JP3484895B2 - Error diffusion circuit of display device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention makes one frame into a plurality of subfields (or subframes) SF1 to SFn.
In the display device (for example, PDP display device) which displays the multi-gradation image (for example, 256 gradation image) by combining a plurality of subfield screens by weighting the luminance of each subfield, the bit of the drive signal The present invention relates to an error diffusion circuit for displaying a pseudo-halftone image in which the number of light sources is reduced to increase the light emission luminance and the image quality is not deteriorated.

[0002]

2. Description of the Related Art Recently, as a thin and lightweight display device, P
Attention has been paid to DP (plasma display panel). 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 D type which have different basic characteristics.
It is divided into two types, C type. In the AC type PDP, sufficient characteristics are obtained with respect to brightness and life, but regarding gray scale display, only a maximum gray scale display of 64 gray scales has been reported. An address / display separation type driving method (ADS subfield method) for multi-gradation display has been proposed. The drive sequence and drive waveform of the PDP used in this method are as shown in FIGS. 7A and 7B, for example.

In FIG. 7A, one frame has a relative luminance ratio of 1, 2, 4, 8, 16, 32, 64, 128.
8 subfields SF1 to SF8
256 gradations are displayed by combining the screen brightness. In FIG. 7B, each subfield is composed of an address period for writing refreshed data for one screen and a sustain period for determining the brightness 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. 2 in this way
56 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.

Conventionally, an error diffusion circuit for displaying a pseudo-halftone image which increases the emission luminance and does not deteriorate the image quality has been conventionally constructed as shown in FIG. In FIG. 8, 10 is an error diffusion circuit, and 12 is a PDP display device as a display device. The error diffusion circuit 10
Is composed of an adder circuit 16, an output control circuit 18, and an output terminal 20 which are sequentially connected to an input terminal 14 of the video signal, and an error detection circuit 22 and a delay circuit 24 which are sequentially connected to the output side of the adder circuit 12. The output side of the delay circuit 24 is coupled to the adder circuit 16 and the PDP display device 12 is coupled to the output terminal 20, and the PDP display device 12 displays the halftone image subjected to the error diffusion processing.

An adder circuit 16 adds a reproduction error generated in the past to the video signal of the n-bit original pixel input to the input terminal 14 to obtain a diffused output signal, and an output control circuit 18 sets the diffused output signal to m. The signal is converted into a signal for sub-field screen display of (≦ n−1) bits and is output to the PDP display device 12 via the output terminal 20, and is used by the error detection circuit 22 for luminance gradation correction of the PDP display device 12. R in advance
The difference between the corrected luminance level set in the OM or the like and the diffused output signal is detected, weighted, delayed by a predetermined pixel by the delay circuit 24, and output to the addition circuit 16 as a reproduction error.

[0008]

However, in the error diffusion circuit 10 shown in FIG. 8, a plurality of subfields S are used.
If the display area (the number of dots) driven in each of the subfields F1 to SFn has a variation (variation), there is a problem that the gradation is not displayed correctly. Especially, halftone display is performed by the error diffusion process, and the number is small (for example, 1
In a display in which the display screen driven by one subfield is small and the display screen driven by a large number of subfields (for example, three) is large, there is a problem in that the gradation is not displayed correctly.

For example, the case where the gradation is not displayed correctly will be described with reference to FIGS. 9 (a) and 9 (b). For convenience of explanation, 1
A frame is composed of four SF1 to SF4, and SF1, S
The relative ratio of the luminance of F2, SF3, and SF4 is set to 1, 2, 4, 8
PDP display device 12 by the subfield driving method
Then, as shown in FIG. 9A, the display level of most of the display screen (62 dots in the figure) is "7", and the display level of part of the display screen (2 dots in the figure) is "8". Consider the case where the adjustment screen is displayed. In this case, display level "7"
For the dots displaying SF, SF1, SF2 and SF3 are turned on and SF4 is turned off, and for the dots displaying the display level "8", SF4 is turned on and SF1, SF2 and SF3 are turned off.

Therefore, SF1, SF2, and SF3 have a large number of display dots (the load of the driving element is large), so that the luminance reduction rate is large, and SF4 has a small number of the display dots (the load of the driving element is small). Therefore, the rate of decrease in brightness is small. Therefore, the dots of the display level "7" that light SF1, SF2, and SF3 are displayed relatively dark,
The dots of display level "8" that light SF4 are displayed relatively bright. If this is expressed by gradation characteristics, FIG.
The display level (luminance level) equal to or higher than the input level “8” is displayed with high luminance because the dots lighting SF4 are relatively bright.

Therefore, a 7-bit (n = 7) input video signal is converted into 4-bit (m
= 4) Considering the case of combining the error diffusion processing for converting into the signal for subfield screen display, the input video level "8" (corresponding to the input video level "64") of the output gradation is different. The error diffusion process is performed for 57 "to" 63 ", and the error diffusion process is not performed for the input video level" 64 ".

Now, considering the case where the input image level "57" is constantly present, most of the output after the error diffusion is the output gradation display level "7" (corresponding to the input image level "56"). The output gradation display level "8" occupies a part of the pattern, resulting in a diffuse pattern. Therefore, by the sub-field driving method, the input image level displayed relatively bright on a part of the display screen having a relatively dark input image level “7” displayed as shown in FIG. 9A. A small screen of "8" was displayed, and the gradation was not displayed correctly.

As a comparative example, the case where the gradation is displayed correctly will be described with reference to FIGS. Figure 10
As shown in (a), when a gradation screen having the same display area (dot number) at the display level "7" and the display level "8" is displayed, the number of dots at which the display level "7" is displayed is Since the number of dots displaying the display level "8" is equal, the number of display dots in SF1, SF2, SF3, and SF4 is the same (the load of the driving element is the same in all subfields), and the luminance reduction rate is the same. Therefore, SF1,
The brightness of the display level "7" that lights SF2 and SF3 and the brightness of the display level "8" that lights only SF4 are both displayed at the same ratio as the initially set weight. Therefore, gradation characteristics proportional to the input level as shown in FIG. 10B can be obtained.

Considering the case where the input image level "60" is constantly present, the result after error diffusion is the output gradation display level "7" (corresponding to the input image level "56") and the output gradation. The display level "8" (corresponding to the input video level "64") is a diffusion pattern that occupies almost half of the whole. Therefore, since the display area of the output gradation display level "7" and the display area of the output gradation display level "8" are almost equal to each other, one of the screens is not conspicuous and the gradation is displayed almost correctly. It

The present invention has been made in view of the above-mentioned problems, and in the case of displaying a pseudo halftone image by performing error diffusion processing in a display device which displays a multi-gradation image using the subfield driving method. Another object of the present invention is to provide an error diffusion circuit of a display device that can display gradation properly.

[0016]

According to another aspect of the present invention, there is provided an error diffusion circuit in which one frame is composed of a plurality of subfields, the brightness of each subfield is weighted, and a combination of a plurality of subfield screens is used. In a display device for displaying a multi-gradation image, a first addition circuit for adding a reproduction error generated in the past from the original pixel to an input n-bit original pixel video signal and an output signal of the first addition circuit. A second adder circuit that obtains a diffused output signal by adding the error diffusion correction signal, and an output that converts this diffused output signal into a signal for sub-field screen display of m (≤n-1) bits and outputs it to a display device. A control circuit, an error detection circuit that detects a difference between a corrected luminance level set for luminance gradation correction of a display device and a diffused output signal, and a detection signal of the error detection circuit are provided. The as reproduced error delays pixels 1
The delay circuit that outputs to the adder circuit and the pseudo random pulse signal
Noise generation circuit that generates a signal, a high frequency extraction circuit that extracts high frequency components from the detection signal of the error detection circuit, and when the absolute value of the extraction signal of this high frequency extraction circuit is less than or equal to a preset threshold value. , The pseudo-random noise generated by the pseudo-noise generation circuit
A gain control circuit for outputting the pulse signal to the second addition circuit as an error diffusion correction signal is provided.

The reproduction error is added to the n-bit input video signal by the first addition circuit, and the error diffusion correction signal is added by the second addition circuit to become a diffusion output signal. The output control circuit outputs m (≦ n−1). ) It is converted into a bit sub-field screen display signal and output to the display device. At this time, the error detection circuit detects the difference between the corrected luminance level set for the luminance gradation correction of the display device and the diffused output signal, and the detection signal is delayed by a predetermined number of pixels by the delay circuit and first added as a reproduction error. Input to the circuit. Moreover,
The gain control circuit generates pseudo noise when the absolute value of the high frequency component extracted from the detection signal of the error detection circuit is below the threshold value.
The pseudo random pulse signal generated in the raw circuit is output to the second addition circuit as an error diffusion correction signal.

Therefore, when the levels of the input video signal and the output gradation (the gradation of the signal output from the output control circuit to the display device) are the same or the level difference is smaller than the set value, the error detection circuit in the signal detected or no high frequency components (error amount) is small (i.e. error amount is zero or less), the absolute value of the extracted signal is equal to or less than the predetermined threshold level, the gain control circuit is pseudo Random pal
The output signal is output to the second adding circuit as an error diffusion correction signal. That is, for the input video signal whose reproduction error is less than the set value in the first adder circuit, pseudo-random
The pulse signal is added as an error diffusion correction signal and input to the output control circuit.

Further, when the level difference between the input video signal and the output gradation exceeds the set value and is large, the signal (error amount) detected by the error detection circuit has a high frequency component equal to or more than the set value. There, the absolute value of the extracted signal exceeds a preset threshold, the gain control circuit is a pseudo random pulse
The signal is not output to the second adder circuit. That is, for the input video signal in which the reproduction error is added in the first adder circuit and the high frequency component exceeds the threshold value, the pseudo random pattern is used.
The loose signal is not added.

As described above, when the absolute value of the high frequency component of the signal output from the first addition circuit is less than or equal to the threshold value (for example, when the input video signal and the output gradation level are the same), the pseudo When the video signal to which the random pulse signal is added is input to the output control circuit as a spread output signal and the absolute value of the high frequency component of the signal output from the first addition circuit exceeds the threshold value (for example, input video When the level difference between the signal and the output gradation is equal to or greater than the set value), the video signal to which the pseudo random pulse signal is not added is input to the output control circuit. For this reason, even if a video signal that causes variations in the area (number of dots) driven in each subfield is input,
It is possible to prevent the bias of the subfields that are turned on and display the gradation correctly. That is, there is no video signal after error diffusion that is driven by a single subfield (one input level is expressed by multiple subfields), variation in display load between subfields is suppressed, and correct halftone is achieved. Can be displayed.

According to the invention of claim 2, in order to make noise components inconspicuous on a dark screen, in the invention of claim 1, the configuration of the gain control circuit is changed as follows. That is, this gain control circuit, when the absolute value of the extraction signal of the high frequency extraction circuit is less than or equal to a preset threshold value,
The gain proportional to the video level of the input video signal causes the pseudo
The magnitude of the similar random pulse signal is controlled and output as an error diffusion correction signal to the second addition circuit. Therefore, for a screen with a low video level of the input video signal (that is, a dark screen), the gain control circuit uses pseudo-random
The amplification degree for the pulse signal can be reduced so that noise larger than that of the image is not added and the image is not disturbed. Other configurations and operations are almost the same as those of the invention of claim 1, and therefore the description thereof is omitted.

According to a third aspect of the invention, in the first aspect of the invention, the configuration of the high frequency extraction circuit is changed as follows. That is, the high frequency extraction circuit extracts high frequency components from the output signal of the first addition circuit (the video signal after error diffusion in which the reproduction error is added to the input video signal). Other configurations and operations are
Since it is the same as the invention of claim 1, the description thereof is omitted.

According to the invention of claim 4, in the invention of claim 2, the configuration of the high frequency extraction circuit is changed as follows. That is, the high frequency extraction circuit extracts high frequency components from the output signal of the first addition circuit (the video signal after error diffusion in which the reproduction error is added to the input video signal). Other configurations and operations are
Since it is the same as the invention of claim 2, the description is omitted.

[0024]

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of an error diffusion circuit of a display device according to the present invention will be described below with reference to FIG. 1, the same parts as those in FIG. 8 are designated by the same reference numerals.
In FIG. 1, 30 is an error diffusion circuit, and 12 is a PDP display device as an example of a display device. The error diffusion circuit 30, similar to the circuit of FIG. 8, has a first adder circuit 16, an output control circuit 18, and an output terminal 20, which are sequentially coupled to an input terminal 14 for a video signal, and an output of the first adder circuit 12. The error detection circuit 22 and the delay circuit 24, which are sequentially coupled to the side, are provided, and the second addition circuit 32 and the pseudo-lander are provided.
Pseudo-noise generation circuit for generating a Muparusu signal (e.g. PN
Noise generation circuit) 34, high frequency extraction circuit 36, and gain control circuit 38.

The second adder circuit 32 is inserted between the first adder circuit 12, the output control circuit 18 and the error detection circuit 22, and adds an error diffusion correction signal to the output signal of the first adder circuit 12. Then, the spread output signal is obtained, and the spread output signal is output to the output control circuit 18 and the error detection circuit 22.

The pseudo noise generating circuit 34 is "1",
It is configured to generate a "0" pseudo-random pulse signal. This pseudo-random pulse signal has a repeating period, but since the period is sufficiently long, it represents a pulse signal that can be regarded as a random pulse signal,
This cycle is, for example, 524,287 of the unit pulse period.
The period is set to double (that is, (2 ¹⁹ -1) times).

The high frequency extraction circuit 36 is a circuit for extracting a high frequency component from a signal obtained by delaying the output signal of the error detection circuit 22 by the delay circuit 24. For example, one dot as shown in FIG. Delay devices 40, 42, coefficient devices 44, 4
It is composed of a general-purpose high-pass filter composed of 6, 48 and an adder 50. The high frequency extracting circuit 36, for example, the was corresponding to the frequency of the output signal of the error detecting circuit 22 <br/>, and a value between 0 and +1, or 0 to -1
And it is configured to output a that signal.

The gain control circuit 38 performs error diffusion correction on the pseudo random pulse signal generated by the pseudo noise generation circuit 34 when the absolute value of the extracted signal of the high frequency extraction circuit 36 is less than a preset threshold value. The second as a signal
It is configured to output to the adder circuit 32.

The gain control circuit 38 calculates the absolute value (for example, a value from 0 to 1) of the extraction signal of the high frequency extraction circuit 36, as shown in FIG. 3, for example.
2 and this absolute value is a preset threshold value (for example, 0.
5) Judgment unit 54 which judges whether or not it is below and outputs a judgment signal (1 or 0), and the judgment signal (1 or 0) of the judgment unit 54 based on the pseudo random pulse signal generated by the pseudo noise generating circuit 34. ) And a multiplier 56 for producing an output signal. Therefore, the number of arithmetic circuits can be reduced and the configuration of the gain control circuit 38 can be simplified.

Next, the operation of FIG. 1 will be described. A reproduction error generated in the past from the original pixel is added to the video signal of the n-bit original pixel input to the input terminal 14 by the first addition circuit 16, and then an error diffusion correction signal is added by the second addition circuit 32. It becomes a spread output signal. This spread output signal is converted into an m-bit signal for subfield screen display by the output control circuit 18, and P is output via the output terminal 20.
By inputting to the DP display device 12, a multi-tone image with m subfield screens is displayed.

The error detection circuit 22 detects the difference between the corrected luminance level set in the memory (for example, ROM) for luminance gradation correction of the PDP display device 12 and the diffused output signal output from the second addition circuit 32. The detection signal is delayed by a predetermined dot by the delay circuit 24 and input to the first addition circuit 16 as a reproduction error.

A high frequency component is extracted from the output signal of the delay circuit 24 by the high frequency extraction circuit 36, and in the gain control circuit 38, the absolute value of the high frequency component is calculated by the absolute value calculation section 52, and the absolute value by the determination section 54. It is determined whether the value is less than or equal to the threshold value, and the multiplier 56 determines the determination signal (1 or 0).
Is multiplied by the pseudo random pulse signal. Therefore, when the absolute value calculated by the absolute value calculation unit 52 is equal to or less than the threshold value, the gain control circuit 38 outputs the pseudo random pulse signal as an error diffusion correction signal to the second addition circuit 32 to set the threshold value. When it exceeds, the pseudo random pulse signal is not added.

Therefore, the level of the video signal input to the input terminal 14 is the same as the level of the gradation (that is, output gradation) of the signal output from the output control circuit 18 to the PDP display device 12 via the output terminal 20. If the level difference is small, the signal (error amount) detected by the error detection circuit 22 has no high band component or is small, and the absolute value of the extracted signal (high band component) is equal to or less than the threshold value. Therefore, the gain control circuit 38 outputs the pseudo random pulse signal to the second adding circuit 32 as an error diffusion correction signal. That is, a pseudo random pulse signal is added by the second adder circuit to the input video signal to which the reproduction error is added by the first adder circuit 16 only by the set value or less, and is input to the output control circuit 18.

Further, when the level difference between the input video signal and the output gradation is large and the absolute value of the high frequency component exceeds the threshold value, the gain control circuit 38 does not add the pseudo random pulse signal. . That is, the pseudo random pulse signal is not added by the second addition circuit to the input video signal to which the reproduction error of the set value or more is added by the first addition circuit 16.

As described above, when the absolute value of the high frequency component is less than or equal to the threshold value (for example, when the input video signal and the output gradation level are the same), the pseudo random pulse signal is superimposed on the video signal. When input to the output control circuit 18 as a diffused output signal and the absolute value of the high frequency component exceeds the threshold value (for example, when the level difference between the input video signal and the output gradation exceeds the set value). , The pseudo random pulse signal is not superimposed on the video signal. Therefore, even when a video signal that causes a variation in the area (number of dots) driven in each subfield is input, it is possible to prevent the biased lighting of the subfield and display a correct gradation. That is,
There is no image signal after error diffusion driven by a single sub-field, and it is possible to suppress variations in display load for each sub-field and display halftones correctly.

In the above embodiment, the gain control circuit is composed of the absolute value calculating section, the judging section and the multiplier, and when the absolute value of the extracted signal of the high frequency extracting circuit is less than the threshold value, the pseudo noise generating circuit. Although the pseudo random pulse signal generated in step S1 is output to the second adder circuit as the error diffusion correction signal, the present invention is not limited to this. For example, as shown in FIG. Value calculation unit 52, determination unit 5
4, the multiplier 56 and the amplifier 58, the magnitude of the pseudo random pulse signal with a gain proportional to the video level of the input video signal when the absolute value of the extraction signal of the high frequency extraction circuit 36 is less than or equal to the threshold value. May be controlled and output to the second addition circuit 32 as an error diffusion correction signal.

In the case of such a configuration, a large noise is generated by reducing the amplification degree for the pseudo random pulse signal by the gain control circuit 38a for a screen with a low video level of the input video signal (that is, a dark screen). It can be added to prevent the image from being distorted.

In the above embodiment, the high frequency extraction circuit extracts the high frequency component from the signal obtained by delaying the detection signal of the error detection circuit by the delay circuit, but the present invention is not limited to this. Instead, the high-frequency extraction circuit 36 shown in FIG. 1 extracts the high-frequency component from the signal before the detection signal of the error detection circuit is delayed by the delay circuit as shown in FIG.
Instead of a, the error diffusion circuit 30a may be configured.

In the above embodiment, the high frequency extraction circuit extracts the high frequency component from the detection signal of the error detection circuit, but the present invention is not limited to this, and FIG. 1 (or FIG. 5). The high-frequency extraction circuit 36 (or 36a) is replaced with a high-frequency extraction circuit 36b for extracting high-frequency components from the output signal of the first addition circuit 16 as shown in FIG.
b may be configured.

In the above-described embodiment, the case where the display device is a PDP display device has been described, but the present invention is not limited to this, and a display device other than the PDP display device (for example, a liquid crystal display device) is also applicable. Available.

[0042]

According to the first and third aspects of the present invention, in a display device for displaying a multi-gradation image by the subfield driving method, first and second addition circuits, an output control circuit, an error detection circuit, a delay circuit, and a pseudo circuit. When the absolute value of the high frequency component of the output signal of the error detection circuit or the first addition circuit is less than or equal to the threshold value (for example, the input video signal and the output floor ) , the noise generation circuit , the high frequency extraction circuit and the gain control circuit are provided. If the key level is the same and there is no high frequency component), the pseudo random pulse signal is added to the input video signal and output to the output control circuit, and the high frequency component of the output signal of the error detection circuit or the first addition circuit is added. When the absolute value of exceeds the threshold value (for example, when the input video signal and the output gradation level are different and there is a high frequency component),
The pseudo random pulse signal is configured not to be added.

Therefore, even when a video signal which causes a variation in the area (number of dots) driven in each subfield is input, it is possible to prevent the biased lighting of the subfield and display the gradation correctly. That is, there is no video signal after error diffusion that is driven by a single subfield (one input level is expressed by multiple subfields), variation in display load between subfields is suppressed, and correct halftone is achieved. Can be displayed.

The inventions of claims 2 and 4 are
In the invention of claim 1, when the absolute value of the extraction signal of the high frequency extraction circuit is equal to or less than the threshold value, the gain control circuit uses the gain proportional to the video level of the input video signal to generate the pseudo random pulse.
Since the signal size is controlled and added to the input video signal as an error diffusion correction signal, the following effects can be achieved in addition to the effects of the inventions of claims 1 and 3.
In other words, for a screen with a low video level of the input video signal (that is, a dark screen), the pseudo control by the gain control circuit
It is possible to reduce the amplification factor for the random pulse signal so that a large noise is not added and the image is not disturbed, and the noise component is not noticeable on a dark screen.

[0045]

[Brief description of drawings]

FIG. 1 is a block diagram illustrating an exemplary embodiment of an error diffusion circuit of a display device according to the present invention.

FIG. 2 is a block diagram showing a specific example of a high frequency extraction circuit of FIG.

FIG. 3 is a block diagram showing a specific example of the gain control circuit of FIG.

FIG. 4 is a block diagram showing another specific example of the gain control circuit of FIG.

FIG. 5 is a block diagram showing another embodiment of the error diffusion circuit of the display device according to the present invention.

FIG. 6 is a block diagram showing another embodiment of the error diffusion circuit of the display device according to the present invention.

FIG. 7 is a drive sequence diagram and a drive waveform diagram in the 256 gradation method.

FIG. 8 is a block diagram showing an error diffusion circuit of a display device in a conventional example.

9A and 9B are a dot arrangement diagram and a gradation characteristic diagram when the gradation is not displayed correctly.

FIG. 10 is a dot arrangement diagram and a tone characteristic diagram when the tone is displayed correctly.

[Explanation of symbols]

10, 30, 30a, 30b ... Error diffusion circuit, 12 ...
PDP display device (an example of display device), 14 ...
Video signal input terminal, 16 ... First addition circuit, 18 ... Output control circuit, 20 ... Output terminal, 22 ... Error detection circuit, 24 ... Delay circuit, 32 ... Second addition circuit, 34
... Pseudo noise generation circuit (an example of a specific pattern generation circuit),
36, 36a, 36b ... High-frequency extraction circuit, 38, 38
a ... Gain control circuit, 40, 42 ... 1-dot delay device,
44, 46, 48 ... Coefficient multiplier, 50 ... Adder, 52 ...
Absolute value calculation unit, 54 ... Judgment unit, 56 ... Multiplier, 5
8 ... Amplifier.

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Masayuki Kobayashi 1116 Suenaga, Takatsu-ku, Kawasaki City, Kanagawa Prefecture, Fujitsu General Company (72) Seiji Matsunaga 1116 Suenaga, Takatsu-ku, Kawasaki City, Kanagawa Prefecture (72) Inventor Toru Aida 1116 Suenaga, Takatsu-ku, Kawasaki-shi, Kanagawa, Ltd. General company, Fujitsu (72) Inventor Hayato, 1116 Suenaga Takatsu-ku, Kawasaki, Kanagawa, Ltd., Fujitsu General (56) References JP 8-146906 (JP, A) JP 7-121135 (JP, A) JP 8-101663 (JP, A) JP 7-288689 (JP, A) JP 6-178304 (JP, A) JP-A-6-46266 (JP, A) JP-A-63-214073 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G09G 3/20 641 G09G 3 / 20 642 G09G 3/28 G09G 5/00 520

Claims (4)

(57) [Claims] 1. A display device, in which one frame is composed of a plurality of sub-fields, the brightness of each sub-field is weighted, and a multi-gradation image is displayed by a combination of a plurality of sub-field screens, the input n-bit A first addition circuit that adds a reproduction error that has occurred in the past from the original pixel to the video signal of the original pixel, and a second addition that adds an error diffusion correction signal to the output signal of the first addition circuit to obtain a diffusion output signal. A circuit, an output control circuit for converting the diffused output signal into a signal for displaying a subfield screen of m (≤n-1) bits and outputting the signal to the display device, and a setting for correcting brightness gradation of the display device. An error detection circuit that detects a difference between the corrected luminance level and the diffused output signal, and a detection signal of the error detection circuit that is delayed by a predetermined number of pixels to reproduce the first error. And a delay circuit to be output to the circuit, the pseudo-La
A pseudo noise generating circuit for generating a random pulse signal, a high frequency extracting circuit for extracting a high frequency component from the detection signal of the error detecting circuit, and an absolute value of the extraction signal of the high frequency extracting circuit is equal to or less than a preset threshold value. And a gain control circuit for outputting the pseudo random pulse signal generated by the pseudo noise generating circuit to the second adding circuit as an error diffusion correction signal. Error diffusion circuit. 2. A display device, in which one frame is composed of a plurality of sub-fields, the brightness of each sub-field is weighted, and a multi-gradation image is displayed by a combination of a plurality of sub-field screens, the input n-bit A first addition circuit that adds a reproduction error that has occurred in the past from the original pixel to the video signal of the original pixel, and a second addition that adds an error diffusion correction signal to the output signal of the first addition circuit to obtain a diffusion output signal. A circuit, an output control circuit for converting the diffused output signal into a signal for displaying a subfield screen of m (≤n-1) bits and outputting the signal to the display device, and a setting for correcting brightness gradation of the display device. An error detection circuit that detects a difference between the corrected luminance level and the diffused output signal, and a detection signal of the error detection circuit that is delayed by a predetermined number of pixels to reproduce the first error. And a delay circuit to be output to the circuit, the pseudo-La
A pseudo noise generating circuit for generating a random pulse signal, a high frequency extracting circuit for extracting a high frequency component from the detection signal of the error detecting circuit, and an absolute value of the extraction signal of the high frequency extracting circuit is equal to or less than a preset threshold value. , The pseudo noise generation time is increased by the gain proportional to the video level of the input video signal.
An error diffusion circuit for a display device, comprising: a gain control circuit for controlling the magnitude of a pseudo random pulse signal generated on the path and outputting it as an error diffusion correction signal to the second addition circuit. 3. A display device, in which one frame is composed of a plurality of sub-fields, the luminance of each sub-field is weighted, and a multi-gradation image is displayed by a combination of a plurality of sub-field screens, the input n-bit A first addition circuit that adds a reproduction error that has occurred in the past from the original pixel to the video signal of the original pixel, and a second addition that adds an error diffusion correction signal to the output signal of the first addition circuit to obtain a diffusion output signal. A circuit, an output control circuit for converting the diffused output signal into a signal for displaying a subfield screen of m (≤n-1) bits and outputting the signal to the display device, and a setting for correcting brightness gradation of the display device. An error detection circuit that detects a difference between the corrected luminance level and the diffused output signal, and a detection signal of the error detection circuit that is delayed by a predetermined number of pixels to reproduce the first error. And a delay circuit to be output to the circuit, the pseudo-La
A pseudo noise generating circuit for generating a random pulse signal, a high frequency extracting circuit for extracting a high frequency component from the output signal of the first adding circuit, and a threshold value for which the absolute value of the extraction signal of the high frequency extracting circuit is preset. A display comprising: a gain control circuit that outputs a pseudo random pulse signal generated by the pseudo noise generation circuit to the second addition circuit as an error diffusion correction signal at the following time: The error diffusion circuit of the device. 4. A display device which comprises one frame composed of a plurality of sub-fields, weights the luminance of each sub-field, and displays a multi-gradation image by a combination of a plurality of sub-field screens. A first addition circuit that adds a reproduction error that has occurred in the past from the original pixel to the video signal of the original pixel, and a second addition that adds an error diffusion correction signal to the output signal of the first addition circuit to obtain a diffusion output signal. A circuit, an output control circuit for converting the diffused output signal into a signal for displaying a subfield screen of m (≤n-1) bits and outputting the signal to the display device, and a setting for correcting brightness gradation of the display device. An error detection circuit that detects a difference between the corrected luminance level and the diffused output signal, and a detection signal of the error detection circuit that is delayed by a predetermined number of pixels to reproduce the first error. And a delay circuit to be output to the circuit, the pseudo-La
A pseudo noise generating circuit for generating a random pulse signal, a high frequency extracting circuit for extracting a high frequency component from the output signal of the first adding circuit, and a threshold value for which the absolute value of the extraction signal of the high frequency extracting circuit is preset. At the following times , the pseudo noise generation time is changed by the gain proportional to the video level of the input video signal.
An error diffusion circuit for a display device, comprising: a gain control circuit for controlling the magnitude of a pseudo random pulse signal generated on the path and outputting it as an error diffusion correction signal to the second addition circuit.