JP2010117612A - Display and display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display and a display method for preferably eliminating problems wherein in controlling of inhibiting the adjustment of image quality in a predetermined region on an image, an image prior to display switching is displayed as an afterimage, on switching of the display, by shortening the time for specifying the region. <P>SOLUTION: In the display 1, a CPU 110 executes a register memory updating program 130a, thereby it is decided whether the coordinates of the start point and the finish point of an OSD (on-screen display) image stored in a region designating data 130c of a ROM 130 are stored in the coordinate-storing section 115a of the register 115; and only when it is decided that there is no storage, will the CPU store the coordinates in the coordinate-storing section 115a. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a display device and a display method.

Conventionally, in a display device such as a liquid crystal television or a plasma television, an OSD (on-screen display) circuit superimposes an OSD signal such as an image quality adjustment screen on a video signal by an OSD (on-screen display) circuit. So-called OSD display in which an image and an OSD image based on an OSD signal are overlaid is enabled.
When image quality adjustment is performed in such an OSD display, the image quality adjustment is performed not only on the video signal but also on the superimposed OSD signal, and the color and brightness of the entire OSD display also change. There has been a problem that operations such as image quality adjustment become difficult.

Therefore, by providing a delay circuit that delays and outputs the input video signal by the time required for image quality adjustment, and inputting the OSD signal to the delay circuit, an OSD image that is not subjected to image quality adjustment and image quality adjustment are performed. A method is known in which an image based on an imaged video signal is displayed on a display screen so that the display portion of the OSD image based on the OSD signal is not affected by image quality adjustment (for example, Patent Document 1). reference).
Further, an on-screen flag corresponding to the display period of the display portion of the OSD image on the composite image is generated, and the on-screen flag is used to control the on / off of the image quality adjustment. A method for preventing image quality adjustment is known (for example, see Patent Document 2).
In order to carry out the above-described method, a coordinate value specifying an area for displaying the OSD image on the screen is acquired and stored in a storage unit such as a register, and the OSD image is displayed based on the coordinate value. It was necessary to perform control so that image quality adjustment was not performed on the display portion.
JP 2007-228167 A JP 2005-217971 A

  However, in the inventions described in Patent Documents 1 and 2, when the OSD display is switched (for example, when another OSD image is displayed or the display position of the OSD image is changed on the screen), the switching is performed in the storage unit. Since it is necessary to update the coordinate value for specifying the new area after each switching, it takes time to update, and in the OSD display after switching, the OSD image in the rectangular area before switching is an afterimage. There was a problem such as being displayed.

  An object of the present invention is to reduce the time relating to area specification in control for prohibiting image quality adjustment of a predetermined area on a screen, so that an image before switching is displayed as an afterimage when switching display. It is an object of the present invention to provide a display device and a display method that can suitably solve the above problem.

In order to solve the above-mentioned problem, the invention described in claim 1
Image quality adjusting means for adjusting the image quality of the image data;
Display means for displaying an image based on the image data whose image quality has been adjusted on a display screen;
On the display screen, designation means for designating an area for prohibiting image quality adjustment by the image quality adjustment means;
A prohibition control unit that performs control for prohibiting image quality adjustment by the image quality adjustment unit in an area designated by the designation unit;
A nonvolatile first storage unit that stores region designation information of the region;
A second storage unit that stores area designation information acquired from the first storage unit;
Obtaining means for obtaining area designation information corresponding to the area designated by the designation means from the first storage unit;
Determination means for determining whether or not the area designation information acquired by the acquisition means is stored in the second storage unit;
First storage control for storing the region designation information in the second storage unit when the determination unit determines that the region designation information acquired by the acquisition unit is not stored in the second storage unit Means,
It is characterized by providing.

  According to a second aspect of the present invention, in the display device according to the first aspect, at the time of initialization, the area designation information is acquired from the first storage unit in a predetermined number in order from a preset frequency of use, And a second storage control means for storing in the second storage unit.

The invention according to claim 3
Image quality adjusting means for adjusting the image quality of the image data;
Display means for displaying an image based on the image data whose image quality has been adjusted on a display screen;
On the display screen, designation means for designating a rectangular area that prohibits image quality adjustment by the image quality adjustment means;
Superimposing means for superimposing the OSD image on the rectangular area specified by the specifying means;
A prohibition control unit that performs control for prohibiting image quality adjustment by the image quality adjustment unit of the rectangular area designated by the designation unit;
A non-volatile first storage unit that stores area designation information of the rectangular area;
A second storage unit that stores area designation information acquired from the first storage unit;
Acquisition means for acquiring area designation information corresponding to the rectangular area designated by the designation means from the first storage unit;
Determining means for determining whether or not the area designation information acquired by the acquiring means is stored in the second storage unit;
First storage control for storing the region designation information in the second storage unit when the determination unit determines that the region designation information acquired by the acquisition unit is not stored in the second storage unit Means,
A second storage control means for acquiring a predetermined number of area designation information from the first storage section in the order of preset use frequency and storing it in the second storage section at the time of initialization;
It is characterized by providing.

According to a fourth aspect of the present invention, in the display method of the display device according to the third aspect,
The second storage control means, upon initialization, obtains a predetermined number of area designation information from the first storage unit in the order of preset usage frequency, and stores it in the second storage unit; ,
The designating unit designating a rectangular area on the display screen for prohibiting image quality adjustment by the image quality adjusting unit;
The obtaining unit obtaining region designation information corresponding to the rectangular region designated by the designation unit from the first storage unit;
The step of determining whether the determination means stores the area designation information acquired by the acquisition means in a second storage unit;
When the first storage control unit determines that the region specifying information acquired by the acquiring unit is not stored in the second storage unit by the determining unit, the specification information is stored in the second storage unit. Memorizing steps,
The prohibition control means obtains area designation information corresponding to the rectangular area designated by the designation means from the second storage unit, and performs control for prohibiting image quality adjustment by the image quality adjustment means in the rectangular area; The superimposing means superimposing an OSD image on the rectangular region of an image based on image data whose image quality has been adjusted;
The display means displaying on the display screen an image in which an OSD image is superimposed on the rectangular region of the image based on the image data whose image quality has been adjusted;
It is characterized by including.

According to the present invention, the area specifying information corresponding to the area specified by the specifying means by the acquiring means is acquired from the first storage unit, and the acquired area specifying information is stored in the second storage unit by the determining means. If it is determined that the area is not included, the first storage control means stores the area designation information in the second storage unit.
In other words, according to the present invention, the area designation information is stored in the second storage unit only when the area designation information is not stored in the second storage unit. The processing required for designating a region for which adjustment is prohibited is reduced, and the time required for control for prohibiting image quality adjustment by the prohibition control means can be shortened.
Therefore, according to the present invention, in the control for prohibiting the image quality adjustment of a predetermined area on the screen, by shortening the time relating to the area specification, an image before switching is displayed as an afterimage when switching the display. It can be said that this problem can be preferably solved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The scope of the invention is not limited to the illustrated example.
FIG. 1 is a block diagram showing a main configuration of the liquid crystal display device of the present embodiment.

As shown in FIG. 1, the display device 1 of the present embodiment includes a signal input unit 10, a video processing unit 30, a synchronization signal control circuit 50, an image quality adjustment unit 80 (image quality adjustment unit, prohibition control unit), and a liquid crystal display unit 90. (Display unit), control unit 100, operation unit 200 (designating unit), and the like, and receives a video signal such as a television broadcast signal input from the signal input unit 10 and applies it to the liquid crystal display unit 90. It is a liquid crystal television that outputs video based on a signal.
The display device 1 is not limited to a liquid crystal television, and may of course be a video display device that uses a plasma display panel (PDP), a plasma television that outputs video from the PDP, or the like.

  The signal input unit 10 includes, for example, an antenna and tuner for receiving a television broadcast signal, various video terminals for receiving a video signal from an external device, and the like. The data is output to the processing unit 30.

  The video processing unit 30 includes an A / D conversion unit 30a, a decoder 30b, an IP conversion unit 30c, a scaler 30d, and an OSD processing unit 30e (superimposing means). The input video signal is subjected to predetermined video processing and output to the image quality adjustment unit 80.

The A / D converter 30a converts the input video signal into a digital signal.
The decoder 30b separates the video signal and the audio signal from the input digital signal, and outputs the separated audio signal to an audio signal processing unit (not shown) for output to the speaker. Further, the decoder 30b demodulates the three primary color signals of R, G, and B from the video signal.

The IP conversion unit 30c converts a continuous interlaced video signal into a progressive video signal.
The scaler 30d performs a scaling process on the input digital video signal so as to match the number of pixels of the screen of the liquid crystal display unit 90, and generates image data for one screen to be displayed on the liquid crystal display unit 90. To do. Then, by outputting the image data generated in this way to the liquid crystal display unit 90, an image based on the image data is displayed on a display screen 90a of the liquid crystal display unit 90 described later.

The OSD processing unit 30e receives the video signal output from the scaler 30d and superimposes an OSD signal based on an on-screen display (OSD) image on the video signal, thereby displaying a predetermined still image superimposed on the video. Alternatively, a process for performing so-called OSD display can be performed on the display screen 90a of the liquid crystal display unit 90, for example, by displaying a predetermined still image.
In addition, the OSD processing unit 30e can receive data such as character information from the control unit 100, and can generate a still image based on the data such as the character information.
The OSD image includes, for example, an image related to an adjustment screen for image quality adjustment such as contrast and an image related to an adjustment screen for sound adjustment such as volume, and these are displayed in a part of a rectangular area of the display screen 90a. The

  The synchronization signal control circuit 50 inputs a synchronization signal included in the video signal input to the signal input unit 10 and outputs it to the video processing unit 30 and the image quality adjustment unit 80 in synchronization with a clock signal of an oscillation circuit (not shown). Then, the signal is synchronized.

The image quality adjustment unit 80 includes an image quality adjustment circuit 80a, a delay circuit 80b, and a switch 80c. The image quality adjustment circuit 80a and the delay circuit 80b are connected in parallel. The video signal that has passed through is output to the liquid crystal display unit 90.
The image quality adjustment circuit 80a applies color adjustments such as contrast adjustment, TINT adjustment, brightness adjustment, skin color correction, black and white expansion adjustment, delay adjustment, horizontal sharpness adjustment, gamma correction, noise to the video signal input from the video signal processing unit 30. Processing such as removal is performed, and the video signal after the adjustment processing is output as image data to the liquid crystal display unit 90 via a low voltage differential signal interface (LVDS) or the like.
The delay circuit 80b does not perform the image quality adjustment performed by the image quality adjustment circuit 80a on the video signal input from the video signal processing unit 30, and the video input after a predetermined time has elapsed since the video signal was input. The signal is output to the liquid crystal display unit 90.
The switch 80c is connected by switching whether the video signal input from the video signal processing unit 30 is input to the image quality adjustment circuit 80a or the delay circuit 80b under the control of the control unit 100 described later.

The liquid crystal display unit 90 includes a liquid crystal driving circuit, a liquid crystal panel, and a backlight (not shown) and forms a display screen 90a.
That is, the display screen 90a generates a voltage for driving a panel corresponding to each RGB of the liquid crystal panel by a liquid crystal driving circuit, supplies a voltage from an inverter (not shown) to turn on the backlight, and irradiates the liquid crystal panel from the back side. The image based on the image data is displayed on the liquid crystal panel.

For example, the operation unit 200 includes various buttons and switches for performing image quality adjustment and volume adjustment when an OSD display such as an image adjustment screen or a sound adjustment screen is displayed on the display screen 90a.
In addition, the user may start / end OSD display on the display screen 90a, switch to another OSD display, or display a plurality of OSD displays (a plurality of OSD images are displayed simultaneously) by the operation unit 200. Since the display position of the OSD image on the display screen 90a can be changed, the operation unit 200 functions as part of a designation unit that designates an area where image quality adjustment is prohibited.

  The control unit 100 includes, for example, a CPU (Central Processing Unit) 110, a RAM (Random Access Memory) 120 used as a work area of the CPU 110, and a ROM (Read Only Memory) 130 (first memory) that stores various programs executed by the CPU 110. Storage section) and the like.

  The CPU 110 includes a register 115 (second storage unit), and executes various programs stored in the ROM 130 in accordance with input signals input from each unit of the display device 100, and is based on the program related to the execution. Thus, the overall operation of the display device 100 is comprehensively controlled by outputting an output signal to each unit.

  The register 115 is a storage area in the CPU 110 where information can be read / written at high speed. The register 115 temporarily holds a calculation result or reads / writes data stored in the RAM 120 or the ROM 130. Addresses can be held, and operating states of processors and peripheral devices can be held and changed.

  Here, as shown in FIGS. 3 to 4, the register 115 includes a coordinate storage unit 115 a and a flag setting unit 115 b.

The coordinate storage unit 115a includes storage areas divided into eight area numbers A to H, and each of the area numbers A to H has a display position of an OSD image formed of a rectangular area displayed on the display screen 90a. The x- and y-coordinates of the start point and the end point that specify this are stored.
Specifically, for example, as shown in FIG. 2, an OSD image L is displayed on the display screen 90a. The coordinates (Lx1, Ly1) indicating the start point of this OSD image L (that is, the closest point from the origin with the upper left corner of the display screen 90a as the origin), and the end point (that is, the point farthest from the origin) , The CPU 110 stores the coordinates (Lx2, Ly2) in any one of the area numbers A to H (for example, the area number A in FIG. 3B) of the coordinate storage unit 115a.
Here, as shown in FIG. 3 (1), the coordinate storage unit 115a has all the area numbers A to H blank (empty area) in the initial state (the OSD image is not displayed after the display device 1 is activated). ).
Each x and y value is 2 bytes, and the area numbers A to H each have a capacity of 8 bytes (that is, the sum of the start point: 2 bytes × 2 and the end point: 2 bytes × 2). ing.

The flag setting unit 115b uses ON / OFF (display state / non-display state of the OSD image) used when displaying the OSD image on the display screen 90a based on the coordinates stored in the area numbers A to H of the coordinate storage unit 115a. ) A flag for switching, and a 1-bit flag corresponding to each of the area numbers A to H is allocated to bit 0 to bit 7.
Specifically, for example, when the OSD image L illustrated in FIG. 2 is displayed on the display screen 90a by the operation of the operation unit 200 by the user, as illustrated in FIG. When the bit 0 corresponding to the area number A of the coordinate storage unit 115a in which the coordinates of the start point and end point are stored is turned ON and the display of the OSD image L is ended, the area number A is set as shown in FIG. By turning off the corresponding bit 0, the display state / non-display state of the OSD image can be grasped.

  The OSD display is started / finished on the display screen 90a by the user's operation of the operation unit 200, and the OSD display is switched (change of the display position of the OSD image on the display screen 90a, display of another OSD image, etc.) Each time is performed, a request (signal) relating to the change of the coordinates of the start point and end point of the OSD image constituting the area designation data 130c stored in the ROM 130, which will be described later, and the flag setting is transmitted to the CPU 110.

  The RAM 120 includes, for example, a program storage area for expanding a processing program executed by the CPU 110, a data storage area for storing a processing result generated when the input data and the processing program are executed, and the like.

  The ROM 130 is a non-volatile memory. For example, a register update program 130a (acquisition means, determination means, first storage control means, designation means), an image adjustment control program 130b (prohibition control means), an area in the program storage area The area designation data 130c as the designation information is provided.

  The area designation data 130c stores a plurality of coordinates of the start point and the end point of an OSD image made up of a rectangular area. That is, each time the user starts / ends the OSD display, switches to another OSD display, or performs a plurality of OSD displays, the CPU 110 acquires the coordinates of the OSD image related to the OSD display. Then, the OSD display on the display screen 90a is realized by superimposing the OSD signal by the OSD processing unit 30e or the like.

The register storage update program 130a stores and updates the coordinate storage unit 115a and the flag setting unit 115b of the register 115 when the OSD display is started / finished on the display screen 90a or the OSD display is switched. It is a program that realizes the function to perform.
Specifically, the OSD display is started / finished on the display screen 90 a or the OSD display is switched by the operation of the operation unit 200 by the user, and the OSD display is related to the OSD display from the area designation data 130 c stored in the ROM 130. When the CPU 110 acquires a request for changing the coordinates of the start point and end point of the OSD image and the flag, the CPU 110 executes the register storage update program 130a, and the coordinates of the start point and end point of the received OSD image are stored in the area of the coordinate storage unit 115a. It is determined whether or not it exists in the numbers A to H. If it exists, the ON / OFF of bit 0 to bit 7 of the flag setting unit 115b corresponding to the area number is updated, and if it does not exist, the coordinates of the start point and end point are updated. Is stored in the blank area number, and the flag setting unit 115 corresponding to the area number is stored. To update the ON / OFF of bit0~bit7.
Therefore, the CPU 110 functions as an acquisition unit, a determination unit, and a first storage control unit by executing the register storage update program 130a.
Further, when an image quality adjustment control program 130b described later is executed, control is performed so that image quality adjustment is not reflected in the displayed area of the OSD image based on the coordinates and the flag. By executing the above, it functions as a designation means for designating an area where image quality adjustment is prohibited.

  More specifically, the following processing is performed using FIGS.

  First, as shown in FIG. 3A, in the initial state, the area numbers A to H of the coordinate storage unit 115a are all blank (empty areas).

Next, the rectangular OSD image L shown in FIG. 2 is displayed on the display screen 90a by the operation of the operation unit 200 by the user, and the CPU 110 uses the coordinates of the start point (Lx1, Ly1) and the end point of the OSD image L. Assume that (Lx2, Ly2) and a request to display the image are received.
In this case, as shown in FIG. 3 (1), the coordinates (Lx1, Ly1) and (Lx2, Ly2) are not stored in any of the area numbers A to H of the coordinate storage unit 115a. As shown in FIG. 3B, the coordinates (Lx1, Ly1) and (Lx2, Ly2) are stored in the area number A, and bit0 corresponding to the area number A is updated to ON.

Next, in addition to the OSD image L shown in FIG. 2, the OSD image M is simultaneously displayed on the display screen 90a by the operation of the operation unit 200 by the user, and the CPU 110 determines the coordinates of the start point and end point of the OSD image L Assume that a request to display an image and a request to set the coordinates of the start point (Mx1, My1) and end point (Mx2, My2) of the OSD image M and the image to the display state are received.
In this case, as shown in FIG. 3B, the coordinates (Lx1, Ly1) and (Lx2, Ly2) are already stored in the area number A of the coordinate storage unit 115a, and bit0 corresponding to the area number A is ON. Therefore, the storage update process for the OSD image L is not performed. On the other hand, since the coordinates (Mx1, My1) and (Mx2, My2) are not stored in any of the area numbers A to H, the CPU 110 coordinates the area number B as shown in FIG. (Mx1, My1) and (Mx2, My2) are stored, and bit1 corresponding to the area number B is updated to ON.

Next, by the operation of the operation unit 200 by the user, the OSD image L shown in FIG. 2 is not displayed on the display screen 90a, only the OSD image M is displayed, and the CPU 110 coordinates the start point and end point of the OSD image L. And the request to set the image to the non-display state, the coordinates of the start point (Mx1, My1) and the coordinate of the end point (Mx2, My2) of the OSD image M, and the request to set the image to the display state.
In this case, as shown in FIG. 3 (3), the coordinates (Lx1, Ly1) and (Lx2, Ly2) are already stored in the area number A of the coordinate storage unit 115a, and bit0 corresponding to the area number A is ON. Therefore, as shown in FIG. 4 (4), a process of updating bit0 to OFF is performed. On the other hand, since the coordinates (Mx1, My1) and (Mx2, My2) have already been stored in the area number B, and bit1 corresponding to the area number B is ON, the storage update process for the OSD image M is not performed. .

Next, the OSD image M shown in FIG. 2 is not displayed on the display screen 90a by the operation of the operation unit 200 by the user. Assume that (Mx2, My2) and a request to put the image into a non-display state are received.
In this case, as shown in FIG. 4 (4), coordinates (Mx1, My1) and (Mx2, My2) are already stored in the area number B of the coordinate storage unit 115a, and bit1 corresponding to the area number B is ON. Therefore, as shown in FIG. 4 (5), a process of updating bit1 to OFF is performed.

The image quality adjustment control program 130b adjusts the image quality for the area where the OSD image is displayed on the display screen 90a when the OSD display is started on the display screen 90a or the OSD display is switched. This program realizes functions that are not reflected.
Specifically, when the OSD display is started on the display screen 90a or the OSD display is switched, the CPU 110 executes the image quality adjustment control program 130a and refers to the flag setting unit 115b to set the flag. The area number set to ON is specified, and the area where the OSD image is displayed on the display screen 90a based on the coordinates of the start point and end point of the area number specified from the coordinate storage unit 115a (that is, image quality adjustment) The area that is prohibited. Then, when the video signal input to the image quality adjustment unit 80 is an area where the OSD image is displayed, the CPU 110 performs control to connect the switch 80c to the delay circuit 80b, and the video signal input to the image quality adjustment unit 80 is In the area where the OSD image is not displayed, control is performed so that the switch 80c is connected to the image quality adjustment circuit 80a, thereby prohibiting image quality adjustment for the area where the OSD image is displayed.
The CPU 121 functions as a prohibition control unit by executing the image quality adjustment control program 130a.

"Image quality adjustment process"
Next, the flow of image quality adjustment processing performed in the display device 1 of the present embodiment will be described with reference to the flowchart of FIG.
First, it is assumed that the OSD display is made on the display screen 90a when the user operates the operation unit 200 (step S1).
Next, the CPU 110 updates the coordinates storage unit 115a and the flag setting unit 115b by executing the register storage update program 130a (step S2).
Next, the CPU 110 executes the image quality adjustment control program 130b to perform control so that the image quality adjustment is not reflected in the area where the OSD image is displayed (step S3).
Next, the CPU 110 determines whether or not the OSD display has been switched (that is, whether or not a request for changing the coordinates of the start point and end point of the OSD image and the flag is transmitted to the control unit 100) (step S4). If it is determined that the OSD display has been switched (step S4; Yes), the processes after step S2 are repeated.
On the other hand, when the CPU 110 determines that the OSD display has not been switched (step S4; No), the process is terminated.

As described above, according to the display device 1, by executing the register storage update program 130a, the coordinates of the start point and end point of the OSD image stored in the area designation data 130c of the ROM 130 are stored in the coordinate storage unit 115a of the register 115. Only when it is determined whether or not it is stored, and only when it is determined that it is not stored, the coordinates are stored in the coordinate storage unit 115a. This burden is preferably reduced.
Further, once the coordinates of the start point and end point of the OSD image are once stored in the coordinate storage unit 115a as described above, when the display of the image is subsequently deleted or redisplayed at the same position, the coordinate storage unit 115a It is not necessary to delete or store the coordinates of the start point and end point of the image, and it is only necessary to update ON / OFF of the 1-bit flag of the flag setting unit 115b, thereby further reducing the processing load on the CPU 110.
Therefore, according to the present invention, in the control for prohibiting the image quality adjustment of a predetermined area on the screen, by shortening the time relating to the area specification, an image before switching is displayed as an afterimage when switching the display. It can be said that this problem can be preferably solved.

"Modification 1"
In the display device 1, the coordinate storage unit 115 a of the register 115 is not limited to one in which all the area numbers A to H are blank (empty area) in the initial state as shown in FIG. For example, as shown in FIG. 6 (1), the coordinate values of the start point and the end point of the OSD image that are known to be frequently used are stored in the area numbers A to H in advance. Also good.
In this case, when the control unit 110 is initialized, the CPU 110 executes the register storage update program 130a to obtain the coordinate value that is known to be frequently used from the area designation data 130c of the ROM 130, and the coordinate A predetermined number (for example, eight corresponding to the region numbers A to H) is stored in the coordinate storage unit 115a in descending order of the use frequency.
Therefore, the CPU 110 functions as a second storage control unit by executing the register storage update program 130a.

  The flow of processing performed by the CPU 110 executing the register storage update program 130a in the above case will be described with reference to FIGS. 2, 6, and 7. FIG.

  First, as shown in FIG. 6 (1), when the control unit 100 is initialized, the coordinate values of the start point and the end point with higher use frequency are acquired from the area designation data 130c of the ROM 130, and the use frequency is in descending order. Are stored in the region numbers A to H.

Next, the OSD image L shown in FIG. 2 is displayed on the display screen 90a by the operation of the operation unit 200 by the user. The CPU 110 starts the coordinates (Lx1, Ly1) of the OSD image L and the coordinates (Lx2) of the end point. , Ly2) and a request to display the image.
In this case, as shown in FIG. 6A, the coordinates (Lx1, Ly1) and (Lx2, Ly2) are already stored in the area number H of the coordinate storage unit 115a, and bit7 corresponding to the area number H is OFF. Therefore, as shown in FIG. 6 (2), a process for updating bit7 to ON is performed.

Next, in addition to the OSD image L shown in FIG. 2, the OSD image M is simultaneously displayed on the display screen 90a by the operation of the operation unit 200 by the user, and the CPU 110 determines the coordinates of the start point and end point of the OSD image L Assume that a request to display an image and a request to set the coordinates of the start point (Mx1, My1) and end point (Mx2, My2) of the OSD image M and the image to the display state are received.
In this case, as shown in FIG. 6B, the coordinates (Lx1, Ly1) and (Lx2, Ly2) are already stored in the area number H of the coordinate storage unit 115a, and bit7 corresponding to the area number H is ON. Therefore, the storage update process for the OSD image L is not performed. On the other hand, since the coordinates (Mx1, My1) and (Mx2, My2) are already stored in the area number D of the coordinate storage unit 115a, and bit3 corresponding to the area number D is OFF, FIG. 6 (3) As shown in FIG. 5, processing for updating bit3 to ON is performed.

Next, in addition to the OSD images L and M shown in FIG. 2, the OSD image N is simultaneously displayed on the display screen 90a by the operation of the operation unit 200 by the user, and the CPU 110 starts and ends the OSD images L and M. And the request to set the image to the display state, the coordinates of the start point (Nx1, Ny1) and the coordinate of the end point (Nx2, Ny2) of the OSD image N, and the request to set the image to the display state. .
In this case, as shown in FIG. 6 (3), the coordinates (Lx1, Ly1) and (Lx2, Ly2) are already stored in the area number H of the coordinate storage unit 115a, and bit7 corresponding to the area number H is ON. Since the coordinates (Mx1, My1) and (Mx2, My2) have already been stored in the area number D and bit3 corresponding to the area number D is ON, the storage update for the OSD images L and M is performed. No processing is done.

On the other hand, coordinates (Nx1, Ny1) and (Nx2, Ny2) are not stored in any of the area numbers A to H.
Therefore, the CPU 110 extracts only the bits for which the flag is set to OFF in the flag setting unit 115b, identifies the area number having the lowest use frequency among the area numbers corresponding to the extracted bits, A process of updating (overwriting) the coordinates of the area number to the coordinates of the start point and end point of the OSD image N is performed.
That is, as shown in FIG. 6 (4), the CPU 110 extracts bit0 to bit2 and bit4 to bit6 from the flag setting unit 115b, and area numbers (area numbers A to C, area numbers) corresponding to the bits. (E to G), the coordinates of the lowest region number G are updated to (Nx1, Ny1) and (Nx2, Ny2), and the bit 6 corresponding to the region number G is updated to ON.

Next, the OSD images L, M, and N shown in FIG. 2 are all hidden on the display screen 90a by the operation of the operation unit 200 by the user, and the CPU 110 starts and ends the OSD images L, M, and N. Assume that a request to hide all the coordinates and the image is received.
In this case, as shown in FIG. 7 (4), the coordinates of the start and end points of the OSD images L, M, and N are already stored in the region numbers H, D, and G of the coordinate storage unit 115a, and the region numbers H, Since bits 7, 3, and 6 corresponding to D and G are ON, as shown in FIG. 7 (5), processing for updating bits 7, 3, and 6 to OFF is performed.

As described above, according to “Modification 1” of the display device 1 according to the present embodiment, the register storage update program 130a recognizes that the frequency of use is empirically high in the coordinate storage unit 115a of the register 115. Since the coordinate values of the start point and end point of the OSD image are acquired from the area designation data 130c of the ROM 130 and stored in advance in the area numbers A to H in the order of the frequency of use, the register storage update program 130a is executed. The number of times that the coordinates of the start point and end point of the OSD image are newly stored in the coordinate storage unit 115a can be suitably reduced.
Therefore, it is possible to more suitably solve the problem that the OSD image before switching is displayed as an afterimage.

The scope of the present invention is not limited to the above embodiment, and various improvements and design changes may be made without departing from the spirit of the present invention.
For example, the display device 1 is a television for receiving digital broadcasts, receives a digital broadcast signal, superimposes data broadcast data included in the signal as a still image on the digital broadcast signal, and displays it on the display screen. It may be a thing.
In addition, the number of times the coordinates stored in each of the area numbers A to H are used in the register 115 of “Modification 1”, that is, the number of times that the flag corresponding to each of the area numbers A to H is turned ON. A counter for counting may be provided, and the coordinates stored in the region numbers A to H may be replaced in descending order of use frequency based on the number of times. As a result, the area number for which the coordinate update process is performed can be the least frequently used each time.

It is a block diagram which illustrates the principal part structure of the display apparatus in this embodiment. It is a figure which shows the state by which OSD display was made | formed on the display screen of the display apparatus in this embodiment. It is a figure which illustrates the structure of the register | resistor in this embodiment. It is a figure which illustrates the structure of the register | resistor in this embodiment. It is a flowchart explaining the image adjustment process in this embodiment. It is a figure which illustrates the composition of another register in this embodiment. It is a figure which illustrates the composition of another register in this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Display apparatus 10 Signal input part 30 Image | video process part 30a A / D conversion part 30b Decoder 30c IP conversion part 30d Scaler 30e OSD process part (superimposition means)
50 Sync signal control circuit 80 Image quality adjustment section (image quality adjustment means, prohibition control means)
80a Image quality adjustment circuit 80b Delay circuit 80c Switch 90 Liquid crystal display unit (display means)
90a Display screen 100 Control unit 110 CPU (acquisition means, determination means, first storage control means, designation means, prohibition control means, second storage control means)
115 register (second storage unit)
115a Coordinate storage unit 115b Flag setting unit 120 RAM
130 ROM (first storage unit)
130a Register storage update program (acquisition means, determination means, first storage control means, designation means, second storage control means)
130b Image quality adjustment control program (prohibition control means)
130c Area designation data 200 Operation part (designation means)

Claims (4)

Image quality adjusting means for adjusting the image quality of the image data;
Display means for displaying an image based on the image data whose image quality has been adjusted on a display screen;
On the display screen, designation means for designating an area for prohibiting image quality adjustment by the image quality adjustment means;
A prohibition control unit that performs control for prohibiting image quality adjustment by the image quality adjustment unit in an area designated by the designation unit;
A nonvolatile first storage unit that stores region designation information of the region;
A second storage unit that stores area designation information acquired from the first storage unit;
Obtaining means for obtaining area designation information corresponding to the area designated by the designation means from the first storage unit;
Determination means for determining whether or not the area designation information acquired by the acquisition means is stored in the second storage unit;
First storage control for storing the region designation information in the second storage unit when the determination unit determines that the region designation information acquired by the acquisition unit is not stored in the second storage unit Means,
A display device comprising: A second storage control means for acquiring a predetermined number of area designation information from the first storage section in the order of preset use frequency and storing it in the second storage section at the time of initialization;
The display device according to claim 1, further comprising: Image quality adjusting means for adjusting the image quality of the image data;
Display means for displaying an image based on the image data whose image quality has been adjusted on a display screen;
On the display screen, designation means for designating a rectangular area that prohibits image quality adjustment by the image quality adjustment means;
Superimposing means for superimposing the OSD image on the rectangular area designated by the designation means;
A prohibition control unit that performs control for prohibiting image quality adjustment by the image quality adjustment unit of the rectangular area designated by the designation unit;
A non-volatile first storage unit that stores area designation information of the rectangular area;
A second storage unit that stores area designation information acquired from the first storage unit;
Acquisition means for acquiring area designation information corresponding to the rectangular area designated by the designation means from the first storage unit;
Determination means for determining whether or not the area designation information acquired by the acquisition means is stored in the second storage unit;
First storage control for storing the region designation information in the second storage unit when the determination unit determines that the region designation information acquired by the acquisition unit is not stored in the second storage unit Means,
A second storage control means for acquiring a predetermined number of area designation information from the first storage section in the order of preset use frequency and storing it in the second storage section at the time of initialization;
A display device comprising: The display method of the display device according to claim 3,
The second storage control means, upon initialization, obtains a predetermined number of area designation information from the first storage unit in the order of preset usage frequency, and stores it in the second storage unit; ,
The designating unit designating a rectangular area on the display screen for prohibiting image quality adjustment by the image quality adjusting unit;
The obtaining unit obtaining region designation information corresponding to the rectangular region designated by the designation unit from the first storage unit;
The step of determining whether the determination means stores the area designation information acquired by the acquisition means in a second storage unit;
When the first storage control unit determines that the region specifying information acquired by the acquiring unit is not stored in the second storage unit by the determining unit, the specification information is stored in the second storage unit. Memorizing steps,
The prohibition control means obtains area designation information corresponding to the rectangular area designated by the designation means from the second storage unit, and performs control for prohibiting image quality adjustment by the image quality adjustment means in the rectangular area; The superimposing means superimposing an OSD image on the rectangular region of an image based on image data whose image quality has been adjusted;
The display means displaying on the display screen an image in which an OSD image is superimposed on the rectangular region of the image based on the image data whose image quality has been adjusted;
A display method comprising:

Images