JP2009038759A - Video image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To relieve a stress (feeling of oppression) caused on a user (viewer) when a video image is displayed with a large screen size on a large-size video display device. <P>SOLUTION: When display of a new video image is started on a liquid display panel 16 of the video image display device, for example, when a state change occurs on the liquid display panel 16 from a state in which no video image is being displayed to a state in which a video image is displayed, or when an input destination of a video image signal corresponding to a video image to be displayed on the liquid display panel 16 or when a broadcast channel for video image display changes, the new video image is first displayed on a small-size screen and then displayed on a large-size screen of the liquid display panel 16. In such case, according to the change of the video image display size, a light source for backlight for illuminating a display region of the image turns on while a light source for illuminating a non-display region of the image turns off. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a video display device including a video display unit such as a liquid crystal display panel, and more particularly to a video display device that can reduce stress on a user from a large screen display video by a large video display unit.

In recent years, large-sized liquid crystal television receivers (an example of video display devices) have become widespread, so that it is possible to provide realistic video even when viewing broadcast programs related to movies, sports, natural scenery, etc. became.
In addition, large LCD television receivers have a high brightness of the entire light source (so-called backlight) that illuminates the liquid crystal display panel that displays the image from the back side. It becomes very bright. For this reason, a large-sized liquid crystal television receiver may give stress to the user (viewer) depending on the state of video display.
On the other hand, Patent Document 1 discloses a television receiver that changes the display size of a video on a liquid crystal display panel according to the genre of a broadcast program that is displaying the video.
Patent Document 2 discloses a technique for changing the light emission area of a plasma display in accordance with the size of a display screen in an image display device having a large plasma display. Further, Patent Document 2 discloses a technique for measuring the distance between the viewer's eyes and the display screen and changing the light emission area of the plasma display according to the distance.
Japanese Patent Laid-Open No. 10-108108 JP 2003-58101 A

By the way, a user who watches a large-screen video on a large video display device continuously views a series of videos that can anticipate a certain change in the video, such as when watching a video of a single broadcast program. However, when a new video that cannot be predicted to change is suddenly displayed on a large screen, for example, when the power is turned on, the stress is not great. feel. Similarly, when the video signal to be displayed is switched (channel change (channel selection), video signal input destination switching, etc.), the battle scene changes rapidly from a static video such as a slowly changing landscape. Even when the video is switched to a dynamic video such as the above, the user feels a great stress when the video with rapid changes is suddenly displayed on a large screen.
On the other hand, as shown in Patent Document 1, even if the display size of the video is changed according to the genre of the broadcast program, the stress applied to the user is not eliminated. For example, if the genre of the broadcast program of the channel selected when the power is turned on is a genre suitable for large screen display such as movies, a new video is suddenly displayed on the large screen. This gives a great stress to the user.
In addition, neither of the techniques disclosed in Patent Document 1 and Patent Document 2 can reduce the stress given to the user while responding to the request when the user (viewer) wants to view a large screen image. There was a problem.
Accordingly, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide stress (compression) to a user (viewer) when displaying a video with a large screen size in a large video display device. An object of the present invention is to provide an image display device capable of reducing the feeling of the image.

In order to achieve the above object, a video display device according to the present invention includes a video display unit and the following components (1).
(1) When display of a new video is started by the video display unit, the new video is displayed in the standard size after being displayed on the video display unit with an initial size smaller than a predetermined standard size. Video size switching means.
For example, the video size switching means switches the display size of the new video on the video display unit from the initial size stepwise to switch to the standard size.
In the video display device according to the present invention, when a new video that cannot be predicted by the user is displayed with a large screen size, the new video is first reduced in a small size (the initial size) so as not to stress the user. The display size is changed so that the user can predict the change in the video content to some extent, and the display size of the video is switched to a larger size (the standard size). By such a video size switching process, it is possible to reduce the stress on the user while responding to the user's request to view a large screen video.
In addition, since the display size of the video is changed in small increments by magnifying and displaying the new video, the stress on the user can be further reduced.

Further, as an example of a more specific configuration of the video display device according to the present invention, the video size switching means includes one or both of the components shown in the following (2) and (3). It is possible that there is.
(2) Automatic video size switching means for automatically switching the video display size as a predetermined time elapses after the new video is displayed on the video display unit at the initial size.
(3) Manual video size switching means for switching the video display size in accordance with an operation on a predetermined operation unit after the new video is displayed at the initial size on the video display unit.
In addition, as a timing at which the display of the new video at which the processing by the video size switching unit is executed, a timing including one or more of the following (a1) to (a3) can be considered.
(A1) Timing when switching from a state where no image is displayed on the image display unit to a state where an image is displayed.
(A2) Timing when the input destination of the video signal corresponding to the video displayed on the video display unit is changed.
(A3) Timing when the broadcast channel corresponding to the video displayed on the video display unit is changed by channel selection based on the broadcast signal.
The timings shown in (a1) to (a3) are timings when a new video that cannot be predicted by the user is displayed on the video display unit, and the video is suddenly displayed in a large size (large screen) at such timing. When this happens, the user feels a lot of stress.
A specific example of the standard size is the maximum display size of the video in the video display unit.
The video display unit may be a liquid crystal display panel, and the video display device according to the present invention may further include a plurality of light sources that illuminate the liquid crystal display panel from the back side. In this case, the video display device (that is, the liquid crystal display device) according to the present invention may further include one or both of the following (4) and (5).
(4) In response to switching of the video display size by the video size switching means, the light source that illuminates the display area of the new video on the liquid crystal display panel is turned on and the non-display area of the new video is illuminated Light source blink control means for turning off the light source.
(5) Light source luminance control means for increasing the luminance of the light source from a relatively low luminance to a high luminance in accordance with the switching of the video display size from the initial size to the standard size by the video size switching means.
In a liquid crystal display device, the power consumption of the light source (so-called backlight) accounts for most of the power consumption of the entire device. Therefore, if the video display device (liquid crystal display device) according to the present invention includes the components shown in the above (4) or (5), a relatively large power saving effect can be obtained.
Note that the video display state at the initial size is temporary, and it is sufficient that the video content can be generally grasped. Therefore, the light source luminance control means can suppress the luminance of the light source in the image display state at the initial size to be low, and no particular problem occurs even if the sharpness of the image at that time is somewhat impaired.

  According to the present invention, when a new video whose change cannot be predicted by the user is displayed with a large screen size, the display size of the video can be switched from a small size to a large size. When desired, the stress on the user can be reduced while responding to the request.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that the present invention can be understood. The following embodiment is an example embodying the present invention, and does not limit the technical scope of the present invention.
FIG. 1 is a block diagram showing a schematic configuration of a liquid crystal television receiver X which is an example of a video display device according to an embodiment of the present invention, and FIG. FIG. 3 is a flowchart showing a display screen size control procedure in the liquid crystal television receiver X, and FIG. 4 shows an arrangement state of backlight light sources in the liquid crystal television receiver X. FIG. 5 is a diagram illustrating an example of a lighting state of a backlight light source in the liquid crystal television receiver X. FIG.

First, the configuration of a liquid crystal television receiver X, which is an example of a video display device according to an embodiment of the present invention, will be described with reference to the block diagram shown in FIG.
The liquid crystal television receiver X extracts a video signal related to a broadcast program from a television broadcast signal received by an antenna or the like, and displays a video based on the video signal on a liquid crystal display panel 16 (an example of a video display unit). It is. On the back surface of the liquid crystal display panel 16, a cold-cathode tube 18 (shown as CCFL in the figure) that emits light blue and a red light-emitting LED 21 as a light source for a backlight that illuminates the liquid crystal display panel 16 from the back surface are provided. ing.
As shown in FIG. 1, a liquid crystal television receiver X includes a digital tuner 1, a demodulation circuit 2, a demultiplexer 3, a video decoder circuit 4, a video input selection circuit 5, a video processing circuit 6, an external input unit 7, and a control circuit. 8, remote control light receiving unit 9, remote control 15, liquid crystal display panel 16, cold cathode tube 18 and LED 21, which are light sources for backlight, inverter circuit 17, LED drive circuit 20, brightness sensor 19, color sensor 22, no image detection A circuit 23, an audio decoder circuit 10, an audio input selection circuit 11, an audio processing circuit 12, an amplifier 13, and a speaker 14 are provided.

The digital tuner 1 selects a carrier frequency component including a broadcast program signal instructed to be selected by the control circuit 8 and transmits the selected carrier frequency component to the demodulator 2 at the subsequent stage.
The demodulation circuit 2 demodulates a transport stream signal (Transport Stream signal: hereinafter referred to as a TS signal) from a carrier frequency component transmitted from the digital tuner 1.
The demultiplexer 3 separates and extracts a video signal and an audio signal corresponding to a broadcast program to be viewed and additional data from the TS signal extracted by the digital tuner 1 and the demodulation circuit 2. Further, the demultiplexer 3 extracts a video signal and an audio signal of a broadcast program to be viewed according to a PID (Packet IDentification) received from the control circuit 8, and each signal is extracted from the video decoder circuit 4 and the video signal. The data is transmitted to each of the audio decoder circuits 10.
The video decoder circuit 4 decodes the video signal received from the demultiplexer 3 and transmits the decoded video signal to the video input selection circuit 5. Similarly, the audio decoder circuit 10 decodes the audio signal received from the demultiplexer 3 and transmits the decoded audio signal to the audio input selection circuit 11.

The external input unit 7 is a signal input interface for inputting a video signal and an audio signal from an external device. The video signal input through the external input unit 7 is transmitted to the video input selection circuit 5, and the audio signal is transmitted to the audio input selection circuit 11.
The video input selection circuit 5 includes a video signal of a channel selected by the digital tuner 1 according to a control command from the control circuit 8 (a video signal input through the video decoder circuit 4), and the external input unit. 7 is a circuit that selects any one of the video signals input through 7 and transmits it to the video processing circuit 6. In other words, the video input selection circuit 5 is a circuit that selects (switches) a video signal input destination corresponding to a video to be displayed on the liquid crystal display panel 16.
The video processing circuit 6 performs various signal processing on the video signal selected by the video input selection circuit 5. For example, the video processing circuit 6 has a screen size switching function for switching the screen size of the video to be displayed on the liquid crystal display panel 16 to the size specified by the control circuit 8.

The audio input selection circuit 11 includes an audio signal of a channel selected by the digital tuner 1 in accordance with a control command from the control circuit 8 (an audio signal input through the audio decoder circuit 10), and the external input unit. 7 is a circuit that selects any one of the audio signals input through 7 and transmits it to the audio processing circuit 12.
The audio processing circuit 12 performs various signal processing on the audio signal selected by the audio input selection circuit 11 in accordance with an instruction from the control circuit 8. For example, equalization processing, surround processing, or the like that matches the characteristics of the speaker 14 is performed. The amplifier 13 performs processing for amplifying or attenuating the audio signal processed by the audio processing circuit 12 in accordance with an instruction from the control circuit 8 and outputs the amplified signal to the speaker 14.
The liquid crystal display panel 16 displays video (broadcast program video) based on the video signal output from the video processing circuit 6.
The brightness sensor 19 is a sensor that detects the brightness of the front side of the liquid crystal display panel 16, and the color sensor 22 is a color distribution (R, G, B) of light on the back side of the liquid crystal display panel 16. Sensor). These sensors are used for brightness (output) control of the cold cathode tube 18 and the LED 21 as will be described later.

The control circuit 8 includes an MPU 8a that is an arithmetic means, a ROM 8b (EPROM) that is a storage means in which a control program executed by the MPU 8a is stored in advance, and various types of data that are read and written (referenced or written) in processing executed by the MPU 8a. A non-volatile memory 8c for storing data is provided, and the entire liquid crystal television receiver X is controlled. The nonvolatile memory 8c is, for example, a flash memory.
The no-video detection circuit 23 receives in advance a video signal selected by the video input selection circuit 5 and input to the video processing circuit 6, that is, a video signal corresponding to a video displayed on the liquid crystal display panel 16. This is a circuit that detects whether or not a state (hereinafter referred to as a no-video continuation state) indicating no video (a completely dark video) continues for a predetermined time (for example, about 3 seconds to 10 seconds) or longer. For example, the non-video detection circuit 23 is in a state where no video signal is input to the video processing circuit 6 or the sum of luminance levels (video gradation values) of each pixel in the video signal input to the video processing circuit 6. When the state where the value or the average value is less than the predetermined lower limit value continues for a predetermined time or more, it is determined that the imageless state is continued, and the determination result is transmitted to the control circuit 8. .

The remote control light receiving unit 9 is a signal transmission interface for receiving a radio signal by infrared from a remote control 15 (remote operation unit) for operating the liquid crystal television receiver X according to a predetermined signal transmission protocol. The remote control light receiving unit 9 acquires operation input information for the remote control 15 by infrared signal transmission, and transmits the operation input information to the control circuit 8.
The cold cathode tube 18 which is a light source for backlight of the liquid crystal display panel 16 emits combined light (light blue) of light of each wavelength of green and blue, and is configured by arranging a plurality of cold cathode tubes. ing. Similarly, the LED 21 which is a light source for the backlight is a red LED that emits light of red wavelength, and is arranged in a plurality between the plurality of cold cathode tubes 18.
FIG. 4 is a diagram illustrating an arrangement state of the light sources for the backlight (the cold cathode tubes 18 and the LEDs 21) inside the liquid crystal television receiver X.
As shown in FIG. 4, the cold cathode tubes 18 are arranged in the vertical direction in a region extending over the entire back surface of the liquid crystal display panel 16, and a plurality of LEDs 21 are equally spaced between the plurality of cold cathode tubes 18. It is arranged.

The inverter circuit 17 (shown as an INV circuit in the figure) is a circuit that adjusts the power supplied to each of the plurality of cold cathode tubes 18 in accordance with a control signal output from the control circuit 8. That is, the inverter circuit 17 adjusts the brightness of the cold-cathode tube 18 by PWM (Pulse Width Modulation) dimming and controls turning on and off according to the control signal transmitted from the control circuit 8. I do. The inverter circuit 17 can individually turn on, turn off, and control the brightness of each cold cathode tube 18.
The LED drive circuit 20 is a circuit that adjusts the power supplied to the LED 21 (red LED) in accordance with a control command output from the control circuit 8. That is, the LED drive circuit 20 adjusts the brightness of the LED 21 and controls turning on and off according to the control signal transmitted from the control circuit 8. The LED drive circuit 20 can individually turn on, turn off, and control the brightness for each LED 21 in one horizontal column (one row).
The control circuit 8 detects the detection level of the brightness sensor 19 that detects the brightness on the front side of the liquid crystal display panel 16 and the color sensor 22 that detects the color distribution of light on the back side of the liquid crystal display panel 16. The brightness (light quantity) of the cold cathode tube 18 and the brightness (light quantity) of the LED 21 are adjusted according to the detection result, but the detailed explanation is omitted here.

Next, a display screen size control procedure realized by the control circuit 8 (the MPU 8a) executing a predetermined program will be described with reference to the flowchart shown in FIG. S1, S2,... Shown below represent identification codes of processing procedures (steps).
First, the control circuit 8 determines whether or not the current time is the timing at which a new video display is started on the liquid crystal display panel 16 according to a predetermined determination rule (S1).
Here, when the current time satisfies one of the following determination conditions (c1) to (c4), the control circuit 8 is at a timing when a new video display is started on the liquid crystal display panel 16. Determine that there is.
(C1) In response to a power ON operation on the remote controller 15, the liquid crystal television receiver X starts from a standby state (a state in which no image is displayed on the liquid crystal display panel 16), and an image generated by the liquid crystal display panel 16 Display is in a state of starting from now (an example of timing when switching from a state in which no video is displayed on the video display unit to a state in which video is displayed). The power ON operation is an operation of pressing a “power key” provided on the remote controller 15.
(C2) The input destination of the video signal corresponding to the video to be displayed on the liquid crystal display panel 16 by the video input selection circuit 5 according to the control command output from the control circuit 8 in response to the input switching operation to the remote controller 15 It is time to switch (change) (the digital tuner 1 or the external input unit 7). The input switching operation is an operation of pressing an “input switching key” provided on the remote controller 15.
(C3) When the digital tuner 1 switches a broadcast channel to be selected from a broadcast signal according to a control command output from the control circuit 8 in response to a channel selection operation (channel selection operation) on the remote controller 15 (ie, , When the broadcast channel corresponding to the video to be displayed on the liquid crystal display panel 16 is changed by channel selection based on the broadcast signal). The channel selection operation includes an operation of pressing a “numeric key” provided on the remote controller 15 or a channel selection key (“channel up key” or “channel down key”) sequentially.
(C4) The detection result of the non-video detection circuit 23 is a video signal corresponding to the video displayed on the liquid crystal display panel 16 (video signal selected by the video input selection circuit 5 and input to the video processing circuit 6). Is the time when the non-video continuation state (a state in which no video is continuously displayed for a predetermined time or longer) is switched to a non-no-video state (a state with video) (the video is displayed on the video display unit). An example of timing when switching from a state where video is not displayed to a state where video is displayed). For example, when the input destination of the video signal is the external input unit 7 connected to the recording data playback device, the playback device is switched from the playback stop state to the playback start state. The condition of c4) is satisfied.
Note that the control circuit 8 repeats the process of step S1 until the present time satisfies the determination condition of any of (c1) to (c4).
Since the point in time when the determination conditions shown in (c1) to (c4) are satisfied is a timing at which a new video for which the user (viewer) cannot predict a change is displayed on the liquid crystal display panel 16, at such a timing. When the video is suddenly displayed at a large size, the user feels a lot of stress.

When the control circuit 8 determines in step S1 that the current time is the timing at which display of a new video is started on the liquid crystal display panel 16 (when display of a new video is started), By executing the processing of steps S2 to S8 shown in FIG. 5, the new image is displayed in a large screen size preset on the liquid crystal display panel 16 (for example, the maximum display size of the image on the liquid crystal display panel 16: the standard size). Display with a smaller screen size (an example of the initial size) than the small screen size (an example of the video size switching means).
That is, first, the control circuit 8 starts measuring time by controlling a timer circuit (not shown) (S2).
Further, the control circuit 8 performs the video processing so that the video (new video) based on the video signal input to the video processing circuit 6 is reduced and displayed in a partial region at the center of the liquid crystal display panel 16. The circuit 6 is controlled (S3, setting of a small screen size). For example, when the size of the liquid crystal display panel 16 (the large screen size) is 52 type, the small screen size is set to a size corresponding to a 26 type screen.
Further, the control circuit 8 controls the inverter circuit 17 and the LED drive circuit 20 to turn off the light source (the cold cathode tube 18 and the LED 21) that illuminates the non-display area of the image on the liquid crystal display panel 16. Then, control is performed to turn on (or maintain the lighted state) the light source that illuminates the video display area (S4).
FIG. 5 is a diagram illustrating an example of a lighting state of the backlight light source after the process of step S4 (when a new image is displayed in the small screen size).
For example, in the process of step S3, the control circuit 8 turns on only the one that illuminates the image display area a2 of the small screen size among the plurality of cold cathode tubes 18 and LEDs 21 that are not displayed. The display area is switched to a state in which the illumination is turned off.

Next, the control circuit 8 has performed a predetermined screen enlargement operation on the remote controller 15 (hereinafter referred to as a first release condition) in the state of video display with the small screen size, and step S2. Until the time measured by the timer circuit started in step e.g. has passed a preset time ts (hereinafter referred to as a set time) (hereinafter referred to as a second release condition). A determination process of the first release condition and the second release condition is executed (S5, S6). Here, the screen enlargement operation is, for example, a press operation of a screen enlargement key provided on the remote controller 15 (one-touch operation of a specific operation key).
When the control circuit 8 detects that at least one of the first release condition and the second release condition is satisfied in the video display state with the small screen size, the control circuit 8 By controlling the LED drive circuit 20, all the light sources (the cold cathode tubes 18 and the LEDs 21) that illuminate the entire display area of the liquid crystal display panel 16 are turned on (S7).
Further, the control circuit 8 starts the entire display area of the liquid crystal display panel 16 from the state in which the video (new video) based on the video signal input to the video processing circuit 6 is displayed in the small screen size. The video processing circuit 6 is controlled to shift to the state displayed in (S8), and then the process shifts to step S1 described above.
In this way, the control circuit 8 automatically displays the new image on the liquid crystal display panel 16 with the small screen size (S3), and then automatically changes to the large screen size as the predetermined time ts elapses. Switching is performed (S6, S8, an example of the automatic video size switching means).
The control circuit 8 displays a new image on the liquid crystal display panel 16 with the small screen size (S3), and then responds to the operation of the screen enlargement key on the remote controller 15 (an example of the operation unit). The video display size is switched (switching from the small screen size to the large screen size) (S5, S8, an example of the manual video size switching means).

As described above, the control circuit 8 starts the display of a new video by the liquid crystal display panel 16 (when any of the conditions (c1) to (c4) is satisfied). Then, after the new image is displayed on the liquid crystal display panel 16 with the small screen size smaller than the large screen size, the processing for displaying the new image with the large screen size (S2 to S8) is executed. That is, when the control circuit 8 displays a new video that cannot be predicted by the user (viewer) in the large screen size, the control circuit 8 first displays the new video in the small screen size so as not to stress the user. The display size of the video is changed to the large screen size after the user makes the change in the video content predictable to some extent. By such a video size switching process, it is possible to reduce the stress on the user while responding to the user's request to view a large screen video.
FIG. 2 is a diagram illustrating a state in which the display image on the liquid crystal display panel 16 is switched from a static image with a gradual change to a dynamic image (a beast image) with a drastic change. In addition, the arrow in FIG. 2 represents the order of switching.
In the conventional technique, as shown in FIG. 2 (a), since the original static image is instantaneously switched to a dynamic image (new image) with a large screen size, the user feels a great stress.
On the other hand, when the television receiver X performs video switching due to the establishment of the discrimination condition (c2) or (c3), as shown in FIG. 2 (b), the first stage in which an unpredictable sudden video change may occur. First, switch from the original static video to a dynamic video with a small screen size (new video), and then change to a dynamic video with a large screen size after it has become possible to predict video changes to some extent. . As a result, the user's stress is greatly reduced than before.

In step S8, the control circuit 8 increases the display size of the video (new video) on the liquid crystal display panel 16 step by step from the small screen size (dividing the display size into a plurality of steps). Switching to the large screen size is also conceivable. Thereby, since the display size of the video is changed in small increments, the stress on the user can be further reduced.
In steps S4 and S7, the control circuit 8 turns on the light source (the cold cathode tube 18 and the LED 21) that illuminates a new image display area on the liquid crystal display panel 16 in accordance with the switching of the image display size. And turning off the light source that illuminates the non-display area of the image (an example of the light source blinking control means). The power consumption of the liquid crystal television receiver X can be reduced by the processing in steps S4 and S7.
For example, when the size of the liquid crystal display panel 16 (the large screen size) is 52 type, the small screen size is reduced to half the size of the entire display area and supplied to the backlight light source that illuminates the non-display area of the image. By controlling the power, the power consumption can be suppressed to an extent corresponding to a 37-inch liquid crystal television receiver.

In steps S4 and S7, the control circuit 8 controls the inverter circuit 17 and the LED drive circuit 20 in accordance with the switching of the video display size, thereby providing a light source for backlight (the cold cathode tube 18). It is also conceivable to increase the luminance of the LED 21) from a relatively low luminance to a high luminance (an example of the light source luminance control means). Such control can also reduce power consumption.
Here, the video display state in the small screen size is temporary, and it is a state that it is sufficient if the video content can be generally grasped. Therefore, even if the brightness of the backlight light source in the image display state with the small screen size is kept low and the sharpness of the image at that time is somewhat impaired, no particular problem occurs.

In the embodiment described above, the inverter circuit 17 and the LED driving circuit 20 can turn on and off the light sources 18 and 21 for the backlight in units of one row (one horizontal column). However, the unit that can be turned on / off can be considered to be another unit. For example, the inverter circuit 17 and the LED drive circuit 20 can turn on and off the light sources 18 and 21 for the backlight in units of two rows (two columns in the horizontal direction) It is conceivable that the LED drive circuit 20 can be turned on and off in units of a plurality of adjacent LEDs 21.
In the above-described embodiment, the backlight is an example of a hybrid type composed of both the cold cathode tube 18 and the LED 21. However, only the cold cathode tube emitting white light, only the LED emitting white light or A backlight composed of a combination of RGB three-color LEDs is also conceivable.
In addition, the present invention has a remarkable effect when applied to a video display device having a large video display unit having a large screen size, and its application target is not necessarily limited to a liquid crystal display device. The present invention can also be applied to other video display devices.

  The present invention is applicable to a video display device.

1 is a block diagram illustrating a schematic configuration of a liquid crystal television receiver X that is an example of a video display device according to an embodiment of the present invention. The figure showing a mode that the display image of a liquid crystal display panel switches from a static image to a dynamic image. 6 is a flowchart showing a procedure for controlling the display screen size in the liquid crystal television receiver X. The figure showing the arrangement state of the light source for backlights in the inside of liquid crystal television receiver X. The figure showing an example of the lighting state of the light source for backlights in the liquid crystal television receiver.

Explanation of symbols

X: liquid crystal television receiver 1: digital tuner 2: demodulation circuit 3: demultiplexer 4: video decoder circuit 5: video input selection circuit 6: video processing circuit 7: external input unit 8: control circuit 9: remote control light receiving unit 10 : Audio decoder circuit 11: Audio input selection circuit 12: Audio processing circuit 13: Amplifier 14: Speaker 15: Remote control 16: Liquid crystal display panel 17: Inverter circuit 18: Cold cathode tube (light source for backlight)
19: Brightness sensor 20: LED drive circuit 21: LED (light source for backlight)
22: Color sensor 23: No-image detection circuit S1, S2,...: Step (processing procedure)

Claims (9)

A video display device having a video display unit,
When the display of a new video is started by the video display unit, the video size switching is performed so that the new video is displayed in the standard size after being displayed in the video display unit with an initial size smaller than a predetermined standard size. An image display device comprising means.   The video display device according to claim 1, wherein the video size switching unit is configured to gradually increase the display size of the new video in the video display unit from the initial size to the standard size.   The video size switching means includes automatic video size switching means for automatically switching the video display size as a predetermined time elapses after the new video is displayed on the video display unit at the initial size. The video display device according to claim 1 or 2.   The video size switching means includes manual video size switching means for switching the video display size in accordance with an operation on a predetermined operation unit after the new video is displayed at the initial size on the video display unit. The video display device according to any one of claims 1 to 3.   The timing at which the display of the new video at which the processing by the video size switching means is started is switched from a state in which no video is displayed on the video display unit to a state in which video is displayed, the video display One or more of the timing when the input destination of the video signal corresponding to the video to be displayed on the screen is changed and the timing when the broadcast channel corresponding to the video to be displayed on the video display unit is changed by channel selection based on the broadcast signal The video display device according to claim 1, comprising:   The video display device according to claim 1, wherein the standard size is a maximum video display size in the video display unit. The video display unit is a liquid crystal display panel;
The video display device according to claim 1, further comprising a plurality of light sources that illuminate the liquid crystal display panel from the back side thereof.   In response to switching of the video display size by the video size switching means, the light source that illuminates the display area of the new video on the liquid crystal display panel is turned on and the light source that illuminates the non-display area of the new video The video display device according to claim 7, further comprising light source blinking control means for turning off the light.   And a light source luminance control unit configured to increase the luminance of the light source from a relatively low luminance to a high luminance in accordance with the switching of the video display size from the initial size to the standard size by the video size switching unit. Item 9. The video display device according to any one of Items 7 and 8.

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