JP3414161B2 - Pseudo halftone image display device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is for displaying a pseudo halftone image by an error diffusion method or an ordered dither method in a display device using a PDP (plasma display panel) or LCDP (liquid crystal display panel) as a display panel. The present invention relates to a pseudo halftone image display device.

[0002]

2. Description of the Related Art Recently, as a thin and lightweight display device, P
DP is drawing attention. This PDP driving method is completely different from the conventional CRT driving method and is a direct driving method using a digitized video input signal. Therefore, the brightness gradation emitted from the panel surface is determined by the number of bits of the signal to be handled.

PDPs are AC type and DC type which have different basic characteristics.
It can be divided into two types. In the AC type PDP, there was only a report about a gray scale display up to a maximum of 64 gray scale displays at a prototype level, but a future 256 gray scale method by an address / display separation type driving method (ADS subfield method) was proposed. There is.

This ADS subfield method is, for example,
As shown in FIG. 2, one frame (or one field)
And the relative ratio of brightness is 1, 2, 4, 8, 16, 32, 6
It is composed of 8 subfields of 4, 128, and 256 gradations are displayed by combining the luminance of 8 screens. Each subfield is composed of an address period for writing refreshed data for one screen and a sustain period for determining the luminance level of the subfield. In the address period, wall charges are initially formed in each pixel at the same time on the entire screen, and then sustain pulses are applied to the entire screen for display. The brightness of the subfield is proportional to the number of sustain pulses and is set to a predetermined brightness. In this way, 256 gradation display is realized.

In the AC driving method as described above, as the number of gradations is increased, the number of bits in the address period as a preparation period for lighting and emitting the panel within one frame period is increased. The period is relatively short and the maximum brightness is low. In this way, since the brightness gradation emitted from the panel surface is determined by the number of bits of the signal to be handled, if the number of bits of the signal to be handled is increased, the image quality is improved, but the light emission luminance is reduced, and conversely If the number of bits is reduced, the light emission luminance is increased, but gradation display is reduced and the image quality is deteriorated.

The processing by the error diffusion method or the systematic dither method for minimizing the density error between the input signal and the light emission luminance while reducing the bit number of the output drive signal more than the bit number of the input signal is a pseudo intermediate process. This is a process for expressing tones, and is used when expressing light and shade with a small number of tones.

A conventional general error diffusion circuit 10 is shown in FIG.
It is configured as shown in. In this circuit 10,
N (eg 8) bits (N (eg 25
6) The video signal of the original pixel Ai, j corresponding to the gradation) is input, passes through the vertical direction addition circuit 14 and the horizontal direction addition circuit 16, and the bit number is m (for example, 4) (m) by the bit conversion circuit 18. ≦ n−1) bits (corresponding to M (for example, 16) gradations) are reduced, and the PDP 20 as a display panel emits light through a panel drive circuit (not shown).

The error detection circuit 22 is a horizontal addition circuit 1
The error diffusion signal output from 6 is compared with the data stored in advance in the ROM or the like to detect the error, and the error weighting circuit 2
Reference numerals 4 and 26 multiply the detected signal by a predetermined coefficient and weight it for output, and the h-line delay circuit 28 delays the output signal of the error weighting circuit 24, and reproduces it as a reproduction error generated in the pixel before the h-line. The signal is output to the vertical addition circuit 14, and the d-dot delay circuit 30 delays the output signal of the error weighting circuit 26 and outputs it to the horizontal addition circuit 16 as a reproduction error generated in the pixel before d dots.

As a result, as shown in FIG. 4, the output terminal of the bit conversion circuit 18 instantaneously outputs a signal of a light emission luminance level represented by 4 bits like a stepped solid line. Despite this, in reality, since the emission luminance levels above and below the solid-line stairs are alternately output at a predetermined ratio, they are recognized in an averaged state, and a corrected luminance line of y = x like a dotted line is obtained. .

[0010]

However, when the error diffusion process is performed by using the personal computer video signal as an input signal, there is a problem that a pseudo pattern appears due to the error diffusion.
It is considered that, since the personal computer video signal is digitally input, the same level is continuously input without including analog noise, and a pseudo pattern due to error diffusion appears.

In view of the above problems, the present applicant selects whether or not to perform error diffusion processing depending on whether the input video signal is a personal computer video signal or a general video signal, and the number of subfields in one frame. A pseudo-halftone image display device by error diffusion as shown in FIG. 5 has already been proposed for the purpose of preventing the generation of a pseudo-pattern by switching between the two (see Japanese Patent Laid-Open No. 7-14092).
3).

In FIG. 5, reference numeral 32 is a video processing unit, 34 is a video display unit, and the video processing unit 32 is a video signal switching unit 3.
6, the error diffusion circuit 10 and the signal selection unit 38, the video display unit 34 is composed of the PDP 20 and the panel control drive unit 40, the panel control drive unit 40 is a 6-bit memory 42 for personal computer video, 4 bits for general video Memory 44,
It comprises a bit switching unit 46 and an address control unit 48.

In the above-mentioned configuration, if the personal computer video signal input to the personal computer video signal input terminal 52 is selected by the switching signal input to the switching signal input terminal 50, the video signal switching unit 36 is set to the input terminal 52. The input personal computer video signal is selected, and the signal selector 38 selects the personal computer video signal that does not pass through the error diffusion circuit 10 to select the PDP.
Output to 20. Further, the bit switching section 46 selects the data in the 6-bit memory 42 for personal computer video, and this data is sent to the PDP 20 via the address control section 48.
Therefore, the PDP 20 can obtain an image by the video signal from which the error diffusion is not performed from the signal selection unit 38 and the address signal from the address control unit 48. For the image at this time, by using the data of the personal computer video 6-bit memory 42, the gradation necessary for the personal computer is obtained, and since the error diffusion processing is not performed, the pseudo pattern caused by the error does not occur. .

Assuming that the general video signal input to the general video signal input terminal 54 is selected by the switching signal input to the switching signal input terminal 50, the video signal switching unit 36 selects the general video signal input to the input terminal 54. Then, the signal selection unit 38 selects the general video signal that has passed through the error diffusion circuit 10 and outputs it to the PDP 20. Further, the bit switching unit 46 selects the data in the general video 4-bit memory 44, and this data is sent to the PDP 20 via the address control unit 48. Therefore, the PDP 20 can obtain an image by the error-diffused video signal from the signal selection unit 38 and the address signal from the address control unit 48. For the image at this time, the number of sub-frames of one frame, the number of sustain pulses, etc. can be switched by using the data in the general video 4-bit memory 44. The sustain period is longer than that of the above, and the image has high brightness and high contrast.

However, in the already proposed display device shown in FIG. 5, the driving gradation number of the PDP 20 is switched depending on whether the input video signal is a personal computer video signal or a general video signal (switching between 6-bit gradation and 4-bit gradation). However, since the number of output bits (grayscale number) of the error diffusion circuit 10 is fixed (4 bit grayscale), in order to avoid saturation of the panel drive current, a panel drive monitoring unit is provided to drive the grayscale of the PDP 20. In the case of considering a configuration for optimizing the number (for example, reducing the number of bits of the panel drive signal when displaying a bright screen), the PD
There is a problem that the output bit number of the error diffusion circuit 10 cannot be controlled to be increased or decreased according to the increase or decrease of the drive gradation number of P20, and the image quality is deteriorated due to the change of the gradation number.

The present invention has been made in view of the above-mentioned problems, and in a display device in which the number of drive gradations (the number of display bits) of the display panel on the image display side is optimized,
It is an object of the present invention to obtain a pseudo halftone image display device capable of preventing the deterioration of image quality due to the change in the number of gradations.

[0017]

According to the present invention, pseudo-halftone processing is performed on an input video signal of N gradations to obtain M gradations (M≤N-
1) A pseudo halftone processing circuit that converts and outputs the display signal, a panel drive circuit that outputs a panel drive signal based on the output signal of the pseudo halftone processing circuit, and a based on the output signal of the panel drive circuit Based on the output signal of the display panel and the panel drive circuit that displays the pseudo-halftone image
A panel drive monitoring circuit that outputs a panel drive control signal for optimizing the number of drive gray scales of the display panel to the panel drive circuit and also outputs a panel drive state signal indicating the drive state of the display panel, and this panel drive monitoring And an output gradation number setting circuit for variably setting the gradation number M of the output signal in the pseudo-halftone processing circuit to the driving gradation number of the display panel based on the panel driving state signal of the circuit. It is a feature.

When an input video signal of N gradations is subjected to pseudo-halftone processing (for example, error diffusion processing) by a pseudo-halftone processing circuit (for example, error diffusion circuit) and is inputted to the panel drive circuit as a display signal of M gradations, this A drive signal is input from the panel drive circuit to the display panel to display a pseudo halftone image. When the drive signal from the panel drive circuit is input to the panel drive monitoring circuit, the panel drive control signal output from the panel drive monitoring circuit causes the number of gray scales of the output signal of the panel drive circuit to change the number of drive gray scales of the display panel. The value is optimized. For example, for a screen whose display level is below a predetermined value (for example, a dark screen), the gradation number of the output signal is made equal to the original gradation number M (for example, 64) of the display signal, and the display level is brighter than the predetermined value. Regarding the screen, when the gradation number of the output signal is set to a value smaller than the original gradation number M of the display signal (for example, 32) and the screen returns to a screen whose display level is equal to or lower than a predetermined value,
Control is performed so that the number of gradations of the output signal is returned to the initial value (for example, 64).

When a drive signal from the panel drive circuit is input to the panel drive monitoring circuit, a panel drive state signal indicating the drive state of the display panel is output from the panel drive monitoring circuit and input to the output gradation number setting circuit. Therefore, the output gradation number setting circuit sets the gradation number M of the output signal in the pseudo halftone processing circuit to the driving gradation number (for example, 6) of the display panel.
4 or 32). Therefore, the gradation number of the output signal in the pseudo halftone processing circuit is changed according to the change of the driving gradation number of the display panel, and the deterioration of the image quality due to the change of the gradation number can be prevented.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described with reference to FIG. 1, the same parts as those in FIGS. 3 and 5 are designated by the same reference numerals. In FIG. 1, reference numeral 56 is a video processing unit, and 58.
Represents a video display section. The video processing unit 56 includes an error diffusion circuit 60, an output gradation number setting circuit 62 and a comparison data setting circuit 64, and the video display unit 58 includes a panel driving circuit 66, a display panel 68 including a PDP, and a panel driving circuit. It comprises a monitoring circuit 70.

The error diffusion circuit 60 is similar to the case of FIG. 5 in that the vertical direction addition circuit 14, the horizontal direction addition circuit 16 and the bit conversion circuit 1 which are sequentially coupled to the input terminal 12.
8a, an error detection circuit 22a coupled to the output side of the horizontal direction addition circuit 16, error weight circuits 24 and 26 coupled to the output side of the error detection circuit 22a, and outputs of the error weight circuits 24 and 26. It is composed of an h-line delay circuit 28 and a d-dot delay circuit 30 which delay the signal and output it as a reproduction error to the vertical direction addition circuit 14 and the horizontal direction addition circuit 16. The panel drive monitoring circuit 70 includes a panel drive controller 72 and a drive current monitor 74.

Next, the operation of the above embodiment will be described.
N (eg 8) bits (N (eg 25
6) When the video signal of the original pixel Ai, j corresponding to the gradation) is input, the vertical direction addition circuit 14 and the horizontal direction addition circuit 16
The error diffusion signal is obtained by adding the reproduction errors generated in the past from the original pixel, and the number of bits is m (for example, 6) (m ≦ n−1) bits (M (for example, 64) floor) in the bit conversion circuit 18a. Corresponding to the tone) and input as a display signal to the panel drive circuit 66 of the video display unit 58.
Then, a drive signal (for example, an m-bit (M gradation) video signal for subfield screen display and an address signal) is input from the panel drive circuit 66 to the display panel 68,
The display panel 68 displays a pseudo halftone image due to error diffusion.

The error detection circuit 22a detects the error by comparing the error diffusion signal output from the horizontal direction addition circuit 16 with the data stored in advance in the ROM or the like, and the error weight circuits 24 and 26 detect the detected signal. Is multiplied by a predetermined coefficient to be weighted and output, and the h-line delay circuit 28 delays the output signal of the error weighting circuit 24 and outputs it to the vertical direction addition circuit 14 as a reproduction error generated in the pixel before the h-line. The d dot delay circuit 30 delays the output signal of the error weighting circuit 26 and outputs it to the horizontal direction addition circuit 16 as a reproduction error generated in the pixel before d dots.

When a drive signal from the panel drive circuit 66 is input to the panel drive monitor circuit 70, a panel drive control signal is output from the panel drive control section 72 of the panel drive monitor circuit 70 to the panel drive circuit 66 to drive the panel. Circuit 6
The number of bits of the output signal of 6 is controlled to a value that optimizes the number of drive gradations of the display panel 68. Specifically, the panel drive control unit 72 of the panel drive monitoring circuit 70 detects the control current or the control voltage supplied from the panel drive circuit 66 to the display panel 68 and controls the panel drive circuit 66 so that the panel drive circuit 66 is driven. The number of gradations can be optimized.

For example, for a screen whose display level is below a predetermined value (for example, a dark screen), the number of bits of the output signal is made equal to the initial number of bits of the display signal m (for example, 6), and the display level exceeds the predetermined value. For a bright screen, the bit number of the output signal is set to a value smaller than the initial bit number m of the display signal (for example, 5), and when the display level returns to a screen below a predetermined value, the bit number of the output signal is set to the initial value ( For example, control is performed to return to 6).

When the drive signal from the panel drive circuit 66 is input to the panel drive monitor circuit 70, the drive current monitor section 74 of the panel drive monitor circuit 70 outputs a panel drive state signal indicating the drive state of the display panel 68. The panel drive state signal is a signal indicating the number of drive bits, the number of drive subfields, or the number of drive gradations of the display panel 68.

The output gradation number setting circuit 62 determines the bit number m (corresponding to the gradation number M) of the display signal in the error diffusion circuit 60 based on the panel driving state signal described above, and the driving gradation of the display panel 68. The number of bits corresponding to the number is variably set.
For example, if the panel drive state signals representing the drive bit numbers 6 and 5 of the display panel 68 are “1” and “0”,
When the panel drive state signal is "1", the output gradation number setting circuit 62 causes the bit number m of the bit conversion circuit 18a to be m.
Is set to a corresponding value (for example, 6), and when the panel drive state signal is "0", the output gradation number setting circuit 62 sets the bit number m of the bit conversion circuit 18a to a corresponding value (for example, 5). It

Further, the comparison data setting circuit 64 compares the comparison data stored in the ROM or the like of the error detection circuit 22a with the comparison data corresponding to the number of drive gradations of the display panel 68 based on the panel drive state signal. (That is, set to comparison data corresponding to the bit number m of the bit conversion circuit 18a). For example, the panel drive status signal is "1"
(When the number of bits m of the bit conversion circuit 18a is 6), one of the two types of comparison data (corresponding to when m is 6) stored in the ROM or the like of the error detection circuit 22a by the comparison data setting circuit 64. (Comparison data) is set and the panel drive state signal is “0” (when the bit number m of the bit conversion circuit 18a is 5), the comparison data setting circuit 64 stores 2 in the ROM of the error detection circuit 22a. The other type of comparison data (comparison data corresponding to m = 5) is set.

Therefore, when the number of bits of the output signal of the panel drive circuit 66 is controlled to a value (for example, 5) that optimizes the number of drive gray levels of the display panel 68, the number of output gray levels is changed by the panel drive state signal. Since the setting circuit 62 variably sets the number of bits m of the output signal of the error diffusion circuit 60 to the number of bits (for example, 5) corresponding to the number of drive gradations of the display panel 68,
The number of drive gray scales of the display panel 68 can be optimized in order to avoid saturation of the panel drive current, and the error diffusion circuit 6 can be changed according to the change of the number of drive gray scales of the display panel 68.
By changing the number of bits of the output signal of 0, it is possible to prevent the deterioration of the image quality due to the change in the number of gradations.

In the above embodiment, the number of drive bits of the display panel is 6 and 5 in order to avoid saturation of the panel drive current.
Corresponding to the panel drive status signals "1" and "0", and the panel drive status signal corresponding to the panel drive status signals "1" and "0". Although the case where the bit numbers m of the bit conversion circuit are set to 6 and 5 respectively has been described, the present invention is not limited to this, and the number of drive bits of the display panel is 3 or more types (for example, 6 and 5). And 4), and in response to this, there are three or more types of panel drive status signals (“10”, “01”, and “00”).
And the number of bits of the bit conversion circuit corresponding to this changes to m
Can also be used for the case where is set to a corresponding value (for example, 6 and 5 and 4). Further, although the number of display bits has been described, the present invention is not limited to this, and may be a value corresponding to the number of display gradations (for example, 64 gradations or 55 gradations).

In the above-described embodiment, the case where the pseudo halftone processing circuit is an error diffusion circuit that performs pseudo halftone processing by the error diffusion processing method has been described, but the present invention is not limited to this, and the pseudo halftone processing is not limited to this. It can also be used in the case of a systematic dither circuit in which the circuit performs pseudo halftone processing by the systematic dither method.

In the above-mentioned embodiment, the case where the display panel of the image display unit is the PDP has been described, but the present invention is not limited to this, and it can be applied to the case of a digital display panel (for example, LCDP). .

[0033]

According to the pseudo halftone image display device of the present invention, a pseudo halftone processing circuit (for example, error diffusion circuit), a panel drive circuit, a display panel (for example, PDP), a panel drive monitoring circuit, and an output gradation number setting circuit. When the number of gray scales of the output signal of the panel drive circuit is controlled by the panel drive control signal output from the panel drive monitoring circuit to a value that optimizes the number of drive gray scales of the display panel, the number of output gray scales Since the setting circuit variably sets the gradation number M of the output signal in the pseudo-halftone processing circuit to the driving gradation number of the display panel based on the panel driving state signal, the display panel is prevented in order to avoid saturation of the panel driving current. The number of drive gradations can be optimized, and the number of output signal gradations in the pseudo halftone processing circuit can be changed in accordance with the change in the number of drive gradations of the display panel to cause a change in the number of gradations. The deterioration of image quality can be prevented.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a pseudo halftone image display device according to the present invention.

FIG. 2 is a drive sequence and drive waveform diagram when displaying 256 gradations by a subfield method.

FIG. 3 is a block diagram of an error diffusion circuit used in a general pseudo halftone image display device.

FIG. 4 is a characteristic diagram of drive signal vs. emission brightness level when n = 8 (corresponding to 256 gradations) and m = 4 (corresponding to 16 gradations) in the case of FIG.

FIG. 5 is a block diagram of a proposed pseudo halftone image display device.

[Explanation of symbols]

10, 60 ... Error diffusion circuit, 12 ... Input terminal, 14
... vertical direction addition circuit, 16 ... horizontal direction addition circuit, 1
8, 18a ... Bit conversion circuit, 20 ... PDP (example of plasma display panel, display panel), 22,
22a ... Error detection circuit, 24, 26 ... Error weight circuit,
28 ... h line delay circuit, 30 ... d dot delay circuit, 32, 56 ... Image processing unit, 34, 58 ... Image display unit, 62 ... Output gradation number setting circuit, 64 ... Comparison data setting circuit, 66 ... Panel drive Circuits, 68 ... Display panel, 70 ... Panel drive monitoring circuit, 72 ... Panel drive control unit, 74 ... Drive current monitoring unit.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI G09G 3/20 642 G09G 3/20 642P G02F 1/133 575 G02F 1/133 575 G09G 3/28 G09G 3/36 3/36 3 / 28 K (72) Inventor Hayato Denda 1116 Suenaga, Takatsu-ku, Kawasaki-shi, Kanagawa Kanagawa Prefecture General Company (56) References JP-A-6-289812 (JP, A) JP-A-6-259034 (JP, A) JP 4-338998 (JP, A) JP 8-190360 (JP, A) JP 7-219493 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) ) G09G 3/20 641 G09G 3/20 642 G02F 1/133 575 G09G 3/28 G09G 3/36

Claims (6)

(57) [Claims] 1. A pseudo-halftone processing circuit for performing pseudo-halftone processing on an input video signal of N gradations, converting the display signal of M gradations (M≤N-1) and outputting the display signal, and the pseudo-halftone processing circuit. A panel drive circuit that outputs a panel drive signal based on the output signal of the processing circuit, a display panel that displays a pseudo-halftone image based on the output signal of the panel drive circuit, and an output signal of the panel drive circuit A panel drive monitoring circuit that outputs a panel drive control signal for optimizing the number of drive gray scales of the display panel to the panel drive circuit, and outputs a panel drive state signal indicating a drive state of the display panel, Based on the panel drive state signal of the panel drive monitoring circuit, an output gray scale number setting for variably setting the gray scale number M of the output signal in the pseudo halftone processing circuit to the drive gray scale number of the display panel. Halftone image display apparatus characterized by comprising; and a circuit. 2. The pseudo halftone image display device according to claim 1, wherein the pseudo halftone processing circuit is an error diffusion circuit that performs pseudo halftone processing by an error diffusion processing method. 3. The pseudo-halftone image display device according to claim 1, wherein the pseudo-halftone processing circuit is a systematic dither circuit that performs pseudo-halftone processing by a systematic dither method. 4. The pseudo halftone image display device according to claim 1, wherein the panel drive state signal is a signal representing the number of drive bits of the display panel. 5. The pseudo halftone image display device according to claim 1, wherein the panel drive state signal is a signal representing the number of drive subfields of the display panel. 6. The pseudo halftone image display device according to claim 1, wherein the panel drive state signal is a signal representing the number of drive gradations of the display panel.