JP2016126968A - Light emission control system and method of using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a light emission control device side to visually specify the position of each of plural light emission devices when predetermined characters/pictures and hue patterns are expressed/represented by plural light emission devices.SOLUTION: A light emission control system for controlling plural light emission devices each having a light emission part, a signal receiver and an individually different identifier to emit light in predetermined patterns comprises light emission control means for transmitting a light emission instruction to a light emission device specified by a predetermine identifier out of the plural light emission devices, and transmitting an instruction of imaging the specified light emission device to an imaging part, the imaging part for imaging the specified light emission device and a reference object upon reception of the instruction, position information extraction means for calculating position information on the position relationship between the specified light emission device and the reference object from an image picked up by the imaging part, and a storage part for storing the position information calculated by the position information extraction means in association with the predetermined identifier.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a light emission control system that enhances a production effect in an event venue such as a concert venue or a stadium.

  There are various production methods to enhance the atmosphere in event venues such as concert venues and stadiums. In particular, in the production method that enhances the visual effect by using the illumination device, an example is an effect in which a spectator is provided with an LED penlight, etc., and light emission from the penlight is controlled to draw a predetermined figure or color pattern. is there.

  In recent years, with the development of wireless communication technology, each light-emitting device is assigned an address corresponding to the seat position of the venue, and given to the visitors, the light-emitting control is performed from the control device to each light-emitting device. A signal is transmitted and a predetermined character / picture or color pattern is expressed on the entire scale of the venue (for example, Patent Document 1).

  However, in a large-scale venue, it is difficult to fully match the individual light emitting devices of the audience with the seat position, such as the spectator moving during the event or passing the light emitting device with the wrong address. . Therefore, in Patent Document 2, it is also devised that the light emitting device has a function of specifying the current position such as GPS, and the position information of each light emitting device is transmitted to the control device side, and light emission control is performed based on this information. .

JP 2003-36981 A JP 2005-251443 A

  However, GPS does not provide accuracy of the installation position, and cannot be applied to directional light emitting devices. In addition, mounting a GPS module on each light emitting device increases the cost and is a problem.

  The present invention has been made in view of the above-described problems, and proposes a light-emitting device control system that can visually identify the position of a light-emitting device to which an address is assigned from the light-emission control device side, and that can be quickly associated. It is.

  A light emission control system according to one aspect of the present invention causes a plurality of light emitting devices including a light emitting unit, a signal receiving unit, and an individually different identifier to emit light in a predetermined pattern. A light emission control means for transmitting a light emission command to the light emitting device identified by the predetermined identifier and transmitting an instruction for photographing of the identified light emitting device to the photographing unit; the light emitting device identified by receiving the instruction and the reference object; A position information extraction unit that calculates position information about the positional relationship between the light emitting device identified from the image captured by the image capturing unit and the reference object, and position information calculated by the position information extraction unit And a storage unit for storing in association with the identifier.

  A method of using a light emission control system according to an aspect of the present invention is to cause a plurality of light emitting devices including a light emitting unit, a signal receiving unit, and an individually different identifier to emit light in a predetermined pattern. ) A step of transmitting a light emission command to a light emitting device specified by a predetermined identifier among a plurality of light emitting devices and instructing photographing of the specified light emitting device; and (b) receiving the instruction and specifying Photographing the light emitting device and the reference object, (c) calculating position information about the positional relationship between the identified light emitting device and the reference object from the photographed image, and (d) the calculated Storing the position information in association with a predetermined identifier, and sequentially performing these steps (a) to (d) for all the light-emitting devices in which the position information is to be stored.

  According to the present invention, a light emitting module, a function of receiving a signal from the light emission control side, and a simple light emitting device having only three elements of an identifier (ID), the position of the light emission control side is visually captured and processed. By doing so, it is possible to easily control the light emission of the entire venue, so that the device can be realized at low cost and can contribute to the promotion of the spread.

1 is an overall view including a light emission control system and a plurality of light emitting devices according to an embodiment of the present invention. It is a functional block diagram of the imaging device which concerns on embodiment of this invention. It is the figure which showed the detail which the imaging device based on embodiment of this invention extracts position information. It is a functional block diagram of the light emission control apparatus which concerns on embodiment of this invention. It is a flowchart in the light-emitting device position information acquisition mode of the light emission control apparatus which concerns on embodiment of this invention. It is a functional block diagram of the apparatus which concerns on another embodiment of this invention.

Hereinafter, embodiments will be specifically described with reference to the drawings.
The numerical values, shapes, constituent elements, arrangement positions of the constituent elements, and the like shown in the following embodiments are merely examples, and various modifications and changes can be made within the scope of the invention.

(Embodiment)
FIG. 1 is an overall view of a light emission control system 1 according to the present embodiment. The light emission control system 1 controls the photographing device 10, the light emission control device 30, and the plurality of light emitting devices 20. In this specification, a plurality of light emitting devices are collectively referred to by reference numeral 20. Although only 15 light emitting devices are illustrated in FIG. 1, the number is not limited.

  In FIG. 1, a photographing device 10 is for associating positions and identifiers of a plurality of light emitting devices, and is specifically a camera (still image, moving image). It is necessary to have a communication function for transmitting to the device 30 and receiving a command from the light emission control device side 30. The light emission control device 30 instructs each light emitting device to emit light based on a light emission pattern input in advance or on the spot. Details of the imaging device 10 and the light emission control device 30 will be described later.

  Although not shown, the light emitting device 20 includes a light emitting element, a signal receiving unit, and an identifier. The light emitting element is generally an LED, but may be an incandescent bulb, a laser, a fluorescent tube, or the like. The signal receiving unit is for receiving a light emission command from the light emission control device 30. The signal transmission method depends on the scale of the venue, but is, for example, transmission using a wireless LAN signal. Of course, some facilities may be wired. Any identifier can be used as long as it can identify and identify individual light-emitting devices. However, if communication is received from the light-emission control unit via a wireless LAN or the like, the identifier is different for each light-emitting device. Preferably, the MAC address is uniquely determined. The identifier is written in a nonvolatile memory such as a ROM. In FIG. 1, the state where the light emitting device is lit is shown in black.

  FIG. 2 is a functional block diagram of the photographing apparatus 10 according to the embodiment of the present invention. The imaging device 10 includes an imaging unit 11, a reception unit 12, a transmission unit 13, a position information extraction unit 14, and a storage unit 15.

  The photographing unit 11 photographs the light emitting device in the light emitting state in conjunction with the photographing command of each light emitting device received from the light emission control device 30.

  The receiving unit 12 receives an identifier of each light emitting device and a shooting command transmitted from the light emission control device 30 by wired or wireless means.

  The transmission unit 13 pairs the identifier of each light emitting device and the position information obtained as a result of photographing, and transmits the pair to the light emission control device 30 by wired or wireless means.

  The position information extraction unit 14 calculates the distance of the position of the light emitting device from the reference object (reference object) based on the image taken by the photographing unit 11 to obtain position information. In reality, light emission from objects other than light emitting elements (reflected light, etc.) may also exist. Therefore, a predetermined threshold value for the intensity of the bright spot is set, and target light emission is performed from a bright spot above this threshold value. Determine the device.

  FIG. 3 shows an example. From the captured image, the horizontal distance (x) and the vertical distance (y) to the light emitting device Q in the light emitting state expressed in black are calculated using the pole P standing at the upper left as a reference. The position information may be accurate enough to distinguish the individual seats shown in FIG. The photographing apparatus 10 is preferably fixed by a tripod or the like at the time of photographing. However, if the positional relationship with the reference object can be known, the photographing apparatus 10 may be photographed by holding it.

  In addition, if the area to be photographed is vast, it may be divided into several zones, a reference object is set in each zone, and an image for obtaining position information may be photographed for each zone. In this case, it is necessary to separately hold the absolute coordinates of each reference object for each zone or the relative coordinates between the reference objects provided for each zone. The information may be acquired by the imaging device 10 and transmitted to the light emission control device 30, or the user may input a numerical value into the light emission control device 30 itself. The position information of the light emitting device 20 for each zone may be converted into integrated coordinates based on the position information of the reference object itself, or an effect may be performed for each zone as it is.

  Returning to FIG. 2, the storage unit 15 temporarily stores the identifier of the light emitting device sent from the light emission control device 30, and when the position information extraction unit 14 calculates the position information, the identifier of the light emitting device is obtained. The information is temporarily stored in association with each other and sequentially transmitted to the light emission control device 30.

FIG. 4 is a functional block diagram of the light emission control device 30 according to the embodiment of the present invention. The light emission control device includes an input means 31 (mouse, keyboard, etc.), a display device (display, not shown), a storage unit 32 (hard disk, ROM, RAM, etc.), an information processing device (CPU, not shown), and the like. The function can be realized by a PC (personal computer) provided with a communication device (functionally, a transmission unit 33 and a reception unit 34). A characteristic part of the present invention is the light emission control means 35, and its function is embodied by hardware or software. The light emission control means 35 has two modes: (1) a light emitting device position information acquisition mode, and (2) an effect light emission control mode. This will be described in detail below.
(1) Light-emitting device position information acquisition mode In this mode, the position of each light-emitting device is specified before the production starts. Specifically, two steps of (a) causing a specific light-emitting device to emit light and (b) causing the photographing device 10 to acquire position information of the light-emitting device are performed on all the light-emitting devices. It will be. When the positions of all the light emitting devices are specified, this mode is completed, and the position information is associated with the identifier of the light emitting device at that position on a one-to-one basis and stored in the storage unit as a position information table.
(2) Production light-emission control mode In this mode, light is emitted in time series toward individual light-emitting devices based on a predetermined light-emission pattern or a light-emission command input from the input means 31 on the spot (light-emission). (Including not making it light, or designating a specific color to emit light). The director creates a light emission pattern on a two-dimensional screen (more specifically, on a three-dimensional image obtained by adding a time axis thereto). At this time, the two-dimensional x and y coordinates are converted into the identifiers of the light emitting elements, and the two-dimensional drawing pattern is replaced with the color information and lighting presence / absence information for each identifier. To each light emitting device.

  FIG. 5 is a flowchart in the light emitting device position information acquisition mode of the light emission control device 30 according to the embodiment of the present invention.

  In step S501, prior to specifying the position information, the position information of all target light emitting devices stored in the storage unit 32 is cleared.

  In step S502, one light emitting device whose position information is cleared (position information is not specified) among the target light emitting devices 20 is specified.

  In step S503, a light emission command is transmitted to the target light emitting device through the transmission unit 33 (for example, a light emission command is issued using the MAC address of each light emitting device 20 as key information and the IP address associated therewith as a destination). Network transmission)

  In step S <b> 504, the identifier of the target light emitting device and the photographing command are transmitted to the photographing apparatus 10 through the transmission unit 33. (For example, the identifier is the MAC address of the light emitting device that has transmitted the light emission command.)

  In step S <b> 505, the identifier of the target light emitting device and the two-dimensional position information (x and y coordinate values) of the light emitting element are received from the imaging device 10 through the receiving unit 34. This may be received for each light-emitting device, or may be received collectively after the photographing device has specified the position for all the light-emitting devices.

  In step S506, the identifier of the light emitting device and the two-dimensional position information of the light emitting element are stored in the storage unit 32 as the light emitting element position information.

  In step S507, it is determined whether or not there is a light emitting device in which the position information is cleared (position information is not specified). If it exists, the process returns to step S502. If not, it is determined that all position information has been acquired, and the process proceeds to step S508.

  In step S508, the fact that the position information of all the light emitting devices has been acquired is displayed to the user, and the series of flows is completed.

(Other embodiments)
In the description so far, it has been described that the photographing device 10 extracts the position information of each light emitting device from the photographed image. However, when the photographing device 10 has low processing capability, the photographed image is displayed as the light emission control device 30. The light emission control device 30 may extract the position information of the light emitting device.

  In the above description, the photographing apparatus and the light emission control apparatus have been described as separate units. However, the photographing apparatus and the light emission control apparatus may be provided in one apparatus. For example, if there is hardware such as a smartphone with a camera function or a tablet PC with a camera function, the function can be realized in one apparatus. FIG. 6 shows a functional block diagram of such an integrated light emission control device 60. In the embodiment of the invention shown in FIG. 6, the receiving unit is omitted. In the light-emitting device position information acquisition mode, the light-emission control unit 61 issues a light-emission command to each light-emitting device and directly issues a photographing instruction to the photographing unit 62. Further, the position information of each light emitting element acquired from the photographed image is stored in the storage unit 64 as it is, and is used in the effect light emission control mode. The role of the transmitter 66 is a function of transmitting a light emission command to the light emitting device in accordance with an instruction from the light emission control means 61 in both the light emitting device position information acquisition mode and the effect light emission control mode. In addition, the photographing unit 62 and the position information extracting unit 63 have the same function as the functional block with the same name in FIG. 2, and the input unit 65 has the same function as the functional block with the same name in FIG. With this integrated light emission control device 60, functions equivalent to those described in the previous embodiment can be realized with a single piece of hardware.

  In the above description, information is transmitted and received by wireless communication. However, wired transmission and reception may be performed.

  Furthermore, in the explanation so far, the use of controlling the light emission of a plurality of light-emitting devices to create an arbitrary pattern and using it for production such as a concert / event venue has been described, but other decoration means, advertising / advertisement means, or It can also be used as an information transmission means.

  The present invention relates to a light emission control system that enhances the production effect in an event venue such as a concert venue, a stadium, etc., and by easily capturing and processing the position of each light emitting device from the light emission control side, the light emission of the entire light emitting device can be easily performed. Control can be performed, and the device can be realized at low cost, thereby contributing to the promotion of the spread. Further, the present invention is useful not only for illumination effects at event venues, but also for visual effects that are used for various decoration and advertising purposes.

DESCRIPTION OF SYMBOLS 1 Light emission control system 10 Image pick-up device 11 Image pick-up part 12 Reception part 13 Transmission part 14 Position information extraction means 15 Storage part 20 Light emission apparatus 30 Light emission control apparatus 31 Input means 32 Storage part 33 Transmission part 34 Reception part 35 Light emission control means 60 Integrated type Light emission control device 61 Light emission control means 62 Image capturing section 63 Position information extraction means 64 Storage section 65 Input means 66 Transmission section

Claims (2)

A light emission control system that causes a plurality of light emitting devices including a light emitting unit, a signal receiving unit, and an individually different identifier to emit light in a predetermined pattern,
A light emission control means for transmitting a light emission command to a light emitting device identified by a predetermined identifier among the plurality of light emitting devices, and transmitting an instruction for photographing the identified light emitting device to a photographing unit;
In response to the instruction, a photographing unit that photographs the identified light emitting device and the reference object;
Position information extracting means for calculating position information about a positional relationship between the identified light emitting device and a reference object from an image photographed by the photographing unit;
A storage unit that stores the position information calculated by the position information extraction unit in association with the predetermined identifier;
And a light emission control system.
A method of using a light emission control system for causing a plurality of light emitting devices including a light emitting unit, a signal receiving unit, and an individually different identifier to emit light in a predetermined pattern,
(A) a step of transmitting a light emission command to a light emitting device specified by a predetermined identifier among the plurality of light emitting devices, and instructing photographing of the specified light emitting device;
(B) receiving the instruction, photographing the specified light emitting device and a reference object;
(C) calculating position information about a positional relationship between the identified light emitting device and a reference object from a captured image;
(D) storing the calculated position information in association with the predetermined identifier;
A method in which the steps (a) to (d) are sequentially performed on all the light emitting devices that should store position information.