JP2004111213A - Lighting device and illuminating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting device capable of interfering with a stealthy photographing by an imaging system. <P>SOLUTION: The imaging interfering lighting device 2 irradiates an interfering infrared-ray light LIR by periodically increasing and decreasing the light output of an infrared LED 7, and at the same time, interfering illumination lights LRGB is irradiated by making a red-color LED 6A, a green-color LED 6B and a blue-color LED 6C periodically emit light in time sharing at every color, and an interfering flashlight LF is irradiated by turning an interfering flashlight 9 into a slave light emission, in case a flashlight is emitted from a still camera 3A, With this, color tints of an object for lighting sensed by a human being and those of images taken by the imaging system 3 can be differentiated, and thus, a stealth photograph of the object for lighting 4 by the imaging system can be interfered with. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a lighting device, and is suitably applied to, for example, a lighting device that illuminates an art object, an artist, or the like in which a voyeur by an imaging device is prohibited.
[0002]
[Prior art]
Today, from the viewpoint of protecting copyrights and portrait rights in museums, art galleries, concerts, etc., red light is used in order to prevent so-called voyeurism, in which images and artists are photographed without permission by imaging devices such as still cameras and video cameras. 2. Description of the Related Art A voyeur interfering device that radiates external light from a subject itself to an external light of a certain intensity or more has been proposed (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP 2001-313006 A
[0004]
[Problems to be solved by the invention]
[0005]
By the way, in such a voyeur prevention device, since infrared light is irradiated only in a certain radius range around the irradiation point, and it is impossible to shoot only from the front of the irradiation direction of the infrared light, it is impossible to take a work of art or In order to completely obstruct the voyeur of the artist, it is necessary to attach a plurality of anti-voyeur devices of a predetermined size to the artwork or the like, and the aesthetic appearance of the artwork or the like is impaired.
[0006]
On the other hand, even if the anti-voyeur device is attached only to the place where the voyeur is predicted for the artwork or the artist, in a wide place where an unspecified number of people visit, such as museums, museums, concerts, etc. The problem is that shooting of artworks and artists is not always performed from the front of the irradiation direction of infrared light, and there is a possibility that shooting may be performed from an unexpected direction other than the front of the irradiation direction. there were.
[0007]
The present invention has been made in view of the above points, and has as its object to propose an illumination device that can prevent pirating by an imaging device.
[0008]
[Means for Solving the Problems]
In order to solve such a problem, in the present invention, in a lighting device that illuminates an illumination target, a light source that emits a plurality of monochromatic lights each having a different wavelength, the light source is controlled, and the plurality of monochromatic lights are cycled in a time-division manner. And a light source control unit for adding and mixing the plurality of monochromatic lights by emitting light.
[0009]
Therefore, even when the illumination target is imaged by the imaging device, the imaging device discretely captures the illumination target in the imaging device. The illumination target can be photographed with an image having a different hue from the perceived added and mixed hue, thereby disturbing the color balance in the imaging device.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
[0011]
In FIG. 1, reference numeral 1 denotes an imaging disturbance system as a whole, and an imaging disturbance illumination device 2 applies a disturbance illumination light LRGB, a disturbance infrared light LIR, and a disturbance flash light LF to an illumination target 4 such as a work of art or an artist in a wide range. , The so-called voyeurism in which the illumination target 4 is photographed without permission by the imaging device 3 such as the still camera 3A or the video camera 3B.
[0012]
Further, the imaging disturbing illumination device 2 is configured to be able to communicate with the imaging device 3 by infrared rays, and when receiving the disturbing light release request signal transmitted from the imaging device 3, the imaging disturbing illumination device 2 Accordingly, after temporarily stopping the irradiation of the disturbing illumination light LRGB, the disturbing infrared light LIR, and the disturbing flash light LF, a notification that the photographing is temporarily possible is transmitted by transmitting an imaging permission signal to the imaging device 3. The illumination target 4 is photographed only by a specific imaging device 3.
[0013]
In practice, an imaging obstruction module 5 is provided on a facing surface 2A of the imaging obstruction lighting device 2 facing the illumination target 4, as shown in FIG.
[0014]
This imaging disturbing module 5 has a lighting unit in which a plurality of light sources for illumination are regularly arranged on the left side, each of which includes a set of a red LED 6A emitting red light, a green LED 6B emitting green light, and a blue LED 6C emitting blue light. The red LED 6A, the green LED 6B, and the blue LED 6C have the LED group 6, and emit the disturbing illumination light LRGB by sequentially and sequentially emitting light of the same color in a time-division manner.
[0015]
The imaging obstruction module 5 is provided with a plurality of infrared LEDs 7 that emit infrared light below the illumination LED group 6 as a light source. Each infrared LED 7 emits infrared light while periodically increasing or decreasing the amount of light emission. Irradiates interfering infrared light LIR.
[0016]
Further, the imaging disturbance module 5 is provided with a flash detection photodiode 8 for detecting light emission of a flash light in the imaging device 3 near the center thereof, and a disturbance flash light 9 above the flash detection photodiode 8. Then, the interfering flash light 9 emits slave light in response to the light emission of the flash light of the imaging device 3, thereby irradiating the interfering flash light LF.
[0017]
In addition, the imaging disturbing module 5 includes a release signal receiving photodiode 10 for receiving a disturbing light release request signal transmitted from the imaging device 3 on the right side thereof, and a disturbing light via the releasing signal receiving photodiode 10. When receiving the release request signal, a communication LED 11 for transmitting a photographing permission signal to the imaging device 3 in response to the request is provided.
[0018]
By the way, the infrared LED 7 stops the irradiation of the infrared light at intervals of several tens of [〓], and thereby the interference between the infrared communication performed by using the photodiode 10 for receiving the release signal and the communication LED 11 and the infrared light by the infrared LED 7. Can be prevented.
[0019]
Actually, as shown in FIG. 3, a color circulating signal generating unit 21 and an infrared LED driving unit are provided inside the imaging disturbance illuminating device 2, as shown in FIG. The signal generation unit 22, the flash drive unit 23, and the release signal determination unit 24 are connected, and the red LED 6A, the green LED 6B, and the blue LED 6C of the illumination LED group 6 are connected to the color circulation signal generation unit 21 via the amplifiers 25A to 25B. The infrared LED 7 is connected to the infrared LED drive signal generator 22 via an amplifier 26.
[0020]
The flash drive unit 23 is connected to a pulse detection unit 27 to which the flash detection photodiode 8 is connected, and the disturbing flash light 9 as a light emitting unit. The diode 10 and a release signal generating unit 29 to which the communication LED 11 is connected via the amplifier 28 are connected.
[0021]
In this case, the control unit 20 generates a color circulating signal by the color circulating signal generating unit 21 as a light source control unit in the imaging disturbance mode in which the imaging device 3 interferes with the photographing of the illumination target 4, and the amplifier 25 </ b> A to 25 </ b> C After that, the signal is amplified to a predetermined signal level, and then transmitted to the red LED 6A, the green LED 6B, and the blue LED 6C of the illumination LED group 6, respectively.
[0022]
Accordingly, the illumination LED group 6 emits the disturbing illumination light LRGB by periodically emitting red light, green light, and blue light from the red LED 6A, the green LED 6B, and the blue LED 6C in a time division manner based on the color circulating signal. It has been made.
[0023]
As shown in FIG. 4, the red LED 6A emits red light having a half-width of about 30 [nm] and a peak near a wavelength of 660 [nm], and the green LED 6B has a half-width as shown in FIG. It emits green light having a peak near a wavelength of 520 [nm] at about 30 [nm]. The blue LED 6C emits blue light having a half width of about 30 [nm] and a peak near a wavelength of 460 [nm].
[0024]
Then, as shown in FIG. 5, in the chromaticity diagram of CIE (Commission International de 1 'Eclairage), the illumination LED group 6 becomes white light W1 when red light, green light and blue light are added and mixed. As described above, the luminances of the red LED 6A, the green LED 6B, and the blue LED 6C are respectively set.
[0025]
In the illumination LED group 6, the red LED 6A, the green LED 6B, and the blue LED 6C emit light during a light emission period in which red light, green light, and blue light are added and mixed by an afterimage phenomenon generated in human vision and are perceived as white light W1. Light is emitted periodically in the division.
[0026]
Actually, as shown in FIG. 6, in the illumination LED group 6, the light emission period Ta of each of the red LED 6A, the green LED 6B, and the blue LED 6C is 1 / th of the imaging period t of the video camera 3B (for example, 1/60 second for one field). By setting to 4, the number of times of light emission of the red LED 6A, the green LED 6B, and the blue LED 6C changes irregularly for each imaging period t.
[0027]
Accordingly, in the video camera 3B, since the illumination target 4 is discretely photographed for each field (that is, for each imaging period t), the red LED 6A emits light twice in the field F1, and thus the video camera 3B takes on red light. In the next field F2, since the green LED 6B emits light twice, the image is tinged with green light.
[0028]
Thus, when the illumination target 4 is photographed by the video camera 3B in the image capturing obstruction lighting device 2, a plurality of temporally continuous fields F1, F2,... , F2,..., Flicker is generated by changing the color of the image, and as a result, it is possible to interfere with the shooting by the video camera 3B.
[0029]
Further, in the image capturing obstruction lighting device 2, when the illumination target 4 is photographed by the still camera 3A, the image is changed to the color of the emission color of the red LED 6A, the green LED 6B, or the blue LED 6C emitted at the moment of the photography, and The color balance is disturbed, so that shooting by the still camera 3A can be obstructed.
[0030]
By the way, some still cameras 3A have a flash light as an imaging side light emitting unit, and the flash light is emitted when the illumination target 4 is photographed.
[0031]
In this case, in the image capturing obstruction lighting device 2, since the light amount of the flash light of the still camera 3 </ b> A is larger than the light amount of the illumination LED group 6, the shooting of the illumination target 4 by the still camera 3 </ b> A is performed by the disturbance illumination light LRGB of the illumination LED group 6. Cannot interfere.
[0032]
At this time, the image capturing disturbing illumination device 2 irradiates the disturbing flash light LF by illuminating the disturbing flash light 9 in accordance with the emission of the flash light from the still camera 3A, thereby preventing the still camera 3A from photographing the illumination target 4. It has been made to be able to.
[0033]
Actually, as shown in FIG. 7A, when the flash light is emitted from the still camera 3A, the control unit 20 receives the light emission of the flash light via the flash detection photodiode 8 and receives this light. By performing the photoelectric conversion, a photodiode output signal as shown in FIG. 7B is obtained, and the photodiode output signal is sent to the pulse detector 27.
[0034]
The pulse detection unit 27 as a light emission detection unit obtains a differential output signal as shown in FIG. 7C by differentiating the photodiode output signal supplied from the flash detection photodiode 8, and obtains the differential output signal. It is determined whether or not the light emission received through the flash detection photodiode 8 is the light emission of the flash light of the still camera 3A, and if the light emission is the light emission of the flash light, the differential output signal is flash-driven. To the unit 23.
[0035]
After generating a flash output signal based on the differential output signal, the flash drive unit 23 sends this to the disturbing flashlight 9.
[0036]
As a result, the disturbing flash light 9 emits slave light several seconds after the flash light of the still camera 3A is emitted based on the flash output signal, as shown in FIG. 7D.
[0037]
Thus, in the imaging disturbance illumination device 2, the disturbance flash light LF is emitted by emitting the disturbance flash light 9 with a light amount about 100 times as large as the light amount of the flash light of the still camera 3A, and the still camera 3A is irradiated on the still camera 3A. Overexposure to prevent the still camera 3A from taking a picture of the illumination target 4 with the emission of the flashlight.
[0038]
Incidentally, as shown in FIG. 4, the light emission characteristics of the interfering flashlight 9 are almost flat from a wavelength of about 400 [nm] to about 650 [nm], and decrease from the vicinity of the wavelength of 650 [nm] to the left.
[0039]
In addition, in the imaging obstruction mode, the imaging obstruction illumination device 2 irradiates the obstruction illumination light LRGB with the illumination LED group 6 and irradiates the interference infrared light LIR with the infrared LED 7 as an infrared irradiation means.
[0040]
In practice, the control unit 20 generates a periodically changing infrared LED drive signal by the infrared LED drive signal generation unit 12 as infrared control means, and sends this to the predetermined signal level via the amplifier 21. After amplification, it is transmitted to the infrared LED 7.
[0041]
Thereby, the infrared LED 7 emits infrared light while periodically increasing or decreasing the light emission amount based on the infrared LED drive signal, thereby irradiating the interfering infrared light LIR.
[0042]
As shown in FIG. 4, the infrared LED 7 emits infrared light having a half width of about 50 [nm] and a peak near a wavelength of 870 [nm] as shown in FIG.
[0043]
By the way, as shown in FIG. 8, the sensitivity characteristics of a CCD (Charge Coupled Device) imaging device generally used for the imaging device 3 such as the still camera 3A and the video camera 3B are not limited to the visible light range but also to the human. It has sensitivity to long wavelengths (wavelengths of about 700 [nm] or more) such as infrared rays that are invisible to human eyes, and is different from human visibility characteristics.
[0044]
Therefore, as shown in FIG. 9, the imaging device 3 is provided with an infrared cut filter having a characteristic of removing infrared rays, so that the CCD imaging device is corrected so as to have sensitivity in the same visible light range as human vision. are doing.
[0045]
For this reason, the infrared rays from the infrared LED 7 reaching the CCD image pickup device of the imaging device 3 are attenuated to about several percent near the peak 870 [nm] of the infrared LED 7 by the infrared cut filter, and the exposure of the imaging device 3 is greatly reduced. It doesn't go crazy.
[0046]
However, since the imaging disturbing illumination device 2 emits the disturbing infrared light LIR by periodically increasing or decreasing the amount of emitted infrared light in the infrared LED 7, the exposure in the imaging device 3 varies according to the amount of emitted light. Let it.
[0047]
Therefore, the image capturing obstruction lighting device 2 causes the video camera 3B to generate flicker by changing the exposure according to the light emission amount that periodically increases and decreases by the infrared LED 7, and captures the image of the illumination target 4 by the video camera 3B. It is made to be able to obstruct.
[0048]
Further, when the illumination target 4 is photographed by the still camera 3A, the image capturing obstruction lighting device 2 changes the exposure in accordance with the amount of infrared light emitted from the infrared LED 7 at the moment of the photographing, whereby the still camera 3A performs photographing. It is designed to interfere.
[0049]
On the other hand, when receiving the interference light release request signal from the imaging device 3, the imaging interference illumination device 2 temporarily stops the irradiation of the interference illumination light LRGB, the interference infrared light LIR, and the interference flash light LF to stop the imaging device. The mode shifts to a photographing permission mode in which the photographing of the illumination target 4 by the photographing object 3 is temporarily permitted.
[0050]
In practice, when receiving the received signal from the imaging device 3 via the release signal receiving photodiode 11, the control unit 20 sends this to the release signal determination unit 24.
[0051]
The control unit 20 determines whether or not the received signal received via the release signal receiving photodiode 11 as the receiving means is an interference light release request signal by the release signal determination unit 24, and When it is determined that the image capturing mode is satisfied, the mode shifts from the imaging disturbance mode to the imaging permission mode.
[0052]
Thereby, the control unit 20 controls the color circulating signal generation unit 21 based on the interference light release request signal, and simultaneously emits the red LED 6A, the green LED 6B or the blue LED 6C of the illumination LED group 6 with a constant light emission amount. The color-mixed white light W1 is irradiated, and the irradiation of the disturbing illumination light LRGB is temporarily stopped.
[0053]
Further, the control unit 20 controls the infrared LED drive signal generation unit 22 and the flash drive unit 23 based on the interference light release request signal, and stops the irradiation of infrared rays by the infrared LED 7 and the slave light emission by the interference flashlight 9. , The irradiation of the interfering infrared light LIR and the interfering flash light LF is temporarily stopped.
[0054]
At this time, the control unit 20 generates a photographing permission signal by the release signal generation unit 29, amplifies the signal to a predetermined signal level via the amplifier 23, and then transmits a disturbing light release request signal via the communication LED 11. It is transmitted only to the imaging device 3.
[0055]
The control unit 20 shifts from the imaging permission mode to the imaging obstruction mode again after a lapse of a predetermined time from the transmission of the imaging permission signal to the imaging device 3, and interrupts the imaging of the illumination target 4 by the imaging device 3.
[0056]
As a result, the imaging disturbance illumination device 2 notifies the imaging device 3 that has transmitted the disturbance light release request signal of the predetermined time during which imaging can be performed only, and thereby only within the predetermined time during which imaging with respect to the imaging device 3 is possible. The illumination object 4 is photographed.
[0057]
In practice, the control unit 20 supplies power to each circuit block when the power-on is instructed by, for example, pressing a predetermined switch (not shown), and the control unit 20 (not shown) Then, the imaging disturbance processing program is transferred from the ROM to the RAM and started up, the imaging disturbance processing procedure shown in FIG. 10 is started from the start step of the routine RT1, and the process proceeds to step SP1.
[0058]
In step SP1, the control unit 20 starts irradiation of the disturbing illumination light LRGB by sequentially emitting the red LED 6A, the green LED 6B, and the blue LED 6C in a time-division manner by the illumination LED group 6, and proceeds to the next step SP2.
[0059]
In step SP2, the control unit 20 starts irradiation of the interfering infrared light LIR by emitting or emitting infrared light by periodically increasing or decreasing the amount of light emitted by the infrared LED 7, and proceeds to the next step SP3.
[0060]
In step SP3, the control unit 20 determines whether the supply of power to each circuit block has been stopped, for example, because the switch has been pressed again.
[0061]
If a positive result is obtained in step SP3, this means that the supply of power to each circuit block in the image-obstruction illuminating device 2 is stopped by pressing the switch, that is, the illumination LED group 6, the infrared LED 7, and the This indicates that the emission of the obstruction flashlight 9 has been stopped. At this time, the control unit 20 moves to the next step SP9 and ends the imaging obstruction processing procedure.
[0062]
On the other hand, if a negative result is obtained in step SP3, this means that the switch is not depressed, and power is continuously supplied to each circuit block in the image capturing obstruction lighting device 2 and the operation is started in an operable state. That is, while the disturbing illumination light LRGB is being continuously emitted by the illumination LED group 6 and the disturbing infrared light LIR is being continuously emitted by the infrared LED 7, the control unit 20 The process moves to the next step SP4.
[0063]
In step SP4, the control unit 20 determines whether or not the pulse detection unit 27 has received light emission of the flash light in the still camera 3A via the flash detection photodiode 8.
[0064]
Here, if a positive result is obtained, this means that the light emission of the flash light in the still camera 3A has been received via the flash detection photodiode 8, that is, the still camera 3A has caused the flash light to emit light and the illumination target 4 This indicates that the image has been taken, and at this time, the control unit 20 proceeds to the next step SP5.
[0065]
In step SP5, the control unit 20 causes the flash driving unit 23 to emit the disturbing flash light 9 by causing the disturbing flash light 9 to emit the slave light, and returns to step SP6.
[0066]
On the other hand, if a negative result is obtained in step SP4, this means that the flash light from the still camera 3A has not been received via the flash detection photodiode 8, that is, the still camera 3A has emitted the flash light. This indicates that the illumination target 4 has not been photographed, and at this time, the control unit 20 proceeds to the next step SP6.
[0067]
In step SP6, the control unit 20 causes the release signal determination unit 24 to determine whether or not a disturbing light release request signal has been received from the imaging device 3 via the release signal receiving photodiode 10.
[0068]
Here, if a negative result is obtained, this means that the interfering light release request signal has not been received from the imaging device 3 via the release signal receiving photodiode 10, and at this time, the control unit 20 again executes the step Returning to SP3, the above processing is repeated.
[0069]
On the other hand, if a positive result is obtained in step SP6, this means that the interference light release request signal is received from the imaging device 3 via the release signal receiving photodiode 10, that is, the illumination target 4 Can be photographed, and at this time, the control unit 20 moves to the next step SP7.
[0070]
In step SP7, the control unit 20 stops the irradiation of the disturbing illumination light LRGB by simultaneously emitting the red LED 6A, the green LED 6B, or the blue LED 6C of the illumination LED group 6 with a constant light emission amount, and also disturbs the disturbing infrared light by the infrared LED 7. The irradiation of the interfering flash light LF by the light LIR and the interfering flash light 9 is stopped.
[0071]
At this time, the control unit 20 notifies the imaging available time by transmitting an imaging permission signal to the imaging device 3 via the communication LED 11, and proceeds to the next step SP8.
[0072]
In step SP8, the control unit 20 determines whether or not a certain time has elapsed based on an internal clock (not shown) in the control unit 20, and waits until the certain time has elapsed.
[0073]
If an affirmative result is obtained in step SP8, this means that the time measured by the internal clock in the control unit 20 has passed for a certain period of time, and at this time, the control unit 20 returns to step SP1 again and proceeds to step SP1. By repeating the above processing, the irradiation of the disturbing illumination light LRGB by the illumination LED group 6 and the irradiation of the disturbing infrared light LIR by the infrared LED 7 are started again.
[0074]
In the above configuration, in the imaging disturbance mode, the red LED 6A, the green LED 6B, and the blue LED 6C periodically emit light in a time sharing manner to irradiate the disturbance illumination light LRGB in the image disturbance mode.
[0075]
Accordingly, the image-obstructing illumination device 2 can add and mix red light, green light, and blue light and perceive it as white light W1 by the afterimage phenomenon that occurs in human vision, and thus illuminate the illumination target 4 brightly with the white light W1. it can.
[0076]
At this time, in the imaging obstruction illumination device 2, even if the illumination target 4 is photographed without permission by the still camera 3A, the red LED 6A, the green LED 6B, or the blue LED 6C emits light at the moment when the illumination target 4 is photographed by the still camera 3A. The image is a tinted image, so that the voyeur by the still camera 3A can be prevented.
[0077]
Further, in the image capturing obstruction lighting device 2, any one of the red LED 6A, the green LED 6B, and the blue LED 6C of the illumination LED group 6 emits light for each field F1, F2,... Even if the video object 3 is photographed by the video camera 3B. An image having a tint is generated and flicker is generated.
[0078]
Then, in the image capturing obstruction lighting device 2, even when the flash light is emitted when the still camera 3A captures the illumination target 4 in the image capturing obstruction mode, the obstructing flash light 9 is over-exposed by emitting the slave light, thereby The voyeur using the flash light by the still camera 3A can be prevented.
[0079]
Further, in the image capturing obstruction lighting device 2, in the image obstructing mode, the infrared LED 7 emits infrared light by periodically increasing or decreasing the amount of light emission, thereby emitting the interference infrared light LIR.
[0080]
As a result, in the imaging disturbance illumination device 2, the exposure is disturbed by the disturbance infrared light LIR emitted by the infrared LED 7 at the moment when the illumination target 4 is photographed by the still camera 3A, and thus the voyeur by the still camera 3A can be further disturbed. .
[0081]
Further, in the image capturing obstruction lighting device 2, when the video object 3B is photographed by the video camera 3B, flicker is generated in accordance with the periodic increase and decrease in the amount of infrared light emitted by the infrared LED 7, and thus the voyeur by the video camera 3B is further reduced. Can interfere.
[0082]
On the other hand, upon receiving the interference light release request signal from the imaging device 3, the imaging interference illumination device 2 temporarily suspends the irradiation of the interference illumination light LRGB, the interference infrared light LIR, and the interference flash light LF, and cancels the interference light. Only the imaging device 3 that has transmitted the request signal is notified of the predetermined time during which the image of the illumination target 4 can be captured so that the illumination target 4 can be captured.
[0083]
Accordingly, in the image capturing obstruction lighting device 2, even in a place where an unspecified number of people enter and leave and the illumination target 4 may be voyeurized, the person who can photograph the illumination target 4 for a legitimate purpose, not for voyeurism, Shooting can be performed within a predetermined time in which shooting is possible.
[0084]
According to the above configuration, in the imaging disturbing illumination device 2, the disturbing infrared light LIR is radiated by emitting infrared light by periodically increasing or decreasing the light emission amount by the infrared LED 7, and the red LED 6A, the green LED 6B, and the blue LED 6C. Irradiates disturbing illumination light LRGB by emitting light periodically in a time-division manner for each color, and disturbs the disturbing flash light LF by emitting the disturbing flash light 9 as a slave when the flash light is emitted in the still camera 3A. By irradiating, the hue of the illumination target 4 perceived by a human can be different from the hue of the image captured by the imaging device 3, and thus piracy by the imaging device 3 can be prevented.
[0085]
In the above-described embodiment, a case has been described where the red LED 6A, the green LED 6B, and the blue LED 6C are periodically emitted in a time-division manner in the illumination LED group 6 so that the white light W1 is perceived. The present invention is not limited to this. In the illumination LED group 50, in addition to the red LED 6A, the green LED 6B, and the blue LED 6C, a cyan LED 6D that emits cyan color light as monochromatic light is periodically emitted in a time-division manner so that white light is perceived. Alternatively, white light may be perceived by periodically emitting light in a time sharing manner using a light source that emits various monochromatic lights.
[0086]
In this case, the light emission characteristics of the cyan LED 6D are similar to those of the red LED 6A, the green LED 6B, the blue LED 6C, etc. shown in FIG. 4, and as shown in FIG. Emit cyan light having a peak near [nm].
[0087]
Then, as shown in FIG. 12, the illumination LED group 50 is obtained by adding and mixing red light, blue light and cyan light, and red light, blue light and green light on the CIE chromaticity diagram, respectively. Each luminance of the red LED 6A, the green LED 6B, the blue LED 6C, and the cyan LED 6D is set so that the white light W2 in the white area C is obtained.
[0088]
Incidentally, the white area C generally indicates a chromaticity range that is regarded as the same white light as the white light W1 described above.
[0089]
Also, the illumination LED group 50 is perceived as white light W2 by adding and mixing red light, green light and blue light due to an afterimage phenomenon generated in human vision, and also adds and mixes red light, blue light and cyan light. The red LED 6A, the green LED 6B, the blue LED 6C, and the cyan LED 6D emit light periodically in a time-division manner during a light emission period that is perceived as white light W2.
[0090]
In practice, as shown in FIG. 13, in the illumination LED group 50, the emission period Tb of each of the red LED 6A, the green LED 6B, the blue LED 6C, and the cyan LED 6D is equal to the imaging period t of the video camera 3B (for example, 1/60 second per field). , The red LED 6A, the green LED 6B, and the cyan LED 6D, and the red LED 6A, the green LED 6B, and the blue LED 6C emit light alternately in each imaging period t.
[0091]
By the way, in the imaging device 3, since the human visual sensitivity characteristic differs from the spectral sensitivity characteristic of the CCD imaging device of the imaging device 3, for example, as shown in FIG. 14, the peak of the wavelength at which the cyan LED 6D emits light is 490 [nm]. In the vicinity, the light becomes cyan light for human vision, but according to the spectral sensitivity characteristics of the CCD image sensor, the light emission intensity of blue light becomes stronger than the light emission intensity of green light, so that the image becomes a hue tinged with blue light. .
[0092]
Accordingly, in the video camera 3B, since the illumination target 4 is discretely photographed for each field F1, F2,... (That is, for each imaging period t), the cyan LED 6D is emitted in the field F1. The image becomes blue light, and in the next field F2, the image becomes white light W2 in which red light, green light and blue light are added and mixed.
[0093]
In this way, in the image capturing obstruction lighting device 2, when the video object 3B is photographed by the video camera 3B, a plurality of temporally continuous fields F1, F2,... .. Flicker is generated by alternately changing the image into a blue-colored image for each of the fields F1, F2,..., And as a result, it is possible to hinder shooting by the video camera 3B.
[0094]
In this case, when the illumination target 4 is photographed by the still camera 3A, the imaging obstruction illumination device 2 emits any one of the red LED 6A, green LED 6B, blue LED 6C or cyan LED 6D (cyan LED 6D) emitted at the moment of photographing. In this case, the image is changed to a hue having blue light due to the spectral sensitivity characteristic), thereby disturbing the color balance of the image, and as a result, voyeuring by the still camera 3A can be obstructed.
[0095]
In addition, as shown in FIG. 15, when the cyan LED 6D periodically emits light in time division in addition to the red LED 6A, the green LED 6B, and the blue LED 6C, as shown in FIG. May be periodically emitted in a time-division manner.
[0096]
In this case, not only when the emission time Tc of the green LED 6B and the emission time Tc of the cyan LED 6D is shortened but also when the emission time Tc is increased, when the illumination target 4 is photographed in the video camera 3B, the emission of the cyan LED 6D causes the blue color. An image of a hue tinged with light (according to the above-described spectral sensitivity characteristic of the CCD image sensor) and an image of white light W2 in which the red LED 6A, the green LED 6B, and the blue LED 6C are added and mixed alternately to generate flicker. Thus, the photographing by the video camera 3B can be disturbed as in the case described above.
[0097]
Further, in the above-described embodiment, a case has been described in which the light source is selected such that the white light W1 is perceived by the afterimage phenomenon of human vision. However, the present invention is not limited to this, and the present invention is not limited thereto. The light source may be selected such that other various color lights such as cyan, magenta, and yellow light are perceived.
[0098]
Further, in the above-described embodiment, a case has been described in which the image capturing obstruction lighting device 2 and the image capturing device 3 communicate with each other using infrared rays. However, the present invention is not limited to this, and Bluetooth (registered trademark) is used. Wireless connection may be performed by other various wireless communication methods such as a short-range wireless communication method conforming to the standard. In this case, since there is no interference between infrared communication and infrared light from the infrared LED 7, the infrared LED 7 The wireless communication with the imaging device 3 can be performed without stopping the irradiation of the infrared rays at intervals of several tens [〓].
[0099]
【The invention's effect】
As described above, according to the present invention, even when the illumination target is imaged by the imaging device, the illumination target emits light at the time of the imaging because the imaging device discretely images the illumination target. A lighting device that can cause an illumination target to be photographed with an image having a different hue from the added and mixed hue perceived by humans based on the monochromatic light to deviate the color balance in the imaging device, and thus hinder voyeurism by the imaging device. Can be realized.
[Brief description of the drawings]
FIG. 1 is a schematic diagram illustrating an overall configuration of an image capturing disturbance system according to the present invention.
FIG. 2 is a schematic diagram illustrating a configuration of a facing surface of the imaging disturbance illumination device.
FIG. 3 is a block diagram illustrating a circuit configuration of the imaging disturbance illumination device.
FIG. 4 is a schematic diagram illustrating light emission characteristics of a red LED, a green LED, a blue LED, an infrared LED, and a disturbing flashlight.
FIG. 5 is a schematic diagram of red light, green light and blue light represented on a CIE chromaticity diagram.
FIG. 6 is a schematic diagram illustrating emission periods of a red LED, a green LED, and a blue LED.
FIG. 7 is a schematic diagram illustrating slave light emission of a disturbing flash light.
FIG. 8 is a schematic diagram illustrating sensitivity characteristics of a CCD image sensor.
FIG. 9 is a schematic diagram illustrating transmission characteristics of an infrared cut filter.
FIG. 10 is a flowchart illustrating a procedure of an imaging disturbance process.
FIG. 11 is a schematic diagram illustrating emission characteristics of a red LED, a green LED, a blue LED, a cyan LED, an infrared LED, and a disturbing flashlight.
FIG. 12 is a schematic diagram of cyan light, red light, green light, and blue light represented on a CIE chromaticity diagram.
FIG. 13 is a schematic diagram illustrating a light emitting period (1) of a red LED, a green LED, a blue LED, and a cyan LED according to another embodiment.
FIG. 14 is a schematic diagram illustrating spectral sensitivity characteristics of a CCD image sensor.
FIG. 15 is a schematic diagram illustrating a light emitting period (2) of a red LED, a green LED, a blue LED, and a cyan LED according to another embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Imaging disturbance system 2 ... Imaging disturbance illumination device 3 ... Imaging device 3A ... Still camera 3B ... Video camera 4 ... Illumination target 5 ... Imaging disturbance module 6 ... Illumination LED group, 6A: red LED, 6B: green LED, 6C: blue LED, 7: infrared LED, 8: flash detection photodiode, 9: disturbing flash light, 10: release signal Photodiode, 11 Communication LED, 20 Control unit.

Claims (7)

In a lighting device that shines light on an illumination target,
A light source that emits a plurality of monochromatic lights having different wavelengths,
A lighting device, comprising: a light source control unit that controls the light source and periodically emits the plurality of monochromatic lights in a time-division manner to add and mix the plurality of monochromatic lights. The plurality of monochromatic lights are selected so that the light source emits periodically in a time-division manner under the control of the light source control means to produce white light when the additive color mixing is performed. Item 2. The lighting device according to Item 1. The lighting device according to claim 2, wherein the light source emits red light, green light, and blue light as the plurality of monochromatic lights. Infrared irradiation means for irradiating the illumination target with infrared light,
The illumination device according to claim 1, further comprising an infrared control unit that controls the infrared irradiation unit and changes the amount of emitted infrared light periodically. Light emission detection means for detecting that the imaging side light emission means of the imaging device has emitted light,
5. The lighting device according to claim 4, further comprising: a light emitting unit that emits light with a higher light emission amount than the imaging side light emitting unit when the light emission of the imaging side light emitting unit of the imaging device is detected by the light emission detecting unit. apparatus. A receiving unit that receives a request signal for requesting cancellation of the prohibition of shooting of the illumination target from the imaging device;
When the request signal is received from the imaging device via the receiving means, the light source is controlled by the light source control means to simultaneously and temporarily emit the plurality of monochromatic lights, and the infrared light emitted by the infrared irradiating means and The lighting device according to claim 5, wherein light emission by the light emitting means is temporarily stopped. In a lighting device that shines light on an illumination target,
A light source controlling step of controlling a light source that emits a plurality of monochromatic lights having different wavelengths, and periodically adding the plurality of monochromatic lights in a time-division manner to add and mix the plurality of monochromatic lights. And lighting method.

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