KR20130003384A - Digital multimedia data display system for convergence type display and mirror - Google Patents

Abstract

PURPOSE: An Image and mirror fusion type digital multimedia data display system is provided to freely change an image and a mirror function according to an approach position and transmit data through a display. CONSTITUTION: A glass mirror(200) is installed on the front side corresponding to a display panel(120). The glass mirror projects images outputted from the display panel and displays the image on a screen. When the image output of the display panel is off, the glass mirror functions as a mirror. A sensor(300) senses the image output of the display panel based on a current approach position of a user and transmits a position sensing signal to a drive controller(150). A switching unit(400) switches on and off the input power by outputting the signal sensed by the sensor through the drive controller. [Reference numerals] (110) Storage unit; (120) LCD panel; (130) Input unit; (140) Backlight unit; (150) Drive controller; (300) Sensor; (400) Switching unit

Description

Image and mirror convergence type digital multimedia data display system {DIGITAL MULTIMEDIA DATA DISPLAY SYSTEM FOR CONVERGENCE TYPE DISPLAY AND MIRROR}

The present invention relates to an image and mirror convergent digital multimedia data display system. More particularly, the present invention relates to an image and mirror according to an access position and information transfer through the display by selectively displaying an image through a display according to a user's approaching position. And a mirror-fused digital multimedia data display system in which a furnace function is freely converted.

In general, display devices such as exhibitions, billboards, and electronic photo frames have a light source on the back of the printed surface on which the image is printed, and the image can be displayed on the front or used as a mirror using the front glass according to the on / off of the light source. have.

Image display devices provided in various places, such as the interior of a general building and a lot of subway history, various exhibition halls, product stores, etc., are commonly used as advertising and promotional means for interior purposes or corporate promotional images and marketing of various products.

Such an image display device installs a light source inside the frame housing, attaches a sheet on which an image of an advertisement copy, a campaign, a landscape, a person, etc. is printed to the outer surface, and irradiates light onto the sheet through a light source to display the front glass image. Imaging display means to be exposed through.

Recently, a mirror combined image display device having a function of a mirror in addition to the function of such an image display is also known.

The mirror combined image display device sequentially arranges light sources such as an image film and a fluorescent lamp in the rear of a conventional half mirror having a translucent function and a reflective function. The light source is turned off by selectively turning on and off the light source by a sensing operation. When the half mirror is reflected like a mirror, the image of the image film is displayed through the half mirror when the light source is turned on.

Meanwhile, a display apparatus for outputting image data information as an image through a display panel is also known.

1 illustrates a conventional image display system 10 that is generally used, and includes a storage unit 20 for storing multimedia data and a display panel for receiving and outputting a multimedia data signal input to the storage unit 20 ( 30), the transmission window 40 for transmitting the image output from the display panel 30 to be seen to the outside, the external input unit 50 for inputting the image signal and the multimedia data input to the storage unit 20 is outputted To this end, the display panel 30 includes a driving controller 60 that controls driving of the display panel 30 and the backlight unit 50.

Here, the image display device 70 showing the screen through the display panel 30 passes the light emitted from the backlight unit 50 through the display panel 30 and then enlarges and projects the screen through the transmission window 40. It works to express.

Light has waves in a certain direction. When the wave reaches the filter vertically, the light cannot pass through, and only when the wave reaches horizontally. In the display device 70, the LCD panel is arranged in a predetermined direction by an electric field, and in this case selectively passes light having a wave in a predetermined direction, the liquid crystal is linearly arranged by an electric field due to the molecular structure, Due to its mechanical properties, it is rotated by 90 degrees between layers again.

When the polarized light is stimulated by the rotationally arranged rear polarizer, the light is twisted in the polarized direction according to the rotation angle of the molecule. When this light reaches the front polarizer or analyzer, visible light is output from the screen.

In this case, when light is arranged at 90 degrees with respect to the polarizer in the front polarizer, the light is blocked. Use color filters to express colors. The pixel unit of the filter consists of three subpixels of RGB, and in LCD, RGB is a checkerboard structure.

The image display device 70 driven by the conventional display panel 30 is installed at any place regardless of the location, and the multimedia data stored in the storage device or the video signal transmitted through the communication module can be easily outputted to the screen for various kinds of information or There was an advantage that can repeatedly show the image, but the following problems.

First, since the light emitted from the backlight unit passes through the panel and is projected through the lens, the difference in visibility is greatly affected by the ambient illumination. The luminance difference is large according to the amount of ambient light. In this regard, the Republic of Korea Patent Publication No. 10-2008-0042540 discloses a 'digital display system'. This technique is designed to control the lighting unit according to the ambient light, but it is structurally complicated and has low reliability.

Second, only the function of outputting the video signal input from the multimedia data storage unit through the drive control unit is used as a simple image display use is limited to the use because it is not possible to replace or use other uses.

Third, when power is supplied to the driving module irrespective of the information user, an image is output on the screen accordingly, and image control for recognizing the access position of the information user is impossible. In addition, since the driving is determined only under the direct operation conditions of the power switch, there is a problem that automatic image control is impossible under other conditions not directly by the direct operation of the power switch.

The present invention was devised to improve the problems of the prior art. In the digital multimedia display, the light emitted from the backlight unit is passed through the panel to minimize the influence of the image quality due to the ambient illumination in the process of outputting the screen. The purpose of this is to turn off the image output screen at the position where it can be used as a mirror display for other purposes.

Another object of the present invention is to automatically turn on and off the display driving according to the access position of the information user, in addition to the simple screen output through the display panel to induce a change in the image output according to the access position of the user of the information in various forms To let them know.

The image and mirror fusion type digital multimedia display system according to the present invention for achieving the above object,

A storage unit for storing digital multimedia data, a display unit for receiving and outputting a multimedia data signal input to the storage unit, an external input unit for inputting an image signal, and a display panel for outputting multimedia data input to the storage unit; In the digital multimedia display system comprising a drive control unit for controlling the drive of the backlight unit for irradiating light,

A glass mirror installed at a front side corresponding to the display panel so as to transmit an image output from the display panel to the outside to be viewed as a screen, and function as a mirror when the image output of the display panel is turned off;

A detection sensor which detects an image output of the display panel based on a current approach position of a user and transmits a position detection signal to the driving controller;

And a switching unit for outputting a signal detected by the detection sensor through a driving control unit to turn on and off input power.

In addition, the glass mirror,

A transparent glass substrate layer capable of maintaining the overall shape of the glass mirror and transmitting light thereto;

Titanium coated on the back surface of the transparent glass substrate layer to transmit the image light emitted from the display panel and display it on the screen, and to serve as a mirror that can illuminate an object at low illumination where image output is stopped or visible light is blocked. Characterized in that the deposition coating layer.

In addition, the titanium deposition coating layer is deposited on the rear surface of the glass mirror is characterized in that deposited on the rear surface of the transparent glass substrate by an optical coating method using titanium.

In addition, the detection sensor,

Detection sensor casing body,

A connection end formed in a part of the casing main body and outputting a detection signal to a drive control unit;

And an optical lens unit configured on an upper side of the casing main body, the light lens unit configured to set a detection area and emit light to emit light in order to recognize the approach of an object within the set detection area, and a light detector to detect light. .

In addition, the switching unit,

An output circuit unit connected to the detection sensor;

Characterized in that it comprises a signal transmission unit for transmitting the detection signal of the detection sensor to the output circuit unit, the voltage control unit, LED driving circuit unit and the oscillation circuit unit.

According to the present invention, a display function is freely converted so that an image through a multimedia data display device can be selectively viewed according to a user's approaching position, so that the image can be used as a mirror in a state where the image is stopped according to the information passing through the display and the access position. It is installed in various places such as passenger terminal, building lobby, rest room, restroom and meeting room, etc., and it can be used as a display for information transmission and mirror as the user's choice.

In addition, it is possible to obtain a high-quality high-brightness image quality from the image output through the display panel and at the same time can be used as a high-definition mirror display in the image pause state, it can be used to replace the mirror in various places equipped with a mirror.

1 is a block diagram of a conventional digital multimedia display device.
FIG. 2 is a block diagram of an image and mirror fusion digital multimedia data display system according to an exemplary embodiment of the present invention. FIG.
3 is an explanatory diagram of an image and mirror fusion type digital multimedia data display system according to an embodiment of the present invention, where (a) is an image output diagram and (b) is a diagram showing a mirror display state.
Figure 4 shows the configuration of the detection sensor 300 according to an embodiment of the present invention as an example, (a) is a front view, (b) is a plan view, (c) is one side view.
5 is a configuration diagram of a detection sensor circuit according to an exemplary embodiment of the present invention.
6 is a photograph of a product according to an embodiment of the present invention, (a) is an image output state, (b) is a photograph of a mirror display state.

Hereinafter, the present invention will be described in detail with reference to the drawings.

2 is a block diagram of an image and mirror convergence digital multimedia data display system according to an exemplary embodiment of the present invention. 3 is an explanatory diagram of an image and mirror fusion type digital multimedia data display system according to an embodiment of the present invention, where (a) is an image output diagram and (b) is a diagram showing a mirror display state. Figure 4 shows the configuration of the detection sensor 300 according to an embodiment of the present invention as an example, (a) is a front view, (b) is a plan view, (c) is one side view. 5 is an example of configuration of a detection sensor circuit according to an exemplary embodiment of the present invention. 6 is a product photograph according to an embodiment of the present invention, (a) is an image output state, (b) is a photograph of a mirror display state.

Image and mirror fusion type digital multimedia display system 100 according to the present invention, as shown in Figures 2 to 4, is configured to automatically control the driving of the display unit 500 by object recognition, through which the usual multimedia When the screen output of the data is executed and the user's approach is recognized by the sensor, the screen output is stopped and functions as a mirror.

The main part includes a storage unit 110 for storing digital multimedia data, a display unit 500 for receiving and outputting a multimedia data signal input to the storage unit 110, an external input unit 130 for inputting a video signal, and In order to output the multimedia data input to the storage 110, the display panel 120 and the driving control unit 150 for controlling the driving of the backlight unit 140 irradiating light.

In addition, the digital multimedia display system 100 is installed at the front side corresponding to the display panel 120 to transmit the image output from the display panel 120 to the outside to be seen as a screen, and at the same time, the image of the display panel 120. When the output is turned off, the glass mirror 200 functions as a mirror.

In addition, the detection sensor 300 is configured to detect the image output of the display panel 120 based on the current approach position of the user and transmit a position detection signal to the driving controller 150.

The switching unit 400 outputs a signal detected by the detection sensor 300 through the driving controller 150 to turn on and off input power.

In addition, the glass mirror 200 may be coated on the rear surface of the transparent glass substrate layer 210 and the transparent glass substrate layer 210 that maintain the overall shape of the glass mirror 200 and may transmit light. It is composed of a titanium deposition coating layer 220 that transmits the image light emitted from the 120 to be displayed on the screen, and to function as a mirror for projecting the object at low illuminance in which image output is stopped or visible light is blocked.

Here, the titanium deposition coating layer 220 deposited on the back surface of the glass mirror 200 is deposited on the back surface of the transparent glass substrate 210 by an optical coating method using titanium.

The method for obtaining the titanium deposition coating layer 220 is obtained by injecting an electron beam into an evaporation chemical in a crucible that accelerates hot electrons with a filament current to dissolve molten water. That is, the chemicals in the crucible are accelerated and vaporized by the electron beam to be adsorbed on the rear surface of the transparent glass substrate layer 210 to form a thin film. The color of this deposited layer shows the characteristics of the champagne gold color. If you place black on the back, it looks gold, and if you place white, it looks purple or blue.

While the titanium deposition coating layer 220 deposited by the deposition method is more difficult to process than a general deposition product, the surface is smooth and has the advantage of forming a coating layer uniformly over the entire surface. The largest volume available today is 1100 * 670mm.

For reference, the mirrors currently in use are mostly products that have a mineral deposition product or a film attached thereto. Technically, it was produced by vacuum deposition using nickel.

In case of attaching film paper, silver and green are used, and there are few limitations on size and small quantity production is possible, but it has a disadvantage of lack of sharpness.

In addition, the detection sensor 300 preferably uses a detection sensor of the following standard.

Detection sensor 300



Distance measuring range
(Detection area) 10-80 cm Output method analog electric current 30 mA Input voltage DC4.5V ~ 5.5V Working temperature -10 ℃ ~ + 60 ℃ Storage temperature -20 ℃ ~ + 70 ℃ size 29.5mm * 13mm * 13.5mm Controller-Switching Units (400)



Input method analog Input voltage DC4.5V ~ 5.5V Working temperature -10 ℃ ~ + 60 ℃ Storage temperature -20 ℃ ~ + 70 ℃ size 32mm * 10mm * 6mm

The detection sensor 300 is not shown in detail in the mounting position, but may be installed and operated in a concealed place not visible from the front or outside of the panel constituting the display unit.

Preferred detection sensor 300 is a sensor having a lens that can set a detection area, as shown in FIG.

The main part is composed of a detection sensor casing main body 310, a part of the main body 310, and a connection end 320 for outputting a detection signal to the drive control unit, and an upper side of the main body 310, which is approximately 1 m or about or about An optical lens unit including a light emitter 330 that emits light and a light detector 340 that detects light in order to recognize an approach of an object in a detection area of about 10 to 80 cm, and a main body 310 by a display casing or a structure. It is configured to form a joint hole 350 of the body 310 to be fixed to.

Figure 4 shows the configuration of the detection sensor 300 according to an embodiment of the present invention as an example, (a) is a front view, (b) is a plan view, (c) is one side view.

In addition, as shown in FIG. 5, the switching unit 400 outputs the output circuit unit 410 connected to the detection sensor 300, and outputs the detection signal of the detection sensor 300 to the output circuit unit 410 and the voltage control unit ( The signal transmission unit 430 to be transmitted to the 420, the LED driving circuit unit 440 and the oscillation circuit unit 450 is composed of.

6 shows an example of a display by an image and mirror fused multimedia data display manufactured according to an embodiment of the present invention, (a) is an example of image output of multimedia data, and (b) is an example of a mirror display. Examples of product photos shown.

Reference numeral '600' denotes a 'frame' supporting the display unit 500 including the glass mirror and the display panel 120 in combination.

The operation of the image and mirror fusion multimedia data display system according to the present invention configured as described above will be described in detail.

BACKGROUND ART A digital information display (DID) is known as a device for storing digital multimedia data and repeatedly outputting it as necessary.

The advantage of DID is that it is relatively easy to deliver the screen to the user to install and deliver in various places. It is easily installed and operated at airports, lobbies, merchandise stores, and lounges.

In the image and mirror convergence multimedia data display system according to the present invention, when the screen is automatically displayed and the object (user) reaches a predetermined area, that is, the proximity detection area by the detection sensor 300, the image display state is stopped and the mirror (mirror) It is switched to a function, and when an object leaves the detection area, it is switched to the image display state again.

The meaning of image and mirror fusion means to have a mirror function in addition to image output through the display unit 500.

A general multimedia data display apparatus executes only repeated image output of stored data, but the image and mirror fusion type multimedia data display system 100 according to the present invention is configured to function as a mirror in a condition where image output stops at the same time as image output. .

2 is an overall configuration diagram of an image and mirror fusion type digital multimedia display system. The multimedia data controlled by the driving controller 150 is implemented as an image through the display panel 120, and the image is a front-side glass mirror 200. The light is transmitted through the glass mirror 200 and displayed on the screen.

In this state, when an object approaches a predetermined detection area through the detection sensor 300, the detection sensor 300 recognizes this, transmits a detection signal to the driving controller 150, and executes electrical control through the switching unit 400. Stop image output.

When image output through the display panel 120 is stopped, the glass mirror 200 functions as a mirror display instead of image output. In other words, the front object exhibits a mirror function that can be projected onto the glass mirror 200.

Accordingly, the user is in a state where the mirror can be seen instead of the image at the position approaching the glass mirror 200.

If it is assumed that the multimedia data display system is operated in a place where a mirror is needed, the multimedia data image output can be seen at a long distance and the user can see his / her appearance through the glass mirror 200 instead of the multimedia image at a near position.

To this end, the glass mirror 200 according to the present invention necessitates a function of clearly displaying an object when switching to the mirror function while displaying the image output on the display panel 120 in a normal and high definition.

FIG. 3A is a diagram schematically illustrating a process in which an image output through the display panel 120 passes through the front glass panel 20 as it is, and is viewed as a screen, and FIG. 3B illustrates the display panel 120. ) Shows a state in which external visible light is reflected by the glass mirror 200 in the absence of an image output and functions as a mirror.

The glass mirror 200 is configured to be transmitted as it is when the image is output as it is, so that the glass mirror 200 can be seen as a screen, and high luminance reflection can be performed as a mirror while the image output is stopped.

The glass mirror 200 according to the present invention is coated on the back surface of the transparent glass substrate layer 210 and the transparent glass substrate layer 210 that can transmit light to transmit the image light emitted from the display panel 120 It was used to have a titanium deposition coating layer 220 to be displayed on the screen and to function as a mirror that can project the object at low illumination, the image output is stopped or visible light is blocked.

The titanium deposition coating layer 220 coated on the rear surface of the glass mirror 200 is deposited on the rear surface of the transparent glass substrate 210 by an optical coating method using titanium, and the method of obtaining the titanium deposition coating layer 220 is It is obtained by injecting an electron beam into an evaporation chemical in a crucible that dissolves molten water by accelerating hot electrons with a filament current. The chemical in the crucible is accelerated and vaporized by an electron beam to be adsorbed on the back surface of the transparent glass substrate layer 210 to form a thin film. do. The color of this deposited layer has a champagne gold color.

If you place black on the back, it looks gold, and if you place white, it looks purple or blue.

While the titanium deposition coating layer 220 deposited by the deposition method is more difficult to process than a general deposition product, the surface is smooth and has the advantage of forming a coating layer uniformly over the entire surface.

In this way, the front surface of the transparent glass substrate layer 210 and the rear surface of the titanium mirror coating layer 220 is made of a glass mirror 200 without causing a disturbance to the output image and at the same time can obtain a clear mirror function.

In comparison, the mirrors used in the past are mostly a product deposited with a mineral deposition product or a film attached thereto. In the case of mineral deposition, technically, the mirror is produced by a vacuum deposition method using nickel, but the sharpness of the mirror is inferior. In the case of attaching the film, the color is silver and green, the size is limited and small quantity production is possible.

As described above, the present invention allows the light emitted from the backlight unit to pass through the panel in the digital multimedia display, thereby minimizing the effect of the image quality due to the ambient illumination in the process of outputting the screen. It can be used as a mirror display for other purposes.

In addition, the display drive is automatically turned on and off according to the user's approaching position, and in addition to the simple screen output through the display panel, the user can induce a change in image output according to the access position of the information user and deliver various types of screens to the user. This has the advantage of improving the information transfer effect by increasing the frequency of use directly or indirectly.

As described above, the present invention has been described with reference to the drawings and specification, with reference to an embodiment of the invention, but it is an example. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention.

100: digital multimedia data system
110: storage unit
120: display panel
130:
140: backlight unit
150: drive control unit
200: glass mirror
210: transparent glass substrate
220: titanium deposition coating layer
300: detection sensor
310: casing body
320: connection end
330 light emitter
340: Light Detector
400: switching unit
410: output circuit
420: voltage control unit
430: signal transmission unit
440: LED drive circuit
450: oscillation circuit
500: display unit
600: frame

Claims (5)

Storage unit 110 for storing digital multimedia data, the display unit 500 for receiving and outputting the multimedia data signal input to the storage unit 110, the external input unit 130 and the storage unit for inputting a video signal ( In the digital multimedia display system 100 comprising a drive control unit 150 for controlling the driving of the display panel 120 and the backlight unit 140 irradiating light to output the multimedia data input to 110,
It is installed on the front side corresponding to the display panel 120 to transmit the image output from the display panel 120 to the outside to be seen as a screen, and at the same time it functions as a mirror when the image output of the display panel 120 is turned off. Glass mirror 200;
A detection sensor 300 which detects an image output of the display panel 120 based on a current access position of the user and transmits a position detection signal to the driving controller 150;
Image and mirror fusion type digital multimedia display system, characterized in that consisting of a switching unit 400 for outputting the signal detected by the detection sensor 300 through the drive control unit 150 to turn on and off the input power. The method of claim 1,
The glass mirror 200,
A transparent glass substrate layer 210 capable of maintaining the overall shape of the glass mirror 200 and transmitting light thereto;
It is coated on the rear surface of the transparent glass substrate layer 210 to transmit the image light emitted from the display panel 120 to display on the screen, and to stop the output of the image or to project the object at low illumination with the visible light blocked Image and mirror fusion type digital multimedia display system, characterized in that consisting of a titanium deposition coating layer 220 to function as a mirror. The method of claim 2,
The titanium deposition coating layer 220 deposited and coated on the rear surface of the glass mirror 200 is deposited on the rear surface of the transparent glass substrate 210 by an optical coating method using titanium. Display system. The method of claim 1,
The detection sensor 300,
Detection sensor casing main body 310,
A connection end 320 which is formed in a part of the main body 310 and outputs a detection signal to a driving control unit;
The light emitter 330 is configured on the upper side of the main body 310 to set a detection area and emits light in order to recognize the approach of an object within the set detection area. The light detector 340 detects light. Image and mirror fusion multimedia display system, characterized in that composed of an optical lens unit. The method of claim 1,
The switching unit 400,
An output circuit unit 410 connected to the detection sensor 300,
Characterized in that it comprises a signal transmission unit 430, LED driving circuit unit 440 and oscillation circuit unit 450 for transmitting the detection signal of the detection sensor 300 to the output circuit unit 410 and the voltage control unit 420 Image and mirror fusion multimedia display system.

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