JP4986111B2 - Lighting control device and lighting control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting control device and a lighting control system capable of easily and surely identifying a pattern data in the course of light control. <P>SOLUTION: When a data request signal is inputted from an external input device 6 through a renewal control part 12, each lighting control part 22 outputs an execution data showing a pattern data and a number data of a neon unit 24 during light control at that time, to the renewal control part 12. When the execution data is inputted from the lighting control part 22, the renewal control part 12 outputs the execution data to the external input device 6. <P>COPYRIGHT: (C)2007,JPO&amp;INPIT

Description

The present invention relates to a lighting control system that performs lighting control of light emitters such as neon tubes and LEDs.

  For example, a neon lighting system such as a huge neon signboard provided on the roof of a building is configured by using a large number of neon tubes, and the neon tubes are repeatedly turned on and off in a predetermined pattern, thereby producing an overall effect. A certain lighting mode is realized. Such a neon lighting system is composed of a plurality of neon tubes and a lighting control device to which the neon tubes are connected, and the lighting control device realizes the effect by changing the lighting pattern of the corresponding neon tube as needed. Yes.

As this type of neon lighting system, conventionally, for example, a lighting control device described in Patent Document 1 has been proposed.
This lighting control device controls the turning on / off and the luminance (lighting pattern) of a plurality of corresponding neon tubes based on pattern data input from an external input device. Specifically, the control unit of the lighting control device includes a memory, and pattern data input from an external input device such as a personal computer is recorded in the memory. The pattern data is composed of a plurality of data indicating a time-series change mode of the lighting pattern of the neon tube. And a control part performs lighting control of a neon tube based on the pattern data recorded on the memory. Specifically, the control unit updates the pattern data every time a predetermined time (for example, 10 milliseconds) elapses, and turns on the neon tube based on the updated pattern data.

Such pattern data can be rewritten. When new pattern data is input from the external input device, the control unit rewrites the pattern data by overwriting the existing pattern data with the new pattern data. . In general, a personal computer or the like is used as the external input device, and the pattern data is created by programming with the external input device.
Japanese Patent Laid-Open No. 07-160214

  In this type of lighting control device, for example, when only a part of a series of lighting effects is changed, only a part of all pattern data may be changed by specifying the changed part. However, in order to change such partial pattern data, the time from the start of the lighting effect to the change location is measured and the pattern data corresponding to the change location is specified based on the measurement time. It is necessary to change the program. In other words, it is necessary to perform a lighting effect from the beginning, to find a change location, to measure the time from the start of the production to the change location, and to change the corresponding change location in the pattern data program. . For this reason, the operation of changing such pattern data is complicated. In particular, when the amount of pattern data is large, that is, when the production time is long, the above work is very complicated and substantially difficult. Therefore, there is a disadvantage that even if only part of the pattern data is desired to be changed, the entire pattern data must be changed.

The present invention has been made in view of such circumstances, and an object thereof is to provide a lighting control system capable of easily and reliably specifying pattern data during lighting control.

In order to solve the above-described problem, in the invention according to claim 1, when a plurality of pattern data indicating a time-series change mode of the lighting pattern of the light emitter is input from an external input device, the pattern data is stored. Recording means for recording and lighting control of the light emitter based on the pattern data recorded in the recording means, and updating the pattern data every time a preset periodic update time elapses. changing the lighting mode, comprising a plurality of lighting control device the execution data item indicated by the pattern data before Symbol lighting control in and a lighting control means for performing data output control of outputting to the external input device, wherein the plurality of lights A network connection is made to each lighting control means between the lighting control means and the external input device of the control device, and the pattern data is input from the external input device. A lighting control system comprising an overall control device that outputs the pattern data to the corresponding lighting control means when the lighting control means is connected to the lighting control means from the external input device via the overall control device. When a plurality of pattern data is input, the data recording control for recording the pattern data in the recording means in a state in which the number data is associated with the pattern data, and the number data is input from the overall control device The lighting control for lighting the light emitter with a lighting pattern based on the pattern data corresponding to the input number data, and executing the execution data indicating the pattern data during the lighting control with the overall control device Data output control to the external input device via the control unit, the overall control device, the number data recorded in itself Data update control for sequentially outputting to each lighting control means via the network to update the pattern data, and when the execution data is input from the lighting control means, the execution data is input to the external input device. The gist is to perform data output mediation control .

According to the above configuration, the lighting control unit performs the lighting control of the light emitter based on the pattern data recorded in the recording unit, while outputting the execution data indicating the pattern data during the lighting control to the external input device. Take control. Therefore, the external input device can recognize which pattern data is currently used for lighting control. Therefore, for example, even when only a part of a series of lighting effects is changed, the pattern data corresponding to the changed portion can be easily specified, and the change work can be easily performed. . Further, when the pattern data from the external input device is input via the overall control device, each lighting control unit records the pattern data in the recording unit in a state in which the number data is associated with the pattern data. Then, when the number data is input from the overall control device, each lighting control unit turns on the light emitter based on the pattern data corresponding to the number data. For this reason, it becomes possible to control lighting control by all the lighting control devices in an integrated manner by the overall control device. In addition, execution data output from each lighting control means can be input to an external input device via the overall control device. Therefore, the external input device can recognize which pattern data each lighting control unit is currently performing lighting control based on such execution data. Therefore, for example, even when only a part of a series of lighting effects is changed, the pattern data corresponding to the changed portion can be easily specified, and the change work can be easily performed. .

According to a second aspect of the present invention, in the lighting control system according to the first aspect , the lighting control means is provided on the condition that a data request signal for requesting output of the execution data is input from the external input device. The gist is to perform the data output control.

  According to the above configuration, data output control is performed only when a data request signal is input from the external input device to the lighting control means. That is, data output control is performed only when required by an external input device. For this reason, it is possible to prevent data output control in an unnecessary state.

According to a third aspect of the present invention, in the lighting control system according to the first or second aspect, the lighting control means has a data designation signal indicating that one of the plurality of pattern data is designated. When it is input from the external input device, the gist is to start lighting control using the pattern data specified by the data specifying signal as start data.

  According to the above configuration, when the data designation signal is input, the lighting control means performs lighting control using the pattern data designated by the data designation signal among the plurality of pattern data constituting the series of lighting effects as start data. Start. That is, even if the designated pattern data is pattern data indicating an effect place in the middle of a series of lighting effects, the lighting control means starts lighting control using the pattern data as start data. For this reason, for example, when it is desired to change the pattern data of the latter half of a series of lighting effects, the change data can be specified in a short time by specifying the pattern data indicating the intermediate production location as start data. Is possible.

According to a fourth aspect of the present invention, in the lighting control system according to any one of the first to third aspects, the lighting control signal includes a lighting holding signal indicating that the lighting state is held from the external input device. The gist of the present invention is to perform lighting holding control for holding the lighting state of the light emitter at that time by stopping the update of the pattern data when input.

  According to the above configuration, the lighting state of the light emitter at that time can be held by inputting the lighting holding signal from the external input device to the lighting control means. For this reason, for example, when changing a part of all the pattern data, the lighting state of the light emitter at the change corresponding portion is clearly determined by maintaining the lighting state of the light emitter at the change corresponding portion. It becomes possible to recognize.

In the invention according to claim 5, when a plurality of pattern data indicating a time-series change mode of the lighting pattern of the light emitter is inputted from an external input device, the recording means records the pattern data, and the recording means Lighting control means for performing lighting control of the light emitter based on the pattern data recorded on the light source, and changing the lighting mode of the light emitter by updating the pattern data each time a preset periodic update time elapses; And a plurality of lighting control devices including the lighting control device, the lighting control device of the lighting control device is connected to each lighting control means between the lighting control means and the external input device, the pattern data is input from the external input device A lighting control system comprising a general control device for outputting the pattern data to the corresponding lighting control means, When the plurality of pattern data are input from the external input device via the overall control device, the control means records the pattern data in the recording means in a state in which number data is associated with each pattern data. Data recording control to be performed, and when number data is input from the overall control device, lighting control is performed to turn on the light emitter with a lighting pattern based on pattern data corresponding to the input number data, and the overall control is performed. The control device sequentially outputs the number data recorded therein to each of the lighting control means via the network to update the pattern data, and outputs the updated number data to the external input device. The main point is to perform data output mediation control .

According to the above configuration, when the pattern data from the external input device is input via the overall control device , each lighting control unit stores the pattern data in the recording unit in a state in which the number data is associated with the pattern data. Record. Then, when the number data is input from the overall control device, each lighting control unit turns on the light emitter based on the pattern data corresponding to the number data. For this reason, it becomes possible to control lighting control by all the lighting control devices in an integrated manner by the overall control device. Further, since the updated number data can be input from the overall control device to the external input device, the external input device uses the number data as the pattern data used for lighting control of the light emitter at the time of input. It becomes possible to recognize from the correspondence relationship. Therefore, the external input device can recognize based on such number data which pattern data each lighting control means currently performs.

As described above in detail, according to the present invention, it is possible to provide a lighting control system capable of easily and reliably specifying pattern data during lighting control.

DESCRIPTION OF EMBODIMENTS Hereinafter, an embodiment embodying the present invention will be described in detail with reference to FIGS.
<Outline of system configuration>
As shown in FIG. 1, a lighting control system 1 includes an overall control unit (overall control device) 2 and a plurality of lighting control units (lighting control devices) 4 connected to the overall control unit 2 via a bus 3 via a network. And. Therefore, network communication is possible between the overall control unit 2 and each lighting control unit 4. In the present embodiment, it is assumed that 25 lighting control units 4 are connected to the overall control unit 2, and only the first to fourth lighting control units 4a to 4d are shown in FIG. And Incidentally, the number of lighting control units 4 that can be connected to the overall control unit 2 depends on the drive function of the overall control unit 2 and is not limited to 25 lighting control units 4, for example, 100 lighting control units. It is also possible to connect.

  Each lighting control unit 4 is connected to an AC power source (100 V, 60 Hz commercial power source here), and the overall control unit 2 is connected to a DC power source obtained by converting the AC power source into a DC by an AC / DC converter 5. .

<Configuration of central control unit 2>
The overall control unit 2 includes a communication interface 11 connected to the bus 3, an update control unit 12 connected to the communication interface 11, and a switching operation unit 13 connected to the update control unit 12.

The communication interface 11 transmits various signals input from the update control unit 12 to each lighting control unit 4 via the bus 3.
The switching operation unit 13 includes a dip switch or the like and is connected to the update control unit 12. The switching operation unit 13 is for performing a mode switching operation for switching the mode of the update control unit 12. Therefore, when the operation is performed by the switching operation unit 13, the operation signal is input to the update control unit 12.

  The update control unit 12 is a CPU unit including a CPU, a ROM, a RAM, and the like (not shown), and includes a nonvolatile memory 12M. In the present embodiment, a plurality of number data corresponding to positive integer values is recorded in the memory 12M. And the update control part 12 performs the data update control which outputs the update signal containing the said number data to the communication interface 11 whenever the preset regular update time passes. In the present embodiment, the regular update time is set to 10 milliseconds. Specifically, when outputting the number data, the update control unit 12 first outputs an update signal including number data corresponding to “0”, and thereafter, every time the periodic update time elapses, “1”. , “2”, “3”, etc., the number data corresponding to the positive integer value added by 1 is output to update the number data. Note that the update control unit 12 is not necessarily limited to updating the number data incremented by one when the number data is updated. For example, the number data corresponding to “1” to the number data corresponding to “5”. It is also possible to update to completely different number data such as updating to

  The update control unit 12 can be connected to an external input device 6 such as a personal computer. A plurality of pattern data respectively indicating lighting patterns of a plurality of light emitters (here, neon tubes) controlled by each lighting control unit 4 is created by the external input device 6 and lighting control is performed from the external input device 6. It is set by being input to the system 1. Specifically, in the external input device 6, a plurality of pattern data indicating lighting patterns of a plurality of light emitters, number data indicating the reproduction order of the pattern data, address data for designating each lighting control unit 4, and New data is created by associating with each other. Then, when the external input device 6 is connected to the update control unit 12, the new data is input to the update control unit 12. Such new data is created by being programmed by the external input device 6 and confirmed by simulation reproduction on the monitor of the external input device 6. More specifically, for example, as shown in FIG. 2A, pattern data with respect to the passage of time of each neon tube (shown here schematically as neon tubes N1 to N5) is displayed on the monitor of the external input device 6. The pattern data is set based on this display. Here, the pattern data of the neon tube N1 with respect to time t is a0 to a8, the pattern data of the neon tube N2 is b0 to b8, the pattern data of the neon tube N3 is c0 to c8, and the pattern data of the neon tube N4 is d0 to d8. The pattern data of d8 and neon tube N5 are shown as e0 to e8. Then, as shown in FIG. 2B, the reproduction state of each of the neon tubes N1 to N5 based on the set lighting mode is displayed on the monitor of the external input device 6. For this reason, by confirming this reproduction state, the lighting mode of each of the neon tubes N1 to N5 can be finely adjusted. When each pattern data set in this way is input to the update control unit 12, number data is assigned according to the reproduction order of each pattern data, and each pattern data is updated with the number data. 12 is input.

  The external input device 6 outputs a data request signal to the update control unit 12 when a data request operation is performed by the operator. Furthermore, when a data designation operation is performed by the operator, the external input device 6 outputs a data designation signal including number data indicated by the data designation operation to the update control unit 12.

  When the signal indicating that the mode switching operation has been performed (mode switching signal) is input from the switching operation unit 13, the update control unit 12 switches to the normal mode or the data rewrite mode according to the mode switching signal. Change. Incidentally, in the normal mode, the update control unit 12 performs data update control for outputting the number data. On the other hand, in the data rewriting mode, the update control unit 12 outputs a mode setting signal indicating that it is in the data rewriting mode and new data input from the external input device 6 to the communication interface 11 to output each of the lighting control units 4. Data rewrite control is performed to rewrite data. The address data is set in correspondence with the setting state of the address setting unit 23 of each lighting control unit 4 to be described later.

  Further, when the data request signal is input from the external input device 6 in the normal mode, the update control unit 12 outputs data to the external input device 6 that is subjected to lighting control by each lighting control unit 4 at that time. Perform output mediation control. Specifically, when a data request signal is input from the external input device 6 in the normal mode, the update control unit 12 outputs the data request signal to each lighting control unit 4. And the update control part 12 will output the execution data to the external input apparatus 6, if the execution data containing the pattern data in lighting control from each lighting control unit 4 are input.

  In addition, when the data designation signal is input from the external input device 6, the update control unit 12 sets the number data designated by the data designation signal as start data, and sets the number data to each lighting control unit 4. Output. That is, for example, when the number data designated by the data designation signal is “5”, the update control unit 12 first outputs the number data corresponding to “5”, and thereafter, every time the periodic update time elapses, The number data is updated by outputting number data corresponding to a positive integer value obtained by adding one by one, such as “6”, “7”.

<Configuration of lighting control unit 4>
On the other hand, each lighting control unit 4 includes a communication interface 21 connected to the bus 3, a lighting control unit 22 as a lighting control unit connected to the communication interface 21, and an address connected to the lighting control unit 22. A setting unit 23 is provided. In FIG. 1, only the configuration of the first lighting control unit 4a is shown in detail, but the second to fourth lighting control units 4b to 4c also have the same configuration as the first lighting control unit 4a.

The communication interface 21 receives various signals output from the overall control unit 2 via the bus 3 and outputs them to the lighting control unit 22.
The address setting unit 23 includes an operation unit such as a dip switch having eight switch units, for example, and is set so that the setting states of the lighting control units 4 are not the same. A setting signal indicating the setting state of the address setting unit 23 is input to the lighting control unit 22.

  A neon unit 24 as a light emitter is connected to the lighting control unit 22 of each lighting control unit 4. Each of these neon units 24 includes a plurality of neon tubes and a neon transformer for causing the neon tubes to emit light (not shown). In the present embodiment, the neon unit 24 includes a plurality of neon tubes of three colors, red, blue, and green. Such a neon unit 24 causes the corresponding neon tube to emit light based on the control signal output from the lighting control unit 22.

  The lighting control unit 22 is a CPU unit including a CPU, a ROM, a RAM, and the like (not shown), and includes a nonvolatile memory 22M as a recording unit. In the present embodiment, the memory 22M stores lighting data in which the plurality of number data and a plurality of pattern data indicating a time-series change pattern of the lighting pattern of the neon unit 24 are associated with each other.

  Specifically, as shown in FIG. 3, for example, in the memory 22M of the first lighting control unit 4a, number data corresponding to “0” and pattern data indicated by “A-0” are associated as lighting data. The number data corresponding to “1” and the pattern data indicated by “A-1” are recorded in association with each other. In this way, each number data and pattern data is represented as pattern data “A-2” for number data “2”, pattern data “A-3” for number data “3”, and so on. It is associated and recorded in the memory 22M.

  Similarly, the memory 22M of the second lighting control unit 4b stores the pattern data “B-0” for the number data “0”, the pattern data “B-1” for the number data “1”, and the number data “0”. Number data and pattern data are recorded in association with each other, such as pattern data “B-2” for number 2 and pattern data “B-3” for number data “3”. Yes.

  As shown in the figure, the pattern data indicated by “A-0”, for example, turns on the red neon tube of the corresponding neon unit 24 at 100% output and turns off the blue neon tube and the green neon tube. The lighting pattern to be set is set. On the other hand, the pattern data indicated by “B-0” is set to a lighting pattern in which the red neon tube and the blue neon tube of the corresponding neon unit 24 are turned on with 70% output and the green neon tube is turned off. ing. That is, even with the same number data, the lighting pattern is different between the pattern data recorded in the memory 22M of the first lighting control unit 4a and the pattern data recorded in the memory 22M of the second lighting control unit 4b. May be set.

  On the other hand, for example, the pattern data indicated by “A-1” and “B-1” both turn off the red neon tube and the green neon tube of the corresponding neon unit 24 and output the blue neon tube at 100%. The lighting pattern is set to light up with. That is, the pattern data of each lighting control unit 4a, 4b corresponding to the same number data may show the completely same lighting pattern.

  In the present embodiment, the pattern data indicated by “A-2” is set to a lighting pattern in which the red neon tube and the blue neon tube are turned off and the green neon tube is turned on with 100% output. The pattern data indicated by “A-3” is set to a lighting pattern in which the red neon tube and the blue neon tube are turned on with 100% output and the green neon tube is turned off. Similarly, the pattern data indicated by “B-2” is a lighting pattern in which the red neon tube is turned off while the blue neon tube is turned on at 70% output and the green neon tube is turned on at 100% output. Is set to The pattern data indicated by “B-3” is set to a lighting pattern in which the red neon tube and the blue neon tube are turned on with 100% output and the green neon tube is turned off.

  Then, the lighting control unit 22 performs lighting control, data rewrite control, and data output control of the neon unit 24 based on various signals output from the overall control unit 2 (update control unit 12). Specifically, when the mode switching signal is input from the update control unit 12, the lighting control unit 22 starts the memory 22M from the normal mode in which the lighting control of the neon unit 24 based on the pattern data recorded in the memory 22M is performed. The mode shifts to a data rewrite mode in which data rewrite control for rewriting the pattern data recorded in is performed. When the data request signal is input from the update control unit 12, the lighting control unit 22 performs patterning control and outputs pattern data used for lighting control at that time to the update control unit 12. Perform output control.

  More specifically, when number data is input from the overall control unit 2 in the normal mode, the lighting control unit 22 reads pattern data corresponding to the number data from the memory 22M, and uses each lighting pattern based on the pattern data. The neon unit 24 is turned on. That is, when the number data “0” is output from the overall control unit 2, the lighting control unit 22 of the first lighting control unit 4a is the pattern data “A-0”, and the lighting control unit 22 of the second lighting control unit 4b is The neon unit 24 is turned on with a lighting pattern based on the pattern data “B-0”.

  Therefore, in the lighting control system 1 configured as described above, the lighting pattern is updated at the same timing when each lighting control unit 4 receives the number data output from the overall control unit 2 every 1/60 seconds. It will be. In addition, since the number data is absolute value data, even if some of the lighting control units 4 cannot normally receive the number data, the lighting control unit 4 is not updated when the data is updated next time. If the data is received normally, all the lighting control units 4 update the pattern data based on the same number data. For this reason, the lighting pattern update timing does not shift between the lighting control unit 4 that has successfully received the number data and the lighting control unit 4 that has not been able to normally receive the number data.

  In addition, when the mode setting signal output from the overall control unit 2 (update control unit 12) is input, the lighting control unit 22 shifts from the normal mode to the data rewrite mode and performs data recording control. Specifically, when new data is input in such a data rewriting mode, the lighting control unit 22 first includes address data included in the new data and address data indicated by a setting signal input from the address setting unit 23. It is judged whether or not. As a result, when it is determined that the address data match, the lighting control unit 22 records the pattern data and number data included in the new data in the memory 22M. At this time, if pattern data and number data are already recorded in the memory 22M, the lighting control unit 22 overwrites and updates the existing data with new pattern data and number data. If it is determined that the address data do not match, the lighting control unit 22 ignores the new data. Therefore, by operating the switching operation unit 13 of the overall control unit 2, the update control unit 12 and the lighting control unit 22 are switched to the data rewriting mode, and new data is input to the update control unit 12 from the external input device 6. New number data can be recorded in the memory 12M of the update control unit 12. At the same time, new pattern data and number data can be recorded in the memory 22M of the lighting control unit 22 of each lighting control unit 4.

  Further, when the data request signal output from the overall control unit 2 is input, the lighting control unit 22 indicates the lighting mode of the neon unit 24 that performs the lighting control at that time, that is, the pattern data at that time. Data output control for outputting execution data to the overall control unit 2 is performed.

<Lighting data rewrite (new input) operation>
Next, the pattern data and number data rewriting (new input) operation in the lighting control system 1 configured as described above will be described in detail with reference to FIG.

  First, as shown in the figure, when a switching operation to the data rewrite mode is performed by the switching operation unit 13 of the overall control unit 2 in step S1, the update control unit 12 enters the data rewrite mode, and a mode setting indicating that. A signal is output to each lighting control unit 4. For this reason, in step S2, each lighting control unit 22 enters the data switching mode when the mode setting signal is input.

  On the other hand, when new data composed of pattern data and number data is created by programming and simulation by the external input device 6 in step S3 and the new data is input to the update control unit 12, the update control unit 12 in step S4 Among the new data, number data is recorded in the memory 12M. At the same time, the update control unit 12 outputs new data to each lighting control unit 22 via the bus 3.

  In step S5, each lighting control unit 22 records lighting data associated with the corresponding address data, that is, pattern data and number data, in the memory 22M based on the address data included in the new data. At this time, when lighting data is already recorded in the memory 22M, each lighting control unit 22 deletes the lighting data and records new lighting data in the memory 22M. That is, each lighting control unit 22 overwrites lighting data.

  Then, when the recording of such lighting data is completed, each lighting control unit 22 outputs a completion signal indicating that to the update control unit 12 in step S6, and shifts to the normal mode in step S7.

  When the completion signal is input from the lighting control unit 22 to be rewritten, the update control unit 12 switches to the normal mode in step S8. Note that the processes in steps S6 to S8 are not necessarily performed.

<Data output operation>
Next, the operation of outputting pattern data (execution data) during lighting control from the lighting control system 1 to the external input device 6 will be described in detail with reference to FIG.

  As shown in the figure, in the normal mode, the update control unit 12 outputs number data to each lighting control unit 22 in step S11. In step S12, each lighting control unit 22 performs lighting control of each neon unit 24 based on the pattern data corresponding to the number data.

  On the other hand, when such a lighting control is performed, a data request signal is output from the external input device 6 in step S13, and when the data request signal is input to the update control unit 12, the update control unit 12 in step S14. Outputs the data request signal to each lighting control unit 22.

  When the data request signal is input from the update control unit 12, each lighting control unit 22 updates the execution data at that time, that is, the pattern data and number data during the lighting control of the neon unit 24. 12 is output.

  When the execution data is input from each lighting control unit 22, the update control unit 12 outputs the execution data to the external input device 6. In step S17, the external input device 6 displays the input execution data on the monitor.

  That is, when a data request signal is input from the external input device 6 to the lighting control system 1, the data request signal is input to each lighting control unit 22 via the update control unit 12. As a result, each lighting control unit 22 performs data output control for outputting the pattern data that is currently controlled for lighting to the external input device 6 via the update control unit 12. Further, the update control unit 12 outputs a data request signal input from the external input device 6 to each lighting control unit 22 and data to output execution data output from the lighting control unit 22 to the external input device 6. Perform output mediation control.

  Here, the operation of the external input device 6 during such a data output operation will be described. As a specific example, as shown in FIG. 2, the pattern data of the neon tubes N1 to N5 (neon tubes constituting the neon unit 24) with respect to time (effect time) t are a0 to a8, b0 to b8, The case where c0 to c8, d0 to d8, and e0 to e8 are set will be described.

  In this case, for example, number data and pattern data (neon tube N1 → a4, neon tube N2 → b5, neon tube N3 → c4, neon tube N4 → d3, neon tube N5 → It is assumed that execution data including e4) is input to the external input device 6. Then, in order to show execution data corresponding to the time tx, an instruction line (scanning line) as shown by a broken line in FIG. 2A is visualized, and each neon tube N1 to N1 shown in FIG. On the lighting simulation screen of N5, the lighting mode based on the execution data is visualized as a simulation image.

  Therefore, by connecting the external input device 6 to the lighting control system 1 and performing an operation for requesting data, the pattern data during the lighting control performed at that time is reliably reflected on the monitor. be able to. Therefore, the operator can easily and surely recognize which pattern data is controlled to turn on the neon unit 24 by visually checking the monitor.

<Specifying start data>
Further, the lighting control system 1 controls the lighting of the neon unit 24 by each lighting control unit 4 using the pattern data specified by the data specifying signal as start data when the data specifying signal is input from the external input device 6. Is done.

  More specifically, as described above, the update control unit 12 normally outputs the number data “0” by outputting the number data corresponding to “0” when outputting the number data to each lighting control unit 22. The lighting control of the neon unit 24 by the lighting control unit 22 is started with the pattern data corresponding to " That is, for example, as indicated by time t0 in FIG. 2A, the first pattern data (in this case, a0 to e0) is set as start data among the pattern data configured in time series.

  However, for example, when the number data corresponding to the time tx is input from the external input device 6 in the figure, the update control unit 12 outputs the number data to each lighting control unit 22, whereby each lighting control unit 22. Starts lighting control of the neon unit 24 based on the pattern data (in this case, a4, b5, c4, d3, e4) corresponding to the number data.

  For this reason, the external input device 6 is connected to the lighting control system 1 and the operation for designating the lighting control start data is performed by the external input device 6 to freely set the lighting control start location. Can do.

Therefore, according to the present embodiment, the following effects can be obtained.
(1) When the pattern data is input from the external input device 6 via the overall control unit 2, the lighting control unit 22 of each lighting control unit 4 corresponds to the pattern data in a state in which number data is associated with the pattern data. Data is recorded in the memory 22M. Then, when the number data is input from the update control unit 12 of the overall control unit 2, each lighting control unit 22 lights the light emitter based on the pattern data corresponding to the number data. For this reason, the lighting control by all the lighting control units 4 can be comprehensively controlled by the overall control unit 2. Execution data output from each lighting control unit 22 is input to the external input device 6 via the update control unit 12. Therefore, the external input device 6 can recognize which pattern data each lighting control unit 22 is currently performing lighting control based on such execution data. Therefore, for example, even when only a part of a series of lighting effects is changed, the pattern data corresponding to the changed portion can be easily specified, and the change work can be easily performed. .

  (2) Only when a data request signal is input from the external input device 6 to the update control unit 12, the data output control by the lighting control unit 22 and the data output mediation control by the update control unit 12 are performed, and the lighting is performed at that time. The controlled pattern data is output to the external input device 6. That is, the data output control is performed only when the external input device 6 requires it. For this reason, data output control in an unnecessary state can be prevented.

  (3) When a data designation signal is input from the external input device 6 via the update control unit 12, the lighting control unit 22 designates a plurality of pattern data constituting a series of lighting effects by the data designation signal. The lighting control of the neon unit 24 is started using the number data and the corresponding pattern data as start data. That is, even if the designated pattern data is pattern data indicating an effect location in the middle of a series of lighting effects, the lighting control unit 22 starts lighting control using the pattern data as start data. For this reason, for example, when it is desired to change the pattern data of the latter half of a series of lighting effects, the change data can be specified in a short time by specifying the pattern data indicating the intermediate production location as start data. Can do.

  (4) When the data request signal is input from the external input device 6, the update control unit 12 outputs the data request signal to each lighting control unit 22, and the pattern data input from the lighting control unit 22 and Execution data including number data is output to the external input device 6. That is, the execution data itself whose lighting is controlled by each lighting control unit 22 is input to the external input device 6. For this reason, the external input device 6 can reliably obtain execution data for which lighting control is actually performed.

In addition, you may change embodiment of this invention as follows.
In the embodiment, the lighting control system 1 includes the overall control unit 2, the plurality of lighting control units 4, and the bus 3 that connects them. However, the lighting control system 1 is not limited to this, and may be configured by a single lighting control unit 4 as shown in FIG. 6, for example.

Specifically, the lighting control unit (lighting control device) 4 includes a lighting control unit 22 and a switching operation unit 25.
The switching operation unit 25 is configured by a dip switch or the like, and is connected to the lighting control unit 22. The switching operation unit 25 can perform a mode switching operation for selectively switching the mode of the lighting control unit 22 to the normal mode or the data rewriting mode. For this reason, when the operation is performed by the switching operation unit 25, the operation signal is input to the lighting control unit 22.

  In addition, the lighting control unit 22 can connect the external input device 6. Then, when the new data is input from the external input device 6 in a state where the lighting control unit 22 is switched to the data rewriting mode by the switching operation unit 25, the lighting data rewriting operation is performed. Further, when the data request signal is input from the external input device 6, the lighting control unit 22 outputs the pattern data during lighting control of the neon unit 24 to the external input device 6 at that time. Further, when a data designation signal is input from the external input device 6, the lighting control unit 22 performs lighting control of the neon unit 24 using the pattern data designated by the data designation signal as start data.

  Even in such a modification, the memory 22M of the lighting control unit 22 may record number data set corresponding to the pattern data together with the pattern data. And the lighting control part 22 may perform lighting control of the neon unit 24 based on the pattern data corresponding to the updated number data while updating number data for every regular update time.

  In each embodiment, the external input device 6 may be capable of outputting a mode switching signal to the update control unit 12 or the lighting control unit 22. The update control unit 12 or the lighting control unit 22 selects the normal mode or the data switching mode regardless of the operation state of the switching operation units 13 and 25 when the mode switching signal is input from the external input device 6. May be switched automatically. That is, the update control unit 12 or the lighting control unit 22 may include both a manual mode switching function by the switching operation units 13 and 25 and an automatic mode switching function by a mode switching signal from the external input device 6. In such a modification, the switching operation units 13 and 25 may be omitted, and the mode may be switched only by the automatic mode switching function.

  In the embodiment, when a data request signal is input from the external input device 6 to the update control unit 12, the data request signal is output to each lighting control unit 22, and at that time, the neon unit 24 is controlled to be turned on. The pattern data and number data being input are input from the lighting control unit 22 to the external input device 6 via the update control unit 12. However, each lighting control unit 22 may not perform output control of execution data based on such a data request signal. Instead, when the data request signal is input from the external input device 6, the update control unit 12 outputs the number data output to each lighting control unit 22 at that time to the external input device 6. It may be. Specifically, for example, as shown in FIG. 7, in each of steps S21 and S22, based on the number data output from the update control unit 12, each lighting control unit 22 turns on the neon unit 24 based on the corresponding pattern data. Take control. In the meantime, when the data request signal output from the external input device 6 in step S23 is input to the update control unit 12, the update control unit 12 outputs the latest output to each lighting control unit 22 in step S24. The number data may be output to the external input device 6. In step S25, the external input device 6 determines on which pattern data each lighting control unit 22 is currently performing lighting control based on the pattern data corresponding to the number data input from the update control unit 12. You may come to recognize. In this way, each lighting control unit 22 does not need to perform any processing based on the data request signal input from the external input device 6, so that the processing load on the lighting control unit 22 can be reduced. In addition, since the number of processes from when the external input device 6 outputs the data request signal to when the number data is input to the external input device 6 is reduced, the input responsiveness of the number data can be improved.

  In such a modification, the update control unit 12 can output the updated number data to the external input device 6 every time the number data is updated regardless of whether or not the data request signal is input from the external input device 6. It may be. In this way, an operation for outputting a data request signal from the external input device 6 is not required, and the external input device 6 is actually controlled for lighting only by connecting the external input device 6 to the update control unit 12. The execution data being performed can be obtained reliably.

In the embodiment, when the lighting holding signal is input from the external input device 6 in the normal mode, the update control unit 12 fixes the number data output to each lighting control unit 22 at that time. The lighting holding signal may be output to each lighting control unit 22. Then, each lighting control unit 22 performs lighting holding control for holding the lighting state of the neon unit 24 without updating the pattern data when the lighting holding signal is input from the update control unit 12. It may be. In this way,
When a lighting hold signal is input from the external input device 6 to the lighting controller 22, the lighting state of the neon unit 24 at that time is held. For this reason, for example, when a part of each pattern data is changed, the lighting state of the change-corresponding portion can be clearly recognized by clearly holding the lighting state of the change-corresponding portion.

Such a lighting holding signal may be input to the update control unit 12 together with the data designation signal.
In the above modification, the update control unit 12 receives the number data every time the state holding time set longer than the periodic update time elapses after the lighting holding signal is input from the external input device 6. May be updated. In this way, each lighting control unit 22 updates the lighting state of the neon unit 24 on condition that the number data has been updated. It will be in the sent state.

  In addition, the lighting mode of the neon unit 24 may be updated on condition that an operation for updating data is performed by the external input device 6 or the update control unit 12 without being limited to the automatic frame advance function. Good.

  In the embodiment, the overall control unit 2 may have an update speed adjustment function that can adjust the update interval of the number data for each lighting control unit 4. Specifically, the overall control unit 2 is provided with speed adjusting means such as a speed adjusting operation section, and the update speed of the number data for each lighting control section 22 is changed from the update control section 12 according to the operation mode of the speed adjusting means. . In this way, the lighting control system 1 alone can change a series of lighting effect speeds without performing the lighting data changing process by the external input device 6. In addition, in this case, although the speed of the lighting mode of the neon unit 24 simulated on the monitor of the external input device 6 and the speed of the actual lighting mode of the neon unit 24 do not match, the lighting control system from the external input device 6 By inputting the data request signal to 1, the external input device 6 can surely recognize the pattern data at that time. Therefore, for example, even when only a part of a series of lighting effects is changed, the pattern data corresponding to the changed portion can be easily specified, and the change work can be easily performed. . Incidentally, in the lighting control system in the background art, when such a speed adjustment function is provided, it is more difficult to specify pattern data, and it is not possible to specify and change only a part of pattern data. It becomes very difficult.

  In the lighting control system 1 shown in FIG. 6 as the modified example, the speed adjusting means may be arranged in the lighting control unit 4. In this case, the lighting control unit 22 may change a series of lighting effect speeds by changing the pattern data update speed according to the operation mode of the speed adjusting means.

  The update control unit 12 is not limited to outputting pattern data and number data for which lighting control is performed by the lighting control unit 22 only when a data request signal is input from the external input device 6, and the lighting control unit 12 The pattern data and number data being controlled may be output to the external input device 6 periodically, for example, every predetermined time. In this way, it is not necessary to perform an operation for outputting a data request signal from the external input device 6, and the ease of operation can be improved.

  In each of the above embodiments, the neon unit 24 having a neon tube is used as the light emitter. However, for example, an LED or an incandescent bulb may be used as the light emitter, and a lighting control unit 4 that controls lighting of the LED or the incandescent bulb may be used. In the first to third embodiments, the lighting control system 1 includes a lighting control unit 4 that controls lighting of the neon unit 24 and a lighting control unit 4 that controls lighting of LEDs, incandescent bulbs, and the like. It may be.

Next, in addition to the technical ideas described in the claims, the technical ideas grasped by the embodiment described above are listed below.
(1) In the lighting control device according to claim 4, when the lighting control unit has stopped updating pattern data by the lighting holding control, a preset state holding time has elapsed. And when at least one of the conditions for the data update operation is satisfied, the light emitter is changed based on the pattern data set as the next lighting mode of the pattern data in the holding state. Turn it on.

  (2) The lighting control device according to any one of claims 1 to 4 and (1), further including a speed adjusting unit capable of adjusting an update speed of the pattern data, wherein the lighting control unit Changing the update speed of the pattern data in accordance with the adjustment state by the adjustment means;

  (3) In the lighting control system according to claim 5, when the data request signal is input from the external input device, the update control unit outputs the data request signal to the lighting control unit. .

  (4) In the lighting control system according to claim 5 or (3), when the data designation signal is input from the external input device, the update control means uses the data designation signal as the lighting control system. Output to the means.

  (5) In the lighting control system according to any one of (5), (3), and (4), the update control unit may be configured such that when the lighting holding signal is input from the external input device, By stopping the update of the number data to the lighting control means, the lighting holding control for holding the lighting state of the light emitter at that time is performed.

The block diagram which shows schematic structure of the lighting control system of one Embodiment of this invention. (A), (b) is a schematic diagram which shows roughly the example of a display of the monitor screen of the external input apparatus of the embodiment. The table | surface which shows the number data and fixed pattern data which are recorded on the lighting control unit of the embodiment. The sequence chart which shows roughly the lighting data rewriting operation | movement of the embodiment. 6 is a sequence chart schematically showing a data output operation of the embodiment. The block diagram which shows schematic structure of the lighting control system of other embodiment. The sequence chart which shows roughly the data output operation | movement of other embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Lighting control system, 2 ... Overall control unit (overall control apparatus), 4 (4a-4d) ... Lighting control unit (lighting control apparatus), 6 ... External input apparatus, 12 ... Update control part, 22 ... Lighting control means A lighting control unit, 22M, a memory as recording means, 24, a neon unit as a light emitter.

Claims (5)

Based on the pattern data recorded on the recording means and recording means for recording the pattern data when a plurality of pattern data indicating the time-series change pattern of the lighting pattern of the light emitter is input from the external input device The lighting control of the light emitter is performed, and the pattern data is updated every time a preset periodic update time elapses to change the lighting mode of the light emitter, and execution data indicating the pattern data during the lighting control is displayed. A plurality of lighting control devices including a lighting control means for performing data output control to be output to the external input device, and each lighting control between the lighting control means of the plurality of lighting control devices and the external input device. Connected to the network when the pattern data is input from the external input device, the pattern data is sent to the corresponding lighting control means. A lighting control system comprising a general control device for force,
Each of the lighting control means records the pattern data in a state in which number data is associated with each of the pattern data when the plurality of pattern data is input from the external input device via the overall control device. Data recording control to be recorded in the means, and lighting control for turning on the light emitter with a lighting pattern based on pattern data corresponding to the input number data when number data is input from the overall control device And performing data output control to output execution data indicating the pattern data under lighting control to the external input device via the overall control device,
The overall control device sequentially outputs number data recorded therein to each lighting control means via the network to update the pattern data, and the execution data is input from the lighting control means. And a data output mediation control for outputting the execution data to the external input device.   2. The lighting control according to claim 1, wherein the lighting control unit performs the data output control on condition that a data request signal for requesting output of the execution data is input from the external input device. system.   When the data designation signal indicating that one of the plurality of pattern data is designated is input from the external input device, the lighting control means uses the pattern data designated by the data designation signal as start data. The lighting control system according to claim 1 or 2, wherein lighting control is started.   When the lighting control signal indicating that the lighting state is to be held is input from the external input device, the lighting control unit stops updating the pattern data, thereby holding the lighting state of the light emitter at that time. The lighting control system according to claim 1, wherein the lighting holding control is performed. Based on the pattern data recorded on the recording means and recording means for recording the pattern data when a plurality of pattern data indicating the time-series change pattern of the lighting pattern of the light emitter is input from the external input device A plurality of lighting control devices including lighting control means for performing lighting control of the luminous body and changing the lighting mode of the luminous body by updating the pattern data each time a preset periodic update time elapses. In addition, when the pattern data is input from the external input device, the pattern data is associated with each lighting control unit connected between the lighting control unit of the lighting control device and the external input device. A lighting control system including a general control device that outputs to a lighting control means,
Each of the lighting control means records the pattern data in a state in which number data is associated with each of the pattern data when the plurality of pattern data is input from the external input device via the overall control device. Data recording control to be recorded in the means, and lighting control to turn on the light emitter with a lighting pattern based on the pattern data corresponding to the input number data when the number data is input from the overall control device ,
The overall control device is configured to update the pattern data by sequentially outputting the number data recorded therein to the lighting control means via the network, and the updated number data to the external input device. A lighting control system characterized by performing data output mediation control for output to a lamp.

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