JP4035010B2 - Security device and security system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
Recently, picking damage and the like occur frequently, and interest in crime prevention is increasing not only in companies but also in general households. Security contracts with security companies have traditionally been adopted only by companies, but are now spreading to ordinary households. Many discount-related products such as simple crime prevention devices that can be purchased easily and inexpensively, such as window open / close detectors and picking sensors, alarms that notify gas leaks and fires, and simple digesters are sold at discount stores. ing. The present invention provides a security apparatus and a security system that can be provided at a low cost with a simple method of use, particularly for home security in a general home, among systems related to security.
[0002]
[Prior art]
A system widely used as a security system in an ordinary home is a system for signing a security contract with a security company. In this system, a home controller that can communicate with the control center of a security company is installed in the building. In addition, sensors that can communicate with the home controller by wire or wirelessly are arranged in the building as needed. For example, security sensors that detect the presence of people, etc. are installed in places that are easy to enter from the outside, such as entrances and windows, and gas leak sensors that detect gas leaks and fire sensors that detect fires are located near water heaters. Is installed.
[0003]
When someone enters the building without permission, or when a gas leak or fire occurs, the home controller detects an abnormality through the sensor and transmits an abnormality signal to the control center of the security company. When the security company receives the abnormal signal, it notifies the emergency start base to the waiting guard and the patrol guard that the abnormality has occurred, and prompts the guard to the house that sent the abnormal signal. When the security guard arrives at the abnormal signal transmission site, the contents of the abnormal signal transmitted from the home controller to the control center confirm that there are no intruders, no gas leaks, no fire has occurred, etc. Contact the police or fire department if necessary.
[0004]
On the other hand, as an alarm device that can be purchased at a low price, for example, there is a picking sensor. The picking sensor detects fine vibrations generated during the picking operation by a built-in sensor, and emits a large-capacity alarm sound when the vibrations are detected. When used, it only needs to be hung on a door knob or the like, and since a normal battery is used for the power source, it can be easily installed.
[0005]
Another alarm device is a gas leak sensor. The gas leak sensor is installed in a state where it is plugged into an outlet near the water heater or gas stove. And when a gas leak or incomplete combustion of gas is detected, an alarm sound is emitted.
[0006]
[Problems to be solved by the invention]
In general households, home security is performed using the methods described above, but these methods have the following problems.
If you have a security contract with a security company, the cost, including the initial investment, is high. Compared to a long time ago, the cost has become considerably cheaper, but it is still difficult to introduce easily. In addition, in many cases, contracts with security companies must be selected from several patterns prepared in advance by the security company, and it is not permitted to contract only the necessary functions. . Furthermore, when installing a home controller or various sensors, there is a problem that installation is troublesome because it is necessary to make a new mounting hole in the wall or fix the wiring in the house.
[0007]
On the other hand, when an inexpensive alarm device is used, the problem of cost burden and installation is solved, but another problem arises. In the early days of picking sensors, when an intruder picked up the sensor, the intruder gave up the intrusion when the sensor sensed vibration and an alarm sound was emitted. Recently, however, the intruder's picking technology has become clever and sophisticated, so even if picking is started and an audible alarm is sounded, the intruder is released in a very short time, and the picking sensor's audible alarm is stopped. End up. And once invaded, there is a problem that after that, there is no means to inform the outside of the intrusion.
[0008]
Further, in the gas sensor, when a gas leak occurs while the resident is at home, the gas leak can be notified by an alarm sound. However, when the resident is out, there is a problem that even if an alarm sound is emitted from the gas sensor, a gas leak cannot be notified.
[0009]
[Means for solving the problems]
In order to solve the above problems, the present invention provides: The sensor unit that senses the surrounding alarm sound, and the alarm signal is transmitted according to the output of the sensor unit, while the alarm signal is stopped when the alarm stop signal is received, and the alarm signal that is received when the alarm signal is received Can communicate with at least one security device including a transmission unit that relays and transmits an alarm signal to the external device upon receiving an alarm signal. Comprising a relay device, wherein when the relay device transmits the alarm signal to the external device, the alarm stop signal is transmitted to the security device that is the source of the alarm signal, Security system Is to provide.
[0010]
The present invention also provides: A sensor unit that senses surrounding alarm sounds; While transmitting an alarm signal according to the output of the sensor unit, the alarm signal is stopped when the alarm stop signal is received, and at least one transmission unit that relays and transmits the received alarm signal when the alarm signal is received The security device and an external device that cannot communicate directly with the security device, and a relay device that transmits the alarm signal to the external device when the alarm signal is received. When sending the alarm signal to the external device, the alarm stop signal is sent to the security device that is the source of the alarm signal. Security characterized by transmission system Is to provide.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described below by taking home security of a general household as an example. FIG. 1 is a diagram showing an overall configuration of a security system when the present invention is applied to home security in a general home. Each configuration will be described below.
[0012]
Reference numeral 1 denotes a building, in which a picking sensor 2a, a gas leak sensor 2b, a window opening / closing detector 2c, a security device 3, and a network computer 4 are installed. Gas leak sensor 2a, picking sensor 2b, and window open / close detector 2c are inexpensive products sold at discount shops, etc., and if the installed sensor detects abnormalities due to vibration caused by picking or gas odor, an alarm It emits sound. Although three types of alarm devices are shown in the figure, the detection function is not particularly specified and any alarming sound may be used. Also, the number of alarms is not particularly specified and may be any number. Hereinafter, these alarm devices are collectively referred to as a simple alarm device 2.
[0013]
The security device 3 senses the alarm sound of the simple alarm device 2 and transmits a signal (hereinafter referred to as an alarm signal) notifying that there is an abnormality in a wireless or wired manner, or an alarm from another device. It has a relay function for receiving and transmitting a signal for stopping transmission of a signal or an alarm signal (hereinafter referred to as an alarm stop signal), and details will be described later. A network computer 4 is connected to one of the plurality of security devices 3 via a cable 5a.
[0014]
Reference numeral 6 denotes a general public line such as a telephone line or an Internet line, which is connected to the network computer 4 and also connected to a mobile phone 7a, a general phone 7b, a personal computer 7c, etc. (hereinafter collectively referred to as an external communication terminal 7). Has been.
[0015]
Next, details of the security device 3 will be described.
FIG. 2 shows the appearance of the security device 3. Reference numeral 31 denotes a sensor unit for sensing external sound, and reference numeral 32 denotes a power supply unit for taking in an AC 100V power supply for operation. Reference numeral 33 denotes a communication connection terminal, which will be described in detail later.
[0016]
FIG. 3 is a functional block diagram of the security device 3. As shown in the figure, the security device 3 includes a sensor unit 31, a power supply unit 32, a communication unit 33, a wireless unit 34, and a processing unit 35. The sensor unit 31 is a part that senses external sound. A reference volume is set in advance in the sensor unit 31, and only sound information exceeding the reference volume (hereinafter referred to as sensed sound information) is transmitted to the processing unit 35 with respect to the sensed sound. As described above, the power supply unit 32 is a part that takes in an AC 100V power supply for operation, and includes an insertion plug to a power outlet.
[0017]
The communication unit 33 is a part that performs transmission / reception of an alarm signal for notifying that the alarm sound of the simple alarm device 2 has been sensed and an alarm stop signal for stopping transmission of the alarm signal to and from the network computer 4. The wireless unit 34 is a part that receives the alarm signal or the alarm stop signal described above from another security device 3 or transmits the alarm signal or the alarm stop signal to the other security device 3.
[0018]
The processing unit 35 is a part that controls the overall operation of the security device 3, and includes a storage device and a random number generator. In the storage device, an ID number, a frequency range for alarm sound identification, and a designated time for alarm sound identification are input in advance. This ID number is for enabling identification of each device even when there are a plurality of security devices 3, and different numbers are assigned to all the devices. The frequency range for alarm sound identification is a setting for determining whether it is an alarm sound from the simple alarm device 2 with respect to the sensor sound information input to the processing unit 35 via the sensor unit 31 based on the frequency of the sensor sound. It is a value, and a value suitable for the alarm sound of the simple alarm device 2 is input. The designated time for identifying the warning sound is a set value for determining whether the sound is the warning sound based on the duration of the detected sound for the detected sound information. The random number generator is used to give inconsistent numerical values to alarm signal data to be described later.
[0019]
FIG. 4 shows a data structure 8 of an alarm signal transmitted and received by the security device 3. In the figure, the transmission ID 8a is an ID number of a device that senses an alarm sound from the simple alarm device 2 and first transmits an alarm signal. The target ID 8b is an ID number of the final destination of the alarm signal, and usually an ID indicating the network computer 4 is input. The random number data 8c is a numerical value for preventing this alarm signal from being confused with a past alarm signal that has already been transmitted, and an inconsistent numerical value is given by the random number generator of the processing unit 35. The control code 8d is a numerical value indicating the control content of the signal. The retransmission count data 8e is a numerical value indicating the number of times the alarm signal is retransmitted when the alarm stop signal is not sent to the device that first transmitted the alarm signal.
[0020]
In the example of the data configuration 8 of the alarm signal shown in FIG. 4, the transmission ID 8 a of the device that first transmitted the alarm signal is 02000001 and the target ID 8 b is 1001001 that is an ID indicating the network computer 4. The random number data 8c for identification not to be confused with other signals is 134, and the control code 8d is 09 which means that the sensor unit 31 has detected an alarm sound. The retransmission count data 8e is 010, and when an alarm stop signal is not sent, the alarm signal is retransmitted 10 times.
[0021]
FIG. 5 shows a data structure 9 of an alarm stop signal transmitted / received by the security device 3. In the figure, a transmission ID 9a is an ID of a device that transmits an alarm stop signal, and normally an ID indicating the network computer 4 is input. The target ID 9b is an ID number of a device that senses an alarm sound from the simple alarm device 2 and first transmits an alarm signal. As the random number data 9c, the same numerical value as that of the alarm signal is input as it is. The control code 9d is an ID indicating the control content of the signal, and a numerical value for stopping the transmission of the alarm signal is input. As the retransmission count data 8e, the numerical value of the alarm signal is used as it is.
[0022]
In the example of the data structure 9 of the alarm stop signal shown in FIG. 5, the transmission ID 8 a is 02000001 of the device that first transmitted the alarm signal, and the target ID 8 b is 1001001 that is an ID indicating the network computer 4. Further, the identification random number data 8c is 134 which is the same as the alarm signal of FIG. 4, and the control code 8d is 00 which means that the sensor unit 31 stops the transmission of the alarm signal. The retransmission count data 8e is 010, which is the same as the alarm signal table 8.
[0023]
Next, the operation of the security device 3 will be described.
FIG. 6 shows an operation flowchart when the security device 3 senses an alarm sound.
The security device 3 is in a reception standby state before operation (step S1). When the sensor unit 31 senses any sound, it is determined whether the sound is higher than the set reference volume (steps S2 and S3). When the volume is lower than the reference volume, it is determined that the alarm sound is not generated, and the reception standby state is entered again. When the volume is higher than the reference volume, the sensing sound information is transmitted to the processing unit 35. The processing unit 35 determines whether or not the frequency of the sensing sound is within the frequency range preset in the processing unit 35 for the sensing sound information (step S4). If it is outside the set range, it is determined that the alarm sound is not generated, and the reception standby state is entered again. If it is within the set range, the process proceeds to the next step S5. Next, it is determined by the processing unit 35 whether the duration of the sensed sound is continued for a preset time, for example, 5 seconds or more (step S5). If the sensed sound is not continued, it is determined that it is not an alarm sound, and the reception standby state is entered again. In other cases, it is determined that the sensed sound is an alarm sound, and a transmission signal transmission instruction is sent from the processing unit 35 to the wireless unit 34.
[0024]
In the wireless unit 34, an alarm signal is transmitted wirelessly (step S6). The alarm signal transmission instruction is also sent from the processing unit 35 to the communication connection terminal 33. When the network computer 4 is connected to the communication connection terminal 33 via the cable 5a, the network computer If the alarm signal is transmitted to No. 4, otherwise, the process proceeds to Step S9 (Steps S7 and S8). Next, it is determined whether the security device 3 has received an alarm stop signal (step S9). If it has been received, the process ends. If not, the process proceeds to step S10. Then, it is determined whether the number of retransmissions of the alarm signal has reached the number of retransmissions data 8e. If the number of retransmission times data is less than 8e, the process proceeds to step S6, and the alarm signal is transmitted again. If the retransmission count data 8e has been reached, the operation ends and a reception standby state is entered.
[0025]
FIG. 7 shows an operation flowchart when the security device 3 wirelessly receives an alarm signal and an alarm stop signal.
The security device 3 is in a reception standby state before operation (step S1). And when the radio | wireless part 35 receives an alarm signal or an alarm stop signal, the data will be sent to the process part 35 (step S2). Here, the received alarm signal and alarm stop signal data are stored in the storage device of the processing unit 35 within a certain range, for example, within the past 30 minutes. Therefore, based on the stored data, it is determined whether the currently received alarm signal or alarm stop signal is the same as the alarm signal or alarm stop signal transmitted in the past (step S3). In the same case, since the response to the signal received this time has already been completed, the operation ends. If they are different, a signal transmission instruction is sent from the processing unit 35 to the radio unit 34, and an alarm signal or an alarm stop signal having the same data as the received signal is transmitted from the radio unit 34 by radio (step S4). ). Then, the data of the transmitted signal is stored in the processing unit 35.
[0026]
Next, it is determined whether or not the network computer 4 is connected to the communication terminal 33 (step S5). If it is not connected, the operation ends, and if not, it is determined whether the signal transmitted in step S4 is an alarm signal (step S6). If it is not an alarm signal, the operation ends, otherwise an alarm signal or the like is transmitted to the network computer 4 (step S7).
[0027]
FIG. 8 shows an operation flowchart when the security device 3 receives an alarm stop signal from the network computer 4.
The security device 3 is in a reception standby state before operation (step S1). Then, when the communication unit 33 receives an alarm stop signal from the network computer 4, the data is sent to the processing unit 35 (step S2). An instruction to send an alarm stop signal is sent from the processing unit 35 to the radio unit 34, and an alarm stop signal is transmitted from the radio unit 34 by radio (step S3). The data of the transmitted signal is the same as the data of the alarm stop signal received by the communication unit 33.
[0028]
FIG. 9 shows an operation flowchart of the network computer 4.
The network computer 4 is in a reception standby state before operation (step S1). Then, when an alarm signal is received from the security device 3, the reception of the alarm signal is notified to the external terminal 7 via the general public line 6 (steps S2 and S3). The external terminal 7 is a mobile phone 7a, a company PC 7b, or the like, and a notification destination address is registered in the network computer 4 in advance. The contents notified to the external terminal 7 may be the same as the alarm signal data, but only necessary contents are extracted and notified from there, or further necessary information is added to the notification. May be.
[0029]
Next, the network computer 4 creates alarm stop signal data based on the data configuration 8 of the received alarm signal. (Step S4). Here, the transmitter ID 8a is rewritten to the ID of the network computer 4 from the ID of the simple security device 3 that has transmitted the abnormal signal. The target ID 8b is rewritten from the ID of the network computer 4 to the ID of the security device 3. Further, the control code 8d is rewritten from 09 indicating abnormal sound input to the sensor unit 31 to 00 for instructing stop of abnormal signal transmission. Next, an alarm stop signal is transmitted from the network computer 4 to the security device 3 (step S5).
[0030]
Next, a method for transmitting an alarm signal and an alarm stop signal in the security system will be described.
FIG. 10 shows a first installation example of a security system configured by connecting a plurality of security devices to a network. FIG. 11 shows the transmission status of the alarm signal pulse and the alarm stop signal pulse when the security device A 101a first transmits the alarm signal.
[0031]
First, when the security device A 101a detects some sound and determines that it is an alarm sound from the simple alarm device 2, an alarm signal is transmitted wirelessly. This alarm signal is received by all the security devices installed in the range 101b within which the radio signal from the security device A 101a can reach, for example, within a radius of 5 m, and is received by the security device B 102a in this figure. In the security device B 102a, it is determined from the transmitter ID 8a and the random number data 8c on the alarm signal data that the alarm signal is the first signal received, and the alarm signal of the same data is transmitted wirelessly.
[0032]
The alarm signal is received by the security device A 101a and the security device C 103a installed in the range 102b where the wireless signal of the security device B 102a can reach. In the security device A 101a, it is determined from the alarm signal data that the received alarm signal is the same as the signal already transmitted by the terminal itself, and no response is made to the alarm signal. In the security device C103a, it is determined that it is not re-reception based on the received alarm signal data, and an alarm signal having the same data configuration is transmitted wirelessly.
[0033]
Next, this alarm signal is received by the security device B 102a and the security device D 104a, but the security device B 102a does not respond because the data of the received signal is the same as the already transmitted signal. In the security device D104a, since the received alarm signal is received for the first time, the alarm signal having the same data configuration is transmitted wirelessly and connected to the network computer 4, so the alarm signal is also cabled to the network computer 4. It is transmitted via 5a. In the network computer 4, the external terminal 7 is notified that the alarm signal has been received, and alarm stop signal data is created based on the data structure 8 of the received alarm signal. Then, an alarm stop signal is transmitted to the security device D104a via the cable 5a. An alarm stop signal is transmitted wirelessly from the security device D104a, and is transmitted to the security device A101a via a path opposite to the alarm signal. When the security device A 101a receives an alarm stop signal for the alarm signal transmitted by the security device A 101a, the operation of the alarm signal transmission is stopped.
[0034]
If the alarm stop signal is not transmitted to the security device A 101a due to the influence of the radio wave condition on the way, the alarm signal is retransmitted for the number of times of retransmission data 8e until the alarm stop signal is received. .
[0035]
FIG. 12 shows a second installation example of the security system, and FIG. 13 shows a transmission state of an alarm signal pulse when the security device A 111a transmits an initial alarm signal.
When the security device A 111a detects some sound and determines that it is an alarm sound from the simple alarm device 2, an alarm signal is transmitted wirelessly. This alarm signal is received by all the security devices installed in the range 111b within which the radio signal from the security device A 111a reaches, for example, within a radius of 5 m. In this figure, the security device B 112a and the security device C 113a receive the alarm signal. To do. Then, an alarm signal having the same data as the signal received by both devices is transmitted wirelessly, and the security device A 111a and the security device D 114a receive this alarm signal.
[0036]
Here, the timing until the security device 3 receives and transmits a signal will be described. The alarm signal is received, it is determined whether or not it is transmitted as described above, and the processing unit 35 determines the timing from reception to transmission by the random number generation function for the signal to be transmitted. Therefore, even if the security device B 112a and the security device C 113a receive the alarm signal from the security device A 111a at the same timing, the timing at which the alarm signal is transmitted next is different. Therefore, the alarm signals from the security device B 112a and the security device C 113a arrive at the security device A 111a and the security device D 114a at different timings.
[0037]
In the security device A111a, since the received alarm signal is the same as the already transmitted signal, no response is made to this alarm signal. Further, in the security device D114a, a response is made only for the alarm signal received earlier, and no response is made for the alarm signal received later because it is the same as the previous alarm signal. In response to the previously received alarm signal, the security device D 114a transmits an alarm signal to the network computer 4 via the cable 5a, and notifies the external terminal 7 that the alarm signal has been received. In the network computer 4, alarm stop signal data is created based on the received alarm signal data, and the alarm stop signal is transmitted to the security device A 111a through the reverse path. Here, the transmission path of the alarm stop signal is not necessarily the reverse path of the alarm signal, and is determined by the transmission timing of the random number data 9c. When the security device A111a receives an alarm stop signal for the alarm signal transmitted by the terminal itself, the operation of the alarm signal transmission is stopped.
[0038]
By the way, as described above, the signal transmission timing in the security device B 112a and the security device C 113a varies depending on the random number data 8c by the random number generation function, but when transmitted at the same timing, the operation is as follows. . First, when the security device D114a receives alarm signals of the same data at the same timing, no response is made to these alarm signals. Then, since the alarm stop signal is not transmitted to the security device A 111a, the alarm signal is transmitted again after a certain interval. Here, since the alarm signal data is newly created, it is not confused with the previously transmitted alarm signal.
[0039]
Then, the newly transmitted alarm signal is transmitted again to the security device D 114a via the security device B 112a and the security device C 113a. Since the alarm signals transmitted from the security device B 112a and the security device C 113a have different transmission timings depending on the random number generated by the random number generation function, the security device D 114a responds only to the previously received alarm signal. . Here, when the reception timing becomes the same again, an alarm signal indicating that the data is new is transmitted again from the security device A 111a.
[0040]
Note that the alarm signal transmitted from the security device A111a is retransmitted for the number of times of retransmission data 8e until the alarm stop signal is received as described above in consideration of the poor radio wave condition on the way.
[0041]
FIG. 14 shows a third installation example of the security system, and FIG. 15 shows a transmission state of an alarm signal pulse when the security device A 121a transmits an initial alarm signal.
When the security device A 121a detects some sound and determines that it is an alarm sound from the simple alarm device 2, an alarm signal is transmitted wirelessly. This alarm signal is received by the security device B 122a, the security device C 123a, and the security device D 124a, and an alarm signal having the same data as the alarm signal received by each device is transmitted. The security device E125a responds only to the alarm signal received earliest among the alarm signals from the security devices B122a to D124a. The other alarm signals are not responded because the data is the same as the previously received alarm signal.
[0042]
Since the network device 4 is connected to the security device E125a, the alarm signal is transmitted to the network computer 4 via the network cable 5a. Then, the network computer 4 notifies the external terminal that the alarm signal has been received. Next, the network computer 4 creates alarm stop signal data based on the received alarm signal data, and transmits it to the security device E125a via the network cable 5a. Then, an alarm stop signal is transmitted wirelessly from the security device E125a, and is transmitted to the security device A 121a through a path opposite to the alarm signal. Here, the transmission path of the alarm stop signal is not necessarily the reverse path of the alarm signal, and is determined by the transmission timing of the random number data 9c. When the security device A 121a receives an alarm stop signal for the alarm signal transmitted by the own device, the operation of the alarm signal transmission is stopped.
[0043]
【The invention's effect】
As described above in detail, according to the present invention, it is possible to provide a security device and a security system that are inexpensive and easy to use, using the conventional simple alarm device as it is. Further, since the security device can be operated from one unit and signals are transmitted and received between the devices wirelessly, it is not necessary to newly install a cable in the building, and the number of the devices can be easily increased.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a security system using a security device.
FIG. 2 is an external view of a security device.
FIG. 3 is a functional block diagram of the security device.
[Fig. 4] Data structure of alarm signal
FIG. 5 is a data configuration diagram of an alarm stop signal.
FIG. 6 is an operation flowchart when an alarm sound is detected.
FIG. 7 is an operation flowchart when an alarm signal and an alarm stop signal are received in the radio unit.
FIG. 8 is an operation flowchart when a wired alarm stop signal is received in the communication unit.
FIG. 9 is an operation flowchart of the network computer.
FIG. 10 shows a first installation example of a security device.
FIG. 11: Transmission status of alarm signal pulse in the first installation example
FIG. 12 shows a second installation example of the security device.
FIG. 13 shows the transmission status of alarm signal pulses in the second installation example.
FIG. 14 shows a third installation example of the security device.
FIG. 15: Alarm signal pulse transmission status in the third installation example
[Explanation of symbols]
2 Simple alarm device
3 security devices
31 Sensor part
33 Communication Department
34 Radio section
35 processor
4 Network computer
8 Data structure of alarm signal
9 Data structure of alarm stop signal
101a, 102a, 103a, 104a Security device
101b, 102b, 103b, 104b Communication range of security device
105 Network computer

Claims (5)

While sending the alarm signal according to the sensor unit that detects the surrounding alarm sound and the output of the sensor unit, when the alarm stop signal is received, the transmission of the alarm signal is stopped, and when the alarm signal is received, the received alarm signal is A relay that can communicate with at least one security device including a transmission unit that performs relay transmission and an external device that cannot directly communicate with the security device, and that transmits the alarm signal to the external device when the alarm signal is received The relay device transmits an alarm stop signal to the security device that is the source of the alarm signal when the relay device transmits the alarm signal to the external device. system. The security system according to claim 1 , wherein the security device has the sensor unit and the transmission unit integrally configured. 3. The security system according to claim 1, wherein the security device includes an insertion plug to a power outlet and is attached to the power outlet to take in power. . The security system according to any one of claims 1 to 3 ,
When the security device is the transmission source, the security device adds the ID assigned to the security device as the transmission ID and the ID of the external device that is the transmission destination of the warning signal as the target ID to the warning signal. A security system that outputs and relays an alarm signal as it is without adding these IDs when relaying an alarm signal from another security device. The security system according to any one of claims 1 to 4 ,
The external device generates a target ID that is a transmission destination of a stop signal that stops transmission of an alarm signal based on the received transmission ID, adds the target ID, and outputs the stop signal. Security system.

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