DE3906924A1 - Grey-scale imaging method having a pixel-matrix display device - Google Patents

Abstract

A method for grey-scale representation by means of a pixel-matrix display device comprises the following steps: subdividing the picture elements on a screen of the display device in areas having a number of in each case N picture elements, so that N+1 grey steps can be generated by luminous and non-luminous picture elements, and setting each picture element to a desired degree of the grey-scale representation, the picture elements which are next to one another at least in the same region being set to different phases in the grey-scale representation and those picture elements at the same positions in the respective areas being set to the same phases in the grey-scale representation when their degree of grey-scale representation is the same. <IMAGE>

Description

The invention relates to a method for grayscale representation according to the preamble of claim 1, for use with a dot matrix display device, the e.g. B. use in personal computers and word processors finds.

In a dot matrix display device without grayscale Display function or binary level display function, such as. B. a liquid crystal display device, an electroluminescent or plasma display device, there is a simulated Grayscale representation z. B. using the conventional Area gray scale method (aerea gray scale method), also known as the DIZZA process or using the conventional frame thinning process (frame thinning method). The area grayscale process however, has the disadvantage of a diminished one Resolution on. In the frame thinning process the difficulty that especially with a multi Grayscale display so-called flicker phenomena occur with regard to such picture elements that with a medium gray level. Should in particular a large area with the same average gray level are shown, the flicker phenomena fall heavily in weight. This leads to a deterioration in Picture quality.  

A grayscale display system for reducing such flicker is already disclosed in Japanese Patent Laid-Open No. Sho. 61-205 983. In this grayscale display system, the different picture elements each belong to one of two groups. Thus, as shown in FIG. 22, there exist picture elements α and picture elements β . These picture elements α and β are driven in opposite phases.

The picture elements α and the picture elements β are each arranged alternately in the vertical and horizontal directions in order to form a zigzag-shaped grid structure. By triggering the picture elements α and β in opposite phase, flicker phenomena can be significantly reduced.

If, in the prior art described above, each picture element is to display eight gray levels, the lighting mode of the picture elements α must be selected for the individual gray levels in accordance with FIG. 23. In FIG. 23, corresponding gray levels for duty ratios 8/8, 7/8, 6/8, 5/8, 4/8, 3/8, 2/8 and 0/8 are respectively denoted by (1) to (8) . The high level indicates the on or lighting state of the picture element, while the low level marks the off state of the picture element. The term "duty cycle" indicates the ratio of the number of frames in which a picture element is illuminated in a period to the total number of frames forming the period, the lighting mode of the picture element in each gray level comprising eight frames that represent the period form.

The lighting mode of the picture element β is shown in FIG. 24, with (1) to (8) denoting eight gray levels, in the same way as already described in connection with FIG. 23. Fig. 25 shows a composite representation of the turn-on or light-emitting states of the image elements α and β in the respective gray levels. It therefore shows the visually recognizable lighting state when the picture elements α and β are viewed at the same time. The respective gray states or gray levels are also shown in FIG. 25 with (1) to (8). As can easily be seen from FIG. 25, the grayscale display does not take place with smooth levels, which is particularly true for the grayscale with a duty cycle of 2/8 and 6/8, but also for the gray levels with a duty cycle of 3/8, 5 / 8 and 7/8 applies. For example, B. the frequency of the vertical synchronization signal 70 Hz, there is a brightness fluctuation of 17.5 Hz with respect to the gray levels with a duty cycle of 3/8, 5/8 and 7/8, and a brightness fluctuation of 35 Hz with respect to the gray levels with a duty cycle from 2/8 and 6/8. Such a fluctuation in brightness cannot be reduced even if the area for displaying these gray levels is enlarged. If, in particular, an area exceeding a predetermined size is shown on the screen in the gray level with a duty cycle of 3/8, flicker phenomena become noticeable at a frequency of 17.5 Hz and reduce the image quality quite considerably. With this method, it is therefore difficult to carry out a multi-grayscale display without deteriorating the image quality at the respective grayscale.

The invention has for its object a method for To create grayscale representation that the above described Overcomes disadvantages and with which it is possible to respective grayscale without deteriorating the image quality to create.

The solution to the problem is in the characteristic Part of claim 1 specified. Advantageous configurations the invention can be found in the subclaims.  

A method according to the invention for gray scale display by means of a dot matrix display device by following these steps:

• - dividing the picture elements on a screen of the display device into areas each having a number of N picture elements in order to be able to produce N +1 gray levels by luminous and non-luminous picture elements, and
• - Set each picture element to a desired one Degree of grayscale display, the at least in same area adjacent to each other picture elements on different phases in the grayscale display and those picture elements in the same positions in the respective areas on the same phases can be set in the grayscale display if their level of grayscale display is the same.

The invention is described below with reference to the Drawing described in more detail. It shows

FIGS. 1A and 1B are block diagrams of a gray-scale display circuit 1 according to one embodiment of the invention,

Figs. 2A and 2B by means of the gray scale display circuit 1 generated images on a screen,

Figure 3 is generated in a display mode areas. Of four rows and four columns,

Fig. 4 to 17 lighting operation kinds of picture element groups P 00 to P 33 in different gray levels,

Fig. 18 is an illustration generated on a screen according to another embodiment of the invention,

Fig. 19 lighting operation types of pixels A to H in the other embodiment,

Fig. 20 shows a composite representation of pixel groups a to d in the lighted state,

Fig. 21 is a composite representation of picture element groups E to H in the lighting state,

Shows a screen display generated by a conventional grayscale imaging system. 22,

Fig. 23 image elements α in the lighting state for individual gray levels in the conventional system,

Fig. 24 picture elements β in the illuminated state for individual gray levels in the conventional system and

Fig. 25 fluctuations in brightness on the entire screen of the conventional system.

To carry out the method according to the invention, use a dot matrix display device as described in general for brightness display using binary levels is used. It can therefore also be a conventional one Display device are used, e.g. B. a liquid crystal, Electroluminescent or plasma display device.

The liquid crystal display device can e.g. B. from Be a reflection type or have a rear projection screen, where there are 640 × 480 pixel elements.

In general, such a display device a raster scan for image display without grayscale using known methods and control circuits.  

In accordance with the invention, a grayscale representation carried out in such a way that picture elements in a luminous state and a non-luminous state brought in accordance with the Degree of grayscale display or grayscale during one image period. Each picture element is during the grayscale display controlled with a different phase, so that flicker is avoided when all picture elements are the same in at least one section Take grayscale for image display.

A picture period can be specified by the sum of those times in which the respective picture elements for the grayscale display are in the luminous and non-luminous state. Switching between the luminous and non-luminous state, and vice versa, can be accomplished by generating partial images (frame by frame basis). The expression partial image or frame means a period in which a complete image is generated on the screen. According to the invention, a grayscale can therefore be recognized after z. B. N partial images or frames have been generated.

The expression "display status of a picture element" means that a picture element to be displayed in an operating state brought from the operating state of a Image element differs, which serves as a background. In other words, there are picture elements that serve as the background serve in the non-luminous state while itself picture elements to be displayed are in the illuminated state, or the other way around.

The following is an embodiment of the invention Described in more detail with reference to the drawing.

In this exemplary embodiment, an image is displayed with 16 gray levels. According to FIG. 2A, the picture elements of a matrix-like distribution on a screen of a dot matrix display device 20 are divided in such a way that 16 picture elements belong to each group, which are arranged along four adjacent rows and columns. There are four picture elements along a row in the X direction, while there are also four picture elements along a column in the Y direction. So there are a plurality of picture element areas, each area containing four rows and four columns, each with four picture elements on the screen. An example arrangement of picture elements in an area is shown in FIG. 2B. Accordingly, the picture elements are also arranged or classified in the other areas. A picture element group P 00 - P 33 therefore belongs to each area.

FIGS. 1A and 1B show block diagrams of a gray-scale display circuit 1, with which the picture elements located in the respective regions can be converted in the luminous and non-luminous state. The grayscale display circuit 1 contains light signal generator circuits 11 a to 11 e for generating signals for the purpose of converting the respective picture elements at different grayscale into the luminous / non-luminous state, as will be described in more detail below, and a multiplexer 12 .

Addressing signals (location signals) X 0 , X 1 , Y 0 , Y 1 for determining certain picture element groups P 00 - P 33 , to which individual picture elements belong, are e.g. B. supplied via a display control circuit, not shown, which contains a microcomputer to the flare signal generator circuits 11 a to 11 e . Furthermore, light signals C 0 - C 15 , which correspond to the respective 16 gray levels in the respective picture element groups P 00 - P 33 , are generated by the light signal generator circuit 11 a to 11 e and passed to the multiplexer 12 . Upon receipt of gray level signals GD 0 - GD 3 for individual picture elements, the multiplexer 12 selects a desired signal from the light signals C 0 - C 15 and delivers the desired signal to a driver circuit 21 for controlling the dot matrix display device 20 .

The aforementioned display control circuit and the driver circuit 21 may have a conventional structure. A vertical synchronization signal, a reset signal, and gray level signals, all of which have been described above, are output from the display control circuit.

The light signal generator circuit 11 a contains z. B. a memory circuit 13 a with a 4 bit × 16 structure, a 16-bit shift register 14 a , a multiplexer 15 a and an inverter 16 a . The light signal generator circuit 11 b and 11 c have a structure corresponding to the light signal generator circuit 11 a . In the following, the same devices of the light signal generator circuits 11 a to 11 c are provided with the same reference numerals, only the letters a , b and c being used to distinguish the respective generator circuits. The light signal generator circuit 11 d contains a memory circuit 13 d with a 3 bit × 16 structure, an 8 bit shift register 14 d , a multiplexer 15 d and an inverter 16 d .

The addressing signals X 0 , X 1 , Y 0 , Y 1 fed to the light signal generator circuit 11 a arrive in the memory circuit 13 a , which uses the addressing signals X 0 , X 1 , Y 0 , Y 1 for addresses and to the multiplexer 15 a value outputs in a 4-bit memory field, which are determined by the addresses. The multiplexer 15 a selects a signal to be output at the output terminals Q 0 - Q 15 of the shift register 14 a and outputs this at its output. The output signal of the multiplexer 15 a is transmitted to the multiplexer 12 as a light signal C 2 in order to determine the timing for luminous picture elements at a gray level K 2 . The relationship between the degree of a grayscale representation or the degree of grayscale and the respective sampling ratios is given in Table 1 below.

Table I

The light signal C 2 from the multiplexer 15 a is inverted by the inverter 16 a , the inverted signal being supplied to the multiplexer 12 as a light signal C 12 for the gray level K 12 . An initial value entered in the shift register 14 a is led to the connections D 0 - D 15 via a memory device, not shown, after the reset signal has occurred. The entered initial value is then shifted synchronously with a vertical synchronization signal and output via the outputs Q 0 - Q 15 . The output terminal AUS and the input terminal ON of the shift register 14 a are connected to each other to form a ring counter. Initial values given for the connections D 0 - D 15 of the shift register 14 a are shown in Table 2. The memory circuit 13 a outputs signals that are determined by the addressing signals X 0 , X 1 , Y 0 , Y 1 , and represent the picture element groups P 00 - P 33 . Values of these signals are shown in Table 3. The letter h indicates that the numbers entered in Table 3 are hexadecimal numbers. These signal values show how the phases of the individual picture element groups P 01 - P 33 are shifted from the phase of the signal for the picture element group P 00 , which serves as the basis.

Table 2

Table 3

Using the values shown in Tables 1, 2 and 3 So each of the picture elements with a desired Grayscale is shown, with the adjacent Picture elements different at least in the same area Phases in the grayscale display and the picture elements in the same positions in the different areas have the same phases in the grayscale display, when the grayscale degree is the same.

The light signal generator circuits 11 b , 11 c have, as already mentioned, essentially the same structure as the light signal generator circuit 11 a , but the initial values entered in the shift registers 14 b , 14 c differ from the memory content in the memory circuits 13 b , 13 or from the initial values in the shift register 14 a . The light signal generator circuit 11 b therefore generates a light signal C 4 for determining the timing of the lighting of the picture elements with the gray level K 4 as well as an additional light signal C 10 for the gray level K 10 , which is achieved by inverting the light signal C 4 with the aid of the inverter 16 b is obtained. These signals C 4 and C 10 are supplied to the multiplexer 12 . Similarly, the light signal generator circuit 11 c generates a light signal C 6 for the gray level K 6 and additionally a light signal C 8 for the gray level K 8 by inverting the light signal C 6 with the aid of the inverter 16 c . These signals C 6 and C 8 are also transmitted to multiplexer 12 . The shift registers 14 a , 14 b and 14 c are of the 16-bit type. The light signals C 2 , C 12 , C 4 , C 10 , C 6 , C 8 from the light signal generator circuits 11 a to 11 c are thus generated cyclically with 16 inputs of the vertical synchronization signal, ie with a 16-field (frame) Period.

The light signal generating circuit 11 d are light signals C 5, C 9, which are repeated on the basis of an 8-sub-picture (frame) period. The shift register 14 d therefore has an 8-bit structure, while the memory circuit 13 d has a 4-bit × 16 structure. The multiplexer 15 selectively outputs signals d, which are submitted to the terminals Q 0 to Q 7 of the shift register 14 d, the multiplexer 15 receives d 3-bit reference data from the memory circuit 13 d. Initial values in the shift register 14 d and memory contents of the memory circuit 13 d are given in tables 2 and 3.

The light signal generator circuit 11 e contains a counter 17 , NOR circuits AN 1 to AN 3 , EXCLUSIVE OR gates XOR 1 to XOR 12 and inverters 16 e to 16 g and supplies 12 light signals C 1 , C 3 , C to the multiplexer 7 , C 11 , C 13 , C 14 for the respective gray levels K 1 , K 3 , K 7 , K 11 , K 13 , K 14 . The counter 17 with a 4-bit construction receives the vertical synchronization signal in order to increment a counter synchronously therewith. The value of the 0th bit of the counter 17 or the output Q 0 of the counter 17 is transmitted to the EXCLUSIVE-OR gates XOR 1 , XOR 3 , XOR 5 and XOR 9 . The value of the first bit of the counter 17 or its output Q 1 , on the other hand, is transmitted to the EXCLUSIVE-OR gates XOR 4 , XOR 7 and XOR 10 . Furthermore, the second bit of the counter 17 or its output Q 2 is supplied to the EXCLUSIVE-OR gates XOR 8 and XOR 11 . The value of the third bit of the counter 17 or its output Q 3 is fed to the XOR 12 EXCLUSIVE OR gate.

Addressing signal X 0 is received by EXCLUSIVE-OR gates XOR 2 , XOR 4 , XOR 7 and XOR 11 , while addressing signal Y 0 is received by EXCLUSIVE-OR gates XOR 2 , XOR 3 , XOR 8 and XOR 12 . The addressing signal X 1 is supplied to the EXCLUSIVE-OR gate XOR 6 . Furthermore, the addressing signal Y 1 is transmitted to the EXCLUSIVE-OR gates XOR 6 and XOR 9 .

An output signal from the EXCLUSIVE-OR gate XOR 2 is supplied to an EXCLUSIVE-OR gate XOR 1 , while an output signal from the EXCLUSIVE-OR gate XOR 1 is supplied to the multiplexer 12 as a light signal C 7 .

Output signals from the EXCLUSIVE-OR gates XOR 3 and XOR 4 are transferred to a NOR circuit AN 1 after being inverted. An output signal of the NOR circuit AN 1 is supplied to the multiplexer 12 as a light signal C 3 . The output signal of the NOR circuit AN 1 inverted by the inverter 16 e is transmitted to the multiplexer 12 as a light signal C 11 .

An output signal of the EXCLUSIVE-OR gate XOR 6 is fed to the EXCLUSIVE-OR gate XOR 5 . Output signals of the EXCLUSIVE-OR gates XOR 5 , XOR 7 and XOR 8 are inverted and then transmitted to a NOR circuit AN 2 . An output signal of the NOR circuit AN 2 is supplied as a light signal C 1 to the multiplexer 12 and, after being inverted by the inverter 16 f, is also transmitted as a light signal C 13 to the multiplexer 12 .

Output signals from the EXCLUSIVE-OR gates XOR 9 , XOR 10 , XOR 11 and XOR 12 are inverted and then supplied to a NOR circuit AN 3 . An output signal from the NOR circuit AN 3 is then transmitted as a light signal C 14 to the multiplexer 12 via the inverter 16 g .

The light signal C 0 for the gray level K 0 is given to the multiplexer 12 via an earth line, while the light signal C 15 for the gray level K 15 is given to the multiplexer 12 via a line to which a predetermined voltage is applied.

FIGS. 4 to 17 show display modes of individual picture element groups P 00 to P 33. The mode of operation is described in detail below with reference to these figures. In Figs. 4 through 17 of each high level representing an illumination condition and each low level of a non-lighting state. Fig. 4 shows a display mode for a gray level K 1 or a sampling ratio 2/16 in 16 fields or frames or in a period for picture element groups P 00 to P 33 . The numbers in parentheses (1) to (16) in Fig. 4 are each assigned to individual picture element groups P 00 to P 33 . The same relationship can also be found in FIGS. 5 to 17. In the present exemplary embodiment, 16 frames or sub-images form one frame period.

In the case of the duty cycle 2/16 or the gray level K 1 , the multiplexer 12 supplies the light signal C 1 to the driver circuit 21 in accordance with the gray level signals GD 0 to GD 3 , which represent the gray level K 1 .

For example, the addressing signals X 0 , Y 0 , X 1 , Y 1 , which determine the picture element group P 00 , are all at low level (L level), while in frame number F 0, the signals from counter 17 are also all at low level lie. The output signals from the EXCLUSIVE-OR gates XOR 5 , XOR 7 and XOR 8 are therefore also at a low level, while the light signal C 1 , that is to say the output signal, from the NOR circuit AN 2 is at a high level. Accordingly, the picture element group P 00 lights up in the frame with the number F 0 . Thereafter, some of the 0th to 2nd bits of the counter 17 go high in accordance with the input of the vertical synchronization signal, so that some of the output signals provided by the XOR 5 , XOR 7 and XOR 8 EXCLUSIVE OR gates also go high Take level. The output signal from the NOR circuit AN 2 then changes to the low level. This means that the picture element group P 00 in the frame with the numbers F 1 to F 7 is converted into the non-illuminating state. In the frame with the number 8, the 0th and the 2nd bit are at a low level, as in the case of the frame with the number F 0 , so that the picture element group P 00 assumes the luminous state again.

The display modes of the following picture element groups P 01 to P 33 in the frames with the numbers F 0 to FF are out of phase relative to the display mode of the picture element group P 00 .

Delays in the phase of picture element groups P 01 to P 33 with respect to the phase of the display mode for picture element group P 00 are shown in Table 3.

FIG. 5 shows display modes of the picture element groups P 00 to P 33 for the gray level K 2 and a duty ratio 3/16. In the following, a display mode of operation is explained in more detail in which all picture elements within an area are displayed on the screen of a dot matrix display device 20 with the same gray level. An initial value in the shift register 14 a is set in accordance with Table 2 such that high level signals are supplied to the terminals D 0 , D 5 and D 10 . Accordingly, a high level signal is output to the terminals Q 0 , Q 5 and Q 10 in frame No. F 0 . As Table 3 shows, the values of the signals that are output by the memory circuit 13 a with respect to the picture element groups P 00 , P 22 and P 02 now assume the sizes 00 h, 05 h and 0 Ah. Then signals for the connections Q 0 , Q 5 , Q 10 from the multiplexer 15 a are selectively output via the output connection AUS. Accordingly, a display state is obtained in frame No. F 0 with respect to the area set on the screen as shown in Fig. 3 (1). In Fig. 3, "1" is a lighting state, while "0" is a non-lighting state.

In the frame with the number F 1 , the initial values are shifted once in the shift register 14 a , so that a signal with a high level is consequently output to the connections Q 15 , Q 4 , Q 9 . Referring to Table 3, the display status shown in Fig. 3 (2) is obtained, in which the picture element groups P 20 , P 11 and P 33 light up.

In frame number F 2 , the output value from the shift register 14 a is shifted further, so that a high-level signal is output from the terminals Q 14 , Q 3 , Q 8 . The picture element groups P 13 , P 31 , P 01 shown in FIG. 3 (3) light up.

In frame number F 3 , the output value from the shift register 14 a is shifted again, so that a high-level signal is output from the terminals Q 13 , Q 2 and Q 7 . It can be seen from Table 3 that signals for the terminals Q 13 , Q 2 , Q 7 are output from the output terminal AUS with respect to the picture element groups P 23 , P 03 and P 21 , so that a display state is finally obtained as shown in FIG. 3 (4) is shown.

FIGS. 6 to 17 show display modes of operation for pixel groups P 00 to P 33 in the case of gray scale K 3 to K 14.

In the various areas which have been defined in the manner described above, the picture element groups P 00 to P 33 , which are converted frame by frame into the display state, are randomly selected, as a result of which flicker on the screen can be effectively suppressed. The composition of the display states of the picture element groups P 00 to P 33 in each gray level according to FIGS. 4 to 17 can then in fact completely compensate for the fluctuation in brightness in the individual areas.

In the embodiment described above,  create uniform images without flicker, even if large areas of the image have the same grayscale one Plurality of grayscales are shown. The grayscale can be set individually for each picture element be, so that there are no in the method according to the invention Decreasing the resolving power results, as in the case of State of the art using the area grayscale Procedure is the case.

FIG. 18 is a diagram showing on a screen that has been generated according to another embodiment of the invention. In this other exemplary embodiment, eight gray levels are displayed, for which areas of eight picture elements are set. According to FIG. 18, all picture elements are divided into picture element groups a to h , each of the regions thus obtained containing the picture element groups a to h mentioned . An area can e.g. B. contain two rows with four picture elements and four columns with two picture elements or two columns with four picture elements and four rows with two picture elements.

Fig. 19 shows the display mode with respect to a gray level with the duty ratio 3/8 in eight frames or one frame or a period for picture element groups a to h . Corresponding to FIG. 19 of each high level representing a lighting state, while each low level represents a non-lighting state. (1) to (8) in FIG. 19 denote individual picture element groups a to h .

Fig. 20 shows a composite display status of the picture element groups a to d . In contrast, Fig. 21 shows a composite display status of the picture element groups e to h . As can be seen in FIGS. 20 and 21, the magnitude of the brightness fluctuation is 1/4 when the brightness in the luminous state is 1 and in the non-luminous state 0, such a brightness fluctuation occurring at a frequency of 35 Hz when the frequency of the vertical synchronization signal is at 70 Hz. With respect to the prior art, it can be seen in Fig. 25 under (6) that the magnitude of the brightness fluctuation is 1/2, the frequency at which this fluctuation occurs is 17.5 Hz. In contrast, according to the invention, the magnitude of the fluctuation in brightness is only half as large, while the frequency concerned is twice as large. This shows that flicker phenomena can be suppressed more effectively in the method according to the invention. In the method according to the invention, brightness fluctuations can also be completely eliminated in a region which is larger than four picture elements, as can be seen from a summary of FIGS. 20 and 21.

According to the invention, it is now possible to use multi-tone Generate displays on binary level displays, without the resolution deteriorating and Flicker is to be feared.

The exemplary embodiments described above relate to representations with eight or sixteen gray levels. However, the invention is not restricted to this. Of course, an image can also be displayed with a different number of gray levels. According to the first exemplary embodiment, an area or partial area contains 4 × 4 picture elements, but can also contain 2 × 8 picture elements as a group. The initial values for the display in the frame with the number F 0 and the values for the phase delays are only values given, for example. Other suitable values can also be used here.

In the above embodiments of the invention an image representation on the condition that a frame  consists of a field (drawing file). Of course leaves but also use a display device in which a frame consists of two fields (drawing files).

The memory circuits 13 a , 13 b , 13 c , 13 d can have a logic circuit structure, while the light signal generator circuit 11 e can have the same structure as the light signal generator circuit 11 a .

Claims (3)

1. Method for gray level display by means of a dot matrix display device, characterized by the following steps:

• - dividing the picture elements on a screen of the display device into areas with a number of N picture elements each, in order to be able to generate N +1 gray levels by luminous and non-luminous picture elements, and
• - Setting each picture element to a desired level of gray level display, the picture elements lying at least in the same area adjacent to one another being set to different phases in gray level display and those picture elements in the same positions in the respective areas being set to the same phases in gray level display if their level the grayscale display is the same.

2. The method according to claim 1, characterized in that that each of the areas on the screen for Representation of 16 shades of gray, four rows and four columns of picture elements. 3. The method according to claim 1, characterized in that each of the areas on the screen for Representation of eight grayscale two rows and four columns of picture elements.