CN114828352B

CN114828352B - Thing networking lighting control system

Info

Publication number: CN114828352B
Application number: CN202210571933.0A
Authority: CN
Inventors: 胡兴; 张文华; 张家华; 黄武能; 钟霖; 彭涛
Original assignee: Shenzhen Shangwei Photoelectric Engineering Co ltd; Huizhou Xieneng Technology Co ltd; Shenzhen Seva Lighting Co Ltd
Current assignee: Shenzhen Shangwei Photoelectric Engineering Co ltd; Huizhou Xieneng Technology Co ltd; Shenzhen Seva Lighting Co Ltd
Priority date: 2022-05-24
Filing date: 2022-05-24
Publication date: 2023-03-10
Anticipated expiration: 2042-05-24
Also published as: CN114828352A

Abstract

The invention provides an Internet of things illumination control system, which comprises: the monitoring module is used for constructing a control link between the user terminal and the lamp based on the Internet of things, and acquiring configuration parameters of the lamp in the lighting control area and environment parameters of the lighting control area based on the control link; the scheme determination module is used for generating a lighting control scheme based on the lamp configuration parameters and the environment parameters and generating a target control instruction based on the lighting control scheme; and the control module is used for carrying out illumination control on the lamps in the illumination control area through the target control instruction based on the Internet of things and feeding back a control result to the user terminal based on the Internet of things. The corresponding control scheme is determined according to the environmental parameters of the illumination control area and the configuration information of the lamp, so that adaptive illumination is performed on the illumination control area, the energy-saving effect is ensured to be achieved on the premise of normal illumination, and the intelligence of illumination control is improved.

Description

Thing networking lighting control system

Technical Field

The invention relates to the technical field of Internet of things control, in particular to an Internet of things illumination control system.

Background

At present, with the continuous progress of the technology of the internet of things, intelligent equipment plays an indispensable role in the life of people, and the technology of the internet of things and the intelligent equipment are combined to provide great convenience for the life of people;

at present, most of internet-of-things illumination control systems on the market intelligently start or close lamps at regular time, the illumination intensity of the lamps cannot be adjusted according to the current ambient light intensity, and meanwhile, the lamps cannot be controlled to adopt different working powers to adapt to the current ambient requirements, so that the control effect is greatly reduced, and a large amount of energy waste is caused;

therefore, the invention provides an internet of things lighting control system, which is used for determining a corresponding control scheme according to the environmental parameters of a lighting control area and the configuration information of a lamp, so that adaptive lighting of the lighting control area is realized, an energy-saving effect is ensured to be achieved on the premise of normal lighting, and the intelligence of lighting control is improved.

Disclosure of Invention

The invention provides an Internet of things lighting control system which is used for determining a corresponding control scheme according to lighting control area environment parameters and lamp configuration information, so that adaptive lighting of a lighting control area is realized, an energy-saving effect is ensured to be achieved on the premise of normal lighting, and the intelligence of lighting control is improved.

The invention provides an Internet of things illumination control system, which comprises:

the monitoring module is used for constructing a control link between the user terminal and the lamp based on the Internet of things, and acquiring configuration parameters of the lamp in the lighting control area and environment parameters of the lighting control area based on the control link;

a scheme determination module for generating a lighting control scheme based on the configuration parameters and the environmental parameters, and generating target control instructions based on the lighting control scheme;

and the control module is used for carrying out illumination control on the lamps in the illumination control area through the target control instruction based on the Internet of things and feeding back a control result to the user terminal based on the Internet of things.

Preferably, an thing networking lighting control system, monitoring module includes:

the detection unit is used for acquiring a terminal identifier of a lamp in an illumination control area and determining a service type for controlling the lamp based on the terminal identifier;

the link construction unit is used for accessing an Internet of things gateway based on the service type, and the Internet of things gateway allocates a network routing port based on the service type, wherein the network routing port is a bidirectional port and is respectively connected with a user terminal and a lamp of the lighting control area;

the link establishing unit is configured to respectively obtain a first port address and a second port address of a lamp and a user terminal in the lighting control area based on the network routing port, and establish a control link between the user terminal and the lamp based on the first port address, the second port address and the network routing port.

Preferably, an thing networking lighting control system, monitoring module still includes:

the parameter acquisition unit is used for sending an information acquisition instruction to a preset sensor carried by a lamp in the illumination control area based on the control link, and the preset sensor reads configuration parameters of the lamp and acquires environment parameters of the illumination control area based on the information acquisition instruction, wherein the environment parameters comprise natural light brightness of the illumination control area and current time information;

the data feedback unit is used for classifying and compressing the obtained configuration parameters and the obtained environment parameters to obtain a first compressed data packet and a second compressed data packet, and placing the first compressed data packet and the second compressed data packet in a data transmission queue;

the data feedback unit is configured to determine a transmission sequence of the first compressed data packet and the second compressed data packet based on a data transmission queue, and send the first compressed data packet and the second compressed data packet to a user terminal through the control link based on the transmission sequence.

Preferably, an thing networking lighting control system, data feedback unit includes:

the parameter analysis subunit is used for acquiring the acquired configuration parameters of the lamp and the environment parameters of the lighting control area, and respectively determining the category identifiers of the configuration parameters and the environment parameters;

a compression configuration determining subunit, configured to determine, based on the category identifier, compression configurations for the configuration parameter and the environment parameter, respectively, and determine, based on the compression configurations, a relative distance value between each parameter of the configuration parameter and the environment parameter in a preset time sequence period, respectively;

the compressing subunit is configured to determine a number of bytes compressed for the configuration parameter and the environment parameter according to the distribution characteristic of the distance relative value, and compress the configuration parameter and the environment parameter according to the number of bytes compressed based on the compression configuration;

and the packing subunit is configured to set a target packet header respectively based on the configuration parameters and the category identifiers of the environment parameters, and pack the compressed configuration parameters and the environment parameters based on the target packet header.

Preferably, the lighting control system of the internet of things, the scheme determining module, includes:

the parameter acquisition unit is used for acquiring configuration parameters of the lamp and environment parameters of the illumination control area, and respectively determining a first data attribute and a second data attribute corresponding to the configuration parameters and the environment parameters;

the data cleaning unit is used for respectively determining a first data structure and a second data structure of the configuration parameters and the environmental parameters based on the first data attributes and the second data attributes, and matching a first data cleaning rule and a second data cleaning rule from a preset rule base based on the first data structure and the second data structure;

the data cleaning unit is further used for cleaning the configuration parameters and the environmental parameters respectively based on the first data cleaning rule and the second data cleaning rule to obtain target configuration parameters and target environmental parameters;

the analysis unit is used for extracting data characteristics of the target configuration parameters and determining the brightness adjustment level and the target spectrum type of the lamps in the lighting control area based on the data characteristics;

the analysis unit is further configured to determine a target value of the individual data in the target environment parameter, and determine the illumination intensity of the lighting control area based on the target value;

the analysis unit is further used for acquiring a space structure diagram of the lighting control area and determining the space characteristics of the lighting control area based on the space structure diagram;

the analysis unit is further configured to determine, based on the spatial features, position data of luminaires in the lighting control area, and determine, based on the position data, target illumination points of the lighting control area, where the target illumination points are at least one;

a control scheme determining unit, configured to determine an association attribute of the target illumination point and the lighting control area, determine a target brightness level and a target light color of a lamp of the target illumination point in the lighting control area based on the association attribute and the illumination intensity of the lighting control area, and determine a first lighting control scheme based on the target brightness level and the target light color.

Preferably, an internet of things lighting control system, the analysis unit includes:

the sequencing subunit is used for acquiring multiple groups of environment parameters of the lighting control area and sequencing the environment parameters based on a time development sequence, wherein the environment parameters are acquired at different time periods every day;

the illumination intensity analysis subunit is used for determining values of the environmental parameters at different time points based on the sequencing result and determining the illumination intensities of the illumination control areas at different time points in one day based on the values;

the illumination intensity analysis subunit is further configured to draw an illumination intensity variation curve based on the illumination intensities of the illumination control area at different time points in a day, and determine illumination intensity variation values at adjacent times based on the illumination intensity variation curve;

and the control scheme optimization subunit is configured to determine, based on the illumination intensity variation value, target brightness levels and target light colors at different times in the first lighting control scheme, and complete optimization of the first lighting control scheme.

Preferably, the lighting control system of the internet of things, the control scheme determining unit, includes:

the monitoring subunit is used for acquiring lighting data of the lamps in the lighting control area in a preset time period based on the Internet of things, and determining time points and frequency values of the lamps turned on and turned off every day by a user based on the lighting data;

and the habit analysis subunit is used for determining the lighting behavior habit of the user based on the time point and the frequency value of the lamp which is turned on and off by the user every day, and adjusting the first lighting control scheme based on the lighting behavior habit to obtain a second lighting control scheme.

Preferably, the lighting control system of the internet of things, the scheme determining module, further includes:

the scheme acquisition unit is used for acquiring the generated lighting control scheme and determining the execution parameters of the lamp in the lighting control scheme;

the instruction generating unit is used for determining keywords in the execution parameters and determining script files corresponding to the keywords, wherein the number of the keywords is at least one;

the instruction generating unit is used for matching the script file with instruction definitions in a preset instruction library and determining a target instruction definition corresponding to the script file;

and the instruction generating unit is used for calling a standard text corresponding to the script file based on the target instruction definition and generating a corresponding target control instruction based on the standard text.

Preferably, an internet of things lighting control system, the control module includes:

the instruction analysis unit is used for acquiring the obtained target control instruction and transmitting the target control instruction to the gateway of the Internet of things based on the control link;

the instruction analysis unit is used for carrying out protocol conversion on the target control instruction based on the gateway of the Internet of things to obtain an execution instruction, and determining an instruction identifier of the execution instruction, wherein the execution instruction is an instruction set of each lamp in the lighting control area, and the lamps are not unique;

the area analysis unit is used for acquiring the area characteristics of the lighting control area and determining the distribution information of the lamp based on the area characteristics;

the area analysis unit is further configured to perform area division on the lighting control area based on the distribution information to obtain sub lighting control areas, where at least two sub lighting control areas are obtained;

the area analysis unit is further configured to determine target lamps in the sub-lighting control areas and determine target identifiers of the target lamps in the sub-lighting control areas;

the command transmission unit is used for determining sub-control circuits of the target lamps in the sub-lighting control areas based on the target identifiers, and meanwhile, matching the command identifiers with the target identifiers of the target lamps to obtain the target lamps corresponding to the execution commands;

the instruction transmission unit is further used for transmitting the execution instruction to a target lamp based on the sub-control circuit based on a matching result and controlling the target lamp to execute corresponding lighting operation;

the feedback unit is used for acquiring working parameters of the target lamp for executing corresponding lighting operation in real time and feeding the working parameters back to the gateway of the Internet of things on the basis of the sub-control link;

the feedback unit is further used for feeding back the working parameters to the user terminal based on the internet of things gateway, and completing feedback of lighting control of the internet of things.

Preferably, an internet of things lighting control system, the feedback unit includes:

the result receiving subunit is configured to receive working parameters of each target lamp and determine a parameter value of the working parameter, where the working parameter includes an illumination intensity and a working power of the target lamp;

the comparison subunit is used for acquiring a standard threshold in the target control instruction and comparing the parameter value with the standard threshold;

if the difference value between the parameter value and the standard threshold value is within a preset difference value range, judging that the lighting control of the target lamp is qualified;

otherwise, judging that the lighting control of the target lamp is unqualified, analyzing the working parameters of the target lamp, and determining abnormal data in the working parameters;

and the alarm unit is used for determining the reason for controlling the abnormity of the target lamp based on the abnormal data and sending an alarm prompt to the user terminal.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a structural diagram of an internet of things lighting control system according to an embodiment of the present invention;

fig. 2 is a structural diagram of a monitoring module in an internet of things lighting control system according to an embodiment of the present invention;

fig. 3 is a structural diagram of a scheme determination module in an internet of things lighting control system in an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it should be understood that they are presented herein only to illustrate and explain the present invention and not to limit the present invention.

Example 1:

the embodiment provides an internet of things lighting control system, as shown in fig. 1, including:

a scheme determination module for generating a lighting control scheme based on the configuration parameters and the environmental parameters, and generating a target control instruction based on the lighting control scheme;

In this embodiment, the user terminal refers to an intelligent terminal with a communication or networking function, and is specifically a mobile phone or the like.

In this embodiment, the luminaire may be an intelligent luminaire with networking functionality and with different sensors.

In this embodiment, the control link refers to a control link established between the user terminal and the lamp in the lighting control area, and the control link may send a corresponding control instruction to the lamp to control the lamp.

In this embodiment, the lighting control area refers to a place where lighting control is required, specifically, a room, a factory building, a hall, and the like.

In this embodiment, the configuration parameters of the lamp refer to the light brightness adjustment level of the lamp, and the light intensity, the working power, and the like corresponding to different levels.

In this embodiment, the environmental parameter of the lighting control area refers to the current natural light intensity of the lighting control area and the current time information.

In this embodiment, the lighting control scheme refers to controlling the lighting brightness of the lamps in the lighting control area and the time when the lamps are turned on or off.

In this embodiment, the target control instruction refers to a code instruction or a voice instruction for controlling the lamps in the lighting control area to execute corresponding control functions.

In this embodiment, the feedback of the control result to the user terminal based on the internet of things means that the control execution result is fed back to the user terminal through the internet of things, so that the user can know the current control situation in time.

The beneficial effects of the above technical scheme are: the corresponding control scheme is determined according to the environmental parameters of the illumination control area and the configuration information of the lamp, so that adaptive illumination of the illumination control area is realized, the energy-saving effect is ensured to be achieved on the premise of normal illumination, and the intelligence of illumination control is improved.

Example 2:

on the basis of the foregoing embodiment 1, this embodiment provides an internet of things lighting control system, as shown in fig. 2, the monitoring module includes:

the link building unit is used for accessing an Internet of things gateway based on the service type, and the Internet of things gateway allocates a network routing port based on the service type, wherein the network routing port is a bidirectional port and is respectively connected with a user terminal and a lamp in the lighting control area;

In this embodiment, the terminal identifier is a kind of tag used to mark the kinds or functions of different lamps.

In this embodiment, the service type refers to a purpose to be controlled through the internet of things, a function to be realized by the lamp, and the like.

In this embodiment, the internet of things gateway refers to a sensor or software acting between the user terminal and the lamp, and can perform format packaging on the instruction sent by the user terminal, so that the instruction is transmitted to the corresponding lamp, and the working information of the lamp can be fed back to the user terminal.

In this embodiment, the network routing port refers to a data port for connecting a data transmission link between a user terminal and a luminaire.

In this embodiment, the first port address refers to a communication address of the luminaire.

In this embodiment, the second port address refers to a communication address of the user terminal.

The beneficial effects of the above technical scheme are: the method has the advantages that accurate analysis of the service types controlled based on the Internet of things technology is achieved by determining the terminal identification of the lamp, so that corresponding ports are conveniently distributed for the user terminal and the lamp, the lamp is connected with the user terminal through the ports, a control link between the lamp and the user terminal is established, smooth transmission of instructions of the user terminal is guaranteed, and accurate and effective control over the lamp is achieved.

Example 3:

on the basis of the above embodiment 1, this embodiment provides an internet of things lighting control system, and the monitoring module further includes:

the parameter acquisition unit is used for sending an information acquisition instruction to a preset sensor carried by a lamp in the illumination control area based on the control link, and the preset sensor reads configuration parameters of the lamp and acquires environmental parameters of the illumination control area based on the information acquisition instruction, wherein the environmental parameters comprise natural light brightness of the illumination control area and current time information;

and the data feedback unit is used for determining the transmission sequence of the first compressed data packet and the second compressed data packet based on a data transmission queue and sending the first compressed data packet and the second compressed data packet to the user terminal through the control link based on the transmission sequence.

In this embodiment, the preset sensor is set in advance and is used to acquire configuration information of the lamp and current environmental parameters of the lighting control area, where the preset sensor is specifically an image acquirer, a photosensitive sensor, or the like.

In this embodiment, the first compressed data packet refers to a data packet obtained by compressing the configuration parameter parameters of the lamp.

In this embodiment, the second compressed packet refers to a packet obtained by compressing the environment parameter.

In this embodiment, the data transmission queue is a carrier for transmitting configuration parameters and environment parameters.

The beneficial effects of the above technical scheme are: the information distribution information of the lamp and the environmental parameters of the lighting control area are obtained based on the sensor, and the configuration information and the environmental parameters are compressed, packaged and fed back to the user terminal, so that the user terminal can conveniently make a corresponding control scheme in time according to the configuration information and the environmental parameters of the lamp, and accurate control over the lighting control area is achieved.

Example 4:

on the basis of the above embodiment 3, this embodiment provides an internet of things lighting control system, and the data feedback unit includes:

and the packing subunit is used for respectively setting a target packet header based on the configuration parameters and the category identifiers of the environmental parameters, and packing the compressed configuration parameters and the environmental parameters based on the target packet header.

In this embodiment, the category identifier is a label tag used to characterize the data types of the configuration parameters and the environmental parameters, and the type of the configuration parameters and the environmental parameters can be determined quickly and accurately through the label tag.

In this embodiment, the compression configuration refers to a compression strength used for compressing the configuration parameters and the environmental parameters, specifically, the compression volume and the compression speed are required.

In this embodiment, the preset time sequence segment is set in advance and is used for sampling and analyzing the configuration parameters and the environmental parameters, so that the analysis efficiency is improved, and the reference basis for compressing the configuration parameters and the environmental parameters is determined.

In this embodiment, the distance relative value refers to the number of bytes left between adjacent data.

In this embodiment, the distribution characteristic refers to whether the distance between adjacent data is consistent with respect to the value, or whether the spare bytes between individual data are larger or smaller.

In this embodiment, the target packet header refers to an identifier for marking different types of compressed packet data, and the packet header can be used to quickly and accurately determine the corresponding data type of the compressed packet.

The beneficial effects of the above technical scheme are: the configuration parameters and the environmental parameters are efficiently and accurately compressed by determining the relative distance values between the data of the configuration parameters and the data of the environmental parameters, so that the transmission efficiency of the data when the data are transmitted to a user terminal is improved, meanwhile, packet headers are arranged on the data packets after compression, a user can conveniently decompress and read different types of data according to the packet headers, and the effect and the accuracy of controlling the lamp through the Internet of things are improved.

Example 5:

on the basis of the foregoing embodiment 1, this embodiment provides an internet of things lighting control system, as shown in fig. 3, the scheme determining module includes:

the data cleaning unit is further configured to respectively clean the configuration parameters and the environmental parameters based on the first data cleaning rule and the second data cleaning rule to obtain target configuration parameters and target environmental parameters;

the analysis unit is used for extracting data characteristics of the target configuration parameters and determining the brightness adjustment level and the target spectrum type of the lamps in the illumination control area based on the data characteristics;

a control scheme determining unit, configured to determine an association attribute of the target illumination point and the lighting control area, determine a target brightness level and a target light color of a luminaire of the target illumination point in the lighting control area based on the association attribute and an illumination intensity of the lighting control area, and determine a first lighting control scheme based on the target brightness level and the target light color.

In this embodiment, the first data attribute refers to a data type of the configuration parameter of the luminaire, a corresponding data amount, and the like.

In this embodiment, the second data attribute refers to the kind of data contained in the lighting control area and the corresponding amount of data.

In this embodiment, the first data structure refers to main data and interference data included in configuration parameters of the lamp, and a ratio, a value, and the like corresponding to the main data and the interference data, where the main data is an adjustable range of working power, an adjustable range of brightness, and the like of the lamp.

In this embodiment, the second data structure refers to data about light intensity, space size, and the like, and external light disturbance data and the like included in the environmental parameter, that is, the constituent of the environmental parameter.

In this embodiment, the preset rule base is set in advance and is used for storing the data cleaning rules corresponding to different types of data.

In this embodiment, the first data cleansing rule refers to a data cleansing rule suitable for cleansing the configuration parameters of the lamp.

In this embodiment, the second data cleansing rule refers to a data query rule applicable to cleansing the environmental parameters of the lighting control area, and is one or more of a preset rule base.

In this embodiment, the target configuration parameters and the target environment parameters refer to data obtained by cleaning interference data in the configuration parameters and the environment parameters through the first data cleaning rule and the second data cleaning rule, and the two data can directly reflect the configuration condition of the lamp and the environment condition of the lighting control area.

In this embodiment, the data characteristics refer to specific values of the configuration parameters, specific values of each configuration parameter, and the like.

In this embodiment, the brightness adjustment level refers to a level at which the light intensity can be adjusted by the lamp, specifically, the brightness is decreased progressively in the first level, the second level, the third level, and the like.

In this embodiment, the target spectrum type refers to a light color, specifically, a warm color, a bright color, and the like, which can be used by the luminaire.

In this embodiment, the target value refers to a specific value of each data in the environmental parameter.

In this embodiment, the spatial structure diagram refers to a design drawing for indicating the spatial structure and the like of the illumination control area.

In this embodiment, the spatial characteristics refer to connection relationships or connection conditions between different area blocks in the lighting control area.

In this embodiment, the location data refers to the mounting locations of the different light fixtures in the lighting control area.

In this embodiment, the target illumination point refers to a point in the selected lighting control area to analyze the light brightness provided by the lamp, so as to determine whether the light brightness provided by the lamp meets the requirement.

In this embodiment, the association attribute refers to a position of the target illuminance point in the lighting control area and a light luminance relationship between the target illuminance point and the lighting control area.

In this embodiment, the target brightness level refers to the brightness level that the luminaire finally determines.

In this embodiment, the first lighting control scheme refers to the light brightness level of the lamp and the finally adopted light color determined according to the current light intensity in the lighting control area.

In this embodiment, the target light color refers to the light color finally adopted by the lamp.

In this embodiment, determining the target brightness level and the target light color of the luminaire of the target illumination point in the lighting control area based on the association attribute and the illumination intensity of the lighting control area includes:

the method comprises the following steps of acquiring the wavelength of light of a lamp, calculating the luminous flux of the lamp based on the wavelength of the light, and calculating the illuminance value of the lamp on the target illuminance point based on the luminous flux, wherein the specific steps comprise:

calculating the luminous flux of the luminaire according to the formula:

wherein Φ represents a luminous flux of the luminaire; α represents the maximum value of the spectral efficiency of the radiation, typically taking the value of 683 lumens per watt;

a spectral distribution representative of the luminaire radiant flux; θ represents a spectral luminous efficiency value of the luminaire; λ represents the wavelength of light of the luminaire;

calculating an illuminance value of the target illuminance point according to the following formula:

wherein the content of the first and second substances,

an illuminance value representing the target illuminance point; mu represents an error factor, and the value range is (0.02, 0.05); i represents the current number of luminaires in the lighting control area; n represents the total number of luminaires in the lighting control area; phi _i Represents the luminous flux of the ith lamp; delta _i The power factor of the ith lamp is represented, and the value range is (0, 0.9); x is the number of _i An abscissa value representing an ith lamp in the lighting control area; x is the number of _m An abscissa value representing the target illuminance point in the lighting control area; y is _i A vertical coordinate value representing an ith lamp in the lighting control area; y is _m A vertical coordinate value representing the target illumination point in the lighting control area; z is a radical of _i An ordinate value representing the ith lamp in the lighting control area; z is a radical of _m A vertical coordinate value representing the target illumination point in the lighting control area;

comparing the illumination value with a preset illumination value;

if the illuminance value is smaller than a preset illuminance value, judging that the illumination intensity of the lamp to the target illumination point is unqualified, and adjusting the brightness level and the target light color of the lamp until the illuminance value is larger than or equal to the preset illuminance value;

otherwise, judging that the current target brightness level and the illumination intensity of the target light color to the target illumination point are qualified, and finishing the formulation of the illumination control scheme.

The spectral light efficiency values refer to the average relative sensitivity of the human eye to various wavelengths of light.

The spectral efficiency of the radiation is the monochromatic luminous flux which can be generated by the monochromatic luminous radiation flux with a certain lamp light wavelength.

The beneficial effects of the above technical scheme are: the configuration parameters of the lamp and the environmental parameters of the lighting control area are cleaned, the configuration parameters and the environmental parameters are accurate and reliable, a corresponding control scheme is guaranteed to be accurately set, secondly, the configuration parameters of the lamp are analyzed, the brightness adjustment grade and the light color of the lamp are effectively obtained, finally, the illumination intensity of the lighting control area is determined according to the environmental parameters, the brightness grade and the light color of the lamp are accurately judged according to the illumination intensity, the lighting control scheme is accurately and reliably set, the intelligence of lamp control is improved, the lighting control scheme is guaranteed to be suitable for the current environment, and meanwhile, the energy is saved conveniently.

Example 6:

on the basis of the foregoing embodiment 5, the present embodiment provides an internet of things lighting control system, and the analysis unit includes:

the sequencing subunit is used for acquiring multiple groups of environment parameters of the lighting control area and sequencing the environment parameters based on a time development sequence, wherein the environment parameters are acquired at different time periods each day;

the illumination intensity analysis subunit is further configured to draw an illumination intensity change curve based on the illumination intensities of the illumination control area at different time points in a day, and determine illumination intensity change values at adjacent times based on the illumination intensity change curve;

In this embodiment, the illumination intensity variation curve refers to a curve form drawn by the illumination intensity values of the illumination control area at different times of a day, so that the illumination intensity of the illumination control area at different time points of a day can be observed conveniently, and the brightness level and the light color of the lamp can be adjusted in real time, wherein the illumination intensity of the lamp at different time points of a day is an average value of multiple sets of environmental parameters.

In this embodiment, the illumination intensity variation value refers to a variation value of illumination intensity of the illumination control area between adjacent time points in a day.

The beneficial effects of the above technical scheme are: by analyzing the illumination intensity of the illumination control area at different time points in one day, the brightness level and the light color of the lamp can be adjusted in real time according to the illumination intensity of the illumination control area at different time points, so that the illumination requirement of the illumination control area is met, the energy is saved, and the energy utilization rate is improved.

Example 7:

on the basis of the foregoing embodiment 5, this embodiment provides an internet of things lighting control system, and the control scheme determining unit includes:

the monitoring subunit is used for acquiring lighting data of the lamps in the lighting control area in a preset time period based on the Internet of things, and determining time points and frequency values of the lamps which are turned on and off by a user every day based on the lighting data;

and the habit analysis subunit is used for determining the lighting behavior habit of the user based on the time point and the frequency value of turning on and off the lamp of the user every day, and adjusting the first lighting control scheme based on the lighting behavior habit to obtain a second lighting control scheme.

In this embodiment, the preset time period is set in advance, specifically, one week, one month, and the like.

In this embodiment, the lighting data refers to the time period of the lamp operation, or the time point of being turned on or off every day, and the like.

In this embodiment, the lighting behavior habit refers to the behavior of a user for controlling a lamp, and the behavior shows a change rule.

In this embodiment, the second lighting control scheme is the control function of adding timing start and closing of the light fixture on the basis of the first lighting control scheme, and is the optimization result of the first lighting control scheme.

The beneficial effects of the above technical scheme are: by determining the lighting data of the user to the lamp in a certain time period, the lighting behavior habit of the user is analyzed, and the time for turning on and off the lamp every day is accurately analyzed through the lighting behavior habit, so that the first lighting control scheme is optimized, and the control intelligence of the lamp in the lighting control area is improved.

Example 8:

on the basis of the foregoing embodiment 1, this embodiment provides an internet of things lighting control system, and the scheme determining module further includes:

the scheme acquisition unit is used for acquiring the generated lighting control scheme and determining execution parameters of the lamp in the lighting control scheme;

In this embodiment, the execution parameters refer to specific control data of the brightness, the light color, the working power, the working current, and the like of the lamp.

In this embodiment, the keyword refers to a piece of data that can indicate the final execution destination of the execution parameter.

In this embodiment, the script file refers to a code file corresponding to the keyword.

In this embodiment, the predetermined instruction library is set in advance, and is used for storing different instruction definitions.

In this embodiment, the target instruction definition refers to a standard instruction corresponding to the keyword, that is, an instruction that can be recognized by the luminaire.

In this embodiment, the standard text refers to the target instruction definition corresponding to the encoding file.

The beneficial effects of the above technical scheme are: by determining the control execution parameters of the lamp in the lighting control scheme and analyzing the execution parameters, the execution parameters are converted into corresponding control instructions, so that the lamp can be controlled correspondingly, and the control efficiency and accuracy are improved.

Example 9:

on the basis of the above embodiment 1, this embodiment provides an internet of things lighting control system, and the control module includes:

the area analysis unit is used for acquiring area characteristics of the lighting control area and determining distribution information of the lamp based on the area characteristics;

the area analysis unit is further configured to perform area division on the lighting control areas based on the distribution information to obtain sub lighting control areas, where at least two sub lighting control areas are obtained;

In this embodiment, the protocol conversion refers to format conversion of the target control instruction through the internet of things gateway, and the target control instruction is converted into an instruction language that can be recognized by the lamp and meets the requirements of the internet of things, so as to control the corresponding lamp to execute corresponding operations.

In this embodiment, the execution instruction is sent to another data format of the target control instruction which is identified by the lamp, and the data format is the same as the target control instruction control purpose and is different from the target control instruction control purpose.

In this embodiment, the instruction identifier is a tag used to tag different execution instructions, and the lamp controlled by the execution instruction can be determined quickly and accurately by the tag.

In this embodiment, the area feature refers to an association relationship between area blocks in the lighting control area.

In this embodiment, the distribution information refers to the installation positions of the light fixtures in the lighting control area, so as to facilitate the regional control of different light fixtures in the lighting control area.

In this embodiment, the sub-lighting control area refers to a small area block obtained by dividing the lighting control area, and different lamps corresponding to different small area blocks are different.

In this embodiment, the target luminaire refers to a luminaire in each sub-lighting control area, and there is at least one luminaire in each sub-lighting control area.

In this embodiment, the target identifier may be a distinguishable label using different mark symbols, specifically numbers and the like.

In this embodiment, the sub-control circuit is a circuit for performing block control on each sub-lighting area after dividing the lighting control area.

In this embodiment, the operating parameters refer to operating data of each lamp after receiving the control command, including current brightness, light color, power, and the like of the lamp.

The beneficial effects of the above technical scheme are: the target control instruction is subjected to protocol conversion, the distribution condition of the lamps in the lighting control area is determined, the lighting control area is divided, and the control instruction is transmitted to the corresponding lamps according to the division result, so that the lamps in different areas in the lighting control area are controlled in a blocking mode, the intelligence of controlling the lamps based on the Internet of things is improved, a user can conveniently control the lamps in the corresponding areas to be turned on and off according to the requirements of the user, and the control effect is improved.

Example 10:

on the basis of the foregoing embodiment 9, this embodiment provides an internet of things lighting control system, and the feedback unit includes:

the comparison subunit is used for acquiring a standard threshold in a target control instruction and comparing the parameter value with the standard threshold;

and the alarm unit is used for determining the reason for the abnormal control of the target lamp based on the abnormal data and sending an alarm prompt to the user terminal.

In this embodiment, the standard threshold refers to a final objective of controlling the lamp in the target control instruction, specifically, a working value to be achieved by each parameter.

In this embodiment, the abnormal data refers to data that does not meet the requirement of the target control instruction in the operating parameters.

In this embodiment, the abnormal control reason refers to a fault reason that the lamp does not meet the target control instruction requirement.

The beneficial effects of the above technical scheme are: the working condition of the lamp is analyzed in real time through the working parameters of the lamp, so that the lamp is ensured to be timely subjected to corresponding alarm operation when the lamp does not meet the control requirement, the working performance of the lamp is ensured to be detected while the lamp is controlled, and the control effect is improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. An Internet of things lighting control system, comprising:

the control module is used for carrying out illumination control on the lamps in the illumination control area through the target control instruction based on the Internet of things and feeding back a control result to the user terminal based on the Internet of things;

the monitoring module still includes:

2. The lighting control system of the internet of things of claim 1, wherein the monitoring module comprises:

3. The lighting control system of the internet of things as claimed in claim 1, wherein the data feedback unit comprises:

a compression configuration determining subunit, configured to determine compression configurations for the configuration parameters and the environment parameters respectively based on the category identifier, and determine distance relative values between the parameters of the configuration parameters and the environment parameters in a preset time sequence segment respectively based on the compression configurations;

4. The lighting control system of the internet of things as claimed in claim 1, wherein the scheme determination module comprises:

5. The lighting control system of the internet of things as claimed in claim 4, wherein the analysis unit comprises:

the illumination intensity analysis subunit is used for determining values of the environmental parameters at different time points based on the sequencing result and determining the illumination intensity of the illumination control area at different time points in one day based on the values;

6. The lighting control system of the internet of things according to claim 4, wherein the control scheme determination unit comprises:

7. The lighting control system of the internet of things of claim 1, wherein the scheme determination module further comprises:

8. The lighting control system of the internet of things as claimed in claim 1, wherein the control module comprises:

the instruction analysis unit is used for acquiring the obtained target control instruction and transmitting the target control instruction to the Internet of things gateway based on the control link;

the feedback unit is used for acquiring working parameters of the target lamp for executing corresponding lighting operation in real time and feeding the working parameters back to the gateway of the Internet of things based on the sub-control link;

9. The lighting control system of the internet of things as claimed in claim 8, wherein the feedback unit comprises: