JP2020039788A - Light emission performance system - Google Patents

Abstract

To provide a light emission performance tool that even in the case of being the light emission performance tool outside a main site in which an event is held, enables synchronization with a light emission mode of the light emission performance tool inside the main site.SOLUTION: A light emission performance system 100 comprises: a light emission control circuit for receiving a light emission control signal HCS from a centralized light emission control device 30 to control a light emission mode of a light emission body; a light emission round fan 10 for transmitting a motion detection signal MDS by a motion sensor to the centralized light emission control device 30; a light emission control signal generation unit for generating the light emission control signal HCS for making the light emission round fan 10 be in a specific light emission mode; and the centralized light emission control device 30 for receiving the motion detection signal MDS from the motion sensor. On the basis of the motion detection signal MDS, the light emission control signal generation unit generates an additional light emission control signal ACS and transmits the ACS to the light emission round fan 10. On the basis of the additional light emission control signal ACS, the light emission control circuit controls the light emission mode of the light emission body.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a light-emitting effect system using a light-emitting effect device, and more particularly, to a light-emitting effect system capable of synchronizing a staging operation even in a remote place by Internet communication.

  2. Description of the Related Art A luminous performance tool such as a penlight is known as a tool for producing a further excitement in a concert hall or the like. In order to enhance the production effect of the venue using such a luminous performance tool, there is a limit to the livelihood production of the venue in the production of simple luminescence only, and it is known that a variety of luminescence modes can be provided. I have.

  With respect to a light emitting effect system using such a light emitting effect device, the light emitting mode of the light emitter of the light emitting effect device is controlled as disclosed in Patent Document 1 (Japanese Patent Application Laid-Open No. 2015-2958) by the applicant. At this time, a configuration has been proposed in which a light emission control signal transmitted from the centralized light emission control device to the light emission performance tool is transmitted using a carrier wave based on sound waves. By adopting such a configuration of the light emitting effect system, the event organizer can control all of the light emitting effects held by the visitors in the venue to an arbitrary light emitting mode.

JP, 2015-2958, A (claim 1 etc.)

  2. Description of the Related Art In recent years, in an event such as a sports tournament, a number of spectators who have not entered the main venue where the event is held have gathered at the public viewing venue and have been trying to excite them with the audience in the main venue. For this reason, within the main venue where the event is held, the light emission mode of the luminous performance tool held by the visitor can be collectively controlled by the event organizer, but the main venue such as a public viewing venue can be controlled. However, there is a problem that it is not possible to perform collective control as in the light emitting mode of the light emitting performance tool in the main hall outside the hall.

  Therefore, the present invention has an object to provide a luminous effect production system using a luminous effect tool that can be synchronized with the luminous mode of the luminous effect tool inside the venue, even if the luminous performance device is outside the venue. I have.

  As a result of intensive studies made by the inventor to solve the above-mentioned problems, the following structure has been conceived. That is, the present invention is a light emitting effect system using a plurality of light emitting effects, and a centralized light emission control device that can be interconnected with the light emitting effects via Internet communication, wherein the light emitting effects, power supply A light emitter, a first receiver for receiving a light emission control signal emitted from the centralized light emission controller via the Internet communication, and the light emitter based on the light emission control signal received by the first receiver. A light emission control circuit that controls a light emission mode of the light emitting device, a motion sensor, and a first transmission device that transmits an operation detection signal from the motion sensor to the centralized light emission control device via the Internet communication. A control device, a light emission control signal generation unit that generates the light emission control signal for setting a light emission mode of the light emitting body in the light emission performance tool to a specific light emission mode; A second transmitting device that transmits the light emission control signal to the outside via the Internet communication; and a second transmitting device that receives the operation detection signal transmitted from the first transmitting device of the light emitting device via the Internet communication. And a receiving device, wherein when the operation detection signal is transmitted from the light emission performance tool to the centralized light emission control device, the light emission control signal generation unit generates an additional light emission control signal based on the operation detection signal. Operation, the second transmission device transmits the additional light emission control signal to the light emission director, which is the source of the operation detection signal, and the light emission control circuit controls the light emission of the light emitter based on the additional light emission control signal. And an operation of prioritizing the light emission mode to the light emission mode of the light emitter based on the light emission control signal.

  Thereby, even if the light emitting performance tool is outside the main venue, it can be synchronized with the light emitting mode of the light emitting performance tool inside the main venue. In addition, since the light emission mode of the light emitting body can be changed in accordance with the operation of each light emitting effect tool, the effect of the light emitting effect system can be enhanced.

  Further, time information at the time of detecting the operation of the motion sensor is linked to the operation detection signal, and the light emission control signal generating unit links the time information to the additional light emission control signal, It is preferable that the circuit controls the light emission mode of the light emitter in the order of the time information linked to the additional light emission control signal.

  This makes it possible to change the light emission mode of the light-emitting performance tool according to the operation of the light-emitting performance tool held by the visitor over time, thereby further improving the performance effect of the light-emitting performance system.

  Further, the light emission control signal generation unit associates control duration information specifying a control duration with the additional light emission control signal, and the light emission control circuit is configured to emit light of the light emitter based on the additional light emission control signal. It is preferable to perform the control over the control continuation time, and after the control continuation time elapses, return to the light emission mode of the light emitter based on the light emission control signal.

  With these, it is possible to maintain the basic light emitting mode of the light emitting effect tool in the light emitting effect system, and to switch between the basic light emitting mode and the additional light emitting mode according to the event. Can be improved.

  The light emission control signal is a basic light emission control signal that controls the light emission mode of the light emission performance tool before the light emission mode of the light emission performance tool is controlled by the centralized light emission control device; And a designated light emission control signal for directly controlling the light emission mode of some of the designated light emission performance tools.

  This allows the event organizer to set the light emission performance tool held by the visitor to an arbitrary light emission mode, thereby realizing the light emission effect intended by the event organizer.

  The storage unit of the centralized light emission control device stores in advance operation mode switching determination data for determining whether or not the operation mode of the light emission performance tool needs to be switched from the operation detection signal, When the operation control unit determines that the operation detection signal transmitted from the light-emitting performance tool satisfies the condition specified in the operation mode switching determination data, the operation control unit determines in advance that the storage unit For each of the operation detection signals transmitted from the light-emitting performance device over the operation mode switching time stored in the operation mode switching time, the total value of the number of the light-emitting performance devices to which the operation detection signal is transmitted and the signal intensity of the motion detection signal Executing a voting operation mode for calculating a cumulative value of the operation mode, and after elapse of the operation mode switching time, the operation control unit sends the light emission control signal generation unit the light emission control signal generation unit. Along with generating the voting result light emission control signal based on the cumulative value of the tool and the cumulative value of the signal strength, the second transmission device transmits the voting result light control signal to the light emission performance device, and It is preferable that the light emission control circuit controls the light emission mode of the light emitter based on the voting result light emission control signal for a preset voting result output time.

  Further, the operation detection signal in the voting operation mode is associated with the position information of the light-emitting effector, and the operation control unit determines a signal intensity and an operation detection duration for each operation of detecting the operation detection signal. It is more preferable to calculate a totaling result based on the position information with respect to the total value of and to output the totaling result over a predetermined output time to an output unit.

  As a result, during the event, a voting game by the event participants can be performed, and the excitement of the venue can be further improved.

  By employing the configuration of the light emitting effect system according to the present invention, even a light emitting effect device outside the main venue can be synchronized with the light emitting mode of the light emitting effect device in the main room. In addition, since the light emission mode of the light emitter can be changed in accordance with the operation of each light emitting effect, the effect of the light emitting effect system in the main hall and outside the main hall can be enhanced.

It is a schematic structure figure of a light emission production system in this embodiment. It is a lineblock diagram of a luminous production tool in this embodiment. It is a block diagram of the centralized light emission control device in this embodiment. It is a block diagram of the centralized light emission control device in a modification. It is an outline operation | movement flowchart of the light emission production system in this embodiment. FIG. 6 is a schematic operation flowchart when a switching flow to a voting mode is activated in the schematic operation flow illustrated in FIG. 5.

  Hereinafter, the light emitting effect system 100 according to the present invention will be described. As shown in FIG. 1, a light emitting effect system 100 according to the present embodiment includes a centralized light emitting control that can be interconnected with a light emitting fan 10 as a plurality of light emitting effects and an light emitting fan 10 via an Internet communication network 20 as Internet communication. And an apparatus 30. In the light-emitting effect system 100 according to the present embodiment, the centralized light-emission control device 30 controls the light-emitting mode of the light-emitting body 12 mounted on the light-emitting fan 10 between remote locations via the Internet communication network 20 so as to be a specific light-emitting mode. It is characterized by doing.

  As shown in FIG. 2, the light emitting fan 10 according to the present embodiment includes a battery 11 as a power source, a light emitting body 12, and a first transmitting / receiving device 13 that transmits and receives data between the centralized light emitting control device 30. A light emission control circuit 14 that controls the light emission mode of the light emitter 12 to be a specific light emission mode based on a light emission control signal HCS transmitted from the centralized light emission control device 30, a motion sensor 15, a light emission control signal HCS, and the like. And an operation switch 17.

  The battery 11 in the present embodiment is housed in the grip 10A of the light emitting fan 10. The luminous body 12 is appropriately disposed on the fan surface 10B of the luminous fan 10. The luminous bodies 12 are provided on the fan surface 10B in an arrangement capable of providing the specific light emission mode required in the light emitting effect system 100 on the fan surface 10B. As the illuminant 12, a known configuration typified by an LED, an organic EL, or the like can be employed, and a detailed description of the configuration will be omitted.

  When an LED is used as the illuminant 12, the illuminant 12 is disposed at a predetermined interval on the frame 10C of the fan 10B as shown in FIG. 2, and the irradiation light of the LED is attached to the fan 10B. Output to the outside through the formed film body. In addition, a mode in which the luminous body 12 is appropriately disposed on the fan surface portion 10B and a mode in which an organic EL is used as the luminous body 12 can be adopted. When an organic EL is used as the light emitting body 12, a form in which the fan 10B is formed by the organic EL or a form in which the organic EL is attached to a film constituting the fan 10B can be adopted.

  As shown in FIG. 3, the first transmission / reception device 13 can receive the light emission control signal HCS transmitted from the second transmission / reception device 32 (the second transmission device 32A) of the centralized light emission control device 30 via the Internet communication network 20. It has a first receiving device 13A and a first transmitting device 13B that transmits the operation detection signal MDS detected by the motion sensor 15 to the centralized light emission control device 30 via the Internet communication network 20. Since the second transmitting / receiving device 32 can adopt the same configuration (second transmitting device 32A, second receiving device 32B) as the first transmitting / receiving device 13, detailed description is omitted here. As described above, the first transmitting / receiving device 13 and the second transmitting / receiving device 32 enable the plurality of light emitting fans 10 and the centralized light emission control device 30 to be connected to each other via the Internet communication network 20.

  The light emission control circuit 14 emits the light emission control signal HCS from the second transmission device 32A of the centralized light emission control device 30 and received by the first reception device 13A and stored in the storage unit 16 represented by a nonvolatile memory. The light emission mode of the light emitting body 12 is controlled based on the above. The light emission control circuit 14 performs control to change the light emission mode of the light emitter 12 in a time-series or color manner based on the light emission control signal HCS read from the storage unit 16.

  The light emission control signal HCS according to the present embodiment controls the light emission mode of the light emitter 12 so that the light emission fan 10 becomes the basic light emission mode before the control of the light emission mode by the centralized light emission control device 30 (when entering the event venue). A basic light emission control signal BCS for control and designated light emission control for controlling the light emission mode of the light emitter 12 in at least one light emission fan 10 (a part of the light emission fan 10) specified by the centralized light emission control device 30 Signal PCS. By employing such a configuration of the emission control signal HCS, the event organizer can arbitrarily control the emission mode of the emission fan 10. This allows the event organizer to control the light emitting mode of the light emitting fan 10 before the event is held and the light emitting mode of the light emitting fan 10 immediately before the event is held or at the start of the event. It can greatly excite the event venue.

  The motion sensor 15 is provided on the gripping portion 10A of the light emitting fan 10 and detects an operation of the light emitting fan 10 by a visitor holding the light emitting fan 10. In the present embodiment, the motion sensor 15 is provided on the grip 10A of the light emitting fan 10 as shown in FIG. 2, but the motion sensor 15 may be provided on the fan surface 10B. As the motion sensor 15, a sensor configured by combining an acceleration sensor, a gyro sensor, and the like is preferably used. According to the motion sensor 15, the acceleration, inclination, moving direction, rotation state, and the like of the light emitting fan 10 can be detected. The motion detection signal MDS detected by the motion sensor 15 is transmitted from the first transmission device 13B to the second reception device 32B of the centralized light emission control device 30 shown in FIG. Is stored in a storage unit 36 such as a nonvolatile memory.

  The motion sensor 15 according to the present embodiment links the time information TD at the time of detecting the operation to the operation detection signal MDS detected based on the operation of the light emitting fan 10. Although the time information TD in the present embodiment employs Japan Standard Time (JST), it is also possible to use Coordinated Universal Time (UTC). Adopting such a standard time is advantageous in that time information in the light emitting fan 10 and the centralized light emission control device 30 between remote locations can be unified. The operation detection signal MDS to which the time information TD is linked in this way is transmitted from the first transmission device 13B to the centralized light emission control device 30 (second reception device 32B) shown in FIG. 3 via the Internet communication network 20. .

  Like the operation detection signal MDS in the present embodiment, by linking the time information TD when the motion sensor 15 detects the operation of the light emitting fan 10, the light emission control signal generation unit 34 of the centralized light emission control device 30 The additional light emission control signal ACS based on the operation detection signal MDS can be finely generated in time series. As such a usage pattern, it is possible to exemplify the control of the light emission mode of the light emitting fan 10 according to the choreography of the song, and it is advantageous in that the light emission effect at the event venue can be made richer. .

  As shown in FIG. 3, the light emission control signal generation unit 34 in the present embodiment is configured to store the light emission mode database DB stored in the storage unit 36 in advance based on the operation detection signal MDS and the time information TD stored in the storage unit 36. , The element information ELn (n is a natural number) of the light emission mode is read out, and an additional light emission control signal ACS corresponding to each operation detection signal MDS is generated. Here, a form in which the element information ELn of the light emission mode is sequentially adopted in time series is illustrated, but a combination of the content of the operation detection signal MDS and the time information TD is linked to the element information ELn of the light emission mode. It is also possible to adopt a mode in which the element information ELn of the light emission mode is made to correspond to the operation detection signal MDS only when the condition is met. Adopting such a configuration is advantageous in that even if the motion sensor 15 detects an operation unnecessary for the light emission effect, the operation detection signal MDS can be prevented from being reflected in the light emission effect. .

  Further, the light emission control signal generation unit 34 associates the time information TD of the operation detection signal MDS with the additional light emission control signal ACS, and specifies the control duration of the light emission mode of the light emitter 12 based on the additional light emission control signal ACS. Control duration information KJ can be added.

  The additional light emission control signal ACS generated by the light emission control signal generator 34 in this manner is transmitted from the second transmitter 32A via the Internet communication network 20 to the light emission fan 10 (the first receiver) of the operation detection signal MDS. 13A). When the first receiving device 13A receives the additional light emission control signal ACS, the process for storing the additional light emission control signal ACS in the storage unit 16 and the control of the light emission mode of the light emitter 12 based on the additional light emission control signal ACS by the light emission control circuit 14 are controlled for the control duration. Executes for the time specified by information KJ.

  The light emission control circuit 14 that has received the additional light emission control signal ACS as described above controls the light emission mode of the light emitter 12 based on the additional light emission control signal ACS, and controls the light emission mode of the light emitter 12 based on the light emission control signal HCS. Execute prior to control. In addition, the light emission control circuit 14 controls the light emission mode of the light emitter 12 along the order of the time information TD linked to the additional light emission control signal ACS and for the time specified by the control duration information KJ. When the operation control of the light emission mode of the light emitter 12 by all the additional light emission control signals ACS is completed, the light emission control circuit 14 performs control to return to the light emission mode of the light emitter 12 based on the light emission control signal HCS. At this time, the light emission control circuit 14 is preset by the event organizer to select either the basic light emission control signal BCS or the designated light emission control signal PCS among the light emission control signals HCS.

  The light emitting effect system 100 according to the present embodiment can also be switched to a visitor voting operation mode by the operation of the light emitting fan 10. In order to execute the voting operation mode, as shown in FIG. 4, an operation of determining whether or not the operation mode of the light emitting fan 10 needs to be switched in the storage unit 36 of the centralized light emission control device 30 based on the operation detection signal MDS. The mode switching determination data MCD and the operation mode switching time information MCT that defines the duration of the switched operation mode are additionally stored in advance. Further, the centralized light emission control device 30 refers to the operation detection signal MDS to the operation mode switching determination data MCD to determine whether or not the operation mode needs to be switched (necessary to switch to the voting operation mode). Are additionally provided.

  The operation control unit 38 stores the operation detection signal MDS transmitted from the light emitting fan 10 in the time zone designated by the event organizer (always or a specific time zone) in the operation mode switching determination data MCD stored in the storage unit 36. To reference. If the operation detection signal MDS satisfies the detection operation conditions defined in the operation mode switching determination data MCD, it is determined that switching to the voting operation mode is requested, and the switching request count value CRV having an initial value of 0 is set. Is incremented by one. The operation control unit 38 compares the switching request count value CRV stored in the storage unit 36 with the switching determination value JV defined in the operation mode switching determination data MCD, and determines whether the switching request count value CRV is the operation mode. When the value exceeds the switching determination value JV defined in the switching determination data MCD, the light emitting effect system 100 is switched to the voting mode. The continuation time of switching to the voting mode is performed over the time specified in the operation mode switching time information MCT stored in the storage unit 36.

  During the switching to the voting mode, the motion sensor 15 links the motion detection signal MDS with the position information given in advance to the light emitting fan 10 and transmits the motion detection signal MDS to the centralized light emission control device 30. The position information of the light-emitting fan 10 is obtained from a MAC address or an access point assigned to an access point (not shown) of the first transmitting / receiving device 13 to the Internet communication network 20 or a satellite provided at a main venue, a public viewing venue, or the like. It can be obtained from the positioning system. It is preferable that the motion detection signal MDS includes a signal strength (an index indicating the intensity of the motion) and a motion detection continuation time for each motion of the light emitting fan 10 detected by the motion sensor 15.

  The operation control unit 38 of the centralized light emission control device 30 performs the voting data totalizing process using the operation detection signal MDS transmitted from each light emitting fan 10. Specifically, the operation control unit 38 calculates the signal intensity of the operation detection signal MDS and the signal intensity / time integrated value STV of the operation detection continuation time, and also accumulates the signal intensity / time integrated value STV for each position information. The process of storing the signal strength / time integrated cumulative value ACV in the storage unit 36 is performed over the time specified in the operation mode switching time information MCT. The cumulative value of the number of light emitting fans 10 (the number of participants in the voting mode) that have transmitted the operation detection signal MDS can be counted and stored in the storage unit 36. When the time specified in the operation mode switching time information MCT elapses, the voting mode ends.

  When the voting mode ends, the operation control unit 38 emits a voting result based on the signal strength / time integrated cumulative value ACV for each position information stored in the storage unit 36 in the light emission control signal generation unit 34 and the number of participations in the voting mode. A control signal VRS is generated, and the second transmission device 32A transmits the voting result light emission control signal VRS to the light emitting fan 10. It is preferable that the voting result light emission control signal VRS be associated with the control duration of the light emission mode of the light emitter 12 based on the voting result light emission control signal VRS as voting result output time information.

  When the light emitting fan 10 receives the voting result light control signal VRS, the light emission control circuit 14 controls the light emission mode of the light emitter 12 based on the voting result light control signal VRS for a time specified in the voting result output time information. . At this time, the operation control unit 38 of the centralized light emission control device 30 calculates the aggregation result calculated based on the position information of each operation detection signal MDS for the signal strength / time integrated cumulative value ACV for each operation of detecting the operation detection signal MDS. It is also possible to output to a monitor as an output unit (not shown) installed in the main hall or the public viewing hall for a predetermined output time. The output time to the monitor may be stored in the storage unit 36 of the centralized light emission control device 30 in advance.

  When the control of the light emission mode of the light emitter 12 based on the voting result light emission control signal VRS is completed, the light emission control circuit 14 returns to the control of the light emission mode of the light emitter 12 by the light emission control signal HCS. By installing the voting mode as described above in the light emitting effect system 100, a voting game can be performed between the respective venues, and the voting results between the respective venues such as the main venue and the public viewing venue can be displayed. This is advantageous in that the output to the monitor can further increase the excitement of visitors.

  Next, a light emitting effect method using the light emitting effect system 100 according to the present embodiment will be described. FIG. 5 is a schematic flow chart showing the light emitting effect method in the present embodiment. A light emission control signal HCS is transmitted from the centralized light emission control device 30 on the event organizer side to the light emission fan 10 held by the visitor via the Internet communication network 20 (step 1). The light emission fan 10 receiving the light emission control signal HCS controls the light emission mode of the light emitter 12 based on the light emission control signal HCS by the light emission control circuit 14 (step 2). The light emission control signal HCS includes a basic light emission control signal BCS for the entire light emission fan 10 and a designated light emission control signal PCS for directly controlling the light emission mode of the light emitter 12 of the light emission fan 10 designated by the event organizer. The light emission mode of the light emitter 12 is controlled by the light emission control circuit 14 based on the received light emission control signal HCS. In particular, the designated light emission control signal PCS is advantageous because the light emission effect intended by the event organizer can be executed from before the event is held until the end of the event.

  When the light emitting fan 10 performs a predetermined operation by a visitor after the event starts, the motion sensor 15 generates an operation detection signal MDS and transmits it to the centralized light emission control device 30 (step 3). When the centralized light emission control device 30 receives the operation detection signal MDS, the light emission mode element information ELn (n is a natural number) in the light emission mode database DB of the storage unit 36 is obtained from the time information TD associated with the operation detection signal MDS. It reads out and generates an additional light emission control signal ACS corresponding to each operation detection signal MDS and transmits it to the light emission fan 10 (step 4). The operations in steps 3 and 4 are repeatedly performed until the motion sensor 15 detects the additional detection of the motion detection signal MDS, or until there is no element information ELn of the light emission mode corresponding to the operation detection signal MDS in the light emission mode database DB. Upon receiving the additional light emission control signal ACS, the light emission fan 10 controls the light emission mode of the light emitter 12 based on the additional light emission control signal ACS, prior to the light emission control signal HCS (step 5).

  Immediately before the end of the event, the centralized light emission control device 30 again transmits the last light emission control signal HCS to the light emission fan 10 via the Internet communication network 20 (step 6). The last light emission control signal HCS transmitted to the light emission fan 10 immediately before the end of the event always includes a light emission mode control command, light emission mode control time information, and clear information. The light emission control circuit 14 of the light emission fan 10 controls the light emission mode of the light emitter 12 over the time specified by the light emission mode control time information based on the last light emission control signal HCS received immediately before the end of the event (step 7). ). Thereafter, the light emission control circuit 14 executes a process of erasing the light emission control signal HCS and the additional light emission control signal ACS stored in the storage means 16 (END).

  After the light emission control signal HCS and the additional light emission control signal ACS are erased from the storage means 16, the owner of the light emitting fan 10 presses the operation switch 17 to arbitrarily or the light emission mode pattern stored in the storage means 16 in advance. Can be used by sequentially switching the light emission mode of the light emitting body 12 along the line. The light emission mode pattern stored in the storage means 16 in advance can be downloaded from the centralized light emission control device 30 or another data server using the Internet communication network 20.

  The switching flow to the voting mode can be executed by the centralized light emission control device 30 at an arbitrary timing after step 3 or at a time designated by the event organizer. Hereinafter, a flow of switching to the voting mode will be described with reference to FIG.

  When entering the voting mode switching flow, the operation control unit 38 of the centralized light emission control device 30 determines whether the operation detection signal MDS satisfies the condition specified in the operation mode switching determination data MCD (S- 1). When the operation control unit 38 determines that the operation detection signal MDS satisfies the condition specified in the operation mode switching determination data MCD, the storage unit 36 increases the switching request count value CRV by one from 0 (S -2). Do nothing if the conditions are not met. The operation control unit 38 determines whether or not the switching request count value CRV has exceeded the switching determination value JV (S-3), and when it determines that the switching request count value CRV has exceeded the switching determination value JV, the operation control unit 38. Numeral 38 executes the voting operation mode for the time specified in the operation mode switching time information MCT stored in the storage unit 36 in advance (S-4). If it is determined that the switching request count value CRV does not exceed the switching determination value JV, nothing is performed. When the switching request count value CRV within the predetermined time does not exceed the predetermined value, the operation control unit 38 performs a process of rejecting the switching request.

  When the voting operation mode is executed, the cumulative value of the number of light emitting fans 10 that transmitted the operation detection signal MDS during the execution of the voting operation mode (voting mode participation number) and the detection signal for each detection operation of the operation detection signal MDS A signal strength / time integrated total value ACV, which is a cumulative value of the product of the signal strength and the operation continuation time, is calculated and stored in the storage unit 36 (S-5). When the time specified in the operation mode switching time information MCT elapses, the operation control unit 38 causes the light emission control signal generation unit 34 to output the voting result light emission control signal VRS based on the number of voting mode participations and the signal strength / time integrated cumulative value ACV. Is generated and transmitted from the second transmission device 32A to the light-emitting fan 10 (S-6). When the light emitting fan 10 receives the voting result light emission control signal VRS, the light emission control circuit 14 controls the light emission mode of the light emitter 12 based on the voting result light emission control signal VRS (S-7). The control of the light emission mode of the light emitter 12 based on the voting result light control signal VRS ends after a preset voting result output time, and returns to the control of the light emission mode of the light emitter 12 based on the normal light emission control signal HCS ( The voting mode is ended) (S-END).

  In addition, the operation control unit 38 generates the voting result light emission control signal VRS and transmits the signal to the light emission fan 10 (S-6), and then determines whether or not the position information of the light emission fan 10 is linked to the operation detection signal MDS. (SS-1) may be added. The linking of the position information to the light emitting fan 10 can be realized by incorporating a signal receiver of the satellite positioning system in the light emitting fan 10 or by setting in advance based on the distribution place of the light emitting fan 10. is there. If the position information of the light-emitting fan 10 is linked to the motion detection signal MDS, a process of calculating the sum of the signal strength / time integrated cumulative value ACV based on the position information (SS-2) is executed. If the position information of the light emitting fan 10 is not linked to the operation detection signal MDS, the process proceeds to (S-7). Then, (SS-3) of outputting the tally result (voting result) to a monitor (not shown) installed at the venue as an output unit for a predetermined output time may be executed. As the predetermined output time, a form in which the predetermined output time is stored in the storage unit 36 in advance or a form in which a time designated by the event organizer is used can be adopted.

  As described above, when the voting mode is executed in an event which is simultaneously held in a plurality of venues such as a main venue and a public viewing venue based on the position information associated with the light-emitting fan 10, when the voting mode is executed, Presenting the totaled voting results to the visitor is advantageous in that the excitement of the venue in the voting mode can be improved. After executing the step (SS-3), the process proceeds to the step (S-7), and the display flow of the tally result in the voting mode ends.

  As described above, since the communication between the light-emitting fan 10 and the centralized light-emission control device 30 is performed via the Internet communication network 20, the light-emitting fan 10 of the visitor of the event site and a location remote from the event site. The light emission mode of the light emitter 12 can be synchronized with the light emission fan 10 of the visitor of the venue. That is, the visitor can obtain the same excitement as in the event venue not only at the event venue but also at other places.

  As described above, the light emitting effect system 100 according to the present invention has been described in detail based on the embodiment. However, the technical scope of the present invention is not limited to the above embodiment. For example, in the above embodiment, the light emission control signal generation unit 34 of the centralized light emission control device 30 performs a process of linking the time information TD linked to the operation detection signal MDS to the additional light emission control signal ACS. However, this processing is not essential. In addition, the light emission control signal generation unit 34 executes a process of linking the control light emission control signal ACS with control duration information KJ that specifies the light emission control duration of the light emitting body 12 based on the additional light emission control signal ACS. However, this is not required.

  When the time information TD at the time of detecting the operation by the motion sensor 15 is not linked to the additional light emission control signal ACS, the light emission control circuit follows the order of reception of the additional light emission control signal ACS by the first transceiver 13 of the light emitting fan 10. What is necessary is just to perform the process in which the light emitting mode of the light emitting body 12 is sequentially controlled. If the light emission control signal generator 34 does not link the control duration information KJ to the additional light emission control signal ACS, the specified duration specified in advance by the event organizer or the first receiving device 13A The light emission control circuit 14 may control the light emission mode of the light emitter 12 based on the additional light emission control signal ACS until the next light emission control signal ACS is received.

  Further, the light emission control circuit 14 according to the present embodiment controls the light emission mode of the light emitter 12 based on the additional light emission control signal ACS, and then performs control to return to the light emission mode of the light emitter 12 based on the light emission control signal HCS. However, after controlling the light emission mode of the light emitting body 12 based on the additional light emission control signal ACS, a process of turning off the light emitting body 12 may be performed.

  Then, it is also possible to adopt a form in which the form described in the above embodiment and the above-described modification are appropriately combined.

10 luminous fan, 10A grip, 10B fan, 10C skeleton,
11 battery,
12 luminous body,
13 first transmitting / receiving device, 13A first receiving device, 13B first transmitting device,
14 emission control circuit,
15 motion sensor,
16 storage means,
17 operation switch,
20 Internet communication network,
30 centralized light emission control device,
32 second transmitting / receiving device, 32A second transmitting device, 32B second receiving device,
34 light emission control signal generator,
36 storage unit,
38 operation control unit,
100 luminous production system,
HCS emission control signal, BCS basic emission control signal, PCS designated emission control signal,
MDS operation detection signal, TD time information,
DB Emission mode database, ELn element information,
ACS additional light emission control signal, KJ control duration information,
MCD operation mode switching determination data, MCT operation mode switching time information,
CRV switching request count value, JV switching judgment numerical value,
STV signal strength / time integrated value, ACV signal strength / time integrated value,
VRS Voting result light emission control signal

Claims (6)

A light emission production system using a plurality of light emission effectors, and a centralized light emission control device that can be interconnected with the light emission effector via Internet communication,
The luminous performance tool,
A power supply, a luminous body, a first receiving device that receives a light emission control signal emitted from the centralized light emission control device via the Internet communication, and a first reception device that receives the light emission control signal based on the light emission control signal received by the first reception device. A light emission control circuit that controls a light emission mode of the light emitter, a motion sensor, and a first transmission device that transmits an operation detection signal by the motion sensor to the centralized light emission control device via the Internet communication,
The centralized light emission control device,
A light emission control signal generation unit that generates the light emission control signal for setting the light emission mode of the light emitter in the light emission effector to a specific light emission mode, and a light emission control signal that transmits the light emission control signal to the outside via the Internet communication 2 transmitting device, and a second receiving device for receiving the operation detection signal transmitted from the first transmitting device of the light emitting effector via the Internet communication,
When the operation detection signal is transmitted to the centralized light emission control device from the light emission performance tool,
An operation in which the light emission control signal generation unit generates an additional light emission control signal based on the operation detection signal;
An operation in which the second transmission device transmits the additional light emission control signal to the light emission performance device that is a transmission source of the operation detection signal;
The light emission control circuit executes an operation of prioritizing a light emission mode of the light emitter based on the additional light emission control signal over a light emission mode of the light emitter based on the light emission control signal, respectively. . The motion detection signal is linked with time information at the time of detecting the motion of the motion sensor,
The light emission control signal generator associates the time information with the additional light emission control signal,
The light emission production system according to claim 1, wherein the light emission control circuit controls a light emission mode of the light emitter according to an order of the time information associated with the additional light emission control signal. The light emission control signal generator associates control duration information specifying a control duration with the additional light emission control signal,
The light emission control circuit controls the light emission mode of the light emitter based on the additional light emission control signal over the control duration time, and after the control duration time elapses, the light emission body of the light emitter based on the light emission control signal The light emission production system according to claim 1 or 2, wherein the light emission mode is returned to a light emission mode. The light emission control signal is
A basic light emission control signal for controlling the light emission mode of the light emission effector before the light emission effector of the light emission effector is controlled by the centralized light emission controller, and a part of the light emission effect specified by the central light emission controller. The light emission production system according to any one of claims 1 to 3, further comprising: a designated light emission control signal when directly controlling the light emission mode of the tool. In the storage unit of the centralized light emission control device, operation mode switching determination data for determining whether to switch the operation mode of the light emitting performance tool from the operation detection signal is stored in advance,
When the operation control unit of the centralized light emission control device determines that the operation detection signal transmitted from the light emission performance tool satisfies the condition specified in the operation mode switching determination data, the operation control unit The cumulative value of the number of the light-emitting effects devices to which the operation detection signal is transmitted and the operation for each of the operation detection signals transmitted from the light-emitting effect devices over the operation mode switching time stored in the storage unit in advance. Execute the voting operation mode for calculating the cumulative value of the signal strength of the detection signal,
After the operation mode switching time has elapsed, the operation control unit causes the light emission control signal generation unit to generate a voting result light emission control signal based on the total value of the light emission performance tool and the total value of the signal intensity, Causing the second transmission device to transmit the voting result light emission control signal to the light emission performance tool,
5. The light emission control circuit of the light emitting effector controls the light emission mode of the light emitter based on the voting result light emission control signal for a preset voting result output time. 6. The light-emission production system according to any one of the above. In the operation detection signal in the voting operation mode, position information of the light emitting performance tool is linked,
The operation control unit calculates an aggregation result based on the position information with respect to the signal strength and the cumulative value of the operation detection duration for each detection operation of the operation detection signal, and outputs the aggregation result to an output unit in a predetermined manner. The light emission production system according to claim 5, wherein the light emission effect system is output over time.

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