CN110609534A - Intelligent household control method and system - Google Patents

Abstract

The invention relates to the technical field of intelligent home, in particular to an intelligent home control method and system, wherein the method comprises the following steps: the sending equipment generates a control signaling according to the sending equipment rule configuration file and sends the control signaling to a message channel set in the sending equipment rule configuration file; and the receiving equipment acquires the control signaling from the message channel set in the rule configuration file of the receiving equipment, matches the control signaling with the rule configuration file of the receiving equipment, and executes the corresponding function if the matching is successful. According to the method and the device, the mutual control of the devices in the network is realized according to the rule configuration file, and the load of edge control in the network is reduced; the control and decision-making capability of the equipment is greatly released, and the equipment can execute complex function scenes under the condition of completely not influencing a bottom layer protocol, and has high compatibility.

Description

Intelligent household control method and system

Technical Field

The invention relates to the technical field of intelligent home, in particular to an intelligent home control method and system.

Background

Along with the development of wireless technology, the intellectualization of household products is more and more popular in the industry. At present, a control system of an intelligent home is mainly based on short-distance wireless communication protocols such as WIFI, ZigBee, Bluetooth and some private protocols, and is provided with one or more gateways, so that an internet of things network taking a home as a unit is formed. The products in the network may be lamps, switches, sensors, control modules adapted to the home appliance, etc.

The establishment of a mature intelligent home network requires network distribution equipment to add various intelligent products into the network, and the equipment can be a mobile phone or an intelligent sound box. After the distribution network is completed, a user can utilize a mobile phone, an intelligent sound or a trigger device in the network to realize scene control of electrical appliances such as lamps, televisions, air conditioners, curtains and the like.

Under the actual condition, the mobile phone is used for controlling, so that the process is complicated, and the use habit of the user is not met. The voice control through the intelligent sound equipment is simplified in operation process, but the problems of high manufacturing cost and low control accuracy are brought. The reasons for the low control accuracy are: for voice control, devices within the network are exposed in groups, and it is difficult for a sound to control individual devices within the same group.

Disclosure of Invention

The invention aims to solve the technical problem in the prior art and provides an intelligent home control method and system.

In order to solve the above technical problem, an embodiment of the present invention provides an intelligent home control method, implemented in a network inter-device control manner, including:

the sending equipment generates a control signaling according to a sending equipment rule configuration file and sends the control signaling to a message channel set in the sending equipment rule configuration file;

the receiving equipment acquires a control signaling from a message channel set in a receiving equipment rule configuration file, matches the control signaling with the receiving equipment rule configuration file, and executes a corresponding function if the matching is successful;

the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

In order to solve the above technical problem, an embodiment of the present invention further provides an intelligent home control system, implemented in a network device mutual control manner, including:

the sending equipment is used for generating a control signaling according to a sending equipment rule configuration file and sending the control signaling to a message channel set in the sending equipment rule configuration file;

the receiving equipment is used for acquiring a control signaling from a message channel set in a rule configuration file of the receiving equipment, matching the control signaling with the rule configuration file of the receiving equipment, and executing a corresponding function if the matching is successful;

the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

The invention has the beneficial effects that: the method is realized in a mode of mutual control of devices in the network, and the mutual control of the devices in the Internet of things is realized in a mode of minimum closed loop, so that the method can reduce the load of the edge control in the network without depending on the forwarding and decision of intermediate devices; the server is only responsible for generating the rule configuration file, and issues the rule configuration file to the corresponding equipment through the gateway, and the server does not play any role in the interaction between the equipment of the Internet of things and the equipment; the rule configuration file greatly releases the control and decision-making capability of the equipment, works in an application layer, and can enable the equipment to execute complex function scenes under the condition of not influencing a bottom layer protocol completely. It is worth mentioning that the sending of the rule configuration file only exerts the bearer capability thereof, and provides a possible channel for the efficient control of the device. The specific control logic of the device depends on each unit component in the rule configuration file, and the units in the rule configuration file are changeable and extensible, so that the device provides infinite possibility for future compatibility.

Drawings

FIG. 1 is a schematic flow chart of an intelligent home control method provided by an embodiment of the present invention

Fig. 2 is a schematic flowchart of rule configuration file issuing according to an embodiment of the present invention;

fig. 3 is a rule configuration file of devices A, B and C in scenario 1 according to an embodiment of the present invention;

fig. 4 is a schematic diagram of processing a control signaling by a receiving device according to an embodiment of the present invention;

fig. 5 is a rule configuration file of devices a and B in scenario 2 according to an embodiment of the present invention;

fig. 6 is a rule configuration file of devices A, B and C in scenario 3 according to an embodiment of the present invention.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the invention.

Fig. 1 is a schematic flow chart of an intelligent home control method according to an embodiment of the present invention. As shown in fig. 1, the method includes:

the sending equipment generates a control signaling according to a sending equipment rule configuration file and sends the control signaling to a message channel set in the sending equipment rule configuration file;

the receiving equipment acquires a control signaling from a message channel set in a receiving equipment rule configuration file, matches the control signaling with the receiving equipment rule configuration file, and executes a corresponding function if the matching is successful;

the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

It should be noted that the control devices in the smart home, such as switches and sensors, are low power consumption devices, and can be completely made into a product powered only by a battery. Therefore, the steps of wiring in the wall can be simplified, the convenience of control can be improved to a great extent, the installation position is very flexible, and the portable installation can be carried out according to the user intention and different scenes, which is not possessed by the traditional mode.

In the embodiment, a cloud configuration approach is adopted, so that the intelligent product in a mesh network (wireless mesh network) can be controlled more efficiently and flexibly. A 'secret number' of device-to-device data interaction in the Internet of things is established, namely a sending device rule configuration file and a receiving device rule configuration file.

As shown in fig. 2, the cloud server analyzes control logics of a sending device and a receiving device in the smart home network, and generates a rule configuration file; the server sends the rule configuration file to the home gateway; the home gateway has the capability of connecting the Internet and accessing the home Internet of things; the home gateway sends a corresponding rule configuration file to the equipment according to a designed communication protocol; the device receives the rule configuration file and obtains specific control or controlled capability.

In the embodiment, the intelligent home control is realized in a network device mutual control mode, the device mutual control in the internet of things is realized in a minimum closed loop mode, forwarding and decision making of intermediate devices are not depended on, and load of edge control in the network is reduced; the server is only responsible for generating the rule configuration file, and issues the rule configuration file to the corresponding equipment through the gateway, and the server does not play any role in the interaction between the equipment of the Internet of things and the equipment; the rule configuration file greatly releases the control and decision-making capability of the equipment, works in an application layer, and can enable the equipment to execute complex function scenes under the condition of not influencing a bottom layer protocol completely. It is worth mentioning that the sending of the rule configuration file only exerts the bearer capability thereof, and provides a possible channel for the efficient control of the device. The specific control logic of the device depends on each unit component in the rule configuration file, and the units in the rule configuration file are changeable and extensible, so that the device provides infinite possibility for future compatibility.

Optionally, the sending device rule configuration file reflects role attributes and function attributes of the sending device, and the receiving device rule configuration file reflects role attributes and function attributes of the receiving device.

Optionally, the sending device rule configuration file and the receiving device rule configuration file are in a form of a key table, and include keys and corresponding parameter values.

The rule configuration file needs to reflect the role attributes and the function attributes of the device, and the attributes are expressed in a mode of 'keys'. The rule profile is actually a permutation combination of the various keys and some parameter values. Specifically, the logic nesting relation of a certain rule configuration file is expressed by a JSON data format, then the rule configuration file is analyzed into a binary serialization format according to an intermediate algorithm, and the content of the binary system is the core composition component of the rule configuration file. The use of the rule configuration file does not cause any influence on the wireless communication protocol. The device can have strong control or controlled capability in a minimum closed loop without increasing the burden of a server or a gateway.

To elaborate the structure of the rule configuration file, a key table (table 1) of a version of the rule configuration file is given below, and a part of the table is explained in detail. It should be noted that the content of the part does not have uniqueness, and can be modified and adjusted according to specific requirements, but at the same time, the cloud server and the embedded hardware end are changed in a consistent manner.

TABLE 1

Table 1 illustrates the following: A. a transmitting device and a receiving device: corresponding to the devices with control and controlled attributes in the internet of things, such as switches and lamps.

B. Message channel: a logical channel marked with a number is similar to the concept of a multicast address. The meaning of this is that the message sent by the sending device can be responded to by the receiving device on the same channel.

C. Mode content: the type of the trigger function of the sending device is determined by the mode type, such as on and off, scene control, and the like.

D. Scene content: the specific scene response of the receiving device is a collection of multiple elements, and in addition to the scene number, parameter settings, such as brightness, temperature and humidity, etc., need to be added according to specific attributes of the device.

E. Time delay: the time interval from the receipt of the message to the actual execution by the receiving device.

F. Script: for hardware devices capable of handling scripts, the scripts can be configured to have the capability of performing complex functions, such as control of automatic color temperature.

G. The limiting conditions are as follows: the effective time, the starting time, the ending time and the cycle number belong to the scope of the limiting conditions.

H. Functional parameters are as follows: the switch, the brightness, the temperature and the humidity belong to functional parameters and are related to the self-attribute of the equipment.

I. Additional description: the rule file configuration has great flexibility, and the content in the table can be adjusted according to actual requirements.

Optionally, the generating, by the sending device, the control signaling according to the sending device rule configuration file includes: and generating a control signaling comprising a sending equipment address, a rule configuration file version number, a message channel number, a trigger version number, a mode type and a scene number according to the sending equipment rule configuration file.

Optionally, the matching the control signaling with the rule configuration file of the receiving device, and if the matching is successful, executing a corresponding function, including: and matching the control signaling with the rule configuration file of the receiving equipment, and executing the function corresponding to the scenario number when the control signaling is consistent with the version number, the message channel number, the trigger version number, the mode type and the scenario number of the rule configuration file in the rule configuration file of the receiving equipment.

Optionally, the sending device sends the control signaling to a message channel set in the rule configuration file of the sending device in a broadcast manner.

The smart home control method is further described with reference to the following examples.

Scene 1: switch a is activated to cause lamp B, C to appear 50 and 100 intensities, respectively.

From left to right in fig. 3 are the rule profiles of device A, B, C, respectively. The file version number is the version number of the rule configuration file as the name implies. A message channel, in essence, is a logical link marked by a channel number. And the trigger version number represents a layer of restriction condition added in the information interaction between the sending device and the receiving device so as to meet the requirements of specific situations. In practical cases, the switch a sends control signaling to a specified message channel (multicast-like address) in a broadcast manner, and the content of the signaling includes:

(ii) a self address (unicast address);

second, the version number of the rule configuration file: 1;

③ message channel number: 2;

fourthly, triggering version number: 3;

mode type: 1 (indicating triggering scene control, distinguished from operations such as on and off);

the situation is numbered: 1001;

B. after receiving the signaling, as shown in fig. 4, the specific processing is described as follows:

judging whether the version numbers of the configuration files are consistent or not, and discarding the configuration files if the version numbers are inconsistent;

judging whether the serial numbers of the message channels are consistent or not, and discarding if the serial numbers are inconsistent;

judging whether the trigger version numbers are consistent or not, and discarding if the trigger version numbers are inconsistent;

judging whether the local mode type exists or not, and discarding if the local mode type does not exist;

judging whether the scene numbers are matched according to the found scene modes, and discarding the scene numbers if the scene numbers are not matched;

sixthly, matching to the scene number 1001, and performing brightness adjustment of 50 and 100, respectively.

Scene 2: and controlling the trigger A to enable the air conditioner B to have different response capabilities in different time periods, wherein 8-18 points are in a refrigeration mode, and 18-8 points of the next day are in a sleep mode.

Fig. 5 shows the rule configuration file of device A, B from left to right, respectively. Unlike scenario 1, scenario 2 does not have multiple peer devices, but performs more complex functions for a single peer device. At this time, the effective time in the key table is allocated to the use field, the configuration file of the air conditioner B is changed in fig. 5, and the start times are respectively added for the cooling mode and the sleep mode in the execution content of the scenario number 1000: 8: 00. end time: 18: 00 and start time: 18: 00. end time: 8: 00. In actual control, a broadcasts signaling first, and the signaling content is as follows:

firstly, switching on and off A in the same scene 1;

the situation is numbered: 1000, parts by weight;

b receives the signaling, and the operation is as follows:

b, C in scene 1;

sixthly, matching the scene number to 1000, and judging the current time;

seventhly, executing a refrigeration mode when the current time is 8-18 points; and at 18-8 points, executing a sleep mode.

Scene 3: the two ends of the corridor are respectively provided with a human body detection sensor A, B, and the center of the corridor is provided with an illuminating lamp C. When any of A, B detects a person, lamp C is turned on. The lights are turned off only if no one is detected at A, B.

Fig. 6 shows the rule configuration file of device A, B, C from left to right, respectively. In this scenario, two detectors control the same lamp, and the lamp control logic is coupled to both detectors. In fig. 6, the lamp profile adds an address list including A, B addresses to the execution contents of scene numbers 1000 and 1001, respectively. In the control process, A or B broadcasts signaling, and the signaling content comprises:

firstly, the address of A or B;

② -fourthly, the same as A in the scene 1;

scenario numbering: 1000 (light on) or 1001 (light off);

the response logic for lamp C receiving the signaling is:

b, C in scene 1;

and sixthly, if the scene number is matched with 1000, turning on the light. Meanwhile, according to the address list, if the signaling comes from A, a variable u1 corresponding to A is marked as 1; if from B, the variable u2 corresponding to B is marked as 1.

If the matching scene number 1001 is determined, whether the signaling is from a or B is determined, a sets u1 to 0, B sets u2 to 0, and if and only if u1 is equal to u2, the lamp performs the lamp-off operation.

This also meets the use requirements of real-world situations. In practice, if someone goes from one end of the corridor to the other, say from a to B, A, B, C has the following interaction flow: a monitors a person, sends a light-on instruction → C receives an instruction, executes the light-on operation → the person walks into the monitoring range B, B sends a light-on instruction → C receives an instruction, the light is in an on state at the moment, the light-on operation can be selected to be executed again or a message is ignored → the detection range of the person walking out of the A, A sends a light-off instruction → C receives an instruction, a corresponding variable value u1 is cleared, the light-off operation → the person walks out of the corridor is not executed because the light-off condition is not met, B sends a light-off message → C receives an instruction, the corresponding variable value u2 is cleared, the light-off condition is met, and the light-off is executed.

The embodiment of the invention also provides an intelligent home control system which is realized in a mode of mutual control of devices in a network and comprises a sending device and a receiving device.

The sending equipment is used for generating a control signaling according to a sending equipment rule configuration file and sending the control signaling to a message channel set in the sending equipment rule configuration file; the receiving equipment is used for acquiring a control signaling from a message channel set in a receiving equipment rule configuration file, matching the control signaling with the receiving equipment rule configuration file, and executing a corresponding function if the matching is successful; the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

In the embodiment, the intelligent home control is realized in a network device mutual control mode, the device mutual control in the internet of things is realized in a minimum closed loop mode, forwarding and decision making of intermediate devices are not depended on, and load of edge control in the network is reduced; the server is only responsible for generating the rule configuration file, and issues the rule configuration file to the corresponding equipment through the gateway, and the server does not play any role in the interaction between the equipment of the Internet of things and the equipment; the rule configuration file greatly releases the control and decision-making capability of the equipment, works in an application layer, and can enable the equipment to execute complex function scenes under the condition of not influencing a bottom layer protocol completely. It is worth mentioning that the sending of the rule configuration file only exerts the bearer capability thereof, and provides a possible channel for the efficient control of the device. The specific control logic of the device depends on each unit component in the rule configuration file, and the units in the rule configuration file are changeable and extensible, so that the device provides infinite possibility for future compatibility.

Optionally, the sending device rule configuration file reflects role attributes and function attributes of the sending device, and the receiving device rule configuration file reflects role attributes and function attributes of the receiving device.

Optionally, the sending device is specifically configured to generate, according to the sending device rule configuration file, a control signaling including a sending device address, a rule configuration file version number, a message channel number, a trigger version number, a mode type, and a scenario number.

Optionally, the receiving device is specifically configured to match the control signaling with the receiving device rule configuration file, and execute a function corresponding to the scenario number when the control signaling is consistent with the rule configuration file version number, the message channel number, the trigger version number, the mode type, and the scenario number in the receiving device rule configuration file.

It is clear to those skilled in the art that, for convenience and brevity of description, the specific working processes of the above-described apparatuses and units may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the above-described apparatus embodiments are merely illustrative, and for example, a division of a unit is merely a logical division, and an actual implementation may have another division, for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed.

Units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment of the present invention.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit can be realized in a form of hardware, and can also be realized in a form of a software functional unit.

The integrated unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention essentially or partially contributes to the prior art, or all or part of the technical solution can be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. The intelligent home control method is characterized by being realized in a mode of mutual control of equipment in a network, and comprises the following steps:

the sending equipment generates a control signaling according to a sending equipment rule configuration file and sends the control signaling to a message channel set in the sending equipment rule configuration file;

the receiving equipment acquires a control signaling from a message channel set in a receiving equipment rule configuration file, matches the control signaling with the receiving equipment rule configuration file, and executes a corresponding function if the matching is successful;

the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

2. The method of claim 1, wherein the sending device rule profile reflects role attributes and function attributes of the sending device, and wherein the receiving device rule profile reflects role attributes and function attributes of the receiving device.

3. The method of claim 1, wherein the sending device rule profile and the receiving device rule profile are in the form of a key table comprising keys and corresponding parameter values.

4. The method according to any one of claims 1 to 3, wherein the sending device generates the control signaling according to a sending device rule profile, comprising:

and generating a control signaling comprising a sending equipment address, a rule configuration file version number, a message channel number, a trigger version number, a mode type and a scene number according to the sending equipment rule configuration file.

5. The method of claim 4, wherein the matching the control signaling with the rule configuration file of the receiving device, and if the matching is successful, executing a corresponding function comprises:

and matching the control signaling with the rule configuration file of the receiving equipment, and executing the function corresponding to the scenario number when the control signaling is consistent with the version number, the message channel number, the trigger version number, the mode type and the scenario number of the rule configuration file in the rule configuration file of the receiving equipment.

6. The method according to any one of claims 1 to 3, wherein the sending device sends the control signaling to the message channel set in the rule configuration file of the sending device by broadcasting.

7. The utility model provides an intelligence house control system which characterized in that realizes with the mutual control mode of equipment in the network, includes:

the sending equipment is used for generating a control signaling according to a sending equipment rule configuration file and sending the control signaling to a message channel set in the sending equipment rule configuration file;

the receiving equipment is used for acquiring a control signaling from a message channel set in a rule configuration file of the receiving equipment, matching the control signaling with the rule configuration file of the receiving equipment, and executing a corresponding function if the matching is successful;

the sending equipment rule configuration file and the receiving equipment rule configuration file are generated by a server through analyzing control logics of sending equipment and receiving equipment in the intelligent home network and are sent to the corresponding sending equipment and receiving equipment through a home gateway.

8. The system of claim 7, wherein the sending device rule profile reflects role attributes and function attributes of the sending device and the receiving device rule profile reflects role attributes and function attributes of the receiving device.

9. The system according to claim 7 or 8, wherein the sending device is specifically configured to generate, according to the sending device rule profile, a control signaling that includes a sending device address, a rule profile version number, a message channel number, a trigger version number, a mode type, and a scenario number.

10. The system according to claim 9, wherein the receiving device is specifically configured to match the control signaling with the receiving device rule configuration file, and execute the function corresponding to the scenario number when the control signaling is consistent with the rule configuration file version number, the message channel number, the trigger version number, the mode type, and the scenario number in the receiving device rule configuration file.