CN112188701B - Monitoring system for stage lighting - Google Patents

Abstract

The invention discloses a monitoring system for stage lighting, which comprises a processor, an effect monitoring module, a danger monitoring module, an equipment initial inspection module, a driving control module, a data storage module and an early warning display module, wherein the effect monitoring module is used for monitoring the effect of stage lighting; the effect monitoring module is arranged, and the effect monitoring module can bring good experience to audiences by monitoring and adjusting the stage effect; the danger monitoring module is arranged, and the danger of the lamp can be avoided by monitoring the stage lighting, so that the safety of audiences and workers is protected; the invention is provided with the equipment initial inspection module, and the equipment initial inspection module is used for carrying out safety monitoring on electric equipment, lamps and fire-proof facilities, so that the danger caused by stage lighting can be eliminated in advance, and the safety is improved.

Description

Monitoring system for stage lighting

Technical Field

The invention belongs to the technical field of stage equipment control, and particularly relates to a monitoring system for stage lighting.

Background

The stage lighting is also called stage lighting, and is called lighting for short, and is one of the key means of stage art modeling. With the development of the plot, the stage lighting equipment and the technical means are applied to create the environment, render the atmosphere and highlight the central characters through the light color and the change thereof, create the space sense and the time sense of the stage, shape the external image of the stage performance and provide necessary lighting effect. While the aesthetic feeling of the stage is improved, a large number of lamps are concentrated on the stage, so that a series of safety problems are caused.

The patent of publication number CN207740867U provides a stage lighting heat abstractor, including stage main part, motor and axis of rotation, the last fixed surface of stage main part has the slide rail, and the inside of slide rail has placed the gyro wheel, the gyro wheel is fixed in the bottom of mount, and is provided with the connecting rod on the mount, the one end of connecting rod is fixed on the fan shell, and the bottom mounting of fan shell has a handle bar, the motor sets up in the inside of fan shell, and the motor is connected with the fan shell through the dead lever, the one end of axis of rotation is connected with the motor, and the other end of axis of rotation is connected with the flabellum. This stage lighting heat abstractor is provided with the slide rail at the upper surface of stage main part to the mount is connected with the slide rail through the gyro wheel of its bottom, and the area of whole stage is very big, and the different time needs radiating position also different, can adjust the front and back position of mount like this through slide rail and gyro wheel.

The scheme takes the problem of the rise of the stage temperature caused by the heating of the stage lighting into consideration, and provides the stage lighting heat dissipation device which solves the problem of the rise of the stage temperature to a certain extent; however, the above solution does not provide the function of early warning, and only deals with the temperature rise caused by the stage light, so the above solution still needs to be further improved.

Disclosure of Invention

In order to solve the problems of the scheme, the invention provides a monitoring system for stage lighting.

The purpose of the invention can be realized by the following technical scheme: a monitoring system for stage lighting comprises a processor, an effect monitoring module, a danger monitoring module, an equipment primary detection module, a driving control module, a data storage module and an early warning display module;

the effect monitoring module is used for monitoring the lighting effect of stage lighting, the lighting effect includes main light intensity, supplementary light intensity, magenta proportion, yellow proportion and cyan proportion of stage lighting, and concrete monitoring step is:

z1: acquiring a stage lighting mode;

z2: when stage lighting mode is for predetermineeing the light mode, acquire stage performance form serial number and adjust light, concrete regulation step is:

z21: acquiring a serial number i of a stage performance form; acquiring a light intensity preset scheme and a color preset scheme corresponding to the number i through a data storage module;

z22: acquiring a main light intensity ZGi and an auxiliary light intensity FGi of the current stage lighting, acquiring a light intensity superposition coefficient GDi through a formula Di = alpha 1 × ZGi + alpha 2 × FGi, and acquiring a light intensity superposition coefficient GDi through a formula

Acquiring a light intensity distribution coefficient GFi, wherein alpha 1, alpha 2 and alpha 3 are preset proportionality coefficients, and alpha 1+ alpha 2=0.5 × alpha 3;

z23: acquiring a magenta proportion SPi, a yellow proportion SHI and a cyan proportion SQi of current stage lighting, acquiring a color superposition coefficient YDi through a formula YDi = beta 1 × SPi + beta 2 × SHI + beta 3 × SQi, and acquiring a color superposition coefficient 324 zxft 3242 through a formula YFi = beta 4 × e ^{-β5×(SPi+SHi+SQi)} Acquiring a color distribution coefficient YFi, wherein beta 1, beta 2, beta 3, beta 4 and beta 5 are preset proportionality coefficients, beta 1+ beta 2+ beta 3=1.125, beta 4-0.1 × beta 5=0;

z24: when the YGDi-gamma 1 is not less than the GDi and not more than the YGDi + gamma 1 and the YGFi-gamma 2 is not less than the GFi and not more than the YGFi + gamma 2, the main light intensity, the auxiliary light intensity, the light intensity superposition coefficient and the light intensity distribution coefficient are sent to the early warning display module and the data storage module through the processor; otherwise, sending a light intensity adjusting instruction to the driving control module through the processor; the YGDi is a preset light intensity superposition coefficient, the YGFi is a preset light intensity distribution coefficient, the gamma 1 and the gamma 2 are preset proportionality coefficients, and the gamma 1 is more than 0 and the gamma 2 is more than or equal to 0.1;

z25: when YYDi-delta 1 is not less than YDi and not more than YYDi + delta 1 and YYFi-delta 2 is not less than YFi and not more than YFi + delta 2, sending the magenta ratio, the yellow ratio, the cyan ratio, the color superposition coefficient and the color distribution coefficient to the early warning display module and the data storage module through the processor; otherwise, sending a color adjusting instruction to the driving control module through the processor; the method comprises the following steps of (1) enabling YYDi to be preset color superposition coefficients, YYYFi to be preset color distribution coefficients, delta 1 and delta 2 to be preset proportional coefficients, and enabling 0< delta 1 > to be not more than delta 2 to be constructed into (0.1125);

z3: when the stage lighting mode is the manual regulation mode, acquiring the stage performance form serial number and regulating the light, wherein the specific regulation steps are as follows:

z31: acquiring a serial number i of a stage performance form; acquiring a preset light intensity preset scheme and a preset color scheme corresponding to the number i through a data storage module;

z32: displaying the data of the light intensity preset scheme and the color preset scheme acquired in the step Z31 through an early warning display module, and adjusting the main light intensity, the auxiliary light intensity, the magenta ratio, the yellow ratio and the cyan ratio of stage lighting through a driving control module;

z33: acquiring an artificial light intensity superposition coefficient RGDI and an artificial light intensity distribution coefficient RGFi through a formula in Z22 and a light effect in Z32; acquiring an artificial color superposition coefficient RYDi and an artificial color distribution coefficient RYFi according to a formula in Z23 and a light effect in Z32;

z34: when the YGDi-gamma 1 is not less than RGDI not more than YGDi + gamma 1 and the YGFi-gamma 2 is not less than RGFi not more than YGFi + gamma 2, no instruction is sent; otherwise, setting the light intensity preset scheme data in the early warning display module to be red flashing; when the YYDi-delta 1 is not less than or equal to RYDi and not more than YYDi + delta 1 and the YYFi-delta 2 is not less than or equal to RYFi and not more than YFi + delta 2, no command is sent; otherwise, the color preset scheme in the early warning display module is set to be blue flashing.

Preferably, the danger monitoring module is used for monitoring working data in real time, the working data include temperature value, the speed of clipper, the average value of lamps and lanterns vibration amplitude and the minimum distance of lamps and lanterns and curtain, and concrete monitoring step is:

x1: acquiring a temperature value above the stage, and marking the temperature value as WD; acquiring the speed of the lamp console pusher, and marking the speed as TS; obtaining the vibration amplitude of the lamp on the stage, and marking the vibration amplitude as ZP after solving the average value of the vibration amplitude; acquiring the minimum distance between a lamp on the stage and the curtain, and marking the minimum distance as XL;

x2: when TS is larger than L1 and ZP is larger than L2, sending a resistance increasing instruction to a driving control module through a processor, wherein L1 is a preset clipper speed threshold value, and L2 is a preset vibration amplitude average value threshold value;

x3: when WD is greater than L3 and XL is greater than L4, a stage heat dissipation instruction is sent to the driving control module through the processor, and a stage high-temperature instruction is sent to the early warning display module; wherein L3 is a preset stage temperature threshold, and L4 is a preset minimum distance threshold;

x4: by the formula

Obtaining a stage risk coefficient WW, wherein delta 1 and delta 2 are preset proportionality coefficients, and delta 1<δ 2,e is a natural constant;

x5: when WW is larger than L5, an emergency refuge instruction is sent to the driving control module and the early warning display module through the processor; wherein L5 is a preset stage risk coefficient threshold.

Preferably, the driving control module comprises a lamp console control unit, a heat dissipation unit and an emergency unit; when the drive control module receives the light intensity adjusting instruction or the color adjusting instruction, the stage lighting is adjusted through the lamp console; when the driving control module receives the resistance increasing instruction, the resistance of the lamp console pusher is increased through the lamp console control unit; when the drive control module receives a stage high-temperature instruction, the stage is cooled through the heat dissipation unit; when the driving control module receives the emergency escape instruction, the power supply of the stage lighting is cut off, and only the emergency lamp is kept on.

Preferably, the equipment preliminary examination module includes electric leakage detecting element, lamps and lanterns detecting element and fire prevention detecting element, and concrete detection step is:

c1: the electric leakage detection unit is used for carrying out electric leakage detection on the electric equipment, the electric leakage detection result is marked as LD, the LD value is 0 or 1, wherein 0 represents the existence of the electric leakage equipment, and 1 represents the absence of the electric leakage equipment;

c2: the lamp installation is detected through the lamp detection unit, the lamp detection result is marked as DJ, and the value of DJ is 0 or 1, wherein 0 represents that the lamp installation does not meet the requirement, and 1 represents that the lamp installation meets the requirement;

c3: the fireproof facilities are detected by a fireproof detection unit, the fireproof detection result is marked as FH, the value of the FH is 0 or 1, wherein 0 represents that the fireproof detection is unqualified, and 1 represents that the fireproof detection is qualified; the fire-protection facilities comprise fire hydrants and fire fighting channels;

c4: acquiring a device initial detection coefficient SB by a formula SB = LD multiplied by DJ multiplied by FH; when SB =1, sending an equipment initial inspection qualified instruction to an early warning display module through a processor; and when SB =0, sending an unqualified device initial inspection instruction to the early warning display module through the processor.

Preferably, the early warning display module includes display element and early warning unit, the data unit is used for the display data, the early warning unit is used for receiving the instruction and carries out the suggestion, the early warning unit includes alarm lamp and bee calling organ, and concrete suggestion step is:

v1: when the early warning unit receives a stage high-temperature instruction, the alarm lamp is set to be in a blue flashing state;

v2: when the early warning unit receives an emergency escape instruction, the alarm lamp is set to be in a red flashing state, and the buzzer gives an alarm;

v3: when the early warning unit receives an equipment initial inspection qualified instruction, the alarm lamp is set to be in a green normally-on state; when the early warning unit receives the unqualified device initial inspection instruction, the alarm lamp is set to be in an orange flashing state.

Preferably, the stage lighting mode comprises a manual adjusting mode and a preset lighting mode.

Preferably, the stage performance form numbers i =1, 2, 3, 4, 5 and 6; wherein 1 represents drama, 2 represents art, 3 represents music, 4 represents dance, 5 represents acrobatics, and 6 represents martial arts.

Preferably, the light intensity preset scheme comprises a preset light intensity superposition coefficient YGDi and a preset light intensity distribution coefficient YGFi; the color presetting scheme comprises a preset color superposition coefficient YYDi and a preset color distribution coefficient YYYFi.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention is provided with an effect monitoring module, which is used for monitoring the lighting effect of stage lighting and comprises a preset lighting mode and a manual adjusting mode; under a preset lighting mode, acquiring stage performance form numbers and lighting effects, acquiring a light intensity superposition coefficient, a light intensity distribution coefficient, a color superposition coefficient and a color distribution coefficient according to the lighting effects and a formula, comparing the light intensity superposition coefficient, the light intensity distribution coefficient, the color superposition coefficient and the color distribution coefficient with preset data, and automatically adjusting the lighting effects through a lamp console if the comparison result does not meet the requirements; under the manual adjustment mode, by acquiring stage performance form numbers and lighting effects, acquiring a light intensity superposition coefficient, a light intensity distribution coefficient, a color superposition coefficient and a color distribution coefficient according to the lighting effects and a formula, comparing the light intensity superposition coefficient, the light intensity distribution coefficient, the color superposition coefficient and the color distribution coefficient with preset data, and if the comparison result does not meet the requirements, performing early warning through an early warning display unit; the stage effect is monitored and adjusted, so that good experience can be brought to audiences;

2. the invention is provided with a danger monitoring module, and the setting is used for monitoring working data in real time; acquiring a temperature value above a stage, acquiring the speed of a lamp console pusher, acquiring the vibration amplitude of lamps on the stage, calculating the average value of the vibration amplitudes, and acquiring the minimum distance between the lamps on the stage and a curtain; the acquired data are analyzed independently, and corresponding instructions are sent to a driving control module or an early warning display module according to the analysis results; the method comprises the steps of obtaining a stage danger coefficient through a formula, comparing the stage danger coefficient with a preset stage danger coefficient threshold value, and sending a corresponding instruction to a driving control module and an early warning display module according to a comparison result; the device can avoid the danger of the lamp by monitoring the stage light, and is beneficial to protecting the safety of audiences and workers;

3. the device is provided with an equipment initial detection module, the equipment initial detection module is used for detecting the electric leakage of electric equipment through an electric leakage detection unit, detecting the installation of a lamp through a lamp detection unit, detecting a fireproof facility through a fireproof detection unit, acquiring an equipment initial detection coefficient through a formula, and early warning according to the value of the equipment initial detection coefficient; this setting carries out safety monitoring to consumer, lamps and lanterns and fire prevention facility, can get rid of the danger that stage lighting brought in advance, improves the security.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of the principle of the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a monitoring system for stage lighting includes a processor, an effect monitoring module, a danger monitoring module, an equipment preliminary inspection module, a driving control module, a data storage module, and an early warning display module;

the effect monitoring module is used for monitoring stage lighting's light effect, and light effect includes stage lighting's main light intensity, supplementary light intensity, magenta proportion, yellow proportion and cyan proportion, and concrete monitoring step is:

z1: acquiring a stage lighting mode;

z2: when the stage light mode is the preset light mode, the stage performance form number is acquired and the light is adjusted, and the specific adjusting step is as follows:

z21: acquiring a serial number i of a stage performance form; acquiring a light intensity preset scheme and a color preset scheme corresponding to the number i through a data storage module;

z22: acquiring a main light intensity ZGi and an auxiliary light intensity FGi of the current stage lighting, acquiring a light intensity superposition coefficient GDi through a formula Di = alpha 1 × ZGi + alpha 2 × FGi, and acquiring a light intensity superposition coefficient GDi through a formula

Acquiring a light intensity distribution coefficient GFi, wherein alpha 1, alpha 2 and alpha 3 are preset proportionality coefficients, and alpha 1+ alpha 2=0.5 × alpha 3;

z23: acquiring a magenta proportion SPi, a yellow proportion SHI and a cyan proportion SQi of current stage lighting, acquiring a color superposition coefficient YDi through a formula YDi = beta 1 × SPi + beta 2 × SHI + beta 3 × SQi, and acquiring a color superposition coefficient 324 zxft 3242 through a formula YFi = beta 4 × e ^{-β5×(SPi+SHi+SQi)} Acquiring a color distribution coefficient YFi, wherein beta 1, beta 2, beta 3, beta 4 and beta 5 are preset proportionality coefficients, beta 1+ beta 2+ beta 3=1.125, beta 4-0.1 × beta 5=0;

z24: when the YGDi-gamma 1 is not less than GDi and not more than YGDi + gamma 1 and the YGFi-gamma 2 is not less than GFi and not more than YGFi + gamma 2, the main light intensity, the auxiliary light intensity, the light intensity superposition coefficient and the light intensity distribution coefficient are sent to the early warning display module and the data storage module through the processor; otherwise, sending a light intensity adjusting instruction to the driving control module through the processor; the YGDi is a preset light intensity superposition coefficient, the YGFi is a preset light intensity distribution coefficient, the gamma 1 and the gamma 2 are preset proportionality coefficients, and the gamma 1 is more than 0 and the gamma 2 is more than or equal to 0.1;

z25: when YYDi-delta 1 is not less than YDi is not less than YYDi + delta 1 and YYFi-delta 2 is not less than YFi is not less than YYFi + delta 2, sending the magenta ratio, the yellow ratio, the cyan ratio, the color superposition coefficient and the color distribution coefficient to the early warning display module and the data storage module through the processor; otherwise, sending a color adjusting instruction to the driving control module through the processor; the method comprises the following steps of (1) enabling YYDi to be preset color superposition coefficients, YYYFi to be preset color distribution coefficients, delta 1 and delta 2 to be preset proportional coefficients, and enabling 0< delta 1 > to be not more than delta 2 to be constructed into (0.1125);

z3: when the stage lighting mode is the manual regulation mode, acquiring the stage performance form serial number and regulating the light, wherein the specific regulation steps are as follows:

z31: acquiring a serial number i of a stage performance form; acquiring a preset light intensity preset scheme and a preset color scheme corresponding to the number i through a data storage module;

z32: displaying the data of the light intensity preset scheme and the color preset scheme acquired in the step Z31 through an early warning display module, and adjusting the main light intensity, the auxiliary light intensity, the magenta ratio, the yellow ratio and the cyan ratio of stage lighting through a driving control module;

z33: acquiring an artificial light intensity superposition coefficient RGDI and an artificial light intensity distribution coefficient RGFi through a formula in Z22 and a light effect in Z32; acquiring an artificial color superposition coefficient RYDi and an artificial color distribution coefficient RYFi according to a formula in Z23 and a light effect in Z32;

z34: when the YGDi-gamma 1 is not less than RGDI not more than YGDi + gamma 1 and the YGFi-gamma 2 is not less than RGFi not more than YGFi + gamma 2, no instruction is sent; otherwise, setting the light intensity preset scheme data in the early warning display module to be red flashing; when the YYDi-delta 1 is not less than or equal to RYDi and not more than YYDi + delta 1 and the YYFi-delta 2 is not less than or equal to RYFi and not more than YFi + delta 2, no command is sent; otherwise, the color preset scheme in the early warning display module is set to be blue flashing.

Further, the danger monitoring module is used for monitoring working data in real time, the working data comprise a temperature value, a speed of the clipper, an average value of vibration amplitude of the lamp and a minimum distance between the lamp and the curtain, and the specific monitoring steps are as follows:

x1: acquiring a temperature value above the stage, and marking the temperature value as WD; acquiring the speed of the lamp console pusher, and marking the speed as TS; obtaining the vibration amplitude of the lamp on the stage, and marking the vibration amplitude as ZP after solving the average value of the vibration amplitude; acquiring the minimum distance between a lamp on the stage and the curtain, and marking the minimum distance as XL;

x2: when TS is larger than L1 and ZP is larger than L2, sending a resistance increasing instruction to a driving control module through a processor, wherein L1 is a preset clipper speed threshold, and L2 is a preset vibration amplitude average value threshold;

x3: when WD is greater than L3 and XL is greater than L4, a stage heat dissipation instruction is sent to the driving control module through the processor, and a stage high-temperature instruction is sent to the early warning display module; wherein L3 is a preset stage temperature threshold, and L4 is a preset minimum distance threshold;

x4: by the formula

Obtaining a stage risk coefficient WW, wherein delta 1 and delta 2 are preset proportionality coefficients, and delta 1<δ 2,e is a natural constant;

x5: when WW is larger than L5, an emergency refuge instruction is sent to the driving control module and the early warning display module through the processor; wherein L5 is a preset stage risk coefficient threshold.

Furthermore, the driving control module comprises a lamp console control unit, a heat dissipation unit and an emergency unit; when the drive control module receives the light intensity adjusting instruction or the color adjusting instruction, the stage lighting is adjusted through the lamp console; when the driving control module receives the resistance increasing instruction, the resistance of the lamp console pusher is increased through the lamp console control unit; when the drive control module receives a stage high-temperature instruction, the stage is cooled through the heat dissipation unit; when the driving control module receives the emergency escape instruction, the power supply of the stage lighting is cut off, and only the emergency lamp is kept on.

Further, the equipment primary detection module includes electric leakage detection unit, lamps and lanterns detecting element and fire prevention detecting element, and concrete detection step is:

c1: the electric leakage detection unit is used for carrying out electric leakage detection on the electric equipment, the electric leakage detection result is marked as LD, the LD value is 0 or 1, wherein 0 represents the existence of the electric leakage equipment, and 1 represents the absence of the electric leakage equipment;

c2: the installation of the lamp is detected through the lamp detection unit, the lamp detection result is marked as DJ, the value of the DJ is 0 or 1, wherein 0 represents that the lamp installation does not meet the requirement, and 1 represents that the lamp installation meets the requirement;

c3: the fireproof facilities are detected by a fireproof detection unit, the fireproof detection result is marked as FH, the value of the FH is 0 or 1, wherein 0 represents that the fireproof detection is unqualified, and 1 represents that the fireproof detection is qualified; the fire-fighting facilities comprise fire hydrants and fire fighting channels;

c4: acquiring a device initial detection coefficient SB by a formula SB = LD multiplied by DJ multiplied by FH; when SB =1, sending an equipment primary inspection qualified instruction to an early warning display module through a processor; and when SB =0, sending an unqualified primary inspection instruction of the equipment to the early warning display module through the processor.

Further, the early warning display module includes display element and early warning unit, and the data unit is used for the display data, and the early warning unit is used for receiving the instruction and carries out the suggestion, and the early warning unit includes alarm lamp and bee calling organ, and concrete suggestion step is:

v1: when the early warning unit receives a stage high-temperature instruction, the alarm lamp is set to be in a blue flashing state;

v2: when the early warning unit receives an emergency escape instruction, the alarm lamp is set to be in a red flashing state, and the buzzer gives an alarm;

v3: when the early warning unit receives an equipment initial inspection qualified instruction, the alarm lamp is set to be in a green normally-on state; when the early warning unit receives the unqualified device initial inspection instruction, the alarm lamp is set to be in an orange flashing state.

Further, the stage lighting mode comprises a manual adjusting mode and a preset lighting mode.

Further, the stage performance form numbers i =1, 2, 3, 4, 5, and 6; wherein 1 represents drama, 2 represents art, 3 represents music, 4 represents dance, 5 represents acrobatics, and 6 represents martial arts.

Further, the light intensity preset scheme includes a preset light intensity superposition coefficient YGDi and a light intensity distribution coefficient YGFi; the color presetting scheme includes a preset color superposition coefficient YYDi and a preset color distribution coefficient YYFi.

The above formulas are all quantitative calculation, the formula is a formula obtained by acquiring a large amount of data and performing software simulation to obtain the latest real situation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.

The working principle of the invention is as follows:

the effect monitoring module comprises a preset light mode and a manual adjusting mode; under a preset lighting mode, acquiring stage performance form numbers and lighting effects, acquiring a light intensity superposition coefficient, a light intensity distribution coefficient, a color superposition coefficient and a color distribution coefficient according to the lighting effects and a formula, comparing the light intensity superposition coefficient, the light intensity distribution coefficient, the color superposition coefficient and the color distribution coefficient with preset data, and automatically adjusting the lighting effects through a lamp console if the comparison result does not meet the requirements; under the manual adjustment mode, by acquiring stage performance form numbers and lighting effects, acquiring a light intensity superposition coefficient, a light intensity distribution coefficient, a color superposition coefficient and a color distribution coefficient according to the lighting effects and a formula, comparing the light intensity superposition coefficient, the light intensity distribution coefficient, the color superposition coefficient and the color distribution coefficient with preset data, and if the comparison result does not meet the requirements, performing early warning through an early warning display unit;

acquiring a temperature value above a stage, acquiring the speed of a lamp console pusher, acquiring the vibration amplitude of lamps on the stage, calculating the average value of the vibration amplitudes, and acquiring the minimum distance between the lamps on the stage and a curtain; the acquired data are analyzed independently, and corresponding instructions are sent to a driving control module or an early warning display module according to the analysis results; the method comprises the steps of obtaining a stage danger coefficient through a formula, comparing the stage danger coefficient with a preset stage danger coefficient threshold value, and sending a corresponding instruction to a driving control module and an early warning display module according to a comparison result;

carry out electric leakage detection to consumer through electric leakage detecting element, detect the installation of lamps and lanterns through lamps and lanterns detecting element, detect fire prevention facility through fire prevention detecting element, acquire equipment initial detection coefficient through the formula to carry out the early warning according to the value of equipment initial detection coefficient.

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

The 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 (5)

1. A monitoring system for stage lighting is characterized by comprising a processor, an effect monitoring module, a danger monitoring module, an equipment initial inspection module, a driving control module, a data storage module and an early warning display module;

the effect monitoring module is used for monitoring the lighting effect of stage lighting, the lighting effect includes main light intensity, supplementary light intensity, magenta proportion, yellow proportion and cyan proportion of stage lighting, and concrete monitoring step is:

z1: acquiring a stage lighting mode;

z2: when the stage light mode is the preset light mode, the stage performance form number is acquired and the light is adjusted, and the specific adjusting step is as follows:

z21: acquiring a serial number i of a stage performance form; acquiring a light intensity preset scheme and a color preset scheme corresponding to the number i through a data storage module;

z22: acquiring a main light intensity ZGi and an auxiliary light intensity FGi of the current stage lighting, acquiring a light intensity superposition coefficient GDi through a formula Di = alpha 1 × ZGi + alpha 2 × FGi, and acquiring a light intensity superposition coefficient GDi through a formula

Acquiring a light intensity distribution coefficient GFi, wherein alpha 1, alpha 2 and alpha 3 are preset proportionality coefficients, and alpha 1+ alpha 2=0.5 × alpha 3;

z23: acquiring a magenta proportion SPi, a yellow proportion SHI and a cyan proportion SQi of current stage lighting, acquiring a color superposition coefficient YDi through a formula YDi = beta 1 × SPi + beta 2 × SHI + beta 3 × SQi, and acquiring a color superposition coefficient 324 zxft 3242 through a formula YFi = beta 4 × e ^{-β5×(SPi+SHi+SQi)} Acquiring a color distribution coefficient YFi, wherein beta 1, beta 2, beta 3, beta 4 and beta 5 are preset proportionality coefficients, beta 1+ beta 2+ beta 3=1.125, beta 4-0.1 × beta 5=0;

z24: when the YGDi-gamma 1 is not less than the GDi and not more than the YGDi + gamma 1 and the YGFi-gamma 2 is not less than the GFi and not more than the YGFi + gamma 2, the main light intensity, the auxiliary light intensity, the light intensity superposition coefficient and the light intensity distribution coefficient are sent to the early warning display module and the data storage module through the processor; otherwise, sending a light intensity adjusting instruction to the driving control module through the processor; the YGDi is a preset light intensity superposition coefficient, the YGFi is a preset light intensity distribution coefficient, the gamma 1 and the gamma 2 are preset proportionality coefficients, and the gamma 1 is more than 0 and is more than or equal to gamma 2 and is less than or equal to 0.1;

z25: when YYDi-delta 1 is not less than YDi is not less than YYDi + delta 1, YYYFI-delta 2 is not less than YFi is not less than YYFI + delta 2, the magenta proportion, the yellow proportion, the cyan proportion, the color superposition coefficient and the color distribution coefficient are sent to the early warning display module and the data storage module through the processor; otherwise, sending a color adjusting instruction to the driving control module through the processor; the color matching method comprises the following steps of A, obtaining YYDi, YYYFi and delta 1 and delta 2, wherein the YYDi is a preset color superposition coefficient, the YYYFi is a preset color distribution coefficient, the delta 1 and the delta 2 are preset proportionality coefficients, and delta 1 is more than 0 and less than or equal to delta 2 and less than 0.1125;

z3: when the stage lighting mode is the manual regulation mode, acquiring stage performance form numbers and regulating light, wherein the specific regulation steps are as follows:

z31: acquiring a serial number i of a stage performance form; acquiring a preset light intensity preset scheme and a preset color scheme corresponding to the number i through a data storage module;

z32: displaying the data of the light intensity preset scheme and the color preset scheme acquired in the step Z31 through an early warning display module, and adjusting the main light intensity, the auxiliary light intensity, the magenta ratio, the yellow ratio and the cyan ratio of stage lighting through a driving control module;

z33: acquiring an artificial light intensity superposition coefficient RGDI and an artificial light intensity distribution coefficient RGFi through a formula in Z22 and a light effect in Z32; acquiring an artificial color superposition coefficient RYDi and an artificial color distribution coefficient RYFi according to a formula in Z23 and a light effect in Z32;

z34: when the YGDi-gamma 1 is not less than RGDI not more than YGDi + gamma 1 and the YGFi-gamma 2 is not less than RGFi not more than YGFi + gamma 2, no instruction is sent; otherwise, setting the light intensity preset scheme data in the early warning display module to be red flashing; when the YYDi-delta 1 is not less than or equal to RYDi and not more than YYDi + delta 1 and the YYFi-delta 2 is not less than or equal to RYFi and not more than YFi + delta 2, no command is sent; otherwise, the color preset scheme in the early warning display module is set to be blue flashing.

2. A monitoring system for stage lighting according to claim 1, wherein the hazard monitoring module is configured to monitor the working data in real time, the working data includes a temperature value, a speed of the clipper, an average value of vibration amplitudes of the lamp, and a minimum distance between the lamp and the curtain, and the monitoring steps are as follows:

x1: acquiring a temperature value above the stage, and marking the temperature value as WD; acquiring the speed of the lamp console pusher, and marking the speed as TS; obtaining the vibration amplitude of the lamp on the stage, and marking the vibration amplitude as ZP after solving the average value of the vibration amplitude; acquiring the minimum distance between a lamp on the stage and the curtain, and marking the minimum distance as XL;

x2: when TS is larger than L1 and ZP is larger than L2, sending a resistance increasing instruction to a driving control module through a processor, wherein L1 is a preset clipper speed threshold value, and L2 is a preset vibration amplitude average value threshold value;

x3: when WD is larger than L3 and XL is larger than L4, a stage heat dissipation instruction is sent to the driving control module through the processor, and a stage high-temperature instruction is sent to the early warning display module; wherein L3 is a preset stage temperature threshold, and L4 is a preset minimum distance threshold;

x4: by the formula

Obtaining a stage risk coefficient WW, wherein delta 1 and delta 2 are preset proportionality coefficients, and delta 2,e is a natural constant when delta 1 is larger than delta 5363;

x5: when WW is larger than L5, an emergency refuge instruction is sent to the driving control module and the early warning display module through the processor; wherein L5 is a preset stage risk coefficient threshold.

3. A monitoring system for stage lighting according to claim 1, wherein the drive control module comprises a light console control unit, a heat dissipation unit and an emergency unit; when the drive control module receives the light intensity adjusting instruction or the color adjusting instruction, the stage lighting is adjusted through the lamp console; when the driving control module receives the resistance increasing instruction, the resistance of the lamp console pusher is increased through the lamp console control unit; when the drive control module receives a stage high-temperature instruction, the stage is cooled through the heat dissipation unit; when the driving control module receives the emergency escape instruction, the power supply of the stage lighting is cut off, and only the emergency lamp is kept on.

4. A monitoring system for stage lighting according to claim 1, wherein the equipment preliminary examination module includes an electric leakage detection unit, a lamp detection unit and a fire prevention detection unit, and the specific detection steps are as follows:

c1: the electric leakage detection unit is used for carrying out electric leakage detection on the electric equipment, the electric leakage detection result is marked as LD, the LD value is 0 or 1, wherein 0 represents the existence of the electric leakage equipment, and 1 represents the absence of the electric leakage equipment;

c2: the lamp installation is detected through the lamp detection unit, the lamp detection result is marked as DJ, and the value of DJ is 0 or 1, wherein 0 represents that the lamp installation does not meet the requirement, and 1 represents that the lamp installation meets the requirement;

c3: the fireproof facilities are detected by a fireproof detection unit, the fireproof detection result is marked as FH, the value of the FH is 0 or 1, wherein 0 represents that the fireproof detection is unqualified, and 1 represents that the fireproof detection is qualified;

c4: acquiring a device initial detection coefficient SB by a formula SB = LD multiplied by DJ multiplied by FH; when SB =1, sending an equipment initial inspection qualified instruction to an early warning display module through a processor; and when SB =0, sending an unqualified device initial inspection instruction to the early warning display module through the processor.

5. The monitoring system for stage lighting according to claim 1, wherein the early warning display module includes a display unit and an early warning unit, the data unit is used for displaying data, the early warning unit is used for receiving instructions and giving a prompt, the early warning unit includes an alarm lamp and a buzzer, and the specific prompting steps are as follows:

v1: when the early warning unit receives a stage high-temperature instruction, the alarm lamp is set to be in a blue flashing state;

v2: when the early warning unit receives an emergency escape instruction, the alarm lamp is set to be in a red flashing state, and the buzzer gives an alarm;

v3: when the early warning unit receives an equipment initial inspection qualified instruction, the alarm lamp is set to be in a green normally-on state; when the early warning unit receives the unqualified device initial inspection instruction, the alarm lamp is set to be in an orange flashing state.

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