CN112333931B - Remote control method and system of composite flash initiator, electronic equipment and storage medium - Google Patents

Abstract

The application relates to a remote control method, a system, electronic equipment and a storage medium of a composite ignition device, which comprises the steps of receiving and storing a light parameter instruction; executing the operation of obtaining the light parameter information according to the light parameter storage instruction, and storing the light parameter information into a parameter state table; receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, and calling light parameter information in the parameter state table; and sending the light parameter information to the corresponding lamp transceiver for light adjustment. The problem of thereby having the photography efficiency of the photographic business to specific light effect, the unable storage light parameter information commonly used of present messenger's flashing ware influences photographic efficiency is solved, and this application has the effect that improves photographic work efficiency.

Description

Remote control method and system of composite flash initiator, electronic equipment and storage medium

Technical Field

The present disclosure relates to the field of photography wireless control, and in particular, to a remote control method and system for a composite flash initiator, an electronic device, and a storage medium.

Background

In a studio, photography is performed by light, and generally, a flash lamp and a normally-on lamp are used. People have more and more paid attention to the light modeling of studio in recent years, utilize flash light and the lamp that often shines to mutually support and carry out the photographic creation, can create a lot of classic outstanding photographic works. In the field of photography, the conventional flash lamp can only be used on a camera hot shoe, so that the surface of a shot object is only covered by flash light and lacks of shadow positions, and the whole ambient light is not natural.

At present, along with the development of science and technology, the functions of a flash initiator are more and more diversified, the existing 2.4G frequency wireless electrified flash initiator can realize wireless remote control with a plurality of flash lamps through a grouping code matching technology, the flash initiator is generally divided into two parts, one is a transmitter and the other is a transceiver, wherein the transmitter is arranged on a camera top hot shoe, the transceiver is arranged on the flash lamps, the flash lamps can be triggered to be synchronous by pressing a shutter, the existing flash initiator lacks the function of controlling normally-on lamps, but because the existing normally-on lamps can also control the light intensity through a normally-on lamp wireless remote controller, and the transceivers corresponding to the normally-on lamp wireless remote controllers are arranged on the normally-on lamps, because the flash lamps and the normally-on lamps can both adopt a wireless protocol for remote control communication, the protocol compatibility problem between the flash initiators can be easily solved, the normally-on lamp wireless remote controllers and the flash initiator are combined into a whole to become a composite flash initiator, the function of controlling the normally-on lamp is increased for the flash initiator, the integration of the photographic light and the remote controller is realized, the complexity of using a plurality of remote controllers is reduced, and the operation of a user is more convenient.

In view of the above-mentioned related technologies, the inventor believes that there is a drawback in that, in a studio operation, a general photographer is not suitable for moving a lamp in the studio, and because a studio often has a plurality of specific shooting services, when a client shoots a specific service, the shooting efficiency of the photographer can be improved by directly turning on the lamp without repeatedly adjusting the light parameters, wherein the photographer has a set of light environment parameter setting values for each shooting service by virtue of his own experience, but the light environment parameters are greatly different from each other, and the photographer can only remember the values of the light parameters by using his own memory, and when switching the light effect environment, he needs to manually adjust the required light parameters, but the effect still has a certain deviation, and thus needs to be further improved.

Disclosure of Invention

The application aims to provide a remote control method, a remote control system, electronic equipment and a storage medium of a composite flash initiator, and the remote control method, the remote control system, the electronic equipment and the storage medium have the characteristics of being capable of storing various light parameters and improving the working efficiency of a photographer by calling.

In a first aspect, the present application provides a remote control method for a composite flash initiator, which adopts the following technical scheme:

a remote control method of a composite ignition device comprises the following steps:

receiving a storage light parameter instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction;

executing an operation of obtaining lamplight parameter information according to a stored lamplight parameter instruction, and storing the lamplight parameter information into a parameter state table, wherein the lamplight parameter information comprises flash lamp parameter information, normally-on lamp parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table;

receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, and calling light parameter information in the parameter state table, wherein the calling of the preset light instruction comprises calling of a flash lamp parameter instruction, calling of a normally-on light parameter instruction and calling of a full-light parameter instruction;

and sending the light parameter information to the corresponding lamp transceiver for light adjustment.

Through adopting above-mentioned technical scheme, after the user utilizes compound flashing guiding device to accomplish the debugging to the light effect according to self demand, the compound input that leads the flashing device of accessible triggers storage light parameter instruction, thereby through storage light parameter instruction with light parameter information storage in the parameter state table, the user is when needing certain light effect to shoot, the accessible directly triggers on compound flashing guiding device and calls light parameter instruction, and then call required light parameter information, and with this light parameter information transmission department to lamps and lanterns transceiver, adjust light intensity and state, the operation is thus simple, can save the time that all need adjust light parameter repeatedly at every turn, user's shooting efficiency has been improved.

The present application may be further configured in a preferred example to: executing the operation of obtaining the light parameter information according to the light parameter storage instruction, and storing the light parameter information into a parameter state table, and further comprising:

when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table;

when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling a camera to shoot a first normally-on image, performing gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table;

when the received light parameter storage instruction is a full-light storage instruction, full-light parameter information is acquired and stored to a full-light parameter state table, meanwhile, the automatic flashing light and the synchronous control camera shoot a first full-light image, gray processing is carried out on the first full-light image, a full-light reference gray image is obtained, and the full-light reference gray image is stored to the parameter state table.

Through adopting above-mentioned technical scheme, the storage light parameter information instruction that sets up has three kinds, has embodied the many suitability of this application, and the user can save corresponding light parameter information according to self demand, for example, in actual life, the user may only several kinds of fixed demands to the light effect of the lamp that often shines, and has great change demand to the flash light, consequently, the user can save several kinds of lamp light parameter information often to the pertinence. In addition, after the light parameter information is stored, the lamp can be correspondingly operated according to the category of the stored light parameter instruction, the camera is used for obtaining the image, the image is subjected to gray level processing after the image is obtained, so that a reference gray level image is obtained, the reference gray level image can reflect the light intensity of the set light parameter, the composite flash initiator can obtain whether the light effect caused by the stored light parameter information is deviated from the light effect in the current practical application scene through the light intensity, and the accuracy of the light effect in the shooting operation process of a user is ensured.

The present application may be further configured in a preferred example to: further comprising:

when the light parameter calling instruction is received and called as a flash lamp parameter calling instruction, sending a closing instruction to a normally-on light transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a second flash lamp image, carrying out gray level processing on the second lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result;

when the light parameter calling instruction is received and is a normally-on parameter calling instruction, a closing instruction is sent to a flash lamp transceiver, a camera is automatically controlled to shoot a second normally-on image, the second normally-on image is subjected to gray level processing to obtain a normally-on gray level image, the normally-on gray level image is compared with a normally-on reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result;

when the light parameter calling instruction is received and is a full light parameter calling instruction, the flashing light is automatically triggered, the camera is synchronously controlled to shoot a first full light image, gray processing is carried out on the first full light image to obtain a full light gray image, gray value comparison is carried out on the normally-on light gray image and a full light reference gray image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

By adopting the technical scheme, after the user selects the corresponding light parameter calling instruction, the composite flash initiator selects the corresponding light parameter information according to the light parameter calling instruction, and sends the light parameter information to the lamp transceiver, after the lamp adjusts the light effect according to the light parameter information, the lamp and the camera can be controlled through the composite flash initiator, the image of the current light effect is obtained, the image is subjected to gray scale processing, a gray scale image is obtained, the gray scale image is compared with a reference gray scale image, the matching degree of the current light environment and the preset light environment is obtained, whether an alarm signal is sent or not is judged, the intellectualization of the composite flash initiator is reflected, and the time that the user feels the difference of the light environment through eyes and continuously debugs the light parameter information can be reduced.

The present application may be further configured in a preferred example to: further comprising:

the alarm signal includes detection request confirmation information;

determining to send a query instruction to the lamp transceiver according to the detection request confirmation information;

and receiving a light detection result in real time, and sending prompt information to a user according to the light detection result.

By adopting the technical scheme, when the change of the lighting effect is large, the set detection request confirmation information can provide the condition of further detecting whether all lamps operate normally for the user, and the user can perform corresponding processing according to the detection result.

In a second aspect, the present application provides a remote control system for a composite ignition device, which adopts the following technical scheme:

a remote control system for a composite ignition, comprising:

a receiving module: the device comprises a storage light parameter instruction, a control instruction and a display instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on lamp storage instruction and a full-light storage instruction;

a storage module: the system comprises a parameter state table, a parameter state table and a control module, wherein the parameter state table is used for executing operation of obtaining lamplight parameter information according to a stored lamplight parameter instruction and storing the lamplight parameter information into the parameter state table, the lamplight parameter information comprises flash lamp parameter information, normally-on lamp parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table;

a calling module: the system comprises a parameter state table, a light parameter calling instruction, a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction, wherein the parameter state table is used for receiving the light parameter calling instruction, finding out a corresponding parameter state table according to the light parameter calling instruction and calling light parameter information in the parameter state table;

a sending module: and the lamp parameter information is sent to the corresponding lamp transceiver for lamp light adjustment. .

The present application may be further configured in a preferred example to: the memory module further includes:

a flash reference image acquisition unit: when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table;

a normally-on reference image acquisition unit: when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling a camera to shoot a first normally-on image, performing gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table;

full light reference image acquisition unit: when the received light parameter storage instruction is a full-light storage instruction, full-light parameter information is acquired and stored to a full-light parameter state table, meanwhile, the automatic flashing light and the synchronous control camera shoot a first full-light image, gray processing is carried out on the first full-light image, a full-light reference gray image is obtained, and the full-light reference gray image is stored to the parameter state table.

The present application may be further configured in a preferred example to: the sending module further comprises:

flash lamp contrast unit: when the light parameter calling instruction is received and called as a flash lamp parameter calling instruction, sending a closing instruction to a normally-on light transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a second flash lamp image, carrying out gray level processing on the second lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result;

a normally-on lamp comparison unit: when the light parameter calling instruction is received and is a normally-on parameter calling instruction, a closing instruction is sent to a flash lamp transceiver, a camera is automatically controlled to shoot a second normally-on image, the second normally-on image is subjected to gray level processing to obtain a normally-on gray level image, the normally-on gray level image is compared with a normally-on reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result;

full light contrast unit: when the light parameter calling instruction is received and is a full light parameter calling instruction, the flashing light is automatically triggered, the camera is synchronously controlled to shoot a first full light image, gray processing is carried out on the first full light image to obtain a full light gray image, gray value comparison is carried out on the normally-on light gray image and a full light reference gray image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

In a third aspect, the present application provides an electronic device, which adopts the following technical solutions:

an electronic device comprising a memory, a processor and a computer program stored in said memory and executable on said processor, said processor implementing the steps of the method for remote control of a composite flash initiator as described above when executing said computer program.

In a fourth aspect, the present application provides a computer storage medium, where the following technical solutions:

a computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, carries out the steps of the method for remote control of a composite flash initiator as described above.

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

after the user carries out parameter control to lamps and lanterns in the film studio through using compound flashing initiator, if need the storage to set up when light parameter information, can trigger compound flashing initiator input in the storage light parameter instruction realize saving corresponding light parameter, this application storage light parameter instruction is provided with the multiple, can adapt to the different storage demands of user. When the user wants to call out certain light parameter information of storage before, through triggering the call light parameter instruction in the compound flashing ware input, the compound flashing ware that draws sends light parameter information to lamps and lanterns transceiver department, and then realizes the regulation to lamps and lanterns light, and this easy operation is convenient, has saved the time that a pair of lamps and lanterns adjusted again, has effectively improved user's shooting efficiency.

Drawings

Fig. 1 is a flowchart of a remote control method of a composite ignition device according to an embodiment of the present application.

FIG. 2 is a flow chart of a method for remotely controlling a composite ignition in another embodiment of the present application.

FIG. 3 is a block diagram of a remote control system for a hybrid ignition system according to one embodiment of the present application.

Fig. 4 is a schematic block diagram of an electronic device in an embodiment of the present application.

In the figure, 1, a receiving module, 2, a storage module, 21, a flash reference image acquiring unit, 22, a normally-on reference image acquiring unit, 23, a full-light reference image acquiring unit, 3, a calling module, 4, a sending module, 41, a flash comparing unit, 42, a normally-on comparing unit, 43 and a full-light comparing unit.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is further described in detail below with reference to fig. 1-4 and the embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The light in the studio mainly comprises a flash lamp and a normally-on lamp, and in practical application, the flash lamp and the normally-on lamp have different remote control protocols.

This application improves to a compound trigger based on current trigger technique, can control the flash light and can control the lamp that often lights again, it includes the main control unit, flash light remote control communication unit and the lamp remote control communication unit that often lights that are connected with the main control unit electricity, and signal transceiver, wherein, in this embodiment, it is unanimous with the flash light remote control protocol to predetermine the communication protocol that the main control unit adopted, flash light remote control communication unit includes flash light frequency generator, flash light frequency generator is connected with signal transceiver electricity, can communicate with flash light transceiver through signal transceiver.

The normally-on lamp remote control communication unit comprises a normally-on lamp frequency generator and a protocol conversion module, wherein the protocol conversion module is electrically connected with the signal transceiver, when a normally-on lamp remote control signal needs to be sent, the main control unit sends the normally-on lamp remote control signal to the normally-on lamp remote control communication unit, the normally-on lamp frequency generator generates a carrier wave, the protocol conversion module converts and modulates the control signal on the carrier wave according to a remote control protocol complied by the protocol conversion module to form a wireless signal, the wireless signal is sent to the normally-on lamp transceiver from the signal transceiver, in addition, the signal transceiver can also receive an external signal from the normally-on lamp transceiver, when the external signal from different protocol standards is received, the external signal needs to be sent to the protocol conversion module, and the protocol conversion module converts the external signal and then sends the converted external signal to the main control unit for processing. For example, the protocol adopted by the flash lamp is the infrared NEC code standard, the normally-on lamp is the infrared RC-5 code standard, and the carrier frequencies and the encoding modes of the two are different, so that in the embodiment, the protocol of the commonly-used lamp can be converted into the same protocol as that of the flash lamp, that is, the infrared RC-5 code is converted into the infrared NEC code through the protocol conversion module, so that the composite flash initiator can simultaneously control the flash lamp and the normally-on lamp, and the convenience of a user is improved.

The embodiment of the application discloses a remote control method of a composite ignition device, wherein the remote control method of the composite ignition device is based on the following steps of preprocessing:

before the flash lamp and the normally-on lamp are operated by the composite flash initiator for the first time, the matching buttons on the composite flash initiator are pressed to match codes with the flash lamps and the normally-on lamps respectively, and lamps successfully matched are grouped and numbered according to a preset rule, for example, a flash lamp group starts with an F, a normally-on lamp group starts with an L, and each lamp in the group is coded according to an arabic number sequence, specifically, the format of the light number is as follows: "F-1" and "L-1". In this example, the composite flash initiator is provided with a main menu, functions in the main menu on the screen of the composite flash initiator can be selected through an up-down selection key, a confirmation key and a return key, after the lamps are successfully matched, the lamps which need to be adjusted correspondingly can be found in the light adjusting function to adjust parameters, and meanwhile, the composite flash initiator sends light adjusting parameter signals with light address codes to the corresponding lamp transceivers through the signal transceivers.

Referring to fig. 1, a remote control method of a composite flash initiator specifically includes:

and S1, receiving a storage light parameter instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction.

Wherein, after the user carries out parameter adjustment to all lights according to self demand, the accessible triggers storage light parameter instruction and carries out the storage operation to the corresponding light parameter information that wants to save, in this embodiment, storage light parameter instruction can adopt several conventional ways to trigger, include triggering through conventional button, wherein the button is including flash light storage button, normal light storage button and full light storage button, correspond flash light storage instruction respectively, normal light storage instruction and full light storage instruction, perhaps also can show all storage light parameter instructions through the software interface, rethread upper and lower selection button is pressed the enter key and is triggered after selecting.

And S2, executing the operation of obtaining the light parameter information according to the stored light parameter instruction, and storing the light parameter information into a parameter state table, wherein the light parameter information comprises flash lamp parameter information, normally-on parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on parameter state table and a full-light parameter state table.

Specifically, the flash light parameter information includes flash light on-off state, flash light compensation parameters, flash light modes and the like, wherein the flash light compensation parameters are related to the flash amount output by the flash light, the flash light amount output by the flash light can be controlled by adjusting the flash light compensation parameters, the flash light modes include a high-speed synchronous mode, a low-speed synchronous mode, a front curtain synchronous mode and a rear curtain synchronous mode, different flash light modes can control different flash light speeds, and various photos with different artistic effects can be shot by synchronous or differential matching of the flash light speed and the shutter speed. The normally-on lamp parameter information comprises a normally-on lamp switch state, a normally-on lamp power parameter and the like, wherein the lamp intensity of the normally-on lamp can be controlled by adjusting the normally-on lamp power parameter. In this embodiment, the full-light parameter information includes the flash lamp parameter information and the normally-on parameter information.

After each lamp is successfully matched, the composite flash initiator can be provided with a corresponding lamplight parameter information table according to the lamplight number and the lamplight parameter information, and is also provided with two link tables for respectively grouping and recording the lamplight numbers of the flash lamp and the normally-on lamp, the lamplight numbers in the link tables are associated with the corresponding lamplight parameter information tables, so that a background system can find the corresponding lamplight parameter information tables through the link tables and carry out operations such as calling, inquiring, adding and deleting on the lamplight parameter information tables, and after the composite flash initiator receives a stored lamplight parameter instruction, taking the stored lamplight parameter instruction as a normally-on lamp storage instruction as an example, finding the corresponding normally-on lamp number in the link tables, linking to the associated lamplight parameter information table according to the lamplight number, carrying out information integration on the information in the lamplight parameter information table and storing the information in the parameter state table, in this embodiment, a new parameter state table is established every time a stored light parameter instruction is pressed, each parameter state table records a light effect parameter value, the parameter state table includes three categories of a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table according to the stored light parameter instruction, and meanwhile, the parameter state tables need to be numbered in groups to distinguish different groups of parameter state tables, so that a user can call the parameter state tables conveniently according to the numbers of the parameter state tables, and finally, the composite flash initiator confirms establishment of the parameter state tables by receiving a confirmation instruction. The user can clear all the parameter state tables and record new light parameter information again after the lamp is replaced or moved according to the scene.

Further, referring to fig. 2, steps S21, S22, and S23 are added after step S2:

and S21, when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically igniting a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table.

And S22, when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, and meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling the camera to shoot a first normally-on image, carrying out gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table.

S23, when the received light parameter storage instruction is a full light storage instruction, acquiring and storing full light parameter information to a full light parameter state table, simultaneously, automatically guiding the flash light and synchronously controlling the camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light reference gray level image, and storing the full light reference gray level image into the parameter state table.

Specifically, after the composite flash initiator is electrically connected with the camera through a hot shoe key, a communication channel is established with the camera, the shooting function of the camera can be utilized to acquire images, and the images are stored in a readable storage medium of the composite flash initiator, wherein after a light parameter storage instruction is received, corresponding parameter information is acquired and stored into a corresponding parameter state table according to the type of the light parameter storage instruction, the later process takes the situation of a flash lamp as an example, when a user wants to store the flash lamp parameter information, the flash lamp parameter information which is debugged can be stored into the flash lamp parameter state table by triggering the flash lamp storage instruction, at the moment, the composite flash initiator can control to turn off a normally-on lamp by sending a turn-off instruction to a normally-on lamp transceiver, so that the influence of the normally-on the light intensity of the flash lamp is reduced, and meanwhile, the composite flash initiator flashes and synchronously controls the camera to shoot a real object without a background plate on site, the method comprises the steps of obtaining a first flash image, compounding a flash initiator and further carrying out gray level processing on the first flash image to obtain a flash reference gray level image, finally storing the image and flash parameter information into a flash parameter state table together, wherein the gray level range in a gray level image pixel point can visually represent light intensity, so that when a user wants to call certain light parameter information, further inspection can be carried out on the light intensity displayed by the parameter information data, and the accuracy of a light effect can be guaranteed.

S3, receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, calling light parameter information in the parameter state table, and calling preset light instructions including a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction.

Specifically, when a user needs to select a certain light effect, the user can call the light parameter command through triggering, in the embodiment, the number of the parameter state table stored in advance can be displayed for the user in the screen interface of the composite flash initiator, the user can select the number of the required parameter state table through the input end, the corresponding light parameter command is triggered according to the category of the parameter state table, and the background system of the composite flash initiator can call the light parameter information in the parameter state table through calling the light parameter command. In this embodiment, the flash parameter calling instruction may call flash light parameter information, the normally-on parameter calling instruction may call normally-on parameter information, and the full-light parameter calling instruction may call full-light parameter information, that is, may call flash light parameter information and normally-on parameter information at the same time.

And S4, sending the light parameter information to the corresponding lamp transceiver for light adjustment.

Specifically, after the composite flash initiator calls the light parameter information, the light parameter information is sent to the corresponding lamp transceiver through the signal transceiver, and therefore light is adjusted.

Further, referring to fig. 2, steps S41, S42, and S43 are added after step S4:

and S41, when the received light parameter calling instruction is a flash lamp parameter calling instruction, sending a closing instruction to the normally-on light transceiver, automatically turning on the flash lamp and synchronously controlling the camera to shoot a second flash lamp image, carrying out gray level processing on the second flash lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

And S42, when the received light parameter calling instruction is a normally-on light parameter calling instruction, sending a closing instruction to the flash lamp transceiver, automatically controlling the camera to shoot a second normally-on light image, carrying out gray level processing on the second normally-on light image to obtain a normally-on light gray level image, comparing the normally-on light gray level image with a normally-on light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

S43, when the received light parameter calling instruction is a full light parameter calling instruction, automatically flashing a flash lamp and synchronously controlling a camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light gray level image, carrying out gray level comparison on the normally-lit gray level image and the full light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

Specifically, taking the case of the flash as an example for illustration, after the composite flash initiator sends flash parameter information to the flash transceiver and waits for a certain light parameter conversion time, the composite flash initiator automatically controls the flash initiator and synchronously controls the camera to shoot a second flash image, the step is similar to the step of obtaining the image in step S21, and obtains a flash gray image by performing a similar image gray processing step on the second flash image, and compares the gray value matching degrees of the flash gray image and the flash reference gray image, when the gray value matching degree reaches or is higher than a preset matching degree (for example, the preset matching degree is 80%), it is proved that the current light intensity is substantially the same as the light intensity under the original parameter setting, the light effect is determined to be substantially identical, and no warning signal needs to be sent to the user, when the gray value matching degree is lower than the preset matching degree, the light effect is judged to be abnormal, and an alarm signal is sent to the user, in this embodiment, the abnormality of the light effect can be prompted to the user by setting a preset prompting mode, and the preset prompting mode can include, but is not limited to: the text information, such as "the effect of the flash light has a large change, please check" and the like, further includes a mode of voice broadcasting the lamp flash, the matching degree of the normally-on or full-light gray scale image and the determination result thereof, and simultaneously displaying the determination result in the interface to prompt the user.

Further, referring to fig. 2, the alarm signal includes the inspection request confirmation information, and steps S5, S6 are added after steps S41, S42, S43:

and S5, determining to send a query instruction to the lamp transceiver according to the detection request confirmation information.

And S6, receiving the light detection result in real time, and sending prompt information to the user according to the light detection result.

The lamps in the studio are not suitable to be moved, and if the gray value matching degree does not reach the standard, the lamps are possibly damaged, so that the generated light quantity is different from the set value. After the alarm signal prompts, the composite flash initiator prompts the user of the detection request confirmation information of automatic jumping out to prompt whether the damage condition of the lamp needs to be detected or not, sends query instructions to all lamp transceivers, and receives response signals of the lamp in real time.

The lamp is internally provided with a detection circuit for detecting the power of the lamp by detecting the voltage and current of the lamp, the lamp can interact with the composite flash initiator through the lamp transceiver, when an inquiry command from the composite flash initiator is received, the lamp transceiver sends the detected lamp power to the signal transceiver of the composite flash initiator, the composite flash initiator can compare the lamp power with the lamp power corresponding to the lamplight effect required by the lamp correspondingly, so as to judge whether the lamp is normal, if all the obtained lamp detection results are normal, prompt information of 'lamp normal and lamp position check' is sent to a user, and if the composite flash initiator receives the abnormal condition in the lamp detection results, the lamp number can be sent to the user and prompt information of 'lamp abnormal finding and timely replacement' is attached.

In addition, the detection request confirmation information can be used for carrying out closing prompt setting or keeping using setting on a setting interface of the composite flash initiator according to the requirements of a user.

It should be understood that, the sequence numbers of the steps in the foregoing embodiments do not imply an execution sequence, and the execution sequence of each process should be determined by its function and inherent logic, and should not constitute any limitation to the implementation process of the embodiments of the present application.

The embodiment of the application also provides a remote control method of the composite flash initiator, and a remote control system of the composite flash initiator corresponds to the remote control method of the composite flash initiator in the embodiment one by one. Referring to fig. 3, the remote control system of the composite ignition includes: the system comprises a receiving module 1, a storage module 2, a flash reference image acquisition unit 21, a normally-on reference image acquisition unit 22, a full-light reference image acquisition unit 23, a calling module 3, a sending module 4, a flash comparison unit 41, a normally-on comparison unit 42 and a full-light comparison unit 43. The functional modules are explained in detail as follows:

the receiving module 1: the device is used for receiving and storing the light parameter instruction, wherein the light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction.

The storage module 2: the parameter state table comprises a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table.

Calling a module 3: the system comprises a parameter state table, a parameter state table and a preset light instruction, wherein the parameter state table is used for receiving and calling the light parameter instruction, finding the corresponding parameter state table according to the light parameter calling instruction and calling light parameter information in the parameter state table, and calling the preset light instruction comprises a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction.

The sending module 4: and the lamp parameter information is sent to the corresponding lamp transceiver for lamp light adjustment.

Further, the storage module 2 further includes:

the flash reference image acquisition unit 21: when the received light parameter storage instruction is a flash lamp storage instruction, flash lamp parameter information is obtained and stored in a flash lamp parameter state table, meanwhile, a closing instruction is sent to a normally-on lamp transceiver, a flash lamp is automatically led and a camera is synchronously controlled to shoot a first flash lamp image, gray processing is carried out on the first flash lamp image, a flash lamp reference gray image is obtained, and the flash lamp reference gray image is stored in the flash lamp parameter state table.

Normally-on reference image acquisition unit 22: when the received light parameter storage instruction is a normally-on storage instruction, normally-on parameter information is acquired and stored to a normally-on parameter state table, meanwhile, a closing instruction is sent to a flash lamp transceiver, the camera is automatically controlled to shoot a first normally-on image, gray processing is carried out on the first normally-on image, a normally-on reference gray image is obtained, and the normally-on reference gray image is stored to the normally-on parameter state table.

The all-light reference image acquisition unit 23: when the received light parameter storage instruction is a full-light storage instruction, full-light parameter information is acquired and stored in a full-light parameter state table, meanwhile, the automatic flashing light and the synchronous control camera shoot a first full-light image, gray processing is carried out on the first full-light image, a full-light reference gray image is obtained, and the full-light reference gray image is stored in the parameter state table.

Further, the calling module 4 further includes:

flash comparing unit 41: when the light parameter calling instruction is received and called as a flash lamp parameter calling instruction, a closing instruction is sent to a normally-on lamp transceiver, a flash lamp is automatically switched on and a camera is synchronously controlled to shoot a second flash lamp image, the second lamp image is subjected to gray level processing to obtain a flash lamp gray level image, the flash lamp gray level image is compared with a flash lamp reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

Normally-on lamp comparison unit 42: when the light parameter calling instruction is received and is a normally-on parameter calling instruction, a closing instruction is sent to the flash lamp transceiver, the camera is automatically controlled to shoot a second normally-on image, the second normally-on image is subjected to gray level processing to obtain a normally-on gray level image, the normally-on gray level image is compared with a normally-on reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

Full light contrast unit 43: when the light parameter calling instruction is received and is a full light parameter calling instruction, the flashing light is automatically triggered, the camera is synchronously controlled to shoot a first full light image, gray processing is carried out on the first full light image to obtain a full light gray image, gray value comparison is carried out on the normally-on light gray image and a full light reference gray image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

The composite flash initiator receives the stored light parameter instruction through the receiving module 1, stores the corresponding light parameter information into the parameter state table according to the stored light parameter instruction through the storage module 2, specifically, stores the flash lamp parameter information into the flash lamp parameter state table through the flash lamp storage instruction, stores the normally-on light parameter information into the normally-on light parameter state table through the normally-on light storage instruction, and stores the full-light parameter information into the full-light parameter state table through the full-light storage instruction.

Further, the storage module 2 includes a flash reference image acquisition unit 21, a normally-on reference image acquisition unit 22, and a full-light reference image acquisition unit 23. In this embodiment, when the composite flash device receives a flash storage command, the flash reference image obtaining unit 21 is triggered to send a turn-off command to the normally-on lamp transceiver, and the flash lamp is automatically turned on and the camera is synchronously controlled to capture a first flash image, the first flash image is subjected to gray scale processing to obtain a flash reference gray scale image, and finally the flash reference gray scale image is stored in the flash parameter state table, when the composite flash device receives the normally-on lamp storage command, the normally-on lamp reference image obtaining unit 22 is triggered to send a turn-off command to the flash lamp transceiver, and the camera is automatically controlled to capture a first normally-on lamp image, the first normally-on lamp image is subjected to gray scale processing to obtain a normally-on lamp reference gray scale image, and finally the normally-on lamp reference gray scale image is stored in the normally-on lamp parameter state table, when the composite flash device receives the full-light storage command, triggering the full-light reference image obtaining unit 23 to automatically flash and synchronously control the camera to shoot the first full-light image, performing gray level processing on the first full-light image to obtain a full-light reference gray level image, and finally storing the full-light reference gray level image into the parameter state table.

When a user needs to call the required light parameter information, the light parameter calling instruction can be received by the triggering calling module 3, a corresponding parameter state table is found according to the light parameter calling instruction, the light parameter information is called from the parameter state table, specifically, the flash lamp parameter information can be called by calling the flash lamp parameter instruction, the normally-on light parameter information can be called by calling the normally-on light parameter instruction, and the full-light parameter information can be called by calling the full-light parameter instruction. And then, the composite ignition device sends the light parameter information to the corresponding lamp transceiver by using the sending module 4 to adjust the light.

Wherein, the sending module 4 includes a flash comparing unit 41, a normally-on comparing unit 42 and a full-light comparing unit 43, in this embodiment, after calling the light parameter information according to the call light parameter instruction and sending the light parameter information to the light transceiver, the light effect image after the light parameter change can be compared with the light reference image, so as to determine whether to send an alarm signal to prompt the user, when the light parameter information is called the flash parameter information, the flash comparing unit 41 is triggered to send a close instruction to the normally-on light transceiver, and automatically turn on the flash and synchronously control the camera to shoot the second flash image, perform gray processing on the second flash image, obtain the flash gray image, compare the flash gray image with the flash reference gray image, and obtain the comparison result, and determine whether to send the alarm signal to the user according to the comparison result, when the calling light parameter information is calling normally-on parameter information, the normally-on comparison unit 42 is triggered to send a turn-off command to the flash transceiver, and the camera is automatically controlled to capture a second normally-on image, performing gray scale processing on the second normally-on image to obtain a normally-on gray scale image, comparing the normally-on gray scale image with the normally-on reference gray scale image to obtain a comparison result, judging whether to send alarm signal to the user according to the comparison result, when the full light parameter information is called, triggering the full light contrast unit 43 to automatically flash and synchronously controlling the camera to capture the first full light image, and carrying out gray level processing on the first full-light image to obtain a full-light gray level image, carrying out gray level comparison on the normally-on light gray level image and the full-light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user according to the comparison result.

The specific definition of the remote control system of the composite flash initiator can be referred to the definition of the remote control method of the composite flash initiator in the above and the description thereof is omitted. All or part of the modules in the remote control system of the composite flash initiator can be realized by software, hardware and a combination thereof. The modules can be embedded in a hardware form or independent of a processor in the electronic device, and can also be stored in a memory of the electronic device in a software form, so that the processor can call and execute operations corresponding to the modules.

In the embodiment, an electronic device is provided, and the electronic device is a composite flash initiator. Referring to fig. 4, the electronic device includes a processor, a memory, a network interface, and a database connected through a system bus. Wherein the processor of the electronic device is configured to provide computing and control capabilities. The memory of the electronic equipment comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the electronic device is used for storing the detection data table. The network interface of the electronic device is used for connecting and communicating with an external terminal through a network. The computer program is executed by a processor to implement a method for remote control of a composite flash initiator.

In one embodiment, an electronic device is provided, comprising a memory, a processor, and a computer program stored on the memory and executable on the processor, the processor implementing the following steps when executing the computer program:

and S1, receiving a storage light parameter instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction.

And S2, executing the operation of obtaining the light parameter information according to the stored light parameter instruction, and storing the light parameter information into a parameter state table, wherein the light parameter information comprises flash lamp parameter information, normally-on parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on parameter state table and a full-light parameter state table.

S3, receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, calling light parameter information in the parameter state table, and calling preset light instructions including a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction.

And S4, sending the light parameter information to the corresponding lamp transceiver for light adjustment.

Further, the steps added after step S2 are:

and S21, when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically igniting a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table.

And S22, when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, and meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling the camera to shoot a first normally-on image, carrying out gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table.

S23, when the received light parameter storage instruction is a full light storage instruction, acquiring and storing full light parameter information to a full light parameter state table, simultaneously, automatically guiding the flash light and synchronously controlling the camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light reference gray level image, and storing the full light reference gray level image into the parameter state table.

Further, the steps added after step S4 are:

and S41, when the received light parameter calling instruction is a flash lamp parameter calling instruction, sending a closing instruction to the normally-on light transceiver, automatically turning on the flash lamp and synchronously controlling the camera to shoot a second flash lamp image, carrying out gray level processing on the second flash lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

And S42, when the received light parameter calling instruction is a normally-on light parameter calling instruction, sending a closing instruction to the flash lamp transceiver, automatically controlling the camera to shoot a second normally-on light image, carrying out gray level processing on the second normally-on light image to obtain a normally-on light gray level image, comparing the normally-on light gray level image with a normally-on light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

S43, when the received light parameter calling instruction is a full light parameter calling instruction, automatically flashing a flash lamp and synchronously controlling a camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light gray level image, carrying out gray level comparison on the normally-lit gray level image and the full light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

Further, the alarm signal includes a check request confirmation message, and the steps added after steps S41, S42, and S43 are:

and S5, determining to send a query instruction to the lamp transceiver according to the detection request confirmation information.

And S6, receiving the light detection result in real time, and sending prompt information to the user according to the light detection result.

The embodiment of the application discloses a computer readable storage medium, wherein a computer program is stored on the computer readable storage medium, and when being executed by a processor, the computer program realizes the following steps:

and S1, receiving a storage light parameter instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction.

And S2, executing the operation of obtaining the light parameter information according to the stored light parameter instruction, and storing the light parameter information into a parameter state table, wherein the light parameter information comprises flash lamp parameter information, normally-on parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on parameter state table and a full-light parameter state table.

S3, receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, calling light parameter information in the parameter state table, and calling preset light instructions including a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction.

And S4, sending the light parameter information to the corresponding lamp transceiver for light adjustment.

Further, the steps added after step S2 are:

and S21, when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically igniting a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table.

And S22, when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, and meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling the camera to shoot a first normally-on image, carrying out gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table.

S23, when the received light parameter storage instruction is a full light storage instruction, acquiring and storing full light parameter information to a full light parameter state table, simultaneously, automatically guiding the flash light and synchronously controlling the camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light reference gray level image, and storing the full light reference gray level image into the parameter state table.

Further, the steps added after step S4 are:

and S41, when the received light parameter calling instruction is a flash lamp parameter calling instruction, sending a closing instruction to the normally-on light transceiver, automatically turning on the flash lamp and synchronously controlling the camera to shoot a second flash lamp image, carrying out gray level processing on the second flash lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

And S42, when the received light parameter calling instruction is a normally-on light parameter calling instruction, sending a closing instruction to the flash lamp transceiver, automatically controlling the camera to shoot a second normally-on light image, carrying out gray level processing on the second normally-on light image to obtain a normally-on light gray level image, comparing the normally-on light gray level image with a normally-on light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

S43, when the received light parameter calling instruction is a full light parameter calling instruction, automatically flashing a flash lamp and synchronously controlling a camera to shoot a first full light image, carrying out gray level processing on the first full light image to obtain a full light gray level image, carrying out gray level comparison on the normally-lit gray level image and the full light reference gray level image to obtain a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result.

Further, the alarm signal includes a check request confirmation message, and the steps added after steps S41, S42, and S43 are:

and S5, determining to send a query instruction to the lamp transceiver according to the detection request confirmation information.

And S6, receiving the light detection result in real time, and sending prompt information to the user according to the light detection result.

The computer-readable storage medium stores a computer program which, when executed by a processor, implements the steps of the method for remote control of a composite flash initiator described above.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware related to instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, the computer program can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile 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), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

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

Claims (7)

1. A remote control method of a composite ignition device is characterized by comprising the following steps:

receiving a storage light parameter instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on light storage instruction and a full light storage instruction;

executing an operation of obtaining lamplight parameter information according to a stored lamplight parameter instruction, and storing the lamplight parameter information into a parameter state table, wherein the lamplight parameter information comprises flash lamp parameter information, normally-on lamp parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table;

when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table;

when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling a camera to shoot a first normally-on image, performing gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table;

when the received light parameter storage instruction is a full-light storage instruction, acquiring and storing full-light parameter information to a full-light parameter state table, simultaneously, automatically guiding a flash light and synchronously controlling a camera to shoot a first full-light image, carrying out gray level processing on the first full-light image to obtain a full-light reference gray level image, and storing the full-light reference gray level image into the parameter state table;

receiving a light parameter calling instruction, finding a corresponding parameter state table according to the light parameter calling instruction, and calling light parameter information in the parameter state table, wherein the light parameter calling preset instruction comprises a flash lamp parameter calling instruction, a normally-on light parameter calling instruction and a full-light parameter calling instruction;

and sending the light parameter information to the corresponding lamp transceiver for light adjustment.

2. The method of claim 1, further comprising:

when the light parameter calling instruction is received and called as a flash lamp parameter calling instruction, sending a closing instruction to a normally-on light transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a second flash lamp image, carrying out gray level processing on the second lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result;

when the light parameter calling instruction is received and is a normally-on parameter calling instruction, a closing instruction is sent to a flash lamp transceiver, a camera is automatically controlled to shoot a second normally-on image, the second normally-on image is subjected to gray level processing to obtain a normally-on gray level image, the normally-on gray level image is compared with a normally-on reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result;

when the light parameter calling instruction is received and is a full light parameter calling instruction, the flashing light is automatically triggered, the camera is synchronously controlled to shoot a first full light image, gray processing is carried out on the first full light image to obtain a full light gray image, gray value comparison is carried out on the normally-on light gray image and a full light reference gray image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

3. The method of claim 2, further comprising:

the alarm signal includes detection request confirmation information;

determining to send a query instruction to the lamp transceiver according to the detection request confirmation information;

and receiving a light detection result in real time, and sending prompt information to a user according to the light detection result.

4. A remote control system for a composite ignition system, comprising:

a receiving module: the device comprises a storage light parameter instruction, a control instruction and a display instruction, wherein the storage light parameter instruction comprises a flash lamp storage instruction, a normally-on lamp storage instruction and a full-light storage instruction;

a storage module: the system comprises a parameter state table, a parameter state table and a control module, wherein the parameter state table is used for executing operation of obtaining lamplight parameter information according to a stored lamplight parameter instruction and storing the lamplight parameter information into the parameter state table, the lamplight parameter information comprises flash lamp parameter information, normally-on lamp parameter information and full-light parameter information, and the parameter state table comprises a flash lamp parameter state table, a normally-on lamp parameter state table and a full-light parameter state table;

the memory module further includes: the device comprises a flash lamp reference image acquisition unit, a normally-on reference image acquisition unit and a full-light reference image acquisition unit;

a flash reference image acquisition unit: when the received light parameter storage instruction is a flash lamp storage instruction, acquiring and storing flash lamp parameter information to a flash lamp parameter state table, meanwhile, sending a closing instruction to a normally-on lamp transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a first flash lamp image, carrying out gray level processing on the first flash lamp image to obtain a flash lamp reference gray level image, and storing the flash lamp reference gray level image into the flash lamp parameter state table;

a normally-on reference image acquisition unit: when the received light parameter storage instruction is a normally-on storage instruction, acquiring and storing normally-on parameter information to a normally-on parameter state table, meanwhile, sending a closing instruction to a flash lamp transceiver, automatically controlling a camera to shoot a first normally-on image, performing gray level processing on the first normally-on image to obtain a normally-on reference gray level image, and storing the normally-on reference gray level image into the normally-on parameter state table;

full light reference image acquisition unit: when the received light parameter storage instruction is a full-light storage instruction, acquiring and storing full-light parameter information to a full-light parameter state table, simultaneously, automatically guiding a flash light and synchronously controlling a camera to shoot a first full-light image, carrying out gray level processing on the first full-light image to obtain a full-light reference gray level image, and storing the full-light reference gray level image into the parameter state table;

a calling module: the system comprises a parameter state table, a light parameter calling instruction, a normally-on light parameter calling instruction and a full light parameter calling instruction, wherein the parameter state table is used for storing the light parameter information of the lamp;

a sending module: and the lamp parameter information is sent to the corresponding lamp transceiver for lamp light adjustment.

5. The remote control system of claim 4, wherein the transmission module further comprises:

flash lamp contrast unit: when the light parameter calling instruction is received and called as a flash lamp parameter calling instruction, sending a closing instruction to a normally-on light transceiver, automatically guiding a flash lamp and synchronously controlling a camera to shoot a second flash lamp image, carrying out gray level processing on the second lamp image to obtain a flash lamp gray level image, comparing the flash lamp gray level image with a flash lamp reference gray level image, obtaining a comparison result, and judging whether to send an alarm signal to a user or not according to the comparison result;

a normally-on lamp comparison unit: when the light parameter calling instruction is received and is a normally-on parameter calling instruction, a closing instruction is sent to a flash lamp transceiver, a camera is automatically controlled to shoot a second normally-on image, the second normally-on image is subjected to gray level processing to obtain a normally-on gray level image, the normally-on gray level image is compared with a normally-on reference gray level image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result;

full light contrast unit: when the light parameter calling instruction is received and is a full light parameter calling instruction, the flashing light is automatically triggered, the camera is synchronously controlled to shoot a first full light image, gray processing is carried out on the first full light image to obtain a full light gray image, gray value comparison is carried out on the normally-on light gray image and a full light reference gray image to obtain a comparison result, and whether an alarm signal is sent to a user or not is judged according to the comparison result.

6. An electronic 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 method for remote control of a composite flash initiator according to any one of claims 1-3 when executing the computer program.

7. A computer-readable storage medium, characterized in that a computer program is stored which can be loaded by a processor and which executes a method for remote control of a composite flash initiator according to any one of claims 1 to 3.

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