JP2012100159A - Video display device and television receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video display device and a television receiver which even if a video display part is inclined, is capable of displaying a video as it is while keeping the original posture of the video.SOLUTION: The inclination of a liquid crystal panel 161 that displays the video on the basis of an input video signal is detected by an inclination angle sensor 163. In response to the detected inclination of the liquid crystal panel 161, the video is displayed on the liquid crystal panel 161, at a display angle which allows keeping of the horizontal angle and vertical angle at which the video originally has to be displayed on the basis of the video signal.

Description

  The present invention relates to a video display device such as a television receiver that displays video based on an input video signal, and more particularly to a video display mode.

The video display device displays video based on the input video signal. For example, an example of a video display device is a television receiver that displays a television program based on a television broadcast signal.
By the way, there are directions (horizontal direction and vertical direction) that should be originally displayed in the video displayed on the video display device. Usually, in the video display device, the video is displayed in a state where the original vertical and horizontal directions of the video are aligned with the vertical and horizontal directions of the video display unit (liquid crystal panel or the like). This is based on the premise that the video display device is placed on a TV stand, a table or the like, and the video display unit of the video display device maintains a predetermined posture. On the other hand, for example, Patent Document 1 discloses that when the display is inverted 180 °, the content of the screen display is also inverted 180 °.

JP-A-8-95525

By the way, in recent years, video display devices are not always placed on a television stand or a table. For example, it can be placed on a wall or carried around freely. Therefore, the posture of the video display unit of the video display device is not always maintained in a predetermined state. Specifically, when the left and right direction of the video display unit is tilted with respect to the horizontal direction, the video viewed from the viewer is also tilted. Therefore, the problem is that the video cannot be viewed at the original angle.
Accordingly, the present invention has been made in view of the above circumstances, and the object of the present invention is to display the image while maintaining the original posture even when the image display unit is tilted. An object of the present invention is to provide a video display device and a television receiver.

To achieve the above object, the present invention provides a video display unit that displays video based on an input video signal, a tilt detection unit that detects a tilt of the video display unit, and a tilt detection unit that detects the tilt. Display angle control means for displaying the video on the video display unit at a display angle that maintains the original horizontal and vertical directions of the video to be displayed based on the video signal according to the tilt of the video display unit; It is comprised as a video display device characterized by comprising.
According to the present invention, even when the video display unit is tilted, the video based on the video signal is displayed in a state where the original posture of the video is maintained. Can be viewed at the original correct angle.

By the way, if the video display unit is tilted, the size of the video that can be displayed while maintaining the original horizontal direction and vertical direction of the video in the video display unit changes. Therefore, it is conceivable to further include display size control means for changing the display size of the video in accordance with the tilt of the video display unit detected by the tilt detection means.
For example, the display size control means may display the video at the maximum display size that can be displayed while maintaining the original horizontal and vertical directions and aspect ratio of the video in the video display unit. It is done. As a result, the entire video based on the video signal can be displayed while maintaining the original posture and form of the video. In this method, when the longitudinal direction of the image display unit changes from horizontal to vertical, the display size of the image gradually decreases and then increases gradually. Some viewers may not want such changes.
Therefore, when the longitudinal direction of the video display unit is horizontal, the display size control means has a display size that can be displayed while maintaining the original horizontal and vertical directions and aspect ratio of the video in the video display unit. When the longitudinal direction of the video display unit is vertical, the display size that can be displayed while maintaining the original horizontal direction and vertical direction and aspect ratio of the video in the video display unit is set as the minimum size, and the video It is also conceivable that the display size of the video is gradually reduced from the maximum size to the minimum size as the longitudinal direction of the display unit approaches from horizontal to vertical. As a result, when the longitudinal direction of the video display unit changes from horizontal to vertical, the video display unit is changed only in a direction in which the display size of the video is reduced, and conversely, the longitudinal direction of the video display unit changes from vertical to horizontal. In this case, it can be changed only in the direction in which the display size of the video is increased.
Further, in the present invention, an appropriate change in the display angle and display size of the video is performed by a display correspondence information storage in which display correspondence information in which the tilt of the video display unit is associated with the display angle and display size of the video is stored. The display angle control means and the display size control means set the video display angle and display size in the video display unit based on the display correspondence information stored in the display correspondence information storage means. It can be realized by what it does.

Further, the video display device displays a stereoscopic video by displaying a left-eye video and a right-eye video having different display positions on the video display unit, and only the left-eye video is displayed on the viewer's left eye. And 3D glasses for visually recognizing only the right eye image, and the 3D glasses allow only the left eye image to be viewed by the viewer's left eye using a polarization method using circularly polarized light. It is also conceivable that only the right eye image is visually recognized by the right eye. With such a configuration, the stereoscopic video displayed by the stereoscopic video display means can be viewed in a state in which the original posture of the video is maintained regardless of the tilt of the video display unit.
However, in this configuration, when the viewer's field of view tilts with respect to the horizontal, for example, when the viewer wearing stereoscopic glasses lies down, the left-right direction in the viewer's field of view and the original left-right direction of the video are displayed. There is a tilt between the direction.
In view of this, the apparatus further includes glasses inclination detecting means for detecting the inclination of the stereoscopic glasses, and the display angle control means determines whether the stereoscopic glasses have left and right in accordance with the inclination of the stereoscopic glasses detected by the glasses inclination detecting means. It is conceivable that the image is displayed at a display angle in which the direction and the original horizontal direction of the image, the vertical direction of the stereoscopic glasses and the original vertical direction of the image are parallel to each other. As a result, it is possible to set the display angle appropriately by giving priority to the direction of the stereoscopic video viewed from the viewer.
If the display angle or display size of the video is changed in the video display unit, an area where no video exists in the displayable area of the video display unit is generated. For this reason, it is conceivable to further include a solid image display means for displaying a black solid image outside the video display area in the video display unit.
By the way, the present invention includes a video display device according to the present invention configured as described above, and the video display unit displays a video based on at least a television broadcast signal. It may be considered as an invention.

  According to the present invention, even when the video display unit is tilted, the video based on the video signal is displayed in a state where the original posture of the video is maintained. Can be viewed at the original correct angle.

The schematic diagram which shows the external appearance of the television receiver X which concerns on embodiment of this invention. 1 is a block diagram illustrating a schematic configuration of a television receiver X according to an embodiment of the present invention. The principal part schematic diagram of the internal structure of the monitor part 1 of the television receiver X which concerns on embodiment of this invention. The flowchart for demonstrating an example of the procedure of the display control process performed with the television receiver X which concerns on embodiment of this invention. The figure which shows an example of display corresponding | compatible information. The figure which shows an example of the execution result of a display control process. The figure which shows the other example of the execution result of a display control process. The figure which shows the other example of the execution result of a display control process.

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.
First, an external configuration of the television receiver X according to the embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 1, a television receiver X according to an embodiment of the present invention includes a monitor unit 1 (an example of a video display device) that displays video, a cradle unit 2 to which the monitor unit 1 can be attached and detached. It has. Here, FIG. 1A shows a state in which the monitor unit 1 is set on the cradle unit 2, and FIG. 1B shows a state in which the monitor unit 1 is detached from the cradle unit 2.
The cradle unit 2 is connected to a broadcast receiving antenna 3 for receiving a television broadcast signal from a television broadcast station. The cradle unit 2 inputs the television broadcast signal received from the broadcast receiving antenna 3 to the monitor unit 1 by wired communication or wireless communication using radio waves. Thereby, the monitor unit 1 displays the video of the television program based on the input television broadcast signal.
The cradle unit 2 is connected to a commercial AC power supply 4 and is driven by electric power supplied from the commercial AC power supply 4. On the other hand, the monitor unit 1 is not connected to a commercial AC power source but is driven by electric power supplied from a secondary battery or the like mounted on the monitor unit 1. The secondary battery is charged by attaching the monitor unit 1 to the cradle unit 2. Further, a wireless power transmission technology that wirelessly supplies power from the cradle unit 2 to the monitor unit 1 may be employed. Of course, a configuration in which the monitor unit 1 can be connected to a commercial AC power supply is also conceivable.
The present invention can also be applied to a video display device such as a display device used for a personal computer or the like. In the present embodiment, a configuration in which the monitor unit 1 can be freely carried is described as an example. However, the monitor unit 1 may be arranged on a wall.

Next, detailed configurations of the monitor unit 1 and the cradle unit 2 will be described with reference to FIG.
As shown in FIG. 2, the cradle unit 2 includes a main control unit 21, a wireless transmission / reception unit 22, a wired connection detection unit 23, a video processing unit 24, an audio processing unit 25, a tuner 26, an external input unit 27, and a signal switching unit 28. , OSD control unit 29, wired interface 30 and the like.
The main control unit 21 includes control devices such as a CPU, a RAM, and a ROM, and comprehensively controls the cradle unit 2 according to a predetermined control program. The main control unit 21 may be an electric circuit such as an ASIC.

The tuner 26 is a signal (hereinafter referred to as a broadcast signal) in which video signals for a plurality of channels of various television broadcasts such as digital terrestrial broadcasts and BS / CS broadcasts and audio signals synchronized with the video are superimposed from the broadcast receiving antenna 3. Receive. The tuner 26 extracts (selects) a broadcast channel signal instructed by the main control unit 21 from the broadcast signal, extracts a video signal and an audio signal by detecting the extracted signal, and extracts the video signal and the audio signal. A signal is input to the signal switching unit 28.
The external input unit 27 is an interface for inputting a composite video signal and audio signal input from the outside, a separate video signal and audio signal (so-called S terminal signal), and the like to the signal switching unit 28. . For example, a video playback device Y such as a DVD recorder, a Blu-ray recorder, or a hard disk recorder is connected to the external input unit 27.
The signal switching unit 28 inputs the video signal and the audio signal input from either the tuner 26 or the external input unit 27 selected according to the control instruction from the main control unit 21 to the video processing unit 24 and the audio processing unit 25. .
Further, the OSD control unit 29 is an OSD to be displayed on the monitor unit 1 in a superimposed manner on the video such as menu display, electronic program guide, various status information (volume, display channel, etc.) in accordance with a control instruction from the main control unit 21. Information is input to the video processing unit 24.
The video processing unit 24 separates a horizontal synchronization signal and a vertical synchronization signal from the video signal, generates a clock signal that is phase-synchronized with the synchronization signal, separates a luminance signal and a color signal from the video signal, and performs a predetermined image quality improvement process. Various video processes are performed, and the processed video signal is output. In addition, when OSD information is input from the OSD control unit 29, the video processing unit 24 also has an OSD display function for generating a video signal for displaying the OSD information superimposed on the display video.
The audio processing unit 25 performs various signal processing such as equalization processing and surround processing on an input audio signal, and outputs the processed audio signal.
The video signal and the audio signal output from the video processing unit 24 and the audio processing unit 25 are input to the wireless transmission / reception unit 22 and the wired interface 30, respectively.

The wireless transmission / reception unit 22 has a communication modem function for realizing wireless data communication with the wireless transmission / reception unit 12 of the monitor unit 1 by transmitting / receiving radio waves through the antenna 22a. The communication modem function realizes wireless communication by an OFDM (Orthogonal Frequency-Division Multiplexing) wireless system compliant with, for example, the IEEE802.11 standard used also for a wireless LAN or the like. For example, a 2.4 GHz band, a 5 GHz band, or the like is used as the frequency of this wireless communication.
Specifically, the wireless transmission / reception unit 22 transmits data such as a video signal and an audio signal output from the video processing unit 24 and the audio processing unit 25 according to a control instruction from the main control unit 21 by wireless communication. Send to. For example, video signals and audio signals are transmitted in a video compression format such as MPEG2.

The wired interface 30 has a connection terminal that is connected to the wired interface 18 of the monitor unit 1 when the monitor unit 1 is attached to the cradle unit 2. The wired interface 30 also includes a modem function for realizing wired data communication with the monitor unit 1 via a connection terminal. Specifically, the wired interface 30 sends data such as video signals and audio signals output from the video processing unit 24 and the audio processing unit 25 to the monitor unit 1 by wired communication in response to a control instruction from the main control unit 21. Send.
The wired connection detection unit 23 detects whether or not the wired interface 30 is connected to the wired interface 18 of the monitor unit 1, that is, whether or not the monitor unit 1 and the cradle unit 2 are connected by wire. Note that various conventional disconnection detection techniques can be used as a method for detecting the presence or absence of connection by the wired connection detection unit 23. Then, the detection result by the wired connection detection unit 23 is input to the main control unit 21. The detection result is used in the main control unit 21 to determine whether to perform data communication with the monitor unit 1 by wired communication or wireless communication.

On the other hand, the monitor unit 1 includes a main control unit 11, a wireless transmission / reception unit 12, a data processing unit 13, a video processing unit 14, an audio processing unit 15, a video display unit 16, a speaker 17, a wired interface 18, and the like.
The main control unit 11 has control devices such as a CPU, a RAM, and a ROM, and comprehensively controls the monitor unit 1 according to a predetermined control program. The main controller 11 may be an electric circuit such as an ASIC.
The wireless transmission / reception unit 12 has a communication modem function for realizing wireless data communication with the wireless transmission / reception unit 22 of the cradle unit 2 by transmitting / receiving radio waves through the antenna 12a. The communication modem function realizes wireless communication by an OFDM (Orthogonal Frequency-Division Multiplexing) wireless system compliant with, for example, the IEEE802.11 standard used also for a wireless LAN or the like. For example, a 2.4 GHz band, a 5 GHz band, or the like is used as the frequency of this wireless communication. Specifically, the wireless transmission / reception unit 12 receives data such as a video signal and an audio signal transmitted from the cradle unit 2 by wireless communication, and inputs the data to the data processing unit 13.
The data processing unit 13 is a decoder that decodes data in a video compression format such as MPEG2 input from the wireless transmission / reception unit 12. The video signal and audio signal decoded by the data processing unit 13 are input to the video processing unit 14 and the audio processing unit 15.

The wired interface 18 has a connection terminal that is connected to the wired interface 30 of the cradle unit 2 when the monitor unit 1 is attached to the cradle unit 2. The wired interface 18 also includes a modem function for realizing wired data communication with the cradle unit 2 via a connection terminal. Specifically, the wired interface 18 receives data such as a video signal and an audio signal transmitted from the monitor unit 1 by wired communication, and inputs the video signal and the audio signal to the video processing unit 14 and the audio processing unit 15. .
The audio processing unit 15 performs various types of audio processing such as volume adjustment, equalization processing, and surround processing on the audio signal input from the data processing unit 13 or the wired interface 18, and outputs the processed audio signal to the speaker 17. input. Thereby, the speaker 17 reproduces sound based on the sound signal input from the sound processing unit 15.

The video processing unit 14 has arithmetic means such as a CPU and MPU, and performs various image processing such as scaling processing and resolution conversion processing on the video signal input from the data processing unit 13 or the wired interface 18. The processed video signal is input to the video display unit 16. As a result, the video display unit 16 displays a video based on the input video signal.
The video processing unit 14 includes a ROM 141 and a RAM 142 therein. The ROM 141 stores in advance a predetermined control program executed by the video processing unit 14 and various parameters. The RAM 142 is a memory used as a work area (temporary storage area) for processing executed by the video processing unit 14, and a detection result by an inclination angle sensor 163 to be described later is also appropriately stored in the RAM 142.

As shown in FIGS. 2 and 3, the video display unit 16 includes a liquid crystal panel 161, a backlight 162, an inclination angle sensor 163 (an example of an inclination detection unit), and the like.
The liquid crystal panel 161 is formed of a liquid crystal layer, a scan electrode and a data electrode for applying a scan signal and a data signal to the liquid crystal layer, and has a conventionally known active liquid crystal device having a plurality of liquid crystal elements whose transmittance changes depending on the applied voltage. It is a matrix type liquid crystal panel. The aspect ratio (aspect ratio) of the liquid crystal panel 161 is 16: 9. The video display unit 16 is also provided with a liquid crystal driving circuit (not shown) for controlling the driving of the liquid crystal elements of the liquid crystal panel 161 based on the input video signal, vertical synchronizing signal, and horizontal synchronizing signal. As a result, a video based on the video signal input from the video processing unit 14 is displayed on the liquid crystal panel 161.
The backlight 162 includes a large number of LEDs arranged in parallel on at least one side of the liquid crystal panel 161 and a light guide plate that guides light emitted from the LEDs to the entire back surface of the liquid crystal panel 161. That is, the backlight 162 is a so-called edge-type backlight that illuminates the liquid crystal panel 161 from the back surface by each of the LEDs arranged at the edge of the liquid crystal panel 161. Specifically, the backlight 162 in the present embodiment has an LED substrate 162a on which a plurality of LEDs corresponding to the upper side of the liquid crystal panel 161 are mounted as shown in FIG. The LED substrate 162a is disposed in parallel with the longitudinal direction of the liquid crystal panel 161. Therefore, the inclination of the LED substrate 162a is the same as the inclination of the liquid crystal panel 161.
The tilt angle sensor 163 is provided on the LED substrate 162 a of the backlight 162 and detects the tilt of the liquid crystal panel 161. Of course, the installation position of the inclination angle sensor 163 is not limited to the position on the LED substrate 162a, but may be any position where the inclination of the liquid crystal panel 161 can be detected. The tilt angle sensor 163 is a conventionally known tilt angle sensor such as an acceleration sensor or a gyro sensor. Specifically, the tilt angle sensor 163 sets the tilt (tilt angle) between the longitudinal direction and the horizontal direction of the liquid crystal panel 161 when the liquid crystal panel 161 is in a predetermined posture as 0 ° (see FIG. 6A). The inclination of the liquid crystal panel 161 is detected. The predetermined posture is such that the predetermined vertical direction in the liquid crystal panel 161 is the vertical vertical direction, and the predetermined horizontal direction in the liquid crystal panel 161 is parallel to the horizontal direction. The tilt angle of the liquid crystal panel 161 detected at any time by the tilt angle sensor 163 is stored in the RAM 142 of the video processing unit 14.

In the television receiver X according to the present embodiment configured as described above, the video processing unit 14 executes display control processing (see FIG. 4) described later, whereby the video display angle and display on the liquid crystal panel 161 are displayed. It is characterized in that the size is changed according to the detection result by the inclination angle sensor 163. Note that the display control process may be executed by the main control unit 11.
Hereinafter, an example of the procedure of the display control process executed by the video processing unit 14 will be described with reference to the flowchart of FIG. 4, S1, S2,... Represent processing procedure (step) numbers.
Whether or not the display control process is executed, that is, whether a display angle of a display image and a display size automatic change function, which will be described later, are performed in the display control process, is turned on or off according to an operation input by the user. Can be changed.

(Steps S1 and S2)
First, in step S <b> 1, the video processing unit 14 detects the current tilt of the liquid crystal panel 161 by the tilt angle sensor 163. As described above, the inclination detected by the inclination angle sensor 163 is stored in the RAM 142 in the video processing unit 14. Therefore, the video processing unit 14 can acquire the information by reading the current inclination of the liquid crystal panel 161 from the RAM 142.
Next, in step S2, the video processing unit 14 determines the display angle and display size of the video on the liquid crystal panel 161 according to the inclination of the liquid crystal panel 161 detected in step S1. Then, the video processing unit 14 displays video on the liquid crystal panel 161 at the determined display angle and display size in steps S3 and S4 described later. Here, the video processing unit 14 when executing such processing corresponds to display angle control means and display size control means.

Here, a specific example of the method for setting the display angle and display size of the video in step S2 will be described.
First, in the ROM 141 (an example of the display correspondence information storage unit) of the video processing unit 14, as shown in FIG. 5, table information (display) in which the tilt of the liquid crystal panel 161 is associated with the display angle and display size of the video. An example of correspondence information) is stored.
Here, the “video display angle” is an inclination of the original horizontal direction of the video displayed on the liquid crystal panel 161 with respect to the longitudinal direction (left-right direction) of the liquid crystal panel 161. The “video display angle” in the table information cancels the tilt of the liquid crystal panel 161 by tilting the video displayed on the liquid crystal panel 161, and the original horizontal direction of the video to be displayed based on the video signal. And a display angle for generally maintaining the vertical direction.
The “video display size” indicates a ratio when the size of video that can be displayed when the longitudinal direction of the liquid crystal panel 161 is horizontal is 100%. The “image display size” in the table information is determined in accordance with the inclination of the liquid crystal panel 161, and without changing the aspect ratio of the image on the liquid crystal panel 161 where the inclination occurs, and the original horizontal level of the image. This is the maximum display size that can be displayed while maintaining the direction and the vertical direction. For example, since the aspect ratio (aspect ratio) of the liquid crystal panel 161 is 16: 9, the “image display size” when the inclination of the liquid crystal panel 161 is 90 ° is 56% (≈9 / 16). It can be set.

Specifically, in the table information shown in FIG. 5, when the inclination of the liquid crystal panel 161 is 0 ° or more and less than 5 °, the “video display angle” is 0 ° and the “video display size” is 100%. . When the inclination of the liquid crystal panel 161 is 5 ° or more and less than 10 °, the “video display angle” is −5 ° and the “video display size” is 90%. Further, when the inclination of the liquid crystal panel 161 is 10 ° or more and less than 15 °, the “video display angle” is −10 ° and the “video display size” is 85%.
Here, “video display angle” and “video display size” are set corresponding to a predetermined range of tilt of the liquid crystal panel 161 (tilt angle 5 °). If the “angle” and “image display size” are set, the accuracy of maintaining the original posture of the image can be improved. In addition, separate display correspondence information may be used in which the inclination and display angle of the liquid crystal panel 161 and the inclination and display size of the liquid crystal panel 161 are associated with each other. Of course, it is also conceivable that mathematical formulas for calculating “video display angle” and “video display size” corresponding to the inclination of the liquid crystal panel 161 are determined in advance.
Further, when the liquid crystal panel 161 is rotated by 360 ° or more, naturally, an angle exceeding 360 ° is adopted as the tilt angle.
Then, the video display unit 14 extracts a display angle and a display size corresponding to the tilt of the liquid crystal panel 161 detected by the tilt angle sensor 163 based on the table information (see FIG. 5) stored in the ROM 141, The display angle and the display size of the image displayed on the liquid crystal panel 161 are determined.

(Steps S3 to S4)
Subsequently, in step S3, the video processing unit 14 changes the display size of the video signal so that the video based on the input video signal is displayed with the display size set in step S2. Execute. As a result, the image is displayed on the liquid crystal panel 161 at the maximum display size that can be displayed while maintaining the original horizontal direction and vertical direction of the image and the aspect ratio. This scaling process is executed after the OSD process for superimposing the OSD information on the video signal. Therefore, when OSD information is included in the video signal, the size of the OSD information is also reduced at the same time.
Thereafter, in step S4, the video processing unit 14 displays the video based on the video signal whose display size has been changed in step S3 at the display angle set in step S2. The video rotation process for changing the display angle is executed. In order to simplify the processes of steps S3 and S4 executed by the video processing unit 14, a plurality of patterns of conversion filters for converting the video signal according to the setting contents in the table information are set in advance, and the conversion filter It is also conceivable to change the display angle and display size of the video by selectively using.
By the way, if the display angle or display size of the video is changed in steps S3 and S4, a blank area where no video exists is generated on the liquid crystal panel 161. Therefore, in the subsequent step S5, the video processing unit 14 executes an image composition process for displaying a black painted image in a blank area when the video after the video processing in steps S3 and S4 is displayed on the liquid crystal panel 161. To do. As a result, a black painted image can be displayed outside the video display area on the liquid crystal panel 161. Here, the video processing unit 14 when executing such processing corresponds to a solid image display means.
Thereafter, in the monitor unit 1 of the television receiver X, the processes in steps S1 to S5 described above are repeatedly executed. As a result, the display angle and display size of the display image on the liquid crystal panel 161 of the monitor unit 1 are appropriately set according to the inclination of the liquid crystal panel 161 in step S2.

FIG. 6 shows an example of the execution result of the display control process (see FIG. 4). 6A, 6 </ b> B, and 6 </ b> C illustrate display examples of images when the inclination of the liquid crystal panel 161 between the longitudinal direction and the horizontal direction is 0 °, 40 °, and 90 °. .
First, as shown in FIG. 6A, when the liquid crystal panel 161 is not tilted, the maximum display size (100%) that can be displayed on the liquid crystal panel 161 is displayed. The video is displayed in a state where the inclination with respect to the liquid crystal panel 161 is 0 °, that is, in a state where the predetermined vertical and horizontal directions on the liquid crystal panel 161 coincide with the original vertical and horizontal directions.
On the other hand, as shown in FIGS. 6B and 6C, when the liquid crystal panel 161 is tilted, the video display size is the maximum that can be displayed on the liquid crystal panel 161 without changing the aspect ratio. Changed to display size and displayed. Also, as shown in FIGS. 6B and 6C, the display angle of the image on the liquid crystal panel 161 is rotated by the same inclination in the opposite direction to the inclination direction corresponding to the inclination of the liquid crystal panel 161. Yes, the video viewed from the viewer is maintained in the original horizontal and vertical directions.
Accordingly, a viewer of the television receiver X can view the video in a state where the original horizontal direction, vertical direction, and aspect ratio of the video are always maintained regardless of whether the liquid crystal panel 161 is tilted or not. . Further, the entire video is contained in the liquid crystal panel 161, and the viewer can always watch the entire video.

In the embodiment, the case where the video is reduced within the range of the size that can be displayed on the liquid crystal panel 161 in order to always display the entire video on the liquid crystal panel 161 has been described as an example.
However, in this case, when the angle of the liquid crystal panel 161 with respect to the horizontal direction in the longitudinal direction is tilted from 0 ° (FIG. 6A) to 90 ° (FIG. 6C), in the process, FIG. As shown in FIG. 6, the video display size is smaller than that of the tilted state by 90 °. That is, in this case, when the longitudinal direction of the liquid crystal panel 161 changes from horizontal to vertical, the display size of the video gradually changes and then changes gradually.
Accordingly, when the longitudinal direction of the liquid crystal panel 161 is horizontal, the video processing unit 14 sets the display size that can be displayed on the liquid crystal panel 161 while maintaining the original horizontal and vertical directions and aspect ratio of the video to the maximum size, When the longitudinal direction of the liquid crystal panel 161 is vertical, the display size that can be displayed while maintaining the original horizontal direction, vertical direction, and aspect ratio of the image on the liquid crystal panel 161 is set to the minimum size, and the longitudinal direction of the liquid crystal panel 161 is It can be considered that the display size of the video is gradually reduced from the maximum size to the minimum size as it becomes closer to the vertical from the horizontal. Note that such an adjustment method can be implemented by preliminarily determining the contents of such adjustment as the setting contents of the table information (see FIG. 5).
FIG. 7 shows an example of the display result of the liquid crystal panel 161 in such a configuration. In the display results shown in FIGS. 7A to 7C, the liquid crystal panel 161 is tilted from 0 ° (FIG. 7A) to 90 ° (FIG. 7C) with respect to the horizontal direction of the longitudinal direction. In the state shown in FIG. 7 (b), which passes through the process, the size of the display image is a size between the state of FIG. 7 (a) and the state of FIG. 7 (c). Of course, the same applies to the case of changing from the state of FIG. 7C to the state of FIG. 7A.
Therefore, according to such a configuration, when the inclination of the liquid crystal panel 161 is changed between horizontal and vertical, an uncomfortable change in which the size of the display image gradually decreases and finally increases again is prevented. can do.

In the present embodiment, a case will be described in which the present invention is applied to a stereoscopic video display device that displays stereoscopic video. In the present embodiment, only differences from the television receiver X (see FIG. 1) will be described.
In the television receiver X according to the present embodiment, the video processing unit 14 performs a stereoscopic video display process for displaying a stereoscopic video by causing the liquid crystal panel 161 to display a left-eye video and a right-eye video with different display positions. To do. Here, the video processing unit 14 when executing such processing corresponds to the stereoscopic video display means. Specifically, the video processing unit 14 generates a stereoscopic video signal for alternately displaying the left-eye video and the right-eye video on the liquid crystal panel 161 in the stereoscopic video display process, and inputs the stereoscopic video signal to the video display unit 16.
In addition, the television receiver X includes stereoscopic glasses that allow a viewer to visually recognize only the left-eye video and a right eye to visually recognize only the right-eye video by a polarization method using circularly polarized light. Therefore, the liquid crystal panel 161 is provided with a polarizing filter for outputting circularly polarized light.
Thus, the viewer of the television receiver X can view the stereoscopic image by wearing the stereoscopic glasses, viewing the left-eye image displayed on the liquid crystal panel 161 with the left eye, and viewing the right-eye image with the right eye. it can.

The video processing unit 14 executes the display control process (see FIG. 4) to change the display angle and the display size of the video according to the inclination of the liquid crystal panel 161 for the stereoscopic video signal. Execute the process. Specifically, the video processing unit 14 outputs the video display unit 16 after performing various types of video processing such as OSD information synthesis processing and image conversion processing between 2D (planar video) and 3D (stereoscopic video). Immediately before the conversion to the LVDS signal (Low voltage differential signaling), the processing of steps S3 and S4 in the display control processing is executed. As a result, the video processing unit 14 changes the video display angle and the display size in the same manner for both the video signal for 2D video display and the video signal for 3D video display. , The video can always be displayed in a state where the original posture of the video is maintained.
In particular, since the stereoscopic glasses and the liquid crystal panel 161 do not use linearly polarized light but show stereoscopic images by a polarization method using circularly polarized light, the liquid crystal panel 161 tilts when viewing stereoscopic images. Even when the image is generated, the video displayed on the liquid crystal panel 161 can be viewed as a stereoscopic video.

Here, FIG. 8 shows a display example of a stereoscopic video when the display control process is executed, where (a) is a left-eye video and (b) is a right-eye video.
As shown in FIGS. 8A and 8B, since there is an inclination (tilt angle 40 °) between the longitudinal direction and the horizontal direction of the liquid crystal panel 161, each of the left-eye image and the right-eye image is shown in FIG. Similar to the display result of (b), the display size is reduced to correspond to the inclination of the liquid crystal panel 161. Similarly to the display result of FIG. 6B, the left-eye image and the right-eye image have the display angle corresponding to the inclination of the liquid crystal panel 161 so that the original horizontal direction and vertical direction of the image are maintained. Is displayed.
The left-eye video and the right-eye video are displayed so as to be slightly shifted left and right in the original horizontal direction of the video. Accordingly, the viewer wearing the 3D glasses views the 3D image while maintaining the original posture by viewing the left eye image displayed on the liquid crystal panel 161 with the left eye and the right eye image with the right eye. be able to.

By the way, in the television receiver X that allows a viewer who uses the stereoscopic glasses to view stereoscopic video, the stereoscopic video viewed by the viewer is always displayed in a state where the original horizontal and vertical directions of the video are maintained. It is possible to hope for that.
Therefore, a configuration is provided in which the stereoscopic glasses are provided with an inclination detection sensor (an example of glasses inclination detecting means) for detecting the inclination of the stereoscopic glasses, and the detection result of the inclination detection sensor is transmitted from the stereoscopic glasses to the monitor unit 1. Can be considered. The data communication at this time may adopt a conventional method such as radio communication (RF communication) using radio waves or infrared communication.
If the video processing unit 14 determines that the stereoscopic glasses are tilted based on the detection result transmitted from the stereoscopic glasses, in step S2 of the display control process (see FIG. 4). Depending on the inclination of the stereoscopic glasses, the horizontal angle of the stereoscopic glasses and the original horizontal direction of the video, and the vertical direction of the stereoscopic glasses and the original vertical direction of the stereoscopic glasses are set in parallel, depending on the inclination of the stereoscopic glasses. It is conceivable to modify and change the image so that the image is displayed at the display angle. Note that the table information (see FIG. 5) is determined so that the display angle and display size of the video can be set not only according to the inclination of the liquid crystal panel 161 but also the inclination of the stereoscopic glasses. Is also possible.
Thus, in the television receiver X, if the display angle and the display size of the video are adjusted according to the inclination of the stereoscopic glasses, the viewer wearing the stereoscopic glasses always sees the original image when viewed from himself / herself. A stereoscopic image can be viewed in a state where the horizontal direction and the vertical direction are maintained.

  The present invention can be used for a video display device and a television receiver.

1: Monitor unit (video display device)
2: Cradle unit 3: Broadcast receiving antenna 4: Commercial AC power supply 11: Main control unit 12: Wireless transmission / reception unit 12a: Antenna 13: Data processing unit 14: Video processing unit 141: ROM
142: RAM
15: Audio processing unit 16: Video display unit 161: Liquid crystal panel 162: Backlight 163: Tilt angle sensor 17: Speaker 18: Wired interface 21: Main control unit 22: Wireless transmission / reception unit 22a: Antenna 23: Wired connection detection unit 24 : Video processing unit 25: Audio processing unit 26: Tuner 27: External input unit 28: Signal switching unit 29: OSD control unit 30: Wired interface X: Television receiver Y: Video playback device

Claims (9)

A video display unit for displaying video based on an input video signal;
Tilt detecting means for detecting the tilt of the video display unit;
In accordance with the inclination of the image display unit detected by the inclination detection means, the image is displayed on the image display unit at a display angle that maintains the original horizontal and vertical directions of the image to be displayed based on the image signal. Display angle control means for displaying;
A video display device comprising:   The video display apparatus according to claim 1, further comprising display size control means for changing a display size of the video in accordance with a tilt of the video display unit detected by the tilt detection means.   3. The display size control means for displaying the video at a maximum display size that can be displayed while maintaining the original horizontal and vertical directions and aspect ratio of the video in the video display unit. Video display device.   When the longitudinal direction of the video display unit is horizontal, the display size control means sets the maximum display size that can be displayed while maintaining the original horizontal and vertical directions and aspect ratio of the video in the video display unit. When the longitudinal direction of the video display unit is vertical, the video display unit sets the display size that can be displayed while maintaining the original horizontal direction and vertical direction and aspect ratio of the video to the minimum size, and the video display unit The video display device according to claim 2, wherein the display size of the video is gradually reduced from the maximum size toward the minimum size as the longitudinal direction of the video becomes closer to vertical from horizontal. A display correspondence information storage unit that stores display correspondence information in which a tilt of the video display unit is associated with a display angle and / or a display size of the video;
The display angle control means and / or the display size control means sets a display angle and / or a display size of the video in the video display unit based on the display correspondence information stored in the display correspondence information storage means. The video display device according to claim 1. 3D image display means for displaying a 3D image by displaying a left eye image and a right eye image with different display positions on the image display unit, and only the left eye image is visually recognized by the viewer's left eye, and the right eye 3D glasses for viewing only the video,
The video according to any one of claims 1 to 5, wherein the stereoscopic glasses allow a viewer's left eye to see only the left eye video and a right eye to see only the right eye video by a polarization method using circularly polarized light. Display device. Further comprising glasses inclination detecting means for detecting the inclination of the stereoscopic glasses,
In accordance with the inclination of the stereoscopic glasses detected by the glasses inclination detecting means, the display angle control means is a horizontal direction of the stereoscopic glasses and the original horizontal direction of the image, an up and down direction of the stereoscopic glasses and the original image of the image. The video display device according to claim 6, wherein the video is displayed at a display angle in which the vertical directions are parallel to each other.   The video display device according to claim 1, further comprising a solid image display unit that displays a black solid image outside the video display area in the video display unit.   A television receiver comprising the video display device according to claim 1, wherein the video display unit displays video based on at least a television broadcast signal.

Images