JP6518103B2 - INFORMATION COLLECTING DEVICE, SENSOR NODE, AND INFORMATION COLLECTING SYSTEM COMPRISING THEM - Google Patents

Description

  The present invention relates to an information collection device, a sensor node, and an information collection system provided with them.

  Conventionally, a wearable terminal provided with a sensor capable of measuring vital information such as heart rate, pulse and exercise amount is known (Patent Document 1).

  In addition, terminals that display vital information and wearable terminals that sense vital information are mainly one-to-one, and the distance between these terminals is about several meters.

JP, 2014-168685, A

  When it is considered to collect vital information from a person who is exercising, it is appropriate to collect vital information by wireless communication, but when there are a large number of exercisers in a limited area, the wireless band is insufficient. Also, depending on the position of the exerciser, it may be assumed that sufficient communication speed can not be secured or it is out of reach.

  Therefore, according to the embodiment of the present invention, it is possible to provide an information collecting apparatus capable of collecting sensor information accurately even if there are a large number of mobiles.

  In addition, according to the embodiment of the present invention, a sensor node capable of accurately transmitting sensor information even if the number of mobile bodies becomes large is provided.

  Furthermore, according to the embodiment of the present invention, it is possible to provide an information collecting system capable of collecting sensor information accurately even if there are a large number of mobiles.

  According to the embodiment of the present invention, the information collecting apparatus comprises the receiving means. The receiving means includes a first wireless communication according to a first wireless communication standard having a first communication area and a second wireless communication according to a second wireless communication standard having a second communication area wider than the first communication area. Sensor information including at least information on a mobile unit is received from a plurality of sensor nodes installed in the mobile unit by wireless communication excluding at least any of communication and excluding multi-hop communication by second wireless communication.

  The information collection apparatus receives sensor information from a plurality of sensor nodes by wireless communication using at least the first wireless communication or the second wireless communication except for multi-hop communication by the second wireless communication. As a result, concentration of the wireless communication used for transmitting the sensor information on the second wireless communication is suppressed, and the band shortage of the second wireless communication is suppressed.

  Therefore, even if there are a large number of moving objects, sensor information can be accurately collected.

  Further, according to the embodiment of the present invention, the sensor node is a sensor node installed in a mobile unit existing in the second communication area centering on the information collection device according to claim 1, A generation unit and a transmission unit are provided. The generation means generates first sensor information including information on the mobile. The transmitting means uses at least one of the first and second wireless communications described in Configuration 1 for the first sensor information generated by the generating means, and excludes multi-hop communications by the second wireless communication. Transmit to the information collection apparatus by wireless communication.

  The sensor node transmits sensor information to the information collection device by wireless communication using at least the first wireless communication or the second wireless communication except multi-hop communication by the second wireless communication. As a result, concentration of the wireless communication used for transmitting the sensor information on the second wireless communication is suppressed, and the band shortage of the second wireless communication is suppressed.

  Therefore, even if there are a large number of mobile units, sensor information can be accurately transmitted to the information collection device.

Furthermore, according to the embodiment of the present invention, the information collection system
An information collecting apparatus according to any one of claims 1 to 7;
The sensor node according to any one of claims 8 to 14,
And a display device for displaying the information collected by the information collection device.

  Therefore, information can be accurately collected from the sensor node, and the collected information can be displayed on the display device.

  Even if there are a large number of moving objects, sensor information can be accurately collected.

FIG. 1 is a schematic view of an information collection system according to an embodiment of the present invention. It is the schematic of the sensor node shown in FIG. It is the schematic of the information gathering apparatus shown in FIG. It is a block diagram of sensor information. It is a block diagram of advice information. It is a figure which shows the 1st example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows the 1st example of the information gathering method in the information gathering system shown in FIG. It is a figure which shows the 2nd example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows the 2nd example of the information gathering method in the information gathering system shown in FIG. It is a figure which shows the 3rd example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows the 3rd example of the information gathering method in the information gathering system shown in FIG. It is another flowchart which shows the 3rd example of the information gathering method in the information gathering system shown in FIG. It is a figure which shows the 4th example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows operation | movement of the relay node in the 4th example of the information gathering method. In the 4th example of an information gathering method, it is a flow chart which shows operation of a sensor node which transmits sensor information to a relay node. It is a figure which shows the 5th example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows the 5th example of the information gathering method in the information gathering system shown in FIG. It is a figure which shows the 6th example of the information gathering method in the information gathering system shown in FIG. It is a flowchart which shows the 6th example of the information gathering method in the information gathering system shown in FIG. It is another block diagram of advice information. It is a figure which shows various wireless communication standards. It is a figure which shows the combination of radio | wireless communication RF1 and radio | wireless communication RF2.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding portions are denoted by the same reference characters and description thereof will not be repeated.

  FIG. 1 is a schematic view of an information collecting system according to an embodiment of the present invention. Referring to FIG. 1, an information collection system 10 according to the embodiment of the present invention includes sensor nodes 1 to 7, an information collection device 8, and a display device 9.

  The sensor nodes 1 to 7, the information collection device 8 and the display device 9 are disposed in the wireless communication space.

  Each of the sensor nodes 1 to 7, the information collection device 8 and the display device 9 transmits and receives information using, for example, wireless communication according to either the BLE (Bluetooth Low Energy) standard or the IEEE 802.11ah standard.

  The BLE standard has a 2.4 GHz frequency band and the IEEE 802.11ah standard has a 900 MHz frequency band. Thus, the BLE standard and the IEEE 802.11ah standard are wireless communication standards with different characteristics.

  Also, the BLE standard has a transmission distance of, for example, 10 m, and the IEEE 802.11ah standard has a transmission distance of, for example, 1 km or more. Furthermore, the BLE standard has a bandwidth of 80 MHz in the range of 2401 MHz to 2481 MHz, for example, and the IEEE 802.11ah standard has a bandwidth of 14 MHz in the range of 915.8 MHz to 929.8 MHz, for example.

  Thus, the IEEE 802.11ah standard has a wider communication area than the BLE standard and has a narrower bandwidth than the BLE standard.

  In the following, wireless communication according to the BLE standard is referred to as “wireless communication RF1”, and wireless communication according to the IEEE 802.11ah standard is referred to as “wireless communication RF2”.

  The sensor nodes 1 to 7 exist in the communication area of the IEEE 802.11ah standard centering on the information collection device 8. That is, when the information collection device 8 uses the wireless communication RF2, the sensor nodes 1 to 7 exist in an area where information can be directly received from the information collection device 8. And each of the sensor nodes 1-7 is installed in the person who is moving, for example. More specifically, each of the sensor nodes 1 to 7 is installed, for example, at a person who is taking physical education classes at a school.

  Each of the sensor nodes 1 to 7 detects vital information IF_VTL such as the heart rate and the temperature of the person in which the sensor nodes 1 to 7 are installed. Also, each of the sensor nodes 1 to 7 detects its own position information IF_PST and its own moving speed V_Mv. Furthermore, each of the sensor nodes 1 to 7 detects its own remaining battery level BR.

  Each of the sensor nodes 1 to 7 receives the advice information from the information collection device 8 using the wireless communication RF2.

  Each of the sensor nodes 1 to 7 selects one of the wireless communication RF1 and the wireless communication RF2 by a method described later based on the received advice information, and selects the selected wireless communication (the wireless communication RF1 and the wireless communication RF2). And transmits to the information collecting apparatus 8 sensor information SIF including vital information IF_VTL, own position information IF_PST, own moving speed V_Mv and battery remaining amount BR.

  In this case, the sensor nodes 1 to 3 directly transmit the sensor information SIF to the information collecting apparatus 8 using one of the wireless communication RF1 and the wireless communication RF2.

  The sensor nodes 4 to 7 transmit the sensor information SIF to the information collection device 8 via the sensor node 3 using one of the wireless communication RF1 and the wireless communication RF2.

  The information collection device 8 receives sensor information SIF from the sensor nodes 1 to 7 using either the wireless communication RF1 or the wireless communication RF2, and stores the received sensor information SIF.

  The information collection device 8 generates topology information of the sensor nodes 1 to 7 and the information collection device 8 based on a plurality of sensor information SIF received from the sensor nodes 1 to 7. More specifically, the information collection device 8 detects the sensor nodes 1 to 7 based on the position information IF_PST and the movement speed V_Mv of the sensor nodes 1 to 7 included in the plurality of sensor information SIF and the position information IF_PST of its own. And the relative positional relationship between the information collecting devices 8 and the topology of the sensor nodes 1 to 7 and the information collecting device 8 based on the positional information IF_PST of the sensor nodes 1 to 7 and the moving speed V_Mv and the relative positional relationship. To detect In this case, the information collection device 8 detects the topology in consideration of the positions of the sensor nodes 1 to 7 after the movement based on the moving speeds V_Mv of the sensor nodes 1 to 7. Then, the information collection device 8 generates topology information indicating the detected topology.

  The information collection device 8 also determines the transmission amount TXV and the transmission interval TXITV of the sensor information SIF to be transmitted by each of the sensor nodes 1 to 7 based on the plurality of sensor information SIF.

  Then, the information collection device 8 is mounted on the generated topology information, the transmission amount TXV and transmission interval TXITV of the sensor information SIF, the frequency f to be used by the sensor nodes 1 to 7, and the sensor nodes 1 to 7 Advice information AvIF1 including a sensor, a GPS (Global Positioning System), and an instruction signal instructing on / off of the acceleration sensor is generated.

  Then, the information collection device 8 broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 using the wireless communication RF2.

  Further, the information collection device 8 transmits vital information IF_VTL included in the sensor information SIF to the display device 9 by wireless communication or wire communication.

  The display device 9 receives vital information IF_VTL from the information collecting device 8, and AR-displays the received vital information IF_VTL. That is. The display device 9 displays vital information IF_VTL superimposed on a real landscape.

  FIG. 2 is a schematic view of the sensor node 1 shown in FIG. Referring to FIG. 2, sensor node 1 includes wireless modules 11 and 12, microcomputer 13, heart rate sensor 14, temperature sensor 15, acceleration sensor 16, GPS 17, and rechargeable battery 18.

  Each of the wireless modules 11 and 12, the microcomputer 13, the heart rate sensor 14, the body temperature sensor 15, the acceleration sensor 16 and the GPS 17 is driven by the power from the rechargeable battery 18. The power consumption of the sensor node 1 is, for example, several mW.

  The wireless module 11 receives, from the microcomputer 13, the sensor information SIF, the transmission amount TXV of the sensor information SIF, the transmission interval TXITV of the sensor information SIF, and the frequency f_1. Then, the wireless module 11 selects a frequency matching the frequency f_1 from the 2.4 GHz band, and transmits the sensor information SIF using the wireless communication RF1 at the selected frequency. In this case, the wireless module 11 transmits the sensor information SIF in accordance with the transmission amount TXV and the transmission interval TXITV of the sensor information SIF received from the information collection device 8.

  The wireless module 12 receives, from the microcomputer 13, the sensor information SIF, the transmission amount TXV of the sensor information SIF, the transmission interval TXITV of the sensor information SIF, and the frequency f_2. Then, the wireless module 12 selects a frequency matching the frequency f_2 from the 900 MHz band, and transmits the sensor information SIF using the wireless communication RF2 at the selected frequency. In this case, the wireless module 12 transmits the sensor information SIF in accordance with the transmission amount TXV and the transmission interval TXITV of the sensor information SIF received from the information collection device 8.

  The wireless module 11 or the wireless module 12 transmits the sensor information SIF, for example, at a transmission interval TXITV of 10 seconds.

  The microcomputer 13 receives the advice information AvIF 1 from the wireless module 12. Then, the microcomputer 13 selects one of the BLE standard and the IEEE 802.11ah standard based on the topology information of the sensor nodes 1 to 7 included in the advice information AvIF1.

  More specifically, when the microcomputer 13 determines that the sensor node 1 exists in the communication area of the wireless communication RF1 centering on the information collecting apparatus 8 based on the topology information, the microcomputer 13 selects the wireless communication RF1 and detects the sensor When it is determined that the node 1 exists outside the communication area of the wireless communication RF1 and within the communication area of the wireless communication RF2 centering on the information collecting apparatus 8, the wireless communication RF2 is selected.

  Further, the microcomputer 13 advises the heartbeat sensor 14, the temperature sensor 15, the acceleration sensor 16 and an instruction signal instructing the GPS 17 to turn on / off, the transmission amount TXV of the sensor information SIF, and the transmission interval TXITV of the sensor information SIF and the frequency f. It detects from information AvIF1.

  Further, the microcomputer 13 receives the heart rate HR from the heart rate sensor 14, receives the body temperature BT from the body temperature sensor 15, receives the moving speed V_Mv from the acceleration sensor 16, receives the position information IF_PST from the GPS 17, and receives the battery remaining from the rechargeable battery 18. Receive the amount BR. Then, the microcomputer 13 generates sensor information SIF including the heart rate HR, the body temperature BT, the moving speed V_Mv, the position information IF_PST, and the battery remaining amount BR. Then, to the wireless module (one of wireless modules 11 and 12) that performs wireless communication (one of wireless communication RF1 or RF2) selected by the above-described method among the wireless communication RF1 and the wireless communication RF2. The sensor information SIF, the transmission amount TXV of the sensor information SIF, and the transmission interval TXITV of the sensor information SIF are output.

  Further, the microcomputer 13 turns on or off the heart rate sensor 14, the temperature sensor 15, the acceleration sensor 16 and the GPS 17 based on the instruction signal received from the information acquisition device 8.

  The heart rate sensor 14 detects the heart rate HR of the person in which the sensor node 1 is installed, and outputs the detected heart rate HR to the microcomputer 13.

  The body temperature sensor 15 detects the body temperature BT of the person in which the sensor node 1 is installed, and outputs the detected body temperature BT to the microcomputer 13.

  The acceleration sensor 16 detects the moving velocity V_Mv of the sensor node 1 and outputs the detected moving velocity V_Mv to the microcomputer 13.

  The GPS 17 detects the position information IF_PST of the sensor node 1 and outputs the detected position information IF_PST to the microcomputer 13.

  The rechargeable battery 18 supplies power to the wireless modules 11 and 12, the microcomputer 13, the heart rate sensor 14, the temperature sensor 15, the acceleration sensor 16 and the GPS 17.

  The sensor nodes 2 to 7 shown in FIG. 1 also have the same configuration as the sensor node 1 shown in FIG.

  FIG. 3 is a schematic view of the information collecting apparatus 8 shown in FIG. Referring to FIG. 3, the information collection device 8 includes wireless modules 81 and 82, a CPU (Central Processing Unit) 83, a GPS 84, a nonvolatile database (DB) 85, and a LAN (Local Area Network) 86. And a power supply 87.

  Each of the wireless modules 81 and 82, the CPU 83, the GPS 84, the non-volatile DB 85, and the LAN 86 is driven by the power from the power supply 87.

  The wireless module 81 receives the sensor information SIF by the wireless communication RF1, and outputs the received sensor information SIF to the CPU 83.

  Upon receiving the advice information AvIF1 from the CPU 83, the wireless module 82 broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 by wireless communication RF2.

  Further, the wireless module 82 receives the sensor information SIF by the wireless communication RF2, and outputs the received sensor information SIF to the CPU 83.

  The CPU 83 receives the sensor information SIF from the wireless module 81 or the wireless module 82, and stores the received sensor information SIF in the non-volatile DB 85. In addition, the CPU 83 receives the position information IF_PST of the information collecting device 8 from the GPS 84.

  Then, the CPU 83 reads the sensor information SIF stored in the non-volatile DB 85, and detects the position information IF_PST and the moving speed V_Mv of the sensor nodes 1 to 7 based on the read sensor information SIF.

  Then, the CPU 83 detects the relative positional relationship between the sensor nodes 1 to 7 and the information collecting device 8 based on the position information IF_PST and the moving speed V_Mv of the sensor nodes 1 to 7 and the position information IF_PST of the information collecting device 8. . Then, the CPU 83 is a sensor based on the position information IF_PST and the moving speed V_Mv of the sensor nodes 1 to 7, the position information IF_PST of the information collecting device 8, and the relative position relationship between the sensor nodes 1 to 7 and the information collecting device 8. The topology of the nodes 1 to 7 and the information collection device 8 is detected, and topology information indicating the detected topology is generated.

  Further, the CPU 83 selects the frequency f to be used by the sensor nodes 1 to 7. More specifically, when the sensor nodes 1 to 7 use the wireless communication RF1, the CPU 83 selects an arbitrary frequency f_1 in the 2.4 GHz band as a frequency to be used by the sensor nodes 1 to 7 and sets the sensor nodes 1 to 1 When 7 uses the wireless communication RF2, an arbitrary frequency f_2 in the 900 MHz band is selected as a frequency to be used by the sensor nodes 1 to 7.

  Further, the CPU 83 determines the transmission amount TXV of the sensor information SIF and the transmission interval TXITV. More specifically, the CPU 83 detects the amount of sensor information SIF and the amount of change, and based on the detected amount of sensor information SIF and the amount of change, the path from each sensor node 1 to 7 to the information collection device 8 The transmission amount TXV and the transmission interval TXITV of the sensor information SIF are determined for each of the sensor nodes 1 to 7 so that the wireless communication in the second embodiment does not run out of bandwidth.

  Further, the CPU 83 detects the battery remaining amount BR from the sensor information SIF, and based on the detected battery remaining amount BR, the heart rate sensor 14, the body temperature sensor 15, the acceleration sensor 16 and each sensor node 1 to 7 are An instruction signal instructing on / off of the GPS 17 is generated.

  Then, the CPU 83 turns on / off the topology information, the frequency f (f_1, f_2) that each sensor node 1 to 7 should use, the transmission amount TXV of the sensor information SIF, the transmission interval TXITL of the sensor information SIF, and the heart rate sensor 14 etc. And generates the advice information AvIF1 including an instruction signal for instructing the wireless module 82, and outputs the generated advice information AvIF1 to the wireless module 82.

  Furthermore, when the CPU 83 receives an output request for information from the display device 9 via the LAN 86, it reads the heart rate HR and the body temperature BT from the sensor information SIF stored in the non-volatile DB 85, and reads the read heart rate HR and the body temperature BT. Are transmitted to the display device 9 via the LAN 86.

  The GPS 84 detects the position information IF_PST of the information collecting device 8, and outputs the detected position information IF_PST to the CPU 83.

  Nonvolatile DB 85 stores sensor information SIF.

  The LAN 86 is a wired LAN or a wireless LAN. Then, the LAN 86 establishes a communication link with the display device 9 by a wired LAN or a wireless LAN.

  FIG. 4 is a configuration diagram of the sensor information SIF. Referring to FIG. 4, sensor information SIF includes an address and a data area. The address and data areas are associated with each other.

  The address is an address of one of the sensor nodes 1 to 7. The data area includes a heart rate HR, a body temperature BT, position information IF_PST, a moving speed V_Mv, and a remaining battery charge BR.

  As described above, the heart rate HR, the body temperature BT, the position information IF_PST, the moving speed V_Mv, and the remaining battery charge BR are associated with the address of the sensor node (any of the sensor nodes 1 to 7). The heart rate HR, the body temperature BT, the position information IF_PST, the moving speed V_Mv, and the remaining battery charge BR are stored in association with the respective addresses of the sensor nodes 1 to 7.

  FIG. 5 is a block diagram of the advice information AvIF1. Referring to FIG. 5, the advice information AvIF1 includes a broadcast address and a data area. The broadcast address and data area are associated with each other.

  The broadcast address is an address for transmitting the advice information AvIF 1 to all of the sensor nodes 1 to 7.

  The data area includes topology information, frequency f, transmission amount TXV of sensor information SIF, transmission interval TXITV of sensor information SIF, and an instruction signal IST instructing on / off of the heart rate sensor 14 or the like.

  The topology information is composed of information for constructing a topology indicating a wireless link between the sensor nodes 1 to 7 and the information collection device 8.

  The frequency f is composed of a frequency f_1 associated with the wireless communication RF1 and a frequency f_2 associated with the wireless communication RF2.

  The transmission amount TXV of the sensor information SIF is composed of the addresses Add1 to Add7 of the sensor nodes 1 to 7 and the transmission amounts TXV1 to TXV7 associated with the addresses Add1 to Add7 of the sensor nodes 1 to 7.

  The transmission interval TXITV of the sensor information SIF is composed of the addresses Add1 to Add7 of the sensor nodes 1 to 7, and the transmission intervals TXITV1 to TXITV7 associated with the addresses Add1 to Add7 of the sensor nodes 1 to 7.

  The instruction signal IST includes the addresses Add1 to Add7 of the sensor nodes 1 to 7 and the instruction signals IST1 to IST7 associated with the addresses Add1 to Add7 of the sensor nodes 1 to 7. The instruction signals IST1 to IST7 are signals indicating on or off associated with the heart rate sensor 14, the body temperature sensor 15, the acceleration sensor 16 and the GPS 17, and the heart rate sensor 14, the body temperature sensor 15, the acceleration sensor 16 and the GPS 17. It consists of

  FIG. 6 is a diagram showing a first example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 6, sensor nodes 1 to 7 are present in region REG1. The area REG1 is an area from which the information can be received by the wireless communication RF2 from the information collecting apparatus 8. The CPU 83 of the information collecting device 8 determines an area REG2 in which the sensor information SIF can be transmitted (or transferred) by the wireless communication RF1 based on the position information IF_PST of the information collecting device 8 received from the GPS 84. Then, the CPU 83 of the information collection device 8 generates area information IF_REG1 indicating the determined area REG2. Further, as described above, the CPU 83 of the information collection device 8 determines the frequency f, the transmission amount TXV of the sensor information SIF, and the transmission interval TXITV of the sensor information SIF, and generates the instruction signal IST.

  Then, the CPU 83 of the information collection device 8 stores the area information IF_REG1 and the position information IF_PST of the information collection device 8 in the topology information, and transmits the frequency f, the transmission amount TXV of the sensor information SIF, the transmission interval TXITV of the sensor information SIF and the instruction The signal IST is added to generate the advice information AvIF1.

  Then, the CPU 83 of the information collection device 8 outputs the advice information AvIF 1 to the wireless module 82.

  The wireless module 82 of the information collection device 8 stores the broadcast address in the advice information AvIF1 received from the CPU 83, and broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 by the wireless communication RF2.

  The wireless module 12 of each of the sensor nodes 1 to 7 receives the advice information AvIF1 by the wireless communication RF2, and outputs the received advice information AvIF1 to the microcomputer 13.

  In the sensor nodes 1 to 7, the microcomputer 13 receives the advice information AvIF1 from the wireless module 12, and receives topology information (the area information IF_REG1 and the position information IF_PST of the information collecting apparatus 8), the frequency f, and the sensor from the received advice information AvIF1. The transmission amount TXV of the information SIF, the transmission interval TXITV of the sensor information SIF, and the instruction signal are detected.

  Then, whether the microcomputer 13 of the sensor node 1 can transmit the sensor information SIF by the wireless communication RF1 based on the area information IF_REG1, the position information IF_PST of the information collecting device 8 and the position information IF_PST of the sensor node 1 Determine More specifically, the microcomputer 13 of the sensor node 1 calculates the distance between the sensor node 1 and the information collecting device 8 based on the position information IF_PST of the information collecting device 8 and the position information IF_PST of the sensor node 1 If it is determined that the calculated distance is equal to or less than the radius of the area REG2 represented by the area information IF_REG1, it is determined that the sensor information SIF can be transmitted by the wireless communication RF1. On the other hand, when the microcomputer 13 of the sensor node 1 determines that the calculated distance is larger than the radius of the region REG2 represented by the region information IF_REG1, it determines that the sensor information SIF can not be transmitted by the wireless communication RF1.

  In FIG. 6, since the distance between the sensor node 1 and the information collecting apparatus 8 is equal to or less than the radius of the region REG2, the microcomputer 13 of the sensor node 1 determines that the sensor information SIF can be transmitted by the wireless communication RF1. Do.

  Similarly, the microcomputer 13 of each of the sensor nodes 2, 3, 4, 6, 7 determines that the sensor information SIF can not be transmitted by the wireless communication RF1, and the microcomputer 13 of the sensor node 5 detects the sensor information SIF. Is determined to be transmittable by the wireless communication RF1.

  Then, the microcomputer 13 of the sensor node 1 outputs the frequency f_1 associated with the wireless communication RF1, the sensor information SIF, the transmission amount TXV1, and the transmission interval TXITV1 to the wireless module 11. The wireless module 11 of the sensor node 1 receives the frequency f_1, the sensor information SIF, the transmission amount TXV1 and the transmission interval TXITV1 from the microcomputer 13, and transmits the sensor information SIF to the information collection device 8 using the wireless communication RF1 at the frequency f_1. . In this case, the wireless module 11 of the sensor node 1 transmits the sensor information SIF in accordance with the transmission amount TXV1 and the transmission interval TXITV1.

  The sensor node 5 also transmits the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF1 in the same manner as the sensor node 1.

  The microcomputer 13 of the sensor node 2 outputs the frequency f_2 associated with the wireless communication RF2, the sensor information SIF, the transmission amount TXV2, and the transmission interval TXITV2 to the wireless module 12. The wireless module 12 of the sensor node 2 receives the frequency f_2, the sensor information SIF, the transmission amount TXV2 and the transmission interval TXITV2 from the microcomputer 13, and transmits the sensor information SIF to the information collection device 8 using the wireless communication RF2 at the frequency f_2. . In this case, the wireless module 12 of the sensor node 2 transmits the sensor information SIF in accordance with the transmission amount TXV2 and the transmission interval TXITV2.

  Each of the sensor nodes 3, 4, 6, 7 transmits the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2 in the same manner as the sensor node 2.

  In each of the sensor nodes 1 to 7, the microcomputer 13 turns on or off the heartbeat sensor 14, the temperature sensor 15, the acceleration sensor 16, and the GPS 17 in accordance with the instruction signal IST.

  FIG. 7 is a flowchart showing a first example of the information collection method in the information collection system 10 shown in FIG.

  In FIG. 7, it is assumed that the sensor nodes 1 to 7 transmit the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2 before receiving the advice information AvIF1 from the information collecting apparatus 8. The first example of the method will be described.

  Referring to FIG. 7, when information collection is started, information collection device 8 determines region REG2 in which sensor information SIF can be transmitted (or transferred) by wireless communication RF1 based on position information IF_PST_8 of its own. (Step S1). More specifically, the information collection device 8 determines a semicircular area as the area REG2 with the transmission distance of the radio communication RF1 as the radius centering on the position indicated by the position information IF_PST_8 of its own.

  Then, the information collection device 8 determines the frequency f to be used by the sensor nodes 1 to 7, the transmission amount TXV of the sensor information SIF, and the transmission interval TXITV of the sensor information SIF by the method described above, and turns on the heartbeat sensor 14 and the like. Or generates an instruction signal IST for turning off (step S2).

  Thereafter, the information collection device 8 generates advice information AvIF1 including area information IF_REG1 indicating the area REG2, frequency f, transmission amount TXV, transmission interval TXITV, own position information IF_PST_8, and an instruction signal IST (step S3).

  Then, the information collection device 8 broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 by the wireless communication RF2 (step S4).

  The sensor node 1 receives the advice information AxIF by the wireless communication RF2 (step S5).

  Then, the sensor node 1 detects area information IF_REG1, frequency f, transmission amount TXV, transmission interval TXITV, position information IF_PST_8, and an instruction signal IST from the advice information AvIF1 (step S6).

  Thereafter, the sensor node 1 calculates the distance between itself and the information collecting apparatus 8 based on its own position information IF_PST_1 and position information IF_PST_8 (step S7).

  Then, the sensor node 1 determines whether the calculated distance is larger than the radius of the area REG2 indicated by the area information IF_REG1 (step S8).

  When it is determined in step S8 that the calculated distance is not larger than the radius of the region REG2, that is, when it is determined that the sensor information SIF can be transmitted by the wireless communication RF1, the sensor node 1 performs wireless communication at the frequency f_1. The sensor information SIF is transmitted at the transmission interval TXITV using the RF1 (step S9). In this case, the sensor node 1 transmits the sensor information SIF within the transmission amount TXV.

  On the other hand, when it is determined in step S8 that the calculated distance is larger than the radius of the region REG2, that is, when it is determined that the sensor information SIF can not be transmitted by the wireless communication RF1, the sensor node 1 has a frequency f_2. The sensor information SIF is transmitted at the transmission interval TXITV using the wireless communication RF2 (step S10). In this case, the sensor node 1 transmits the sensor information SIF within the transmission amount TXV.

  Then, after step S9 or step S10, the sensor node 1 turns on or off the heartbeat sensor 14, the temperature sensor 15, the acceleration sensor 16 and the GPS 17 according to the instruction signal IST (step S11).

  Thereafter, the information collection device 8 receives the sensor information SIF by the wireless communication RF1 or the wireless communication RF2, and stores the received sensor information SIF in the non-volatile DB 85 (step S12).

  This completes the series of operations.

  Each of the sensor nodes 2 to 7 also transmits the sensor information SIF to the information collecting apparatus 8 through the wireless communication RF1 or the wireless communication RF2 in accordance with steps S5 to S11, and turns on or off the heartbeat sensor 14 or the like.

  In the information collection method shown in FIG. 7, some of the sensor nodes 1 to 7 transmit the sensor information SIF to the information collection apparatus 8 using the wireless communication RF1, and the rest of the sensor nodes 1 to 7 use the wireless communication RF2. The sensor information SIF is transmitted to the information collecting apparatus 8 using

  As a result, the band shortage for the wireless communication RF2 is suppressed, and the sensor nodes 1 to 7 can deliver the sensor information SIF to the information collection device 8.

  Therefore, the information collecting apparatus 8 can accurately collect vital information such as heart rate and temperature even if the number of people in which the sensor node is installed increases.

  FIG. 8 is a diagram showing a second example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 8, sensor nodes 1 to 7 are present in region REG1. The CPU 83 of the information collecting device 8 can transmit the sensor information SIF to the relay node using only the wireless communication RF1 based on the position information IF_PST of the sensor nodes 1 to 7 and the information collecting device 8 and the transmission distance of the wireless communication RF1. The region REG3 is determined.

  More specifically, the CPU 83 of the information collecting device 8 calculates the distance between the sensor nodes 1 to 7 and the information collecting device 8 based on the sensor nodes 1 to 7 and the position information IF_PST of the information collecting device 8. Then, the CPU 83 of the information collecting device 8 detects the sensor node 1 whose distance from the information collecting device 8 is equal to or less than the transmission distance of the wireless communication RF1 or the wireless communication RF2 based on the calculated distance. Further, the CPU 83 of the information collection device 8 detects the sensor nodes 3, 5, 7 whose distance from the sensor node 1 is equal to or less than the transmission distance of the wireless communication RF1 based on the calculated distance. Then, the CPU 83 of the information collection device 8 detects an area surrounding the existence areas of the sensor nodes 1, 3, 5, and 7 as the area REG3.

  Further, the CPU 83 of the information collecting device 8 determines a relay node for relaying the sensor information SIF among the sensor nodes 1, 3, 5, and 7. The CPU 83 of the information collection device 8 determines, for example, the sensor node 1 as a relay node. In this case, the CPU 83 of the information collection device 8 determines the sensor node with the smallest degree of movement as the relay node, based on the movement speeds of the sensor nodes 1 to 7, for example. The smallest degree of movement means that the frequency of access to the region REG3 is the least.

  Then, the CPU 83 of the information collection device 8 detects the address Add1 of the sensor node 1 (relay node).

  Furthermore, as described above, the CPU 83 of the information collection device 8 determines the frequency f, the transmission amount TXV of the sensor information SIF, and the transmission interval TXITV of the sensor information SIF, and generates an instruction signal.

  Then, the CPU 83 of the information collection device 8 receives a signal IF_DLY indicating that the sensor node 1 is a relay node, position information IF_PST_1 of the sensor node 1, an address Add1 of the sensor node 1 (relay node), and the information collection device 8 The position information IF_PST_8 is stored in the topology information, and the frequency f, the transmission amount TXV of the sensor information SIF, the transmission interval TXITV of the sensor information SIF, and the instruction signal are added to generate the advice information AvIF1.

  Then, the CPU 83 of the information collection device 8 outputs the advice information AvIF 1 to the wireless module 82.

  The wireless module 82 of the information collection device 8 stores the broadcast address in the advice information AvIF1 received from the CPU 83, and broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 by the wireless communication RF2.

  The wireless module 12 of each of the sensor nodes 1 to 7 receives the advice information AvIF1 by the wireless communication RF2, and outputs the received advice information AvIF1 to the microcomputer 13.

  The microcomputer 13 of the sensor nodes 1 to 7 transmits the signal IF_DLY from the advice information AvIF1, the position information IF_PST_1, the address Add1 of the sensor node 1 (relay node), the position information IF_PST_8 of the information collecting apparatus 8, the frequency f, and the sensor information SIF. The quantity TXV, the transmission interval TXITV of the sensor information SIF and the indication signal are detected.

  Then, the microcomputer 13 of the sensor node 1 detects that the sensor node 1 is a relay node based on the signal IF_DLY.

  In addition, the microcomputer 13 of the sensor node 1 calculates the distance between the sensor node 1 and the information collecting apparatus 8 based on the position information IF_PST_1 and IF_PST_8, and the calculated distance corresponds to the communication area of the wireless communication RF1 or the wireless communication RF2. The wireless communication to be used by the sensor node 1 is determined to be either the wireless communication RF1 or RF2 by determining whether or not it is equal to or less than the radius of.

  The microcomputer 13 of the sensor nodes 3, 5, and 7 detects that the sensor node 1 is a relay node based on the signal IF_DLY.

  Then, the microcomputer 13 of the sensor node 3 calculates the distance between the sensor node 1 and the sensor node 3 based on the position information IF_PST_1 of the sensor node 1 and the position information IF_PST_3 of the sensor node 3, and the calculated distance Is detected to be equal to or less than the radius of the communication area of the wireless communication RF1, and it is determined that the sensor information SIF can be transmitted to the sensor node 1 by the wireless communication RF1.

  The microcomputers 13 of the sensor nodes 5 and 7 also determine that the sensor information SIF can be transmitted to the sensor node 1 by the wireless communication RF1 by the same method as the microcomputer 13 of the sensor node 3.

  In each of the sensor nodes 2, 4 and 6, the microcomputer 13 determines that the sensor information SIF can not be transmitted to the sensor node 1 by the wireless communication RF1 by the same method as the microcomputer 13 of the sensor node 1. Then, the microcomputer 13 of the sensor nodes 2, 4 and 6 determines to transmit the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2 by the method described in FIG.

  Then, the microcomputer 13 of the sensor node 3 sends the frequency f_1 associated with the wireless communication RF1, the address Add1 of the sensor node 1, the sensor information SIF, the transmission amount TXV3, and the transmission interval TXITV3 to the wireless module 11. Output. The wireless module 11 of the sensor node 3 receives the frequency f_1, the address Add1 of the sensor node 1, the sensor information SIF, the transmission amount TXV3 and the transmission interval TXITV3 from the microcomputer 13 and uses the wireless communication RF1 at the frequency f_1 to transmit the sensor information SIF. Send to sensor node 1 In this case, the wireless module 11 of the sensor node 3 transmits the sensor information SIF in accordance with the transmission amount TXV3 and the transmission interval TXITV3.

  The sensor nodes 5 and 7 also transmit the sensor information SIF to the sensor node 1 by the wireless communication RF1 in the same manner as the sensor node 3.

  The wireless module 11 of the sensor node 1 receives the sensor information SIF from the sensor nodes 3, 5, and 7, and relays the received sensor information SIF to the information collection device 8 using either the wireless communication RF1 or the wireless communication RF2. Do.

  Also, the sensor node 1 transmits its sensor information SIF to the information collection device 8 by either the wireless communication RF1 or the wireless communication RF2 according to the method described above.

  The microcomputer 13 of the sensor node 2 outputs the frequency f_2 associated with the wireless communication RF2, the sensor information SIF, the transmission amount TXV2, and the transmission interval TXITV2 to the wireless module 12. The wireless module 12 of the sensor node 2 receives the frequency f_2, the sensor information SIF, the transmission amount TXV2 and the transmission interval TXITV2 from the microcomputer 13, and transmits the sensor information SIF to the information collection device 8 using the wireless communication RF2 at the frequency f_2. . In this case, the wireless module 12 of the sensor node 2 transmits the sensor information SIF in accordance with the transmission amount TXV2 and the transmission interval TXITV2.

  Each of the sensor nodes 4 and 6 transmits sensor information SIF to the information collecting apparatus 8 by wireless communication RF2 in the same manner as the sensor node 2.

  In each of the sensor nodes 1 to 7, the microcomputer 13 turns on or off the heartbeat sensor 14, the temperature sensor 15, the acceleration sensor 16, and the GPS 17 in accordance with the instruction signal IST.

  Although it has been described that the sensor nodes 3, 5, and 7 transmit the sensor information SIF directly to the sensor node 1, the embodiment of the present invention is not limited thereto, and each sensor node performs multi-hop wireless communication. The sensor information SIF may be transmitted to the relay node (sensor node 1) by RF1.

  FIG. 9 is a flowchart showing a second example of the information collection method in the information collection system 10 shown in FIG.

  Also in FIG. 9, it is assumed that the sensor nodes 1 to 7 transmit the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2 before receiving the advice information AvIF1 from the information collecting apparatus 8. Explain the method.

  The sensors 3, 5, and 7 can transmit the sensor information SIF to the sensor node 1 using only the wireless communication RF1.

  Furthermore, let sensor node 1 be a relay node.

  The flowchart shown in FIG. 9 is obtained by replacing step S1 of the flowchart shown in FIG. 7 with steps S1A and S1B, replacing step S3 with step S3A and adding steps S21 to S26, and the others are shown in FIG. It is the same as the flowchart.

  Referring to FIG. 9, when information collection is started, information collection device 8 relays sensor information SIF using only wireless communication RF 1 based on the position information of sensor nodes 1 to 7 and information collection device 8. The area REG3 that can be transmitted to the node is determined by the method described above (step S1A).

  Then, the information collection device 8 determines a relay node capable of relaying the sensor information SIF in the region REG3 by the above-described method (step S1B).

  Thereafter, step S2 described above is executed.

  Subsequently, the information collecting device 8 provides the advice information AvIF 1 including the signal IF_DLY, the position information of the information collecting device 8, the position information of the relay node, the address of the relay node, the frequency f, the transmission amount TXV, the transmission interval TXITV and the instruction signal IST. Generate (step S3A).

  Then, steps S4 and S5 described above are sequentially executed.

  After Step S5, each of the sensor nodes 1, 3, 5 and 7 receives the advice information AvIF1 to the signal IF_DLY, the position information of the information collecting apparatus 8, the position information of the relay node, the address of the relay node, the frequency f, and the transmission amount TXV. The transmission interval TXITV and the instruction signal IST are detected (step S21).

  Then, the sensor nodes 1, 3, 5 and 7 detect that the sensor node 1 is a relay node based on the signal IF_DLY (step S22). Thereafter, the sensor node 1 determines wireless communication to be used from among the wireless communication RF1 and RF2 according to the above-mentioned method based on the information collection device 8 and the position information of the relay node (step S23). The sensor nodes 3, 5, and 7 detect that the sensor information SIF can be transmitted to the relay node (sensor node 1) using the wireless communication RF1 based on the position information of the relay node and itself (step S24). ).

  Thereafter, the sensor nodes 3, 5, and 7 transmit the sensor information SIF to the relay node (sensor node 1) at the transmission interval TXITV using the wireless communication RF1 at the frequency f_1 (step S25). In this case, the sensor nodes 3, 5, and 7 transmit the sensor information SIF within the range of the transmission amount TXV.

  The relay node (sensor node 1) receives the sensor information SIF, and relays the received sensor information SIF to the information collection device 8 using one of the wireless communication RF1 and RF2 (step S26).

  Further, the relay node (sensor node 1) transmits its sensor information SIF to the information collecting apparatus 8 at the transmission interval TXITV using one of the wireless communication RF1 and RF2 (step S27). In this case, the relay node (sensor node 1) transmits sensor information SIF within the range of the transmission amount TXV.

  On the other hand, after the step S5, the sensor nodes 2, 4 and 6 transmit the sensor information to the information collecting apparatus 8 by the wireless communication RF1 or the wireless communication RF2 according to the steps S6 to S10 shown in FIG.

  Then, after steps S27 and S28, the above-described steps S11 and S12 are sequentially executed. This completes the series of operations.

  In step S25, the sensor nodes 3, 5, and 7 may transmit the sensor information SIF to the relay node (sensor node 1) by the multihop wireless communication RF1.

  Also in the information collection method shown in FIG. 9, the sensor nodes 1, 3, 5, 7 transmit the sensor information SIF to the information collection device 8 using only the wireless communication RF1, and the sensor nodes 2, 4, 6 The sensor information SIF is transmitted to the information collecting apparatus 8 using one of the communication RF1 and the wireless communication RF2.

  As a result, the band shortage for the wireless communication RF2 is suppressed, and the sensor nodes 1 to 7 can deliver the sensor information SIF to the information collection device 8.

  Therefore, the information collection device 8 can accurately collect vital information such as heart rate and temperature even if there are many people exercising.

  In the second example of the information collection method, it has been described that the CPU 83 of the information collection device 8 determines the region REG3 in which the sensor information SIF can be transmitted to the information collection device 8 using only the wireless communication RF1.

  Since the transmission distance of the wireless communication RF1 is shorter than the transmission distance of the wireless communication RF2, determining the region REG3 detects the densely arranged sensor nodes 1, 3, 5, and 7 among the sensor nodes 1 to 7. Equivalent to Further, determining the relay node from the sensor nodes 1, 3, 5, and 7 present in the region REG3 corresponds to detecting the relay node from the densely arranged sensor nodes 1, 3, 5, and 7.

  Therefore, the second example of the information collection method detects the sensor nodes 1, 3, 5, and 7 closely packed from the sensor nodes 1 to 7, and relay nodes from the detected sensor nodes 1, 3, 5, and 7 (Sensor node 1) is detected, and the densely arranged sensor nodes 3, 5, and 7 transmit the sensor information SIF to the information collection device 8 via the relay node (sensor node 1) using the wireless communication RF1, and The sensor nodes 2, 4 and 6 not transmitting transmit the sensor information SIF to the information collecting apparatus 8 using the wireless communication RF1 or the wireless communication RF2.

  FIG. 10 is a diagram showing a third example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 10, sensor nodes 1 to 7 transmit sensor information SIF to information collecting apparatus 8 according to the flowchart shown in FIG. 7 or FIG.

  Then, the CPU 83 of the information collection device 8 transmits vital information such as heart rate and temperature to the display device 9 via the LAN 86. The display device 9 displays the vital information received from the information collecting device 8.

  Further, the CPU 83 of the information collection device 8 discovers a change in the vital information of the person in which the sensor node 5 is installed, for example, in accordance with a preset program. For example, the CPU 83 of the information collection device 8 discovers that the heart rate of the person in which the sensor node 5 is installed is rapidly increasing.

  Then, when the CPU 83 of the information collection device 8 discovers that there is an abnormality in the vital information of the person in which the sensor node 5 is installed, it designates the sensor nodes 1 to 4, 6 and 7 to which transmission of the sensor information SIF should be stopped. To generate the signal DSGN_STOP. The signal DSGN_STOP is an address Add1 to Add4, Add6, Add7 of the sensor nodes 1 to 4, 6, 7 to which transmission of the sensor information SIF should be stopped, and a signal STOP indicating that transmission of the sensor information SIF should be stopped. It consists of

  Then, the CPU 83 of the information collection device 8 outputs the signal DSGN_STOP to the wireless module 82.

  The wireless module 82 of the information collection device 8 receives the signal DSGN_STOP, and broadcasts the received signal DSGN_STOP to the sensor nodes 1 to 7 by the wireless communication RF2.

  The sensor nodes 1 to 7 receive the signal DSGN_STOP. Then, in response to the signal DSGN_STOP, the microcomputer 13 of the sensor nodes 1 to 4, 6, and 7 detects that the transmission of the sensor information SIF should be stopped.

  Then, the microcomputer 13 of the sensor nodes 1 to 4, 6, and 7 stops the output of the sensor information SIF to the wireless module 11 or the wireless module 12. Thus, the sensor nodes 1 to 4, 6, 7 stop transmitting the sensor information SIF.

  On the other hand, based on the signal DSGN_STOP, the microcomputer 13 of the sensor node 5 detects that its own address is not included in the signal DSGN_STOP. Then, the microcomputer 13 of the sensor node 5 outputs the sensor information SIF to the wireless module 11 or 12. Thereby, the sensor node 5 continues to transmit sensor information SIF to the information collection device 8.

  In addition, when the CPU 83 of the information collection device 8 finds that there is a change in vital information, a signal for designating the sensor nodes 1 to 4, 6 and 7 to which the sensor information SIF transmitted from the sensor node 5 should be transferred. Generate DSGN_TFR. The signal DSGN_TFR is composed of the addresses Add1 to Add4, Add6 and Add7 of the sensor nodes 1 to 4, 6 and 7 to which the sensor information SIF should be transferred, and the signal TFR indicating that the sensor information SIF should be transferred.

  Then, the CPU 83 of the information collection device 8 outputs the signal DSGN_TFR to the wireless module 82.

  The wireless module 82 of the information collection device 8 receives the signal DSGN_TFR, and broadcasts the received signal DSGN_TFR to the sensor nodes 1 to 7 by the wireless communication RF2.

  The sensor nodes 1 to 7 receive the signal DSGN_TFR. Then, upon receiving the sensor information SIF from another sensor node in response to the signal DSGN_TFR, the microcomputer 13 of the sensor nodes 1 to 4, 6, 7 detects that the received sensor information SIF should be transferred.

  Then, the microcomputer 13 of the sensor nodes 1 to 4, 6, 7 stops the output of the sensor information SIF generated by itself to the wireless module 11 or the wireless module 12.

  When the microcomputer 13 of the sensor nodes 1, 3, and 6 receives the sensor information SIF from the sensor node 5, the microcomputer 13 outputs the received sensor information SIF to the wireless module 11 or the wireless module 12 to transfer the sensor information SIF. . The sensor nodes 2, 4 and 7 do not receive the sensor information SIF from the sensor node 5, and thus do not transfer the sensor information SIF.

  On the other hand, the microcomputer 13 of the sensor node 5 detects that its own address is not included in the signal DSGN_TFR based on the signal DSGN_TFR. Then, the microcomputer 13 of the sensor node 5 outputs the sensor information SIF to the wireless module 11 or 12. Thereby, the sensor node 5 continues to transmit sensor information SIF to the information collection device 8.

  As described above, sensor nodes other than the sensor node mounted on a person who has a change in vital information stop transmitting the sensor information SIF or transfer the sensor information SIF received from another sensor node.

  Therefore, a sensor node mounted on a person who has a margin in the bandwidth and has a change in vital information transmits the sensor information SIF correctly to the information collecting apparatus 8 by continuously transmitting and / or retransmitting the sensor information SIF. it can. As a result, the reliability of the information collection system 10 can be improved.

  FIG. 11 is a flowchart showing a third example of the information collection method in the information collection system 10 shown in FIG.

  The third example of the information collection method will be described on the premise that the sensor nodes 1 to 7 transmit the sensor information SIF to the information collection apparatus 8 by the wireless communication RF1 or the wireless communication RF2.

  Referring to FIG. 11, the information collection device 8 determines whether or not there is a change in vital information of a person depending on whether or not the signal EMG is received (step S31).

  In this case, when the information collection device 8 receives the signal EMG, it determines that there is an anomaly in the vital information of a certain person, and when it does not receive the signal EMG, it determines that there is no variation in the vital information of a certain person .

  In step S31, when it is determined that there is a change in vital information of a certain person, the information collection device 8 generates a signal DSGN_STOP for specifying a sensor node for which transmission of sensor information SIF should be stopped (step S32). .

  Then, the information collection device 8 broadcasts the signal DSGN_STOP to the sensor nodes 1 to 7 by the wireless communication RF2 (step S33).

  The sensor nodes 1 to 7 receive the signal DSGN_STOP by the wireless communication RF2 (step S34).

  The sensor node 5 detects that the transmission of the sensor information SIF does not have to be stopped based on the signal DSGN_STOP (step S35).

  Then, the sensor node 5 transmits the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF1 or the wireless communication RF2 (step S36).

  On the other hand, after the step S34, the sensor nodes 1 to 4, 6, 7 detect that the transmission of the sensor information SIF should be stopped based on the signal DSGN_STOP (step S37).

  Then, the sensor nodes 1 to 4, 6, 7 stop transmitting the sensor information SIF (step S38).

  After steps S36 and S38, the information collection device 8 receives the sensor information SIF from the sensor node 5, and stores the received sensor information SIF in the non-volatile DB 85 (step S39). This completes the series of operations.

  FIG. 12 is another flowchart showing a third example of the information collection method in the information collection system 10 shown in FIG.

  The flowchart shown in FIG. 12 is obtained by replacing steps S32, S33, S34, S35, S37 and S38 in the flowchart shown in FIG. 11 with steps S32A, S33A, S34A, S35A, S37A and S38A, respectively. It is the same as the flowchart shown in FIG.

  Referring to FIG. 12, when information collection is started, step S31 described above is executed.

  In step S31, when it is determined that there is a change in vital information of a certain person, the information collection device 8 generates a signal DSGN_TFR for specifying a sensor node to which the sensor information SIF should be transferred (step S32A).

  Then, the information collection device 8 broadcasts the signal DSGN_TFR to the sensor nodes 1 to 7 by wireless communication RF2 (step S33A).

  The sensor nodes 1 to 7 receive the signal DSGN_TFR by the wireless communication RF2 (step S34A).

  The sensor node 5 detects that it is not necessary to transfer the sensor information SIF based on the signal DSGN_TFR (step S35A).

  Then, the sensor node 5 executes step S36 described above.

  On the other hand, after the step S34A, the sensor nodes 1 to 4, 6, 7 detect that the sensor information SIF should be transferred based on the signal DSGN_TFR (step S37A).

  Then, when receiving the sensor information SIF from the sensor node 5, the sensor nodes 1 to 4, 6, 7 transfer the received sensor information SIF (step S38A).

  After the step S36A and the step S38A, the above-mentioned step S39 is executed, and the series of operations is finished.

  According to the flowchart shown in FIG. 11 or 12, the sensor node 5 mounted on a person having a change in vital information transmits the sensor information SIF to the information collecting apparatus 8, and the sensor nodes 1 to 4 other than the sensor node 5 , 6, 7 stop transmitting the sensor information SIF, or transfer the sensor information SIF received from the sensor node 5 to the information collecting device 8.

  As a result, a margin is created in the wireless communication band, and a sensor node mounted on a person who has a change in vital information performs continuous transmission and / or retransmission of sensor information SIF, and another sensor node relays sensor information SIF. As a result, the sensor information SIF can be accurately transmitted to the information collection device 8. As a result, the reliability of the information collection system 10 can be improved.

  FIG. 13 is a diagram showing a fourth example of the information collection method in the information collection system 10 shown in FIG.

  Referring to (a) of FIG. 13, sensor nodes 5 and 6 transmit sensor information SIF to sensor node 7 by wireless communication RF1, and sensor node 7 receives sensor information SIF received from sensor nodes 5 and 6. It relays to the information collecting device 8 by the wireless communication RF1.

  In such a situation, the sensor node 7 moves violently and moves away from the information collection device 8 (see (b) in FIG. 13).

  The microcomputer 13 of the sensor node 7 performs wireless communication based on position information of the sensor node 7 before movement, position information of the sensor node 7 after movement, and advice information AvIF 1 from the information collection device 8 before movement of the sensor node 7. It is determined that the sensor information SIF can not be transmitted to the information collection device 8 by the communication RF1, and the wireless communication RF2 is switched to. Then, the sensor node 7 transmits the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2.

  Further, even if the microcomputer 13 of the sensor nodes 5, 6 transmits the sensor information SIF to the sensor node 7, the wireless communication with the sensor node 7 is interrupted by not receiving the reception confirmation from the sensor node 7. Detect that.

  Then, the microcomputer 13 of the sensor nodes 5, 6 switches the relay destination to the sensor node 1, transmits the sensor information SIF to the sensor node 1 by the wireless communication RF1, and the sensor node 1 detects the sensor from the sensor nodes 5, 6. The information SIF is sent to the information collection device 8.

  Further, the microcomputer 13 of the sensor nodes 5 and 6 switches the wireless communication to the wireless communication RF2, and directly transmits the sensor information SIF to the information collecting apparatus 8 by the wireless communication RF2.

  As described above, in the fourth example of the information collection method, the sensor node 7 switches the wireless communication scheme according to its own determination, and the sensor nodes 5 and 6 switch the wireless communication scheme or the relay destination according to their own determination.

  As a result, the sensor information SIF can be accurately transmitted to the information collecting apparatus 8 also by the movement of the sensor node.

  FIG. 14 is a flowchart showing the operation of the relay node in the fourth example of the information collection method.

  In FIG. 14, the operation of the relay node will be described by taking the sensor node 7 as an example.

  Referring to FIG. 14, when a series of operations are started, microcomputer 13 of sensor node 7 acquires positional information of sensor node 7 before movement and positional information of sensor node 7 after movement (see FIG. 14). Step S41).

  Then, the microcomputer 13 of the sensor node 7 acquires the advice information AvIF1 from the information collection device 8 before the movement of the sensor node 7 (step S42).

  Thereafter, the microcomputer 13 of the sensor node 7 determines whether or not the sensor node 7 has moved rapidly based on the acquired positional information before and after the movement (step S43).

  Here, the rapid movement means movement in which the sensor information SIF can not be delivered to the information collection device 8 by the wireless communication method currently used by the sensor node 7.

  Therefore, in step S43, the microcomputer 13 of the sensor node 7 determines whether or not the sensor node 7 has moved rapidly by the following method.

  The microcomputer 13 of the sensor node 7 stores the position information of the information collecting device 8. Then, the microcomputer 13 of the sensor node 7 calculates the distance between the sensor node 7 and the information collecting device 8 after the movement based on the position information of the sensor node 7 after the movement and the position information of the information collecting device 8. . Then, when the distance after movement is equal to or less than the radius of the area of the wireless communication RF1, the microcomputer 13 of the sensor node 7 determines that the sensor node 7 has not moved suddenly. On the other hand, when the distance after movement is larger than the radius of the area of the wireless communication RF1, the microcomputer 13 of the sensor node 7 determines that the sensor node 7 has moved rapidly.

  When it is determined in step S43 that the sensor node 7 has not moved suddenly, the series of operations proceeds to step S47 described later.

  On the other hand, when it is determined in step S43 that the sensor node 7 has moved rapidly, the microcomputer 13 of the sensor node 7 performs wireless communication based on the position information before and after the movement of the sensor node 7 and the advice information AvIF1. It is further determined whether to switch the method (step S44).

  In this case, the microcomputer 13 of the sensor node 7 considers the fact that the radio communication RF1 is selected based on the advice information AvIF1 before the movement, and the distance after the movement is less than the radius of the area of the radio communication RF1. If it is, it is determined that the wireless communication scheme is not switched. On the other hand, the microcomputer 13 of the sensor node 7 determines to switch the wireless communication scheme when the distance after movement described above is larger than the radius of the wireless communication RF1.

  When it is determined in step S44 that the wireless communication method is to be switched, the microcomputer 13 of the sensor node 7 switches to the wireless communication method (wireless communication RF2) appropriate for the position after movement (step S45).

  Then, the sensor node 7 transmits the sensor information SIF to the information collecting apparatus 8 using the switched wireless communication system (wireless communication RF2) (step S46).

  On the other hand, when it is determined in step S44 that the wireless communication method is not to be switched, or when it is determined in step S43 that the sensor node 7 has not moved rapidly, the sensor node 7 performs the wireless communication method before switching ( The sensor information SIF is transmitted to the information collecting apparatus 8 using the wireless communication RF1) (step S47).

  Then, after step S46 or step S47, the series of operation ends.

  As described above, when the sensor node 7 is accompanied by a sudden movement, the sensor node 7 switches to the position after the movement to a suitable wireless communication system by its own judgment. Then, the sensor node 7 transmits the sensor information SIF to the information collection device 8 using the switched wireless communication method.

  Therefore, even if the sensor node moves rapidly, the sensor information SIF can be accurately transmitted to the information collecting apparatus 8.

  FIG. 15 is a flowchart showing an operation of the sensor node transmitting sensor information to the relay node in the fourth example of the information collection method.

  In FIG. 15, the operation of the sensor node transmitting sensor information SIF to the relay node will be described by taking the sensor node 5 as an example.

  Referring to FIG. 15, when a series of operations are started, sensor node 5 transmits sensor information SIF to the relay destination (sensor node 7) (step S51).

  Then, the microcomputer 13 of the sensor node 5 determines whether or not there is reception confirmation from the relay destination (step S52).

  When it is determined in step S52 that there is no reception confirmation from the relay destination, the microcomputer 13 of the sensor node 5 switches to another wireless communication method or another relay destination (step S53).

  In this case, the microcomputer 13 of the sensor node 5 transmits the sensor information SIF to the information collection device 8 using the original wireless communication RF1 based on the topology of the sensor nodes 1 to 7 An appropriate relay destination is detected in sensor nodes other than the sensor node 7), and the relay destination is switched to the detected relay destination. Further, the microcomputer 13 of the sensor node 5 switches to a wireless communication system suitable for directly transmitting the sensor information SIF to the information collecting apparatus 8.

  Then, the microcomputer 13 of the sensor node 5 transmits the sensor information SIF to the information collecting apparatus 8 using the switched other wireless communication method, or to the relay destination after switching using the wireless communication method before switching Sensor information SIF is transmitted (step S54).

  On the other hand, when it is determined in step S52 that there is reception confirmation from the relay destination, the microcomputer 13 of the sensor node 5 transmits the sensor information SIF to the relay destination before switching using the wireless communication system before switching. (Step S55).

  Then, after step S54 or step S55, a series of operation ends.

  As described above, when the sensor node 5 can not relay the sensor information SIF due to the rapid movement of the original relay destination, the sensor node 5 switches the relay destination or the wireless communication system according to its own judgment. Then, the sensor node 5 directly transmits the sensor information SIF to the information collecting apparatus 8 using the switched wireless communication system, or transmits the sensor information SIF to the switched relay destination using the wireless communication system before switching. Do.

  Therefore, even if the original relay destination is unable to relay the sensor information SIF due to the sudden movement, the sensor information SIF can be accurately transmitted to the information collecting apparatus 8.

  FIG. 16 is a diagram showing a fifth example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 16, microcomputer 13 of sensor node 6 determines whether or not an abnormality of vital information is found. Here, the abnormality of vital information means that the heart rate rapidly rises or falls, or the body temperature rapidly rises or falls.

  If the microcomputer 13 of the sensor node 6 determines that an abnormality of vital information is found, it determines which of the wireless communication RF1 and the wireless communication RF2 can transmit the sensor information SIF to the information collecting apparatus 8. More specifically, the microcomputer 13 of the sensor node 6 calculates the distance between the sensor node 6 and the information collecting device 8 based on the position information of the sensor node 6 and the position information of the information collecting device 8. Then, when the calculated distance is equal to or less than the radius of the communication area of the wireless communication RF1, the microcomputer 13 of the sensor node 6 determines that the sensor information SIF can be transmitted to the information collecting apparatus 8 using the wireless communication RF1. When the calculated distance is larger than the radius of the communication area of the wireless communication RF1, it is determined that the sensor information SIF can be transmitted to the information collecting apparatus 8 using the wireless communication RF2.

  Then, when the microcomputer 13 of the sensor node 6 determines the wireless communication method capable of transmitting the sensor information SIF to the information collecting device 8, the microcomputer 13 transmits the sensor information SIF to the information collecting device 8 using the determined wireless communication method.

  FIG. 17 is a flowchart showing a fifth example of the information collection method in the information collection system 10 shown in FIG.

  In addition, in FIG. 17, the 5th example of the information collection method is demonstrated by making the sensor node 6 into an example.

  Referring to FIG. 17, when a series of operations are started, microcomputer 13 of sensor node 6 has found an abnormality in vital information by determining whether the heart rate or the temperature exceeds a reference value. It is determined whether or not (step S61).

  In this case, for the reference value for the heart rate, for example, the lower limit reference value is set to 30 times / minute, and the upper limit reference value is set to 100 times / minute. Further, for the reference value for the body temperature, for example, the lower limit reference value is set to 30 ° C., and the upper limit reference value is set to 42 ° C.

  Then, when the heart rate falls below the lower limit reference value or when the heart rate exceeds the upper limit reference value, the microcomputer 13 of the sensor node 6 determines that an abnormality of vital information is found.

  Further, when the temperature falls below the lower limit reference value or when the temperature exceeds the upper limit reference value, the microcomputer 13 of the sensor node 6 determines that an abnormality of vital information is found.

  When it is determined in step S61 that an abnormality of vital information is found, the microcomputer 13 of the sensor node 6 can determine whether the sensor information SIF can be delivered to the information collecting apparatus 8 by the wireless communication RF1 by the method described above. Further determination is made (step S62).

  When it is determined in step S62 that the sensor information SIF can be delivered to the information collecting apparatus 8 by the wireless communication RF1, the sensor node 6 transmits the sensor information SIF to the information collecting apparatus 8 using the wireless communication RF1 (step S63). ).

  On the other hand, when it is determined in step S62 that the sensor information SIF can not be delivered to the information collecting apparatus 8 by the wireless communication RF1, the sensor node 6 transmits the sensor information SIF to the information collecting apparatus 8 using the wireless communication RF2. (Step S64).

  Then, after step S63 or step S64, a series of operation ends.

  Each of the sensor nodes 1 to 5 also transmits sensor information SIF to the information collecting apparatus 8 according to the flowchart shown in FIG. 17 when an abnormality of vital information is found.

  As described above, when each sensor node 1 to 7 finds an abnormality in vital information, it preferentially transmits the sensor information SIF to the information collecting apparatus 8 by using the radio communication RF1 in priority, and the sensor information SIF is transmitted in the radio communication RF1. If delivery can not be performed, the sensor information SIF is transmitted to the information collection device 8 using the wireless communication RF2.

  In this way, it is possible to suppress the bandwidth shortage of the wireless communication RF2 while ensuring delivery of vital information in which an abnormality is found to the information collecting apparatus 8.

  FIG. 18 is a diagram showing a sixth example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 18, the CPU 83 of the information collection device 8 manages the battery remaining amount of the sensor nodes 1 to 7. Then, the CPU 83 of the information collection device 8 lengthens the transmission interval TXITV of the sensor information SIF in the sensor node 6 when the battery remaining amount of the sensor node 6 is lower than the reference value among the battery remaining amounts of the sensor nodes 1 to 7. The set transmission interval TXITV is included in the advice information AvIF1 and broadcast to the sensor nodes 1 to 7 using the wireless communication RF2.

  For example, the transmission interval TXITV of the sensor nodes 1 to 5 is set to the transmission interval TXITV1, and the transmission interval TXITV of the sensor node 6 is set to the transmission interval TXITV2. In this case, the transmission interval TXITV2 is longer than the transmission interval TXITV1.

  The sensor nodes 1 to 7 receive the advice information AvIF1. Then, each of the sensor nodes 1 to 5 transmits the sensor information SIF to the information collecting apparatus 8 at the transmission interval TXITV1, and the sensor node 6 transmits the sensor information SIF to the information collecting apparatus 8 at the transmission interval TXITV2.

  As a result, the battery life of the sensor node 6 can be extended, and the information collection device 8 can collect sensor information SIF from the sensor node 6 even if the remaining battery capacity decreases.

  FIG. 19 is a flowchart showing a sixth example of the information collection method in the information collection system 10 shown in FIG.

  Referring to FIG. 19, CPU 83 of information collecting device 8 refers to sensor information SIF of sensor nodes 1 to 7 stored in nonvolatile DB 85, and determines a reference among the battery residual amounts of sensor nodes 1 to 7. The remaining battery level below the value is detected (step S71).

  Then, the CPU 83 of the information collection device 8 sets the transmission interval TXITV of the sensor nodes 1 to 5 whose battery remaining amount is the reference value or more to the transmission interval TXITV1 (step S72).

  Further, the CPU 83 of the information collecting device 8 sets the transmission interval TXITV of the sensor node 6 whose battery remaining capacity is below the reference value as the transmission interval TXITV2 (> TXITV1) (step S73).

  Then, the CPU 83 of the information collection device 8 transmits the addresses Add1 to Add5, Add7 of the sensor nodes 1 to 5 and Add7 to the transmission interval TXITV1, and Add7: TXITV1 and the address Add6 of the sensor node 6 The advice information AvIF1 including Add6: TXITV2 associated with the interval TXITV2 is generated. Then, the wireless module 82 of the information collection device 8 broadcasts the advice information AvIF1 to the sensor nodes 1 to 7 by wireless communication RF2 (step S74).

  The sensor nodes 1 to 7 receive the advice information AvIF1 by the wireless communication RF2 (step S75).

  Then, based on the advice information AvIF1, the sensor node 6 transmits the sensor information SIF to the information collection device 8 at the transmission interval TXITV2 using the wireless communication RF1 or the wireless communication RF2 (step S76).

  Meanwhile, based on the advice information AvIF1, the sensor nodes 1 to 5 transmit the sensor information SIF to the information collection device 8 at the transmission interval TXITV1 using the wireless communication RF1 or the wireless communication RF2 (step S77).

  Then, the information collection device 8 receives the sensor information SIF from the sensor nodes 1 to 7, and stores the received sensor information SIF in the non-volatile DB 85 (step S78). This completes the series of operations.

  As described above, the information collection device 8 collects the sensor information SIF by lengthening the transmission interval TXITV of the sensor node 6 whose battery remaining amount is below the reference value. Therefore, the battery life of the sensor node 6 can be extended, and the information collecting apparatus 8 can collect the sensor information SIF also from the sensor node 6 even if the battery remaining amount decreases.

  FIG. 20 is another configuration diagram of the advice information. Referring to FIG. 20, the advice information AxIF2 is the topology information of the advice information AvIF1 shown in FIG. 5 in which the position information of the sensor nodes 1 to 7 and the information collecting apparatus 8 is stored. It is the same.

  The position information of the sensor nodes 1 to 7 and the information collecting device 8 includes the addresses Add 1 to Add 8 of the sensor nodes 1 to 7 and the information collecting device 8, and the position information (x1, y1) of the sensor nodes 1 to 7 and the information collecting device 8. , (X2, y2), (x3, y3), (x4, y4), (x5, y5), (x6, y6), (x7, y7), (x8, y8) are respectively associated with each other Become.

  Then, the CPU 83 of the information collection device 8 outputs the advice information AvIF2 to the wireless module 82, and the wireless module 82 of the information collection device 8 broadcasts the advice information AvIF2 to the sensor nodes 1 to 7 by the wireless communication RF2.

  The sensor nodes 1 to 7 receive the advice information AvIF2. Then, the microcomputer 13 of the sensor node 1 receives topology information (Add1: (x1, y1), Add2: (x2, y2), Add3: (x3, y3), Add4: (x4, y4) included in the advice information AvIF2. , Add5: (x5, y5), Add6: (x6, y6), Add7: (x7, y7), Add8: (x8, y8)), the sensor nodes 1 to 7 and the information collection device 8 mutually interact Calculate the distance between

  Then, the microcomputer 13 of the sensor node 1 constructs the topology of the sensor nodes 1 to 7 and the information collection device 8 based on the calculated distance. Thereafter, when the distance between the sensor node 1 and the information collection device 8 is less than or equal to the radius of the communication area of the wireless communication RF1, the microcomputer 13 of the sensor node 1 performs wireless communication RF1 based on the constructed topology. It selects and transmits sensor information SIF to the information collecting device 8 using the wireless communication RF1.

  On the other hand, when the distance between the sensor node 1 and the information collection device 8 is larger than the radius of the communication area of the wireless communication RF1, the microcomputer 13 of the sensor node 1 selects the wireless communication RF2 and wirelessly transmits the sensor information SIF. It transmits to the information gathering apparatus 8 using communication RF2.

  Further, when the distance between the sensor node 1 and the information collecting device 8 is larger than the radius of the communication area of the wireless communication RF1, the microcomputer 13 of the sensor node 1 is more than the sensor node 1 based on the constructed topology. The relay node is selected from sensor nodes close to the information collection device 8. In this case, the microcomputer 13 of the sensor node 1 preferentially selects a sensor node that can deliver the sensor information SIF by the wireless communication RF1 as a relay node. Then, when there is no relay node capable of delivering the sensor information SIF by the wireless communication RF1, the microcomputer 13 of the sensor node 1 selects a sensor node capable of delivering the sensor information SIF by the wireless communication RF2 as the relay node. . Then, the sensor node 1 transmits the sensor information SIF to the relay node by the wireless communication RF1 or the wireless communication RF2.

  Each of the sensor nodes 2 to 7 also transmits the sensor information SIF to the information collection device 8 by selecting the wireless communication RF1 or the wireless communication RF2 in the same manner as the sensor node 1.

  Thus, the information collecting device 8 broadcasts the position information of the sensor nodes 1 to 7 and the information collecting device 8 to the sensor nodes 1 to 7, and the sensor nodes 1 to 7 include the sensor nodes 1 to 7 and the information collecting device 8. One of the radio communication RF1 and the radio communication RF2 is selected based on the position information, and the sensor information SIF is transmitted to the information collection device 8.

  Therefore, the information collecting device 8 only broadcasts the position information of the sensor nodes 1 to 7 and the information collecting device 8 to the sensor nodes 1 to 7, and the sensor node 7 performs either the wireless communication RF1 or the wireless communication RF2. It can be selected.

  When the position information of the sensor node 1 received from the information collection device 8 is different from the current position information of the sensor node 1, the microcomputer 13 of the sensor node 1 uses the current position information to detect the sensor nodes 1 to 7 and The mutual distances of the information collecting devices 8 are calculated, and the calculated distances are used to reconstruct the topology of the sensor nodes 1 to 7 and the information collecting device 8. Then, the microcomputer 13 of the sensor node 1 selects one of the radio communication RF1 and the radio communication RF2 by the above-described method using the reconstructed topology. The same applies to the sensor nodes 2 to 7.

  FIG. 21 is a diagram showing various wireless communication standards. FIG. 22 is a diagram showing a combination of the wireless communication RF1 and the wireless communication RF2.

  Referring to FIG. 21, the BLE standard has a frequency band of 2.4 GHz and a transmission distance of 10 m, as described above. IEEE 802.15.4g has a frequency band of 900 MHz and a transmission distance of 300 m.

  The IEEE 802.11ac has a frequency band of 5 GHz and a transmission distance of 60 to 130 m.

  The IEEE 802.11ah has a 900 MHz frequency band and a transmission distance of 1 km or more. And in IEEE 802.11ah, the transmission rate is in the range of 150 kbps (1 MHz wide) to 40 Mbps (8 MHz wide).

  The combination of the radio communication RF1 and the radio communication RF2 is not limited to BLE and IEEE 802.11ah, but may be any of the combinations shown in FIG. 22. Generally, two radio communication standards having different transmission distances are used. If it is, it may be any combination.

  As described above, the information collection device 8 collects vital information of a person in motion from various sensor nodes 1 to 7 installed in the person in motion by various methods, and the collected vital information is displayed Displayed by 9

  As a result, it is possible to acquire information on heart rate and temperature during exercise, and to easily find out whether or not an abnormality has occurred in the person who is exercising.

  In the above, it has been described that vital information consists of heart rate and body temperature, but the embodiment of the present invention is not limited to this, and vital information may be blood pressure, and biological information detectable by a sensor Any biological information may be used.

  In the above description, it is described that the sensor nodes 1 to 7 are installed in a person who is in motion, but the embodiment of the present invention is not limited to this, and the sensor nodes 1 to 7 are construction sites It may be installed on workers of the above, fire station staff, people for disaster response, livestock, birds and fish, etc., and may be installed on carriers, carts, robots and the like.

  When sensor nodes 1 to 7 are installed on workers at construction sites, fire department officers, people who respond to disasters, livestock, birds, fish, etc., sensor information SIF is vital to the heart rate of workers at construction sites, etc. Contains information.

  In addition, when the sensor nodes 1 to 7 are installed in addition to the carriage, the carriage, the robot, and other animals, the sensor information SIF includes information on the carriage, the carriage, the robot, and the like. For example, when the sensor nodes 1 to 7 are installed on a transport vehicle, the sensor information SIF includes at least one of presence / absence of a failure of the transport vehicle, performance characteristics, and diagnostic information. In addition, when the sensor nodes 1 to 7 are installed on the bogie, the sensor information SIF includes the presence or absence of the bogie failure. Furthermore, when the sensor nodes 1 to 7 are installed in the robot, the sensor information SIF includes at least one of presence / absence of a failure of the robot, performance characteristics, and diagnostic information.

  Therefore, in the embodiment of the present invention, the sensor information SIF is a worker at a construction site, a fire station clerk, a person responding to a disaster, vital information such as livestock, birds and fish, or a characteristic of an engine of a transport vehicle, a bogie Including the presence or absence of failure and the operating characteristics of the robot. And, workers on construction site, fire department staff, disaster response people, vital information such as livestock, birds and fish, engine characteristics of transport vehicle, presence or absence of trolley failure and robot operation characteristics Configure Information.

  Further, in the embodiment of the present invention, the sensor information SIF may include only information on the mobile, or may include information on the mobile, position information of the sensor node, and the moving speed. It may include information on the mobile unit, position information and movement speed of the sensor node, and battery remaining amount, and generally, at least one of information on the mobile unit, position information, moving speed and battery remaining amount As long as it contains This is because the information collection device 8 can collect information of a mobile unit in which a sensor node is installed.

  In this case, the information on the moving object is vital information when the moving object is a human or an animal, and is information indicating whether or not there is a failure of the above-described moving vehicle or the like when the moving object is a transporting vehicle or a truck. And vital information may be a heart rate, body temperature, blood pressure, etc., and may be other than that.

  Furthermore, although it has been described above that the information collecting device 8 and the display device 9 are physically provided separately, the embodiment of the present invention is not limited to this, and the information collecting device 8 and the display device 9 are not limited thereto. May be physically provided integrally.

  Furthermore, in the above description, in each of the sensor nodes 1 to 7, the wireless module 11 and the wireless module 12 have been described as physically provided separately, but the embodiment of the present invention is not limited thereto. Each of the sensor nodes 1 to 7 may be physically provided with one wireless module if it can be changed to a different wireless communication scheme. The same applies to the wireless modules 81 and 82 of the information collection device 8.

  In the first example of the information collection method described above, it has been described that each of the sensor nodes 1 to 7 transmits the sensor information SIF to the information collection device 8 using the wireless communication RF1 or the wireless communication RF2.

In the second example of the information collection method described above, the information collection device 8 determines the area REG3 to which the sensor information SIF can be transmitted (or transferred) using only the wireless communication RF1, and is included in the area REG3. The sensor node transmits the sensor information SIF to the relay node included in the region REG3 using the wireless communication RF1, and the relay node transmits the sensor information SIF received from another sensor node using the wireless communication RF1 or the wireless communication RF2. It has been described that the sensor node relayed to the information collecting device 8 and not included in the region REG3 transmits the sensor information SIF to the information collecting device 8 using the wireless communication RF1 or the wireless communication RF2. And
Furthermore, in the third example of the information collection method described above, each of the sensor nodes 1 to 7 transmits the sensor information SIF to the information collection device 8 using the same wireless communication as the first and second examples of the information collection method. Described to send.

  Furthermore, in the fourth example of the information collection method described above, when the relay node moves rapidly, the relay node switches the wireless communication RF1 to the wireless communication RF2 and transmits the sensor information SIF to the relay node. Has described switching the relay destination or switching the wireless communication scheme from the wireless communication RF1 to the wireless communication RF2.

  Furthermore, in the fifth example of the information collection method described above, it has been described that the sensor node that has found an abnormality of vital information transmits the sensor information SIF to the information collection apparatus 8 by the wireless communication RF1 or the wireless communication RF2.

  Furthermore, in the sixth example of the information collection method described above, the sensor node whose battery remaining capacity falls below the reference value lengthens the transmission interval TXITV to set the sensor information SIF as the information collection device by the wireless communication RF1 or the wireless communication RF2. It explained that it sent to 8.

Therefore, in the embodiment of the present invention, the sensor nodes 1 to 7
(1) Direct communication to information collecting apparatus 8 using wireless communication RF1 or wireless communication RF2 (2) Multi-hop communication to information collecting apparatus 8 using wireless communication RF1 (3) Sensor node using wireless communication RF2 Multi-hop communication from the sensor node to the information collecting device 8 using direct communication from the relay node to the relay node and direct communication from the relay node to the information collecting device 8 using the wireless communication RF1 (4) using the wireless communication RF1 Sensor by any of multi-hop communication from the sensor node to the information collecting device 8 using direct communication from the sensor node to the relay node and direct communication from the relay node to the information collecting device 8 using the wireless communication RF 2 The information SIF may be delivered to the information collection device 8. Then, in the embodiment of the present invention, the sensor nodes 1 to 7 do not deliver the sensor information SIF to the information collection device 8 by multi-hop communication using the wireless communication RF2.

  That is, in the embodiment of the present invention, the sensor nodes 1 to 7 do not have any of the above (1), (2), (3) and (4) except for multi-hop communication by the wireless communication RF2. It is sufficient that the sensor information SIF be delivered to the information collecting device 8 using communication. Since the wireless communication RF2 is used to broadcast the advice information from the information collection device 8 to the sensor nodes 1 to 7, it is necessary to avoid multi-hop communication by the wireless communication RF2 to suppress the band shortage of the wireless communication RF2. Because there is

  Furthermore, in the embodiment of the present invention, the first and second wireless communications are determined based on the magnitude of the transmission distance regardless of the wide and narrow bandwidths. That is, the first wireless communication has a first communication area, and the second wireless communication has a second communication area wider than the first communication area.

  Furthermore, in the embodiment of the present invention, the information collecting device 8 holds the position information and / or the moving speed of the sensor nodes 1 to 7 and the information collecting device 8, so that the sensor node 1 holds It can be determined which of the radio communication RF1 and the radio communication RF2 should be used based on the position information and / or the moving speed of the information collection device 8 and the position information and / or the moving speed of the information collection device 8. Therefore, the information collection device 8 includes a signal indicating the wireless communication to be used by the sensor nodes 1 to 7 (a signal indicating that the wireless communication RF1 or the wireless communication RF2 is to be used) in the advice information and detects the sensor by the wireless communication RF2. It may be broadcast to nodes 1-7. In this case, each of the sensor nodes 1 to 7 transmits the sensor information SIF using the wireless communication RF1 or the wireless communication RF2 based on the signal indicating that the wireless communication RF1 or the wireless communication RF2 should be used included in the advice information. Do.

  Furthermore, in the embodiment of the present invention, the advice information may include only the topology information indicating the topology of the sensor nodes 1 to 7 and the information collection device 8, and the representative sensor among the densely-packed sensor nodes may be included. Only node identification information and location information may be included, only transmission amount and transmission interval of sensor information may be included, and only a signal indicating stopping transmission of sensor information may be included. It may include only signals instructing the on / off of the heart rate sensor 14 and the body temperature sensor 15 and the like, and topology information indicating the topology of the sensor nodes 1 to 7 and the information collecting device 8 and the sensor nodes 1 to 7 use Wireless communication (any of the wireless communication RF1 and RF2) and may include the sensor nodes 1 to 7 and In addition to the topology information indicating the topology of the information collection device 8, at least one of the frequency to be used by the sensor nodes 1 to 7, the transmission amount of the sensor information, the transmission interval of the sensor information, and the signal instructing on / off of the sensor Generally, topology information indicating the topology of the sensor nodes 1 to 7 and the information collection device 8, frequency, transmission amount of sensor information, transmission interval of sensor information, heart rate sensor 14 etc. It is sufficient to include at least one of the instruction signals for turning off.

  According to the embodiment of the present invention, the information collecting apparatus has the following configuration.

[Configuration 1]
The information collecting device comprises receiving means. The receiving means includes a first wireless communication according to a first wireless communication standard having a first communication area and a second wireless communication according to a second wireless communication standard having a second communication area wider than the first communication area. Sensor information including at least information on a mobile unit is received from a plurality of sensor nodes installed in the mobile unit by wireless communication excluding at least any of communication and excluding multi-hop communication by second wireless communication.

  According to the configuration 1, the sensor information is received from the plurality of sensor nodes by the wireless communication using at least the first wireless communication or the second wireless communication except the multi-hop communication by the second wireless communication. As a result, concentration of the wireless communication used for transmitting the sensor information on the second wireless communication is suppressed, and the band shortage of the second wireless communication is suppressed.

  Therefore, even if there are a large number of moving objects, sensor information can be accurately collected.

[Configuration 2]
In configuration 1, the sensor information further includes position information and moving speed of the sensor node. The information collecting apparatus further includes a generation unit and a transmission unit. The generation means detects the relative positional relationship between the plurality of sensor nodes and the information collection device based on position information and movement speeds of the plurality of sensor nodes included in the plurality of sensor information received from the plurality of sensor nodes. A plurality of sensor nodes and the topology of the information collecting apparatus based on the detected positional information of the plurality of sensor nodes, the moving speed and the relative positional relationship, and the first advice including topology information indicating the detected topology Generate information. The transmitting means broadcasts the first advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to configuration 2, topology information indicating the topology of the plurality of sensor nodes and the information collection device is transmitted to the plurality of sensor nodes. As a result, each sensor node selects the first wireless communication or the second wireless communication based on the topology information. That is, each sensor node selects one of the first and second wireless communications based on the topology information from the information collection device.

  Therefore, each sensor node can easily select one of the first and second wireless communications.

[Configuration 3]
In the configuration 1, the generation means detects a dense sensor node among the plurality of sensor nodes based on position information of the plurality of sensor nodes and the movement speed, and detects the dense sensor nodes from among the detected dense sensor nodes. A representative sensor node is detected, and second advice information including identification information of the detected representative sensor node and position information of the representative sensor node is generated. The transmitting means broadcasts the second advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to configuration 3, the information collection device transmits the identification information of the representative sensor node among the densely populated sensor nodes and the position information of the representative sensor node to the plurality of sensor nodes. Then, among the densely populated sensor nodes, sensor nodes other than the representative sensor node calculate the distance from the representative sensor node to the sensor node based on the position information of the sensor node and the position information of the representative sensor node. It detects that the distance is equal to or less than the radius of the communication area of the first wireless communication, and transmits the sensor information to the representative sensor node using the first wireless communication. Also, the representative sensor node relays sensor information from other sensor nodes using the first wireless communication or the second wireless communication.

  Therefore, the information collecting apparatus can collect sensor information from the sensor nodes in close proximity by the first wireless communication.

[Configuration 4]
In Configuration 1, the information collection device further comprises determination means. The determination means further detects the amount of sensor information and the amount of change based on the plurality of sensor information received from the plurality of sensor nodes, and based on the amount and the amount of change of the detected sensor information, The transmission amount and the transmission interval of the sensor information to be transmitted by each sensor node are determined so that the communication band of the second wireless communication does not become insufficient. The generation means generates third advice information by further including the transmission amount and the transmission interval of the sensor information determined by the determination means in the first advice information or the second advice information. The transmitting means broadcasts the third advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to the fourth configuration, the information collection device can collect sensor information by suppressing the bandwidth shortage of the first and second wireless communication.

[Configuration 5]
In Configuration 1, the generation means, in response to the detection of an abnormality in the information on the mobile object, the sensor information from sensor nodes other than the sensor node installed in the mobile object on which the abnormality in the information on the mobile object is detected. The fourth advice information including a signal indicating stopping transmission is generated. The transmitting means broadcasts the fourth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to configuration 4, it is possible to accurately collect sensor information from a sensor node installed in a mobile unit in which an abnormality in information about the mobile unit has been found.

[Configuration 6]
In configuration 4, the sensor information further includes the remaining amount of battery. The determination means further detects, based on a plurality of sensor information of a plurality of sensor nodes, a sensor node whose battery remaining amount falls below a reference value, and extends the transmission interval for transmitting the sensor information to the detected sensor node. Determine the long transmission interval. The generation unit generates fifth advice information in which the transmission interval of the sensor information included in the third advice information is changed to the long transmission interval determined by the determination unit. The transmitting means broadcasts the fifth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to the configuration 6, the battery life of the sensor node whose battery remaining amount is low can be extended, and sensor information can be collected also from the sensor node whose battery remaining amount is low.

[Configuration 7]
In the configuration 1, the generation unit is configured to detect the frequency used by each sensor node, the first instruction signal instructing the on / off of the position detector mounted on each sensor node, and the sensor on / off detecting information on the mobile object. The sixth advice information including the second instruction signal instructing the off is generated. The transmitting means broadcasts the sixth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication.

  According to the seventh aspect, the information collection device can control the frequency used by each sensor node. In addition, it is possible to control the on / off of the position detector and sensor mounted on the sensor node.

  Further, according to the embodiment of the present invention, the sensor node has the following configuration.

[Configuration 8]
A sensor node installed in a mobile unit existing in a second communication area centering on the information collection device according to Configuration 1, wherein the sensor node includes a generation unit and a transmission unit. The generation means generates first sensor information including information on the mobile. The transmitting means uses at least one of the first and second wireless communications described in Configuration 1 for the first sensor information generated by the generating means, and excludes multi-hop communications by the second wireless communication. Transmit to the information collection apparatus by wireless communication.

  According to configuration 8, the sensor node transmits the sensor information to the information collection device by wireless communication using at least the first wireless communication or the second wireless communication except for multi-hop communication by the second wireless communication. As a result, concentration of the wireless communication used for transmitting the sensor information on the second wireless communication is suppressed, and the band shortage of the second wireless communication is suppressed.

  Therefore, even if there are a large number of mobile units, sensor information can be accurately transmitted to the information collection device.

[Configuration 9]
In configuration 8, the generation unit generates position information and movement speed of the sensor node in the first sensor information to generate second sensor information. The transmission means transmits the second sensor information generated by the generation means to the information collection device.

  According to the configuration 9, the information collecting apparatus can detect the topology of the plurality of sensor nodes and the information collecting apparatus based on the position information and the moving speed of the sensor node.

[Configuration 10]
In Configuration 8 or 9, the sensor node further comprises receiving means and selecting means. The receiving means receives advice information including topology information indicating a topology of the plurality of sensor nodes and the information collection device from the information collection device by the second wireless communication. The selection means selects one of the first and second wireless communication based on the topology information included in the advice information received by the reception means. The transmitting means transmits the first sensor information or the second sensor information to the information collecting apparatus using the wireless communication selected by the selecting means.

  According to the configuration 10, the sensor node can easily select one of the first and second wireless communications based on the topology information received from the information collection device.

[Configuration 11]
In configuration 10, the sensor node further comprises topology construction means. The topology construction means constructs a new topology based on the topology information included in the advice information received by the reception means, and the position information and movement speed of the sensor node. The selection means selects one of the first and second wireless communications based on the new topology.

  According to the configuration 11, each sensor node can select one of the first and second wireless communication reflecting its own position information and moving speed.

[Configuration 12]
In the configuration 8 or 9, the transmitting unit is configured to transmit the first information when the advice information received by the receiving unit indicates that the sensor node should use the first wireless communication or the second wireless communication. The first sensor information or the second sensor information is transmitted to the information collection device using wireless communication or second wireless communication.

  According to configuration 12, each sensor node transmits sensor information using the first wireless communication or the second wireless communication according to the control from the information collection device.

  Therefore, the information collecting apparatus can control the wireless communication system to accurately collect sensor information.

[Configuration 13]
In the configuration 8 or 9, the transmitting unit is configured to transmit the first sensor information or the second sensor information when the advice information received by the receiving unit includes a signal indicating that the transmission of the sensor information from the sensor node is to be discontinued. Stop sending sensor information for

  According to the configuration 13, the information collection device can accurately collect sensor information from sensor nodes other than the sensor node.

[Configuration 14]
In the configuration 8 or 9, the transmission unit transmits the first sensor information or the second sensor information to the information collection apparatus according to the transmission interval when the advice information received by the reception unit includes the transmission interval of the sensor information. .

  According to the configuration 14, the information collection device can collect more sensor information.

  Further, according to the embodiment of the present invention, the information collecting system has the following configuration.

[Configuration 15]
Information collection system
An information collecting apparatus according to any one of configurations 1 to 7;
A sensor node according to any one of configurations 8 to 14;
And a display device for displaying the information collected by the information collection device.

  According to the configuration 15, it is possible to accurately collect information from the sensor node and display the collected information on the display device.

  It should be understood that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

  The present invention is applied to an information collection device, a sensor node and an information collection system provided with them.

  1 to 7 sensor nodes, 8 information collecting devices, 9 display devices, 10 information collecting systems, 11, 12, 81, 82 wireless modules, 13 microcomputers, 14 heart rate sensors, 15 temperature sensors, 16 acceleration sensors, 17, 84 GPS , 18 rechargeable batteries, 83 CPU, 85 non-volatile DB, 86 LAN, 87 power supplies.

Claims (14)

Any one of first wireless communication according to a first wireless communication standard having a first communication area and second wireless communication according to a second wireless communication standard having a second communication area wider than the first communication area Receiving means for receiving sensor information including at least information on a mobile body from a plurality of sensor nodes installed in the mobile body by wireless communication excluding multi-hop communication by the second wireless communication using at least provided,
The sensor information further includes position information and moving speed of the sensor node,
The receiving unit detects relative positional relationships between the plurality of sensor nodes and the information collection apparatus based on position information and movement speeds of the plurality of sensor nodes included in the plurality of sensor information received from the plurality of sensor nodes. A topology of the plurality of sensor nodes and the information collection device is detected based on position information of the plurality of detected sensor nodes, movement speed and relative positional relationship, and a first information including topology information indicating the detected topology Generating means for generating advice information;
Further comprising transmitting means for broadcasting to the plurality of sensor nodes of the first advice information generated by the second wireless communication by said generating means, information collection device. The generation means detects a dense sensor node among the plurality of sensor nodes based on position information and movement speed of the plurality of sensor nodes, and represents a representative of the detected dense sensor nodes. Detecting a sensor node, and generating second advice information including identification information of the detected representative sensor node and position information of the representative sensor node;
The information collecting apparatus according to claim 1, wherein the transmission unit broadcasts the second advice information generated by the generation unit to the plurality of sensor nodes by the second wireless communication. The amount of sensor information and the amount of change are further detected based on the plurality of pieces of sensor information received from the plurality of sensor nodes, and the first and the second are detected based on the detected amount of sensor information and the amount of change. And a determination unit configured to determine a transmission amount and a transmission interval of the sensor information to be transmitted by each sensor node so that the communication band of the second wireless communication does not become insufficient.
The generation means generates third advice information including the transmission amount and the transmission interval of the sensor information determined by the determination means;
The information collecting apparatus according to claim 1, wherein the transmission unit broadcasts the third advice information generated by the generation unit to the plurality of sensor nodes by the second wireless communication. The generation unit is configured to, in response to the detection of an abnormality in the information on the mobile unit, the sensor information from sensor nodes other than the sensor node installed on the mobile unit in which the abnormality on the information on the mobile unit is detected. Generating fourth advice information including a signal indicating stopping transmission;
The information collecting apparatus according to claim 1, wherein the transmitting means broadcasts the fourth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication. The sensor information further includes a battery remaining amount,
The determination means further detects, based on a plurality of sensor information of the plurality of sensor nodes, a sensor node in which the battery remaining amount falls below a reference value, and the detected sensor node should transmit the sensor information. Determine the long transmission interval by increasing the transmission interval,
The generation unit generates fifth advice information in which the transmission interval of the sensor information included in the third advice information is changed to the long transmission interval determined by the determination unit.
The information collecting apparatus according to claim 3 , wherein the transmitting means broadcasts the fifth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication. The generation means may turn on / off a frequency used by each sensor node, a first instruction signal instructing on / off of a position detector mounted on each sensor node, and a sensor detecting information on the mobile object. Generating sixth advice information including a second instruction signal to instruct;
The information collecting apparatus according to claim 1, wherein the transmitting means broadcasts the sixth advice information generated by the generating means to the plurality of sensor nodes by the second wireless communication. A sensor node installed in a mobile unit existing in the second communication area centering on the information collecting apparatus according to claim 1,
Sensor node generation means for generating first sensor information including information on the mobile object;
A multi-hop communication by the second wireless communication, using at least one of the first and second wireless communication according to claim 1, the first sensor information generated by the sensor node generating means And a sensor node transmission unit that transmits the information to the information collection device by wireless communication excluding the above. The sensor node generation unit generates second sensor information including position information and movement speed of the sensor node.
The sensor node according to claim 7 , wherein the sensor node transmission means transmits the second sensor information generated by the sensor node generation means to the information collection device. Sensor node receiving means for receiving advice information including topology information indicating a plurality of sensor nodes and the topology of the information collection device from the information collection device by the second wireless communication;
And selection means for selecting one of the first and second wireless communications based on topology information included in the advice information received by the sensor node reception means.
The sensor node transmitting means transmits the first sensor information and the second sensor information using a wireless communication selected by the selection unit to the information collection device, the sensor node according to 請 Motomeko 8 . The system further comprises topology construction means for constructing a new topology based on the topology information included in the advice information received by the sensor node reception means, and the position information and movement speed of the sensor node.
The sensor node according to claim 9 , wherein the selection means selects one of the first and second wireless communications based on the new topology. When the sensor node transmission means includes a signal indicating that the sensor node should use the first wireless communication or the second wireless communication, the advice information received by the sensor node reception means includes The sensor node according to claim 9 , wherein the first sensor information or the second sensor information is transmitted to the information collection device using one wireless communication or the second wireless communication. The sensor node transmission means, when the advice information received by the sensor node reception means includes a signal indicating that the transmission of the sensor information from the sensor node is to be discontinued, the first sensor information or the first sensor information The sensor node according to claim 9 , wherein transmission of the second sensor information is stopped. The sensor node transmitting unit collects the first sensor information or the second sensor information according to the transmission interval when the advice information received by the sensor node receiving unit includes a transmission interval of the sensor information. The sensor node according to claim 9 , transmitting to a device. An information collecting apparatus according to any one of claims 1 to 6 .
The sensor node according to any one of claims 7 to 13 ,
And a display device for displaying information collected by the information collection device.

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