TWI838969B - Wireless security system - Google Patents

Abstract

The wireless security system is suitable for a mobile terminal device. The wireless security system includes a host device, a sensing device, and an engineering maintenance program. The sensing device is wirelessly communicated with the host device and is provided with a connection path indicator. The engineering maintenance program is installed on the mobile terminal device, the engineering maintenance program is wirelessly communicated with the host device, and the engineering maintenance program displays a wireless network node structure and a network signal strength. When the sensing device receives a confirmation signal from the host device, the connection path indicator shows different lighting states according to the wireless network node structure.

Description

Wireless security system

The present invention relates to a security system, in particular to a wireless security system.

In order to protect the safety of people and property, homes, offices and factories are equipped with security systems. The security system includes a security host and sensors that provide various functions. These sensors are electrically connected to the security host through cables and receive commands from the security host or transmit sensing signals to the security host. When the security host receives the sensing signals provided by these sensors, it will interpret the sensing signals. When the security host interprets that an abnormality has indeed occurred, it will send an alarm signal to the control center, security personnel or users.

In order to make the security system's defense function more complete, it is necessary to increase the number of sensors. When the cables connected to the sensors and the security host are damaged, the security system will lose some of its effectiveness or stop operating completely. In order to prevent the cables from being maliciously damaged or affecting the aesthetics of the decoration, the cables connected to the security host and these sensors need to be laid out in hidden or shielded places. In this way, the layout of the security system is limited by space, which reduces the flexibility of the security system layout and increases the investment in construction and material costs.

The technical problem to be solved by the present invention is to provide a wireless security system to address the deficiencies of existing technologies.

In order to solve the above technical problems, one of the technical solutions adopted by the present invention is to provide a wireless security system applicable to a mobile terminal device, the wireless security system includes a host device, a sensing device and an engineering maintenance program. The sensing device is wirelessly connected to the host device and is provided with a connection path indicator. The engineering maintenance program is installed on the mobile terminal device, the engineering maintenance program is wirelessly connected to the host device, and the engineering maintenance program displays the wireless network node architecture and the network signal strength. When the sensing device receives a confirmation signal from the host device, the connection path indicator presents different lighting states according to the difference in the wireless network node architecture.

One of the beneficial effects of the present invention is that the wireless security system provided by the present invention allows for a higher degree of freedom in the deployment of the security system and can reduce construction and material costs, which can make up for the fact that "wired system security" is easily damaged and causes the circuit defense line to fail. Moreover, engineers only need to observe the display status of the connection path indicator on the sensing device to know the real-time connection path and status of the wireless security system. In addition to the connection path indicator, engineers can also know the real-time connection status between the host device and the sensing device of the security system through the engineering maintenance program. In addition, the network signal strength of the sensing device can also be known through the engineering maintenance program. In this way, engineers can control and maintain wireless security systems more quickly, accurately and efficiently without the need for professional and expensive instruments (such as spectrum analyzers).

To further understand the features and technical contents of the present invention, please refer to the following detailed description and drawings of the present invention. However, the drawings provided are only for reference and description and are not used to limit the present invention.

A1~A6: Wireless security system

MT: Mobile terminal device

1:Host device

D1~D6: Sensing device

APP1: Engineering maintenance program

2: Wireless Sharing Device

3: Modem

4: Manage the server

5: Connection path indicator

NS: Network signal strength

APP2: Customer application

CM: Client Device

WNC1~WNC4: Wireless network node architecture

REP1~REP3: Repeater

HUB1~HUB3: loop expander

Figure 1 is a schematic diagram of the first embodiment of the wireless security system of the present invention.

Figure 2 is a schematic diagram of the engineering maintenance program in Figure 1 showing the wireless network node architecture and network signal strength.

Figure 3 is a schematic diagram of the second embodiment of the wireless security system of the present invention.

Figure 4 is a schematic diagram of the engineering maintenance program in Figure 3 showing the wireless network node architecture and network signal strength.

Figure 5 is a schematic diagram of the third embodiment of the wireless security system of the present invention.

Figure 6 is a schematic diagram showing the wireless network node architecture of the engineering maintenance program of Figure 5.

FIG7 is a schematic diagram of the fourth embodiment of the wireless security system of the present invention.

Figure 8 is a schematic diagram showing the wireless network node architecture of the engineering maintenance program in Figure 7.

FIG9 is a schematic diagram of the fifth embodiment of the wireless security system of the present invention.

FIG10 is a schematic diagram of the sixth embodiment of the wireless security system of the present invention.

The following is a specific implementation example to illustrate the implementation method of the "wireless security system" disclosed in the present invention. Technical personnel in this field can understand the advantages and effects of the present invention from the content disclosed in this manual. The present invention can be implemented or applied through other different specific implementation examples, and the details in this manual can also be modified and changed based on different viewpoints and applications without deviating from the concept of the present invention. In addition, the attached drawings of the present invention are only for simple schematic illustrations and are not depicted according to actual sizes. Please note in advance. The following implementation method will further explain the relevant technical content of the present invention in detail, but the disclosed content is not used to limit the scope of protection of the present invention.

It should be understood that although the terms "first", "second", "third" and so on may be used in this article to describe various components or signals, these components or signals should not be limited by these terms. These terms are mainly used to distinguish one component from another component, or one signal from another signal. In addition, the term "or" used in this article may include any one or more combinations of the related listed items depending on the actual situation.

FIG1 is a schematic diagram of the first embodiment of the wireless security system of the present invention. As shown in FIG1, the wireless security system A1 is applicable to the mobile terminal device MT, and the wireless security system A1 includes a host device 1, multiple sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3 (such as ADSL Modem) and a control server 4. The sensing devices D1~D6 can be different types of sensors, such as smoke sensors, temperature sensors, door alarms, or humidity sensors. Alternatively, some of the sensing devices D1~D6 are sensors of the same type, and the other part is another type of sensor. The number and type of the above-mentioned sensing devices are only examples, and the present invention is not limited thereto.

Host device 1 is connected to wireless router 2 via local area network (LAN), wireless router 2 is connected to modem 3 via wide area network (WAN), and modem 3 is connected to control server 4 via asymmetric digital subscriber line (ADSL).

The engineering maintenance program APP1 is installed on the mobile terminal device MT, and the engineer executes the engineering maintenance program APP1 to perform a registration procedure on the control server 4. When the engineering maintenance program APP1 completes the registration procedure on the control server 4, the engineering maintenance program APP1 is wirelessly connected to the host device 1. For example, the engineering maintenance program APP1 is connected to the host device 1 via a WIFI network or a mobile data network.

When the engineering maintenance program APP1 is connected to the host device 1 via a wireless network, the engineer can operate the engineering maintenance program APP1 to pair the sensing devices D1~D6 with the host device 1 respectively. When the sensing devices D1~D6 have completed the pairing process with the host device 1 respectively, the sensing devices D1~D6 are connected to the host device 1 via a wireless network (WIFI network or radio frequency communication network).

FIG2 is a schematic diagram of the engineering maintenance program of FIG1 displaying the wireless network node architecture and network signal strength. As shown in FIG2, the engineering maintenance program APP1 of the mobile terminal device MT displays the wireless network node architecture WNC1 of the wireless security system A1. In this embodiment, the multiple network nodes of the wireless network node architecture WNC1 of the wireless security system A1 are respectively the host device 1 and the sensing devices D1~D6.

The engineering maintenance program APP of the mobile terminal device MT also displays the network signal strength NS of each of the sensing devices D1~D6. When the network signal strength of at least one of the sensing devices D1~D6 is lower than the preset strength threshold, the engineering maintenance program APP1 generates an alarm display and reports the strength signal abnormality event to the control server 4.

For example, the network signal strength NS of each of the sensing devices D1~D6 is represented by five signal grids. When the signal grid of the sensing device D1 is greater than or equal to 3 grids, each signal grid is green. When the signal grid of the sensing device D1 is less than 3 grids, each signal grid is red. In this way, the engineering personnel can quickly go to the location of the sensing device D1 for inspection and maintenance according to the network signal strength NS displayed by the engineering maintenance program APP1. In addition, the engineering maintenance program APP1 will also report the abnormal situation of the network signal strength of the sensing device D1 to the control server 4, and the control center can send engineering personnel to the location of the sensing device D1 for inspection and maintenance.

In addition, the wireless security system A1 further includes a client application APP2, which is installed on the client device CM. The client application APP2 is connected to the host device 1 through the WIFI network or mobile data network. When any of the sensing devices D1~D6 is triggered due to an abnormal event, the client application APP2 generates an alarm display.

For example, when the sensor device D1 senses an abnormal condition and is triggered, the computer image of the sensor device D1 on the customer application APP2 appears red, while the computer images of other sensor devices D2~D5 appear green. In this way, the user can immediately go to the location of the sensor device D1 for investigation according to the color displayed by the customer application APP2.

Each of the sensing devices D1 to D6 is provided with a connection path indicator 5. The following will focus on the connection path indicator 5 on the sensing device D1. The operating principle of the connection path indicator 5 on the other sensing devices D2 to D6 is the same as that of the connection path indicator 5 on the sensing device D1.

In order to save power, the connection path indicator light 5 on the sensing device D1 is usually off. Only when the sensing device D1 detects an abnormal condition and is triggered, for example, when the sensing device D1 is a temperature sensor, when the sensed temperature of the sensing device D1 is greater than the preset temperature threshold, the sensing device D1 transmits a trigger signal to the host device 1 via the WIFI network or the radio frequency communication network. When the host device 1 receives the trigger signal from the sensing device D1, the host device 1 feeds back a confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal from the host device 1, the connection path indicator light 5 on the sensing device D1 presents the first light state. For example, the first lighting state is that the connection path indicator light 5 on the sensing device D1 flashes once.

FIG3 is a schematic diagram of the second embodiment of the wireless security system of the present invention. As shown in FIG3, the wireless security system A2 includes a host device 1, sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3, a control server 4, and a plurality of repeaters REP1~REP3.

The engineering staff operates the engineering maintenance program APP1 of the mobile terminal device MT to pair the sensing devices D1~D3 with the host device 1. When the sensing devices D1~D3 complete the pairing process with the host device 1, the sensing devices D1~D3 are connected to the host device 1 via the WIFI network or the RF communication network.

Since the distance between the sensing devices D4~D6 and the host device 1 is far, the engineer first performs the pairing procedure between the sensing devices D4~D6 and the host device 1 respectively by operating the engineering maintenance program APP1. After the pairing procedure between the sensing devices D4~D6 and the host device 1 is completed, the engineer then performs the pairing procedure between the repeaters REP1~REP3 and the host device 1 respectively by operating the engineering maintenance program APP1. When the pairing procedure between the repeaters REP1~REP3 and the host device 1 is completed, the repeaters REP1~REP3 are connected to the host device 1 via the wireless network. Finally, the sensing devices D4~D6 can be connected to the host device 1 respectively through the repeaters REP1~REP3.

FIG4 is a schematic diagram of the engineering maintenance program of FIG3 displaying the wireless network node architecture. As shown in FIG4, the engineering maintenance program APP1 of the mobile terminal device MT displays the wireless network node architecture WNC2 of the wireless security system A2. In this embodiment, the multiple network nodes of the wireless network node architecture WNC2 of the wireless security system A2 are respectively the host device 1, the sensor devices D1~D6 and the repeaters REP1~REP3.

In the second embodiment, each of the sensing devices D1~D6 is also provided with a connection path indicator light 5. The connection path indicator lights 5 on the sensing devices D1 and D4 will be described below. The operating principle of the connection path indicator lights 5 on the sensing devices D2~D3 is the same as that of the sensing device D1, and the operating principle of the connection path indicator lights 5 on the sensors D5~D6 is the same as that of the sensing device D4.

When the sensing device D1 is triggered, the sensing device D1 sends a trigger signal to the host device 1. When the host device 1 receives the trigger signal of the sensing device D1, the host device 1 feeds back a confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal of the host device 1, the connection path indicator 5 on the sensing device D1 presents a first light state. For example, the first light state is that the connection path indicator 5 on the sensing device D1 flashes once.

When the sensing device D4 is triggered, the sensing device D4 sends a trigger signal to the repeater REP1. When the repeater REP1 receives the trigger signal from the sensing device D4, then the repeater REP1 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the repeater REP1, the host device 1 feeds back a confirmation signal to the repeater REP1. When the repeater REP1 receives the confirmation signal from the host device 1, then the repeater REP1 transmits the confirmation signal to the sensing device D4. When the sensing device D4 receives the confirmation signal from the repeater REP1, the connection path indicator light 5 on the sensing device D4 presents a second light state. For example, the second lighting state is that the connection path indicator light 5 on the sensing device D4 flashes twice.

FIG5 is a schematic diagram of the third embodiment of the wireless security system of the present invention. As shown in FIG5, the wireless security system A3 includes a host device 1, sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3, a control server 4, and a plurality of loop expanders HUB1~HUB2.

The engineer performs the pairing procedure between the loop extender HUB1 and the host device 1 by operating the engineering maintenance program APP1 of the mobile terminal device MT. When the pairing procedure between the loop extender HUB1 and the host device 1 is completed, the loop extender HUB1 is connected to the host device 1 via the wireless network. Then, the engineer performs the pairing procedure between the sensing devices D1~D3 and the loop extender HUB1 by operating the engineering maintenance program APP1. When the pairing procedure between the sensing devices D1~D3 and the loop extender HUB1 is completed, the sensing devices D1~D3 are connected to the loop extender HUB1 via the wireless network. Finally, the sensing devices D1~D3 are connected to the host device 1 through the loop expander HUB1.

The engineer performs the pairing procedure between loop extender HUB2 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB2 and host device 1 is completed, loop extender HUB2 is connected to host device 1 via the wireless network. Then, the engineer performs the pairing procedure between sensing devices D4~D6 and loop extender HUB2 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D4~D6 and loop extender HUB2 is completed, sensing devices D4~D6 are connected to loop extender HUB2 via the wireless network. Finally, sensing devices D4~D6 are connected to host device 1 via loop extender HUB2.

In practical applications, for example, the sensing devices D1~D3 connected to the loop expander HUB1 can be the defense zone on the first floor, and the sensing devices D4~D6 connected to the loop expander HUB2 can be the defense zone on the second floor. Or for example, the sensing devices D1~D3 connected to the loop expander HUB1 can be the first defense zone on the first floor, and the sensing devices D4~D6 connected to the loop expander HUB2 can be the second defense zone on the first floor.

The above loop expanders and the number of sensing devices are only examples, and the present invention is not limited thereto. One of the uses of the loop expander is to increase the number of sensing devices that the host device can connect to. For example, the upper limit of the number of sensing devices that the host device can connect to is six. Through the loop expander, the number of sensing devices that the host device can connect to can be increased.

FIG6 is a schematic diagram of the engineering maintenance program of FIG5 showing the wireless network node architecture. As shown in FIG6, the engineering maintenance program APP1 of the mobile terminal device MT displays the wireless network node architecture WNC3 of the wireless security system A3. In this embodiment, the multiple network nodes of the wireless network node architecture WNC3 of the wireless security system A3 are respectively the host device 1, the sensor devices D1~D6 and the loop expanders HUB1~HUB2.

In the third embodiment, each of the sensing devices D1 to D6 is also provided with a connection path indicator light 5. The connection path indicator lights 5 on the sensing devices D1 and D4 will be described below. The operating principle of the connection path indicator lights 5 on the sensing devices D2 to D3 is the same as that of the sensing device D1, and the operating principle of the connection path indicator lights 5 on the sensing devices D5 to D6 is the same as that of the sensing device D4.

When the sensing device D1 is triggered, the sensing device D1 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the sensing device D1, the loop expander HUB1 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When the loop expander HUB1 receives the confirmation signal from the host device 1, the loop expander HUB1 transmits the confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal from the loop expander HUB1, the connection path indicator light 5 on the sensing device D1 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D1 flashes slowly once.

When the sensing device D4 is triggered, the sensing device D4 sends a trigger signal to the loop expander HUB2. When the loop expander HUB2 receives the trigger signal from the sensing device D4, the loop expander HUB2 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB2, the host device 1 feeds back a confirmation signal to the loop expander HUB2. When the loop expander HUB2 receives the confirmation signal from the host device 1, the loop expander HUB2 transmits the confirmation signal to the sensing device D4. When the sensing device D4 receives the confirmation signal from the loop expander HUB2, the connection path indicator light 5 on the sensing device D4 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D4 flashes slowly once.

FIG7 is a schematic diagram of the fourth embodiment of the wireless security system of the present invention. As shown in FIG7, the wireless security system A4 includes a host device 1, sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3, a control server 4, a repeater REP1, and loop expanders HUB1~HUB2.

The engineer performs the pairing procedure between the loop extender HUB1 and the host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between the loop extender HUB1 and the host device 1 is completed, the loop extender HUB1 is connected to the host device 1 via the wireless network. Then, the engineer performs the pairing procedure between the sensing device D1 and the repeater REP1 and the loop extender HUB1 by operating the engineering maintenance program APP1. When the pairing procedure between the sensing device D1 and the repeater REP1 and the loop extender HUB1 is completed, the sensing device D1 and the repeater REP1 are connected to the loop extender HUB1 via the wireless network. Finally, the sensor device D1 and repeater REP1 are connected to the host device 1 through the loop expander HUB1.

The engineer performs the pairing procedure between loop extender HUB1 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB1 and host device 1 is completed, loop extender HUB1 is connected to host device 1 via a wireless network. The engineer performs the pairing procedure between sensing devices D2~D3 and loop extender HUB1 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D2~D3 and loop extender HUB1 is completed, sensing devices D2~D3 are connected to loop extender HUB1 via a wireless network. Then, finally, sensing devices D2~D3 are connected to host device 1 via loop extender HUB1.

The engineer performs the pairing procedure between loop extender HUB2 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB2 and host device 1 is completed, loop extender HUB2 is connected to host device 1 via a wireless network. The engineer performs the pairing procedure between sensing devices D4~D6 and loop extender HUB2 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D4~D6 and loop extender HUB2 is completed, sensing devices D4~D6 are connected to loop extender HUB2 via a wireless network. Finally, sensing devices D4~D6 are connected to host device 1 via loop extender HUB2.

FIG8 is a schematic diagram of the engineering maintenance program of FIG7 showing the wireless network node architecture. As shown in FIG8, the engineering maintenance program APP1 of the mobile terminal device MT displays the wireless network node architecture WNC4 of the wireless security system A4. In this embodiment, the multiple network nodes of the wireless network node architecture WNC4 of the wireless security system A4 are respectively the host device 1, the sensor devices D1~D6, the loop expanders HUB1~HUB2 and the repeater REP1.

In the fourth embodiment, each of the sensing devices D1 to D6 is also provided with a connection path indicator light 5. The connection path indicator lights 5 on the sensing devices D1, D2, and D4 will be described below. The operation principle of the connection path indicator light 5 on the sensing device D3 is the same as that of the sensing device D2, and the operation principle of the connection path indicator light 5 on the sensing device D5 and D6 is the same as that of the sensing device D4.

When the sensing device D1 is triggered, the sensing device D1 sends a transmission signal to the repeater REP1. When the repeater REP1 receives the trigger signal from the sensing device D1, the repeater REP1 then transmits the trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the repeater REP1, the loop expander HUB1 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When the loop expander HUB1 receives the confirmation signal, the loop expander HUB1 sends the confirmation signal to the repeater REP1. When the repeater REP1 receives the confirmation signal from the loop expander HUB1, it transmits the confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal from the repeater REP1, the connection path indicator 5 on the sensing device D1 presents the fourth light state. For example, the fourth light state is that the connection path indicator 5 on the sensing device D1 flashes twice slowly.

When the sensing device D2 is triggered, the sensing device D2 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the sensing device D2, the loop expander HUB1 sends a trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When the loop expander HUB1 receives the confirmation signal, the loop expander HUB1 sends a confirmation signal to the sensing device D2. When the sensing device D2 receives the confirmation signal from the loop expander HUB1, the connection path indicator light 5 on the sensing device D2 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D2 flashes slowly once.

When the sensing device D4 is triggered, the sensing device D4 sends a trigger signal to the loop expander HUB2. When the loop expander HUB2 receives the trigger signal from the sensing device D4, the loop expander HUB2 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB2, the host device 1 feeds back a confirmation signal to the loop expander HUB2. When the loop expander HUB2 receives the confirmation signal from the host device 1, the loop expander HUB2 transmits the confirmation signal to the sensing device D4. When the sensing device D4 receives the confirmation signal from the loop expander HUB2, the connection path indicator light 5 on the sensing device D4 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D4 flashes slowly once.

FIG9 is a schematic diagram of the fifth embodiment of the wireless security system of the present invention. As shown in FIG9 , the wireless security system A5 includes a host device 1, sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3, a control server 4, and loop expanders HUB1~HUB3.

The engineer performs the pairing procedure between loop extender HUB1 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB1 and host device 1 is completed, loop extender HUB1 is connected to host device 1 via a wireless network. Then, the engineer performs the pairing procedure between sensing devices D1~D2 and loop extender HUB1 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D1~D2 and loop extender HUB1 is completed, sensing devices D1~D2 are connected to loop extender HUB1 via a wireless network. Finally, sensing devices D1~D2 are connected to host device 1 via loop extender HUB1.

The engineer performs the pairing procedure of loop expander HUB2 and loop expander HUB1 by operating the engineering maintenance program APP1. When the loop expander HUB2 and loop expander HUB1 complete the pairing procedure, loop expander HUB2 is connected to loop expander HUB1 via the wireless network. Then, the engineer performs the pairing procedure of sensing devices D3~D4 and loop expander HUB2 by operating the engineering maintenance program APP1. When the sensing devices D3~D4 and loop expander HUB2 complete the pairing procedure, sensing devices D3~D4 are connected to loop expander HUB2 via the wireless network. Finally, the sensing devices D3~D4 are connected to the host device 1 through the loop expanders HUB1~HUB2.

The engineer performs the pairing procedure between loop extender HUB3 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB3 and host device 1 is completed, loop extender HUB3 is connected to host device 1 via a wireless network. Then, the engineer performs the pairing procedure between sensing devices D5~D6 and loop extender HUB3 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D5~D6 and loop extender HUB3 is completed, sensing devices D5~D6 are connected to loop extender HUB3 via a wireless network. Finally, sensing devices D5~D6 are connected to host device 1 via loop extender HUB3.

In practical applications, for example, the sensing devices D1~D2 connected to the loop expander HUB1 and the sensing devices D3~D4 connected to the loop expander HUB2 can be the first defense zone on the first floor, and the sensing devices D5~D6 connected to the loop expander HUB3 can be the second defense zone on the first floor. For example, the sensing devices D1~D2 connected to the loop expander HUB1 can be the first defense zone on the first floor, the sensing devices D3~D4 connected to the loop expander HUB2 can be the second defense zone on the first floor, and the sensing devices D5~D6 connected to the loop expander HUB3 can be the third defense zone on the first floor.

In the fifth embodiment, each of the sensing devices D1 to D6 is also provided with a connection path indicator light 5. The connection path indicator lights 5 on the sensing devices D1, D3 and D5 will be described below. The operation principle of the connection path indicator light 5 on the sensing device D2 is the same as that of the sensing device D1, the operation principle of the connection path indicator light 5 on the sensing device D4 is the same as that of the sensing device D3, and the operation principle of the connection path indicator light 5 on the sensing device D6 is the same as that of the sensing device D5.

When the sensing device D1 is triggered, the sensing device D1 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal, the loop expander HUB1 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When the loop expander HUB1 receives the confirmation signal, it transmits the confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal from the loop expander HUB1, the connection path indicator 5 on the sensing device D1 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D1 flashes slowly once.

When the sensing device D3 is triggered, the sensing device D3 sends a trigger signal to the loop expander HUB2. When the loop expander HUB2 receives the trigger signal from the sensing device D3, the loop expander HUB2 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the loop expander HUB2, the loop expander HUB1 sends a trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When loop expander HUB1 receives the confirmation signal, loop expander HUB1 transmits the confirmation signal to loop expander HUB2. When loop expander HUB2 receives the confirmation signal from loop expander HUB1, loop expander HUB2 transmits the confirmation signal to sensing device D3. When sensing device D3 receives the confirmation signal from loop expander HUB2, the connection path indicator light 5 on sensing device D3 presents the third light state. For example, the third light state is that the connection path indicator light 5 on sensing device D3 flashes slowly once.

When the sensing device D5 is triggered, the sensing device D5 sends a transmission signal to the loop expander HUB3. When the loop expander HUB3 receives the trigger signal, the loop expander HUB3 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB3, the host device 1 feeds back a confirmation signal to the loop expander HUB3. When the loop expander HUB3 receives the confirmation signal, it transmits the confirmation signal to the sensing device D5. When the sensing device D5 receives the confirmation signal from the loop expander HUB3, the connection path indicator 5 on the sensing device D5 presents a third light state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D5 flashes slowly once.

FIG10 is a schematic diagram of the sixth embodiment of the wireless security system of the present invention. The wireless security system A6 includes a host device 1, sensing devices D1~D6, an engineering maintenance program APP1, a wireless sharing device 2, a modem 3, a control server 4, and loop expanders HUB1~HUB3.

The engineer performs the pairing procedure between loop extender HUB1 and host device 1 by operating the engineering maintenance program APP1. When the pairing procedure between loop extender HUB1 and host device 1 is completed, loop extender HUB1 is connected to host device 1 via a wireless network. Then, the engineer performs the pairing procedure between sensing devices D1~D3 and loop extender HUB1 by operating the engineering maintenance program APP1. When the pairing procedure between sensing devices D1~D3 and loop extender HUB1 is completed, sensing devices D1~D3 are connected to loop extender HUB1 via a wireless network. Finally, sensing devices D1~D3 are connected to host device 1 via loop extender HUB1.

The engineer performs the pairing procedure of loop expander HUB2 and loop expander HUB1 by operating the engineering maintenance program APP1. When loop expander HUB2 and loop expander HUB1 complete the pairing procedure, loop expander HUB2 is connected to loop expander HUB1 via a wireless network. Then, the engineer performs the pairing procedure of sensing devices D4~D5 and loop expander HUB2 by operating the engineering maintenance program APP1. When sensing devices D4~D5 and loop expander HUB2 complete the pairing procedure, sensing devices D4~D5 are connected to loop expander HUB2 via a wireless network. Finally, the sensing devices D4~D5 are connected to the host device 1 through the loop expanders HUB1~HUB2.

The engineer performs the pairing procedure between the loop expander HUB3 and the loop expander HUB2 by operating the engineering maintenance program APP1. When the pairing procedure between the loop expander HUB3 and the loop expander HUB2 is completed, the loop expander HUB3 is connected to the loop expander HUB2 via the wireless network. Then, the engineer performs the pairing procedure between the sensor device D6 and the loop expander HUB3 by operating the engineering maintenance program APP1. When the pairing procedure between the sensor device D6 and the loop expander HUB3 is completed, the sensor device D6 is connected to the loop expander HUB3 via the wireless network. Finally, the sensor device D6 is connected to the host device 1 through the loop expanders HUB1~HUB3.

In practical applications, for example, the sensing devices D1~D3 connected to the loop expander HUB1 can be the defense zone on the 1st floor, the sensing devices D4~D5 connected to the loop expander HUB2 can be the defense zone on the 2nd floor, and the sensing device D6 connected to the loop expander HUB3 can be the defense zone on the 3rd floor.

In the sixth embodiment, each of the sensing devices D1 to D6 is also provided with a connection path indicator light 5. The connection path indicator lights 5 on the sensing devices D1, D4 and D6 will be described below. The operation principle of the connection path indicator lights 5 on the sensing devices D2 to D3 is the same as that of the sensing device D1, and the operation principle of the connection path indicator lights 5 on the sensing device D5 is the same as that of the sensing device D4.

When the sensing device D1 is triggered, the sensing device D1 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal, the loop expander HUB1 transmits the trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When the loop expander HUB1 receives the confirmation signal, it transmits the confirmation signal to the sensing device D1. When the sensing device D1 receives the confirmation signal from the loop expander HUB1, the connection path indicator 5 on the sensing device D1 presents a third light state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D1 flashes slowly once.

When the sensing device D4 is triggered, the sensing device D4 sends a trigger signal to the loop expander HUB2. When the loop expander HUB2 receives the trigger signal from the sensing device D4, the loop expander HUB2 sends a trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the loop expander HUB2, the loop expander HUB1 sends a trigger signal to the host device 1. When the host device 1 receives the trigger signal from the loop expander HUB1, the host device 1 feeds back a confirmation signal to the loop expander HUB1. When loop expander HUB1 receives the confirmation signal, loop expander HUB1 transmits the confirmation signal to loop expander HUB2. When loop expander HUB2 receives the confirmation signal from loop expander HUB1, loop expander HUB2 transmits the confirmation signal to sensing device D4. When sensing device D4 receives the confirmation signal from loop expander HUB2, the connection path indicator light 5 on sensing device D4 presents the third light state. For example, the third light state is that the connection path indicator light 5 on sensing device D4 flashes slowly once.

When the sensing device D6 is triggered, the sensing device D6 sends a trigger signal to the loop expander HUB3. When the loop expander HUB3 receives the trigger signal, the loop expander HUB3 transmits the trigger signal to the loop expander HUB2. When the loop expander HUB2 receives the trigger signal from the loop expander HUB3, the loop expander HUB2 transmits the trigger signal to the loop expander HUB1. When the loop expander HUB1 receives the trigger signal from the loop expander HUB2, the loop expander HUB1 transmits the trigger signal to the host device 1.

When host device 1 receives a trigger signal from loop expander HUB1, host device 1 feeds back a confirmation signal to loop expander HUB1. When loop expander HUB1 receives the confirmation signal, it transmits the confirmation signal to loop expander HUB2. When loop expander HUB2 receives the confirmation signal from loop expander HUB1, it transmits the confirmation signal to loop expander HUB3. When loop expander HUB3 receives the confirmation signal from loop expander HUB2, it transmits the confirmation signal to sensing device D6. When the sensing device D6 receives the confirmation signal from the loop expander HUB3, the connection path indicator light 5 on the sensing device D6 presents the third lighting state. For example, the third lighting state is that the connection path indicator light 5 on the sensing device D6 flashes slowly once.

[Beneficial effects of the embodiment]

One of the beneficial effects of the present invention is that the wireless security system provided by the present invention allows for a higher degree of freedom in the deployment of the security system and can reduce construction and material costs, which can make up for the fact that "wired system security" is easily damaged and causes the circuit defense line to fail. Moreover, engineers only need to observe the display status of the connection path indicator on the sensing device to know the real-time connection path and status of the wireless security system. In addition to the connection path indicator, engineers can also know the real-time connection status between the host device and the sensing device of the security system through the engineering maintenance program. In addition, the network signal strength of the sensing device can also be known through the engineering maintenance program. In this way, engineers can control and maintain the wireless security system more quickly, accurately and efficiently without the need for professional and expensive instruments (such as spectrum analyzers).

The above disclosed contents are only the preferred feasible embodiments of the present invention, and do not limit the scope of the patent application of the present invention. Therefore, all equivalent technical changes made by using the contents of the description and drawings of the present invention are included in the scope of the patent application of the present invention.

A1: Wireless security system

MT: Mobile terminal device

1:Host device

D1~D6: Sensing device

APP1: Engineering maintenance program

2: Wireless Sharing Device

3: Modem

4: Manage the server

5: Connection path indicator

APP2: Customer application

CM: Client Device

Claims (9)

A wireless security system is applicable to a mobile terminal device, the wireless security system includes: a host device; a sensing device, wirelessly connected to the host device and provided with a connection path display light; and an engineering maintenance program installed in the mobile terminal device, the engineering maintenance program wirelessly connected to the host device, the engineering maintenance program displays a wireless network node architecture and a network signal strength, the wireless network node The architecture has multiple network nodes, and the multiple network nodes at least include the host device and the sensing device; when the sensing device is triggered, the sensing device sends a trigger signal, and when the host device receives the trigger signal, the host device sends the confirmation signal to the sensing device; when the sensing device receives the confirmation signal, the connection path indicator light presents different lighting states according to the difference of the wireless network node architecture. The wireless security system as described in claim 1, wherein when the multiple wireless network nodes are the host device and the sensing device respectively, the sensing device is connected to the host device via a wireless network, and the connection path indicator light presents a first light state. A wireless security system as described in claim 1, wherein when the multiple wireless network nodes are the host device, the sensing device and a repeater, the sensing device is connected to the repeater via a wireless network, the repeater is connected to the host device via the wireless network, and the connection path indicator light presents a second light state. The wireless security system as described in claim 1, wherein when the multiple wireless network nodes are the host device, the sensing device and at least one loop extender, the sensing device is connected to the at least one loop extender via a wireless network, the at least one loop extender is connected to the host device via the wireless network, and the connection path indicator light presents a third light state. The wireless security system as described in claim 4, wherein the at least one loop extender is a first loop extender and a second loop extender, and the first loop extender and the second loop extender are respectively matched to the host device. The wireless security system as described in claim 4, wherein the at least one loop extender is a first loop extender and a second loop extender, the first loop extender is matched to the host device, and the second loop extender is matched to the first loop extender. The wireless security system as described in claim 1, wherein when the multiple wireless network nodes are the host device, the sensing device, a repeater, and a loop extender, the sensing device is connected to the repeater via a wireless network, the repeater is connected to the loop extender via the wireless network, the loop extender is connected to the host device via the wireless network, and the connection path indicator light presents a fourth light state. The wireless security system as described in claim 1 further includes a wireless sharing device, a modem, a control server and a client application, the host device is connected to the wireless sharing device, the wireless sharing device is connected to the modem, the modem is connected to the control server, and the client application is connected to the host device via a wireless network. A wireless security system as described in claim 8, wherein when the engineering maintenance program completes a registration process on the control server, the engineering maintenance program is connected to the host device via the wireless network.

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