CN220234752U - Multi-device synchronous scheduling system for virtual film field - Google Patents

Abstract

The utility model provides a multi-device synchronous scheduling system for a virtual film field, which comprises an electronic clap board, a dynamic capture system, a synchronizer and a plurality of virtual film field subsystems, wherein the dynamic capture system is used for capturing the dynamic capture of the electronic clap board; the dynamic capture system is electrically connected with each virtual field subsystem through a synchronizer respectively, so that the operation of each virtual field subsystem can be controlled; an electronic switch is arranged on the electronic clap board; the electronic switch can provide a starting signal for the dynamic capture system under triggering; the electronic clap board comprises an electronic clap board body and a turning plate; the turning plate can trigger an electronic switch on the electronic clap plate body to provide a starting signal for the dynamic capture system when the clap is taken down; the dynamic capture system is configured to receive a start signal to control synchronous operation of each virtual field subsystem through the synchronizer; by adopting the synchronous scheduling system, the electronic switch is arranged on the electronic clap board, so that the electronic clap board can trigger the synchronous operation of each virtual film subsystem when the clap board is shot down.

Description

Multi-device synchronous scheduling system for virtual film field

Technical Field

The utility model belongs to the technical field of multi-device synchronous scheduling systems, and particularly relates to a multi-device synchronous scheduling system for a virtual chip yard.

Background

The first clap board in the film history is invented by Frank schlin (Frank thread) which is the main pipe of the Australian melbourne Eftee film studio in the 20 th century, so that the clap board has very close relation with film work since birth, and is an indispensable field scheduling tool in the film shooting process.

The traditional film clap board is a wooden small board with black and white alternate stripes, the form structure and material materials are designed based on the functions of on-site scheduling and clap signal, and key data information such as the date of the shooting day, the scene of the shot content, the number of mirrors, the number of times, the camera card number and the like is written by a clap or director assistant by using a marker pen. After a director sends a start instruction on a shooting site, a scene will sound a scene board and uniformly send shooting preparation signals to departments such as actors, shooting, recording, art props, lamplight and the like, so that all departments are scheduled to synchronously start shooting work; the system has the functions of giving command signals for all departments in the field to synchronously start working, carrying out material management and rough cutting arrangement on DIT in the field according to shooting scenes and mirror number information on the clap boards and the clap tables, further optimizing the working efficiency of later-stage link editing, ensuring that the clap boards are special clap board sounds are important references for aligning video and audio material plywood by the sound departments, ensuring the synchronous accuracy of sound and picture, and being an important pivot in the middle-stage shooting and later-stage manufacturing processes of films, and determining the manufacturing efficiency and the finishing quality of films.

Along with the continuous development of the film industry in the last hundred years, the hollywood industrialization and large-scale special effect scene production has the advantages that the shooting mode directly promotes the functional form of the film scene, such as the electronic scene and the intelligent scene, the performance quality and the signal marking function of the scene are effectively enhanced, the electronic scene can be applied to various complex special effect lens shooting and different weather and landform conditions, and meanwhile, the electronic scene can digitally and intelligently display information of different scenes and lens numbers, so that the efficiency of purely manual work scene shooting is saved, and the marking recognition of later editing on various material information is more accurately optimized.

At the moment of the comprehensive development of film digitization and virtual shooting technology, new technologies such as virtual shooting and motion capture are comprehensively popularized, and the technology is widely applied to the fields of film, television, animation and the like, and the requirements for multi-department work scheduling and information synchronization of the clabs in the shooting process are also changed.

In the motion capturing link of the virtual film field, different devices are required to acquire character limb motions, expression motions and the like respectively, each shooting device captures character performance data by utilizing corresponding software, records and measures the motion trail of a performer in space in real time, synchronously transmits the motion trail to the main control device, directly transfers the motion trail to the virtual character through the three-dimensional engine, realizes real-time monitoring of animation effects, and simultaneously converts the animation effects into animation files corresponding to an animation production system in a computer; in the procedure, a plurality of department personnel and equipment are required to start synchronously in a starting link of the shooting before shooting, data of the performance of the dynamic capturing actors, such as on-site sound, camera lens scheduling, and data materials of the dynamic capturing actions, facial expressions, fingers and the like of the roles are uniformly collected, and the corresponding virtual shooting procedure experience and higher technical operation level of each department personnel are required in the link, so that coordination and accuracy of virtual shooting and action capturing data can be ensured. The current latest technical mode is that the process of motion capture of the virtual film field has extremely high requirements on unified scheduling and data information synchronization of multi-equipment shooting, and is also a core link for smoothly advancing the control field by virtual shooting film production.

However, compared with the traditional film clap board or digital clap board, the single material information marking and clap board scheduling mode is difficult to unify complex shooting manufacturing equipment of the film farm, huge data information arrangement and synchronous scheduling work increases trivial labor cost, cannot be compatible with the systematic, technical and precise digital industrial manufacturing modes, cannot meet the quantization function requirements of the virtual film farm and motion capture shooting, and is a link needing key optimization and lifting in the current virtual film farm manufacturing process.

Based on the technical problems existing in the synchronous scheduling of the virtual chip field multi-device, no relevant solution exists yet; there is therefore an urgent need to seek an effective solution to the above problems.

Disclosure of Invention

The utility model aims at solving the defects existing in the technology, and provides a multi-device synchronous scheduling system for a virtual film field, which aims at solving the problem of synchronous operation of multiple devices of the existing virtual film field.

The utility model provides a multi-equipment synchronous scheduling system for a virtual film field, which comprises an electronic clap board, a dynamic capture system, a synchronizer and a plurality of virtual film field subsystems in synchronous linkage;

the dynamic capturing system is electrically connected with each virtual field subsystem in synchronous linkage through a synchronizer, so that the operation of each virtual field subsystem can be controlled;

an electronic switch is arranged on the electronic clap board and is connected with the dynamic capture system; the electronic switch can provide a starting signal for the dynamic capture system under triggering;

the electronic clap board comprises an electronic clap board body and a turning plate, and the turning plate can be rotatably arranged on the electronic clap board body; the electronic switch is arranged on the electronic clap board body; the turning plate can trigger an electronic switch on the electronic clap plate body to provide a starting signal for the dynamic capture system when the clap is taken down;

the dynamic capture system is configured to receive a start signal to control synchronous operation of the respective virtual field subsystems via the synchronizer.

Further, the electronic switch comprises an electronic keystroke device which is arranged on the table surface of the electronic clap board body; the turning plate can be rotatably arranged on one side of the table surface of the electronic slate body, and can touch the circuit of the electronic keystroke device to be communicated when the electronic keystroke device is in shooting, so that a starting signal is provided for the dynamic capture system.

Further, the dynamic capturing system comprises a main control unit, wherein the main control unit comprises a main control chip, a wireless transmission module is arranged on the main control chip, and the wireless transmission module is in communication connection with the main control chip; the electronic keystroke device is in wireless communication connection with the main control chip through the wireless transmission module, so that a start signal can be sent to the main control unit.

Further, the dynamic capturing system comprises a main control unit, wherein the main control unit is provided with a GPIO interface; the electronic key device is connected with the GPIO interface of the main control unit through the GPIO line, so that a start signal can be sent to the main control unit.

Further, one end of the synchronizer is in communication connection with the main control chip, and the other end of the synchronizer is in communication connection with the subsystems of the virtual film fields respectively; the synchronizer can simultaneously start the subsystem of each virtual chip field to start running when receiving the control signal provided by the main control chip.

Further, the plurality of virtual film field subsystems comprise a surface capturing system, a finger capturing system, a shooting system and a recording system; the surface capturing system, the finger capturing system, the shooting system and the recording system are respectively and independently connected with the main control chip in a communication way through a synchronizer.

Further, the wireless transmission module is in communication connection with the main control chip through a 2.4G wireless network.

Further, a touch block is arranged on the bottom surface of the turning plate, and the touch block can press the electronic button device to be connected when the turning plate is shot downwards, so that the electronic button device provides a starting signal for the dynamic capturing system.

Further, a USB interface is arranged on the main control unit; one end of the synchronizer is connected with a USB interface on the main control unit through a USB optical fiber line; the synchronizer synchronously transmits signals to each virtual slice subsystem with a maximum error of less than ten frames.

Further, a sounding component is arranged on the touch block or the electronic keystroke device, and the turning plate can touch the sounding component to give out prompt sound when the electronic keystroke device is touched by the downward swatter.

Further, the electronic clap board body or the turning board is provided with a sounding component, and the turning board can touch the sounding component to give out prompt sound when the electronic keylocker is touched by the lower clap.

The multi-equipment synchronous scheduling system provided by the utility model has the advantages of high efficiency, digitalization and accuracy in manufacturing process, and has the following specific technical effects:

the multi-equipment synchronous scheduling system provided by the utility model can uniformly schedule and synchronously start the shooting tasks of the lens without controlling each shooting equipment by multiple persons;

the second, the multi-equipment synchronous scheduling system provided by the utility model, the wireless transmission module develops the logic circuit based on the singlechip, the digital signal is sent to the main control unit through the 2.4G wireless network, and the signal synchronizer receives the signal based on the electronic circuit technology, so as to ensure the accurate synchronization of the signal source;

thirdly, the multi-equipment synchronous scheduling system provided by the utility model can effectively reduce the length deviation of dynamic capturing data and shooting materials, and can obtain relatively consistent data materials;

fourth, the multi-equipment synchronous scheduling system provided by the utility model simplifies the personnel work function in the virtual shooting, optimizes the on-site scheduling and communication, and promotes the post-production efficiency and the data handover error of the virtual shooting.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

The utility model will be further described with reference to the accompanying drawings in which:

FIG. 1 is a schematic diagram of a multi-device synchronous scheduling system for virtual film fields according to the present utility model;

FIG. 2 is a schematic diagram of a multi-device synchronous scheduling system for virtual slots according to the present utility model;

fig. 3 is a schematic diagram of an electronic slate structure of the present utility model.

In the figure: 1. an electronic slate body; 2. turning plate; 3. a touch block; 4. an electronic key press.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise. The meaning of "a number" is one or more than one unless specifically defined otherwise.

In the description of the present utility model, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", etc., are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

1-3, the present utility model provides a multi-device synchronous scheduling system for virtual film fields, wherein the synchronous scheduling system comprises an electronic slate, a dynamic capture system, a synchronizer and a plurality of virtual film field subsystems in synchronous linkage; specifically, the dynamic capture system is electrically connected with each virtual field subsystem in synchronous linkage through a synchronizer, so that the operation of each virtual field subsystem can be controlled; further, an electronic switch is arranged on the electronic clap board and is in communication connection with the dynamic capture system, so that signal transmission is realized; further, the electronic switch can provide a starting signal for the dynamic capture system under the triggering, so that the dynamic capture system controls the synchronous operation of each virtual film field subsystem; further, the electronic clap board comprises an electronic clap board body 1 and a turning plate 2, wherein the turning plate 2 can be rotatably arranged on the electronic clap board body 1, so that virtual film scene starting is realized; further, the electronic switch is arranged on the electronic clap board body 1, and the turning board 2 can trigger the electronic switch on the electronic clap board body 1 to provide a start signal for the dynamic capture system when the clap board is shot down, and the dynamic capture system is configured to receive the start signal, so that the synchronous operation of each virtual clap subsystem is controlled through the synchronizer, and the start information node for acquiring data is accurately positioned, so that the alignment of data information is ensured; by adopting the synchronous scheduling system, the electronic switch is arranged on the electronic clap board, so that the electronic clap board can trigger the synchronous operation of each virtual film field subsystem when the clap board is shot down; the multi-equipment synchronous scheduling system for the virtual film field can solve the problems that a plurality of people are required to operate and start the equipment for capturing simultaneously in the action capturing link of the virtual film field, the work load of technicians is increased, the efficient implementation of a shooting process is improved, the time deviation of equipment opening time of a large-time virtual shooting middle-later-period producer is solved, the opening errors of various equipment such as shooting, sound and dynamic capturing on various information data and materials are effectively avoided, the alignment work problem of the multi-equipment data information and materials is solved, the data can be directly aligned synchronously and matched with the endpoints of the various materials, and more accurate unified sound-image materials and dynamic capturing data than manual DIT can be directly obtained.

Preferably, in combination with the above, as shown in fig. 1 to 3, the electronic switch includes an electronic key 4, and the electronic key 4 is disposed on the table top of the electronic slate body 1; specifically, the turning plate 2 can be rotatably arranged on one side of the table surface of the electronic clap board body 1, and can be contacted with a circuit of the electronic keystroke device 4 when in shooting, so that a starting signal is provided for a dynamic capturing system of the electronic keystroke device, and synchronous operation of each virtual film field subsystem is realized.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, the dynamic capture system includes a main control unit, the main control unit includes a main control chip, a wireless transmission module is arranged on the main control chip, and the wireless transmission module is in communication connection with the main control chip; the wireless transmission module develops a logic circuit based on a singlechip, so that communication transmission is realized; specifically, the electronic keystroke device 4 is in wireless communication connection with the main control chip through the wireless transmission module, so that a start signal can be sent to the main control unit; specifically, the electronic clap board triggers the electronic keystroke device to respond in the moment of shooting, the main control chip converts the generated analog signal into a digital signal, the digital signal is transmitted to the main control unit of the dynamic film capturing field through the 2.4G wireless network, the signal synchronizer is based on the electronic circuit technology and is used for receiving the control signal of the main control unit (namely the main control computer) of the film field, the digital signal is converted into an analog signal, and the analog signal is synchronously output to equipment such as film expression capturing, recording and shooting in a multichannel mode to be used as starting control after being processed by filtering, power amplification and the like, so that the synchronous start of film field data recording information is ensured, and the problem of multi-source signal synchronization is solved.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, the dynamic capture system includes a main control unit, and the main control unit is provided with a GPIO interface; specifically, the electronic key 4 is connected with the GPIO interface of the main control unit through the GPIO line, so that a start signal can be sent to the main control unit, signal transmission can be realized, and the start signal can be sent to the main control unit.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, one end of the synchronizer is in communication connection with the main control chip, and the other end of the synchronizer is respectively in communication connection with the subsystems of each virtual film field; specifically, the synchronizer can start the subsystem of each virtual chip field to start running at the same time when receiving the control signal provided by the main control chip.

Preferably, in combination with the above solution, as shown in fig. 1 to 3, the plurality of virtual film subsystems include a surface capturing system, a finger capturing system, a shooting system and a recording system; specifically, the surface capturing system, the finger capturing system, the shooting system and the recording system are respectively and independently connected with the main control chip in a communication way through the synchronizer, so that synchronous operation is realized.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, the wireless transmission module is connected with the main control chip through a 2.4G wireless network in a communication manner; specifically, in the scene of dynamic capturing, a multi-device synchronous scheduling system is used, a system starting signal is triggered while a plate is made before a lens is started, the starting signal is transmitted to a control computer of the dynamic capturing system through a 2.4G network, then the starting signal is synchronously transmitted to digital cameras, recording, surface capturing and virtual synthesizing devices through a system synchronizer with the maximum error less than a few frames, start and stop information and time of all captured data are synchronized, the operation problem caused by manually starting the device is accurately solved, meanwhile, the process progress of virtual capturing can be accelerated by accurate synchronous scheduling, the low-efficiency butt joint cost of multiple departments is reduced, and the synchronously transmitted data are directly aligned to be uniform data materials, so that the subsequent work of animation and later departments is directly facilitated; further, as the multi-device synchronous scheduling system develops a logic circuit based on a single chip microcomputer through a wireless transmission module, digital signals are sent to a main control unit through a 2.4G wireless network, and meanwhile, a signal synchronizer receives the signals based on an electronic circuit technology, so that accurate synchronization of signal sources is ensured, and data alignment work of post-production is optimized; meanwhile, accurate shooting data and materials can be obtained by using the virtual shooting flow of the multi-equipment synchronous scheduling system, so that the working efficiency of technicians and the communication cost of field shooting are greatly optimized.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, a touch block 3 is arranged on the bottom surface of the turning plate 2, and the touch block 3 is a silica gel plate or a silica gel sheet and can press the electronic keystroke device 4 to be connected when the turning plate 2 is shot downwards, so that the electronic keystroke device 4 provides a starting signal for the dynamic capturing system; by adopting the scheme, the touch block 3 is arranged on the bottom surface of the turning plate 2 and is matched with the electronic keystroke device 4 on the electronic clap board body 1, so that the circuit of the electronic keystroke device 4 is accurately extruded to be connected when the turning plate 2 is shot down, and the buffering effect can be achieved.

Preferably, in combination with the above scheme, as shown in fig. 1 to 3, a USB interface is provided on the main control unit; one end of the synchronizer is connected with a USB interface on the main control unit through a USB optical fiber line; the synchronizer synchronously transmits signals to each virtual slice subsystem with a maximum error of less than ten frames.

Preferably, in combination with the above-mentioned scheme, as shown in fig. 1 to 3, in this embodiment, the touch block 3 or the electronic keystroke device 4 is provided with a sound generating component, so that the panel turnover 2 can touch the sound generating component to generate a prompt sound when the electronic keystroke device 4 is touched by a downward beat; specifically, the sounding component is arranged on the contact surface of the touch block 3 and the electronic keystroke device 4, so that the turning plate 2 triggers the sounding component to give out prompt sounds when the sounding component is touched by the lower swatter, and thus, a stadium can sense or know the starting of the equipment at the first time.

Preferably, in combination with the above-mentioned scheme, as shown in fig. 1 to 3, in this embodiment, a sound generating component is disposed on the electronic slate body 1 or the board 2, so that the board 2 can touch the sound generating component to generate a prompt sound when the electronic keylocker 4 is touched by a lower beat; specifically, the sounding component sets up on the contact surface of sub-slate body 1 and turning over board 2, makes like this turns over board 2 and beats down touching sounding component in the twinkling of an eye and triggers sounding component and send the suggestion sound, and the staff can the start-up of first time perception or knowing equipment like this.

The multi-device synchronous scheduling system provided by the utility model can be used as a technical system developed in the creation of video animation scientific research projects in colleges and universities, and can obtain effective verification on synchronous optimization of data and improvement of shooting efficiency through the practice of project flow, and can obtain accurate dynamic capturing data and shooting materials; meanwhile, the multi-equipment synchronous scheduling system is firstly applied to scientific research creation of college animation, optimizes the technical difficulty of equipment operation and personnel communication cost, and facilitates college animation teaching and creation practice. In the device flow chart of the multi-device synchronous scheduling system of the cinema children animation film 'fly to moon', the electronic slate triggers a starting signal, and synchronous signals are sent out to a face capturing system, a finger capturing system, a shooting system and a recording system through connection of a dynamic capturing system and a synchronizer, so that the multi-device synchronous accurate control is realized.

The multi-equipment synchronous scheduling system provided by the utility model has the advantages of high efficiency, digitalization and accuracy in manufacturing process, and has the following specific technical effects:

the multi-equipment synchronous scheduling system provided by the utility model can uniformly schedule and synchronously start the shooting tasks of the lens without controlling each shooting equipment by multiple persons;

the second, the multi-equipment synchronous scheduling system provided by the utility model, the wireless transmission module develops the logic circuit based on the singlechip, the digital signal is sent to the main control unit through the 2.4G wireless network, and the signal synchronizer receives the signal based on the electronic circuit technology, so as to ensure the accurate synchronization of the signal source;

thirdly, the multi-equipment synchronous scheduling system provided by the utility model can effectively reduce the length deviation of dynamic capturing data and shooting materials, and can obtain relatively consistent data materials;

fourth, the multi-equipment synchronous scheduling system provided by the utility model simplifies the personnel work function in the virtual shooting, optimizes the on-site scheduling and communication, and promotes the post-production efficiency and the data handover error of the virtual shooting.

The above description is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model in any way. Many possible variations and modifications of the disclosed technology can be made by anyone skilled in the art, or equivalent embodiments with equivalent variations can be made, without departing from the scope of the disclosed technology. Therefore, any modification, equivalent variation and modification of the above embodiments according to the technology of the present utility model fall within the protection scope of the present utility model.

Claims (10)

1. The multi-equipment synchronous scheduling system for the virtual film field is characterized by comprising an electronic clap board, a dynamic capture system, a synchronizer and a plurality of virtual film field subsystems which are synchronously linked;

the dynamic capture system is electrically connected with each virtual field subsystem in synchronous linkage through the synchronizer, so that the operation of each virtual field subsystem can be controlled;

an electronic switch is arranged on the electronic clap board and is connected with the dynamic capturing system; the electronic switch can provide a starting signal for the dynamic capture system under the triggering;

the electronic clap board comprises an electronic clap board body (1) and a turning plate (2), wherein the turning plate (2) can be rotatably arranged on the electronic clap board body (1); the electronic switch is arranged on the electronic clap board body (1); the turning plate (2) can trigger the electronic switch on the electronic slate body (1) to provide a starting signal for the dynamic capture system when the electronic slate body is shot down;

the dynamic capture system is configured to receive the start signal to control synchronous operation of each virtual field subsystem via the synchronizer.

2. The multi-device synchronous scheduling system for virtual film farms according to claim 1, characterized in that the electronic switch comprises an electronic keylocker (4), the electronic keylocker (4) being arranged on a table top of the electronic slate body (1); the turning plate (2) can be rotatably arranged on one side of the table top of the electronic clap board body (1), and can be contacted with the electronic button device (4) to be connected when the clap is taken down, so that a starting signal is provided for the dynamic capturing system.

3. The multi-device synchronous scheduling system for virtual film farms according to claim 2, wherein the dynamic capture system comprises a main control unit, the main control unit comprises a main control chip, a wireless transmission module is arranged on the main control chip, and the wireless transmission module is in communication connection with the main control chip; the electronic key device (4) is in wireless communication connection with the main control chip through the wireless transmission module, so that the starting signal can be sent to the main control unit.

4. The multi-device synchronous scheduling system for virtual film farms according to claim 2, wherein the dynamic capture system comprises a main control unit, and the main control unit is provided with a GPIO interface; the electronic keystroke device (4) is connected with the GPIO interface of the main control unit through a GPIO line, so that the starting signal can be sent to the main control unit.

5. The multi-device synchronous scheduling system for virtual fields according to claim 3, wherein one end of the synchronizer is in communication connection with the main control chip, and the other end of the synchronizer is in communication connection with subsystems of each virtual field respectively; the synchronizer can start the subsystem of each virtual chip field to start running at the same time when receiving the control signal provided by the main control chip.

6. The multi-device synchronous scheduling system for virtual film fields of claim 3, wherein the plurality of virtual film field subsystems comprises an facial capture system, a finger capture system, a shooting system, and a sound recording system; the surface capturing system, the finger capturing system, the shooting system and the recording system are respectively and independently connected with the main control chip in a communication way through the synchronizer.

7. The multi-device synchronous scheduling system for virtual titles of claim 3, wherein the wireless transmission module is communicatively coupled to the master control chip via a 2.4G wireless network.

8. The multi-device synchronous scheduling system for virtual film fields according to claim 2, wherein a touch block (3) is arranged on the bottom surface of the turning plate (2), and the touch block (3) can press the electronic button device (4) to be connected when the turning plate (2) is shot down, so that the electronic button device (4) provides a starting signal for the dynamic capturing system.

9. The multi-device synchronous scheduling system for virtual film fields according to claim 3 or 4, wherein the main control unit is provided with a USB interface; one end of the synchronizer is connected with the USB interface on the main control unit through a USB optical fiber line; the synchronizer synchronously transmits signals to each virtual field subsystem with a maximum error of less than ten frames.

10. The multi-device synchronous scheduling system for virtual film fields according to claim 8, wherein a sound generating component is arranged on the touch block (3) or the electronic key device (4), and the turning plate (2) can touch the sound generating component to generate a prompt sound when the electronic key device (4) is touched by a lower beat; or,

the electronic clap board is characterized in that a sounding component is arranged on the electronic clap board body (1) or the turning plate (2), and the turning plate (2) can touch the sounding component to give out prompt sound when the electronic clap board (4) is touched by lower clap.