JP2016168301A - Study desk with display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To impart good visual angle characteristics to a study desk user and prevent peeping by others.SOLUTION: A study desk (1) with a display device is configured by installing a display device (20) vertically with respect to a desk top face (11) at one end part of the rectangular desk top face (11), a display screen (21) of the display device (20) facing the opposite end part of the desk top face (11). In the display device (20), the view angle of the end part in the width direction of the display device (20) is wider than that of the central part in the width direction of the display device (20).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a learning desk with a display device, and more particularly to a learning desk with a display device in which a display device is installed perpendicular to the desk surface.

  Information technology (IT) in the educational environment itself, including the deployment of information terminals such as tablets, high-speed broadband connections at schools, electronic blackboards, wireless LAN environment maintenance, utilization of digital textbooks and teaching materials, etc. The government's proposal to promote the use of IT in the educational environment itself to improve the academic ability of children and students and improve IT literacy is under consideration. Through these efforts, the IT environment will be realized in all elementary schools, junior high schools, high schools, and special support schools during the 2010s.

Regarding a learning desk for preparing a learning environment, for example, Patent Document 1 discloses an information equipment built-in desk that is intended to provide a desk that can be easily used and stored easily at any time. Yes.
This information device built-in desk is provided with a drawer with a lid that opens upward with the side portion as a fulcrum at the bottom of the writing table of the desk, and the information device is housed inside the drawer, while the display unit of the information device is covered with the lid. Attach to the back of the. When using information equipment, pull out the drawer, open the lid, and operate. When not in use, close the lid and store the drawer on the desk.

Further, in the learning desk, it is necessary to prevent peeping from the surroundings when using a display device that displays teaching materials and the like. Regarding a technique for controlling the appearance of a display device, for example, Patent Document 2 discloses a display device for switching the viewing angle. The display of this display device includes a polarization adjustment layer that is converted into a pixel, and a polarization correction layer is provided between the polarizing plates so as to be separated from the polarization adjustment layer. The polarization correction layer includes a plurality of region sets, and the polarization correction effect differs depending on the set.
This display can be switched between a private viewing mode with a narrow viewing angle and a public viewing mode with a wide viewing angle. In the private visual field mode, the compensated image can be seen from the visual field range, but the disordered image can be seen from outside the visual field range, so that personal information can be protected. Disable the polarization correction layer to provide public mode.

JP-A-6-309066 JP 2006-171728 A

  As described above, in schools, efforts are being made to realize IT in the educational environment, but the reality is that IT is not progressing in the learning environment for children at home. For example, at home, a notebook PC (notebook personal computer) or tablet terminal is simply used for learning, but the notebook PC or tablet terminal cannot be used efficiently at a learning desk. . In a learning desk, it is required to realize a learning style that enables efficient learning using a notebook PC or tablet.

  At this time, a display device can be placed on the learning desk, and learning can be performed while appropriately displaying images such as teaching materials on the display device. However, since the learning desk is for personal use, it has been described above. Thus, it is necessary to devise a technique for preventing peeping from others. At this time, since the angle of the line of sight with respect to the screen changes according to the position where the viewer sits in front of the learning desk, considering the viewing position on the learning desk, there is no problem with the display screen for the learning desk user. It is necessary to make the display screen invisible or difficult to see from others on the side of the learning desk.

  Patent Document 1 discloses an information device built-in desk in which an upper device is provided on the back surface of a lid that opens upward. Further, the display device of Patent Document 2 switches the entire screen to either the wide viewing angle mode or the low viewing angle mode. However, in any of the patent documents, there is no mention of the problem of improving the visibility of the display screen according to the new position and preventing looking from the side.

  The present invention has been made in view of the above circumstances, and is a learning desk with a display device in which a display device is installed vertically on an end of a desk surface, and has a good viewing angle with respect to a user of the learning desk An object of the present invention is to provide a learning desk with a display device that imparts characteristics and prevents peeping from others.

  In order to solve the above-mentioned problems, the first technical means of the present invention is directed to one end portion of a rectangular desk top surface, with the display screen of the display device facing the opposite end portion of the desk top surface. A learning desk with a display device in which the display device is installed perpendicular to the upper surface, wherein the display device has a viewing angle at the end in the width direction of the display device rather than at the center in the width direction of the display device. Is characterized by a wide area.

  According to a second technical means, in the first technical means, the display device has a viewing angle control film for controlling a viewing angle on a surface of a display screen of the display device, The plurality of light shielding portions arranged in parallel in a stripe shape are arranged such that the longitudinal direction of each light shielding portion coincides with the height direction of the display device, and the interval between the adjacent light shielding portions is the same as that of the display device. The end portion is wider in the width direction of the display device than the center portion in the width direction.

  According to a third technical means, in the second technical means, the interval between the adjacent light shielding portions gradually increases from the center in the width direction of the display device toward the end in the width direction of the display device. It is characterized by being.

  According to a fourth technical means, in the first technical means, the display device includes a liquid crystal display panel that performs display by spatial light modulation using liquid crystal, and the liquid crystal display panel includes two regions having different liquid crystal orientations. And controlling the viewing angle of the display device according to the arrangement of the two regions in the width direction of the display device, and the different liquid crystal alignments in the width direction of the display device at an end portion in the width direction of the display device The regions are alternately arranged, and in the central portion in the width direction of the display device, the same liquid crystal alignment regions are continuously arranged in a constant size in the width direction of the display device. Is.

  A fifth technical means includes a sensor for detecting a position of a person in front of the learning device with a display device in the fourth technical means, and the liquid crystal display panel has the different liquid crystal alignment regions alternately. An arrangement in which the arrangement is arranged and an arrangement in which regions of the same liquid crystal alignment are continuously arranged with a constant size can be switched by a voltage applied to the liquid crystal, and according to the detection result by the sensor, The arrangement range in which different liquid crystal alignment regions are alternately arranged and the arrangement range in which the same liquid crystal alignment regions are continuously arranged with a constant size are made variable.

  A sixth technical means is the fourth technical means, wherein the liquid crystal display panel is divided into a plurality of parts in the width direction of the display device, a predetermined divided region at an end in the width direction, and a center in the width direction. One or a plurality of divided areas between the divided areas, and the plurality of divided areas from the divided area at the end in the width direction of the display device toward the divided area at the center. The size of the region of the same liquid crystal alignment continuously arranged is increased.

  According to the present invention, it is a learning desk with a display device in which a display device is installed vertically at an end portion of a desk surface, which gives a favorable viewing angle characteristic to a user of the learning desk and looks into it from others. An object of the present invention is to provide a learning desk with a display device that can prevent the above.

It is a figure which shows the example of an external appearance structure of the learning desk with a display apparatus by this invention. It is a figure for demonstrating the viewing angle of the display screen in a learning desk with a display apparatus. It is a figure explaining the structural example for controlling the viewing angle of a display apparatus. It is a figure for demonstrating the space | interval of the louver light-shielding part of the viewing angle control film which concerns on Embodiment 1. FIG. It is a figure for demonstrating the other example of a setting of the viewing angle of the display screen in a learning desk with a display apparatus. It is another figure for demonstrating the other example of a setting of the viewing angle of the display screen in a learning desk with a display apparatus. It is a figure for demonstrating the viewing angle of the display screen in the learning desk with a display apparatus of Embodiment 2. FIG. 10 is a diagram for explaining a setting example of a divided area of a screen when the display device in Embodiment 3 is viewed from the front. FIG. It is a figure for demonstrating Embodiment 4 of the learning desk with a display apparatus of this invention. It is a figure for demonstrating the structure in the learning desk with a display apparatus of Embodiment 6. FIG.

(Embodiment 1)
FIG. 1 is a diagram showing an example of the external configuration of a learning desk with a display device according to the present invention. FIG. 1 (A) is an overall perspective view of the learning desk with a display device, and FIG. It is a figure which shows roughly the state which is utilizing.
The learning desk 1 with a display device is configured by combining a desk 10 and a thin display device 20. The display device 20 is a thin display device using an FPD (Flat Panel Display), and is configured as a liquid crystal display device using a liquid crystal display panel, for example.

The display device 20 is installed perpendicularly to the desk top surface 11 at one end of the rectangular desk top surface 11 of the desk 10 with the display screen 21 of the display device 20 facing the opposite end of the desk top surface 11. Has been.
The viewer 2 can perform work such as learning by using the desk top surface 11 of the desk 10 while sitting on the front surface of the learning desk 1 with display device and watching the display screen 21 of the display device 20.

  FIG. 2 is a diagram for explaining a viewing angle of a display screen in a learning desk with a display device. In the present embodiment, according to the position of the viewer who views the display device 20 of the learning desk with display device 1, the viewing angle is set so that the image can be viewed up to the end of the display screen 21, and the display is performed. The viewing angle is set so that the display content of the display screen 21 cannot be correctly viewed at a position outside the learning desk with device 1 in the horizontal direction (width direction). For this reason, in this embodiment, the viewing angle of the display device 20 of the learning desk 1 with a display device is changed in the width direction of the screen of the display device 20, and the width direction of the display device 20 is larger than the central portion of the display device 20. Widen the viewing angle at the edge.

FIG. 2A is a diagram for explaining the view angle of the display screen 21 when the viewer 2 is in the center in the width direction (horizontal direction) of the learning desk with a display device. In this case, the viewing angle of the display device 20 is set so that the display on the display screen 21 can be correctly viewed even when the viewer 2 is at the end in the width direction of the display device 20.
If the viewing angle is set uniformly in the width direction at this time, as shown in FIG. 2 (B), when the viewer 2 is located at the side end of the learning desk 1 with a display device, the side end The partial area e of the display screen 21 on the side far from the screen cannot be seen correctly.

  Therefore, as shown in FIG. 2C, the widthwise end of the display device 20 is provided so that the viewer 2 at the side end of the learning desk with display device 1 can correctly view the entire display screen 21. Widen the viewing angle. Then, the viewing angle is set so that the viewer who is further away from the learning device with display 1 in the width direction cannot correctly see the display screen 21 at the far end.

In order to realize this, the viewing angle of the display device 20 is set so that the end in the width direction is larger than the viewing angle at the center in the width direction. The viewing angle at the center in the width direction is determined based on the viewing angle when the viewer visually recognizes from the center in the width direction, and the viewing angle at the end in the width direction is determined when the viewer views from the end in the width direction. It can be determined based on the viewing angle.
In this case, when the viewing distance is the distance from the display screen 21 to the viewer 2 in the vertical direction of the display screen 21, as shown in FIG. 2A, the viewing angle at the center in the width direction of the display device 20 is
Tan ⁻¹ ((width of display screen × ½) / viewing distance) × 2 = α.
As shown in FIG. 2B, the viewing angle at the end in the width direction of the display device 20 is
Tan ⁻¹ (width of display screen / viewing distance) × 2 = β.

FIG. 3 is a diagram illustrating a configuration example for controlling the viewing angle of the display device. The display device 20 includes a liquid crystal display panel 22. As shown in FIG. 3A, the light r emitted from the surface of the liquid crystal display panel 22 diffuses over a wide angular range. A viewing angle control film 30 is attached to the surface of the liquid crystal display panel 22 in order to control this diffusion and control to a constant viewing angle. That is, the display device 20 has the viewing angle control film 30 on the surface thereof.
FIG. 3B shows a partial cross-sectional configuration of the viewing angle control film 30, and FIG. 3C shows a partial planar configuration of the viewing angle control film 30.

The viewing angle control film 30 includes louver light shielding portions 31 arranged at predetermined intervals, and a transmissive portion 32 that transmits light is provided between the louver light shielding portions 31. The louver light shielding portions 31 are arranged in parallel in a stripe shape, and are arranged so that the longitudinal direction of each louver light shielding portion 31 coincides with the height direction of the display device 20. The louver shading unit 31 limits the transmission angle of the transmitted light that passes through the transmission unit 32, thereby controlling the viewing angle of the screen.
The size of the viewing angle can be arbitrarily set by changing the interval between the louver shading parts 31. The viewing angle control film 30 is formed as a resin film having a thickness of about 0.1 mm, for example. A louver shading portion 31 made of a material that does not transmit light is disposed inside the transparent resin layer film.

In the present embodiment, the interval between the louver light shielding portions 31 is configured to gradually increase from the center portion in the width direction of the display device 20 toward the end portion.
4A is a diagram for explaining the interval between the louver light shielding portions of the viewing angle control film according to the present embodiment, and FIG. FIG. 4C is a diagram illustrating the interval between the louver light shielding portions at the center in the screen width direction. The horizontal direction of each figure is provided so as to coincide with the width direction of the display device 20. Each of these drawings is simplified for the purpose of conceptually explaining the interval between the louver shading portions 31.

  As shown in FIG. 4A, the interval between the louver shading portions 31 of the viewing angle control film 30 is wider at the end portion in the width direction of the display device 20 than at the center portion in the width direction of the display device 20, The interval is configured to become wider from the center in the width direction of the display device 20 toward the end. Thereby, the viewing angle in the width direction of the display device 20 gradually increases from the central portion toward the end portion. In this case, the viewing angle at the center in the width direction is determined based on the viewing angle when the viewer visually recognizes from the center in the width direction, and the viewing angle at the end in the width direction is viewed by the viewer from the end in the width direction. The viewing angle can be determined based on the viewing angle.

  Thereby, when a viewer views the display device 20 within the range in the width direction of the display device with a display device 1, the entire area of the display screen 21 can be visually recognized comfortably, and the learning device with a display device 1 Outside the range in the width direction, the display on the display screen 21 of the display device 20 cannot be completely viewed, and it is possible to protect the privacy by preventing peeping from the side.

(Embodiment 2)
In the present embodiment, as in the third embodiment, the viewing angle at the end in the width direction is made wider than the central portion in the width direction of the display device 20 of the learning device 1 with a display device. A liquid crystal display device is used as the display device 20, and viewing angle control is executed by controlling the liquid crystal alignment of the liquid crystal display panel.

5 and 6 are diagrams for explaining other setting examples of the viewing angle of the display screen in the learning desk with a display device, and FIG. 5 explains the liquid crystal alignment in the wide viewing angle mode with a relatively wide viewing angle. FIG. 6 is a diagram for explaining liquid crystal alignment in the viewing angle suppression mode in which the viewing angle is relatively narrow. 5 and 6 coincides with the width direction (horizontal direction) of the display device 20.
The display device 20 of the learning desk with display device 1 includes a liquid crystal display panel 22. The liquid crystal display panel 22 controls the alignment state of the liquid crystal 23 using a counter electrode sandwiching the liquid crystal 23 layer, and displays an image by spatial light modulation. The display method here is a VA (Vertical Alignment) method.

In the wide viewing angle mode of FIG. 5, a viewer within a wide viewing angle can visually recognize the image displayed on the liquid crystal display panel 22. On the other hand, in the viewing angle suppression mode of FIG. 6, only the viewer within a narrow viewing angle can view the image displayed on the liquid crystal display panel 22.
The liquid crystal display panel 22 has two regions having different liquid crystal alignments, and controls the viewing angle of the display device 20 according to the arrangement of the two regions in the width direction of the display device 20.

In the wide viewing angle mode of FIG. 5, the liquid crystal display panel 22 represents one pixel with two pixels in the vertical direction. For example, it is assumed that a display with high resolution in the vertical direction by dividing and driving upper and lower pixels as sub-pixels in a multi-pixel structure is applied.
Here, one pixel has two regions having different liquid crystal alignments. These two regions are alternately set in the width direction of the liquid crystal display panel. Each of the regions R1 and R2 operates as one pixel. In this example, the upper and lower sub-pixels constituting one pixel are controlled so that one has a liquid crystal alignment A and the other has a liquid crystal alignment B different from the crystal alignment A. The liquid crystal alignment A and the liquid crystal alignment B are substantially symmetric with respect to the normal line of the screen of the liquid crystal display panel 22 as a target axis.

  In the wide viewing angle mode, the liquid crystal alignment in the horizontal direction and the vertical direction of adjacent sub-pixels, for example, each sub-pixel in FIG. 5 is different, so that the viewer cannot distinguish and visually recognize them. For this reason, an observer sees the average value of the transmittance of the two liquid crystal alignments A and B at all viewing angles. For example, when the liquid crystal panel 22 of FIG. 5 is viewed from the front, both the liquid crystal alignments A and B are visually recognized as a halftone of the average value of A and B. On the other hand, when the liquid crystal alignments A and B are viewed from an oblique direction, one of these liquid crystal alignments should appear as white and the other as black, for example, but the viewer cannot distinguish between these differences. Similar to the front view, it is visually recognized as a halftone. Thereby, an image can be visually recognized with a wide viewing angle.

The display device of FIG. 6 is also applied to a multi-pixel structure in which the upper and lower pixels in the vertical direction are divided and driven as sub-pixels as in FIG.
In the viewing angle suppression mode of FIG. 6, regions of the same liquid crystal alignment are continuously arranged with a certain size in the width direction of the display device 20. That is, a region having the same liquid crystal alignment has a spread of a plurality of pixels. Here, each of the regions R3 and R4 has a substantially uniform liquid crystal alignment, but the liquid crystal alignment in the region R3 and the liquid crystal alignment in the region R4 are different from each other. The two different types of liquid crystal alignments are arranged approximately symmetrically with the normal line of the liquid crystal display panel 22 as the target axis.

The viewing angle suppression mode regions R3 and R4 are a region in which a plurality of pixels are gathered, and have a sufficient size that the viewer can visually recognize. That is, the viewer does not see the average value of the transmittance of the two regions as in the wide viewing angle mode described above, but the difference between the transmittances of the two regions R3 and R4 at a specific viewing angle. It is visually recognized as a pattern that can be distinguished by an observer. This difference in transmittance increases corresponding to the viewing angle.
The regions R3 and R4 have the same transmittance when viewed in the axial direction because the liquid crystal alignment in the regions R3 and R4 is symmetrical with the normal line of the screen of the liquid crystal display panel 22 as the target axis. Thereby, the difference in the region is not visually recognized by the viewer in the axial direction.

When the viewer's line of sight deviates from the vertical direction of the liquid crystal display panel, the regions R3 and R4 exhibit different transmittances for the same applied voltage. Thus off-axis viewers will see different brightness patterns, which will obscure the image. For example, a black and white checkered pattern can be seen, making it difficult to see the original display image.
As described above, in the fourth embodiment of the present invention, the wide viewing angle mode and the viewing angle suppression mode can be switched by switching the liquid crystal 23 itself by performing voltage control of the electrodes between the pixels.

In the present embodiment, the divided area to be displayed in the wide viewing angle mode and the divided area to be displayed in the viewing angle suppression mode are set at the same time in the screen of the display device 20. And the width direction end portion are controlled to have different viewing angles.
FIG. 7 is a diagram for explaining the viewing angle of the display screen in the learning device with a display device according to the second embodiment. In the embodiment according to the present invention, the viewing angle is set so that the image can be viewed up to the end of the display device 20 according to the position of the viewer who views the display device 20 of the learning device 1 with a display device. At the same time, the viewing angle is set so that the display content of the display device 20 cannot be correctly viewed at a position outside the learning desk with display device 1 in the width direction. For this purpose, the viewing angle of the display device 20 of the learning desk with display device 1 is configured to vary in the width direction (horizontal direction) of the display device 20. Here, the viewing angle at the end in the width direction of the display device 20 is made wider than the central portion in the width direction of the display device 20.

  In the present embodiment, as shown in FIG. 7, the display device 20 is divided into three in the width direction, the central divided region M2 is operated in the viewing angle suppression mode, and the two divided regions M1 on both sides thereof are operated. , M3 are operated in the above wide viewing angle mode. In this case, the viewer 2 a at the center in the width direction of the learning desk 1 with display device can correctly view the end of the display screen 21. The state of the screen visually recognized by the viewer 2a at this time is shown in the visual recognition screen 40.

  On the other hand, the viewer 2b who is outside the range in the width direction of the learning desk with display device 1 cannot view the display screen 21 correctly. In this case, in the divided areas M1 and M3 operating in the wide viewing angle mode, the so-called whiteout in which the gradation of the bright portion of the screen disappears becomes difficult to see, and the divided areas M1 operating in the viewing angle suppression mode are difficult to see. For example, a black-and-white pattern can be seen and the original display image cannot be correctly recognized. A visual screen 41 shows the state of the screen visually recognized by the viewer 2b at this time.

  In this manner, the display device 20 of the learning desk with a display device 1 is divided in the width direction, the central divided region is operated in the viewing angle suppression mode with a narrow viewing angle, and the divided regions on both sides of the central portion are set to have a viewing angle. By operating in a wide wide viewing angle mode, it is possible to prevent peeping from the side of the display device 20 of the learning device 1 with a display device, and learning with a display device in a public place where an unspecified number of people are present. Even when the desk 1 is installed, the privacy of the user can be protected.

Further, in the case of the viewing angle configuration as shown in FIG. 7 above, when the viewer moves from the center position in the width direction of the learning device 1 with the display device to the outside in the width direction, Some begin to lack from the field of view. For example, when the viewer moves from the center position in the width direction of the learning desk with display device 1 to the right side in the width direction, the image at the left end of the divided area operating in the view angle suppression mode deviates from the view angle.
In order to cope with this, a sensor for detecting the position of the viewer is provided for the learning desk 1 with a display device, and the viewing angle suppression mode and the wide viewing angle are set according to the position of the viewer according to the detection result of the sensor. The range of the mode division area may be variably set. For example, when the viewer moves in any direction from the center in the width direction of the learning desk with display device 1, the width of the divided areas M1 and M3 in the wide viewing angle mode on the opposite side to the moving direction is increased. Thereby, it is possible for the viewer who views within the range in the width direction of the learning desk with display device 1 to correctly view the display screen 21 and to prevent peeping from outside the range in the width direction. .
As the sensor, for example, a human sensor using infrared rays, ultrasonic waves, visible light, or the like can be applied. A human sensor or the like that detects the position of a person based on a change in an image captured by the camera may be applied.

  When the liquid crystal display panel 22 can be switched between the viewing angle suppression mode and the wide viewing angle mode, for example, one counter electrode of the liquid crystal display panel 22 is segmented, and in the wide viewing angle mode, two liquid crystals are contained in one pixel. Switch to the above orientation. In one pixel, the same voltage V1 is applied to all regions of the segmented electrode. The switching of orientation is controlled by a weak electric field generated at the end of the segmented electrode. The weak electric field is generated by protrusions on the electrode surface.

The liquid crystal display panel 22 further includes an in-plane electrode, which switches the liquid crystal between the first arrangement in the wide viewing angle mode and the second arrangement in the viewing angle suppression mode.
The in-plane electrode is used to form an electric field in a substantially plane of the liquid crystal layer. In order to realize the viewing angle suppression mode, the voltage V2 is applied through the adjacent in-plane electrodes in the wide viewing angle mode. The voltage V2 is lower than the normal voltage V1. The in-plane electric field due to the in-plane electrode exceeds the effect of the weak electric field from the segment electrode, and the viewing angle suppression mode is switched in which the liquid crystal alignment is the same in a certain size region. The electrode configuration for switching between the viewing angle suppression mode and the wide viewing angle mode can be appropriately designed without being limited to the above example.

(Embodiment 3)
In the second embodiment, the display device 20 is divided and operated in two operation modes, the viewing angle suppression mode and the wide viewing angle mode. In the present embodiment, the liquid crystal display panel is controlled so as to give a viewing angle intermediate between the viewing angles of these two operation modes.
As a configuration for providing an intermediate viewing angle between the viewing angle suppression mode and the wide viewing angle mode according to the second embodiment, substantially uniform liquid crystal alignment regions are continuously arranged in the viewing angle suppression mode shown in FIG. The size in the width direction of the regions R3 and R4 is changed.
That is, in the viewing angle suppression mode of the second embodiment, the size in the width direction is smaller than the size in the width direction of the display device in the region where the substantially uniform liquid crystal alignment regions are continuously arranged. By doing so, it is possible to set a wider viewing angle region than the viewing angle suppression mode with the narrowest viewing angle. In this case, the wide viewing angle mode and the viewing angle suppression mode can be used as long as the size in which the substantially uniform liquid crystal alignment regions are continuously arranged is larger than the wide viewing angle mode in which different liquid crystal alignment regions are alternately arranged. An area having an intermediate viewing angle can be set.
Further, when a plurality of intermediate viewing angles are set, the size in which the substantially uniform liquid crystal alignment regions are continuously arranged may be changed stepwise.

  FIG. 8 is a diagram for explaining an example of setting the divided areas of the screen when the display device according to this embodiment is viewed from the front. Here, the display screen is divided into seven in the width direction of the display device 20. The outermost divided regions M1 and M3 in the width direction operate in the wide viewing angle mode. The wide viewing angle mode has the same liquid crystal alignment as that in FIG. Further, the center divided region M2 in the width direction of the screen operates in the viewing angle suppression mode. The viewing angle suppression mode is assumed to have the same liquid crystal alignment as that in FIG. 6 described in the fourth embodiment.

The divided areas M4 and M5 and the divided areas M6 and M7 are set between the divided area M2 in the viewing angle suppression mode and the divided area M1 operating in the wide viewing angle mode.
The divided areas M4 and M7 are located outside the divided areas M5 and M6, and are larger than the viewing angles of the divided areas M5 and M6 and smaller than the viewing angles of the divided areas M1 and M3 in the wide viewing angle mode. give. In the divided regions M4 and M7, the width direction sizes of the regions R3 and R4 in which the regions having the same liquid crystal alignment shown in FIG. 6 are continuously arranged are larger than those of the divided regions M1 and M3. As a result, the viewing angles of the divided areas M4 and M7 are smaller than the divided areas M1 and M3 in the wide viewing angle mode.

  Further, the divided areas M5 and M6 give a viewing angle larger than the viewing angle of the divided area M2 operating in the viewing angle suppression mode and smaller than the viewing angles of the divided areas M4 and M7. In the divided regions M5 and M6, the size in the width direction of the region where the liquid crystal alignment regions are continuously arranged is larger than that of the divided regions M4 and M6. Thereby, the viewing angles of the divided areas M5 and M6 are smaller than those of the divided areas M4 and M7.

  As described above, the liquid crystal display panel of the present embodiment is divided into a plurality in the width direction in the display device direction, and further between the predetermined divided region at the end in the width direction and the divided region at the center in the width direction. It has one or a plurality of divided areas. In the plurality of divided regions, the size of the region having the same liquid crystal alignment continuously arranged from the divided region at the end in the width direction of the display device toward the divided region at the center increases. The number of divided areas is not limited to the above example, and a larger number of divided areas can be set.

  With the above configuration, the viewing position in the width direction of the learning device 1 with the display device is changed by changing the viewing angle stepwise in the width direction of the display device 20 from the central divided region toward the outer divided region. However, the visibility of the display screen can be improved, and further, the peeping from the side of the display device 20 is prevented, so that a learning desk with a display device can be used in a public place where there are many unspecified people. Even when 1 is installed, the user's privacy can be protected.

(Embodiment 4)
FIG. 9 is a diagram for explaining a fourth embodiment of the learning desk with a display device of the present invention.
The display device 20 is installed perpendicularly to the desk top surface 11 at one end of the rectangular desk top surface 11 of the desk 10 with the display screen 21 of the display device 20 facing the opposite end of the desk top surface 11. Has been.
The user can perform work such as learning by using the desk top surface 11 of the desk 10 while sitting on the front surface of the learning desk with display device 1 and viewing the display screen 21 of the display device 20.

In the present embodiment, in addition to the configuration in which the viewing angle is optimized in each of the above embodiments, the appropriate viewing distance of the display device is optimized.
The display device 20 generally has an appropriate viewing distance. If the viewing distance is too short, the pixels on the screen scanning line are visually discriminated by the user, and the displayed image cannot be comfortably viewed. This appropriate viewing distance is, for example, at least three times the length (3H) of the height (H) of the display screen 21.
Here, when the HDTV standard was formulated by the Japan Broadcasting Corporation, 1125 scanning lines were determined ("Hi-Vision Technology", edited by the Japan Broadcasting Corporation, Broadcasting Technology Laboratory).
Here, through a psychological experiment for realistic sensation, the realistic sensation begins to become apparent when the angle of view is approximately 20 °, and the realistic sensation becomes remarkable when the angle of view is 30 °. When viewing a still image, the most preferred viewing distance is 2H to 3H with respect to the screen height H, and the angle of view is 20 to 30 °. When using a moving image, the most preferable viewing distance is 4H, and the angle of view is 19 °. Based on this, the optimum viewing distance is set to 3H, and at that time, there are about 1000 required scanning lines that a person with visual acuity of 1.0 cannot discriminate the scanning lines, so the number of scanning lines of the preceding NTSC and PAL systems Thus, 1125 scanning lines having an integer ratio were determined.
That is, according to the high-definition standard, by viewing the screen at a distance of three times (3H) or more of the height of the screen, it is possible to comfortably view the display image without viewing the pixels of the individual scanning lines.

  Actually, the producer who produces the content to be displayed may produce the content on the premise that the content is viewed at a distance of 3H. In particular, in the 3D video with parallax, the appearance and the stereoscopic effect. Many are made to be optimal when viewed at a distance of 3H. Therefore, it can be said that the distance of 3H is an important index in receiving the intention of the producer.

  The above 3H distance is a value when viewing a display screen having a resolution based on the high-definition standard, but in recent years, a display device having a higher resolution of 4K resolution or a display device having an 8K resolution. Has appeared. The highest resolution of high vision is, for example, a resolution of 1920 × 1080 pixels (full high definition; FHD (Full High Definition)), and a 4K image is, for example, a resolution of 4096 × 2160 pixels. The 8K image has pixels that are twice as long as the 4K image.

  The distance of 3H is applied to a high-definition image. When an image with a higher resolution than this is displayed, the appropriate viewing distance is shorter than 3H. For example, in the case of a 4K image, the number of scanning lines (2160 lines) is twice the number of full high-definition scanning lines (1080 lines). Therefore, the optimum viewing distance at which the pixels on the scanning line are not discriminated and visually recognized is at least half that in the case of full high vision, and the distance is 1.5 times the height H of the display screen (1. 5H) or more. In the case of an 8K image, the appropriate viewing distance is 0.75 times (0.75H) or more the height H of the display screen.

  In other words, the length of the appropriate viewing distance of 3H changes according to the ratio S to the number of scanning lines of full high vision. This represents an appropriate viewing distance = 3H / S. Here, H is the height of the display screen 21 of the display device 20, and S is the ratio of the number of scanning lines of the display device 20 to the number of scanning lines of full high vision.

In the display device 1 according to the embodiment of the present invention, the depth of the desk surface of the desk, that is, the desk on which the display device 20 is installed so that the display device 20 can be visually recognized at the appropriate viewing distance or more. The distance from the edge of the end opposite to the end of the upper surface to the display screen 21 of the display device 20 is optimized.
As shown in FIG. 9B, in the normal viewing state, the viewer 2 who views the display device 20 is placed at the end portion on the viewer side of the desk 10 and behind it (from the display device 20). In the direction of leaving). Therefore, the depth L of the desk top surface of the desk 10, that is, the distance L from the end opposite to the end of the desk top surface on which the display device 20 is installed to the display screen 21 of the display device 20 is an appropriate viewing distance. 3H / S or more.

Thereby, when the viewer 2 visually recognizes the display screen 21 of the display device 20 on the learning desk 1 with a display device, the viewer 2 can see a comfortable display image without discriminating the pixels of the scanning line. .
For example, when a 40-inch display device 20 is mounted, for example, the screen height is about 50 cm and the screen width is about 90 cm. When a display device 20 having a resolution of full-high-definition television generally used for this is used, the distance L in the depth direction of the desk is 150 cm according to the above formula, but the display device 20 with 4K resolution is used. As a result, the distance L in the depth direction of the desk becomes 75 cm, which can be a practically appropriate size as a learning desk.

(Embodiment 6)
FIG. 10 is a diagram for explaining the configuration of the learning device with a display device according to the sixth embodiment. As described in the fifth embodiment, the appropriate viewing distance of the display device 20 is when the height of the display screen is H and the ratio of the number of scanning lines of the display device 20 to the number of scanning lines of full HD is S. It becomes more than the length of 3H / S.
Here, in the present embodiment, the display is started from the center position p in the width direction of the edge on the near side (the end side opposite to the end where the display device is installed) of the desk surface on which the viewer is supposed to be located. The distance to the display screen 21 of the apparatus 20 is configured to include at least a region having 3H / S or more.

  As shown in FIG. 10, the distance from the center position p in the width direction of the edge of the desk top surface where the viewer 2 is estimated to be located to the display screen 21 of the display device 20 differs in the width direction of the display device 20. For example, the distance m1 between the center position p in the width direction of the edge of the desk surface and the center position q1 of the display device 20 is the shortest, and the center position p in the width direction of the edge of the desk surface and the horizontal direction edge q3 of the display device 20 are. The distance m3 is the longest.

At this time, the learning desk 1 with a display device is configured so as to include at least a region where the distance between the center position p in the width direction of the edge of the desk surface and the display screen 21 is 3 H / S or more.
In the example of FIG. 10, T indicates a range in which the distance between the center position p in the width direction of the edge of the desk surface estimated to be positioned by the viewer 2 and the display screen 21 is 3 H / S. In this case, the distance m2 between the position q2 of the display screen 21 and the center position p in the width direction of the edge of the desk surface coincides with the distance 3H / S. The distance from the center position p in the width direction is a region of 3H / S or more. The same applies to the left side of the display screen 21. As a result, the learning device with a display device 1 has a distance from the center position p of the edge on the opposite side to the edge on which the display device 20 is installed to the display screen 21 of the display device 20 of 3H /. It includes at least a region that is greater than or equal to S.

  By including an area of 3H / S or more, which is an appropriate viewing distance, in the distance from the viewer to the display screen 21 of the display device 20, the entire display screen substantially conforms to the appropriate viewing distance, and the entire screen is almost appropriate. Can be viewed at a reasonable viewing distance.

  The technical features (components) described in each of the above embodiments can be combined with each other, and new technical features can be formed by combining them.

DESCRIPTION OF SYMBOLS 1 ... Learning desk with a display apparatus, 2 ... Viewer, 2a, 2b ... Viewer, 10 ... Desk, 11 ... Desk top surface, 20 ... Display apparatus, 21 ... Display screen, 22 ... Liquid crystal display panel, 23 ... Liquid crystal, 30 ... viewing angle control film, 31 ... louver shading part, 32 ... transmission part, 40, 41 ... visual recognition screen.

Claims (6)

A learning desk with a display device in which a display screen of the display device is directed to one end portion of a rectangular desk top surface and directed to an end portion on the opposite side of the desk top surface, and the display device is installed perpendicularly to the desk top surface. There,
The learning device with a display device, wherein the display device has a wider viewing angle at the end in the width direction of the display device than at the center in the width direction of the display device. The learning device with a display device according to claim 1,
The display device has a viewing angle control film for controlling the viewing angle on the surface of the display screen of the display device,
The viewing angle control film includes a plurality of light-shielding portions arranged in parallel in a stripe shape so that the longitudinal direction of each light-shielding portion coincides with the height direction of the display device, and an interval between adjacent light-shielding portions. The learning device with a display device is characterized in that the end portion is wider in the width direction of the display device than the central portion in the width direction of the display device. The learning device with a display device according to claim 2,
The distance between the adjacent light shielding portions gradually increases from the center in the width direction of the display device toward the end in the width direction of the display device. Learning device. The learning device with a display device according to claim 1,
The display device includes a liquid crystal display panel that performs display by spatial light modulation using liquid crystal,
The liquid crystal display panel has two regions having different liquid crystal orientations, and controls the viewing angle of the display device according to the arrangement of the two regions in the width direction of the display device.
The different liquid crystal alignment regions are alternately arranged in the width direction of the display device at an end portion in the width direction of the display device, and in the width direction of the display device in a center portion in the width direction of the display device. A liquid crystal display panel, wherein regions having the same liquid crystal alignment are continuously arranged with a constant size. In the learning apparatus with a display device according to claim 4,
A sensor for detecting the position of a person in front of the learning device with a display device;
The liquid crystal display panel can be switched between an arrangement in which the different liquid crystal alignment regions are alternately arranged and an arrangement in which the same liquid crystal alignment regions are continuously arranged with a certain size by a voltage applied to the liquid crystal. Electrode structure,
According to the detection result by the sensor, the range of the arrangement in which the different liquid crystal alignment regions are alternately arranged and the range of the arrangement in which the same liquid crystal alignment regions are continuously arranged with a constant size are made variable. A learning device with a display device. In the learning apparatus with a display device according to claim 4,
The liquid crystal display panel is divided into a plurality of parts in the width direction of the display device, and one or more of the liquid crystal display panel is further provided between a predetermined divided area at the end in the width direction and a divided area at the center in the width direction. Has divided areas,
In the plurality of divided regions, the size of the region of the same liquid crystal alignment arranged continuously increases from the divided region at the end in the width direction of the display device toward the divided region at the center. A learning device with a display device.

Images