JP4288494B2 - Monitor device - Google Patents

Description

  The present invention relates to a monitor device, and more particularly to a monitor device capable of mirror display.

Conventionally, when the power is on, an image is transmitted and displayed, and when the power is off, the following technique is used as a mirror surface.
First, in Japanese Patent Application Laid-Open No. 2002-122860, a transflective polarizing plate is provided on the front surface of a liquid crystal display element, and when the illumination means is off, external light hits the transflective polarizing plate, and the external light is transflective. There is a description of a technique in which a predetermined amount of light is reflected by a mold polarizing plate and a mirror effect is generated on the transflective polarizing plate.
In Japanese Patent Laid-Open No. 2002-229494, various information is transmitted and displayed on the liquid crystal display unit when the backlight is turned on, which includes a half mirror that acts as a mirror surface when the information display unit is turned off. There is a description of a cover as a half mirror that acts as a mirror surface when the light is turned off.
Japanese Patent Application Laid-Open No. 2003-241175 describes a technique that functions as a liquid crystal screen when the power is turned on and as a mirror surface when the power is turned off.
JP2002-122860 JP 2002-229494 A JP 2003-241175 A

The above prior art has the following problems.
When the above technique is applied to a television receiver, when the power is turned off, such as when the television receiver is not being viewed, the mirror surface always becomes a mirror surface, and it may be uncomfortable and uncomfortable. In the above-mentioned Japanese Patent Application Laid-Open No. 2002-122860, there is no description of means for making a non-mirror surface, and it always becomes a mirror surface when the power is off. In Japanese Patent Laid-Open No. 2002-229494, there is a description of a cover that becomes a mirror surface when the backlight is turned off, but there is no description about removal of the cover, and the cover is always a mirror surface when the light is turned off. Also in Japanese Patent Laid-Open No. 2003-241175, there is no particular description about the means for making a non-mirror surface. The above technique always becomes a mirror surface, and the above technique is not stable when applied to a television receiver.
The present invention is to solve the above problems, and provides a monitor device capable of providing a calm space capable of appropriate display in accordance with the condition of the room where the monitor device capable of mirror display is installed. For the purpose.

In order to solve the above-mentioned problems, the present invention provides an information display unit capable of displaying various types of information and images, and a generally flat display disposed on the front of the display. When the display is on, information and images are displayed. A light-control glass capable of controlling the light transmittance on the front side of the mirror-finished layer in a monitor device capable of mirror-like display with a mirror-finished layer that is transmissively displayed and is mirror-finished when the display is off; It is set as the characteristic characterized by comprising.
In the said structure , the said mirror surface treatment layer is arrange | positioned in the front surface of the said substantially planar display, and also the said light control glass is arrange | positioned in front of the said mirror surface treatment layer. The mirror surface treatment layer is a non-mirror surface when the display is on, and is a mirror surface when the display is off. By arranging the light control glass on the front surface of the mirror surface treatment layer, the mirror display can be controlled by changing the transmittance of the light control glass.
Here, when the display of the display is turned off, a mirror surface should be formed on the front side of the display by the mirror surface treatment layer. However, if the transmittance of the light control glass disposed in front of the light control glass is lowered, the light transmitted through the light control glass is reduced and does not become a mirror surface. Of course, when the mirror surface is desired, the transmittance of the light control glass may be increased.

  Moreover, the said mirror surface treatment layer is a half mirror, reflects incident light from the whole surface side, and functions as a mirror surface. At this time, if the back side is dark, it functions more as a mirror surface. However, if the back side is bright, bright light on the back side is transmitted so that the reflected light on the front side is better than that and does not function as a mirror surface.

When carrying out the above Symbol onset bright in the plasma display, the plasma display on SL dimmer glass was placed a glass optical filter strengthen the front of the PDP module is configured as the optical filter, the light control glass and PDP module The mirror surface treatment layer is provided on any of the surfaces facing the surface.
According to the above arrangement, replacing the tempered glass of the optical filter constituting the plasma display to the light control glass, the light control glass and the PDP is subjected to mirror surface processing on either side of the opposing surfaces. Thus, it is set as the structure which has arrange | positioned the said mirror surface treatment layer in the front surface of the said PDP, and also arrange | positioned the said light control glass in the front surface.
Here, the plasma display is configured by arranging an optical filter on the front side thereof. The optical filter is made of light control glass, and a mirror-finished layer is disposed on one of the opposing surfaces of the light control glass optical filter and the PDP module so that the display is not displayed. If the transmittance of the light control glass is lowered, the mirror surface treatment layer located on the back side of the optical filter does not function as a mirror surface. Similarly, when the transmittance of the light control glass, which is an optical filter, is increased while the display is not displayed, the mirror-treated layer located on the back side of the optical filter functions as a mirror surface.

The upper Symbol light control glass is configured as a glossy glass disposed in front of the LCD module comprising a backlight unit and the control board and the liquid crystal panel, mirror finishing layer on the surface facing the liquid crystal panel in the light control glass It is the structure characterized by having provided.
In the above configuration , the glossy glass constituting the LCD module is replaced with the light control glass, and a mirror surface treatment is performed on one of the opposing surfaces of the light control glass and the liquid crystal panel. Thus, it is set as the structure which arrange | positions the mirror surface treatment layer in the front surface of the said display, and also arrange | positions the said light control glass in the front surface.
In general, an LCD module does not have an optical filter like a plasma display, but recently, glossy glass is often attached to the front side from the viewpoint of aesthetics and the like. While this glossy glass is made of light control glass, the transmittance of the light control glass, which is glossy glass, can be lowered while the display is not displayed in a state where the mirror surface treatment layer is disposed on the surface of the light control glass facing the liquid crystal panel. In this case, the mirror surface treatment layer located on the back side of the glossy glass does not function as a mirror surface. Similarly, if the display is hidden and the transmittance of the light control glass, which is glossy glass, is increased, the mirror-treated layer located on the back side of the glossy glass functions as a mirror surface.

Upper Symbol dimmer glass has a structure which is characterized in that is detachable to the front surface of the display.
In the said structure , the said light control glass can be removed in the said display front surface.

Therefore, when the upper Symbol dimmer glass was attached to the display, it has a configuration which is characterized by comprising a brightness adjustment circuit to increase the brightness of the display.
In the above configuration , when the specular control device is mounted on the display, the mounting of the specular control device is detected, and the brightness adjustment circuit provided on the display side increases the brightness of the display. Here, the mirror surface control device includes a mirror surface treatment layer and a light control glass, and the mirror surface treatment layer divides incident light into transmitted light and reflected light. Therefore, incident light from the display is reduced when passing through the mirror-finished layer. However, in the present invention, in order to increase the brightness of the display when the light control glass is attached to the display, such a decrease is compensated for and displayed at the same brightness as before the light control glass is attached. Become.

Specific structure of the mirror control device, the present invention comprises an upper Symbol dimmer glass, frame part and, the frame upper side and the lower side from the light control glass side connecting portion that protrudes toward the side of the display in the unit And the display has a display side connection portion that is detachably connected to the light control glass side connection portion in a facing position, and the light control glass side connection portion and the display side connection portion are respectively It has a structure characterized by having a connector terminal for electrical connection.
In the above-described configuration , the substantially rectangular light-control glass that substantially matches the size of the display is mirror-finished, and a substantially rectangular frame portion is provided around the mirror surface. Further, the light control glass side connection portion is extended from the upper side and the lower side of the frame portion toward the display side at a right angle to the frame portion. By attaching the upper and lower light control glass side connection portions on a substantially U-shape, it is possible to mount the light control glass side connection portion on the front surface of the display. In addition, a connector terminal is disposed on the light control glass side connecting portion, and a connector terminal that is fitted in a pair with the light control glass side connector terminal is disposed on the display side. The mirror surface control device is electrically and mechanically connected to the display by the connector.

The control of the light control glass, the upper Symbol dimmer glass has a structure which is characterized by comprising a transmission control circuit for controlling the transmittance at a given voltage control.
In the above configuration , the transmittance of the light control glass is controlled by the transmittance control circuit provided in the internal circuit of the display. In general, the change in the transmittance of the light control glass is to change the direction of the liquid crystal molecules and increase or decrease the light transmittance by applying a voltage to the liquid crystal molecules arranged inside the light control glass. The transmittance control circuit controls the voltage.

Upper Symbol displays have a spot killer circuit together are constituted by CRT, the transmittance control circuit, wherein the controller controls to reduce the transmission rate before the operation of the spot killer in synchronism with the spot killer circuit The configuration is as follows.
In the above configuration , a predetermined signal is input to the transmittance control circuit at a timing before the spot killer operation is performed after the display is turned off to lower the transmittance of the light control glass. Thus, the light control glass becomes opaque and covers the display before a spot appears on the display. As described above, even if the spot is generated, it cannot be visually recognized if it is covered with the opaque surface of the light control glass.

The upper SL transmittance control circuit has a configuration, wherein the lower the transmittance at the time of disturbance of the display screen of said display.
In the above configuration , when the display becomes a distorted screen due to the selection of a television receiver or the like, the distorted display screen is detected by the internal circuit of the display. Then, the transmittance control circuit lowers the transmittance of the light control glass. Therefore, if the transmittance is lowered, the light control glass becomes opaque, and the disturbance of the screen is covered with an opaque surface.

Upper Symbol display has a blue back control circuit which operates when the disturbance of the screen, the transmittance control circuit has a configuration, wherein the lower the transmittance in synchronization with the operation of the blue back control circuit.
In the above-described configuration , when the image synchronization signal cannot be obtained on the display, there is a blue-back function with a monochromatic OSD display that covers a disturbed received video particularly when the tuner of the television receiver is selected. Here, the microcomputer of the display control circuit that has detected the screen disturbance inputs a blue back control signal to the OSD circuit, and simultaneously inputs the transmittance control signal to the transmittance control circuit. The OSD circuit generates a blue back screen on the display through a predetermined circuit, and the transmittance control circuit turns off the application of voltage to the light control glass to lower the transmittance of the light control glass. Accordingly, the transmittance control circuit makes the light control glass opaque in synchronization with the display of the blue back.

Upper Symbol displays have a television receiver tuner, the transmittance control circuit has a configuration, wherein the lower the detection to transmission asynchronous during reception of a television broadcasting in the television receiver tuner .
In the above configuration , when a synchronization signal from the transmission side cannot be obtained when a tuner is tuned in a television receiver including the display having the mirror surface control device, the microcomputer of the display control circuit performs asynchronous detection. A transmittance control signal is output to the transmittance control circuit. The transmittance control circuit turns off the application of voltage to the light control glass to lower the transmittance of the light control glass.

Upper Symbol display is capable of forming a partially black screen the light control glass has a structure which is characterized in that it is possible to clear the black screen portion.
In the above configuration , the display can be partially covered by the OSD display of the display. A black screen is partially formed on the display if the partially covered region is formed in black. Moreover, in the said light control glass, the transmittance | permeability can be controlled for every area | region divided into the predetermined magnitude | size, and the same area | region as the area | region displayed black on the said display can be displayed transparently. At this time, areas other than the transparent display are opaque, and only the black screen area is partially transparent.

Using the means of partial black screen display described above of the display, the upper Symbol display has a configuration which is a possible side-by-side display of two screens.
In the above configuration , an image can be displayed by the side-by-side display pattern during image display on the display. The side-by-side is composed of a first image displayed in a half image area on the display and a second image displayed in the other half image area, and a function capable of displaying two screens on the same display. It is. For example, the black screen is displayed without displaying one image in the two-screen display on the display. Then, it is possible to use only the area displayed on the black screen as a mirror surface.

The upper Symbol display has a configuration which is a possible picture-in-picture display of the two screens.
In the above configuration , an image can be displayed by the display pattern of the picture-in-picture while the image is displayed on the display. The picture-in-picture is composed of a first image displayed in the image area on the entire surface of the display and a second image displayed in a part of the image area in the first image. This is a function that can display two screens. For example, the two-screen display is performed on the display, and the black image is displayed without displaying the second image that is the partial image region. Then, it is possible to use only the area displayed on the black screen as a mirror surface.

The mirror-finished layer of the mirror control unit, the upper Symbol mirror finishing layer has a structure which is characterized in that characterized in that it is a mirror film that has been subjected to mirror surface processing.
In the said structure , when providing a mirror surface treatment layer in the said mirror surface control apparatus, a mirror surface treatment layer can be provided by sticking the film in which the mirror surface treatment was performed.

Upper Symbol mirror film has a structure, characterized in that the paste on the side facing to the display in the light control glass.
In the said structure , the said mirror surface film is affixed on the said light control glass, The said mirror surface film surface is made into the said display side, and it attaches to the said display.

The upper Symbol mirror film has a structure characterized in that it is attached to the surface of the display.
In the said structure , the said mirror surface film is affixed on the surface of the said display.

Here, the present invention provides a mirror-finished film on a front surface of a display in a substantially planar plasma display device, which displays a transparent image when the display is on, and performs a mirror surface treatment that becomes a mirror when the display is off. in the monitor device capable of mirror-displays arranged, comprising a controllable light control glass light transmittance on the front side of the mirror film, the light control glass, a strengthened glass optical filter The mirror film is attached to any one of the opposing surfaces of the light control glass and the display, and the light control glass is formed from a frame part and an upper side and a lower side of the frame part. A light control glass side connection part protruding toward the side, and the display can be attached to and detached from the light control glass side connection part at a position facing the light control glass side connection part. Has a display side connecting portion connected to said light control glass side connecting portion and the display-side connecting part has a configuration each having a connector terminal for electrically connecting.

As described above, according to the present invention, it is possible to provide a plasma display capable of turning on and off the mirror display when the power is turned off.
According to the present invention, by controlling the light control glass, it is possible to select a mirror surface or a non-mirror surface when the display power is turned off.
Additional mirror, the selection of the non-specular, can be carried out at up plasma display. Furthermore, it is feasible in L CD.
According to the present invention, the mirror surface control function can be conveniently removed, and the display alone can be used. Also, since it can be carried, it can be attached to another display if the display sizes are approximately the same. Further, according to the present invention, when the detachable mirror surface control device is attached to the display, it is possible to increase the luminance and eliminate visual discomfort before and after the attachment / detachment. Furthermore, according to the present invention, the mirror surface control function can be used only by mounting on the display.
According to the present invention, there is an effect of eliminating discomfort when the power is turned off in the CRT display. In addition, according to the present invention, in particular, there is an effect of eliminating discomfort caused by a distorted received image when a tuner of a television receiver is selected.
According to the present invention, discomfort is reduced compared to when the entire surface is a mirror in a partial mirror display. In addition, the variation of display mirroring spreads.
According to the present invention, when a mirror surface treatment is applied to a display or a light control glass, it is sufficient to attach a film and the workability is good. Moreover, it is not necessary to deposit.

Here, embodiments of the present invention will be described in the following order.
(1) First embodiment:
(2) Second embodiment:
(3) Third embodiment:
(4) Summary:
(1) First embodiment:

FIG. 1 is a block diagram showing a schematic configuration of a television receiver including a mirror surface control apparatus according to the present embodiment. In the present embodiment, a double tuner including a tuner a41 and a tuner b42 is provided in order to support a two-screen display function. In the figure, a television receiver provided with a mirror surface control device is roughly composed of a transmittance control circuit 31, a microcomputer 40, a power supply circuit 50, a light control glass transformer 50a, tuners 41 and 42, a chroma IC 43, 44, a display drive circuit 45, and an OSD circuit 46. In the following description, description of the audio signal is omitted.
In the figure, tuners 41 and 42 receive a television signal having a desired frequency corresponding to the television broadcast band via antennas 41a and 42a, and select only a required signal from the received television signal to amplify the high frequency. Then, it is converted into an intermediate frequency signal and output.
When the intermediate frequency signals output from the tuners 41 and 42 are input to the chroma ICs 43 and 44, the chroma ICs 43 and 44 perform various signal processing on the input intermediate frequency signals to restore the composite video signal. The video signal and the like are extracted and output to the display driving circuit 45. The display driving circuit 45 performs image quality adjustment and the like on the video signal, adds an OSD signal from the OSD circuit 46, and outputs the signal to the display 10.
The light control glass transformer 50 a in the power supply circuit 50 converts a home AC power supply into a light control glass driving DC power supply, and supplies power to the light control glass via the transmittance control circuit 31.
A microcomputer 40 is connected to each of the devices. The microcomputer 40 gives a control instruction to each device via the IIC bus 60 based on an operation executed by the operation panel 40a or the remote control I / F 40b. Control is in progress. The power supply circuit 50 supplies power to each device.

  FIG. 2 is a schematic perspective view showing a configuration of a display portion in the large-screen flat television receiver of the present embodiment. The display part is composed of a display 10, a mirror-finished layer (mirror film) 20, and a light control glass 30. The mirror surface treatment layer (mirror surface film) 20 is a film that has undergone a mirror surface treatment, and is affixed to the back surface of the light control glass 30. The light control glass 30 to which the mirror film 20 is attached is disposed on the front surface of the display 10 with the mirror film 20 side set to the display 10 side. The light control glass 30 includes a power interface and a control interface, and is electrically connected to the control circuit board of the display 10 via a flat cable (not shown). On the control circuit board, a transmittance control circuit 31 of the light control glass 30 described later is provided, and the transmittance control circuit 31 controls the transmittance of the light control glass 30.

  The mirror-finished film 20 transmits and displays information and video by incident light by display display when the display 10 is powered on. However, when the power of the display 10 is off, the incident light is lost, so that the light is not transmitted and becomes a mirror surface. In general, the light control glass 30 is composed of a liquid crystal sheet, an intermediate film, and a plate glass. The liquid crystal sheet is sandwiched between the intermediate film and the both surfaces are sandwiched between the plate glasses. The liquid crystal sheet has a structure in which liquid crystal is sandwiched between two conductive films with lead wires. Normally, the liquid crystal molecules of the liquid crystal sheet are irregularly arranged to diffuse light and become opaque, but when a voltage is applied to the liquid crystal between the conductive films via the lead wires provided in the conductive film, The liquid crystal molecules of the liquid crystal sheet are aligned and transmit light. And the said light control glass 30 changes to transparency. Thus, the light control glass 30 can control the light transmittance with the voltage.

  The voltage control of the light control glass 30 is performed by the transmittance control circuit 31. In FIG. 1, the transmittance control circuit 31 is connected to a control microcomputer 40 of the control circuit of the display 10, and an operation panel 40a and a remote control I / F 40b are connected to the microcomputer 40. Here, a signal indicating the display pattern of the display 10 is input to the microcomputer 40 from the operation panel 40a and the remote control I / F 40b. The microcomputer 40 outputs a signal for controlling the transmittance of the light control glass 30 according to the instruction to the transmittance control circuit 31. The transmittance control circuit 31 controls the transmittance of the light control glass 30 by turning on and off the voltage applied to the light control glass 30 supplied from the light control glass transformer 50a based on the input signal.

Next, the display pattern of the display 10 utilizing the properties of the mirror film 20 and the light control glass 30 will be described. FIG. 3 is a diagram showing a display pattern of the display according to the present invention. First, when displaying an image on the display 10, the power of the display 10 is turned on, and the voltage applied to the light control glass 30 is turned on to increase the transmittance and make it transparent. Then, the image displayed on the display 10 passes through the mirror film 20 and further passes through the light control glass 30. Therefore, the image displayed on the display 10 can be observed.
When the display 10 is used as a mirror surface, the power of the display 10 is turned off, and the voltage applied to the light control glass 30 is turned on to increase the transmittance and make it transparent. Then, since the incident light from the display 10 is lost, the mirror film 20 becomes a mirror surface without transmitting light. Further, since the light control glass 30 is also transparent, the mirror surface is transmitted and the display 10 can be made a mirror surface.
Further, when the display 10 is turned off and the display 10 is not a mirror surface, the voltage applied to the light control glass 30 is turned off to reduce the transmittance and make it opaque. Then, the mirror surface by the effect | action of the said mirror surface film 20 is covered with the opaque surface of the said light control glass 30, and the said display 10 can be made non-mirror surface.
When the display 10 does not display an image, the display 10 is turned on, the voltage applied to the light control glass 30 is turned off, and the transmittance is lowered to make it opaque. Then, the image displayed on the display 10 passes through the mirror film 20 but is covered with the opaque surface of the light control glass 30. Therefore, the video displayed on the display 10 cannot be observed. However, if it is applied to a television receiver or the like, only sound can be heard.

Here, the OSD display of the display 10 will be described. When an operation for executing OSD display is performed with the operation panel 40a and the remote control I / F 40b while displaying an image on the display 10, the microcomputer 40 detects a signal for executing the OSD display and sends an OSD generation signal to the OSD circuit 46. Is output. Then, in response to the instruction, the OSD circuit 46 generates an OSD signal and outputs the OSD signal to the display driving circuit 45. The display drive circuit 45 performs predetermined signal processing on the OSD signal and outputs the OSD display superimposed on the video signal on the display 10.
The OSD display can cover the entire display with a single color, and in this embodiment, the OSD display has a blue back function with a single-color OSD display that covers a disturbed image. In the above television receiver, since the television signal is not received until the reception frequency is matched with the frequency of the desired broadcast station at the time of tuning by the tuners 41 and 42, a distorted video is originally displayed on the display 10. It will be projected. In order to prevent this, the blue-back image based on the OSD signal is superimposed on the distorted image during the channel selection operation, thereby preventing the unsightly received image from being viewed on the display 10.

  In the present embodiment, the method of superimposing the above-mentioned distorted image on the operation panel 40a and the remote control I / F 40b can be selected from blue background display and opaque display of the light control glass 30. Here, the flowchart of the said blue back operation | movement and the synchronous operation | movement of the said light control glass 30 is shown in FIG. In the figure, it is determined whether or not an asynchronous signal is detected by the chroma ICa 43 during the channel selection operation by the tuner a41 via the antenna 41a (step S100). If it is determined that asynchronous is detected, the microcomputer 40 inputs a control signal for generating a blue back screen to the OSD circuit 46. Then, the OSD signal is input to the display driving circuit 45, and the display driving circuit 45 superimposes the blue back screen on the distorted image from the chroma ICa 43, and as a result, displays the blue back screen whose entire surface is blue on the display 10. . (Step S110). Further, it is determined whether or not the light control glass 30 is selected to be opaque (step S120). If the light control glass 30 is selected, the microcomputer 40 outputs a signal for decreasing the transmittance to the transmittance control circuit 31. To do. Then, the transmittance control circuit 31 turns off the voltage applied to the light control glass 30, and the light control glass 30 becomes opaque (step S130). In addition, when the asynchronous is not detected in the step S100, that is, when the synchronization signal is detected and when the opaque selection is not selected in the step S120, the blue back synchronization operation is finished without doing anything. . In this way, the light control glass 30 can be made opaque in synchronization with the operation of the blue back, and the disturbed image during the channel selection operation can be covered with the light control glass 30.

An example in which the display 10 is partially mirrored using the OSD display and the action of the light control glass 30 will be described. When a predetermined area on the display 10 is covered with a single black color by OSD display during video display on the display 10, the area displayed in black becomes a light-shielded state by the action of the mirror film 20 and becomes a mirror surface. At this time, since the light control glass 30 is transparent, a part of the display screen can be used as a mirror surface.
Furthermore, in the liquid crystal sheet that constitutes the light control glass 30 and the conductive film is divided into a predetermined size and the transmittance can be controlled for each of the sections, the transmittance control circuit 31 performs the predetermined control on the display 10. It is possible to make only the area of the transparent or opaque. Therefore, when the power of the display 10 is turned off and the display 10 is a full mirror by the action of the mirror film 20, the light control glass 30 is partially transparently displayed and the portions other than the transparent display portion are opaque. It is possible to form a mirror surface of a desired size on the display.

Here, in the television receiver according to the present embodiment having the two-screen display function, the display 10 is partially mirror-displayed using the black display by the OSD during the video display of the display 10 described above. An example will be described.
In the two-screen display function, the display drive circuit 45 receives television signals of different desired frequencies received by the tuners a41 and b42 shown in FIG. 1 as two different video signals via the chroma ICa43 and chroma ICb44, and the display The drive circuit 45 synthesizes the first image displayed in the predetermined main image area of the display 10 and the second image displayed in the sub-image area that is an area other than the main image area. This is a function for generating a signal including the two screens on the same display 10.

In the above-described two-screen display, there is a side-by-side display pattern in which different images are displayed on the right half and the left half on the same display.
As shown in FIG. 5A, the display 10 displays the first image in the left half area 11a of the display 10 according to the side-by-side display pattern, and the second half area 11b displays the second image. Is displayed. Here, the user inputs a signal with the left half 11a as a mirror surface by the operation panel 40a or the remote control I / F 40b. The signal is input to the microcomputer 40. The microcomputer 40 outputs an OSD generation signal to the OSD circuit 46, and the OSD circuit inputs an OSD signal to the display driving circuit 45. The display driving circuit 45 superimposes a black OSD display on the first video signal received from the chroma ICa 43 and outputs the superimposed image to the display 10.
As a result, on the display 10, the left half 11a is displayed in black on the entire surface by OSD, but the right half 11b displays the second video as it is. Then, the left-half region 11 a displayed in black is in a light-shielding state and becomes a mirror surface by the action of the mirror filter 20. If the display driving circuit 45 superimposes and outputs the OSD on the second video signal from the chroma ICa 44, the right half of the image area 11b on the display 10 where the second image is displayed is displayed in black by the OSD. The mirror surface 20 becomes a mirror surface by the action of the mirror surface filter 20. At this time, the first video is displayed in the left half image area 11a.

Similarly, as another mode of two-screen display, there is a picture-in-picture display pattern in which different images are displayed in the main image area on the entire surface of the same display and the sub-image area which is a part of the area.
As shown in FIG. 5B, the display 10 displays a first image in the main image area 12a on the entire surface of the display 10 according to the picture-in-picture display pattern, and the first image is displayed on the main image area 12a. A second video is displayed in some of the sub-image areas 12b. Here, the user inputs a signal for mirroring a part of the sub-image area 12b through the operation panel 40a or the remote control I / F 40b. The signal is input to the microcomputer 40. The microcomputer 40 outputs an OSD generation signal to the OSD circuit 46, and the OSD circuit inputs the OSD signal to the display driving circuit 45. The display driving circuit 45 superimposes the black OSD on the second video signal received from the chroma ICb 44 and outputs the superimposed signal to the display 10.
As a result, a part of the sub-image area 12b is displayed black by OSD on the display 10, but the main image area 12a on the entire surface of the display 10 is displayed as it is. Then, the part of the sub-image area 12 b displayed in black is in a light-shielding state and partially becomes a mirror surface on the display 10 by the action of the mirror filter 20. When the display driving circuit 45 superimposes and outputs the OSD on the first video signal from the chroma ICa 44, the main image area 12a on the entire surface of the display 10 becomes black and becomes a mirror surface. At this time, the second video is displayed in the sub-image area 12b which is a part on the mirror surface. Thus, using the picture-in-picture function, one of the two image areas 12a and 12b having different sizes can be used as a mirror surface.
The selection of the black display area by the OSD can be performed by the operation panel 40a or the remote control I / F 40b.
As described above, it is possible to expand the variation of the mirror display by using the operation of the mirror filter 20 and the light control glass 30 by the mirror control device.

  As described above, the present invention can be applied to a plasma display as long as the above-described display 10, mirror filter 20, and light control glass 30 are configured. As shown in FIG. 6, the plasma display generally includes a PDP module 110 and an optical filter 130 made of tempered glass. The optical filter 130 made of the tempered glass is replaced with the light control glass 130a, and the mirror film 120 is attached to one of the surfaces where the light control glass 130a and the PDP face each other. The light control glass 130a includes a power source and a control interface, and is electrically connected to the control circuit board of the PDP module 110 by a flat cable (not shown). Thus, it can be set as the structure similar to this invention which has arrange | positioned the said mirror surface film 120 in the front surface of the said PDP module 110, and also arrange | positioned the said light control glass 130a in the front surface.

Similarly, the present invention can be applied to an LCD. As shown in FIG. 7, the LCD generally includes an LCD module 210a composed of a backlight unit, a control board, and a liquid crystal panel, a glossy glass 230 disposed on the front surface of the liquid crystal panel, the LCD module 210a and the glossy glass. The LCD module frame 210b is a frame portion that covers the periphery of 230. The glossy glass 230 is replaced with the light control glass 230a. And the mirror surface film 220 is affixed on either surface of the said light control glass 230a and the said liquid crystal panel which opposes. The light control glass 230a includes a power source and a control interface, and is electrically connected to the control circuit board of the LCD module 210a by a flat cable (not shown). Thus, it can be set as the structure similar to this invention which arrange | positions the mirror surface film 220 in the front surface of the said liquid crystal panel, and also arrange | positions the said light control glass 230a in the front surface.
(2) Second embodiment:

  FIG. 8 is a schematic perspective view of the attachment / detachment mechanism according to the present embodiment. In this embodiment, it is comprised from the connector 330a for connecting to the transmittance | permeability control circuit of the said light control glass provided on the control board of the display 310 and the mirror surface process layer and light control glass which are not shown in said 1st embodiment. An embodiment in which the mirror surface control device 330 is detachable will be described.

  The substantially rectangular light control glass that is substantially the same as the size of the display 310 is mirror-finished, and a substantially rectangular frame portion 330b is provided around it. Further, the light control glass side connection portions 330c and 330d are extended from the upper side and the lower side of the frame portion 330b toward the display 310 at a right angle to the frame portion 330b. A substantially rectangular protrusion 330a is disposed downward on the light control glass side connection part 330c, and the protrusion 330a is provided with a predetermined control interface and a power interface for the light control glass. ing. On the other hand, on the display 310 side, a substantially rectangular recess 310a is provided at a position corresponding to the protrusion 330a at the top of the display 310, and a pair of the light control glass side connector terminal is fitted to the bottom surface thereof. Connector terminals are placed upward. Accordingly, the mirror surface control device 330 inserts a rectangular protrusion 330a provided above the light control glass side connection portion 330c into a recess 310a provided on the upper side of the display 310, and electrically connects the display 310 and the mirror 310. Connected mechanically and mechanically. The recess 310a has a lid (not shown). And when not in use, the opening opened upward by the lid is closed to prevent the entry of dust when the display 310 is used alone, thereby reducing the uncomfortable appearance. Furthermore, a downwardly movable mechanism and a spring mechanism (not shown) are provided below the frame portion 330b, and the frame portion 330b can be extended downward. The mirror surface control device 330 can be mounted on the front surface of the display 310 by engaging the upper and lower light control glass side connection portions 330c and 330d in a substantially U shape.

  Here, since the above-described mirror-treated layer divides incident light into transmitted light and reflected light, the brightness of the display 310 changes depending on the presence or absence of the mirror-treated layer. That is, when the display 310 is turned on, an image is displayed with the brightness set on the display 310. However, when the mirror-finished layer is arranged on the front surface of the display 310, the brightness is reduced. Sexuality gets worse. Therefore, if the mirror surface control device 330 including the mirror surface treatment layer is detachable as described above as in the present embodiment, the luminance when the display 310 is observed when mounted and removed is changed. End up.

For this reason, in this embodiment, the attachment / detachment state of the mirror surface control device 330 to the display 310 is determined, and the brightness of the display 310 is increased at the time of attachment. In order to realize such a function, in this embodiment, an attachment / detachment detection circuit (not shown) that detects attachment / detachment of the mirror surface control device 330 in the connector 330a shown in FIG. 8 and the display 310 according to the result of the attachment / detachment detection circuit. And a luminance adjustment circuit for changing the luminance of the.
Here, the brightness adjustment circuit controls to increase the brightness of the display 310 when the attachment / detachment detection circuit detects attachment of the mirror surface control device 330, and when the removal of the mirror surface control device 330 is detected, Control is performed to lower the brightness of the display 310.
As said means, the said mirror surface control apparatus 330 is connected with the said display 310 by the connector 330a provided with the power supply interface and the interface for control. When the connector 330a is connected to the display 310, the attachment / detachment detection circuit on the display 310 side detects the attachment of the mirror surface control device 330, and the brightness adjustment circuit provided on the display side adjusts the brightness of the display. It is possible to raise. In addition, when the mirror surface control device 330 is detached from the display 310, the detached state of the mirror surface control device 330 can be detected by the attachment / detachment detection circuit, and the brightness of the display 310 can be lowered by the brightness adjustment circuit. It is. In this way, it is possible to eliminate visual discomfort due to a change in the brightness of the display before and after the mirror surface controller 330 is attached / detached.
(3) Third embodiment:

FIG. 9 is a block diagram showing a schematic configuration of a CRT display including the mirror surface control apparatus according to the present embodiment. Since the parts to which the reference numerals in FIG. 1 corresponding to the last two digits in FIG. 1 are assigned have a common configuration, the description thereof is omitted here.
In the figure, when the intermediate frequency signal output from the tuner 441 is input to the chroma IC 443, the chroma IC 443 performs various signal processing on the input intermediate frequency signal to restore the composite video signal, and the video signal Etc. are extracted and image quality adjustment is performed on the video signal, and the OSD signal from the OSD circuit 446 is added and output to the CRT display 410 to display the video. The high voltage circuit 448 generates a high voltage to be applied to the CRT display 410, or generates a high voltage necessary for other circuits.

  Further, when the power of the CRT display 410 is turned off, a spot is generated at the approximate center of the CRT display 410. The control circuit of the CRT display 410 with respect to the spot includes a spot killer circuit 447 that discharges the charge remaining on the CRT.

Here, an embodiment in which the transmittance of the light control glass 430 is lowered when a spot is generated on the CRT display 410, and the spot is hidden by covering the CRT display 410 with the opaque surface of the light control glass 430 will be described.
As a schematic operation from the power-off operation of the CRT display 410 to the spot killer operation, FIG. 10 shows a flowchart of the spot killer synchronization operation of the light control glass 430 according to the present embodiment. In the figure, the microcomputer 440 determines whether or not a power-off operation has been performed on the operation panel 440a or the remote control I / F 440b (step S200). When it is determined that the power-off operation has been performed, the microcomputer 440 outputs an applied voltage off signal to the light control glass 430 to the transmittance control circuit 431. Then, the transmittance control circuit 431 receiving the signal turns off the voltage applied to the light control glass 430 to lower the transmittance and make it opaque (step S210). The microcomputer 440 outputs a spot killer control signal (step S220). The spot killer control signal is input to the spot killer circuit 447 and the spot killer operation is performed (step S230). Then, the power is turned off after a predetermined time (step S240), and the spot killer synchronization operation is terminated.

As described above, the microcomputer 440 transmits a predetermined control signal at a timing at which the transmittance control circuit 431 can operate before the spot killer circuit 447 performs the spot killer operation after the display 410 is turned off. Input to the rate control circuit 431. When the transmittance control circuit 431 turns off the voltage applied to the light control glass 430 and lowers the light transmittance of the light control glass 430 to make it opaque, the light control glass 430 is displayed before a spot appears on the display 410. The display 410 is surely covered.
(4) Summary:

  As described above, in the present invention, the specular filter 20 is disposed on the front surface of the display 10, and the light control glass 30 is disposed on the front surface to control the transmittance of the light control glass 30. A mirror surface or non-mirror surface can be selected when the power is turned off. Therefore, it is possible to provide a monitor device that can display appropriately according to the condition of the room in which the monitor device capable of mirror display is installed and can provide a calm space.

It is the block diagram which showed schematic structure of the television receiver provided with the mirror surface control apparatus. It is a schematic perspective view of the display part concerning 1st embodiment. It is a figure which shows the display pattern of the display concerning 1st embodiment. It is a flowchart of the blue back synchronous operation | movement concerning 1st embodiment. It is the schematic of the display display pattern concerning 1st embodiment. It is a schematic perspective view of the plasma display concerning a first embodiment. It is a schematic perspective view of LCD concerning 1st embodiment. It is a schematic perspective view of the attachment / detachment mechanism concerning 2nd embodiment. It is the block diagram which showed schematic structure of the CRT display provided with the mirror surface control apparatus. It is a flowchart of the spot killer synchronizing operation | movement concerning 3rd embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Display 11a, 12a ... Main image area 11b, 12b ... Sub image area 20 ... Mirror surface film (mirror surface processing layer)
DESCRIPTION OF SYMBOLS 30 ... Light control glass 31 ... Transmittance control circuit 40 ... Microcomputer 40a ... Operation panel 40b ... Remote control I / F
41 ... tuner a
42 ... tuner b
41a, 42a ... Antenna 43 ... Chroma ICa
44 ... Chroma ICb
45 ... Display drive circuit 46 ... OSD circuit 50 ... Power supply circuit 50a ... Transformer for dimming glass

Claims (16)

Mirror surface display is possible by placing a mirror film on the front of the display of a roughly flat plasma display device that displays images transparently when the display is on and mirrors when the display is off. In a monitor device
Provided with a light control glass capable of controlling the light transmittance on the front side of the mirror film,
The light control glass is constructed as a strengthening glass optical filter,
Affixing the mirror film on any of the facing surfaces of the light control glass and the display ,
Furthermore, the light control glass has a frame part, and a light control glass side connection part protruding toward the display side from the upper side and the lower side of the frame part,
The display has a display side connection part that detachably connects the light control glass side connection part to the position facing the light control glass side connection part,
The said light control glass side connection part and the said display side connection part each have a connector terminal electrically connected, The monitor apparatus characterized by the above-mentioned . And Overview Once the flat panel display, is disposed in front of the display, when the display view is on is transmitted displays information or images, mirror display when the display starts off and a mirror finish layer becomes mirror surface In possible monitoring devices,
Comprising a light control glass capable of controlling the light transmittance on the front side of the mirror-treated layer ,
The light control glass has a frame part, and a light control glass side connection part protruding toward the display side from the upper side and the lower side of the frame part,
The display has a display side connection part that detachably connects the light control glass side connection part to the position facing the light control glass side connection part,
The said light control glass side connection part and the said display side connection part each have a connector terminal electrically connected, The monitor apparatus characterized by the above-mentioned . The display is a PDP module,
The light control glass is constituted by an optical filter made of tempered glass arranged in front of the PDP module, providing the above mirror finishing layer either at the surface facing the said light control glass and PDP module The monitor device according to claim 2. The display is an LCD module including a backlight unit, a control board, and a liquid crystal panel.
The light control glass is configured as a glossy glass arranged in front of the L CD module, characterized by providing the mirror-finished layer on one of definitive to opposing surfaces between the light control glass and the liquid crystal panel The monitor device according to claim 2. Depending on the connection of the connector terminals, a detection circuit for detecting the attachment to the display of the light control glass, when the detection circuit detects the mounting, and a luminance adjustment circuit for increasing the brightness of the display The monitor device according to any one of claims 2 to 4, further comprising: The monitor device according to any one of claims 2 to 5, wherein the light control glass includes a transmittance control circuit that controls the transmittance by a predetermined voltage control. The light control glass includes a transmittance control circuit that controls the transmittance by a predetermined voltage control, and the display includes a CRT and a spot killer circuit, and the transmittance control circuit includes the spot killer circuit. 3. The monitor device according to claim 2 , wherein control is performed so as to lower the transmittance before the operation of the spot killer in synchronization with the circuit. The monitor device according to claim 6 , wherein the transmittance control circuit lowers the transmittance when the screen of the display is disturbed. The display has a blue back control circuit that operates when the screen is disturbed,
The monitor device according to claim 8 , wherein the transmittance control circuit lowers the transmittance in synchronization with the operation of the blue back control circuit. The display has a television receiver tuner,
9. The monitor device according to claim 8 , wherein the transmittance control circuit detects asynchronism at the time of reception of a television broadcast by the television reception tuner and lowers the transmittance. The display can partially form a black screen,
The monitor device according to any one of claims 2 to 10 , wherein the light control glass is capable of making the black screen portion transparent. The monitor device according to any one of claims 2 to 11 , wherein the display is capable of two-screen side-by-side display. The monitor device according to any one of claims 2 to 12 , wherein the display is capable of two-screen picture-in-picture display. The monitor device according to any one of claims 2 to 13 , wherein the mirror- finished layer is a mirror-finished mirror-finished film. The monitor device according to claim 14 , wherein the mirror film is attached to a side of the light control glass facing the display. The monitor apparatus according to claim 14 , wherein the mirror film is attached to a surface of the display.

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