KR102363605B1 - Method for setting a identification mark of a individual display device in a multi display system - Google Patents

Abstract

The present invention relates to a method for setting an individual video device identification code in a multi-image system. In the present invention, the process of automatically setting/applying an identification code in a signal transmission system of a video control device and a module block of each individual video device is performed. After additional components (eg, master controller, sub-controller, light-emitting sensor, light-receiving sensor, etc.) are installed for It induces the coordinate setting step and the identification code setting step to proceed automatically for each individual video device. , by making it possible to simply and automatically set/assign an identification code corresponding to each individual imaging device without complicated manual work, in the end, various problems (e.g., loss of manpower) caused by the manual installation procedure of identification codes on the side of individual imaging devices problem, cost loss problem, time loss problem, control signal wiring limitation problem, etc.) can be guided to effectively escape.

Description

Method for setting a identification mark of a individual display device in a multi display system

The present invention relates to a method for automatically setting an identification code corresponding to each individual imaging device constituting a multiple imaging system, and more particularly, to a signal transmission system of an image control device and a module block of each individual imaging device, After additionally installing the components (eg, master controller, sub-controller, light emitting sensor, light receiving sensor, etc.) for automatically proceeding with the setting/granting procedure of the identification code, based on these components, the X coordinate initial setting step, Inducing the initial Y coordinate setting step, X coordinate setting step, Y coordinate setting step, identification code setting step, etc. to proceed automatically for each individual video device. Even under a situation where the device arrangement is changing, it is possible to simply and automatically set/assign the identification code corresponding to each individual imaging device without complicated manual work. A method of setting individual video equipment identification codes for multiple video systems that can guide effectively avoiding various problems caused by the installation procedure (e.g., manpower loss, cost loss, time loss, control signal wiring limitation, etc.) is about

Recently, with the rapid development of electrical/electronic related technologies, a multi-image system capable of displaying various types of images in various formats (eg, panoramic format, etc.) is showing

For example, Korean Patent Registration No. 10-904499 (Name: Multi-image display apparatus, panoramic image display apparatus, and multi-image display method using the same) (announced on June 24, 2009), Korean Patent Publication No. 10-2011-85332 No. (Name: Multi-Display Device, Electronic Device, and Control Method of Multi-Display Device) (published on July 27, 2011), Korean Patent Laid-Open No. 10-2011-85334 (Name: Multi-Display Device and Control Method of Multi-Display Device) ), published on July 27, 2011) and Korean Patent Application Laid-Open No. 10-2014-46319 (Name: Multi-display device and multi-display method) (published on April 18, 2014), an example of a multi-image system according to the prior art is disclosed. It is disclosed in more detail.

Meanwhile, under this conventional system, as shown in FIG. 1 , the multiple imaging system 10 includes a plurality of individual imaging devices 11 and various data (eg, control data) using the plurality of individual imaging devices 11 . , image data, image enlargement data, image segmentation data, etc.), the image control device 12 that controls the image output status of the individual video device 11 is systematically combined.

At this time, since the multiple imaging system 10 is composed of a plurality of individual imaging devices 11 , each individual imaging device 11 has an identification code SI (eg, 1,2,3,4,5,...) must be set/given in advance.

Of course, in the state in which the identification code SI corresponding to the individual imaging device 11 is preset/given to each individual imaging device 11 in this way, the image control device 12 side uses the identification code SI based on the Multiple imaging systems ( 10) side will support you so that you can proceed with the multi-image display procedure assigned to you normally without any problems.

Under this conventional system, when operating the multiple imaging system 10 , for example, repair/replacement of individual imaging devices 11, replacement/relocation of signal connection cables, change of image expression mode of multiple imaging systems 10, etc. Several factors such as design change of the image system occur, and in this case, the image system operator side newly adds individual image equipment 11 or replaces/excludes individual image equipment 11 that have already been placed on individual images. There is no choice but to take various measures to change the arrangement of devices.

Of course, even after the arrangement of the individual imaging devices 11 is changed, the individual imaging devices 11 must be distinguished from each other on the image control device 12 side. After the shape transformation is completed, it is inevitable to proceed with the procedure of assigning a corresponding identification code (SI) to the corresponding individual imaging device 11 .

However, in the conventional case, since there is no means for automatically assigning an identification code SI to each individual imaging device 11 constituting the multiple imaging system 10, the arrangement of the individual imaging devices 11 described above is not available. In the aspect of shape transformation, the imaging system operator inevitably complicates the procedure of manually assigning a corresponding identification code (SI) to each of the individual imaging devices 11 by consuming a large number of manpower and cost, and furthermore, a long time. In the end, there is no choice but to bear the serious manpower loss problem, cost loss problem, and time loss problem.

In particular, in the phase of modification of the arrangement of the conventional individual video equipment, the operator of the video system has to widely consider the manual installation procedure of identification codes and the length of the signal connection cable, so it is inevitably subject to many restrictions on the wiring of control signals. , in the end, even the serious problems that come with it have no choice but to bear.

Domestic Registration Patent No. 10-904499 (Name: Multi-image display device, panoramic image display device, and multi-image display method using the same) (announced on June 24, 2009) Korean Patent Laid-Open Patent No. 10-2011-85332 (Title: Multi-display device, electronic device, and control method of multi-display device) (published on July 27, 2011) Korean Patent Laid-Open Patent No. 10-2011-85334 (Title: Multi-display device and control method of multi-display device) published on July 27, 2011) Korean Patent Publication No. 10-2014-46319 (Title: Multi-display device and multi-display method) (published on April 18, 2014)

Accordingly, an object of the present invention is to configure the components (e.g., master controller, sub-controller, light emitting After additionally installing sensors, light receiving sensors, etc.), based on these components, If the device-side X-coordinate is set to 0 and the luminous sensor of the left neighbor is not detected, the X-coordinate of the individual imaging device is set to 1, and if the luminous sensor of the right neighbor is not detected, the X-coordinate of the individual imaging device is set to the maximum. X coordinate initial setting step of setting to a value>, <When the light emitting sensor is turned on and the upper neighboring light emitting sensor is detected, the Y coordinate of the individual imaging device is set to 0, and the upper neighboring light emitting sensor detects it If not, the Y coordinate of the individual imaging device is set to 1, and if the luminescence sensor of the lower neighbor is not detected, the Y coordinate initial setting step of setting the Y coordinate of the individual imaging device to the maximum value>, <X of the individual imaging device It is determined whether the coordinates are set to 0 or the maximum value, and if the X-coordinate of the individual imaging device is set to 0 or the maximum value, the light emitting sensor of the left neighbor is detected with the light emitting sensor turned on, If the corresponding light emitting sensor is not detected, the X-coordinate setting that resets the X-coordinate of the individual video device, which was set to 0 or the maximum value, to 1+N (N=1,2,3...) under the control of the master controller Step>, <It is determined whether the Y coordinate of the individual imaging device is set to 0 or the maximum value, and if the Y coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, If the light emitting sensor of the upper neighbor is detected and the corresponding light emitting sensor is not detected, the Y coordinate of the individual video device, which was set to 0 or the maximum value, is set to 1+N (N=1,2,3... ‥) to reset the Y coordinate setting step>. <It is determined whether the setting of the X and Y coordinates of the individual video device is complete, and if it is confirmed that the X and Y coordinates of the individual video device are set, under the control of the master controller, the X and Y coordinates that have been set Systematically proceed with the identification code setting step> of converting the coordinates into a pre-set identification code, and through this, the image system operator can change the arrangement of individual imaging devices, even under a situation where the configuration of individual imaging devices is changed. By making it possible to simply and automatically set/assign an identification code corresponding to each individual imaging device without any work, in the end, various problems caused by the manual installation procedure of the identification code on the individual imaging device side (e.g., loss of manpower, cost) It is to guide you to effectively escape from the loss problem, time loss problem, control signal wiring limitation problem, etc.).

Other objects of the present invention will become more apparent from the following detailed description and accompanying drawings.

In order to achieve the above object, in the present invention, under the control of the master controller, sub-controllers installed in a plurality of individual imaging devices constituting a multi-image system, respectively, are installed on the upper, lower, left, and right of the individual video devices. When the light emitting sensor is turned on and the light emitting sensor of the left neighbor is detected, the X coordinate of the individual imaging device is set to 0. If the light emitting sensor of the left neighbor is not detected, the X coordinate of the individual imaging device is set to 1. In addition, when the light emitting sensor of the right neighbor is not detected, an X-coordinate initial setting step of setting the X-coordinate of each imaging device to a preset maximum value; When the light emitting sensor is turned on and the light emitting sensor of the upper neighbor is detected, the Y coordinate of each imaging device is set to 0. If the light emitting sensor of the upper neighbor is not detected, the Y coordinate of the individual imaging device is set to 1. an initial Y-coordinate setting step of setting the Y-coordinate of each imaging device to a preset maximum value when the light emitting sensor of the lower neighbor is not detected; It is determined whether the X-coordinate of the individual imaging device is set to 0 or the maximum value, and if the X-coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, the left neighbor When the light emitting sensor is detected and the corresponding light emitting sensor is not detected, the X-coordinate of the individual imaging device set to 0 or the maximum value is set to 1+N (N=1,2,3...) according to the control of the master controller an X-coordinate setting step of resetting to ; It is determined whether the Y coordinate of the individual imaging device is set to 0 or the maximum value, and when the Y coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, When the light emitting sensor is detected and the corresponding light emitting sensor is not detected, the Y coordinate of the individual video device, which was set to 0 or the maximum value, is 1+N (N=1,2,3...) Y coordinate setting step of resetting to ; It is determined whether the setting of the X and Y coordinates of the individual video devices has been completed, and when it is confirmed that the X and Y coordinates of the individual video devices are set, under the control of the master controller, the settings of the individual video devices that have been set Disclosed is a method for setting an identification code for an individual imaging device in a multiple imaging system, comprising the step of setting an identification code for converting the X coordinate and the Y coordinate into a preset identification code.

In the present invention, components (eg, master controller, sub-controller, light-emitting sensor, light-receiving sensor) for automatically performing the procedure of setting/providing identification codes in the signal transmission system of the video control device and the module block of each individual video device etc.), and based on these components, <When the light emitting sensor installed at the top, bottom, left and right of each imaging device is turned on and the luminescence sensor of the left neighbor is detected, the X coordinate of the individual imaging device is set to 0, and if the luminescence sensor of the left neighbor is not detected, the X coordinate of the individual imaging device is set to 1, and if the luminescence sensor of the right neighbor is not detected, the X coordinate of the individual imaging device is set to the maximum value. X-coordinate initial setting step>, <When the light emitting sensor is turned on and the upper neighbor's light emitting sensor is detected, the Y coordinate of the individual imaging device is set to 0. If the upper neighboring light emitting sensor is not detected, the individual image Y coordinate initial setting step of setting the Y coordinate of the device to 1, and setting the Y coordinate of the individual imaging device to the maximum value if the luminescent sensor of the lower neighbor is not detected>, <The X coordinate of the individual imaging device is 0 or It is determined whether it is set to the maximum value, and if the X-coordinate of the individual imaging device is set to 0 or the maximum value, in the state that the light emitting sensor is turned on, the light emitting sensor of the left neighbor is detected, and the corresponding light emitting sensor is If not detected, under the control of the master controller, the X coordinate setting step of resetting the X coordinate of the individual video device, which was set to 0 or the maximum value, to 1+N (N=1,2,3...)>, < It is determined whether the Y-coordinate of the individual imaging device is set to 0 or the maximum value, and if the Y-coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, the light emission of the upper neighbor When a sensor is detected and the corresponding light emitting sensor is not detected, the Y coordinate of the individual imaging device, which was set to 0 or the maximum value, is reset to 1+N (N=1,2,3…) under the control of the master controller. Y coordinate setting step to set>. <It is determined whether the setting of the X and Y coordinates of the individual video device is complete, and if it is confirmed that the X and Y coordinates of the individual video device are set, under the control of the master controller, the X and Y coordinates that have been set Since the identification code setting step> of converting the coordinates into a preset identification code is systematically carried out, under the implementation environment of the present invention, the image system operator side is in a situation where the arrangement of individual video devices is transformed. Also, without complicated manual work, it is possible to simply and automatically set/assign an identification code corresponding to each individual imaging device. As a result, various problems (e.g., manpower loss problem, cost loss problem, time loss problem, control signal wiring limitation problem, etc.) can be effectively avoided.

1 is an exemplary diagram conceptually illustrating a multi-image system according to the prior art.
2 is an exemplary diagram conceptually illustrating a multi-image system employing the present invention.
3 to 18 are exemplary views conceptually illustrating a procedure for setting an individual video device identification code according to the present invention.
19 is an exemplary diagram conceptually illustrating a multi-image system employing another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a method for setting an individual imaging device identification code in a multi-video system according to the present invention will be described in more detail as follows.

As shown in FIG. 2 , the multiple imaging system 100 employing the present invention includes a plurality of individual imaging devices 101 and various data (eg, control data, image data) using the plurality of individual imaging devices 101 . , image enlargement data, image segmentation data, etc.), the image control device 102 that controls the image output status of the individual video device 101 takes a systematically combined configuration.

At this time, since the multi-image system 100 is composed of a plurality of individual imaging devices 101, each individual imaging device 101 has an identification code SI (eg, 1,2,3,4,5,...) (refer to Fig. 18) must be set/given in advance.

Of course, in the state in which the identification code SI corresponding to the individual imaging device 101 is preset/given to each individual imaging device 101 in this way, the image controller 102 side uses the identification code SI based on the identification code SI. By transmitting various data (eg, control data, image data, image enlargement data, image segmentation data, etc.) corresponding to each individual imaging device 101 while distinguishing each individual imaging device 101 from each other, a multiple imaging system ( 100) side, without any problems, will support the multi-image display procedure assigned to them normally.

Naturally, even under the adoption system of the present invention, if the multiple imaging system 100 is operated, for example, repair/replacement of individual imaging devices 101, replacement/relocation of signal connection cables, and Several factors for changing the design of the image system, such as changing the image expression form, occur. In this case, the image system operator may newly add individual image equipment 101 or replace/exclude the individual image equipment 101 that has already been placed. There is no choice but to take various measures to modify the arrangement of individual imaging devices, such as

Of course, even after the arrangement of the individual imaging devices 101 is modified, the individual imaging devices 101 must be distinguished from each other on the image control device 102 side. After the shape transformation is completed, it is inevitable to proceed with a procedure for assigning a corresponding identification code (SI) to the corresponding individual imaging device 101 .

As described above, in the conventional case, the image system operator side inevitably spends a large number of manpower, a lot of money, and a long time in the phase of changing the arrangement of the individual imaging devices 101 on the side of the imaging system operator. Although the procedure for manually assigning the corresponding identification code (SI) to the image was complicated, in this case, the video system operator had a serious problem of manpower loss, cost loss, and time loss, as well as a control signal wiring limitation problem. I had no choice but to bear it.

Under such a sensitive situation, as shown in FIG. 2, in the present invention, in the signal transmission system of the image control device 102 and the module block of each individual imaging device 101, the identification code (SI) on the side of the individual imaging device 101 ) (see FIG. 18) after additionally installing components for automatically proceeding with the setting/granting procedure, for example, the master controller 103, the sub-controller 107, the sensor tool 104, and the like, and based on these, <Procedures for setting/applying an identification code (SI) targeting individual imaging devices 101> automatically proceeds will be taken.

In this case, on the sensor tool 104 side, the master controller 103 and the sub-controller ( 107), by turning on or off the light emitting sensor 105, the <automatic identification code assignment/setting procedure for the individual imaging device 101 by the sub-controller 107> is normally performed without any problems. It will play a role in helping you progress.

In addition, the master controller 103 communicates with <video control device 102> and <sub-controller 107 installed in each individual video device 101>, and various control messages (eg, initial X coordinates). Setting control message, Y coordinate initial setting control message, X coordinate setting control message, Y coordinate setting control message, identification code conversion/setting control message, etc.) , the sub-controller 107 side, while checking the light emission state of the neighboring light emitting sensors 105 arranged next to each other according to the control message setting details, the X coordinate, the Y coordinate, and the It plays a role of controlling so that an identification code, etc. can be set automatically.

Further, the sub-controller 107 side communicates with the master controller 103, the light-emitting sensor 105, the light-receiving sensor 106, etc. while installed in each individual imaging device 101, and According to the transmitted various control messages (e.g., X coordinate initial setting control message, Y coordinate initial setting control message, X coordinate setting control message, Y coordinate setting control message, identification code conversion/setting control message, etc.) After the light emitting sensor 105 of the individual imaging device 101 in the presence of an individual image device 101 emits/exits, the light emission state of the neighboring light emitting sensor 105 (eg, the upper neighboring light emitting sensor, the left neighboring light emitting sensor, etc.) is measured by the light receiving sensor 106 . While checking through, according to the check result, the individual imaging device 101 side X coordinate initial setting procedure, the individual imaging device 101 side Y coordinate initial setting procedure, the individual imaging device 101 side X coordinate setting procedure, and individual image The device 101 side Y coordinate setting procedure and the individual video device 101 side identification code conversion/setting procedure are automatically performed sequentially.

Hereinafter, a method for setting an individual imaging device identification code unique to the present invention based on each component having the above-described configuration will be described in more detail.

First, when the transformation of the arrangement of the individual imaging devices 101 is completed, the master controller 103 communicates with the image control device 102 to confirm that the transformation of the arrangement of the individual imaging devices 101 is completed, and then Under the control of the control device 102, a series of information generation routines are performed, and various control messages (eg, X coordinate initial setting control message, Y coordinate initial setting control message, X coordinate setting control message, Y coordinate setting control message, A process of generating an identification code conversion/setting control message, etc.) and transmitting various generated control messages to the sub-controller 107 installed in each individual video device 101 is performed (refer to FIG. 2 ).

Under the transmission situation of these various control messages (eg, X coordinate initial setting control message, Y coordinate initial setting control message, X coordinate setting control message, Y coordinate setting control message, identification code conversion/setting control message, etc.), first, each The sub-controller 107 installed in the individual video device 101 receives/receives the X-coordinate initial setting control message from the master controller 103, and then installs it on the top, bottom, left, and right of the individual video device 101 accordingly. When the light emitting sensor 105 is turned on and the light emitting sensor 105 of the left neighbor is detected, the X coordinate of the individual imaging device 101 is set to 0, and the light emitting sensor 105 of the left neighbor is set to 0. If is not detected, the X coordinate of the individual imaging device 101 is set to 1, and if the light emitting sensor 105 of the right neighbor is not detected, the X coordinate of the individual imaging device 101 is set to the preset maximum value ( For example, the X coordinate initial setting step of setting to 255) proceeds.

Under this X coordinate initial setting step, as shown in Fig. 3 (for convenience, in Figs. 3 to 18, the light receiving sensor is omitted) (In addition, in Figs. 3 to 18, black The color indicates the light emission state of the light emitting sensor 105, and the white color indicates the extinction state of the light emission sensor 105), for example, on the side of the sub-controller 107a belonging to the individual imaging device 101a, the individual imaging device ( In the state in which the light emitting sensors installed at the top, bottom, left, and right of 101a) are turned on, the light emitting sensor of the left neighbor is detected and the corresponding light emitting sensor is not illuminated, and the X of the individual imaging device 101a belonging to the user is The coordinates are set to 1 (for reference, since no other individual imaging devices are disposed in the left neighbor of the individual imaging device 101a, the sub-controller 107a determines that the light emitting sensor of the left neighbor is in the extinction state. being).

In addition, under the X coordinate initial setting step, as shown in FIG. 3 , for example, on the side of the sub-controller 107e belonging to the individual imaging device 101e, the In a state in which the light emitting sensor is turned on, the light emitting sensor 105b of the left neighbor is detected, the light emitting sensor 105b is checked, and the X coordinate of the individual imaging device 101e to which the user belongs is set to 0. will set

In addition, under the X coordinate initial setting step, as shown in FIG. 3 , for example, on the side of the sub-controller 107j belonging to the individual imaging device 101j, the With the light emitting sensor turned on, it detects the light emitting sensor 105j of the left neighbor, confirms that the light emitting sensor 105j is emitting light, and sets the X coordinate of the individual imaging device 101j to 0 will set

Furthermore, under the X coordinate initial setting step, as shown in FIG. 3 , for example, on the side of the sub-controller 107k belonging to the individual imaging device 101k, it was installed on the top, bottom, left and right of the individual imaging device 101k. In a state in which the light emitting sensor is turned on, the light emitting sensor of the right neighbor is detected, the corresponding light emitting sensor is not illuminated, and the X coordinate of the individual imaging device 101k to which the user belongs is the maximum value (eg, 255). (For reference, since no other individual imaging devices are disposed on the right side of the individual imaging device 101k, the sub-controller 107k determines that the light emitting sensor on the right side is in the extinction state) ( Also, in this case, the light emission state of the light emitting sensor 105m disposed on the left side is ignored).

On the other hand, under the condition that the X-coordinate initial setting procedure by the X-coordinate initial setting control message is completed, the sub-controller 107 installed in each individual video device 101 receives/receives the Y-coordinate initial setting control message. After that, when the light emitting sensor 105 installed in the upper, lower, left and right of the individual imaging device 101 is turned on and the light emitting sensor 105 of the upper neighbor is detected, the individual imaging device 101 If the Y-coordinate of is set to 0 and the light-emitting sensor 105 of the upper neighbor is not detected, the Y-coordinate of the individual imaging device 101 is set to 1, and if the light-emitting sensor 105 of the lower neighbor is not detected, An initial Y coordinate setting step of setting the Y coordinate of the individual imaging device 101 to a preset maximum value (eg, 255) is performed.

Under this Y-coordinate initial setting step, as shown in FIG. 4 , for example, on the side of the sub-controller 107d belonging to the individual imaging device 101d, the light emitting sensors installed at the top, bottom, left and right sides of the individual imaging device 101d. is turned on, it detects the light emitting sensor of the upper neighbor, confirms that the light emitting sensor is not emitting light, and sets the Y coordinate of the individual imaging device 101d to which it belongs (for reference, Since no other individual imaging devices are disposed in the upper neighborhood of the individual imaging device 101d, the sub-controller 107d determines that the light emitting sensor of the upper neighbor is in the extinction state).

In addition, under the Y coordinate initial setting step, as shown in FIG. 4 , for example, on the side of the sub-controller 107i belonging to the individual imaging device 101i, the With the light emitting sensor turned on, it detects the light emitting sensor 105k of the upper neighbor, confirms that the light emitting sensor 105k is emitting light, and sets the Y coordinate of the individual imaging device 101i to 0. will set

In addition, as shown in FIG. 4 under the Y coordinate initial setting step, for example, on the side of the sub-controller 107b belonging to the individual imaging device 101b, the With the light emitting sensor turned on, it detects the light emitting sensor 105d of the upper neighbor, confirms that the light emitting sensor 105d is emitting light, and sets the Y coordinate of the individual imaging device 101b to 0. will set

Furthermore, under the Y coordinate initial setting step, as shown in FIG. 4 , for example, on the side of the sub-controller 107f belonging to the individual imaging device 101f, the With the light emitting sensor turned on, it detects the light emitting sensor of the lower neighbor, confirms that the light emitting sensor is not emitting light, and sets the X coordinate of the individual imaging device 101f to the maximum value (eg, 255) (For reference, since no other individual imaging devices are disposed in the lower neighbor of the individual imaging device 101f, the sub-controller 107f does not detect the light emitting sensor of the lower neighbor, and the corresponding luminescence sensor It is determined that the light is in the extinction state) (in addition, in this case, the light emission state of the light emitting sensor 105g disposed on the upper side is ignored).

On the other hand, the above-described X coordinate initial setting step (refer to FIG. 3) and Y coordinate initial setting step (refer to FIG. 4) form each column (R1, R2, R3, R4) and row (L1, L2, L3, L4) When the process for each individual imaging device 101 is completed, the sub-controller 107 installed in each individual imaging device 101 receives/receives the X-coordinate setting control message from the master controller 103 side, The corresponding X-coordinate setting step is followed.

First, as the start of the X-coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 determines whether the X-coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. , When the X-coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the X coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value. If it is not set to 0 or the maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Under this procedure, as shown in FIG. 5 , the sub-controller 107c installed in the individual imaging device 101c confirms that the X-coordinate of the individual imaging device 101c to which it belongs is set to 1, and then emits light. A procedure of turning off (extinguishing) the sensor 105 is performed, and the sub-controller 107h installed in the individual imaging device 101h sets the X coordinate of the individual imaging device 101h to 0. After confirming that the light emitting sensors (105k, 105m) are turned on (lighting them), the sub-controller (107m) installed in the individual imaging device (101m) also has its own individual image. After confirming that the X-coordinate of the device 101m is set to the maximum value (eg, 255), a procedure of turning on the light emitting sensor 105 (lighting the point) is performed.

In this way, under a situation in which the light emitting sensor 105 of the individual imaging device 101 in which the X-coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 6, the individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) The procedure of resetting the X-coordinate to 1+N (N=1,2,3...), which had been set to 0 or the maximum value under the control of If is previously set to the maximum value (eg, 255), the procedure of notifying the master controller 103 that the X-coordinate setting for the individual imaging device 101 of the column (eg, R2) to which it belongs is completed> etc will proceed.

Under this procedure, for example, the sub-controller 107d belonging to the individual imaging device 101d turns on the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101d, and the left neighbor emits light. By detecting the sensor 105a, it is confirmed that the light emitting sensor 105a is turned off, and the X-coordinate (refer to FIG. 5) of the individual imaging device 101b to which the person belongs, which was previously set to 0, is set to 2 (ie, 1). +1) is reset (refer to FIG. 6).

As another example, the sub-controller 107e belonging to the individual imaging device 101e also turns on the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101e, and the light emitting sensor 105b of the left neighbor is turned on. ), it is confirmed that the corresponding light emitting sensor 105a is turned off, and the X-coordinate (refer to FIG. 5) of the individual imaging device 101e belonging to the person who has been previously set to 0 is set to 2 (ie, 1+1). to reset (see FIG. 6).

As another example, the sub-controller 107f belonging to the individual imaging device 101f also turns on the luminescence sensors installed on the top, bottom, left, and right of the individual imaging device 101f, and turns on the luminescence sensor ( 105c) is detected, and it is confirmed that the corresponding light emitting sensor 105c is turned off, and the X-coordinate (refer to FIG. 5) of the individual imaging device 101f belonging to the person who has been previously set to 0 is set to 2 (ie, 1+1). ) to reset (see FIG. 6).

At this time, the sub-controller 107f belonging to the individual imaging device 101f checks that the Y-coordinate of the individual imaging device 101f to which it belongs is preset to the maximum value (eg, 255), For example, the procedure of notifying the master controller 103 that the X-coordinate setting of the individual imaging device 101 of R2 has been completed is performed. As a result, the master controller 103 sets a new X-coordinate without any difficulty. By transmitting the control message to the sub-controller 107 side, it is possible to complete the X-coordinate setting for the individual imaging device 101 belonging to the current row R2, and the individual image belonging to the next row (eg, R3). It is possible to start anew setting of the X coordinate for the device 101 .

On the other hand, when the X-coordinate setting for the individual imaging devices 101 in the row R2 is completed, the sub-controller 107 installed in each individual imaging device 101 receives a new one from the master controller 103 side. After receiving/receiving the X-coordinate setting control message, the corresponding X-coordinate setting step is followed.

Even at this time, as a start of a new X coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 checks whether the X coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. If it is determined and the X coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the X coordinate of the individual imaging device 101 to which the person belongs If the coordinates are not set to 0 or a maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Even under this procedure, as shown in FIG. 7 , the sub-controller 107e installed in the individual imaging device 101e checks that the X-coordinate of the individual imaging device 101e to which it belongs is set to 2, A procedure of turning off (extinguishing) the light emitting sensor 105i is performed, and on the sub-controller 107h installed in the individual imaging device 101h, the X coordinate of the individual imaging device 101h to which it belongs is set to 0. After confirming that the settings are set, the procedure of turning on the light emitting sensors (105k, 105m) (lighting them) is carried out, and the sub-controller (107m) installed in the individual imaging device (101m) also has its own individual After confirming that the X-coordinate of the imaging device 101m is set to the maximum value (eg, 255), a procedure of turning on the light emitting sensor 105 (lighting the point) is performed.

In this way, under the condition that the light emitting sensor 105 of the individual imaging device 101 in which the X coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 8, the individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) The procedure for resetting the X-coordinate to 1+N (N=2,3...), which had been set to 0 or the maximum value under the control of If it is preset to a value (eg, 255), the procedure of notifying the master controller 103 that the X-coordinate setting for the individual video device 101 of the column (eg, R3) to which it belongs is completed> will proceed

Even under this procedure, for example, on the side of the sub-controller 107h belonging to the individual imaging device 101h, with the light emitting sensors installed on the top, bottom, left, and right of the individual imaging device 101h turned on, the left neighbor Detects the light emitting sensor 105h, confirms that the light emitting sensor 105h is turned off, and sets the X coordinate (refer to FIG. 7) of the individual imaging device 101b to 3 (that is, 1+2) is reset (refer to FIG. 8).

As another example, the sub-controller 107i belonging to the individual imaging device 101i also turns on the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101i, and the light emitting sensor 105i of the left neighbor is turned on. ), it is confirmed that the corresponding light emitting sensor 105i is turned off, and the X-coordinate (refer to FIG. 7) of the individual imaging device 101i belonging to the person who was previously set to 0 is 3 (ie, 1+2) is reset to (see FIG. 8).

As another example, the sub-controller 107j belonging to the individual imaging device 101j also turns on the luminescence sensors installed on the top, bottom, left, and right of the individual imaging device 101j, while turning on the luminescence sensor ( 105j) is detected, it is confirmed that the corresponding light emitting sensor 105j is turned off, and the X-coordinate (refer to FIG. 7) of the individual imaging device 101j belonging to the person who has been previously set to 0 is 3 (ie, 1+2). ) to reset (see FIG. 8).

At this time, the sub-controller 107j belonging to the individual imaging device 101j checks that the Y-coordinate of the individual imaging device 101j to which it belongs is preset to the maximum value (eg, 255), For example, the procedure of notifying the master controller 103 that the X-coordinate setting of the individual imaging device 101 of R3 has been completed is carried out. As a result, the master controller 103 sets a new X-coordinate without any difficulty. By transmitting the control message to the sub-controller 107 side, it is possible to complete the X-coordinate setting for the individual imaging device 101 belonging to the current row R3, and the individual image belonging to the next row (eg, R4). It is possible to start anew setting of the X coordinate for the device 101 .

On the other hand, when the X-coordinate setting for the individual imaging devices 101 belonging to the column R3 is completed, the sub-controller 107 installed in each individual imaging device 101 receives a new one from the master controller 103 side. After receiving/receiving the X-coordinate setting control message, the corresponding X-coordinate setting step is followed.

Even at this time, as a start of a new X coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 checks whether the X coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. If it is determined and the X coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the X coordinate of the individual imaging device 101 to which the person belongs If the coordinates are not set to 0 or a maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Even under this procedure, as shown in FIG. 9 , the sub-controller 107i installed in the individual imaging device 101i confirms that the X coordinate of the individual imaging device 101i to which it belongs is set to 3, A procedure of turning off (extinguishing) the light emitting sensor 105n is carried out, and on the side of the sub-controller 107k installed in the individual imaging device 101k, the X coordinate of the individual imaging device 101k to which it belongs is the maximum value. After confirming that it is set to (for example, 255), the procedure of turning on the light emitting sensor 105 (lighting it) proceeds, and the sub-controller 107m installed in the individual imaging device 101m also , after confirming that the X-coordinate of the individual imaging device 101m to which the user belongs is set to the maximum value (eg, 255), the procedure of turning on the light emitting sensor 105 (lighting it) proceeds.

In this way, under a situation in which the light emitting sensor 105 of the individual imaging device 101 in which the X-coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 10, the individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) The procedure of resetting the X coordinate of the individual imaging device 101, which was set to 0 or the maximum value, to 1+N (N=2,3…) under the control of 101), if both the X and Y coordinates are preset to the maximum value (eg, 255), the procedure of notifying the master controller 103 that the coordinate value reset by the user is the end value of the X coordinate>, etc. will proceed with

Even under this procedure, for example, on the side of the sub-controller 107k belonging to the individual imaging device 101k, with the light emitting sensors installed on the top, bottom, left, and right of the individual imaging device 101h turned on, the left neighbor Detects the light emitting sensor 105m, confirms that the light emitting sensor 105m is turned off, and the X-coordinate of the individual imaging device 101k to which the person who has been preset to the maximum value (eg, 255) belongs (refer to FIG. 9 ) ) is reset to 4 (ie, 1+3) (see FIG. 10).

As another example, the sub-controller 107m belonging to the individual imaging device 101m also turns on the luminescent sensors installed on the top, bottom, left, and right of the individual imaging device 101m, and the light emitting sensor 105o of the left neighbor is turned on. ( That is, it is reset to 1+3) (refer to FIG. 10).

At this time, on the side of the sub-controller 107m belonging to the individual imaging device 101m, as shown in FIG. 9, before the reset procedure, the X coordinate of the individual imaging device 101m to which it belongs is the maximum value (eg, 255). ), and after confirming that the Y coordinate of the individual imaging device 101j is also preset to the maximum value (eg, 255), the coordinate value (ie, 4) reset by the user is the X coordinate. A procedure of notifying the master controller 103 that it is the end value of by transmitting to the sub-controller 107, the X coordinate setting for the individual imaging devices 101 belonging to all columns R1, R2, R3, R4 can be finalized, and each row (eg, L1) , L2, L3, L4), it is possible to start a new Y coordinate setting for the individual imaging device 101.

On the other hand, the above-described X coordinate initial setting step (refer to FIG. 3) and Y coordinate initial setting step (refer to FIG. 4), and the X coordinate setting step (refer to FIGS. 5 to 10) are performed in each column (R1, R2, R3, R4) and each individual imaging device 101 constituting the rows L1, L2, L3, and L4 are completed, the sub-controller 107 installed in each individual imaging device 101 side of the master controller 103 ), after receiving/receiving the Y-coordinate setting control message from the side, the corresponding Y-coordinate setting step is followed.

First, as the start of the Y coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 determines whether the Y coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. , When the Y coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the Y coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value. If it is not set to 0 or the maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Under this procedure, as shown in FIG. 11 , the sub-controller 107d installed in the individual imaging device 101d confirms that the Y coordinate of the individual imaging device 101d to which it belongs is set to 1, and then emits light. A procedure of turning off (extinguishing) the sensor 105 is performed, and on the sub-controller 107b installed in the individual imaging device 101b, the Y coordinate of the individual imaging device 101b to which it belongs is set to 0. After confirming that the luminescence sensor 105b is turned on (lighting), the sub-controller 107m installed in the individual imaging device 101m also has its own individual imaging device ( After confirming that the Y-coordinate of 101m) is set to the maximum value (eg, 255), a procedure of turning on the light emitting sensor 105 (lighting the point) is performed.

In this way, under a situation in which the light emitting sensor 105 of the individual imaging device 101 in which the Y-coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 12, the corresponding individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) Procedure for resetting the Y coordinate of the individual imaging device 101 to 1+N (N=1,2,3...), which was set to 0 or the maximum value under the control of If the X-coordinate of the device 101 is previously set to the end value of the X-coordinate (eg, 4), the master indicates that the Y-coordinate setting for the individual imaging device 101 in the row (eg, L2) to which it belongs is completed. Procedure for notifying the controller 103 side> and the like.

Under this procedure, for example, on the side of the sub-controller 107b belonging to the individual imaging device 101b, the light emission of the upper neighboring Detects the sensor 105d, confirms that the light emitting sensor 105d is turned off, and sets the Y coordinate (refer to FIG. 11) of the individual imaging device 101d to 2 (ie, 1), which has been previously set to 0. +1) is reset (refer to FIG. 12).

As another example, the sub-controller 107i belonging to the individual imaging device 101i also turns on the luminescent sensors installed at the top, bottom, left, and right of the individual imaging device 101i, and the upper neighboring luminescence sensor 105k ), it is confirmed that the light emitting sensor 105k is turned off, and the Y-coordinate (refer to FIG. 11) of the individual imaging device 101i belonging to the person who has been previously set to 0 is set to 2 (ie, 1+1). to reset (see FIG. 12).

As another example, the sub-controller 107n belonging to the individual imaging device 101n also turns on the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101n. 105p), it is confirmed that the corresponding light emitting sensor 105p is turned off, and the Y-coordinate (refer to FIG. 11) of the individual imaging device 101n belonging to the person who has been previously set to 0 is set to 2 (ie, 1+1). ) to reset (see FIG. 12).

At this time, the sub-controller 107n belonging to the individual imaging device 101n checks that the X-coordinate of the individual imaging device 101n to which it belongs is preset to the end value of the X-coordinate (eg, 4). A procedure of notifying the master controller 103 that the Y-coordinate setting for the individual video device 101 in the row (eg, L2) is completed proceeds. As a result, the master controller 103 performs a new By transmitting the Y-coordinate setting control message to the sub-controller 107 side, the Y-coordinate setting for the individual video device 101 belonging to the current row (L2) can be completed, and the Y-coordinate setting can be completed in the next row (eg, L3). It is possible to newly start setting the Y coordinate for the individual imaging device 101 to which it belongs.

On the other hand, when the Y-coordinate setting for the individual imaging devices 101 in the row L2 is completed, the sub-controller 107 installed in each individual imaging device 101 receives a new one from the master controller 103 side. After receiving/receiving the Y-coordinate setting control message, the corresponding Y-coordinate setting step is followed.

Even at this time, as a start of a new Y coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 checks whether the Y coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. When it is determined and the Y-coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the Y coordinate of the individual imaging device 101 to which the person belongs If the coordinates are not set to 0 or a maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Even under this procedure, as shown in FIG. 13, the sub-controller 107b installed in the individual imaging device 101b confirms that the Y coordinate of the individual imaging device 101b to which it belongs is set to 2, A procedure of turning off (extinguishing) the light emitting sensor 105b is performed, and on the sub-controller 107q installed in the individual imaging device 101q, the Y coordinate of the individual imaging device 101q to which it belongs is set to 0. After confirming that it is set, the procedure of turning on the light emitting sensor 105 (lighting it) is performed, and the sub-controller 107c installed in the individual imaging device 101c also has its own individual imaging device. After confirming that the Y-coordinate of 101c is set to the maximum value (eg, 255), a procedure of turning on the light emitting sensor 105 (lighting the point) is performed.

In this way, under a situation in which the light emitting sensor 105 of the individual imaging device 101 in which the Y-coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 14, the corresponding individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) The procedure of resetting the Y coordinate of the individual imaging device 101, which was set to 0 or the maximum value, to 1+N (N=2,3…) under the control of If the X coordinate of 101) is preset to the end value of the X coordinate (eg, 4), the master controller ( 103) to notify the party>, etc.

Even under this procedure, for example, on the side of the sub-controller 107r belonging to the individual imaging device 101r, with the light emitting sensors installed on the top, bottom, left, and right of the individual imaging device 101r turned on, the upper neighboring Detects the light emitting sensor 105s, confirms that the light emitting sensor 105s is turned off, and sets the Y coordinate (refer to FIG. 13) of the individual imaging device 101r to which the person belongs to 3 (that is, 1+2) is reset (refer to FIG. 14).

As another example, the sub-controller 107s belonging to the individual imaging device 101s also turns on the luminescence sensors installed on the top, bottom, left, and right of the individual imaging device 101s, and the light emitting sensor 105t of the upper neighbor is turned on. ), it is confirmed that the corresponding light emitting sensor 105t is turned off, and the Y coordinate (refer to FIG. 13) of the individual imaging device 101s to which the person belongs, which was previously set to 0, is 3 (ie, 1+2) to reset (see FIG. 14).

As another example, the sub-controller 107q belonging to the individual imaging device 101q also turns on the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101q, and the light emitting sensor ( 105r), it is confirmed that the corresponding light emitting sensor 105r is turned off, and the Y coordinate (refer to FIG. 13) of the individual imaging device 101q belonging to the person who has been previously set to 0 is 3 (ie, 1+2). ) to reset (see FIG. 14).

At this time, the sub-controller 107q belonging to the individual imaging device 101q checks that the X-coordinate of the individual imaging device 101q to which it belongs is preset to the end value of the X-coordinate (eg, 4), and then A procedure of notifying the master controller 103 that the Y-coordinate setting for the individual video device 101 in the row (eg, L3) is completed proceeds. As a result, the master controller 103 performs a new method without any difficulty. By transmitting the Y-coordinate setting control message to the sub-controller 107 side, the Y-coordinate setting for the individual video device 101 belonging to the current row (L3) can be finished, and the Y-coordinate setting can be completed in the next row (eg, L4). It is possible to newly start setting the Y coordinate for the individual imaging device 101 to which it belongs.

On the other hand, when the Y-coordinate setting for the individual imaging devices 101 in the row L3 is completed, the sub-controller 107 installed in each individual imaging device 101 receives a new one from the master controller 103 side. After receiving/receiving the Y-coordinate setting control message, the corresponding Y-coordinate setting step is followed.

Even at this time, as a start of a new Y coordinate setting step, the sub-controller 107 installed in each individual imaging device 101 checks whether the Y coordinate of the individual imaging device 101 to which it belongs is set to 0 or the maximum value. When it is determined and the Y-coordinate of the individual imaging device 101 to which the person belongs is set to 0 or the maximum value, the light emitting sensor 105 is turned on (lighted), and the Y coordinate of the individual imaging device 101 to which the person belongs If the coordinates are not set to 0 or a maximum value (eg, 255), a procedure of turning off (extinguishing) the light emitting sensor 105 is performed.

Even under this procedure, as shown in FIG. 15, the sub-controller 107i installed in the individual imaging device 101i confirms that the Y coordinate of the individual imaging device 101i to which it belongs is set to 2, A procedure of turning off (extinguishing) the light emitting sensor 105n is carried out, and on the side of the sub-controller 107c installed in the individual imaging device 101c, the Y coordinate of the individual imaging device 101c to which it belongs is the maximum value. After confirming that it is set to (for example, 255), the procedure of turning on the light emitting sensor 105c (lighting it) proceeds, and the sub-controller 107m installed in the individual imaging device 101m also After confirming that the Y-coordinate of the individual imaging device 101m to which the user belongs is set to the maximum value (eg, 255), the procedure of turning on the light emitting sensor 105 (lighting it) is performed.

In this way, under a situation in which the light emitting sensor 105 of the individual imaging device 101 in which the Y-coordinate is set to 0 or the maximum value is turned on (point light), as shown in FIG. 16, the corresponding individual imaging device ( 101) (that is, the sub-controller 107 installed in the individual imaging device in which the luminescence sensor 105 is turned on) The procedure for resetting the X-coordinate to 1+N (N=2,3...), which had been set to 0 or the maximum value under the control of If the coordinate end value (eg, 4) is preset and the Y coordinate of the individual imaging device 101 to which the user belongs is preset to the maximum value, the coordinate value reset by the user is the end value of the Y coordinate. Procedure for notifying the master controller 103 side> and the like.

Even under this procedure, for example, on the side of the sub-controller 107c belonging to the individual imaging device 101c, with the light emitting sensors installed at the top, bottom, left, and right of the individual imaging device 101c turned on, the upper neighboring The light emitting sensor 105e is detected, and it is confirmed that the light emitting sensor 105e is turned off, and the Y coordinate of the individual imaging device 101c to which the person belongs, which has been previously set to the maximum value (eg, 255) (refer to FIG. 15 ) ) is reset to 4 (ie, 1+3) (refer to FIG. 16).

As another example, the sub-controller 107j belonging to the individual imaging device 101j also turns on the light emitting sensors installed on the top, bottom, left, and right of the individual imaging device 101j, and the light emitting sensor 105l of the upper neighbor is turned on. ( That is, it is reset to 1+3) (refer to FIG. 16).

As another example, the sub-controller 107m belonging to the individual imaging device 101m also turns on the luminescence sensors installed on the top, bottom, left, and right of the individual imaging device 101m, and the luminescence sensor ( 105q), confirms that the corresponding light emitting sensor 105q is turned off, and sets the Y coordinate (refer to FIG. 15) of the individual imaging device 101m to 4 (ie, 1+3) is reset (refer to FIG. 16).

At this time, on the side of the sub-controller 107m belonging to the individual imaging device 101m, as shown in FIG. 15, before the reset procedure, the X coordinate of the individual imaging device 101m to which it belongs is the end value of the X coordinate ( For example, after confirming that it is preset to 4) and the Y coordinate of the individual imaging device 101m to which the user belongs is preset to the maximum value (eg, 255), the coordinate value reset by the user (ie, 4) A procedure of notifying the master controller 103 that this is the end value of the Y coordinate is performed, and in the end, the master controller 103 recognizes that all settings for the Y coordinate have been completed without any difficulty, and then the identification code By sending the setting control message to the sub-controller 107 side, Y-coordinate setting for the individual video devices 101 belonging to all rows (L1, L2, L3, L4) can be finalized, and each column ( For example, R1, R2, R3, R4) and each row (eg, L1, L2, L3, L4) can quickly start the identification code conversion/setting procedure for the individual video device 101.

On the other hand, as shown in FIG. 17, through each procedure described above, individual imaging devices belonging to each column (eg, R1, R2, R3, R4) and each row (eg, L1, L2, L3, L4) ( 101), when the X coordinate setting and Y coordinate setting are completed, the sub-controller 107 installed in each individual video device 101 receives/receives an identification code setting control message from the master controller 103 side. , according to the received/received received/received identification code setting control message, <Setting the X and Y coordinates of the individual video device 101 with the preset identification code (SI) (eg, 1,2,3,4 , . . ) conversion/setting procedure of the identification code> will be followed.

Under this identification code conversion/setting procedure, for example, on the side of the sub-controller 107a belonging to the individual video device 101a, according to the identification code setting control message, the individual video device (1,1) that has been set to (1,1) ( As shown in FIG. 18, the X and Y coordinates of 101a) are converted/set into an identification code SI of <1>.

As another example, the sub-controller 107d belonging to the individual video device 101d shows the X and Y coordinates of the individual video device 101d that have been set to (1,2) according to the identification code setting control message. 18, it is converted/set into an identification code SI of <2>.

As another example, on the side of the sub-controller 107f belonging to the individual video device 101f, the X and Y coordinates of the individual video device 101f, which have been set to (2,4), are set according to the identification code setting control message. As shown in FIG. 18, it is converted/set to an identification code SI of <14>.

Of course, all of the above-mentioned <Identification code conversion/setting procedure for converting the set X and Y coordinates into preset identification codes (SI) (eg, 1,2,3,4,...)> When finished, as shown in FIG. 18 , each individual imaging device 101 has a stable identification code SI (eg, 1,2,3,4, ...) corresponding to the individual imaging device 101 . As a result, the image control device 102 distinguishes each individual imaging device 101 from each other based on the identification code SI even after the arrangement of the individual imaging devices 101 is changed. Various data (eg, control data, image data, image enlargement data, image segmentation data, etc.) corresponding to the respective individual imaging device 101 can be normally transmitted without any difficulty.

As described above, in the present invention, in the signal transmission system of the video control device 102 and the module block of each individual video device 101, components for automatically performing the setting/granting procedure of the identification code (SI), for example, , the master controller 103, the sub-controller 107, the light emitting sensor 105, the light receiving sensor 106, etc. are additionally installed, and based on these components, When the light emitting sensor 105 is turned on and the light emitting sensor of the left neighbor is detected, the X-coordinate of the individual imaging device 101 is set to 0, and if the light emitting sensor of the left neighbor is not detected, the individual imaging device (101) When the X-coordinate of the side is set to 1 and the light-emitting sensor of the right neighbor is not detected, the X-coordinate initial setting step of setting the X-coordinate of the individual imaging device 101 to the maximum value>, <Light-emitting sensor 105 ) is turned on, and when the light emitting sensor of the upper neighbor is detected, the Y coordinate of the individual imaging device 101 side is set to 0. If the coordinates are set to 1 and the luminescence sensor of the lower neighbor is not detected, the Y coordinate initial setting step of setting the Y coordinate of the individual imaging device 101 to the maximum value>, <X coordinate of the individual imaging device 101 It is determined whether is set to 0 or the maximum value, and if the X-coordinate of the individual imaging device 101 is set to 0 or the maximum value, the light emission of the left neighbor is turned on while the light emitting sensor 105 is turned on. When a sensor is detected and the corresponding light emitting sensor is not detected, the X-coordinate of the individual imaging device 101, which was set to 0 or the maximum value, is 1+N (N=1,2, 3 ...) to reset the X coordinate setting step>, <It is determined whether the Y coordinate of the individual imaging device 101 is set to 0 or the maximum value, and the Y coordinate of the individual imaging device 101 is set to 0 or the maximum value. If it is set to a value, in the state that the light emitting sensor 105 is turned on, the light emitting sensor of the upper side is detected, and if the corresponding light emitting sensor is not detected, the master control The Y coordinate setting step of resetting the Y coordinate of the individual video device 101, which was set to 0 or the maximum value, to 1+N (N=1,2,3…) under the control of the controller 103> . <It is determined whether the setting of the X and Y coordinates of the individual imaging device 101 is completed, and when it is confirmed that the setting of the X and Y coordinates of the individual imaging device 101 is completed, according to the control of the master controller 103 , and the identification code setting step of converting the X and Y coordinates that have been set into a preset identification code (SI)>, etc., under the implementation environment of the present invention, the image system operator Even under a situation where the arrangement of the imaging device 101 is changing, it is possible to simply and automatically set/assign an identification code (SI) corresponding to each individual imaging device 101 without complicated manual work, As a result, various problems (eg, manpower loss problem, cost loss problem, time loss problem, control signal wiring limitation problem, etc.) caused by the manual installation procedure of the identification code (SI) on the individual imaging device 101 side can be effectively avoided. there will be

Various modifications may be made to the present invention according to circumstances.

For example, in the present invention, as shown in FIG. 19 , the master controller 103 is set to any one of all individual imaging devices constituting the multi-image system 100, for example, under <X coordinate setting procedure and Y coordinate setting procedure. , it is also possible to take a changed action to be installed in the individual imaging device 101m> in which both the X-coordinate and the Y-coordinate have the maximum value (eg, 255).

Of course, even in this case, when the configuration change phase of the individual imaging device 101 arrives, the master controller 103 and the sub-controller 107 cooperate with each other in the X coordinate initial setting step and the Y coordinate initial setting step. , X-coordinate setting step, Y-coordinate setting step, identification code setting step, etc. are automatically performed for each individual imaging device 101. As a result, the image system operator side, without complicated manual work, performs each individual image Since it is possible to simply and automatically set/assign an identification code (SI) corresponding to the device 101, various problems (eg, manpower) caused by the manual installation procedure of the identification code (SI) on the individual imaging device 101 side loss problem, cost loss problem, time loss problem, control signal wiring limitation problem, etc.) can be effectively avoided.

The present invention is not limited to a specific field, and in various fields requiring identification/management of individual devices, overall useful effects are exhibited.

And, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be practiced with various modifications by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or point of view of the present invention, and such modified embodiments should fall within the scope of the appended claims of the present invention.

10,100: multi-image system
11,101: individual imaging device
12,102: video control device
103: master controller
104: sensor tool
105: light emitting sensor
106: light receiving sensor
107: sub controller

Claims (5)

Under the control of the master controller, it is performed by sub-controllers installed in each of the multiple individual imaging devices constituting the multi-image system,
When the light emitting sensor installed at the top, bottom, left and right of the individual imaging device is turned on and the light emitting sensor of the left neighbor is detected, the X coordinate of the individual imaging device is set to 0, and when the light emitting sensor of the left neighbor is not detected , an initial X-coordinate setting step of setting the X-coordinate of the individual imaging device to 1 and setting the X-coordinate of the individual imaging device to a preset maximum value when the light emitting sensor of the right neighbor is not detected;
When the light emitting sensor is turned on and the light emitting sensor of the upper neighbor is detected, the Y coordinate of each imaging device is set to 0; an initial Y-coordinate setting step of setting the Y-coordinate of each imaging device to a preset maximum value when the light emitting sensor of the lower neighbor is not detected;
It is determined whether the X-coordinate of the individual imaging device is set to 0 or the maximum value, and if the X-coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, the left neighbor When the light emitting sensor is detected and the corresponding light emitting sensor is not detected, the X coordinate of the individual imaging device set to 0 or the maximum value is set to 1+N (N=1,2,3...) according to the control of the master controller. an X-coordinate setting step of resetting to ;
It is determined whether the Y coordinate of the individual imaging device is set to 0 or the maximum value, and if the Y coordinate of the individual imaging device is set to 0 or the maximum value, with the light emitting sensor turned on, When the light emitting sensor is detected and the corresponding light emitting sensor is not detected, the Y coordinate of the individual video device, which was set to 0 or the maximum value, is 1+N (N=1,2,3...) Y coordinate setting step of resetting to ;
It is determined whether the setting of the X and Y coordinates of the individual video devices has been completed, and when it is confirmed that the X and Y coordinates of the individual video devices are set, under the control of the master controller, the settings of the individual video devices that have been set A method for setting an identification code for an individual imaging device in a multi-image system, comprising the step of setting an identification code for converting the X coordinate and the Y coordinate into a preset identification code. According to claim 1, wherein the sub-controller indicates that the X-coordinate setting for the individual video device in the column to which it belongs is completed if the Y-coordinate of the individual video device is preset to the maximum value in the progress of the X-coordinate setting step. The method of setting an individual imaging device identification code of a multi-video system, characterized in that the master controller is notified. According to claim 1, wherein the sub-controller, in the progress of the X-coordinate setting step, if the X coordinate and the Y coordinate of each video device are preset to the maximum value, the coordinate value reset by the sub-controller is the end of the X coordinate. A method for setting an individual imaging device identification code in a multi-video system, characterized in that the value is notified to the master controller. The sub-controller according to claim 1, wherein if the X-coordinate of the individual video device is preset as the end value of the X-coordinate in the progress of the Y-coordinate setting step, the Y-coordinate of the individual video device in the row to which the sub-controller belongs A method for setting an individual imaging device identification code in a multiple imaging system, characterized in that notifying the master controller that the setting has been completed. According to claim 1, wherein the sub-controller side, in the progress of the Y coordinate setting step, the X coordinate of each video device is preset to the end value of the X coordinate, the Y coordinate of the individual video device is preset to the maximum value If it is, the method for setting an individual imaging device identification code in a multi-video system, characterized in that it notifies the master controller that the coordinate value reset by itself is the end value of the Y coordinate.

Images