KR890002721B1 - Total information system for industrial television - Google Patents

Abstract

The system combined with the industrial television system of the distributive control and the optical video system of the central control comprises an image controller (10) for taking the image with a camera and converting the taken image to the optical video signal, a subcenter circuit (20) for controlling the video signal distributively, a management controller (30) for controlling the video signal contrally, a main video exahanging circuit (40) for exahanging the video signal with the counter channel, a converter (50) for converting the video, audio, and control signal to the optical one, and a terminal (60) for controlling all the information.

Description

Production Information System

1 is a block diagram of a comprehensive information system for production control according to the present invention.

2 is a conceptual diagram showing an embodiment of FIG.

3 is a block diagram of a concrete circuit diagram of the industrial television system of FIG.

Block diagram of a concrete circuit diagram of the optical image system of FIG.

5 is an explanatory diagram of a Wavelength Division Multiplex (WDM) device.

* Explanation of symbols for main parts of the drawings

10: image generation and control unit 20: sub-center unit

30: control unit 40: main video exchange unit

50: converter 60: video conference terminal

200: industrial television system 300: optical video system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a comprehensive information system for production control, and more particularly, to an integrated information system using an industrial television system (hereinafter referred to as "ITV") system in a distributed control system and a light beam image system in a centralized control system. In recent years, a factory or a company having a large-scale system and a management department needs an ITV system that monitors the operation status of each major process of the factory and an optical video conference system to enhance the business efficiency of the company.

Therefore, in a factory or enterprise with such a large production system, various meetings, public relations and education, etc. are carried out for continuous monitoring of the operation status of each factory, smooth work processing between related departments and work cabs, and rapid planning and recovery planning. The necessity of a comprehensive information and communication system that maximizes its scope of use, such as expansion of new participation opportunities, is being maximized. As a communication system that monitors the operation status of the main process in the conventional factory, it has not only escaped the scope of the monitoring system using ITV, and the establishment of such a monitoring system was used as a jurisdiction system at a predetermined place, so that they are separated from each other. There is no linkage monitoring system with the relevant departments in the wrong location, and multi-way video conferencing is conducted when selecting a screen at any point in the process to establish a recovery plan. And it was difficult to quickly transmit high quality signals of voice signals.

In particular, when the distance between each process department of the factory and the management department is located at a distant distance, the simultaneous transmission of video and audio signals and the transmission of high quality signals for interchange of the signals have also been difficult. Accordingly, an object of the present invention is to provide a system that enables comprehensive production control by simultaneously implementing an ITV system that monitors the operation status of each factory and an optical video conference system for improving work efficiency of a company.

It is still another object of the present invention to provide a system capable of transmitting a high quality signal without being subjected to electromagnetic interference by using an optical transmission device. It is another object of the present invention to provide an integrated information communication system that enables the interchange of all video and audio information by organically combining an ITV and an optical image system. It is another object of the present invention to provide a comprehensive information system that uses a distributed control ITV system and a centralized control optical video conference system together. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a block diagram of a comprehensive information control system for production control according to the present invention, in which an optical image conference having an organic interchange relationship with an ITV system 200 capable of monitoring operation status, facility operation, accidents or environmental conditions, etc. System 300.

The ITV system 200 includes an image generation and control unit 10, a sub center unit 20, and a control unit 30. The optical video conference system 300 includes a video conference terminal unit 60 and a change unit. 50, the main video switching unit 40. In the ITV system 200, the image generation and control unit 10 generates a video signal captured from an industrial television camera installed at each process of a factory or a necessary monitoring place, and converts the video signal into an optical signal and outputs the converted video signal. At the same time, the industrial television camera accurately controls the video signal according to the control signal generated by the sub-center unit 20 or the control unit 30 to be described later. Since the connection and control relationship are described in detail with reference to FIG. 3, the camera will not be shown in FIG.

The sub center unit 20 converts the optical signal into an electrical signal by inputting the optically changed video signal generated and input from the image generation and control unit 10 to the optical cable 70 and at the same time, monitoring each process or necessary. The industrial television camera installed at the site is divided into a predetermined number of main groups for each process function, and each main group is divided into predetermined subgroups, and video signals transmitted therefrom are automatically scanned and output for each subgroup, and randomly selected from the main group. The output signal is converted into an optical signal and output, and at the same time, the operation state of the sub-center unit 20 can be monitored by the supervisor's control selection, and the camera remotely output from the related unit 30 to be described later. The control data is bidirectional WDM (Wavelength Division Modulation) so that the control signal has priority over the control signal of the camera of the sub-center unit 20. Output through the optical transmission path (80b) through the optical transmission path (150) through the WDM device, the remote control signal of the camera is also output through the optical transmission path (80b) through the device, the camera Since the control unit 20 and the control unit 30 can control the control unit 30 and preferentially control the sub-center unit 20, the distributed control method is processed.

The control unit 30 outputs the light-converted scanning video signal transmitted from the sub-center unit 20 to the optical transmission path 90 so that the main video exchange unit 40 of the optical video conferencing system 300 described later. By monitoring the entire operation status by bypassing the video matrix exchanger and inputting it to the control unit 30 through the optical transmission path 100, the monitor for the person in charge of the monitor unit selects and monitors each screen at the same time. The industrial television camera can be used to control the optical transmission path by controlling the control board to adjust up, down, left, right, rotation, zoom, camera power on / off and automatic scanning, and selection of a desired screen. 80a) bypasses the main central processing unit through the decoder of the main video exchanger 40 to be described later, and enters the subcenter 20 through the encoder and the optical transmission path 80b.

On the other hand, the video conferencing terminal 60 of the optical video conferencing system 300 is provided with a video camera, a sub-set of a microphone and a keyboard, a speaker and a monitor, and a video signal, an audio signal and a control signal. Output and enter The conversion unit 50 converts the electrical signals of the video signal, the audio signal, and the control signal output from the video conferencing terminal unit 60 into optical modulation signals and transmits them to an optical transmission path, and transmits the transmitted optical modulation signals. The electronic signal is demodulated again to output the signals to the output line 110 and the video signal, the control signal and the audio signal of the other party to be output from the main video exchanger 40 which will be described later to the output line 110. The electronic signal is converted into an optical modulation signal and transmitted to an optical transmission path, and the optical modulation signal is converted into an electrical signal and output to the output line 120.

The main video exchanger 40 sets the video screen of each camera grouped on the optical transmission path 90 outputted from the sub-center unit 20 of the ITV system 200 to a sub set of the video conference terminal 60. A video input of the camera of the videoconferencing terminal unit 60 is performed while performing an exchange operation so as to be inputted through the optical transmission path 90 by a key feed operation of the videoconferencing terminal unit 60 and displayed on a monitor of the videoconferencing terminal unit 60. The control unit 30 is switched to output through the optical transmission path (100). Therefore, the optical video conferencing system 300 is a centralized control method connected to the main video switching unit 40 through the video conferencing terminal unit 60 and the conversion unit 50 of all subscribers.

Meanwhile, as described above, the ITVT system 200 distributes the cameras grouped into subgroups according to the process for each function, and the control method can be controlled by the control unit 30 even though the control center 30 remotely controls the cameras. Therefore, it can be seen that the distributed control method is connected to the control unit 30 through the sub-center unit 20. FIG. 2 is a conceptual diagram of a case where a comprehensive information system for production control of FIG. 1 according to the present invention is implemented in a company, where a camera is installed at a location requiring a function or a monitoring system of each process, but where the camera is installed As the image generation and control unit 10 of FIG. 1, the camera of FIG. 1 is installed to monitor operation status, facility operation accidents, and environmental conditions. Therefore, the video signal captured by the camera is optically converted and transmitted to the subcenter unit 20 through the optical cable highway, and the subcenter unit 20 converts the transmitted optical conversion video signal into an electrical video signal. The video signal of the grouped subgroups by function and the arbitrarily selected main group video signal are optically converted again and transmitted through the optical cable highway, and the operation status light described above is monitored through the monitor in the field manager's office of the factory. Enables monitoring by the keypad selection of the ITV control board in the module. The light-converted video signal transmitted from the sub center unit 20 is input to the controller 30 according to the switching of the main video exchanger 40 of FIG. 1 so that the entire process of the controller 30 is monitored. The above-mentioned camera is remotely controlled by the keypad operation of the ITV control board in the control unit 30.

As shown in FIG. 2, the control unit 30 displays the input video signal which is scanned and transmitted to the comprehensive monitor to monitor the entire operation status, and the operation status arbitrarily selected by the personnel in charge through the personnel monitor. You can watch it closely, watch it through multi-vision, or close it up on the widescreen. The above-described ITV system 200 is connected to the main video switching unit 40 of the optical video conferencing system 300 and the optical cable highway and the video conferencing terminal unit 60 to have an organic mutual relationship with the system. Information exchange is performed in the main video exchanger 40.

The video conferencing terminal unit 60 includes a video conferencing camera, a microphone, a subset, a monitor, and the like. It is installed in the maintenance department head or support department head office, work progress room, judgment room (D / R), seminar room (S / R), and public relations center, respectively, and the department is connected to the main video exchange unit 40 through an optical cable highway. By intensive control. In addition, each room can also have a countermeasure meeting by looking at the video signal of the field camera by manipulation of a subset. The dotted line in FIG. 2 is the transmission of the optical video conference, and the solid line is the ITV transmission path.

In addition, the main video exchanger 40 not only exchanges the video screens of the other parties for the optical video conference of each room, but also exchanges the audio signals at the same time. A subset of keypads provided in each room may be displayed directly on the monitor.

3 is a detailed circuit diagram of the ITV system 200 of FIG. 1 according to the present invention, in which the image generation and control unit 10 of the industrial television cameras 1a-1c and the cameras 1a-1c, which photograph each process, is used. Pan / Tilt heads 2a-2c having a motor for rotating up, down, left, right and right, and an electro-optical converter 5a-5c for converting a video signal into an optical signal. And the control data signal to control the motor of the pan / tilt heads 2a-2c to adjust the up, down, left and right rotational movements of the camera and to adjust the zoom lens of the camera. A relay unit 3a-3c, an opto-electric and an electro-optical converter 4a-4c for receiving and simultaneously transmitting control data, and a bidirectional WDM device 6a-6c for transmitting the control data. do.

Meanwhile, the sub-center unit 20 converts an optical video signal input through the optical transmission paths 7a-7c output from the image generation and control unit 10 into an electrical signal 21a-21c. And input the converted video signals to automatically scan the video signals of the subgroups and simultaneously output video signals of the selected main group to the transmission paths 201 and 202 according to the control signals of the data multiplexer 23. A sub video exchanger 22, an electro-optical converter 36 for converting the automatically scanned electrical video signal into an optical signal and outputting the optical signal to the optical transmission path 52, and a video signal of the randomly selected main group. Inputs the control data of the electro-optical converter 37 and the control unit 30 to be described later and converts and outputs the optical signal, and the bidirectional WDM device 35 for transmitting control data, and the control unit 30 to be described later. Sub control data of The control interface 32 which operates preferentially to the control data of the tab part 20 and the central processing unit (CPU) are incorporated, and various control data, namely camera 1a-1c selection control signals and cameras, are operated by operation of the keypad. The first ITV controller 29 generating the drive control signal of (1a-1c) and the priority control data of the control unit 30 by the control interface 32 are transmitted to the first ITV controller 29. At the same time, the control unit for supplying the control data transmitted from the camera (1a-1c) to the control interface circuit 32, the control data of the first ITV controller 29 and output from the control interface circuit 32 ( 30 is connected to the remote receiving circuit 33 for inputting the control data of the control unit 30, and the WDM device 6a-6c of the image generation and control unit 10 is connected to the unit 1: 1 to transmit the control data. And control data from the cameras 1a-1c into the remote receiving circuit 33. A control signal of the sub video exchanger 22 by inputting a control signal to the control data of the control unit 30 outputted from the remote receiving circuit 33 and outputting the control signal of the sub-data exchanger 22. And a data multiplexer 23 for remote control of the ITV and the cameras 1a-1c through the 24a-24c and the WDM devices 26a-26c, and a power supply circuit 25 for supplying power to various circuits. do.

In addition, the control unit 30 will be described later through the terminal 52a the automatic scanning video signal and the video signal of the randomly selected main group transmitted from the sub-center unit 20 to the optical transmission paths 52 and 53. The optical signal is inputted by the photo-electric converters 101 and 102 of FIG. 4 by inputting the terminal 52a of FIG. 4 to the terminal 53a of FIG. 4 described later through the terminal 53a. The video matrix exchanger 84 of FIG. 4 is bypassed, and the optical video signal is converted by the electro-optical converter 103 and 104, respectively, through the terminals 52b and 53b. An optical-to-electric converter (42) (43) for outputting to the terminals (52b) and (53b) of FIG. 3 and converting the optical video signal into an electrical signal; and a second ITV controller (46) having a central processing unit; To monitor the ITV camera for each main group according to the control data of the management personnel of the And a multi-vision 48, a widescreen 49, and a comprehensive monitor 51, and a remote receiving circuit of the corresponding group of the respective sub-center units 20 through the remote transmitting circuit 45. 33) is configured to transmit the control data via the electro-optical and photo-electric converter 44 and the WDM device 41 for transmitting control data. On the other hand, the control data output from the WDM device 41 is input to the terminal 54b of FIG. 4 through the terminal 54b during operation of the ITV system 200, and the control data is decoded by the decoder 96. And bypasses the main central processing unit 98, outputs the control data to the terminal 54 through the encoder 97, and the WDM device 35 of the sub-center unit 20 through the terminal 54a of FIG. ).

The dotted line in the figure shows the transmission portion of the control data, and the electro-optical and optical-electric converters 4, 24, 34, 44 and the WDM devices 6a-6c and 26a-26c in the dotted line. 35 and 41 use a bidirectional WDM transmission scheme. In the bidirectional WDM transmission scheme, as shown in FIG. 5, transmission control data is converted into a wavelength [lambda] 1 by an electro-optical converter (E / O) of electro-optical and photo-electric converters 4 and 26. The reception control data is converted into a wavelength [lambda] 2 by an opto-electric converter (O / E), and becomes an optical signal of [lambda] 1 + [lambda] 2 through a polarization splitter of a known WDM device 6 (24). Will be sent.

The operating relationship of the ITV system 200 of FIG. 3 is as follows.

The video signal output from the cameras 1a-1c of the ITV system 200 is converted into an optical signal through the electro-optical converters 5a-5c and transmitted to the sub-center unit 20.

The sub-center unit 20 converts the optical signal into an electrical signal by the photo-electric converters 21a-21c for converting the optical signal into electrical signals, and then corresponds to the cameras 1a-1c of the ITV system 200. The video signals of the subgroups, each of which is collected, are output to the output line 201 by the sub video exchanger 22, and the scanned video signals of the subgroups are output to the output line 202. The person in charge of 30 outputs the video signals of the cameras 1a-1c by the person in charge of the second ITV controller 46 and the subcenter 20 operated by the first ITV controller 29.

The video signals output to the output lines 201 and 202 are converted into optical signals by the electro-optical converters 36 and 37, respectively, and are connected to the terminals 52a (through the tube transmission paths 52 and 53). 53b) to input terminals 52a and 53b of FIG. 4 and bypass the video matrix exchanger 94 through the photo-electric converters 101 and 102, respectively, and to the electro-optical converter 103 ( 104 is output to the complexes 52b and 53b, and are converted into electrical signals by the photo-electric converters 42 and 43 of the controller 30 of FIG. The corresponding channel of 51 is outputted. On the other hand, the person in charge selection video signal outputted to the output line 202 is output to the person in charge monitor 47 through the photo-electric converter 43. On the other hand, some of the video outputs of the output lines 201 and 202 are monitored through the video switch 27 by the selection of the keypad of the first TV controller 29 so that the person in charge of the sub-center unit 20 can see them. ) In addition, since the optical video signals on the optical transmission lines 52 and 53 are once input to the video matrix switch 94 of FIG. 4, the videoconferencing subscriber can select and view them when necessary, while the ITV control data signal 30 is outputted from the second ITV controller 46, converted to an optical signal by the electro-optical converter 44 via the remote transmission circuit 45, and transmitted by the WDM device 41.

The transmitted control data is inputted to the terminal 54b of FIG. 4 via the terminal 53b, bypasses the main central processing unit 98 through the decoder 96, and the terminal through the encoder 97. Output to 54a is connected to the terminal 53a of FIG. 3, and it inputs to the sub-center part 20. FIG.

The control data transmitted from the sub-center unit 20 is divided by the WDM device 35 and converted into an electric signal by an electro-optical and photo-electric conversion of the photo-electric converter 34, and the control data is controlled. The WDM device is inputted to the data multiplexer 23 through the remote receiving circuit 33 through the interface 32 and analyzed by the control data signal through the electro-optical converters 24 a-24c of the corresponding channel. The control data signal is inputted to the relay unit 3a-3c through the photoelectric converter of the WDM device 6a-6c and the electro-optical and photo-electric converter 4a-4c of the corresponding terminal via 26a-26c). Analyzes the camera's zoom, focus, and pan / tilt up, down, left, and right signals.

In addition, when the first ITV controller 29 of the sub-center unit 20 is to be controlled, it is input to the control interface 32 through the remote transmitter 31. In this case, simultaneous control of the control unit 30 and the western center unit 20 gives priority to the control unit 30 by the control interface 32 to perform distributed control.

4 is a block diagram of a concrete circuit diagram of the optical videoconferencing system 300 according to the present invention, wherein the video conferencing terminal unit 60 is an optical video conferencing camera 61 and an upper, lower, left, right control of the camera. A pan / tilt head 62 with a built-in motor, a microphone 63, a subset 64 for remote control of all functions such as subscriber selection system adjustment by direct operation by a conference participant who performs an optical video conference, and a speaker The audio signal of the microphone 63 and the video switch 67 which is a switch of the line 72 to which the optical imaging conference camera 61 and an auxiliary camera are connected by the 65 and the monitor 66, and a manual switch. The audio mix and amplifier 68 for mixing and amplifying the signal, and the control signal transmitted from the main central processing unit 98 of the main video exchanger 40 described later to decode the power of the camera 61. Off, zoom lens, pan / tilt head 62 and all other control signals. And Saint supplying local controller 69 which is configured as an audio amplifier 71 for amplifying the other of the audio signal.

The conversion unit 50 outputs the subscriber's video signal, audio signal, and control signal output through the output lines 74, 75, and 76 of the video conferencing terminal 60, respectively. By optically modulating the 20HZ-4.5MHZ wideband video signal, the 30HZ-3.4HZ audio signal is loaded on the carrier of 6.6MHZ, and the 300HZ-3.4HZ control signal is carried on the carrier of 6MHZ. An electro-optical converter 80 for carrying out optical modulation and outputting it to one optical fiber cable 82, and the video signal and audio signal transmitted by frequency division by inputting the optical modulation output signal to the optical-electric converter 84; And demodulating a control signal to input the demodulated video signal to the video matrix exchanger 94 through the output line 86 and to input the audio signal to the audio matrix exchanger 95 through the output line 88. Via the output line 87 Decodes the control signal by inputting to the order 96, inputs it to the main CPU 98, and thereby decodes the control signal commanded by the CPU 98 to the encoder 97 to control reception. A video matrix exchanger 94 and an audio matrix exchanger are inputted through the output line 92 to the electro-optical converter 85 and controlled by a control signal on the control bus 99 by the software of the main central processing unit 98. 95, the video signal and the audio signal of the other party are exchanged to output the other video signal and the audio signal to the video output line 91 and the audio output line 93, respectively, and input to the electro-optical converter 85. Input to electro-optical converter 85.

The electro-optical converter 85 is a circuit which operates in the same manner as the electro-optical converter 80 described above, and after the signals are converted into optical signals and transmitted to the optical cable 83, the electro-optical converter ( Input to an opto-electric converter 81 which performs the same operation as 84). Accordingly, the conversion unit 50 becomes a part composed of the above-described electro-optical converters 80 and 85, the photo-electric converters 81 and 84, and the optical transmission paths 82 and 83.

On the other hand, the main video exchanger 40 is a part composed of the above-described video matrix exchange 94, audio matrix exchange 95, decoder 96, encoder 97 and main central processing unit 98. The matrix exchanger 94 has an optical video signal of the ITV camera through the terminals 52a and 53b in the optical transmission paths 52 and 53 of FIG. A videoconferencing subscriber can select and view the video signal by inputting through 102.

The operation of the optical image conference system of FIG. 4 described above is as follows. The video signal output from the camera 61 of the optical imaging conference is described above together with the audio signal and the control signal output from the microphone 63 and the subset 64 in the electro-optical converter 80 through the video switch 67. As modulated and converted into an optical signal, it is then converted by the photo-electric converter 84 into an electrical signal, and the video signal is input to the video matrix exchange 94. At the same time, the audio signal demodulated by the opto-electric converter 84 is input to the audio matrix exchanger 95 and the control signal is divided by the decoder 96 and transmitted to the main central processing unit 98. The program drives the video matrix exchange 94 and the audio matrix exchange 95 by a program to select and connect a target channel. Therefore, the video signal and the audio signal of the other party are amplified by the audio amplifier 71 through the electro-optical converter 85, the optical transmission path 83, and the optical-electric converter 81, and are listened to the speaker 65. The signal is visible to the monitor 66.

The video matrix on the optical transmission paths 52 and 53 of the ITV system is also manipulated through the opto-electric converters 101 and 102 by manipulating the subset 64 of the videoconferencing terminal unit 60. It is inputted to the switchboard 94 and exchanged (by the control signal by the control signal of the main central processing unit 98) so that the video signal can be displayed on the monitor 66 in the same manner as described above.

The video signal is also transmitted by the videoconferencing camera 61 via the electro-optical converters 103 and 104 by means of a programmed command of the central processing unit 98 by an exchange operation of the video matrix exchange 94. It may be transmitted to the control unit 30 may cause an image to appear on the monitor of the control unit 30.

As described above, the present invention not only maximizes the efficiency of corporate business by organically connecting the industrial television system and the optical video conferencing system, but also improves transmission quality by eliminating electronic obstacles by installing a remote communication network with optical fiber cables. It is easy to understand that the safety of the process and the quick response to accidents can be taken by monitoring the operation status at all times.

Claims (1)

A communication system for production control, comprising: an image generation system having an industrial television camera for monitoring an on-site situation and controlling for image generation of the camera, and converting the generated video signal into an optical signal and outputting the image signal; And a control unit 10 and outputs a video signal scanned by dividing the generated video signal into a plurality of subgroups and a video signal by a random selection of a person in charge as an optical video signal and controlling the industrial television camera. The sub-center unit 20 of the distributed control method for generating and outputting to the generation and control unit 10 and selecting and viewing the video signal, and inputting the scanned video signal and the video signal selected by the person in charge Monitors video signals as images and monitors the video signals of selected cameras by the person in charge The video conferencing terminal unit 60 includes a control unit 30, an optical video camera, a microphone, a subset of a speaker and a monitor, and transmits and receives a video signal, an audio signal, and a control signal. A converter 50 for modulating and demodulating and transmitting a signal and a control signal into an optical signal, and a main video exchanger 40 for exchanging a video signal, an audio signal, and the selected video signal of a counterpart channel to the control signal. Comprehensive information communication system for production control.

Images