JP3246217B2 - Display method of halftone image on display panel - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a display panel such as a plasma display panel (hereinafter simply referred to as PDP) or a liquid crystal display panel (hereinafter simply referred to as LCD). (1 field screen) is divided into N (N is an integer of 2 or more) subfield screens corresponding to the display gradation, and the number of display pulses of each subfield screen is weighted corresponding to each bit, thereby inputting. The present invention relates to a method for displaying an N-bit halftone image of a video signal. Here, one frame screen represents one screen displayed during one frame period Tf (about (1/30) second), and one field screen represents one screen displayed during one field period (about (1/60) second). Express.

[0002]

2. Description of the Related Art When displaying a halftone image of an input video signal (for example, a television signal) on a device having a large threshold characteristic such as a PDP, it is generally performed using a pulse modulation method in which the number of times of light emission is proportional to the video signal. ing. Specifically, the input video signal is digitized, each frame screen is divided by the number of bits to create N subfield screens, and each subfield screen emits light a number of times proportional to the weight of the digital video signal. Performs gradation display. The display order of the subfield screen corresponding to each bit has been conventionally fixed.

[0003] For example, when displaying a halftone with 8 bits and 256 gradations, as shown in FIG. 6, one frame screen (one frame period Tf (for example, about (1/30) second))
Is divided into eight subfield screens (screens displayed in subfield periods SF1 to SF8), and each subfield period SF1,..., SF8 is divided into an erasing period IP, an address period AP, and a display period SP. The display period SP is weighted with a ratio of 1: 2: 4: 8:...: 128.

The IP and the AP are the same in each subfield period (for example, the sum of the IP and the AP is 1.5 ms). The display order of the subfield screen corresponding to each bit is, for example, SF1, SF2, SF3, SF4, SF
5, SF6, SF7, SF8 in a fixed order.

[0005]

However, in the conventional halftone image display method described above, the display order of the subfield screen is fixed (fixed), so that the moving image moves in the background image. In the case of a screen, a false image occurs in the boundary area between the moving image and the background image, and when this false image appears in a false contour part that occurs in a part where the brightness changes gradually, such as a human face, the original brightness change There is a problem that a sharp change in brightness occurs in a gentle portion (color generally changes in the case of color), and display quality is significantly impaired.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and eliminates a false image generated when a boundary of a moving image is visually observed in a display panel (for example, a PDP) which performs gradation display by a subfield method. It is an object of the present invention to provide a method for displaying a halftone image on a display panel, which can prevent a decrease in display image quality.

[0007]

According to a first aspect of the present invention, a unit display screen of a display panel is divided into N subfield screens corresponding to a display gradation of N bits (N is an integer of 2 or more). In a method of displaying a halftone image of an input video signal by weighting the number of display pulses of each subfield screen corresponding to each bit, a false image area generated at a boundary between a moving image and a background image on the display screen of the display panel Is detected, it is determined whether or not the brightness of the false image area is higher than the brightness when the input video signal is faithfully displayed, and the lighting of the pixels of the false image area is controlled based on the determination result. It is characterized by becoming.

According to a second aspect of the present invention, in the first aspect, the detection of the false image area and the determination of the luminance of the false image area correspond to a moving image and a background image on two continuous unit display screens. This is obtained from the luminance of the subfield screen, the display order, and the time distribution.

[0009]

According to the first aspect of the present invention, a false image region generated at a boundary between a moving image and a background image on a display screen of a display panel (for example, a PDP) is detected, and the luminance of the false image region faithfully displays an input video signal. It is determined whether or not the brightness is higher than the brightness at the time, and the lighting of the pixels in the fake image area is controlled based on the determination result. Lighting of pixels in the false image area is controlled according to whether the image is bright or dark (for example, non-lighting when bright and lighting when dark) eliminate the false image.

According to a second aspect of the present invention, in the first aspect of the present invention, the detection of the false image area and the determination of the luminance of the false image area correspond to a moving image and a background image on two continuous unit display screens. The detection of the false image area and the determination of the luminance of the false image area are facilitated by obtaining the luminance, the display order, and the time distribution of the subfield screen.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a halftone image display method according to the present invention will be described below with reference to FIGS. FIG. 1 shows a schematic configuration of a main part of a driving device for carrying out the method of the present invention. In FIG. 1, reference numerals 10, 12, and 14 denote first, second, and third frame memories having a memory capacity capable of reading and writing digital video signals for one frame screen.

The first, second and third frame memories 1
An input terminal 18 of a digital video signal is connected to the writing side of 0, 12, 14 via a first switching circuit 16 that is switched and controlled by a control circuit (not shown). The first, second, and third frame memories 10, 12,
A signal processing circuit 24 is connected to the read side of the signal processing circuit 14 via second and third switching circuits 20 and 22 that are switched and controlled by a control circuit (not shown). On the output side of the signal processing circuit 24, a PDP (for example, a display capacity of 640
× 480 pixels of PDP) 28 are connected.

The first, second and third frame memories 1
Memory control by a memory control circuit (not shown) and first, second, and third switching circuits 16, 20,
By the switching control by 22, a frame of the digital video signal input to the input terminal 18 for one frame screen is sequentially written, and the digital video signal is appropriately read from the frame memory which has been written into the predetermined memory area. Have been.

For example, as shown in the figure, signals of two consecutive frame screens are sequentially written into the first and second frame memories 10 and 12, and then the third frame memory 14 is written.
When the writing of the signal of one frame screen subsequent to the first frame is started, the first and second frame memories 10 and 12
Are read out at appropriate timing and input to the signal processing circuit 24.

The signal processing circuit 24 includes the area detection circuit 3
0, a luminance determination circuit 32, and a luminance correction circuit 34. The area detection circuit 30 determines the PDP 28 based on the brightness, display order, and time distribution of a field screen corresponding to a moving image and a background image in two consecutive frame screens.
Is configured to detect a fake image area generated at the boundary between the moving image and the background image on the display screen of FIG.

The luminance discriminating circuit 32 determines the luminance of the false image area based on the luminance, display order, and time distribution of the field screen corresponding to the moving image and the background image in two consecutive frame screens. Is determined so as to determine whether or not the display is brighter than the display brightness (hereinafter, simply referred to as the original luminance in this embodiment). The brightness correction circuit 34 is configured to control the lighting of the pixels in the false image area detected by the area detection circuit 30 based on the determination output of the brightness determination circuit 32.
Therefore, the signal processing circuit 24 outputs a digital video signal for displaying a screen on which the luminance of the false image area has been corrected.

Next, an example in which the method of the present invention is carried out using the driving device of FIG. 1 will be described with reference to FIGS. A: First, as shown in FIG. 2, a case where a moving image moves in a dark (for example, SF1 having a luminance weight of 1) background image in a dark (for example, SF2 having a luminance weight of 2) background image will be described.

For convenience of explanation, as shown in FIG. 2, the horizontal axis is time T, the vertical axis is distance X in the X direction (for example, the upward direction of the screen), and the display order of subfields is SF2, SF1.
And the subfield time interval between SF2 and SF1 is Ts
It is assumed that the moving image is moving at a speed V in the X direction.

(A) In each of the frame screens displayed during one frame period Tf, among subfield screens SF2 and SF1 constituting one frame screen, SF2 is displayed first, and then SF1 is displayed. A viewer watching the moving image with the brightness of SF2 looks at the rear end of the moving direction of the moving image as moving along the thin line L1.
Also, the tip of the background image with the brightness of SF1 in contact with the moving image is
It appears to move along the thin line L2. Therefore, L
The display portion corresponding to the oblique band portion 40 between 1 and L2 appears darker than the original luminance.

That is, as shown in FIG. 2 and FIG.
The timing of watching the subfield screen of F1 is T
If it is assumed that T1 and T2, at T1 and T2, the viewer is following the moving image moving upward (X direction) on the screen, and the rear end of the moving image (corresponding to SF2) is located at the position of the thin line L1. Seems to exist. For this reason, the area (the trailing edge of the moving image) 42 indicated by the two-dot chain line, which corresponds to the distance Xs from the rear end to the front end of the background image (corresponding to SF1), is the luminance of the original background image (SF1). ) Is darker, resulting in false image areas. Here, Xs is V · Ts (representing V × Ts).

(B) The false image area 42 is detected by the area detection circuit 30 of the signal processing circuit 24. In other words, the area detection circuit 30 is configured to control the two frame memories 1 of the first, second, and third frame memories 10, 12, and 14.
A false image is generated based on digital video signals of two successive frame screens (signals corresponding to the luminance, display order, and time distribution of the field screens SF2 and SF1 corresponding to the moving image and the background image) sequentially read from 0 and 12 respectively. The area 42 is detected.

(C) Next, the luminance determination circuit 32 of the signal processing circuit 24 determines whether the luminance of the false image area 42 is higher than the original luminance. That is, the luminance discrimination circuit 32 includes the first, second, and third frame memories 10, 12,
14, a digital video signal of two consecutive frame screens sequentially read from two frame memories 10 and 12 (field screen SF2 corresponding to a moving picture and a background picture).
It is determined that the luminance of the fake image area 42 is lower than the original luminance (the luminance SF1 of the background image) based on the luminance of the SF1 and the signal corresponding to the display order and the time distribution of the SF1.

(D) Next, the luminance correction circuit 34 of the signal processing circuit 24 controls the lighting of the pixels in the false image area 42 based on the discrimination output of the luminance discrimination circuit 32. That is, the luminance correction circuit 34 corrects the digital video signal for display so that the pixels in the false image area 42 are turned on based on the discrimination output of the luminance discrimination circuit 32. This correction is
In FIG. 2, this corresponds to extending the background image (SF1) to the fake image area 42. In FIG. 3, the same as the background image between the rear part of the moving image (SF2) and the background image (SF1) (the rear edge of the moving image). This is equivalent to adding the luminance correction amount 44.

For this reason, a digital video signal in which the luminance of the false image area 42 is corrected is output from the signal processing circuit 24, and this output signal is input to the drive circuit 26, and the PDP 28
To drive display. The PDP 28 displays a screen corresponding to the digital video signal without the false image area 42. That is, a moving image (SF2) moving at a speed V in the X direction in the background image (SF1) is displayed without a false image.

B: Second, as shown in FIG. 4, a dark (eg, SF1, SF2 with a luminance weight of 1, 2) moving image moves in a bright (eg, SF3 with a luminance weight of 4) background image. Will be described. For convenience of explanation, the display order of the subfields is SF2, SF as shown in FIG.
3, it is assumed that the subfield time interval between SF3 and SF1 is Ts in SF1, and the other is the same as that in FIG.

(A) The subfield screens SF2, SF3, SF1 constituting the frame screen are SF2, SF3,
Displayed in the order of SF1. A viewer watching the moving image with the brightness of SF1 + SF2 looks at the rear end of the moving direction of the moving image as moving along the thin line L1. In addition, the leading end where the background image with the luminance of SF3 is in contact with the moving image appears to move along the thin line L2. Therefore, the display portion corresponding to the oblique band portion 50 between L1 and L2 looks brighter than the original luminance.

That is, as shown in FIG. 4 and FIG.
Assuming that the timing of viewing the subfield screen of the background image of F3 is T1, at this time T1, the observer is following the moving image moving upward (X direction) on the screen.
Moving image (SF1 + SF2) of background image (SF3) with high brightness
It can be seen that the tip on the (corresponding) side is present at the position of the fine line L2 shifted by Xs in the X direction from the original fine line L1.

For this reason, the area (rear part of the moving image) 52 indicated by the two-dot chain line corresponding to the distance Xs becomes brighter by the luminance (SF3) than the original luminance (SF1 + SF2) of the moving image, and becomes a false image area. .

(B) The false image area 52 is detected by the area detection circuit 30 of the signal processing circuit 24 in the same manner as in the case (b) of A. (C) Next, the luminance determination circuit 32 of the signal processing circuit 24
Determines that the luminance of the false image area 52 is brighter than the original luminance (SF1 + SF2) in the same manner as in the case of (c) in A.

(D) Next, the luminance correction circuit 34 of the signal processing circuit 24 determines the fake image area 5 based on the discrimination output of the luminance discrimination circuit 32 in the same manner as in (d) of A.
The digital video signal for display is corrected so that the second pixel is turned on. This correction corresponds to the removal of the background image (SF3) only in the false image region 52 in FIG. 4, and in FIG. 5, the background image (SF3) and the background image between the moving image (SF1 + SF2) and the background image (SF3) are removed. This is equivalent to reducing the correction amount 54 of the same luminance.

For this reason, a digital video signal in which the luminance of the false image area 52 has been corrected is output from the signal processing circuit 24, and this output signal is input to the driving circuit 26, and the PDP 28
To drive display. The PDP 28 displays a screen corresponding to a digital video signal without the false image area 52. That is, a moving image (SF1 + SF2) moving at a speed V in the X direction in the background image (SF3) is displayed without a false image.

In the above embodiment, N = 2 (A: when the moving image is brighter than the background image), or when N = 3.
The present invention is used in the case of eight gradation display (B: when the moving image is darker than the background image). However, the present invention is not limited to this, and when N is an integer of 2 or more (for example, N = 8) 25
Of course, it can be used for (6 gradations (8 bits)) display).

In the above embodiment, in order to facilitate detection of a false image area, the present invention is applied to a case where a false image occurs at the rear of a moving image. However, the present invention is not limited to this. It can be used for a case where a fake image occurs at a boundary between a moving image and a background image. For example,
The present invention can also be applied to a case where a false image occurs at the front end in the moving direction of the moving image.

In the above embodiment, in order to facilitate detection of the false image area and determination of the luminance of the false image area, the detection of the false image area and the determination of the luminance of the false image area are continuously performed. The luminance, the display order, and the time distribution of the subfield screen corresponding to the moving image and the background image in the unit display screen are determined based on the luminance, the display order, and the time distribution. However, the present invention is not limited to this. A fake image area generated at the boundary of the image is detected, and it is determined whether or not the luminance of the fake image area is higher than the original luminance (that is, the luminance when the input video signal is faithfully displayed). It is only necessary to control the lighting of the pixels in the false image area to eliminate the false image.

In the above embodiment, the display panel is P
The case where the present invention is used as DP has been described,
The present invention is not limited to this, and the present invention can be applied to a display panel (for example, LCD) other than the PDP.

[0036]

According to the first aspect of the present invention, in a display panel (for example, a PDP) which performs gradation display by a subfield method, a false image region generated at a boundary between a moving image and a background image is detected, and the luminance of the false image region is detected. Determines whether the brightness is higher than the brightness when the input video signal is faithfully displayed, and controls the lighting of the pixels in the false image area based on the determination result. Can be prevented from decreasing.

According to a second aspect of the present invention, in the first aspect of the present invention, the detection of the false image area and the determination of the luminance of the false image area correspond to a moving image and a background image on two continuous unit display screens. Since it is determined from the luminance of the subfield screen, the display order, and the time distribution, it is possible to easily detect a false image area and determine the luminance of the false image area.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a main part of a driving device that performs a halftone image display method for a display panel according to the present invention.

FIG. 2 is a diagram for explaining an operation of eliminating a false image generated on a screen in which a bright moving image moves in the X direction in a dark background image by using the driving device of FIG. 1; FIG. 4 is an explanatory diagram in which the vertical axis represents the distance in the X direction.

FIG. 3 is a diagram for explaining an operation of eliminating a false image generated on a screen in which a bright moving image moves in the X direction in a dark background image by using the driving device of FIG. 1; FIG. 5 is an explanatory diagram in which a distance is set and a luminance B is set on a vertical axis.

FIG. 4 is a view for explaining an operation of eliminating a false image generated on a screen in which a dark moving image moves in the X direction in a bright background image by using the driving device of FIG. 1; FIG. 4 is an explanatory diagram in which the vertical axis represents the distance in the X direction.

FIG. 5 is a diagram for explaining an operation of eliminating a false image generated on a screen in which a dark moving image moves in the X direction in a bright background image by using the driving device of FIG. 1; FIG. 5 is an explanatory diagram in which a distance is set and a luminance B is set on a vertical axis.

FIG. 6 shows one frame period for displaying one frame screen and a subfield period for displaying a subfield screen constituting one frame screen when displaying 256 gradations (8 bits) by a general subfield method. FIG.

[Explanation of symbols]

10, 12, 14 ... frame memory, 16, 20, 2
2 switching circuit, 18 input terminal, 24 signal processing circuit, 26 driving circuit, 28 PDP (plasma display panel), 30 area detection circuit, 32 luminance determination circuit, 34 luminance correction circuit, 40, 50: oblique band portion, 42, 52: false image area, 44, 54: correction amount, B: luminance, L1: line representing the movement of the rear end in the moving direction of the moving image, L2: front end of the background image on the moving image side line representing the movement of the parts, (corresponding to the sub-field screen) SF1 to SF8 ... subfields, T ... time, T _1, T ₂ ... time, Ts ... subfield interval, Tf ... 1 frame period (unit display period Example of unit display screen),
V: moving speed of moving image, X, Xs: distance.

Claims (2)

(57) [Claims] 1. A unit display screen of a display panel is divided into N subfield screens corresponding to a display gradation of N bits (N is an integer of 2 or more). In the method of displaying a halftone image of an input video signal by performing weighting corresponding to (i), a false image region generated at a boundary between a moving image and a background image on the display screen of the display panel is detected, and the luminance of the false image region is determined. Display the input video signal faithfully
Determining whether or not the brightness is higher than the brightness at the time of the display, and controlling the lighting of the pixels in the false image area based on the determination result. 2. The method according to claim 1, wherein the detection of the false image area and the determination of the luminance of the false image area include the luminance of a subfield screen corresponding to a moving image and a background image in two continuous unit display screens.
2. The halftone image display method for a display panel according to claim 1, wherein the method is obtained from a display order and a time distribution.