CN116321610B - Intelligent light control method and control system - Google Patents

Abstract

The application belongs to the field of intelligent lamplight, relates to a data analysis technology, and is used for solving the problem that the prior art cannot analyze the behavior characteristics of a user in the process of automatic brightness adjustment control, in particular to an intelligent lamplight control method and a control system, wherein the intelligent lamplight control method comprises a processor, and the processor is in communication connection with a brightness control module, a switching analysis module, an operation analysis module and a storage module; the brightness control module is used for controlling and analyzing the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode; the switching analysis module is used for analyzing the brightness switching state of the intelligent lamplight; the intelligent lighting system can control and analyze the lighting brightness of intelligent lighting, comprehensively analyze and calculate various parameters in a lighting area through an automatic mode to obtain a control coefficient, and can directly regulate the brightness according to a control gear in the next control period.

Description

Intelligent light control method and control system

Technical Field

The application belongs to the field of intelligent lamplight, relates to a data analysis technology, and particularly relates to an intelligent lamplight control method and a control system.

Background

The intelligent lighting system is a system for intelligent control and management of light, compared with traditional lighting, the intelligent lighting system can realize light soft start, dimming, one-to-one remote control, partition light full-on and full-off management and the like, can use various control modes such as remote control, timing, concentration, remote control and the like, and even uses a computer to carry out advanced intelligent control on the light, thereby achieving the functions of energy conservation, environmental protection, comfort and convenience of intelligent lighting.

The existing intelligent light control method and control system generally have the function of automatic brightness adjustment control, but the user behavior characteristics cannot be analyzed in the process of automatic brightness adjustment control, the automatic brightness adjustment according to a fixed program may cause the problems of overhigh adjustment frequency, shortened light service life and reduced user experience caused by overhigh light brightness switching frequency.

The application provides a solution to the technical problem.

Disclosure of Invention

The application aims to provide an intelligent light control method and a control system, which are used for solving the problem that the existing intelligent light control method and control system cannot analyze the behavior characteristics of a user in the process of automatic brightness adjustment control;

the technical problems to be solved by the application are as follows: how to provide an intelligent light control method and a control system capable of analyzing the behavior characteristics of a user in the process of automatic brightness adjustment control.

The aim of the application can be achieved by the following technical scheme:

an intelligent light control system comprises a processor, wherein the processor is in communication connection with a brightness control module, a switching analysis module, an operation analysis module and a storage module;

the brightness control module is used for controlling and analyzing the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode;

the switching analysis module is used for analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, a control set is formed by the control gears of adjacent control periods, and whether two control gears in the control set are identical or not is judged: if the control sets are the same, marking the control sets as stable sets; if the control sets are different, marking the control sets as switching sets, marking the quantity ratio of the switching sets to the control sets as switching coefficients, acquiring a switching threshold value through a storage module, and comparing the switching coefficients with the switching threshold value: if the switching coefficient is smaller than the switching threshold value, not carrying out combined analysis on the control period; if the switching coefficient is greater than or equal to the switching threshold value, carrying out combined analysis on the control period;

the operation analysis module is used for monitoring and analyzing the operation state of the intelligent lamplight.

As a preferred embodiment of the present application, the process of controlling illumination brightness using the fixed mode includes: the method comprises the steps that a user selects one gear as a fixed gear in fixed brightness gears, and when the user selects a fixed mode to carry out illumination brightness, the illumination gear of intelligent lamplight is adjusted to the fixed gear;

the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, and acquiring sound data SY and vibration data ZD of an illumination area in the control periods, wherein the process for acquiring the sound data SY comprises the following steps: acquiring noise decibel values in an illumination area in real time, and marking the maximum value of the noise decibel values in the illumination area in a control period as sound data SY; the process of obtaining the vibration data ZD includes: acquiring a vibration frequency value of the floor in the illumination area in real time, and marking the maximum value of the vibration frequency value of the floor in the illumination area in a control period as vibration data ZD; obtaining a control coefficient KZ of a control period by carrying out numerical calculation on sound data SY and vibration data ZD; the control interval and the brightness gear are obtained through the storage module, the control interval corresponds to the brightness gear one by one, the brightness gear corresponding to the control interval is marked as the control gear by the control coefficient KZ of the control period, and the brightness of the intelligent lamplight is adjusted to the control gear when the next control period starts.

As a preferred embodiment of the present application, the specific process of performing the merging analysis on the control period includes: the average value of the maximum value and the minimum value of the control coefficient of the control range corresponding to the control range is marked as the control standard value of the control range, the absolute value of the difference value of the control standard values of the two control ranges in the switching set is marked as the control amplitude value of the switching set, the control amplitude threshold value is obtained through the storage module, and the control amplitude value is compared with the control amplitude threshold value: if the amplitude control value is smaller than the amplitude control threshold value, marking the corresponding switching set as a low amplitude set; if the amplitude control value is greater than or equal to the amplitude control threshold value, marking the corresponding switching set as a high-amplitude set; and forming a control set by using control standard values corresponding to the control gears of all the low-amplitude sets, performing variance calculation on the control set to obtain a behavior coefficient, acquiring a behavior threshold value through a storage module, comparing the behavior coefficient with the behavior threshold value, and judging whether the monitoring period has a merging characteristic or not through a comparison result.

As a preferred embodiment of the present application, the specific process of comparing the behavior coefficient with the behavior threshold value includes: if the behavior coefficient is greater than or equal to the behavior threshold, judging that the control period does not have the merging characteristic; if the behavior coefficient is smaller than the behavior threshold, judging that the control period has a merging characteristic, sorting the control gears according to the sequence of the number of elements in the control set from more to less, marking the control gear with the first sorting as a preselected gear, respectively marking the element sorting corresponding to two adjacent control intervals of the control interval corresponding to the preselected gear as a high-order value and a low-order value, and forming a merging set by the sorting value as one and the low-order value; and marking the control gear with the second sequence as a preselected gear and reconstructing a merging set, and so on, marking the last control gear with the second sequence as the preselected gear and obtaining a merging set, summing two elements in the merging set and taking an average value to obtain a merging value of the merging set, merging the two control gears in the merging set with the smallest merging value to obtain a merging gear, and forming a control interval of the merging gear by the control coefficient minimum value and the control coefficient maximum value of the control interval corresponding to the two control gears.

As a preferred embodiment of the application, the specific process of monitoring and analyzing the operation state of the intelligent lamplight by the operation analysis module comprises the following steps: acquiring external temperature data WW and current data DL of intelligent lamplight in a control period; the operation coefficient YX of the intelligent lamplight is obtained by carrying out numerical calculation on external temperature data WW and current data DL; the operation threshold value YXmax is obtained through the storage module, the operation coefficient YX of the intelligent lamplight is compared with the operation threshold value YXmax, and whether the operation state of the intelligent lamplight in the control period meets the requirement or not is judged according to the comparison result.

As a preferred embodiment of the present application, the external temperature data WW is a maximum value of an air temperature value of the intelligent lighting area within a control period, and the process of acquiring the current data DL includes: obtaining the maximum value and the minimum value of the current value of the intelligent light connection circuit in the control period, marking the average value of the maximum value and the minimum value of the current value in the control period as a flow average value, marking the difference value of the maximum value and the minimum value of the current value in the control period as a flow difference value, and marking the sum value of the flow average value and the flow difference value as current data DL.

A method of intelligent light control, comprising the steps of:

step one: control and analyze the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode;

step two: the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, acquiring sound data SY and vibration data ZD of an illumination area in the control period, performing numerical calculation to obtain a control coefficient KZ, acquiring a control gear through the control coefficient KZ, and adjusting the brightness of intelligent lamplight to the control gear when the next control period starts;

step three: and analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, forming a control set by the control gears of adjacent control periods, marking the control set as a switching set or a stable set, marking the number ratio of the switching set to the control set as a switching coefficient, and judging whether the control period is subjected to combination analysis or not through the switching coefficient;

step four: monitoring and analyzing the running state of intelligent lamplight: and acquiring external temperature data WW and current data DL of the intelligent lamplight in the control period, performing numerical calculation to obtain an operation coefficient YX, and judging whether the operation state of the intelligent lamplight in the control period meets the requirement or not according to the numerical value of the operation coefficient YX.

The application has the following beneficial effects:

1. the illumination brightness of the intelligent lamplight can be controlled and analyzed through the brightness control module, the selection space of a user is improved through a double-mode control mode, and the control coefficients are obtained through comprehensive analysis and calculation of various parameters in an illumination area through an automatic mode, so that the corresponding control gear is selected through the control coefficients, and the brightness can be directly adjusted according to the control gear in the next control period;

2. the brightness switching state of intelligent lamplight can be analyzed through the switching analysis module, the combination analysis necessity is fed back through the control gear distribution condition of each control period, the switching relevance among all control gears is analyzed when the combination analysis is needed, the two control gears with the highest relevance degree are combined, and the gear switching frequency is reduced while the illumination effect is ensured;

3. the intelligent lamplight control system has the advantages that the operation analysis module can monitor and analyze the operation state of the intelligent lamplight, and the operation coefficient is obtained by comprehensively analyzing and calculating each operation parameter of the intelligent lamplight in a control period, so that the operation state of the intelligent lamplight is fed back through the operation coefficient, early warning is timely carried out when the operation state is abnormal, and the service life of the intelligent lamplight is prolonged.

Drawings

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

FIG. 1 is a system block diagram of a first embodiment of the present application;

fig. 2 is a flowchart of a method according to a second embodiment of the application.

Detailed Description

The technical solutions of the present application will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Example 1

As shown in fig. 1, an intelligent lighting control system includes a processor, and the processor is communicatively connected with a brightness control module, a switching analysis module, an operation analysis module and a storage module.

The brightness control module is used for controlling and analyzing the illumination brightness of the intelligent lamplight: the illumination brightness control mode of intelligent light includes fixed mode and automatic mode, adopts the process of fixed mode to carry out illumination brightness control to include: the method comprises the steps that a user selects one gear as a fixed gear in fixed brightness gears, and when the user selects a fixed mode to carry out illumination brightness, the illumination gear of intelligent lamplight is adjusted to the fixed gear; the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, and acquiring sound data SY and vibration data ZD of an illumination area in the control periods, wherein the process for acquiring the sound data SY comprises the following steps: acquiring noise decibel values in an illumination area in real time, and marking the maximum value of the noise decibel values in the illumination area in a control period as sound data SY; the process of obtaining the vibration data ZD includes: acquiring a vibration frequency value of the floor in the illumination area in real time, and marking the maximum value of the vibration frequency value of the floor in the illumination area in a control period as vibration data ZD; obtaining a control coefficient KZ of a control period through a formula KZ=α1×SY+α2×ZD, wherein α1 and α2 are both proportional coefficients, and α1 > α2 > 1; the control interval and the brightness gear are obtained through the storage module, the control interval corresponds to the brightness gear one by one, the brightness gear corresponding to the control interval of the control coefficient KZ of the control period is marked as the control gear, and the brightness of the intelligent lamplight is adjusted to the control gear when the next control period starts; the intelligent lamplight brightness control system comprises a control system, a control system and a control system, wherein the control system is used for controlling and analyzing the illumination brightness of intelligent lamplight, improving the selection space of a user in a dual-mode control mode, comprehensively analyzing and calculating various parameters in an illumination area in an automatic mode to obtain control coefficients, selecting a corresponding control gear through the control coefficients, and adjusting the brightness according to the control gear in the next control period.

The switching analysis module is used for analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, a control set is formed by the control gears of adjacent control periods, and whether two control gears in the control set are identical or not is judged: if the control sets are the same, marking the control sets as stable sets; if the control sets are different, marking the control sets as switching sets, marking the quantity ratio of the switching sets to the control sets as switching coefficients, acquiring a switching threshold value through a storage module, and comparing the switching coefficients with the switching threshold value: if the switching coefficient is smaller than the switching threshold value, not carrying out combined analysis on the control period; if the switching coefficient is greater than or equal to the switching threshold, carrying out combined analysis on the control period: the average value of the maximum value and the minimum value of the control coefficient of the control range corresponding to the control range is marked as the control standard value of the control range, the absolute value of the difference value of the control standard values of the two control ranges in the switching set is marked as the control amplitude value of the switching set, the control amplitude threshold value is obtained through the storage module, and the control amplitude value is compared with the control amplitude threshold value: if the amplitude control value is smaller than the amplitude control threshold value, marking the corresponding switching set as a low amplitude set; if the amplitude control value is greater than or equal to the amplitude control threshold value, marking the corresponding switching set as a high-amplitude set; the control set is formed by control standard values corresponding to the control gears of all low-amplitude sets, variance calculation is carried out on the control set to obtain a behavior coefficient, a behavior threshold is obtained through a storage module, and the behavior coefficient is compared with the behavior threshold: if the behavior coefficient is greater than or equal to the behavior threshold, judging that the control period does not have the merging characteristic; if the behavior coefficient is smaller than the behavior threshold, judging that the control period has a merging characteristic, sorting the control gears according to the sequence of the number of elements in the control set from more to less, marking the control gear with the first sorting as a preselected gear, respectively marking the element sorting corresponding to two adjacent control intervals of the control interval corresponding to the preselected gear as a high-order value and a low-order value, and forming a merging set by the sorting value as one and the low-order value; marking the control gear of the second sequence as a preselected gear and then forming a merging set, and so on, marking the last control gear of the sequence as the preselected gear and obtaining a merging set, summing two elements in the merging set and taking an average value to obtain a merging value of the merging set, merging the two control gears in the merging set with the minimum value of the merging value to obtain a merging gear, and forming a control interval of the merging gear by the minimum value of the control coefficients of the corresponding control intervals of the two control gears and the maximum value of the control coefficients; the brightness switching state of intelligent lamplight is analyzed, the necessity of merging analysis is fed back through the distribution condition of the control gears of each control period, the switching relevance among all the control gears is analyzed when the merging analysis is needed, the two control gears with the highest relevance degree are merged, and the gear switching frequency is reduced while the illumination effect is ensured.

The operation analysis module is used for monitoring and analyzing the operation state of the intelligent lamplight: the method comprises the steps of obtaining external temperature data WW and current data DL of intelligent lamplight in a control period, wherein the external temperature data WW is the maximum value of an air temperature value of an intelligent lamplight illumination area in the control period, and the obtaining process of the current data DL comprises the following steps: obtaining the maximum value and the minimum value of the current value of the intelligent light connection circuit in a control period, marking the average value of the maximum value and the minimum value of the current value in the control period as a flow average value, marking the difference value of the maximum value and the minimum value of the current value in the control period as a flow difference value, and marking the sum value of the flow average value and the flow difference value as current data DL; obtaining an operation coefficient YX of intelligent lamplight through a formula YX=β1WWW+β2xDL, wherein β1 and β2 are proportionality coefficients, and β1 is larger than β2 and larger than 1; the operation threshold value YXmax is obtained through the storage module, and the operation coefficient YX of the intelligent lamplight is compared with the operation threshold value YXmax: if the operation coefficient YX is smaller than the operation threshold YXmax, judging that the operation state of the intelligent lamplight in the control period meets the requirement; if the operation coefficient YX is greater than or equal to the operation threshold YXmax, judging that the operation state of the intelligent lamplight in the control period does not meet the requirement, sending an operation abnormal signal to a processor by an operation analysis module, and sending the operation abnormal signal to a mobile phone terminal of a manager after the processor receives the operation abnormal signal; the intelligent lamplight control system monitors and analyzes the running state of the intelligent lamplight, obtains the running coefficient by comprehensively analyzing and calculating each running parameter of the intelligent lamplight in a control period, feeds back the running state of the intelligent lamplight through the running coefficient, and timely gives an early warning when the running state is abnormal, so that the service life of the intelligent lamplight is prolonged.

Example two

As shown in fig. 2, a method for intelligent light control includes the following steps:

step one: control and analyze the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode;

step two: the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, acquiring sound data SY and vibration data ZD of an illumination area in the control period, performing numerical calculation to obtain a control coefficient KZ, acquiring a control gear through the control coefficient KZ, and adjusting the brightness of intelligent lamplight to the control gear when the next control period starts;

step three: and analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, forming a control set by the control gears of adjacent control periods, marking the control set as a switching set or a stable set, marking the number ratio of the switching set to the control set as a switching coefficient, and judging whether the control period is subjected to combination analysis or not through the switching coefficient;

step four: monitoring and analyzing the running state of intelligent lamplight: and acquiring external temperature data WW and current data DL of the intelligent lamplight in the control period, performing numerical calculation to obtain an operation coefficient YX, and judging whether the operation state of the intelligent lamplight in the control period meets the requirement or not according to the numerical value of the operation coefficient YX.

An intelligent light control method and control system, when in operation, adopts an automatic mode to control the illumination brightness: generating a control period, dividing the control period into a plurality of control periods, acquiring sound data SY and vibration data ZD of an illumination area in the control period, performing numerical calculation to obtain a control coefficient KZ, acquiring a control gear through the control coefficient KZ, and adjusting the brightness of intelligent lamplight to the control gear when the next control period starts; at the end time of the control period, forming a control set by the control gears of adjacent control periods, marking the control set as a switching set or a stable set, marking the number ratio of the switching set to the control set as a switching coefficient, and judging whether the control period is subjected to combination analysis or not through the switching coefficient; and acquiring external temperature data WW and current data DL of the intelligent lamplight in the control period, performing numerical calculation to obtain an operation coefficient YX, and judging whether the operation state of the intelligent lamplight in the control period meets the requirement or not according to the numerical value of the operation coefficient YX.

The foregoing is merely illustrative of the structures of this application and various modifications, additions and substitutions for those skilled in the art can be made to the described embodiments without departing from the scope of the application or from the scope of the application as defined in the accompanying claims.

The formulas are all formulas obtained by collecting a large amount of data for software simulation and selecting a formula close to a true value, and coefficients in the formulas are set by a person skilled in the art according to actual conditions; such as: formula kz=α1×sy+α2×zd; collecting a plurality of groups of sample data by a person skilled in the art and setting a corresponding control coefficient for each group of sample data; substituting the set control coefficient and the acquired sample data into a formula, forming a binary one-time equation set by any two formulas, screening the calculated coefficient and taking an average value to obtain values of alpha 1 and alpha 2 which are respectively 2.34 and 2.16;

the size of the coefficient is a specific numerical value obtained by quantizing each parameter, so that the subsequent comparison is convenient, and the size of the coefficient depends on the number of sample data and the corresponding control coefficient is preliminarily set for each group of sample data by a person skilled in the art; as long as the proportional relation between the parameter and the quantized value is not affected, for example, the control coefficient is proportional to the value of the sound data.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the application disclosed above are intended only to assist in the explanation of the application. The preferred embodiments are not intended to be exhaustive or to limit the application to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the application and the practical application, to thereby enable others skilled in the art to best understand and utilize the application. The application is limited only by the claims and the full scope and equivalents thereof.

Claims (7)

1. The intelligent light control system is characterized by comprising a processor, wherein the processor is in communication connection with a brightness control module, a switching analysis module, an operation analysis module and a storage module;

the brightness control module is used for controlling and analyzing the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode;

the switching analysis module is used for analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, a control set is formed by the control gears of adjacent control periods, and whether two control gears in the control set are identical or not is judged: if the control sets are the same, marking the control sets as stable sets; if the control sets are different, marking the control sets as switching sets, marking the quantity ratio of the switching sets to the control sets as switching coefficients, acquiring a switching threshold value through a storage module, and comparing the switching coefficients with the switching threshold value: if the switching coefficient is smaller than the switching threshold value, not carrying out combined analysis on the control period; if the switching coefficient is greater than or equal to the switching threshold value, carrying out combined analysis on the control period;

the operation analysis module is used for monitoring and analyzing the operation state of the intelligent lamplight.

2. An intelligent lighting control system according to claim 1, wherein the process of using a fixed pattern for lighting intensity control comprises: the method comprises the steps that a user selects one gear as a fixed gear in fixed brightness gears, and when the user selects a fixed mode to carry out illumination brightness, the illumination gear of intelligent lamplight is adjusted to the fixed gear;

the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, and acquiring sound data SY and vibration data ZD of an illumination area in the control periods, wherein the process for acquiring the sound data SY comprises the following steps: acquiring noise decibel values in an illumination area in real time, and marking the maximum value of the noise decibel values in the illumination area in a control period as sound data SY; the process of obtaining the vibration data ZD includes: acquiring a vibration frequency value of the floor in the illumination area in real time, and marking the maximum value of the vibration frequency value of the floor in the illumination area in a control period as vibration data ZD; obtaining a control coefficient KZ of a control period by carrying out numerical calculation on sound data SY and vibration data ZD; the control interval and the brightness gear are obtained through the storage module, the control interval corresponds to the brightness gear one by one, the brightness gear corresponding to the control interval is marked as the control gear by the control coefficient KZ of the control period, and the brightness of the intelligent lamplight is adjusted to the control gear when the next control period starts.

3. An intelligent lighting control system according to claim 2, wherein the specific process of performing the combined analysis of the control periods comprises: the average value of the maximum value and the minimum value of the control coefficient of the control range corresponding to the control range is marked as the control standard value of the control range, the absolute value of the difference value of the control standard values of the two control ranges in the switching set is marked as the control amplitude value of the switching set, the control amplitude threshold value is obtained through the storage module, and the control amplitude value is compared with the control amplitude threshold value: if the amplitude control value is smaller than the amplitude control threshold value, marking the corresponding switching set as a low amplitude set; if the amplitude control value is greater than or equal to the amplitude control threshold value, marking the corresponding switching set as a high-amplitude set; and forming a control set by using control standard values corresponding to the control gears of all the low-amplitude sets, performing variance calculation on the control set to obtain a behavior coefficient, acquiring a behavior threshold value through a storage module, comparing the behavior coefficient with the behavior threshold value, and judging whether the monitoring period has a merging characteristic or not through a comparison result.

4. A smart light control system as claimed in claim 3, wherein the specific process of comparing the behaviour coefficient with the behaviour threshold comprises: if the behavior coefficient is greater than or equal to the behavior threshold, judging that the control period does not have the merging characteristic; if the behavior coefficient is smaller than the behavior threshold, judging that the control period has a merging characteristic, sorting the control gears according to the sequence of the number of elements in the control set from more to less, marking the control gear with the first sorting as a preselected gear, respectively marking the element sorting corresponding to two adjacent control intervals of the control interval corresponding to the preselected gear as a high-order value and a low-order value, and forming a merging set by the sorting value as one and the low-order value; and marking the control gear with the second sequence as a preselected gear and reconstructing a merging set, and so on, marking the last control gear with the second sequence as the preselected gear and obtaining a merging set, summing two elements in the merging set and taking an average value to obtain a merging value of the merging set, merging the two control gears in the merging set with the smallest merging value to obtain a merging gear, and forming a control interval of the merging gear by the control coefficient minimum value and the control coefficient maximum value of the control interval corresponding to the two control gears.

5. The intelligent lighting control system of claim 4, wherein the specific process of the operation analysis module for monitoring and analyzing the operation state of the intelligent lighting comprises: acquiring external temperature data WW and current data DL of intelligent lamplight in a control period; the operation coefficient YX of the intelligent lamplight is obtained by carrying out numerical calculation on external temperature data WW and current data DL; the operation threshold value YXmax is obtained through the storage module, the operation coefficient YX of the intelligent lamplight is compared with the operation threshold value YXmax, and whether the operation state of the intelligent lamplight in the control period meets the requirement or not is judged according to the comparison result.

6. An intelligent lighting control system according to claim 5, wherein the external temperature data WW is the maximum value of the air temperature value of the intelligent lighting area in the control period, and the process of obtaining the current data DL comprises: obtaining the maximum value and the minimum value of the current value of the intelligent light connection circuit in the control period, marking the average value of the maximum value and the minimum value of the current value in the control period as a flow average value, marking the difference value of the maximum value and the minimum value of the current value in the control period as a flow difference value, and marking the sum value of the flow average value and the flow difference value as current data DL.

7. A method for intelligent light control, comprising the steps of:

step one: control and analyze the illumination brightness of intelligent lamplight: the illumination brightness control mode of the intelligent lamplight comprises a fixed mode and an automatic mode;

step two: the process of controlling the illumination brightness in the automatic mode comprises the following steps: generating a control period, dividing the control period into a plurality of control periods, acquiring sound data SY and vibration data ZD of an illumination area in the control period, performing numerical calculation to obtain a control coefficient KZ, acquiring a control gear through the control coefficient KZ, and adjusting the brightness of intelligent lamplight to the control gear when the next control period starts;

step three: and analyzing the brightness switching state of the intelligent lamplight: at the end time of the control period, forming a control set by the control gears of adjacent control periods, marking the control set as a switching set or a stable set, marking the number ratio of the switching set to the control set as a switching coefficient, and judging whether the control period is subjected to combination analysis or not through the switching coefficient;

step four: monitoring and analyzing the running state of intelligent lamplight: and acquiring external temperature data WW and current data DL of the intelligent lamplight in the control period, performing numerical calculation to obtain an operation coefficient YX, and judging whether the operation state of the intelligent lamplight in the control period meets the requirement or not according to the numerical value of the operation coefficient YX.