KR20040019526A - Liquid crystal display monitor embedded a Charge Coupled Device Camera - Google Patents

Abstract

PURPOSE: A liquid crystal monitor having a CCD camera is provided to mount a CCD camera adjacently to a center of a liquid crystal monitor, thereby minimizing movement of the line of vision in a multimedia work by using the CCD camera and the liquid crystal monitor, and reduce the manufacturing cost. CONSTITUTION: A liquid crystal monitor is formed of a front bezel(210), a liquid crystal panel(220), a back light unit(230), and a rear bezel(240). A CCD(Charge Coupled Device) camera(250) is installed in a space formed by coupling the front bezel and the rear bezel, having a CCD element and a lens part. The front bezel has an aperture(211) to expose the lens part of the CCD camera.

Description

Liquid crystal display monitor embedded a Charge Coupled Device Camera}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal monitor incorporating a CCD (Charge Coupled Device) camera, and more particularly to a liquid crystal monitor using a smart panel incorporating a driving circuit of a CCD camera.

Liquid crystal monitors are attracting attention as one of the next-generation flat panel display devices with display elements using light emitting diodes (LEDs), plasma display panels (PDPs), electroluminescent panels (ELs), and the like. As the early problems have been overcome to some extent with the development of the technology, it has recently been in the spotlight as a display device to replace the conventional CRT monitor.

Such a liquid crystal monitor includes a liquid crystal panel in which liquid crystal is injected between an upper plate and a lower plate; A driving circuit unit for driving the liquid crystal panel; And a backlight unit that provides display light for image output through the liquid crystal panel.

The liquid crystal panel includes a TFT array process for forming a switching element for applying a pixel unit signal, a color filter process for forming an RGB color filter for realizing color, and a cell process for forming a liquid crystal cell for changing light transmittance. It is completed through the, and serves to represent the color image by controlling the light transmitted to the pixel according to the signal voltage of each pixel input from the driving circuit unit the white plane light incident from the backlight unit.

Meanwhile, due to the spread of high-speed Internet networks using optical cables, large-capacity data transmission is possible, so that companies that provide two-way data communication services such as online video conferencing and online video chat have emerged. CCD cameras are also becoming commonplace.

1 is a diagram illustrating a multimedia use environment that is generally used.

As shown in FIG. 1, in a general multimedia use environment, a personal computer 110 and a liquid crystal monitor 120 are placed on a holder such as a desk, and a CCD camera 130 is disposed on an upper bezel of the liquid crystal monitor 120. Is equipped.

Here, the liquid crystal monitor 120 is required to be placed in the center of the user's eyes in that it is the user's main information transmission tool, the CCD camera 130 should not invade the user's workspace spatially, the front of the user The image must be able to be obtained and placed close to the central processing unit such as personal computer 110 and the power supply. Therefore, the user tends to position the liquid crystal monitor 120 at the center of his eyes and to mount the CCD camera 130 on the upper bezel of the liquid crystal monitor 120.

However, as the liquid crystal monitors 120 are large and slim in recent years, the use environment as described above may cause inconvenience.

For example, when the liquid crystal monitor 120 is large, the interval between the main line of sight (a line of sight for the use of the liquid crystal monitor) and the secondary line of sight (a line of sight for the use of a CCD camera) increases, so that when the LCD monitor 130 is working. The user has to lift his head more than before, which causes the fatigue of the user during long-term work such as video conferencing.

In addition, as the LCD monitor 120 becomes slim, it is not easy to secure a free space for mounting the CCD camera 130 on the top of the bezel of the LCD monitor.

In addition, since the CCD camera 130 and the liquid crystal monitor 120 are separately used in the above-described use environment, problems such as a cost increase due to a separate purchase, difficulty in installation and wiring arrangement, and problems in mobility reduction are pointed out.

Of course, in order to solve the above problems, the CCD camera 130 is a liquid crystal monitor

Although it may be considered to embed the bezel on the front surface of the 120, the bezel thickness increases when the conventional method is embedded, which is contrary to the recent technology trend. In addition, the CCD camera 130 requires a considerable fine adjustment for optimal use due to the characteristics of the product, such as an optical product, there is a fear that if the built-in without considering this rather adverse effects.

As described above, in the conventional multimedia use environment, there are various problems such as increased fatigue, increased cost, and reduced mobility due to the use of a CCD camera and a liquid crystal monitor separately.

The present invention minimizes the user's eye movements due to multimedia work by mounting a CCD camera close to the center of the liquid crystal monitor, and has a high price competitiveness and mobility by integrating the CCD camera and the liquid crystal monitor. It is an object of the present invention to provide a CCD camera built-in liquid crystal monitor that provides a more convenient multimedia using environment by allowing the operation characteristics to be adjusted.

1 is a view showing a general multimedia using environment.

2 is a view showing the configuration of a CCD camera built-in liquid crystal monitor according to an embodiment of the present invention.

3 is a block diagram illustrating a circuit configuration of a liquid crystal monitor with a built-in CCD camera according to an embodiment of the present invention.

4 and 5 are views showing the configuration of the OSD screen for fine adjustment of the CCD camera in the present invention.

6 is a diagram illustrating a multimedia use environment according to the present invention;

<Explanation of symbols for the main parts of the drawings>

110, 610 ... Personal computer (PC) 120, 620 ... LCD monitor

130, 630 ... CCD camera 210 ... front bezel

212 ... OSD panel 220 ... LCD panel

230 ... backlight unit231 ... lamp

232 ... light guide plate 233 ... support main

240 ... rear bezel

The present invention for achieving the above object, the liquid crystal panel for defining an image display area; A CCD camera formed to expose a lens portion on the front bezel for protecting the liquid crystal panel; A CCD driver formed in the non-image display area of the liquid crystal panel to drive the CCD camera; And an OSD controller for adjusting operating characteristics of the CCD camera. Characterized in that comprises a.

Preferably, the liquid crystal panel is a smart panel, and the CCD camera is formed such that the lens unit is exposed on the front bezel of a position close to the image display area of the liquid crystal panel.

The OSD controller may include: an OSD processor configured to provide an ODS screen for adjusting operation characteristics of a CCD camera to the liquid crystal panel; An OSD operation unit for providing an interface means between the OSD processing unit and a user; Characterized in that configured to include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing the configuration of a liquid crystal monitor with a built-in CCD camera according to an embodiment of the present invention.

Referring to FIG. 2, the LCD monitor has a structure in which a front bezel 210, a liquid crystal panel 220, a backlight unit 230, and a rear bezel 240 are sequentially fastened, and the front bezel 210 and the rear surface are fastened. A CCD camera 250 having a CCD element and a lens unit is installed in a space secured by the bezel 240.

In the front bezel 210, an opening 211 exposing the lens unit of the built-in CCD camera 250 is formed close to the image display area of the front bezel 210, and the fines of the liquid crystal monitor and the CCD camera 250 are formed. OSD panel 212 is provided for adjustment.

The liquid crystal panel 220 is divided into an active area 221 which provides a display screen, and a non-pixel area 222 in which various circuits for driving the pixel are mounted, and the non-pixel area 222. The driving circuit of the CCD camera 250 and the OSD control circuit for the fine adjustment of the CCD camera 250 are mounted in a predetermined region 222a of FIG.

The liquid crystal panel 220 is preferably a smart panel. A smart panel is a panel that integrates an additional circuit such as an analog-to-digital converting circuit and an inverter circuit for back light with an existing general liquid crystal panel. It is thinner and lighter than the product, and features various designs of the product.

Therefore, when the smart panel is used, various circuits of the driving unit of the CCD camera 250 and the OSD control unit for adjusting the operating characteristics of the CCD camera 250 may be mounted on the liquid crystal panel 220. The increase in volume is virtually insignificant.

The back light unit 230 is a means for providing the liquid crystal panel 220 with white plane light suitable for image realization. The backlight unit 230 may include a lamp 231 used as a light source and a light guide plate for implementing plane light. 232), and a reflecting plate (not shown) that improves light utilization rate is configured in the form of a module fastened to one support main 233. If the reflective liquid crystal panel is used, which does not require its own light source, the backlight unit 230 may be omitted.

3 is a block diagram illustrating a circuit configuration of a liquid crystal monitor with a built-in CCD camera according to an embodiment of the present invention.

Referring to FIG. 3, the LCD monitor includes a liquid crystal panel 310 having a pixel area, a CCD camera 320 and a CCD camera 320 formed to expose a lens portion on a front bezel for protecting the liquid crystal panel 310. It comprises a CCD driver 330 formed in the non-pixel area of the liquid crystal panel 310 to drive the LCD, and an OSD control unit 340 for providing an OSD screen and OSD operation for the fine adjustment of the CCD camera 320 do.

Here, the CCD camera 320 converts the light coming through the lens unit 320a into an electrical signal using the CCD device 320b and then applies the same to the DSP 330a which will be described later.

The CCD driver 330 may include a DSP 330a, a JPEG converter 330b, a CPU 330c, a memory 330d, and the like.

The digital signal processor (DSP) 330a converts an electrical signal of an image input through the CCD camera 320 into a digital signal, and applies the digital signal to the JPEG converter 330b. A multiplexer is transferred to the driving circuit of the liquid crystal panel 260. The MUX is a digital multiplexing device that selects any one input signal from the signal output from the DSP 330a by a selection control signal and loads it into a driving circuit of the liquid crystal panel 310. to be.

Joint Photographic coding Experts Group Converter 330

b) compresses the digital image signal input through the DSP 330a using the international standard of color still picture compression.

The CPU 330c may include a CCD driver 330 and an OSD controller.

General control is performed according to various operations of the 340, and control is performed to perform data communication with an external personal computer through the RS-232C 280.

The memory 330d serves as a buffer for storing a compressed image signal compressed through the JPEG converter 330b for a predetermined time, and the operating software required for the operation of the CPU 330c and the JPEG converter 330b and the Stores operating software (hereinafter, referred to as a 'driver driver') necessary for the operation of the CCD camera 320.

The OSD control unit 340 includes an OSD operation unit 340a and an OSD processing unit 340b, which are mutually interfaced by the CPU 330c.

The OSD operation unit 340a generally has a key array structure (212 of FIG. 2), and typically includes 4 to 6 function keys and character keys, and provides a key input signal corresponding to a key input by a user. Is generated and output to the CPU 330c.

The OSD processing unit 340b provides itself with images and text necessary for adjusting the display quality of the liquid crystal monitor without an external input signal, and simultaneously provides images and text necessary for adjusting operation characteristics of the CCD camera 320. Provided by itself.

Next, the process of adjusting the operation characteristics of the CCD camera through the OSD screen in the CCD camera built-in liquid crystal monitor having the above configuration will be described.

First, when a driving power is applied to the liquid crystal monitor, and a control signal of the CPU 330c is applied to the CCD element 320b according to a user's command, the CCD element 320b electrically transmits light entering through the lens 320a. The signal is converted into a signal and applied to the DSP 330a.

The DSP 330a converts the applied electrical signal into a digital signal and applies it to the JPEG converter 330b. The DSP 330a transfers the converted digital signal to the liquid crystal panel 310 through a MUX (not shown).

In this case, when it is determined that the image of the CCD camera displayed through the liquid crystal panel 310 does not have a desired display quality, the user sends a key input signal to the CPU 330c through the OSD operation unit 340a, and the OSD processing unit ( 340b outputs an appropriate OSD screen to the liquid crystal panel 310 in response.

Meanwhile, FIG. 4 and FIG. 5 show one configuration of an OSD screen for fine adjustment of the CCD camera 320.

As shown in FIG. 4, the initial OSD screen requires the selection of a device requiring fine adjustment among a liquid crystal monitor and a CCD camera. In response to the user selecting a CCD camera adjustment item, as shown in FIG. 5, the next OSD screen displays detailed items that can be finely adjusted, such as brightness, contrast, focusing, and the like. The value is given. In this case, the user may increase or decrease the set value by key operation through the OSD operation unit 340a. As an example, FIG. 5 illustrates a case in which the brightness of the CCD camera is increased by a level of '1' from the default value by selecting 'CCD camera' as the adjustment device requiring fine adjustment and selecting the 'brightness' adjustment item.

Thereafter, the user selects another fine adjustment item while viewing the OSD screen outputted, and continues to adjust until a camera image having a desired display quality is obtained through fine adjustment through the OSD operation unit 340a. Save the adjustment and exit the OSD screen. At this time, the adjustment value set through the OSD operation unit 340a is a memory.

This affects the driving driver of the CCD camera 320 stored at 330d. Accordingly, the CCD camera 320 has different operating characteristics than before. The adjustment value is stored in the memory 330d and used as a default value when the CCD camera 320 is used later.

As such, the user can adjust various operating characteristics of the CCD camera 320, for example, brightness, contrast, and focus, by simple operation through the OSD screen.

On the other hand, Figure 6 is a view showing a multimedia using environment according to the present invention.

As shown in FIG. 6, in the multimedia use environment according to the present invention, a personal computer 610 and a liquid crystal monitor 620 are placed on a holder such as a desk, and a CCD camera 630 is built in the front bezel of the liquid crystal monitor. It is. In this case, the CCD camera 630 is preferably formed in close proximity to the image display area of the liquid crystal monitor.

In such a usage environment, the distance between the main gaze of the user (a gaze suitable for the use of the liquid crystal monitor 620) and the auxiliary gaze (a gaze suitable for the use of the CCD camera 630) is smaller than that of the conventional art (A ₁ > A ₂ ). . That is, the user can suppress the movement of the gaze by the gaze interval reduced during the multimedia work, thereby creating a more convenient use environment.

As described above, the above embodiments are disclosed for the purpose of illustration, and those skilled in the art will appreciate that various modifications, improvements, substitutions, and additions may be made without departing from the spirit of the present invention. Accordingly, the technical scope of the present invention should be defined by the appended claims.

As described above, the liquid crystal monitor with built-in CCD camera according to the present invention integrates the CCD camera and the liquid crystal monitor using a smart panel concept, so that an increase in volume due to integration is hardly generated.

In addition, the liquid crystal monitor minimizes the user's gaze movement in multimedia work using the CCD camera and the liquid crystal monitor, provides high price competitiveness and mobility due to the integration of the CCD camera, and finely adjusts operation characteristics of the CCD camera on the OSD. In this way, the user can build a more convenient multimedia environment.

Claims (5)

A liquid crystal panel defining an image display area; A CCD camera formed to expose a lens portion on the front bezel for protecting the liquid crystal panel; A CCD driver formed in the non-image display area of the liquid crystal panel to drive the CCD camera; And An OSD controller for adjusting operating characteristics of the CCD camera; CCD camera built-in liquid crystal monitor comprising a. The method of claim 1, The liquid crystal panel is a CCD camera built-in liquid crystal monitor, characterized in that the smart panel. The method of claim 1, And the CCD camera is formed such that the lens part is exposed on the front bezel at a position close to the image display area of the liquid crystal panel. The method of claim 1, wherein the OSD control unit, An OSD processor for providing an ODS screen for adjusting operation characteristics of a CCD camera to the liquid crystal panel; An OSD operation unit for providing an interface means between the OSD processing unit and a user; CCD camera built-in liquid crystal monitor comprising a. The method of claim 4, wherein And an OSD screen provided by the OSD processing unit includes at least one fine adjustment item among brightness adjustment, contrast adjustment, and focusing adjustment of the CCD camera.