JP6044178B2 - Detection system, sensor, setting information management method and program - Google Patents

Description

  The present invention relates to a detection system, a sensor, a setting information management method, and a program, and more particularly, to a detection system including a plurality of sensors and a server that communicates with the plurality of sensors.

  Conventionally, for example, as in the “Mimamori Hotto Line” described in Non-Patent Document 1, a service for detecting an operation on a specific device such as a pot and confirming the safety of an elderly person has been realized. .

Mimamori Hot Line-Parents' spirits can be seen in the pot-Zojirushi Mahobin Co., Ltd. [online], Internet <URL: http://www.mimamori.net/>

  For example, “Mimamori Hotto Line” in Non-Patent Document 1 converts the hardware of a pot into a black box, performs a measurement process by actively using the pot in a living environment, and notifies this by e-mail. It can be evaluated that special hardware is developed and measurement processing is performed, and services specialized for this are provided. In this way, at present, sensors are used mainly in homes where the content and location of measurement are fixed, the hardware is converted into a black box, and the measurement environment is under the control of the contractor. ing.

  However, originally, the sensor can collect various data such as temperature, humidity, and pressure. Furthermore, measurement information can be obtained moment by moment at a plurality of installation locations. However, the measurement contents are diverse and the measurement amount is enormous. Therefore, it is difficult for general consumers without specialized knowledge to use measurement information.

  Accordingly, an object of the present invention is to propose a detection system and the like that can be easily used by installing a plurality of sensors in a distributed manner, without requiring specialized knowledge, and managing them centrally.

  A first aspect of the present invention is a detection system including a plurality of sensors and a server that communicates with the plurality of sensors, wherein each sensor communicates with a measurement unit that performs measurement processing and the server. A communication unit and a main body unit detachably connected to at least the measurement unit are provided, and the main body unit stores actual sensor information storage means for storing actual sensor setting information and the actual sensor information storage means. Control means for controlling the measurement unit and the communication unit according to the actual sensor setting information, and actual sensor information changing means for changing the actual sensor setting information stored in the actual sensor information storage means, The server includes virtual sensor information storage means for storing virtual sensor information indicating settings of a plurality of virtual sensors obtained by virtualizing each of the plurality of sensors, and the virtual sensor from the information processing apparatus. Receiving means for receiving a virtual sensor information change instruction for changing part or all of the information, and virtual sensor information changing means for changing the virtual sensor information stored in the virtual sensor information storage means in accordance with the virtual sensor information change instruction And transmitting a real sensor information change instruction for instructing the change of the real sensor setting information according to the change of the virtual sensor information to the sensor in which the virtual sensor information of the corresponding virtual sensor is changed. And in the sensor, the communication unit receives the actual sensor information change instruction, and the actual sensor information change means is stored in the actual sensor information storage means in accordance with the actual sensor information change instruction. The actual sensor setting information is changed, and the control means measures the measurement according to the changed actual sensor setting information. And it is for controlling the communication unit.

  A second aspect of the present invention is the detection system according to the first aspect, wherein in the sensor, the main body part and the communication part are detachably connected, and the communication part is Under the control of the control means, measurement information measured and collected by the measurement unit is transmitted to the server, the reception means provided in the server receives the measurement information, and the server The measurement result storage means for storing the received measurement information and the measurement information stored in the measurement result storage means are processed according to the type of measurement value measured by the sensor and / or the measurement environment measured by the sensor. Measurement information analysis means for performing

  A third aspect of the present invention is a sensor that transmits measurement information to a server, and performs a measurement process to collect the measurement information, a communication unit that communicates with the server, the measurement unit, and the measurement unit. A main body unit detachably connected to the communication unit, the main body unit stores real sensor information storing actual sensor setting information, and when the communication unit receives an actual sensor information change instruction from the server, Actual sensor information changing means for changing the actual sensor setting information stored in the actual sensor information storage means in accordance with an actual sensor information change instruction, and controlling the measuring section and the communication section in accordance with the changed actual sensor setting information Control means.

  A fourth aspect of the present invention is a setting information management method for managing actual sensor setting information of a plurality of sensors, wherein each sensor includes a measurement unit that performs measurement processing, and a communication unit that performs communication with a server. A virtual body for storing virtual sensor configuration information indicating settings of a plurality of virtual sensors obtained by virtualizing each of the plurality of sensors. The server includes a sensor information storage unit, and the receiving unit included in the server receives a virtual sensor information change instruction for changing a part or all of the plurality of virtual sensor information from the information processing apparatus, and the virtual included in the server A sensor information changing unit changes the virtual sensor information stored in the virtual sensor information storage unit according to the virtual sensor information change instruction. And an actual sensor instructing a change in the actual sensor setting information in accordance with the virtual sensor configuration information to the sensor in which the virtual sensor information of the corresponding virtual sensor is changed An actual sensor information change instruction transmission step for transmitting an information change instruction; an actual sensor information change instruction reception step for the communication unit included in the sensor to receive the actual sensor information change instruction; and an actual sensor information change included in the sensor. An actual sensor information changing step in which the means changes the actual sensor setting information stored in the actual sensor information storage means in accordance with the actual sensor information change instruction; and the control means provided in the sensor includes the changed actual sensor setting information. The control unit includes a control step for controlling the measurement unit and the communication unit.

  According to a fifth aspect of the present invention, in a computer that is detachably connected to a measurement unit that performs measurement processing and collects measurement information and is connected to a communication unit that communicates with a server, the actual sensor information changing means includes the communication unit. When the actual sensor information change instruction is received from the server, the actual sensor information changing step for changing the actual sensor setting information stored in the actual sensor information storage means according to the actual sensor information change instruction, and the control means are changed. It is a program for implement | achieving the control step which controls the said measurement part and the said communication part according to the said actual sensor setting information.

  In the sensor of the present invention, the main body part and the measuring part can be attached and detached, and the main body part can be replaced with various types of measuring devices (pluggable). Conventionally, such a sensor requires an expert to set a specific profile according to the type of measurement unit according to the actual hardware configuration of each sensor. According to each aspect of the present invention, by virtualizing sensors on a server and managing them as virtual sensors, the sensor's actual sensor setting information (profile) is centrally managed by the server even if the sensors are distributed. It becomes possible to do. On the server, virtualized information is stored for each sensor, and a general consumer can change the virtual sensor setting on the server from an information processing device such as a personal computer or a smartphone. This profile is automatically reflected in the actual sensor setting information of the actual sensor. Accordingly, the user can centrally manage and use a plurality of sensors arranged in a distributed manner without special expertise.

  Furthermore, as in the second aspect of the present invention, the main unit and the communication unit are detachable, and an appropriate communication environment can be prepared according to the place where the sensor is installed. The measurement information of the sensor is accumulated on the server by the communication unit. Therefore, the analysis of measurement information by a plurality of sensors can be performed centrally and comprehensively in the server. For such so-called big data analysis, expert support is necessary. Centralized and comprehensive analysis on the server makes it easy for professionals to support and use measurement information.

  For example, a map of the installation location may be stored in the server, and the installation position may be managed by linking the virtual sensor with this map on the server. Then, the measurement information analysis means may take into account, for example, the relative positional relationship between the sensors and the influence of walls between the sensors in the analysis of the measurement results. Such analysis based on the location is necessary information for consumers living in the environment, but it has been difficult for experts to provide services in order to make hardware black boxes. It is an area. According to the present invention, sensor management and measurement information analysis according to such a specific installation environment can also be realized on the server in an integrated manner.

1 is a schematic block diagram of a detection system 1 according to an embodiment of the present invention. It is a figure which shows an example in which the detection system of FIG. 1 is used in daily life. It is a flowchart which shows an example of operation | movement of the detection system 1 in the scene of FIG. Is a block diagram showing an example of a hardware configuration of the sensor 5 _n in FIG. It is a flowchart which shows an example of operation | movement of CPU53 of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to this embodiment.

FIG. 1 is a schematic block diagram of a detection system 1 according to an embodiment of the present invention. The detection system 1 includes a server 3 (an example of “server” in the claims of the present application) and a plurality of sensors 5 ₁ ,..., 5 _N (an example of “sensors” in the claims of the present application). And an information processing device 7 (an example of “information processing device” in the claims of the present application).

  The server 3 is constructed as a cloud server on the Internet. The server 3 includes a virtual sensor information storage unit 11 (an example of “virtual sensor information storage unit” in the claims), a reception unit 13 (an example of “reception unit” in the claims), and a virtual sensor information change unit 15. (An example of “virtual sensor information changing means” in claims of this application), a transmission unit 17 (an example of “transmission means” in claims of this application), and a measurement information storage unit 19 (“measurement information storage means” of claims of this application) And a measurement information analysis unit 21 (an example of “measurement information analysis means” in the claims).

The sensor 5 _n (n is an integer from 1 to N) includes a communication unit 23 (an example of a “communication unit” in the present application claim), a main body unit 25 (an example of a “main body unit” in the present application claim), A measurement unit 27 (an example of a “measurement unit” in the claims) is provided. The communication unit 23, a plurality of communication devices 29 _1, ..., and a 29 _P. Measurement unit 27, a plurality of measuring devices 41 _1, ..., and a 41 _Q. The main unit 25 includes a plurality of communication device connection units 31 ₁ ,..., 31 _P , an actual sensor information storage unit 33 (an example of “actual sensor information storage unit” in the claims of the present application), and a control unit 35 (application claims). provided with an example) of the "control means", the actual sensor information change unit (an example of "actual sensor information changing means" in the claims), a plurality of measuring devices connecting portions 39 _1, ..., a 39 _Q. An example of the operation of the detection system 1 in a specific use environment will be specifically described later with reference to FIGS. 2 and 3. An example of the hardware configuration and operation of the sensor 5 _n will be specifically described later with reference to FIGS. 4 and 5.

  The information processing apparatus 7 includes a display unit 43, an input unit 45, and a communication unit 47.

  Each of the plurality of measurement devices 41 of the communication unit 27 performs measurement processing. Each measuring device 41 measures, for example, pyroelectricity, AC current, temperature, humidity, acceleration, illuminance, gas, atmospheric pressure, thermocouple, pressure, and the like. The measuring device 41 is detachably connected by a measuring device connecting portion 39 of the main body portion 25. The measurement information measured and collected by each measurement device 41 is transmitted to the server 3 by the communication device 29 of the communication unit 23.

The plurality of communication devices 29 ₁ ,..., 29 _P of the communication unit 23 are for communicating with the server 3, respectively. Each of the plurality of communication devices 29 is configured to configure a network by configuring a wired LAN, connecting to a public line (such as a 3G line), or wireless communication such as Wi-Fi or Bluetooth (registered trademark), for example. Is. The sensor 5 _n is connected to the Internet via a router or a gateway by, for example, Ethernet (registered trademark) by the communication device 29, and communication with the server 3 is established. The communication device 29 is detachably connected by a communication device connection unit 31 of the main body unit 25.

The actual sensor information storage unit 33 stores a profile (setting information) of the sensor 5 _n (an example of “actual sensor setting information” in the claims of the present application) (hereinafter referred to as “actual sensor setting information”). The control unit 35 refers to the actual sensor setting information stored in the actual sensor information storage unit 33 and controls the operation of the sensor 5 _n . The actual sensor information changing unit 37 changes the actual sensor setting information stored in the actual sensor information storage unit 33.

The virtual sensor information storage unit 11 corresponds to each of the plurality of sensors 5 ₁ ,..., 5 _N , and indicates virtual sensor information 22 _{1 ,.} Is memorized. The virtual sensor information 22 includes, for example, the hardware configuration of the virtual sensor, the usage environment of the virtual sensor, and the like. Further, for example, a virtual sensor profile (hereinafter referred to as “virtual sensor setting information”) is stored, and the actual sensor setting information of the corresponding sensor 5 in accordance with the correction of the virtual sensor setting information of the virtual sensor information 22. May be corrected.

  The receiving unit 13 receives measurement information measured and collected by the measuring device of each sensor 5 from each sensor 5, or issues a virtual sensor information change instruction for changing a part or all of the settings and / or configurations of the virtual sensor. Or received from the information processing apparatus 7. Here, “A and / or B” means A, B, or A and B.

  The virtual sensor information changing unit 15 changes the virtual sensor information stored in the virtual sensor information storage unit 11 in accordance with the virtual sensor information change instruction received from the information processing device 7.

  The measurement information storage unit 17 stores measurement information collected from each sensor 5. The measurement information analysis unit 19 analyzes the measurement information stored in the measurement information storage unit 17.

  The transmission unit 21 transmits the virtual sensor information stored in the virtual sensor information storage unit to the information processing apparatus 7 or responds to the change of the virtual sensor information to the sensor 5 whose virtual sensor information has been changed. An actual sensor information change instruction for instructing change of actual sensor setting information is transmitted, or an analysis result of the measurement information analysis unit 21 is transmitted to the information processing apparatus 7.

When the transmission unit 21 of the server 3 transmits the real sensor information change instruction to the sensor 5 _n, the communication device 29 of the sensor 5 _n of the communication unit 23 receives the actual sensor information change instruction. When the communication device 29 receives the actual sensor information change instruction, the actual sensor information change unit 37 changes the actual sensor setting information stored in the actual sensor information storage unit 33 in accordance with the actual sensor information change instruction. The control unit 35 controls the operation of the sensor 5 _n with reference to the changed actual sensor setting information.

The information processing apparatus 7 is, for example, a personal computer or a smartphone. This is used by the user who installed the sensor 5. The display unit 43 included in the information processing apparatus 7 displays virtual sensor information stored in the virtual sensor information storage unit 11 received by the communication unit 47 from the server 3. When the user connects the communication device 29 and the measurement device 41 to the main body portion 25 of the sensor 5 _n and installs the communication device 29 and the measurement device 41 in a predetermined position, the user operates the input unit 45 with reference to the content displayed on the display unit 43, and If there is no virtual sensor information 22 _n corresponding to the sensor 5 _n in No. 3, this is newly input, or if it already exists, information for correcting the existing virtual sensor information 22 _n is input.

Note that the virtual sensor information change instruction by the information processing device 7 may be, for example, due to a change in the hardware configuration of the sensor 5 _n . This is a case where the setting location is not changed, and the hardware configuration is changed from, for example, a measuring device that detects a low temperature to a measuring device that can detect a high temperature. In this case, the information processing device 7 may maintain the setting of the measurement timing of the virtual sensor in the server 3 and change only the hardware configuration information of the virtual sensor. Further, for example, it is possible to change the installation location or change the measurement timing without changing the hardware configuration of the sensor 5 _n . In this case, the hardware configuration of the virtual sensor in the server 3 may not be changed by the information processing device 7, but only the setting of the measurement timing of the virtual sensor may be changed. An instruction to change both of these is also conceivable.

The communication unit 47 transmits input information as a virtual sensor information change instruction to the server 3. In the server 3, the receiving unit 13 receives this virtual sensor information change instruction. The virtual sensor information changing unit 15 changes the virtual sensor information of the sensor 5 _n according to the virtual sensor information change instruction. The transmission unit 21 transmits an actual sensor information change instruction to the sensor 5 _n .

Referring to FIGS. 2 and 3, an outline of the installation of the sensor 5 _n to the reception of the measurement result by the information processing apparatus 7. FIG. 2 is a diagram illustrating an example in which the detection system of FIG. 1 is used in daily life. FIG. 3 is a flowchart showing an example of the operation of the detection system 1 in the scene of FIG.

In the example of FIG. 2 and FIG. 3, the user, the main body portion 25 of the sensor 5 _n, connected to a measuring device 41 for measuring acceleration, the communication device 29 for wireless LAN such as Wi-Fi, sensor 5 _n Is installed on the door (step STP1 in FIG. 3). Thus, since the sensor 5 _n can realize various measurement functions and communication functions, it can be referred to as a smart sensor box. After connection, the user, and turn the sensor 5 _n, the sensor 5 _n performs initialization process (step STP2 of Fig. 3). For example, the types of the measuring device 41 and the communication device 29 connected to the server 3 are confirmed, or the communication device 29 establishes a communication path with the server 3. In FIG. 2, it is assumed that the communication between the sensor 5 _n and the server 3 is realized via the router 9 under the control of the control unit 35 of the sensor 5 _n .

The user operates the information processing apparatus 7 owned by the user, and sets virtual sensor information corresponding to the sensor 5 _n , a usage environment, and the like for the server 3 constructed on the cloud. A change instruction is transmitted (step STP3 in FIG. 3).

The server 3 corrects the virtual sensor information 22 _n according to the virtual sensor information change instruction. Even when the sensor 5 _n measures acceleration, for example, the actual sensor setting information is preferably different between when the sensor 5 _n is provided on a door and when the sensor 5 _n is provided on a ball or the like. The reason is that when it is provided on the door, it will be a typical movement, but when it is provided on a ball, etc., it will be an irregular movement and the data required for judgment will be different. This is because it is desirable to make the information different. In addition, for example, when measuring pyroelectricity, since changes in light including infrared rays are detected, changes at a certain speed are required, and if the specimen moves slowly, there is a possibility that it cannot be detected. is there. In order to set or correct such a sensor profile, for example, a program may be written and transferred to hardware for setting. However, this presupposes a very high level of expertise. Further, a method of adjusting the sensor by attaching a special part such as a knob may be considered. However, with such a method, generally only simple settings are realized.

According to the present invention, the user only needs to operate the virtual sensor of the server 3. The server 3 transmits to the sensor 5 _n an actual sensor information change instruction for setting actual sensor setting information corresponding to the corrected virtual sensor. The actual sensor information changing unit 37 of the sensor 5 _n corrects the actual sensor setting information in accordance with the actual sensor information change instruction (step STP4 in FIG. 3).

The control unit 35 of the sensor 5 _n refers to the corrected actual sensor setting information and transmits the measurement information measured by the measuring device 41 to the server 3 (step STP5 in FIG. 3). Then, the measurement information analysis unit 19 of the server 3 analyzes, for example, that the elderly are living well by regularly opening and closing the door (step STP6 in FIG. 3), and notifies that fact. It transmits to the information processing apparatus 7 (step STP7 of FIG. 3).

Thus, the user who set up the sensor 5 _n, even without any special expertise, only by operating the virtual sensor on the server 3 in accordance with the actual hardware configuration of the sensor 5 _n, the sensor 5 _n You can use the service you used.

For example, the server 3 adds information indicating the hardware configuration of the virtual sensor to the actual sensor information change instruction, and the actual sensor information change unit 37 of the sensor 5 _n is included in the received actual sensor information change instruction. Check the consistency between the hardware configuration of the virtual sensor and the actual hardware configuration, and if they match, make corrections according to the actual sensor information change instruction. 3 may be transmitted. In addition, the number of sensors 5 is expected to be enormous. In order to identify each sensor 5, an ID may be given to each sensor 5. For example, other identification information such as an IP address or a MAC address may be used as the ID, or the ID may be unique locally based on the user or the installation location.

Next, the configuration and operation of the sensor 5 _{n in} FIG. 1 will be specifically described with reference to FIGS. 4 and 5.

FIG. 4 is a block diagram showing an example of a hardware configuration of the sensor 5 _n of FIG. The same components as those in FIG. 1 are denoted by the same reference numerals. In FIG. 4, the communication unit 23 includes a communication device 29 ₁ for wired LAN and a Wi-Fi communication device 29 ₂ for wireless LAN. The communication devices 29 ₁ and 29 ₂ are connected to the main body portion 25 by communication device connection portions 31 ₁ and 31 ₂ , respectively. The communication device connection units 31 ₁ and 31 ₂ are connectors, for example, for connecting each communication device 29 and the main body unit 25 detachably.

The measurement unit 27 includes an acceleration measurement device 41 ₁ , a pyroelectric measurement device 41 ₂ , an AC current measurement device 41 _3, and a humidity measurement device 41 ₄ . These measuring devices are connected to the main body 25 by means of communication device connecting portions 31 ₁ and 31 ₂ , respectively. Measuring device 41 ₁ to 41 _4, respectively, by the measuring device connecting portions 39 ₁ to 39 ₄ connected to the main body portion 25. Measuring device connection portion 39 _{1-39 4} is, for example, a connector is provided for removably connected. Each measuring device may be operated by providing a processing device individually, or may be operated under the control of the CPU 53.

The main body unit 25 further includes a NIC 51, a CPU 53, and a memory 55. The memory 55 stores a profile and corresponds to the actual sensor information storage unit 33 in FIG. The NIC 51 is a network interface controller and controls communication by the communication device 29. The CPU 53 controls the operation of the sensor 5 _n according to a program as a central processing unit. The NIC 51 and the CPU 53 correspond to the control unit 35 in FIG. Further, the CPU 53 corresponds to the actual sensor information changing unit 37 in FIG. 1 as changing the profile of the memory 55.

  FIG. 5 is a flowchart showing an example of the operation of the CPU 53 of FIG. When starting the process, the CPU 53 performs an initialization process (step ST1 in FIG. 5). In the initial state, all devices are assumed to be in a slave state (a state in which the device operates according to the operation of another device). Then, the communication device 29 is controlled to establish communication with the server 3. Thereafter, the CPU 53 is set to a master state (a state in which it operates with respect to another device). Subsequently, the CPU 53 scans the measuring device 41 and recognizes the connected measuring device 41 (step ST2 in FIG. 5). The CPU 53 stores the connection information of the measuring device 41 in the memory 55 (step ST3 in FIG. 5).

  Subsequently, the polling operation (steps ST4 to ST11 in FIG. 5) of the connected measuring device 41 is performed. Specifically, the CPU 53 selects the measurement device 41 (step ST4 in FIG. 5), and obtains data from the selected measurement device 41 (step ST5 in FIG. 5). And it transfers to a slave state from a master state, and will be in the state which operate | moves by operation | movement of the measuring apparatus 41 (step ST6 of FIG. 5). It is determined whether there is data measured by the measuring device (step ST7 in FIG. 5). If there is data, data processing (for example, processing for transmitting data to the server 3) is performed (step ST8 in FIG. 5). ), The process is repeated until the time determined by the profile (8 ms is illustrated in FIG. 5) (step ST9 in FIG. 5), and if the bus is in an active state, it is in a non-active state. When waiting (step ST10 in FIG. 5) and entering the inactive state, the slave state is shifted to the master state (step ST11 in FIG. 5), and the same processing is performed on the next measuring apparatus (FIG. 5). Steps ST4 to ST11). The CPU 53 may perform other operations during standby because the bus is in an active state.

Even if the communication device 29 and / or the measurement device 41 are replaced by the operation of FIG. 5 and the hardware configuration is changed, the sensor 5 _n operates, performs measurement processing, and transmits the measurement result to the server 3. be able to. The profile is corrected according to the actual sensor information change instruction when the virtual sensor information of the server 3 is corrected.

  FIG. 5 shows an example in which the CPU 53 performs polling. For example, when the sensor moves due to an external factor (for example, when the current flows (consumes power) or the sensor moves because of the operation), it can be realized in the same way. is there. The present invention is not limited to the case of FIG.

DESCRIPTION OF SYMBOLS 1 Detection system, 3 server, 5 ₁ , ..., 5 _N sensor, 7 Information processing device, 9 Router, 11 Virtual sensor information storage unit, 13 Reception unit, 15 Virtual sensor information change unit, 17 Measurement information storage unit, 19 Measurement information analysis unit, 21 transmission unit, 22 _1, ..., 5 _N virtual sensor information, the communication unit 23, 25 main body, 27 measuring unit, 29 _1, ..., 29 _P communication device, 31 _1, ... 31 _P communication device connected , 33 actual sensor information storage unit, 35 control unit, 37 actual sensor information change unit, 39 ₁ ,..., 39 _Q measurement device connection unit, 41 ₁ ,..., 41 _Q measurement device, 43 display unit, 45 input unit, 47 communication unit, 51 NIC, 53 CPU, 55 memory

Claims (3)

A detection system comprising a plurality of sensors and a server communicating with the plurality of sensors,
Each of the sensors includes a measurement unit, a communication unit, and a main body unit,
The main body includes the actual sensor information changing means, actual sensor information storage means, and control means,
The server includes virtual sensor information storage means, virtual sensor information change means, reception means, and transmission means,
In each of the sensors,
It said body portion, and between the said communicating portion between the measuring unit is detachably connected,
The measurement unit collects measurement information by performing a measurement process, and can change the measurement process by connecting another measurement unit instead of the measurement unit,
The communication unit transmits the measurement information to the server, and can change communication processing by connecting another communication unit instead of the communication unit.
In the server,
The virtual sensor information storage means stores virtual sensor information corresponding to each sensor,
The virtual sensor information includes virtual sensor setting information,
The virtual sensor setting information is setting information corresponding to the type of meter side of virtual sensors virtualizing said sensor corresponding,
The receiving unit may receive the virtual sensor information change instruction to change some or all of the virtual sensor information,
The virtual sensor information changing means, the if the virtual sensor information change instruction instructs the change of the virtual sensor setting information, change the virtual sensor setting information,
The transmission means changes the actual sensor information instructing the sensor corresponding to the virtual sensor whose virtual sensor setting information has been changed to change the actual sensor setting information in accordance with the change of the virtual sensor setting information. to send instructions to,
In the sensor in which the corresponding virtual sensor setting information has been changed ,
The communication unit receives the actual sensor information change instruction,
The actual sensor information changing means changes the said actual sensor setting information stored in the real sensor information storage means in accordance with said actual sensor information change instruction,
The control means that controls the measurement unit and the communication unit in accordance with the actual sensor setting information changed, the detection system. The virtual sensor information includes information indicating a hardware configuration,
The information indicating the hardware configuration can identify the measurement unit connected to the main body of the corresponding sensor,
If the virtual sensor information change instruction instructs the change of the plurality of measurement units in the information indicating the hardware configuration, the hardware stored in the virtual sensor information storage means according to the virtual sensor information change means to change the information indicating the configuration, the detection system of claim 1, wherein. In each of the sensors, there are a plurality of measurement units connected to the main body, and the measurement process can be changed by removing some or all of the plurality of measurement units and connecting another change unit,
In the server,
The information indicating the hardware configuration can identify each measurement unit connected to the main body of the corresponding sensor,
The detection system according to claim 1 or 2, wherein the virtual sensor setting information is for setting setting information corresponding to a type of each of the measurement units connected to the corresponding sensor .