CN111885804A - Wireless remote control method and device for cabinet light and storable medium - Google Patents

Abstract

The invention relates to the technical field of case control and wireless communication, in particular to a wireless remote control method and device for case light and a storable medium. The invention can acquire the first environment illumination data, the second environment illumination data and the third environment illumination data collected by the photosensitive sensor through the data signal micro-converter when receiving a signal access application uploaded by the photosensitive sensor through the data signal micro-converter, when the intelligent lamp group emits light according to the light adjustment instruction and when the environment light response information sent by the intelligent lamp group is detected, and generate the self-adaptive adjustment instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data and send the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjustment instruction. The invention can adaptively adjust and control the light of the case according to the illumination condition of the actual environment.

Description

Wireless remote control method and device for cabinet light and storable medium

Technical Field

The invention relates to the technical field of cabinet control and wireless communication, in particular to a wireless remote control method and device for cabinet light and a storable medium.

Background

With the development of science and technology, computers have become essential tools in people's lives. The computer not only can be convenient for people to work, but also can be used for people to entertain and relax in spare time. The case is one of important parts of the computer, and can ensure the normal and stable operation of the computer.

Today, the demands of people on the chassis are rising from internal operation functions to appearance auxiliary functions. For example, cabinets with light variability are becoming more and more popular with consumers. By adjusting the light of the case, the user requirements under different scenes can be met. For example, at night, the light of the case can be controlled to display in a night light mode.

However, most of the existing control technologies for the cabinet light need to be manually controlled or can only be mechanically changed according to a set time period, and cannot be adaptively adjusted according to the illumination condition of the actual environment.

Disclosure of Invention

In order to overcome at least the above-mentioned disadvantages of the prior art, an object of the present invention is to provide a wireless remote control method and apparatus for a cabinet light, and a storable medium.

In a first aspect, a wireless remote control method for cabinet light is provided, and is applied to a light microcontroller, where the light microcontroller is disposed inside a cabinet, and the method includes:

when a signal access application uploaded by a photosensitive sensor through a data signal micro-converter is received, acquiring first environment illumination data acquired by the photosensitive sensor based on the data signal micro-converter and issuing a lamplight adjusting instruction to the data signal micro-converter based on the signal access application so that the data signal micro-converter sends the lamplight adjusting instruction to an intelligent lamp bank arranged outside the case;

when the intelligent lamp set emits light according to the light adjusting instruction, the data signal micro-converter is used for acquiring second environment illumination data collected by the photosensitive sensor at regular time;

when environment light response information sent by the intelligent lamp bank is detected, acquiring acquisition parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction through the data signal micro-converter, and acquiring third environment illumination data acquired by the photosensitive sensor through the data signal micro-converter when the acquisition parameter configuration information is input to the data signal micro-converter by the photosensitive sensor;

generating a self-adaptive adjusting instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data, and issuing the self-adaptive adjusting instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjusting instruction.

Optionally, based on the signal access application, the data signal micro-converter issues a light adjustment instruction to enable the data signal micro-converter to send the light adjustment instruction to an intelligent light bank arranged outside the chassis, and the method specifically includes:

analyzing the signal access application to obtain an access protocol of the signal access application, and extracting protocol fields of the access protocol to obtain a protocol field set comprising protocol authentication fields and equipment identification information corresponding to the protocol authentication fields;

judging according to the protocol field set, extracting coded signals of a target protocol authentication field in the protocol field set meeting preset control conditions, and acquiring signal coding distribution information between the data signal micro-converter and the intelligent lamp group;

and generating a light adjustment instruction according to the signal coding distribution information, and issuing the light adjustment instruction to the data signal micro-converter according to an instruction frequency band corresponding to the preset control condition, so that the data signal micro-converter sends the light adjustment instruction to an intelligent lamp group arranged outside the case.

Optionally, the acquiring, by the data signal micro-converter, the second ambient light data collected by the photosensitive sensor at regular time specifically includes:

determining the corresponding acquisition time step of the photosensitive sensor according to the position information of the photosensitive sensor;

and acquiring second ambient light data acquired by the photosensitive sensor through the data signal micro-converter according to the acquisition time step.

Optionally, the acquiring parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction is acquired by the data signal micro-converter, and the acquiring parameter configuration information specifically includes:

acquiring sensing response data uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction;

and constructing a first data characteristic and a second data characteristic of the sensing response data, and mapping first characteristic information with the maximum characteristic identification degree in the first data characteristic to a configuration text corresponding to second characteristic information with a configuration identifier in the second data characteristic to obtain the acquisition parameter configuration information.

Optionally, the generating a self-adaptive adjustment command according to the first environmental illumination data, the second environmental illumination data, and the third environmental illumination data and issuing the self-adaptive adjustment command to the intelligent lamp group through the data signal micro-converter includes:

determining a first illumination intensity change track between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data and a second illumination intensity change track between the second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data;

for the first environment illumination data, performing environment weight weighting on the first environment illumination data according to the first illumination intensity variation track by taking the first illumination intensity distribution information as a reference distribution to obtain fourth environment illumination data; for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity variation track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data;

respectively carrying out illumination intensity curve drawing on the first environment illumination data, the second environment illumination data, the fourth environment illumination data, the second environment illumination data, the third environment illumination data, the second environment illumination data and the fifth environment illumination data to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information and fourth illumination intensity curve information;

determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information;

judging whether the first curve similarity and the second curve similarity both fall into a preset similarity interval or not;

if yes, determining instruction generation logic information for performing self-adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating a self-adaptive adjustment instruction according to the fitting result, and issuing the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

Optionally, the method further comprises:

if the first curve similarity and the second curve similarity do not fall into a preset similarity interval, respectively determining a first interval difference value and a second interval difference value between the first curve similarity and the preset similarity interval and between the second curve similarity and the preset similarity interval;

comparing the magnitude of the first interval difference value and the magnitude of the second interval difference value;

when the first interval difference value is smaller than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the second illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

Optionally, the method further comprises:

when the first interval difference value is larger than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the third illumination intensity curve information and the fourth illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

The second aspect provides a wireless remote control unit of quick-witted case light, is applied to light microcontroller, light microcontroller sets up in the inside of quick-witted case, the device includes:

the instruction issuing module is used for acquiring first environment illumination data acquired by the photosensitive sensor based on the data signal micro-converter and issuing a light adjusting instruction to the data signal micro-converter based on the signal access application so that the data signal micro-converter sends the light adjusting instruction to an intelligent lamp group arranged outside the case when receiving a signal access application uploaded by the photosensitive sensor through the data signal micro-converter;

the timing acquisition module is used for acquiring second environment illumination data acquired by the photosensitive sensor in a timing manner through the data signal micro-converter when the intelligent lamp bank emits light according to the light adjustment instruction;

the information acquisition module is used for acquiring acquisition parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the lamplight adjustment instruction through the data signal micro-converter when detecting environment lamplight response information sent by the intelligent lamp bank, and acquiring third environment illumination data acquired by the photosensitive sensor through the data signal micro-converter when the photosensitive sensor inputs the acquisition parameter configuration information to the data signal micro-converter;

and the light adjusting module is used for generating a self-adaptive adjusting instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data and issuing the self-adaptive adjusting instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjusting instruction.

Optionally, the light adjustment module is specifically configured to:

determining a first illumination intensity change track between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data and a second illumination intensity change track between the second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data;

for the first environment illumination data, performing environment weight weighting on the first environment illumination data according to the first illumination intensity variation track by taking the first illumination intensity distribution information as a reference distribution to obtain fourth environment illumination data; for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity variation track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data;

respectively carrying out illumination intensity curve drawing on the first environment illumination data, the second environment illumination data, the fourth environment illumination data, the second environment illumination data, the third environment illumination data, the second environment illumination data and the fifth environment illumination data to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information and fourth illumination intensity curve information;

determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information;

judging whether the first curve similarity and the second curve similarity both fall into a preset similarity interval or not;

if yes, determining instruction generation logic information for performing self-adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating a self-adaptive adjustment instruction according to the fitting result, and issuing the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

In a third aspect, a storable medium having a program stored thereon, the program when executed by a processor implementing the above-described wireless remote control method for a cabinet light is provided.

The wireless remote control method, the wireless remote control device and the storable medium for the light of the machine case provided by the embodiment of the invention can acquire first environment illumination data, second environment illumination data and third environment illumination data collected by the photosensitive sensor through the data signal micro-converter when receiving a signal access application uploaded by the photosensitive sensor through the data signal micro-converter, when the intelligent lamp group emits light according to the light adjustment instruction and when environment light response information sent by the intelligent lamp group is detected, generate a self-adaptive adjustment instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data and send the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjustment instruction. Therefore, the light of the chassis can be adaptively adjusted and controlled according to the illumination condition of the actual environment.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a flowchart of a wireless remote control method for a cabinet light according to an embodiment of the present invention.

Fig. 2 is a functional block diagram of a wireless remote control device for a cabinet light according to an embodiment of the present invention.

Fig. 3 is a block diagram of a lighting microcontroller according to an embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

In order to better understand the technical solutions of the present invention, the following detailed descriptions of the technical solutions of the present invention are provided with the accompanying drawings and the specific embodiments, and it should be understood that the specific features in the embodiments and the examples of the present invention are the detailed descriptions of the technical solutions of the present invention, and are not limitations of the technical solutions of the present invention, and the technical features in the embodiments and the examples of the present invention may be combined with each other without conflict.

Referring first to fig. 1, a flowchart of a wireless remote control method for a cabinet light is provided, where the method may be applied to a light microcontroller disposed inside a cabinet, and the method includes the following steps S110 to S140.

Step S110, when receiving the signal access application that photosensitive sensor passed through the data signal micro-converter and uploaded, based on the data signal micro-converter acquires the first environment illumination data that photosensitive sensor gathered and based on the signal access application to the data signal micro-converter issues light adjustment instruction so that the data signal micro-converter will light adjustment instruction sends for setting up and is in the outside intelligent banks of quick-witted case.

And step S120, when the intelligent lamp bank emits light according to the light adjusting instruction, acquiring second environment illumination data acquired by the photosensitive sensor at regular time through the data signal micro-converter.

Step S130, when detecting the environment light response information sent by the intelligent lamp group, acquiring acquisition parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction through the data signal micro-converter, and acquiring third environment illumination data acquired by the photosensitive sensor through the data signal micro-converter when the photosensitive sensor inputs the acquisition parameter configuration information to the data signal micro-converter.

Step S140, generating a self-adaptive adjustment command according to the first environmental illumination data, the second environmental illumination data, and the third environmental illumination data, and issuing the self-adaptive adjustment command to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts a light emitting state based on the self-adaptive adjustment command.

In this embodiment, the first environment illumination data, the second environment illumination data, and the third environment illumination data are illumination intensity data in an environment where the chassis is located.

Based on the contents described in the above steps S110 to S140, when a signal access application uploaded by the photosensitive sensor through the data signal micro-converter is received, the intelligent lamp group emits light according to the light adjustment instruction, and when the environment light response information sent by the intelligent lamp group is detected, the data signal micro-converter can obtain the first environment light data, the second environment light data, and the third environment light data collected by the photosensitive sensor, generate the adaptive adjustment instruction according to the first environment light data, the second environment light data, and the third environment light data, and issue the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the adaptive adjustment instruction. Therefore, the light of the chassis can be adaptively adjusted and controlled according to the illumination condition of the actual environment.

In an alternative embodiment, in order to ensure the accuracy of the light adjustment command, the issuing of the light adjustment command to the data signal micro-converter based on the signal access application, which is described in step S110, so that the data signal micro-converter sends the light adjustment command to the intelligent light group disposed outside the chassis may specifically include the following contents described in step S111 to step S113.

Step S111, analyzing the signal access application to obtain an access protocol of the signal access application, and extracting protocol fields of the access protocol to obtain a protocol field set comprising protocol authentication fields and equipment identification information corresponding to the protocol authentication fields.

And step S112, judging according to the protocol field set, extracting a coded signal of a target protocol authentication field in the protocol field set meeting preset control conditions, and acquiring signal coding distribution information between the data signal micro-converter and the intelligent lamp group.

And step S113, generating a light adjustment instruction according to the signal coding distribution information, and sending the light adjustment instruction to the data signal micro-converter according to an instruction frequency band corresponding to the preset control condition, so that the data signal micro-converter sends the light adjustment instruction to an intelligent lamp group arranged outside the case.

When the contents described in the above steps S111 to S113 are applied, the accuracy of the light adjustment instruction can be ensured.

In an implementation manner, the step S120 of obtaining the second ambient lighting data collected by the photosensitive sensor through the data signal micro-converter at regular time may specifically include the following steps: and determining a corresponding acquisition time step of the photosensitive sensor according to the position information of the photosensitive sensor, and acquiring second environment illumination data acquired by the photosensitive sensor through the data signal micro-converter according to the acquisition time step. In this way, real-time and flexibility of the second ambient lighting data acquisition may be ensured.

In detail, in order to accurately and completely determine the acquisition parameter configuration information, the acquisition of the acquisition parameter configuration information uploaded by the photosensitive sensor to the data signal micro-converter based on the light adjustment instruction through the data signal micro-converter in step S130 specifically includes the contents described in step S131 and step S132 below.

And S131, acquiring sensing response data uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjusting instruction.

Step S132, constructing a first data feature and a second data feature of the sensing response data, and mapping first feature information having a maximum feature recognition degree in the first data feature to a configuration text corresponding to second feature information having a configuration identifier in the second data feature to obtain the acquisition parameter configuration information.

In this way, based on the contents described in step S131 and step S132, the acquisition parameter configuration information can be determined accurately and completely.

In a more detailed embodiment, in order to ensure accurate adaptive adjustment and control of the intelligent lamp group, the step of generating an adaptive adjustment command according to the first ambient lighting data, the second ambient lighting data and the third ambient lighting data and issuing the adaptive adjustment command to the intelligent lamp group through the data signal micro-converter, which is described in step S140, may specifically include the following steps S141 to S147.

Step S141, determining a first illumination intensity variation trajectory between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data, and a second illumination intensity variation trajectory between second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data.

Step S142, performing, for the first environmental illumination data, environmental weight weighting on the first environmental illumination data according to the first illumination intensity variation trajectory by using the first illumination intensity distribution information as a reference distribution to obtain fourth environmental illumination data; and for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity change track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data.

Step S143, respectively subjecting the first environment illumination data and the second environment illumination data, the first environment illumination data and the fourth environment illumination data, the second environment illumination data and the third environment illumination data, and the second environment illumination data and the fifth environment illumination data to illumination intensity curve drawing to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information, and fourth illumination intensity curve information.

Step S144, determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information, and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information.

Step S145, judging whether the first curve similarity and the second curve similarity both fall within a preset similarity interval.

Step S146, if yes, determining instruction generation logic information for adaptive adjustment of the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating the adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

Step S147, if not, respectively determining a first interval difference value and a second interval difference value between the first curve similarity and the second curve similarity and the preset similarity interval; comparing the magnitude of the first interval difference value and the magnitude of the second interval difference value; when the first interval difference value is smaller than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the second illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter; when the first interval difference value is larger than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the third illumination intensity curve information and the fourth illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

In practical implementation, by applying the contents described in the above steps S141 to S147, accurate adaptive adjustment and control of the intelligent lamp set can be ensured.

Based on the same inventive concept, please refer to fig. 2 in combination, a wireless remote control device 200 for light of a chassis is provided, which is applied to a light microcontroller, the light microcontroller is disposed inside the chassis, and the device includes:

the instruction issuing module 210 is configured to, when receiving a signal access application uploaded by a photosensitive sensor through a data signal micro-converter, acquire first environment illumination data acquired by the photosensitive sensor based on the data signal micro-converter and issue a light adjustment instruction to the data signal micro-converter based on the signal access application, so that the data signal micro-converter sends the light adjustment instruction to an intelligent light group arranged outside the chassis;

the timing acquisition module 220 is configured to acquire second ambient illumination data acquired by the photosensitive sensor at regular time through the data signal micro-converter when the intelligent lamp bank emits light according to the light adjustment instruction;

an information obtaining module 230, configured to, when detecting ambient light response information sent by the intelligent light bank, obtain, by the data signal micro-converter, acquisition parameter configuration information uploaded by the photosensitive sensor to the data signal micro-converter based on the light adjustment instruction, and obtain, by the data signal micro-converter, third ambient light data acquired by the photosensitive sensor when the photosensitive sensor inputs the acquisition parameter configuration information to the data signal micro-converter;

and a light adjusting module 240, configured to generate a self-adaptive adjustment instruction according to the first environment illumination data, the second environment illumination data, and the third environment illumination data, and send the self-adaptive adjustment instruction to the intelligent light group through the data signal micro-converter, so that the intelligent light group adjusts a light emitting state based on the self-adaptive adjustment instruction.

Optionally, the light adjustment module 240 is specifically configured to:

determining a first illumination intensity change track between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data and a second illumination intensity change track between the second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data;

for the first environment illumination data, performing environment weight weighting on the first environment illumination data according to the first illumination intensity variation track by taking the first illumination intensity distribution information as a reference distribution to obtain fourth environment illumination data; for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity variation track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data;

respectively carrying out illumination intensity curve drawing on the first environment illumination data, the second environment illumination data, the fourth environment illumination data, the second environment illumination data, the third environment illumination data, the second environment illumination data and the fifth environment illumination data to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information and fourth illumination intensity curve information;

determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information;

judging whether the first curve similarity and the second curve similarity both fall into a preset similarity interval or not;

if yes, determining instruction generation logic information for performing self-adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating a self-adaptive adjustment instruction according to the fitting result, and issuing the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter;

if not, respectively determining a first interval difference value and a second interval difference value between the first curve similarity and the second curve similarity and the preset similarity interval; comparing the magnitude of the first interval difference value and the magnitude of the second interval difference value; when the first interval difference value is smaller than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the second illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter; when the first interval difference value is larger than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the third illumination intensity curve information and the fourth illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

In the embodiment of the present invention, as shown in fig. 3, the light microcontroller 300 includes at least one processor 301, at least one memory 302 connected to the processor 301, and a bus 303; wherein, the processor 301 and the memory 302 complete the communication with each other through the bus 303; the processor 301 is configured to call the program instructions in the memory 302 to execute the above-mentioned wireless remote control method of the box light.

Further, a storable medium is provided on which a program is stored, which when executed by the processor 301 implements the cabinet light wireless remote control method as shown in fig. 1.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, systems, and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing server to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing server, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

In a typical configuration, a server includes one or more processors (CPUs), memory, and a bus. The server may also include input/output interfaces, network interfaces, and the like.

The memory may include volatile memory in a computer readable medium, Random Access Memory (RAM) and/or nonvolatile memory such as Read Only Memory (ROM) or flash memory (flash RAM), and the memory includes at least one memory chip. The memory is an example of a computer-readable medium.

Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read Only Memory (ROM), Electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), Digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape storage or other magnetic storage servers, or any other non-transmission medium that can be used to store information that can be accessed by a computing server. As defined herein, a computer readable medium does not include a transitory computer readable medium such as a modulated data signal and a carrier wave.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or server that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or server. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, method, article, or server comprising the element.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The above are merely examples of the present application and are not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. The wireless remote control method for the light of the case is characterized by being applied to a light microcontroller, wherein the light microcontroller is arranged in the case, and the method comprises the following steps:

when a signal access application uploaded by a photosensitive sensor through a data signal micro-converter is received, acquiring first environment illumination data acquired by the photosensitive sensor based on the data signal micro-converter and issuing a lamplight adjusting instruction to the data signal micro-converter based on the signal access application so that the data signal micro-converter sends the lamplight adjusting instruction to an intelligent lamp bank arranged outside the case;

when the intelligent lamp set emits light according to the light adjusting instruction, the data signal micro-converter is used for acquiring second environment illumination data collected by the photosensitive sensor at regular time;

when environment light response information sent by the intelligent lamp bank is detected, acquiring acquisition parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction through the data signal micro-converter, and acquiring third environment illumination data acquired by the photosensitive sensor through the data signal micro-converter when the acquisition parameter configuration information is input to the data signal micro-converter by the photosensitive sensor;

generating a self-adaptive adjusting instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data, and issuing the self-adaptive adjusting instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjusting instruction.

2. The method according to claim 1, wherein issuing a lighting adjustment instruction to the data signal micro-converter based on the signal access application so that the data signal micro-converter sends the lighting adjustment instruction to an intelligent light group disposed outside the chassis specifically includes:

analyzing the signal access application to obtain an access protocol of the signal access application, and extracting protocol fields of the access protocol to obtain a protocol field set comprising protocol authentication fields and equipment identification information corresponding to the protocol authentication fields;

judging according to the protocol field set, extracting coded signals of a target protocol authentication field in the protocol field set meeting preset control conditions, and acquiring signal coding distribution information between the data signal micro-converter and the intelligent lamp group;

and generating a light adjustment instruction according to the signal coding distribution information, and issuing the light adjustment instruction to the data signal micro-converter according to an instruction frequency band corresponding to the preset control condition, so that the data signal micro-converter sends the light adjustment instruction to an intelligent lamp group arranged outside the case.

3. The method of claim 1, wherein the periodically acquiring, by the data signal micro-converter, the second ambient lighting data collected by the light sensitive sensor comprises:

determining the corresponding acquisition time step of the photosensitive sensor according to the position information of the photosensitive sensor;

and acquiring second ambient light data acquired by the photosensitive sensor through the data signal micro-converter according to the acquisition time step.

4. The method according to claim 1, wherein acquiring, by the data signal micro-converter, the acquisition parameter configuration information uploaded by the photosensor to the data signal micro-converter based on the light adjustment instruction specifically comprises:

acquiring sensing response data uploaded to the data signal micro-converter by the photosensitive sensor based on the light adjustment instruction;

and constructing a first data characteristic and a second data characteristic of the sensing response data, and mapping first characteristic information with the maximum characteristic identification degree in the first data characteristic to a configuration text corresponding to second characteristic information with a configuration identifier in the second data characteristic to obtain the acquisition parameter configuration information.

5. The wireless remote control method of cabinet light according to any one of claims 1 to 4, wherein the generating a self-adaptive adjustment command according to the first environment light data, the second environment light data and the third environment light data and issuing the self-adaptive adjustment command to the intelligent light group through the data signal micro-converter comprises:

determining a first illumination intensity change track between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data and a second illumination intensity change track between the second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data;

for the first environment illumination data, performing environment weight weighting on the first environment illumination data according to the first illumination intensity variation track by taking the first illumination intensity distribution information as a reference distribution to obtain fourth environment illumination data; for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity variation track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data;

respectively carrying out illumination intensity curve drawing on the first environment illumination data, the second environment illumination data, the fourth environment illumination data, the second environment illumination data, the third environment illumination data, the second environment illumination data and the fifth environment illumination data to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information and fourth illumination intensity curve information;

determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information;

judging whether the first curve similarity and the second curve similarity both fall into a preset similarity interval or not;

if yes, determining instruction generation logic information for performing self-adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating a self-adaptive adjustment instruction according to the fitting result, and issuing the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

6. The method of claim 5, further comprising:

if the first curve similarity and the second curve similarity do not fall into a preset similarity interval, respectively determining a first interval difference value and a second interval difference value between the first curve similarity and the preset similarity interval and between the second curve similarity and the preset similarity interval;

comparing the magnitude of the first interval difference value and the magnitude of the second interval difference value;

when the first interval difference value is smaller than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the second illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

7. The method of claim 6, further comprising:

when the first interval difference value is larger than the second interval difference value, determining instruction generation logic information for performing adaptive adjustment on the intelligent lamp group according to the third illumination intensity curve information and the fourth illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating an adaptive adjustment instruction according to the fitting result, and issuing the adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

8. The utility model provides a wireless remote control unit of quick-witted case light, its characterized in that is applied to light microcontroller, light microcontroller sets up in the inside of quick-witted case, the device includes:

the instruction issuing module is used for acquiring first environment illumination data acquired by the photosensitive sensor based on the data signal micro-converter and issuing a light adjusting instruction to the data signal micro-converter based on the signal access application so that the data signal micro-converter sends the light adjusting instruction to an intelligent lamp group arranged outside the case when receiving a signal access application uploaded by the photosensitive sensor through the data signal micro-converter;

the timing acquisition module is used for acquiring second environment illumination data acquired by the photosensitive sensor in a timing manner through the data signal micro-converter when the intelligent lamp bank emits light according to the light adjustment instruction;

the information acquisition module is used for acquiring acquisition parameter configuration information uploaded to the data signal micro-converter by the photosensitive sensor based on the lamplight adjustment instruction through the data signal micro-converter when detecting environment lamplight response information sent by the intelligent lamp bank, and acquiring third environment illumination data acquired by the photosensitive sensor through the data signal micro-converter when the photosensitive sensor inputs the acquisition parameter configuration information to the data signal micro-converter;

and the light adjusting module is used for generating a self-adaptive adjusting instruction according to the first environment illumination data, the second environment illumination data and the third environment illumination data and issuing the self-adaptive adjusting instruction to the intelligent lamp group through the data signal micro-converter, so that the intelligent lamp group adjusts the light emitting state based on the self-adaptive adjusting instruction.

9. The device of claim 8, wherein the light adjustment module is specifically configured to:

determining a first illumination intensity change track between first illumination intensity distribution information corresponding to the first environment illumination data and second illumination intensity distribution information corresponding to the second environment illumination data and a second illumination intensity change track between the second illumination intensity distribution information corresponding to the second environment illumination data and third illumination intensity distribution information corresponding to the third environment illumination data;

for the first environment illumination data, performing environment weight weighting on the first environment illumination data according to the first illumination intensity variation track by taking the first illumination intensity distribution information as a reference distribution to obtain fourth environment illumination data; for the second environment illumination data, performing environment weight weighting on the second environment illumination data according to the second illumination intensity variation track by taking the second illumination intensity distribution information as a reference distribution to obtain fifth environment illumination data;

respectively carrying out illumination intensity curve drawing on the first environment illumination data, the second environment illumination data, the fourth environment illumination data, the second environment illumination data, the third environment illumination data, the second environment illumination data and the fifth environment illumination data to obtain first illumination intensity curve information, second illumination intensity curve information, third illumination intensity curve information and fourth illumination intensity curve information;

determining a first curve similarity between the first illumination intensity curve information and the second illumination intensity curve information and a second curve similarity between the third illumination intensity curve information and the fourth illumination intensity curve information;

judging whether the first curve similarity and the second curve similarity both fall into a preset similarity interval or not;

if yes, determining instruction generation logic information for performing self-adaptive adjustment on the intelligent lamp group according to the first illumination intensity curve information and the third illumination intensity curve information, fitting the first environment illumination data, the second environment illumination data and the third environment illumination data according to the instruction generation logic information, generating a self-adaptive adjustment instruction according to the fitting result, and issuing the self-adaptive adjustment instruction to the intelligent lamp group through the data signal micro-converter.

10. A storable medium having a program stored thereon, the program, when executed by a processor, implementing the cabinet light wireless remote control method according to any one of claims 1 to 7.

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