WO2014026420A1 - Method for controlling other lights via power switch of one light - Google Patents

Abstract

The present invention relates a method for controlling other lights via the power switch of one light. The method comprises: when a master light and slave lights are all on, a master processor in said master light obtains the off/on signal of a master power switch which constitutes a loop with said master light; if the master power switch is off and turned on before a temporary power circuit in said master light stops power supply to the master processor and a master Radio Frequency (RF) module in said master light, then the master processor controls said master RF module to search for slave RF modules in slave lights within the signal range of the master RF module; said master RF module establishes wireless communication links with one and more slave RF modules which are found by the master RF module; By said master RF module, said master processor sends every slave RF module, which establishes wireless communication link with said master RF module, a signal of stopping power supply to slave radiant which is in the same light with the slave RF module.

Description

 Method of controlling other lights through a power switch of a light

[Technical Field]

 The present invention relates to a method of controlling and driving in a lighting system, and more particularly to a method of controlling other lighting lamps through a power switch of a light.

【Background technique】

 In daily life, the switch of the light in the family is a light corresponding to a switch, or a switch corresponding to a plurality of lights, and the lights and switches must be connected by wires, and the switch and the lamp form a loop through the switch pair The lamp is powered on/off to control the light on and off, and there are many lights in a family, the bedroom has, the living room also has, the stairs are also there, the living room and bedroom lights are independently controlled by their respective switches, some At the time, for example, before going to sleep in the bedroom, when the bedroom lights are turned off, the lights in the living room and the stairs are not closed. At this time, it is more troublesome to get up to turn off the lights in the living room and the stairs. For example, when watching TV in the living room, you will find If the lights in the bedroom are not closed, then you have to get up and turn off the lights in the bedroom. It will also be more troublesome, especially for a duplex family with upper and lower floors.

Therefore, in real life, there is still a technical requirement for controlling one or more other light switches through a power switch of a light. If the conventional wiring switch control method requires rewiring, and the wiring length is large, it is complicated. And in the existing life, almost no family has such wiring design, only the bedroom switch controls the bedroom lights, the living room lights control the living room, or only one main switch can control all the lights on and off. . In order to solve this problem, people also think of another method, namely: through the wireless control technology, through the controller to control the lighting of each light, using a dedicated remote control to control the light of each light That said, there is almost no practical significance, because the remote control is very difficult to store, and a remote control usually only controls one light. To solve this problem, the invention patent of Chinese Patent Application No. 201210043237.9 proposes an Android-based smart Mobile phone lighting control system, including Android smartphone app console, WiFi Protocol converter, ZigBee intelligent terminal controller, this system does not need external remote control, can realize wireless convenient control, and provides various intelligent operation and management such as light switch, brightness adjustment, lighting scene mode switching.

 For the above-mentioned lighting control with the WiFi module through the Android smartphone, although there is a smart phone as the control terminal, there is no need for a dedicated remote controller, but since it is necessary to control the lighting, it is necessary to pass the Android smart phone and the WiFi module in advance. The lights are coded and linked, and there is no way for those who do not have an Android smartphone or who have not previously linked the smartphone to the lights to control the lights in different places, and when the lights need to be controlled It is also inconvenient to take out the phone for control. On the other hand, the cost of the WiFi module is also high. If multiple lights are controlled by a smartphone, it is also necessary to pass the converter, and the cost of the converter is relatively high.

[Summary of the Invention]

 SUMMARY OF THE INVENTION The object of the present invention is to solve the technical problem that the illumination lamp in the home cannot be controlled by other illumination light switches in the prior art, and the present invention provides a method of controlling other illumination lamps through a power switch of an illumination lamp.

 It should be noted that the illumination lamp of the present invention can be referred to as a main illumination lamp only when the power switch of the illumination lamp constitutes a circuit, and the main illumination lamp is distinguished in the present invention. In order to express clearly, but in fact, there is no primary or secondary. Any one of the lights can be called the main light when controlling other lights. The controlled lights are called the slave lights, the main lights and the lights. The lights can be interchanged for roles.

 The specific technical solutions of the present invention are as follows:

 The present invention provides a method of controlling other illumination lamps through a power switch of an illumination lamp, characterized in that the method comprises:

 When the main illumination lamp and the slave illumination lamp are both turned on, the main processor located in the main illumination lamp acquires an off/on signal of the main power switch forming a loop with the main illumination lamp;

 The main power switch is turned off and the temporary power supply circuit in the main illuminator stops to the main illuminator

Λt Chu Chu ^ ^ ^, ίΓ-^ϋ , mt Chu Chu system to the t RF 婼 block ^ gold t The RF module within the signal range of the RF module from the RF module;

 The primary radio frequency module establishes a wireless communication link with one or more of the primary radio frequency modules, and the primary processor establishes, by the primary radio frequency module, each slave of the wireless communication link with the primary radio frequency module. The RF module sends a signal that stops supplying power to the slave illuminator that is located in the same illumination from the RF module;

 Acquiring a signal received from the slave radio frequency module with a slave processor located in the same illumination light from the radio frequency module, and controlling, according to the signal, stopping from the power supply module in the same illumination lamp as the slave processor to supply power to the slave illuminator .

 The method further includes:

 Whenever the primary RF module searches for a secondary RF module and establishes a communication link with the secondary RF module, the primary processor controls the primary illuminator to reduce the brightness of the gradient within the same illumination as the primary processor.

 The method further includes:

 Obtaining state information of the operation from the illuminator from the processor, after the slave illuminator is extinguished, the slave processor transmits status information that is extinguished from the illuminant by transmitting from the radio frequency module to the main radio frequency module;

 The main processor controls the main illuminator to increase the brightness of a gradient each time the main radio frequency module receives a status information of the slave illuminator that is sent from the radio frequency module;

 When all of the slave illuminators are extinguished, the brightness of the master illuminator is restored to the brightness of the primary RF module before searching for the slave RF module.

 The method further includes:

 When the main illumination lamp is in an on state, the slave illumination lamp is in an off state, and the power switch of the illumination lamp is turned on, the main processor located in the main illumination lamp acquires a main power source that forms a loop with the main illumination lamp. Switch off/on signal;

 The main power switch is turned off and is turned on before the temporary power supply circuit in the main illuminator stops supplying power to the main processor and the main radio frequency module in the main illuminator, and the main processor passes the main radio frequency module to the main The radio frequency module establishes a signal that each of the wireless communication links transmits from the radio frequency module to the slave illuminator that is located in the same illumination lamp as the radio frequency module;

^From the RF block, the illumination of the rainbow trout is from the Chu nz off ^The receiver receives from the RF block And controlling, according to the signal, the power supply from the power module to the slave illuminator in the same illuminator as the slave processor.

 The method further includes:

 When the main illuminator is in an on state and the illuminator is in a off state, the main power switch is turned off and the temporary power supply circuit in the illuminator stops supplying power to the main processor and the main radio frequency module in the illuminating lamp. The main illuminator in the illuminator is turned off first, then the main RF module disconnects the communication link from each of the slave RF modules, and the illuminator remains off.

 The method further includes:

 When the main illumination lamp is turned off, and the slave illumination lamp is in the off state, and the slave power source switch that constitutes the loop from the illumination lamp is in an on state, the slave slave device located in the illumination lamp acquires the slave power source from the illumination lamp. Switch off/on signal;

 Disconnecting from the power switch and turning it on again, the slave processor controls the power supply from the power module to the slave illuminator. The method further includes:

 When the main illuminator is in an on state, the slave illuminator is in a closed state, and the slave power switch is in an on state, the slave slave is located in the illuminator and is configured to form a loop from the illuminator. Disconnect/on signal from the power switch;

 Disconnected from the power switch and turned on again, power is supplied from the power module to the illuminator from the processor control control, and the communication link established between the slave RF module and the main RF module is disconnected.

 The method further includes:

 When the main illumination lamp and the slave illumination lamp are both in an open state, and the main RF module is in a connected state with the communication link established from the radio frequency module, the slave processor located in the illumination lamp acquires a loop with the slave illumination lamp. Disconnect/on signal from the power switch;

 Disconnected from the power switch and turned on before the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the radio frequency module in the slave light, the slave processor sends a break from the radio frequency module to the master radio frequency module. Opening a communication link with each of the slave radio modules;

 After the communication link between the slave radio frequency module and the main radio frequency module is disconnected, the slave illumination lamp searches for a radio frequency module of the other illumination lamps within the range of the illumination lamp signal and establishes a communication link, the slave illumination lamp

^ ^ τέ? m明^ n≠ ^ K also illuminates the rainbow ^ ^ 信信寻 The method further includes:

 When the main illumination lamp and the slave illumination lamp are both in an open state, and the main RF module is in a connected state with the communication link established from the radio frequency module, the slave processor located in the illumination lamp acquires a loop with the slave illumination lamp. Disconnect/on signal from the power switch;

 The communication link between the RF module and the primary RF module is disconnected from the power switch and is turned on after the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the RF module in the slave light. Disconnected, the slave power supply module supplies power from the power module to the slave illuminator.

 The method further includes:

 After the power switch of the slave illumination lamp is turned on again, the slave processor located in the slave illumination lamp acquires a disconnection/conduction signal from the power switch that forms a loop with the slave illumination lamp;

 The slave switch is disconnected from the power switch and is turned on before the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the slave radio frequency module, the slave processor controlling the slave radio frequency module to search for the slave Other slave RF modules within the RF module signal range;

 The slave radio frequency module establishes a wireless communication link with the other slave radio frequency module searched by the slave radio frequency module, and the slave processor passes the slave radio frequency module to each of the other slave radio frequency modules that establish a wireless communication link with the slave radio frequency module. Transmitting a signal that is illuminated or extinguished from other illuminators that are located in the same illumination from the RF module;

 The slave processor, which is located in the same illumination from the RF module, acquires signals received from other slave RF modules and controls other slaves that are in the same illumination as the other slaves to light or deactivate according to the signals.

 The radio frequency module is a one-to-many 2.4G wireless communication module.

 The temporary power supply circuit includes an energy storage component, and the energy storage component includes one or more of a capacitor, an inductor, and a battery.

 Compared with the prior art, the beneficial technical effects of the present invention are:

The invention controls the collective lighting and extinguishing of other lighting lamps by using the power switch of any lighting lamp. Since the control tool is a power switch, which is almost a control tool of the existing lighting fixture, if the present invention is to be completed By using the power switch of any illuminator to control the stagnation of other illuminators, only the left side of the snow can change the illumination, so the right ancient method The advantages of single order and low cost.

 Since each illuminator has a power switch, how many xenon lights there are, how many power switches there are, and each power switch can control all the luminaires, so no wireless remote control is needed, and no multiple remote controls are needed. Moreover, even if the lighting fixture is added, it is possible to control all the lighting fixtures without changing the original remote controller setting, and it is also unnecessary to manage the remote controller, which is convenient for people to use.

 The method for controlling other illumination lamps through the power switch of a lighting lamp is very simple, easy to learn and use, so it is very convenient to operate, and it is relatively easy to popularize and popularize.

[Description of the Drawings]

 1 is a structural block diagram of a lighting lamp of the present invention;

 2 is a schematic structural view of a home lighting system of the present invention;

 Figure 3 is a block diagram showing the structure of the illumination lamp of the present invention;

 4 is a flow chart showing a method of controlling other illumination lamps through a power switch of an illumination lamp according to Embodiment 1 of the present invention;

 5 is a flow chart showing a method of controlling other illumination lamps through a power switch of an illumination lamp according to Embodiment 2 of the present invention;

 6 is a flow chart showing a method of controlling other illumination lamps through a power switch of an illumination lamp according to Embodiment 3 of the present invention;

 7 is a flow chart showing a method of controlling other illumination lamps through a power switch of an illumination lamp according to Embodiment 4 of the present invention;

 Fig. 8 is a flow chart showing a method of controlling other illumination lamps through a power switch of an illumination lamp according to Embodiment 5 of the present invention.

【detailed description】

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to make the description too clear, and not limited to The present invention provides a method for controlling the lighting/off of other lighting fixtures in a home lighting system by means of a power switch of a lighting lamp. The home lighting system of the present invention includes a plurality of lighting lamps, as shown in FIG. Each of the illumination lamps includes a processor 11 (which includes a storage module for storing control commands), a radio frequency module 12 connected to the processor 11, a temporary power supply circuit 13, and a power source controlled by the processor 11. The module 14 and the illuminant 15 electrically connected to the power module 14 respectively form a loop between the illuminating lamp and a power switch, and the temporary power supply circuit continues to process when the power module stops supplying power to the processor 11 and the RF module 12 and the illuminant. The device 11 and the radio frequency module 12 are powered.

 Since the processor in each illuminator can only control the power module in the illuminator to supply power to the illuminator, and the power switch of each illuminator does not form a loop with other illuminators, it is difficult to switch the on/off signal of the power switch. Direct control of other lights, only by means of the RF module to send the control signal represented by the power switch on/off signal to other lights, in order to achieve the purpose of controlling other lights through the power switch of a light.

 As shown in FIG. 2, in the home lighting system, a first lighting lamp and a first power switch 21 for controlling the first lighting, a second lighting, and a second lighting control second power switch 22, a third lighting a lamp and a third power switch 23 for controlling the third illuminator, a fourth illuminator, and a fourth power switch 24 for controlling the fourth illuminator, a fifth illuminator, and a fifth power switch 25 for controlling the fifth illuminator, sixth a illuminating light and a sixth power switch 26 for controlling the sixth illuminating light, wherein each of the illuminating lights and the power switch are connected according to an existing common single-pole single-throw lighting circuit, the first illuminating lamp is located in the master bedroom, and the second illuminating lamp Located in the second bedroom, the third illuminator is located in the living room, the fourth illuminator is located in the kitchen, the fifth illuminator is located in the restroom, and the sixth illuminator is located in the study room.

 As shown in FIG. 3, the processor, the radio frequency module, the temporary power supply circuit, the power module, and the illuminator in the first illuminator are respectively referred to as a first processor, a first radio frequency module, a first temporary power supply circuit, and a first power supply. The module and the first illuminant; similarly, the processor, the radio frequency module, the temporary power supply circuit, the power module and the illuminator in the second illuminator are respectively referred to as a second processor, a second radio frequency module, and a second temporary power supply circuit And a second power module and a second illuminator; and so on, the processor, the radio frequency module, the temporary power supply circuit, the power module, and the illuminator in the sixth illuminator are respectively referred to as a sixth processor, a sixth radio frequency module, and a sixth Six temporary power supply circuits, a sixth power supply module, and a sixth illuminant.

On the right day, the ten-night snow left t钋 official residence\needle K also lights the rainbow iH thousand system, the right day ten waiting snow left Other lights are controlled in the bedroom, and other lights are controlled by the third power switch in the living room before going out.

 Since different lamps are turned on and off in different states during use, and the on/off states of the power switches connected to the lamps are different, different conditions may occur during the control, and different conditions may occur in different situations. Methods, the method for controlling the lighting/off of other lighting fixtures in a home lighting system of the present invention by a power switch of a lighting lamp is further illustrated and described below by way of embodiments.

 Example 1

 In this embodiment, the situation that occurs is: each illumination light is in an on state, and it is now required to use a first power switch located in the master bedroom to control other illumination lamps other than the first illumination lamp to be extinguished, as shown in the figure.

4, the control method is as follows:

 S11: The first processor in the first illumination device obtains an off/on signal of the first power switch;

S12: determining whether the temporary power supply circuit in the first illumination light is turned off before the first power switch is turned off, and before the first radio frequency module in the first illumination and the first illumination module is powered on;

 S13: when the first power switch is turned off and the temporary power supply circuit in the first illumination stops before being powered to the first processor and the first RF module, the first processor controls the first RF module search to be located at the first The other five radio frequency modules in the range of the radio frequency signal of the radio frequency module (ie, the second radio frequency module, the third radio frequency module, the fourth radio frequency module, the fifth radio frequency module, and the sixth radio frequency module);

 Since the temporary power supply circuit only supplies power to the first processor and the first RF module, the first processor and the first RF module are working normally before the temporary power supply circuit stops supplying power. After the temporary power supply circuit stops supplying power, the first The power module and the first illuminator stop working due to power failure, and the first illuminator is extinguished.

 S14: During the search process, each time the first radio frequency module searches for a radio frequency module and establishes a communication link with the radio frequency module, the first processor controls the first power supply circuit to supply power to the first illuminant to reduce the maximum brightness. 10%. The 10% is a gradient, and the brightness of the illuminator decreases linearly and discretely. Of course, the reduced gradient can also be set to 5%, 8%, 15% and other percentages.

Since the other five RF modules are all powered, the first RF module can search for 5. - , ^金Hi also 5. - ^ ^ κ also s. - ^ n≠ A request signal for establishing a communication connection is established, and the other five radio frequency modules establish a one-to-many topology wireless communication link with the first radio frequency module after the verification is passed.

 S15: After the wireless communication link is established, the first processor sends the other five processors to the other five radio frequency modules through the first radio frequency module (ie, the second processor, the third processor, and the fourth processing) , the fifth processor, the sixth processor) respectively control the other five illumination lamps (ie: the second illumination lamp, the third illumination lamp, the fourth illumination lamp, the fifth illumination lamp, the sixth illumination lamp) are extinguished signal;

S16: The other five processors acquire the signals from the radio module to control the other five power modules to stop supplying power to the other five illuminators.

 S17: after each power module stops supplying power to the illuminator, the processor connected to each power module sends the illuminant extinction signal to the first radio frequency module through the radio frequency module connected to each processor;

 S18: The first processor obtains a signal that the illumination lamp is turned off, and then controls the first power supply circuit to increase the power supply to the first illuminant by 10% of the maximum brightness.

 S19: when the first power switch is turned off and the temporary power supply circuit in the first illumination lamp is turned on after the power supply to the first processor and the first radio frequency module is stopped, the first illumination light is turned off and is turned on again, the first process is performed. The first RF module and the first RF module are powered off.

 In this way, the purpose of controlling the other five illumination lamps to be extinguished by the first power switch of the first illumination lamp is completed.

 After the first radio frequency module searches for one radio frequency module and establishes a communication link with the radio frequency module, the brightness of the first illuminant is lowered by a gradient, and each time the illuminating light is extinguished, the brightness of the first illuminant is increased by a gradient. When all the lights are off, the brightness of the first illuminator returns to the highest brightness. The reason for this design is: Since people control other lights in the master bedroom, they cannot be viewed in the bedroom. When the other lights are all extinguished, it is necessary to indicate the state of the other lights by the state change of the first lights. This will help the user to determine very accurately whether other lights are turned off in the master bedroom.

 In this way, the purpose of controlling the other five illumination lamps to be extinguished by the first power switch of the first illumination lamp is completed.

^Example 2 In the above embodiment 1, in the case where the second illumination lamp, the third illumination lamp, the fourth illumination lamp, the fifth illumination lamp, the sixth illumination lamp, and the first illumination lamp are all bright, the first in the master bedroom is passed. The power switch controls the other five illumination lights to be completely extinguished. The result of the embodiment is as follows: The first illumination light is on, and the other illumination lights need to be turned on again by the power switch of the first illumination lamp. Five lights, as shown in Figure 5, are controlled as follows:

 S20: the first processor acquires the disconnection/conduction of the first power switch when the first illumination lamp is turned on, the other five illumination lamps are turned off, and the power switches of the other five illumination lamps are in an on state. Signal

 S21: determining whether the temporary power supply circuit in the first illumination light is turned off before the first power switch is turned off, and before the first radio frequency module in the first illumination and the first illumination module is powered on;

 S22: when the first power switch is turned off and the temporary power supply circuit in the first illumination lamp is turned on before stopping power supply to the first processor and the first radio frequency module, the first radio frequency module sends to each of the other radio frequency modules to each The illuminant restores the signal of the power supply;

 S23: The other five processors respectively obtain the restored power supply signal from each radio frequency module, and control each power supply module to resume power supply to each illuminant.

 S24: when the first power switch is turned off and after the temporary power supply circuit in the first illumination stops supplying power to the first processor and the first RF module, the first illuminant is extinguished because the first power module stops supplying power, and then Moreover, because the input of the external power supply of the first power module is lit, and the first RF module stops working due to power failure, the communication link between the first RF module and the other RF modules is disconnected.

 After the communication link of the first RF module and the other RF modules is disconnected, the on/off signal of the first power switch of the first illumination lamp cannot control the illumination of other illumination lamps, only after the first illumination lamp is lit. When the first power switch is turned off and turned on before the temporary power supply circuit stops supplying power, the first RF module starts to search for other RF modules in its signal range, and establishes a communication link with other searched RF modules.

The first power switch is turned off and is turned on after the temporary power supply circuit in the first illumination lamp stops supplying power to the first processor and the first radio frequency module, and the time interval between the first power switch being turned off and being turned on may be The length can be short, and the longer ones often appear after the other lights are controlled to be extinguished. The first lighting fire is then turned on and off, and only the left and right snows are illuminated. Only open. For example, before the nighttime sleep, the other five lights are all controlled to be extinguished by the first power switch, and then the first light is turned off by the first power switch until the next day, when the light needs to be turned on again, the first power switch is turned on. Turn on.

 When the first illuminator disconnects the communication link from the other radio frequency module due to the disconnection of the first power switch until the temporary power supply circuit stops supplying power, since the first radio frequency module is in the absence of power supply The other RF modules are disconnected from the communication link, so the first RF module controls the switch status of other lights, so the other five lights remain off.

 Example 3

 When the first light is turned off or on, the first power switch is turned off or turned on, and the other five lights are turned off, and the other five power switches are in the on state, the second power switch and the third power source are required to pass. The switch, the fourth power switch, the fifth power switch, and the sixth power switch respectively control the second illumination, the third illumination, the fourth illumination, the fifth illumination, and the sixth illumination to be re-opened, and the second power is The example of the switch controlling the second light to be turned back on is to control the method of re-opening the other five lights by the other five power switches. As shown in Fig. 6, the method is as follows:

 S31: The second processor located in the second illumination light acquires the disconnection/guide communication number of the second power switch;

 S32: determining whether the temporary power supply circuit in the second illumination is turned off before the second power switch is turned off, and before the second RF module in the second processor and the second illumination is powered on;

 S33: when the second power switch is turned off and turned on before the second temporary power supply circuit stops supplying power to the second processor and the second RF module, the second processor clears the control command sent by the second illuminator (ie, controls a signal that the second illuminator is turned on or off), the second illuminator is first turned off and then turned on;

 S34: when the second power switch is turned off and is turned on after the second temporary power supply circuit stops supplying power to the second processor and the second RF module, the control command stored in the first processor disappears due to power failure, and the second The illuminator is extinguished first and then turned on.

Similarly, after the third illumination lamp, the fourth illumination lamp, the fifth illumination lamp, and the sixth illumination lamp are turned off, and the third power switch, the fourth power switch, the fifth power switch, and the sixth power switch are in an on state, It is necessary to separately control the lighting by the third power switch, the fourth power switch, the fifth power switch and the sixth power switch, and the lighting rainbow, only the snow photo 匕Ϊ#古法# ρ-^ν^ ^ Example 4

 In the foregoing embodiment 2, the first radio frequency module passively disconnects the communication link from the other radio frequency module because there is no power supply, and the first radio frequency module actively disconnects the communication link from the other radio frequency module. The situation occurs when the first illuminator is in an on state, and the communication link of the first radio frequency module with other radio frequency modules is always in communication state, when the other illuminating lights are controlled by the third power switch of the third illuminating lamp located in the living room When it is off. The first light and the other five lights are all turned on, the first power switch and the other five power switches are in the on state, and the communication link between the first RF module and the other five RF modules is In the connected state, the control of the embodiment is required to be controlled by the third power switch to control the other lights to be completely extinguished. As shown in FIG. 7, the control method includes:

 S41: The third processor in the third illumination device obtains an off/on signal of the third power switch;

S42: determining whether the temporary power supply circuit in the third illumination is turned off before the third power supply is turned off, and before the third RF module in the third processor and the third illumination is powered off;

 S43: when the third power switch is turned off and is turned on before the temporary power supply circuit in the third illumination stops supplying power to the third processor and the third radio frequency module, the third processor passes the third radio frequency module to the first radio frequency Transmitting, by the module, a communication link between the second radio frequency module, the third radio frequency module, the fourth radio frequency module, the fifth radio frequency module, and the sixth radio frequency module;

 S44: After the communication link between the third RF module and the first RF module is disconnected, the third processor controls the third RF module to search for the other five RF modules that are all located in the RF signal range of the third RF module ( That is: a first radio frequency module, a second radio frequency module, a fourth radio frequency module, a fifth radio frequency module, and a sixth radio frequency module);

 S50: Since the temporary power supply circuit only supplies power to the third processor and the third RF module, the third processor and the third RF module are working normally before the temporary power supply circuit stops supplying power. After the temporary power supply circuit stops supplying power, The third power module and the third illuminator stop working due to power failure, the third illuminator is extinguished, and the third radio frequency module is disconnected from the communication link of the first radio frequency module due to power failure, and the other second The communication link of the radio frequency module, the fourth radio frequency module, the fifth radio frequency module, and the sixth radio frequency module is kept in communication with the first radio frequency module.

f ϋ"ί£Φ , 笫三RF婼块备金刭一RF婼块^^ The RF 婼 The block establishes a communication link, and the third processor controls the third power supply circuit to supply power to the third illuminator by 10% of the maximum brightness. The 10% is a gradient, and the brightness of the illuminant decreases linearly discretely. Of course, the reduced gradient can also be set to 5%, 8%, 15% and other percentages.

 Since the other five RF modules are in the power-on state, the third RF module can search for the other five RF modules, and after searching for the other five RF modules, send the request signals for establishing the communication connection to the other five RF modules. The other five RF modules establish a one-to-many topology wireless communication link with the third RF module after verification.

 S46: After the wireless communication link is established, the third processor sends the other five processors to the other five radio frequency modules through the third radio frequency module (ie, the first processor, the second processor, and the fourth processing) , the fifth processor, the sixth processor) respectively control the other five illumination lamps (ie: the first illumination lamp, the second illumination lamp, the fourth illumination lamp, the fifth illumination lamp, the sixth illumination lamp) are extinguished signal;

S47: The other five processors acquire the signals from the RF module to control the other five power modules to stop the other five illuminants.

 S48: after each power module stops supplying power to the illuminator, the processor connected to each power module sends the illuminant extinction signal to the third radio frequency module through the radio frequency module connected to each processor;

 S49: Each time the third processor acquires a signal that the illumination light is off, controlling the power supply of the third power supply circuit to the third luminous body to increase the maximum brightness by 10%.

 After the communication link between the third RF module and the first RF module is disconnected, the first illumination, the second illumination, the fourth illumination, the fifth illumination, and the sixth are controlled by the third power switch. The illuminator controls the second illuminator, the third illuminator, the fourth illuminator, the fifth illuminator, and the sixth illuminator similarly to the first power switch. In the first embodiment, the first illumination lamp is a main illumination lamp, a second illumination lamp, a third illumination lamp, a fourth illumination lamp, a fifth illumination lamp, and a sixth illumination lamp; in this embodiment, the third illumination lamp Main lighting, first lighting, second lighting, fourth lighting, fifth lighting, and sixth lighting, the main lighting is used to control the lighting, the main lighting and the secondary lighting are different Which illuminator is the controller, which illuminator is the controlled person, the main illuminator that controls the function of other illuminators, and the illuminator that is controlled is the illuminator.

Plate according to ^Example 2 ^ Chu, Zuo Yiyi Lighting Rainbow, 笫二照明虹, 笫四照明虹, 笫照 After the light of the third light is turned off by the power switch of the third light, the first light, the second light, the fourth light, the fifth light, the first light can also be controlled by the power switch of the third light The six lights are turned back on. According to the principle of Embodiment 3, after the first illumination lamp, the second illumination lamp, the fourth illumination lamp, the fifth illumination lamp, and the sixth illumination lamp are turned off by the power switch control of the third illumination lamp, the power supply of the third illumination lamp When the switch is turned off, the third illuminator is also extinguished.

 Example 5

 After the first, second, fourth, fifth, and sixth lights are turned back on by the power switch of the third light, the third power module of the third light is turned off and The third temporary circuit is turned on after the power supply is stopped, and the third illumination lamp is turned off and then turned back on again, the communication link between the third RF module and the first RF module is disconnected, the second RF module, the fourth RF module, The communication link between the fifth radio frequency module and the sixth radio frequency module and the first radio frequency module is still in a connected state. At this time, if the first power switch of the first illumination lamp is used to control the extinction of other illumination lights again, The radio frequency module is still in communication connection with the second radio frequency module, the fourth radio frequency module, the fifth radio frequency module, and the sixth radio frequency module, so the first power switch is turned off and the temporary power supply circuit stops to the first processor and the first radio frequency. When the module is powered on, the first RF module does not need to search for the RF module of other lamps in its signal range, and directly to the RF of other lamps. The module sends a signal for controlling the other lights to be extinguished. Since the communication link of the third RF module and the first RF module has been disconnected, the on/off signal of the first power switch can only control the second illumination, the fourth illumination, The fifth illuminator and the sixth illuminator are extinguished. In order to control the other five illuminators by the first illuminator, it is necessary to make the first power switch be turned off for a long time, so that the temporary power supply circuit stops to the first processor and the first radio frequency module, and the first radio frequency module After the communication link between the other RF modules is disconnected, after the first illumination lamp is turned on and the first power switch is quickly disconnected-conducted, the first RF module searches for other RF modules in the signal range again. Establish a communication link with the other five RF modules to complete the network connectivity conditions for controlling the other five lights. Specifically, as shown in FIG. 8, the method includes the following:

S51: When all six illumination lights are on, six power switches are in a conductive state, and the first RF module establishes a communication chain with the second RF module, the fourth RF module, the fifth RF module, and the sixth RF module. After the road, the first processor in the first illumination acquires the disconnection/lead seek of the first power switch: S52: determining whether the temporary power supply circuit in the first illumination light stops before the first power switch is turned off, and is turned on before the first radio frequency module in the first processor and the first illumination is powered on;

 S53: when the first power switch is turned off and the temporary power supply circuit in the first illumination lamp is turned on before stopping power supply to the first processor and the first radio frequency module, the first processor passes the first radio frequency module to the other four The radio frequency module sends the other four lights (ie: the second processor, the fourth processor, the fifth processor, the sixth processor) to control the other four lights (ie: the second light, The fourth illumination lamp, the fifth illumination lamp, and the sixth illumination lamp are extinguished signals, and the first processor controls the first power supply circuit to supply power to the first illuminant to reduce the maximum brightness by 40%. Since the first RF module only establishes a communication link with the four RF modules, it is necessary to reduce the four gradients, each gradient being 10% of the highest brightness.

 S54: Similarly, after the temporary power supply circuit stops supplying power, the first power module and the first illuminator stop working due to power failure, and the first illuminator is extinguished.

 S55: The other four processors acquire the signals from the RF module to control the other four power modules to stop supplying power to the other four illuminators.

 S56: after each power module stops supplying power to the illuminator, the processor connected to each power module sends the illuminant extinguishing signal to the first radio frequency module through the radio frequency module connected to each processor;

 S57: The first processor obtains a signal that the illumination lamp is turned off, and then controls the first power supply circuit to increase the power supply to the first illuminant by 10% of the maximum brightness.

 Example 6

The second illuminator, the fourth illuminating light, the fifth illuminating light and the sixth illuminating light are turned off at the first illuminating light, the first illuminating light and the third illuminating light are in a lighting state, and the six power switches are all turned on. The communication link between the first RF module and the third RF module is disconnected, and the communication link is maintained between the first RF module and the second RF module, the fourth RF module, the fifth RF module, and the sixth RF module. At this time, the third power switch needs to be used to control the other four lights to be turned on again. The third RF module needs to establish a communication link with the other four RF modules first, because the first RF module has already acted as the primary RF module and the first Between the two RF modules, the fourth RF module, the fifth RF module, and the sixth RF module, the signal is 铋^, 笫^, 笫, 婼, 婼, 婼, 婼, 婼, 婼, 婼 The third RF module can establish a communication link with the second radio frequency module, the fourth radio frequency module, the fifth radio frequency module, and the sixth radio frequency module, and the second radio frequency module, the fourth radio frequency module, and the fifth radio frequency The module and the sixth RF module are simultaneously turned on by the first power switch and the third power switch. The method of controlling the second illumination lamp, the fourth illumination lamp, the fifth illumination lamp, and the sixth illumination lamp by the third power switch is similar to that of Embodiment 1 and Embodiment 2, and will not be described again. The embodiment of the present invention only introduces that the processor controls the illumination of other illumination lamps by obtaining a signal that the power switch is continuously turned off/conducted (continuous conduction refers to being turned on before the temporary power supply circuit is powered off). It is also contemplated by one of ordinary skill in the art in view of the principles of the present invention that more functions and state changes of other illuminators can be controlled by taking the power switch continuously off/on two or more times, these functions and state changes. Including the change of color and the change of brightness, for example, the power switch is continuously turned off/conducted twice, the brightness of the illumination lamp will be controlled, and the power switch is continuously turned off/conducted three times, and the color change of the illumination lamp will be controlled. Continuous disconnection/conduction of two or more times means that the host processor has not sent any control commands to the slave radio module during two or more passes. It should be noted that the above embodiments are only for explaining the technical solutions of the present invention, and the present invention is not limited thereto. Although the present invention is described in detail with reference to the preferred embodiments, those skilled in the art should understand that the technical solutions of the present invention can be Modifications or equivalents are intended to be included within the scope of the appended claims.

Claims

What is claimed is: 1. A method of controlling other illuminators by a power switch of a luminaire, the method comprising:

 When the main illumination lamp and the slave illumination lamp are both turned on, the main processor located in the main illumination lamp acquires an off/on signal of the main power switch forming a loop with the main illumination lamp;

 The main power switch is turned off and the temporary power supply circuit in the main illumination lamp is turned on before the main processor and the main radio frequency module in the main illumination lamp are powered off, and the main processor controls the main radio frequency module to search for the main radio frequency module signal. a range of RF modules from within the illuminator;

 The primary radio frequency module establishes a wireless communication link with one or more of the primary radio frequency modules, and the primary processor establishes, by the primary radio frequency module, each slave of the wireless communication link with the primary radio frequency module. The RF module sends a signal that stops supplying power to the slave illuminator that is located in the same illumination from the RF module;

 Acquiring a signal received from the slave radio frequency module with a slave processor located in the same illumination light from the radio frequency module, and controlling, according to the signal, stopping from the power supply module in the same illumination lamp as the slave processor to supply power to the slave illuminator .

 2. The method of controlling a plurality of illuminators by a power switch of a luminaire according to claim 1, wherein the method further comprises:

 Whenever the primary RF module searches for a secondary RF module and establishes a communication link with the secondary RF module, the primary processor controls the primary illuminator to reduce the brightness of the gradient within the same illumination as the primary processor.

 3. The method of controlling a plurality of illuminators by a power switch of a luminaire according to claim 2, wherein the method further comprises:

 Obtaining state information of the operation from the illuminator from the processor, after the slave illuminator is extinguished, the slave processor transmits status information that is extinguished from the illuminant by transmitting from the radio frequency module to the main radio frequency module;

 The main processor controls the main illuminator to increase the brightness of a gradient each time the main radio frequency module receives a status information of the slave illuminator that is sent from the radio frequency module;

 When all of the slave illuminators are extinguished, the brightness of the master illuminator is restored to the brightness of the primary RF module before searching for the slave RF module.

4. Plate slave brake inflammation 1 -3 any one #过一照明虹液开照明火丁 The method is characterized in that the method further comprises:

 When the main illumination lamp is in an on state, the slave illumination lamp is in an off state, and the power switch of the illumination lamp is turned on, the main processor located in the main illumination lamp acquires a main power source that forms a loop with the main illumination lamp. Switch off/on signal;

 The main power switch is turned off and is turned on before the temporary power supply circuit in the main illuminator stops supplying power to the main processor and the main radio frequency module in the main illuminator, and the main processor passes the main radio frequency module to the main The radio frequency module establishes a signal that each of the wireless communication links transmits from the radio frequency module to the slave illuminator that is located in the same illumination lamp as the radio frequency module;

 Acquiring a signal received from the slave radio frequency module with a slave processor located in the same illumination lamp from the radio frequency module, and controlling, according to the signal, the power supply from the power module to the slave illuminator in the same illumination lamp as the slave processor .

 The method of controlling a plurality of illumination lamps by a power switch of an illumination lamp according to any one of claims 1 to 3, wherein the method further comprises:

 When the main illuminator is in an on state and the illuminator is in a off state, the main power switch is turned off and the temporary power supply circuit in the illuminator stops supplying power to the main processor and the main radio frequency module in the illuminating lamp. The main illuminator in the illuminator is turned off first, then the main RF module disconnects the communication link from each of the slave RF modules, and the illuminator remains off.

 The method of controlling other illumination lamps by a power switch of an illumination lamp according to claim 5, wherein the method further comprises:

 When the main illumination lamp is turned off, and the slave illumination lamp is in the off state, and the slave power source switch that constitutes the loop from the illumination lamp is in an on state, the slave slave device located in the illumination lamp acquires the slave power source from the illumination lamp. Switch off/on signal;

 Disconnecting from the power switch and turning it on again, the slave processor controls the power supply from the power module to the slave illuminator.

The method of controlling a plurality of illumination lamps by a power switch of an illumination lamp according to any one of claims 1 to 3, wherein the method further comprises:

When the main illuminator is in the on state, the illuminator is in the off state, and the slave power switch is in the on state, the slave slave is located in the illuminator and is obtained from the illumination rainbow. Back to disconnect from i / ϋ search: Disconnecting from the power switch and turning it on again, power is supplied from the power module to the illuminator from the processor control control, and the communication link established between the slave RF module and the main RF module is disconnected.

 8. The method of controlling a plurality of illuminators by a power switch of a luminaire according to claim 4, wherein the method further comprises:

 When the main illumination lamp and the slave illumination lamp are both in an open state, and the main RF module is in a connected state with the communication link established from the radio frequency module, the slave processor located in the illumination lamp acquires a loop with the slave illumination lamp. Disconnect/on signal from the power switch;

 Disconnected from the power switch and turned on before the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the radio frequency module in the slave light, the slave processor sends a break from the radio frequency module to the master radio frequency module. Opening a communication link with each of the slave radio modules;

 After the communication link between the slave radio frequency module and the main radio frequency module is disconnected, the slave illumination light searches for the radio frequency module of the other illumination lamps within the range of the illumination lamp signal and establishes a communication link, the radio frequency of the slave illumination lamp The module sends signals to other radios' RF modules that control whether other lights are on or off.

 9. The method of controlling a plurality of illuminators by a power switch of a luminaire according to claim 4, wherein the method further comprises:

 When the main illumination lamp and the slave illumination lamp are both in an open state, and the main RF module is in a connected state with the communication link established from the radio frequency module, the slave processor located in the illumination lamp acquires a loop with the slave illumination lamp. Disconnect/on signal from the power switch;

 The communication link between the RF module and the primary RF module is disconnected from the power switch and is turned on after the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the RF module in the slave light. Disconnected, the slave power supply module supplies power from the power module to the slave illuminator.

 10. The method of controlling a plurality of illuminators by a power switch of a luminaire according to claim 9, wherein the method further comprises:

 After the power switch of the slave illumination lamp is turned on again, the slave processor located in the slave illumination lamp acquires a disconnection/conduction signal from the power switch that forms a loop with the slave illumination lamp;

Disconnecting from the power switch and conducting conduction before the temporary power supply circuit in the slave light source stops supplying power to the slave processor and the slave radio frequency module in the slave light, the slave processor controlling the slave radio frequency module to search for the gold From the RF block, the search for the K is also from the RF block: The slave radio frequency module establishes a wireless communication link with the other slave radio frequency module searched by the slave radio frequency module, and the slave processor passes the slave radio frequency module to each of the other slave radio frequency modules that establish a wireless communication link with the slave radio frequency module. Transmitting a signal that is illuminated or extinguished from other illuminators that are located in the same illumination from the RF module;

 The slave processor, which is located in the same illumination from the RF module, acquires signals received from other slave RF modules and controls other slaves that are in the same illumination as the other slaves to light or deactivate according to the signals.