CN117677002A - Cross-platform control system and method for visualization of lamplight interaction information - Google Patents

Abstract

The invention discloses a cross-platform control system and a cross-platform control method for light interaction information visualization, wherein the system comprises a lamp, a judging module, a functional module, a color module, a power module and an operation interface display module; s1, after a lamp is connected, identifying whether the lamp has a number; if yes, determining the target lamplight according to the number and entering step S2; if not, the number is set for the lamp and then the step S2 is carried out; s2, judging the type of the lamp; if the light is a double-color white light, the step S4a is carried out, and if the light is RGB or more multi-color light, the step S3 is carried out; s3, selecting a light emitting mode of the lamp, and if the first light emitting mode is selected, entering a step S4a; if the second light emitting mode is selected, entering a step S4b; s4a, adjusting parameters of a two-color white light source; and S4b, adjusting parameters of the color light source. The control system provided by the invention has the functions of direct control, no function identification obstacle in vision and real-time and real-field control of light.

Description

Cross-platform control system and method for visualization of lamplight interaction information

Technical Field

The invention belongs to the field of light control systems, and particularly relates to a cross-platform control system and method for visualizing light interaction information.

Background

In recent years, with the rapid development of the video industry and the great improvement of 5G network speed, video presentation becomes an indispensable information propagation means. Various application scenes promote the complicated requirements of light application from simple to complex, however, in the aspect of controlling the lights, particularly in the scene of simultaneous application of multiple lights, confusion of a control field caused by light effect setting is always difficult to avoid. Some lamps can only be adjusted on the lamps, some lamps can be adjusted by remote control, some lamps can be controlled by wireless lamps, but the visual logic on the control platform panels is not consistent. For the same function, it is one selection method for adjusting on the lamp, another selection method for adjusting by a remote controller, and a different selection method for adjusting on the mobile terminal app. That is, on the single-light control panel, on the remote controller panel, on the mobile terminal app, and then on the DMX light cluster console, the same function corresponds to four different key positions and application interfaces, so that the user often suffers from visual logic conversion when switching different adjustment methods, and the regularity, the rapidity and the accuracy during use are seriously disturbed.

In addition, most of the information interaction between the control platform and the lamplight is unidirectional: the platform can send out the instruction to the lamp body, change light, however the current parameter of the unable real-time synchronous light of platform. If the light is adjusted in other ways at this time, the mind of the user is undoubtedly disturbed.

The patent number CN201910958781.8 discloses a visual light control system and a visual light control method, which can collect on-site light effect video data and visualize the light effect video data. However, the lamplight visualization of the patent cannot be displayed and controlled across platforms.

Disclosure of Invention

The invention aims to provide a cross-platform control system and a cross-platform control method for visualization of lamplight interaction information, which have the functions of direct control in visual sense, no function identification obstacle in visual sense and real-time and real-field lamplight control.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows:

a cross-platform control system for visualizing lamplight interaction information comprises a lamp, a judging module, a functional module, a color module, a power module and an operation interface display module;

the judging module is used for identifying and judging the number, the model and the light source of the lamp after the lamp is connected;

the functional module comprises a light coding sub-module and a light effect mode sub-module, and the light coding sub-module numbers the lamps again; the light effect mode submodule is used for controlling the lamp to emit various types of light effects and numbering the lamp again;

the color module is used for adjusting the color, the color temperature and the tone of the lamplight emitted by the lamp;

the power module is used for changing the lamplight color of the lamp into a designated color and a designated color temperature and also used for changing the lamplight brightness of the lamp;

the operation interface display module is used for displaying the judging module, the functional module, the color module and the power module as operation interfaces;

the cross-platform control system further comprises a plurality of operation platforms, and each operation platform comprises the operation interface.

According to the cross-platform control system for the visualization of the lamplight interaction information, after a lamp is connected, the number and the model of the lamp are identified through the judging module, whether the lamp is a dual-color white light source or a color light source is automatically judged, and corresponding functions in the functional module, the color module and the power module are awakened; and a plurality of operation platforms are set to be the same operation interface, the operation interfaces are unified, the interface for calling the functions is concise and efficient, and the page does not need to be switched repeatedly.

Preferably, the cross-platform control system further comprises an interaction module and a memory module; the interaction module and the memory module are both arranged in the lamp; the interaction module comprises a lamp body control sub-module, a remote control sub-module and a cluster control sub-module, and the plurality of operation platforms are communicated with the lamps through the lamp body control sub-module, the remote control sub-module and the cluster control sub-module; the memory module is used for memorizing the lamplight parameters of the lamp.

Preferably, the functional module, the color module and the power module are sequentially arranged on the operation interface; the functional module, the color module and the power module all comprise a plurality of control items; the operation platform is provided with an operation module for operating the plurality of control items.

Preferably, the power module comprises a light color chip sub-module and a light brightness sub-module; the photochromic sub-module is used for setting various color parameters; the lamplight brightness submodule is used for adjusting the power of the lamp; the operation module is used for operating the light color sub-module and the light brightness sub-module; the operation module is positioned at one side of the operation interface; the operation module is a knob or a tab.

Preferably, the operation platform comprises a selection module and an amplifying module; the selection module is used for selecting any item in a plurality of control items; the amplifying module is used for amplifying the control items selected by the selecting module.

Preferably, the operation platform further comprises a parameter display module; the parameter display module is used for displaying the lamplight parameters contained in the control items amplified by the amplifying module; the operation platform further comprises an error touch prevention module; the anti-false touch module is used for shielding unselected control items when the control items are selected by the selection module.

Preferably, the operation platform further comprises a storage module; the storage module is used for storing the operation process of the operation module.

Preferably, the power module is further used for changing the power state of the lamp and displaying; the power supply state of the lamp comprises an alternating current power supply state, a direct current power supply state and a simultaneous alternating current charging state of direct current power supply; the lamp is powered by direct current while the power in the alternating current charging state is at least ten times that in the direct current power state.

Preferably, the lamp model comprises a double-color white light lamp and a multi-color lamp of RGB and above; the light-emitting mode of the dual-color white light lamp comprises a first light-emitting mode; the light-emitting modes of the RGB and above multi-color lamps comprise a first light-emitting mode and a second light-emitting mode; the first light emitting mode comprises a bicolor white light source; the second light emitting mode includes a color light source.

The invention also provides a cross-platform control method for the visualization of the lamplight interaction information, which is applied to the cross-platform control system for the visualization of the lamplight interaction information; the cross-platform control method comprises the following steps:

s1, after a lamp is connected, identifying whether the lamp has a number; if yes, determining the target lamplight according to the number and entering step S2; if not, the number is set for the lamp and then the step S2 is carried out;

s2, judging the type of the lamp; if the light is a double-color white light, the step S4a is carried out, and if the light is RGB or more multi-color light, the step S3 is carried out;

s3, selecting a light emitting mode of the lamp, and if the first light emitting mode is selected, entering a step S4a; if the second light emitting mode is selected, entering a step S4b;

s4a, adjusting parameters of a two-color white light source;

and S4b, adjusting parameters of the color light source.

The beneficial effects are that:

the system is characterized in that a judgment module is used for identifying the number and the model of a lamp after the lamp is connected, automatically judging whether the lamp is a double-color white light source or a color light source, waking up corresponding functions in a functional module, a color module and a power module, and realizing the control of the lamp by combining the method; and a plurality of operation platforms are set to be the same operation interface, the operation interfaces are unified, the interface for calling the functions is concise and efficient, and the page does not need to be switched repeatedly.

Drawings

FIG. 1 is a block diagram showing a cross-platform control system for visualizing light interaction information according to a first embodiment;

FIG. 2 is a single lamp control logic diagram of a cross-platform control system for visualizing light interaction information according to the first embodiment;

FIG. 3 is a schematic diagram of an operation interface of a cross-platform control system for visualizing light interaction information according to the first embodiment;

FIG. 4 is a flow chart of a cross-platform control method for visualizing light interaction information according to the second embodiment;

fig. 5 is a control timing diagram of a cross-platform control method for visualizing lamplight interaction information according to the second embodiment.

Reference numerals

100. An operation interface of the lamp body screen display; 200. an operation interface displayed on a remote controller screen; 300. an operation interface of the mobile phone terminal app; 400. and (3) an operation interface of the tablet terminal app.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will explain the specific embodiments of the present invention with reference to the accompanying drawings. It is evident that the drawings in the following description are only examples of the invention, from which other drawings and other embodiments can be obtained by a person skilled in the art without inventive effort.

The technical scheme of the invention is described in detail in the following by specific embodiments.

Example 1

As shown in fig. 1 to 3, the present embodiment provides a cross-platform control system for visualizing lamplight interaction information, which includes a lamp, a judging module, a functional module, a color module, a power module, and an operation interface display module;

the judging module is used for identifying and judging the number, the model and the light source of the lamp after the lamp is connected;

the functional module comprises a light coding sub-module and a light effect mode sub-module, and the light coding sub-module numbers the lamps again; the light effect mode submodule is used for controlling the lamp to emit various types of light effects and numbering the lamp again;

the color module is used for adjusting the color, the color temperature and the tone of the lamplight emitted by the lamp;

the power module is used for changing the lamplight color of the lamp into a designated color and a designated color temperature and also used for changing the lamplight brightness of the lamp;

the operation interface display module is used for displaying the judging module, the functional module, the color module and the power module as operation interfaces;

the cross-platform control system also includes a plurality of operating platforms, each operating platform including an operating interface.

Preferably, the cross-platform control system further comprises an interaction module and a memory module; the interaction module and the memory module are both arranged in the lamp; the interaction module comprises a lamp body control sub-module, a remote control sub-module and a cluster control sub-module, and a plurality of operation platforms are communicated with the lamps through the lamp body control sub-module, the remote control sub-module and the cluster control sub-module; the memory module is used for memorizing the lamplight parameters of the lamp.

Preferably, the functional module, the color module and the power module are sequentially arranged on the operation interface; the functional module, the color module and the power module all comprise a plurality of control items; the operation platform is provided with an operation module for operating the plurality of control items.

Preferably, the power module comprises a light color sub-module and a light brightness sub-module; the photochromic sub-module is used for setting various color parameters; the lamplight brightness submodule is used for adjusting the power of the lamp; the operation module is used for operating the light color sub-module and the light brightness sub-module; the operation module is positioned at one side of the operation interface; the operation module is a knob or a tab.

Preferably, the operation platform comprises a selection module and an amplifying module; the selection module is used for selecting any item in a plurality of control items; the amplifying module is used for amplifying the control items selected by the selecting module.

Preferably, the operation platform further comprises a parameter display module; the parameter display module is used for displaying the lamplight parameters contained in the control items amplified by the amplifying module.

Preferably, the operation platform further comprises an error touch prevention module; the anti-false touch module is used for shielding unselected control items when the selection module selects the control items.

Preferably, the operation platform further comprises a storage module; the storage module is used for storing the operation process of the operation module.

Preferably, the power module is further configured to change a power state of the lamp and display the changed power state.

Preferably, the power state of the lamp comprises an alternating current power supply state, a direct current power supply state, and a simultaneous alternating current charging state of the direct current power supply; the lamp is powered by dc power while the ac charging state is at least ten times as powerful as the dc power state.

Preferably, the lamp type includes a double-color white light lamp and a multi-color lamp of RGB or above; the light-emitting mode of the dual-color white light lamp includes a first light-emitting mode; the light emitting modes of the RGB and above multi-color lamps include a first light emitting mode and a second light emitting mode; the first light emitting mode comprises a bicolor white light source; the second light emitting mode includes a color light source.

Specifically, light of the multi-color lamps of RGB and above includes RGB, RGBW, RGBWW, RGBALC; when the light is RGBALC, the color light source is a light combination algorithm LED lamp with six primary colors of RGBALC, and the six primary colors are red, green, blue, amber, lemon yellow and cyan respectively.

Specifically, the functional module of the embodiment includes a function adjusting key, the color module includes a color adjusting key, and the power module includes a power adjusting key; and the function adjusting key, the color adjusting key and the power adjusting key can be physical keys or virtual keys. When the function adjusting key, the color adjusting key and the power adjusting key are virtual keys, the selected item is enlarged when the light mode and the light number are selected, and the selected item is highlighted when other items are selected.

Specifically, in the cross-platform control system for visualizing lamplight interaction information in this embodiment, after a lamp is connected, the number and the model of the lamp are identified through a judging module, whether the lamp is a dual-color white light source or a color light source is automatically judged, and corresponding functions in a functional module, a color module and a power module are awakened; and the system has an account login function, a user can register and login the account, and the stored light setting or the stored light setting in the imported account can be directly used.

Specifically, the functional module of the embodiment includes a light coding sub-module and a light effect mode sub-module. When the judging module judges the target lamplight, the lamplight coding sub-module can renumber the target lamplight, and when a plurality of lamplights are used for shooting, different lamplights can be distinguished according to the number. The light effect mode submodule has 9 light effects of firework, lightning, damaged bulb, television, pulse, flashing light, stroboscopic light, explosion and flame, and the light effects are hidden and gradually dimly illuminated, different parameters and instructions are built in, and the selected target light can simulate corresponding effects by itself.

Specifically, the color module of the embodiment is used for adjusting the color of the lamplight. If the target lamplight is a double-color white light source, the color temperature of the white light can be adjusted in the color module; if the target lamp light is a color light source, the color form to be presented can be selected in the color module, and then the color phase or the white color temperature of the multi-color lamp with RGB and above can be further adjusted.

Specifically, the power module of the embodiment includes a light color sub-module and a light brightness sub-module. The light color sub-module is internally provided with a plurality of fixed color parameters, and the target light is changed into the color immediately after the selection. The function can also be used for directly shooting or selecting a picture, clicking any position on the picture, and enabling the target lamplight to display the color at the position. The light brightness submodule function directly adjusts the brightness of the light by changing the power of the light. In addition, the power module also has the power state of the icon representation target lamplight, and the power state is divided into 3 types: an alternating current power supply state, a direct current power supply state, and a simultaneous alternating current charging state of direct current power supply.

Further, the power module of the embodiment adjusts the photoelectric color saturation of the lamplight by controlling the lamplight power; when the power of the target lamplight is changed from small to large, not only the brightness of the light is increased, but also the color saturation is correspondingly increased. When the color module is used for regulating and controlling the target lamplight, the power module is started at the same time, so that the adjustment of the hue, brightness and saturation of the target lamplight is realized.

Furthermore, when the light effect mode submodule of the functional module controls the light to emit flame light effect, the number of the light, the column where the number is located and various parameters of the column can be seen on an operation interface; at this time, the multi-color lamps of RGB and above are made to show orange color, and the power supply state is the state of charging with alternating current while supplying power with direct current, and output with 100% power. When the functional module controls the lamplight to emit explosion light effect, the double-color white light is used, the color temperature is 2800K, the power supply state is the direct current power supply state, and the power is output at 10%. If the user logs in the account, the parameter settings can be saved through a saving module, so that quick setting and calling are realized.

Specifically, the multiple operation platforms in the embodiment are a lamp body screen display, a remote controller screen display, a mobile phone end app and a tablet end app, are set to be the same operation interface, and are characterized by being visualized and flattened by taking 'horizontal and vertical' as a design principle; the operation interfaces are unified, the interfaces for calling the functions are concise and efficient, the pages do not need to be switched repeatedly, and the functions are set to only need to go through two-level pages at most. And the tablet terminal app is tiled and unfolded on the same screen due to the fact that the tablet terminal app has more visible space, multiple lamps can be controlled simultaneously, and operation time is further saved.

Specifically, as shown in fig. 3, in this embodiment, four operation interfaces of a lamp body screen display, a remote controller screen display, a mobile phone end app and a tablet end app are divided into 3 areas according to corresponding functions of a function module, a color module and a power module, and are arranged in sequence, and adjustment of target light is also performed in the arrangement sequence.

Further, on the lamp body screen display and the remote controller screen display, a secondary knob is arranged on one side of the panel; and the label tabs are arranged on the same side of the panel on the mobile phone end app and the tablet end app and are used for operating a plurality of control items contained in the functional module, the color module and the power module.

Further, an operation interface of the lamp body screen display and the remote controller screen display is adjusted through the secondary knob. The knob is turned to select a function module, adjust a corresponding parameter, which is a first-stage operation, and the knob is pressed to enter an option, confirm the selected parameter and return, which is a second-stage operation. On the mobile phone end app and the tablet end app, the corresponding function or option can be selected by touching the tag tab, and different parameters can be adjusted by sliding the pull rod. The control gesture principle used by the two types of platforms is similar, and the universal use habit is met. The method comprises the following steps: selecting a light coding or light efficiency mode in the functional module, a double-color white light or RGB (red, green and blue) color light mode in the color module and color paper or illumination brightness adjustment in the power module through a secondary knob or tag tab; and are both visual click choices.

Further, the light coding sub-module is taken as an example of light numbering. If the user sets on the lamp body or uses the remote controller to set, firstly, the knob on one side of the functional module is turned to the left to enter the function, the area where the module is located is lightened, the amplified number appears in the option bar, the knob is turned left and right to select the desired number, finally, the knob is pressed down, and the system confirms the light number and automatically returns to the previous page. If the user sets through the mobile phone end or the tablet end app, firstly clicking the tag tab of the function module at the upper right side of the operation interface, then sliding the amplified number for selection, and then tapping the tab after the selection to determine the number of the lamplight.

Specifically, in this embodiment, by the selection module, the amplifying module, and the parameter display module, when a certain module is selected by the selection module, the options (light number, light mode, color temperature bar, hue circle, saturation bar) of the module will be amplified and highlighted. For example, when the color temperature of a certain double-color white light lamp is set, the color temperature strip is unfolded and lightened, and meanwhile, the color temperature value is displayed below the color temperature strip, so that accurate parameter regulation is achieved.

Further, when the bicolor white light is adjusted, through the anti-false touch module, when a certain module is adjusted, the content of the module is lightened, and an irrelevant module or option is displayed in a gray non-adjustable state. For example, if the color of a double-color white light lamp is set, the uppermost functional module is displayed in gray, and the color module and the power module are simultaneously lightened, so that the hue and saturation of the color lamp can be adjusted at one time. When the RGB and above multi-color lamps are regulated, the uppermost button is a hue regulating button, the middle button is a saturation regulating button, and the lower button is a brightness regulating button.

Specifically, in the cross-platform control system with visualized lamplight interaction information, starting from the bottom logic used by the whole lamplight, the basic operation logic (single-lamp control logic is shown in fig. 2) of the lamplight control is set through the interaction module, lamplight parameters can be memorized, lamp body control, remote control and cluster control are realized, other devices are not required to be connected between lamplight and a control platform, information on the lamplight and the control platform is bidirectional, the platform can regulate and control lamplight parameters, and the lamplight parameters can be fed back to a page of each control platform in real time.

Example two

As shown in fig. 4 to 5, the present embodiment provides a cross-platform control method for visualizing light interaction information, which is applied to a cross-platform control system for visualizing light interaction information in the first embodiment, and the cross-platform control method includes the following steps:

s1, after a lamp is connected, identifying whether the lamp has a number; if yes, determining the target lamplight according to the number and entering step S2; if not, the number is set for the lamp and then the step S2 is carried out;

s2, judging the type of the lamp; if the light is a double-color white light, the step S4a is carried out, and if the light is RGB or more multi-color light, the step S3 is carried out;

s3, selecting a light emitting mode of the lamp, and if the first light emitting mode is selected, entering a step S4a; if the second light emitting mode is selected, entering a step S4b;

s4a, adjusting parameters of a two-color white light source;

and S4b, adjusting parameters of the color light source.

Specifically, the first light emission mode emits a bi-color white light; the second light emitting mode emits RGB dual color white light.

Specifically, if the target light identified in step S1 has already been saved by the saving module with respect to the light setting, the setting may be directly invoked. And in step S1, the light mode of the lamp can be selected by the functional module.

Further, in step S2, it is determined whether the lamp is a dual-color white light lamp or an RGB dual-color white light lamp; if the light is a double-color white light, the step S4a is performed, and if the light is an RGB double-color white light, the step S3 is performed. And in step S2, the color module may also select the light color of the lamp.

Further, in step S3, the lamp is selected to be in a dual-color white light mode or an RBG color lamp mode, and if the dual-color white light mode is selected, step S4a is entered; if the multi-color lamp mode of RGB or above is selected, the process proceeds to step S4b.

Further, the color temperature adjusting function is started and the power module adjusts the white color temperature and brightness of the lamp in the step S4a; in step S4b, the RGB color adjusting function and the power module are started to adjust the hue and saturation of the lamplight. And in the step S4b, the color piece paper can be selected through the light color piece sub-module of the functional module.

The embodiments of the cross-platform control system and the cross-platform control method for visualizing the lamplight interaction information provided by the invention are described in detail. The principles and embodiments of the present invention have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the core concepts of the invention. It should be noted that it will be apparent to those skilled in the art that the present invention may be modified and adapted without departing from the principles of the present invention, and that such modifications and adaptations are intended to be within the scope of the appended claims.

Claims (10)

1. The cross-platform control system for the visualization of the lamplight interaction information is characterized by comprising a lamp, a judging module, a functional module, a color module, a power module and an operation interface display module;

the judging module is used for identifying and judging the number, the model and the light source of the lamp after the lamp is connected;

the functional module comprises a light coding sub-module and a light effect mode sub-module, and the light coding sub-module numbers the lamps again; the light effect mode submodule is used for controlling the lamp to emit various types of light effects;

the color module is used for adjusting the color, the color temperature and the tone of the lamplight emitted by the lamp;

the power module is used for changing the lamplight color of the lamp into a designated color and a designated color temperature and also used for changing the lamplight brightness of the lamp;

the operation interface display module is used for displaying the judging module, the functional module, the color module and the power module as operation interfaces;

the cross-platform control system further comprises a plurality of operation platforms, and each operation platform comprises the operation interface.

2. The cross-platform control system of claim 1, further comprising an interaction module, a memory module; the interaction module and the memory module are both arranged in the lamp; the interaction module comprises a lamp body control sub-module, a remote control sub-module and a cluster control sub-module, and the plurality of operation platforms are communicated with the lamps through the lamp body control sub-module, the remote control sub-module and the cluster control sub-module; the memory module is used for memorizing the lamplight parameters of the lamp.

3. The cross-platform control system according to claim 1, wherein the functional module, the color module and the power module are sequentially arranged on the operation interface; the functional module, the color module and the power module all comprise a plurality of control items; the operation platform is provided with an operation module for operating the plurality of control items.

4. The cross-platform control system of claim 3, wherein the power module comprises a light color chip sub-module and a light brightness sub-module; the photochromic sub-module is used for setting various color parameters; the lamplight brightness submodule is used for adjusting the power of the lamp; the operation module is used for operating the light color sub-module and the light brightness sub-module; the operation module is positioned at one side of the operation interface; the operation module is a knob or a tab.

5. The cross-platform control system of claim 3, wherein the operating platform comprises a selection module and an amplification module; the selection module is used for selecting any item in a plurality of control items; the amplifying module is used for amplifying the control items selected by the selecting module.

6. The cross-platform control system of claim 5, wherein the operating platform further comprises a parameter display module; the parameter display module is used for displaying the lamplight parameters contained in the control items amplified by the amplifying module; the operation platform further comprises an error touch prevention module; the anti-false touch module is used for shielding unselected control items when the control items are selected by the selection module.

7. The cross-platform control system of claim 3, wherein the operating platform further comprises a save module; the storage module is used for storing the operation process of the operation module.

8. The cross-platform control system of claim 1, wherein the power module is further configured to change and display a power state of the lamp; the power supply state of the lamp comprises an alternating current power supply state, a direct current power supply state and a simultaneous alternating current charging state of direct current power supply; the lamp is powered by direct current while the power in the alternating current charging state is at least ten times that in the direct current power state.

9. The cross-platform control system according to any one of claims 1 to 8, wherein the lamp model includes a dual color white light lamp and a multi-color lamp of RGB and above; the light-emitting mode of the dual-color white light lamp comprises a first light-emitting mode; the light-emitting modes of the RGB and above multi-color lamps comprise a first light-emitting mode and a second light-emitting mode; the first light emitting mode comprises a bicolor white light source; the second light emitting mode includes a color light source.

10. The cross-platform control method for visualizing the lamplight interaction information is characterized by being applied to the cross-platform control system for visualizing the lamplight interaction information according to claim 9; the cross-platform control method comprises the following steps:

s1, after a lamp is connected, identifying whether the lamp has a number; if yes, determining the target lamplight according to the number and entering step S2; if not, the number is set for the lamp and then the step S2 is carried out;

s2, judging the type of the lamp; if the light is a double-color white light, the step S4a is carried out, and if the light is RGB or more multi-color light, the step S3 is carried out;

s3, selecting a light emitting mode of the lamp, and if the first light emitting mode is selected, entering a step S4a; if the second light emitting mode is selected, entering a step S4b;

s4a, adjusting parameters of a two-color white light source;

and S4b, adjusting parameters of the color light source.