JP2013042322A - Projection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display a video of high picture quality and high visibility in a bright room.SOLUTION: A projection system includes: a projection device 20 which includes a video display section for taking in a video signal and displaying the video, and converts the video that the video display section displays into video light to perform projection; a screen device 30 for changing a state of a projection face so that a reflection degree of light on a projection face becomes one of a first reflection degree and a second reflection degree; an illuminating device 40 for switching a state of illumination in an appreciation room Rwhere the screen device 30 is installed in accordance with lighting-on and lighting-out; and a controller 10 for controlling the screen device 30 so that the state of the projection face in the screen device 30 is switched in synchronization with a frame frequency of the video signal, controlling the illuminating device 40 so that the illumination becomes a first illumination state in a period in which the reflection degree of the light becomes the first reflection degree, and controlling the video display section so that the video signal is taken in synchronization with switching timing of the state of the projection face.

Description

  The present invention relates to a projection system.

  A projection screen that reduces the influence of indoor illumination light and can be used in a bright room is known (see, for example, Patent Document 1). This document discloses a projection screen that projects image light projected from a projector onto a diffusion plate and displays an image on the diffusion plate. This projection screen is installed in a room provided with an illuminating device that illuminates illumination light whose illuminance periodically changes. When the illuminance of the illumination light on the diffuser plate is low, the projection screen diffuses the image light projected by the projector, When the illuminance of the illumination light is high, the diffusion plate is controlled so as to transmit the illumination light.

JP-A-6-110131

  The projection screen described above can reduce the influence of room illumination light and display an image with high contrast. However, this projection screen is not controlled in consideration of the relationship between each period of the light diffusing state and light transmitting state of the diffusing plate and the address period of the video display unit provided in the projector. Therefore, in the projector system using this projection screen, when the light diffusion state and light transmission state switching period of the diffusion plate is equal to or less than the frame period of the image, an image lacking in a strip shape is displayed in the vertical direction of the frame. become. Further, in the projector system described above, when the switching period exceeds the frame period of the video, in addition to the above problem, a video with awkward movement such as a missing frame is displayed. Therefore, the projector system using the projection screen described above has a problem that although the contrast is improved, the moving image quality is deteriorated.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a projection system capable of displaying an image with high image quality and high visibility in a bright room.

[1] In order to solve the above-described problem, a projection system according to an aspect of the present invention includes a video display unit that captures a video signal based on capture control and displays a video, and the video displayed by the video display unit Based on the projection device that converts the image light into the image light and projects the image light, and the switching control, the reflection degree of the light on the projection surface is higher than the first reflection degree and the first reflection degree. A screen device that changes the state of the projection plane so as to have one of the second reflection degrees, and based on switching control, the illumination state around the screen device is set as the first illumination state The illumination control device that switches between a second illumination state that has an illuminance lower than the illuminance in the first illumination state, and the state of the projection surface in the screen device is the frame circumference of the video signal. The screen device is controlled to switch in synchronization with the number, and the illumination of the illumination adjustment device is in the first illumination state within a period in which the reflection degree of the light becomes the first reflection degree. And a control device that controls the video display unit so as to capture the video signal in synchronization with switching timing of the state of the projection plane in the screen device.
According to this configuration, the control device in the projection system according to one aspect of the present invention reduces the illuminance of the illumination in the illumination adjustment device and reduces the illumination intensity in the projection device when the degree of light reflection on the projection surface in the screen device is not reduced. Control to perform video display of the video display unit. In other words, when the illumination of the illumination adjustment device is set to the first illumination state (for example, lighting), the control device reduces the reflection degree of the light on the projection surface of the screen device, and the spatial light modulation element of the projection device. Control can be performed to permit the capture (addressing) of the video signal. Further, when the illumination of the illumination adjustment device is set to the first illumination state, the control device reduces the degree of reflection of light on the projection surface of the screen device, and reduces the amount of light from the image display unit of the scanning projection device. It can be controlled to prohibit the dimension scan.
With this configuration, in the projection system that is one embodiment of the present invention, when the lighting device is in the first lighting state, the degree of light reflection on the projection surface of the screen device is reduced (first). Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device is dark. On the other hand, in a portion where the image projected by the projection apparatus is bright, the reflected light in the period when the reflection degree of light on the projection surface is high (the period when the second reflection degree is reached) reaches the viewer's eyes.
Therefore, according to the projection system which is one embodiment of the present invention, it is possible to obtain an image that has high contrast and is very easy to see even in an environment illuminated by the illumination adjustment device. At this time, it is possible to prevent an image lacking in a strip shape from being displayed in the vertical direction of the frame or to display an awkward motion image, and to prevent deterioration of the moving image quality of the image.
Here, the first illumination state and the second illumination state are, for example, lighting and extinguishing, or transmission and blocking (light shielding).

[2] In the projection system according to [1], the control device may display the video so that the video display unit displays the video during a period in which the reflection degree of the light is the second reflection degree. It is characterized by controlling the part.
[3] In the projection system according to [1] or [2], the illumination adjustment device is an illumination device that illuminates in the first illumination state or the second illumination state.
[4] In the projection system according to [1] or [2], the illumination adjustment device is a shutter device that takes in external light and illuminates in the first illumination state or the second illumination state. It is characterized by.
[5] In the projection system according to [1] or [2], the illumination adjustment device includes an illumination device that illuminates in the first illumination state or the second illumination state, and external light is taken in to the first illumination state. And a shutter device that illuminates in the first illumination state or the second illumination state.
[6] In the projection system according to any one of [1] to [5], the control device switches the state of the projection surface of the screen device in accordance with the same frequency as the frame frequency of the video signal. The screen device is controlled to be changed.
[7] In the projection system according to any one of [1] to [5], the control device may be configured such that the state of the projection surface of the screen device is an integer multiple of 2 or more of the frame frequency of the video signal. The screen device is controlled to switch according to the frequency.
[8] The projection system according to any one of [1] to [7], wherein the projection apparatus captures the video signal based on the capture control and writes the video signal to a storage unit for each pixel, and a light source. The image display unit displays the image by the light emitted from the light source, converts the image into the image light and projects the image light, and the control device reflects the light The video signal is written to the video display unit within a period when the degree is the first reflection degree.
[9] In the projection system according to [8], the light source is configured to emit light for converting the image displayed on the image display unit into the image light based on switching control. The control device controls the light source to emit no light within a period in which the reflection degree of the light becomes the first reflection degree.
[10] The projection system according to any one of [1] to [7], wherein the projection device captures the video signal based on the capture control, converts the image signal into a light beam, and scans the light beam in two dimensions. The control device projects the light beam two-dimensionally within a period in which the reflection degree of the light is the second reflection degree.

  According to the present invention, an image with high image quality and high visibility can be displayed in a bright room.

1 is a block diagram illustrating a schematic configuration of a projection system according to a first embodiment of the present invention. 6 is a timing chart showing operation timings of various signals generated by the control device of the projection system in the embodiment. It is a figure which shows notionally the mode of the addressing of the video display part by an analog display system in the embodiment. It is a timing chart which shows the operation timing of the various signals which a control device generates in the modification of the embodiment. It is a block diagram which shows the schematic structure of the projection system which is 2nd Embodiment of this invention. 6 is a timing chart showing operation timings of various signals generated by the control device of the projection system in the embodiment. It is a block diagram which shows the schematic structure of the projection system which is 3rd Embodiment of this invention. 4 is a timing chart showing operation timings of various signals generated by the control device in the embodiment. It is a block diagram which shows the schematic structure of the projection system which is 4th Embodiment of this invention. 4 is a timing chart showing operation timings of various signals generated by the control device in the embodiment. It is a block diagram which shows the schematic structure of the projection system which is 5th Embodiment of this invention. 4 is a timing chart showing operation timings of various signals generated by the control device in the embodiment. It is a block diagram which shows the schematic structure of the projection system which is 6th Embodiment of this invention. 4 is a timing chart showing operation timings of various signals generated by the control device in the embodiment. It is a figure which shows notionally the mode of an addressing at the time of applying the video display part by a digital display system to a projection apparatus in 7th Embodiment of this invention. It is a timing chart which shows the operation timing of the various signals which the control device of a projection system in the 8th embodiment of the present invention generates.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
[First Embodiment]
FIG. 1 is a block diagram showing a schematic configuration of a projection system according to the first embodiment of the present invention. As shown in FIG. 1, the projection system 1 includes a control device 10, a projection device 20, a screen device 30, and an illumination device 40. Projecting device 20 is installed in the projection chamber R _1, the screen device 30 and the lighting device 40 is installed for viewing chamber R _2. The projection room R ₁ and the viewing room R ₂ are provided so as to prevent or minimize the incidence of light from outside (external light).

  The projection device 20 is a projector device that takes in a video signal supplied from a video signal supply device (not shown), generates video light based on the video signal, and projects the video light. The video signal supply device is, for example, a computer device, a video playback device, a video camera device, or the like that stores video data in an internal or attached storage device.

The projection device 20 includes, for example, a known three-plate color separation / synthesis optical system as a configuration of the optical system. Specifically, the projection device 20 includes a light source, a spectroscopic unit, three video display units (for red, green, and blue) and a projection optical system, all not shown.
The light source is a light emitting unit that emits light (for example, white light). The light source is realized by, for example, an LED (Light Emitting Diode), a laser diode, or a phosphor.
The spectroscopic unit is a spectroscope that splits light emitted from the light source into red light, green light, and blue light. The spectroscopic unit is realized including, for example, a dichroic prism.

  In the present embodiment, each of the three video display units is a video display element based on an analog display method. The analog display method is a method of expressing gradation according to the level of the instantaneous luminance value. Each video display unit is a spatial light modulation element having a storage unit (storage unit) for each pixel. Each video display unit takes in an address period signal supplied from the control device 10, and takes in a video signal of each color only within an addressing permission period indicated by this address period signal and stores it in the storage unit (addressing). Although details will be described later, the addressing permission period is a part of the frame period. Therefore, each video display unit in the present embodiment holds (stores) pixel information captured by addressing in one frame period.

The red video display unit takes in the red video signal from the video signals and displays the red component video. The red image display unit receives the red light dispersed by the spectroscope and outputs red component image light.
The green video display unit takes in the green video signal from the video signals and displays a green component video. The green image display unit receives the green light dispersed by the spectroscope and outputs the green component image light.
The blue video display unit captures a blue video signal of the video signals and displays a blue component video. The blue image display unit receives blue light dispersed by the spectroscope and outputs blue component video light.

  Each video display unit may be a reflective display element or a transmissive display element. Each video display unit is realized by, for example, a liquid crystal display element (for example, LCOS; Liquid Crystal On Silicon).

  The projection optical system combines a red component, a green component, and a blue component output from the three video display units to generate color image light, and the generated image light to the outside. And a projection lens optical system for projecting. The light combining unit is realized including, for example, a cross dichroic prism.

  The three-plate color separation / combination optical system is an example, and other than this, for example, a single-plate type optical system or a four-plate type color separation / synthesis optical system may be incorporated in the projection apparatus 20. The single-plate optical system obtains a color image using a single image display unit, and is realized by a known method such as a color filter method or a microlens spectroscopic method. The four-plate color separation / combination optical system separates the green image signal into two systems, and the other green component image is separated from the image of one green component by 0.5 or both in the horizontal direction or the vertical direction. The four colors of the first green color, the second green color, the red color, and the blue color are used by shifting pixels.

The control device 10 takes in the video signal supplied from the video signal supply device, extracts a frame synchronization signal from the video signal, and synchronizes with the timing of the frame period indicated by the frame synchronization signal. Switching of the light reflection degree (first reflection degree and second reflection degree) on the projection surface, switching of the illumination state of the illumination device 40 (first illumination state and second illumination state), and projection device It controls the addressing of 20 video display units.
The frame synchronization signal is a signal indicating the frame period of the video, in other words, for example, a vertical synchronization signal. The degree of reflection of light on the projection surface is, for example, the reflectance of light on the projection surface of the screen device 30 and indicates the degree to which light arriving on the projection surface from the projection system 1 and the illumination device 40 is reflected to the viewpoint position. is there. The second reflection degree is higher than the first reflection degree. The first illumination state is a state in which the illuminance by the illumination device 40 is higher than that in the second illumination state. In the present embodiment, the first illumination state is turned on and the second illumination state is turned off.

The control device 10 includes a frame synchronization signal acquisition unit 11 and a timing control unit 12 as its functional configuration.
The frame synchronization signal acquisition unit 11 takes in the video signal, extracts the frame synchronization signal from the video signal, and supplies the frame synchronization signal to the timing control unit 12. For example, the frame synchronization signal acquisition unit 11 takes in an RGB component video signal, extracts a vertical synchronization signal from the RGB component video signal, and supplies the vertical synchronization signal to the timing control unit 12 as a frame synchronization signal.

  Note that when the video signal is an RGB component video signal and the vertical synchronization signal and other signals are separated, the frame synchronization signal acquisition unit 11 is omitted, and the video signal supply device performs vertical synchronization. Only the signal may be directly supplied to the timing controller 12.

The timing control unit 12 takes in the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is the first reflection degree and the first reflection degree. A screen control signal for changing the state of the projection surface so as to have one of the reflection degrees of 2 is generated, and this screen control signal is supplied to the screen device 30.
Specifically, for example, the timing control unit 12 sets a period during which the light reflection degree is set to the first reflection degree to 0 (zero) level, a period to set the second reflection degree to the positive level, and the frame synchronization signal. Is generated as a screen control signal, and the screen control signal is supplied to the screen device 30.

Further, the timing control unit 12 generates an illumination control signal for alternately switching the illumination state of the illumination device 40 between the first illumination state and the second illumination state based on the frame synchronization signal and the screen control signal. Then, this illumination control signal is supplied to the illumination device 40.
Specifically, for example, the timing control unit 12 sets the whole period or a part of the period of the first reflection degree indicated by the screen control signal to a positive level as the period of the first illumination state, The other period is set to the 0 (zero) level as the period for entering the second illumination state, an illumination control signal synchronized with the frame period indicated by the frame synchronization signal is generated, and the illumination control signal is supplied to the illumination device 40.

Further, the timing control unit 12 generates an address period signal indicating an addressing permission period that is a period during which addressing is permitted for each video display unit of the projection device 20 based on the frame synchronization signal and the screen control signal. An address period signal is supplied to the projection device 20.
Specifically, for example, the timing control unit 12 sets the whole period or a part of the period of the first reflection degree indicated by the screen control signal as a positive level as the addressing permission period, and sets the other periods to 0 ( The address period signal synchronized with the frame period indicated by the frame synchronization signal is generated, and this address period signal is supplied to the projection device 20.

  In response to the end of the addressing for each frame by the three video display units, the projection device 20 supplies a screen control request signal to the timing control unit 12, and the timing control unit 12 outputs the screen control request. The screen control signal may be generated by capturing the signal so that the reflection degree of the light becomes the second reflection degree.

  The screen device 30 is a display device that has a projection surface and displays the image by projecting the image light projected from the projection device 20 onto the projection surface. The screen device 30 takes in the screen control signal supplied from the timing control unit 12 of the control device 10, and based on the screen control signal, the reflection degree of the light on the projection surface is the first reflection degree and the second reflection degree. The state of the projection plane is changed so as to become one of the degrees. For example, when the level of the screen control signal is 0 (zero) level, the screen device 30 sets the reflection degree of light on the projection surface to the first reflection degree, and the level of the screen control signal is a positive level. Sometimes, the reflection degree of light on the projection surface is set to the second reflection degree.

  The screen device 30 is configured by a member that can electrically change the degree of reflection of light on the projection surface. In the present embodiment, for example, an electronic powder fluid (registered trademark) is applied as a member capable of electrically changing the degree of light reflection. Electron powder fluid (registered trademark) has a high response time of about 0.2 milliseconds. The projection surface of the screen device 30 constituted by the electronic powder fluid (registered trademark) has, for example, no color and low brightness when the light reflection degree is set to the first reflection degree, and the second reflection. When the degree is set, for example, the color has no color and high brightness. The color having no color and low brightness is, for example, black or dark gray. Moreover, the color with no color and high brightness is, for example, white or light gray.

The details of the electronic powder fluid (registered trademark) are disclosed in the following documents.
Y. Masuda, et. Al., “Novel type of Multi-Stable Reflective Display using Electric Powder”, Proc. Of IDW / AD '05, EP1-1, pp.821-824

Illumination apparatus 40 is an illumination adjusting device for illuminating the interior of the viewing chamber R _2. The illumination device 40 takes in the illumination control signal supplied from the timing control unit 12 of the control device 10, and based on the illumination control signal, the illumination state is changed into the first illumination state (lighted) and the second illumination state. Switch between (lights off). For example, the lighting device 40 is in the first lighting state when the lighting control signal is at the positive level, and is in the second lighting state when the lighting control signal is at the 0 (zero) level. The illumination unit of the illumination device 40 is realized by, for example, LED illumination that emits white light.

In this embodiment, as shown in FIG. 1, the projection room R ₁ and the viewing room R ₂ are separated, but the illumination light of the illumination device 40 enters the projection lens optical system of the projection device 20. If a possibility that there are no, or quantity of such illumination effect to the extent not undergo is small, it may be installed a projection device 20 and the screen unit 30 and the lighting device 40 for viewing chamber R _2.

FIG. 2 is a timing chart showing operation timings of various signals generated by the control device 10 of the projection system 1. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
As shown in the figure, the interval between the rising edges of adjacent pulses indicated by the frame synchronization signal is one frame period of the video.
The screen control signal is a period of 0 (zero) level (“darkness”), which is a period in which the light reflection state of the projection surface of the screen device 30 is set to the first reflectivity within one frame period indicated by the frame synchronization signal. And a period of positive level (denoted as “bright”), which is the period of the second reflectivity.
The duty ratio of the rectangular wave in the screen control signal may be 50% or may be other than that.

The illumination control signal is set to a positive level (denoted as “lighting”) as a period for entering the first illumination state, with the entire period or a part of the period corresponding to the first reflectivity indicated by the screen control signal being set. This period is set to 0 (zero) level (denoted as “lights off”) as the period for entering the second illumination state, and is synchronized with the frame period indicated by the frame synchronization signal.
According to FIG. 2, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.

  The address period signal is a positive level (denoted as “permitted”) with the period of the first reflectivity indicated by the screen control signal as the addressing permission period, the other period is set to 0 (zero) level, and the frame synchronization signal is It is synchronized with the frame period shown.

FIG. 3 is a diagram conceptually showing an addressing state of the video display unit by the analog display method. In the conceptual diagram of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the rows. FIG. 2 is an enlarged view of the time axis scale with respect to FIG.
As shown in FIG. 3, for each of the first frame and the second frame, the light reflection state of the projection surface in the screen device 30 is the first reflection degree (“dark”), and the address permission period (“ Within the permission “), each video display unit based on the analog display method performs a video signal writing process. Moreover, the illuminating device 40 lights up in the period used as 1st reflectivity. On the other hand, during the period excluding the address permission period, each video display unit does not perform the video signal writing process and holds the video signal written immediately before.

  As described above, the control device 10 in the projection system 1 according to the first embodiment of the present invention projects on the screen device 30 when the illumination of the illumination device 40 is in the first illumination state (for example, lighting). Control is performed to reduce the degree of reflection of light on the surface and to allow addressing of the video display unit of the projection device 20.

  According to this configuration, in the projection system 1, when the illumination device 40 is set to the first illumination state, the reflection degree of light on the projection surface of the screen device 30 is reduced (becomes the first reflection degree). Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20 is dark. On the other hand, in a portion where the image projected by the projector 20 is bright, the reflected light in the period when the reflection degree of the light on the projection surface is high (the period when the reflection degree is the second) reaches the viewer's eyes.

Therefore, according to the projection system 1, even in an environment where viewing chamber R ₂ by the illumination unit 40 is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20 is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Therefore, according to the projection system 1 of the present embodiment, it is possible to display an image with high image quality and high visibility in a bright room.

[Modification of First Embodiment]
In the first embodiment described above, the timing control unit 12 sets the period in which the light reflection degree is set to the first reflection degree to 0 (zero) level, the period to make the second reflection degree to the positive level, and the frame frequency. The screen control signal having the same frequency as that of the screen control signal is generated, and the screen control signal is supplied to the screen device 30.
In the modification of the first embodiment, the timing control unit 12 generates a screen control signal having a frequency that is an integer multiple of 2 or more of the frame frequency.

Since the configuration of the projection system according to this modification is the same as that of the projection system 1 according to the first embodiment, the block diagram of this modification will be omitted and described with reference to FIG.
In the present modification, the frame synchronization signal acquisition unit 11 of the control device 10 has the same configuration as the frame synchronization signal acquisition unit 11 according to the first embodiment. Therefore, the description here is omitted.
The timing control unit 12 of the control device 10 performs timing control different from the timing control unit 12 in the first embodiment. Therefore, the projection device 20, the screen device, and the illumination device 40 operate at an operation timing different from that of the first embodiment.

The timing control unit 12 takes in the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is the first reflection degree and the second reflection degree. A screen control signal for changing the state of the projection surface so as to be one of the reflection degrees of the screen is generated, and the screen control signal is supplied to the screen device 30.
Specifically, for example, the timing control unit 12 sets a period during which the light reflection degree is set to the first reflection degree to 0 (zero) level, a period to set the second reflection degree to the positive level, and the frame synchronization signal. Is generated as a screen control signal, and the screen control signal is supplied to the screen device 30.

Similarly to the first embodiment, the timing control unit 12 alternates the lighting state of the lighting device 40 between the first lighting state and the second lighting state based on the frame synchronization signal and the screen control signal. The illumination control signal to be switched to is generated, and this illumination control signal is supplied to the illumination device 40.
Specifically, for example, the timing control unit 12 sets the whole period or a part of the period of the first reflection degree indicated by the screen control signal to a positive level as the period of the first illumination state, The other period is set to the 0 (zero) level as the period for entering the second illumination state, an illumination control signal synchronized with the frame period indicated by the frame synchronization signal is generated, and the illumination control signal is supplied to the illumination device 40.

Further, the timing control unit 12 generates an address period signal indicating an addressing permission period for each video display unit of the projection device 20 based on the frame synchronization signal and the screen control signal. To supply.
Specifically, for example, the timing control unit 12 sets, for each frame period, a positive level in which the entire period or a part of the first period corresponding to the first reflectivity indicated by the screen control signal is set as the addressing permission period. The other period is set to 0 (zero) level, an address period signal synchronized with the frame period indicated by the frame synchronization signal is generated, and this address period signal is supplied to the projection apparatus 20. That is, the pulse period of the address period signal generated by the timing control unit 12 is the same as the frame period.

  As in the first embodiment, the timing control unit 12 sets the whole period or a part of the period of the first reflectivity indicated by the screen control signal as a positive level as the addressing permission period, and other periods. May be set to 0 (zero) level, and an address period signal synchronized with the frame period indicated by the frame synchronization signal may be generated.

FIG. 4 is a timing chart showing operation timings of various signals generated by the control device 10 according to this modification. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
As shown in the figure, the interval between the rising edges of adjacent pulses indicated by the frame synchronization signal is one frame period of the video.
The screen control signal is a period of 0 (zero) level (“darkness”), which is a period in which the light reflection state of the projection surface of the screen device 30 is set to the first reflectivity within one frame period indicated by the frame synchronization signal. And a period of positive level (denoted as “bright”), which is a period for which the second reflectivity is set, are included twice. That is, the frequency of the pulse of the screen control signal is twice the frame frequency.

The illumination control signal is set to a positive level (denoted as “lighting”) as a period for entering the first illumination state, with the entire period or a part of the period corresponding to the first reflectivity indicated by the screen control signal being set. This period is set to 0 (zero) level (denoted as “lights off”) as the period for entering the second illumination state, and is synchronized with the frame period indicated by the frame synchronization signal.
According to FIG. 4, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.

  The address period signal is set to a positive level (denoted as “permitted”) with the first period of the first reflectivity indicated by the screen control signal as the addressing permission period for each frame period, and the other periods are set to 0 (zero). The level is synchronized with the frame period indicated by the frame synchronization signal. That is, the pulse period of the address period signal generated by the timing control unit 12 is the same as the frame period.

  As described above, in the projection system 1 which is a modification of the first embodiment, the pulse frequency of each of the screen control signal and the illumination control signal is an integer multiple of 2 or more of the frame frequency. Flicker on the projection surface can be reduced or eliminated.

[Second Embodiment]
About the same structure as the projection system 1 which is 1st Embodiment mentioned above, the same structure name and the same code | symbol are attached | subjected, and the description is abbreviate | omitted.
FIG. 5 is a block diagram showing a schematic configuration of a projection system according to the second embodiment of the present invention. As shown in the figure, the projection system 1a has a configuration in which the control device 10 and the projection device 20 are changed to the control device 10a and the projection device 20a with respect to the projection system 1 according to the first embodiment.

  The projection device 20a controls the light emission of the light source in addition to the function of the projection device 20 in the first embodiment. That is, the projection device 20a takes in the light source control signal supplied from the control device 10a and supplies this light source control signal to the light source. The light source switches between non-emission and emission based on the supplied light source control signal. Details of the light source control signal will be described later.

  The control device 10a takes in a video signal supplied from a video signal supply device (not shown), extracts a frame synchronization signal from the video signal, and projects the screen device 30 based on the timing of the frame period indicated by the frame synchronization signal. Switching of the light reflection degree (first reflection degree and second reflection degree) on the surface, switching of the illumination state (first illumination state and second illumination state) of the illumination device 40, and the projection device 20a The non-light emission and light emission switching of the light source and the addressing of the video display unit of the projector 20a are controlled. In the present embodiment, the first illumination state is turned on and the second illumination state is turned off.

  The control device 10a has a configuration in which the timing control unit 12 is changed to the timing control unit 12a with respect to the control device 10 in the first embodiment.

As in the first embodiment, the timing control unit 12a takes in the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is determined. A screen control signal for changing the state of the projection plane so as to be either the first reflection degree or the second reflection degree is generated, and this screen control signal is supplied to the screen device 30.
Similarly to the first embodiment, the timing control unit 12a determines the illumination state of the illumination device 40 based on the frame synchronization signal and the screen control signal as the first illumination state (lighted) and the second illumination state. An illumination control signal that is switched alternately between (lights off) is generated, and this illumination control signal is supplied to the illumination device 40.

Further, the timing control unit 12a generates a light source control signal for alternately switching non-light emission and light emission of the light source of the projection device 20a based on the frame synchronization signal and the screen control signal, and the light source control signal is generated by the projection device 20a. To supply.
Specifically, for example, the timing control unit 12a sets the first reflection degree period indicated by the screen control signal to a non-emission period (non-emission period) as 0 (zero) level, and other periods. Is set to a positive level as a light emission period (light emission period), a light source control signal synchronized with the frame period indicated by the frame synchronization signal is generated, and this light source control signal is supplied to the projection device 20a.

  Further, as in the first embodiment, the timing control unit 12a, based on the frame synchronization signal and the screen control signal, indicates an addressing permission period that is a period during which addressing is permitted for the video display unit of the projection device 20a. A period signal is generated, and this address period signal is supplied to the projection device 20a.

FIG. 6 is a timing chart showing operation timings of various signals generated by the control device 10a of the projection system 1a. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
Of the various signals generated by the control device 10a, the same signals as those generated by the control device 10 according to the first embodiment will be described using the same signal names.

  The light source control signal has a first reflection degree period indicated by the screen control signal as a non-emission period, 0 (zero) level (denoted as “non-emission”), and other periods as emission periods, a positive level (“ Light emission ”) and is synchronized with the frame period indicated by the frame synchronization signal.

According to FIG. 6, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.
Further, the period of the first reflection degree in the screen control signal and the period of non-light emission in the light source control signal are the same period.

  As described above, the control device 10a in the projection system 1a according to the second embodiment of the present invention projects on the screen device 30 when the illumination of the illumination device 40 is in the first illumination state (for example, lighting). Control is performed to reduce the degree of reflection of light on the surface, to turn off the light source of the projection device 20a, and to allow addressing of the video display unit.

  According to this configuration, in the projection system 1a, when the illumination device 40 is set to the first illumination state, the reflection degree of light on the projection surface of the screen device 30 is reduced (becomes the first reflection degree). Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20a is dark. On the other hand, in the portion where the image projected by the projection device 20a is bright, the reflected light in the period when the reflection degree of light on the projection surface is high (the period when the second reflection degree is reached) reaches the viewer's eyes.

Therefore, according to the projection system 1a, even under circumstances where the lighting device 40 is viewing chamber R ₂ is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20a is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Further, the projection system 1 a makes the light source of the projection device 20 a non-light-emitting when the reflection degree of light on the projection surface of the screen device 30 is reduced. Therefore, the power consumption of the projection apparatus 20a can be reduced, and the projection system 1a can perform efficient projection.

  Therefore, according to the projection system 1a of the present embodiment, it is possible to efficiently display an image with high image quality and high visibility in a bright room.

[Third Embodiment]
About the same structure as the projection system 1 which is 1st Embodiment mentioned above, the same structure name and the same code | symbol are attached | subjected, and the description is abbreviate | omitted.
FIG. 7 is a block diagram showing a schematic configuration of a projection system according to the third embodiment of the present invention. As shown in the figure, the projection system 1b has a configuration in which the illumination device 40 is deleted and a shutter device 50 is added to the projection system 1 according to the first embodiment, and the control device 10 is changed to the control device 10b. Have The shutter device 50 is installed in a window provided in the viewing chamber R ₂ to incorporate external light.

  The control device 10b takes in a video signal supplied from a video signal supply device (not shown), extracts a frame synchronization signal from the video signal, and projects the projection of the screen device 30 based on the timing of the frame period indicated by the frame synchronization signal. Switching of the light reflection degree (first reflection degree and second reflection degree) on the surface, switching of the illumination state (first illumination state and second illumination state) of the shutter device 50, and the projection device 20 Control of the video display unit. In the present embodiment, the first illumination state is transmission, and the second illumination state is blocking (light shielding).

  The control device 10b has a configuration in which the timing control unit 12 is changed to a timing control unit 12b with respect to the control device 10 in the first embodiment.

  Similar to the first embodiment, the timing control unit 12b captures the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is determined. A screen control signal for changing the state of the projection plane so as to be either the first reflection degree or the second reflection degree is generated, and this screen control signal is supplied to the screen device 30.

Further, the timing control unit 12b generates a shutter control signal for alternately switching the illumination state of the shutter device 50 between the first illumination state and the second illumination state based on the frame synchronization signal and the screen control signal. Then, this shutter control signal is supplied to the shutter device 50.
Specifically, for example, the timing control unit 12b sets the whole period or a part of the period of the first reflection degree indicated by the screen control signal as a positive level as the period of the first illumination state, The other period is set to 0 (zero) level as a period for entering the second illumination state, a shutter control signal synchronized with the frame period indicated by the frame synchronization signal is generated, and the shutter control signal is supplied to the shutter device 50.

  Similarly to the first embodiment, the timing control unit 12b is an address indicating an addressing permission period, which is a period during which addressing is permitted for the video display unit of the projection device 20, based on the frame synchronization signal and the screen control signal. A period signal is generated, and this address period signal is supplied to the projection apparatus 20.

The shutter device 50 is an illumination adjusting device transmits light incident from the outside through a window of the viewing chamber R _2, or block. The shutter device 50 takes in the shutter control signal supplied from the timing control unit 12b of the control device 10b, and based on the shutter control signal, the illumination state is changed into the first illumination state (transmission) and the second illumination state. Switch between (blocking) and. For example, the shutter device 50 enters the first illumination state when the shutter control signal is at the positive level, and enters the second illumination state when the shutter control signal is at the 0 (zero) level. The shutter device 50 is realized by, for example, a window glass on which a liquid crystal element having a response time of about several milliseconds (for example, 8 milliseconds) is bonded.

FIG. 8 is a timing chart showing operation timings of various signals generated by the control device 10b of the projection system 1b. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
Of the various signals generated by the control device 10b, the same signals as those generated by the control device 10 in the first embodiment will be described using the same signal names.

  The shutter control signal is set to a positive level (denoted as “transmission”) as a period of the first illumination state, with the entire period or a part of the period of the first reflectivity indicated by the screen control signal being set, and the others This period is set to 0 (zero) level (denoted as “blocking”) as the period for entering the second illumination state, and is synchronized with the frame period indicated by the frame synchronization signal.

  According to FIG. 8, in the screen control signal and the shutter control signal, the start timing of the first illumination state in the shutter control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, In addition, the start timing of the period corresponding to the second reflectivity in the screen control signal is simultaneously or delayed with the start timing of the second illumination state in the shutter control signal.

  As described above, the control device 10b in the projection system 1b according to the third embodiment of the present invention sets the projection surface of the screen device 30 when the shutter device 50 is in the first illumination state (for example, transmission). Control is performed to reduce the degree of light reflection and to allow addressing of the video display unit of the projection device 20.

  According to this configuration, in the projection system 1b, when the shutter device 50 is in the first illumination state, the reflection degree of light on the projection surface of the screen device 30 is reduced (becomes the first reflection degree). Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20 is dark. On the other hand, in a portion where the image projected by the projector 20 is bright, the reflected light in the period when the reflection degree of the light on the projection surface is high (the period when the reflection degree is the second) reaches the viewer's eyes.

Therefore, the projection according to the system 1b, even in an environment where viewing chamber R ₂ by the shutter device 50 is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20 is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Therefore, according to the projection system 1b of the present embodiment, it is possible to display an image with high image quality and high visibility in a bright room.

[Fourth Embodiment]
About the same structure as the projection system 1, 1a, 1b from 1st Embodiment mentioned above to 3rd Embodiment, the same structure name and the same code | symbol are attached | subjected, and the description is abbreviate | omitted.
FIG. 9 is a block diagram showing a schematic configuration of a projection system according to the fourth embodiment of the present invention. As shown in the figure, the projection system 1c is the same as the projection system 1 according to the first embodiment except that the illumination device 40 is deleted and a shutter device 50 is added, and the control device 10 and the projection device 20 are connected to the control device. 10c and the projector 20a.

  The control device 10c takes in a video signal supplied from a video signal supply device (not shown), extracts a frame synchronization signal from the video signal, and projects the projection of the screen device 30 based on the timing of the frame period indicated by the frame synchronization signal. Switching of the reflection degree of light (first reflection degree and second reflection degree) on the surface, switching of the illumination state of the shutter device 50 (first illumination state and second illumination state), and projection device 20a The non-light emission and light emission switching of the light source and the addressing of the video display unit of the projector 20a are controlled. In the present embodiment, the first illumination state is transmission, and the second illumination state is blocking (light shielding).

  The control device 10c has a configuration in which the timing control unit 12 is changed to a timing control unit 12c with respect to the control device 10 in the first embodiment.

Similar to the first embodiment, the timing control unit 12c captures the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is determined. A screen control signal for changing the state of the projection plane so as to be either the first reflection degree or the second reflection degree is generated, and this screen control signal is supplied to the screen device 30.
Similarly to the third embodiment, the timing controller 12c determines the illumination state of the shutter device 50 as the first illumination state (transmission) and the second illumination state based on the frame synchronization signal and the screen control signal. A shutter control signal that is switched alternately between (shut off) is generated, and this shutter control signal is supplied to the shutter device 50.

Similarly to the second embodiment, the timing control unit 12c generates a light source control signal for alternately switching between non-emission and emission of the light source of the projection device 20a based on the frame synchronization signal and the screen control signal, This light source control signal is supplied to the projection device 20a.
Similarly to the first embodiment, the timing control unit 12c has an address indicating an addressing permission period that is a period during which addressing is permitted for the video display unit of the projection device 20a based on the frame synchronization signal and the screen control signal. A period signal is generated, and this address period signal is supplied to the projection device 20a.

FIG. 10 is a timing chart showing operation timings of various signals generated by the control device 10c of the projection system 1c. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
Of the various signals generated by the control device 10c, the same signals as those generated by the control devices 10, 10a, 10b from the first embodiment to the third embodiment are used with the same signal names. Description is omitted.

According to FIG. 10, in the screen control signal and the shutter control signal, the start timing of the first illumination state in the shutter control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, In addition, the start timing of the period corresponding to the second reflectivity in the screen control signal is simultaneously or delayed with the start timing of the second illumination state in the shutter control signal.
Further, the period of the first reflection degree in the screen control signal and the period of non-light emission in the light source control signal are the same period.

  As described above, the control device 10c in the projection system 1c according to the fourth embodiment of the present invention sets the projection surface of the screen device 30 when the shutter device 50 is in the first illumination state (for example, transmission). Control is performed to reduce the degree of light reflection, to turn off the light source of the projection device 20a, and to allow addressing of the video display unit.

  According to this configuration, in the projection system 1c, when the shutter device 50 is in the first illumination state, the reflection degree of light on the projection surface of the screen device 30 is reduced (becomes the first reflection degree). Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20a is dark. On the other hand, in the portion where the image projected by the projection device 20a is bright, the reflected light in the period when the reflection degree of light on the projection surface is high (the period when the second reflection degree is reached) reaches the viewer's eyes.

Therefore, the projection according to the system 1c, even under circumstances where viewing chamber R ₂ by the shutter device 50 is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20a is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Furthermore, the projection system 1c causes the light source of the projection device 20a to emit no light when the degree of light reflection on the projection surface of the screen device 30 is reduced. Therefore, the power consumption of the projection device 20a can be reduced, and the projection system 1c can perform efficient projection.

  Therefore, according to the projection system 1c of the present embodiment, it is possible to efficiently display an image with high image quality and high visibility in a bright room.

[Fifth Embodiment]
About the same structure as the projection system 1 which is 1st Embodiment mentioned above, and the projection system 1b which is 3rd Embodiment, the same structure name and the same code | symbol are attached | subjected, and the description is abbreviate | omitted.
FIG. 11 is a block diagram showing a schematic configuration of a projection system according to the fifth embodiment of the present invention. As shown in the figure, the projection system 1d has a configuration in which a shutter device 50 is added to the projection system 1 according to the first embodiment, and the control device 10 is changed to the control device 10d.

  The control device 10d takes in a video signal supplied from a video signal supply device (not shown), extracts a frame synchronization signal from the video signal, and projects the projection of the screen device 30 based on the timing of the frame period indicated by the frame synchronization signal. Switching of the light reflection degree (first reflection degree and second reflection degree) on the surface, switching of the illumination state of the illumination device 40 (first illumination state and second illumination state), and shutter device 50 Switching of the illumination states (third illumination state and fourth illumination state) and addressing of the video display unit of the projection device 20 are controlled. In the present embodiment, the first illumination state is turned on, the second illumination state is turned off, the third illumination state is transmitted, and the fourth illumination state is blocked (shielded).

  The control device 10d has a configuration in which the timing control unit 12 is changed to a timing control unit 12d with respect to the control device 10 in the first embodiment.

Similar to the first embodiment, the timing control unit 12d captures the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the reflection degree of light on the projection surface of the screen device 30 is determined. A screen control signal for changing the state of the projection plane so as to be either the first reflection degree or the second reflection degree is generated, and this screen control signal is supplied to the screen device 30.
Similarly to the first embodiment, the timing control unit 12d alternately changes the lighting state of the lighting device 40 between the first lighting state and the second lighting state based on the frame synchronization signal and the screen control signal. The illumination control signal to be switched to is generated, and this illumination control signal is supplied to the illumination device 40.

Similarly to the third embodiment, the timing control unit 12d alternates the illumination state of the shutter device 50 between the third illumination state and the fourth illumination state based on the frame synchronization signal and the screen control signal. A shutter control signal to be switched to is generated, and this shutter control signal is supplied to the shutter device 50.
Similarly to the first embodiment, the timing control unit 12d is an address indicating an addressing permission period, which is a period during which addressing is permitted for the video display unit of the projection device 20, based on the frame synchronization signal and the screen control signal. A period signal is generated, and this address period signal is supplied to the projection apparatus 20.

FIG. 12 is a timing chart showing operation timings of various signals generated by the control device 10d of the projection system 1d. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
Of the various signals generated by the control device 10d, the same signals as those generated by the control devices 10 and 10b in the first and third embodiments are used and the description thereof is omitted. To do.

According to FIG. 12, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.
Similarly, in the screen control signal and the shutter control signal, the start timing of the third illumination state in the shutter control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, and The start timing of the second reflection degree period in the screen control signal is simultaneous or delayed with the start timing of the fourth illumination state in the shutter control signal.

  As described above, the control device 10d in the projection system 1d according to the fifth embodiment of the present invention sets the illumination device 40 to the first illumination state (for example, lighting) and sets the shutter device 50 to the third illumination state. When (for example, transmission) is selected, control is performed to reduce the degree of reflection of light on the projection surface of the screen device 30 and to permit addressing of the video display unit of the projection device 20.

  According to this configuration, in the projection system 1d, when the illumination device 40 is in the first illumination state and the shutter device 50 is in the third illumination state, the degree of light reflection on the projection surface of the screen device 30 is reduced. Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20 is dark. On the other hand, in a portion where the image projected by the projector 20 is bright, the reflected light in the period when the reflection degree of the light on the projection surface is high (the period when the reflection degree is the second) reaches the viewer's eyes.

Therefore, according to the projection system 1d, even under circumstances where the lighting device 40 and the shutter device 50 is viewing chamber R ₂ is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20 is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Therefore, according to the projection system 1d of the present embodiment, it is possible to display an image with high image quality and high visibility in a bright room.

[Sixth Embodiment]
About the same structure as the projection system 1, 1a, 1b from 1st Embodiment mentioned above to 3rd Embodiment, the same structure name and the same code | symbol are attached | subjected, and the description is abbreviate | omitted.
FIG. 13 is a block diagram showing a schematic configuration of a projection system according to the sixth embodiment of the present invention. As shown in the figure, the projection system 1e adds a shutter device 50 to the projection system 1 according to the first embodiment, and changes the control device 10 and the projection device 20 to the control device 10e and the projection device 20a. The configuration is as follows.

  The control device 10e takes in a video signal supplied from a video signal supply device (not shown), extracts a frame synchronization signal from the video signal, and projects the projection of the screen device 30 based on the timing of the frame period indicated by the frame synchronization signal. Switching of the light reflection degree (first reflection degree and second reflection degree) on the surface, switching of the illumination state of the illumination device 40 (first illumination state and second illumination state), and shutter device 50 Switching of the illumination states (third illumination state and fourth illumination state), non-emission and emission switching of the light source of the projection device 20a, and addressing of the video display unit of the projection device 20a are controlled. In the present embodiment, the first illumination state is turned on, the second illumination state is turned off, the third illumination state is transmitted, and the fourth illumination state is blocked (shielded).

  The control device 10e has a configuration in which the timing control unit 12 is changed to a timing control unit 12e with respect to the control device 10 in the first embodiment.

As in the first embodiment, the timing control unit 12e takes in the frame synchronization signal supplied from the frame synchronization signal acquisition unit 11, and based on the frame synchronization signal, the degree of light reflection on the projection surface of the screen device 30 is determined. A screen control signal for changing the state of the projection plane so as to be either the first reflection degree or the second reflection degree is generated, and this screen control signal is supplied to the screen device 30.
Similarly to the first embodiment, the timing control unit 12e alternates the lighting state of the lighting device 40 between the first lighting state and the second lighting state based on the frame synchronization signal and the screen control signal. The illumination control signal to be switched to is generated, and this illumination control signal is supplied to the illumination device 40.

Similarly to the third embodiment, the timing control unit 12e alternates the illumination state of the shutter device 50 between the third illumination state and the fourth illumination state based on the frame synchronization signal and the screen control signal. A shutter control signal to be switched to is generated, and this shutter control signal is supplied to the shutter device 50.
Similarly to the second embodiment, the timing control unit 12e generates a light source control signal that alternately switches between non-emission and emission of the light source of the projection device 20a based on the frame synchronization signal and the screen control signal, This light source control signal is supplied to the projection device 20a.
Similarly to the first embodiment, the timing control unit 12e is an address indicating an addressing permission period that is a period during which addressing is permitted for the video display unit of the projection device 20a based on the frame synchronization signal and the screen control signal. A period signal is generated, and this address period signal is supplied to the projection device 20a.

FIG. 14 is a timing chart showing operation timings of various signals generated by the control device 10e of the projection system 1e. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
Of the various signals generated by the control device 10e, the same signals as those generated by the control devices 10, 10a, and 10b in the first to third embodiments are denoted by the same signal names. Description is omitted.

According to FIG. 14, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.
Similarly, in the screen control signal and the shutter control signal, the start timing of the third illumination state in the shutter control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, and The start timing of the second reflection degree period in the screen control signal is simultaneous or delayed with the start timing of the fourth illumination state in the shutter control signal.
Further, the period of the first reflection degree in the screen control signal and the period of non-light emission in the light source control signal are the same period.

  As described above, the control device 10e in the projection system 1e according to the sixth embodiment of the present invention sets the illumination device 40 to the first illumination state (for example, lighting) and sets the shutter device 50 to the third illumination state. When (for example, transmissive) is selected, the degree of reflection of light on the projection surface of the screen device 30 is reduced, the light source of the projection device 20a is turned off, and the video display unit of the projection device 20a is allowed to be addressed. Control as follows.

  According to this configuration, in the projection system 1e, when the illumination device 40 is in the first illumination state and the shutter device 50 is in the third illumination state, the degree of light reflection on the projection surface of the screen device 30 is reduced. Therefore, the amount of reflected light from the projection surface can be greatly reduced. Therefore, the brightness of the display image can be significantly reduced in a portion where the image projected by the projection device 20a is dark. On the other hand, in the portion where the image projected by the projection device 20a is bright, the reflected light in the period when the reflection degree of light on the projection surface is high (the period when the second reflection degree is reached) reaches the viewer's eyes.

Therefore, according to the projection system 1e, even under circumstances where the lighting device 40 and the shutter device 50 is viewing chamber R ₂ is illuminated, it is possible to contrast obtain very legible image high. At that time, the address period during which the video signal is written to the video display unit based on the analog display method of the projection apparatus 20a is limited to a period during which the reflection degree of light on the projection surface is reduced (within the period when the first reflection degree is reached). Therefore, an image lacking in a strip shape is not displayed in the vertical direction of the frame, or an image with awkward movement is not displayed, and deterioration of the moving image quality of the image can be prevented.

  Furthermore, the projection system 1e makes the light source of the projection device 20a non-light-emitting when reducing the degree of light reflection on the projection surface of the screen device 30. Therefore, the power consumption of the projection device 20a can be reduced, and the projection system 1e can perform efficient projection.

  Therefore, according to the projection system 1e of the present embodiment, it is possible to efficiently display an image with high image quality and high visibility in a bright room.

[Seventh Embodiment]
In the projection systems 1 and 1a to 1e according to the first embodiment (including the modification example) to the sixth embodiment described above, the projection devices 20 and 20a take in the video signal supplied from the video signal supply device, and this video The projector is configured to generate video light by displaying a signal on a video display unit using an analog display method and project the video light.
In addition to this, the present invention can be applied to a projection system including a projection device that generates a video light by displaying a video signal on a video display unit using a digital display method, and projects the video light.
Hereinafter, as a seventh embodiment, an example using a digital display type projection apparatus will be described.

  In the present embodiment, each of the three video display units is a video display element based on a digital display method. The digital display method is a method of expressing a gradation by a time ratio of luminance value ON / OFF, that is, by pulse width modulation. Each video display unit captures a video signal only within the addressing permission period indicated by the address period signal supplied from the control device in the present embodiment, as in the above-described embodiments. Each video display unit is realized by, for example, DMD (Digital MicroMirror Device).

In this projection apparatus, a control signal indicating a timing at which a video signal is taken into the video display unit, that is, a video signal writing timing to the video display unit is used as an address period signal.
The control device limits a period in which the reflection degree of the light on the projection surface of the screen device 30 is the first reflection degree to an addressing permission period indicated by the address period signal.
That is, in the present embodiment, the address period signal, the screen control signal, the illumination control signal, the shutter control signal, and the light source control signal are asynchronous with the frame period of the frame synchronization signal.

FIG. 15 is a diagram conceptually showing a state of addressing when a video display unit based on a digital display method is applied to the projection device 20 in the configuration of the first embodiment. In the conceptual diagram of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the rows. In the figure, only a part of one frame period is shown in order to clearly show details.
As shown in the drawing, the light reflection state of the projection surface in the screen device 30 is a period in which the first reflection degree (“dark”) is obtained, and the digital display method is used within the address permission period (“permission”). Each video display unit performs a video signal writing process. Moreover, the illuminating device 40 lights up in the period used as 1st reflectivity. On the other hand, during the period excluding the address permission period, each video display unit does not perform the video signal writing process and holds the video signal written immediately before.

  According to the present embodiment, it is possible to obtain an image with high contrast and very easy to see even in a bright environment. At that time, the address period during which the video signal is written to the video display unit based on the digital display system of the projection apparatus is limited to a period during which the degree of light reflection on the projection surface is reduced, thereby preventing deterioration of the video quality of the video. be able to.

  Therefore, according to the projection system of this embodiment, it is possible to display an image with high image quality and high visibility in a bright room.

[Eighth Embodiment]
In the projection systems 1 and 1a to 1e according to the first embodiment (including the modified example) to the seventh embodiment described above, the projection apparatuses 20 and 20a each include a spatial light modulation element having a storage unit for each pixel as an image display unit. It was set as the projector apparatus used as.
In addition to this, in the projection systems 1, 1b, and 1d in the first embodiment (including the modification), the third embodiment, and the fifth embodiment, the projection device 20 converts the video signal into a light beam that is beam light. The present invention can be applied in place of a scanning projection device that converts and projects a two-dimensional image on a screen by performing two-dimensional scanning with the light beam.
Hereinafter, an example using a scanning projection apparatus will be described as an eighth embodiment.

  In the present embodiment, the video display unit takes in an address period signal (also referred to as a scanning period signal) supplied from the control device, and a beam converted from the video signal only within a scanning permission period indicated by the address period signal. Image display element that receives scanning of a light beam. The video display unit is realized by, for example, a MEMS (Micro Electro Mechanical Systems) scanner that projects color laser light two-dimensionally and projects an image on a screen. The projection apparatus provided with this video display unit is realized by, for example, a laser projector apparatus.

In the scanning type projection apparatus, the scanning permission period indicated by the address period signal is the same as the address period signal generated by the control devices 10 and 10a to 10e in the first embodiment (including the modified example) to the seventh embodiment. This is a period excluding the addressing permission period shown.
That is, the timing control unit of the control device according to the present embodiment sets the entire period or a part of the period corresponding to the second reflectivity indicated by the screen control signal as the scanning permission period, and prohibits the other periods from scanning. An address period signal is generated as a period, and this address period signal is supplied to the scanning projection apparatus.

Next, taking the configuration of the projection system 1 shown in FIG. 1 as an example, the configuration of the projection system according to the eighth embodiment will be described. Only parts different from the projection system 1 according to the first embodiment will be described.
Based on the frame synchronization signal and the screen control signal, the timing control unit 12 generates an address period signal indicating an addressing permission period, which is a period during which addressing is permitted for each video display unit of the projection device 20, and this address period A signal is supplied to the projection device 20.
Specifically, for example, the timing control unit 12 sets the whole period or a part of the period of the second reflection degree indicated by the screen control signal as a positive level as the addressing permission period, and sets the other periods to 0 ( The address period signal synchronized with the frame period indicated by the frame synchronization signal is generated, and this address period signal is supplied to the projection device 20.

  In response to the end of the addressing for each frame by the three video display units, the projection device 20 supplies a screen control request signal to the timing control unit 12, and the timing control unit 12 outputs the screen control request. The screen control signal may be generated by capturing the signal so that the reflection degree of the light becomes the first reflection degree.

FIG. 16 is a timing chart showing operation timings of various signals generated by the control device of the projection system according to the present embodiment. In the timing chart of the figure, the horizontal direction indicates the passage of time, and the vertical direction indicates the level.
As shown in the figure, the interval between the rising edges of adjacent pulses indicated by the frame synchronization signal is one frame period of the video.
The screen control signal is a period of 0 (zero) level (“darkness”), which is a period in which the light reflection state of the projection surface of the screen device 30 is set to the first reflectivity within one frame period indicated by the frame synchronization signal. And a period of positive level (denoted as “bright”), which is the period of the second reflectivity.
The duty ratio of the rectangular wave in the screen control signal may be 50% or may be other than that.

The illumination control signal is set to a positive level (denoted as “lighting”) as a period for entering the first illumination state, with the entire period or a part of the period corresponding to the first reflectivity indicated by the screen control signal being set. This period is set to 0 (zero) level (denoted as “lights off”) as the period for entering the second illumination state, and is synchronized with the frame period indicated by the frame synchronization signal.
According to FIG. 16, in the screen control signal and the illumination control signal, the start timing of the first illumination state in the illumination control signal is simultaneously or delayed with the start timing of the period corresponding to the first reflectivity in the screen control signal, And the start timing of the period used as the 2nd reflection degree in a screen control signal is simultaneous or delayed with the start timing of the 2nd lighting state in an illumination control signal.
The address period signal is a positive level (denoted as “permitted”) with the period of the second reflectivity indicated by the screen control signal as the addressing permission period, and the other period as 0 (zero) level. It is synchronized with the frame period shown.

  Even with the projection system according to the present embodiment, the same effects as those of the first embodiment (including modifications), the third embodiment, and the fifth embodiment can be obtained. High video can be displayed.

As described above in detail, according to each of the above-described embodiments and modifications, the video display unit that captures the video signal based on the capture control and displays the video is provided, and the video displayed by the video display unit is the video light. Based on the projection device 20 that converts the image light and projects the image light, and the switching control, the reflection degree of the light on the projection surface is the first reflection degree and the second reflection degree is higher than the first reflection degree. The screen device 30 that changes the state of the projection surface so as to be one of the reflection degrees of the screen and the lighting state in the surroundings where the screen device 30 is installed based on the switching control are the first lighting state and the first lighting state. The illumination device 40 that switches between the second illumination state having an illuminance lower than the illuminance in the first illumination state, and the state of the projection plane in the screen device 30 are synchronized with the frame frequency of the video signal. The screen device 30 is controlled so as to be switched, and the lighting device 40 is controlled so that the illumination of the lighting device 40 is in the first lighting state within a period in which the reflection degree of light is the first reflection degree. And a control device 10 for controlling the video display unit to capture the video signal in synchronization with the timing of switching the state of the projection surface. The lighting device 40 may be replaced with the shutter device 50, or both the lighting device 40 and the shutter device 50 may be used.
According to each projection system configured as described above, it is possible to obtain an image that has high contrast and is very easy to see even in an environment illuminated by the illumination device 40 (shutter device 50). At this time, it is possible to prevent an image lacking in a strip shape from being displayed in the vertical direction of the frame or to display an awkward motion image, and to prevent deterioration of the moving image quality of the image.

Note that the modification of the first embodiment described above can also be applied to the second to sixth embodiments.
The seventh embodiment described above can also be applied to all of the first embodiment (including modifications) to the sixth embodiment.
In the first embodiment (including modifications) to the eighth embodiment, the projection system may have a configuration in which the control device is incorporated in the projection device.

  Moreover, you may make it implement | achieve a part of function of the control apparatus in each embodiment mentioned above with a computer. In this case, a control program for realizing the control function is recorded on a computer-readable recording medium, and the control program recorded on the recording medium is read by the computer system and executed by the computer system. May be. This computer system includes an operating system (OS) and hardware of peripheral devices. The computer-readable recording medium is a portable recording medium such as a flexible disk, a magneto-optical disk, an optical disk, or a memory card, and a storage device such as a magnetic hard disk or a solid state drive provided in the computer system. Furthermore, a computer-readable recording medium dynamically holds a program for a short time, such as a computer network such as the Internet, and a communication line when transmitting a program via a telephone line or a cellular phone network. In addition, a server that holds a program for a certain period of time, such as a volatile memory inside a computer system serving as a server device or a client in that case, may be included. Further, the control program may be for realizing a part of the functions described above, and further for realizing the functions described above in combination with a program already recorded in the computer system. Also good.

  As mentioned above, although embodiment of this invention was explained in full detail with reference to drawings, the specific structure is not restricted to that embodiment, The design of the range which does not deviate from the summary of this invention, etc. are included.

DESCRIPTION OF SYMBOLS 1,1a-1e Projection system 10,10a-10e Control apparatus 11 Frame synchronous signal acquisition part 12,12a-12e Timing control part 20,20a Projection apparatus 30 Screen apparatus 40 Illumination apparatus (illumination adjustment apparatus)
50 Shutter device (lighting control device)

Claims (10)

A projection device that includes a video display unit that captures a video signal based on capture control and displays the video, and that projects the video light by converting the video displayed by the video display unit into video light;
Based on the switching control, the state of the projection surface so that the reflection degree of light on the projection surface is either the first reflection degree or the second reflection degree that is higher than the first reflection degree. Changing screen device,
Based on the switching control, the illumination adjustment for switching the illumination state around the screen device between the first illumination state and the second illumination state having an illuminance lower than the illuminance in the first illumination state Equipment,
The screen device is controlled so that the state of the projection plane in the screen device is switched in synchronization with the frame frequency of the video signal, and the reflection degree of the light is within the first reflection degree. The video display for controlling the lighting control device so that the lighting of the lighting control device is in the first lighting state, and for capturing the video signal in synchronization with the switching timing of the state of the projection plane in the screen device. A control device for controlling the unit;
A projection system comprising: The said control apparatus controls the said video display part so that the said video display part displays the said image | video within the period when the reflection degree of the said light becomes the said 2nd reflection degree. Projection system. The lighting control device
The projection system according to claim 1, wherein the projection system is an illuminating device that illuminates in the first illumination state or the second illumination state. The lighting control device
The projection system according to claim 1, wherein the projection system is a shutter device that takes in external light and illuminates in the first illumination state or the second illumination state. The lighting control device
An illumination device that illuminates in the first illumination state or the second illumination state, and a shutter device that takes in external light and illuminates in the first illumination state or the second illumination state are provided. The projection system according to claim 1 or 2. The said control apparatus controls the said screen apparatus so that the state of the said projection surface in the said screen apparatus may be switched according to the same frequency as the frame frequency of the said video signal. The projection system according to item. The control device controls the screen device so that the state of the projection plane in the screen device is switched according to a frequency that is an integer multiple of 2 or more of the frame frequency of the video signal. The projection system according to claim 5. The projection apparatus includes a video display unit and a light source that captures the video signal based on the capture control and writes the video signal to a storage unit for each pixel, and causes the video display unit to display the video by light emitted from the light source, An apparatus for projecting the image light by converting the image into the image light;
8. The control device according to claim 1, wherein the video signal is written to the video display unit within a period in which the reflection degree of the light becomes the first reflection degree. Projection system. The light source switches light for converting the video displayed on the video display unit into the video light based on switching control between non-light emission and light emission,
The projection system according to claim 8, wherein the control device controls the light source to emit no light within a period in which the reflection degree of the light becomes the first reflection degree. The projection device is a device that captures the video signal based on the capture control, converts the video signal into a light beam, and projects the light beam as the video light by two-dimensional scanning.
The projection system according to any one of claims 1 to 7, wherein the control device causes the light beam to be two-dimensionally scanned within a period in which the reflection degree of the light becomes the second reflection degree.

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