CN111132433A - Single lamp, intelligent combined lamp system and intelligent combined lamp control method - Google Patents

Abstract

The invention relates to the field of lighting, and discloses a single lamp, an intelligent combined lamp system and an intelligent combined lamp control method. According to the embodiment of the invention, the PLC receiving module receives the carrier signal transmitted from the outside, and the first controller controls the state of the light source according to the carrier signal, so that the single lamp can be controlled to execute corresponding actions, and multiple functions of the single lamp can be realized.

Description

Single lamp, intelligent combined lamp system and intelligent combined lamp control method

Technical Field

The invention relates to the field of illumination, in particular to a single lamp, an intelligent combined lamp system and an intelligent combined lamp control method.

Background

In various illumination occasions of daily life, a plurality of single lamps are often required to be combined together to realize specific functional illumination and decorative illumination, such as various decorative ceiling lamps, bar table lamps and the like, which are formed by combining a plurality of single lamps. A plurality of single lamps which can be controlled in a linkage mode and have mutual correlation in a lighting space are called combined lamps. In the prior art, most of the combined lamps are connected in parallel to a two-core lighting power supply loop, and simple lamp turning-on and lamp turning-off control is realized by switching on or off the power supply loop.

With the progress of science and technology, people have higher requirements on the illumination quality of human living environment, and the concept of 'green illumination' with high efficiency, energy conservation, environmental protection, safety, comfort and intelligence is provided, but the current single lamp or combined lamp has single function and cannot meet the control requirements of users on the single lamp or combined lamp, so that a multifunctional illumination combined lamp control system which accords with the 'green illumination' concept is necessary to be developed.

Disclosure of Invention

The embodiment of the invention provides a single lamp, an intelligent combined lamp system and an intelligent combined lamp control method, which can intelligently control the single lamp and the combined lamp to enable the single lamp and the combined lamp to have multiple lighting functions.

In a first aspect, an embodiment of the present invention provides a single lamp, where the single lamp is accommodated in a lamp, where the lamp includes a lamp socket, where the lamp socket establishes two paths of electrical connections between the single lamp and an external circuit, and the single lamp includes:

a light source;

the light source driving module is connected with the light source and used for driving the light source;

the lamp holder is matched and connected with the lamp holder;

the PLC receiving module is electrically connected with the external circuit through the matching of the lamp holder and is used for receiving a carrier signal input by the external circuit;

the first power supply conversion module is electrically connected with the external circuit through the matching of the lamp holder and is used for receiving low-voltage electric energy input by the external circuit and converting the low-voltage electric energy into electric energy with proper voltage; and

and the first controller is respectively connected with the PLC receiving module and the light source driving module and is used for controlling the state of the light source according to the carrier signal.

Optionally, the single lamp further comprises:

and the first filtering module is respectively connected with the PLC receiving module and the first power conversion module and is used for blocking the loss of the carrier signal contained in the low-voltage electric energy.

Optionally, the lamp holder and the lamp cap are in accordance with any one of E14, E27, E40, G8, G9, B15, B22, MR16, MR11 and GU10 standards.

In a second aspect, embodiments of the present invention provide an intelligent combination lamp system, comprising:

the second power supply conversion module is connected with an external alternating current power supply loop and used for converting the external alternating current power supply into low-voltage electric energy;

the two-core bus is connected with the second power supply conversion module and used for transmitting electric energy signals and carrier signals;

the single lamps are connected with the two-core bus and used for receiving the electric energy and the carrier signal and executing corresponding actions according to the carrier signal;

the control module is connected with the two-core bus and used for sending the carrier signal to control the state of the single lamp;

the intelligent mobile terminal APP is used for sending a first control instruction to the control module; and

and the wireless remote controller is used for sending a second control instruction to the control module.

Optionally, the two-core bus includes a first two-core bus and a second two-core bus, and the first two-core bus is connected to the second power conversion module and the control module, respectively, and is configured to receive the low-voltage electric energy output by the second power conversion module;

the second two-core bus is respectively connected with the control module and the single lamp and used for receiving the carrier signal output by the control module and transmitting the carrier signal to the single lamp.

Optionally, the control module comprises:

the Bluetooth module and/or the wireless communication module are used for receiving an external instruction;

the second controller is respectively connected with the Bluetooth module and/or the wireless communication module and is used for outputting serial instruction data frames according to the external instruction;

the PLC sending module is respectively connected with the second controller and the second two-core bus, and is used for modulating the serial instruction data frame to the carrier signal and outputting the carrier signal to the second two-core bus; and

and the clock module is connected with the second controller and used for providing real-time clock information for the second controller and receiving the setting of the second controller.

Optionally, the intelligent combination lamp system further comprises:

and the second filtering module is connected between the first two-core bus and the second two-core bus in series and is used for allowing the low-voltage electric energy to pass and preventing the carrier signal from passing.

Alternatively,

the second power supply conversion module, the control module, the second filtering module and the first two-core bus are accommodated in a ceiling mounting disc of the decorative ceiling lamp;

the second two-core bus is accommodated in the hollow lamp post bracket of the decorative ceiling lamp;

the single lamp is contained in the lamp of the decorative pendant lamp.

In a third aspect, an embodiment of the present invention provides an intelligent combined lamp control method, which is applied to an intelligent combined lamp system, and the method includes:

establishing communication connection with external equipment through a Bluetooth module and/or a wireless communication module, and acquiring a control instruction sent by the external equipment;

and controlling the single lamp to execute corresponding actions according to the control instruction so as to control the state of the single lamp.

Alternatively,

controlling the single lamp to execute corresponding actions according to the control instruction so as to control the state of the single lamp, wherein the control method comprises the following steps:

generating a serial instruction data frame according to the control instruction, wherein the serial instruction data frame comprises an addressing frame, a luminous flux setting frame, a scene switching frame, a light-on instruction frame and a light-off instruction frame, so that a PLC (programmable logic controller) sending module generates a carrier signal according to the serial instruction data frame;

and controlling the single lamp to execute corresponding actions according to the carrier signal so as to control the state of the single lamp.

Optionally, the serial command data frame includes:

frame ID, check byte, and single lamp address.

Optionally, the single light address is composed of an illumination area number, a group number, and a single light number.

Optionally, if the number of the illumination area is a first preset value, the serial command data frame is valid for the single lamps in all the illumination areas;

if the packet number is a second preset value, the serial command data frame is valid for all the grouped single lamps;

and if the single lamp number is a third preset value, the serial instruction data frame is effective to all the single lamps.

Optionally, the method further comprises:

acquiring an addressing instruction sent by a mobile terminal APP;

generating the addressing frame according to the addressing instruction, wherein the addressing frame carries an address;

and sending the addressing frame to a single lamp in a carrier wave mode so that the single lamp takes the address carried by the addressing frame as the address of the single lamp.

Optionally, the method further comprises:

acquiring a luminous flux setting instruction sent by the mobile terminal APP;

generating the luminous flux setting frame according to the luminous flux setting instruction, wherein the luminous flux setting frame carries a luminous flux value;

and sending the luminous flux setting frame to the single lamp in a carrier wave mode, so that the single lamp with the same address takes out the luminous flux value in the luminous flux setting frame and sets the luminous flux corresponding to the light source to send out according to the luminous flux value.

Optionally, the method further comprises:

acquiring a scene setting instruction sent by the mobile terminal APP;

generating the scene setting frame according to the scene setting instruction, wherein the scene setting frame comprises a target scene number;

and sending the scene setting frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address sets the current state as the parameter of the target scene corresponding to the target scene number and permanently stores the parameter.

Optionally, the method further comprises:

acquiring a scene switching instruction sent by the mobile terminal APP or the wireless remote controller;

generating the scene switching frame according to the scene switching instruction, wherein the scene switching frame comprises a target scene number;

and sending the scene switching frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address takes out corresponding permanently stored scene parameters according to the target scene number for setting the self state to restore the scene.

Optionally, the method further comprises:

acquiring a light turning-off instruction sent by the mobile terminal APP or the wireless remote controller;

generating the light-off instruction frame according to the light-off instruction;

and sending the light-off instruction frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address stores the current luminous flux value, and the luminous flux of the light source is set to be 0, thereby realizing the light-off.

Optionally, the method further comprises:

acquiring a light-on instruction sent by the mobile terminal APP or the wireless remote controller;

generating the light-on instruction frame according to the light-on instruction;

and sending the light-on instruction frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address takes out the luminous flux value stored when the lamp is turned off for setting the luminous flux of the light source, and the light-on is realized.

Optionally, the method further comprises:

presetting one or more light programs;

and sending the luminous flux setting frames with relevance to the continuous and content of one or more single lamps to the single lamps at certain time intervals to realize the lamp light program.

Optionally, the method further comprises:

acquiring a program switching instruction sent by the mobile terminal APP or the wireless remote controller;

and playing the corresponding program according to the program switching instruction.

Optionally, the icons of the function keys of the wireless remote controller are consistent with the icons of the function keys with the same functions on the page of the mobile terminal APP.

Optionally, the method further comprises:

after the program switching instruction and the scene switching instruction are executed, permanently storing a program number or a scene number;

and when the intelligent combined lamp system is powered off and is powered on again, restoring the intelligent combined lamp system to the program or the scene before the power failure according to the program number or the scene number which is stored finally.

Optionally, the method further comprises:

acquiring a time setting instruction which is sent by the mobile terminal APP and contains the current system time of the mobile terminal APP, wherein the time setting instruction comprises time data;

and setting the time of a clock module according to the time data in the time setting instruction so as to synchronize the time of the intelligent combined lamp system and the time of the mobile terminal.

Optionally, the method further comprises:

acquiring the timing task setting instruction sent by the mobile terminal APP, wherein the timing task setting instruction comprises timing task parameters;

and permanently storing and executing the timing task parameters.

The embodiment of the invention has the beneficial effects that: the embodiment provides a single lamp, intelligent combined lamp system and intelligent combined lamp control method, this single lamp is held in lamps and lanterns, lamps and lanterns contain the lamp stand, the lamp stand establishes two way electricity between single lamp and external circuit and connects, this single lamp includes the light source, light source drive module, the lamp holder, the PLC receiving module, first power conversion module and first controller, light source drive module is connected with the light source, be used for driving the light source, the lamp holder is connected with the lamp stand cooperation, the PLC receiving module is connected with the external circuit electricity, be used for receiving the carrier signal of external circuit input, first power conversion module is connected with the external circuit electricity, be used for receiving the low-voltage electric energy of external circuit input and converting into the electric energy of suitable voltage, first controller respectively with the PLC receiving module, light source drive module is connected, be used for according to the state of carrier signal control light source. According to the embodiment of the invention, the PLC receiving module receives the carrier signal transmitted from the outside, and the first controller controls the state of the light source according to the carrier signal, so that the single lamp can be controlled to execute corresponding actions, and multiple functions of the single lamp can be realized. In addition, the intelligent combined lamp system can be installed in the existing lamp, including the decorative ceiling lamp, and is wide in application range and convenient to replace and update.

Drawings

One or more embodiments are illustrated by way of example in the accompanying drawings, which correspond to the figures in which like reference numerals refer to similar elements and which are not to scale unless otherwise specified.

FIG. 1 is a schematic diagram of an intelligent combination lamp system according to an embodiment of the invention;

FIG. 2 is a schematic diagram of a power switch according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a power switch according to another embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a second filtering module and a control module according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a single lamp structure according to an embodiment of the present invention;

FIG. 6 is a schematic view of a lamp structure of a decorative ceiling lamp according to an embodiment of the present invention;

fig. 7 is a flowchart of an intelligent combination lamp control method according to an embodiment of the present invention;

fig. 8 is a schematic view of an addressing operation interface of a mobile terminal APP according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of a color operation interface of a mobile terminal APP according to an embodiment of the present invention;

FIG. 10 is a schematic diagram of a color temperature operation interface of a mobile terminal APP provided in an embodiment of the present invention;

fig. 11 is a schematic view of a slide bar operation interface of a mobile terminal APP according to an embodiment of the present invention;

fig. 12 is a schematic view of a scene setting interface of a mobile terminal APP according to an embodiment of the present invention;

fig. 13 is a schematic diagram of a timing task interface of a mobile terminal APP according to an embodiment of the present invention;

fig. 14 is a schematic diagram of a timing setting interface of a mobile terminal APP according to an embodiment of the present invention;

fig. 15 is a schematic diagram of a control interface of a mobile terminal APP according to an embodiment of the present invention;

fig. 16 is a schematic diagram of a key interface of a wireless remote control according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if not conflicted, the various features of the embodiments of the invention may be combined with each other within the scope of protection of the invention. Additionally, while functional block divisions are performed in apparatus schematics, with logical sequences shown in flowcharts, in some cases, steps shown or described may be performed in sequences other than block divisions in apparatus or flowcharts. The terms "first", "second", "third", and the like used in the present invention do not limit data and execution order, but distinguish the same items or similar items having substantially the same function and action.

Referring to fig. 1 and fig. 2 together, fig. 1 is a diagram illustrating an intelligent combined lamp system 100 according to an embodiment of the present invention, where the intelligent combined lamp system 100 includes an ac commercial power 1, an ac power supply circuit 2, a power switch 3, a power conversion module 4, a low-voltage ac or dc power supply circuit 5, a filtering module 6, a control module 7, an illumination bus 8, single lamps 9(1 to n), a lamp 10, an intelligent mobile terminal APP11, and a wireless remote controller 12.

The alternating current commercial power 1 is connected with the power conversion module 4 through the three-core alternating current power supply circuit 2. The ac power supply line 2 includes a live line 21, a neutral line 22, and a ground line 23. An alternating current power supply line 2 between an alternating current commercial power 1 and a power conversion module 4 is connected in series with a power switch 3, and the power switch 3 controls on and off of alternating current. In some embodiments, the ac mains 1 may be provided by an external ac power supply circuit.

Referring to fig. 2, the embodiment of the present invention provides a power switch, as shown in fig. 2, the power switch 3 is a two-pole switch, and can simultaneously control the connection and disconnection of the live wire 21 and the neutral wire 22.

Referring to fig. 3, another embodiment of the present invention provides a power switch, as shown in fig. 3, the power switch 3 is a single-pole switch, and only controls the connection and disconnection of the live wire 21, and the neutral wire 22 is always connected.

The power conversion module 4 converts the high-voltage AC mains supply 1 into low-voltage AC power or low-voltage DC power, such as AC24V/AC36V/AC48V or DC24V/DC36V/DC48V, and is connected to the filtering module 6 and the control module 7 through the two-core low-voltage power supply line 5.

Preferably, the power conversion module 4 is a switching power supply, such as an SP-150 series switching power supply available from minwegian technologies ltd.

Referring to fig. 4, in the embodiment of the present invention, a filtering module 6 is a low-pass filter, which functions to allow low-voltage ac power or low-voltage dc power at low frequency to pass through and prevent carrier signals at high frequency from passing through, and the filtering module 6 is connected in series between the low-voltage power supply line 5 and the lighting bus 8.

Preferably, the filtering module 6 includes a first inductor 61 and a second inductor 62, the first inductor 61 and the second inductor 62 are respectively connected to the low-voltage power supply line 5 and the lighting bus 8, and generate a low-pass filtering effect to prevent the carrier signal on the lighting bus 8 from flowing into the power conversion module 4 to be consumed, and also prevent the high-frequency noise generated by the power conversion module 4 from interfering with the carrier signal, while allowing the low-frequency low-voltage alternating current or low-voltage direct current output by the power conversion module 4 to flow into the lighting bus 8.

The specifications of the first inductor 61 and the second inductor 62 are selected according to the carrier frequency and the power supply power of the lighting bus 8, for example, when the carrier frequency is 400K to 500K, the power supply power of the lighting bus 8 is 500W, the low-voltage direct-current voltage output by the power conversion module 4 is DC48V, the specifications of the first inductor 61 and the second inductor 62 are preferably 220uH/20A, and a sendust core is adopted.

In some embodiments, the low voltage power supply line 5 and the lighting bus 8 are both a two-core bus, wherein for purposes of differential display, the low voltage power supply line 5 is the first two-core bus and the lighting bus 8 is the second two-core bus.

With continued reference to fig. 4, the control module 7 includes a bluetooth module 71, a wireless communication module 72, an MCU73, a clock module 74, a PLC (power line communication) transmission module 75, and a power conversion module 76.

The power conversion module 76 is connected to the low voltage power supply line 5, and is used for further converting the low voltage power outputted from the power conversion module 4 into a suitable operating voltage suitable for the internal circuit of the control module 7, such as DC12V and DC 5V. The Bluetooth module 71 is used for realizing the communication between the MCU73 and the intelligent mobile terminal APP11, the wireless communication module 72 is used for realizing the communication between the MCU73 and the wireless remote controller 12, and the clock module 74 is used for providing clock information to the MCU 73.

Preferably, the Bluetooth module 71 is an STB1132-25/STB1132-25C available from Shimadu technologies, Inc. in Shenzhen City.

Preferably, the wireless communication module 72 and the wireless remote controller 12 used therewith are implemented by using the WRT8012 suite available from wilter electronics limited, shenzhen city.

Preferably, the clock module 74 is implemented by using an integrated circuit chip PCF85163 manufactured by NXP corporation of the netherlands and peripheral components thereof.

Preferably, the power conversion module 76 is implemented by using an integrated circuit chip TPS54360 manufactured by the american TI corporation and its peripheral devices.

A PLC (power line communication) transmission module 75 is connected to the MCU73 and also to the lighting bus 8. The PLC transmission module 75 is used for modulating the serial command frame output by the MCU73 onto a carrier wave, and then transmitting the modulated serial command frame to the lighting bus 8 for receiving by the single lamp 9 connected in parallel to the lighting bus 8.

Preferably, the PLC transmitting module 75 is implemented by using an integrated circuit chip LW580 manufactured by shenzhen lagrangian electronics ltd and peripheral components thereof.

The lighting bus 8 is connected with the low-voltage power supply line 5 through the filter module 6, receives the low-voltage electric energy output by the power conversion module 4, and transmits the low-voltage electric energy to the single lamp 9 connected with the lighting bus 8, and the lighting bus 8 is simultaneously connected with the PLC sending module 75 in the control module 7, receives the carrier signal output by the PLC sending module, and also transmits the carrier signal to the single lamp 9 connected with the PLC sending module.

The intelligent combined lamp comprises a plurality of (1 to n) single lamps 9, referring to fig. 5, the single lamp 9 is installed in a lamp 10, and the lamp 10 comprises a lamp holder 101 and a lampshade 102. The lamp base 101 may be screw-type, such as E14, E27, E40, bayonet-type, such as B15, B22, or plug-type, such as G8, G9, MR16, MR11, GU 10. All three of the above types of sockets have two electrical contacts to make two electrical connections, so that a single lamp 9 in the fixture 10 can be electrically connected to the two-wire lighting bus 8 outside the fixture 10 through the socket 101.

With continued reference to fig. 5, the single lamp 9 includes a PLC receiving module 91, an MCU92, a light source driving module 93, a light source 94, a filtering module 95, a power conversion module 96, and a lamp holder 97 matched with the lamp holder 101, and when the single lamp 9 is installed in the light fixture 10, the PLC receiving module 91 and the filtering module 95 in the single lamp 9 are electrically connected to the lighting bus 8 through the cooperation of the lamp holder 97 and the lamp holder 101.

The filtering module 95 is a low-pass filter, which functions in the same manner as the filtering module 6, and functions to prevent the high-frequency carrier signal input from the lighting bus 8 from being consumed by the power conversion module 96 and to allow low-frequency low-voltage power to flow into the power conversion module 96. The power conversion module 96 further converts the low-voltage electric energy output by the lighting bus 8 into the voltage required by the work of the internal circuit of the single lamp 9, the PLC receiving module 91 demodulates the serial command frame modulated in the carrier signal and transmits the demodulated serial command frame to the MCU92, and the MCU92 controls the light source driving module 93 according to the content of the serial command frame, thereby controlling the light source 94 to emit the corresponding luminous flux.

In some embodiments, to distinguish between displays, the filtering module 95 is a first filtering module, the filtering module 6 is a second filtering module, the MCU92 is a first controller, and the MCU73 is a second controller. Power conversion module 96 is a first power conversion module, power conversion module 4 is a second power conversion module, and power conversion module 76 is a third power conversion module.

In some embodiments, the PLC receiving module 91 is implemented by using an integrated circuit chip LW570 manufactured by shenzhen lagrangian electronics ltd and peripheral mating components thereof.

The beneficial technical effect of this embodiment is:

the two-core lighting bus 8 plays a dual role of electric energy transmission and control signal (carrier signal) transmission at the same time, can be matched and connected with E14, E27, E40, G8, G9, B15, B22, MR16, MR11 and GU10 standard lamp holders and lamp caps which provide two paths of electric connection, and transmits electric energy and control signals to the intelligent lamps installed in the lamp, so that the application range of the intelligent lighting system is wider, and the intelligent lighting system is beneficial to replacement and update installation and application.

The high-voltage alternating current commercial power is converted into low-voltage alternating current or low-voltage direct current by the power conversion module 4, and then is transmitted to the illumination bus 8 to be provided for the single lamp, and most circuits of the whole illumination system are powered by low-voltage electric energy, so that the possibility of personal injury caused by electric leakage is reduced, and the safety is improved.

The low voltage supplies power to the single lamp, the complexity of the power conversion module 96 in the single lamp is reduced, the overall size of the single lamp is reduced, and the cost is reduced.

Referring to fig. 6, an embodiment of the invention provides a lamp of a decorative ceiling lamp. The ceiling lamp 30 is composed of a ceiling mounting plate 301, a lampshade and lamp holder 302 and a lamp post support 303. In this embodiment, the ceiling mounting plate 301 is attached to a ceiling 304 of an illumination space, the ceiling mounting plate 301 is connected and fixed to a plurality of lamp covers and lamp sockets 302 through a lamp post holder 303, and the lamp post holder 303 is formed by combining hollow metal tubes or tubes made of other materials.

The power conversion module 4, the filtering module 6, the control module 7 and the low-voltage power supply circuit 5 of the intelligent combined lamp system 100 are installed in a ceiling-mounted mounting plate 301, the lighting bus 8 is arranged in an inner cavity of a lamp post bracket 303, and the single lamp 9 is installed in a lampshade and a lamp holder 302.

The intelligent combined lamp has the advantages that the existing decorative ceiling lamp is various in types, different in shape and huge in holding amount, and the intelligent combined lamp can be installed in the existing decorative ceiling lamp for use on the premise of not changing the structure of the existing lamp, so that the intelligent combined lamp is convenient for newer and replaceable lighting application.

Referring to fig. 7, an embodiment of the present invention provides an intelligent combination lamp control method, which is applied to an intelligent combination lamp system, and the intelligent combination lamp control method 200 includes:

step 201: establishing communication connection with external equipment through a Bluetooth module and/or a wireless communication module, and acquiring a control instruction sent by the external equipment;

in the embodiment of the present invention, the external device may be an intelligent mobile terminal APP or a wireless remote controller, and may send a control instruction to the control module, where the control instruction includes data such as an address of the controlled single lamp, a setting parameter of the controlled single lamp, and a luminous flux of the controlled single lamp.

Step 202: and controlling the single lamp to execute corresponding actions according to the control instruction so as to control the state of the single lamp.

The control module generates a corresponding serial instruction data frame according to the control instruction, the serial instruction data frame is sent to the lighting bus in a carrier signal mode through the PLC sending module, the PLC receiving module in the single lamp receives, demodulates and recovers the serial instruction data frame, the single lamp executes corresponding actions according to the content of the received serial instruction data frame, and various control functions of the control module on the single lamp are achieved.

Therefore, the intelligent combined lamp control method can realize various control functions of the single lamp, and the single lamp can realize various running states.

In this embodiment, an intelligent combination lamp control method is adopted to control an intelligent combination lamp, specifically:

in this embodiment, the control function is realized by issuing, transmitting, receiving, analyzing and executing a serial command frame. The intelligent mobile terminal APP11 and the wireless remote controller 12 send control instructions, the control module 7 receives and forwards serial instruction frames or performs corresponding actions, the serial instruction frames can also be sent independently, and the single lamp 9 receives the serial instruction frames and performs corresponding actions according to the contents of the serial instruction frames.

Each individual lamp 9 is programmed with an address and the address values are stored in a non-volatile memory of the MCU92 for reading or rewriting by software in the MCU 92. The address value is composed of an illumination area number, a grouping number and a single lamp number. Preferably, the number of the illumination area ranges from 0 to 31, and occupies 5 bits; the value range of the packet number is 0-31, and the packet number occupies 5 bits; the single lamp number is 0-63, and occupies 6 bits; the whole address value takes 16 bits, 2 bytes.

The serial command frame contains a frame ID to define the function of the serial command frame.

The serial instruction frame comprises check bytes, and the receiving end judges the correctness of the received serial instruction frame according to the check bytes, so that misoperation is avoided.

The serial instruction frame contains the address of the target controlled device, and is only valid for the controlled device with the address meeting the preset rule.

The single lamp 9, as a controlled device, responds only to serial command frames containing target addresses that comply with a predetermined rule.

To achieve flexibility of control, certain specific addresses are defined in the present embodiment as global addresses, which are valid not only for a single lamp, but for a group of lamps.

Preferably, when the number of the illumination area included in the instruction frame is the first preset value, it indicates that the instruction frame is valid for all the areas. In the embodiment of the present invention, the first preset value may be 31.

Preferably, when the packet number included in the instruction frame is the second preset value, it indicates that the instruction frame is valid for all packets. In the embodiment of the present invention, the second preset value may be 31.

Preferably, when the single lamp number included in the command frame is a third preset value, the command frame is indicated to be valid for all the single lamps. In the embodiment of the present invention, the third preset value may be 63.

After the controlled equipment receives the serial command frame, firstly checking the correctness of data transmission according to the check bytes in the serial command frame, checking whether the address is valid for the controlled equipment on the premise of determining the correctness of the data transmission, identifying the frame ID on the premise of valid address, and then carrying out corresponding action.

The beneficial technical effect of this embodiment is that the addresses of the lamps are divided into illumination area numbers, group numbers and single lamp numbers, and global addresses for the areas, the groups and the single lamps are respectively defined, so that the control of the single lamps can be more flexibly realized, for example, the setting and switching of illumination scenes can be implemented for the areas or the groups, one lamp can be controlled when one instruction contains a single address, or a group of lamps can be controlled when the instruction contains a global address, thereby greatly improving the control efficiency.

The serial command frame is divided into the following functions: an addressing frame, a luminous flux setting frame, a scene switching frame, a light-on instruction frame and a light-off instruction frame.

The addressed frame contains a frame ID, a lighting area number, a packet number, a single light number, and check bytes.

The luminous flux setting frame includes a frame ID, an illumination area number, a group number, a single light number, a red luminous flux value, a green luminous flux value, a blue luminous flux value, a warm white luminous flux value, a cold white luminous flux value, an ultraviolet luminous flux value, and a check byte.

The scene setting frame includes a frame ID, an illumination area number, a packet number, a single light number, a scene number, and a check byte.

The scene switching frame includes a frame ID, an illumination area number, a packet number, a single light number, a scene number, and a check byte.

The lighting instruction frame includes a frame ID, an illumination area number, a packet number, a single light number, and a check byte.

The light-off instruction frame includes a frame ID, an illumination area number, a packet number, a single light number, and a check byte.

In some embodiments, a dedicated APP (application software) is installed in the mobile terminal to enable control of the intelligent combination lamp. The APP comprises interfaces such as addressing operation, color temperature operation, slide bar operation, scene setting, timing task setting, time setting and control.

The mobile terminal is a mobile phone installed with an android operating system or an IOS operating system, such as a smart phone of a brand name or an apple brand name. In some embodiments, the mobile terminal may also be a tablet computer, a notebook computer, an iPad, or other user equipment.

If the mobile terminal is a smart phone, after an operator opens an APP11 installed in the smart phone, the Bluetooth searching function of the APP11 is started firstly, a Bluetooth searching interface of the APP lists searched Bluetooth equipment, when an ID number of a Bluetooth module 71 is found in the list, the Bluetooth equipment is clicked, the smart phone is connected with the Bluetooth module 71, then the smart phone APP11 and an MCU73 can establish communication through a Bluetooth link, and at this time, the intelligent combination lamp can be controlled through the operation of the APP 11.

When the bluetooth link is interrupted due to some reason (for example, the smartphone is carried out from the coverage of the bluetooth signal), the bluetooth connection refresh key on the APP11 may be triggered to reestablish the connection.

Referring to fig. 8, an addressing interface 13 of a mobile terminal APP according to an embodiment of the present invention includes, as shown in fig. 8, an illumination area number selection box 131, a group number selection box 132, a single light number selection box 133, and an addressing button 134, where an operator slides the selection box up and down with a hand pointing, and the candidate numbers also roll up and down, and the numbers rolled into between two horizontal lines are selected. Selecting lighting area number in the selection box 131, selecting grouping number in the selection box 132, selecting single lamp number in the selection box 133, and then triggering the addressing key 134, at this time, the APP11 adds frame ID and check byte to the selected area number, grouping number and single lamp number, and composes an addressing instruction, and sends the addressing instruction to the bluetooth module 71 through the bluetooth link, and then sends the addressing instruction to the PLC sending module 75 through the MCU73 in the form of addressing frame, and further forwards the addressing instruction to the lighting bus 8 in the form of carrier signal,

the single lamp 9 connected to the lighting bus 8 generates addressing action after receiving the addressing frame, takes out the lighting area number, the group number and the single lamp number from the addressing frame as the address of the single lamp, and then enters a certain characteristic state, for example, emitting 10% green light or white light, to prompt the operator to successfully address.

Further, the addressing interface 13 includes a light-on button 135 and a light-off button 136. After addressing is completed, an operator triggers the light-on key 135, the APP11 sends a light-on instruction grouped by the current lighting area number, the group number and the single light number, the single light 9 with the same address under the normal condition is lighted, the operator triggers the light-off key 136, the APP11 sends a light-off instruction, and the single light is turned off to prompt the operator that the address of the single light is effective.

It should be noted that when the APP11 issues an addressing command, all the individual lamps 9 connected to the lighting bus 8 will be addressed to the same address. To avoid the programming of different individual lamps to the same address, it is necessary that only one individual lamp 9 is connected to the lighting bus 8 for each addressing, that another individual lamp 9 is replaced after one addressing and that a further addressing is carried out, unless the aim is to program a plurality of individual lamps 9 to the same address, that a plurality of lamps are not connected to the bus 8 for one addressing.

Referring to fig. 9, an embodiment of the present invention provides a color operation interface of a mobile terminal APP, as shown in fig. 9, a color operation interface 14 of an APP11 for controlling a single lamp including red, green and blue light sources. The color operation interface 14 includes a single lamp selection box 141, where the operator can select the target single lamp number by sliding the finger up and down, the selection range is 0-63, and the selection 63 represents the simultaneous selection of all the single lamps in the same group.

The color operating interface 14 further includes a color ring 142 that continuously displays red, green, and blue (RGB) gradations from single red (R-255, G-0, and B-0), to single green (R-0, G-255, and B-0), and to single blue (R-0, G-0, and B-255). When the finger of the operator slides on the color matching ring 142, the color of the finger contact point will be synchronously displayed on the circular color block 143 in the middle of the color matching ring, the APP11 combines the red, green and blue component values of the color selected at the current time (i.e. the color of the color block 143), the current single light number, the default illumination area number, the default grouping number, and the corresponding frame ID and check bit into a light flux setting instruction at a small time interval, such as 0.05 second, and sends the light flux setting instruction to the control module 7 through the bluetooth link, the control module 7 further converts the light flux setting frame into a light flux setting frame, and forwards the light flux setting frame to the illumination bus 8 in the form of a carrier signal, and the light flux setting frame is received by the single light 9 connected to the illumination bus 8, and the MCU92 of the single light 9 receives the light flux setting frame from the illumination bus 8 through the PLC receiving module 91 and then generates a corresponding action under the condition that, The luminous flux values of the green light and the blue light generate corresponding luminous flux control signals, such as PWM signals, to control the light source driving module 93, and further drive the light source 94 to emit corresponding luminous fluxes.

Further, the color operating interface 14 may further include a fast color setting key 144, where the fast color setting key 144 includes 7 keys of red, yellow, green, lake blue, purple, white, and black, when an operator clicks one of the keys, the circular color block 143 becomes a corresponding color, and the APP11 sends a luminous flux setting instruction of the color to control the corresponding single lamp 9 connected to the lighting bus 8 to change to emit the light of the color.

Further, the color operation interface 14 may further include a brightness adjustment slider 145, where the brightness adjustment slider 145 displays a gradually changing color from the brightest right to the darkest left of the currently selected color (i.e., the color displayed by the circular color block 143), when the finger of the operator slides on the brightness adjustment slider 145, the color of the finger contact point will be synchronously displayed on the circular color block 143, and at the same time, the APP11 issues a luminous flux setting instruction including a red, green, and blue (RGB) component of the color, and controls the corresponding single lamp 9 connected to the lighting bus 8 to be changed to emit light of the corresponding color and brightness.

Further, the color operation interface 14 also includes a light-off key 146, and when the operator touches the key, the APP11 issues a light-off command. The light-off instruction is transmitted to the control module 7 through the bluetooth link, and then is converted into a light-off instruction frame by the control module 7, and further is transmitted to the lighting bus 8 in the form of a carrier signal, and is received by the single lamp 9 connected to the lighting bus 8, the PLC receiving module 91 in the single lamp 9 receives, demodulates and forwards the demodulated signal to the MCU92, and the MCU92 generates a corresponding action under the condition of address matching, that is, the current light flux values of various colors of light are stored, and then the light flux of the light source 94 is set to 0, that is, the light is turned off.

Further, the color operation interface 14 further includes a light-on key 147, and when the operator touches the key, the APP11 gives a light-on instruction. The light-on instruction is transmitted to the control module 7 through the Bluetooth link, and then is converted into a light-on instruction frame by the control module 7, and further is transmitted to the illumination bus 8 in the form of a carrier signal and is received by the single lamp 9 connected to the illumination bus 8. The PLC receiving module 91 in the single lamp 9 receives the carrier signal of the light-on command frame, demodulates the carrier signal, and sends the demodulated carrier signal to the MCU92, and the MCU92 generates a corresponding action in the case of address matching, and takes out the luminous flux values of the various color lights stored before turning off the lamp to generate a corresponding luminous flux control signal, such as a PWM signal, to control the light source 94 to emit a corresponding luminous flux, that is, turn on the lamp.

Referring to fig. 10, an embodiment of the present invention provides a color temperature operation interface of a mobile terminal APP, where the color temperature operation interface 15 of the APP11 is used to control a single lamp including a warm white light source and a cold white light source.

The color temperature operation interface 15 includes a single lamp number selection box 151, where an operator can select a target single lamp number by sliding a finger up and down, the selection range is 0-63, and the selection 63 is to simultaneously select all the single lamps in the same group.

The color temperature operation interface 15 includes a color temperature tone ring 152, and the color temperature tone ring 152 continuously displays a gradual color temperature from 6000K to 3000K. When the finger of the operator slides on the color temperature color mixing ring 152, the color of the finger contact point will be synchronously displayed on the circular color block 153 in the middle of the color mixing ring, the APP11 will combine the warm white light and cold white light components of the color temperature (i.e. the color of the color block 153) selected at the current moment, the current single lamp number, the default lighting area number, the group number, the corresponding frame ID and the check bit into a light flux setting command at a small time interval, and send to the control module 7 through the bluetooth link, and then the control module 7 will convert the light flux setting command into a light flux setting frame, and further send to the single lamp 9 connected on the lighting bus 8 in the form of carrier signal, after the MCU92 of the single lamp 9 receives the light flux setting frame from the lighting bus 8 through the PLC receiving module 91, first check whether the frame is wrong in the transmission process according to the check byte carried by the frame, if no error occurs, the frame type is determined according to the frame ID carried by the frame, and under the condition of address matching, the light flux values of warm white light and cold white light are taken out from the frame, so as to generate corresponding light flux control signals, such as PWM signals, to control the light source driving module 93, and further drive the light source 94 to emit corresponding light flux.

Further, the color temperature operation interface 15 may further include a fast color temperature setting key 154, where the fast color temperature setting key 154 includes 6000K, 5500K, 5000K, 4500K, 4000K, 3500K, 3000K, and black 8 keys, when an operator points one of the keys, the circular color block 153 changes to a color corresponding to the color temperature, and the APP11 sends a light flux setting instruction of the color temperature, so as to control the corresponding single lamp 9 connected to the lighting bus 8 to change to emit light of the corresponding color temperature.

Further, the color temperature operation interface 15 may further include a brightness adjustment slider 155, where the brightness adjustment slider 155 displays a gradient color from the brightest right to the darkest left of the currently selected color temperature (i.e., the color temperature displayed by the color block 153), when the finger of the operator slides on the brightness adjustment slider 155, the color temperature of the finger contact point will be synchronously displayed on the circular color block 153 in the middle of the color matching ring, and at the same time, the APP11 issues a luminous flux setting instruction corresponding to the color temperature and the brightness, and controls the corresponding single lamp 9 connected to the lighting bus 8 to be switched to emit light corresponding to the color temperature and the brightness.

Further, the color temperature operation interface 15 further includes a light-off key 156, when the operator touches the light-off key 156, the APP11 sends a light-off instruction, the light-off instruction is transmitted to the control module 7 through the bluetooth link, and then is converted into a light-off instruction frame by the control module 7, and then is forwarded to the lighting bus 8 in the form of a carrier signal, and is received by the single lamp 9 connected to the lighting bus 8, and a corresponding action is generated under the condition of address matching, that is, the current light flux values of the light of each color of the light itself are stored, and then the light flux of the light source 94 is set to 0, that is, the light is turned off.

Further, the color temperature operation interface 15 further includes a light-on key 157, and when the operator touches the key, the APP11 issues a light-on instruction. The light-on instruction is transmitted to the control module 7 through the bluetooth link, is converted into a light-on instruction frame by the control module 7, is forwarded to the lighting bus 8 in the form of a carrier signal, is received and demodulated by the PLC receiving module 91 in the single lamp 9 connected to the lighting bus 8, and is then transmitted to the MCU92, and generates a corresponding action under the condition of address matching, that is, the light flux values of the various color lights stored before turning off the lamp are taken out, and generates a corresponding light flux control signal, such as a PWM signal, to control the light source 94 to emit a corresponding light flux, that is, to turn on the lamp.

Referring to fig. 11, an embodiment of the present invention provides a slide bar operation interface of a mobile terminal APP, where a slide bar control interface 16 of the APP11 precisely controls luminous fluxes of 5 light sources of red, green, blue, cool white, and warm white in a single lamp 9 in a manner that a luminous flux is adjusted by a slide bar.

The slider control interface 16 includes a single light selection box 161 where the operator can select the target single light number by sliding up and down, the selection range is 0-63, and the selection 63 is the simultaneous selection of all single lights in the same group.

The slide control interface 16 includes a red slide 162, a green slide 163, a blue slide 164, a cool white slide 165, and a warm white slide 166, and the operator can adjust the luminous fluxes of red light, green light, blue light, cool white light, and warm white light of the selected single lamp 9 in sequence. When the operator presses the slider button and slides left and right, APP11 will synchronously acquire the value represented by the current slider button position, and the value is used as the corresponding color value to be sent to control module 7 through the Bluetooth link, and the value is converted into a luminous flux setting frame by control module 7, and then forwarded to lighting bus 8 in the form of carrier signals, and the single lamp 9 corresponding to the address is controlled to emit synchronously-changed light.

Further, the slider control interface 16 includes a display character 167 for synchronously displaying the amount of the luminous flux output corresponding to the color light of the single lamp 9 according to the sliding position of the slider button, where the amount of the luminous flux is indirectly expressed by a gray scale level, the gray scale level is from 0 to 255, 0 represents the minimum luminous flux (full black), and 255 represents the maximum luminous flux, and provides reference contrast data for the operator, thereby realizing accurate dimming.

Further, the slide bar control interface 16 further includes a light-off key 168, when the operator touches the light-off key 168 with a finger, the APP11 sends a light-off command, the light-off command is transmitted to the control module 7 through the bluetooth link, and is converted into a light-off command frame by the control module 7, and is forwarded to the lighting bus 8 in the form of a carrier signal, and is received by the single lamp 9 connected to the lighting bus 8, and generates a corresponding action in the case of address matching, that is, current light flux values of various colors of light are stored, and then the light flux of the light source 94 is set to 0, that is, the light is turned off.

Further, a light-on key 169 is included on the slider control interface 16, and when the operator touches the key, the APP11 issues a light-on command. The light-on command is transmitted to the control module 7 through the bluetooth link, and then converted into a light-on command frame by the control module 7, and then forwarded to the lighting bus 8 in the form of a carrier signal, and received by the single lamp 9 connected to the lighting bus 8, and a corresponding action is generated under the condition of address matching, that is, the luminous flux values of various color lights stored before the lamp is turned off are taken out, and a corresponding luminous flux control signal, such as a PWM signal, is generated to control the light source 94 to emit a corresponding luminous flux, that is, to turn on the lamp.

Referring to fig. 12, an embodiment of the present invention provides a scene setting interface of a mobile terminal APP, as shown in fig. 12, the APP11 includes a setting scene dialog box 17.

Further, the color operation interface 14 includes a join scene key 148, the color temperature operation interface 15 includes a join scene key 158, and the slider control interface 16 includes a join scene key 1610, and when the operator touches any one of the 3 keys, the APP11 pops up the set scene dialog 17. The setting scene dialog box 17 comprises a radio box 171 and a confirmation key 172 of a scene list, when an operator selects a certain scene in the scene list, the confirmation key 172 is pressed again, the dialog box 17 exits, and simultaneously the APP11 sends out a scene setting instruction, the scene setting instruction is transmitted to the control module 7 through the bluetooth link, and is converted into a scene setting instruction frame by the control module 7, and the scene setting instruction frame is forwarded to the lighting bus 8 in the form of a carrier signal, so that the current states of all the single lamps 9 are set as the selected scene.

In this embodiment, the individual scene parameters will be permanently stored in the MCU92 in the single lamp 9. The scene parameters include a scene number and light flux values corresponding to lights of various colors in each scene, and when the control module 7 sends a scene switching frame, the single lamp 9 involved may simultaneously take out the light flux values of the lights of various colors corresponding to the scene according to the scene number specified by the scene switching frame, and set the light source 94 to send out the corresponding light flux to complete the scene switching.

Referring to fig. 13, an embodiment of the present invention provides a timing task interface of a mobile terminal APP. As shown in fig. 13, the timed task setting interface 18 of the APP11 includes a mobile terminal time display box 181, a combination lamp time display box 182, a time setting key 183, a combination lamp time viewing key 184, a timed task display box 185, a timed task viewing key 186, and a timed task on/off key 187.

The combination lamp time should be set to be synchronized with the standard time before the timing task is set. In this embodiment, the default mobile terminal time is the standard time (when the operator finds that the mobile terminal time is different from the standard time, the system time of the mobile terminal should be adjusted to be consistent with the standard time first), the mobile terminal time display frame 181 of the timed task setting interface 18 displays the current standard time, when the operator triggers the view button 184, the APP11 sends a time query instruction to the control module 7, when the MCU73 in the control module 7 receives the time query instruction, that is, the current clock information of the read clock module 74 is transmitted to the APP11, and the APP11 displays the received time information on the time display frame 182 of the combination lamp of the timed task setting interface 18.

The time setting can be started when the operator finds that the combined lamp time is deviated from the mobile terminal time (the default is the standard time). The operator touches the time setting button 183, APP11 sends a time setting instruction to the control module 7, the time setting instruction includes current standard time information, and after the MCU73 receives the time setting instruction, the time information is taken out to set the clock module 74, thereby realizing time synchronization between the combination lamp and the mobile terminal.

By "timed task", it is meant that when the combined lamp runs to a predetermined date (week, hour, minute), the combined lamp will automatically execute the predetermined task, and the predetermined task has three modes: switch to standard lighting, switch to a specified program (identified by program number), switch to a specified scene (identified by scene number)

In the timed task display box 185, the timed task parameters are displayed, including the effective week, the effective time, and the task. In the present embodiment, there are a maximum of 8 timed tasks, so there are 8 timed task bars from top to bottom in the timed task setting interface 18.

Referring to fig. 14, an embodiment of the present invention provides a timing setting operation interface of a mobile terminal APP, as shown in fig. 14, a timing setting interface 19 of a timing task includes a "week" check box 191, a "time" check box 192, a "point" check box 193, a task mode check box 194, a scene number/program number check box 195, a "complete" button 196, and a "cancel" button 197.

When the operator wants to perform a timed task setting, the timed task box 185 is touched, at which time the APP11 pops up the timed setting interface 19,

the operator selects the timing task in the week check box 191 that the day of the week is valid, and the selection range is from Monday, Tuesday to Sunday, and can be selected more, even selected completely;

the operator selects a timed task in the hours radio box 192 for several hours to be active, with a selection range from 0 to 23;

the operator selects the timing task fraction valid in the fraction box 193, the selection range is from 0 to 59;

the operator selects the timed task mode in mode radio box 194, with the selection ranges: standard lighting, programs, scenes;

when the operator selects a scene and a program in the mode radio box 194, a scene number or a program number may be further selected in the scene/program number selection box 195;

when the operator has finished selecting the week, time and mode, he presses the finish key 196, the selection parameters of the timed task will be saved by the APP11, the timed setting interface 19 exits, and the above selection parameters are simultaneously displayed in the corresponding timed task bar of the interface 18. The APP11 groups the timed task parameters into a timed task setting command, and sends the timed task setting command to the MCU73 in the control module 7 through the bluetooth link, where the timed task parameters included in the timed task setting command are stored in a timed task list in software of the MCU73 and executed, and the timed task list is stored in a nonvolatile register. When the operator presses the cancel key 197, the timing setting interface 19 exits, the timing task parameters will not be saved, nor will the APP11 send timing task setting instructions.

With continued reference to fig. 13, when the operator triggers the view button 186 for a certain timing task, the APP11 will send a timing task query instruction to the control module 7, and after receiving the timing task query instruction, the MCU73 will send back the parameters of the timing task, which are held in its nonvolatile register, to the APP11, and the APP11 will be stored and displayed in the timing task bar 185.

When the operator presses the start/stop key 187 for a timed task, the timed task will toggle between start and stop. APP11 will send an instruction to MCU73 in control module 7 to start or close the timed task. The MCU73 will start or close the timed task depending on the content of the instruction. The characters on the on/off button 187 are synchronized to indicate whether the timed task is currently on or off.

Referring to fig. 15, an embodiment of the present invention provides a control interface of a mobile terminal APP, as shown in fig. 15, a control interface 20 of an APP11 includes a light-on key 201, a light-off key 202, a standard illumination key 203, a scene switching key 204, a program switching key 205, a scene hot key 206, a current mode display frame 207 of an intelligent combination lamp, a bluetooth search key 208, a bluetooth ID display frame 209, and a bluetooth connection refresh key 2010.

When the operator presses the light-on key 201, the APP11 will issue a light-on command (group number 31, single light number 63) that is valid for all single lights 9 in all groups in a certain lighting area, and then all single lights 9 connected to the lighting bus 8 start the light-on action, i.e. resume the light flux before turning off the lights.

When the operator presses the light-off key 202, the APP11 will issue a light-off command (group number 31, single light number 63) that all the single lights 9 in all the groups in a certain lighting area are valid, at this time, all the single lights 9 connected to the lighting bus 8 start the light-off action, that is, save the current value of the luminous flux of each light source, and then set each light source to have a luminous flux of 0, that is, turn off the light.

When an operator presses the standard illumination key 203, the APP11 sends a scene switching instruction (group number 31, single lamp number 63) for switching all the single lamps 9 in all the groups in a certain illumination area into a special scene, i.e., a standard illumination scene, where the standard illumination state is a preset state before the single lamps 9 leave a factory, and in this state, a more ideal illumination effect can be achieved, for example, the single lamp 9 emits white light with a color temperature of 4000K, a color rendering index of 90, and a maximum luminous flux in this state.

The scene switching key 204 includes two keys "↓" and "↓", where "↓" represents switching of a scene upward by a scene number, and "↓" represents switching of a scene downward by a scene number. And after the scene is switched upwards to the scene with the maximum scene number, switching to the scene with the minimum scene number. And switching to the scene with the maximum scene number after switching the scene to the scene with the minimum scene number downwards. The program switching key 205 includes two keys of "→" and "←", the "→" representing switching of a program up by program number, and the "←" representing switching of a program down by program number. And after the program is switched to the program with the maximum program number upwards, the program with the minimum program number is switched to. And switching to the program with the maximum program number after switching the program number to the program with the minimum program number downwards.

The lighting program of the intelligent combination lamp is a visual effect generated by continuous dynamic change of the color or brightness of light emitted by the plurality of single lamps 9, and is realized by the MCU73 in the control module 7 transmitting continuous luminous flux setting frames with content relevance according to a certain time interval. In this embodiment, a plurality of sets of light programs are prestored in the MCU73 of the control module 7, and the operator sends a program switching instruction frame to activate and switch the playing of the program through the APP11 or the wireless remote controller 12.

The scene keys 206 include S1, S2, S3, S4 and S55 keys, which represent 5 commonly used hot scenes, and the corresponding scene numbers are scene 1, scene 2, scene 3, scene 4 and scene 5, respectively, and the operator should store the most commonly used scenes in the 5 scene numbers. When the operator touches one of the scene keys 206, APP11 will send a scene switch instruction corresponding to the scene number, switching all the single lamps 9 connected to the lighting bus 8 directly to that scene.

The current mode (lighting, scene, program) and scene/program number of the combination light system are displayed in the combination light's current mode display box 207.

Referring to fig. 16, in the embodiment of the present invention, in order to further improve convenience of control, a scheme for controlling the combination lamp by using a wireless remote controller 12 is provided in addition to a mobile terminal APP 11. The wireless remote controller 12 also includes a light-on key, a light-off key, a scene switching key, a program switching key, a standard lighting mode setting key, and scene setting hot keys of S1, S2, S3, S4, and S5. The function key setting of the wireless remote controller is the same as the function key setting of the interface 20, and the icon and the position of the same function key are the same, so that the wireless remote controller 12 and the APP11 can be switched to use by an operator without a learning process and any obstacle.

The indicator light 121 is arranged on the wireless remote controller 12, and when the wireless remote controller is used for the first time, the wireless remote controller 12 and the control module 7 are firstly paired. The pairing method is that when the control module 7 is powered on and the state is normal, the light-off key 122 and the standard illumination setting key 123 are pressed simultaneously, when the indicator light 121 flashes, pairing is successful, and then pairing is not needed when the remote controller 12 is used again, and direct operation can be performed.

The beneficial technical effect of this embodiment is that although the control function of the mobile terminal APP11 is strong and perfect, bluetooth connection is performed before use, and the lighting device in public places belongs to public facilities, and the mobile terminal which is expensive and is used as a private article in most cases is lack of convenience for control. The wireless remote controller is low in cost and can be used as a public article, the wireless remote controller 12 is adopted as the supplement of the mobile terminal APP11, and the main and common core control function is achieved, so that the control means of the intelligent combined lamp is complete, and the functions, the cost and the convenience are balanced.

In this embodiment, the control interface 20 of APP11, and the last program number or scene number (standard lighting is a special scene) of the standard lighting setting, program switching, scene switching operation of the wireless remote controller 12 will be permanently saved by the MCU73 in the control module 7. When the intelligent combined lamp system is powered down and then powered up, for example, the power switch 3 is turned off and then turned on, the MCU73 will restore the saved program or scene before the power down.

In summary, in the embodiments of the present invention, the control module receives and analyzes the instruction sent by the external device, generates the related serial instruction data frame, and transmits the serial instruction data frame to the single lamp in the form of a carrier signal, and the PLC receiving module of the single lamp receives and demodulates the serial instruction data frame, so that the single lamp executes the corresponding action, and controls the state of the single lamp, so that the intelligent combination lamp has the functions of single lamp control, coordinated control, dimming, color and color tuning, color and temperature tuning, scene setting, scene switching, dynamic light program, timing automatic control, and the like, and also has the advantages of high efficiency, energy saving, safety, and environmental protection.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; within the idea of the invention, also technical features in the above embodiments or in different embodiments may be combined, steps may be implemented in any order, and there are many other variations of the different aspects of the invention as described above, which are not provided in detail for the sake of brevity; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (25)

1. A single lamp housed in a light fixture, the light fixture including a socket that establishes two electrical connections between the single lamp and an external circuit, the single lamp comprising:

a light source;

the light source driving module is connected with the light source and used for driving the light source;

the lamp holder is matched and connected with the lamp holder;

the PLC receiving module is electrically connected with the external circuit through the matching of the lamp holder and is used for receiving a carrier signal input by the external circuit;

the first power supply conversion module is electrically connected with the external circuit through the matching of the lamp holder and is used for receiving low-voltage electric energy input by the external circuit and converting the low-voltage electric energy into electric energy with proper voltage; and

and the first controller is respectively connected with the PLC receiving module and the light source driving module and is used for controlling the state of the light source according to the carrier signal.

2. The single lamp of claim 1, further comprising:

and the first filtering module is respectively connected with the PLC receiving module and the first power conversion module and is used for blocking the loss of the carrier signal contained in the low-voltage electric energy.

3. The single lamp of claim 1, wherein the lamp base and the lamp head are in compliance with any one of E14, E27, E40, G8, G9, B15, B22, MR16, MR11, and GU10 standards.

4. An intelligent combination lamp system, comprising:

the second power supply conversion module is connected with an external alternating current power supply loop and used for converting the external alternating current power supply into low-voltage electric energy;

the two-core bus is connected with the second power supply conversion module and used for transmitting electric energy signals and carrier signals;

a plurality of single lamps according to any one of claims 1 to 3, connected to the two-core bus, for receiving the power and the carrier signal, and performing corresponding actions according to the carrier signal;

the control module is connected with the two-core bus and used for sending the carrier signal to control the state of the single lamp;

the intelligent mobile terminal APP is used for sending a first control instruction to the control module; and

and the wireless remote controller is used for sending a second control instruction to the control module.

5. The intelligent combination lamp system of claim 4, wherein the two-core bus comprises a first two-core bus and a second two-core bus, the first two-core bus is connected to the second power conversion module and the control module respectively, and is configured to receive the low-voltage power output by the second power conversion module;

the second two-core bus is respectively connected with the control module and the single lamp and used for receiving the carrier signal output by the control module and transmitting the carrier signal to the single lamp.

6. The intelligent combination lamp system of claim 5, wherein the control module comprises:

the Bluetooth module and/or the wireless communication module are used for receiving an external instruction;

the second controller is respectively connected with the Bluetooth module and/or the wireless communication module and is used for outputting serial instruction data frames according to the external instruction;

the PLC sending module is respectively connected with the second controller and the second two-core bus, and is used for modulating the serial instruction data frame to the carrier signal and outputting the carrier signal to the second two-core bus; and

and the clock module is connected with the second controller and used for providing real-time clock information for the second controller and receiving the setting of the second controller.

7. The intelligent combination lamp system of claim 6, further comprising: and the second filtering module is connected between the first two-core bus and the second two-core bus in series and is used for allowing the low-voltage electric energy to pass and preventing the carrier signal from passing.

8. The intelligent combination lamp system of claim 7,

the second power supply conversion module, the control module, the second filtering module and the first two-core bus are accommodated in a ceiling mounting disc of the decorative ceiling lamp;

the second two-core bus is accommodated in the hollow lamp post bracket of the decorative ceiling lamp;

the single lamp is contained in the lamp of the decorative pendant lamp.

9. An intelligent combined lamp control method is applied to an intelligent combined lamp system, and is characterized by comprising the following steps:

establishing communication connection with external equipment through a Bluetooth module and/or a wireless communication module, and acquiring a control instruction sent by the external equipment;

and controlling the single lamp to execute corresponding actions according to the control instruction so as to control the state of the single lamp.

10. The intelligent combination lamp control method according to claim 9, wherein the controlling the single lamp to perform the corresponding action according to the control instruction to control the single lamp state comprises:

generating a serial instruction data frame according to the control instruction, wherein the serial instruction data frame comprises an addressing frame, a luminous flux setting frame, a scene switching frame, a light-on instruction frame and a light-off instruction frame, so that a PLC (programmable logic controller) sending module generates a carrier signal according to the serial instruction data frame;

and controlling the single lamp to execute corresponding actions according to the carrier signal so as to control the state of the single lamp.

11. The intelligent combination lamp control method of claim 10, wherein the serial command data frame comprises:

frame ID, check byte, and single lamp address.

12. The intelligent combination lamp control method of claim 11, wherein the single lamp address is composed of an illumination area number, a group number, a single lamp number.

13. The intelligent combination lamp control method of claim 12,

if the number of the illumination area is a first preset value, the serial instruction data frame is effective to the single lamps in all the illumination areas;

if the packet number is a second preset value, the serial command data frame is valid for all the grouped single lamps;

and if the single lamp number is a third preset value, the serial instruction data frame is effective to all the single lamps.

14. The intelligent combination lamp control method of claim 13, further comprising:

acquiring an addressing instruction sent by a mobile terminal APP;

generating the addressing frame according to the addressing instruction, wherein the addressing frame carries an address;

and sending the addressing frame to a single lamp in a carrier wave mode so that the single lamp takes the address carried by the addressing frame as the address of the single lamp.

15. The intelligent combination lamp control method of claim 14, further comprising:

acquiring a luminous flux setting instruction sent by the mobile terminal APP;

generating the luminous flux setting frame according to the luminous flux setting instruction, wherein the luminous flux setting frame carries a luminous flux value;

and sending the luminous flux setting frame to the single lamp in a carrier wave mode, so that the single lamp with the same address takes out the luminous flux value in the luminous flux setting frame and sets the luminous flux corresponding to the light source to send out according to the luminous flux value.

16. The intelligent combination lamp control method of claim 15, further comprising:

acquiring a scene setting instruction sent by the mobile terminal APP;

generating the scene setting frame according to the scene setting instruction, wherein the scene setting frame comprises a target scene number;

and sending the scene setting frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address sets the current state as the parameter of the target scene corresponding to the target scene number and permanently stores the parameter.

17. The intelligent combination lamp control method of claim 16, further comprising:

acquiring a scene switching instruction sent by the mobile terminal APP or the wireless remote controller;

generating the scene switching frame according to the scene switching instruction, wherein the scene switching frame comprises a target scene number;

and sending the scene switching frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address takes out corresponding permanently stored scene parameters according to the target scene number for setting the self state to restore the scene.

18. The intelligent combination lamp control method of claim 17, further comprising:

acquiring a light turning-off instruction sent by the mobile terminal APP or the wireless remote controller;

generating the light-off instruction frame according to the light-off instruction;

and sending the light-off instruction frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address stores the current luminous flux value, and the luminous flux of the light source is set to be 0, thereby realizing the light-off.

19. The intelligent combination lamp control method of claim 18, further comprising:

acquiring a light-on instruction sent by the mobile terminal APP or the wireless remote controller;

generating the light-on instruction frame according to the light-on instruction;

and sending the light-on instruction frame to the single lamp in a carrier wave mode, so that the single lamp with the consistent address takes out the luminous flux value stored when the lamp is turned off for setting the luminous flux of the light source, and the light-on is realized.

20. The intelligent combination lamp control method of claim 19, further comprising:

presetting one or more light programs;

and sending the luminous flux setting frames with relevance to the continuous and content of one or more single lamps to the single lamps at certain time intervals to realize the lamp light program.

21. The intelligent combination lamp control method of claim 20, further comprising:

acquiring a program switching instruction sent by the mobile terminal APP or the wireless remote controller;

and playing the corresponding program according to the program switching instruction.

22. The intelligent combination lamp control method of claim 21,

and the icons of the function keys of the wireless remote controller are consistent with the icons of the function keys with the same functions on the APP page of the mobile terminal.

23. The intelligent combination lamp control method of claim 20, further comprising:

after the program switching instruction and the scene switching instruction are executed, permanently storing a program number or a scene number;

and when the intelligent combined lamp system is powered off and is powered on again, restoring the intelligent combined lamp system to the program or the scene before the power failure according to the program number or the scene number which is stored finally.

24. The intelligent combination lamp control method of claim 23, further comprising:

acquiring a time setting instruction which is sent by the mobile terminal APP and contains the current system time of the mobile terminal APP, wherein the time setting instruction comprises time data;

and setting the time of a clock module according to the time data in the time setting instruction so as to synchronize the time of the intelligent combined lamp system and the time of the mobile terminal.

25. An intelligent combination lamp control method according to claims 14-24, wherein the method further comprises:

acquiring the timing task setting instruction sent by the mobile terminal APP, wherein the timing task setting instruction comprises timing task parameters;

and permanently storing and executing the timing task parameters.

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