CN116669267A - Cloud monitoring method and device for stage lamp, computer equipment and storage medium - Google Patents

Abstract

The application relates to a cloud monitoring method, a cloud monitoring device, computer equipment and a storage medium of a stage lamp, wherein the method comprises the steps of obtaining monitoring feedback data of the stage lamp in a current running state and internal current data corresponding to the current running state, analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp, carrying out power adjustment on a current display function of the stage lamp according to the fault event data to obtain display power parameters of the stage lamp, summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority. The application has the effect of improving the monitoring timeliness of the fault hidden trouble of the stage lamp.

Description

Cloud monitoring method and device for stage lamp, computer equipment and storage medium

Technical Field

The application relates to the technical field of stage lamp control, in particular to a cloud monitoring method and device for stage lamps, computer equipment and a storage medium.

Background

At present, stage lamps are widely applied to the scene of each large performance, stage art modeling is carried out through the combination of various light equipment, so that the outside rendering is carried out on performers or performance drafts, more gorgeous and shocking stage effects are presented for audiences, and therefore, higher requirements are also put forward on the safety of the stage lamps in the performance process.

In the existing stage lamp monitoring method, the lamps are monitored in real time through monitoring equipment such as a camera and the like on site, so that when abnormal conditions such as spontaneous combustion sparks or non-display and the like occur to the lamps, the stage lamps are monitored through abnormal images corresponding to the abnormal conditions, but fault conditions such as internal data exceeding standard or internal invisible wear and tear of the lamps cannot be collected by the camera, and certain hysteresis exists in the monitoring of the stage lamps in the initial stage of the invisible display fault, so that the existing stage lamp monitoring mode has the defect of insufficient time in monitoring the fault hidden danger of the stage lamps.

Disclosure of Invention

In order to improve monitoring timeliness of fault hidden danger of stage lamps, the application provides a cloud monitoring method, a cloud monitoring device, computer equipment and a storage medium of stage lamps.

The first object of the present application is achieved by the following technical solutions:

A cloud monitoring method of stage lamps, comprising:

acquiring monitoring feedback data of stage lamps in a current running state and internal current data corresponding to the current running state;

analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

according to the fault event data, performing power adjustment on the current display function of the stage lamp to obtain the display power parameter of the stage lamp;

and summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority.

Through adopting above-mentioned technical scheme, through the acquisition to the control passback data of the stage lamp of present running state, monitor the light display effect of stage lamp, and monitor the inside running state of stage lamp through inside current data, help carrying out the multidimensional control to stage lamp, and carry out fault parameter analysis to stage lamp through control passback data and inside current data, thereby help carrying out comprehensive remote monitoring to stage lamp through stage lamp's fault event data, and adjust the power of present display function according to fault event data, help carrying out the compensation to stage lamp's fault parameter according to showing the power parameter, reduce the risk of stage lamp self trouble, make stage lamp's inside current service condition and stage lamp's present display effect looks adaptation, and gather the fault event data that shows power parameter and corresponds, form the stage fault set of being convenient for remote transmission, and carry out the multidimensional control to stage lamp through the monitor end that corresponds the control authority, carry out the omnidirectional control to stage lamp through stage lamp outside light display effect and inside current flow direction, improve the timeliness of hiding the fault monitoring, and through the fault probability of the stage lamp of reducing the inside fault probability of adjusting, thereby the fault probability of stage lamp emergence of the inside fault bead of stage lamp.

The present application may be further configured in a preferred example to: the step fault parameters are analyzed according to the monitoring feedback data and the internal current data to obtain the fault event data of the step lamp, and the step lamp fault event data comprises the following specific steps:

analyzing the lamp bead display function of the stage lamp according to the monitoring feedback data to obtain display function analysis data corresponding to the current monitoring time node;

performing power supply allocation processing on the display function analysis data according to the internal current data to generate a power utilization allocation scheme of the current display combination of the stage lamp;

according to the electricity utilization allocation scheme, position marks are carried out on the lamp beads with abnormal electricity utilization, and abnormal lamp bead position parameters are obtained;

and carrying out electric energy abnormality association on the abnormal lamp bead position parameters and the corresponding power utilization allocation scheme to obtain fault event data corresponding to the stage lamp power utilization abnormal faults.

By adopting the technical scheme, the display analysis is carried out on the lamp bead display function of the stage lamp according to the monitoring feedback data of the stage lamp, whether the actual lamp bead display function corresponds to the current monitoring time node is judged, accurate monitoring is facilitated on the display error between the lamp bead display function of the stage lamp and the corresponding display effect according to the display function analysis data, so that the power supply allocation processing can be carried out on the display function analysis data according to the internal current data, the power consumption allocation scheme of the stage lamp is matched with the lamp bead matching sequence of the current display combination, the rationality of electric energy allocation is improved, and in the monitoring process of the power consumption allocation, the position of the abnormal lamp bead is marked, so that the accurate assembly position of the abnormal lamp bead in the stage lamp is obtained, the abnormal lamp bead is conveniently and specifically monitored, the monitoring accuracy of the abnormal lamp bead is improved, the position parameter of the abnormal lamp bead is associated with the corresponding power consumption allocation scheme according to the abnormal condition of the electric energy, the fault analysis corresponding to the abnormal fault of the stage lamp is facilitated, and the monitoring accuracy of the fault lamp bead of the abnormal power consumption condition is improved.

The present application may be further configured in a preferred example to: and according to the fault event data, performing power adjustment on the current display function of the stage lamp to obtain the display power parameter of the stage lamp, wherein the method specifically comprises the following steps:

acquiring a switching time node for switching adjacent display functions of the stage lamp according to the fault event data;

performing time delay calculation on the switching time node to obtain a switching time delay parameter corresponding to the current display state of the stage lamp;

according to the switching delay parameter, evaluating the current working performance of the stage lamp to obtain a performance evaluation result of the stage lamp;

and monitoring the residual service life of the stage lamp in the current running state according to the performance evaluation result.

Through adopting above-mentioned technical scheme, when the stage lamp breaks down, obtain the switching time node when the stage lamp carries out adjacent demonstration function switching according to corresponding fault event data, help carrying out accurate control to the display error influence of stage lamp according to switching time node, and calculate the function switching time delay of stage lamp through switching time node, thereby obtain the function switching time delay parameter of stage lamp under current fault influence, help carrying out accurate control to the current display state of stage lamp according to switching time delay parameter, and evaluate the current working property of stage lamp according to switching time delay parameter, help carrying out the performance evaluation result through the stage lamp, monitor the influence error of current fault event to stage lamp working property, monitor the working property error of stage lamp from the multidimensional monitoring fault event, improve the control comprehensiveness of stage lamp, predict the remaining service life of stage lamp according to the performance evaluation result, thereby be convenient for carry out remaining service life control to the stage lamp under the current running state, can in time carry out maintenance to the fault lamp pearl according to remaining service life, thereby improve the whole working stability of stage lamp.

The present application may be further configured in a preferred example to: the step lamp in the current running state is monitored for residual service life according to the performance evaluation result, and the method specifically comprises the following steps:

acquiring the current working temperature of the stage lamp under the current working performance according to the performance evaluation result;

when the current working temperature has overload risk, calculating a temperature difference value between the current working temperature and a preset working temperature threshold;

according to the temperature difference, performing temperature cooling adjustment on the overload lamp beads of the stage lamp to obtain working temperature monitoring data of the stage lamp;

and predicting the residual working life of the stage lamp in the current running state according to the working temperature monitoring data to obtain a life prediction result corresponding to the current overload risk.

Through adopting above-mentioned technical scheme, obtain the current operating temperature of stage lamp under the current performance according to the performance evaluation result, help carrying out the control to the current operating performance of stage lamp according to current operating temperature, and when current operating temperature has overload risk, calculate the temperature difference between current operating temperature and the preset operating temperature threshold, help carrying out overload temperature difference compensation to stage lamp according to the temperature difference, reduce stage lamp's temperature overload risk, and through the temperature cooling regulation to overload lamp pearl, the fan of control stage lamp carries out the heat dissipation work to overload lamp pearl, thereby monitor stage lamp's operating temperature, help carrying out the prediction to stage lamp's temperature monitoring convenience according to operating temperature monitoring data, and carry out the suitability of prediction life-span result and current temperature overload risk to stage lamp's remaining operating life according to operating temperature monitoring data under the current running state, improve stage lamp's operating life monitoring accuracy.

The present application may be further configured in a preferred example to: the step lamp in the current running state is monitored for residual service life according to the performance evaluation result, and the method further comprises the following steps:

acquiring the current illuminance of the stage lamp in the current running state;

when the current illuminance exceeds a preset exposure threshold, adjusting the light source power of the stage lamp;

according to the light source power, carrying out state adjustment on the light source display state of the stage lamp to obtain a light source state adjustment parameter corresponding to the switching state of the current display function of the stage lamp;

and monitoring the light source state of the stage lamp according to the light source state adjusting parameters.

Through adopting above-mentioned technical scheme, obtain the current illuminance of stage lamp under the current running state of stage lamp, help judging whether there is the exposure phenomenon at current stage lamp, and when current illuminance exceeded the exposure threshold value of predetermineeing, adjust the light source power of the light source of stage lamp, reduce the exposure risk of stage lamp through the light source power regulation, further, according to current light source power, carry out the state adjustment to the light source display state of stage lamp, make the switching state looks adaptation of the current state of light source after adjusting and current display function, and according to light source state adjustment parameter, monitor the light source state of stage lamp, thereby improve the control comprehensiveness to the stage lamp light source, reduce the display error of stage lamp light source exposure.

The present application may be further configured in a preferred example to: summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority, and further comprising:

acquiring a working signal of each lamp bead of the stage lamp and a response time of the working signal;

according to the response time length, signal fault analysis is carried out on the abnormal signal reception of the stage lamp, and a signal fault analysis result corresponding to the working state of each lamp bead is obtained;

re-planning the current power utilization allocation scheme of the stage lamp according to the signal fault analysis result to obtain an electric energy adjustment scheme for shunting the electric energy corresponding to the fault lamp bead;

and monitoring the signal receiving and transmitting state of the stage lamp according to the electric energy adjustment scheme.

Through adopting above-mentioned technical scheme, according to the receiving and dispatching state of stage lamp pearl to control signal, obtain the working signal of every lamp pearl of stage lamp and the signal response duration of every lamp pearl to working signal, help judging whether there is signal reception abnormality at present lamp pearl according to signal response duration, thereby signal fault analysis is carried out to the signal reception abnormality of stage lamp, help monitoring whether can normal operating to the current working state of every lamp pearl according to signal fault analysis result, reduce the abnormal error of lamp pearl signal reception state, and according to signal fault analysis result, plan again the current power consumption allotment scheme of stage lamp, make the electric energy allotment of stage lamp laminate the combination condition of current lamp pearl more, and shunt the corresponding electric energy of trouble lamp pearl, help improving the electric energy utilization ratio of stage lamp through the electric energy adjustment scheme, monitor the signal receiving and dispatching state of stage lamp according to the electric energy adjustment scheme, help expanding the current electric energy allotment condition and the monitoring dimension of signal receiving and dispatching state of stage lamp, improve the monitoring accuracy to hidden trouble of stage lamp.

The present application may be further configured in a preferred example to: and according to the response time length, performing signal fault analysis on the abnormal signal reception of the stage lamp to obtain a signal fault analysis result corresponding to the working state of each lamp bead, and further comprising:

according to the response time length, performing function switching time delay analysis on the control lamp beads corresponding to the stage lamps to obtain a function switching hysteresis parameter;

according to the function switching hysteresis parameter, the duty ratio switching speed of the current display color of the control lamp bead is adjusted;

and carrying out state association on the duty ratio switching speed and the signal receiving and transmitting state of the control lamp bead to obtain the signal control data of the stage lamp.

Through adopting above-mentioned technical scheme, according to the response duration of stage lamp pearl to control signal, carry out function switching delay analysis to the lamp pearl under the current display mode of stage lamp, help judging whether current function switching delay can influence the whole display effect of stage lamp according to the hysteresis parameter of function switching, and according to the hysteresis parameter of function switching, adjust the duty cycle switching speed of the current display colour of control lamp pearl, help reducing the influence of function switching hysteresis to the stage lamp display effect, thereby make the current display colour and the current display function looks adaptation of stage lamp, and carry out the state association with the signal receiving and dispatching state of duty cycle switching speed and control lamp pearl, be convenient for carry out remote transmission with the stage lamp signal control data after the association, improve the data relativity between the signal control data of stage lamp, help the control convenience of stage lamp.

The second object of the present application is achieved by the following technical solutions:

a cloud monitoring device of stage lamps, comprising:

the data acquisition module is used for acquiring monitoring feedback data of the stage lamp in the current running state and internal current data corresponding to the current running state;

the data analysis module is used for analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

the data processing module is used for carrying out power adjustment on the current display function of the stage lamp according to the fault event data to obtain the display power parameter of the stage lamp;

and the data monitoring module is used for summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority.

Through adopting above-mentioned technical scheme, through the acquisition to the control passback data of the stage lamp of present running state, monitor the light display effect of stage lamp, and monitor the inside running state of stage lamp through inside current data, help carrying out the multidimensional control to stage lamp, and carry out fault parameter analysis to stage lamp through control passback data and inside current data, thereby help carrying out comprehensive remote monitoring to stage lamp through stage lamp's fault event data, and adjust the power of present display function according to fault event data, help carrying out the compensation to stage lamp's fault parameter according to showing the power parameter, reduce the risk of stage lamp self trouble, make stage lamp's inside current service condition and stage lamp's present display effect looks adaptation, and gather the fault event data that shows power parameter and corresponds, form the stage fault set of being convenient for remote transmission, and carry out the multidimensional control to stage lamp through the monitor end that corresponds the control authority, carry out the omnidirectional control to stage lamp through stage lamp outside light display effect and inside current flow direction, improve the timeliness of hiding the fault monitoring, and through the fault probability of the stage lamp of reducing the inside fault probability of adjusting, thereby the fault probability of stage lamp emergence of the inside fault bead of stage lamp.

The third object of the present application is achieved by the following technical solutions:

a computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the processor implementing the steps of the cloud monitoring method of stage lamps described above when the computer program is executed by the processor.

The fourth object of the present application is achieved by the following technical solutions:

a computer readable storage medium storing a computer program which when executed by a processor implements the steps of the cloud monitoring method of stage lighting described above.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the lamp display effect of the stage lamp is monitored by acquiring the monitoring feedback data of the stage lamp in the current running state, the internal running state of the stage lamp is monitored by the internal current data, the stage lamp is monitored in a multi-dimensional mode, fault parameter analysis is carried out on the stage lamp by the monitoring feedback data and the internal current data, comprehensive remote monitoring is carried out on the stage lamp by the fault event data of the stage lamp, the power of the current display function is adjusted according to the fault event data, the fault parameter of the stage lamp is compensated according to the display power parameter, the risk of self faults of the stage lamp is reduced, the internal current service condition of the stage lamp is matched with the current display effect of the stage lamp, the display power parameter and the corresponding fault event data are summarized to form a stage lamp fault set which is convenient for remote transmission, the stage lamp is monitored in a multi-dimensional mode by the monitoring end corresponding to the monitoring authority, the external lamp light display effect and the internal current flowing direction are monitored in an all-dimensional mode, the timeliness of hiding fault monitoring is improved, the fault is hidden by the power adjustment of the stage lamp, the fault probability of the stage lamp is reduced, and the hidden fault time of the stage lamp is reduced, and the fault probability of the stage lamp is hidden is reduced;

2. According to the monitoring feedback data of the stage lamp, display analysis is carried out on the lamp bead display function of the stage lamp, whether the actual lamp bead display function corresponds to a current monitoring time node or not is judged, accurate monitoring is facilitated on display errors between the lamp bead display function of the stage lamp and a corresponding display effect according to the display function analysis data, so that power supply allocation processing can be carried out on the display function analysis data according to internal current data, the power consumption allocation scheme of the stage lamp is matched with the lamp bead matching sequence of the current display combination, the rationality of power consumption allocation is improved, position marking is carried out on the lamp bead with abnormal power consumption in the monitoring process of the power consumption allocation, accurate assembly position of the abnormal lamp bead in the stage lamp is obtained, the abnormal lamp bead is conveniently monitored in a targeted mode, the monitoring accuracy of the abnormal lamp bead is improved, and according to the power consumption abnormal condition, the position parameters of the abnormal lamp bead are associated with the corresponding power consumption scheme, so that the stage lamp bead is helped to carry out corresponding fault analysis on the power consumption abnormal condition of the stage lamp, and the monitoring accuracy of the lamp bead with abnormal power consumption condition of the stage lamp is improved;

3. when a stage lamp breaks down, according to corresponding fault event data, obtain the switching time node when the stage lamp carries out adjacent display function and switch, help carrying out accurate control to the display error influence of stage lamp according to switching time node, and calculate the function switching time delay of stage lamp through switching time node, thereby obtain the function switching time delay parameter of stage lamp under current fault influence, help carrying out accurate control to the current display state of stage lamp according to switching time delay parameter, and evaluate the current working property of stage lamp according to switching time delay parameter, help monitoring the influence error of current fault event to stage lamp working property through the performance evaluation result of stage lamp, monitor the working property error of stage lamp from the multi-dimensional fault event, improve the control comprehensiveness of stage lamp, predict the remaining service life of stage lamp according to the performance evaluation result, thereby be convenient for carry out remaining service life control to stage lamp under the current running state, can in time change the fault bead according to remaining service life, thereby improve the whole working stability of stage lamp.

Drawings

Fig. 1 is a flowchart of a cloud monitoring method of stage lamps according to an embodiment of the present application.

Fig. 2 is a flowchart of a cloud monitoring method step S20 of a stage lamp according to an embodiment of the present application.

Fig. 3 is a flowchart illustrating a cloud monitoring method step S30 of a stage lamp according to an embodiment of the present application.

Fig. 4 is a flowchart illustrating an implementation of step S304 of a cloud monitoring method of stage lamps according to an embodiment of the present application.

Fig. 5 is a flowchart of a cloud monitoring method for a stage lamp for monitoring a light source status according to an embodiment of the present application.

Fig. 6 is a flow chart of a current splitting implementation of a cloud monitoring method for stage lamps according to an embodiment of the present application.

Fig. 7 is a flowchart of a method for monitoring a stage lamp according to an embodiment of the present application.

Fig. 8 is a block diagram of a cloud monitoring device for stage lamps according to an embodiment of the present application.

Fig. 9 is a schematic diagram of the internal structure of a computer device for implementing the cloud monitoring method of stage lamps.

Detailed Description

The present application will be described in further detail with reference to the accompanying drawings.

In an embodiment, as shown in fig. 1, the application discloses a cloud monitoring method of stage lamps, which specifically comprises the following steps:

S10: acquiring monitoring feedback data of stage lamps in a current running state and internal current data corresponding to the current running state;

specifically, the monitoring feedback data of the stage lamp is obtained through the monitoring equipment preset on the stage scene, the monitoring feedback data comprise image or video data for collecting the light display effect of the stage lamp in the current running state, and the current data of the stage lamp are collected according to the preset current sensor, so that the internal current data corresponding to the current running state are obtained, and the timely monitoring of the self data of the lamp is facilitated.

S20: analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

specifically, the current distributed to each lamp bead is analyzed according to the internal current data, so that whether the lamp bead of the stage lamp fails or not is judged according to the matching condition between the actual current distributed to each lamp bead and the corresponding display function, the failure event data of the stage lamp is obtained, wherein the failure event data of the stage lamp comprises the failure between the actual current and the display function change, the display function is normal due to the fact that the actual current is suddenly changed, or the display function is not displayed and exposed due to the fact that the actual current is normal.

Specifically, as shown in fig. 2, step S20 specifically includes the following steps:

s201: analyzing the lamp bead display function of the stage lamp according to the monitoring feedback data to obtain display function analysis data corresponding to the current monitoring time node;

specifically, the light display effect of the stage lamp under the current running state is analyzed according to the monitoring feedback data, the current display function of the stage lamp is included, such as a stroboscopic display function, a flash display function, a gradual change display function or a pulse change display function, and display numerical values corresponding to the display function are included, the function change speed is 0-255, the color change combination and the corresponding display brightness value are included, the display function data of the stage lamp under the current monitoring time node are subjected to time correlation through analysis of the monitoring feedback data in the form of pictures or video streams, and the display function data comprise display function names, corresponding display numerical values, display color combinations, corresponding display brightness values and the like, so that the display function analysis data of the stage lamp are obtained.

S202: according to the internal current data, carrying out power supply allocation processing on the display function analysis data to generate a power utilization allocation scheme of the current display combination of the stage lamp;

specifically, according to the internal current data, power supply allocation processing is performed on the display function analysis data, for example, according to the lamp bead combination and calling condition when the stage lamp display function is switched, a power supply circuit of the lamp bead corresponding to the original display function is cut off, the power supply circuit of the lamp bead corresponding to the current display combination after the switching is communicated, and according to the display numerical value of the display function after the current display combination adjustment, such as the jumping speed, the brightness value and the like, the current size of each lamp bead is adjusted, so that the adjusted stage lamp can display according to the preset display function, and a power utilization allocation scheme corresponding to the adjusted display function is obtained.

S203: according to the electricity utilization allocation scheme, position marking is carried out on the lamp beads with abnormal electricity utilization, so that abnormal lamp bead position parameters are obtained;

specifically, according to the electricity consumption allocation scheme, the abnormal current position of the abnormal current flow or the current abrupt change such as short circuit or open circuit is marked, the control lamp bead matched with the abnormal current position is searched, and the abnormal electricity consumption lamp bead is marked according to the display position and the display sequence of the control lamp bead in the current display function, so that the abnormal lamp bead position parameter is obtained, wherein the abnormal lamp bead position parameter comprises the display position and the display sequence of the abnormal lamp bead in the current display combination.

S204: and carrying out electric energy abnormality association on the abnormal lamp bead position parameters and the corresponding power utilization allocation scheme to obtain fault event data corresponding to stage lamp power utilization abnormal faults.

Specifically, the abnormal lamp bead position parameters and the corresponding power utilization allocation schemes are subjected to abnormal association of electric energy, the abnormal lamp bead position parameters comprise the current magnitude distributed to the abnormal lamp bead positions and the calling time of the abnormal lamp beads to the electric energy, the current abrupt change abnormal values generated by the abnormal lamp beads comprise the rising or reducing difference value of current cliffs, and the associated abnormal lamp bead positions and the power utilization allocation schemes corresponding to the lamp beads are used as fault event data and are associated with the corresponding stage lamp power utilization abnormal fault phenomenon.

S30: according to the fault event data, performing power adjustment on the current display function of the stage lamp to obtain the display power parameter of the stage lamp;

specifically, as shown in fig. 3, step S30 specifically includes the following steps:

s301: acquiring a switching time node for switching adjacent display functions of stage lamps according to the fault event data;

specifically, according to the fault event data, after receiving a display function switching instruction of the stage lamp, recording the power supply current change time and the color change time of each lamp bead of the stage lamp, and taking an average value of a time node at which the power supply current starts to change and a time node at which the color of the lamp bead changes as a switching time node for function switching.

S302: performing time delay calculation on the switching time node to obtain a switching time delay parameter corresponding to the current display state of the stage lamp;

specifically, if after the stage lamp receives a display function switching instruction, the lamp beads to be displayed corresponding to the next display function of the stage lamp are recombined and subjected to power utilization allocation, a power utilization time node when the current change of the lamp beads to be displayed starts is obtained, the lamp light display time node when the lamp beads to be displayed corresponding to the stage lamp beads start to change in the display function in the feedback data is monitored, and a time difference value between the lamp light display time node and the power utilization time node is used as switching time delay, so that a switching time delay parameter corresponding to the current display state of the stage lamp is obtained.

S303: according to the switching delay parameters, the current working performance of the stage lamp is evaluated, and a performance evaluation result of the stage lamp is obtained;

specifically, according to the switching delay parameter, the current working performance of the stage lamp is evaluated, such as the aging degree of the lamp bead, the utilization rate of electric energy, and the switching reaction rate between the display functions after the current is switched on, such as the reaction time required by the conversion of the duty ratio of the band under the same current, the first function switching reaction time when the stage lamp is put into use is used as a reference index, and the ratio between the function switching reaction time under the current working performance and the reference index is used as a current working performance evaluation result, so that the current working performance evaluation result of the stage lamp is obtained.

S304: and monitoring the residual service life of the stage lamp in the current running state according to the performance evaluation result.

Specifically, as shown in fig. 4, step S304 specifically includes the following steps:

s3041: acquiring the current working temperature of the stage lamp under the current working performance according to the performance evaluation result;

specifically, according to the performance evaluation result representing the response capability of the stage lamp to the function switching instruction in the current running state, the current working temperature under the current working performance is collected through a preset temperature sensor in the current running state, and the current working temperature comprises the working lamp bead temperature and the lamp bead temperature of the lamp bead to be controlled corresponding to the next display function.

S3042: when the overload risk exists in the current working temperature, calculating a temperature difference value between the current working temperature and a preset working temperature threshold;

specifically, if the maximum working temperature of the stage lamp is obtained according to the setting parameters of the stage lamp in the outlet, setting the maximum working temperature in the factory specification as a working temperature threshold, acquiring the current external environment temperature, and acquiring the temperature rise index of the current working temperature under the influence of the external environment temperature, wherein the stage lamp temperature change parameter under each unit time is used as the corresponding temperature rise index under the influence of the current external environment temperature, the ratio between the current temperature rise index and the temperature rise index is used as a temperature rise compensation coefficient, the difference between the current working temperature and the working temperature threshold is calculated, and the product between the temperature rise compensation coefficient and the temperature difference is used as the temperature difference when overload risk exists.

S3043: according to the temperature difference, performing temperature cooling adjustment on the overload lamp beads of the stage lamp to obtain working temperature monitoring data of the stage lamp;

specifically, according to the temperature difference, call the fan module that stage lamp was preset to carry out temperature cooling adjustment processing to the stage lamp, when the temperature difference is bigger, increase fan module's air supply speed accelerates the heat dissipation rate of stage lamp, when the temperature difference is less, reduce fan module's air supply speed and reduce stage lamp's energy consumption, carry out the temperature cooling of overload lamp pearl through adjusting fan module, adjust the operating temperature of come the stage lamp through the current temperature of overload lamp pearl and corresponding fan module, thereby obtain stage lamp's operating temperature monitoring data.

S3044: and predicting the residual working life of the stage lamp in the current running state according to the working temperature monitoring data to obtain a life prediction result corresponding to the current overload risk.

Specifically, according to the working temperature monitoring data, the remaining working life of the stage lamp in the current running state is predicted, for example, the heating rate of the overload lamp bead when the display function is switched and the heat dissipation rate of the overload lamp bead under the action of the fan module are obtained, the ratio between the heating rate and the heat dissipation rate is used as the current working life prediction parameter, the ratio between the initial heating rate and the initial heat dissipation rate of the stage lamp when the stage lamp is put into use is obtained as the ideal working life parameter, and the difference between the current working life prediction parameter and the ideal working life parameter is used as the remaining working life prediction parameter, so that the prediction result of the remaining working life of the stage lamp under the current overload risk is obtained.

In one embodiment, in order to monitor the stage lamp in the current operation state from multiple dimensions, as shown in fig. 5, step S304 further includes:

s3045: acquiring the current illuminance of the stage lamp in the current running state;

specifically, the real-time illuminance of the stage lamp is obtained through the preset illuminometer, and the change conditions of the illuminance under different display functions are recorded according to the display color and the jumping speed of the display function of the current running state of the stage lamp, so that the current illuminance of the stage lamp is obtained.

S3046: when the current illuminance exceeds a preset exposure threshold, adjusting the light source power of the stage lamp;

specifically, the current external environment illumination intensity is obtained, a saturation choke coil is connected in series to a power supply of the stage lamp, the power supply current of each lamp bead is subjected to shunt control through the saturation choke coil, when the power supply current of the lamp bead reaches the saturation current value of the saturation choke coil, the saturated illuminance corresponding to the saturation current value is obtained, the sum of the saturated illuminance and the external environment illumination intensity is used as an exposure threshold of the stage lamp, whether the current illuminance exceeds the exposure threshold is judged through the illuminance difference value of the exposure threshold and the current illuminance, in the error range, when the current illuminance approaches the exposure threshold, the light source power of the stage lamp is reduced, so that the current illuminance is reduced to be within the safety range of the exposure threshold, and when the current illuminance is lower than a preset light display effect, if a viewer cannot observe the lamp tube of the stage lamp under the current external environment illuminance, the light source power of the stage lamp is turned up.

S3047: according to the light source power, carrying out state adjustment on the light source display state of the stage lamp to obtain a light source state adjustment parameter corresponding to the switching state of the current display function of the stage lamp;

Specifically, according to the light source power of the stage lamp after adjusting, the state adjustment is carried out on the light source display state of the stage lamp, the light source state comprises light source display brightness, switching time between strong light and weak light of the light source, corresponding display states and the like, and parameter adjustment is carried out on the light source display state parameters according to the light source power, so that the display state of the light source is more adaptive to the switching state of the current display function, and further a more coordinated stage lamp light display effect is achieved.

S3048: and monitoring the light source state of the stage lamp according to the light source state adjusting parameters.

Specifically, the light source state of the stage lamp is monitored according to the light source state adjusting parameters, when the state of the light source changes, the state changes such as brightness parameter change, switching between the strong light state and the weak light state of the light source and the like are included, and state change data are packed and sent to the monitoring end with corresponding monitoring permission, so that the monitoring end can monitor the light source state of the stage lamp in time.

S40: and summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority.

Specifically, the current display power parameters of the stage lamp and the corresponding fault events are summarized, a corresponding stage lamp fault set is generated according to the fault type of the stage lamp, the monitoring authority matched with the stage lamp fault set is searched through the preset stage lamp control authority setting, and after the matching is successfully searched, the stage lamp fault set is sent to the monitoring end corresponding to the control authority.

In one embodiment, in order to more reasonably shunt the current of the failed lamp bead, as shown in fig. 6, step S40 further includes:

s401: acquiring a working signal and response time length of the working signal of each lamp bead of the stage lamp;

specifically, the working signal of each stage lamp and the working state of the power supply circuit are obtained through a preset heartbeat detection mechanism, wherein the working signal comprises the brightness, the color change duty ratio and the current display function of each lamp bead, the response time of the working signal is the time required by the lamp bead to switch the current display value to the expected display value in the control instruction after receiving the corresponding control instruction, and the time from the lamp bead to the time from the receiving of the working signal to the display according to the expected display value is the response time of the working signal.

S402: according to the response time length, carrying out signal fault analysis on the abnormal signal reception of the stage lamp to obtain a signal fault analysis result corresponding to the working state of each lamp bead;

specifically, according to the response time of each working lamp bead to the working signal, performing fault analysis on the abnormal signal reception of each lamp bead of the stage lamp, if the first signal response time is used as the signal fault analysis basis according to the stage lamp when the stage lamp is put into use, in the error range, when the response time of the lamp bead exceeds the highest response threshold value of the first signal response time, indicating that the signal reception of the current lamp bead is abnormal, at the moment, the display effect of the lamp bead is not matched with the expected display value, taking the actual response time of the lamp bead and the display effect of the actual lamp bead as the current working state of the lamp bead, and generating the signal fault analysis result of the lamp bead by combining the current calling condition of the lamp bead.

In an embodiment, when the response time exceeds the preset response threshold, that is, there is hysteresis between the failed lamp bead and the preset display effect, in order to perform function switching adjustment on the failed lamp bead in time, as shown in fig. 7, step S402 further includes the following steps:

s4021: according to the response time length, performing function switching time delay analysis on the control lamp beads corresponding to the stage lamps to obtain a function switching hysteresis parameter;

Specifically, according to the actual response time length of the fault lamp bead, performing function switching time delay analysis on all the lamp beads under the current display combination of the stage lamp, for example, according to the display sequence of the fault lamp bead in all the lamp beads, when the response time length of the fault lamp bead is longer, the display response time of the display lamp bead after the fault lamp bead is the sum of the self response time and the response time length of the fault lamp bead, and so on, thereby obtaining the function switching hysteresis parameter of each lamp bead, wherein the function switching time delay of each lamp bead after the fault lamp bead in the display sequence is the sum of the self response time and the response time length of the fault lamp bead, and the parameter after the function switching of the fault lamp bead is the actual response time length of the self.

S4022: according to the function switching hysteresis parameters, the duty ratio switching speed of the current display color of the lamp beads is adjusted and controlled;

specifically, the duty ratio switching speed of the current display color of each control lamp bead is further adjusted according to the function switching hysteresis parameters, so that after each control lamp bead receives a function switching instruction, the corresponding duty ratio switching speed can be adjusted by adjusting the current, the current control lamp bead can switch the current display function to the expected display function more quickly, and error interference of the function switching hysteresis parameters is reduced.

S4023: and carrying out state association on the switching speed of the duty ratio and the signal receiving and transmitting state of the control lamp bead to obtain the signal control data of the stage lamp.

Specifically, after the adjustment of the duty ratio switching speed of the control lamp bead is completed, according to the current display state of the stage lamp, the duty ratio switching speed corresponding to the current display state is associated with the signal receiving and transmitting state of the control lamp bead, including the duty ratio switching speed of the lamp bead in each signal receiving and transmitting state and the color switching speed between the display color switching of the lamp bead, so as to obtain the signal control data of the stage lamp.

S403: re-planning the current power utilization allocation scheme of the stage lamp according to the signal fault analysis result to obtain an electric energy adjustment scheme for shunting the electric energy corresponding to the fault lamp bead;

specifically, according to the signal fault analysis result, current distributed to the fault lamp beads in the current power consumption allocation scheme is subjected to split treatment, the idle lamp beads in the idle state closest to the assembly position of the fault lamp beads are searched, the idle lamp beads are replaced by the fault lamp beads in the lamp bead matching sequence with the expected display function, and power supply current of the fault lamp beads is distributed to the idle lamp beads, so that the power adjustment scheme for performing display control on the idle lamp beads is obtained.

S404: according to the electric energy adjustment scheme, the signal receiving and transmitting state of the stage lamp is monitored.

Specifically, through the electric energy adjustment scheme, the signal receiving and dispatching state of stage lamp is monitored, including the receiving and dispatching and the demonstration of the work signal that the idle lamp pearl was originally belonged to the trouble lamp pearl, the display function and the demonstration colour numerical value of the idle lamp pearl of control passback data analysis through idle lamp pearl, according to the stage effect that display function and demonstration colour numerical value present, judge whether the receiving and dispatching of idle lamp pearl to the work signal is accomplished to monitor the signal receiving and dispatching state of stage lamp.

It should be understood that the sequence number of each step in the foregoing embodiment does not mean that the execution sequence of each process should be determined by the function and the internal logic, and should not limit the implementation process of the embodiment of the present application.

In an embodiment, a cloud monitoring device for a stage lamp is provided, where the cloud monitoring device for a stage lamp corresponds to the cloud monitoring method for a stage lamp in the foregoing embodiment one by one. As shown in fig. 8, the cloud monitoring device of the stage lamp comprises a data acquisition module, a data analysis module, a data processing module and a data monitoring module. The functional modules are described in detail as follows:

The data acquisition module is used for acquiring monitoring feedback data of the stage lamp in the current running state and internal current data corresponding to the current running state;

the data analysis module is used for analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

the data processing module is used for carrying out power adjustment on the current display function of the stage lamp according to the fault event data to obtain the display power parameter of the stage lamp and obtain the display power parameter of the stage lamp;

and the data monitoring module is used for summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set and transmitting the stage lamp fault set to a monitoring end with corresponding monitoring authority.

Preferably, the data analysis module specifically includes:

the display analysis sub-module is used for analyzing the lamp bead display function of the stage lamp according to the monitoring feedback data to obtain display function analysis data corresponding to the current monitoring time node;

the power consumption allocation submodule is used for carrying out power supply allocation processing on the display function analysis data according to the internal current data to generate a power consumption allocation scheme of the current display combination of the stage lamp;

The abnormal marking sub-module is used for marking the positions of the lamp beads with abnormal electricity consumption according to the electricity consumption allocation scheme to obtain abnormal lamp bead position parameters;

and the electric energy association sub-module is used for carrying out electric energy abnormal association on the abnormal lamp bead position parameters and the corresponding power utilization allocation scheme to obtain fault event data corresponding to stage lamp power utilization abnormal faults.

Preferably, the data processing module specifically includes:

the time data acquisition sub-module is used for acquiring a switching time node for switching adjacent display functions of the stage lamp according to the fault event data;

the time delay calculation sub-module is used for performing time delay calculation on the switching time node to obtain a switching time delay parameter corresponding to the current display state of the stage lamp;

the performance evaluation sub-module is used for evaluating the current working performance of the stage lamp according to the switching delay parameter to obtain a performance evaluation result of the stage lamp;

and the service life monitoring sub-module is used for monitoring the residual service life of the stage lamp in the current running state according to the performance evaluation result.

Preferably, the life monitoring submodule specifically includes:

the temperature data acquisition unit is used for acquiring the current working temperature of the stage lamp under the current working performance according to the performance evaluation result;

The temperature difference calculation unit is used for calculating a temperature difference value between the current working temperature and a preset working temperature threshold when the overload risk exists in the current working temperature;

the temperature adjusting unit is used for performing temperature cooling adjustment on the overload lamp beads of the stage lamp according to the temperature difference value to obtain working temperature monitoring data of the stage lamp;

and the life prediction unit is used for predicting the residual working life of the stage lamp in the current running state according to the working temperature monitoring data, and obtaining a life prediction result corresponding to the current overload risk.

Preferably, the lifetime monitoring sub-module further comprises:

the illumination data acquisition unit is used for acquiring the current illuminance of the stage lamp in the current running state;

the power adjusting unit is used for adjusting the light source power of the stage lamp when the current illuminance exceeds a preset exposure threshold;

the state adjusting unit is used for carrying out state adjustment on the light source display state of the stage lamp according to the light source power to obtain a light source state adjusting parameter corresponding to the switching state of the current display function of the stage lamp;

the light source monitoring unit is used for monitoring the light source state of the stage lamp according to the light source state adjusting parameters.

Preferably, the data monitoring module further comprises:

the response data acquisition sub-module is used for acquiring the working signal of each lamp bead of the stage lamp and the response time length of the working signal;

the signal fault analysis sub-module is used for carrying out signal fault analysis on abnormal signal reception of the stage lamp according to the response time length to obtain a signal fault analysis result corresponding to the working state of each lamp bead;

the electric energy planning sub-module is used for re-planning the current power utilization allocation scheme of the stage lamp according to the signal fault analysis result to obtain an electric energy adjustment scheme for shunting the electric energy corresponding to the fault lamp bead;

and the signal monitoring sub-module is used for monitoring the signal receiving and transmitting state of the stage lamp according to the electric energy adjustment scheme.

Preferably, the signal fault analysis sub-module further comprises:

the hysteresis parameter acquisition unit is used for carrying out function switching time delay analysis on the control lamp beads corresponding to the stage lamps according to the response time length to obtain a function switching hysteresis parameter;

the speed adjusting unit is used for adjusting and controlling the duty ratio switching speed of the current display color of the lamp beads according to the function switching hysteresis parameters;

and the state association unit is used for carrying out state association on the switching speed of the duty ratio and the signal receiving and transmitting state of the control lamp bead to obtain the signal control data of the stage lamp.

For specific limitations of the cloud monitoring device of the stage lamp, reference may be made to the above limitation of the cloud monitoring method of the stage lamp, and no further description is given here. All or part of the modules in the cloud monitoring device of the stage lamp can be realized by software, hardware and a combination thereof. The above modules may be embedded in hardware or may be independent of a processor in the computer device, or may be stored in software in a memory in the computer device, so that the processor may call and execute operations corresponding to the above modules.

In one embodiment, a computer device is provided, which may be a server, and the internal structure of which may be as shown in fig. 9. The computer device includes a processor, a memory, a network interface, and a database connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer device is used for storing monitoring data in the display function switching process of the stage lamp. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program, when executed by a processor, implements a method of cloud monitoring of stage lamps.

In one embodiment, a computer readable storage medium is provided, on which a computer program is stored which, when executed by a processor, implements the steps of a method of cloud monitoring of stage lamps as described above.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional units and modules is illustrated, and in practical application, the above-described functional distribution may be performed by different functional units and modules according to needs, i.e. the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-described functions.

The above embodiments are only for illustrating the technical solution of the present application, and not for limiting the same; although the application has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present application, and are intended to be included in the scope of the present application.

Claims (10)

1. A cloud monitoring method of stage lamps, comprising:

acquiring monitoring feedback data of stage lamps in a current running state and internal current data corresponding to the current running state;

Analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

according to the fault event data, performing power adjustment on the current display function of the stage lamp to obtain the display power parameter of the stage lamp;

and summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority.

2. The cloud monitoring method of stage lamps according to claim 1, wherein the analyzing the fault parameters of the stage lamps according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamps specifically comprises:

analyzing the lamp bead display function of the stage lamp according to the monitoring feedback data to obtain display function analysis data corresponding to the current monitoring time node;

performing power supply allocation processing on the display function analysis data according to the internal current data to generate a power utilization allocation scheme of the current display combination of the stage lamp;

according to the electricity utilization allocation scheme, position marks are carried out on the lamp beads with abnormal electricity utilization, and abnormal lamp bead position parameters are obtained;

And carrying out electric energy abnormality association on the abnormal lamp bead position parameters and the corresponding power utilization allocation scheme to obtain fault event data corresponding to the stage lamp power utilization abnormal faults.

3. The cloud monitoring method of stage lamps according to claim 1, wherein the step of performing power adjustment on a current display function of the stage lamps according to the fault event data to obtain display power parameters of the stage lamps specifically comprises:

acquiring a switching time node for switching adjacent display functions of the stage lamp according to the fault event data;

performing time delay calculation on the switching time node to obtain a switching time delay parameter corresponding to the current display state of the stage lamp;

according to the switching delay parameter, evaluating the current working performance of the stage lamp to obtain a performance evaluation result of the stage lamp;

and monitoring the residual service life of the stage lamp in the current running state according to the performance evaluation result.

4. A method for monitoring the cloud of stage lamps according to claim 3, wherein the monitoring the remaining service life of the stage lamps in the current operation state according to the performance evaluation result specifically comprises:

Acquiring the current working temperature of the stage lamp under the current working performance according to the performance evaluation result;

when the current working temperature has overload risk, calculating a temperature difference value between the current working temperature and a preset working temperature threshold;

according to the temperature difference, performing temperature cooling adjustment on the overload lamp beads of the stage lamp to obtain working temperature monitoring data of the stage lamp;

and predicting the residual working life of the stage lamp in the current running state according to the working temperature monitoring data to obtain a life prediction result corresponding to the current overload risk.

5. A method of cloud monitoring of stage lamps according to claim 3, wherein said monitoring of remaining operational life of the stage lamps in a current operational state based on the performance evaluation results further comprises:

acquiring the current illuminance of the stage lamp in the current running state;

when the current illuminance exceeds a preset exposure threshold, adjusting the light source power of the stage lamp;

according to the light source power, carrying out state adjustment on the light source display state of the stage lamp to obtain a light source state adjustment parameter corresponding to the switching state of the current display function of the stage lamp;

And monitoring the light source state of the stage lamp according to the light source state adjusting parameters.

6. The cloud monitoring method of stage lamps according to claim 1, wherein the step fault set is obtained by summarizing the display power parameter and the corresponding fault event data, and the step fault set is sent to a monitoring end with a corresponding monitoring authority, and further comprising:

acquiring a working signal of each lamp bead of the stage lamp and a response time of the working signal;

according to the response time length, signal fault analysis is carried out on the abnormal signal reception of the stage lamp, and a signal fault analysis result corresponding to the working state of each lamp bead is obtained;

re-planning the current power utilization allocation scheme of the stage lamp according to the signal fault analysis result to obtain an electric energy adjustment scheme for shunting the electric energy corresponding to the fault lamp bead;

and monitoring the signal receiving and transmitting state of the stage lamp according to the electric energy adjustment scheme.

7. The cloud monitoring method of stage lamps according to claim 6, wherein the step of analyzing signal faults of abnormal signal reception of the stage lamps according to the response time length to obtain signal fault analysis results corresponding to the working state of each lamp bead, further comprises:

According to the response time length, performing function switching time delay analysis on the control lamp beads corresponding to the stage lamps to obtain a function switching hysteresis parameter;

according to the function switching hysteresis parameter, the duty ratio switching speed of the current display color of the control lamp bead is adjusted;

and carrying out state association on the duty ratio switching speed and the signal receiving and transmitting state of the control lamp bead to obtain the signal control data of the stage lamp.

8. Cloud monitoring device of stage lamp, its characterized in that includes:

the data acquisition module is used for acquiring monitoring feedback data of the stage lamp in the current running state and internal current data corresponding to the current running state;

the data analysis module is used for analyzing fault parameters of the stage lamp according to the monitoring feedback data and the internal current data to obtain fault event data of the stage lamp;

the data processing module is used for carrying out power adjustment on the current display function of the stage lamp according to the fault event data to obtain the display power parameter of the stage lamp;

and the data monitoring module is used for summarizing the display power parameters and the corresponding fault event data to obtain a stage lamp fault set, and sending the stage lamp fault set to a monitoring end with corresponding monitoring authority.

9. Computer device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, characterized in that the processor implements the steps of the cloud monitoring method of a stage lamp according to any of claims 1 to 7 when the computer program is executed by the processor.

10. A computer readable storage medium storing a computer program, characterized in that the computer program when executed by a processor implements the steps of the cloud monitoring method of a stage lamp according to any of claims 1 to 7.