WO2015135462A1 - Resilient network construction method for remote programmable supervision and control system - Google Patents

Abstract

Disclosed is a resilient network construction method for a remote programmable supervisory control system. The remote programmable supervisory control system comprises an intelligent network device, a local area network router, and a master host communicating with the local area network router. The method comprises the following steps: sending a master host beacon by the master host, the master host beacon comprising online routing data of the local area network router; the intelligent network device receiving the master host beacon sent from the master host so as to log in to the local area network router by means of the online routing data; making the master host log in to the intelligent network device; sending a control command by the master host to the intelligent network device; the intelligent network device receiving the control command and executing the content of the control command; and the intelligent network device returning an execution status message to the master host after executing the content of the control command.

Description

Elastic network construction method for remote programmable monitoring and control system

Cross-reference to related applications

The present application claims priority to Chinese Patent Application No. 20141009036, filed on Jan. 12, 2014, the entire content of which is hereby incorporated by reference.

Technical field

The present disclosure relates to an elastic network construction method, and more particularly to an elastic network construction method for a remote programmable control system for a smart home.

Background technique

In the well-known Smart Home system, all networked appliances must be controlled by a specific, dedicated central servo host, and these networked appliances and the central server are usually soft (hard) and hardware. difference. For example, in the central servo host, a preset control program must be stored in advance, and the central servo host itself is not a networked electrical appliance. These networked electrical appliances must store a processing program corresponding to the control program of the central servo host in advance, and the like. . Therefore, the flexibility of these networked appliances and the central servo host is extremely low, and it is not possible to immediately make different control changes in response to the needs of the user. For example, if the central servo host is initially set to control the operation of the networked appliance A and the networked appliance B, respectively, the user then wants to simultaneously control both the networked appliance A and the networked appliance B through the central server. At this time, the user must first ask the supplier of the smart home system to reset the control program of the central servo host and the processing procedures of the networked electrical appliances, and then simultaneously control the networked electrical appliance A and the networked electrical appliance through the central servo host. B. In addition, new or changed networked devices must also be implemented with the vendor of the smart home system, or require special assistive devices and special skills to make changes to the settings. Since the modification of the setting procedure of the central servo host usually has to be performed by a person in the professional field (for example, the supplier of the smart home system), or an additional auxiliary device is required, this is for the general user (especially the year). The elderly and children are extremely inconvenient and the maintenance of this central servo host is also true. In addition, these networked appliances must be used with a specific, dedicated central servo host, that is, these networked appliances cannot be compatible with other central servos when they cross other domains, so it is difficult To incorporate the increasingly diverse smart home system applications.

Therefore, there is an urgent need for an elastic network construction method for a remote programmable remote control system for a smart home, which allows a user to build his own smart home environment in a more convenient and flexible manner, and Allowing the user to remotely control and monitor one or more home appliances and/or one or more detection devices linked to the remote programmable monitoring control system through the remote programmable monitoring control system An intelligent environment that controls and monitors the interaction of programmatic links.

Summary of the invention

To solve the above problems, according to an embodiment of the present disclosure, an elastic network construction method for a remote programmable control system for a smart home is provided, where the remote programmable control system includes a smart network device, a zone network router and a master host communicating with the zone network router, the method comprising the steps of: transmitting, by the master host, a master host beacon, wherein the master host beacon includes a route of the zone router Online data; the smart network device receives the master host beacon sent from the master host to log in to the network router by using the routed online data; and the master host is logged into the smart network device; The control host sends a control command to the smart network device; the smart network device receives the control command and executes the content of the control command; and the smart network device returns an execution status message to the content after executing the content of the control command Master host.

According to another embodiment of the present disclosure, an elastic network construction method for a remote programmable control system for a smart home is provided, the remote programmable control system comprising a plurality of smart network devices, a network a router, and a master host communicating with the network router, the method includes the following steps: sending, by the master host, a master host beacon, where the master host beacon includes route online data of the network router; All the smart network devices receive the master host beacon sent from the master host to log in to the network router by using the routed online data, wherein each of the smart network devices has a master communication channel and a node communication channel Any one of the plurality of smart network devices is arbitrarily designated as a regional host, and the remaining smart network devices are used as node slaves, wherein the master communication channel and the node communication channel of the regional host are set to be on, and the node is The node's node communication channel is set to on, the slave's master communication channel is set to off, and the host and the section in the area are The master host sign the host region, so that the calibration of the master host; machine through the node between the communication channel used to broadcast or polling call sign from a communication parsed The address of the regional host and the node sends a response command from the fuselage to the regional host, wherein the regional host communicates with the master host through the master communication channel; the regional host receives the sent from the master host The node responds to the command from the fuselage, and then issues the node from the fuselage split response command to all the slaves of the node; and the slave slave receives the node from the fuselage to respond to the command, and then the node is The machine status message is replied to the master host.

According to the method of the present disclosure, the general family can transform their home into the smart home environment they want in a low-cost and easy way in a low-cost and easy way without the relevant technical ability. The smart network device in this disclosure is like a multi-head socket that can be purchased at a hypermarket. It is easy to use and easy to use. It has a high degree of custom space, which will make the "home" more suitable for the "family" needs. Fusion. This allows so-called smart homes to no longer be equated with high-priced systems or luxury homes to break down the barriers that the prole family often encounters in technology or affordability when they enter smart homes. This also enables the realization of home smartness to expand from the top of the pyramid. After entering the general family, it will start to spread and create new home needs, which will inspire more wisdom and home creativity, so that more families can go further. Safe, more comfortable, and smarter directions continue to evolve. In view of the above, the smart network device in the present disclosure is also a general-purpose device, which is easy to embed in a third-party controller. When combined with the home appliance manufactured by the home appliance manufacturer, the smart network device in the present disclosure can be further fitted with the controller of the home appliance product, that is, the home appliance product can be upgraded to a true smart home appliance. In addition, since the smart network device in the present disclosure is a general-purpose device, its manufacturing cost may drop sharply as its production scale increases, thereby reducing the current price barrier of smart home appliances and traditional home appliances, which helps Popularization of smart homes.

Other embodiments and advantages of the present invention will become more apparent from the following detailed description of the accompanying drawings. In addition, components and principles that are well known in the present specification are not described in detail in order not to obscure the present disclosure.

DRAWINGS

1 shows a schematic diagram of a remote programmable monitoring control system for a smart home in accordance with an embodiment of the present disclosure.

2 shows a block diagram of a smart network device in accordance with an embodiment of the present disclosure.

FIG. 3 shows a regional host setup flow in accordance with an embodiment of the present disclosure.

FIG. 4 shows a smart network automatic deployment process in accordance with an embodiment of the present disclosure.

FIG. 5 shows a smart network programmable, monitoring process A in accordance with an embodiment of the present disclosure.

FIG. 6 shows a smart network programmable, monitoring process B in accordance with an embodiment of the present disclosure.

detailed description

1 shows a schematic diagram of a remote programmable monitoring control system for a smart home in accordance with an embodiment of the present disclosure. As shown in FIG. 1, the remote programmable monitoring control system may include one or more smart network devices installed in the home, and the user may arbitrarily designate one of the smart network devices as the regional host, and the remaining smart network devices. Then, as a node slave, the regional host can act as a backup node slave, and the node slave can serve as a backup area host. Therefore, these smart network devices have no fixed master-slave relationship, which can be implemented by the user. The requirements are arbitrarily specified.

The remote programmable monitoring and control system further includes a local area network router that is set up at home and a master host that communicates with the area network router. In an embodiment of the present disclosure, the master host may be a mobile master host, such as a smart phone, a smart watch, a notebook computer, a personal digital assistant (PDA), a tablet. The computer or the like may be a fixed master host such as a personal computer (PC) or the like, but is not limited thereto. The smart network devices may be connected to one or more household appliances (eg, microwave ovens, refrigerators, air conditioning systems, timers, video monitors, etc., but are not limited thereto) and/or one or more detection devices (eg, smoke sensors, Light sensor, thermometer, hygrometer, etc., but not limited to this).

With the remote programmable monitoring control system in the present disclosure, the user can remotely control and monitor these home appliances and/or detection devices through the master host. In addition, the user can programmatically set the linked execution relationship of the home appliances and/or the detecting device through the master host. For example, the user can programmatically set the linkage execution relationship between the microwave oven, the sound, and the smoke sensor through the master host, so when the user sends a control command through the master host, the microwave oven can be executed. The interlocking operation of the sound and smoke sensors.

2 shows a block diagram of a smart network device in accordance with an embodiment of the present disclosure. As shown in FIG. 2, the smart network device may include a network transceiver module, a microprocessor, a smart network device status and setting interface, a control output port, a switch module, a lower controller output port, a monitor input port, and a lower controller. Enter 埠. The lower controller output port can be included with digitally controlled electrical equipment (eg, Digitally controlled microwave ovens, etc., but not limited to this) A/D processor with signal connection, and D/A connected to analog control electrical equipment (for example, but not limited to, an analog control mode) processor. The lower controller input port may include an A/D processor connected to an analog output sensing device (eg, an analog temperature sensor, etc., but not limited thereto), and a digital output sensing device (eg, a digital temperature sensor, etc. However, it is not limited to the digital receiving port of the signal connection. The smart device status and setting interface can be connected to the smart device status display signal to display the status of the smart network device. The smart network device status and setting interface can be manually switched with the master/slave mode to switch the key signal to designate the smart network device as the regional host or node slave by the master/slave mode manual switching key switch. The switch module can be connected to the total power supply of the electrical equipment of the digital control electrical equipment and the electrical power signal of the electrical equipment of the analog control electrical equipment. The "signal connection" herein refers to a connection relationship formed by signal transmission between devices, which is not limited to an entity or a non-physical connection between device hardware.

This network transceiver module can be used to receive and transmit signals, data, and the like. In the present disclosure, the network transceiver module can provide a master communication channel and a node communication channel. The master communication channel may be a transmission protocol using a strict priority of the information link, such as a transmission control protocol (TCP) communication protocol channel, but is not limited thereto. The communication channel of the node may be a transmission protocol that uses information link efficiency priority, such as a user datagram protocol (UDP) communication protocol channel, but is not limited thereto. In the present disclosure, the master communication channel and the node communication channel of the smart network device as the regional host are all set to be turned on; and the node communication channel of the smart network device as the node slave is set to be turned on, and The master communication channel is set to off. The regional host communicates with the master host through the master communication channel; while the zone host and the node slave communicate with each other through the node communication channel, using the polling mode or the broadcast mode. Therefore, the node slave does not directly communicate with the master host, that is, all data transmission between the node slave and the master host must pass through the regional host. The node slave responds to its identity and control status through the node communication channel. In addition, the data packets transmitted by each of the smart network devices on these channels have a consistent protocol format, so that all the smart network devices can use the same data parsing program.

In FIG. 2, when the smart network device is used as a regional host, its network transceiver module can receive network data (ie, communication data) sent by the master host and the node slave, and the data generated by the microprocessor can be The network data sent by the node slave is transmitted to the master host. Conversely, when the smart network device acts as a node slave, its network transceiver module can receive the master host and then pass through the regional host. The transmitted network data is transferred to the regional host by the data generated by its microprocessor, and then transmitted by the regional host to the master host.

The microprocessor can be used to control the transceiver operation of the network transceiver module. In addition, the microprocessor can be used to parse network data from the master host to determine whether the network data is valid (eg, to parse whether the check code contained in the network data conforms to a default format, device authorization included in the network data If the code is invalid, etc., if it is determined to be invalid, the network data is ignored; if it is determined to be valid, it is further determined whether the network data is related to its own device (for example, parsing the destination IP address string included in the network data) Whether it is consistent with the IP assigned by the local router to the local router, etc.); if it is determined that it is not related to the own device, the network data is ignored, and if it is determined to be related to the own device, the content of the network data is executed. For example, the master host sends a control command to the regional host A, and then the regional host A further issues the control command of the self-control host to the node slaves B, C, and D. At this time, the regional host A and all the nodes The microprocessors of machines B, C, and D can parse control commands from the master host to determine whether the control command is valid (eg, than the check code, device authorization code, etc. included in the control command), assuming The regional host A and the node slaves B and C determine that the control command is invalid, and the node slave D determines that the control command is valid, then the regional host A and the node slaves B and C will ignore the control command, and the node slave D further determines whether the control command is related to the device itself (for example, than the destination IP address string included in the control command, etc.), and if it is determined that it is not related to the device, the control command is ignored, and if it is determined Related to the device, the content of the control command is executed, that is, the microprocessor of the node slave D can transmit the control command to the switch module through the control output port, thereby controlling the power of the digital control electrical device. The total power supply of the equipment or the electrical equipment of the analog control electrical equipment is turned on and off, or the control command can be transmitted to the output of the lower controller through the control output port, and then the control command is sent to the digital control electrical device or the analog control electrical device. To control the operating conditions of digital control electrical equipment or analog control electrical equipment (such as digital control adjustment to perform microwave power or start-up time, analog control adjustment of lamp brightness, etc.). In addition, when the control command is an identity response command, the node slave D can transmit the node slave status message to the area host A, and then reply the node slave status message from the node slave D to the master through the area host A. Control the host.

All smart network devices store a check code table (table) containing various preset check codes. The check code contained in the network data is posted at a fixed address in the network data packet. The code can be used, for example, to represent the whole packet. For example, 0xFA12 means that the packet belongs to the control command packet, 0xFB14 means that the packet belongs to the response data packet, 0xFC66 represents the handshake packet, and 0xFDFF represents this as the global request. In response to the packet, 0xFD65 represents this as a request to specify a slave response packet, etc., but is not limited to this. When determining whether the check code contained in the network data is valid, the smart network device parses whether the check code contained in the network data is posted at a fixed address in the network data packet, and checks the network data to include Check if the code matches the check code in its check code table. If both of the above are satisfied, it is determined that the check code contained in the network data is valid; if the two are not satisfied at the same time, it is determined to be invalid, and the network data is ignored. The purpose of the check code is to prevent misidentification of similar packets that may occur sporadicly throughout the network transmission. In addition, in the control program of the individual smart network device, the program to be called next may be known by the check code. If the check code is invalid, the device program does not call the basis, and the smart network device will ignore the invalid check. Code network data.

All smart network devices store their own device authorization code. The device authorization code of the smart network device can be pre-stored in the main control host. When the master host sends a control command to the smart network device, the device authorization code of the smart network device is posted at a specific address in the control command packet. After receiving the control command, the smart network device parses whether the device authorization code included in the control command conforms to the device authorization code of the own device, and if yes, determines that the control command is valid, and if not, the determination is invalid. And ignore this control command.

The smart network device can also have a "monitor" function in addition to the "control" function. For example, the A/D processor of the lower controller input port of the smart network device can receive the analog monitoring signal from the analog output sensing device, and the digital receiving port of the lower controller input port of the smart network device can receive the sensing from the digital output. Digital monitoring signal of the device. Then, by monitoring the input port, the received monitoring signal is fed back to the microprocessor, and then transmitted to the master host by the network transceiver module (via the regional host). For example, the digital temperature sensor can transmit the temperature monitoring signal to the lower controller input port, and then feedback the temperature monitoring signal to the microprocessor through the monitoring input port, and then transmit it through the network transceiver module (via the regional host) To the master host.

The flexible network construction method for the remote programmable remote control system of the smart home in the present disclosure may include, but is not limited to, an area host setting process, a smart network automatic deployment process, and a smart network programmable and monitoring process. These will be described in detail below with reference to the embodiments shown in FIGS. 3 to 6. Process. The flowcharts shown in FIG. 3 to FIG. 6 are presented for the purpose of illustrating the method in the present disclosure, and should not be construed as limiting the disclosure.

FIG. 3 shows a regional host setup flow in accordance with an embodiment of the present disclosure. As shown in FIG. 3, according to the regional host setting process of the embodiment, the master host that communicates with the network router enters the search area host program and sends a master host beacon, and the master host beacon includes The routing data of this local area network router. The one or more smart network devices receive the master host beacon sent from the master host to log in to the area network router by using the routed online data contained in the master host beacon. When the smart network device logs in to the local area network router, the local area network router can allocate an internet protocol address (IP address) to the smart network device by, for example, a dynamic host configuration protocol (DHCP) mechanism. When only a single smart network device is set, the designated command may be sent to the smart network device through the master host to designate the smart network device as the regional host; or the master/slave of the smart network device may be manually switched. The mode manual switching key (Fig. 2) designates the smart network device as the regional host, that is, the "trigger entity setting device" shown in Fig. 3. In the case where only a single smart network device is set, the smart network device can be both a regional host and a node slave. When multiple smart network devices are set, the designated command may be sent to one of the smart network devices by the master host to complete the designation of the regional host; or the master/slave of the smart network devices may be manually switched. The mode manual switch key is used to designate a regional host for one of these smart network devices. As described above, the master communication channel and the node communication channel of the regional host are all set to be on; the master communication channel of the node slave is set to be off, and the node communication channel is set to be on.

According to an embodiment of the present disclosure, in the case where the master host is a portable master host (eg, a smart phone, a smart watch, a notebook computer, a personal digital assistant, a tablet computer, etc.), the master host enters To set up the network connection range of the local area network router in the home and log in to the local area network router through the wireless Fidelity (WiFi) communication protocol to obtain the routing online data of the local area network router, at this time, the main control host is in progress. Field status, this means that the user carrying the master host has returned to the home; otherwise, if the master host is disconnected from the network connection range of the home network router in the home, then log in to another local area network (for example, other residential area networks, wide area 3G) The 4G network, etc.), at this time, the master host is in the off-site state, which means that the user carrying the master host has left the home. If the master host fails to log in to the home network router and cannot obtain the routed online data of the router, the master host beacon sent by the master host will not include the router of the area network. The online data is routed, so the smart device cannot log in to the local router.

After completing the regional host setup process of Figure 3, the zone master and node slaves can be defined. Then enter the intelligent network automatic deployment process.

FIG. 4 shows a smart network automatic deployment process in accordance with an embodiment of the present disclosure. According to the intelligent network automatic deployment process of the embodiment, the regional host sends the regional host identification beacon, and the regional host identification beacon includes the IP address of the current regional host, the device function attribute of the regional host itself, and the like. Then, the master host receives the host identification beacon of the area, and further logs the received area host IP address as the area host login address to log in to the area host. In an embodiment of the present disclosure, the IP address of the specified regional host, the device function attribute, and the like may be stored in the master host in advance, and then the master host further logs in as the regional host login address. Host for this zone. When the master host logs in to the zone host, the master host sends data containing the device authorization code of the zone host to the zone host as the login authentication. If the regional host login procedure fails, the master host will enter the search area host program again, and the regional host setup process shown in FIG. 3 is executed. If the regional host login procedure is successful, the master host will calibrate the address of the regional host and send the node from the fuselage sub-response command to the regional host. At this time, if there is a node slave, the regional host will release the node from the fuselage sub-response command to all the node slaves after receiving the response from the node sent by the master host. Then, after receiving the command from the fuselage, the node slave transmits the node slave status message to the regional host, and then returns the node slave status message to the master host through the area host, thus completing the automatic Distribution mechanism. The purpose of the automatic network deployment mechanism is to investigate how many node slaves exist in the domain where the regional host is located. Once the master host logs into the zone host, it can stay connected to the zone host through the zone router. The node-sending response command from the master host may include the device authorization code of the node slave and the like. Then enter the Zhi network to control and monitor the process (Figure 5 and Figure 6).

FIG. 5 shows a smart network programmable, monitoring process A in accordance with an embodiment of the present disclosure. According to the smart network programmable control and monitoring process A according to the embodiment, the communication data (ie, network data) can be sent to the regional host through the master host, and then the regional host issues the communication data to all the node slaves. If the communication data contains a control command, when the regional host and/or the node slave determines that the communication data is valid and relevant, the control command is executed. In the case where this control command is executed by the node slave, after executing the control command, the node slave issues an execution status message to the regional host, after which the area master The machine then reverts the execution status message of the node slave to the master host; on the other hand, in the case that the area host executes the control command, the area host also issues an execution status message to the master after executing the control command. Host. This control command can be a general real-time control command or a linked logical command. In the case where the control command is a linked logical command, if the user has set a linked execution relationship with the home appliance and/or the detecting device connected to the regional host or the node slave through the master host, when the regional host or When the node slave executes the linked logic command, the home appliance and/or the detecting device connected thereto can be controlled in a linked manner. Therefore, the unrelated household appliances and/or the detecting device can be linked, for example, performing the interlocking operation of the electric lamp, the microwave oven, the smoke sensor, the interlocking operation of the video monitor and the electronically controlled door lock, the thermometer and the air conditioning system. The linkage operation, etc., but is not limited to this.

If the communication data belongs to the node from the fuselage to respond to the command without the control command, when the node slave determines that the communication data is valid and relevant, the node slave status message is returned to the master host through the regional host.

In addition, the flexible network in the present disclosure is characterized in that, in addition to the elastically assignable area host, the increase, decrease, occurrence or disappearance of the node slave at any time does not hinder the operation of the entire network system, because the master host can pass through the area host. The command to ask the node slave to reply to the identity and status is continuously issued. When the regional host receives the response from the node slave to this command as invalid (or does not receive a response), it is considered that the slave has disappeared.

In accordance with an embodiment of the present disclosure, in the case where the master host is a portable master host (eg, a smart phone), when the user carrying the master host is from the outside (ie, another local area network, such as another cell) When the local area network, wide-area 3G, 4G network, etc.) return home (ie, enter the network connection range of the network routers that are set up at home), the master host will switch the local area network, and vice versa. Therefore, the master host can judge the user's approach (return to home) and departure (away from home) according to the switching of the local area network in which it is located. In this way, when the master host switches the local area network, the master host can automatically send control commands to the regional host.

FIG. 6 shows a smart network programmable, monitoring process B in accordance with an embodiment of the present disclosure. According to the smart network of the embodiment, the process B can be used to process the response data (for example, the node slave status message, the execution status message, and the like) from the node slave, and the response data is parsed. Determine if this response data is valid. For example, the regional host can determine whether the response data is valid by using the check code, source IP, and the like included in the data. Automatic meshing mechanism In this case, the purpose of the regional host issuing node to respond to the command from the fuselage is to have all the nodes respond to their identity. At this time, the regional host does not recognize the IP of the object from the node's response packet, but only checks the code. determination. If it is determined that the response data is invalid, the slave node is reported to the master host to disappear (ie, the connection fails). If it is determined that the response data is valid, the status of the slave slave control and the status of the regional host itself are reported to the master host.

In an embodiment of the present disclosure, the regional host is in a state of waiting for the target node slave to reply after issuing a response from the target node to the specific node of the master host from the fuselage. If the regional host does not receive the response data of the target node slave for more than a predetermined time, the regional host will report the target node slave failure to the master host.

After receiving the response data from the regional host, the master host will parse whether the response data is valid, for example, by determining the response data in the response data, the source IP, the check code, and the like. If the determination is invalid, the regional host is regarded as disconnected. At this time, the main control host can trigger a warning (such as sound, text message, etc.) to remind the user; if it is determined to be valid, the reporting area host itself controls the current situation. And displayed on the man-machine interface of the master host. The two flow charts shown in Figures 5 and 6 can be joined together to form an infinite loop.

Unlike the well-known smart home system that must handle the entire device identification and transmission instructions by a specific, dedicated central servo host, the present disclosure is characterized in that there is no need to set a specific, dedicated central servo host, ie, the present disclosure. The smart network device in the text does not have a congenitally fixed master-slave difference in its soft (hard) and hardware. Therefore, each smart network device can be arbitrarily designated as a regional host or a node slave according to user requirements. As far as the present disclosure is concerned, when the smart network device as the regional host fails, the user can designate another smart network device as the new regional host to solve the known smart home system because the specific, dedicated central servo host is lost. The problem that caused the entire system to collapse. In addition, the central servo host of the known smart home system is not easy to maintain, and the setting modification procedure must be assisted by a person in the professional field or a special special device.

In addition, when the smart network device in the present disclosure moves across the domain, since it does not depend on a specific, dedicated central server, it can be fully compatible with the new domain operation, so the same master program software can be loaded. And the different master hosts of the domain in which the smart network device is located are controlled, so the smart network device in the present disclosure has good compatibility and mobility. According to the present disclosure, as long as the host host loaded with the same master program software can be used, there is no relevant skill background at all. Users can easily build the smart home form they want.

Another feature of the present disclosure is that, unlike the well-known smart home system (and thus various registration aids or means) that must perform registration actions in advance through a specific, dedicated central servo host, the present disclosure utilizes " Global bidirectional protocol parsing, that is, all communication data between the smart network devices (ie, between node slaves and node slaves, or between zone masters and node slaves) and with the master host All can be received by all the smart network devices (regional host and node slaves), which is called "global". Therefore, the smart network device will receive an invalid command that may not be related to itself but the check code and the authorization code are legal. The flexible application focus is here. Moreover, because the command of the regional host is issued, regardless of the presence or absence of the node slave, the increase, decrease, occurrence or disappearance of the node slave does not have any impact on the operation of the entire network system.

In addition, in the present disclosure, all the smart network devices in the same local area network have a node communication channel, and any smart network device performs this data if it determines that the data transmitted on the communication channel of the node is valid and relevant. The content, and after the corresponding program related to the content is processed, can actively respond to the processing host with the processing result to form "two-way communication".

In addition, in the present disclosure, all the smart network devices in the same local area network have a node communication channel, and any data packet transmitted by the smart network device on the communication channel of the node has a consistent protocol format for all wisdom. The network device uses the same data parsing program, which is called "protocol parsing". Therefore, any smart network device can send the source of the data appearing on the communication channel of its own node, the object of the sending object (determine whether it is related to itself), whether the handle and the check code conform to the preset format, and whether the authorization code is correct. (Resolve whether the data is valid), analyze the contents of the control command (determine the processing procedure to be taken later), and so on.

Another feature in the present disclosure is that the control command is triggered by the entry and exit identification mechanism of the portable action master (eg, the current smart phone, smart watch, etc.). In general, when the master host successfully switches between different domains automatically, it is usually directly related to the user's action to change the geographic location. For example, the action of the user leaving the home will automatically move the host host that is carried away from the remote network of the home network to automatically join other remote networks (such as other residential area networks, wide-area 3G, 4G networks, etc.). The master host can determine that the user has left the home (ie, left the field) according to the change of the domain information of the login address. Conversely, the action of the user going home will enable the hosted host to enter the home network communication range and automatically from other remote networks (such as other residential area networks, wide areas). The 3G, 4G network, etc.) joins the local area network. At this time, the master host can determine that the user has returned home (ie, entering the market) according to the change of the domain information of the login address. Therefore, in the present disclosure, the decision transition of the master host and the departure field (the successful conversion of the login domain) is used as a trigger signal, and then the smart host is triggered to automatically execute when the entry and exit conditions occur respectively. Home network response. For example, when you are away from home, all lights are automatically turned off, locked, and the indoor monitoring system is activated. When you return home, the lights are automatically turned on, unlocked, the indoor monitoring system is turned off, and the air conditioning equipment is turned on.

There is no need for a specific, dedicated central servo host in the present disclosure to pre-store any automatic reaction procedures. All of the smart network devices in this disclosure are also identical in nature (which can be arbitrarily defined by the user as a regional host or a node slave). Therefore, unlike other systems that require a specific, dedicated central servo host, the smart network device in the present disclosure does not need to be pre-stored in the departure intelligent response program; the user can follow the disclosure to The off-site intelligent response mechanism is randomly set in the mobile action master host, and then the master host controls the smart network device.

Another feature of the present disclosure is that a specific, dedicated central servo host is not required, and the unrelated home appliance can still be linked to the detecting device. For example, the user can perform remote, flexible, real-time settings through the master host, and perform the desired switch and switch logic linkage operation, switch and detection (digital or analog) logic linkage operation, switch and person (as mentioned above) The intelligent automatic response of the entry and exit field is logically linked. As described above, all the smart network devices in the present disclosure do not need to store the programmable logic processing program in advance; the user can programmatically set the programmable logic processing program of the smart network device through the master host according to the present disclosure. . In the well-known system that requires a specific, dedicated central servo host, when the user wishes to change the logical reaction relationship within the smart home network, it is necessary to rely on the assistance of the person in the professional field or special special device assistance to complete the logical reaction relationship. Settings.

While the present invention has been described with reference to the preferred embodiments of the embodiments of the present invention, it is understood that various modifications, changes and equivalents can be made without departing from the spirit and scope of the disclosure. However, such modifications, variations and equivalent substitutions are still within the scope of the patent application of the present disclosure.

Claims (19)

1. An elastic network construction method for a remote programmable control system, the remote programmable control system comprising a smart network device, a regional network router, and a master host communicating with the network router, the characteristics thereof Therefore, the method includes the following steps:

   Sending, by the master host, a master host beacon, where the master host beacon includes route online data of the network router;

   The smart network device receives the master host beacon sent from the master host to log in to the local area network router by using the routed online data;

   Logging in the master host to the smart network device;

   Sending, by the master host, a control command to the smart network device;

   Receiving the control command and executing the content of the control command; and

   After executing the content of the control command, the smart network device returns an execution status message to the master host.
2. The flexible network construction method of the remote programmable control system according to claim 1, wherein the master host is a mobile master host, and when the master host switches the local area network, The master host automatically sends the control command to the smart network device.
3. The flexible network construction method of the remote programmable control system according to claim 1, wherein the smart network device is connected to one or more home appliances and/or one or more detecting devices.
4. The flexible network construction method of the remote programmable monitoring control system according to claim 3, further comprising the following steps:

   The linked execution relationship of the one or more home appliances and/or the one or more detecting devices is programmable in a programmable manner by the master host.
5. The flexible network construction method of the remote programmable monitoring control system according to any one of claims 1 to 4, wherein the step of the smart network device receiving the control command and executing the content of the control command comprises:

   The smart network device determines whether the control command is valid according to the content of the control command:

   If it is determined to be invalid, the control command is ignored.

   If the determination is valid, further determining whether the control command is related to the content of the control command Related to itself; and

   When the smart network device further determines whether the control command is related to itself according to the content of the control command:

   If the decision is not related to itself, the control command is ignored.

   If it is determined that it is related to itself, the content of the control command is executed.
6. The flexible network construction method of the remote programmable control system according to claim 5, wherein the determining, by the smart network device, whether the control command is valid according to the content of the control command comprises:

   The smart network device compares the check code and/or the device authorization code included in the control command to determine whether the control command is valid.
7. The flexible network construction method of the remote programmable control system according to claim 5, wherein the step of determining, by the smart network device, whether the control command is related to itself according to the content of the control command comprises:

   The smart network device compares the destination IP address string included in the control command to determine whether the control command is related to itself.
8. An elastic network construction method for a remote programmable control system, the remote programmable control system comprising a plurality of smart network devices, a regional network router, and a master host communicating with the network router, The feature is that the method comprises the following steps:

   Sending, by the master host, a master host beacon, where the master host beacon includes route online data of the network router;

   All the smart network devices receive the master host beacon sent from the master host to log in to the network router by using the routed online data, wherein each of the smart network devices has a master communication channel and a node communication channel ;

   Any one of the plurality of smart network devices is arbitrarily designated as a regional host, and the remaining smart network devices are used as node slaves, wherein the master communication channel and the node communication channel of the regional host are set to be on, and the node slaves are set. The node communication channel is set to be on, the slave communication channel of the node is set to off, and the communication channel between the host and the slave in the area is through the node, using polling mode or broadcast mode. Communication analysis by call sign;

   Log the master host to the area host, so that the master host calibrates the address of the area host And sending a node from the fuselage sub-response command to the regional host, wherein the regional host communicates with the main control host through the main control communication channel;

   The area host receives the node from the host host to send a response command from the fuselage, and then issues the node from the fuselage split response command to all of the node slaves; and

   After receiving the command from the fuselage, the slave slave replies to the master slave host through the zone master message.
9. The flexible network construction method of the remote programmable control system according to claim 8, wherein the master communication channel is a TCP communication protocol channel.
10. The flexible network construction method of the remote programmable control system according to claim 8, wherein the node communication channel is a UDP communication protocol channel.
11. The flexible network construction method of the remote programmable control system according to claim 8, wherein the step of arbitrarily designating one of the plurality of smart network devices as a regional host comprises:

    Through the master host, a specified command is sent to one of the plurality of smart network devices to complete the designation of the host in the area.
12. The flexible network construction method of the remote programmable monitoring control system according to claim 8, wherein all of the smart network devices each have a master/slave mode manual switching key, and arbitrarily designate the plurality of smart network devices. One of the steps as a zone host includes:

    The master/slave mode manual switching key of the plurality of smart network devices is manually switched to perform designation of the regional host for one of the plurality of smart network devices.
13. The flexible network construction method of the remote programmable control system according to claim 8, wherein the plurality of smart network devices are respectively connected to one or more home appliances and/or one or more detecting devices.
14. The flexible network construction method of the remote programmable control system according to claim 13, further comprising the following steps:

    The linked execution relationship of the one or more home appliances and/or the one or more detecting devices is programmable in a programmable manner by the master host.
15. The flexible network construction method of the remote programmable monitoring control system according to any one of claims 8 to 14, further comprising the following steps:

    Sending, by the master host, a control command to the regional host;

    The regional host receives the control command and issues the control command to all of the node slaves;

    The area host and all the node slaves determine whether the control command is valid according to the content of the control command:

    If it is determined to be invalid, the control command is ignored.

    If the determination is valid, further determining whether the control command is related to itself according to the content of the control command; and

    When the area host and all of the node slaves further determine whether the control command is related to itself according to the content of the control command:

    If the decision is not related to itself, the control command is ignored.

    If it is determined that it is related to itself, the content of the control command is executed.
16. The flexible network construction method of the remote programmable control system according to claim 15, wherein the master host is a mobile master host, and the control command is sent to the host controller by the master host This step for the zone host contains:

    When the master host switches the local area network, the master host automatically sends the control command to the area host.
17. The flexible network construction method of the remote programmable monitoring control system according to claim 15, wherein the area host and/or the node slave replies an execution status message to the master after executing the control command. Control the host.
18. The flexible network construction method of the remote programmable control system according to claim 15, wherein the area host and all of the node slaves determine whether the control command is valid according to the content of the control command. contain:

    The area host compares the check code and/or device authorization code included in the control command with all of the node slaves to determine whether the control command is valid.
19. The flexible network construction method of the remote programmable control system according to claim 15, wherein the area host and all of the node slaves determine whether the control command is related to itself according to the content of the control command. The steps include:

    The area host compares all the node slaves with the destination IP address string contained in the control command to determine whether the control command is related to itself.

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