CN111083835A - LED intelligent lighting system based on full spectrum and method thereof - Google Patents

LED intelligent lighting system based on full spectrum and method thereof Download PDF

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CN111083835A
CN111083835A CN201911379747.1A CN201911379747A CN111083835A CN 111083835 A CN111083835 A CN 111083835A CN 201911379747 A CN201911379747 A CN 201911379747A CN 111083835 A CN111083835 A CN 111083835A
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illumination
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time
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CN111083835B (en
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魏相飞
桑永树
史衍昆
刘军
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Anhui Shilin Lighting Co Ltd
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Anhui Shilin Lighting Co Ltd
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Abstract

The invention discloses an LED intelligent lighting system based on full spectrum and a method thereof, wherein the system comprises a data acquisition module, a data analysis module, a data processing module, an information collection module, a controller, a signal operation module, a data monitoring module and a data interconnection module; the data acquisition module is used for acquiring the illumination working condition information of the LED lamp in real time and transmitting the illumination working condition information to the data analysis module; after receiving the real-time illumination working condition information of the LED lamp, the data analysis module performs illumination working condition analysis operation on the LED lamp; the invention relates to a method for carrying out two-stage deep hierarchical analysis on the illumination running condition of a full-spectrum LED lamp by using differentiated data calibration and assigned weight analysis, and then the obtained processing signal is associated with the working condition of a corresponding power line, and the analysis is carried out by using a first-stage verification formula, so that reasonable illumination optimization measures are made, and the accuracy and pertinence of the processing process are improved.

Description

LED intelligent lighting system based on full spectrum and method thereof
Technical Field
The invention relates to the technical field of LED intelligent illumination, in particular to an LED intelligent illumination system based on full spectrum and a method thereof.
Background
The full spectrum refers to a spectrum containing a spectrum curve of ultraviolet light, visible light and infrared light, the proportion of red, green and blue in the visible light part is similar to that of sunlight, and the color rendering index is close to 100. The spectrum of the sunlight can be called as a full spectrum, and the color temperature of the sunlight changes along with the change of four seasons, morning and evening, namely the LED lamp based on the full spectrum has the function of changing the working states such as the color temperature and the like along with the change of time.
However, in the document with publication number CN109246915A, it is determined whether the lighting lamp is turned on in the high light mode or continues to be turned on in the low light mode only according to whether someone is moving around the collected lighting lamp, so as to perform real-time monitoring and management on the night lighting system and the lighting lamp; the system is combined with the existing full-spectrum-based LED intelligent lighting system and the method thereof, most of the existing systems only analyze and judge the conditions of the power supply voltage and the power supply current of a full-spectrum LED lamp independently, but the working conditions of the power circuit related to the full-spectrum LED lamp are rarely related to each other, so that the whole processing process is single, the accuracy and the pertinence are poor, the lighting operation condition of the full-spectrum LED lamp is difficult to be subjected to assignment type weight analysis calibrated by differentiating data, the obtained processing signal is related to the working condition of the power circuit corresponding to the processing signal, and the obtained analysis signal is used for calling data to perform secondary deep hierarchical analysis through a primary verification formula analysis, so that reasonable optimized lighting measures are made, and the accuracy and the pertinence of the processing process are improved;
in order to solve the above-mentioned drawbacks, a technical solution is now provided.
Disclosure of Invention
The invention aims to provide an LED intelligent illumination system and method based on a full spectrum, the illumination operation condition of a full spectrum LED lamp is subjected to assignment type weight analysis calibrated by differentiated data, an obtained processing signal is associated with the working condition of a power line corresponding to the processing signal, and the obtained analysis signal is used for calling data to perform secondary deep hierarchical analysis through a primary verification formula analysis, so that reasonable illumination optimization measures are made, and the accuracy and pertinence of the processing process are improved.
The technical problems to be solved by the invention are as follows:
according to an effective mode, the problems that most of the existing full-spectrum LED lamps only analyze and judge the power supply voltage and power supply current conditions independently, but the working conditions of the power lines related to the full-spectrum LED lamps are rarely related, so that the whole processing process is single, the accuracy and the pertinence are poor, the lighting running conditions of the full-spectrum LED lamps are difficult to perform assignment type weight analysis through dissimilarity data calibration, the obtained processing signals are related to the working conditions of the power lines corresponding to the processing signals, and the obtained analysis signals are used for calling data to perform secondary deep hierarchical analysis through the primary verification formula analysis, so that reasonable illumination optimization measures are made, and the accuracy and the pertinence of the processing process are improved are solved.
The purpose of the invention can be realized by the following technical scheme:
the LED intelligent lighting system based on the full spectrum comprises a data acquisition module, a data analysis module, a data processing module, an information collection module, a controller, a signal operation module, a data monitoring module and a data interconnection module;
the data acquisition module is used for acquiring the illumination working condition information of the LED lamp in real time and transmitting the illumination working condition information to the data analysis module;
after receiving the real-time illumination working condition information of the LED lamp, the data analysis module performs illumination working condition analysis operation on the LED lamp to obtain a fluctuating illumination signal and a normal illumination signal in a first time level, and transmits the fluctuating illumination signal and the normal illumination signal to the data processing module;
after the data processing module receives the real-time normal lighting signal, the data processing module does not process the real-time normal lighting signal; after receiving the real-time fluctuating illumination signal, the data processing module calls the line working condition information of each LED lamp in the same time period corresponding to the real-time fluctuating illumination signal from the information collecting module, analyzes the line working condition information, obtains a line fluctuating signal and a line monitoring signal in the same time period corresponding to the fluctuating illumination signal of the first time level, and transmits the line fluctuating signal and the line monitoring signal to the signal operation module through the controller;
the information collection module is used for collecting the line working condition information of the LED lamp in real time and storing the line working condition information to the inner space;
after receiving the real-time line monitoring signal, the signal operation module calls a real-time voltage value and a real-time current value of the corresponding LED lamp and the power line of the LED lamp from the data monitoring module, and sends the real-time voltage value and the real-time current value to a display screen after color marking;
after receiving the real-time line fluctuation signals, the signal operation module calls the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the signal operation module from the data processing module, wherein the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal lighting signals for 3 times or less and line fluctuation signals for 2 times or more, generating optimized lighting signals by the LED lamp, and under other conditions, generating attention monitoring signals by the LED lamp, and transmitting the optimized lighting signals and the attention monitoring signals to the data interconnection module;
the data monitoring module is used for monitoring the voltage value and the current value of the LED lamp and the power line where the LED lamp is located in real time and storing the voltage value and the current value into the internal space;
after receiving the real-time optimized lighting signal, the data interconnection module edits a text of power supply and lighting to be overhauled with the corresponding LED lamp, and sends the text and the LED lamp to a mobile phone of a manager together, and the mobile phone of the manager is communicated with the data interconnection module in a wireless transmission mode and the like; and after receiving the real-time attention monitoring signal, the data interconnection module sends the LED lamp corresponding to the data interconnection module to a display screen after the LED lamp is marked by letters.
Furthermore, the lighting condition information of the LED lamp consists of the power factor of the LED lamp, the voltage factor of the LED lamp and the temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation and the environment temperature variation of the LED lamp, and all the data can be obtained according to the modes of a sensor, a monitor and the like.
Further, the specific steps of the illumination condition analysis operation are as follows:
the method comprises the following steps: acquiring lighting working condition information of the LED lamps in a first time level, respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence, the first time level represents the duration of 5 minutes, a variable i corresponds to each LED lamp, and n represents a positive integer greater than 1;
step two: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
step three: the power factor Qi of each LED lamp, the voltage factor Wi of each LED lamp and the temperature factor Ei of each LED lamp are given with weight coefficients z, x and c respectively, z is larger than c and is larger than x, and z + x + c is 4.2899, then the illumination stability magnitude Ri of each LED lamp in the first time level is obtained according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, the LED lamp corresponding to the Ri generates a fluctuating illumination signal, otherwise, the LED lamp corresponding to the Ri generates a normal illumination signal.
Furthermore, the line working condition information of the LED lamp consists of line heat production data of the LED lamp, line current data of the LED lamp and line partial discharge data of the LED lamp; the circuit heat production data of the LED lamp represents total heat energy generated by a power circuit where the LED lamp is located, the circuit current data of the LED lamp represents total current variation when the power circuit where the LED lamp is located operates, the circuit partial discharge data of the LED lamp represents total partial discharge generated by the power circuit where the LED lamp is located, and all the data can be obtained according to the modes of a sensor, a monitor and the like.
Further, the specific steps of the line condition analysis operation are as follows:
the method comprises the following steps: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat production data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, the Tj, the Yj and the Uj are in one-to-one correspondence with each other, a variable j corresponds to each LED lamp in the fluctuating illumination signal, and m represents a positive integer greater than 1;
step two: according to the formula
Figure BDA0002341958280000051
Obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than y and t + y + u is 3.2881, δ, ε and μ are verification coefficients, δ is larger than ε and is larger than μ and δ + ε + μ is 2.8441;
step three: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj.
The LED intelligent lighting method based on the full spectrum comprises the following steps:
the method comprises the following steps: the method comprises the following steps of collecting illumination working condition information of the LED lamp in real time, and analyzing the illumination working condition of the LED lamp, wherein the method comprises the following steps:
s1: acquiring lighting working condition information of the LED lamps in a first time level, respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence, the first time level represents the duration of 5 minutes, a variable i corresponds to each LED lamp, and n represents a positive integer greater than 1;
s2: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
s3: firstly, respectively endowing a power factor Qi of each LED lamp, a voltage factor Wi of each LED lamp and a temperature factor Ei of each LED lamp with weight coefficients z, x and c, wherein z is larger than c and is larger than x, and z + x + c is 4.2899, then obtaining the illumination stability magnitude Ri of each LED lamp in a first time level according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, generating a fluctuating illumination signal for the LED lamp corresponding to the Ri, otherwise, generating a normal illumination signal for the LED lamp corresponding to the Ri;
obtaining a fluctuating illumination signal and a normal illumination signal within a first time level;
step two: according to the real-time normal illumination signal, no processing is carried out on the signal; according to the real-time fluctuating illumination signals, the line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signals is called, and line working condition analysis operation is carried out on the line working condition information, and the method comprises the following specific steps:
d1: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat production data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, the Tj, the Yj and the Uj are in one-to-one correspondence with each other, a variable j corresponds to each LED lamp in the fluctuating illumination signal, and m represents a positive integer greater than 1;
d2: according to the formula
Figure BDA0002341958280000071
Obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than y and t + y + u is 3.2881, δ, ε and μ are verification coefficients, δ is larger than ε and is larger than μ and δ + ε + μ is 2.8441;
d3: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj;
obtaining a line fluctuation signal and a line monitoring signal in the same time period corresponding to the fluctuation illumination signal of the first time level;
step three: according to the real-time line monitoring signals, the real-time voltage values and the real-time current values of the corresponding LED lamps and the power lines where the LED lamps and the power lines are located are taken, and the real-time voltage values and the real-time current values are sent to a display screen after being subjected to color marking; according to the real-time line fluctuation signals, calling the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the real-time line fluctuation signals, wherein the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal illumination signals for 3 times or less and the line fluctuation signals for 2 times or more, generating optimized illumination signals by the LED lamp, and otherwise, generating attention monitoring signals by the LED lamp;
step four: editing a power supply and illumination to-be-overhauled text of the corresponding LED lamp according to the real-time optimized illumination signal, and sending the text and the LED lamp to a mobile phone of a manager together, wherein the mobile phone of the manager is communicated with the data interconnection module in a wireless transmission mode and the like; according to the real-time attention monitoring signal, the LED lamp corresponding to the attention monitoring signal is sent to a display screen after being marked by letters;
the lighting working condition information of the LED lamp consists of the power factor of the LED lamp, the voltage factor of the LED lamp and the temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation of the LED lamp and the environment temperature variation, and all the data can be obtained in a sensor, a monitor and other modes;
the circuit working condition information of the LED lamp consists of circuit heat production data of the LED lamp, circuit current data of the LED lamp and circuit partial discharge data of the LED lamp; the circuit heat production data of the LED lamp represents total heat energy generated by a power circuit where the LED lamp is located, the circuit current data of the LED lamp represents total current variation when the power circuit where the LED lamp is located operates, the circuit partial discharge data of the LED lamp represents total partial discharge generated by the power circuit where the LED lamp is located, and all the data can be obtained according to the modes of a sensor, a monitor and the like.
The invention has the beneficial effects that:
the method comprises the steps of acquiring illumination working condition information of the LED lamps in real time, and analyzing the illumination working conditions, namely calibrating and carrying out assignment type weight processing on power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps through differentiation data to obtain fluctuating illumination signals and normal illumination signals in a first time level;
according to the real-time fluctuating illumination signals, the line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signals is called, and line working condition analysis operation is carried out on the line working condition information, namely line heat production data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp are subjected to data calibration and first-stage verification formula analysis, and line fluctuating signals and line monitoring signals in the same time period corresponding to the fluctuating illumination signals of the first time stage are obtained;
according to the real-time line monitoring signals, the real-time voltage values and the real-time current values of the corresponding LED lamps and the power lines of the LED lamps are taken and sent to a display screen after being color-marked;
according to the real-time line fluctuation signals, the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the real-time line fluctuation signals are also called, and the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal illumination signals for 3 times or less and the line fluctuation signals for 2 times or more, generating optimized illumination signals by the LED lamp, and under other conditions, generating attention monitoring signals by the LED lamp to complete secondary depth stratification analysis;
editing a power supply and illumination to-be-overhauled text by the LED lamp corresponding to the optimized illumination signal, and sending the text and the LED lamp to a mobile phone of a manager; the LED lamp corresponding to the attention monitoring signal is marked by letters and then sent to a display screen; and then the illumination running condition of the full-spectrum LED lamp is subjected to the evaluation formula weight analysis calibrated by the differentiated data, the obtained processing signal is associated with the working condition of the corresponding power line, and the analysis is carried out by a primary verification formula, so that the obtained analysis signal is used for calling data to carry out secondary deep hierarchical analysis, and accordingly, reasonable illumination optimization measures are made, and the accuracy and pertinence of the processing process are improved.
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In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings;
FIG. 1 is a block diagram of the system of the present invention.
Detailed Description
As shown in fig. 1, the full spectrum-based LED intelligent lighting system includes a data acquisition module, a data analysis module, a data processing module, an information collection module, a controller, a signal operation module, a data monitoring module, and a data interconnection module;
the data acquisition module is used for acquiring the illumination working condition information of the LED lamp in real time, and the illumination working condition information of the LED lamp consists of the power factor of the LED lamp, the voltage factor of the LED lamp and the temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, and the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation and the environment temperature variation of the LED lamp and transmits the maximum fluctuation value to the data analysis module;
the data analysis module is used for analyzing the lighting condition after receiving the lighting condition information of the real-time LED lamp, and comprises the following specific steps:
the method comprises the following steps: acquiring lighting working condition information of the LED lamps in a first time level, respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence, the first time level represents the duration of 5 minutes, a variable i corresponds to each LED lamp, and n represents a positive integer greater than 1;
step two: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
step three: firstly, respectively endowing a power factor Qi of each LED lamp, a voltage factor Wi of each LED lamp and a temperature factor Ei of each LED lamp with weight coefficients z, x and c, wherein z is larger than c and is larger than x, and z + x + c is 4.2899, then obtaining the illumination stability magnitude Ri of each LED lamp in a first time level according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, generating a fluctuating illumination signal for the LED lamp corresponding to the Ri, otherwise, generating a normal illumination signal for the LED lamp corresponding to the Ri;
obtaining a fluctuating illumination signal and a normal illumination signal in a first time level, and transmitting the fluctuating illumination signal and the normal illumination signal to the data processing module;
after the data processing module receives the real-time normal lighting signal, the data processing module does not process the real-time normal lighting signal; after receiving the real-time fluctuating illumination signal, the data processing module calls the line working condition information of each LED lamp in the same time period corresponding to the fluctuation illumination signal from the information collecting module, wherein the line working condition information of the LED lamps consists of line heat production data of the LED lamps, line current data of the LED lamps and line partial discharge data of the LED lamps; the circuit heat production data of the LED lamp represents the total heat energy generated by the power circuit where the LED lamp is located, the circuit current data of the LED lamp represents the total current variation when the power circuit where the LED lamp is located operates, the circuit partial discharge data of the LED lamp represents the total partial discharge generated by the power circuit where the LED lamp is located, and the circuit working condition analysis operation is carried out on the total partial discharge, and the specific steps are as follows:
the method comprises the following steps: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat production data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, the Tj, the Yj and the Uj are in one-to-one correspondence with each other, a variable j corresponds to each LED lamp in the fluctuating illumination signal, and m represents a positive integer greater than 1;
step two: according to the formula
Figure BDA0002341958280000111
M, obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than t and smaller than y, t + y + u is 3.2881, delta, epsilon and mu are verification coefficients, delta is larger than epsilon and larger than epsilon2.8441 at μ and δ + ε + μ;
step three: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj;
obtaining a line fluctuation signal and a line monitoring signal in the same time period corresponding to the fluctuation illumination signal of the first time level, and transmitting the line fluctuation signal and the line monitoring signal to the signal operation module through the controller;
the information collection module is used for collecting the line working condition information of the LED lamp in real time and storing the line working condition information to the inner space;
after receiving the real-time line monitoring signal, the signal operation module calls a real-time voltage value and a real-time current value of the corresponding LED lamp and the power line thereof from the data monitoring module, and sends the real-time voltage value and the real-time current value to a display screen after color marking;
after receiving the real-time line fluctuation signals, the signal operation module calls the normal lighting signals, the fluctuation lighting signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the signal operation module from the data processing module, wherein the second time level represents the duration of 30 minutes after the first time level; when the LED lamp generates normal lighting signals for 3 times or less and line fluctuation signals for 2 times or more, generating optimized lighting signals by the LED lamp, and under other conditions, generating attention monitoring signals by the LED lamp, and transmitting the optimized lighting signals and the attention monitoring signals to the data interconnection module;
the data monitoring module is used for monitoring the voltage value and the current value of the LED lamp and the power line where the LED lamp is located in real time and storing the voltage value and the current value into the internal space;
after receiving the real-time optimized lighting signal, the data interconnection module edits a text of power supply and lighting to be overhauled with the corresponding LED lamp, and sends the text and the LED lamp to a mobile phone of a manager together, and the mobile phone of the manager is communicated with the data interconnection module in a wireless transmission mode and the like; and after receiving the real-time attention monitoring signal, the data interconnection module sends the LED lamp corresponding to the data interconnection module to a display screen after the LED lamp is marked by letters.
The LED intelligent lighting method based on the full spectrum comprises the following steps:
the method comprises the following steps: the method comprises the following steps of collecting illumination working condition information of the LED lamp in real time, and analyzing the illumination working condition of the LED lamp, wherein the method comprises the following steps:
s1: acquiring lighting working condition information of the LED lamps in a first time level, and respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence with each other, and the first time level represents the duration of 5 minutes;
s2: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
s3: firstly, respectively endowing a power factor Qi of each LED lamp, a voltage factor Wi of each LED lamp and a temperature factor Ei of each LED lamp with weight coefficients z, x and c, wherein z is larger than c and is larger than x, and z + x + c is 4.2899, then obtaining the illumination stability magnitude Ri of each LED lamp in a first time level according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, generating a fluctuating illumination signal for the LED lamp corresponding to the Ri, otherwise, generating a normal illumination signal for the LED lamp corresponding to the Ri;
to obtain a fluctuating illumination signal, a normal illumination signal within a first time level;
step two: according to the real-time fluctuating illumination signals, the line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signals is called, and line working condition analysis operation is carried out on the line working condition information, and the method comprises the following specific steps:
d1: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat generation data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, and Tj, Yj and Uj are in one-to-one correspondence with each other;
d2: according to the formula
Figure BDA0002341958280000141
Obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than y and t + y + u is 3.2881, δ, ε and μ are verification coefficients, δ is larger than ε and is larger than μ and δ + ε + μ is 2.8441;
d3: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj;
obtaining a line fluctuation signal and a line monitoring signal in the same time period corresponding to the fluctuation illumination signal of the first time level;
step three: according to the real-time line monitoring signals, the real-time voltage values and the real-time current values of the corresponding LED lamps and the power lines where the LED lamps and the power lines are located are taken, and the real-time voltage values and the real-time current values are sent to a display screen after being subjected to color marking; according to the real-time line fluctuation signals, calling the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the real-time line fluctuation signals, wherein the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal illumination signals for 3 times or less and the line fluctuation signals for 2 times or more, generating optimized illumination signals by the LED lamp, and otherwise, generating attention monitoring signals by the LED lamp;
step four: editing a power supply and illumination to-be-overhauled text of the corresponding LED lamp according to the real-time optimized illumination signal, and sending the text and the LED lamp to a mobile phone of a manager; according to the real-time attention monitoring signal, the LED lamp corresponding to the attention monitoring signal is sent to a display screen after being marked by letters; and then the illumination running condition of the full-spectrum LED lamp is subjected to the evaluation formula weight analysis calibrated by the differentiated data, the obtained processing signal is associated with the working condition of the corresponding power line, and the analysis is carried out by a primary verification formula, so that the obtained analysis signal is used for calling data to carry out secondary deep hierarchical analysis, and accordingly, reasonable illumination optimization measures are made, and the accuracy and pertinence of the processing process are improved.
The LED intelligent lighting system and the method based on the full spectrum are characterized in that in the working process, a data acquisition module acquires the lighting working condition information of an LED lamp in real time, wherein the lighting working condition information of the LED lamp consists of the power factor of the LED lamp, the voltage factor of the LED lamp and the temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, and the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation and the environment temperature variation of the LED lamp and transmits the maximum fluctuation value to the data analysis module;
after receiving the real-time illumination working condition information of the LED lamps, the data analysis module carries out illumination working condition analysis operation on the LED lamps, namely the power factors of the LED lamps, the voltage factors of the LED lamps and the temperature factors of the LED lamps are subjected to differentiated data calibration and assignment type weight processing to obtain fluctuating illumination signals and normal illumination signals in a first time level, and the fluctuating illumination signals and the normal illumination signals are transmitted to the data processing module together;
after the data processing module receives the real-time normal lighting signal, the data processing module does not process the real-time normal lighting signal; after receiving the real-time fluctuating illumination signal, the data processing module calls the line working condition information of each LED lamp in the same time period corresponding to the fluctuation illumination signal from the information collecting module, wherein the line working condition information of the LED lamps consists of line heat production data of the LED lamps, line current data of the LED lamps and line partial discharge data of the LED lamps; the line heat production data of the LED lamps represent the total heat energy generated by the power line where the LED lamps are located, the line current data of the LED lamps represent the total current variation when the power line where the LED lamps are located operates, the line partial discharge data of the LED lamps represent the total partial discharge generated by the power line where the LED lamps are located, and line working condition analysis operation is carried out on the line partial discharge data, namely the line heat production data of each LED lamp, the line current data of each LED lamp and the line partial discharge data of each LED lamp are subjected to data calibration and primary verification formula analysis to obtain line fluctuation signals and line monitoring signals in the same time period corresponding to the fluctuation illumination signals of the first time level, and the line fluctuation signals and the line monitoring signals are transmitted to the signal operation module through the controller;
the information collection module is used for collecting the line working condition information of the LED lamp in real time and storing the line working condition information to the inner space;
after receiving the real-time line monitoring signal, the signal operation module calls a real-time voltage value and a real-time current value of the corresponding LED lamp and the power line thereof from the data monitoring module, and sends the real-time voltage value and the real-time current value to a display screen after color marking;
after receiving the real-time line fluctuation signals, the signal operation module calls the normal lighting signals, the fluctuation lighting signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the signal operation module from the data processing module, wherein the second time level represents the duration of 30 minutes after the first time level; when the LED lamp generates normal illumination signals for 3 times or less and the line fluctuation signals for 2 times or more, generating optimized illumination signals by the LED lamp, and under other conditions, generating attention monitoring signals by the LED lamp, and transmitting the optimized illumination signals and the attention monitoring signals to the data interconnection module together to complete the secondary advanced hierarchical analysis;
the data monitoring module is used for monitoring the voltage value and the current value of the LED lamp and the power line where the LED lamp is located in real time and storing the voltage value and the current value into the internal space;
after receiving the real-time optimized lighting signal, the data interconnection module edits a text of power supply and lighting to be overhauled with the corresponding LED lamp, and sends the text and the LED lamp to a mobile phone of a manager together, and the mobile phone of the manager is communicated with the data interconnection module in a wireless transmission mode and the like; after receiving the real-time attention monitoring signal, the data interconnection module sends the LED lamp corresponding to the data interconnection module to a display screen after the LED lamp is marked by letters; and then the illumination running condition of the full-spectrum LED lamp is subjected to the evaluation formula weight analysis calibrated by the differentiated data, the obtained processing signal is associated with the working condition of the corresponding power line, and the analysis is carried out by a primary verification formula, so that the obtained analysis signal is used for calling data to carry out secondary deep hierarchical analysis, and accordingly, reasonable illumination optimization measures are made, and the accuracy and pertinence of the processing process are improved.
The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (6)

1. The LED intelligent lighting system based on the full spectrum is characterized by comprising a data acquisition module, a data analysis module, a data processing module, an information collection module, a controller, a signal operation module, a data monitoring module and a data interconnection module;
the data acquisition module is used for acquiring the illumination working condition information of the LED lamp in real time and transmitting the illumination working condition information to the data analysis module;
after receiving the real-time illumination working condition information of the LED lamp, the data analysis module performs illumination working condition analysis operation on the LED lamp to obtain a fluctuating illumination signal and a normal illumination signal in a first time level, and transmits the fluctuating illumination signal and the normal illumination signal to the data processing module;
after receiving the real-time fluctuating illumination signal, the data processing module calls the line working condition information of each LED lamp in the same time period corresponding to the real-time fluctuating illumination signal from the information collecting module, analyzes the line working condition information, obtains a line fluctuating signal and a line monitoring signal in the same time period corresponding to the fluctuating illumination signal of the first time level, and transmits the line fluctuating signal and the line monitoring signal to the signal operation module through the controller;
the information collection module is used for collecting the line working condition information of the LED lamp in real time and storing the line working condition information to the inner space;
after receiving the real-time line monitoring signal, the signal operation module calls a real-time voltage value and a real-time current value of the corresponding LED lamp and the power line of the LED lamp from the data monitoring module, and sends the real-time voltage value and the real-time current value to a display screen after color marking;
after receiving the real-time line fluctuation signals, the signal operation module calls the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the signal operation module from the data processing module, wherein the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal lighting signals for 3 times or less and line fluctuation signals for 2 times or more, generating optimized lighting signals by the LED lamp, and under other conditions, generating attention monitoring signals by the LED lamp, and transmitting the optimized lighting signals and the attention monitoring signals to the data interconnection module;
the data monitoring module is used for monitoring the voltage value and the current value of the LED lamp and the power line where the LED lamp is located in real time and storing the voltage value and the current value into the internal space;
after receiving the real-time optimized lighting signal, the data interconnection module edits a text of power supply and lighting to be overhauled to the corresponding LED lamp, and sends the text and the LED lamp to a mobile phone of a manager; and after receiving the real-time attention monitoring signal, the data interconnection module sends the LED lamp corresponding to the data interconnection module to a display screen after the LED lamp is marked by letters.
2. The full spectrum based LED intelligent lighting system according to claim 1, wherein the lighting condition information of the LED lamp is composed of a power factor of the LED lamp, a voltage factor of the LED lamp and a temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, and the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation and the environment temperature variation of the LED lamp.
3. The full spectrum-based LED intelligent lighting system according to claim 1, wherein the lighting condition analyzing operation comprises the following steps:
the method comprises the following steps: acquiring lighting working condition information of the LED lamps in a first time level, and respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence with each other, and the first time level represents the duration of 5 minutes;
step two: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
step three: the power factor Qi of each LED lamp, the voltage factor Wi of each LED lamp and the temperature factor Ei of each LED lamp are given with weight coefficients z, x and c respectively, z is larger than c and is larger than x, and z + x + c is 4.2899, then the illumination stability magnitude Ri of each LED lamp in the first time level is obtained according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, the LED lamp corresponding to the Ri generates a fluctuating illumination signal, otherwise, the LED lamp corresponding to the Ri generates a normal illumination signal.
4. The full spectrum-based LED intelligent lighting system according to claim 1, wherein the line operating condition information of the LED lamp is composed of line heat generation data of the LED lamp, line current data of the LED lamp, and line partial discharge data of the LED lamp; the circuit heat production data of the LED lamp represents total heat energy generated by a power circuit where the LED lamp is located, the circuit current data of the LED lamp represents total current variation when the power circuit where the LED lamp is located operates, and the circuit partial discharge data of the LED lamp represents total partial discharge generated by the power circuit where the LED lamp is located.
5. The full spectrum based LED intelligent lighting system according to claim 1, wherein the specific steps of the line condition analyzing operation are as follows:
the method comprises the following steps: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat generation data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, and Tj, Yj and Uj are in one-to-one correspondence with each other;
step two: according to the formula
Figure FDA0002341958270000031
Obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than t and smaller than y, and t + y + u is 3.2881, delta, epsilon and mu are verification coefficients, delta is larger than epsilon and larger than mu, and delta + epsilon + mu is 2.8441;
step three: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj.
6. The LED intelligent lighting method based on the full spectrum is characterized by comprising the following steps:
the method comprises the following steps: the method comprises the following steps of collecting illumination working condition information of the LED lamp in real time, and analyzing the illumination working condition of the LED lamp, wherein the method comprises the following steps:
s1: acquiring lighting working condition information of the LED lamps in a first time level, and respectively calibrating power factors of the LED lamps, voltage factors of the LED lamps and temperature factors of the LED lamps to be Qi, Wi and Ei, wherein i is 1.. n, the Qi, the Wi and the Ei are in one-to-one correspondence with each other, and the first time level represents the duration of 5 minutes;
s2: when the power factor Qi of each LED lamp is greater than the maximum value of the preset range q, within the preset range q, and less than the minimum value of the preset range q, respectively giving calibration positive values M1, M2, and M3, and M1 is greater than M2 and greater than M3; when the voltage factor Wi of each LED lamp is larger than the maximum value of the preset range w, is positioned in the preset range w and is smaller than the minimum value of the preset range w, the voltage factor Wi is respectively endowed with calibration positive values N1, N2 and N3, and N1 is larger than N2 and is larger than N3; when the temperature factor Ei of each LED lamp is larger than the maximum value of the preset range e, is located in the preset range e and is smaller than the minimum value of the preset range e, the temperature factor Ei is respectively endowed with calibration positive values B1, B2 and B3, and B1 is larger than B2 and is larger than B3;
s3: firstly, respectively endowing a power factor Qi of each LED lamp, a voltage factor Wi of each LED lamp and a temperature factor Ei of each LED lamp with weight coefficients z, x and c, wherein z is larger than c and is larger than x, and z + x + c is 4.2899, then obtaining the illumination stability magnitude Ri of each LED lamp in a first time level according to a formula Ri Qi + z + Wi x + Ei, when the illumination stability magnitude Ri is larger than a preset value r, generating a fluctuating illumination signal for the LED lamp corresponding to the Ri, otherwise, generating a normal illumination signal for the LED lamp corresponding to the Ri;
obtaining a fluctuating illumination signal and a normal illumination signal within a first time level;
step two: according to the real-time fluctuating illumination signals, the line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signals is called, and line working condition analysis operation is carried out on the line working condition information, and the method comprises the following specific steps:
d1: acquiring line working condition information of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and respectively marking line heat generation data of each LED lamp, line current data of each LED lamp and line partial discharge data of each LED lamp as Tj, Yj and Uj, wherein j is 1.. m, and Tj, Yj and Uj are in one-to-one correspondence with each other;
d2: according to the formula
Figure FDA0002341958270000051
Obtaining line factors Pj, t, y and u of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, wherein u is smaller than t and smaller than y, and t + y + u is 3.2881, delta, epsilon and mu are verification coefficients, delta is larger than epsilon and larger than mu, and delta + epsilon + mu is 2.8441;
d3: comparing the line factors Pj of each LED lamp in the same time period corresponding to the fluctuating illumination signal of the first time level, and when the line factors Pj are greater than or equal to a preset value p, generating a line fluctuating signal by the LED lamp corresponding to the Pj, otherwise, generating a line monitoring signal by the LED lamp corresponding to the Pj;
obtaining a line fluctuation signal and a line monitoring signal in the same time period corresponding to the fluctuation illumination signal of the first time level;
step three: according to the real-time line monitoring signals, the real-time voltage values and the real-time current values of the corresponding LED lamps and the power lines where the LED lamps and the power lines are located are taken, and the real-time voltage values and the real-time current values are sent to a display screen after being subjected to color marking; according to the real-time line fluctuation signals, calling the normal illumination signals, the fluctuation illumination signals, the line fluctuation signals and the line monitoring signals of the LED lamps in a second time level corresponding to the real-time line fluctuation signals, wherein the second time level represents the time length of 30 minutes after the first time level; when the LED lamp generates normal illumination signals for 3 times or less and the line fluctuation signals for 2 times or more, generating optimized illumination signals by the LED lamp, and otherwise, generating attention monitoring signals by the LED lamp;
step four: editing a power supply and illumination to-be-overhauled text of the corresponding LED lamp according to the real-time optimized illumination signal, and sending the text and the LED lamp to a mobile phone of a manager; according to the real-time attention monitoring signal, the LED lamp corresponding to the attention monitoring signal is sent to a display screen after being marked by letters;
the lighting working condition information of the LED lamp consists of the power factor of the LED lamp, the voltage factor of the LED lamp and the temperature factor of the LED lamp; the power factor of the LED lamp represents the total variation between the output power and the rated power of the LED lamp, the voltage factor of the LED lamp represents the maximum fluctuation value between the working voltage and the rated voltage of the LED lamp, and the temperature factor of the LED lamp represents the maximum fluctuation value between the working temperature variation and the environment temperature variation of the LED lamp;
the circuit working condition information of the LED lamp consists of circuit heat production data of the LED lamp, circuit current data of the LED lamp and circuit partial discharge data of the LED lamp; the line heat production data of the LED lamp represents total heat energy generated by a power line where the LED lamp is located, the line current data of the LED lamp represents total current variation when the power line where the LED lamp is located operates, and the line partial discharge data of the LED lamp represents total partial discharge generated by the power line where the LED lamp is located.
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