CN116634635A

CN116634635A - Lamp installation verification method, device, equipment and medium

Info

Publication number: CN116634635A
Application number: CN202310904500.7A
Authority: CN
Inventors: 颜广子; 吴文龙
Original assignee: Shenzhen Zhiyan Technology Co Ltd; Shenzhen Qianyan Technology Co Ltd
Current assignee: Shenzhen Zhiyan Technology Co Ltd; Shenzhen Qianyan Technology Co Ltd
Priority date: 2023-07-24
Filing date: 2023-07-24
Publication date: 2023-08-22
Anticipated expiration: 2043-07-24
Also published as: CN116634635B

Abstract

The application relates to a lamp installation checking method, a device, equipment and a medium, wherein the method comprises the following steps: acquiring a pattern layout of a lamp, wherein the pattern layout comprises a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generation sequence identifier and a selected interface identifier thereof, each lamp block identifier is used for indicating one lamp block of the lamp, and each selected interface identifier is one of a plurality of selectable interfaces of the lamp block; generating a lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface, and sending the lighting control instruction to the lamp so as to control each lamp block to emit light according to the corresponding working time sequence information; and based on the lamp blocks, emitting light according to the corresponding working time sequence information to respond to the pattern confirmation instruction, and verifying the pattern layout to be related to the characteristic identifiers of the lamps as an effective pattern layout. The application can remarkably improve the working efficiency of installing and checking the personalized lamp and greatly improve the use experience of a user on the spliced lamp.

Description

Lamp installation verification method, device, equipment and medium

Technical Field

The present application relates to the field of lamps, and in particular, to a lamp installation verification method, a corresponding device, an electronic device, and a computer readable storage medium.

Background

With the improvement of life quality of people, higher requirements are placed on material life, so that intelligent home furnishings are rapidly developed, and more people begin to use the intelligent home furnishings. The lighting equipment is used as an important component of the intelligent home, the requirements of people on the lighting equipment are gradually not met by the simple lighting function any more, and the requirements of the lighting equipment on individuation and scene lamp design and installation are greatly improved.

At present, the installation and verification method provided by the lamp is extremely complicated and cannot acquire accurate installation and verification information, a user cannot quickly and intuitively master the related installation and verification flow to carry out installation and verification on the lamp, the accuracy of the installation and verification on the lamp is low, installation error operation is easy to occur in the installation process of the lamp, damage to lamp blocks of the lamp is caused, the user repeatedly installs the lamp blocks, labor cost and material cost are increased, and the installation experience of the user is poor and enterprise benefit is influenced.

In summary, in order to solve the problem that a user cannot quickly and intuitively master the related installation verification process to perform installation verification on the lamp, the accuracy of the installation verification on the lamp is not high, and the like, the inventor performs corresponding exploration in consideration of solving the problem.

Disclosure of Invention

The present application is directed to a lamp installation verification method, a corresponding device, an electronic apparatus, and a computer readable storage medium.

In order to meet the purposes of the application, the application adopts the following technical scheme:

the lamp installation checking method provided by the application suitable for one of the purposes comprises the following steps:

acquiring a pattern layout of a lamp, wherein the pattern layout comprises a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generation sequence identifier and a selected interface identifier thereof, each lamp block identifier is used for indicating one lamp block of the lamp, and each selected interface identifier is one of a plurality of selectable interfaces of the lamp block;

generating a lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface, and sending the lighting control instruction to the lamp so as to control each lamp block to emit light according to the corresponding working time sequence information;

and based on the lamp blocks, emitting light according to the corresponding working time sequence information to respond to the pattern confirmation instruction, and verifying the pattern layout to be related to the characteristic identifiers of the lamps as an effective pattern layout.

Optionally, the step of sending the lighting control instruction to the lamp to control each lamp block to emit light according to the corresponding working time sequence information includes the following steps:

displaying a plurality of plane movement directions of the light emitting of each lamp block in an installation checking interface based on the corresponding generation sequence identifiers of each lamp block in the lamps of the pattern layout and the selected interface identifiers;

determining the target movement direction of the light emission of each lamp block according to the plurality of plane movement directions;

and determining the target movement direction of the light emission of each lamp block as the corresponding working time sequence information of each lamp block, and controlling each lamp block to emit light according to the corresponding working time sequence information.

judging whether each lamp block emits light according to a verification color threshold corresponding to the lamp block, and triggering an alarm indication on the current lamp block if the current lamp block does not emit light according to the verification color threshold corresponding to the current lamp block;

according to the alarm indication response installation guide instruction, switching to an installation guide interface corresponding to the current lamp block;

And circularly playing the installation guide video corresponding to the current lamp block in the installation guide interface until the current lamp block emits light according to the corresponding verification color threshold value.

obtaining a space topological graph of the lamps in the pattern layout, and displaying the space topological graph of the lamps in the pattern layout to an installation checking interface, wherein the space topological graph shows the space position layout of each lamp block in the lamps in the pattern layout in a physical space;

determining an initialization lamp block of the lamp with the style layout in the installation checking interface based on the generating sequence identifier and the selected interface identifier;

and determining the position of the initialized lamp block corresponding to the space position layout of each lamp block in the physical space as a verification starting point.

Optionally, the step of displaying the spatial topological graph of the lamp with the style layout to the installation checking interface includes the following steps:

determining layout description information of the lamps of the pattern layout based on the generation sequence identification and the selected interface identification of the lamps of the pattern layout;

And generating a space topological graph of the lamp of the pattern layout in the reference coordinate system of the installation checking interface according to the layout description information, wherein the layout description information is used for describing the space position relation information corresponding to the physical space of each lamp block of the lamp of the pattern layout.

Optionally, the step of generating the lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface includes the following steps:

determining the working time sequence information of each lamp block of the lamp with the pattern layout based on the relative spatial position relation of each lamp block in the lamp with the pattern layout relative to the verification starting point, the corresponding generating sequence identifier of each lamp block and the selected interface identifier;

and packaging the working time sequence information of each lamp block into a light-emitting control instruction, and determining a target light-emitting sequence corresponding to each lamp block according to the light-emitting control instruction, wherein the target light-emitting sequence represents a light-emitting sequence corresponding to a designated position of the spatial position layout of each lamp block in a physical space.

Optionally, the step of emitting light according to the corresponding operation time sequence information based on the lamp blocks to respond to the pattern confirmation instruction comprises the following steps:

The space positions of all lamp blocks in the lamps of the pattern layout in the preset plane movement direction are related by taking the preset verification starting point as a reference to determine the working time sequence information;

determining the time sequence position of each lamp block relative to the verification starting point according to the working time sequence information, and mapping the time sequence position into a space position in a reference coordinate system of an installation verification interface;

displaying visual verification identifiers corresponding to the lamp blocks at the space positions, and verifying the lamp blocks one by one based on the visual verification identifiers to determine a successful lamp block verification result;

and responding to the pattern confirmation instruction based on the lamp block verification success result.

A lamp installation verification device according to another object of the present application includes:

the system comprises a pattern layout acquisition module, a pattern layout acquisition module and a control module, wherein the pattern layout acquisition module is used for acquiring the pattern layout of a lamp, the pattern layout comprises a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generation sequence identifier and a selected interface identifier thereof, each lamp block identifier is used for indicating one lamp block of the lamp, and each selected interface identifier is one of a plurality of selectable interfaces of the lamp block;

the lighting control module is used for generating a lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface, and sending the lighting control instruction to the lamp so as to control each lamp block to emit light according to the corresponding working time sequence information;

The lamp verification module is used for responding to the pattern confirmation instruction based on the light emitting of each lamp block according to the corresponding working time sequence information, and verifying the pattern layout as an effective pattern layout in association with the characteristic identification of the lamp.

A luminaire installation verification device according to another object of the application comprises a central processor and a memory, said central processor being arranged to invoke the steps of running a computer program stored in said memory for performing the luminaire installation verification method according to the application.

A computer readable storage medium adapted to another object of the present application stores a computer program implemented according to the luminaire installation checking method in the form of computer readable instructions, which when invoked by a computer, performs the steps comprised by the corresponding method.

Compared with the prior art, the method and the device aim at the problems that a user cannot quickly and intuitively master the relevant installation and verification process to install and verify the lamp, the accuracy of the installation and verification of the lamp is not high, and the like, according to the verification information determined by the user in the process of customizing the lamp in an individualized way, the real-time interaction between the terminal equipment and the individualized lamp actually installed in the physical space is realized, the installation and verification of the individualized lamp in the physical space is carried out according to the verification information in an undemanding way, the position where the installation error or the lamp block fault actually occurs in the individualized lamp can be accurately positioned, the working efficiency of the installation and verification of the individualized lamp is obviously improved, the use experience of the user on products is greatly improved, the lamp block is prevented from being repeatedly disassembled due to the installation and verification error of a certain lamp block by the user, the lamp block is prevented from being damaged in the disassembly process, the labor cost and the material cost are prevented from increasing, the lamp installation and verification method is extremely convenient, the manual verification in the past is converted into a convenient man-machine interaction means, the installation and verification efficiency of the individualized lamp is improved, and the method is beneficial to the quick popularization and application of the individualized lamp in industry.

Drawings

The foregoing and/or additional aspects and advantages of the application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, in which:

fig. 1 is a schematic structural diagram of a spliced lamp in an embodiment of the application;

FIG. 2 is a schematic flow chart of a lamp installation verification method in an embodiment of the application;

FIG. 3 is a schematic flow chart of controlling each lamp block to emit light according to the corresponding working time sequence information in the embodiment of the application;

FIG. 4 is a schematic diagram of a flow chart of installation verification according to verification colors of lamp blocks and designated positions of verification color display in an embodiment of the application;

FIG. 5 is a schematic flow chart of determining a verification start point of a spliced lamp in a spatial position layout of a physical space according to an embodiment of the application;

FIG. 6 is a schematic flow chart showing a space topology diagram of a spliced lamp to an installation checking interface in an embodiment of the application;

FIG. 7 is a schematic flow chart of a lighting control instruction organized according to work time sequence information generated by each lamp block according to a generating sequence identifier and a selected interface in the embodiment of the application;

FIG. 8 is a flow chart of a response pattern confirmation instruction based on each lamp block emitting light according to its corresponding operation timing information in an embodiment of the present application;

FIG. 9 is a schematic block diagram of a lamp installation verification device in an embodiment of the application;

fig. 10 is a schematic structural diagram of a computer device according to an embodiment of the present application.

Detailed Description

Embodiments of the present application are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the application.

As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless expressly stated otherwise, as understood by those skilled in the art. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It will be understood that when an element is referred to as being "connected" or "coupled" to another element, it can be directly connected or coupled to the other element or intervening elements may also be present. Further, "connected" or "coupled" as used herein may include wirelessly connected or wirelessly coupled. The term "and/or" as used herein includes all or any element and all combination of one or more of the associated listed items.

It will be understood by those skilled in the art that all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs unless defined otherwise. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

As used herein, "client," "terminal device," and "terminal device" are understood by those skilled in the art to include both devices that include only wireless signal receivers without transmitting capabilities and devices that include receiving and transmitting hardware capable of two-way communication over a two-way communication link. Such a device may include: a cellular or other communication device such as a personal computer, tablet, or the like, having a single-line display or a multi-line display or a cellular or other communication device without a multi-line display; a PCS (Personal Communications Service, personal communication system) that may combine voice, data processing, facsimile and/or data communication capabilities; a PDA (Personal Digital Assistant ) that can include a radio frequency receiver, pager, internet/intranet access, web browser, notepad, calendar and/or GPS (Global Positioning System ) receiver; a conventional laptop and/or palmtop computer or other appliance that has and/or includes a radio frequency receiver. As used herein, "client," "terminal device" may be portable, transportable, installed in a vehicle (aeronautical, maritime, and/or land-based), or adapted and/or configured to operate locally and/or in a distributed fashion, at any other location(s) on earth and/or in space. As used herein, a "client," "terminal device," or "terminal device" may also be a communication terminal, an internet terminal, or a music/video playing terminal, for example, a PDA, a MID (Mobile Internet Device ), and/or a mobile phone with music/video playing function, or may also be a device such as a smart tv, a set top box, or the like.

The application refers to hardware such as a server, a client, a service node, etc., which essentially is an electronic device with personal computer and other functions, and is a hardware device with a central processing unit (including an arithmetic unit and a controller), a memory, an input device, an output device, etc., which are necessary components revealed by Feng Reyi man principle, etc., wherein a computer program is stored in the memory, and the central processing unit calls the program stored in the memory to run, executes instructions in the program, and interacts with the input and output devices, thereby completing specific functions.

It should be noted that the concept of the present application, called "server", is equally applicable to the case of server clusters. The servers should be logically partitioned, physically separate from each other but interface-callable, or integrated into a physical computer or group of computers, according to network deployment principles understood by those skilled in the art. Those skilled in the art will appreciate this variation and should not be construed as limiting the implementation of the network deployment approach of the present application.

The spliced lamp provided by the application is formed by adjacently splicing a plurality of lamp blocks, and can have a plurality of different product forms according to different structures of the lamp blocks and different splicing relations. The spliced lamp provided by the application can be suitable for being used as an atmosphere lamp, can play a role in dressing the space atmosphere, and is often installed in an indoor space.

For example, referring to fig. 1, fig. 1 is a spliced lamp formed by splicing a plurality of lamp blocks 1 with a regular hexagonal structure, wherein each lamp block 1 includes a plurality of light emitting units, for example, the light emitting units are distributed on each side of the regular hexagonal structure, each prismatic block, etc., so that light emitting control with different granularity can be implemented on each lamp block 1, for example, each prismatic region, side, or all light emitting units in the lamp block 1 can be controlled individually.

Each lamp block 1 is provided with an installation interface and an electrical interface which are spliced with other lamp blocks 1, or the installation interface and the electrical interface are combined into the same electromechanical interface, and a user can assemble spliced lamps in different forms by splicing different lamp blocks 1 in sequence to splice different topological effects.

For convenient control, the spliced lamps are usually provided with a main control module 2, and the main control module 2 usually comprises a control chip, a communication component and the like.

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, microcontroller), a DSP (Digital Signal Processing ), and the like, where the control Chip generally includes a central processing unit and a memory, and is mainly used to store and execute program instructions to implement corresponding functions. The communication component can be used for communicating with external equipment, for example, can communicate with various intelligent terminal equipment such as a personal computer, a smart phone and the like, so that a user can give an installation checking instruction of the lamp to the spliced lamp through the terminal equipment.

After receiving the installation verification instruction of the lamp through the communication component, the control chip correspondingly analyzes the installation verification instruction into lamp block installation verification signals corresponding to the lamp blocks for controlling the spliced lamp, outputs the lamp block installation verification signals to the lamp blocks 1, and controls the light emitting units of the lamp blocks 1 to play corresponding light effects.

In some embodiments, the master control module 2 may also configure power adapters, control panels, display screens, etc. as desired. The power adapter is mainly used for converting commercial power into direct current so as to supply power for the whole spliced lamp. The control panel typically provides one or more keys for implementing on-off control, etc. of the main control module 2. The display screen can be used for displaying various control information so as to be matched with keys in the control panel and support the realization of man-machine interaction functions. In some embodiments, the control panel may be integrated into the same touch display as the display.

The lamp installation checking method can be realized as a computer program product, and is installed in terminal equipment to run, so that a man-machine interaction interface is provided for a user, the user is used for completing personalized customization of lamps to determine lamps with various patterns and layouts, then the user is used for splicing and installing entity lamp blocks corresponding to the lamps with the patterns and layouts to determine the spliced lamps, and then the terminal equipment is used for sending an installation checking instruction corresponding to the spliced lamps so as to carry out installation checking on each entity lamp block in the spliced lamps, and whether each entity lamp block in the spliced lamps is installed correctly is detected.

On the basis of the above exemplary scenario, referring to fig. 2, in one embodiment of the present application, a lamp installation verification method includes the following steps:

step S10, acquiring a pattern layout of a lamp, wherein the pattern layout comprises a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generation sequence identifier and a selected interface identifier thereof, each lamp block identifier is used for indicating one lamp block of the lamp, and each selected interface identifier is one of a plurality of selectable interfaces of the lamp block;

Before the pattern layout of the lamp is obtained, the terminal equipment responds to a lamp splicing request triggered by a user to display a lamp block splicing interface of the terminal equipment, and the pattern layout of the lamp is displayed in an initialized mode in the lamp block splicing interface. After the pattern layout of the lamp is displayed in an initialized manner in the lamp block splicing interface of the terminal equipment, a user can perform splicing operation on the pattern layout of the lamp in the initialized manner according to personal preference to splice lamps in any pattern layout, at least one splicing operation triggered by responding to a selected interface corresponding to any one lamp block identifier of the lamp blocks in the lamp block splicing interface is performed, the selected interface identifier and the generating sequence identifier of the lamp block to be acted are determined based on the splicing operation to update the pattern layout of the lamp, and the selected interface identifier and the generating sequence identifier corresponding to each lamp block to be acted are stored in a server of a manufacturer.

In some embodiments, the recommended operation of the style layout of the lamp is triggered in response to the recommended event in the lamp block splicing interface, one or more style layouts of the lamp that can be spliced may be displayed according to the number of lamp blocks selected in the lamp block splicing interface and the lamp block graphics, and after any style layout corresponding to a lamp block graphics is selected, the canvas in the lamp block splicing interface may directly apply the style layout corresponding to the lamp block graphics.

And the user installs each entity lamp block corresponding to the lamps in the style layout to determine the spliced lamp, and the spliced lamp can communicate with various terminal devices such as a personal computer and a smart phone so that the user can send a lamp installation checking instruction to the spliced lamp through the terminal devices. When the user finishes the splicing of the entity lamp blocks of the spliced lamp, the terminal equipment can acquire the pattern layout of the spliced lamp and the corresponding target luminous time sequence of the spliced lamp through a server of a manufacturer, and the terminal equipment can transmit the target luminous time sequence of the spliced lamp to the spliced lamp and feed back the actual luminous time sequence of the spliced lamp to the terminal equipment. The pattern layout comprises a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generation sequence identifier and a selected interface identifier thereof, and each lamp block identifier is used for indicating one lamp block of the lamp.

Step S20, generating a light-emitting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identification and the selected interface, and sending the light-emitting control instruction to the lamp so as to control each lamp block to emit light according to the corresponding working time sequence information;

The spliced lamp emits light according to corresponding working time sequence information by controlling different lamp blocks, so that the motion process of each lamp block in the spliced lamp is molded, the light motion process of the spliced lamp is displayed, and a space atmosphere is rendered and a moving picture effect is constructed. The corresponding generation sequence of each lamp block in the spliced lamp and the difference of the selected interfaces are different, and the corresponding work time sequence information is different, so that since the corresponding generation sequence identification of each lamp block in the spliced lamp and the different selected interfaces are different, namely the corresponding work time sequence information of each lamp block in the spliced lamp is different, the spliced lamp has a movement flow of light emission according to the corresponding work time sequence information of each lamp block, and the installation errors of the corresponding entity lamp blocks of the spliced lamp can lead to different generated lamp effects. And generating a lighting control instruction of each lamp block in the spliced lamp according to the generating sequence identifier and the selected interface, wherein the lighting control instruction is organized according to the working time sequence information, and when a user finishes splicing the entity lamp blocks of the spliced lamp, the terminal equipment sends the lighting control instruction to the spliced lamp so as to control each lamp block to emit light according to the corresponding working time sequence information, so that the lighting effect corresponding to each lamp block in the spliced lamp is generated, and whether the user installs the entity lamp block corresponding to the spliced lamp correctly is checked.

And step S30, based on the lamp blocks, emitting light according to the corresponding working time sequence information to respond to a pattern confirmation instruction, and verifying the pattern layout and the characteristic identification of the lamp as an effective pattern layout.

When the user finishes the splicing of the entity lamp blocks of the spliced lamp, after the terminal equipment sends the luminous control instruction to the spliced lamp, each lamp block in the spliced lamp emits light according to the corresponding working time sequence information, the corresponding light effect of each lamp block in the spliced lamp is generated, and the fact that the user installs each lamp block corresponding to the spliced lamp correctly is explained. And based on the lamp blocks, emitting light according to the corresponding working time sequence information to respond to a pattern confirmation instruction, verifying the characteristic identifiers of the lamps associated with the pattern layout to be the effective pattern layout, namely, associating the pattern layout of the spliced lamp with the selected interfaces corresponding to the lamp blocks in the spliced lamp and generating the lamp with the sequentially verified effective pattern layout.

Compared with the prior art, the method and the device aim at the problems that a user cannot quickly and intuitively master the relevant installation and verification flow to carry out installation and verification on the lamp, the accuracy of the installation and verification on the lamp is not high, and the like, according to the verification information determined by the user in the process of customizing the lamp in an individualized way, the real-time interaction between the terminal equipment and the individualized lamp actually installed in the physical space is realized, the installation and verification on the individualized lamp in the physical space is carried out according to the verification information in an undemanding way, the installation and verification error or the lamp fault position in the individualized lamp can be accurately positioned, the working efficiency of the installation and verification on the individualized lamp is remarkably improved, the use experience of the user on products is greatly improved, the lamp is prevented from being repeatedly disassembled due to the fact that the lamp is in a certain lamp block is in an installation and verification error condition, the lamp block is damaged in the disassembly process, the labor cost and the material cost are prevented from being increased.

On the basis of any embodiment of the present application, referring to fig. 3, the step of sending the lighting control instruction to the lamp to control each lamp block to emit light according to the corresponding working time sequence information includes the following steps:

step S201, displaying a plurality of plane movement directions of the light emitting of each lamp block in an installation checking interface based on the corresponding generation sequence identifiers of the lamp blocks in the lamps of the pattern layout and the selected interface identifiers;

the plane movement direction determines the spatial position sequence of each lamp block in the spliced lamp relative to a verification starting point, so that when the entity lamp blocks corresponding to the spliced lamp installed by a user are installed and verified according to the relative spatial position relation of each lamp block in the spliced lamp relative to the verification starting point, the terminal equipment displays a plurality of plane movement directions of each lamp block in an installation and verification interface based on the corresponding generation sequence identification of each lamp block in the spliced lamp and the selected interface identification, compares whether the plane movement direction of each lamp block of the spliced lamp installed in the entity space by the user is consistent with the plane movement direction of each lamp block of the spliced lamp in the installation and verification interface, and if the plane movement direction of each lamp block of the spliced lamp in the installation and verification interface is consistent with the plane movement direction of each lamp block of the spliced lamp in the installation and verification interface, the spliced lamp is correctly installed; if the plane movement direction of the light emission of the entity lamp block is inconsistent with the plane movement direction of the light emission of each lamp block of the spliced lamp in the installation checking interface, the installation error of the spliced lamp is indicated, and therefore the installation checking of the spliced lamp is achieved.

Step S203, determining the target movement direction of the light emission of each lamp block according to the plurality of plane movement directions;

and after the corresponding generation sequence identifiers and the selected interface identifiers of the lamp blocks in the spliced lamp show the luminous multiple plane movement directions of the lamp blocks in the installation checking interface, namely, the corresponding luminous movement flow of the spliced lamp is determined, and the luminous target movement directions of the lamp blocks are determined according to the corresponding multiple plane movement directions of the lamp blocks in the spliced lamp.

Step 205, determining the target movement direction of each light block to emit light as the corresponding working time sequence information of each light block, and controlling each light block to emit light according to the corresponding working time sequence information.

The generation sequence of each lamp block in the spliced lamp and the difference of the selected interfaces are different, the corresponding working time sequence information is different, the spliced lamp essentially emits light according to the corresponding working time sequence information by controlling the different lamp blocks, the motion flow of each lamp block in the spliced lamp is molded, and the target motion direction of the light emission of each lamp block is determined as the corresponding working time sequence information of each lamp block. And determining the target movement direction of the light emission of each lamp block, namely determining the corresponding working time sequence information of each lamp block in the spliced lamp, so as to control the light emission of each lamp block according to the corresponding working time sequence information.

According to the embodiment, the working time sequence information of each lamp block of the spliced lamp can be reversely pushed out by utilizing the selected interface identification and the generated sequence identification of each lamp block of the spliced lamp, the target luminous direction of the spliced lamp on the space position in the installation checking interface is determined, a user can conveniently and intuitively install and check the spliced lamp in real time, and the obtained result is realized.

On the basis of any embodiment of the present application, referring to fig. 4, the step of sending the lighting control instruction to the lamp to control each lamp block to emit light according to the corresponding working time sequence information includes the following steps:

step S2001, judging whether each lamp block emits light according to the verification color threshold corresponding to the lamp block, if the current lamp block does not emit light according to the verification color threshold corresponding to the current lamp block, triggering an alarm indication on the current lamp block;

after the user installs the entity lamp blocks corresponding to the spliced lamp, the user sends a lamp installation checking instruction to the spliced lamp through the terminal equipment, and whether each lamp block in the spliced lamp emits light according to the checking color threshold corresponding to the lamp block is judged. After the connection of each lamp block interface of the spliced lamp is displayed in the installation and verification interface of the terminal equipment, the lamp blocks can lighten the verification color at the designated position, a user can compare the verification color position of each lamp block of the spliced lamp and the corresponding verification color threshold value thereof displayed in the installation and verification interface of the terminal equipment with the display state of the entity lamp block of each lamp block at the moment, and if the current entity lamp block does not emit light according to the corresponding verification color threshold value or the verification color position thereof, an alarm indication is triggered at the current entity lamp block.

Step 2003, according to the alarm indication response installation guide instruction, switching to an installation guide interface corresponding to the current lamp block;

and the terminal equipment receives and responds to the alarm instruction triggered by the current entity lamp block, and switches to an installation guide interface corresponding to the current entity lamp block according to the installation guide instruction responded by the alarm instruction so as to reinstall the entity lamp block.

And step 2005, circularly playing the installation guide video corresponding to the current lamp block in the installation guide interface until the current lamp block emits light according to the corresponding verification color threshold value.

After switching to an installation guide interface corresponding to the current entity lamp block, determining an installation step of the current entity lamp block as a target installation step, displaying a demonstration interface aiming at the target installation step, and circularly playing an installation guide video corresponding to the target installation step in the demonstration interface, wherein the demonstration interface can be displayed on the current installation guide interface in a floating window mode. And circularly playing the installation guide video corresponding to the target installation step in the demonstration interface, and reinstalling the current entity lamp block by a user according to the installation guide video corresponding to the target installation step until the current entity lamp block emits light according to the corresponding verification color threshold value, and verifying that the current entity lamp block is successfully installed.

According to the embodiment, the real-time verification of the installation process of the spliced lamp is performed, the colors and the positions of the lamp blocks actually displayed in the physical space are compared with the verification colors and the designated positions in the installation verification interface, so that a user can quickly understand whether the lamp blocks are installed correctly or not, the installation efficiency of the spliced lamp is greatly improved, when the lamp block installation errors or faults are verified, the installation guiding flow information is responded quickly, the error lamp blocks of the spliced lamp are corrected in time and installed correctly, the situation that the lamp blocks are required to be detached in a large range due to the fact that a certain lamp block is installed incorrectly is avoided, and manpower and material resources are saved.

On the basis of any embodiment of the present application, referring to fig. 5, the step of sending the lighting control instruction to the lamp to control each lamp block to emit light according to the corresponding operation timing information includes the following steps:

step 2011, acquiring a space topological graph of the lamp with the pattern layout, and displaying the space topological graph of the lamp with the pattern layout to an installation checking interface, wherein the space topological graph shows the space position layout of each lamp block in the lamp with the pattern layout in a physical space;

the spliced lamp is formed by sequentially abutting a plurality of lamp blocks in a physical space according to a certain topological relation, after a user finishes splicing corresponding entity lamp blocks in the spliced lamp, an installation checking interface of the terminal equipment presents a spatial position layout corresponding to the spliced lamp, the spatial position layout is abstracted into a data model, a spatial topological diagram is formed according to the data model composition, the representation of the spatial position layout among the lamp blocks of the spliced lamp can be realized, and the pattern map formed by splicing the spliced lamp in the physical space is displayed in the installation checking interface of the terminal equipment.

Step S2013, determining an initialized lamp block of the lamp with the pattern layout in the installation checking interface based on the generation sequence identifier and the selected interface identifier;

and each lamp block in the spliced lamp is different in corresponding generation sequence and selected interface, corresponding work time sequence information is different, and the initialized lamp block of the spliced lamp in the installation checking interface is determined based on the generation sequence identification and the selected interface identification.

Step S2015, determining the position of the initialized lamp block corresponding to the spatial position layout of each lamp block in the physical space as a verification starting point.

The spliced lamp emits light according to corresponding working time sequence information by controlling different lamp blocks, so that the motion process of each lamp block in the spliced lamp is molded, the light motion process of the spliced lamp is displayed, and a space atmosphere is rendered and a moving picture effect is constructed. The method comprises the steps that the generation sequence of each lamp block in the spliced lamp and the difference of selected interfaces are different, corresponding working time sequence information is different, the lamps in the pattern layout have luminous motion processes, the spliced lamp is started at different verification starting points, different verification results are generated, in order to improve the accuracy of lamp installation verification, the luminous motion processes corresponding to the spliced lamp are determined, a user can clearly verify the spliced lamp installed by the user, and the position of the initialized lamp block corresponding to the spatial position layout of each lamp block in a physical space is determined as the verification starting point, namely, the first entity lamp block installed by the user is used as the verification starting point.

According to the embodiment, the verification starting point is visually displayed in the space topological graph of the spliced lamp, so that a user can intuitively and clearly install and verify the spliced lamp in the space position layout in the physical space, the accuracy of the installation and verification of the spliced lamp is improved, the corresponding luminous motion flow of the spliced lamp is vividly displayed, the position where the installation error or the lamp block fault actually occurs in the personalized lamp is accurately positioned, and the working efficiency of the installation and verification of the personalized lamp is remarkably improved.

On the basis of any embodiment of the present application, referring to fig. 6, the step of displaying the spatial topology map of the lamp with the style layout to the installation checking interface includes the following steps:

step S20111, determining layout description information of the lamps of the pattern layout based on the generation sequence identifiers of the lamps of the pattern layout and the selected interface identifiers;

after the user completes the splicing of the corresponding entity lamp blocks in the spliced lamp, the terminal equipment can acquire the corresponding generation sequence identifiers and the selected interface identifiers of the lamp blocks in the spliced lamp from a server of a manufacturer, and the layout description information of the lamp with the style layout is determined based on the generation sequence identifiers and the selected interface identifiers of the spliced lamp.

And step S20113, generating a space topological diagram of the lamp with the pattern layout in the reference coordinate system of the installation checking interface according to the layout description information, wherein the layout description information is used for describing the space position relation information corresponding to the physical space of each lamp block of the lamp with the pattern layout.

After determining the generating sequence identifier and the selected interface identifier of each lamp block, since each lamp block in the spliced lamp can be connected with one or more other lamp blocks, in fact, each lamp block has side connection relationship information, in the process that a user performs the splicing of lamps with the pattern layout in the canvas of the lamp block splicing interface of the terminal device, the generating sequence identifier and the selected interface identifier corresponding to each lamp block in the spliced lamp can be determined, for example, the side connection relationship information corresponding to each lamp block in the spliced lamp can be determined, for example, the side connection is established by the N 'selected interface of the M' selected interface N lamp block of the M lamp block, so that the relationship information can be represented as data, the layout description information is formed by the data, and as will be understood, the layout description information describes the spatial position relationship information corresponding to the actual physical space of each lamp block of the spliced lamp. The side connection relation information of each lamp block in the spliced lamp with the layout pattern is given in the layout description information, and the layout diagram of each lamp block can be constructed according to the side connection relation information to obtain a space topological diagram.

In some embodiments, the spliced lamp may be laid out on a plane, and in a two-dimensional space, the generating sequence identifier of each lamp block and the position of the selected interface identifier are determined according to the edge connection relationship information display of each lamp block in the spliced lamp, so that a space topological graph of the spliced lamp is spliced, and the space topological graph is correspondingly displayed in the installation inspection interface of the terminal device.

In some embodiments, the spliced lamp may be laid out in a three-dimensional space, a physical space in which the spliced lamp is located is modeled, and then a spatial topological graph is constructed by using edge connection relationship information corresponding to each lamp block in the modeling space, and then the spatial topological graph is displayed in an installation inspection interface of the terminal device at an optimal viewing angle.

According to the embodiment, the space topological graph can be generated based on the actual layout relation of each lamp block of the spliced lamp in the physical space, so that the space topological graph displayed in the installation checking interface of the terminal equipment can accurately correspond to the space layout of the spliced lamp in the physical space, the edge connection relation among each lamp block is accurately displayed, the installation checking of the spliced lamp by a user is ensured to be more accurate, and the installation checking of the spliced lamp by the user can be simply and clearly performed.

On the basis of any embodiment of the present application, referring to fig. 7, the step of generating the lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface includes the following steps:

step S207, determining the working time sequence information of each lamp block of the lamp with the pattern layout based on the relative spatial position relation of each lamp block in the lamp with the pattern layout relative to the verification starting point, the corresponding generation sequence identifier of each lamp block and the selected interface identifier;

the spliced lamp essentially emits light according to corresponding working time sequence information by controlling different lamp blocks, a motion process of each lamp block in the spliced lamp is molded, so that a light motion process of the spliced lamp is displayed, a space atmosphere is rendered, a moving picture effect is constructed, the relative spatial position relation, the generating sequence and the selected interface of each lamp block in the spliced lamp relative to a verification starting point are different, the corresponding working time sequence information is different, and the working time sequence information of each lamp block in the spliced lamp is determined based on the relative spatial position relation, the corresponding generating sequence identification and the selected interface identification of each lamp block in the spliced lamp.

Step S209, packaging the working time sequence information of each lamp block into a lighting control instruction, and determining a target lighting sequence corresponding to each lamp block according to the lighting control instruction, where the target lighting sequence represents a lighting sequence corresponding to a specified position of a spatial position layout of each lamp block in a physical space.

After the working time sequence information of each lamp block of the spliced lamp is determined, determining a luminous motion flow corresponding to the spliced lamp, packaging the working time sequence information of each lamp block into a luminous control instruction, and determining a target luminous sequence corresponding to each lamp block according to the luminous control instruction, wherein the target luminous sequence represents a luminous sequence corresponding to a designated position of a spatial position layout of each lamp block in a physical space.

According to the embodiment, the working time sequence information of each lamp block in the spliced lamp is determined based on the relative spatial position relation of each lamp block in the spliced lamp relative to the verification starting point, the corresponding generation sequence identifier of each lamp block and the selected interface identifier, so that the accuracy of the corresponding light-emitting time sequence information of each lamp block in the spliced lamp can be ensured, the designated position of the spatial position layout of each lamp block in the spliced lamp in the physical space and the light-emitting sequence are ensured to emit light, and the accuracy of the installation verification of the spliced lamp is improved.

Referring to fig. 8, the step of emitting light according to the corresponding operation timing information based on each lamp block to respond to the pattern confirmation command according to any embodiment of the present application includes the following steps:

step S301, determining the working time sequence information by taking the established checking starting point as a reference and correlating the space position of each lamp block in the lamps with the pattern layout in the established plane movement direction;

the working time sequence of each lamp block in the spliced lamp is in a sequential relationship, the time sequence relationship corresponds to the position relationship in the space topological graph, specifically, the luminous control instruction of the spliced lamp in the layout pattern takes the checking starting point as a reference, and the position sequence of each lamp block in space relative to the checking starting point is converted into the time sequence in the moving process according to the plane moving direction specified by the moving process of the adopted lamp effect.

In some embodiments, when the pattern layout of the spliced lamp is a circular layout, in a space topology diagram of the circular layout, a central lamp block with a circle center is determined to be the verification starting point, and when the plane movement direction of the movement flow of the lamp effect is specified to be spread to the periphery, in the lighting control instruction of the spliced lamp of the layout pattern, the working time sequence information of the central lamp block can be represented as 0 second, the working time sequence information of a first circle of lamp blocks next to the central lamp body unit can be represented as 0.3 second, the working time sequence information of a second circle of lamp blocks next to the first circle of lamp blocks can be represented as 0.6 second, and so on, by specifying the working time sequence information of each lamp block, when the spliced lamp is controlled to emit light, each lamp body unit performs lighting display according to the calculated time difference of the corresponding working time sequence, so as to cooperatively present the movement flow of the lamp effect.

Step S303, determining the time sequence position of each lamp block relative to the verification starting point according to the working time sequence information, and mapping the time sequence position into a space position in a reference coordinate system of an installation verification interface;

after the plane movement direction of the light emission of the spliced lamp is determined, working time sequence information of a movement base point corresponding to a central lamp block can be deduced by utilizing time difference among working time sequence information among different lamp blocks, the working time sequence information is mapped into a space topological graph of the spliced lamp, so that the time sequence positions of the lamp blocks relative to the verification starting point are deduced, and even if the verification starting point is outside the space topological graph of the spliced lamp, the space position of the lamp block can be still determined based on a reference coordinate system of an installation verification interface of the terminal equipment.

In some embodiments, the spatial topology of the spliced lamp may be in a circular layout, which specifies that the direction of movement of the plane of the light emitted by the spliced lamp is a type that diffuses to the periphery, the verification starting point is located outside the spatial topology and belongs to the center of the circular layout, and the working time sequence information of the verification starting point should be represented as 0 seconds, but the working time sequence information is not encapsulated in the light emission control instruction due to no corresponding lamp block, however, each lamp block of the spliced lamp has set the working time sequence information of the lamp blocks of different circles in a mode of equal time difference, for example, 0.3 seconds, and then the time difference can be used to determine that the working time sequence information is an area occupied by one lamp block every 0.3 seconds, so that the specific spatial position of the working time sequence information in the reference coordinate system of the installation verification interface of the terminal device, namely, the position of the verification starting point can be deduced reversely. When the time sequence position of the verification starting point is mapped to the space position in the reference coordinate system of the installation verification interface of the terminal equipment, the calculation of the relevant position information can be correspondingly performed by using the reference coordinate system of the modeling space, so that the specific position of the verification starting point in the modeling space can be rapidly determined.

Step S305, displaying the visual verification identifiers corresponding to the lamp blocks at the space positions, and verifying the lamp blocks one by one based on the visual verification identifiers to determine a lamp block verification success result;

and reversely pushing out coordinate information of the checking starting point in an installation checking interface of the terminal equipment by utilizing the working time sequence information of each lamp block in the spliced lamp, determining the space position of the checking starting point in the installation checking interface, then marking each lamp block in the spliced lamp in the layout style by using visual checking marks such as a selected interface mark, a checking color designated position mark and the like, and carrying out comparatively real-time and visual installation checking on the spliced lamp, thereby facilitating comparatively visual and clear installation checking on the spliced lamp installed in a physical space by a user on the installation checking interface in the terminal equipment by a user, and realizing the achievement.

Step S307, responding to the pattern confirmation instruction based on the lamp block verification success result.

After a lamp block verification success result of the spliced lamp is determined, responding to the pattern confirmation instruction based on the lamp block verification success result, associating the pattern layout of the spliced lamp with the selected interfaces corresponding to the lamp blocks in the spliced lamp and generating the lamp with the pattern layout pattern which is verified to be effective in sequence.

According to the embodiment, the working time sequence information of each lamp block of the spliced lamp can be reversely deduced by utilizing the selected interface identification and the generated sequence identification of each lamp block of the spliced lamp, the spatial position of each lamp block in the installation and verification interface relative to the verification starting point is determined, then the visual identification is used for identification, a user can conveniently and intuitively install and verify the spliced lamp in real time, and the method is achieved.

Referring to fig. 9, a lamp installation checking device according to one of the objects of the present application includes a pattern layout obtaining module 1100, a lighting control module 1200 and a lamp checking module 1300. The style layout obtaining module 1100 is configured to obtain a style layout of a lamp, where the style layout includes a plurality of lamp block identifiers, each lamp block identifier carries a corresponding generating sequence identifier and a selected interface identifier thereof, each lamp block identifier is used for indicating one lamp block of the lamp, and each selected interface identifier is one of a plurality of selectable interfaces of the lamp block; the lighting control module 1200 is configured to generate a lighting control instruction of each lamp block organized according to the working time sequence information according to the generating sequence identifier and the selected interface, and send the lighting control instruction to the lamp to control each lamp block to emit light according to the corresponding working time sequence information; the lamp verification module 1300 is configured to verify the feature identifier of the lamp associated with the pattern layout as an effective pattern layout based on the lamp blocks emitting light according to the corresponding operation time sequence information to respond to the pattern confirmation instruction.

On the basis of any embodiment of the present application, the light emission control module 1200 includes:

the plane direction display unit is used for displaying a plurality of plane movement directions of the light emitting of each lamp block in the installation checking interface based on the corresponding generation sequence identifiers of the lamp blocks in the lamps in the style layout and the selected interface identifiers;

a target direction determining unit configured to determine a target moving direction of the light emission of each lamp block according to the plurality of plane moving directions;

and the control unit is used for determining the target movement direction of the light emission of each lamp block as the corresponding working time sequence information of each lamp block and controlling each lamp block to emit light according to the corresponding working time sequence information.

the verification color judging unit is used for judging whether each lamp block emits light according to the corresponding verification color threshold value of the lamp block, and triggering an alarm indication on the current lamp block if the current lamp block does not emit light according to the corresponding verification color threshold value;

the guide interface switching unit is used for responding to the installation guide instruction according to the alarm instruction and switching to an installation guide interface corresponding to the current lamp block;

And the circulating playing unit is used for circularly playing the installation guide video corresponding to the current lamp block in the installation guide interface until the current lamp block emits light according to the corresponding verification color threshold value.

the topological graph acquisition unit is used for acquiring a spatial topological graph of the lamp with the pattern layout, displaying the spatial topological graph of the lamp with the pattern layout to the installation checking interface, wherein the spatial topological graph shows the spatial position layout of each lamp block in the lamp with the pattern layout in a physical space;

an initial lamp block determining unit, configured to determine an initial lamp block of the lamp with the pattern layout in the installation checking interface based on the generating sequence identifier and the selected interface identifier;

and the verification starting point determining unit is used for determining the position of the initialized lamp block corresponding to the space position layout of each lamp block in the physical space as a verification starting point.

On the basis of any embodiment of the present application, the topology map acquisition unit includes:

a layout information determining unit configured to determine layout description information of the lamps of the pattern layout based on the generation sequence identification of the lamps of the pattern layout and the selected interface identification;

And the topology diagram determining unit is used for generating a space topology diagram of the lamp with the pattern layout in the reference coordinate system of the installation checking interface according to the layout description information, wherein the layout description information is used for describing the space position relation information corresponding to the physical space of each lamp block of the lamp with the pattern layout.

a working time sequence determining unit, configured to determine working time sequence information of each lamp block of the lamp of the pattern layout based on a relative spatial position relation of each lamp block in the lamp of the pattern layout relative to the verification starting point, a corresponding generation sequence identifier of each lamp block, and a selected interface identifier;

the light emitting sequence determining unit is used for packaging the work time sequence information of each lamp block into a light emitting control instruction, and determining a target light emitting sequence corresponding to each lamp block according to the light emitting control instruction, wherein the target light emitting sequence represents the light emitting sequence corresponding to the designated position of the spatial position layout of each lamp block in the physical space.

On the basis of any embodiment of the present application, the lamp verification module 1300 includes:

The working time sequence determining unit is used for determining the working time sequence information by taking the established checking starting point as a reference and correlating the space positions of each lamp block in the lamps of the pattern layout in the established plane movement direction;

the space position determining unit is used for determining the time sequence position of each lamp block relative to the verification starting point according to the working time sequence information and mapping the time sequence position into a space position in a reference coordinate system of an installation verification interface;

the verification result determining unit is arranged to display visual verification identifiers corresponding to the lamp blocks at the space positions, and verify the lamp blocks one by one based on the visual verification identifiers to determine a successful lamp block verification result;

and the pattern confirmation unit is used for responding to the pattern confirmation instruction based on the lamp block verification success result.

On the basis of any embodiment of the present application, referring to fig. 10, another embodiment of the present application further provides a lamp installation checking device, where the lamp installation checking device may be implemented by a computer device, and as shown in fig. 10, 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 computer readable instructions, the database can store a control information sequence, and when the computer readable instructions are executed by a processor, the processor can realize a lamp installation checking method. 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 store computer readable instructions that, when executed by the processor, cause the processor to perform the luminaire installation verification 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. 10 is merely a block diagram of some of the structures associated with the present inventive arrangements and is not limiting of the computer device to which the present inventive arrangements may be applied, and that a particular computer device may include more or fewer components than shown, or may combine some of the 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-modules in fig. 9, and the memory stores program codes and various types of data required for executing the above 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 lamp installation checking 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 luminaire installation verification method according to any one of the embodiments of the present application.

The application also provides a computer program product comprising computer programs/instructions which when executed by one or more processors implement the steps of the luminaire installation verification method according to any one of the embodiments of the application.

Those skilled in the art will appreciate that all or part of the processes implementing the methods of the above embodiments of the present application may be implemented by a computer program for instructing relevant hardware, where the computer program may be stored on a computer readable storage medium, where the program, when executed, may include processes implementing the 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 it will be apparent to those skilled in the art that modifications and adaptations can be made without departing from the principles of the present application, and such modifications and adaptations are intended to be comprehended within the scope of the present application.

In conclusion, the lamp installation and verification method is extremely convenient, the previous manual verification is converted into a convenient man-machine interaction means, the installation and verification efficiency of the personalized lamp is improved, and the rapid popularization and application of the personalized lamp in industry are facilitated.

Claims

1. The lamp installation checking method is characterized by comprising the following steps of:

2. The lamp mounting verification method according to claim 1, wherein the step of transmitting the lighting control instruction to the lamp to control each lamp block thereof to emit light according to the corresponding operation timing information thereof comprises the steps of:

3. The lamp mounting verification method according to claim 1, wherein the step of transmitting the lighting control instruction to the lamp to control each lamp block thereof to emit light according to the corresponding operation timing information thereof comprises the steps of:

4. The lamp mounting verification method according to claim 1, wherein the step of transmitting the lighting control instruction to the lamp to control each lamp block thereof to emit light according to the corresponding operation timing information thereof comprises the steps of:

5. The luminaire mounting verification method of claim 4, wherein the step of displaying a spatial topology of the patterned luminaire to a mounting verification interface comprises the steps of:

6. The lighting fixture installation verification method according to claim 4 or 5, wherein the step of generating the lighting control instructions for each lamp block organized according to the operation timing information according to the generation sequence identification and the selected interface comprises the steps of:

7. The lamp mounting verification method according to any one of claims 4 to 5, wherein the step of emitting light in response to the pattern confirmation instruction based on the respective lamp blocks according to the corresponding operation timing information thereof, comprises the steps of:

8. A lamp installation verification device, comprising:

9. A luminaire installation verification device comprising a central processor and a memory, characterized in that the central processor is adapted to invoke a computer program stored in the memory for performing the steps of the method according to any of claims 1 to 7.

10. A computer-readable storage medium, characterized in that it stores in the form of computer-readable instructions a computer program implemented according to the method of any one of claims 1 to 7, which, when invoked by a computer, performs the steps comprised by the corresponding method.