CN112512190A - Method and system for binding kinetic energy switch and lamp - Google Patents

Abstract

The invention relates to a method for binding a kinetic energy switch and a lamp, which comprises a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver, and the method comprises the following steps: the mobile phone end receives signals of all powered kinetic energy switches and receivers, and a space three-dimensional model is established according to the signal intensity and a preset building model; the mobile phone end turns on the channels of the receiver in turn so as to enable the lamps corresponding to the channels of the receiver to be lightened, the mobile phone end simultaneously displays the channels of the receiver which is turned on at present, and the receiver receives the identification number of the kinetic energy switch so as to enable the kinetic energy switch corresponding to the identification number to be bound with the turned-on channels. The embodiment of the invention also provides a corresponding system. The method and the system in the embodiment of the invention can effectively improve the binding efficiency and reduce the time cost.

Description

Method and system for binding kinetic energy switch and lamp

Technical Field

The invention relates to the field of lamp control, in particular to a method and a system for binding a kinetic energy switch and a lamp.

Background

During construction, the matching of the kinetic energy switch and the receiver is complex. Generally, constructors arrange all wires well and connect the receivers and the lamps, the receivers and the lamps are connected through conducting wires during engineering construction, the condition that a single receiver corresponds to a plurality of lamps exists for a multi-channel receiver, and finally the kinetic energy switches are installed and matched. When the matching is performed, the mobile phone app searches all receivers, but a constructor does not know which receiver switch channel the lamp corresponds to. And each receiver switch channel can only be clicked, and the corresponding relation between the lamp and the receiver switch channel can be found by looking at the on and off of the lamp. And after finding out the relation between the lamp and the receiver switch channel, binding the kinetic energy switch to the corresponding receiver switch channel. Therefore, each time a constructor binds a kinetic energy switch, the constructor needs to repeatedly click on the mobile phone app to find out a receiver switch channel corresponding to the lamp, and construction cost is increased.

When finding out the channel of the lamp corresponding to the receiver switch through the mobile phone, the user clicks the code matching and binding, and only the kinetic energy switch needs to be pressed once, so that the code matching and binding can be realized. However, in the code binding process, if other room users press the kinetic energy switch of the product, the switch is also bound to the receiver, so that the switches of other users can control the lamp, and serious use conflict is caused.

Disclosure of Invention

The invention provides a method for binding a kinetic energy switch and a lamp, aiming at solving the problems of low construction efficiency and high labor cost of binding the conventional kinetic energy switch and the lamp, and the method comprises a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver, and the method comprises the following steps:

the mobile phone end receives signals of all powered kinetic energy switches and receivers, and a space three-dimensional model is established according to the signal intensity and a preset building model;

the mobile phone end turns on the channels of the receiver in turn so as to enable the lamps corresponding to the channels of the receiver to be lightened, the mobile phone end simultaneously displays the channels of the receiver which is turned on at present, and the receiver receives the identification number of the kinetic energy switch so as to enable the kinetic energy switch corresponding to the identification number to be bound with the turned-on channels.

Further, the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to a receiver for opening a channel, so that the kinetic energy switch is bound with the channel of the receiver.

Further, an RFID label is arranged on the kinetic energy switch, after the mobile phone end opens the channel of the receiver, the mobile phone end reads the RFID label on the kinetic energy switch, acquires the identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel opened by the receiver is bound with the kinetic energy switch.

Further, the step of building a spatial three-dimensional model comprises:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model.

Further, after the mobile phone end receives signals of all powered-on kinetic energy switches and receivers, the distance is calculated according to the strength of the signals, and the kinetic energy switches and the receivers are displayed in a sequencing mode according to the distance.

On the other hand, the invention also provides a system for binding the kinetic energy switch and the lamp, which comprises a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver; the mobile phone end is used for receiving signals of all powered-on kinetic energy switches and receivers and establishing a space three-dimensional model according to the signal intensity and a preset building model; the mobile phone end is further used for opening the channels of the receivers in turn so that the lamps corresponding to the channels of the receivers are lightened, the mobile phone end simultaneously displays the channels of the receivers which are opened at present, and the receivers receive the identification numbers of the kinetic energy switches so that the kinetic energy switches corresponding to the identification numbers are bound with the opened channels.

Further, the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to a receiver for opening a channel, so that the kinetic energy switch is bound with the channel of the receiver.

Further, an RFID label is arranged on the kinetic energy switch, after the mobile phone end opens the channel of the receiver, the mobile phone end reads the RFID label on the kinetic energy switch, acquires the identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel opened by the receiver is bound with the kinetic energy switch.

Further, the process of establishing the spatial three-dimensional model by the mobile phone terminal includes:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model.

And further, the mobile phone end is also used for calculating the distance according to the strength of the signals after receiving the signals of all the powered kinetic energy switches and the receivers, and sequencing and displaying the switches and the receivers according to the distance.

The method and the system in the embodiment of the invention can reduce the steps of engineering installation and debugging, improve the installation efficiency and reduce the time cost.

Drawings

The features and advantages of the present invention will be more clearly understood by reference to the accompanying drawings, which are illustrative and not to be construed as limiting the invention in any way, and in which:

FIG. 1 is a schematic structural view of a binding system in some embodiments of the invention;

FIG. 2 is a schematic flow chart diagram of a binding method in some embodiments of the invention;

fig. 3 is a flowchart illustrating a binding method according to another embodiment of the present invention.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

The binding method in the embodiment of the invention comprises the following steps:

and in the one-key batch alternate binding scheme, the system starts all receivers by electrifying, and all the receivers are in a configurable binding state. At this time, the mobile phone app can search all receivers through the search button and display the receivers in sequence according to the strength of the received signals, wherein the signals adopt 433MHZ wireless signals. The sequencing mode calculates the actual position of the receiver from near to far through a corresponding algorithm by a background. And the three-dimensional space models of the kinetic energy switch, the APP terminal and the receiver are automatically generated, and the actual space position corresponding relation can be known by calculating the distance between signal sources and calculating a low-precision three-dimensional model by adding preset house model parameters.

The wireless kinetic energy switch is provided with a plurality of keys, and one key corresponds to one control channel of the receiver. The receiver is powered on through the house electrical line, and the house electrical line needs to be powered on manually to achieve power-on. The wireless kinetic energy switch divides the former old switch into a strong current part and a weak current part, the strong current part is connected to an actual electric circuit to receive a control signal to realize a control target, and the weak current part only has one self-generating control module to only transmit the control signal. Generally, a wireless function switch is provided with a self-generating control module, and when a user presses down, the self-generating control module generates electric energy to send a signal.

Constructor binds the button through clicking a key batch, and cell-phone app can press the intensity of received signal automatically and carry out break-make in turn to every receiver passageway, establishes connection through the 433 agreement, and the house circuit is put through, and the cell-phone all can establish the connection through external 433 modules in 10 minutes after the receiver all switches on, automatic disconnection after 10 minutes, and the time can freely be set for. The method comprises the following steps of 1, alternately switching on and off, reminding a constructor of a receiver 2 at which position, and checking which of linked lists is not paired. And the position relation between the receiver which is lighted when the lamp is lighted and the kinetic energy switch and the mobile phone is displayed on the APP, the receiver is provided with an indicator lamp, the indicator lamp and the lamp are lighted when the lamp is lighted, the position and whether the lamp is matched or not are reminded when the lamp is lighted, and the receiver is automatically lighted according to the polling time when the lamp is lighted. . When a certain lamp is on, the corresponding receiver channel of the lamp is in a binding state, and a constructor can bind to the corresponding receiver channel of the lamp only by pressing a kinetic energy switch (or other triggering modes). The kinetic energy switch is pressed down and then the lamp is turned off, which represents that the pairing is successful under the 433 protocol. Therefore, the operation of repeatedly clicking the mobile phone app to find the receiver channel can be saved. The constructor can bind the corresponding lamp by pressing (or triggering) the kinetic energy switch only when seeing that the corresponding lamp is on. Under one-touch batch polling binding, the user may also set a polling interval for each channel matching the binding.

The method system of the invention is shown in figure 1: comprises a lamp, a receiver, a mobile phone and a wireless function switch.

The embodiment of the invention is also provided with a binding conflict solution scheme:

when the receiver is in the binding state, other constructors may press the kinetic energy switch of the product of the model to be bound to the receiver by mistake. The method for solving the problem is to add an rfid tag on the wireless kinetic energy switch. After the constructor uses one key to bind the buttons in batch in turn, when the constructor sees that the lamps to be bound are on, the constructor only needs to make the mobile phone close to the kinetic energy switch, the mobile phone can read the rfid on the kinetic energy switch, and writes the id number, the corresponding receiver and the channel value into the receiver and successfully binds. This will not be mistakenly bound to the receiver even if the switch is pressed by the constructor in another room during this period.

The principle of establishing the space three-dimensional model in the embodiment of the invention is as follows:

the relationship between the transmission power and the reception power of the wireless signal can be expressed by equation (1), PR is the reception power of the wireless signal, PT is the transmission power of the wireless signal, which is the distance between the transceiver units, and n is a propagation factor, the magnitude of which depends on the environment in which the wireless signal propagates.

PR＝PT/rn (1)

The logarithm of the two sides of the formula (1) is taken to obtain the formula (2)

10^nlgr＝10lgPT/PR (2)

The transmitting power of the node is known, and the transmitting power is substituted into the formula (2) to obtain the formula (3)

10lgPR＝A-10*nlg r (3)

The left half 10IgPR of equation (3) is an expression for converting the received signal power to dBm, and may be directly written as equation (4), where a may be regarded as the power of the received signal when the signal is transmitted 1m close in equation (4).

PR(dBm)＝A-10*nlg r (4)

The relationship between the received signal strength and the signal transmission distance is determined by the values of constants a and n obtained in equation (4).

The formula (example) used specifically is:

distance 10^ ((27.55- (20 × log10 (frequency)) + signalLevel)/20).

For example: the frequency is 2412MHz, signalLevel is-57 dbm, and the result is 7.000397427391188 m.

The system presets a building model, and the parameters comprise the height of each floor, the height of the whole floor, the number of floors and the room pattern. And calculating the distance between the receiver, the wireless kinetic energy switch and the mobile phone, the actual floor number, the floor height and the like in real time through a background to obtain an actual low-precision three-dimensional model. Corresponding to the position relation of the actual receiver, the kinetic energy switch and the mobile phone.

As shown in fig. 2, in the embodiment of the present invention, the construction debugging personnel control system starts all the receivers by powering on, and all the receivers are in a configurable binding state for 10 minutes. And then, pressing a mobile phone app search button to search all receivers, calculating the actual positions of the receivers by the background through a corresponding algorithm, and displaying the receivers in a sequence according to the specific distance/position.

Constructors can automatically press the positions and the strength of received signals to make and break each receiver channel in turn by clicking one-key batch binding buttons. When a certain lamp is on, the corresponding receiver channel of the lamp is in a binding state, and a constructor can bind to the corresponding receiver channel of the lamp only by pressing a kinetic energy switch (or other triggering modes). At this moment, the APP can automatically produce corresponding position labels for name remarking. Therefore, the operation of repeatedly clicking the mobile phone app to find the receiver channel can be saved. The constructor can bind the corresponding lamp by pressing (or triggering) the kinetic energy switch only when seeing that the corresponding lamp is on. The process that the corresponding relation needs to be found through manual debugging when the installation position is not clear is avoided. Under one-key batch-by-batch alternate binding, the constructor may also set a polling interval for each channel matching the binding.

When the receiver is in a binding state, the wireless kinetic energy switch is pressed to trigger. When the receiver is in a binding state, the preset program adds an rfid tag to the wireless kinetic energy switch. After constructor used a key to bind the button in turn in batches, when seeing that the lamps and lanterns that need bind are bright, constructor only need be close to the kinetic energy switch with the cell-phone, and cell-phone APP will read the rfid on the kinetic energy switch after the distance is less than 1m, writes into in the receiver and bind successfully this id number and corresponding receiver and channel value. So that the user of the other room will not be mistakenly bound to the receiver even if he presses the switch during this period.

As shown in fig. 3, an embodiment of the present invention provides a method for binding a kinetic energy switch and a lamp, including a mobile phone terminal and a receiver, where the lamp is connected to a channel of the receiver, and the method includes:

s110, the mobile phone end receives signals of all powered-on kinetic energy switches and receivers, and a space three-dimensional model is built according to the signal intensity and a preset building model;

and S120, the mobile phone end turns on the channels of the receiver in turn so as to light the lamps corresponding to the channels of the receiver, the mobile phone end simultaneously displays the channels of the receiver which is turned on at present, and the receiver receives the identification number of the kinetic energy switch so as to bind the kinetic energy switch corresponding to the identification number with the turned-on channels. The mobile phone end can display the positions of the receiver and the kinetic energy switch in the space three-dimensional model, and a user can conveniently and quickly position the receiver and the kinetic energy switch.

The mobile phone end can open each channel according to a time period polling mode, after a certain channel is opened, the lamp is opened, and a constructor or a user presses down the trigger wireless function switch, so that the kinetic energy switch is bound with the opened receiver channel. And then the mobile phone end sequentially opens other channels. Thus, the constructor can configure all the lamps after polling and starting in sequence. The construction efficiency is effectively improved.

Further, the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to a receiver for opening a channel, so that the kinetic energy switch is bound with the channel of the receiver.

Further, an RFID label is arranged on the kinetic energy switch, after the mobile phone end opens the channel of the receiver, the mobile phone end reads the RFID label on the kinetic energy switch, acquires the identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel opened by the receiver is bound with the kinetic energy switch. The bound channels are limited, so that the condition of mistaken binding is prevented.

Further, the step of building a spatial three-dimensional model comprises:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model. The preset positions are building gates, for example, and matching is performed according to the distance between each room and the building gate and the distance calculated according to the signal intensity, and the receivers or the kinetic energy switches can be set in the corresponding rooms at close distances.

Further, after the mobile phone end receives signals of all powered-on kinetic energy switches and receivers, the distance is calculated according to the strength of the signals, and the kinetic energy switches and the receivers are displayed in a sequencing mode according to the distance.

On the other hand, the invention also provides a system for binding the kinetic energy switch and the lamp, which comprises a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver; the mobile phone end is used for receiving signals of all powered-on kinetic energy switches and receivers and establishing a space three-dimensional model according to the signal intensity and a preset building model; the mobile phone end is further used for opening the channels of the receivers in turn so that the lamps corresponding to the channels of the receivers are lightened, the mobile phone end simultaneously displays the channels of the receivers which are opened at present, and the receivers receive the identification numbers of the kinetic energy switches so that the kinetic energy switches corresponding to the identification numbers are bound with the opened channels.

Further, the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to a receiver for opening a channel, so that the kinetic energy switch is bound with the channel of the receiver.

Further, an RFID label is arranged on the kinetic energy switch, after the mobile phone end opens the channel of the receiver, the mobile phone end reads the RFID label on the kinetic energy switch, acquires the identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel opened by the receiver is bound with the kinetic energy switch.

Further, the process of establishing the spatial three-dimensional model by the mobile phone terminal includes:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model.

And further, the mobile phone end is also used for calculating the distance according to the strength of the signals after receiving the signals of all the powered kinetic energy switches and the receivers, and sequencing and displaying the switches and the receivers according to the distance.

The method and the system in the embodiment of the invention can reduce the steps of engineering installation and debugging, improve the installation efficiency and reduce the time cost.

In the present invention, the terms "first", "second", and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The term "plurality" means two or more unless expressly limited otherwise.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A method for binding a kinetic energy switch and a lamp is characterized by comprising a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver, and the method comprises the following steps:

the mobile phone end receives signals of all powered kinetic energy switches and receivers, and a space three-dimensional model is established according to the signal intensity and a preset building model;

the mobile phone end turns on the channels of the receiver in turn so as to enable the lamps corresponding to the channels of the receiver to be lightened, the mobile phone end simultaneously displays the channels of the receiver which is turned on at present, and the receiver receives the identification number of the kinetic energy switch so as to enable the kinetic energy switch corresponding to the identification number to be bound with the turned-on channels.

2. The method of claim 1, wherein the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to a receiver that opens a channel to bind the kinetic energy switch with the channel of the receiver.

3. The method for binding the kinetic energy switch and the lamp as claimed in claim 1, wherein the kinetic energy switch is provided with an RFID tag, and after the mobile phone terminal opens the channel of the receiver, the mobile phone terminal reads the RFID tag on the kinetic energy switch to obtain the identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel opened by the receiver is bound with the kinetic energy switch.

4. The method of claim 1, wherein the step of building a three-dimensional model of space comprises:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model.

5. The method for binding the kinetic energy switch and the lamp as claimed in claim 1, wherein the distance is calculated according to the intensity of the signal after the mobile phone terminal receives the signals of all the powered kinetic energy switches and receivers, and the kinetic energy switches and the receivers are displayed in sequence according to the distance.

6. A kinetic energy switch and lamp binding system is characterized by comprising a mobile phone end and a receiver, wherein the lamp is connected with a channel of the receiver; the mobile phone end is used for receiving signals of all powered-on kinetic energy switches and receivers and establishing a space three-dimensional model according to the signal intensity and a preset building model; the mobile phone end is further used for opening the channels of the receivers in turn so that the lamps corresponding to the channels of the receivers are lightened, the mobile phone end simultaneously displays the channels of the receivers which are opened at present, and the receivers receive the identification numbers of the kinetic energy switches so that the kinetic energy switches corresponding to the identification numbers are bound with the opened channels.

7. The kinetic energy switch and lamp binding system of claim 6, wherein the kinetic energy switch is triggered by a user, and the kinetic energy switch sends an identification number to the receiver that opens the channel to bind the kinetic energy switch with the channel of the receiver.

8. The system of claim 6, wherein the kinetic energy switch is provided with an RFID tag, and after the mobile phone starts a channel of the receiver, the mobile phone reads the RFID tag on the kinetic energy switch to obtain an identification number of the kinetic energy switch, and sends the identification number to the receiver, so that the channel started by the receiver is bound to the kinetic energy switch.

9. The kinetic energy switch and lamp binding system as claimed in claim 6, wherein the process of the mobile phone end for establishing the spatial three-dimensional model comprises:

the mobile phone end is located at a preset position of the preset building model, the distance between the mobile phone end and the receiver is calculated by the mobile phone end according to the signal intensity, and the position of the receiver is identified in the preset building model by combining the spatial position relation of the preset building model; and the mobile phone end calculates the distance between the mobile phone end and the kinetic energy switch according to the signal intensity, and the position of the kinetic energy switch is identified in the preset building model by combining the spatial position relation of the preset building model.

10. The system for binding the kinetic energy switch and the lamp as claimed in claim 6, wherein the mobile phone terminal is further configured to calculate a distance according to the intensity of the signal after receiving the signals of all the powered kinetic energy switches and the powered receivers, and to display the signals of the powered switches and the powered receivers in a sequence according to the distance.

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