target data arrival rate.

  As described above, in the present embodiment, the data included in the payload of the transmitted data is acquired as adjustment data based on the reliability information. Then, the acquired adjustment data is added to the transmission data. Then, transmission data including the added adjustment data is transmitted to the data receiving terminal 20.

  As a result, compared to the case where the transmitted data is retransmitted as it is, it is possible to reduce the use bandwidth of the network while realizing the arrival rate of the same data. For example, consider a case in which transmission data having a header portion of 39 bytes and a payload of 6 bytes is transmitted. Here, when the transmission data transmitted first is discarded, when the next transmission data is transmitted and the discarded transmission data is retransmitted as it is, the total bandwidth of 45 bytes + 90 bytes (45 bytes × 2) is 135 bytes. Is required. On the other hand, in the case of this embodiment, the discarded transmission data payload (6 bytes) is added to the next transmission data, so the required bandwidth is a total of 96 bytes of 45 bytes + 51 bytes (45 bytes + 6 bytes). It is. That is, in this case, compared to the case where the discarded transmission data is retransmitted as it is, the network bandwidth can be reduced to about 71%. In addition, since the redundancy of the payload portion including the data body is the same as when the discarded transmission data is retransmitted as it is, the same communication quality as when the discarded transmission data is retransmitted as it is can be guaranteed. .

  Furthermore, according to the present embodiment, the data receiving terminal 20 does not require complicated arithmetic processing, and the configuration of the data receiving terminal 20 for improving communication quality is simplified. Thereby, in the communication quality control system 1, the cost required for improving the data arrival rate can be reduced. In addition, since the arithmetic processing is not complicated, the communication quality can be improved even in the data receiving terminal 20 having a low processing capability.

(Modification of the first embodiment)
In 1st Embodiment mentioned above, the data transmission terminal 10 demonstrated the example which acquires a redundancy as reliability information. The flow in which the data transmission terminal 10 calculates the packet transmission interval based on the acquired redundancy has also been described. However, the data receiving terminal 20 may calculate a packet transmission interval (transmission timing information) in advance based on the redundancy, and transmit the result to the data transmitting terminal 10. In this case, the data transmission terminal 10 acquires the packet transmission interval instead of the redundancy, and generates the packet by adding the adjustment data to the transmission data as described above based on the transmission interval. Then, the data transmitting terminal 10 transmits the generated packet to the data receiving terminal 20. Even if it does in this way, the effect similar to 1st Embodiment can be acquired.

(Second Embodiment)
This embodiment is the same as the first embodiment except for the following points.

  In the first embodiment, the data transmission terminal 10 acquires information based on the redundancy as the reliability information, and improves the data arrival rate using the information based on the redundancy. In the present embodiment, the data transmission terminal 10 acquires a retransmission request of a discarded packet as reliability information, and improves the data arrival rate based on the retransmission request.

  In the present embodiment, the reliability calculation unit 220 determines whether or not packet discard has occurred based on the reception status acquired by the data reception unit 210. For example, the reliability calculation unit 220 determines whether or not packet discard has occurred by confirming a sequence number indicating the order of data and information that can specify data omission similar thereto. This sequence number may be added for each packet, or may be added to each data included in the packet. Further, information that can specify data omission is, for example, time information. When a packet is transmitted from the data transmission terminal 10 at a predetermined time, the reliability calculation unit 220 confirms the time information such as the transmission time and the data acquisition time included in the packet, and the data The presence or absence of missing (packet discard) can be determined. Then, the reliability calculation unit 220 can identify the data corresponding to the missing number as the data to be retransmitted. The reliability transmission unit 230 generates a retransmission request including the data number specified by the reliability calculation unit 220 and transmits the retransmission request to the data transmission terminal 10.

  The acquisition unit 110 recognizes data to be retransmitted based on the retransmission request acquired from the data receiving terminal 20. Then, the data adjustment unit 120 adds retransmission data specified from the retransmission request to the next packet transmitted from the data transmission terminal 10. The retransmission data added here can also be called adjustment data. Then, the data transmission unit 130 transmits the packet added with the retransmission data to the data receiving terminal 20.

  Further, the reliability calculation unit 220 can determine whether or not to discard a packet from the packet transmission timing of the data transmission terminal 10. For example, when packets are transmitted from the data transmission terminal 10 at regular intervals, the reliability calculation unit 220 can determine that packet discard has occurred if the packets do not arrive within a predetermined period. As a specific example, in a system in which a packet is transmitted every 30 minutes from the data transmission terminal 10, if the next packet cannot be acquired even after 30 minutes have elapsed since the previous packet was acquired, the reliability The calculation unit 220 can determine that packet discard has occurred. In this case, the reliability transmission unit 230 generates a packet retransmission request that should have been originally acquired, and transmits the packet retransmission request to the data transmission terminal 10.

  The acquisition unit 110 recognizes whether or not the transmitted packet has been discarded depending on the presence or absence of a retransmission request from the data receiving terminal 20. When receiving a retransmission request from the data receiving terminal 20, the data adjustment unit 120 adds the payload included in the previously transmitted packet as retransmission data when the next packet is transmitted. Then, the data transmission unit 130 transmits the packet added with the retransmission data to the data receiving terminal 20.

  A processing flow of the communication quality control system 1 in this embodiment will be described with reference to FIG. FIG. 5 is a sequence diagram illustrating a processing flow of the communication quality control system 1 according to the second embodiment.

  First, the data transmission terminal 10 generates a packet to be transmitted to the data reception terminal 20 (S202). Then, the data transmitting terminal 10 transmits the packet generated in S202 toward the data receiving terminal (S204).

  The data receiving terminal 20 monitors whether the packet transmitted from the data transmitting terminal 10 has been discarded in the middle (S206). For example, the data receiving terminal 20 checks the sequence number added to the packet that has reached the data receiving terminal 20 and determines whether there is no data loss. Here, when there is data loss, the data receiving terminal 20 can determine that the packet has been discarded. In addition, even when the packet has not reached even after a predetermined time has elapsed, the data receiving terminal 20 can determine that the packet has been discarded. If it is determined that the packet has been discarded (S206: YES), the data receiving terminal 20 generates a retransmission request for the packet (S208). For example, the data receiving terminal 20 generates an instruction to include the data included in the packet transmitted this time in the number of data to be retransmitted or the data to be transmitted next as a retransmission request. Then, the data receiving terminal 20 transmits the retransmission request generated in S208 to the data transmitting terminal 10 (S210). The data transmission terminal 10 that has received the retransmission request generates retransmission data to be included in the next packet to be transmitted (S212). When the data transmitting terminal 10 generates a packet to be transmitted next, the data transmitting terminal 10 generates a packet including the retransmission data generated in S212 (S202), and transmits the packet to the data receiving terminal 20 (S204).

  As described above, also according to this embodiment, the same effect as that of the first embodiment can be obtained. In addition, according to the present embodiment, only data that needs to be retransmitted can be made redundant, so that it is possible to further reduce the network bandwidth required for improving the communication quality.

(Third embodiment)
In the present embodiment, a specific use case using a meter compliant with ECHONET Lite is shown. Specifically, a use case in which a smart power meter class having a class group code “0x02” and a class code “0x88” is used to notify the server of meter values every 30 minutes is shown. For example, in this smart energy meter class, when EPC (ECHONET Property Code) is “0xE2,” the accumulated power measurement value for the past 24 hours (measured in the positive direction) is measured every 30 minutes. Value). In the present embodiment, the meter corresponds to the data transmission terminal 10, and the server corresponds to the data reception terminal 20. FIG. 6 is a diagram illustrating an operation concept of the communication quality control system 1 according to the third embodiment.

  Here, the header format of ECHONET Lite is shown in FIG. In the case of transmitting data conforming to ECHONET Lite shown in FIG. 7, a set of EPC, PDC, and EDT corresponds to the payload portion. Therefore, the embodiment described above can be applied.

  First, a specific example when this use case is realized by a modification of the first embodiment will be described.

  First, the server calculates the packet arrival rate of packets transmitted from the meter. Here, it is assumed that the packet arrival rate is calculated as 60%. Further, it is assumed that the target data arrival rate is set to 95%. At this time, the server calculates the redundancy as 4 using the above equation 2. Next, the server calculates the transmission timing of the transmission data using this redundancy. Here, when the EPC is “0xE2”, 48 payloads are included in the transmission data. When the number of payloads is substituted into the above equation 1, the transmission timing of transmission data is calculated as 6 hours. Therefore, the server transmits information indicating the transmission timing every 6 hours as reliability information, and requests a measurement result history of the integrated electric energy. Specifically, the server generates, as reliability information, a packet with EHD1 = 0x01, EHD2 = 0x81, DEOJ = 0x288 ** (** is an instance code), ESV = 0x62, EPC = 0xE2, PDC = 194 . The meter generates a packet every 6 hours based on the received reliability information and transmits it to the server. Specifically, the meters are EHD1 = 0x01, EHD2 = 0x81, DEOJ = 0x288 ** (** is an instance code), ESV = 0x72, EPC = 0xE2, PDC = 194, EDT = *** (every 30 minutes A packet having a measured meter value × 48) is generated and transmitted to the server. By doing in this way, each data measured with the meter every 30 minutes will be transmitted to a server 4 times in total.

  As a result, it is possible to reduce the network bandwidth while increasing the arrival rate of the data measured by the meter.

  Next, a specific example when this use case is realized in the second embodiment will be described.

  The server monitors whether or not a packet transmitted from the meter has arrived. Here, it is assumed that a packet including a measurement result history of integrated power consumption is transmitted at 0:00 AM every day. Then, in the server, for example, when the packet does not reach before AM 1:00, the server determines that the packet discard has occurred, for example, generates a packet including a flag notifying that the packet discard has occurred. Send to meter. When the meter receives from the server that packet discard has occurred, the meter generates retransmission data to be included in the next transmitted packet from the previously transmitted packet. Then, a packet including retransmission data is transmitted to the server. At this time, the current data and the previous data may be distinguished according to the order of the data contained in the payload. Further, the current data and the previous data may be distinguished by a unique command. Further, an unused value in the ECHONET device object detailed specification may be assigned to the EPC included in the retransmission data to distinguish the current data from the previous data. As a specific example, an unused value “0xF1” is defined as indicating 48 data measured every 30 minutes during 24 hours from 24 hours before to 48 hours ago. Then, by assigning “0xF1” to the EPC of the previous data and inserting it into the EDATA of the packet to be transmitted this time, it is possible to generate one packet that can distinguish the current data from the previous data.

  As a result, it is possible to reduce the network bandwidth while increasing the data arrival rate when retransmitting the data of the discarded packet in response to the retransmission request.

  In the above example, ECHONET Lite is used. However, since the ECHONET device object detailed specification of APPENDIX is the same for ECHONET and ECHONET Lite, it can also be applied when ECHONET is used.

  Further, here, the case where the EPC of the smart power meter class is “0xE2” has been described as an example, but other values may be used for the EPC. For example, EPC may be “0x04”. Here, the EPC “0xE4” is a code for acquiring the integrated power amount measurement value in the reverse direction for the past 24 hours, which is measured every 30 minutes.

  Further, here, the smart power meter class has been described as an example, but other classes may be used as long as they are similar applications. For example, an electric energy sensor class (class group code = 0x00, class code = 0x22), an electric energy meter class (class group code = 0x02, class code = 0x80), a water flow meter class (class group code = 0x02, class code = 0x81), gas meter class (class group code = 0x02, class code = 0x82), distribution board metering class (class group code = 0x02, class code = 0x87), smart gas meter class (class group code = 0x02, class code = 0x89) can be used.

  As mentioned above, although embodiment of this invention was described with reference to drawings, these are the illustrations of this invention, Various structures other than the above are also employable.

  In the sequence diagram used in the above description, a plurality of steps (processes) are described in order, but the execution order of the steps executed in each embodiment is not limited to the description order. In each embodiment, the order of the illustrated steps can be changed within a range that does not hinder the contents. Moreover, each above-mentioned embodiment can be combined in the range in which the content does not conflict.

In addition, according to embodiment mentioned above, the following invention is disclosed.
(Appendix 1)
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A data transmission terminal.
(Appendix 2)
The acquisition means acquires the redundancy of the transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the redundancy of the transmission data.
The data transmission terminal according to attachment 1.
(Appendix 3)
The acquisition means acquires timing information indicating a timing of transmitting the data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the timing information.
The data transmission terminal according to appendix 1 or 2.
(Appendix 4)
The acquisition means acquires a retransmission request of transmitted data that is already transmitted transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the transmitted data corresponding to the retransmission request;
The data transmission terminal according to any one of supplementary notes 1 to 3.
(Appendix 5)
The data adjustment means adds information included in the payload of the transmitted data to the transmission data as the adjustment data.
The data transmission terminal according to any one of supplementary notes 1 to 4.
(Appendix 6)
The format of the transmission data is at least one of an ECHONET format and an ECHONET Lite format.
The data transmission terminal according to any one of appendices 1 to 5.
(Appendix 7)
Comprising at least one data transmitting terminal and at least one data receiving terminal;
The data transmission terminal is
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
Have
The data receiving terminal is
Data receiving means for receiving the transmission data;
Reliability calculation means for calculating the reliability information based on the reception status of the transmission data;
Reliability transmission means for transmitting the reliability information calculated by the reliability calculation means to the data transmission terminal;
A communication quality control system.
(Appendix 8)
The data sending terminal
Obtain reliability information indicating the communication quality of the transmission data to be transmitted to the data receiving terminal,
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. To
Transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A communication quality control method.
(Appendix 9)
Computer
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
Program to function as.
(Appendix 10)
The transmission data is an EPC (ECHONET Property Code) that specifies a service target in the ECHONET format or ECHONET Lite format, and includes an electric energy sensor class, an electric energy meter class, a water flow meter class, a gas meter class, and a distribution board metering class. Use at least one of a code indicating a smart meter class and a smart gas meter class,
The data transmission terminal according to attachment 6.
(Appendix 11)
The acquisition means acquires the redundancy of the transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the redundancy of the transmission data.
The communication quality control system according to appendix 7.
(Appendix 12)
The acquisition means acquires timing information indicating a timing of transmitting the data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the timing information.
The communication quality control system according to appendix 7 or 11.
(Appendix 13)
The acquisition means acquires a retransmission request of transmitted data that is already transmitted transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the transmitted data corresponding to the retransmission request;
The communication quality control system according to any one of appendices 7, 11, and 12.
(Appendix 14)
The data adjustment means adds information included in the payload of the transmitted data to the transmission data as the adjustment data.
The communication quality control system according to any one of supplementary notes 7 and 11 to 13.
(Appendix 15)
The format of the transmission data is at least one of an ECHONET format and an ECHONET Lite format.
The communication quality control system according to any one of supplementary notes 7 and 11 to 14.
(Appendix 16)
The transmission data is an EPC (ECHONET Property Code) that specifies a service target in the ECHONET format or ECHONET Lite format, and includes an electric energy sensor class, an electric energy meter class, a water flow meter class, a gas meter class, and a distribution board metering class. Use at least one of a code indicating a smart meter class and a smart gas meter class,
The communication quality control system according to attachment 15.
(Appendix 17)
The reliability calculation means includes
Calculating the reliability information based on at least one of network load and communication quality between the data transmitting terminal and the data receiving terminal;
The communication quality control system according to any one of supplementary notes 7 and 11 to 16.
(Appendix 18)
The data receiving means includes
Reception of the transmission data based on at least one of a data number indicating the order of data included in the transmission data and a data arrival prediction time indicating a prediction time when the transmission data arrives from the data transmission terminal Judge the situation,
18. The communication quality control system according to any one of appendices 7 and 11 to 17.
(Appendix 19)
The reliability calculation means includes
A packet arrival rate indicating a bandwidth of a communication speed bottleneck in communication between the data transmission terminal and the reception data terminal, a maximum value of the transmission data, and an arrival rate of a packet transmitted from the data transmission terminal to the data reception terminal And, based on at least one of the data arrival rates indicating the arrival rate of data included in the packet, the redundancy of the transmission data is calculated as the reliability information.
The communication quality control system according to any one of appendices 7 and 11 to 18.
(Appendix 20)
The reliability calculation means includes
A data arrival rate of the entire network composed of a plurality of the data transmission terminals and at least one data reception terminal, a data arrival rate for each group when grouped with the same number of hops in the network, and the data transmission terminal Calculating the redundancy of the transmission data as the reliability information based on the data arrival rate in any one or more of the data arrival rates for each combination of the data receiving terminal and
The communication quality control system according to any one of supplementary notes 7 and 11 to 19.
(Appendix 21)
The data transmission terminal is
Obtaining the redundancy of the transmission data as the reliability information,
Adding the adjustment data to the transmission data based on the redundancy of the transmission data;
The communication quality control method according to appendix 8, including the above.
(Appendix 22)
The data transmission terminal is
Obtaining timing information indicating the timing of transmitting the data as the reliability information;
Adding the adjustment data to the transmission data based on the timing information;
The communication quality control method according to appendix 8 or 21, including the above.
(Appendix 23)
The data transmission terminal is
Obtaining a retransmission request of transmitted data that is already transmitted data as the reliability information,
Adding the adjustment data to the transmission data based on the transmitted data corresponding to the retransmission request;
The communication quality control method according to any one of supplementary notes 8, 21, and 22.
(Appendix 24)
The data transmission terminal is
Adding information included in the payload of the transmitted data to the transmission data as the adjustment data;
The communication quality control method according to any one of appendices 8 and 21 to 23.
(Appendix 25)
The format of the transmission data is at least one of an ECHONET format and an ECHONET Lite format.
The communication quality control method according to any one of supplementary note 8 and 21 to 24.
(Appendix 26)
The transmission data is an EPC (ECHONET Property Code) that specifies a service object in the ECHONET format or ECHONET Lite format, and includes an electric energy sensor class, an electric energy meter class, a water flow meter class, a gas meter class, and a distribution board metering class. Use at least one of a code indicating a smart meter class and a smart gas meter class,
The communication quality control method according to supplementary note 25.
(Appendix 27)
The computer,
Means for obtaining redundancy of the transmission data as the reliability information;
Means for adding the adjustment data to the transmission data based on the redundancy of the transmission data;
The program according to appendix 9 for functioning as
(Appendix 28)
The computer,
Means for acquiring timing information indicating timing for transmitting the data as the reliability information;
Means for adding the adjustment data to the transmission data based on the timing information;
The program according to appendix 9 or 27 for functioning as:
(Appendix 29)
The computer,
Means for acquiring, as the reliability information, a retransmission request for transmitted data that is already transmitted data;
Means for adding the adjustment data to the transmission data based on the transmitted data corresponding to the retransmission request;
The program according to any one of Supplementary Notes 9, 27, and 28 for functioning as:
(Appendix 30)
The computer,
Means for adding information contained in the payload of the transmitted data to the transmission data as the adjustment data;
The program according to any one of appendixes 9 and 27 to 29 for functioning as:
(Appendix 31)
The computer,
Means for using at least one of ECHONET format and ECHONET Lite format as the format of the transmission data;
The program according to any one of Supplementary Notes 9 and 27 to 30 for functioning as:

DESCRIPTION OF SYMBOLS 1 Communication quality control system 10 Data transmission terminal 110 Acquisition part 120 Data adjustment part 130 Data transmission part 20 Data reception terminal 210 Data reception part 220 Reliability calculation part 230 Reliability transmission part 30 Network

Claims (9)

Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A data transmission terminal. The acquisition means acquires the redundancy of the transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the redundancy of the transmission data.
The data transmission terminal according to claim 1. The acquisition means acquires timing information indicating a timing of transmitting the data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the timing information.
The data transmission terminal according to claim 1 or 2. The acquisition means acquires a retransmission request of transmitted data that is already transmitted transmission data as the reliability information,
The data adjustment means adds the adjustment data to the transmission data based on the transmitted data corresponding to the retransmission request;
The data transmission terminal according to any one of claims 1 to 3. The data adjustment means adds information included in the payload of the transmitted data to the transmission data as the adjustment data.
The data transmission terminal according to any one of claims 1 to 4. The format of the transmission data is at least one of an ECHONET format and an ECHONET Lite format.
The data transmission terminal according to any one of claims 1 to 5. Comprising at least one data transmitting terminal and at least one data receiving terminal;
The data transmission terminal is
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to,
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
Have
The data receiving terminal is
Data receiving means for receiving the transmission data;
Reliability calculation means for calculating the reliability information based on the reception status of the transmission data;
Reliability transmission means for transmitting the reliability information calculated by the reliability calculation means to the data transmission terminal;
A communication quality control system. The data sending terminal
Obtain reliability information indicating the communication quality of the transmission data to be transmitted to the data receiving terminal,
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. To
Transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
A communication quality control method. Computer
Obtaining means for obtaining reliability information indicating communication quality of transmission data to be transmitted to the data receiving terminal;
Based on the acquired reliability information, adjustment data excluding a portion that can be shared with the transmission data in the transmitted data that has already been transmitted to the data receiving terminal is used as the transmission data. Data adjustment means to be added to
Data transmission means for transmitting the transmission data to which the adjustment data is added to the data receiving terminal;
Program to function as.

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