CN117440583B - Indoor lighting lamp, lamp efficiency configuration method, device and equipment - Google Patents

Abstract

The application relates to an indoor lighting lamp, a lamp efficiency configuration method, a device and equipment, wherein the method comprises the following steps: acquiring a first light effect applicable to a first light group in the lamp; determining a second light effect applicable to a second lamp group in the lamp according to the light effect attribute data of the first light effect; and packaging the first light effect and the second light effect into light effect application data to be transmitted to the lamp. The lamp efficiency of a plurality of lamp groups is conveniently and efficiently configured by a user, the capability of the lamp for expanding the lamp groups can be released, the complexity of the lamp efficiency of the lamp configuration by the user is reduced, and the popularization of the indoor lighting lamp can be promoted.

Description

Indoor lighting lamp, lamp efficiency configuration method, device and equipment

Technical Field

The present disclosure relates to the field of lighting control, and in particular, to an indoor lighting device, a method, an apparatus and a device for configuring a lighting effect.

Background

Indoor lighting fixtures are typically relatively single in function, typically providing only a single color switching function. With the increasing demands of people for quality of life, mood light devices have grown. But the ambience light device typically only serves local space or serves some specific needs, such as an atmosphere for rendering a game scene or the like. The other scheme for meeting the demands of people is to add an atmosphere lamp on the original basis of the indoor lighting lamp, so that the indoor lighting lamp can also have the effect of rendering the light atmosphere.

As is well known, indoor lighting fixtures are typically ceiling mounted or wall mounted. The indoor lighting lamp is characterized in that the indoor lighting lamp is usually regulated through an entity control key on a wall, but the regulating effect which can be achieved by the entity control key is very limited, so that even if an atmosphere lamp is additionally arranged on the indoor lighting lamp, consumers still can be forgiving in terms of the using convenience of users, and the popularization of the improved indoor lighting lamp is not facilitated.

The atmosphere lamp device has more convenient function matching in the aspect of lamp effect control, but the atmosphere lamp device is usually realized by converting images or description information into corresponding lamp effect instructions according to a certain data source such as images or similar description information to control the atmosphere lamp to emit light through a computer program, so that the technology complexity is higher, and the atmosphere lamp device cannot be directly moved to the improved indoor lighting lamp for use.

In view of this, the applicant has made necessary searches for a lamp efficiency control technique of an indoor lighting device, which is adapted to the technical requirements of the indoor lighting device with an expanded atmosphere lamp function.

Disclosure of Invention

The application aims to provide an indoor lighting lamp, a lamp efficiency configuration method, a device and equipment.

According to one aspect of the present application, there is provided a light efficiency configuration method, including:

acquiring a first light effect applicable to a first light group in the lamp;

determining a second light effect applicable to a second lamp group in the lamp according to the light effect attribute data of the first light effect;

and packaging the first light effect and the second light effect into light effect application data to be transmitted to the lamp.

According to another aspect of the present application, there is provided a light efficiency configuration apparatus, including:

a first light effect acquisition module configured to acquire a first light effect applicable to a first light group in a lamp;

a second light effect determining module configured to determine a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect;

and the lamp effect transmission application module is used for packaging the first lamp effect and the second lamp effect into lamp effect application data and transmitting the lamp effect application data to the lamp.

According to another aspect of the application, there is provided an indoor lighting fixture, including a controller and a plurality of lamp groups, the controller is configured to receive lamp effect application data generated by the lamp effect configuration method, and control the plurality of lamp groups to play corresponding lamp effects according to the lamp effect application data.

According to another aspect of the present application, there is provided a computer device comprising a central processor and a memory, the central processor being adapted to invoke the steps of running a computer program stored in the memory to perform the light efficacy configuration method.

The present application has many advantages over the prior art, including but not limited to:

firstly, a plurality of lamp groups in a lamp, each lamp group can set corresponding lamp efficiency, in order to improve the lamp efficiency configuration efficiency, the lamp efficiency attribute data related to the first lamp efficiency are used for determining the second lamp efficiency corresponding to the other lamp group in the lamp based on the first lamp efficiency corresponding to one lamp group in the lamp, so that the second lamp efficiency can be generated according to the first lamp efficiency, including automatic generation or customized generation, thereby enabling the first lamp efficiency to play a role in providing guiding reference information for the generation of the second lamp efficiency, improving the generation efficiency of the second lamp efficiency, enabling the second lamp efficiency and the first lamp efficiency to keep a harmonious and harmonious relationship on the light atmosphere, comprehensively improving the configuration efficiency of the lamp efficiency, optimizing the use experience of the lamp, and enabling the lamp to be more popular.

Secondly, the method can enable each lamp group which is originally mutually decoupled and can be independently controlled in the lamp to realize the association control through the lamp effect data, even if the number of the lamp groups in the lamp is more, the technical scheme of the method can be used for determining the lamp effect based on the first lamp effect, and the lamp effect of each other lamp group is determined according to the lamp effect attribute data of the first lamp effect in a standardized mode, so that the lamp effect configuration of a plurality of lamp groups in the lamp is simpler, the complexity of the lamp effect configuration is effectively reduced, the capability of the lamp for expanding the lamp groups can be released, the overall cost of the lamp production link is reduced, and the user management universality of lamp products is greatly expanded because the method can unify the configuration modes of various lamps carrying different lamp groups.

In addition, the technical realization of the lamp effect association configuration among the lamp groups is simplified, so that the lamp is more suitable for being applied to indoor lighting fixtures with the lamp groups, particularly the indoor lighting fixtures comprising atmosphere lamps and illuminating lamps, the patterns of the lighting fixtures can be enriched, and the indoor lighting fixtures are easier to popularize.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic electrical schematic diagram of an exemplary luminaire of the present application;

fig. 2 is a flow chart of a light effect configuration method in an embodiment of the present application;

FIG. 3 is a flowchart illustrating a method for determining a second lighting effect according to a classification tag of the first lighting effect according to an embodiment of the present application;

fig. 4 is a schematic flow chart of determining a second lighting effect according to a scene tag of the first lighting effect and an emotion tag corresponding to audio data in the embodiment of the application;

FIG. 5 is a flowchart illustrating a method for determining a second light effect according to color data of the first light effect according to an embodiment of the present application;

FIG. 6 is a flowchart of determining a second light effect according to a dominant color of the first light effect according to an embodiment of the present application;

FIG. 7 is a flowchart of generating a light source layout view according to link description information to determine a first light effect and a second light effect according to an embodiment of the present application;

fig. 8 and fig. 9 are all exemplary light effect editing interfaces of the present application, respectively showing different links in a user configuration process, wherein fig. 8 shows that a user selects a single selectable color as a corresponding light emitting parameter, fig. 9 shows an effect after the user completes gradual change effect setting, the middle parts of the interfaces of fig. 8 and fig. 9 show a light source layout view, and an editing area is provided at the lower part of the interface for displaying an editable attribute item;

FIG. 10 is a schematic flow chart of previewing and applying lighting effects according to an embodiment of the present application;

FIG. 11 is a schematic structural diagram of a light effect configuration device according to an embodiment of the present application;

fig. 12 is a schematic structural diagram of a computer device in an embodiment of the present application.

Detailed Description

Referring to fig. 1, it can be seen that in a schematic structural diagram of an indoor lighting lamp provided in an embodiment of the present application, the indoor lighting lamp includes a controller and a plurality of lamp groups, wherein the lamp groups at least include a lamp group functioning as a lighting lamp and a lamp group functioning as an atmosphere lamp, the lamp group functioning as the lighting lamp may be referred to as a first lamp group or a main lamp group, and the lamp group functioning as the atmosphere lamp may be referred to as a second lamp group or a sub lamp group. The first lamp set generally comprises at least one light source node, and may also comprise a plurality of light source nodes; the second lamp set typically includes a plurality of light source nodes. The light source nodes in the first lamp group generally have higher working power, the lumen value of the light is also generally higher, the effect of illuminating a large-scale space can be achieved, the chromatic light can be configured relatively simply, and the total number of the light source nodes can be relatively smaller. The light source nodes in the second lamp group can be arranged at lower working power relative to the light sources of the first lamp group due to the function of filling point space atmosphere, and the total number of the light source nodes can be relatively more.

The controller in an indoor lighting fixture typically includes a control chip, a communication assembly, and a bus connector. The control Chip may be implemented by various embedded chips, such as a bluetooth SoC (System on Chip), a WiFi SoC, an MCU (Micro Controller Unit, a microcontroller), a DSP (Digital Signal Processing ), and the like, and generally includes a central processor and a memory, where the memory and the central processor are respectively used to store and execute program instructions to implement corresponding functions. The control chips of the above types can be used for communication components from the outside, and can be additionally configured according to the requirement. The communication component can be used for communicating with external equipment, for example, can communicate with terminal equipment such as a personal computer or various smart phones, so that after a user gives various configuration instructions through the terminal equipment, a control chip of the controller can receive the configuration instructions through the communication component to complete basic configuration so as to control the work of each lamp group. For example, the controller may receive the light effect application data of the present application through the communication component, for controlling each light group to play a corresponding light effect. The bus connector is mainly used for connecting a power supply to a lamp group connected to the bus and transmitting various data, so that pins corresponding to the power bus and the data bus are correspondingly provided. Therefore, when the lamp group needs to be connected with the controller, the lamp group is connected with the bus connector through the connector corresponding to the lamp group.

Each lamp group in the indoor lighting lamp can show various layout relations according to actual needs. The light source nodes of the first lamp group as illustrated in fig. 1 may be arranged in a central area of the indoor lighting fixture, and the light source nodes of the second lamp group are arranged around the central area, forming a concentric arrangement effect, so that the first lamp group in the central area may concentrate the radiated illumination light, and then the second lamp group around the central area renders a specific light atmosphere.

Each light group may be implemented with a light-emitting light strip, which is a light strip composed of one or more light source nodes. When there are multiple light source nodes in the light-emitting strip, the light source nodes are connected in sequence to define a light-emitting link. Of course, a lighting strip can also be considered to form a lighting link when there is only a single light source node. In any case, the same lighting link carries operating current from the same set of cables that access the bus. The light source nodes of the same light-emitting lamp strip with a plurality of light source nodes can be connected in parallel in the electrical connection relation.

Each light source node is typically constituted by a light emitting element, which may be an LED lamp, responsible for emitting different colors of light. Each light source node can be provided with a corresponding control chip as required, and the control chip can select the type according to the disclosure, or select other more economical control chips, and the function of the control chip is mainly that the control data corresponding to the light source node can be extracted from the light effect control data provided by the controller, so that each light emitting element in the light source node is controlled to emit corresponding chromatic light. Considering that the first lamp set and the second lamp set are respectively focused to play a role of lighting and atmosphere decoration, the light emitting element structure of the light source node in the first lamp set may be different from the light emitting element structure of the light source node in the second lamp set, for example, the light source node in the first lamp set may be a light emitting element containing light emitting light of cold color and/or warm color, and the light source in the second lamp set may be a light emitting element containing light emitting light of red, green, blue, white, and the like. Therefore, each lamp group can flexibly realize the electrical structure of the light source node according to different purposes, and the application of the inventive spirit is not affected.

When the indoor lighting lamp is powered on, the control chip of the controller can call and execute the computer program from the memory, the initialization flow defaulted by the computer program is used for powering on the indoor lighting lamp and realizing initialization, and driving configuration of each lamp group and other hardware devices is completed.

In one embodiment, when the indoor lighting fixture is started, the controller may first send a self-checking instruction to each lamp group, and drive the light source node of each lamp group to return the position information of the light source node in the light-emitting link. Because each light source node is provided with a corresponding control chip for carrying out data communication with the control chip in the controller, the characteristic information of the light source node and the characteristic information of other light source nodes can be serially connected in sequence according to a serial communication protocol, so that the representation of the position information of the light source node is realized. The serial communication protocol executed between the controller and the light source node may be any one of IIC (Inter-Integrated Circuit, integrated circuit bus), SPI (serial peripheral interface ), UART (Universal Asynchronous Receiver-Transmitter, universal asynchronous receiver/Transmitter). After the controller obtains the result data returned by the self-check of each light source node from the bus, the result data is analyzed, the position of each light source node in the luminous link corresponding to the whole lamp group can be determined according to the sequence of the characteristic information of each light source node in the result data, and the follow-up controller can generate the control data corresponding to each light source node according to the position information of each light source node when constructing the light effect control data according to the light effect application data.

For each light group, the position information of each light source node indicates the corresponding connection relation information of each light source node, and the link description information corresponding to the luminous link of the light group can be formed, and can be stored in the controller or transmitted to external equipment for use, for example, the terminal equipment of the application can generate a light source layout view by utilizing the link description information corresponding to each light group in the indoor lighting lamp.

It should be noted that when there are more than two lamp groups in the lamp, one of all the lamp groups can be used as the first lamp group, and each other lamp group is used as the second lamp group, and according to the configuration method of the present application, a corresponding lamp effect is configured for each second lamp group, so that the lamp is not limited by the number of the lamp groups, and the technical scheme of the present application can be applied to realize the lamp effect configuration.

According to the product architecture and the working principle of the indoor lighting lamp, the lamp efficiency configuration method can be implemented as a computer program product, run in any terminal equipment and realize lamp efficiency configuration and application through communication between the terminal equipment and a controller of the indoor lighting lamp.

Referring to fig. 2, in one embodiment, the light efficiency configuration method of the present application operates in a terminal device adapted to be communicatively connected to an indoor lighting fixture of the present application, and includes:

step S5100, obtaining a first light effect applicable to a first light group in the lamp;

the exemplary lamp can be an indoor lighting lamp, is suitable for being installed indoors in a ceiling type or wall hanging type, mainly plays a role in lighting, has a function of rendering indoor light atmosphere, and can be used by a user according to the needs. The luminaire comprises a plurality of lamp groups, for example two lamp groups, a first lamp group and a second lamp group, or primary lamp group or secondary lamp group, as examples. Wherein the first lamp group has a small number of light source nodes, e.g. 1 to 3 such light source nodes; the second lamp group has a relatively large number of a plurality of light source nodes, for example 10 to 20 light source nodes. The light source nodes in the first light group may be responsible for selectively emitting cool or warm light, as they mainly serve as illumination, and such light source nodes may comprise only light emitting elements emitting yellow and white light, which are set to emit one color light, which corresponds to the setting of their corresponding light effect, i.e. the first light effect. The light source nodes in the second lamp group can preferably be light source nodes capable of emitting various desired colored lights by mixing the light emitting elements corresponding to the primary colors such as red, green, blue, etc., and thus the second light effect corresponding to the second lamp group can be determined by setting the color matching ratio of the various primary colors for each light source node. Of course, the light source node in the first lamp group can also be implemented by selecting the same light source node as the second lamp group, even can adopt the same or similar structure as the second lamp group, and can be reasonably configured according to the cost and the function requirement.

The light effect of the first light group in the lamp can be standardized and set when leaving the factory or providing the template, or can be preset by a user, namely, the first light effect is suitable for the first light group and is suitable for controlling the first light group to play the corresponding light effect, and when the first light effect is used for determining the second light effect, the set light effect is finished. For example, in one embodiment, when the lamp leaves the factory, the controller of the lamp writes the first light effect corresponding to the first light group in advance, or when the user needs to determine the second light effect for the lamp in the terminal device, the light effect template corresponding to the lamp is called, and the first light effect corresponding to the first light group of the lamp is prestored in the light effect template. In another embodiment, the user may simply set the first light effect corresponding to the first light group, for example, adjust the first light group to be cool light or warm light through a control key of the lamp to set the corresponding first light effect, or set the first light effect by the user by opening a first light effect setting function of the first light group to the user in the terminal device. Therefore, the acquisition mode of the first light effect is flexible and various, and can be realized as required.

The manner in which the lamp obtains the first light effect may also be implemented flexibly, for example, in one embodiment, when the controller has set the first light effect corresponding to the first light group, the terminal device may request the controller to obtain the first light effect through a communication link between the terminal device and the controller of the lamp; in another embodiment, the terminal device pre-stores the lamp effect application data of the lamp history application, so that the first lamp effect suitable for the first lamp group of the lamp can be analyzed and determined from the lamp effect application data.

The light effects in the present application, including the first light effect and the second light effect, may be described in a standardized predetermined format to form corresponding light effect description data. The visual presentation effect of the light effect to which the light effect description data belongs is defined through a plurality of luminous parameters, and picture description data corresponding to a plurality of playing frames in the light effect playing process can be generated through analyzing and converting the light effect description data, so that light effect control data corresponding to each playing frame is generated. Business logic for performing the parsing conversion from light effect description data to light effect control data is typically implemented in a controller of a luminaire, and thus, the generated light effect description data may be packaged in a certain format and sent to the controller for parsing conversion and application. Of course, in some embodiments of the present application, the service logic for performing the parsing conversion from the light effect description data to the light effect control data by the terminal device is adapted to the requirement of displaying the corresponding light effect in the light source layout view of the terminal device, so as to apply the picture description data of each play frame to the light source layout view for displaying.

The lighting parameters used for defining the lighting effect in the present application are normalized according to the implementation effect of the lighting effect, and may include, for example, two color parameters, brightness parameters, etc. used for defining the gradual change effect, and may also include motion parameters, angle parameters, etc. used for defining the motion effect, which do not affect the implementation of the inventive spirit of the present application.

In some embodiments, a service link may be provided to enable a user to select one of the lamp groups of the lamp as the first lamp group, and a list of lamp groups corresponding to the lamp groups of the lamp is provided through a lamp effect editing interface, so that the user selects one of the lamp groups as the first lamp group to call the first lamp effect applicable to the first lamp group. Therefore, for the same lamp, the first lamp group is relatively set, any one lamp group in the lamp can be designated as the first lamp group, and the other lamp groups can be used as the second lamp group for lamp efficiency configuration.

Step S5200, determining a second light effect applicable to a second lamp group in the lamp according to the light effect attribute data of the first light effect;

Under the condition that the first light effect of the first light group of the lamp is set, the corresponding second light effect of the second light group can be determined by a plurality of pre-realized modes according to the light effect attribute data of the first light effect, so that the second light effect is matched with the first light effect to present the overall light effect, and the overall light effect can harmoniously create the sense aesthetic effect. The light effect attribute data of the first light effect, which is corresponding data for describing and defining the association of the first light effect, is usually preset or associated in the corresponding light effect description data, and may be selected according to practical situations, including but not limited to any one of classification tags, scene tags, emotion tags, color data, main colors determined according to the color data, and the like.

Regarding the relevance of the second light effect and the first light effect, the selection of the different light effect attribute data according to the first light effect can be embodied in multiple aspects, for example, between the second light effect and the first light effect, in some embodiments, the relevance corresponding relation can be established based on the emotion attributes corresponding to the atmosphere rendered by the light effects; in some embodiments, an associative correspondence may be established based on the scene for which the light effects are applicable to each other; in some embodiments, an associative correspondence may be established based on classification information predefined to each other; in some embodiments, the associative correspondence may be established based on the dominant hues of each other; in some embodiments, the second light effect may also be determined jointly by providing some light effect attribute data of the emotion attribute in combination with the first light effect via an external medium. And the association between the second light effect and the first light effect can be established, so that the method can be flexibly implemented. And are not exhaustive and are merely illustrative. In the process of determining the second light effect according to the first light effect, according to whether the man-machine interaction business link is introduced, the method can be expressed as a plurality of different embodiments, for example:

In some embodiments, the determining the second light effect of the second light group according to the first light effect may be performed by calling a preset light effect generation interface, and automatically generating by the light effect generation interface according to service logic preset by the corresponding second light group, where the whole process is implemented without human-computer interaction, so that the generation of the second light effect reaches the maximum efficiency.

In some embodiments, the process of determining the second light effect of the second light group according to the first light effect includes a man-machine interaction business link, the terminal device determines one or more candidate light effects according to the first light effect, presents the one or more candidate light effects to the user for selection, and then selects one of the candidate light effects as the second light effect by the user.

In some embodiments, the process of determining the second light effect of the second light group according to the first light effect includes a man-machine interaction business link, the terminal device determines a part of light emitting parameters to be set by a user according to the first light effect, and after the user sets each light emitting parameter, the terminal device constructs the second light effect according to a user setting result. The embodiment can not only promote the use experience of the user to obtain the target light effect expected by the user, but also refine the light effect customizing capability, so that the user can deeply participate in the customizing process of the second light effect, and a more exquisite customizing effect is obtained.

According to the disclosure, the implementation manner of determining the second light effect related to the first light effect is very flexible, but no matter what manner is adopted to determine the second light effect, the second light effect can be coordinated with the first light effect on the basis of reducing the customizing difficulty of the overall light effect of the lamp, and thus, the generated overall light effect can obtain a better exhibiting effect when being played in the lamp.

Step S5300, packaging the first light effect and the second light effect into light effect application data and transmitting the light effect application data to the lamp.

As disclosed in the foregoing, the first light effect and the second light effect may be both represented as light effect description data at the data level, and after the second light effect is determined, the first light effect and the second light effect may be further jointly packaged according to a predetermined format, specifically, the respective light effect description data of the first light effect and the second light effect may be packaged into light effect application data according to a specified format, so that the light effect application data has the capability of simultaneously describing the light effects corresponding to the first light group and the second light group.

After the lamp effect application data is generated, the lamp effect application data can be stored in the terminal equipment for standby or uploaded to a cloud server for calling. In addition, the lamp effect application data needs to be sent to the controller of the lamp, so that the controller can control the first lamp group and the second lamp group to play corresponding lamp effects according to the lamp effect application data.

In some embodiments, after determining the second light effect of the second light group and generating the light effect application data according to the second light effect, the user may trigger the configuration validation instruction through the terminal device, where the triggering of the instruction may be performed through a preset manner such as a button control, a shake, a specific gesture, and the like. In response to the configuration validation instruction, the lamp effect description data corresponding to all the lamp groups can be packaged into lamp effect application data, and the lamp effect application data is transmitted to a controller of the lamp for application.

After receiving the lamp effect application data transmitted by the terminal equipment, the controller of the lamp performs corresponding analysis to extract lamp effect description data corresponding to each lamp group, then determines each play frame of the lamp effect according to corresponding lighting parameters in the lamp effect of each lamp group, correspondingly determines setting data corresponding to each light source node of the corresponding lamp group as control data based on each play frame, then packages the control data of each light source node of the corresponding lamp group into the same lamp effect control data corresponding to each play frame of each lamp group, sends the same lamp effect control data to the corresponding lamp group, reads the control data corresponding to each light source node in the lamp group, and controls the lighting element to emit corresponding light rays, so that each play frame can be cooperatively played through each light source node in the lamp group, and playing of the corresponding lamp effect is realized. It will be appreciated that each light group may play its respective light effect in combination with its corresponding light group light effect description data in the same manner.

In some embodiments proposed for improving the implementation efficiency, for the light source node of the first lamp group that performs the illumination function in the entity lamp set as exemplified in the foregoing, only a single cold color light or warm color light may be emitted, accordingly, the lamp group light effect description data of the first lamp group is correspondingly described, and the controller of the entity lamp set controls the light source node of the first lamp group to continuously emit the corresponding cold color light or warm color light according to the description, without converting the operation of playing the frame. That is, the conversion and application of the light effect control data can be mainly performed on the second light effect of the second light group playing an role in rendering the atmosphere according to actual needs, so that the configuration process of the corresponding light effect control data of the first light group is simplified.

From the above embodiments, the present application has various advantages, including but not limited to:

firstly, a plurality of lamp groups in a lamp, each lamp group can set corresponding lamp efficiency, in order to improve the lamp efficiency configuration efficiency, the lamp efficiency attribute data related to the first lamp efficiency are used for determining the second lamp efficiency corresponding to the other lamp group in the lamp based on the first lamp efficiency corresponding to one lamp group in the lamp, so that the second lamp efficiency can be generated according to the first lamp efficiency, including automatic generation or customized generation, thereby enabling the first lamp efficiency to play a role in providing guiding reference information for the generation of the second lamp efficiency, improving the generation efficiency of the second lamp efficiency, enabling the second lamp efficiency and the first lamp efficiency to keep a harmonious and harmonious relationship on the light atmosphere, comprehensively improving the configuration efficiency of the lamp efficiency, optimizing the use experience of the lamp, and enabling the lamp to be more popular. .

Secondly, the method can enable each lamp group which is originally mutually decoupled and can be independently controlled in the lamp to realize the association control through the lamp effect data, even if the number of the lamp groups in the lamp is more, the technical scheme of the method can be used for determining the lamp effect based on the first lamp effect, and the lamp effect of each other lamp group is determined according to the lamp effect attribute data of the first lamp effect in a standardized mode, so that the lamp effect configuration of a plurality of lamp groups in the lamp is simpler, the complexity of the lamp effect configuration is effectively reduced, the capability of the lamp for expanding the lamp groups can be released, the overall cost of the lamp production link is reduced, and the user management universality of lamp products is greatly expanded because the method can unify the configuration modes of various lamps carrying different lamp groups.

In addition, the technical realization of the lamp effect association configuration among the lamp groups is simplified, so that the lamp is more suitable for being applied to indoor lighting fixtures with the lamp groups, particularly the indoor lighting fixtures comprising atmosphere lamps and illuminating lamps, the patterns of the lighting fixtures can be enriched, and the indoor lighting fixtures are easier to popularize.

On the basis of any embodiment of the method of the present application, referring to fig. 3, determining a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect includes:

Step S5211, determining a classification label corresponding to the first light effect as the light effect attribute data;

in the application, various light effects can be customized in advance, then the light effect description data is used as an independent field, corresponding classification labels are assigned to the light effect description data, the light effect description data is stored in a database, and the light effect description data of the light effects is obtained by detecting the light effect carrying the specified classification labels through the specified classification labels.

Accordingly, in one embodiment, when the first light effect is set, the classification label is correspondingly calibrated, and the classification label of the set first light effect can be correspondingly read as the light effect attribute data by the controller of the terminal device lamp to determine the second light effect.

In another embodiment, a multi-classification model based on deep learning may be trained in advance, the first light effect description data is input into the multi-classification model, and reasoning is performed by the multi-classification model according to the learned classification capability, so that a classification label corresponding to the first light effect can be determined as light effect attribute data for determining the second light effect.

The classification label of the light effect can be set according to the requirement, for example, classification according to the scene to which the light effect is applied, classification according to the emotion type of the atmosphere rendered by the light effect, classification according to the scale level of the light effect downloaded by the user, and the like.

Step S5212, inquiring a preset database, and determining a plurality of candidate light effects corresponding to the classification labels;

after determining the classification tag of the first light effect, the classification tag is used for inquiring in a preset database, so that all the plurality of light effects carrying the classification tag can be searched, and the light effects can be optimized according to a certain index basis. It will be appreciated that the plurality of candidate light effects determined in a ranked manner according to this embodiment are good-quality light effects that are widely accepted by users, are more easily accepted by users of the luminaire, and can promote the success rate of recommendation of the second light effect.

And step S5213, displaying the plurality of candidate light effects on a graphical user interface, and acquiring the candidate light effect selected by the user as a second light effect suitable for the second light group.

After each candidate light effect is obtained, each candidate light effect can be formatted into a recommended light effect list, and the recommended light effect list is displayed in a graphical user interface of the terminal equipment in an icon mode or a list mode for a user to select applications.

When a user selects one candidate light effect from the recommended user list to be used as a target light effect, the target light effect becomes a second light effect suitable for a second light group of the lamp, and the light effect description data of the target light effect is correspondingly acquired and can be used for packaging the light effect application data together with the light effect description data of the first light effect.

According to the embodiment, the plurality of candidate light effects are inquired in the database according to the classification labels of the first light effects so that the user can select the second light effect suitable for the second light group, the efficiency advantage of setting the second light effect can be obtained, the trouble that the user participates in customizing the specific lighting parameters of the second light effect is reduced, the overall is more foolproof, the lamp is easier to accept by the user, and the popularization of lamp products is facilitated.

On the basis of any embodiment of the method of the present application, referring to fig. 4, determining a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect includes:

step S5221, determining a scene tag corresponding to the first light effect as the light effect attribute data;

the light effect has the effect of rendering the atmosphere of the scene, so each light effect of the application can set the scene label corresponding to the scene to which the light effect is applied, such as a rainy scene, a sunny scene, a winter scene, a summer scene, and the like, in the same manner as the classification labels in the previous embodiments. When the first light effect is set, the corresponding scene tag is determined. The user is infected by different scenes and usually has different moods, so that the scene tag of the first light effect actually shows the first emotion characteristic of the user from one aspect, that is, the light effect which can be used as the second light effect can be set with the corresponding scene tag, the scene tag can be used for representing the first emotion characteristic of the user, and the scene tag can be obtained as the light effect attribute data of the first light effect to determine the second light effect.

Step S5222, acquiring rhythm point distribution characteristics of audio data, and determining emotion tags corresponding to the rhythm point distribution characteristics;

the terminal equipment can acquire the audio data through the audio acquisition unit such as a microphone, when a user plays music, the terminal equipment can acquire the environmental sound in real time, and emotion analysis can be carried out on the rhythm point distribution characteristics according to the audio data.

Or, the user plays the music through the terminal device, and the terminal device can also directly call the audio data of the music to perform emotion analysis of the rhythm point distribution characteristics.

When emotion analysis is carried out, rhythm point information corresponding to each rhythm point in audio data can be extracted by means of various existing rhythm point analysis algorithms or by means of a pre-trained deep learning model, and the rhythm point information is displayed along the time sequence of music playing to form rhythm point distribution characteristics. The distribution characteristics of the user at the rhythm points of the played music implies rhythm information of the music, which in one aspect also shows the second emotional characteristics of the user.

In order to quantify the second emotional characteristics of the user, the rhythmic point distribution characteristics may be classified by means of a pre-trained emotion classification model. The emotion classification model takes the rhythm point distribution characteristics of a plurality of pieces of music as an input training sample, adopts emotion labels marked for the music in advance as supervision labels of the sample, and supervises the emotion classification model to train to a convergence state so as to be put into use. When the emotion classification model converges, the emotion classification model has the capability of classifying the input rhythm point distribution characteristics and determining the corresponding emotion labels.

Accordingly, the rhythm point distribution characteristics obtained by extracting the audio data are input into the emotion classification model, so that classification probabilities corresponding to all preset emotion labels can be obtained, and the emotion label corresponding to the maximum value of the classification probabilities is used as the emotion label corresponding to the audio data, namely, the quantized representation of the second emotion characteristics of the user is realized.

Step S5223, querying a preset database, and determining the light effect matched with the scene tag and the emotion tag semanteme as a second light effect suitable for a second light group.

On the basis of obtaining a scene tag corresponding to the first light effect to show a first emotion feature of a user and showing a second emotion feature of the user through rhythm point distribution features of audio data, the scene tag and the emotion tag are utilized to carry out semantic matching with each scene tag which can be used as the second light effect in a database storing the light effect, so that the second light effect matched with the current first emotion feature and the second emotion feature of the user can be searched.

In a more specific embodiment, the semantic similarity between the scene tag of the first light effect, the emotion tag of the audio data and the scene tag of each light effect which can be used as the second light effect in the database can be calculated based on the scene tag and the emotion tag determined in advance respectively to obtain two similarity lists, and then according to the two similarity lists, taking each light effect as a target light effect, matching the first semantic similarity obtained by the scene tag of the target light effect corresponding to the first light effect with the second semantic similarity obtained by the emotion tag of the corresponding audio data, and obtaining the average value by matching preset weights to obtain the effective similarity of the target light effect. After each light effect which can be used as the second light effect obtains the effective similarity, the light effect corresponding to the effective similarity of the maximum value is taken as the second light effect suitable for the second light group, and the determination of the second light effect can be completed.

In other embodiments, a man-machine interaction business link may be further added, a plurality of light effects with higher effective similarity are displayed as candidate light effects in a light effect editing interface, recommended to a user for selection, and the user determines a target light effect from the candidate light effects as a second light effect so as to open richer customization capability to the user, and the effectiveness of determining the second light effect is further improved through user screening.

According to the embodiment, it can be seen that, according to the scene tag of the first light effect, the first emotion feature of the user is evaluated, according to the rhythm point distribution feature of the audio data selected by the user, the emotion tag is determined to evaluate the second emotion feature of the user, two emotion features of the user are associated, semantic matching is performed on the light effect which can be used by the second light effect in the database, the light effect with the highest similarity is determined as the second light effect, the second light effect can accurately and effectively correspond to the emotion of the user when the lamp is used by the user, the determined second light effect is more in line with the subjective feeling of the user, and the determined second light effect corresponds to the atmosphere rendered by the played light effect, so that the user can generate immersion feeling more easily.

On the basis of any embodiment of the method of the present application, referring to fig. 5, determining a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect includes:

Step S5231, determining color data of a first light effect as the light effect attribute data, wherein the color data comprises color values of at least two colors;

the color data of the first light effect may be a variable, and when the first light effect is set, the second light effect is determined according to the first light effect, if the color effect of the second light effect is not coordinated with the color effect of the first light effect, the overall light effect of the whole lamp is not good. In this case, the color data of the first light effect may be used as the light effect attribute data, and the color data of the second light effect may be determined from the color data of the first light effect.

In one embodiment, for the set first light effect, light effect description data of the first light effect may be obtained, and color data specified in the light emitting parameters corresponding to the color parameters is obtained, so as to obtain color values of a plurality of specified colors. In a more specific embodiment, in the light effect description data of the first light effect, two color values may be designated as color parameters thereof, so as to instruct the corresponding first light group to display corresponding color light according to the average value of the two color values, or alternatively display corresponding color light according to the two color values, or control the first light group to play corresponding color light by using the color values in any other way, or the like. In summary, by the color data specified in its light effect description data by the first light effect, more than two color values are obtained, which can be used to determine the second light effect.

Step S5232, determining a light effect spectrum corresponding to the second lamp group according to the color values of the two colors in the color data;

for two color values in the color data of the first light effect, in this embodiment, the two color values may be used as a basis for customizing the second light effect of the second light group as a gradual effect, and accordingly, the two color values may be used as end values at two sides of the spectrum, and the light effect spectrum defined by the two color values may be determined, so as to set the lighting parameter for the second light group based on the light effect spectrum. It will be appreciated that the spectrum of light effects is dependent on the two colour values applied by the first light effect, so that the colour light corresponding to the colour value selected from the spectrum of light effects is still co-ordinated with the colour light emitted by the first light effect.

Step S5233, color-taking and setting the lighting parameters of the second light effect in the light effect spectrum to define the second light effect suitable for the second light group.

When the second light effect corresponding to the second light group needs to be set, for the light effect description data of the second light effect, the light emitting parameter for describing the light emitting color of the second light group can select any color from the light effect spectrum, and the color value of the color is set as the color value of the light emitting parameter.

In one embodiment, the light effect description data of the second light effect describes that each light source node of the second light group plays the corresponding light effect with the gradual effect, and for this purpose, two color values corresponding to the gradual effect need to be set, and accordingly, the two color values can be randomly taken from the light effect spectrum to determine the two color values.

In another embodiment, in the light effect description data of the second light effect, specifically, the light emitting parameters corresponding to the light emitting colors of each light source node of the second light group are set correspondingly, and for this case, according to the sequence relation of each light source node in the light emitting link of the second light group, the light emitting parameters corresponding to each light source node of the second light group can be set by sequentially and equidistant taking values for each light source node along the same direction from the light effect spectrum corresponding to the sequence relation.

In any way, after the setting of the corresponding lighting parameters of the second light effect is completed, the complete definition of the second light effect is formed, and accordingly, the light effect description data of the second light effect can be obtained and used for packaging the light effect application data.

Therefore, on the basis of determining the light effect spectrum according to the color data of the first light effect, various modes can be flexibly selected, and the required light emitting parameters of the second light effect are determined, so that the light emitting color corresponding to the second light effect can be valued from the light effect spectrum.

On the basis of any embodiment of the method of the present application, referring to fig. 6, determining a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect includes:

step S5241, determining the dominant hue of the first light effect as the light effect attribute data;

considering that the first lamp group mainly plays a role of illumination, the first lamp effect is generally used to define monochromatic light, such as cool or warm light, according to which the corresponding color value can be determined as an indication of the dominant hue of the first lamp effect according to the color light set by the first lamp effect. The dominant hue is used as light effect attribute data to determine a second light effect.

Step S5242, determining optional data corresponding to the lighting parameters of the second light effect of the second light group according to the main tone;

after determining the color value of the dominant color shade corresponding to the first light effect, the color system to which the dominant color shade belongs, such as a cold color system or a warm color system, is actually determined, in which case, in order to maintain the harmony of the color light emitted by the second light effect and the color light emitted by the first light effect, the light emitting parameter used in the second light effect may be a light emitting parameter, typically a light emitting parameter representing the light emitting color, a color is selected in the color system to which the dominant color shade belongs, a corresponding color range is determined, and the color range is represented as optional data of the corresponding light emitting parameter so as to provide the user with the option of selecting.

The manner of representing the color range as the selectable data can be flexibly set, for example, the color range can be represented as progress data, and each progress corresponds to a color value of a specific color in the color range; as another example, several color values may be equally spaced from a color range as a limited enumeration of alternative colors in the color range. In summary, the color range corresponding to one lighting parameter can be flexibly represented as the selectable data corresponding to the lighting parameter, so that the user can select a determined target color value from the selectable data in a corresponding manner to set the corresponding lighting parameter.

Step S5243, configuring an editable attribute item corresponding to a lighting parameter of a second light effect, and displaying the editable attribute item to a light effect editing interface to enable the editable item to be related to corresponding optional data;

in order to facilitate setting of the lighting parameters of the second light effect, the attribute items of each lighting parameter required to be set in the light effect description data of the second light effect can be corresponding to the lighting parameters, the lighting parameters are determined to be editable attribute items, then selectable data of the lighting parameters are configured to be defined fields of the editable attribute items, namely, to be user selectable data contents, and then the editable attribute items are displayed in a light effect editing interface for editing the second light effect and are provided for browsing and setting by a user.

Step S5244, obtaining the light emitting parameters of the second light effect formed based on the data selected by the editable attribute items, so as to define the second light effect suitable for the second light group.

In the lighting effect editing interface, corresponding to each lighting parameter of the second lighting effect, an editable attribute item is displayed, a user can call out corresponding selectable data according to each editable attribute item, corresponding target data, such as a certain color value, is selected in the selectable data, after the terminal equipment obtains the data set by the user for the editable attribute item, the data can be used as setting data of the corresponding lighting parameter, so that definition of the corresponding lighting parameter of the second lighting effect is realized, all the user setting data are expressed to the lighting effect description data of the second lighting effect, and definition of the second lighting effect is completed.

According to the embodiment, it is easy to understand that the light emitting parameters corresponding to the light emitting colors of the second light effect can be configured according to the main tone of the first light effect, the editable attribute items corresponding to the light emitting parameters and the selectable data thereof are provided for the user through the light effect editing interface, the setting data corresponding to the light emitting parameters are determined by the user, the user is guided to finish the fine customizing process of the second light effect, the user can edit more detailed expressions of the second light effect more efficiently, the personalized customizing capability of the light effect of the lamp is enriched, the lamp is easier to accept by the user, and the popularization of the lamp is facilitated.

On the basis of any embodiment of the method of the present application, please refer to fig. 7, obtaining a first light effect applicable to a first light group in a light fixture includes:

step S5110, calling link description information corresponding to each light group in the lamp, wherein the link description information is used for describing connection relation information of each light source node in the light group to which the link description information belongs;

the exemplary luminaire may be designed according to a light source layout, which is mainly used to indicate the positional relationship of the light source nodes of different light groups of the luminaire on the same projection plane, and the exemplary light source layout may be such that the first light group is arranged in a central area of the solid luminaire, which may be a circular area, and the light source nodes of the second light group are arranged around the circular area, so that the light of the light source nodes of the second light group can be emitted from the periphery of the central area, thereby playing a role in decoration. In another exemplary light source layout, the light source nodes of the first light group may be arranged in a matrix, the light source nodes of the second light group may be arranged in a matrix, and the light source nodes of the two light groups may be arranged alternately on the projection surface. Therefore, the light source layout of the lamp can be flexibly set, and the creative embodiment of the application is not affected. For easy recall, the light source layout may be stored as a corresponding identifier for the terminal device to read, and thus, the computer program on the terminal device may be realized in a standardized manner, and by loading a data table storing a plurality of known light source layouts and their corresponding identifiers, the light source layout is subsequently queried in the data table according to the identifiers to adapt to the entity lamps designed and produced according to the light source layout, so that the terminal device can compatibly control the entity lamps of a plurality of light source layouts.

The individual light source nodes in each lamp group of the luminaire are typically connected in an orderly fashion, e.g. in an orderly fashion to form a light-emitting strip. Therefore, for a light-emitting lamp strip, the links formed by orderly connecting the light source nodes are light-emitting links, the orderly connection relation of the light source nodes is described in a preset format, the connection relation information among the light source nodes is represented by representing the position information corresponding to the connection sequence of the light source nodes in the light-emitting links, and the data obtained by description form the link description information corresponding to the light-emitting lamp strip, namely the link description information of the corresponding lamp group.

In the exemplary link description information, the sequence identifier of each light source node in the same lamp group can be represented according to the connection sequence of each light source node, and the controller of the lamp can communicate with each light source node according to a preset communication protocol to perform detection so as to obtain the sequence identifier of each light source node, thereby obtaining the link description information.

Step S5120, generating a corresponding light source layout view according to the link description information of each light group, and displaying the light source layout view to a light effect editing interface, wherein the light source layout view comprises light group patterns generated according to the link description information of each light group;

The terminal device can call the light source layout of the entity lamp under the condition that the terminal device knows the light source layout of the entity lamp in advance, for example, the terminal device can prestore various light source layouts and then call the corresponding light source layout through the identification of the specified light source layout. Still take the light source layout of the second light source node around the central area where the first light source is located as an example, the light source layout specifies the light source layout information corresponding to the central area where the first light source is located, and the second light source node around the light source layout information corresponding to the central area, so that after the terminal device invokes the light source layout, a corresponding light source layout view can be constructed according to the link description information corresponding to each light source.

When constructing the light source layout view, firstly determining the area where each lamp group is located according to the lamp group layout information of each lamp group, then positioning each light source node on the corresponding area according to the sequential position information of each light source node and the sequential position information of each light source node, so as to construct the light source layout view. In one embodiment, the light source layout view is generated corresponding to two light groups, the first light group is limited in a central area, each light source node of the second light group is limited in a circular arc area surrounding the central area, for example, when the first light group is in the central area, a single light source node of the first light group can be positioned at the central position of a circular area, or a plurality of light source nodes of the first light group can be relatively uniformly distributed in the circular area; when the second lamp group is located around the central area, the arc area can be evenly distributed for each light source node around the periphery of the circular area, so that the construction of the light source layout view of the whole lamp is completed. According to the mode, the light source layout view is constructed, the first lamp group and the second lamp group can be ensured to reasonably and more fit to perform lamp effect mutual reflection, more immersive light experience is presented, and the first lamp group and the second lamp group are linked to provide more harmonious experience of the lamp effect atmosphere for a user.

After the light source layout view is constructed in the memory, the light source layout view can be drawn and rendered into the light effect editing interface so as to display the corresponding interface effect. Such as the circular lamp panel of fig. 8 and 9, is a light source layout view of an exemplary luminaire with a central region portion for laying out the light source nodes of the first lamp set and a surrounding central region portion for laying out the light source nodes of the second lamp set.

In one embodiment, the light source layout view may be constructed as follows:

firstly, taking a first lamp group in each lamp group as a main lamp group, arranging a light source block corresponding to a light source node of the main lamp group in a central area of a virtual canvas, and generating a corresponding main lamp pattern:

in this embodiment, the terminal device may determine, according to a default service logic, a light source layout view in the system memory according to a determined light source layout, and may specifically be implemented by determining graphic description information of the light source layout view. The light source layout corresponding to the business logic followed by the terminal device may be a light source layout as exemplified above in which the first lamp group is arranged in a central area and the second lamp group is arranged in a surrounding area of the central area.

For this purpose, the terminal device sets a virtual canvas in the system memory, and according to a predetermined size, draws a circular area in the virtual canvas as a central area, and fills the circular area with a default color to indicate a pattern corresponding to the main lamp group, which may be referred to as a main lamp pattern. Thus, the central area where all light source nodes of the main light group are located is represented by the main light pattern.

Then, the second lamp group in each lamp group is taken as a secondary lamp group, and the light source blocks corresponding to the light source nodes of the secondary lamp group are arranged around the central area to generate corresponding secondary lamp patterns:

similarly, based on the light source layout corresponding to the default service logic, an annular ring-shaped area is drawn around the existing circular area of the virtual canvas, and default colors are filled in the annular ring-shaped area to indicate patterns corresponding to the auxiliary lamp groups, which can be called as auxiliary lamp patterns. Because the auxiliary lamp set mainly plays a role of atmosphere rendering, the control of the auxiliary lamp set needs to be embodied to the granularity of the light source nodes, according to the total number of the light source nodes in the auxiliary lamp set, the annular ring-shaped area can be divided into blocks corresponding to the light source nodes according to the total number in a circumferential equal manner, each block is used as the light source block of the corresponding light source node, and the light source blocks are arranged around the circular area of the main lamp set. It is known that each light source node in the secondary light group has its corresponding light source tile in the light source layout view, and the light source tile is a tile that is convenient to be converted or replaced by a light source control.

Finally, converting the main lamp patterns and the auxiliary lamp patterns in the virtual canvas into graphic description information of the light source layout view:

after the drawing of the light source layout view in the virtual canvas is completed, the data description can be carried out on each lamp group pattern, including the main lamp pattern and the virtual pattern, based on the virtual canvas, the lamp group pattern is described as graphic description information which can be analyzed by a video memory, and when the lamp group pattern is submitted to a graphic rendering interface of the video memory, the light source layout view can be quickly rendered in a lamp effect editing interface through the graphic rendering interface, and the lamp group pattern is more quickly displayed on the lamp effect editing interface.

The above embodiment shows that, by using a virtual canvas in a memory, according to the link description information of each lamp group of the lamp, the lamp group pattern corresponding to each lamp group is drawn in the virtual canvas to complete the data description of the light source layout view, so as to obtain the corresponding graphic description information, thereby improving the rendering efficiency of the graphic rendering interface, conveniently editing the light source image blocks of each light source node, and having the advantage of operation efficiency.

In order to facilitate information interaction with a user, the application can correspond to the light source nodes of the lamp group in the lamp, and corresponding light source controls are added to the corresponding positions in the light source layout view. The corresponding light source control can be added only for the light source node of one of the lamp groups, such as the second lamp group playing an atmosphere rendering role, or can be added for the light source nodes of all the lamp groups, and can be set according to actual needs.

The light source control can provide information display function and touch response function, can provide unidirectional man-machine interaction functions such as unidirectional display prompt information function, can provide bidirectional man-machine interaction functions such as simultaneous support of touch response and information display, and can be flexibly configured. In an exemplary embodiment, the light source controls of each light source node of the luminaire can be configured to not only be used for displaying prompt information, but also be used for responding to the touch of a user, so that a comprehensive man-machine interaction function is realized, and an editing preview function and an operation setting function are correspondingly provided.

Based on the information display function realized by the light source control, the light effect and/or the corresponding text information after the user setting can be displayed in the light source layout view according to the light emitting parameters correspondingly set by the user. Based on the touch response function realized by the light source control, the user can be supported to touch the target light source node, and the target light source node is used as the edited light source node, so that the user can edit the corresponding luminous parameters in the light effect editing interface, and the luminous parameters set by the user act on the edited light source node.

The implementation of the light source control can be realized by converting the block corresponding to the light source node in the light source layout view into a corresponding computer object, or can be supported by realizing the man-machine interaction function of the corresponding position after the background process identifies the corresponding position of the light source node in the light source layout view, and can be flexibly set. In one embodiment, the light source layout view may be drawn in advance in the system memory to generate graphic description information thereof, and then transferred to the video memory through the graphic rendering interface for drawing and rendering, so that modification and configuration of the tiles corresponding to each light source node in the light source layout view in the system memory, that is, modification of the relevant attribute items of the light source controls corresponding to each light source node, and timely reflection to the graphic user interface are facilitated. In one embodiment implemented accordingly, a rendered light source layout view may be drawn as follows, including:

firstly, drawing and rendering a light source layout view in a light effect editing interface according to graphic description information of the light source layout view;

after generating the graphic description information of the light source layout view according to the foregoing embodiments of the present application, the terminal device may call a graphic rendering interface provided by an open graphics library (OpenGL) of the operating system, and transfer the graphic description information to the interface, so that the graphic rendering interface draws and renders the light source layout view in a light effect editing interface according to the graphic description information.

Then, each light source block in the graphic description information is configured as a light source control, and a man-machine interaction function is given to the light source control.

For the purpose of adding the light source control for the light source node, the corresponding light source block of each light source node in the light source layout view can be further configured into a corresponding light source control in the system memory, the corresponding light source block is described by the light source control, and the man-machine interaction function is configured for the light source control through the data description of the light source control, so that the corresponding light source block can continue the man-machine interaction function.

The above embodiment shows that, the light source blocks in the light source layout view are configured as corresponding light source controls in the system memory through the graphic description information of the light source layout view, on one hand, the display effect of the light source blocks encapsulated by each light source control can be quickly set based on the graphic description information in the system memory, on the other hand, the light source layout view can be quickly rendered according to the graphic description information by means of the capability of the graphic rendering interface, so that the light emitting effect corresponding to the light emitting parameters set by the user on the light effect editing interface can be quickly updated to the graphic user interface, the occupied system resources are small, the implementation efficiency is high, and the better preview effect can be ensured.

Step S5130, obtaining a first light effect applicable to a first light group in each light group based on the light source layout view, so as to generate a second light effect applicable to a second light group in each light group.

The user may select a light group based on the light effect editing interface to select all light source nodes in the light group, or may select one or more light source nodes in the light group in the light effect editing interface to use the light source nodes as edited light source nodes, and set corresponding lighting parameters for the edited light source nodes.

In one embodiment, a list of light groupings can be provided in a light effects editing interface, and a list of light source nodes in the light groupings for user selection of edited light source nodes in a light source layout view. In another embodiment, the user may also implement the selection of the edited light source node directly based on touching the light source control in the light source layout view.

As shown in fig. 8 and 9, in order to facilitate the user to set the lighting parameters of the edited light source node, in the light effect editing interface, a lighting parameter setting area may be provided by avoiding the area of the light source layout view, or by popping up a control panel, and optional data of various lighting parameters or an input box or the like may be provided in the setting area, so that the user can more conveniently complete the setting of the lighting parameters of the edited light source node.

The specific attribute and specific data content of the lighting parameters of the edited light source nodes and the corresponding relation between the lighting parameters and the edited light source nodes flexibly open the corresponding editing function according to practical situations, for example, the editing function corresponding to a single color attribute which is provided for uniform application by corresponding each edited light source node can be provided, the editing function corresponding to the color attributes of two ends of the set gradient color of all the plurality of edited light source nodes can be also provided, and the editing function can be specifically and flexibly realized.

After the user sets the corresponding lighting parameters for the edited light source nodes, according to the set lighting parameters, setting data corresponding to each edited light source node, such as color values, brightness and the like, can be determined, and editing preview information corresponding to the edited light source nodes can be generated according to the setting data. The editing preview information may be flexibly implemented, for example, if the setting data is a color value or a brightness value, the edited light source node may be controlled to display a corresponding color block in a corresponding area, for example, a corresponding light source control, in the light source layout view according to the color value or the brightness value, or may be converted into a data text, and output to the corresponding area, for example, the corresponding light source control, for display on or near. In other words, according to the lighting parameters, the light source control corresponding to the edited light source node can be controlled to display the editing preview information, and the data form of the editing preview information is flexible and various, in a word, through the editing preview information, the user can more conveniently preview the influence effect of the set lighting parameters on the edited light source node, and can guide the user to accurately set the light effect corresponding to the edited light source node.

On the basis that the light effect editing interface and the light source layout view realize the functions, a user is allowed to select one light group in the lamp as a first light group, then the first light effect is set for the first light group, and on the basis, the guided generation of the second light effect can be realized.

According to the above embodiment, firstly, according to the link description information of each light group, a light source layout view representing the light source node distribution of each light emitting link is generated and displayed in a light effect editing interface, the first light effect is set conveniently by a user through the light source layout view, a scheme for efficiently and conveniently editing the light effect of part of the light groups is provided for the user, the user can edit the light effect more conveniently, then the corresponding light effect of all the light groups is obtained by means of the guiding type generating capability of the system, finally, the light effect application data of the whole light is obtained and applied to the light, the light effect configuration efficiency of the light is effectively improved, and the industrial popularization of the light is facilitated.

On the basis of any embodiment of the method of the present application, please refer to fig. 10, wherein the step of packaging the first light effect and the second light effect into the light effect application data for transmitting to the lamp includes:

step S5310, updating each lamp group pattern in the light source layout view according to the first light effect and the second light effect, so that each lamp group pattern correspondingly displays the corresponding light effect of the first light effect and the second light effect;

After the light effect application data are generated, the terminal equipment can further analyze and convert the service logic of the light effect application data according to the controller of the lamp, analyze and convert the light effect description information corresponding to each of the first light effect and the second light effect, thereby determining each play frame of each light effect, determining the light effect control data corresponding to each play frame, then analyzing and converting the light effect control data corresponding to each play frame of each light effect into the image information of the corresponding light group pattern in the light source layout view according to each play frame as a unit, then further converting the image information into the data of the attribute item of the light source control corresponding to each light source block of the corresponding light group pattern, refreshing the graphic description information of the corresponding light group, drawing and rendering the light group pattern of the corresponding light group in the light source layout view according to the graphic description information corresponding to each light group through the graphic opening interface under the action of the drawing and rendering mechanism of the application, thereby obtaining the corresponding image effect of each play frame, controlling each light group pattern by the corresponding play frame and presenting the corresponding light effect, thereby displaying the corresponding play frame in turn in the light effect editing interface, and playing the light effect in the second light source layout view.

Step S5320, responding to the configuration application instruction, and packaging the first light effect and the second light effect into light effect application data;

after the user previews the light effect animation flow effect through the light source layout view in the light effect editing interface, if the light effect is not required to be modified, a configuration application instruction can be triggered through a preset control, and the terminal equipment can directly package the corresponding light effect description data of the first light effect and the second light effect into the light effect application data for storage and transmission.

Step S5330, transmitting the lamp effect application data to a controller of the lamp, and driving the controller to control the first lamp set and the second lamp set to play the first lamp effect and the second lamp effect correspondingly according to the lamp effect application data.

The terminal equipment further sends the generated lamp effect application data to the controller of the lamp through a communication link established with the controller of the lamp, so that the controller is driven to analyze and convert the lamp effect application data, the lamp effect description data of each lamp group, such as the first lamp effect and the second lamp effect of the first lamp group and the second lamp group, are firstly analyzed and extracted, then according to the conversion process disclosed in the foregoing, the lamp effect control data corresponding to a plurality of playing frames are generated according to the lamp effect description data of each lamp effect of the first lamp effect and the second lamp effect, and then the lamp effect control data are orderly sent to the first lamp group and the second lamp group, so that the first lamp group and the second lamp group can be controlled to cooperatively complete the playing of the corresponding lamp effect, and the lamp atmosphere effect which accords with the expectations of users is obtained.

According to the embodiment, the preview effect of the first light effect and the second light effect is rendered to each corresponding light group pattern in the light source layout view for display, so that a user can quickly know the actual effect of the defined light effect, the user can see the actual effect, and the success rate of customizing the light effect by the user can be improved.

Referring to fig. 11, another embodiment of the present application further provides a light effect configuration apparatus, which includes a first light effect obtaining module 5100, a second light effect determining module 5200, and a light effect transmission application module 5300, where the first light effect obtaining module 5100 is configured to obtain a first light effect applicable to a first light group in a light fixture; the second light effect determining module 5200 is configured to determine a second light effect applicable to the second light group in the lamp according to the light effect attribute data of the first light effect; the light effect transmission application module 5300 is configured to package the first light effect and the second light effect into light effect application data for transmission to the lamp.

On the basis of any embodiment of the apparatus of the present application, the second light effect determining module 5200 includes: a category determining unit configured to determine a category label corresponding to the first light effect as the light effect attribute data; the lamp effect matching unit is used for inquiring a preset database and determining a plurality of candidate lamp effects corresponding to the classification labels; and the light effect selecting unit is used for displaying the plurality of candidate light effects to the graphical user interface and acquiring the candidate light effect selected by the user as a second light effect suitable for the second light group.

On the basis of any embodiment of the apparatus of the present application, the second light effect determining module 5200 includes: a scene determining unit configured to determine a scene tag corresponding to a first light effect as the light effect attribute data; the emotion determining unit is used for acquiring rhythm point distribution characteristics of the audio data and determining emotion tags corresponding to the rhythm point distribution characteristics; the matching setting unit is used for inquiring a preset database and determining the light effect matched with the scene tag and the emotion tag semanteme as a second light effect suitable for a second light group.

On the basis of any embodiment of the apparatus of the present application, the second light effect determining module 5200 includes: a color value determination unit configured to determine color data of a first light effect as the light effect attribute data, the color data including color values of at least two colors; a spectrum determining unit configured to determine a light efficiency spectrum corresponding to the second light group according to color values of two colors in the color data; the light effect setting unit is set to take color in the light effect spectrum and set the lighting parameter of the second light effect so as to define the second light effect suitable for the second light group.

On the basis of any embodiment of the apparatus of the present application, the second light effect determining module 5200 includes: a tone determination unit configured to determine a dominant tone of a first light effect as the light effect attribute data; a parameter definition unit configured to determine, according to the main color, optional data corresponding to a lighting parameter of a second light effect of a second light group; the interface interaction unit is used for configuring an editable attribute item corresponding to the lighting parameter of the second light effect, displaying the editable attribute item to a light effect editing interface, and enabling the editable item to be related to the corresponding selectable data; and the light effect definition unit is used for acquiring the light emitting parameters of the second light effect formed based on the data selected by the editable attribute items so as to define the second light effect suitable for the second light group.

On the basis of any embodiment of the apparatus of the present application, the first light effect obtaining module 5100 includes: the description acquisition unit is used for calling link description information corresponding to each lamp group in the lamp, wherein the link description information is used for describing the connection relation information of each light source node in the lamp group to which the link description information belongs; the view display unit is used for generating a corresponding light source layout view according to the link description information of each lamp group and displaying the light source layout view to the light effect editing interface, wherein the light source layout view comprises lamp group patterns generated according to the link description information of each lamp group; and the light effect editing unit is used for acquiring the first light effect applicable to the first light group in each light group based on the light source layout view and generating the second light effect applicable to the second light group in each light group.

On the basis of any embodiment of the apparatus of the present application, the light effect transmission application module 5300 includes: the light effect display unit is used for updating each lamp group pattern in the light source layout view according to the first light effect and the second light effect, so that each lamp group pattern correspondingly displays the corresponding light effect of the first light effect and the second light effect; the instruction response unit is used for responding to the configuration application instruction and packaging the first light effect and the second light effect into light effect application data; the lamp effect playing unit is used for transmitting the lamp effect application data to a controller of the lamp, and driving the controller to control the first lamp group and the second lamp group to correspondingly play the first lamp effect and the second lamp effect according to the lamp effect application data.

On the basis of any embodiment of the present application, please refer to fig. 12, another embodiment of the present application further provides a computer device, which may be used as a controller in an atmosphere lamp device, as shown in fig. 12, and an internal structure diagram of the computer device is shown. The computer device includes a processor, a computer readable storage medium, a memory, and a network interface connected by a system bus. The computer readable storage medium of the computer device stores an operating system, a database and a computer program for packaging computer readable instructions, the database can store a control information sequence, and the computer readable instructions can enable the processor to realize a lamp efficiency configuration method when the computer readable instructions are executed by the processor. The processor of the computer device is used to provide computing and control capabilities, supporting the operation of the entire computer device. The memory of the computer device may have stored therein computer readable instructions that, when executed by the processor, cause the processor to perform the light efficiency configuration method of the present application. The network interface of the computer device is for communicating with a terminal connection. It will be appreciated by those skilled in the art that the structure shown in fig. 12 is merely a block diagram of some of the structures associated with the present application and is not limiting of the computer device to which the present application may be applied, and that a particular computer device may include more or fewer components than shown, or may combine certain components, or have a different arrangement of components.

The processor in this embodiment is configured to execute specific functions of each module and its sub-module in fig. 11, and the memory stores program codes and various data required for executing the above-mentioned modules or sub-modules. The network interface is used for data transmission between the user terminal or the server. The memory in this embodiment stores program codes and data required for executing all modules/sub-modules in the lighting configuration device of the present application, and the server can call the program codes and data of the server to execute the functions of all sub-modules.

The present application also provides a storage medium storing computer readable instructions that, when executed by one or more processors, cause the one or more processors to perform the steps of the light effect configuration method of any of the embodiments of the present application.

The present application also provides a computer program product comprising computer programs/instructions which, when executed by one or more processors, implement the steps of the light effect configuration method of any of the embodiments of the present application.

Those skilled in the art will appreciate that implementing all or part of the above-described methods of embodiments of the present application may be accomplished by way of a computer program stored on a computer readable storage medium, which when executed, may comprise the steps of embodiments of the methods described above. The storage medium may be a computer readable storage medium such as a magnetic disk, an optical disk, a Read-Only Memory (ROM), or a random access Memory (Random Access Memory, RAM).

The foregoing is only a partial embodiment of the present application, and it should be noted that, for a person skilled in the art, several improvements and modifications can be made without departing from the principle of the present application, and these improvements and modifications should also be considered as the protection scope of the present application.

In summary, the application facilitates the user to efficiently and rapidly configure the light effect of the plurality of light groups, can release the capability of the lamp to expand the light groups, reduces the complexity of the user to configure the light effect of the lamp, and can assist the popularization of the indoor lighting lamp.

Claims (9)

1. A method of lamp efficiency configuration, comprising:

acquiring a first light effect applicable to a first light group in the lamp;

determining a second light effect applicable to a second lamp group in the lamp according to the light effect attribute data of the first light effect;

packaging the first light effect and the second light effect into light effect application data to be transmitted to the lamp;

the obtaining a first light effect applicable to a first light group in a lamp comprises:

invoking link description information corresponding to each lamp group in the lamp, wherein the link description information is used for describing connection relation information of each light source node in the lamp group to which the link description information belongs;

generating a corresponding light source layout view according to the link description information of each light group, and displaying the light source layout view to a light effect editing interface, wherein the light source layout view comprises light group patterns generated according to the link description information of each light group;

And acquiring the first light effect applicable to the first light group in each light group based on the light source layout view, so as to generate the second light effect applicable to the second light group in each light group.

2. The light effect configuration method of claim 1, wherein determining a second light effect applicable to a second light group in the luminaire from the light effect attribute data of the first light effect comprises:

determining a classification label corresponding to the first light effect as the light effect attribute data;

inquiring a preset database, and determining a plurality of candidate lamp effects corresponding to the classification labels;

and displaying the candidate light effects to a graphical user interface, and acquiring the candidate light effect selected by the user as a second light effect suitable for the second light group.

3. The light effect configuration method of claim 1, wherein determining a second light effect applicable to a second light group in the luminaire from the light effect attribute data of the first light effect comprises:

determining a scene tag corresponding to the first light effect as the light effect attribute data;

acquiring rhythm point distribution characteristics of audio data, and determining emotion tags corresponding to the rhythm point distribution characteristics;

inquiring a preset database, and determining the light effect matched with the scene tag and the emotion tag semanteme as a second light effect suitable for a second light group.

4. The light effect configuration method of claim 1, wherein determining a second light effect applicable to a second light group in the luminaire from the light effect attribute data of the first light effect comprises:

determining color data of a first light effect as the light effect attribute data, wherein the color data comprises color values of at least two colors;

determining a corresponding light effect spectrum of the second lamp group according to the color values of the two colors in the color data;

and setting the lighting parameters of the second light effect in the light effect spectrum by taking colors to define the second light effect suitable for the second light group.

5. The light effect configuration method of claim 1, wherein determining a second light effect applicable to a second light group in the luminaire from the light effect attribute data of the first light effect comprises:

determining a dominant hue of a first light effect as the light effect attribute data;

determining optional data corresponding to the lighting parameters of the second light effect of the second light group according to the main tone;

configuring an editable attribute item corresponding to the lighting parameter of the second light effect, and displaying the editable attribute item to a light effect editing interface to enable the editable attribute item to be related to the corresponding selectable data;

And acquiring the light emitting parameters of the second light effect formed based on the data selected by the editable attribute items so as to define the second light effect suitable for the second light group.

6. The light effect configuration method of claim 1, wherein encapsulating the first light effect and the second light effect as light effect application data for transmission to the luminaire comprises:

updating each lamp group pattern in the light source layout view according to the first light effect and the second light effect, so that each lamp group pattern correspondingly displays the corresponding light effect of the first light effect and the second light effect;

responding to the configuration application instruction, and packaging the first light effect and the second light effect into light effect application data;

and transmitting the lamp effect application data to a controller of the lamp, and driving the controller to control the first lamp group and the second lamp group to play the first lamp effect and the second lamp effect correspondingly according to the lamp effect application data.

7. A light efficiency configuration apparatus, comprising:

a first light effect acquisition module configured to acquire a first light effect applicable to a first light group in a lamp;

a second light effect determining module configured to determine a second light effect applicable to a second light group in the luminaire according to the light effect attribute data of the first light effect;

The lamp effect transmission application module is used for packaging the first lamp effect and the second lamp effect into lamp effect application data and transmitting the lamp effect application data to the lamp;

the first light effect acquisition module comprises:

the description acquisition unit is used for calling link description information corresponding to each lamp group in the lamp, wherein the link description information is used for describing the connection relation information of each light source node in the lamp group to which the link description information belongs;

the view display unit is used for generating a corresponding light source layout view according to the link description information of each lamp group and displaying the light source layout view to the light effect editing interface, wherein the light source layout view comprises lamp group patterns generated according to the link description information of each lamp group;

and the light effect editing unit is used for acquiring the first light effect applicable to the first light group in each light group based on the light source layout view and generating the second light effect applicable to the second light group in each light group.

8. An indoor lighting fixture, comprising a controller and a plurality of light banks, wherein the controller is configured to receive light effect application data generated by the method according to any one of claims 1 to 6, and control the plurality of light banks to play corresponding light effects according to the light effect application data.

9. A computer device comprising a central processor and a memory, characterized in that the central processor is arranged to invoke a computer program stored in the memory for performing the steps of the method according to any of claims 1 to 6.