JP7535925B2 - COMMUNICATION DEVICE, COMMUNICATION SYSTEM, AND COMMUNICATION METHOD - Google Patents

Description

The present invention relates to a communication device, a communication system, and a communication method for wireless communication.

A host system that wirelessly communicates with multiple communication devices and executes specific processing based on data received from each communication device has been known for some time. A gateway is interposed between the communication devices and the host system to establish communication, and wireless communication using radio waves is commonly used for communication between the communication devices and the gateway. For example, in facilities such as commercial facilities and industrial facilities, a communication system is used that includes multiple detectors installed within the facility and multiple communication devices that transmit data received from the multiple detectors via wireless communication to a monitoring system via a gateway. The communication device includes a wireless communication module that transmits wireless signals and a CPU that controls the wireless communication module.

Here, the CPU of the communication device controls the wireless communication module at a specified cycle, so that the communication device transmits wireless signals at a fixed, pre-defined cycle. However, there are cases where the timing of wireless signal transmissions in multiple reading devices accidentally overlaps, causing interference between the transmitted radio waves and adversely affecting communication.

Patent Document 1 discloses a technology for preventing communication errors caused by the above-mentioned duplicated transmission of wireless signals. Patent Document 1 discloses a wireless communication network system equipped with multiple wireless terminals that function as communication devices, and the wireless signal transmission cycle is set to be the same for these multiple wireless terminals, but the initial transmission timing is determined based on a serial number uniquely assigned to each terminal so that the initial transmission timing does not overlap between terminals. In this way, the initial transmission timing is determined so that it does not overlap between each wireless terminal, so that duplicate transmission of wireless signals can be prevented even if wireless signals are transmitted with the same transmission cycle.

Patent No. 3454155

In facilities such as the above-mentioned commercial and industrial facilities, the number of detectors and communication devices to be installed increases in proportion to the total floor area. However, if the communication mode described in Patent Document 1 is adopted, all communication devices will transmit wireless signals at the same transmission cycle, so within the transmission cycle of one communication device, all other communication devices will need to transmit wireless signals, and the number of available communication devices will be limited depending on the transmission cycle.

In view of the above problems, the present invention aims to provide a communication device, a communication system, and a communication method that do not limit the number of uses.

To achieve the above object, the communication device of the present invention is characterized by comprising a receiving unit that receives detection results from a detector, a transmitting unit that periodically wirelessly transmits information based on the received detection results to a higher-level device, and a control unit that randomly controls the transmission intervals of the transmitting unit.

The transmission interval includes a first transmission interval and a second transmission interval that is shorter than the first transmission interval, and the control unit randomly controls one or both of the first transmission interval and the second transmission interval.

The control unit is also characterized in that, when it recognizes the occurrence of an event based on the received detection result, it controls the transmission interval to the second transmission interval.

The receiving unit receives the detection results from the multiple detectors, and the control unit controls the transmission interval to the second transmission interval when it recognizes the occurrence of an event based on any of the detection results received from the multiple detectors.

The control unit is also characterized in that it randomly controls one or both of the first transmission interval and the second transmission interval based on a random number.

The transmission interval, which is randomly controlled based on the random number, is determined within a certain range.

The transmitter is also characterized in that it periodically wirelessly transmits information based on the multiple detection results.

Furthermore, the information based on the multiple detection results is the same.

The receiving unit is also characterized in that it receives the detection result from the detector via wired communication.

The detector is a gas measuring device, and the event is characterized in that the gas measuring device detects a gas having a concentration above or below a predetermined concentration.

The first transmission interval is also characterized by being within 3 minutes.

The second transmission interval is also characterized by being within 30 seconds.

The transmitter unit is also characterized by including a long-distance wide-area wireless network module.

To achieve the above object, the communication system of the present invention is characterized by comprising a detector that detects an event and the communication device described above.

To achieve the above object, the communication method of the present invention is characterized by including a receiving step of receiving a detection result from a detector that detects an event, a transmitting step of periodically wirelessly transmitting information based on the received detection result to a higher-level device, and a control step of randomly controlling the transmission interval in the transmitting step.

The communication device, communication system, and communication method of the present invention do not limit the number of uses.

1 is a schematic diagram of a monitoring system according to an embodiment of the present invention. FIG. 2A is a hardware configuration diagram of a gas detector included in the monitoring system, and FIG. 2B is a functional block diagram of the gas detector. FIG. 2A is a hardware configuration diagram of a communication device included in the monitoring system, and FIG. 2B is a functional block diagram of the communication device. 3 is a main flow showing the operation of the communication device. 13A is a flow diagram showing a flow of an interval control process in the above operation flow, and FIG. 13B is a flow diagram showing a flow of an interrupt process. FIG. 4 is a diagram illustrating an example of the operation of the monitoring system.

Embodiments of the communication device, communication system, and communication method according to the present invention will be described below with reference to the drawings, using a monitoring system as an example.

As shown in FIG. 1, the monitoring system 1 of this embodiment is a system for monitoring the occurrence of gas leaks in buildings such as industrial facilities and commercial facilities, and includes multiple gas detectors 10a-10m (hereinafter collectively referred to as gas detectors 10), multiple communication devices 20a-20c (hereinafter collectively referred to as communication devices 20), and a monitoring device 30, which is a higher-level device. In this embodiment, the building is divided into multiple monitoring areas, and multiple gas detectors 10a-10c, 10d-10i, 10j-10m and communication devices 20a, 20b, and 20c capable of wired communication with the multiple gas detectors 10a-10c, 10d-10i, and 10j-10m are installed in each monitoring area. The monitoring device 30 is connected to the communication devices 20 installed in each monitoring area so that they can communicate with each other via a network.

The gas detector 10 is installed at a specified location, such as on a wall or ceiling inside a building, and is a device that detects gas leaks that occur around the installation location. As shown in FIG. 2, the sensor 12 is connected to a microcontroller unit (hereinafter referred to as MCU 14) via an analog-to-digital conversion circuit (hereinafter referred to as ADC 13), and the MCU 14 is connected to a wired communication module 15 that functions as a transmitter 150.

The sensor 12 is typically a sensor that detects the concentration of a flammable or toxic gas, and may be a semiconductor sensor that changes electrical conductivity (resistance value) in response to gas adsorption on the semiconductor surface, or a constant-potential electrolysis sensor that electrolyzes CO gas at a predetermined potential and generates an electrolysis current in response to the gas concentration.

As described above, the output of the sensor 12 is electrically connected to the input of the MCU 14 via the ADC 13. With this configuration, the analog signal output from the sensor 12 is converted to a digital signal by the ADC 13 and input to the MCU 14. The MCU 14 may have the ADC 13 built in. The MCU 14 has a central processing unit (hereinafter referred to as the CPU 16) execute a detection program pre-stored in the memory 17 to cause the MCU 14 to function as an acquisition unit 141 that acquires the output from the sensor 12, a measurement unit 142 that measures the ambient gas concentration based on the acquired output signal, a comparison unit 144 that compares the measured gas concentration with a threshold value 143 for issuing an alarm, and an output unit 145 that outputs the comparison result as a detection result.

The detection result output from the MCU 14 is sent to the communication device 20 via the wired communication module 15. There are no particular limitations on the communication method between the gas detector 10 and the communication device 20, but in this embodiment, an RS485 communication module is used as the wired communication module 15, and multiple gas detectors 10a to 10c are daisy-chained to one communication device 20a. Therefore, the detection result is transmitted to the communication device 20a by a so-called bucket brigade method, in which the detection result is transmitted one after another from the multiple gas detectors 10a to 10c. The same communication mode is also used for the multiple gas detectors 10d to 10i daisy-chained to the communication device 20b, and the multiple gas detectors 10j to 10m daisy-chained to the communication device 20c.

The sensor 12, ADC 13, MCU 14, and wired communication module 15, as well as the board on which the power supply circuit that supplies power to these components is mounted, are housed in a housing and installed at a predetermined location within the building. An opening is formed in front of the sensor 12 in the housing to allow gas to enter the area surrounding the installation location.

Next, the communication device 20 is a device that transmits detection results received from multiple gas detectors 10 to the monitoring device 30, and as shown in FIG. 3, includes a wired communication module 21 (RS485 module) that performs wired communication with the gas detectors 10, a long-distance wide area wireless network module 22 (LoRa module) that communicates with the monitoring device 30, and an MCU 23 that controls the wired communication module 21 and the long-distance wide area wireless network module 22. The long-distance wide area wireless network module 22 is a module for performing long-distance wireless communication by radio waves, and its output is connected to an antenna 24.

The memory 25 of the MCU 23 of the communication device 20 previously stores a communication control program that controls the wired communication module 21 and the long-distance wide area wireless network module 22 to communicate with the gas detector 10 and the monitoring device 30. The CPU 26 of the MCU 23 executes the program, causing the wired communication module 21 to function as a receiver 210 that receives detection results from the gas detector 10, and the long-distance wide area wireless network module 22 to function as a transmitter 220 that transmits the detection results to the monitoring device 30.

The monitoring device 30 is a computer that receives detection results from multiple communication devices 20 installed in the building and monitors gas leaks in the building based on the received detection results, and is connected to the network via a gateway. If the received detection results indicate the occurrence of a gas leak, the monitoring device 30 transmits an alarm command to each alarm (not shown) installed in the building.

Here, the communication device 20 of this embodiment periodically transmits the detection result to the monitoring device 30 at a first interval during normal operation, and periodically transmits the detection result at a second interval that is shorter than the first interval during an abnormal operation in which a gas leak is detected. The first interval and second interval are determined randomly. A specific flow will be described below with reference to FIG. 4.

4 shows a main flow executed by the MCU 23 of the communication device 20. First, the MCU 23 executes a first acquisition process (s10). The first acquisition process (s10) is a process for acquiring detection results from a plurality of gas detectors 10 connected to the communication device 20 by wire when the MCU 23 of the communication device 20 is started.
(1) Specifically, MCU 23 outputs a control signal to control wired communication module 21. The control signal includes an address specifying gas detector 10 from which detection results are to be obtained, and a request for transmission of the detection results to gas detector 10. Wired communication module 21 of communication device 20 outputs a communication signal for communicating with wired communication module 15 of gas detector 10 based on the input control signal.
(2) If the communication signal does not specify its own address, the wired communication module 15 of the gas detector 10 to which the communication signal is input outputs the communication signal to the next gas detector 10. Similarly, if the communication signal does not specify its own address, the next gas detector 10 to which the communication signal is input outputs a communication signal to the next gas detector 10. In this way, the communication signal including the address and the transmission request is transmitted to multiple gas detectors 10 by a so-called bucket brigade method.
(3) On the other hand, when its own address is specified in the input communication signal, wired communication module 15 of gas detector 10 outputs a control signal including a transmission request to MCU 14 of that gas detector 10. In response to the transmission request, MCU 14 of gas detector 10 outputs a control signal including the detection result to wired communication module 15 of that gas detector 10, and wired communication module 15 outputs a communication signal including the detection result to communication device 20. This communication signal is transmitted to communication device 20 in the same manner as the bucket brigade method described above.
(4) When the communication signal is input, the wired communication module 21 of the communication device 20 outputs the detection result contained in the communication signal to the MCU 23 of the communication device 20, incorporating the detection result contained in the communication signal into a control signal. By performing the above process by specifying the address of each gas detector 10, the communication device 20 acquires the detection result from each gas detector 10. The MCU of the communication device 20 stores the detection result in memory 25 in association with detector identification information that identifies each gas detector 10.

When the MCU 23 of the communication device 20 acquires the detection results by the first acquisition process (s10), it executes a transmission process (s20). The transmission process (s20) is a process for transmitting the detection results acquired from each gas detector 10 to the monitoring device 30, and outputs a control signal including the detector identification information stored in the memory 25 and the detection results to the long-distance wide area wireless network module 22. The long-distance wide area wireless network module 22 generates a communication signal based on the input control signal and outputs the communication signal via an antenna. The CPU of the monitoring device 30 to which the communication signal is input stores the detector identification information and detection results included in the communication signal in memory, and activates an alarm installed in the building if the detection results indicate an abnormality.

Whenever the MCU 23 of the communication device 20 executes the above-mentioned transmission process (s20), it executes an interval setting process (s30). The interval setting process (s30) is a process for setting the transmission interval of the detection result, and randomly sets a counter value according to the content of the detection result. The counter value is counted down in an interrupt process (s60) that occurs every second, and the transmission process is executed when the counter value reaches 0. As a result, the communication device 20 repeatedly transmits the detection result at intervals that are set randomly according to the content of the detection result.

Specifically, as shown in FIG. 5(a), in the interval setting process (s30), a first interval setting process (s32) or a second interval setting process (s33) is executed depending on the obtained detection result, and then an interrupt setting process (s34) is executed.
(1) The first interval setting process (s32) is a process for setting the transmission interval to a first interval when the detection result indicates normality (s31: Yes). The first interval is randomly determined within a predetermined range (typically, within a range of 24 to 36 seconds, taking into account ±20% of 30 seconds) centered on a first reference interval (typically, 30 seconds), and is set by substituting a random number generated so as to be a value within the predetermined range (24 to 36) into a counter variable.
(2) The second interval setting process (s33) is a process for setting the transmission interval to a second interval when the detection result indicates an abnormality (s31: No). The second interval is randomly determined within a predetermined range (typically, within a range of 8 to 12 seconds, taking into account ±20% of 10 seconds) centered on a second reference interval (typically, 10 seconds), and is set by substituting a random number generated so as to be a value within the predetermined range (8 to 12) into a counter variable.
(3) After the first interval setting process (s32) or the second interval setting process (s33) is executed, an interrupt setting process (s34) is executed. The interrupt setting process (s34) is a process for generating a timer interrupt every second, and the number of system clocks corresponding to one second and a flag for permitting the interrupt are set in a predetermined register.

Returning to FIG. 4, the MCU 23 of the communication device 20 executes the above-mentioned interval setting process (s30) and then executes the second acquisition process (s40) and confirmation process (s50). The second acquisition process (s40) is a process for acquiring detection results from multiple gas detectors 10, similar to the above-mentioned first acquisition process (s10). The confirmation process (s50) is a process for confirming whether or not a change has occurred in the detection results of each gas detector 10, for example, by taking the exclusive OR of the newly acquired detection result and the detection result acquired previously. If the exclusive OR is "true", it is assumed that a change has occurred in the detection result, and the transmission process (s20) is executed to transmit the changed detection result. Then, as described above, the interval setting process (s30) and the second acquisition process (s40) are executed after the transmission process (s20).

On the other hand, if the exclusive OR is "false" in the confirmation process (s50), it is assumed that there has been no change in the detection result, and the second acquisition process (s40) is repeatedly executed. If the interrupt set in the interrupt setting process (s34) occurs while the second acquisition process (s40) is being repeatedly executed in this manner, the interrupt process (s60) shown in FIG. 5(b) is executed.

In the interrupt process (s60), the counter value set in the interval setting process (s30) is counted down (s61). If the counter value is not "0" as a result of the countdown (s62: No), it is determined that the transmission interval (first transmission interval or second transmission interval) has not yet elapsed, and the interrupt process (s60) is terminated. On the other hand, if the counter value becomes "0" (s62: Yes), it is determined that the transmission interval has elapsed, and a transmission process (s63) is executed, and the detection result is transmitted to the monitoring device 30. Then, when the transmission process (s63) is executed, an interval setting process (s63) is executed. The interval setting process (s63) is the same process as the interval setting process (s30) described above, and the next transmission interval is set anew by this process.

When the above interrupt process (s60) is completed, the process returns to the main flow shown in Figure 4 and each process is executed.

The communication mode of the communication device 20 that operates based on the above flow will be described below by taking the communication device 20a and the gas detectors 10a to 10c shown in FIG. 1 as examples.
(1) When the communication device 20a is started, it executes a first acquisition process (s10) to acquire detection results from the gas detectors 10a to 10c. As shown in Fig. 6, at this point in time, the gas detectors 10a to 10c have not detected any gas leaks, so the communication device 20a acquires detection results indicating normal conditions from the gas detectors 10a to 10c.
(2) The communication device 20a executes a transmission process (s20) and transmits to the monitoring device 30 the detection results (normal) acquired from each of the gas detectors 10a to 10c.
(3) The communication device 20a executes an interval setting process (s30). Since all of the detection results acquired in the first acquisition process (s10) indicate normal conditions (s31: Yes), the first interval setting process (s32) is executed. In this example, the value of the random number generated in the first interval setting process (s32) is "34", and this value is assigned to the counter variable.
(4) The communication device 20a executes an interrupt setting process (s34). By executing this process, a timer interrupt occurs every second.
(5) The communication device 20a executes a second acquisition process (s40) and checks the detection results acquired from the gas detectors 10a to 10c (s50). If the check result shows that there are no changes in all of the acquired detection results (s50: No), the communication device 20a repeats the second acquisition process (s40) and the check process (s50). In this manner, in an interrupt process (s60) that occurs while the second acquisition process (s40) and the check process (s50) are being repeatedly executed, a counter variable is counted down (s61).
(6) When the counter variable counted down in the interrupt process reaches "0" (s62: Yes), that is, when 34 seconds have elapsed, the detection result is transmitted to the monitoring device 30 by a transmission process (s63).
(7) After the transmission process (s63) is executed, the interval setting process (s64) is executed. At this point, all of the detection results acquired by the second acquisition process (s40) indicate normal conditions, so the first interval setting process is executed. The value of the random number generated in the first interval setting process is assigned to a counter variable.
(8) Here, when the gas detector 10c detects a gas leak, the communication device 20a acquires a detection result indicating an abnormality from the gas detector 10c in a second acquisition process (s40). Then, the communication device 20a regards a change in the detection result as having occurred (s50: Yes), executes a transmission process (s20), and transmits the detection result indicating the abnormality to the monitoring device 30.
(9) After executing the transmission process (s20), the communication device 20a executes the interval setting process (s30). At this point, since the detection result acquired in the second acquisition process (s40) includes an abnormality, the second interval setting process (s33) is executed in the interval setting process (s30). In this example, the value of the random number generated in the second interval setting process (s33) is "10", and this value is substituted for the counter variable. After executing the second interval setting process (s33), the communication device 20 executes the interrupt setting process (s34).
(10) After executing the interval setting process (s30) as described above, the communication device 20 executes the second acquisition process (s40) and checks whether or not there has been a change in the acquired detection result (s50). In this example, since there has been no change in the detection result acquired in the previous second acquisition process (s40), the second acquisition process (s40) and the check process (s50) are repeatedly executed. While the second acquisition process (s40) and the check process (s50) are repeatedly executed in this manner, a timer interrupt occurs, and the counter variable is counted down in the interrupt process (s60) (s61).
(11) When the counted-down counter variable becomes "0" (s62: Yes), that is, when 10 seconds have elapsed, the detection result is transmitted to the monitoring device 30 by a transmission process (s63).
(12) After executing the transmission process (s63), the communication device 20a executes an interval setting process (s64) and assigns the value of the random number generated in the second interval setting process to a counter variable.
(13) When the interrupt process is completed, the communication device 20 repeatedly performs the second acquisition process (s40) and the confirmation process (s50). When the gas concentration decreases and the gas detector 10c no longer detects a gas leak, the device acquires a detection result indicating a normal state in the second acquisition process (s40). In this case, the device executes the transmission process (s20) assuming that a change has occurred in the detection result, and transmits the detection result indicating a normal state to the monitoring device 30.
(14) After executing the transmission process (s20), the communication device 20a executes the interval setting process (s30). At this point, the detection result acquired in the second acquisition process (s40) is normal, so in the interval setting process (s30), the first interval setting process (s32) is executed and the value of the random number generated in that process is substituted for the counter variable.

As described above, the communication device 20a acquires detection results from the wired-connected gas detectors 10a to 10c and transmits the acquired detection results to the monitoring device 30. In this way, the MCU 23 of the communication device 20 functions as a control unit 230 (Figure 3) that randomly controls the transmission intervals at which the detection results are transmitted.

According to the monitoring system 1 of this embodiment, even if multiple communication devices transmit detection results at the same time, the next transmission time is determined by a count value generated based on a random number, so that the transmission timings of these multiple communication devices are prevented from continuously overlapping. Therefore, it is possible to prevent continued reception errors caused by communication interference between multiple communication devices.

The communication device, communication system, and communication method according to the present invention have been described above based on the embodiments, but the present invention is not limited to the above-mentioned forms, and may be, for example, in the following forms.

(1) In the above embodiment, the detection result sent from the gas detector 10 to the communication device 20 may be data indicating the gas concentration measured by the gas detector 20, and the communication device 20 may compare the acquired data with a threshold value to determine whether it is normal or abnormal, and transmit the determination result to the monitoring device 30. That is, the communication device 20 may transmit the detection result directly to the monitoring device 30 based on the detection results received from multiple gas detectors 10, or may transmit the result of the determination based on the detection results received from the gas detector 10 to the monitoring device 30.

(2) In the above embodiment, the first reference interval is set to 30 seconds, and the first interval is set within a predetermined range centered on 30 seconds, but the first reference period is not limited to 30 seconds and may be within 3 minutes. Also, in the above embodiment, the second reference interval is set to 10 seconds, and the second interval is set within a predetermined range centered on 10 seconds, but the second reference period is not limited to 10 seconds and may be 30 seconds.

(3) In the above embodiment, both the first interval and the second interval are set based on random numbers, but it is also possible to set either the first interval or the second interval based on random numbers.

(4) In the above embodiment, a timer interrupt occurs every second, but the timer interrupt is not limited to every second, and may occur at intervals less than one second, such as every 10 ms or 100 ms, or at intervals greater than or equal to one second. Note that the counter variable counts down every time a timer interrupt occurs, and the value of the counter variable is determined taking into account the interval of the timer interrupt.

(5) In the main flow of the above embodiment, each of the multiple gas detectors 10 transmits a detection result in response to a request from the communication device 20, but this is not limited to the above. The multiple gas detectors 10 may periodically transmit their detection results to the communication device 20, the communication device 20 may receive the detection results and temporarily store them in the memory 25, and the detection results stored in the memory 25 may be periodically checked to check for changes in status.

(6) In the above embodiment, the communication device 20 transmits the detection results received from multiple gas detectors 10 only once in one transmission process, but the same detection result may be transmitted multiple times in one transmission process.

(7) In the above embodiment, the communication device 20 and the multiple gas detectors 10 are connected in series by a daisy chain connection, but this connection is not limited to this, and multiple gas detectors may be connected in parallel by a wire to the communication device 20.

(8) In the above embodiment, an abnormality is determined when the measured gas concentration exceeds a threshold value. However, since the type of gas to be detected, such as oxygen, is dangerous when its concentration becomes low, an abnormality may also be determined when the measured gas concentration falls below the threshold value.

(9) In the above embodiment, the gas detector 10 that detects the surrounding gas concentration has been described as an example, but the detector may be a temperature detector that detects the surrounding temperature, an odor detector that detects odors, a pressure detector that detects pressure, or the like, and may be a detector that detects events such as gas leaks (abnormal changes in gas concentration), abnormal temperature changes, abnormal odors, and abnormal pressure changes.

(10) In the above embodiment, the monitoring system 1 that monitors gas leaks has been described as an example, but as described in the above modified example, the monitoring system may also be one that monitors temperature, odor, and pressure. In addition, the system is not limited to a monitoring system, and may also be used as a communication system in which multiple communication devices 20 communicate with the above equipment.

1. Surveillance system (communication system)
10 Gas detector (detector)
20 Communication device 210 Receiving unit 220 Transmitting unit 230 Control unit 30 Monitoring device (higher-level device)

Claims (15)

A receiving unit that receives a detection result from the detector;
a transmitting unit that periodically transmits information based on the received detection result to a host device by wireless;
a control unit that randomly controls a transmission interval by the transmission unit;
Equipped with
The control unit is
before recognizing an occurrence of an event based on the detection result, randomly setting a first transmission interval for wirelessly transmitting the information every time the information is wirelessly transmitted;
after recognizing the occurrence of the event based on the detection result, randomly setting a second transmission interval for wirelessly transmitting the information, the second transmission interval being a transmission interval shorter than the first transmission interval, every time the information is wirelessly transmitted;
A communication device that controls the transmitting unit to transmit the information at the first transmission interval or the second transmission interval . The communication device according to claim 1 , wherein the control unit controls the transmission unit to transmit the information at a point in time when the detection result changes. the receiving unit receives the detection results from the plurality of detectors,
The communication device according to claim 1 , wherein the control unit recognizes an occurrence of an event based on any one of the detection results received from the plurality of detectors. The communication device according to any one of claims 1 to 3, wherein the control unit controls the setting of one or both of the first transmission interval and the second transmission interval randomly based on a random number. The communication device according to claim 1 , wherein each of the first transmission interval and the second transmission interval is determined within a certain range. 6. The communication device according to claim 5, wherein a maximum value of the range in which the second transmission interval is determined is smaller than a minimum value of the range in which the first transmission interval is determined. The communication device according to any one of claims 1 to 6, wherein the transmission unit periodically wirelessly transmits information based on the multiple detection results. The communication device according to claim 7, wherein the information based on the multiple detection results is the same. The communication device according to any one of claims 1 to 8, wherein the receiver receives the detection result from the detector via wired communication. the detector is a gas detector,
10. The communication device according to claim 1, wherein the event is the detection by the gas detector of a gas having a concentration equal to or greater than a predetermined concentration or equal to or less than a predetermined concentration. The communication device according to claim 1, wherein the first transmission interval is within 3 minutes. The communication device according to claim 1, wherein the second transmission interval is within 30 seconds. The communication device according to any one of claims 1 to 12, wherein the transmitter includes a long-distance wide area wireless network module. A detector for detecting an event;
A communication device according to any one of claims 1 to 13;
A communication system comprising: a receiving step of receiving a detection result from the detector;
a transmitting step of periodically wirelessly transmitting information based on the received detection result to a host device;
a control step of randomly controlling a transmission interval in the transmitting step;
Equipped with
The control step includes:
before recognizing an occurrence of an event based on the detection result, randomly setting a first transmission interval for wirelessly transmitting the information every time the information is wirelessly transmitted;
after recognizing the occurrence of the event based on the detection result, randomly setting a second transmission interval for wirelessly transmitting the information, the second transmission interval being a transmission interval shorter than the first transmission interval, every time the information is wirelessly transmitted;
A communication method , comprising: controlling to transmit the information at the first transmission interval or the second transmission interval .