JP2004206044A - Lighting device and liquid crystal display using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting device permitting to reduce blurring of movement and tailing in animation display while inhibiting display brightness from falling off, moreover, capable of suppressing power consumption, reducing the weight and size, and prolonging the life of the device, and to provide a liquid crystal display using the same. <P>SOLUTION: A light source control part 22 of a control circuit 16 outputs a luminance control signal to each light source power supply circuit 35-38 in synchronization with latch pulse signals LP outputted to a gate driver 12 from a gate driver control part 18. Based on the inputted luminance control signal, each light source power supply circuit 35-38 changes over the light emitting states of cold cathode tubes 30-33 to any of the 1st to 3rd light emitting states S1-S3 to light an LCD panel 2 from the back surface of the display area. The 1st light emitting state is a turned-off state S1; the 2nd light emitting state a maximum lighting state S2 in which the maximum lighting brightness can be obtained; and the 3rd light emitting state is an intermediate lighting state S3 in which about a half of the 2nd light emitting state can be obtained. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a lighting device that illuminates a display area of a liquid crystal display device, and a liquid crystal display device using the same. In particular, the present invention relates to a lighting device that improves moving image blur and a trailing phenomenon when displaying a moving image, and a liquid crystal display device using the same.
[0002]
[Prior art]
[First Prior Art]
As an alternative to a CRT (Cathod Ray Tube), which is a conventional representative display device, recently, an active matrix type liquid crystal display device (hereinafter, referred to as a TFT) having a TFT (Thin Film Transistor) as a switching element in each pixel. -Abbreviated as LCD) has become mainstream.
[0003]
In principle, the TFT-LCD holds the gradation data written in each pixel for one frame period (equal to the period of the vertical synchronization signal Vsync). In such a hold-type display method, when a moving image is displayed, image quality degradation may occur in which a blurring or tailing phenomenon of an image is visually recognized without being able to follow a quick image change.
[0004]
In order to solve this problem, a method has been proposed in which the display period of the grayscale data of each pixel is limited to a certain period within one frame period in synchronization with the vertical synchronization signal Vsync (for example, see Patent Document 1). . Further, in order to realize the method, an illumination area of a lighting device such as a backlight unit that illuminates an image display area of a TFT-LCD is divided into a plurality of areas within the image display area, and the illumination of each divided area is sequentially blinked. A method has been proposed in which the display period (illumination period) of each divided region is limited to a certain period within one frame period (for example, see Patent Documents 2 to 5).
[0005]
[Second conventional technology]
More specifically, a cold cathode fluorescent lamp (CCFL) is used as a light source of a conventional backlight unit for a TFT-LCD, and the cold cathode fluorescent lamp is constantly lit to illuminate the display area of the LCD. . When a moving image is displayed while the cold-cathode tube is constantly lit, for example, when an attempt is made to display a moving image by rewriting the gradation data in a frame period (period) of 16.7 ms, the response time to the change in the electric field intensity of the liquid crystal molecules is Since there are several tens of milliseconds, the next gradation data is written before the response of the liquid crystal molecules is completed, which causes a problem that the moving image display appears to be "blurred".
[0006]
Further, in the TFT-LCD, since the gradation data written in a certain frame is retained until the gradation data is rewritten in the next frame, display blur based on an ergonomic viewpoint called tracking is visually recognized. Therefore, there is a problem that the degree of blurring of the moving image becomes large.
[0007]
The above problem is described in detail in Non-Patent Documents 1 and 2. Non-Patent Document 2 discloses a study of improving moving image blur by blinking a cold cathode tube of a backlight unit.
[0008]
However, simply blinking the cold-cathode tube of the backlight unit leaves an afterimage of the previous frame, which is visually recognized as a ghost of the moving object in the image. In particular, when a line segment is moved, the line segment is visually recognized as a double or triple tailing phenomenon, which causes a significant reduction in display quality.
[0009]
Therefore, as a countermeasure against the ghost, there has been proposed a scan backlight system in which a backlight unit is divided into a plurality of portions and a light source in each divided region is turned on and off in synchronization with writing of gradation data. In order to realize this, a direct type backlight unit has been proposed in which a plurality of light sources such as fluorescent tubes are arranged substantially in parallel to a gate bus line (scanning line) and the light sources are sequentially turned on and off for each of a plurality of divided regions.
[0010]
FIG. 74 is a cross-sectional view of a direct-type backlight unit used in a conventional TFT-LCD for displaying moving images, taken along a plane perpendicular to the tube axis direction of the cold-cathode tube, and a luminance distribution of illumination light from the backlight unit. Are shown. In FIG. 74, a gate bus line (not shown) of the TFT-LCD 1008 extends in a direction perpendicular to the plane of the drawing. The display start line of one frame is on the "top (top)" side on the left side of the figure, and the final display line is on the "bottom (bottom)" side of the right side of the figure. The backlight unit 1000 is divided into four from “up” to “down” in the figure. Each divided area is isolated by a lamp reflector (reflection plate) 1002 having a U-shaped cross section, and a cold cathode tube 1004 whose tube axis extends in the direction in which the gate bus line extends is arranged in the lamp reflector. The light emission port of the backlight unit 1000 is arranged on the back surface of the display area of the TFT-LCD 1008 via the transmission type diffusion plate 1006.
[0011]
[Third prior art]
In recent years, the screen size and the brightness of the TFT-LCD 1008 have been increasing, but it is necessary to increase the number of arc tubes in the backlight unit 1000 to improve the light emission brightness.
[0012]
In addition, since the TFT-LCD 1008 continuously outputs light for one frame with respect to the CRT, image blur occurs in moving image display, and the image quality performance is inferior to that of the impulse emission CRT (Non-Patent Document 3). To cope with this, Patent Literature 1 proposes an LCD impulse conversion method. In Patent Literatures 2 and 6, the backlight unit 1000 is driven by a duty (flashing) in units of one frame. And black writing are alternately performed to realize an impulse. However, if the duty driving or black writing is simply performed, the light output time is reduced and the luminance of the display is reduced. Therefore, it is necessary to increase the output of the backlight unit 1000 at the same time.
[0013]
[Fourth prior art]
In a scan type or blinking type surface illumination device and a liquid crystal display device, a cold cathode tube or an LED is used as a light source. However, in order to improve the quality of a moving image (reduce blur of an outline), it is turned on at a frequency of 60 Hz. And the light is turned off.
[0014]
[Fifth prior art]
FIG. 75 shows a configuration in which a direct-type backlight unit used in a conventional TFT-LCD for displaying moving images is viewed from the display area side. As shown in FIG. 75, the backlight unit 1000 is divided into four from the top to the bottom in the figure. Each of the divided areas 1010 to 1013 is isolated by a lamp reflector (reflection plate) 1002 (not shown in FIG. 75) having a U-shaped cross section. In the lamp reflector 1002, cold cathode tubes 1004 whose tube axes extend in the direction in which the gate bus lines of the TFT-LCD 1008 (not shown in FIG. 75) extend are arranged. The light emission port of the backlight unit 1000 is disposed on the back surface of the display area of the TFT-LCD 1008 via the transmission type diffusion plate 1006. The direct type is the mainstream as a scan type illumination device.
[0015]
FIG. 76 shows a configuration of a sidelight type backlight unit as another scan type illumination device. As shown in FIG. 76, each of the divided regions 1010 to 1013 of the backlight unit 1000 has a light guide plate 1020 which is optically separated from each other and arranged in a plane. One point light source such as an LED 1022 is disposed on each side end surface of each of the light guide plates 1020 to 1023.
[0016]
[Patent Document 1]
JP-A-9-325715
[Patent Document 2]
JP-A-11-202285
[Patent Document 3]
JP-A-11-202286
[Patent Document 4]
JP 2000-321551 A
[Patent Document 5]
JP 2001-125066 A
[Patent Document 6]
JP-A-5-303078
[Patent Document 7]
JP 2001-184034 A
[0017]
[Non-patent document 1]
Television Image Information Engineering Handbook Ohmsha P70-71
[Non-patent document 2]
ASIA Display / IDW'01 P1779-1780, 1781-1782
[Non-Patent Document 3]
Taiichiro Kurita, "Display Method of Hold-type Display and Image Quality in Moving Image Display", First LCD Forum
[Non-patent document 4]
J. Hirakata et. al. : "High Quality TFT-LCD System for Moving Picture", SID 2002 Digest, p. 1284-1287 (2002)
[Non-Patent Document 5]
D. Sasaki et. al. : "Motion Picture Simulation for Designing High-Picture-Quality Hold-Type Displays", SID 2002 Digest, p. 926-929 (2002)
[Non-Patent Document 6]
K. Sekiya et. al. : "Eye-Trace Integration Effect on The Perception of Moving Pictures and A New Possibilities for Reducing Blue-Hold-Type Display 200, IDs. 930-933 (2002)
[Non-Patent Document 7]
H. Ohtsuki et. al. : "18.1-inch XGA TFT-LCD with Wide Color Reproduction using High Power LED-Backlighting", SID 2002 Digest, p. 1154-1157 (2002)
[Non-Patent Document 8]
Gerald Harbors, 2 outsiders, “LED Backlightingfor LCD-HDTV, [online], Internet <URL: http://www.lumileds.com/pdfs/techpaperspres/IDMC_Paper.pdf>
[0018]
[Problems to be solved by the invention]
[Issues of the first prior art]
However, in the case of the first prior art, if the illumination light source is simply blinked, the display luminance is significantly reduced, and there is a problem that an LCD having a low luminance and a low image quality occurs. For example, if the display area is divided into five divided areas and one frame is sequentially illuminated by 20%, the luminance in one frame period is 1/5 that of 100% illumination. On the other hand, if the lighting time in each of the divided areas is lengthened, the luminance increases, but there is a problem that image quality deterioration such as motion blur becomes remarkable.
[0019]
[Problem of the second prior art]
However, in the direct backlight unit 1000 described with reference to FIG. 74 of the second prior art, since the cold-cathode tubes 1004 are arranged close to the back surface of the TFT-LCD 1000, luminance unevenness is reduced as shown in the upper part of FIG. It has the disadvantage that it is easy to occur. The horizontal axis in the upper part of FIG. 74 represents the position on the back surface of the display area of the TFT-LCD 1008, and the vertical axis represents the luminance. As shown in the brightness distribution curve in the upper part of FIG. 74, the direct-type backlight unit 1000 is apt to cause a brightness difference between a portion immediately above the cold cathode tubes 1004 and a boundary between adjacent cold cathode tubes 1004, thereby causing uneven brightness. It has the disadvantage of being easy. As a method of making the luminance difference hard to see, the gap between the transmission type diffusion plate 1006 and the TFT-LCD 1008 is widened to diffuse and mix the illumination light, or the diffusion degree of the transmission type diffusion plate 1006 is increased, and the cold cathode tube 1004 is diffused. A method has been adopted in which light emitted immediately above is diffused more uniformly. However, the former has a problem that the thickness of the device is increased, and the latter has a problem that the diffused light is again incident on the cold-cathode tube, is absorbed, and the amount of light is reduced.
[0020]
[Problem of Third Conventional Technology]
As in the third prior art, when the luminance of the cold cathode fluorescent lamp 1004 of the backlight unit 1000 is increased to increase the luminance, there arises a problem that power and cost increase. In addition, even when an image having a low average screen brightness is displayed, the temperature of the TFT-LCD 1008 rises because the light emission brightness of the cold cathode tube 1004 remains high. The cooling structure for suppressing the temperature rise also needs to be modified, and in some cases, there is a problem that the device volume of the TFT-LCD 1008 increases.
[0021]
[Problem of Fourth Prior Art]
Since the cold cathode tube and the LED have limitations on the current and supply power to emit light, there is a problem that the luminance cannot be increased by the duty driving. That is, in order to increase the supplied current, the size of the ballast of the cold-cathode tube increases. For this reason, ballasts are heavy, thick, and expensive. Further, there is a problem that the drive voltage increases with an increase in the current, the light-to-light conversion efficiency of the cold-cathode tube is reduced, and the life is shortened. In addition, for example, in a display device of a portable electronic device such as a notebook personal computer, a strict limit is imposed on power supply. Even in a solid-state light source such as an LED, there is a problem that the light-to-light conversion efficiency is reduced and the life is shortened due to an increase in current.
[0022]
[Problem of Fifth Prior Art]
In the direct backlight unit 1000 described with reference to FIG. 75 of the fifth prior art, since the cold cathode tubes 1004 are arranged close to the back surface of the TFT-LCD 1008, the luminance distribution is likely to be non-uniform, and the display is difficult. There is a disadvantage that the above-mentioned uneven brightness tends to occur.
[0023]
In addition, the sidelight type backlight unit 1000 described with reference to FIG. 76 of the fourth prior art does not use a light source such as the cold cathode tube 1004 having a relatively large light emission amount and a long length, so that the luminance is low. It has the problem of being low.
[0024]
An object of the present invention is to provide a lighting device capable of reducing motion blur and tailing in moving image display while suppressing a decrease in display luminance, and a liquid crystal display device using the same.
Another object of the present invention is to provide a lighting device capable of suppressing power consumption, making the device compact and lightweight and having a long life, and a liquid crystal display device using the same.
[0025]
[Means for Solving the Problems]
An object of the present invention is to provide a lighting device for illuminating a display region of an active matrix type liquid crystal display device, wherein at least one light source capable of changing light emission luminance and at least one light emitting region for emitting light from the light source are provided. And a light source control system that switches between a maximum lighting state in which the light emitting region emits light at a predetermined maximum luminance and an intermediate lighting state in which light emission occurs at a predetermined intermediate luminance lower than the maximum luminance. Achieved.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
A lighting device according to a first embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. First, a schematic configuration of a lighting device according to the present embodiment and a liquid crystal display device using the same will be described with reference to FIG. FIG. 1 shows a schematic view of a TFT-LCD 1 as an example of a display device when viewed from the panel display surface side. In the LCD panel 2, the liquid crystal lc is sealed between two glass substrates: an array substrate (not shown) on which the TFTs 4 are formed and a counter substrate (not shown) on which the common electrode Ce is formed. In the illustrated LCD panel 2, an equivalent circuit of one pixel is shown. On the array substrate, for example, a plurality of gate bus lines 6 extending in the horizontal direction of the drawing are formed in parallel in the vertical direction. A plurality of data bus lines 8 extending in the vertical direction in the drawing are formed in parallel with the horizontal direction via an insulating film (not shown). Each of a plurality of regions in a matrix defined by the gate bus lines 6 and the data bus lines 8 formed in the vertical and horizontal directions is a pixel region. A pixel electrode 10 is formed in each pixel region.
[0027]
A TFT 4 is formed near an intersection between the gate bus line 6 and the data bus line 8 in each pixel region. The gate electrode G of the TFT 4 is connected to the gate bus line 6, and the drain electrode D is connected to the data bus line 8. . The source electrode S is connected to the pixel electrode 10. The gate bus line 6 is driven by a gate driver 12, and the data bus line 6 is driven by a data driver 14. When a gray scale voltage (gray scale data) is output from the data driver 14 to each data bus line 8 and a gate signal (gate pulse) is output to any one of the gate bus lines 6, the gate bus line 6 is connected to the gate bus line 6. A series of TFTs 4 to which the gate electrode G is connected are turned on. A gradation voltage is applied to the pixel electrode 10 connected to the source electrode S of the TFT 4, and the liquid crystal lc is driven between the pixel electrode 10 and the common electrode Ce formed on the counter substrate. In each pixel, a liquid crystal capacitor Clc is formed by the pixel electrode 10 and the common electrode Ce and the liquid crystal lc, and a storage capacitor Cs is also formed in parallel with the liquid crystal capacitor Clc.
[0028]
The TFT-LCD 1 includes a control circuit 16 to which a clock CLK and a data enable signal Enab output from a system such as a PC (personal computer) and grayscale data Data are input.
[0029]
The gate driver 12 includes, for example, a shift register. The gate driver 12 receives a latch pulse signal LP from a gate driver control unit 18 in the control circuit 16, outputs gate pulses sequentially from a display start line, and performs line sequential driving. ing.
[0030]
Further, the control circuit 16 has a display data conversion circuit 20. The display data conversion circuit 20 compares, for example, the gradation data Data to be displayed with the previous gradation data Data, and if the data value has changed beyond a predetermined threshold value, the gradation data to be displayed. It has a function of performing predetermined weighting processing or the like on the data Data and outputting the gradation data Data to the data driver 14.
[0031]
Further, the control circuit 16 has a light source control unit 22 that controls a lighting device 24 that illuminates the image display area of the LCD panel 2. The illumination device 24 of the present embodiment uses, for example, a direct-type backlight unit. The direct-type backlight unit of this example has a plurality of (four in this example) divided light-emitting areas 25 to 28, and is arranged so that the LCD panel 2 can be illuminated from the back of the display area. Assuming that the number of gate bus lines in one frame is L, the first light-emitting region 25 has the illumination range from the first gate bus line 6 which is the display start line to the L / 4th gate bus line 6. I have. Similarly, the second light-emitting region 26 has an illumination range from the (L / 4 + 1) th gate bus line 6 to the second L / 4-th gate bus line 6, and the third light-emitting region 27 has a second L / 4 + 1 The illumination range extends from the third gate bus line 6 to the third L / 4th gate bus line 6, and the fourth light emitting region 28 includes the third L / 4 + 1 th gate bus line 6 to the L th gate bus line 6. Up to the illumination range.
[0032]
Each of the light-emitting regions 25 to 28 has a structure in which a light emission opening is formed on the rear surface side of the LCD panel 2 substantially parallel to the extending direction of the gate bus line 6, and the other portions are surrounded by a reflector or the like. In the regions surrounded by the reflectors of the light emitting regions 25 to 28, for example, bar-shaped cold cathode tubes 30 to 33, each of which can change the light emission luminance by controlling the supplied current, respectively, extend in the tube axis direction. The gate bus lines 6 are arranged substantially parallel to the extending direction. A predetermined drive current is supplied to each of the cold cathode tubes 30 to 33 from the light source power supply circuits 35 to 38, respectively. The light source power supply circuits 35 to 38 can provide at least three stages of light emission states to the respective cold cathode tubes 30 to 33 based on a current control signal from the light source control unit 22 of the control circuit 16. . Here, the light emission state of the first stage is the light-off state S1, the light emission state of the second stage is the maximum lighting state S2 at which the maximum lighting luminance is obtained, and the third light emission state is almost the same as the light emission state of the second stage. This is the intermediate lighting state S3 where half the luminance is obtained. Note that the maximum lighting luminance does not necessarily mean the maximum luminance that can be emitted as a specification of the cold cathode tubes 30 to 33, but also includes the maximum luminance within the luminance range adjusted by the light source power supply circuits 35 to 38. A light source control system includes at least the light source control unit 22 and the light source power supply circuits 35 to 38.
[0033]
The light source control unit 22 of the control circuit 16 outputs a light emission control signal to each of the light source power supply circuits 35 to 38 in synchronization with the latch pulse signal LP output from the gate driver control unit 18 to the gate driver 12. Has become. Each of the light source power supply circuits 35 to 38 switches the light emission state of the cold cathode fluorescent lamps 30 to 33 to any one of the first to third light emission states S1 to S3 based on the input light emission control signal, and switches the LCD panel 2. Illuminate from the back of the display area.
[0034]
FIG. 2 shows the output timing of the gate pulse GP output from the gate driver 12 to each gate bus line 6 in synchronization with the input of the latch pulse signal LP, and the light emission luminances B (25) to B (25) of the light emitting regions 25 to 28. 28). The horizontal direction represents time. Here, it is assumed that there are L gate bus lines 6 in the display area as described above, and line numbers GL (1), GL (2),..., GL (L-1), GL (L) is attached.
[0035]
The light source control unit 22 supplies the light source power supply circuit 35 to the cold cathode tube 30 in synchronization with the latch pulse LP for outputting the gate pulse GP (1) to the gate bus line GL (1) as the display start line. An emission control signal for controlling the current is output. As a result, the current flowing from the light source power supply circuit 35 to the cold-cathode tube 30 is controlled, and the light emission luminance B (25) of the light emission region 25 becomes the intermediate lighting state S3, which is almost half the maximum lighting luminance. Thereafter, until the latch pulse LP for outputting the gate pulse GP (3L / 4 + 1) is output to the gate bus line GL (3L / 4 + 1), the light emission luminance B (25) of the light emitting region 25 is maintained in the intermediate lighting state S3. You.
[0036]
When the latch pulse LP for outputting the gate pulse GP (3L / 4 + 1) is output to the gate bus line GL (3L / 4 + 1), the light source control unit 22 transmits a predetermined light emission control signal to the light source power supply circuit 35 in synchronization with the latch pulse LP. Output. As a result, the current flowing from the light source power supply circuit 35 to the cold-cathode tube 30 is controlled, and the light emission luminance B (25) of the light emitting region 25 becomes the maximum lighting state S2 where the maximum lighting luminance is obtained. After that, one frame period f is completed, the next frame period f is started, and the light emission of the light emitting region 25 is performed until the latch pulse LP for outputting the gate pulse GP (1) is output to the gate bus line GL (1). The brightness B (25) is maintained in the maximum lighting state S2. The above operation is repeated every time the next frame period f starts.
[0037]
As a result of this lighting operation, the light emission luminance B (25) of the light emitting region 25 becomes the maximum lighting state S2 only for the 1/4 frame period before the end of the 1 frame period f, and is 1/4 frame from the beginning of one frame (display region). At maximum brightness. From the start of the other one frame period f to the point of 3/4 frame, the light emission luminance B (25) of the light emitting area 25 is maintained in the intermediate lighting state S3 and the 1/4 frame from the beginning of one frame is set to the intermediate luminance. To illuminate.
[0038]
Next, focusing on the light emitting area 26, the light source control unit 22 outputs the gate pulse GP (L / 4 + 1) to the gate bus line GL (L / 4 + 1) moved by １ ／ frame from the display start line. In synchronization with the latch pulse LP, a light emission control signal for controlling a current flowing through the cold cathode tube 31 is output to the light source power supply circuit 36. As a result, the current flowing from the light source power supply circuit 36 to the cold-cathode tube 31 is controlled, and the light emission luminance B (26) of the light emitting area 26 becomes the intermediate lighting state S3, which is almost half the maximum lighting luminance. Thereafter, the light emission luminance B (26) of the light emitting region 26 is maintained in the intermediate lighting state S3 until the latch pulse LP for outputting the gate pulse GP (1) is output to the gate bus line GL (1).
[0039]
When the latch pulse LP for outputting the gate pulse GP (1) is output to the gate bus line GL (1), the light source control unit 22 outputs a predetermined light emission control signal to the light source power supply circuit 36 in synchronization with the output. As a result, the current flowing from the light source power supply circuit 36 to the cold-cathode tube 31 is controlled, and the light emission luminance B (26) of the light emitting area 26 becomes the maximum lighting state S2 where the maximum lighting luminance is obtained. Thereafter, until the latch pulse LP for outputting the gate pulse GP (L / 4 + 1) is output to the gate bus line GL (L / 4 + 1), the light emission luminance B (26) of the light emitting region 26 is maintained in the maximum lighting state S2. You. The above operation is repeated in the cycle of the frame period f.
[0040]
By this lighting operation, the light emission luminance B (26) of the light emitting area 26 becomes the maximum lighting state S2 only during the first １ ／ frame period of one frame period f, and only during the period from the head １ ／ to １ ／ of one frame. Is illuminated at the maximum luminance for the 1/4 frame of the region up to. In other periods, the light emission luminance B (26) of the light emission area 26 maintains the intermediate lighting state S3 and illuminates 1/4 frame of the area from the head 1/4 to 1/2 of one frame with the intermediate luminance. I do.
[0041]
Next, focusing on the light emitting area 27, the light source control unit 22 outputs the gate pulse GP (2L / 4 + 1) to the gate bus line GL (2L / 4 + 1) moved by １ ／ frame from the display start line. In synchronization with the latch pulse LP, a light emission control signal for controlling a current flowing through the cold cathode tube 32 is output to the light source power supply circuit 37. As a result, the current flowing from the light source power supply circuit 37 to the cold-cathode tube 32 is controlled, and the light emission luminance B (27) of the light emitting area 27 becomes the intermediate lighting state S3 which is almost half of the maximum lighting luminance. Thereafter, until the latch pulse LP for outputting the gate pulse GP (L / 4 + 1) is output to the gate bus line GL (L / 4 + 1), the light emission luminance B (27) of the light emitting area 27 is maintained in the intermediate lighting state S3. You.
[0042]
When the latch pulse LP for outputting the gate pulse GP (L / 4 + 1) is output to the gate bus line GL (L / 4 + 1), the light source control unit 22 sends a predetermined light emission control signal to the light source power supply circuit 37 in synchronization with the latch pulse LP. Output. As a result, the current flowing from the light source power supply circuit 37 to the cold-cathode tube 32 is controlled, and the light emission luminance B (27) of the light emitting area 27 becomes the maximum lighting state S2 where the maximum lighting luminance is obtained. Thereafter, until the latch pulse LP for outputting the gate pulse GP (2L / 4 + 1) is output to the gate bus line GL (2L / 4 + 1), the light emission luminance B (27) of the light emitting region 27 is maintained in the maximum lighting state S2. You. The above operation is repeated in the cycle of the frame period f.
[0043]
As a result of this lighting operation, the light emission luminance B (27) of the light emitting region 27 becomes the maximum lighting state S2 only during the ４ frame period from the beginning of the one frame period f to １ ／ to 、. The フ レ ー ム frame of the region from か ら to ／ of the frame is illuminated with the maximum luminance. In the other periods, the light emission luminance B (27) of the light emission area 27 maintains the intermediate lighting state S3 and illuminates 1/4 frame of the area from the first half to 3/4 of one frame with the intermediate luminance. I do.
[0044]
Similarly, in the light emitting area 28, the light source control unit 22 outputs a latch pulse for outputting a gate pulse GP (3L / 4 + 1) to the gate bus line GL (3L / 4 + 1) shifted by 3/4 frame from the display start line. In synchronization with the LP, a light emission control signal for controlling a current flowing through the cold cathode tube 33 is output to the light source power supply circuit 38. As a result, the current flowing from the light source power supply circuit 38 to the cold-cathode tube 33 is controlled, and the light emission luminance B (28) of the light emitting region 28 becomes the intermediate lighting state S3 which is almost half of the maximum lighting luminance. Thereafter, until the latch pulse LP for outputting the gate pulse GP (2L / 4 + 1) is output to the gate bus line GL (2L / 4 + 1), the light emission luminance B (28) of the light emitting region 28 is maintained in the intermediate lighting state S3. You.
[0045]
When the latch pulse LP for outputting the gate pulse GP (2L / 4 + 1) is output to the gate bus line GL (2L / 4 + 1), the light source controller 22 sends a predetermined light emission control signal to the light source power supply circuit 38 in synchronization with the latch pulse LP. Output. As a result, the current flowing from the light source power supply circuit 38 to the cold-cathode tube 33 is controlled, and the light emission luminance B (28) of the light emitting area 28 becomes the maximum lighting state S2 where the maximum lighting luminance is obtained. Thereafter, until the latch pulse LP for outputting the gate pulse GP (3L / 4 + 1) is output to the gate bus line GL (3L / 4 + 1), the light emission luminance B (28) of the light emitting region 28 is maintained in the maximum lighting state S2. You. The above operation is repeated in the cycle of the frame period f.
[0046]
Due to this lighting operation, the light emission luminance B (28) of the light emitting region 28 becomes the maximum lighting state S2 only during a フ レ ー ム frame period from ２ to ／ of the one frame period f, and only during this period, one frame is The lowermost quarter area is illuminated with maximum brightness. In other periods, the light emission luminance B (28) of the light emitting area 28 maintains the intermediate lighting state S3 and illuminates the lowermost 1/4 frame of one frame with the intermediate luminance.
[0047]
By the lighting operation described above, as shown in FIG. 2, the entire display area is illuminated with the intermediate luminance, and the light emission luminance of the area obtained by dividing the display area into four bands in a band parallel to the gate bus line 6 is obtained. The illumination which becomes maximum sequentially in time series is obtained.
[0048]
According to the present embodiment, the luminance is 5/8 times (= 1 / 4A + 3/4 × 1 / 2A A: the maximum luminance) the luminance of the conventional hold-type lighting device that is always driven at the maximum luminance. Thus, it is possible to sufficiently suppress a decrease in luminance and realize a display corresponding to a moving image. In addition, since the conventional scan-type lighting apparatus that supports moving images has a luminance that is 1/4 times that of the conventional hold-type lighting apparatus, the lighting apparatus according to the present embodiment has the same advantages as the conventional scanning-type lighting apparatus. It is possible to realize a display with a high brightness of .5 times.
[0049]
In the present embodiment, an operation example in which illumination is performed at the maximum lighting luminance for one frame period f (for example, 16.7 ms) by 1/4 cycle has been described, but the illumination period at the maximum lighting luminance may be lengthened. It is possible to achieve higher luminance. Further, in the present embodiment, the intermediate brightness in the intermediate lighting state S3 is set to be approximately の of the maximum lighting brightness, but it is of course possible to set other intermediate brightness levels.
[0050]
FIG. 3 shows a subjective evaluation by a plurality of observers of the display quality when a moving image is displayed in the display area of the TFT-LCD 1 shown in FIG. 1 by changing the illumination period and the intermediate luminance level at the maximum lighting luminance. It is graphed as
[0051]
In FIG. 3, the horizontal axis represents the ratio (%) of the maximum lighting state S2 to one frame period f, and the vertical axis represents evaluation based on 1 to 5 evaluation points. Evaluation point 1 indicates a case where moving image blur or tailing in moving image display is “very disturbing”, and evaluation point 2 indicates a case where they are “disturbing”. The evaluation point 3 is a case where the blurring of the moving image is “worried but can be tolerated”, the evaluation point 4 is a case where the difference is understood but can be tolerated, and the evaluation point 5 is “an excellent image quality equivalent to a still image”. This is the case.
[0052]
In the drawing, a straight line (A) connecting circles indicates a case where the luminance level in the intermediate lighting state S3 is the same as the luminance level in the maximum lighting state S2. Therefore, regardless of the ratio of the maximum lighting state S2 to one frame period f (hereinafter, simply referred to as “the ratio of the maximum lighting state S2”), the light is illuminated at the maximum luminance level in the entire area of one frame period f. In other words, the display is equivalent to that of the hold-type driving, and therefore the image quality is such that moving image blurring and tailing are very disturbing, and the evaluation score is 1.
[0053]
In the figure, a polygonal line (B) connecting the X marks indicates a case where the luminance level in the intermediate lighting state S3 is almost half of the luminance level in the maximum lighting state S2. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, a moving image blur and a trail are hardly visually recognized, and an excellent image quality is obtained. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but the evaluation point 3 is obtained up to about 50%.
[0054]
In the figure, a polygonal line (C) connecting triangles indicates a case where the luminance level in the intermediate lighting state S3 is 30% of the luminance level in the maximum lighting state S2. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, an excellent image quality in which moving image blur and tailing are hard to be visually recognized is obtained, and thus the evaluation point is close to 5. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but the evaluation point 3 is obtained up to about 50%.
[0055]
In the drawing, a polygonal line (D) connecting square marks indicates a case where the luminance level in the intermediate lighting state S3 is 0 (zero) and the light emitting state is S1 except for the maximum lighting state S2. This is the same as the illumination method of the conventional scan type LCD. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, an excellent image quality in which moving image blur and tailing are hard to be visually recognized is obtained, so that the evaluation point is further closer to 5. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but an evaluation point of 3 or more is obtained up to about 50%.
[0056]
From FIG. 3, it can be seen that even when the intermediate lighting state S3 is set to about 30% of the luminance level of the maximum lighting state S2, display quality comparable to that of the conventional scanning LCD shown by the broken line (D) can be obtained. Furthermore, if the intermediate lighting state S3 is up to about 50% of the luminance level of the maximum lighting state S2, it can be regarded as an allowable range.
[0057]
Also, if the illumination time in the maximum lighting state S2 is 30% or less of the one frame period f, moving image blur and tailing hardly occur, and up to 50% can be regarded as an allowable range.
[0058]
In the present embodiment, the pixel is illuminated with the maximum luminance when f / 2 to 3f / 4 has elapsed after the writing of the gradation data Data to the pixel electrode 10. This takes into account the response time of the liquid crystal molecules in the liquid crystal lc to the change in the electric field strength. If a liquid crystal material capable of high-speed response is used, for example, the time f / 4 to f / 2 after the writing of the gradation data Data is obtained. It is also possible to illuminate the pixel with the maximum luminance at the point in time.
[0059]
As described above, the lighting device 24 according to the present embodiment is characterized in that it switches between the maximum lighting state S2 and the intermediate lighting state S3 in synchronization with the output control signal (latch pulse LP) of the gate pulse GP. are doing.
[0060]
In the lighting device 24 according to the present embodiment, the gate pulse GP is output to the gate bus line 6, the TFT 4 connected to the gate bus line 6 is turned on, and the gradation data Data is supplied to the pixel electrode 10. Thus, the liquid crystal molecules of the liquid crystal lc are maintained in the intermediate lighting state S3 while the liquid crystal molecules are performing the tilting operation to the desired tilt angle, and are set to the maximum lighting state S2 when the tilt response of the liquid crystal molecules is almost completed. Is controlled as follows. By doing so, the image quality deterioration such as motion blur can be improved as the maximum lighting state S2 becomes shorter, but the display screen becomes lower in brightness because other than the state S2 is kept in the light-off state S1. The problem of the scan type LCD can be solved. In the lighting device 24, even if the maximum lighting state S2 is short, illumination is continued at a predetermined intermediate luminance level by the intermediate lighting state S3, so that a decrease in luminance can be reduced.
[0061]
The reason why image quality deterioration such as motion blur is suppressed by using the present lighting device 24 is that the lighting method skillfully utilizes an ergonomic feature that human eyes perceive changes with emphasis. That is, the image at the moment when the state changes from the intermediate lighting state S3 to the maximum lighting state S2 is sensed by human eyes, and is printed on the retina. This video recognition operation is performed for each frame to prevent the motion blur and the tailing from being visually recognized. On the other hand, since a person perceives the integral value of the light incident on the retina as luminance, the average of the amount of light in the intermediate lighting state S3 and the amount of light in the maximum lighting state S2 is the luminance of the display area of the TFT-LCD1.
[0062]
By applying this embodiment mode, a liquid crystal display device with high luminance and no motion blur can be realized as a simple and thin structure, which can contribute to improvement in display quality and reduction in cost or size of the device. .
[0063]
In the above embodiment, the scanning illumination device in which one frame is divided into four parts has been described. However, the configuration and method of the above embodiment can be applied to any case in which one frame is divided into N parts (N is an integer of 1 or more). It is. For example, when N = 1, the whole is illuminated in the intermediate lighting state S3 during the writing of the gradation data Data to all the pixels of the display area of the LCD panel 2, and a predetermined liquid crystal response time after writing the pixels of the last line. After the elapse, the whole is illuminated in the maximum lighting state S2. The maximum lighting state S2 is realized, for example, during a vertical blanking period. This makes it possible to realize a TFT-LCD using one cold-cathode tube (light source) and suppressing blurring of moving images and tailing while suppressing a decrease in luminance.
[0064]
In the above embodiment, the direct type backlight unit has been described as an example. However, the present invention is not limited to this, and the configuration and method of the present embodiment can be applied to a sidelight type backlight unit in which a light source is disposed at an end of a light guide plate. Of course, it may be applied.
[0065]
Note that the illumination driving method in the illumination device 24 used in the present embodiment is, for example, a method for driving an EL (electroluminescence) display device (using an organic EL element or an inorganic EL element) which is a self-luminous type flat display device. Of course, it may be applied to the method.
[0066]
[Second embodiment]
A lighting device according to a second embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. First, a schematic configuration of a lighting device according to the present embodiment and a liquid crystal display device using the same will be described with reference to FIGS. FIG. 4 shows a schematic configuration of a lighting device according to the present embodiment and a liquid crystal display device using the same. The TFT-LCD 1 shown in FIG. 4 is the same as the TFT-LCD 1 according to the first embodiment described with reference to FIG. 1, and the components having the same functions are denoted by the same reference numerals as those in FIG. The description is omitted. FIG. 5A is a cross-sectional view taken along the line AA in FIG. 4. The lighting device (sidelight type backlight unit) 40 used in the TFT-LCD 1 for displaying a moving image according to the present embodiment is a cold cathode. 2 shows a cross section taken along a plane perpendicular to the pipe axis direction of the pipe. FIG. 5B shows the luminance distribution of the illumination light from the illumination device 40 on the back surface side of the display area of the TFT-LCD 1.
[0067]
The illumination device 40 of the present embodiment is a sidelight type backlight unit in which a cold cathode tube is arranged along an end of a light guide plate having a structure for emitting internally guided light to the outside. The sidelight type backlight unit of the present embodiment has a plurality of (four in this example) divided light emitting areas 41 to 43, and is arranged so that the LCD panel 2 can be illuminated from the back of the display area.
[0068]
Assuming that the number of gate bus lines in one frame is L, the first light emitting region 41 uses the display range from the first gate bus line 6 which is the display start line to the L / 4th gate bus line 6 as an illumination range. I have. Similarly, the second light-emitting region 42 has an illumination range from the (L / 4 + 1) th gate bus line 6 to the second L / 4-th gate bus line 6, and the third light-emitting region 43 has a second L / 4 + 1 The illumination range extends from the third gate bus line 6 to the third L / 4th gate bus line 6, and the fourth light emitting region 44 includes the third L / 4 + 1 th gate bus line 6 to the L th gate bus line 6. Up to the illumination range.
[0069]
As shown in FIG. 5A, two light guide plates 51 and 52 are arranged in substantially the same plane on the side facing the back surface of the TFT-LCD 1. The light guide plate 51 is arranged in the first and second light emitting regions 41 and 42, and the light guide plate 52 is arranged in the third and fourth light emitting regions 43 and 44. A cold cathode tube 46 is disposed at an end of the light guide plate 51 facing the end facing the light guide plate 52, and a cold cathode tube 47 is provided at an end of the light guide plate 52 facing the end facing the light guide plate 51. Is arranged.
[0070]
Further, a light guide plate 50 is arranged adjacent to the first light emitting region 41 on the surface of the light guide plate 51 opposite to the TFT-LCD 1 side. A cold cathode tube 45 is disposed at one end of the light guide plate 50. A light guide plate 53 is arranged adjacent to the fourth light emitting region 44 on the surface of the light guide plate 52 opposite to the TFT-LCD 1 side. A cold cathode tube 48 is disposed at one end of the light guide plate 53. The cold cathode tubes 45 to 48 are formed, for example, in a straight bar shape. Further, the cold cathode tubes 45 to 48 can change the light emission luminance by controlling the supplied current.
[0071]
A predetermined drive current is supplied to each of the cold cathode tubes 45 to 48 from the light source power supply circuits 35 to 38, respectively. The light source power supply circuits 35 to 38 are capable of giving at least three stages of light emission states to the respective cold cathode tubes 45 to 48 based on a current control signal from the light source control unit 22 of the control circuit 16. . Here, the light emission state of the first stage is the light-off state S1, the light emission state of the second stage is the maximum lighting state S2 at which the maximum lighting luminance is obtained, and the third light emission state is almost the same as the light emission state of the second stage. This is the intermediate lighting state S3 where half the luminance is obtained. Here, the maximum lighting brightness does not necessarily mean the highest brightness that can be emitted as a specification of the cold cathode tubes 45 to 48, but also includes the highest brightness within the brightness range adjusted by the light source power supply circuits 35 to 38. .
[0072]
The illumination device 40 according to the present embodiment described above includes a light guide plate (light guide member) 50 and a cold cathode tube 45 disposed at an end of the light source unit (50, 45) that emits light from one surface. And a light source unit (51, 46) including a light guide plate 51 and a cold cathode tube 46 disposed at an end thereof. The illumination device 40 includes a light source unit (53, 48) including a light guide plate 53 and a cold-cathode tube 48 disposed at an end thereof and emitting light from one side, and a light guide plate 52 and an end disposed at the end. And a light source unit (52, 47) having a cold cathode tube 47. Further, the lighting device 40 has a structure in which the light source units (51, 46) and the light source units (52, 47) are arranged on the same plane. Further, the light source units (50, 45) and the light source units (53, 48) are arranged on the same plane.
[0073]
Each of the light emitting regions 41 to 44 has a structure in which a light emitting opening is formed on the back side of the LCD panel 2, and the other portions are surrounded by a diffuse reflection plate 55. A diffusion sheet 60 and the like are arranged between the back surface of the TFT-LCD 1 and the light emission opening of the lighting device 40. The back surface of the light guide plate 50 of the first light emitting region 41, the back surface of the light guide plate 51 of the second light emitting region 42, the back surface of the light guide plate 52 of the third light emitting region 43, and the back surface of the light guide plate 53 of the fourth light emitting region 44. For example, light scattering patterns are printed as light extraction structures 56 to 59 respectively. No light extraction structure is formed on the back surface of the light guide plate 51 in the first light emitting region 41 and on the back surface of the light guide plate 52 in the fourth light emitting region 44.
[0074]
Due to the arrangement of the light extraction structures 56 and 57, most of the light from the cold cathode tubes 45 is scattered by the light extraction structure 56 to guide the light inside the light guide plate 50, and furthermore, the first light emitting region 41 of the light guide plate 51. The light is emitted from the first light emitting region 41 through the portion. At this time, part of the light is guided through the light guide plate 51, scattered by the light extraction structure 57, and emitted from the second light emitting region 42. Further, part of the light is guided from the light guide plate 51 to the light guide plate 52 and the light guide plate 53, scattered by the light extraction structures 58 and 59, and emitted from the third and fourth light emitting regions 43 and 44. That is, most of the light from the cold-cathode tube 45 is used to illuminate the first light-emitting region 41, and the rest is used to illuminate the second to fourth light-emitting regions 42 to 44.
[0075]
Similarly, most of the light from the cold cathode tube 46 is guided through the light guide plate 51 and emitted from the second light emitting region 42 while being scattered by the light extraction structure 57. At this time, part of the light is guided to the light guide plates 50, 52, and 53 and scattered by the light extraction structures 56, 58, and 59, and the first light emitting region 41, the third and fourth light emitting regions 43, Inject from 44. That is, most of the light from the cold-cathode tube 46 is used for illuminating the second light-emitting region 42, and the rest is used for illuminating the first light-emitting region 41, the third and fourth light-emitting regions 43 and 44. .
[0076]
On the other hand, due to the arrangement of the light extraction structures 58 and 59, most of the light from the cold cathode tubes 48 is scattered by the light extraction structure 59 to guide the light inside the light guide plate 53, and furthermore, the fourth light emitting area of the light guide plate 52. The light passes through the portion 44 and is emitted from the fourth light emitting region 44. At this time, a part of the light is guided through the light guide plate 52, scattered by the light extraction structure 58, and emitted from the third light emitting region 43. Further, a part of the light is guided from the light guide plate 52 to the light guide plate 51 and the light guide plate 50, scattered by the light extraction structures 57 and 56, and emitted from the second and first light emitting regions 42 and 41. That is, most of the light from the cold-cathode tube 48 is used to illuminate the fourth light-emitting region 44, and the rest is used to illuminate the first to third light-emitting regions 41 to 43.
[0077]
Similarly, most of the light from the cold cathode tube 47 is emitted from the third light emitting region 43 while being guided through the light guide plate 52 and scattered by the light extraction structure 58. At this time, part of the light is guided to the light guide plates 50, 51, and 53 and scattered by the light extraction structures 56, 57, and 59, and the first light emitting region 41, the second light emitting region 43, and the fourth light The light is emitted from the light emitting region 44. That is, most of the light from the cold cathode tube 47 is used to illuminate the third light-emitting region 43, and the rest is used to illuminate the first and second light-emitting regions 41 and 42 and the fourth light-emitting region 44. Can be
[0078]
The light source control unit 22 of the control circuit 16 shown in FIG. 4 sends a light emission control signal to each of the light source power supply circuits 35 to 38 in synchronization with the latch pulse signal LP output from the gate driver control unit 18 to the gate driver 12. Output. Each of the light source power supply circuits 35 to 38 switches the light emission state of the cold cathode tubes 41 to 44 to any one of the first to third light emission states S1 to S3 based on the input light emission control signal, and switches the LCD panel 2. Illuminate from the back of the display area.
[0079]
In such a configuration, illumination driving similar to that shown in FIG. 2 of the first embodiment is performed. In the present embodiment, the light emission luminances B (25) to B (28) in FIG. 2 are to be read as light emission luminances B (41) to B (44).
[0080]
The light source control unit 22 causes the light source power supply circuit 35 to flow to the cold cathode tube 45 in synchronization with the latch pulse LP for outputting the gate pulse GP (1) to the gate bus line GL (1), which is a display start line. An emission control signal for controlling the current is output. As a result, the current flowing from the light source power supply circuit 35 to the cold cathode tube 45 is controlled, and the light emission luminance B (41) of the light emission area 41 becomes the intermediate lighting state S3, which is almost half the maximum lighting luminance. Thereafter, until the latch pulse LP for outputting the gate pulse GP (3L / 4 + 1) is output to the gate bus line GL (3L / 4 + 1), the light emission luminance B (41) of the light emitting region 41 is maintained in the intermediate lighting state S3. You.
[0081]
When the latch pulse LP for outputting the gate pulse GP (3L / 4 + 1) is output to the gate bus line GL (3L / 4 + 1), the light source control unit 22 transmits a predetermined light emission control signal to the light source power supply circuit 35 in synchronization with the latch pulse LP. Output. As a result, the current flowing from the light source power supply circuit 35 to the cold cathode tube 45 is controlled, and the light emission luminance B (41) of the light emitting region 41 becomes the maximum lighting state S2 where the maximum lighting luminance is obtained. After that, one frame period f is completed, the next frame period f is started, and the light emission of the light emitting region 41 is performed until the latch pulse LP for outputting the gate pulse GP (1) is output to the gate bus line GL (1). The brightness B (41) is maintained in the maximum lighting state S2. The above operation is repeated every time the next frame period f starts.
[0082]
As a result of this lighting operation, the light emission luminance B (41) of the light emitting area 41 becomes the maximum lighting state S2 only for the 1/4 frame period before the end of the 1 frame period f, and corresponds to 1/4 frame from the beginning of one frame (display area). At maximum brightness. From the start of the other one frame period f to the point of 3/4 frame, the light emission luminance B (41) of the light emitting area 41 is maintained in the intermediate lighting state S3 and the 1/4 frame from the beginning of one frame is set to the intermediate luminance. To illuminate.
[0083]
By performing the light emitting operation in the light emitting areas 42, 43, and 44 in the same manner as described in the first embodiment, as shown in FIG. 2, the entire display area is illuminated with the intermediate brightness, and Illumination in which the display area is divided into four sections in a vertical line in a band shape parallel to the gate bus line 6 and the emission luminance sequentially becomes maximum in time series is obtained. In the present description, an example in which the maximum lighting state S2 and the intermediate lighting state S3 are switched has been described. However, similar effects can be obtained by switching between the maximum lighting state S2 and the off state S1.
[0084]
Further, in the present embodiment, a structure in which two light guide plates are stacked and two sets of the light guide plates are arranged in a plane is described, but the same effect can be obtained even if the number of stacked light guide plates is increased. In addition, in the configuration shown in FIG. 5, if the light source power supply circuits 35 to 38 and the like and the cold cathode tubes 45 and 48 are arranged in the concave portions of the backlight (the back surfaces of the light emitting regions 42 and 43), the device can be used. Thinning and miniaturization can be realized.
[0085]
As described above, although the lighting device 40 according to the present embodiment is of the sidelight type, the light source unit mainly illuminating one light emitting region supplies a part of the light to the other adjacent light emitting region, and Since the light source unit that mainly illuminates the other light emitting region can supply a part of the light to the adjacent one light emitting region and complement each other, as shown in FIG. The luminance distribution α can be realized. In addition, by arranging a light source on the end face for each light guide member and individually controlling turning on / off, or turning on / off the light source, a thin liquid crystal display lighting device suitable for displaying moving images is realized. it can.
[0086]
Next, a modified example of the illumination device 40 according to the present embodiment and the TFT-LCD 1 using the same will be described with reference to FIG. The configuration shown in FIG. 6 is the same as the configuration shown in FIG. 5 except that the configuration of the lighting device 40 is partially different. The illumination device 40 shown in FIG. 6 is characterized in that a light mixing region 62 is provided between the light guide plates 51 and 52 of the stacked light source units and the diffusion sheet 60.
[0087]
The light mixing region 62 is formed of a transparent plate made of acrylic, polycarbonate, or the like, a diffusion plate in which fine materials having different refractive indexes such as fibers are mixed with the transparent plate, or an air layer. If the air layer is in the space of 0.5 mm to 10 mm, the brightness distribution α (same as the brightness distribution α in FIG. 5B) when there is no air layer indicated by the broken line in FIG. Luminance variation at the boundary of the light emitting region is reduced, and a luminance distribution β indicated by a solid line with no visible luminance change is obtained.
[0088]
According to the present embodiment, minute luminance changes at the boundaries of the light emitting regions are mixed with each other, and the horizontal streak-like luminance unevenness visually recognized at the boundaries can be reduced or eliminated.
[0089]
In the lighting device 40 shown in FIGS. 5 and 6, all the light extraction structures 56 to 59 of the light guide plates 50 to 53 are arranged below the light guide plates 50 to 53, but the first and fourth light emitting regions 41, By arranging the 44 light extraction structures 56 and 59 on the upper surfaces of the light guide plates 50 and 53, respectively, the light extraction structures 56 to 59 can be arranged in one plane to achieve further uniform brightness.
[0090]
Next, another modified example of the illumination device of the present embodiment will be described with reference to FIG. The configuration shown in FIG. 7 is the same as the configuration shown in FIG. 5 except that the configuration of the lighting device 40 is partially different. The illumination device 40 shown in FIG. 7A is such that a double-sided reflection member 64 for regular reflection or diffuse reflection as shown in FIG. 7B or 7C is arranged in a gap between the light guide plates 51 and 52. It has features. At the boundary between the second and third light-emitting regions 42 and 43 of the illumination device 40 shown in FIGS. 5 and 6, some light is reflected toward the light source by surface reflection at the end surface of the light guide plate, and light is guided again. The rest exits from the end face and enters the other illumination area. For this reason, there is a possibility that light emission is mixed and the moving image performance is reduced. Therefore, a double-sided reflection plate 64 is arranged in a gap between the light guide plates 51 and 52. As a result, mixing of light emission can be prevented, and moving image performance can be improved.
[0091]
FIG. 7B shows the light guide plates 51 and 52 in which the facing end surfaces face substantially perpendicularly and parallel to the light exit surfaces of the light guide plates 51 and 52, and the gap is formed of a double-sided regular reflection plate or a double-sided regular reflection sheet. The configuration in which the double-sided reflecting member 64 is arranged is shown.
[0092]
FIG. 7C illustrates a configuration in which a Λ-shaped gap that opens to the back side is provided at the opposite end faces of the light guide plates 51 and 52, and a double-sided regular reflection plate or a double-sided reflection member 64 made of a double-sided regular reflection sheet is disposed in the gap. Is shown. Since the double-sided reflecting member 64 shown in FIG. 7B has a finite thickness, when viewed from the light exit side (TFT-LCD1 side) of the light guide plates 51 and 52, the gap is visually recognized as a shadow, resulting in uneven brightness. On the other hand, by adopting the configuration shown in FIG. 7C, the double-sided reflecting member 64 becomes invisible from the upper surface, which is effective in reducing uneven brightness. Even if the light guide plates are configured to be in contact with each other near the apex of the Λ shape, a sufficiently excellent effect on moving image performance can be obtained.
[0093]
The apex angle θ of the Λ-shaped double-sided reflection member 64 is θ ≦ 180 ° −4 × sin, where n is the refractive index of the light guide. ^-1 (1 / n) (Expression 1) is preferably satisfied. When the apex angle of the Λ shape is larger than θ in the above equation, the light is guided inside the light guide plate, and a part of the light reflected on the end surface is emitted to the upper surface from the light guide plate. For this reason, bright uneven lines may be generated on the liquid crystal panel surface. Therefore, by adopting the apex angle θ that satisfies the above equation 1, all of the end face reflected light is guided, so that this uneven brightness can be prevented.
[0094]
Equation 1 will be described with reference to FIG. FIG. 8A is an enlarged view of FIG. 7C, and FIG. 8B shows a light path at an end face on the light guide plate 52 side. In FIG. 8B, the light emitted from the light guide plate 52 is composed of the light scattered by the print scattering pattern of the light extraction structure 58 on the lower surface of the light guide plate 52, whereas the light incident from the end face A is guided. When the light is emitted from the light plate 52 to the light-emitting area, only the area where the light beam from the end face A reaches reaches high brightness, resulting in uneven brightness.
[0095]
The apex angle θ is determined under the condition that the incident light from the end surface A does not exit from the exit surface of the light guide plate 52. Here, the incident angle of the light beam incident on the end surface A is a, the refraction angle of the light beam incident on the light guide plate 52 from the end surface A is b, and the light incident on the light guide plate 52 from the end surface A is incident on the light emitting region opening surface of the light guide plate 52. The angle is c, and the refractive index of the light guide plate 52 is n. The incident light from the end surface A of the Λ-shaped portion of the light guide plate 52 is refracted by Snell's law.
[0096]
(1) sin (a) = n × sin (b)
(2) n × sin (c) = sin (d)
The refraction angle b and the incident angle c are represented by the following equations.
(3) 90 ° = b + c + θ / 2
Here, if d ≧ 90 °, light incident on the light guide plate 52 from the end face A does not exit from the light guide plate 52.
(4) In addition, since there is a possibility that light is incident from any direction, a is ± 90 °.
(1) is b = sin ^-1 (1 / n)
(2) is c = sin ^-1 (1 / n).
When these are introduced in (3)
θ = 180 ° -4 × sin ^-1 (1 / n)
From the condition of (4),
θ ≦ 180 ° -4 × sin ^-1 (1 / n)
For example, in the case of PMMA, which is a normal light guide plate material, n = 1.48, and thus θ = 9.97 °.
[0097]
Next, still another modification of the illumination device of the present embodiment will be described with reference to FIG. The configuration shown in FIG. 9 is the same as the configuration shown in FIG. 5 except that the configuration of the lighting device 40 is partially different. FIG. 9A shows a schematic configuration of an illumination device according to the present modification and a liquid crystal display device using the same. The TFT-LCD 1 shown in FIG. 9A is the same as the TFT-LCD 1 according to the present embodiment described with reference to FIG. 4, and the components having the same functions are denoted by the same reference numerals as those in FIG. The description is omitted. FIG. 9B is a cross-sectional view taken along line AA of FIG. 9A, and is a lighting device (sidelight type backlight unit) 40 used in the TFT-LCD 1 for displaying moving images according to the present embodiment. Is a cross section taken along a plane perpendicular to the tube axis direction of the cold cathode tube. FIG. 9C shows the luminance distribution of the illumination light from the illumination device 40 on the back surface side of the display area of the TFT-LCD 1.
[0098]
The configuration shown in FIG. 9 is the same as the configuration shown in FIG. 4 except that the configuration of the illumination device 40 is partially different. The illumination device 40 shown in FIG. 9A is provided with brightness adjustment volumes 70 to 73 in the light source power supply circuits 35 to 38, respectively, so that the amount of light emitted from each of the light emitting regions 41 to 44 can be finely adjusted to be uniform. It is characterized by points.
[0099]
Originally, the emitted light amount differs for each cold cathode tube. For this reason, a problem may occur in which the luminance differs for each of the first to fourth light emitting regions 41 to 44. As a countermeasure against this problem, it is conceivable to evaluate the brightness of each cold-cathode tube and use a combination of cold-cathode tubes having the same brightness, but there is a problem that the manufacturing cost increases. On the other hand, according to the present configuration, it is possible to reduce the luminance variation at low cost and make the display surface luminance uniform.
[0100]
As described above, according to the present embodiment, it is possible to manufacture a small and thin liquid crystal display device suitable for displaying moving images that can obtain a uniform luminance distribution.
[0101]
[Third Embodiment]
A lighting device according to a third embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. 10 to 29 and FIG. 1 showing the first embodiment. The present embodiment has been made to solve the problem of the third related art, and it is necessary to increase the light emission luminance of the cold cathode tube even if the lighting period of the cold cathode tube of the lighting device is shortened. And a display device capable of obtaining a high-quality moving image without any problem.
[0102]
When the ratio of the lighting time (duty ratio) during one frame period of the backlight unit is changed and the gradation data is further processed to adjust the liquid crystal transmittance, a difference in image quality from the original image is felt. A subjective assessment was made of whether It has been found that, even with the same duty ratio, there is a case where a difference between the original image and the image quality is felt or not depending on the image data. FIG. 10 shows an example of this subjective evaluation result. FIG. 10A shows the result of the subjective evaluation at a duty ratio of 80%, and FIG. 10B shows the result of the subjective evaluation at a duty ratio of 60%. The horizontal axis in FIG. 10 represents the average value of all gradation data of 64 gradations of 0 to 63 displayed in one frame. The vertical axis represents the ratio (%) of the number of pixels saturated in luminance by processing image data to the total number of display pixels. Examining the number of high-luminance pixels whose luminance is saturated by adjusting the liquid crystal transmittance shows that the ratio differs depending on the content of the image. The ratio of the number of pixels whose luminance is saturated to the total number of display pixels is 80% for the duty ratio and 60% for the duty ratio. In any of the above, if the pixel ratio at which the luminance is saturated is 2% or less of the entire display, the image quality difference from the original image may not be felt irrespective of the average value (average luminance of the image) of all gradation data of the image. Do you get it. Although individual illustration is omitted, it was found that, as long as the number of pixels whose luminance is saturated is 2% or less, no difference in image quality between the original image and the original image is felt even if the duty ratio is reduced.
[0103]
From the above, a certain percentage of pixels in the image in order from the pixel with the highest luminance are set as the maximum display luminance, and the luminance of each of the remaining pixels excluding this is reduced by reducing the duty ratio of the light source of the backlight unit and increasing the liquid crystal transmittance. By reproducing by raising, even if the duty ratio is lowered, it is possible to make the moving image display quality equal to that of the original image.
[0104]
The liquid crystal display according to the present embodiment has a configuration similar to the configuration shown in FIGS. 1 and 4 shown in the first and second embodiments. 1 and 4 are denoted by the same reference numerals, and detailed description is omitted. The TFT-LCD 1 has an LCD panel 2 that modulates the light transmittance of each of red (R), green (G), and blue (B) sub-pixels two-dimensionally arranged in a matrix based on gradation data. ing. An illuminating device 24 (or an illuminating device 40, hereinafter, described as the illuminating device 24) that irradiates light is provided on the back surface of the display area of the LCD panel 2. The lighting device 24 includes light sources (cold-cathode tubes 30 to 33) and light source power supply circuits 35 to 38 for driving them.
[0105]
The control circuit 16 according to the present embodiment is provided with various circuits for driving the TFT-LCD 1 and a display data conversion circuit 20 for analyzing gradation data Data input from the outside. FIG. 11 shows a schematic operation procedure of the display data conversion circuit 20. As shown in FIG. 11, the display data conversion circuit 20 stores the gradation data Data of one frame of pixels (a combination of R, G, and B sub-pixels) input to the control circuit 16 (step S1). ), Brightness Y = r × R + g × G + b × B (r, g, b include real numbers and numerical values 0) are obtained from the respective gradation data (R, G, B) corresponding to each pixel (step S2). Then, a histogram of the brightness Y of the image is created (step S3). Next, the number of pixels M related to image display in one frame is calculated (step S4), and a fixed number t = M × p, which is a product of the number of pixels M and a predetermined luminance saturation ratio p, is calculated (step S5). The threshold brightness Yα is determined from the histogram of the brightness Y of the image and the fixed number t (step S6). Next, the processed gradation data is output to the plurality of data bus lines 8 based on the threshold brightness Yα (step S7), and the predetermined duty ratio data is output to the light source control unit 22 that controls the light source power supply circuits 35 to 38. (Step S8). The light source control unit 22 controls the light source power supply circuits 35 to 38 based on the duty ratio data to turn on the cold cathode tubes 30 to 33 at a predetermined duty ratio.
[0106]
For example, in the display data conversion circuit 20, the product of the maximum value of the light transmittance (the maximum value of the gradation data Data) and the illumination amount (duty ratio) of the illumination device 24 becomes equal to the threshold brightness Yα. The duty ratio is determined as described above, and the gradation data of the pixels having the lightness Y equal to or higher than the threshold lightness Yα is processed so that the light transmittance becomes the maximum value. Processing is performed so that the product of the determined duty ratio and the product is equal to the brightness Y of the original gradation data of the pixel.
[0107]
FIG. 12 is a flowchart showing a procedure for calculating the brightness Y and creating a histogram in the display data conversion circuit 20. The display data conversion circuit 20 sequentially reads one frame of the gradation data D (R, G, B) stored in a storage device (memory) (not shown) one by one (Steps S10 and S11), for example, Assuming that the constant (r, g, b) = (0.2126, 0.7152, 0.0722), the brightness Y = r × R + g × G + b × B with respect to the read gradation data (R, G, B). Calculation is performed (step S12). Next, 63 is set to the variable s (step S13), and the values of Y and s are compared (step S14). If Y ≠ s, the process proceeds to step S15, in which the s value is reduced by 1, the Y value and the s value are compared again in step S14, and steps S14 and S15 are repeated until Y = s. When Y = s, the process proceeds to step S16, where 1 is added to the frequency L (s) indicating the number of occurrences of lightness Y = s in one frame, and the process returns to step S10. For example, if the gradation data (R, G, B) = (58, 30, 25) is read in step S11, the brightness Y = 35 is calculated in step S12, and the number of appearances of the brightness Y = 35 in one frame Is added to the value of the frequency L (35) indicating (step S16). By repeating steps S10 to S16 by the number of grayscale data for one frame, the respective values of the frequencies L (0) to L (63) of the lightness Y = 0 to 63 in one frame are obtained. A histogram L of Y is calculated.
[0108]
FIG. 13 is a flowchart illustrating a procedure for calculating the number M of pixels occupied by an image when the image is present only in a part of one frame (screen). If the pixels in the two-dimensional array are m rows and n columns, and the brightness Y of the gradation data (R, G, B) in the i row and j columns is 0 (that is, black display in the normally black mode), the pixel (x ( i), y (i)), x (i) = y (j) = 0, and otherwise, x (i) = y (j) = 1. The brightness Y and the value 0 are compared for all the pixels in one frame, and the coordinates (x (i), y (i)) of each pixel are set to x (i) = y (j) = 0 or x (i) = Substitute y (j) = 1. Since the image is almost rectangular, a black and white pixel (x (i) = y (j) = 0) in all columns and rows at the top, bottom, left and right is regarded as the background, and the rest is selected as the image. M. That is, M is obtained by counting the number of x (i) = 1 and the number of y (i) = 1 and taking the product of both. For example, when the display pixel is located substantially at the center of the frame, among the pixels in the xm rows and yn columns in the entire frame, all the video signals are 0x1 to xb rows and xc to xm rows, and y1 to yf columns and The number M of pixels in the range excluding the yg to yn columns is obtained.
[0109]
Specifically, from the state of x (i) = y (j) = 0 for all i and j, variables i = 1 and j = 1 are set in step S20 in FIG. The value is compared with the value n + 1 (step S21). If j = 1 <n + 1, since the data has not been read to the last column n, the process proceeds to step S22 to read the brightness Y of the pixel (1, 1) in the first row and first column. Next, the read lightness Y is compared with a value 0 (zero) (step S23). If Y> 0, there is gradation data other than black at the pixel (1, 1). The process proceeds to set a value 1 to x (1) and a value 1 to y (1), and then proceeds to step S25. If Y = 0, the process moves to step S25 without executing step S24. In this case, x (1) = y (1) = 0 remains.
[0110]
Next, in step S25, the variable i = 1 is compared with the row value m. If i = 1 <m, since the data has not been read to the last row m, the value of i is increased by 1 (step S26), and the process returns to step S21 again to return to the next pixel (2, 1). The brightness Y is read and the brightness Y is compared with a value 0 (step S23). If Y> 0, x (2) = 1 and y (1) in (x (2), y (1)). = 1 (step S24). By repeating this operation until i = m, the processing of m pixels in the j = 1 column is completed.
[0111]
Next, the process proceeds from step S25 to step S27, where the i value is set to the initial value 0, the value of the variable j is increased by 1, and the process returns to step S21 again to return to the pixel (1, 2, ) Is read. Next, the read brightness Y is compared with the value 0 (zero) (step S23). If Y> 0, since there is gradation data other than black at the pixel (1, 2), the process proceeds to step S24. After shifting, the value 1 is set to x (1) of (x (1), y (2)), the value 1 is set to y (2), and the process shifts to step S25. If Y = 0, the process moves to step S25 without executing step S24. In this case, x (1) = y (2) = 0 remains.
[0112]
Next, in step S25, the variable i = 1 is compared with the row value m. If i = 1 <m, since the data has not been read to the last row m, the value of i is increased by 1 (step S26), and the process returns to step S21 again to return to the next pixel (2, 2). The brightness Y is read and the brightness Y is compared with a value 0 (step S23). If Y> 0, x (2) = 1 and y (2) = 1 are set (step S24). By repeating this operation until i = m, processing of m pixels in j = 2 columns is completed. When the above operation is repeated and the variable j = n + 1 in step S21, the process proceeds to a "determination" routine.
[0113]
In the "determination" routine, i = 0 and j = 0 are set in step S28, and then the value of i is increased by 1 in step S29, and the value of x (i) is added to the variable x (step S28). S30). This process is repeated until i = m (row) (step S31), and when i = m, the process proceeds to step S32. In the processing up to step S31, the number x of the pixels used for image display in the row direction is grasped.
Next, in step S32, the value of j is increased by 1 and the value of y (j) is added to the variable y (step S33). This process is repeated until j = n (column) (step S34), and when j = n, the process proceeds to step S35. By the processing up to step S34, the number y of pixels used for image display in the column direction is grasped.
[0114]
Next, in step S35, the product of the number x of image display pixels in the row direction and the number y of image display pixels in the column direction is obtained, and the number M of image display pixels of one frame is obtained.
[0115]
FIG. 14 is a flowchart illustrating a procedure for calculating the threshold brightness Yα. In this procedure, based on the number M of pixels for image display and the predetermined number p, the lightness Y lower by t = Mp in order from the highest lightness is set as the threshold lightness Yα. The predetermined number p represents the ratio of luminance saturation due to image processing, and is preferably p = 0.02 (= 2%) or less from the subjective evaluation result shown in FIG. Assuming that the predetermined number p is 2% and the number of pixels for image display is M = 80000, the constant number t = Mp = 80000 × 2 (%) = 1600. In order to select 1600 brightness Y values in descending order, i = 63 is set in step S1, and L = L (63) is set as the initial value of the frequency L (step S41).
[0116]
In step S42, t = 1600 is compared with L = L (63). If the frequency L (63) is larger, the process proceeds to step S45 to set the threshold brightness Yα = 63. If t = 1600 ≧ L = L (63), 1 is subtracted from i = 63 in step S43 to set i = 62, and L = L (63) + L (62) is calculated in step S44. Returning to step S42 again, the calculated L is compared with t = 1600, and if the frequency L is greater, the process proceeds to step S45 to set the threshold brightness Yα = 62. If t = 1600 ≧ L, L = L (63) + L (62) + L (61)... is repeated to determine Yα. In this routine, the lightness L is sequentially added as L (63) + L (62) + L (61). For example, whether 1600−L (63) is 0 or more, 1600−L (63) − Of course, whether or not L (62) is 0 or more may be sequentially determined.
[0117]
After the threshold brightness Yα is obtained by the procedure shown in FIG. 14, next, the control value of the illumination is determined. For example, it is assumed that the gradation and luminance characteristics are determined by performing γ (gamma) correction or the like on a 64-gradation display. FIG. 15 shows a duty ratio selection lookup table used for selecting the duty ratio of the light source. In the table shown in FIG. 15, the duty ratio (%) is determined corresponding to the value of the threshold brightness Yα obtained by the procedure shown in FIG.
[0118]
The duty ratio may be calculated, but if the calculation formula is complicated, it is easier to prepare a table as shown in FIG. The duty ratio selection look-up table is stored in a memory (not shown) in the display data conversion circuit 20. The display data conversion circuit 20 selects predetermined duty ratio data from the table based on the threshold brightness Yα and outputs the data to the light source control unit 22. The light source control unit 22 controls the light source power supply circuits 35 to 38 based on the input duty ratio data to drive the cold cathode tubes 30 to 33 at a predetermined duty ratio.
[0119]
FIG. 16 shows a lookup table for signal control value selection for determining a control value when outputting processed gradation data to a plurality of data bus lines 8 in accordance with the threshold value brightness Yα. In the top row of the table, the threshold brightness Yα is displayed from left to right in descending order, and the leftmost column shows the original gradation in descending order. For example, when the display luminance is 360 cd at the threshold brightness Yα = 60 and 400 cd at the maximum threshold brightness Yα = 63, the original brightness is set so that the lightness Y = 63 to 60 becomes 100% in the liquid crystal layer. Process the data. When the brightness Y ≦ 59, the original gradation data is processed so that the light transmittance of the liquid crystal layer becomes 400/360 = 10/9 times the original light transmittance. That is, the display output luminance Ii of the brightness Yi equal to or less than the brightness Yα is converted into a light transmittance that is multiplied by (I ÷ Iα). If this control value is stored in a memory as a table as shown in FIG. 16, any necessary arithmetic processing can be omitted.
The duty ratio is determined by the lighting of the light emitting unit according to the ratio of the output display luminance Iα of the threshold brightness Yα to the maximum display output luminance I (= maximum light transmittance × maximum illumination amount).
[0120]
By combining the configurations and procedures shown in FIGS. 11 to 16, the brightness Y is calculated and the histogram L is generated while reading the gradation data (image data) for one frame into the memory. After reading the data, the number M of pixels for image display is calculated, the constant value t = Mp is calculated with p = 2%, and the threshold brightness Yα can be obtained. The duty ratio is selected from the table shown in FIG. 15 and is output to the light source control unit 22. In synchronization with this, the gradation data processed by the table shown in FIG. 16 is output to each data bus line 8.
[0121]
FIG. 17 shows an example of duty driving. The horizontal direction indicates time, and the vertical direction indicates lighting (On) and non-lighting (Off) of the light sources 30 to 33. From the left to the right of the diagram, the duty ratio is 100% (all frames are lit), the duty ratio is 50% (the latter half of the frame is lit 50%), and the duty ratio is 20% (the last frame is 20% before the frame is lit).
[0122]
As a specific example, the above-described circuit is configured in an FPGA, and a 17-inch wide display area uses a sidelight-type backlight (fluorescent tubes arranged above and below the display) or a direct-type 8-light backlight, and uses a backlight. A display device having a display luminance of 200 to 800 nit was manufactured. When a moving image is reproduced on a commercially available DVD, and the display device of this embodiment and the conventional display device are arranged side by side to compare the moving images, the display device of this embodiment is comparable to the conventional display. Was obtained. When the backlight lighting duty ratio of the conventional display device is set to 100%, the average of the duty ratio of the display device of the present embodiment is 50%, which is effective for power saving of the backlight. I understood.
[0123]
Further, if the value of p (> 2%) is further increased, the effect on image quality is small if pixels of lightness Y exceeding threshold value lightness Yα are discrete, but if the pixels are aggregated, image quality is degraded. May be determined. In particular, when pixels are gathered at the center of the screen, the image quality may be determined to be deteriorated even if p is the same. Therefore, a set / discrete state of pixels is extracted as data and used to prevent image quality deterioration. Of course. In this case, the number of elements in each section obtained by dividing the M pixels into several numbers is M1 to Ms, and the above procedure may be used for each of the elements M1 to Ms.
[0124]
Even if the control circuit 16 does not have a frame memory or the like, the image data is passed as display data as it is and the operation according to the present embodiment is applied with a delay of one frame (1/60 sec). Then, there was no problem that the image looked strange or dark.
[0125]
Further, when the brightness Y is 0 to 255 (256 gradations), the lighting control value and the signal control value for the threshold brightness Yα = 0 to 255 should be made into a look-up table by simplifying to 0 to 64. 0 when the threshold brightness Yα = 0, 1 when the threshold brightness Yα = 1 to 4, 2 when the threshold brightness Yα = 5 to 8,..., When the threshold brightness Yα = 253 to 255 When the control values were converted to 64 and displayed, and the above-mentioned moving image was observed, it was generally good.
[0126]
18 to 27 show specific examples. FIG. 18 shows an example in which a sidelight type backlight unit is arranged on an LCD panel. Cold cathode tubes A and B are arranged above and below the display area P. FIG. 19 shows an example in which the cold cathode tubes A and B shown in FIG. 18 are duty driven. The horizontal direction indicates time, and the vertical direction indicates lighting (On) and non-lighting (Off) of the cold cathode tubes A and B. From left to right in the figure, in the first frame, the duty ratio of both the cold cathode tubes A and B is 80%, but the cold cathode tube A is turned on in the latter half of the frame, and the cold cathode tube B is turned on in the first half of the frame. Let me. In the next frame, the duty ratio of both the cold cathode tubes A and B is 40%, but the cold cathode tube A is turned on in the latter half of the frame, and the cold cathode tube B is turned on in the front 40% of the frame.
[0127]
FIG. 20 shows a scan type backlight unit in which the cold cathode tubes A to F are arranged on the back surface of the panel display surface. FIG. 21 shows an example in which the cold cathode tubes A to F are duty-driven. The horizontal direction represents time, and the vertical direction represents lighting (On) and non-lighting (Off) of the cold cathode tubes A to F. From the left to the right in the figure, the duty ratio of each of the cold cathode tubes A to F is changed from 80% to 40%. At this time, the scan state is formed by sequentially shifting the lighting start times (or the turning-off times) of the cold cathode tubes A to F by a predetermined time.
[0128]
FIG. 22 shows an example in which a sidelight type backlight unit is arranged on an LCD panel. Cold cathode tubes A and B are arranged on the left and right from the upper center of the display area P, and cold cathode tubes C and D are arranged on the left and right from the lower center of the display area P. The image P1 is displayed on the left side from the center of the display area P, and the image P2 is displayed on the right side. FIG. 23 shows an example in which the cold cathode tubes A to D shown in FIG. 22 are duty driven.
[0129]
FIG. 24 shows an example in which a direct-type backlight unit is arranged on an LCD panel. The cold cathode tubes A, C, E, and G are arranged on the left from the center of the display area P, and the cold cathode tubes B, D, F, and H are arranged on the right from the center of the display area P. The image P1 is displayed on the left side from the center of the display area P, and the image P2 is displayed on the right side. FIG. 25 shows an example in which the cold cathode tubes A to H shown in FIG. 24 are duty driven.
[0130]
FIG. 26 shows an example in which a direct-type backlight unit is arranged on an LCD panel. LEDs A to C, H to J, K to M, and P to R are arranged in a matrix at the left 2/3 from the center of the display area P, and the LEDs D, E, I, J, N, O, S, and T are arranged in a matrix. The image P1 is displayed at the left 2/3 from the center of the display area P, and the image P2 is displayed at the right 1/3. FIG. 27 shows an example in which the LEDs A to T shown in FIG. 26 are duty-driven.
[0131]
In any display area of the display device shown in the above specific example, the shorter the light emission time of the backlight, the more the blur of a moving image specific to the liquid crystal display device can be improved.
[0132]
In the above embodiment, the average of the duty ratio of the backlight is 50%, but the duty ratio approaches 100% when a bright image as a whole is obtained. As the duty ratio approaches 100%, the effect of improving the blur of a moving image decreases. Therefore, as described in the first and second embodiments, two types of lighting states, full lighting and intermediate lighting, are provided in one frame, and the intermediate brightness, which is the display brightness at the time of the intermediate lighting, is set at the time of the full lighting. The display brightness was set to be 50% of the total lighting brightness.
[0133]
For example, in a display device including a scanning backlight shown in FIG. 1 in which one frame is divided into four regions in order from the top and duty driving is performed in each region, as shown in FIG. 28, the duty ratio is 80%. The first 20% of one frame period is turned off and the remaining 80% of the period is turned on. In this case, in the period between the time T2 of the first 20% (first region) of the one frame period and the time T3 of 25%, the grayscale data Data is written to the pixel during the writing period T1 (indicated by V in the drawing). Despite this, at time T2, the backlight changes from the unlit state S1 to the maximum lit state S2. Further, the light is turned off when the transmittance is high before the next gradation data Data is written. In one frame period, a total of 20% of the four regions are turned on when grayscale data is written, and are turned off immediately before writing the next grayscale data. It feels low and the display quality deteriorates.
[0134]
FIG. 29 shows a duty driving method for solving the above conventional problem. As shown in FIG. 29, the backlight is set to the intermediate lighting state S3 in the first 40% of the one frame period (the grayscale data Data is written to the pixels in the first 25% of the time T1 of the one frame period). Next, the backlight is set to the maximum lighting state S2 in the remaining 60%. In this case, the display brightness that is visually perceived does not change, and the liquid crystal is illuminated by full lighting when the response is almost completed, so that a desired image is printed on the eyes. Therefore, good display quality can be obtained over the entire display area without moving image blur.
[0135]
As described above, according to the present embodiment, a certain percentage of pixels in the order of pixels having the highest luminance in the moving image are set as the maximum display luminance, and the luminance of each of the remaining pixels excluding this is defined as the duty of the backlight. The reproduction is made by lowering the ratio and raising the liquid crystal transmittance. As a result, even if the duty ratio of the backlight is lowered, the moving image display quality can be made equal to that of the original image, and the power consumption of the backlight can be reduced. Further, by combining with a scanning backlight or a blinking backlight, a higher quality liquid crystal display device in which image blur is improved while maintaining the display quality of a moving image can be realized. Although this embodiment is applied to a liquid crystal display device, it can be used for light emission control of an EL (electroluminescence) element.
[0136]
[Fourth Embodiment]
A lighting device according to a fourth embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. The duty drive directly modulates the luminance of the light source of the illuminating device that emits surface light in synchronization with the writing timing of the gradation data Data, but the modulation degree is conventionally very high, for example, the luminance ratio needs to be 20 or more. Was considered. However, as described in the first embodiment, the display quality of a moving image is not deteriorated even if it is not the duty drive for completely turning on or off the light source. The present inventors have found that a sufficient display can be obtained if the luminance ratio is 2 or more. By performing the new duty drive described below according to this knowledge, it is possible to increase the brightness of the display without deteriorating the display quality of the moving image, to increase the luminous efficiency (power ratio) of the cold cathode fluorescent lamp, and to reduce the power consumption. it can. Further, the life of the light source can be prolonged, and the power source can be made small, light, and thin.
[0137]
(Example 4-1)
FIG. 30 shows a backlight structure according to Example 1 of the present embodiment. In this example, the TFT-LCD 1 shown in FIG. 1 according to the first embodiment is used, and FIG. 30 shows a state in which the lighting device 24 is viewed from the light emitting opening side of the first to fourth light emitting regions. ing. The diffusion sheet 60 and the like described in the second embodiment are also arranged on the light exit opening side. The backlight is of a direct type, and each of the light-emitting regions 25 to 28 is incompletely divided into four so that light in adjacent regions is mixed. Otherwise, it is the same as the lighting device 24 shown in FIG. FIG. 31 shows a driving waveform of the backlight according to the first embodiment. FIG. 31 is substantially the same as FIG. 2 except that the output timing of the gate pulse GP output from the gate driver 12 to each gate bus line 6 is the same, but in FIG. B (28) is different in that currents C (30) to C (33) flowing through the cold cathode tubes 30 to 33 in the light emitting regions 25 to 28 are shown.
[0138]
As shown in FIG. 31, the current flowing through each of the cold-cathode tubes 30 to 33 is illuminated in the maximum lighting state S2 after the gradation data is written in a predetermined pixel and the liquid crystal sufficiently reacts to increase the transmittance. Drive is performed as described above. The current state (or power state) of each of the cold-cathode tubes 30 to 33 is the maximum current (or maximum power) when illuminating with the maximum amount of light. The intermediate lighting state S3 is maintained (power is supplied). In this duty drive, the current state (or power state) is repeated in the same cycle as the display data write cycle. As described above, the present embodiment is characterized in that the current flows (or the power is turned on) even when the current is not the maximum current (or the maximum power).
[0139]
Whether or not a person perceives a moving image blur or a trailing phenomenon in the moving image display in the duty driving largely depends on a maximum value of an illumination light amount in the maximum irradiation state S2 and a time width thereof. The quality of the moving image display does not change even in the intermediate lighting state S3 which is approximately half or less of the maximum value between the maximum lighting states S2 repeated at a predetermined frequency.
[0140]
Therefore, according to the present embodiment, it is possible to increase the brightness while suppressing an increase in the power.Therefore, it is not necessary to increase the size of the ballast of the cold cathode fluorescent lamp. Become. Furthermore, since a rise in driving voltage due to an increase in current as in the related art can be suppressed, a decrease in the light-to-light conversion efficiency of the cold-cathode tube can be suppressed and the tube life can be extended. As described above, according to the present embodiment, the moving image display quality is the same, the brightness is increased, and the power consumption is reduced, as compared with the conventional method in which the light is illuminated in the maximum lighting state S2 for a predetermined time and is turned off at other times. In addition, it is possible to reduce the weight, thickness, size, and life of the device.
[0141]
(Example 4-2)
FIG. 32 shows a backlight structure according to Example 2 of the present embodiment. In the present embodiment, the same TFT-LCD 1 as in the first embodiment is used, and FIG. 32 shows a state viewed from the same direction as FIG. 30 of the embodiment. The backlight is of a direct type, and each of the light-emitting regions 25 to 28 is incompletely divided into four so that light in adjacent regions is mixed. Two cold cathode tubes (30a, 30b), (31a, 31b), (32a, 32b), and (33a, 33b) are arranged in each of the light emitting regions 25 to 28.
[0142]
FIG. 33 shows a backlight drive waveform according to the second embodiment. Although the waveforms in FIG. 33 are substantially the same as those in FIG. 31 of the first embodiment, in this embodiment, each of the light emitting regions 25 to 28 is illuminated by two sets of cold cathode tubes. Has the advantage that each current waveform shown in (1) can be realized by a combination of two cold cathode tubes.
[0143]
This will be described more specifically with reference to FIGS. 34 to 36 show timing charts similar to those in FIG. In the case shown in FIG. 34, a current is supplied to the cold cathode tubes 30a, 31a, 32a, and 33a in the respective light emitting regions so as to be in the maximum lighting state S2 in a predetermined cycle and to be in the non-lighting state S1 in other cases. Drive. The cold-cathode tubes 30b, 31b, 32b, and 33b in each light-emitting area are turned off in the maximum lighting state S2 of each of the cold-cathode tubes 30a, 31a, 32a, and 33a in the set, and are turned off in the intermediate lighting state S2 in other cases. Illumination drive is performed by supplying such a current. Thereby, it is possible to illuminate with the same luminance as the luminance obtained by the illumination drive current waveform shown in FIG.
[0144]
In the case shown in FIG. 35, the cold-cathode tubes 30a, 31a, 32a, and 33a in the respective light-emitting regions are driven at a low current, which is an intermediate lighting state S2 ′ lower than the maximum lighting state S2 in a predetermined cycle, respectively. Driving is performed at a low current which results in an intermediate lighting state S3-1 darker than the intermediate lighting state S3 shown in FIG. The cold cathode tubes 30b, 31b, 32b, and 33b in the respective light emitting areas have intermediate differences between the cold cathode tubes 30a, 31a, 32a, and 33a forming a set so that the total sum becomes the maximum lighting state S2 in the intermediate lighting state S2 '. The lamp is driven at a low current to be the lighting state S3-3, and the intermediate lighting state S3-1 of the cold cathode tubes 30a, 31a, 32a, and 33a is the intermediate lighting state S3 of the difference in which the sum becomes the intermediate lighting state S3. Drive at low current. This makes it possible to illuminate with the same luminance as the luminance obtained by the illumination drive current waveform shown in FIG.
[0145]
In the case shown in FIG. 36, the cold-cathode tubes 30a, 31a, 32a, and 33a in the respective light-emitting regions are driven at a low current, which is an intermediate lighting state S2 ″ lower than the maximum lighting state S2 in a predetermined cycle, respectively. Then, the current supply is stopped so as to be in the light-off state S1. The difference between the cold cathode tubes 30b, 31b, 32b, and 33b in each light emitting region is such that the total sum of the cold cathode tubes 30a, 31a, 32a, and 33a in the intermediate lighting state S2 ″ becomes the maximum lighting state S2. By driving continuously at a low current in the intermediate lighting state S3, it is possible to illuminate with the same luminance as the luminance obtained by the illumination driving current waveform shown in FIG.
[0146]
In this way, by controlling the current flowing through the set of cold cathode tubes in each of the light emitting regions 25 to 8, the illumination state shown in FIG. 33 can be obtained. By performing the duty driving shown in this embodiment, it is possible to increase the luminance while suppressing an increase in power. Therefore, it is not necessary to increase the size of the ballast of the cold-cathode tube. become able to. Furthermore, since a rise in driving voltage due to an increase in current as in the related art can be suppressed, a decrease in the light-to-light conversion efficiency of the cold-cathode tube can be suppressed and the tube life can be extended. As described above, according to the present embodiment, the moving image display quality is the same, and high brightness, low power, light weight, thin thickness, small size, and long life can be achieved.
[0147]
(Example 4-3)
Third Embodiment A third embodiment will be described with reference to FIGS. 37 and 38. FIG. 37 shows a backlight drive waveform similarly to FIG. 31 of the first embodiment. The backlight structure of this embodiment is the same as that of the first embodiment shown in FIG. In the case shown in FIG. 37, the cold-cathode tubes 30, 31, 32, and 33 in each light-emitting area are driven by a current that causes the maximum lighting state S2 in a predetermined cycle, and a low current that causes the intermediate lighting state S3 otherwise. (50% of the current value of the maximum lighting state S2), and when transitioning from the maximum lighting state S2 to the intermediate lighting state S3, a period during which the current supply is stopped so as to be in the light-off state S1 for a predetermined time. Provided.
[0148]
In the case shown in FIG. 38, the cold-cathode tubes 30, 31, 32, and 33 in each light-emitting area are driven by a current that causes a maximum lighting state S2 in a predetermined cycle, and a low current that causes an intermediate lighting state S3 otherwise. (50% of the current value of the maximum lighting state S2), and when shifting from the maximum lighting state S2 to the intermediate lighting state S3, the intermediate lighting state S4 which is brighter than the light-off state S1 for a predetermined time and darker than the intermediate lighting state S3. A period for supplying a low current (20% of the current value in the maximum lighting state S2) is provided.
[0149]
As shown in FIG. 37 and FIG. 38, immediately after the state of the maximum current value (or the maximum power or the maximum light amount), the current value (or the power or the maximum light amount) is instantaneously greatly reduced. The impulse effect perceived by humans can be increased by instantaneously recognizing the image and immediately disappearing.
[0150]
FIG. 39 shows the display quality when a moving image is displayed in the display area of the TFT-LCD 1 by changing the intermediate lighting states S3 and S4 in FIG. 38 by setting the current value (relative value) in the maximum lighting state S2 to 10. Is graphed as a subjective evaluation by a plurality of observers.
[0151]
In FIG. 39, the horizontal axis represents the ratio (%) of the maximum lighting state S2 to one frame period f, and the vertical axis represents the evaluation based on 1 to 5 evaluation points. Evaluation point 1 indicates a case where moving image blur or tailing in moving image display is “very disturbing”, and evaluation point 2 indicates a case where they are “disturbing”. The evaluation point 3 is a case where the blurring of the moving image is “worried but can be tolerated”, the evaluation point 4 is a case where the difference is understood but can be tolerated, and the evaluation point 5 is “an excellent image quality equivalent to a still image”. This is the case.
[0152]
In the drawing, a straight line (A) connecting circles indicates a case where (current value in the maximum lighting state S2, current value in the intermediate lighting state S4, current value in the intermediate lighting state S3) = (10, 10, 10). Is shown. In this case, regardless of the ratio of the maximum lighting state S2 to one frame period f (hereinafter, abbreviated as “the ratio of the maximum lighting state S2”), the light is illuminated at the maximum luminance level in the entire area of one frame period f. In other words, the display is equivalent to that of the hold-type driving, and therefore the image quality is such that moving image blurring and tailing are very disturbing, and the evaluation score is 1.
[0153]
In the drawing, a broken line (B) connecting the crosses indicates a case where (current value in the maximum lighting state S2, current value in the intermediate lighting state S4, current value in the intermediate lighting state S3) = (10, 5, 5). Is shown. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, a moving image blur and a trail are hardly visually recognized, and an excellent image quality is obtained. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but the evaluation point 3 is obtained up to about 50%.
[0154]
The broken line (C) indicates the case where (current value in the maximum lighting state S2, current value in the intermediate lighting state S4, current value in the intermediate lighting state S3) = (10, 2, 5). In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, an excellent image quality in which moving image blur and tailing are hard to be visually recognized is obtained, and thus the evaluation point is close to 5. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but the evaluation point 3 is obtained up to about 50%.
[0155]
In the drawing, a broken line (D) connecting the black circles is a case where (current value in the maximum lighting state S2, current value in the intermediate lighting state S4, current value in the intermediate lighting state S3) = (10, 0, 5) Is shown. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, an excellent image quality in which moving image blur and tailing are hardly visually recognized is obtained, and thus the evaluation point is close to 5. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but an evaluation point of 3 or more is obtained up to about 50%.
[0156]
In the drawing, a polygonal line (E) connecting the square marks is (current value in the maximum lighting state S2, current value in the intermediate lighting state S4, current value in the intermediate lighting state S3) = (10, 0, 0). Is shown. This is the same as the illumination method of the conventional scan type LCD. In this case, when the ratio of the maximum lighting state S2 is about 10% to 30%, an excellent image quality in which moving image blur and tailing are hard to be visually recognized is obtained, so that the evaluation point is further closer to 5. When the ratio of the maximum lighting state S2 exceeds 30%, the evaluation gradually decreases, but an evaluation point of 3 or more is obtained up to about 50%.
[0157]
From FIG. 39, it can be seen that even if the intermediate lighting state S3 is set to a luminance level of about 30% of the luminance level of the maximum lighting state S2, display quality comparable to that of the conventional scanning LCD shown by the broken line (E) can be obtained. I understand. Further, the intermediate lighting state S3 can be regarded as an allowable range up to a luminance level of about 50% of the luminance level of the maximum lighting state S2.
[0158]
Also, if the illumination time in the maximum lighting state S2 is 30% or less of the one frame period f, moving image blur and tailing hardly occur, and up to 50% can be regarded as an allowable range.
[0159]
FIG. 40 shows the characteristics of the cold-cathode tube. The horizontal axis represents the current flowing through the cold-cathode tube, and the vertical axis represents the duty ratio. In the drawing, two thick solid lines indicate contour lines of the input power, one of which is at a power of 1.0, and the other is at a power of 0.6. The other nine thin solid lines show the contour lines of the luminance when the luminance is changed from luminance 20 to luminance 100 in steps of 10. From FIG. 40, it can be seen that when the value of the current flowing through the cold-cathode tube increases, the light-to-light conversion efficiency of the cold-cathode tube decreases, and the life tends to be short. Further, a ballast for driving a cold cathode tube requires a large transformer or the like when a current value to flow becomes large, so that the ballast is heavy, thick, and expensive.
[0160]
According to the present embodiment, it is possible to solve the problems of the light-to-light conversion efficiency and the life of the cold cathode tube as shown in FIG. FIG. 41 and FIG. 42 show the effects of using the lighting device of the present embodiment and the duty driving method thereof. The horizontal axis shown in FIGS. 41 and 42 represents time, and the vertical axis represents the amount of light.
[0161]
FIG. 41A shows a conventional duty drive, in which the power is 1.0 (arbitrary unit: hereinafter, abbreviated as au), and a current of 32 mA is supplied to the cold cathode fluorescent lamp by a duty ratio of 33%. Indicates the amount of light when flowing, and indicates a state in which a (time average) luminance of 1.0 (au) is obtained. On the other hand, FIG. 41B shows the duty driving according to the present embodiment, in which the electric power is 1.0 (au) and the current of 13 mA is supplied to the cold-cathode tube in the maximum lighting state S2 with the duty of 13 mA. The amount of light is shown when a current of 5.2 mA is supplied to the cold-cathode tube in the intermediate lighting state S3 during a flow of 33% in the remaining 67%. As a result, a luminance of 1.4 (au) is obtained.
[0162]
As described above, according to the present embodiment, at a constant power, the luminance is 1.4 times and the light-to-light conversion efficiency is about 1.4 times as compared with the related art. According to the present embodiment, the large current value may be 2/5 of the conventional value of 13 mA. As a result, for example, a conventional display device having a display luminance of 300 candela with the same power can have a luminance of 420 candela without deteriorating the moving image quality. Further, the ballast can be made light, thin, small and at low cost.
[0163]
FIG. 42 (a) is the same as FIG. 41 (a). On the other hand, FIG. 42 (b) shows the duty drive according to the present embodiment, in which the power is 1.0 (au) and the cold cathode fluorescent lamp is in the maximum lighting state S2 and has the same 32 mA as the conventional one. Shows a light amount when a current of 7 mA is supplied to the cold-cathode tube during the remaining 67% and the intermediate lighting state S3 is set. According to this, 1.5 times the power of the conventional method can be applied, and the display luminance can be doubled. That is, a display device having a display luminance of 300 candela in the conventional method using the same ballast can be set to have a luminance of 600 candela in this embodiment without deteriorating the moving image quality. In addition, the light-to-light conversion efficiency can be improved to 1.33 times.
[0164]
(Example 4-4)
Embodiment 4 will be described with reference to FIG. FIG. 43A shows a simplified cross section of the backlight unit 75 of this embodiment. The left side of the figure corresponds to the upper side of the display area of the LCD panel 2 shown in FIG. 1, and the right side of the figure corresponds to the lower side of the display area. For example, twelve cold cathode tubes 76a to 76l are grouped every four tubes, and the tube axes are connected to be almost parallel to the gate bus line 6. The cold cathode tubes 76a to 76l are housed in a thin dish-shaped housing, and a diffuse reflection plate 77 is arranged on the inner wall of the housing. Light from the cold cathode tubes 76a to 76l is emitted to the LCD panel 2 not shown in FIG. 43A via a diffusion plate 78 provided in a light emission opening. This structure is a normal structure when viewed as a backlight unit of a hold type LCD. Since no scan drive is performed, there is no partition between the illumination areas.
[0165]
In the backlight unit 75 having such a configuration, when the light source is duty-driven, light overflows into the peripheral region, and the effect of sufficiently suppressing moving image blurring without a partition is exerted. When the duty driving is performed, effects such as higher luminance, power saving, and longer life are obtained. FIG. 43 (b) shows that the backlight unit 75 having the configuration shown in FIG. 43 (a) is driven to scan the cold cathode tubes 76a to 76l so that any one of the four adjacent ones is always lit at a duty ratio of 33%. 5 shows the relationship between the frame position and the luminance at a certain moment when the image is displayed. The left side of the figure corresponds to the upper side of the display area of the LCD panel 2 shown in FIG. 1, and the right side of the figure corresponds to the lower side of the display area. Although the X position of the curve becomes gentle due to the afterglow time (8 ms) of the G (green) phosphor in the cold cathode tube, a trailing phenomenon occurs, but an image quality sufficient for moving images is obtained.
[0166]
FIG. 44 shows the result of performing the duty drive shown in FIG. 37 or FIG. 38 on the backlight unit 75. The horizontal axis and the vertical axis in FIG. 44 are the same as those in FIG. 43 (b). The X position of the curve shown in FIG. 44 is steeper than that in FIG. 43B, and it can be seen that the tailing phenomenon is more effectively suppressed.
[0167]
More specifically, in the normal direct-type backlight shown in FIGS. 43 and 44, the duty driving of the present embodiment is used, and the current supply state as in the related art is not simply made binary (on / off). It has flatness in the state of light quantity. The luminance distribution (illumination light intensity distribution) in FIGS. 43 (b) and 44 shows the illumination light intensity from other cold cathode tubes and the afterglow characteristics of the phosphors (the driving cycle of the liquid crystal display device and the backlight, 60 cycles, (The afterglow time of the G phosphor is about 8 msec, which is not negligible for one frame period of 16.7 msec.). I have. The duty driving method shown in FIG. 37 or FIG. 38 is adopted. Immediately after driving with a large current, the current is greatly reduced to cancel the afterglow of the phosphor, and then the current is smoothly increased.
[0168]
According to this embodiment, it is possible to perform scan driving without deterioration of moving image quality by using the conventional normal direct-type backlight structure as it is, and to mix light amounts of a large number of tubes. Even if there are variations and brightness variations, they can be made uniform so that they cannot be viewed. Further, color variations and luminance variations due to deterioration can be similarly made invisible, so that the life of the display device can be extended.
[0169]
As comparative examples, FIGS. 45 and 46 show a conventional direct-type backlight structure and a duty drive. In a backlight 74 shown in FIG. 45A, a partition 77 is arranged between each of the cold cathode tubes 76a to 76l. Then, at the time of the duty driving, as shown in FIG. 45B, current is sequentially supplied to the cold cathode tubes 76a to 76l to individually turn on / off one by one. FIG. 46 shows the result of performing the conventional duty drive on the backlight unit 74. The horizontal axis and the vertical axis in FIG. 46 are the same as those in FIG. 43 (b). From FIG. 46, it can be seen that there is no moving image blur or tailing phenomenon. However, only a part (around positions 114 to 140 in the figure) is turned on at all frame positions and turned off at other positions. It can be seen that the desired luminance has not been obtained.
[0170]
(Example 4-5)
FIG. 47 shows a backlight unit 75 'according to the fifth embodiment. This backlight unit 75 ′ includes a backlight unit 75 shown in FIG. 43A or a conventional backlight unit in which an incomplete partition is formed between each light emitting area, and a diffusion plate 78 having a light emission opening. An example in which a sidelight type backlight unit is arranged above is shown. In the sidelight type backlight unit, cold cathode tubes 79 for constant illumination and uniform illumination are arranged at both ends of a prism light guide plate 80. According to this configuration, the same effect as in the third embodiment can be obtained.
[0171]
(Example 4-6)
FIG. 48 shows a backlight unit 130 according to the sixth embodiment. The backlight unit 130 according to the present embodiment has two light guide plates 100 and 100 ′ arranged in a stacked manner. The light guide plates 100, 100 'have four light emitting areas B1, B2, A1, A2. A cold-cathode tube 102a is arranged on one end surface of the light guide plate 100 in the lower part of the figure. On the other end surface of the light guide plate 100, a cold cathode tube 102b is arranged. The light guide plate 100 has a light guide region for guiding light from the cold cathode tubes 102a and 102b. The light guide plate 100 in the light emitting area B1 has a wedge shape in which the opposing surface 114 is inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102a side is thin and the thickness on the cold cathode tube 102b side is thick. Is formed. The light guide plate 100 in the light emitting region A1 has a wedge shape in which the opposing surface 114 is inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102a side is large and the thickness on the cold cathode tube 102a side is small. Is formed. A scattering layer 116 as a light scattering element is formed on the facing surface 114 of the light emitting areas A1 and B1. The light guide plate 100 has a light guide region for guiding light from the cold cathode tubes 102a and 102b.
[0172]
A cold-cathode tube 102a 'is arranged on one end surface of the light guide plate 100' which is stacked on the liquid crystal display panel 2 side of the light guide plate 100. Further, a cold cathode tube 102b 'is arranged on the other end surface of the light guide plate 100'. The light guide plate 100 'has a light guide region for guiding light from the cold cathode tubes 102a' and 102b '. The light guide plate 100 ′ in the light emitting region B 2 has a facing surface 114 inclined with respect to the light emitting surface 112 so that the thickness on the cold cathode tube 102 a ′ side is small and the thickness on the cold cathode tube 102 b ′ side is large, It is formed in a wedge shape. The light guide plate 100 ′ in the light emitting area A 2 has the opposing surface 114 inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102 a ′ side is large and the thickness on the cold cathode tube 102 b ′ side is small. , Formed in a wedge shape. A scattering layer 116 as a light scattering element is formed on the facing surface 116 of the regions A2 and B2.
[0173]
In the light emitting region B1 of the light guide plate 100, light guided from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the light exit surface 112 is formed by the wedge shape of the light guide plate 100. Becomes smaller each time the light is reflected by the facing surface 114. For this reason, most of the light guided from the cold cathode tube 102b side is not maintained in the light emitting region B1 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102a to the light emitting region B1 is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102 a to the light emitting region B 1 is maintained in the light emitting region B 1, and hardly exits outside the light guide plate 100. That is, in the light emitting region B1 of the light guide plate 100, (light intensity from the cold cathode tube 102b side / light intensity from the cold cathode tube 102b side)> (light intensity from the cold cathode tube 102a side / light from the cold cathode tube 102a side) Light guide light).
[0174]
In the light emitting region A1 of the light guide plate 100, light guided from the cold cathode tube 102a side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the light exit surface 112 is formed by the wedge shape of the light guide plate 100. Becomes smaller each time the light is reflected by the facing surface 114. For this reason, most of the light guided from the cold cathode tube 102 a side is not maintained in the light emitting region A <b> 1 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102b to the light emitting region A1 is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. Therefore, the light guided from the cold cathode tube 102b side to the light emitting region A1 is maintained in the light emitting region A1 and is hardly emitted outside the light guide plate 100. That is, in the light emitting region A1 of the light guide plate 100, (light intensity from the cold cathode tube 102a side / light intensity from the cold cathode tube 102a side)> (light intensity from the cold cathode tube 102b side / light from the cold cathode tube 102b side) Light guide light).
[0175]
In the light emitting region B2 of the light guide plate 100 ', light guided from the cold cathode tube 102b' side is scattered by the scattering layer 116 when reflected on the opposing surface 114, and light is emitted by the wedge shape of the light guide plate 100. Each time the incident angle with respect to the surface 112 is reflected by the opposing surface 114, the angle decreases. For this reason, most of the light guided from the cold cathode tube 102b 'side is not maintained in the light emitting region B2 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102a 'side to the light emitting region B2 is scattered by the scattering layer 116 when reflected by the facing surface 114, but every time light is reflected by the wedge shape of the light guide plate 100. The light is condensed and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102 a ′ to the light emitting region B 2 is maintained in the light emitting region B 2, and hardly exits outside the light guide plate 100. That is, in the light emitting area B2 of the light guide plate 100 ', (light intensity from the cold cathode tube 102b' side / light intensity from the cold cathode tube 102b 'side)> (light intensity from the cold cathode tube 102a' side / cold cathode) (A guide light amount from the tube 102a 'side).
[0176]
In the light emitting region A2 of the light guide plate 100 ', light guided from the cold cathode tube 102a' side is scattered by the scattering layer 116 when reflected on the facing surface 114, and light is emitted by the wedge shape of the light guide plate 100. Each time the incident angle with respect to the surface 112 is reflected by the opposing surface 114, the angle decreases. For this reason, most of the light guided from the cold cathode tube 102a 'side is not maintained in the light emitting region A2 and is emitted outside the light guide plate 100. On the other hand, the light guided from the cold cathode tube 102b ′ to the light emitting region A2 is scattered by the scattering layer 116 when reflected by the facing surface 114, but the light is reflected by the wedge shape of the light guide plate 100 every time. The light is condensed and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b ′ to the light emitting region A2 is maintained in the light emitting region A2 and does not emit much outside the light guide plate 100. That is, in the light-emitting region B2 of the light guide plate 100 ', (light intensity from the cold cathode tube 102a' side / light intensity from the cold cathode tube 102a 'side)> (light intensity from the cold cathode tube 102b' side / cold cathode) (A guide light amount from the tube 102b 'side).
[0177]
The light-emitting regions B2 and A2 of the light guide plate 100 are non-light-receiving regions that hardly extract both light from the cold-cathode tube 102a and light from the cold-cathode tube 102b. The light-emitting regions B1 and A1 of the light guide plate 100 'are non-light-receiving regions that hardly take out both light from the cold-cathode tube 102a' and light from the cold-cathode tube 102b '.
[0178]
Thus, in the light emitting region A1 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting region B1, more light guided from the cold cathode tube 102b side is extracted. In the light emitting region A2 of the light guide plate 100 ', more light guided from the cold cathode tube 102a' side is extracted, and in the light emitting region B2, more light guided from the cold cathode tube 102b 'side is extracted. When the light guide plates 100 and 100 'are stacked and arranged, light is almost uniformly extracted from all the light emitting regions B1, A1, B2 and A2.
[0179]
On the backlight unit described above, a sidelight type backlight unit is further arranged. In the sidelight type backlight unit, cold cathode tubes 79 for constant illumination and uniform illumination are arranged at both ends of a prism light guide plate 80. According to this configuration, the same effect as in the third embodiment can be obtained.
[0180]
(Example 4-7)
FIG. 49 shows a backlight structure according to Example 7 of the present embodiment. This embodiment also uses the TFT-LCD 1 shown in FIG. 1 according to the first embodiment, and FIG. 49 shows that the sidelight type backlight unit 82 is provided with the light emission openings of the first to fourth light emitting regions 25 to 28. This shows a state viewed from the side. The sidelight type backlight unit 82 has LEDs (light emitting diodes) (84a, 84b), (85a, 85b), (86a, 86b), (87a, 87b) on both sides of the light guide plate 83 in each of the light emitting regions 25 to 28. ) Is arranged. Each of the light-emitting regions 25 to 28 is imperfectly divided into four so that light from adjacent regions is mixed. Otherwise, it is the same as the lighting device 24 shown in FIG. Even when the duty drive according to the present embodiment is applied to the backlight unit having the structure shown in FIG. 49, the same effect as that of the above-described embodiment can be obtained.
[0181]
FIG. 50 shows the current dependence of the luminous efficiency of the LED. The horizontal axis represents the current supplied to the LED, and the vertical axis represents the luminous efficiency (au). FIG. 51 shows the current dependency of the light emission amount of the LED. The horizontal axis represents the current supplied to the LED, and the vertical axis represents the amount of light emission (au). In both figures, curves connecting diamonds represent the characteristics of Ga quaternary (for red) LEDs, curves connecting black circles represent the characteristics of GaN-based 1 (for blue) LEDs, and white circles represent the characteristics. The connected curve represents the characteristics of the GaN-based 2 (for green) LED.
[0182]
As shown in FIGS. 50 and 51, it can be seen that the GaN-based LEDs that emit green (G) light and blue (B) light reduce the light-to-light conversion efficiency due to an increase in current, similarly to the cold cathode tubes. In addition, the LED has the same characteristics as a cold cathode tube in terms of current, duty ratio, power, light-to-light conversion efficiency, light emission amount, and life. Therefore, most of the items described with reference to the cold cathode tube in the above embodiment can be applied to the LED. Further, other discharge tubes and solid-state light-emitting elements have almost the same characteristic tendency, so that the above embodiment can be applied to almost all light sources.
[0183]
As described above, according to the present embodiment, a display device with high brightness, high light-to-light conversion efficiency, low cost, lightness, shortness, small size, long life, excellent color / luminance uniformity, and excellent moving image quality is provided. realizable.
[0184]
[Fifth Embodiment]
A lighting device according to a fifth embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. First, the basic configuration of the lighting device according to the present embodiment will be described with reference to FIGS. FIG. 52 shows a basic configuration of a lighting device according to the present embodiment. As shown in FIG. 52, the lighting device according to this basic configuration has a substantially plate-shaped light guide plate 100 made of, for example, acrylic. A linear light source, for example, a cold cathode tube 102b is arranged on the upper side end surface of the light guide plate 100 in the drawing, with the tube axis direction substantially parallel to the long side direction of the light guide plate 100. A cold cathode tube 102 a is arranged on the lower side end surface of the light guide plate 100 in the drawing, for example, with the tube axis direction substantially parallel to the long side direction of the light guide plate 100. The light guide plate 100 has a light exit surface 112 that emits light, and a facing surface 114 that faces the light exit surface 112. Further, the light guide plate 100 has four light emitting areas A1, B1, A2, and B2 that are divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting areas A1, B1, A2, and B2 of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A1, B1, A2, and B2.
[0185]
The light-emitting regions A1 and A2 each have a lighting element for extracting light guided from the cold-cathode tube 102a side (or the cold-cathode tube 102b side) to the outside of the light guide plate 110. The light-emitting regions B1 and B2 each have a lighting element for extracting light guided from the cold cathode tube 102b side (or the cold cathode tube 102a side) to the outside of the light guide plate 110. Light-emitting areas A1 and A2 (or B1 and B2) for selectively collecting light guided from one cold cathode tube 102a (or 102b) side are light guided from the other cold cathode tube 102b (or 102a) side. Light-emitting regions B1 and B2 (or A1 and A2) for selectively collecting the light to be emitted. Thus, the light-emitting regions A1, A2 (B1, B2) for selectively collecting light guided from the same cold cathode tubes 102a, 102b are not adjacent to each other.
[0186]
The lighting device according to this basic configuration is a sidelight type using a linear light source. For this reason, good display quality without luminance unevenness can be obtained. Further, in the lighting device according to the basic configuration, even if the light emitting region is divided in parallel to the long side direction of the light guide plate 100, the tube axis direction of the cold cathode tubes 102a and 102b is substantially parallel to the long side direction of the light guide plate 100. Can be placed. Therefore, a linear light source having a relatively large light emission amount and a long length can be used, and high luminance can be obtained.
[0187]
FIG. 53 is a diagram illustrating the first principle of the lighting element of the lighting device according to the basic configuration. As shown in FIG. 53, a cold cathode tube 102 a is arranged on one end surface of the light guide plate 100 (the left end surface in FIG. 53), for example, with the tube axis direction substantially parallel to the long side direction of the light guide plate 100. . On the other end surface (right end surface in FIG. 53) of the light guide plate 100, the cold cathode tubes 102b are arranged with the tube axis direction substantially parallel to the long side direction of the light guide plate 100. A lamp reflector 110 is arranged around the cold cathode tubes 102a and 102b. The light guide plate 100 has a light exit surface 112 that emits light, and a facing surface 114 that faces the light exit surface 112. On the surface of the facing surface 114, a scattering layer 116 is formed as a light scattering element for scattering and reflecting light. The scattering layer 116 is made of, for example, a resin mixed with beads or the like, and is formed with a predetermined area gradation. Further, the light guide plate 100 has two light-emitting regions A and B divided substantially in parallel to the tube axis direction of the cold cathode tubes 102a and 102b. A light emitting area B is arranged on the cold cathode tube 102a side, and a light emitting area A is arranged on the cold cathode tube 102b side. The light emitting areas A and B of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A and B. The light guide plate 100 has a light guide region for guiding light from the cold cathode tubes 102a and 102b.
[0188]
The light guide plate 100 in the light emitting region A is formed in a wedge shape in which the thickness at the side end portion side where the cold cathode tubes 102b are arranged is thin, and the thickness at the center portion side is thick. The light guide plate 100 in the light emitting region B is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tubes 102a are arranged is thin and the thickness at the center portion is thick. The wedge shape of the light guide plate 100 functions as a lighting element together with the light scattering element.
[0189]
In the light emitting region B, light guided in the light guide plate 100 from the cold cathode tube 102 a side is scattered by the scattering layer 116 when reflected on the facing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102a side is maintained in the light emitting region B like the light ray L1, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102b side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, the light guided from the cold cathode tube 102b side is not maintained in the light emitting region B, and is emitted outside the light guide plate 100 as a light ray L4. That is, in the light emitting region B, (light intensity from the cold cathode tube 102b / light intensity from the cold cathode tube 102b side)> (light intensity from the cold cathode tube 102a side / light intensity from the cold cathode tube 102a side) Is in a relationship.
[0190]
In the light emitting region A, light guided in the light guide plate 100 from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the facing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b side is maintained in the light emitting region A like the light beam L3, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102a side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, the light guided from the cold cathode tube 102a side is not maintained in the light emitting region A, and is emitted outside the light guide plate 100 like a light ray L2. That is, in the light-emitting area A, (light intensity from the cold cathode tube 102a / light intensity from the cold cathode tube 102a)> (light intensity from the cold cathode tube 102b / light intensity from the cold cathode tube 102b) Is in a relationship.
[0191]
Thus, in the light emitting region A of the light guide plate 100, more light is guided from the cold cathode tube 102a side, and in the light emitting region B, more light is guided from the cold cathode tube 102b side. Note that the air-side interface of the scattering layer 116 is preferably formed to be flat rather than uneven (a so-called bulk-type scattering structure). Thus, the ratio of light emitted from the cold cathode tube 102a side (cold cathode tube 102b side) to the air layer side from the interface of the scattering layer 116 in the light emitting region B (light emitting region A) can be significantly reduced.
[0192]
FIG. 54 is a diagram illustrating the second principle of the lighting element of the lighting device according to the basic configuration. As shown in FIG. 54, the light guide plate 100 has two light emitting areas A and B divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. A light emitting area B is arranged on the cold cathode tube 102a side, and a light emitting area A is arranged on the cold cathode tube 102b side. The light emitting areas A and B of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A and B. The opposing surface 114 of the light guide plate 100 is formed in a prism shape. The prism shape functions as a lighting element for extracting light.
[0193]
The opposing surface 114 of the light emitting region B has a prism shape in which light from the cold cathode tube 102a side does not enter the prism surface 118 and is guided to the light emitting region A as it is as a light ray L1. The prism surface 118 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102b enters the prism surface 118 with a certain probability. The light incident on the prism surface 118 is emitted outside the light guide plate 100 as a light ray L4 by reflection or refraction due to collapse of the total reflection condition.
[0194]
The opposing surface 114 of the light emitting region A has a prism shape in which light from the cold cathode tube 102b does not enter the prism surface 119 and is guided to the light emitting region B as it is as a light ray L3. The prism surface 119 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102a enters the prism surface 119 with a certain probability. The light incident on the prism surface 119 is emitted outside the light guide plate 100 as a light ray L2 by reflection or refraction due to collapse of the total reflection condition.
[0195]
Thus, in the light emitting region A of the light guide plate 100, more light is guided from the cold cathode tube 102a side, and in the light emitting region B, more light is guided from the cold cathode tube 102b side.
[0196]
FIG. 55 is a diagram illustrating the third principle of the lighting element of the lighting device according to the basic configuration. As shown in FIG. 55, a scattering layer 116 is formed on the surface of the facing surface 114 of the light guide plate 100 as a light scattering element for scattering and reflecting light. Further, the light guide plate 100 has two light-emitting regions A and B divided substantially in parallel to the tube axis direction of the cold cathode tubes 102a and 102b. A light emitting area A is arranged on the cold cathode tube 102a side, and a light emitting area B is arranged on the cold cathode tube 102b side.
[0197]
The light guide plate 100 in the light emitting region A is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tube 102a is disposed is thick and the thickness at the center portion is thin. Similarly, the light guide plate 100 in the light emitting region B is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tubes 102b are arranged is thick and the thickness at the center portion is thin. The light emitting areas A and B of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A and B. The light emitting areas A and B are not completely separated. The wedge shape of the light guide plate 100 functions as a lighting element together with the light scattering element.
[0198]
In the light emitting region A, the light guided from the cold cathode tube 102 a side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the incident angle with respect to the light emitting surface 112 is reduced by the wedge shape of the light guide plate 100. Each time the light is reflected by the opposing surface 114, it becomes smaller. For this reason, most of the light guided from the cold cathode tube 102 a side is not maintained in the light emitting region A and is emitted outside the light guide plate 100. On the other hand, the light guided from the cold cathode tube 102a to the light emitting region B is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102 a to the light emitting region B is maintained in the light emitting region B, and does not emit much outside the light guide plate 100.
[0199]
In the light emitting region B, light guided from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the incident angle with respect to the light emitting surface 112 is reduced by the wedge shape of the light guide plate 100. Each time the light is reflected by the opposing surface 114, it becomes smaller. For this reason, most of the light guided from the cold cathode tube 102b side is not maintained in the light emitting region B, and is emitted outside the light guide plate 100. On the other hand, the light guided from the cold cathode tube 102b to the light emitting region A is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b side to the light emitting region A is maintained in the light emitting region A, and is hardly emitted outside the light guide plate 100.
[0200]
Thus, in the light emitting region A of the light guide plate 100, more light is guided from the cold cathode tube 102a side, and in the light emitting region B, more light is guided from the cold cathode tube 102b side.
[0201]
FIG. 56 is a diagram illustrating the fourth principle of the lighting element of the lighting device according to the basic configuration. As shown in FIG. 56, the light guide plate 100 has two light emitting regions A and B divided substantially in parallel to the tube axis direction of the cold cathode tubes 102a and 102b. A light emitting area A is arranged on the cold cathode tube 102a side, and a light emitting area B is arranged on the cold cathode tube 102b side. The opposing surface 114 of the light guide plate 100 is formed in a prism shape. The prism shape functions as a lighting element for extracting light. The light emitting areas A and B of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A and B.
[0202]
The opposing surface 114 of the light emitting area A has a prism shape in which light from the cold cathode tube 102a enters the prism surface 119 with a certain probability and light from the cold cathode tube 102b side does not enter the prism surface 119. The prism surface 119 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. The light that has entered the prism surface 119 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0203]
The opposing surface 114 of the light emitting region B has a prism shape in which light from the cold cathode tube 102b enters the prism surface 118 with a certain probability and light from the cold cathode tube 102a side does not enter the prism surface 118. The prism surface 118 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. The light that has entered the prism surface 118 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0204]
Thus, in the light emitting region A of the light guide plate 100, more light is guided from the cold cathode tube 102a side, and in the light emitting region B, more light is guided from the cold cathode tube 102b side.
[0205]
Hereinafter, the illumination device according to the present embodiment and the liquid crystal display device using the same will be specifically described with reference to Examples 5-1 to 5-6.
[0206]
(Example 5-1)
Next, a lighting device according to Example 5-1 of the present embodiment and a liquid crystal display device using the same will be described with reference to FIGS. FIG. 57 is a block diagram illustrating a schematic configuration of the liquid crystal display device according to the present embodiment. As shown in FIG. 57, the liquid crystal display device includes a backlight unit 130 and a driving circuit including a control circuit 16, a gate driver 12, and a data driver 14. The backlight unit 130 has a light source control unit (light source drive circuit) 132. The light source control unit 132 is connected to the control circuit 16. The control circuit 16 receives a clock CLK, a data enable signal Enab, and gradation data Data output from a system such as a PC. Further, the control circuit 16 has a frame memory (not shown) for storing image signals for one frame. The gate driver 12 and the data driver 14 are connected to the control circuit 16. The gate driver 12 includes, for example, a shift register. The gate driver 12 receives a latch pulse signal LP from a gate driver control unit in the control circuit 16, outputs gate pulses sequentially from a display start line, and performs line sequential driving. I have.
[0207]
The liquid crystal display device has N gate bus lines 6-1 to 6-N (only four are shown in FIG. 57) in the display area 134. Each of the gate bus lines 6-1 to 6-N is connected to a gate driver 12. The display area 134 is divided into four areas B1, A1, B2, and A2 extending parallel to the gate bus line 6. The areas B1, A1, B2, A2 are illuminated by the corresponding light emitting areas B1, A1, B2, A2 of the backlight unit 130, respectively. Gate bus lines 6-1 to 6- (N / 4) are arranged in region B1. In the area A1, gate bus lines 6- (N / 4 + 1) to 6- (N / 2) are arranged. In the area B2, gate bus lines 6- (N / 2 + 1) to 6- (3 × N / 4) are arranged. In the area A2, gate bus lines 6- (3 × N / 4 + 1) to 6-N are arranged.
[0208]
FIG. 58 shows a sectional configuration of the liquid crystal display device according to the present embodiment. FIG. 59 illustrates a cross-sectional configuration of the backlight unit 130 of the lighting device according to the present embodiment. As shown in FIGS. 58 and 59, the liquid crystal display device has a transmissive LCD panel 2 and a backlight unit 130. The backlight unit 130 has the substantially plate-shaped light guide plate 100.
[0209]
On one end surface of the light guide plate 100 (the left end surface in FIGS. 58 and 59), a cold cathode tube 102a of a linear light source is arranged with, for example, the tube axis direction substantially parallel to the long side direction of the light guide plate 100. . On the other end surface of the light guide plate 100 (the right end surface in FIGS. 58 and 59), a cold cathode tube 102b is disposed with the tube axis direction substantially parallel to the long side direction of the light guide plate 100, for example. A lamp reflector 110 is arranged around the cold cathode tubes 102a and 102b. The light guide plate 100 has a light exit surface 112 that emits light, and a facing surface 114 that faces the light exit surface 112. On the facing surface 114, a scattering layer 116 serving as a light scattering element is formed. Further, the light guide plate 100 has four light-emitting regions B1, A1, B2, and A2 that are divided substantially parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting region B1 is arranged on the cold cathode tube 102a side, and the light emitting region A1 is arranged adjacent to the light emitting region B1. A light emitting area B2 is arranged adjacent to the light emitting area A1, and a light emitting area A2 is arranged on the cold cathode tube 102b side. The light-emitting regions B1, A1, B2, and A2 of the light guide plate 100 are integrally formed, and no break is formed at the boundary between the light-emitting regions B1, A1, B2, and A2.
[0210]
The opposing surface 114 of the light-emitting regions B1 and B2 has a prism shape in which light from the cold cathode tube 102a side does not enter the prism surface 118 and is guided to the cold cathode tube 102b side as it is. The prism surface 118 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102b enters the prism surface 118 with a certain probability. The light that has entered the prism surface 118 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0211]
The opposing surface 114 of the light emitting areas A1 and A2 has a prism shape in which light from the cold cathode tube 102b side does not enter the prism surface 119, and is guided to the cold cathode tube 102b side as it is. The prism surface 119 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102a enters the prism surface 119 with a certain probability. The light that has entered the prism surface 119 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0212]
As described above, in the light emitting regions A1 and A2 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting regions B1 and B2, more light guided from the cold cathode tube 102b side. Caught. Further, the light guide plate 100 is configured so that light is extracted almost uniformly in all the light emitting areas B1, A1, B2, and A2.
[0213]
A light distribution sheet group 136 including a plurality of light distribution sheets for improving light distribution characteristics is disposed between the LCD panel 2 and the light guide plate 100. Further, on the opposing surface 114 side of the light guide plate 100, a reflection / scattering sheet 138 that scatters and reflects light is disposed.
[0214]
FIG. 60 shows a lighting device according to the present embodiment and a method of driving a liquid crystal display device using the same. The horizontal axis represents time, and the vertical axis represents the write state ((write / non-write)) of the gradation data and the blinking state (ON / OFF) of the illumination device. The waveform b indicates the write state of the grayscale data in the area A1, the waveform c indicates the write state of the grayscale data in the area B2, and the waveform d indicates the write state of the grayscale data in the area A2. A waveform e indicates a blinking state of the cold-cathode tube 102a, and a waveform f indicates a blinking state of the cold-cathode tube 102b. Reference numeral 132 indicates that the CCFLs 102a and 102b emit light at a blinking frequency equal to the frame frequency (for example, 60 Hz) for a predetermined time in synchronization with the latch pulse signal LP. And timing to maximize the light emission luminance of a, and the timing to maximize the light emission luminance of the cold cathode tube 102b about 8.4msec (1/2 cycle) is varied only.
[0215]
The gradation data is written to the pixels in the areas B1 and B2 at substantially the same timing. The liquid crystal display device according to the present embodiment is of a multi-scan type, and the gate driver 12 includes gate bus lines 6-1, 6- (N / 2 + 1), 6-2, 6- (N / 2 + 2),. The gate pulse GP is output in order. That is, the gate bus lines 6 in the regions B1 and B2 are alternately scanned. The gate pulse GP is output to the gate bus line 6- (N / 4 + 1) half a cycle after the gate pulse GP is output to the gate bus line 6-1. Thereafter, the gate bus line 6- (3 × N / 4 + 1), 6- (N / 4 + 2), 12- (3 × N / 4 + 2),...
[0216]
After a lapse of a predetermined time from the writing of the gradation data to the pixels in the areas B1 and B2, the cold cathode tubes 102b that emit light in the light emitting areas B1 and B2 are turned on. After the cold-cathode tube 102b is turned off, gradation data is written to the pixels in the areas B1 and B2. Similarly, after a predetermined time has elapsed since the gradation data was written to the pixels in the regions A1 and A2, the cold cathode tubes 102a that emit light in the light emitting regions A1 and A2 are turned on. After the cold-cathode tube 102a is turned off, gradation data is written to the pixels in the areas A1 and A2. Thus, the cold cathode tubes on the side of the area where the gradation data is written are turned off. In a liquid crystal display device, it takes several milliseconds to several tens of milliseconds from the writing of gradation data to pixels to the tilting of liquid crystal molecules at a predetermined tilt angle, so that the cold-cathode tube is turned on after the writing of gradation data. As long as the time until the operation is as long as possible, a good moving image display quality can be obtained. For this reason, in this embodiment, writing (rewriting) of the gradation data of the areas A1 and A2 (B1, B2) is started immediately after turning off the cold cathode tubes 102a (102b), and the areas A1, A2 (B1, B2) are started. The time from the completion of the writing of the gradation data in (1) to the lighting of the cold cathode tubes 102a (102b) is secured as the response time of the liquid crystal molecules.
[0219]
In this embodiment, the lighting times of the cold cathode tubes 102a and 102b are the same, but the lighting times of the cold cathode tubes 102a and 102b may be different. In the present embodiment, the cold cathode tubes 102a and 102b are turned on / off at a predetermined frequency. However, the light emission luminance of the cold cathode tubes 102a and 102b may be changed at a predetermined frequency.
[0218]
The illumination device according to the present embodiment is of a sidelight type using cold cathode tubes 102a and 102b as linear light sources. For this reason, good display quality without luminance unevenness can be obtained. Further, in the lighting device according to the present embodiment, even if the light emitting region is divided in parallel to the long side direction of the light guide plate 100, the cold cathode tubes 102a and 102b make the tube axis directions substantially parallel to the long side direction of the light guide plate 100. Can be placed. Therefore, a linear light source having a relatively large light emission amount and a long length can be used. Therefore, a scan-type lighting device with high luminance can be realized, and good display quality without blurring of the outline can be obtained even when displaying a moving image.
[0219]
FIG. 61 is a block diagram illustrating a modification of the configuration of the liquid crystal display device according to the present embodiment. As shown in FIG. 61, in this modification, the gate driver 12 that drives the gate bus lines 6-1 to 6- (N / 2) in the regions B1 and A1, and the gate bus line 6- (in the regions B2 and A2). N / 2 + 1) to 6-N are provided independently of each other. Both gate drivers 12, 12 'are connected to a control circuit 84. At the same time that the gate driver 12 outputs the gate pulse GP to the gate bus line 6-1 in synchronization with the latch pulse LP input from the control circuit 16, the gate driver 12 'connects to the gate bus line 6- (N / 2 + 1). The gate pulse GP is output. Thus, in this modification, at the same time that the gate driver 12 scans in the order of the gate bus lines 6-1, 6-2,..., 6- (N / 2), the gate driver 12 ' Bus lines 6- (N / 2 + 1), 6- (N / 2 + 2),..., 6-N can be scanned in this order. According to this modification, the same effects as those of the above embodiment can be obtained.
[0220]
(Example 5-2)
First, a lighting device according to Example 5-2 of the present embodiment will be described with reference to FIG. FIG. 62 illustrates a cross-sectional configuration of the lighting device according to the present embodiment. As shown in FIG. 62, the light guide plate 100 has four light emitting regions B1, A1, B2, and A2 that are divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting region B1 is arranged on the cold cathode tube 102a side, and the light emitting region A1 is arranged adjacent to the light emitting region B1. A light emitting area B2 is arranged adjacent to the light emitting area A1, and a light emitting area A2 is arranged on the cold cathode tube 102b side. The light-emitting regions B1, A1, B2, and A2 of the light guide plate 100 are integrally formed, and no break is formed at the boundary between the light-emitting regions B1, A1, B2, and A2.
[0221]
In the light guide plate 100, the opposing surface 114 is inclined at a predetermined inclination angle with respect to the light exit surface 112, and is formed in a different wedge shape for each region. The light guide plate 100 of the light emitting regions A1 and A2 is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tube 102a is arranged is thick and the thickness at the side end portion where the cold cathode tube 102b is arranged is thin. Have been. The light guide plate 100 of the light emitting regions B1 and B2 is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tube 102a is arranged is thin, and the thickness at the side end portion where the cold cathode tube 102b is arranged is thick. Have been. For example, the inclination angle of the facing surface 114 in the regions A1 and B2 is smaller than the inclination angle of the facing surface 114 in the regions B1 and A2. The wedge shape of the light guide plate 100 functions as a lighting element together with the light scattering element.
[0222]
In the light emitting regions B1 and B2, light guided in the light guide plate 100 from the cold cathode tube 102a side is scattered by the scattering layer 116 when reflected on the facing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102a side is maintained in the light emitting regions B1 and B2, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102b side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, part of the light guided from the cold cathode tube 102 b side is not maintained in the light emitting regions B <b> 1 and B <b> 2, and is emitted outside the light guide plate 100.
[0223]
In the light emitting regions A1 and A2, light guided in the light guide plate 100 from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the opposing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b side is maintained in the light emitting regions A1 and A2, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102a side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, part of the light guided from the cold cathode tube 102 a side is not maintained in the light emitting regions A <b> 1 and A <b> 2, and is emitted outside the light guide plate 100.
[0224]
As described above, in the light emitting regions A1 and A2 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting regions B1 and B2, more light guided from the cold cathode tube 102b side. Caught. Further, the light guide plate 100 is configured so that light is extracted almost uniformly in all the light emitting areas B1, A1, B2, and A2. According to this embodiment, the same effects as those of the embodiment 5-1 can be obtained.
[0225]
(Example 5-3)
Next, a lighting device according to Example 5-3 of the present embodiment will be described with reference to FIG. FIG. 63 illustrates a cross-sectional configuration of the lighting device according to the present embodiment. As shown in FIG. 63, the light guide plate 100 has four light emitting regions A1, B1, A2, and B2 that are divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting area A1 is arranged on the cold cathode tube 102a side, and the light emitting area B1 is arranged adjacent to the light emitting area A1. A light emitting area A2 is arranged adjacent to the light emitting area B1, and a light emitting area B2 is arranged on the cold cathode tube 102b side. The light emitting areas A1, B1, A2, and B2 of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A1, B1, A2, and B2.
[0226]
In the light guide plate 100, the opposing surface 114 is inclined at a predetermined inclination angle with respect to the light exit surface 112, and is formed in a different wedge shape for each region. The light guide plate 100 of the light emitting regions A1 and A2 is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tube 102a is arranged is thick and the thickness at the side end portion where the cold cathode tube 102b is arranged is thin. Have been. The light guide plate 100 of the light emitting regions B1 and B2 is formed in a wedge shape in which the thickness at the side end portion where the cold cathode tube 102a is arranged is thin, and the thickness at the side end portion where the cold cathode tube 102b is arranged is thick. Have been. For example, the inclination angle of the facing surface 114 in the regions A2 and B1 is smaller than the inclination angle of the facing surface 114 in the regions A1 and B2. The wedge shape of the light guide plate 100 functions as a lighting element together with the light scattering element.
[0227]
In the light emitting regions B1 and B2, light guided in the light guide plate 100 from the cold cathode tube 102a side is scattered by the scattering layer 116 when reflected on the facing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102a side is maintained in the light emitting regions B1 and B2, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102b side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, part of the light guided from the cold cathode tube 102 b side is not maintained in the light emitting regions B <b> 1 and B <b> 2, and is emitted outside the light guide plate 100.
[0228]
In the light emitting regions A1 and A2, light guided in the light guide plate 100 from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the opposing surface 114. However, each time the light is reflected by the wedge shape of the light guide plate 100, it is condensed, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b side is maintained in the light emitting regions A1 and A2, and does not emit much outside the light guide plate 100. On the other hand, light guided from the cold-cathode tube 102a side is scattered by the scattering layer 116 when reflected by the facing surface 114, and the incident angle with respect to the light exit surface 112 is reduced by the wedge shape of the light guide plate 100. It gets smaller every time it is reflected. For this reason, part of the light guided from the cold cathode tube 102 a side is not maintained in the light emitting regions A <b> 1 and A <b> 2, and is emitted outside the light guide plate 100.
[0229]
As described above, in the light emitting regions A1 and A2 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting regions B1 and B2, more light guided from the cold cathode tube 102b side. Caught. Further, the light guide plate 100 is configured so that light is extracted almost uniformly in all the light emitting areas B1, A1, B2, and A2.
[0230]
According to this embodiment, the same effects as those of the embodiment 5-1 can be obtained. Also, in the liquid crystal display device using the backlight unit 130 according to the present embodiment, the timing of the luminance modulation of the cold cathode tubes 102a and 102b is reversed from the timing of the luminance modulation of the embodiment 5-1 shown in FIG. A high-luminance scan-type illumination device can be realized, and good display quality without contour blur can be obtained even when displaying a moving image.
[0231]
(Example 5-4)
Next, an illumination device according to Example 5-4 of the present embodiment will be described with reference to FIG. FIG. 64 illustrates a cross-sectional configuration of the illumination device according to the present embodiment. As shown in FIG. 64, the light guide plate 100 has four light emitting areas A1, B1, A2, and B2 that are divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting area A1 is arranged on the cold cathode tube 102a side, and the light emitting area B1 is arranged adjacent to the light emitting area A1. A light emitting area A2 is arranged adjacent to the light emitting area B1, and a light emitting area B2 is arranged on the cold cathode tube 102b side. The light emitting areas A1, B1, A2, and B2 of the light guide plate 100 are formed integrally, and no break is formed at the boundary between the light emitting areas A1, B1, A2, and B2. The opposing surface 114 of the light guide plate 100 is formed in a prism shape. The prism shape functions as a lighting element for extracting light.
[0232]
The opposing surface 114 of the light-emitting regions B1 and B2 has a prism shape in which light from the cold cathode tube 102a side does not enter the prism surface 118 and is guided to the cold cathode tube 102b side as it is. The prism surface 118 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102b enters the prism surface 118 with a certain probability. The light that has entered the prism surface 118 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0233]
The opposing surface 114 of the light emitting areas A1 and A2 has a prism shape in which light from the cold cathode tube 102b side does not enter the prism surface 119, and is guided to the cold cathode tube 102b side as it is. The prism surface 119 is formed at an inclination angle of, for example, 40 ° to 45 ° with respect to the light exit surface 112. On the other hand, light from the cold cathode tube 102a enters the prism surface 119 with a certain probability. The light that has entered the prism surface 119 exits the light guide plate 100 by reflection or refraction because the condition of total reflection is broken.
[0234]
As described above, in the light emitting regions A1 and A2 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting regions B1 and B2, more light guided from the cold cathode tube 102b side. Caught. Further, the light guide plate 100 is configured so that light is extracted almost uniformly in all the light emitting areas B1, A1, B2, and A2. According to this embodiment, the same effects as those of the embodiment 5-1 can be obtained.
[0235]
(Example 5-5)
Next, a liquid crystal display device according to Example 5-5 of the present embodiment will be described with reference to FIG. FIG. 65 shows a sectional configuration of the liquid crystal display device according to the present embodiment. As shown in FIG. 65, the liquid crystal display device according to this embodiment is of a front light type, and includes a reflective LCD panel 2 and a front light unit 131. The light guide plate 100 of the front light unit 131 has four light emitting regions B1, A1, B2, and A2 that are divided substantially in parallel to the tube axis directions of the cold cathode tubes 102a and 102b. The light emitting region B1 is arranged on the cold cathode tube 102a side, and the light emitting region A1 is arranged adjacent to the light emitting region B1. A light emitting area B2 is arranged adjacent to the light emitting area A1, and a light emitting area A2 is arranged on the cold cathode tube 102b side. The light-emitting regions B1, A1, B2, and A2 of the light guide plate 100 are integrally formed, and no break is formed at the boundary between the light-emitting regions B1, A1, B2, and A2. The opposing surface 114 of the light guide plate 100 is formed in a prism shape. The prism shape functions as a lighting element for extracting light.
[0236]
In the front light system, it is not wise to use the scattering layer 116 or the like as a lighting element. This is because the light scattered by the scattering layer 116 is not emitted in the direction perpendicular to the LCD panel 2, which causes low contrast and low luminance. In addition, since light is directly emitted to the observer side, it causes stray light and low contrast, thereby deteriorating display quality. Therefore, in this embodiment, the lighting element has a prism shape. In addition, by bonding the light guide plate 100 and the polarizing plate 141 together and further bonding the LCD panel 2, the interface reflection can be reduced and the display quality can be further improved.
[0237]
(Example 5-6)
Next, a lighting device according to Example 5-6 of the present embodiment and a liquid crystal display device using the same will be described with reference to FIGS. FIG. 66 shows a sectional configuration of the liquid crystal display device according to the present embodiment. FIG. 67 illustrates a cross-sectional configuration of the lighting device according to the present embodiment. As shown in FIGS. 66 and 67, the backlight unit 130 according to the present embodiment has two light guide plates 100 and 100 ′ arranged in a stacked manner. The light guide plates 100, 100 'have four light emitting areas B1, B2, A1, A2. A cold-cathode tube 102a is disposed on one side end surface (left end surface in FIGS. 66 and 67) of the light guide plate 100 in the lower part of the figure. A cold cathode tube 102b is arranged on the other end surface of the light guide plate 100 (the right end surface in FIGS. 66 and 67). The light guide plate 100 has a light guide region for guiding light from the cold cathode tubes 102a and 102b. The light guide plate 100 in the light emitting area B1 has a wedge shape in which the opposing surface 114 is inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102a side is thin and the thickness on the cold cathode tube 102b side is thick. Is formed. The light guide plate 100 in the light emitting region A1 has a wedge shape in which the opposing surface 114 is inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102a side is large and the thickness on the cold cathode tube 102a side is small. Is formed. A scattering layer 116 as a light scattering element is formed on the facing surface 114 of the light emitting areas A1 and B1. The light guide plate 100 has a light guide region for guiding light from the cold cathode tubes 102a and 102b.
[0238]
A cold-cathode tube 102a 'is arranged on one end surface (left end surface in FIGS. 66 and 67) of the light guide plate 100' which is stacked on the liquid crystal display panel 2 side of the light guide plate 100. A cold cathode tube 102b 'is disposed on the other end surface of the light guide plate 100' (the right end surface in FIGS. 66 and 67). The light guide plate 100 'has a light guide region for guiding light from the cold cathode tubes 102a' and 102b '. The light guide plate 100 ′ in the light emitting region B 2 has a facing surface 114 inclined with respect to the light emitting surface 112 so that the thickness on the cold cathode tube 102 a ′ side is small and the thickness on the cold cathode tube 102 b ′ side is large, It is formed in a wedge shape. The light guide plate 100 ′ in the light emitting area A 2 has the opposing surface 114 inclined with respect to the light exit surface 112 so that the thickness on the cold cathode tube 102 a ′ side is large and the thickness on the cold cathode tube 102 b ′ side is small. , Formed in a wedge shape. A scattering layer 116 as a light scattering element is formed on the facing surface 116 of the regions A2 and B2.
[0239]
In the light emitting region B1 of the light guide plate 100, light guided from the cold cathode tube 102b side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the light exit surface 112 is formed by the wedge shape of the light guide plate 100. Becomes smaller each time the light is reflected by the facing surface 114. For this reason, most of the light guided from the cold cathode tube 102b side is not maintained in the light emitting region B1 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102a to the light emitting region B1 is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102 a to the light emitting region B 1 is maintained in the light emitting region B 1, and hardly exits outside the light guide plate 100. That is, in the light emitting region B1 of the light guide plate 100, (light intensity from the cold cathode tube 102b side / light intensity from the cold cathode tube 102b side)> (light intensity from the cold cathode tube 102a side / light from the cold cathode tube 102a side) Light guide light).
[0240]
In the light emitting region A1 of the light guide plate 100, light guided from the cold cathode tube 102a side is scattered by the scattering layer 116 when reflected on the facing surface 114, and the light exit surface 112 is formed by the wedge shape of the light guide plate 100. Becomes smaller each time the light is reflected by the facing surface 114. For this reason, most of the light guided from the cold cathode tube 102 a side is not maintained in the light emitting region A <b> 1 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102b to the light emitting region A1 is scattered by the scattering layer 116 when reflected by the facing surface 114, but is collected every time the light is reflected by the wedge shape of the light guide plate 100. The light is emitted, and the angle of incidence on the light exit surface 112 increases. Therefore, the light guided from the cold cathode tube 102b side to the light emitting region A1 is maintained in the light emitting region A1 and is hardly emitted outside the light guide plate 100. That is, in the light emitting region A1 of the light guide plate 100, (light intensity from the cold cathode tube 102a side / light intensity from the cold cathode tube 102a side)> (light intensity from the cold cathode tube 102b side / light from the cold cathode tube 102b side) Light guide light).
[0241]
In the light emitting region B2 of the light guide plate 100 ', light guided from the cold cathode tube 102b' side is scattered by the scattering layer 116 when reflected on the opposing surface 114, and light is emitted by the wedge shape of the light guide plate 100. Each time the incident angle with respect to the surface 112 is reflected by the opposing surface 114, the angle decreases. For this reason, most of the light guided from the cold cathode tube 102b 'side is not maintained in the light emitting region B2 and is emitted outside the light guide plate 100. On the other hand, light guided from the cold cathode tube 102a 'side to the light emitting region B2 is scattered by the scattering layer 116 when reflected by the facing surface 114, but every time light is reflected by the wedge shape of the light guide plate 100. The light is condensed and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102 a ′ to the light emitting region B 2 is maintained in the light emitting region B 2, and hardly exits outside the light guide plate 100. That is, in the light emitting area B2 of the light guide plate 100 ', (light intensity from the cold cathode tube 102b' side / light intensity from the cold cathode tube 102b 'side)> (light intensity from the cold cathode tube 102a' side / cold cathode) (A guide light amount from the tube 102a 'side).
[0242]
In the light emitting region A2 of the light guide plate 100 ', light guided from the cold cathode tube 102a' side is scattered by the scattering layer 116 when reflected on the facing surface 114, and light is emitted by the wedge shape of the light guide plate 100. Each time the incident angle with respect to the surface 112 is reflected by the opposing surface 114, the angle decreases. For this reason, most of the light guided from the cold cathode tube 102a 'side is not maintained in the light emitting region A2 and is emitted outside the light guide plate 100. On the other hand, the light guided from the cold cathode tube 102b ′ to the light emitting region A2 is scattered by the scattering layer 116 when reflected by the facing surface 114, but the light is reflected by the wedge shape of the light guide plate 100 every time. The light is condensed and the angle of incidence on the light exit surface 112 increases. For this reason, the light guided from the cold cathode tube 102b ′ to the light emitting region A2 is maintained in the light emitting region A2 and does not emit much outside the light guide plate 100. That is, in the light-emitting region B2 of the light guide plate 100 ', (light intensity from the cold cathode tube 102a' side / light intensity from the cold cathode tube 102a 'side)> (light intensity from the cold cathode tube 102b' side / cold cathode) (A guide light amount from the tube 102b 'side).
[0243]
The light-emitting regions B2 and A2 of the light guide plate 100 are non-light-receiving regions that hardly extract both light from the cold-cathode tube 102a and light from the cold-cathode tube 102b. The light-emitting regions B1 and A1 of the light guide plate 100 'are non-light-receiving regions that hardly take out both light from the cold-cathode tube 102a' and light from the cold-cathode tube 102b '.
[0244]
Thus, in the light emitting region A1 of the light guide plate 100, more light guided from the cold cathode tube 102a side is extracted, and in the light emitting region B1, more light guided from the cold cathode tube 102b side is extracted. In the light emitting region A2 of the light guide plate 100 ', more light guided from the cold cathode tube 102a' side is extracted, and in the light emitting region B2, more light guided from the cold cathode tube 102b 'side is extracted. When the light guide plates 100 and 100 'are stacked and arranged, light is almost uniformly extracted from all the light emitting regions B1, A1, B2 and A2.
[0245]
FIG. 68 shows a lighting device according to the present embodiment and a method for driving a liquid crystal display device using the lighting device. The horizontal axis represents time, and the vertical axis represents the write state ((write / non-write)) of the gradation data and the blinking state (ON / OFF) of the backlight unit 130. The waveform a indicates the light emitting area B1. , The waveform b shows the state of writing the grayscale data in the area B2, the waveform c shows the state of writing the grayscale data in the area A1, and the waveform d shows the state of writing the grayscale data in the area A2. The waveform e shows the blinking state of the cold cathode tube 102b, the waveform f shows the blinking state of the cold cathode tube 102b ', and the waveform g shows the blinking state of the cold cathode tube 102b. A blinking state of the cold cathode tube 102a 'is shown by a waveform h.
[0246]
As shown in FIG. 68, the light source control unit 132 (not shown in FIG. 66) synchronizes the cold cathode fluorescent lamps 102a, 102b, 102a ', and 102b' with the frame frequency (for example, 60 Hz) in synchronization with the latch pulse signal LP. Light is emitted for a predetermined time at the blinking frequency. Further, the light source control unit 132 makes the timing of maximizing the light emission luminance of the cold cathode tube 102b and the timing of maximizing the light emission luminance of the cold cathode tube 102b ′ different by about 4.2 msec (（cycle). ing. Similarly, the timing for maximizing the light emission luminance of the cold cathode tube 102b 'differs from the timing for maximizing the light emission luminance of the cold cathode tube 102a by about 4.2 msec, and thus maximizing the light emission luminance of the cold cathode tube 102a. The timing differs from the timing at which the light emission luminance of the cold cathode tube 102a 'is maximized by about 4.2 msec. The timing for maximizing the light emission luminance of the cold cathode tube 102a 'is different from the timing for maximizing the light emission luminance of the cold cathode tube 102b by about 4.2 msec.
[0247]
After a lapse of a predetermined time from the writing of the gradation data to the pixels in the area B1, the cold cathode tube 102b that emits light in the light emitting area B1 is turned on. After the cold-cathode tube 102b is turned off, gradation data is written to the pixels in the area B1. After a lapse of a predetermined time from the writing of the gradation data to the pixels in the area B2, the cold cathode tube 102b 'for emitting light in the light emitting area B2 is turned on. After the cold-cathode tube 102b 'is turned off, gradation data is written to the pixels in the area B2. Similarly, after a lapse of a predetermined time from the writing of the gradation data to the pixels in the area A1, the cold-cathode tube 102a that emits light in the light emitting area A1 is turned on. After the cold-cathode tube 102a is turned off, gradation data is written to the pixels in the area A1. After a lapse of a predetermined time from the writing of the gradation data to the pixels in the area A2, the cold-cathode tube 102a 'for emitting light in the light-emitting area A2 is turned on. After the cold-cathode tube 102a 'is turned off, gradation data is written to the pixels in the area A2.
[0248]
As described above, the cold-cathode tube that illuminates the area where the gradation data is written is turned off. In the liquid crystal display device, since it takes several msec to several tens of msec from the time when the gradation data is written to the pixel to the time when the liquid crystal molecules are tilted at the predetermined tilt angle, the gradation data is written in a certain region and then the region is written. If the time until the cold-cathode tube illuminating the LED lights up is secured as much as possible, a good moving image display quality can be obtained. For this reason, in this embodiment, the writing of the gradation data is started immediately after the cold cathode tube 102a is turned off.
[0249]
According to this embodiment, the same effects as those of the embodiment 5-1 can be obtained. Further, in the present embodiment, unlike the example 5-1, a multi-scan type liquid crystal display device is not required, so that a scan type lighting device and a liquid crystal display device can be realized without complicating a driving circuit. In the present embodiment, the light guide plates 100 and 100 'have the light-emitting areas A1, A2, B1, and B2 divided into four, but the number of divisions is arbitrary.
[0250]
According to the present embodiment, it is possible to realize a scan-type lighting device and a liquid crystal display device which are easy to configure, are small, thin, and lightweight, and have uniform luminance and color. Further, according to the present embodiment, it is possible to realize a liquid crystal display device which is free from contour blur and excellent in moving image quality.
[0251]
[Sixth Embodiment]
A lighting device according to a sixth embodiment of the present invention and a liquid crystal display device using the same will be described with reference to FIGS. The present embodiment has a feature in a polarizing plate attached to a liquid crystal display device or a lighting device used therein, and a manufacturing method in a case where the polarizing plate is attached to a panel surface of the liquid crystal display device or a light guide plate of the lighting device. It has features.
[0252]
Generally, in a transmissive liquid crystal display device, the transmittance of light incident from the back of the liquid crystal panel is modulated by a liquid crystal layer and emitted to the panel surface, and a backlight unit is arranged on the back side of the liquid crystal panel as a lighting device. ing. On the other hand, in a reflection type liquid crystal display device used for mobile applications, external light enters from the liquid crystal panel surface, passes through the liquid crystal layer, is reflected by the reflective electrode, is modulated by the liquid crystal layer, and is emitted to the panel surface. Has become.
[0253]
Generally, in a reflection type liquid crystal display device, a front light unit (for example, see Example 5-5 of the fifth embodiment (see FIG. 65)) is provided on the liquid crystal panel surface side as an auxiliary illumination light source when external light is small. Are located. The front light unit has a transparent plate-shaped light guide plate disposed on the liquid crystal panel surface side, and a light source disposed on at least one side surface of the light guide plate. A prism is formed on the surface side (external light incident side) of the light guide plate at a small pitch of, for example, 1 mm or less, so that light incident from a light source on the side of the light guide plate is reflected or refracted in an in-plane direction and propagates. Meanwhile, almost vertical light is emitted to the entire surface of the liquid crystal panel. Since the light guide plate needs to have high transmittance, be easily molded, and be lightweight, the same acrylic material as the light guide plate for the backlight unit is frequently used.
[0254]
A polarizing plate is arranged between the light exit surface of the light guide plate on the liquid crystal panel surface side and the liquid crystal panel surface. When this polarizing plate is attached to the light exit surface of the light guide plate on the liquid crystal panel surface side, unnecessary light incident from the light guide plate to the liquid crystal panel surface at a relatively large incident angle is absorbed, and the image quality is deteriorated (black floating, etc.). And a display with high contrast can be obtained.
[0255]
Since the front light unit is mainly used in a small liquid crystal display device, the light guide plate needs to be reduced in weight and size. For this reason, the light guide plate is formed of an extremely thin plate having a thickness of about 1 mm, and has a structure that is easily deformed. On the other hand, the polarizing plate attached to the light guide plate undergoes heat shrinkage of 0.3 to 0.5% at a high temperature. Therefore, there is a problem that the light guide plate is deformed when the polarizing plate thermally contracts at a high temperature. For example, when the liquid crystal display device is left at a high temperature for one day, such as being left in a car on a summer day, the polarizing plate shrinks and the light guide plate is bent. Because it is maintained, the deformation of the light guide plate remains. A protective cover is provided on the outside light incident side of the light guide plate of the front light unit so as not to contaminate the surface prism of the light guide plate, but when the light guide plate is bent and hits this protective cover, both are rubbed. The light guide plate is scratched, and adversely affects display quality such as uneven brightness. If the distance between the light guide plate and the protective cover is increased beforehand to avoid this, an interval of about 5 mm is required, which increases the thickness of the device. In addition, when the light guide plate itself is deformed, the center of the light guide plate becomes a bulge with a mountain, and moiré fringes having a round shape are generated, thereby deteriorating display quality.
[0256]
In order to solve this problem, the present embodiment has found that the heat shrinkage of the polarizing plate is irreversible and that the heat shrinkage is saturated at 0.3 to 0.5%. I used it after irreversible contraction. The heat treatment is performed by leaving the polarizing plate in a predetermined temperature environment for a certain period of time. At this time, if the heat treatment temperature is set to 100 ° C. or more, care must be taken because the polarizing plate itself is deteriorated, the degree of polarization is rapidly reduced, and the display contrast is reduced. If the heat treatment temperature is 40 ° C. or less, the heat shrinkage of the polarizing plate progresses slowly, so that a long time is required for the heat treatment.
[0257]
By giving an appropriate heat treatment to the polarizing plate while taking into account such a heat treatment temperature range, the amount of deformation of the light guide plate can be reduced even when the liquid crystal display device is left at a high temperature. The volume of the device can be reduced by reducing the distance of the protective cover. In addition, since the deformation of the light guide plate can be reduced, the deterioration of display quality due to moire fringes can be reduced. Further, when the ambient temperature returns to room temperature, the deformation of the light guide plate returns to its original state, so that the display quality does not deteriorate.
[0258]
Hereinafter, a description will be given using specific examples. FIG. 69 shows a method of manufacturing the lighting device according to the present embodiment. As shown in FIG. 69, first, in a polarizing plate heat treatment step 91, the polarizing plate is heated at a predetermined temperature in a thermostat. Thereafter, the temperature is returned to room temperature, and then the process proceeds to the step of sticking to the light guide plate 92, and the polarizing plate is stuck on the surface of the light guide plate by the sticking machine. Next, an autoclave treatment is performed (autoclave treatment step 93). Next, in a lamp assembly mounting step 94, a light source or the like is mounted on the light guide plate to complete the front light.
[0259]
Next, conditions for suitably performing the above-described polarizing plate heat treatment step 91 will be described in detail. First, a change in the wavelength at which the transmittance of the absorption axis of the polarizing plate becomes 50% (hereinafter referred to as a cut wavelength shift amount) and a change in the shrinkage rate were examined according to the heat treatment temperature and the heat treatment time (see FIG. 70). Many polarizing plates have an upper limit of use temperature of about 70 ° C. recommended by the manufacturer, and it is known that when the temperature is higher than that, the deterioration of the polarizing plate is accelerated. The deterioration of the polarizing plate is a deterioration of the degree of polarization, and the degree of deterioration can be determined by measuring the cut wavelength of the absorption axis and examining the shift (see FIG. 71).
[0260]
FIG. 70 shows a change in cut wavelength of the absorption axis of the polarizing plate with respect to the heat treatment time in the heat treatment of the polarizing plate in the lighting device according to the present embodiment. The horizontal axis represents the heat treatment time (hr), and the vertical axis represents the cut wavelength shift (nm). In the drawing, broken lines with a short pitch represent data at a heat treatment temperature of 50 ° C. for the polarizing plate. Similarly, the alternate long and short dash line represents data at a heat treatment temperature of 60 ° C., the thin solid line represents data at a heat treatment temperature of 70 ° C., and the long pitch dashed line represents data at a heat treatment temperature of 100 ° C. Also, the thick solid line indicates the cut wavelength shift amount of the polarizing plate used in the 17-inch liquid crystal display device, and is data for comparison in which a polarizing plate without heat treatment was attached to the light guide plate. It is shown.
[0261]
As shown in FIG. 70, the cut wavelength shift amount of “inside the 17-type device” indicated by the thick solid line was −6 nm for the heat treatment of 500 hr and −11 nm for the heat treatment of 1000 hr. On the other hand, in a polarizing plate that has been heat-treated at a temperature of 50 ° C. or higher, the higher the heat-treatment temperature, the greater the amount of shift of the cut wavelength in the same heat-treatment time, and the faster the deterioration. Here, if the heat treatment temperature is 70 ° C. or less and the heat treatment time is up to 50 hours, the cut wavelength shift amount is −11 nm or less, and the data of “inside the 17-inch device” corresponds to the deterioration of 1000 hours at the maximum. You can see that. This 1000 hr is 3% of the lifetime of the 17-inch liquid crystal display device, and was set as an allowable range as the amount of deterioration in the heat treatment of the polarizing plate.
[0262]
FIG. 71 shows the transmission characteristics in the absorption axis direction of the polarizing plate when the polarizing plate is heat-treated at 70 ° C. in the lighting device according to the present embodiment. The horizontal axis represents the wavelength (nm) and the vertical axis represents the transmittance (%). In the figure, the solid line shows the transmission characteristics when the heat treatment time is 200 hours, and the broken line shows the transmission characteristics when the heat treatment time is 0 hours (that is, no heat treatment). The cut wavelength of the absorption axis of the polarizing plate is reduced from about 810 nm to about 785 nm as compared with the case without heat treatment.
[0263]
FIG. 72 shows a change in the shrinkage ratio of the polarizing plate with respect to the heat treatment time in the lighting device according to the present embodiment. The horizontal axis represents the heat treatment time (hr), and the vertical axis represents the shrinkage. The solid line in the figure shows the case where the heat treatment temperature is 70 ° C., and the broken line shows the case where the heat treatment temperature is 60 ° C. The shrinkage ratio of the polarizing plate was measured by measuring the length of the vertical and horizontal sides of the polarizing plate before and after the heat treatment, and calculating the average of the change with respect to the original length. The higher the heat treatment temperature, the faster the polarizing plate shrinks. Therefore, in this example, heat treatment temperatures of 60 ° C. and 70 ° C. are shown. When the heat treatment time is 100 hours or more, the heat shrinkage ratios of the two become the same, but the heat shrinkage speed is faster when the heat treatment temperature is 70 ° C., and the shrinkage of the polarizing plate is almost saturated by the process of 40 to 50 hours. As described above, it is clear that the heat treatment time within 50 hours is also preferable for the cut wavelength shift amount of the absorption axis of the polarizing plate shown in FIG. 70, so that the heat treatment at a heat treatment temperature of 70 ° C. is appropriate. From FIG. 72, if the heat treatment temperature is set to 70 ° C., a heat treatment time of 40 hr at which the heat shrinkage is substantially saturated is desirable.
[0264]
Then, the polarizing plate heat-treated at a heat treatment temperature of 70 ° C. and a heat treatment time of 40 hr was attached to the light guide plate, and the deformation amount of the light guide plate was measured using a thermal shock tester. Specifically, a front light unit having a light source attached to an end of a light guide plate to which a polarizing plate is attached is fixed on four sides on a liquid crystal panel, and is heated at a temperature of 60 ° C. for 25 minutes and at a temperature of −20 ° C. for 35 minutes. Was subjected to a thermal shock test. The amount of deformation of the light guide plate was determined as the amount of deformation by measuring the distance between the most protruding portion at the center of the light guide plate and the edge of the light guide plate.
[0265]
FIG. 73 shows the relationship between the thermal shock test time and the amount of deformation of the light guide plate in the lighting device according to the present embodiment. The horizontal axis represents the thermal shock test time (hr), and the vertical axis represents the amount of deformation (mm) of the light guide plate. In the figure, a solid line represents a polarizing plate that has been subjected to a heat treatment, and a broken line represents a polarizing plate that has not been subjected to a heat treatment.
[0266]
The conventional polarizing plate without heat treatment (dashed line) had a deformation amount of 4.6 mm at a heat shock test time of 600 hr, whereas the heat treated polarizing plate (solid line) had a deformation amount of 1.0 mm at a shock test time of 600 hr. Thus, the deformation was suppressed to 39% of the conventional one.
[0267]
As described above, according to the present embodiment, the front light unit is manufactured by applying an appropriate heat treatment to the polarizing plate to cause irreversible heat shrinkage in advance and then attaching the polarizing plate to the light guide plate. In particular, it is preferable that the amount of heat shrinkage α be in the range of 0 <α ≦ 0.3%. By doing so, even when the liquid crystal display device is left at a high temperature, the amount of deformation of the light guide plate can be greatly reduced. Therefore, the distance between the light guide plate and the protective cover can be reduced by 1 to 2 mm, and the volume of the device can be reduced. Further, since the amount of deformation of the light guide plate is small, moire fringes are also light, and when the ambient temperature returns to room temperature, the light is deformed and returns to its original shape, so that display quality does not deteriorate.
[0268]
Note that, in the present embodiment, the case where the polarizing plate is attached to the light exit surface on the liquid crystal panel surface side of the light guide plate of the front light unit has been described as an example, but in addition to this, on the outside light incident surface side of the light guide plate. The present embodiment can be applied to a case where a light guide plate is attached, a case where the light guide plate is attached to a liquid crystal panel surface, or a case where the light guide plate is attached to a light guide plate of a backlight unit.
[0269]
Further, specifically showing the configuration of the polarizing plate, for example, a polarizing film alone obtained by stretching polyvinyl alcohol (PVA) and dyeing with iodine, or a triacetyl cellulose (TAC) film as a protective film on both sides of the polarizing film, for example, may be used. There is a polarizing plate having an attached structure, or a polarizing plate further laminated with a retardation film having a different linear expansion coefficient or the like. This embodiment is applicable to all of these polarizing plates.
[0270]
The present invention is not limited to the above embodiment, and various modifications are possible.
For example, in the above embodiment, an active matrix type liquid crystal display device has been described as an example, but the present invention is not limited to this, and can be applied to a simple matrix type liquid crystal display device.
[0271]
Further, in the above embodiment, the case where the light emitting region is divided into four regions has been mainly described, but the present invention is not limited to this, and the region can be divided by an arbitrary number of divisions.
[0272]
Furthermore, in the above-described embodiment, the TN mode liquid crystal display device has been described as an example, but the present invention is not limited to this, and can be applied to other liquid crystal display devices such as an MVA mode and an IPS mode.
[0273]
The illumination device according to the first embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Appendix 1)
An illumination device for illuminating a display area of an active matrix liquid crystal display device,
At least one light source capable of changing light emission brightness;
At least one light emitting region for emitting light from the light source;
A lighting device, comprising: a light source power supply circuit that switches between a maximum lighting state in which the light source emits light at a predetermined maximum luminance and an intermediate lighting state in which light emission occurs at a predetermined intermediate luminance lower than the maximum luminance.
[0274]
(Appendix 2)
In the lighting device according to Supplementary Note 1,
The illuminating region has a light emitting opening which is arranged substantially parallel to a direction in which a gate bus line formed in the liquid crystal display device extends when illuminating the display region. apparatus.
[0275]
(Appendix 3)
In the lighting device according to Supplementary Note 1 or 2,
The light source power supply circuit switches between the maximum lighting state and the intermediate lighting state in synchronization with one of gate pulses sequentially output to a plurality of gate bus lines formed in the liquid crystal display device. Lighting equipment.
[0276]
(Appendix 4)
In the lighting device according to any one of supplementary notes 1 to 3,
The lighting device, wherein the intermediate lighting state is set to a luminance level equal to or less than 50% of a luminance level of the maximum lighting state.
[0277]
(Appendix 5)
In the lighting device according to any one of supplementary notes 1 to 4,
The lighting device, wherein the lighting time in the maximum lighting state is 50% or less of one frame period.
[0278]
The illumination device according to the second embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Appendix 6)
The lighting device according to any one of supplementary notes 1 to 5,
A first light source comprising a first light guide plate and a first light source disposed at an end thereof, mainly illuminating the first light emitting region and supplying a part of light to an adjacent second light emitting region. Unit and
A second light guide plate stacked on the first light source unit and a second light source disposed at an end thereof, the second light guide plate mainly illuminating the second light emitting region, and the first light emitting region adjacent thereto; A second light source unit for supplying a part of light to the
A lighting device, comprising:
[0279]
(Appendix 7)
The lighting device according to attachment 6, wherein
The first light guide plate is disposed in the first and second light emitting areas,
The lighting device according to claim 1, wherein the second light guide plate is disposed only in the first light emitting region.
[0280]
(Appendix 8)
The lighting device according to attachment 7, wherein
A third light source including a third light guide plate and a third light source disposed at an end thereof, mainly illuminating the third light emitting region and supplying a part of light to an adjacent fourth light emitting region Unit and
A fourth light guide plate stacked on the third light source unit and a fourth light source disposed at an end thereof, the fourth light guide plate mainly illuminating the fourth light emitting region, and the third light emitting region adjacent thereto; And a fourth light source unit that supplies a part of light to the lighting device.
[0281]
(Appendix 9)
The lighting device according to attachment 8, wherein
The third light guide plate is disposed in the third and fourth light emitting areas,
The lighting device according to claim 1, wherein the fourth light guide plate is disposed only in the fourth light emitting region.
[0282]
(Appendix 10)
The lighting device according to attachment 9, wherein
The first light guide plate and the fourth light guide plate are arranged on the same plane,
The lighting device according to claim 1, wherein the second light guide plate and the third light guide plate are arranged on the same plane.
[0283]
(Appendix 11)
The lighting device according to attachment 10, wherein
A transmission type diffusion plate disposed on the first to fourth illumination regions;
An illumination device, further comprising: a light mixing area disposed between the first to fourth illumination areas and the transmissive diffusion plate.
[0284]
(Appendix 12)
The lighting device according to attachment 11, wherein
The lighting device, wherein the light mixing region is a space or a transparent member having a thickness of 0.5 mm to 10 mm.
[0285]
(Appendix 13)
13. The lighting device according to any one of supplementary notes 10 to 12, wherein
An illumination device, wherein a double-sided reflection plate that performs regular reflection or diffuse reflection is disposed between opposed ends of the second light guide plate and the third light guide plate.
[0286]
(Appendix 14)
The lighting device according to attachment 13, wherein
A lighting device characterized in that a space between opposing ends of the second light guide plate and the third light guide plate is formed in a Λ shape that opens to the back side.
[0287]
(Appendix 15)
The lighting device according to attachment 14, wherein
The apex angle θ of the Λ shape is given by n
θ ≦ 180 ° -4 × sin ^-1 (1 / n)
A lighting device characterized by satisfying the following.
[0288]
(Appendix 16)
In the lighting device according to any one of supplementary notes 1 to 15,
The lighting device according to claim 1, wherein the light source power supply circuit includes a brightness adjustment volume for adjusting brightness of light emitted from the light emitting region.
[0289]
(Appendix 17)
In an active matrix type liquid crystal display device,
A liquid crystal display device comprising the lighting device according to any one of supplementary notes 1 to 16.
[0290]
The lighting device according to the third embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Appendix 18)
An LCD panel that modulates the light transmittance of a plurality of pixels arranged in a matrix based on each gradation data;
An illuminating device that irradiates each pixel with light by changing a ratio (duty ratio) of a lighting time during one frame period;
Calculate the respective brightness and brightness histogram from each of the tone data, determine a threshold brightness from the brightness histogram based on a predetermined pixel ratio of luminance saturation, and process each of the tone data based on the threshold brightness. A display data converter for outputting the duty ratio data for changing the duty ratio to the lighting device while outputting the duty ratio data to the LCD panel.
[0291]
(Appendix 19)
The liquid crystal display device according to attachment 18, wherein
The display data conversion unit,
The liquid crystal display device, wherein the threshold brightness is determined by counting the brightness from the brightness histogram in descending order of brightness based on the ratio of the pixels to be saturated with the brightness.
[0292]
(Appendix 20)
The liquid crystal display device according to attachment 19,
The display data conversion unit,
M (M ≦ N) pixels for which an image is displayed among the N pixels in the one frame are determined, and the threshold brightness is determined based on a product of the number of M pixels and the ratio of the pixels to be saturated with luminance. A liquid crystal display device characterized by determining:
[0293]
(Appendix 21)
21. The liquid crystal display device according to any one of supplementary notes 18 to 20, wherein
The display data conversion unit,
The duty ratio is determined so that the product of the maximum possible value of the grayscale data and the duty ratio is equal to the threshold brightness, and the grayscale data of a pixel having brightness equal to or higher than the threshold brightness becomes the maximum value. In other pixels, processing is performed so that the product of the processed gradation data and the determined duty ratio is equal to the brightness of the original gradation data of the pixel. Liquid crystal display.
[0294]
The lighting device according to the fourth embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Appendix 22)
The lighting device according to any one of supplementary notes 1 to 5,
Comprising a plurality of the light sources in the light emitting area,
The light source control system controls a current flowing through each of the plurality of light sources, and a maximum lighting state in which the light emitting region emits light at a predetermined maximum luminance, and an intermediate lighting state in which the light emitting area emits light at a predetermined intermediate luminance lower than the maximum luminance. And a lighting device characterized by switching.
[0295]
(Appendix 23)
The lighting device according to Supplementary Note 22, wherein
The light source control system includes:
With respect to at least one of the plurality of light sources, the current is turned on in the predetermined lighting cycle in a predetermined cycle, and turned off in other cases,
A lighting device, characterized in that an electric current is supplied to the remaining light sources so as to be turned off at the time of the maximum lighting state and to be at the intermediate lighting state at other times.
[0296]
(Appendix 24)
The lighting device according to Supplementary Note 22, wherein
The light source control system includes:
At least one of the plurality of light sources is set to a first intermediate lighting state lower than the maximum lighting state at a predetermined cycle, and a second intermediate lighting state lower than the first intermediate lighting state otherwise. Apply current so that
For the remaining light sources, the third intermediate lighting state is set so that the illumination area is the maximum lighting state in the first intermediate lighting state, and the illumination area is in the second intermediate lighting state. A lighting device characterized in that a current is supplied so as to be in a fourth intermediate lighting state so as to be in an intermediate lighting state.
[0297]
(Appendix 25)
The lighting device according to Supplementary Note 22, wherein
The light source control system includes:
A current is applied to at least one of the plurality of light sources so as to always be in the intermediate lighting state,
A lighting device, characterized in that a current is supplied to the remaining light sources so that the lighting area is in the maximum lighting state at a predetermined cycle and is turned off at other times.
[0298]
(Supplementary Note 26)
26. The lighting device according to any one of supplementary notes 22 to 25,
The light source control system includes:
A lighting device, wherein current is controlled so that a light-off state is provided between the maximum lighting state and the intermediate lighting state thereafter.
[0299]
(Appendix 27)
26. The lighting device according to any one of supplementary notes 22 to 25,
The light source control system includes:
A lighting device, wherein a current is controlled between the maximum lighting state and the subsequent intermediate lighting state so that a lighting state lower than the intermediate lighting state is achieved.
[0300]
(Appendix 28)
In an active matrix type liquid crystal display device,
28. A liquid crystal display device comprising the lighting device according to any one of Supplementary Notes 22 to 27.
[0301]
The lighting device according to the fifth embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Appendix 29)
First and second linear light sources;
A first light-emitting region including a first light-receiving element for mainly extracting light guided from the first linear light source to the outside; and a light-emitting region mainly including light guided from the second linear light source. A light guide plate comprising: a second light emitting region having a second daylighting element for extracting light to the outside;
The first and second linear light sources are turned on at a predetermined blinking frequency and at different timings for substantially the same lighting time, or the first and second linear light sources are different from each other at a predetermined blinking frequency. A light source driving circuit for lighting only for the lighting time.
[0302]
(Appendix 30)
The lighting device according to attachment 29, wherein
The lighting device according to claim 1, wherein the first and second lighting elements include a prism shape formed on a surface of the light guide plate.
[0303]
(Appendix 31)
The lighting device according to Supplementary Note 29 or 30, wherein
The lighting device according to claim 1, wherein the first and second lighting elements include a light scattering element formed on a surface of the light guide plate.
[0304]
(Supplementary Note 32)
33. The lighting device according to any one of Supplementary Notes 29 to 31,
The lighting device, wherein the first and second lighting elements include a wedge shape of the light guide plate.
[0305]
(Appendix 33)
33. The lighting device according to any one of Supplementary Notes 29 to 32,
The light guide plate has a plurality of the first and second light emitting regions, respectively.
The lighting device according to claim 1, wherein the first and second light emitting regions are alternately arranged.
[0306]
(Supplementary Note 34)
34. The lighting device according to any one of Supplementary Notes 29 to 33,
The first linear light source is disposed close to the second light emitting region,
The lighting device according to claim 1, wherein the second linear light source is disposed close to the first light emitting region.
[0307]
(Appendix 35)
34. The lighting device according to any one of Supplementary Notes 29 to 33,
The first linear light source is disposed close to the first light emitting region,
The lighting device according to claim 1, wherein the second linear light source is disposed close to the second light emitting region.
[0308]
(Appendix 36)
36. The lighting device according to any one of supplementary notes 29 to 35,
A first light guiding region for guiding light from the first linear light source to the first light emitting region, and a light guiding region for guiding light from the second linear light source to the second light emitting region. A second light guide region that emits light,
The lighting device according to claim 1, wherein the first and second light guide regions are provided on a single light guide plate.
[0309]
(Appendix 37)
36. The lighting device according to any one of supplementary notes 29 to 35,
A first light guiding region for guiding light from the first linear light source to the first light emitting region, and a light guiding region for guiding light from the second linear light source to the second light emitting region. A second light guide region that emits light,
The lighting device according to claim 1, wherein the first and second light guide regions are provided on a plurality of the light guide plates arranged in a stacked manner.
[0310]
(Appendix 38)
A liquid crystal display panel including a pair of substrates and liquid crystal sealed between the pair of substrates, a driving circuit that supplies a predetermined driving signal to the liquid crystal display panel, and an illumination device that illuminates the liquid crystal display panel. In a liquid crystal display device having
38. A liquid crystal display device, wherein the lighting device according to any one of supplementary notes 29 to 37 is used.
[0311]
(Appendix 39)
38. The liquid crystal display device according to claim 38, wherein
The liquid crystal display device, wherein the blinking frequency is equal to a frame frequency of the liquid crystal display panel.
[0312]
(Appendix 40)
38. The liquid crystal display device according to claim 38 or 39,
The liquid crystal display device, wherein the first and second light emitting areas are arranged in a scanning direction of the display area.
[0313]
(Appendix 41)
41. The liquid crystal display device according to any one of supplementary notes 38 to 40,
The liquid crystal display device, wherein the driving circuit performs multi-scan of the liquid crystal display panel.
[0314]
(Appendix 42)
23. The liquid crystal display device according to any one of supplementary notes 18 to 22, wherein
The brightness is obtained from the gradation data (R, G, B) of each pixel as brightness Y = r × R + g × G + b × B (r, g, b include real numbers and numerical values 0). Liquid crystal display device.
[0315]
The lighting device according to the sixth embodiment described above and the liquid crystal display device using the same are summarized as follows.
(Supplementary Note 43)
A polarizing plate, which has been heat-shrinked before being attached to a light guide plate surface of a lighting device or a liquid crystal panel surface of a liquid crystal display device.
[0316]
(Appendix 44)
The polarizing plate according to attachment 43, wherein
A polarizing plate comprising a polarizing film and protective films attached to both surfaces thereof, wherein at least the polarizing film is heat-shrinked in advance.
[0317]
(Appendix 45)
The polarizing plate according to Supplementary Note 44, wherein
A polarizing plate, further comprising a retardation film.
[0318]
(Appendix 46)
The polarizing plate according to any one of Supplementary Notes 43 to 45,
The amount of thermal shrinkage α is 0 <α ≦ 0.3%.
[0319]
(Appendix 47)
A lighting device having a light guide plate to which a polarizing plate is attached,
47. A lighting device, wherein the polarizing plate according to any one of supplementary notes 43 to 46 is used as the polarizing plate.
[0320]
(Appendix 48)
The lighting device according to attachment 47, wherein
The lighting device, wherein the polarizing plate is attached to a surface of the light guide plate on the liquid crystal panel side when combined with a liquid crystal panel.
[0321]
(Appendix 49)
A liquid crystal display device having a panel surface to which a polarizing plate is attached,
47. A liquid crystal display device, wherein the polarizing plate according to any one of supplementary notes 43 to 46 is used as the polarizing plate.
[0322]
(Appendix 50)
In an active matrix type liquid crystal display device,
A liquid crystal display device comprising the lighting device described in Supplementary Note 47 or 48.
[0323]
【The invention's effect】
As described above, according to the present invention, it is possible to realize a lighting device and a liquid crystal display device using the lighting device, which can reduce motion blur and tailing in moving image display while suppressing a decrease in display luminance.
Further, according to the present invention, it is possible to realize a lighting device and a liquid crystal display device using the lighting device, in which power consumption can be suppressed, the device can be reduced in size and weight, and the life can be increased.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a lighting device according to a first embodiment of the present invention and a liquid crystal display device using the same.
FIG. 2 shows a gate output from a gate driver 12 to each gate bus line 6 in synchronization with an input of a latch pulse signal LP in the illumination device and the liquid crystal display device using the same according to the first embodiment of the present invention. It is a figure which shows the output timing of the pulse GP, and the light emission brightness | luminance B (25) -B (28) of each light emission area | region 25-28.
FIG. 3 shows a TFT-LCD 1 shown in FIG. 1 in which the lighting period and the intermediate brightness level at the maximum lighting brightness are changed in the lighting device and the liquid crystal display device using the lighting device according to the first embodiment of the present invention. FIG. 8 is a diagram showing display quality when a moving image is displayed in a display area of FIG. 7 as subjective evaluations by a plurality of observers.
FIG. 4 is a diagram showing a schematic configuration of a lighting device and a liquid crystal display device using the same according to a second embodiment of the present invention.
FIG. 5 is a diagram showing a schematic configuration of a lighting device according to a second embodiment of the present invention. FIG. 5A is a cross-sectional view taken along the line AA in FIG. 4. The lighting device (sidelight type backlight unit) 40 used in the TFT-LCD 1 for displaying a moving image according to the present embodiment is a cold cathode. 2 shows a cross section taken along a plane perpendicular to the pipe axis direction of the pipe. FIG. 5B shows the luminance distribution of the illumination light from the illumination device 40 on the back surface side of the display area of the TFT-LCD 1.
FIG. 6 is a diagram showing a modification of the illumination device 40 and the TFT-LCD 1 using the same according to the second embodiment of the present invention.
FIG. 7 is a diagram illustrating another modification of the illumination device 40 according to the second embodiment of the present invention. Illumination device 40 shown in FIG. 7A shows a state in which double-sided reflection member 64 is arranged in a gap between light guide plates 51 and 52. FIG. 7B is a diagram illustrating the double-sided reflecting member 64. FIG. 7C is a diagram showing another double-sided reflecting member 64.
FIG. 8 is a diagram for explaining Expression 1 in a second embodiment of the present invention. FIG. 8A is an enlarged view of FIG. 7C, and FIG. 8B is a view showing a light path at an end face on the light guide plate 52 side.
FIG. 9 is a diagram illustrating still another modification of the illumination device and the liquid crystal display device using the same according to the second embodiment of the present invention. FIG. 9A is a diagram illustrating a schematic configuration of a lighting device according to the present modification and a liquid crystal display device using the same. FIG. 9B is a cross-sectional view taken along line AA of FIG. 9A, and is a lighting device (sidelight type backlight unit) 40 used in the TFT-LCD 1 for displaying moving images according to the present embodiment. FIG. 3 is a diagram showing a cross section of the cross section taken along a plane perpendicular to the tube axis direction of the cold cathode tube. FIG. 9C is a diagram illustrating a luminance distribution of the illumination light from the illumination device 40 on the back surface side of the display area of the TFT-LCD 1.
FIG. 10 In the third embodiment of the present invention, the ratio of the lighting time during one frame period of the backlight unit (duty ratio) is changed, and furthermore, the gradation data is processed so as to reduce the liquid crystal transmittance. FIG. 14 is a diagram illustrating a subjective evaluation of whether or not a difference in image quality from the original image is felt when adjustment is performed.
FIG. 11 is a diagram showing a schematic operation procedure of a display device according to a third embodiment of the present invention and a display data conversion circuit 20 of a liquid crystal display device using the same.
FIG. 12 is a flowchart showing a procedure of calculating a brightness Y and creating a histogram in a display device converting circuit 20 of a lighting device and a liquid crystal display device using the same according to a third embodiment of the present invention.
FIG. 13 is a diagram illustrating an example of calculating the number M of pixels occupied by an image in an illumination device and a liquid crystal display device using the same according to the third embodiment of the present invention, when the image is only part of one frame (screen). 6 is a flowchart showing a procedure for performing the operation.
FIG. 14 is a flowchart illustrating a procedure for calculating a threshold brightness Yα in the lighting device and the liquid crystal display device using the same according to the third embodiment of the present invention.
FIG. 15 is a diagram illustrating a duty ratio selection look-up table used for selecting a duty ratio of a light source in a lighting device according to a third embodiment of the present invention and a liquid crystal display device using the same.
FIG. 16 is a diagram illustrating a case where the processed gradation data is output to a plurality of data bus lines 8 in correspondence with the threshold brightness Yα in the lighting device and the liquid crystal display device using the same according to the third embodiment of the present invention. FIG. 4 is a diagram showing a signal control value selection look-up table for determining the control value of FIG.
FIG. 17 is a diagram illustrating an example of duty driving in a lighting device and a liquid crystal display device using the lighting device according to the third embodiment of the present invention.
FIG. 18 is a diagram showing an example in which a sidelight type backlight unit as an illumination device according to a third embodiment of the present invention is arranged on an LCD panel.
FIG. 19 is a diagram illustrating an example in which the cold cathode tubes A and B of the sidelight type backlight unit as the lighting device according to the third embodiment of the present invention are duty-driven.
FIG. 20 is a diagram showing, as an illumination device according to a third embodiment of the present invention, a scan-type backlight unit in which cold-cathode tubes A to F are arranged on the back surface of a panel display surface.
FIG. 21 is a diagram illustrating an example in which the cold cathode tubes A to F of the lighting device according to the third embodiment of the present invention are duty-driven.
FIG. 22 is a diagram showing an example in which a sidelight type backlight unit of a lighting device according to a third embodiment of the present invention is arranged on an LCD panel.
FIG. 23 is a diagram illustrating an example in which the cold cathode tubes A to D of the sidelight type backlight unit of the lighting device according to the third embodiment of the present invention are duty-driven.
FIG. 24 is a diagram showing an example in which a direct-type backlight unit of a lighting device according to a third embodiment of the present invention is arranged on an LCD panel.
FIG. 25 is a diagram illustrating an example in which the cold cathode tubes A to H of the direct-type backlight unit of the lighting device according to the third embodiment of the present invention are duty-driven.
FIG. 26 is a diagram showing an example in which a direct-type backlight unit of a lighting device according to a third embodiment of the present invention is arranged on an LCD panel.
FIG. 27 is a diagram illustrating an example in which LEDs A to T of a direct-type backlight unit of a lighting device according to a third embodiment of the present invention are duty-driven.
28 shows a state in which the duty ratio is 80%, the first 20% of one frame period is turned off, and the entire 80% of the remaining period is turned on in the display device provided with the scanning backlight shown in FIG. FIG.
FIG. 29 is a diagram illustrating a duty driving method for solving the problem of the backlight in FIG. 28 using the lighting device according to the third embodiment of the present invention.
FIG. 30 is a diagram showing a backlight structure according to Example 1 according to the fourth embodiment of the present invention.
FIG. 31 is a diagram showing a driving waveform of a backlight according to Example 1 according to the fourth embodiment of the present invention.
FIG. 32 is a diagram showing a backlight structure according to Example 2 according to the fourth embodiment of the present invention.
FIG. 33 is a diagram showing a driving waveform of the backlight according to Example 2 according to the fourth embodiment of the present invention.
FIG. 34 is a view showing a specific timing chart of the backlight according to Example 2 according to the fourth embodiment of the present invention.
FIG. 35 is a diagram showing a specific timing chart of the backlight according to Example 2 according to the fourth embodiment of the present invention.
FIG. 36 is a view showing a specific timing chart of the backlight according to Example 2 according to the fourth embodiment of the present invention.
FIG. 37 is a diagram showing a specific timing chart of the backlight according to Example 3 according to the fourth embodiment of the present invention.
FIG. 38 is a view showing a specific timing chart of the backlight according to Example 3 according to the fourth embodiment of the present invention.
39. In the backlight according to Example 3 according to the fourth embodiment of the present invention, the current value (relative value) in the maximum lighting state S2 is set to 10, and the intermediate lighting states S3 and S4 in FIG. 38 are changed. FIG. 7 is a diagram showing the display quality when a moving image is displayed in the display area of the TFT-LCD 1 as a subjective evaluation by a plurality of observers.
FIG. 40 is a view showing characteristics of a cold cathode tube.
FIG. 41 is a diagram showing an illumination device according to a fourth embodiment of the present invention and an effect of using the duty driving method.
FIG. 42 is a diagram showing an illumination device according to a fourth embodiment of the present invention and the effect of using the duty driving method.
FIG. 43 is a diagram illustrating Example 4 of the lighting device according to the fourth embodiment of the present invention.
FIG. 44 is a diagram illustrating a result of performing the duty drive illustrated in FIG. 37 or FIG. 38 on the backlight unit 75 of Example 4 of the illumination device according to the fourth embodiment of the present invention.
FIG. 45 is a diagram showing a conventional direct-type backlight structure and duty driving as a comparative example of the lighting device according to the fourth embodiment of the present invention.
FIG. 46 is a diagram showing a duty drive of a conventional direct-type backlight as a comparative example of the illumination device according to the fourth embodiment of the present invention.
FIG. 47 is a diagram showing a backlight unit 75 ′ according to Example 5 of the lighting device according to the fourth embodiment of the present invention.
FIG. 48 is a diagram showing a backlight unit 130 according to Example 6 of the lighting device according to the fourth embodiment of the present invention.
FIG. 49 is a diagram showing a backlight structure according to Example 7 of the lighting device according to the fourth embodiment of the present invention.
FIG. 50 is a diagram showing current dependency of luminous efficiency of an LED.
FIG. 51 is a diagram showing the current dependence of the light emission amount of an LED.
FIG. 52 is a diagram showing a basic configuration of a lighting device according to a fifth embodiment of the present invention.
FIG. 53 is a diagram illustrating a first principle of a lighting element of a lighting device according to a fifth embodiment of the present invention.
FIG. 54 is a diagram illustrating a second principle of a lighting element of a lighting device according to a fifth embodiment of the present invention.
FIG. 55 is a diagram illustrating a third principle of a lighting element of a lighting device according to a fifth embodiment of the present invention.
FIG. 56 is a diagram illustrating a fourth principle of a lighting element of a lighting device according to a fifth embodiment of the present invention.
FIG. 57 is a block diagram showing a schematic configuration of a liquid crystal display device according to Example 5-1 of the fifth embodiment of the present invention.
FIG. 58 is a diagram showing a cross-sectional configuration of a liquid crystal display device according to Example 5-1 of the fifth embodiment of the present invention.
FIG. 59 is a diagram showing a cross-sectional configuration of a backlight unit of an illumination device according to Example 5-1 of the fifth embodiment of the present invention.
FIG. 60 is a diagram showing a lighting device according to Example 5-1 of the fifth embodiment of the present invention and a method for driving a liquid crystal display device using the same.
FIG. 61 is a block diagram showing a modification of the configuration of the liquid crystal display device according to Example 5-1 of the fifth embodiment of the present invention.
FIG. 62 is a diagram showing a cross-sectional configuration of a lighting device according to Example 5-2 of the fifth embodiment of the present invention.
FIG. 63 is a diagram showing a cross-sectional configuration of a lighting device according to Example 5-3 of the fifth embodiment of the present invention.
FIG. 64 is a diagram showing a cross-sectional configuration of a lighting device according to Example 5-4 of the fifth embodiment of the present invention.
FIG. 65 is a diagram showing a cross-sectional configuration of a liquid crystal display according to Example 5-5 of the fifth embodiment of the present invention.
FIG. 66 is a diagram showing a cross-sectional configuration of a liquid crystal display device according to Example 5-6 of the fifth embodiment of the present invention.
FIG. 67 is a diagram showing a cross-sectional configuration of a lighting device according to Example 5-6 of the fifth embodiment of the present invention.
FIG. 68 is a diagram showing a lighting device according to Example 5-6 of the fifth embodiment of the present invention and a method for driving a liquid crystal display device using the same.
FIG. 69 is a view illustrating the method of manufacturing the lighting device according to the sixth embodiment of the present invention.
FIG. 70 is a diagram showing a change in cut wavelength of the absorption axis of the polarizing plate with respect to the heat treatment time in the heat treatment of the polarizing plate in the lighting device according to the sixth embodiment of the present invention.
FIG. 71 is a diagram showing transmission characteristics in the absorption axis direction of the polarizing plate when the polarizing plate is heat-treated at 70 ° C. in the lighting device according to the sixth embodiment of the present invention.
FIG. 72 is a diagram showing a shrinkage ratio with respect to a heat treatment time of a polarizing plate in the lighting device according to the sixth embodiment of the present invention.
FIG. 73 is a diagram showing a relationship between a thermal shock test time and a light guide plate deformation amount in the lighting device according to the sixth embodiment of the present invention.
FIG. 74 is a cross section of a direct-type backlight unit used for a conventional TFT-LCD for displaying moving images, taken along a plane orthogonal to a tube axis direction of a cold cathode fluorescent lamp, and a luminance distribution of illumination light from the backlight unit. FIG.
FIG. 75 is a view showing a configuration of a direct-type backlight unit used in a conventional TFT-LCD for displaying a moving image as viewed from a display area side.
FIG. 76 is a diagram showing a configuration of a sidelight-type backlight unit as another conventional scan-type illumination device.
[Explanation of symbols]
1,1008 TFT-LCD
2 LCD panel
4 TFT
6 gate bus line
8 Data bus line
10 pixel electrode
12 Gate driver
14 Data Driver
16 Control circuit
18 Gate driver control unit
20 Display data conversion circuit
22 Light source controller
24, 40 lighting device
25-28, 41-43 Light emitting area
30-33, 45-48, 1004 Cold cathode tubes
35-38 Light source power supply circuit
50-53 Light guide plate
56-59 Light extraction structure
60 Diffusion sheet
62 Light mixing area
64 Double-sided reflective member
70-73 Brightness adjustment volume
91 Polarizing plate heat treatment process
92 Sticking process to light guide plate
93 Autoclave process
94 Lamp Assembly Mounting Process
100, 1020 light guide plate
102a, 102a ', 102b, 102b', 1004 cold cathode tubes
110, 1002 Lamp reflector
112 Light exit surface
114 Opposing surface
116 scattering layer
118, 119 prism surface
130, 1000 backlight unit
134 display area
132 Light source controller
136 Oriented sheet group
138 Reflective scattering sheet
140, 141 Polarizing plate
142 TFT substrate
144 Counter substrate
1006 Transmission diffusion plate
1010 to 1013 divided area
1002 Lamp reflector
1022 LED
Clc liquid crystal capacity
Cs storage capacity
G gate electrode
S source electrode
D Drain electrode

Claims (24)

An illumination device for illuminating a display area of an active matrix liquid crystal display device,
At least one light source capable of changing light emission brightness;
At least one light emitting region for emitting light from the light source;
An illumination device comprising: a light source control system that switches between a maximum lighting state in which the light emitting region emits light at a predetermined maximum luminance and an intermediate lighting state in which light emission occurs at a predetermined intermediate luminance lower than the maximum luminance. The lighting device according to claim 1,
The lighting device according to claim 1, wherein the light-emitting region has a light-emitting opening arranged substantially parallel to a direction in which a gate bus line formed in the liquid crystal display device extends. The lighting device according to claim 1 or 2,
The light source control system switches between the maximum lighting state and the intermediate lighting state in synchronization with one of gate pulses sequentially output to a plurality of gate bus lines formed in the liquid crystal display device. Lighting equipment. The lighting device according to any one of claims 1 to 3,
The lighting device, wherein the intermediate lighting state is set to a luminance level equal to or less than 50% of a luminance level of the maximum lighting state. The lighting device according to any one of claims 1 to 4,
The lighting device, wherein the lighting time in the maximum lighting state is 50% or less of one frame period. The lighting device according to any one of claims 1 to 5,
A first light source comprising a first light guide plate and a first light source disposed at an end thereof, mainly illuminating the first light emitting region and supplying a part of light to an adjacent second light emitting region. Unit and
A second light guide plate stacked on the first light source unit and a second light source disposed at an end of the first light source unit, mainly illuminating the second light emitting region, and adjoining the first light emitting region And a second light source unit that supplies a part of light to the lighting device. The lighting device according to claim 6,
The first light guide plate is disposed in the first and second light emitting areas,
The lighting device according to claim 1, wherein the second light guide plate is disposed only in the first light emitting region. The lighting device according to claim 7,
A third light source including a third light guide plate and a third light source disposed at an end thereof, mainly illuminating the third light emitting region and supplying a part of light to an adjacent fourth light emitting region Unit and
A fourth light guide plate stacked on the third light source unit and a fourth light source disposed at an end thereof, the fourth light guide plate mainly illuminating the fourth light emitting region, and the third light emitting region adjacent thereto; And a fourth light source unit that supplies a part of light to the lighting device. An LCD panel that modulates the light transmittance of a plurality of pixels arranged in a matrix based on each gradation data;
An illuminating device that irradiates each pixel with light by changing a ratio (duty ratio) of a lighting time during one frame period;
Calculate the respective brightness and brightness histogram from each of the tone data, determine a threshold brightness from the brightness histogram based on a predetermined pixel ratio of luminance saturation, and process each of the tone data based on the threshold brightness. A display data converter for outputting the duty ratio data for changing the duty ratio to the lighting device while outputting the duty ratio data to the LCD panel. The liquid crystal display device according to claim 9,
The display data conversion unit,
The liquid crystal display device, wherein the threshold brightness is determined by counting the brightness from the brightness histogram in descending order of brightness based on the ratio of the pixels to be saturated with the brightness. The liquid crystal display device according to claim 10,
The display data conversion unit,
M (M ≦ N) pixels for which an image is displayed among the N pixels in the one frame are determined, and the threshold brightness is determined based on a product of the number of M pixels and the ratio of the pixels to be saturated with luminance. A liquid crystal display device characterized by determining: The liquid crystal display device according to any one of claims 9 to 11,
The display data conversion unit,
The duty ratio is determined so that the product of the maximum possible value of the grayscale data and the duty ratio is equal to the threshold brightness, and the grayscale data of a pixel having brightness equal to or higher than the threshold brightness becomes the maximum value. In other pixels, processing is performed so that the product of the processed gradation data and the determined duty ratio is equal to the brightness of the original gradation data of the pixel. Liquid crystal display. The lighting device according to any one of claims 1 to 5,
Comprising a plurality of the light sources in the light emitting area,
The light source control system controls a current flowing through each of the plurality of light sources, and a maximum lighting state in which the light emitting region emits light at a predetermined maximum luminance, and an intermediate lighting state in which the light emitting area emits light at a predetermined intermediate luminance lower than the maximum luminance. And a lighting device characterized by switching. The lighting device according to claim 13,
The light source control system includes:
With respect to at least one of the plurality of light sources, the current is turned on in the predetermined lighting cycle in a predetermined cycle, and turned off in other cases,
A lighting device, characterized in that an electric current is supplied to the remaining light sources so as to be turned off at the time of the maximum lighting state and to be at the intermediate lighting state at other times. The lighting device according to claim 13,
The light source control system includes:
At least one of the plurality of light sources is set to a first intermediate lighting state lower than the maximum lighting state at a predetermined cycle, and a second intermediate lighting state lower than the first intermediate lighting state otherwise. Apply current so that
For the remaining light sources, the third intermediate lighting state is set so that the illumination area is the maximum lighting state in the first intermediate lighting state, and the illumination area is in the second intermediate lighting state. A lighting device characterized in that a current is supplied so as to be in a fourth intermediate lighting state so as to be in an intermediate lighting state. The lighting device according to claim 13,
The light source control system includes:
A current is applied to at least one of the plurality of light sources so as to always be in the intermediate lighting state,
A lighting device, characterized in that a current is supplied to the remaining light sources so that the lighting area is in the maximum lighting state at a predetermined cycle and is turned off at other times. The lighting device according to any one of claims 13 to 16,
The light source control system includes:
A lighting device, wherein current is controlled so that a light-off state is provided between the maximum lighting state and the intermediate lighting state thereafter. The lighting device according to any one of claims 13 to 16,
The light source control system includes:
A lighting device, wherein a current is controlled between the maximum lighting state and the subsequent intermediate lighting state so that a lighting state lower than the intermediate lighting state is achieved. First and second linear light sources;
A first light-emitting region including a first light-receiving element for mainly extracting light guided from the first linear light source to the outside; and a light-emitting region mainly including light guided from the second linear light source. A light guide plate comprising: a second light emitting region having a second daylighting element for extracting light to the outside;
The first and second linear light sources are turned on at a predetermined blinking frequency and at different timings for substantially the same lighting time, or the first and second linear light sources are different from each other at a predetermined blinking frequency. A light source driving circuit for lighting only for the lighting time. The lighting device according to claim 19,
The lighting device according to claim 1, wherein the first and second lighting elements include a prism shape formed on a surface of the light guide plate. A polarizing plate, which has been heat-shrinked in advance before being attached to a light guide plate surface of a lighting device or a liquid crystal panel surface of a liquid crystal display device. A lighting device having a light guide plate to which a polarizing plate is attached,
An illumination device, wherein the polarizing plate according to claim 21 is used as the polarizing plate. A liquid crystal display device having a panel surface to which a polarizing plate is attached,
A liquid crystal display device, wherein the polarizing plate according to claim 21 is used as the polarizing plate. In an active matrix type liquid crystal display device,
A liquid crystal display device comprising the lighting device according to any one of claims 1 to 8 or 13 to 20 or 22.

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