DE19506792A1 - Image quality improving method for image output devices - Google Patents

Abstract

The method comprises the steps of inputting low resolution image information made available by an image output device and isolating a pixel to be converted and a number of surrounding pixels (P). The matrix of highly resolved pixels which replace the pixel to be converted is determined. The detected pixel pattern of low resolution is compared with a first set of predefined low resolution pixel patterns each of which is associated with a matrix of highly resolved pixels. A comparison is also made with a second set of pixel patterns of low resolution which is formed from an inversion of the first set.

Description

The reproduction of any image data with digital output advise such. B. monitors, liquid crystal displays and Ma Trix or laser printers are made by a large number single pixel. These pixels are mostly orthogonal Basic grid arranged. Each pixel can be coordinated naten within the basic grid and by its properties ten such. B. color, intensity and size are described. The width of the basic grid is generally determined by the Number of pixels per inch, dpi (dots per inch).

Binary output devices can only handle a single pixel type produce. The following applies to each position of the basic grid: pixels set or not set. To play an analog Image must first of all correspond to the basic grid of the Output device can be discretized. Lines and Contours of any orientation in stair-like structures converted. The lower the resolution of the output device is, the more clearly these structures become visible and have a disruptive effect on the overall impression of the digital Playback off.

The quality of an output device is therefore becoming common by their basic grid, one speaks of a printer Print resolution, determined. A printer is commonly used at referred to as a 300 dpi or 600 dpi printer. On 600 dpi printer has a higher resolution than a 300 dpi Printer and therefore usually delivers better output quality. However, this is not always the case as others Factors such as B. the diameter of pixels also affect the achievable print quality. Especially, if the print resolution exceeds 600 dpi, it can be fixed make a 600 dpi printer with variable dot size  produces a higher output quality than a 1200 dpi printer with a fixed pixel size.

The actual resolution of the output device will be determined by the costs incurred. Significant influence On the one hand, sizes are the mechanical precision of the output devices and the expense of electronics for processing and Output of the data to be played back. Any doubling of the Dissolution has quadrupled the amount to be processed Amount of data.

Normally the analog image is discretized in the basic grid of the output device. In at least two users However, it can also happen that the resolution of the output device is larger than that of the output device discretized image: 1. The image lies in another Resolution before or 2. The picture can be technologi reasons are only discretized in low resolution.

The raster generator of a printer, such as from US-A-5 012 434 is known from a HOST system encoded and compressed image information in the form of commands len a standardized language, such as. B. IPDS (Intelligent Printer Data Stream) from IBM, PCL (Printer Command Language) from Hewlett Packard or Postscript® (Page Description Language) from Adobe. The raster genera tor has the task of generating the final pixel grid, which is transferred to the paper by the printing unit. The grid resolution generated by the grid generator not only depends on the format of the data coming in from the HOST, but also from the maximum printable resolution.

A typical application is an image that arrives from the HOST with a resolution of 300 dpi and is displayed with a resolution of 600 dpi. The 600 dpi resolution image contains four times as much data as the same image described with the 300 dpi resolution. As a result, the memory requirement and the performance requirements of the raster generator in 600 dpi printing are considerably increased, which leads to an increase in the costs for the electronic hardware of the printer. If only every pixel with a resolution of 300 dpi were replaced by 2 _* 2 pixels with a resolution of 600 dpi, the output image would largely correspond to that of an output device with a resolution of 300 dpi. The stair structures of the 300 dpi image are practically preserved. The advantages of the high-resolution output device remained unused.

For this reason, various paths have been adopted in recent years Increased print quality shown. Such ways are in US-A-4 847 641, US-A-5 029 108, EP-A-0 500 375, EP-A-0 521 491 and EP-A-0 526 738. The three The first solutions were optimized for laser printers that have a single beam deflection system. The video signal that controls the laser diode becomes one Improvement circuit fed in serial form. The Video signal from this circuit can either be unchanged derter form to be looped through or module be used when anti-aliasing is required. A The print resolution is only increased if the enhancement circuit detects a group of pixels, for which finer dots should be printed.

In printers, such as from EP-A-0 521 491 and EP-A-0 526 738 known to contain an LED character generator, it is always required to offer the exact number of data bits that by the number of LEDs in the LED comb of the character generator is determined. Unlike printers with an optical one Laser deflection unit increases the printhead cost in significantly if, for example, instead of a 300 dpi print head a 600 dpi print head is used. In the prior art mentioned, the problem is solved avoided that an increase in resolution only in paper trans port direction is at right angles to the axis of the LED comb stands. The resolution in the direction of the axis of the  Print comb remains unchanged. Because the original 300 dpi print head still used at higher switching frequencies is an increased resolution at a low cost reachable. However, the resolution can only be increased in one direction.

An increase in resolution in two directions is known from EP-A-0 584 966. Depending on an input information that indicates whether it is a gray value image or a black and white image, edge smoothing is carried out or not carried out. In the case of grayscale images, it is assumed that the image is adversely affected by anti-aliasing. If there is a black and white image, then a finite number of templates are used to determine by which 2 _* 2 pixels of a higher resolution a selected pixel of a lower resolution is to be replaced. To save logic gates, the templates can be mirrored on a Y axis and rotated by + 90 ° or by -90 °. In the prior art, for example, the reproduction of an ascending line can thus be improved. However, the representation of a falling line cannot be improved due to a lack of reflection of the templates on an X axis. The solution shown is also only suitable for slow printers, such as. B. desktop printer.

From EP-A-0 356 224 is a data processing unit known, the area for image processing and a Contains area for interpolation of image information. At unchanged total resolution of 300 dpi, for example several lines surrounding a pixel to be converted become Obtaining smoothing information. For smoothness a modulation of the size of a pixel, as well as a shift of the center of a pixel pulled, as only with image display devices with La deflection unit can be used.  

A method for increasing the raster resolution is known from US-A-4 437 122. In order to convert a pixel into several pixels of a finer grid, the pixels immediately surrounding the pixel are used in a 3 _* 3 matrix. The 3 _* 3 matrix is assigned an identifier according to its assignment with black and white pixels, which is compared with corresponding identifiers. If a suitable identifier is found, the central pixel of the 3 _* 3 matrix is replaced by a pixel pattern of the finer grid assigned to this identifier. This procedure requires 2 ^{(3 * 3)} = 512 identifiers. If, for example, the area of the surrounding pixels is enlarged to a 7 _* 7 matrix, then 2 ^{(7 * 7)} = 5.629499 _* 10 ¹⁴ identifiers and corresponding pixel patterns of the finer grid would be required for implementation. Such a method cannot be used in a high-performance printing or copying machine for reasons of time and memory.

The present invention is based on the object Method and device for increasing the image quality in Show image output devices that are fast and reliable casual implementation of image information of a rough catch Allow the image information to be finely screened. The Implementation is said to also produce satisfactory results at Implementation of halftone images, so that a difference whether a halftone image is present or not is unnecessary.

This object is achieved by the in claims 1 and 10 specified features solved. Advantageous configurations and Developments of the invention are specified in the subclaims ben.

The invention makes it possible to quickly and reliably casual implementation of image information of a rough catch to carry out an image of fine screening. In addition, the set of predetermined pixel patterns contributes lower Resolution since it has a limited number of comparisons  makes necessary. Through the second set of pixel patterns low resolution that comes from inverting the first The result of this sentence is that an implementation of Halftone provides a satisfactory result. The Inversion causes, for example, one from the left high resolution from the bottom to the top right Pixels are added while at a corresponding Contour of the same image information, but from the left top to bottom right, high-resolution pixels ent distant, so a low-resolution pixel is not completely is shown. Statistically, this results in the entire image content of a page a constant blackening just before and after the implementation of the image information.

Special configurations of the invention ensure security represents that all possible smoothable pixel structures from the Sets of predetermined pixel patterns are detected and smoothed. In particular, 90 ° corners of the original image information reproduced unadulterated.

According to a particular embodiment of the invention limited the applicability of the invention is not even current implementation of pixel patterns, such as one Implementation from 300 dpi to 600 dpi. Rather, with one Increase the resolution, which is not an integer multiple means that of the pixels to be converted and their reverse training pixel resulting matrix of high resolution pixels in their size fluctuate periodically so that the odd number Increasing the resolution is possible.

By means of a special embodiment of the his device is a conversion of the image information into high speed and reliability. By This speed can be increased in parallel processing be tied.  

Because of their reliability and fulfillment of the highest speed The quality requirements for implementation are fiction according method and the device according to the invention for Suitable for use in high-performance printing or copying machines net.

The invention can also be advantageous for faximile transmission be used in custody. So the fax transmission can for example by image information with a resolution of 200 dpi. By using the invention there is a Decompression into image information with a resolution of 400 dpi. The data to be transferred can thus be independent of other compression methods can be reduced to ¼.

The invention will be explained in more detail below with the aid of the drawing explained. Show

FIG. 1a is a matrix to be output print data in a large ben resolution,

FIG. 1b a matrix to be output, non-smoothed print data in a high resolution,

Fig be output. 1c a matrix of smoothed print data in a high resolution,

Fig. 2 is a schematic representation of the arrangement of clusters of high-resolution pixels in a non-ge-numbered conversion of image information,

Fig. 3, all possible combinations of pixels of a Ma trix, with double resolution, can be replaced with the pixels of the coarse resolution,

A matrix with seven rows and seven rows whose central pixel combination in a high-resolution pixel is to implement Fig. 4,

Fig. 5 shows a matrix according to Fig. 4 are marked in the pixels according to their account at a smoothing rule un differently,

Fig. 6 different smoothing options by means of a diagonal line,

Fig. 7 is a smoothing rule represented as a matrix, which is converted by mirroring rules, and rotation in the other Glättungsre,

Fig smoothing rules represented as a matrix. 8 for the conservation tung 90 degree corners,

Fig. 9 is a set of rules illustrated as a matrix smoothing filter for smoothing the 2-x, x-3 and x-4 structures stairs,

Fig. 10, shown as a set of rules for smoothing matrix smoothing steps 1-2-1 structures,

FIG. 11a, a first zig-zag structure,

Fig. 11b is a matrix represented as a smoothing rule for smoothing the structure of FIG. 11a,

FIG. 12a, a second zig-zag structure,

Fig. 12b is a matrix represented as a smoothing rule for smoothing the structure of FIG. 12a,

Fig smoothing rules represented as a matrix. 13, two for smoothing standard 1-1 staircase structures,

Fig. 14 is a block diagram of the functional units for processing print image,

Fig. 15 is a block diagram of a register chain line a Par allelbus FIFO memory for receiving a pressure,

Fig. 16 is a block diagram of a parallel bus FIFO SpeI memory containing several registers chains according to Fig. 15,

Fig. 17 is a matrix representation of the parallel bus FIFO memory according to Fig. 16,

Fig. 18 is a partial illustration of a block diagram of a decision unit, connected to said parallel bus FIFO memory according to Fig. 16 LAD is Pelbar, and

Fig. 19 is a block diagram of the output circuit is a coupling bar with the arbitration unit of FIG. 18.

According to the exemplary embodiment, a matrix is provided printing information with a low resolution of 300 dpi in a matrix-like image information with a high 600 dpi resolution shown. This corresponds to one Doubling the resolution. With the help of the present inven However, other refinements are also possible, for example possible from 180 to 300 dpi or from 240 to 600 dpi.

A printer with a resolution of 600 dpi is fed image information with a resolution of 300 dpi. Fig. 1a shows a detail from such a matrix with six columns 1 to 6 and six lines S1 to S6. Individual pixels P of this matrix are set. The set pixels P, such as that of column 2 in line S2, are shown blacked out. The non-blackened pixels P, such as. B. that of column 4 in line S4, have no blackening in the figure.

The image information according to FIG. 11 can now be converted into image information according to FIG. 1b in a simple manner by being converted by four corresponding high-resolution pixels HP of the 600 dpi matrix. The set pixel P of column 2 and row S2 of the 300 dpi matrix would accordingly be converted into four set high-resolution pixels HP in columns 2 a, 2 b and rows S2a, S2b of the 600 dpi matrix. The result of this implementation would be an output of the image information with a 600 dpi output device, which largely corresponds to the output of a corresponding output device with a resolution of 300 dpi. The stair structures of the 300 dpi image are practically completely preserved and the advantages of the high-resolution output device remain unused.

In order to take advantage of the high-resolution output device, the invention shows a method and a device with which the coarse jumps and stair structures of the low-resolution image information can be smoothed. The result of this smoothing is shown in Fig. 1c.

Each pixel P of the lower resolution can be converted into four pixels HP of the higher resolution. An original pixel P can therefore have a maximum of 2⁴ = 16 possible combinations HP0. . . HP15 of pixels HP can be assigned to the high resolution. These possible combinations of high-resolution pixels HP0. . . HP15 are shown in Fig. 3. From these possible combinations HP0. . . HP15 should be selected in each case the combination that is best suited for smoothing a step-like structure.

A non-even conversion of image information is also possible. As shown in FIG. 2 using the example of a conversion from 240 dpi to 600 dpi, four clusters P of the 240 dpi matrix are assigned to three clusters with 6 high-resolution pixels HP and one cluster with 7 high-resolution pixels HP. The seventh pixel Φ is optionally assigned to one of the clusters with 6 high-resolution pixels HP. If image information is not converted evenly, more possible combinations HP0 result. . . HP. . than when implementing the resolution by a factor of two.

For deciding which of the possible combinations HP0. . . HP15 is to be chosen for a conversion, it must be determined whether the pixel P to be output is part of a staircase-like structure. This decision can be made by looking at a pixel A to be converted and up to 48 of its neighboring pixels B to y, as shown in FIG. 4. The neighboring pixels B to y form a 7 × 7 matrix, the central pixel P of which is the pixel A to be converted. Using this matrix, each individual pixel P can be queried and implemented. The names of the individual pixels P according to FIG. 4 are referred to below.

An example of a query is shown in FIG. 5. Pixels P with thin borders are not queried and are therefore not used for decision-making. Pixel P with thick borders symbolize a pixel P, which is then queried as to whether it is not set. Pixels P filled in color are then queried as to whether they are set. The example according to FIG. 5 consequently means a query as to whether pixel A is set and pixels B, C, D, H and I are not set. If this condition is met, a certain combination HP0 becomes on the basis of this result. . . HP15 selected according to FIG. 3.

Which of these combinations HP0. . . HP15 is to be selected determined on the basis of the following fundamental considerations. This is the only way to smooth stair structures conditions that with a set pixel P less than four high-resolution pixels HP are set or by the fact that at a converted pixel P at least one high-resolution Pixel HP is set. To the total degree of blackening of the Receiving print information to be output is the rule designed so that on average the same number of high-resolution pixels HP removed as added.

The differences are shown by a staircase structure shown in Fig. 6, which shows a line (0) at an angle of 45 °. If you add a high-resolution pixel HP to this line (0) for each staircase, the line (1) results. If a high-resolution pixel HP is removed from the outer edges of line (0), a line (2) results. Applying both of the described options, that is to say both adding and removing high-resolution pixels HP, would not achieve smoothing. However, if you only add a high-resolution pixel HP on one side of the line (0) and remove the high-resolution pixels HP on the other side of the line (0), you get a line (3). This line (3) is optimally smoothed and also has the same overall degree of blackening as line (0).

To decide which of the combinations HP0. . . HP15 is to be selected, basic rules are established. These basic rules can be expressed by Boolean equations. By using the symmetry properties, three further Boolean equations can be derived from each basic rule. Each of these four symmetrical basic rules can be inverted, which is why each basic rule can be expanded to eight rules. An example of such a basic rule with its derivatives is given in FIG. 7. From the basic rule, three further rules are derived by mirroring on a horizontal that runs through the pixel A to be converted, rotating by 90 ° clockwise and again mirroring on the horizontal. The resulting combination HP0. . . HP15 is also obtained from the above reflections and rotation. The pictorial representation according to FIG. 7 is expressed in the following Boolean equations:

In the Boolean equations denotes a

"∧" a logical AND
" ^- " query a pixel that has not been set

Basic rule:
∧ ∧ ∧ ∧ B ∧ K ∧ D ∧ E ∧ ∧ C ≡ HP6

mirrored on the horizontal:
∧ ∧ ∧ ∧ B ∧ K ∧ G ∧ H ∧ ∧ I ≡ HP3

rotated 90 degrees clockwise:
∧ ∧ ∧ ∧ B ∧ C ∧ H ∧ W ∧ ∧ I ≡ HP4

mirrored on the horizontal:
∧ ∧ ∧ ∧ B ∧ D ∧ I ∧ O ∧ ∧ C ≡ HP4

Basic rule inverted:
A ∧ I ∧ F ∧ Z ∧ ∧ ∧ ∧ ∧ H ∧ ≡ HP3

mirrored on the horizontal:
A ∧ C ∧ F ∧ L ∧ ∧ ∧ ∧ ∧ D ∧ ≡ HP6

rotated 90 degrees clockwise:
A ∧ G ∧ D ∧ V ∧ ∧ ∧ ∧ ∧ F ∧ ≡ HP5

mirrored on the horizontal:
A ∧ E ∧ H ∧ P ∧ ∧ ∧ ∧ ∧ F ∧ ≡ HP5

The rules with which parts of an original pixel P pass through Not removing some high resolution pixels HP will be removed each go from the inversion of the rules that add one high-resolution pixels cause HP. Out This connection shows that when implementing a low resolution image information into a high resolution Statistically, image information has as many high-resolution pixels HP added how to remove. It is therefore at the Reproduction of high-resolution image information in one Printer blackened in about the same area as in the low-resolution image information.

The following explains the rules that are used when converting the low-resolution image information into the high-resolution image information:
Preserved 90 degree corners.

The aim of this rule is to avoid smoothing at 90-degree corners, such as those found in line art drawings. The rule applies to all four possible orientations, both for the positive and the inverted case. As shown in FIG. 8, the rule shown at the top left in FIG. 4 results

A ∧ ∧ ∧ ∧ ∧ ≡ HP9

three more cases by rotation and mirroring. In all these four cases, Pixel A is replaced by the high-resolution combination HP9. The inversion of these four decision rules is shown in the lower line of FIG. 8 Darge. Here the pixel A is replaced by the combination HP0. By applying these rules, 90 degree corners are preserved.

Smooth line elements

A distinction is made between three cases F1, F2, F3 when smoothing line elements:
F1: The central pixel A is part of a contour. A contour is a transition from an area of non-set pixels P to an area of set pixels P.
F2: The central pixel A is located directly next to a hairline made up of pixels P.
F3: The central pixel A is part of a hairline made up of unset pixels.

Line elements can appear on different slopes. In a matrix, this slope becomes one in the form of steps Stairs visible. The degree of the slope can be determined by the width of the individual steps. A flight of stairs level can be the width of one pixel P, of two pixels P, of have three pixels P, etc. The height by one level to be overcome on the other hand, is fixed to a pixel P. puts. Other heights do not need to be considered separately there are seven basic rules, as described above Follow-up rules include those caused by reflections on the X axis and a 90 ° turn, as well as inverting the bottom are generally derivable.  

A first set of rules with which line elements with stair structures of the form 2 ×, 3 × and 4 × can be smoothed with x <1 is shown in FIG. 9. To smooth these stair structures, three rules K0, K1, K2 are required, each of which is different for each of the three cases F1, F2, F3 mentioned above. The first rules K0 are the basic rules, from which the two following rules K1, K2 by horizontally shifting the pixels P to be queried by one column to the right, and adding pixels P to be queried on the left edge of the block of pixels P to be queried be derived. Depending on case F1, the rules are:

Rule K0 case F1:
∧ B ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ K ≡ HP6

Rule K1 case F1:
∧ B ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ K ∧ ∧ a ≡ HP2

Rule K2 case F1:
∧ B ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ K ∧ ∧ ∧ R ≡ HP6

Because of this interdependence of the rules K0, K1, K2 it is ensured that the second or third rule K1, K2 can always be used when regarding the to the current central pixel A adjacent pixel P the first rule K0 was applied. Since the third rule K2 one Represents extension of the second rule K1, this third Rule K2 are queried before the second rule K1. This can depending on the implementation using software or hardware by corresponding entry in the program sequence or by Priorities are assigned.

The same procedure is followed in the other two cases F2 and F3 shown in FIG. 9.

Rule K0 case F2:
∧ B ∧ ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ K ∧ ∧ ∧ ∧ ≡ HP6

Rule K1 case F2:
∧ ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ K ∧ ∧ ∧ ∧ ∧ ∧ ∧ a ∧ ≡ HP2

Rule K2 case F2:
∧ ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ K ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ a ∧ ∧ ∧ R ∧ ≡ HP6

Rule K0 case F3:
∧ B ∧ C ∧ D ∧ E ∧ ∧ G ∧ H ∧ ∧ W ∧ X ∧ Y ∧ ∧ K ≡ HP6

Rule K1 case F3:
∧ ∧ C ∧ D ∧ E ∧ ∧ G ∧ H ∧ I ∧ X ∧ Y ∧ ∧ a ∧ ∧ K ∧ L ≡ HP2

Rule K2 case F3:
∧ ∧ C ∧ D ∧ E ∧ ∧ G ∧ H ∧ I ∧ Q ∧ ∧ S ∧ X ∧ ∧ Y ∧ x ∧ ∧ a ∧ ∧ K ∧ L ≡ HP2

From the respective cases F1, F2, F3 with the respective According to rules K0, K1, K2, there is a combination HP0. . . HP15, as described in the rules K0, K1, K2 above Result is specified.

Since in the rules K0, K1, K2 for smoothing line elements, slopes with a change in the stair width from 1 to 2 and vice versa were not taken into account because of the condition X <1, such stair structures are covered by a second rule set L0, L1, L2, such as shown in Fig. 10 detected. A distinction is also made here between the three cases F1, F2 and F3 mentioned above. This results in the following new rules, each of which is expanded into another seven rules by mirroring, rotating and inverting. As a result, as with all previous rules, slopes of all four directions are detected and, through the inversion, a statistical equalization of added high-resolution pixels HP and removed high-resolution pixels HP is achieved.

The rule set L0, L1, L2 for the detection of stair structures of the form 1-2-1 is:

Rule L0 case F1:
∧ B ∧ C ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ ≡ HP6

Rule L1 case F1:
A ∧ B ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ Z ∧ K ≡ HP13

Rule L2 case F1:
∧ B ∧ C ∧ D ∧ ∧ ∧ ∧ ∧ ∧ ∧ K ∧ ∧ y ∧ a ∧ O ∧ P ∧ ∧ ∧ ∧ h ∧ i ≡ HP0

Rule L0 case F2:
∧ B ∧ ∧ D ∧ E ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ≡ HP6

Rule L1 case F2:
A ∧ B ∧ ∧ ∧ E ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ Z ∧ ∧ ≡ HP13

Rule L2 case F2:
∧ B ∧ ∧ D ∧ ∧ ∧ ∧ ∧ ∧ Z ∧ K ∧ ∧ ∧ y ∧ ∧ ∧ ∧ ∧ ∧ P ∧ ∧ ∧ ∧ ∧ i ≡ HP0

Rule L0 case F3:
∧ B ∧ C ∧ D ∧ E ∧ ∧ G ∧ H ∧ ∧ S ∧ T ≡ HP6

Rule L1 case F3:
A ∧ B ∧ D ∧ E ∧ ∧ G ∧ ∧ ∧ ∧ S ∧ T ∧ V ∧ W ∧ X ∧ ∧ Z ∧ K ≡ HP13

Rule L2 case F3:
∧ B ∧ C ∧ D ∧ ∧ F ∧ G ∧ H ∧ ∧ W ∧ X ∧ Y ∧ ∧ K ∧ ∧ y ∧ a ∧ O ∧ P ∧ ∧ R ∧ S ∧ h ∧ i ≡ HP0

By applying rules L0 and L1, stair structures can be created the form 2-1-2-1 are optimally smoothed. Kicking stairs structures of the form 1-1-2-1-1-2, is characterized by additional Applying rule L2 achieves optimal smoothing.

Smooth out zigzag elements

Zigzag elements are either, as shown in FIG. 11A, individual pixels P which are diagonally offset from one another or, as shown in FIG. 12a, are individual pixels P which are offset from one another by a pixel P and which directly adjoin a contour . These structures can be applied using the rule shown in Fig. 11B

 ∧ B ∧ ∧ D ∧ ∧ ∧ G ∧ H ∧ ∧ ∧ ∧ ≡ HP4

or by applying the rule shown in Fig. 12B

 ∧ B ∧ C ∧ D ∧ H ∧ I ≡ HP4

be completely smoothed. The structure according to FIG. 11A creates a straight line of the thickness of a low-resolution pixel P, and from the structure according to FIG. 12A, an elevation protrudes from the contour at the height of a high-resolution pixel HP. Statistically, the degree of coloring remains constant even when these rules are applied.

Standard smoothing

If none of the rules mentioned so far could be applied, an attempt is made to smooth using two standard rules as shown in FIG. 13. The rules are

 ∧ B ∧ C ∧ D ≡ HP2

and

 ∧ B ∧ ∧ D ∧ ∧ ∧ ∧ ∧ ∧ ∧ ∧ ≡ HP2

By applying these rules, steps 1-1-1 are included the width of a pixel P and the height of a pixel P. Add or remove a high resolution pixel HP in small steps of the height of a high-resolution pixel HP resolved Splits. The two rules distinguish between smoothing a contour and smoothing a hairline. Due to the special symmetry properties result from each of the Rules by mirroring, turning and inverting only three more rules. Again, the statistical swarm tion of the printed image is not changed by the smoothing.

No smoothing

If none of the rules described above are applied , each pixel P set is replaced by four high-resolution ones Pixel HP of the same kind shown.

Application of the rules

An implementation of the rules for implementing an image formation is basically in software and in hardware possible. However, because printers have high speed requirements The implementation is usually carried out in Hardware realized.

The well-known implementation technologies that are hardwired ter logic, a so-called decision circuit DUC (Decision Unit Circuit) contain, process a large Group of pixels surrounding the pixel A to be converted. The Decision unit DUC determines whether a pixel P is a Edge of the drawing, an oblique line, or a gray shade is to be assigned. To consider the large group of Enabling surrounding pixels by the decision unit DUC Chen, a matrix circuit is used. A raster genera tor SRA generates line-by-line pixel data in a serial Bit format and clocks it through one  First-in-first-out memory FIFO. The FIFO is so big chooses that he is able to do some successive Print lines, such as seven lines, at the same time Save time. This FIFO is often used a single SRAM memory realized. In combination with some shift registers connected in series, for example seven registers per print line, all 49 pixels can be used processed at the same time by the decision unit DUC will. This architecture only allows a low one Clock speed and is therefore only for printers with low Ge dizziness, such as B. table laser printer, suitable.

In high-speed printers, where high demands are placed on speed, a circuit configuration is required that contains parallel processing features. Such an electronic circuit HSC having such features is inserted between a raster generator SRA and a character generator ZG according to FIG. 14. The circuit HSC converts image information of low resolution supplied by the raster generator SRA into image information of high resolution. As a result, the output data of the electronic circuit HSC describe each part of the input data in high resolution format.

The original low-resolution image, that of the raster genera tor SRA was created, is put up in blocks of data words shares that sequentially on a parallel input bus LRDBUS, which has a width of 16 bits, for example, are supplied to the electronic circuits HSC. On Data word contains 16 data bits that represent pixels to be printed submit.

Essentially three components are involved in the implementation of the pixels:
The parallel bus FIFO memory PB-FIFO
Each line of low-resolution print data is clocked by a register chain which, as shown in FIG. 15, contains three registers REG1, REG2, REG3 and an SRAM memory SRAM1. All registers REG1, REG2, REG3 and the SRAM memory SRAM1 have a width of 16 bits and thus represent a parallel bus FIFO memory PB-FIFO for the line-by-line storage of print data. The print data are from the parallel input bus tiRDBUS, the coupled to the input of the first register REG1, passed to the parallel bus FIFO memory PB-FIFO. The output of the first register REG1 is coupled via a three-bit data line to the input of a first two-to-one multiplexer MUX1 and via a 16-bit data line to the input of the second register REG2. The output of the second register REG2 is coupled via a 16-bit data line to the input of a second two-to-one multiplexer MUX2 and via a 16-bit data line to the input of the third register REG3. The output of the third register REG3 is coupled via a three-bit data line to the input of a third two-to-one multiplexer MUX3 and via a 16-bit data line to the input of a first SRAM memory SRAM1. The outputs of the first, second and third multiplexers MUX1, MUX2, MUX3 are combined to form a 22-bit data line L1, which is coupled to the decision unit DUC ( FIG. 14). The first SRAM memory SRAM1 transfers output data DOUT1 to a subsequent register chain by means of a 16 bit wide data line. This following register chain has an identical structure.

The parallel bus FIFO memory PB-FIFO contains, as shown in FIG. 16, seven register chains of essentially identical construction. Only the eleventh register REG11 in the fourth register chain is not assigned a multiplexer. The output of the eleventh register REG11 is directly combined with the three-bit outputs of the tenth and twelfth multiplexers MUX10, MUX12 to form a 22-bit data line L4. Furthermore, an SRAM memory is missing at the end of the seventh register chain. The parallel bus FIFO memory PB-FIFO is thus able to store about seven consecutive lines of print data resolved at 300 dpi and to make available access to 16 consecutive pixels of a print line with all the 48 pixels surrounding this print line. Pixels that are no longer required are discarded at the end of the last register chain.

An address control, not shown, parallel bus FIFO Memory PB-FIFO is configured so that one Group of three registers REG1. . . REG21 and an SRAM memory SRAM1. . . SRAM6 exactly one print line with 300 dpi resolution be able to record. The SRAM memory SRAM1. . . SRAM6 are after configured according to the "First In First Out" (FIFO) principle. This allows effective integration of hundreds of Registers of the registers REG1. . . REG21 type used. The SRAM memory SRAM1. . . SRAM6 are thus able to to store large amounts of data in a compact form. One access however, SRAM1 is per SRAM memory. . . SRAM6 only on one simple data block of 16 bits at a time possible. The Register REG1. . . REG21 of the register chains enable one simultaneous access to a larger amount of data. If the 300 dpi data through the parallel bus FIFO memory PB-FIFO ge clocked, they cross all registers REG1. . . REG21 and SRAM memory SRAM1. . . SRAM6.

Fig. 17 shows an arrayed-segment of data seven successive lines of a low been solved image information. This data is in the registers REG1. . . REG21 saved. Via the data lines L1. . . L7, which couple the parallel bus FIFO memory PB-FIFO to the decision unit DUC, is a seven-line and twenty-two-column section of the low-resolution image information is transparent. This transparent area BE4 is shown hatched in FIG. 17. Each register REG1. . . REG21 contains 16 bits of a line of image information.

The matrix, which contains the image information stored in the first registers REG1, REG4, REG7, REG10, REG13, REG16, REG19 of the register chains, is marked in FIG. 17 by the first area BE1. Directly connected to this first area BE1 is a second area BE2 which contains the image information stored in the second registers REG2, REG5, REG8, REG11, REG14, REG17, REG20 of the register chains. Directly connected to this second area BE2 is a third area BE3 which contains the image information stored in the third registers REG3, REG6, REG9, REG12, REG15, REG18, REG21 of the register chains. The central register REG11 always contains the pixel A1, which is converted into the 600 dpi format. . . A16. The other 48 pixels P required for implementation are available for processing in the central, hatched area BE4.

Most printing applications are at the beginning and at At the end of each page, for example, empty a number of four, lines free of print images. In the event that this blank If the data were not available, the data was from one side with the data of a sequence in an indistinguishable manner side mixed. This can be avoided in that the Output of each register REG1. . . REG10, REG12. . . REG21, with off took the central register REG11, with the receipt of a two-to-one multiplexers MUX1. . . MUX21 is coupled. With Using the MUX1 multiplexer. . . MUX21 can actually be used in the Register REG stored data on blank data BLD, which on second input of each multiplexer MUX1. . . MUX21 concerns, can be switched.

Decision unit DUC

The decision unit DUC contains the rules for converting the 300 dpi data into 600 dpi data in hard-wired form. As shown in FIG. 18, 16 decision units DUC work in parallel and independently of each other around 16 pixels A1. . . A16 a resolution of 300 dpi in 64 high-resolution pixels HP with 600 dpi. This data is divided into successive lines at 600 dpi.

During the conversion process, each decision unit DUC evaluates the 48 neighboring pixels of a pixel A1 to be converted. . . A16 in a 300 dpi grid. In order to consider the pixel A1 to be converted. . . To enable A16 surrounding pixels P, the 49 inputs of each decision unit DUC are selected with lines from the seven 22 bit wide data lines L1. . . L7 coupled. In order to convert the pixel A1, that is the pixel A1 in the row 4 in column 17 in FIG. 17, the lines which are assigned to the crossing points of the columns 14 to 20 and the rows 1 to 7 are coupled to the first decision unit DUC1, for example are.

Each decision unit DUC1. . . DUC16 just doesn't contain clocked logic, such as NAND and NOR gates and generates minde at least four output signals HPO, which are the four high-resolution Pixels represent HP, which consists of a 300 dpi pixel A er were fathered. The generation time for the high-resolution Data only depends on the signal transit time through the decision units from DUC. When the printhead of the drawing genera tors ZG is able to measure the diameter of the high-resolution Modulate pixels, then correspondingly more output signals HPO of the decision units DUC required.

c) OUTC output circuit

The output circuit OUTC is shown in FIG. 19. It ensures that the high-resolution 600 dpi data can be output line by line, although it is from the decision units DUC1. . . DUC7 can be generated simultaneously. For this purpose, the output signals HPO of the decision units DUC1. . . DUC7 led to the inputs of two registers REG22, REG23. Their outputs are coupled to a memory unit SRAM7, where the output signals are buffered line by line.

The high resolution 600 dpi data is from memory Unit SRAM7 read out to the input of a register REG24. Of the high-resolution 600 dpi data are Bit wide bus HPO given the data to the character genera gate ZG transmits. The lines are output while a subsequent 300 dpi line in the parallel bus FIFO PB-FIFO memory is clocked. Due to the double width of the Output bus HRD compared to the LRDBUS input bus will be the high-resolution data at twice the rate read how to read the 300 dpi data.

A control bus CBUS is with the grid generator, the electro niche circuit HSC and the character generator ZG pelt. If the raster generator SRA a page of print data generated, it reports this via the control bus CBUS Control electronics of the ZG character generator. This recognizes then that data is available. The parallel bus FIFO memory PB-FIFO and the output circuit OUTC must now go back if it is the first page to be printed after turning on the printer. If so, however a page had been printed while the new page is clocked by the parallel bus FIFO memory PB-FIFO, the first ten multiplexers MUX1. . . MUX10 with the register REG1. . . REG10 are coupled, then to the input with the blank Chen BLD are switched when the new data ent speaking register REG1. . . Reach REG10. The drawing gene rator ZG sends a data clock signal to the raster generator SRA around the first block of 300 dpi data on the input bus To place the LRDBUS. This data is increasing with the Edge of the data clock signal in the parallel bus FIFO memory PB-FIFO clocked. Shoot all subsequent data clock pulses ben the following 300 dpi data block in the Parallel bus FIFO memory PB-FIFO and push the others Data in the parallel bus FIFO memory PB-FIFO further. Of the Raster generator SRA always transfers the 300 dpi data lines wise, and within a row the data blocks  sequentially on the 16 bit bus, for example, pixels 0 to 15, pixels 16 to 31, pixels 32 to 47, and so on.

When the data for the new page, the eleventh register REG11 the decision unit DUC, the 64th generate the corresponding high-resolution output pixel HP and in the memory unit SRAM7 of the output circuit OUTC to save. Another 600 dpi data will follow with each generates the data clock pulse. After the two complete Lines from 600 dpi data from a line from 300 dpi data the 600 dpi print data can be generated Lines in the storage unit SRAM7 of the output circuit circuit OUTC are stored on the 32 bit output bus HRD with the double frequency of the following 300 dpi line be read out. This 600 dpi data must now be Print comb of the character generator to be inscribed before the actual printing can begin.

The data is processed by the described print data preparation transfer between the raster generator SRA and the character set nerator ZG by more than four low-resolution print lines take delayed. This delay has to do with printer control tion are taken into account and compensated for. If the grid generator SRA the last 300 dpi data block of the current one The raster genera gate SRA sends a signal to the control bus CBUS. This signal can to be used, the first ten multiplexers MUX1. . . MUX10 of the parallel bus FIFO memory PB-FIFO in time before the new data is sent to the multiplexers MUX1. . . 10th assigned register REG1. . . Reach REG10. This poses sure that the decision units DUC1. . . DU16 the data Do not mix one page with the data on the next page. When the print data of a new page is finally in the regi ster REG11 are passed, then the multiplexers MU X1. . . MUX10 switched again and the output of the register REG1. . . REG10 with the MUX1 multiplexer. . . MUX10 passed on give. At the same time, the multiplexers MUX12. . . MUX21,  with the registers REG12. . . REG21 are coupled to the Blank data switched. Each of these subsequent multiples xer MUX12. . . Only then will MUX21 become the connection to the corresponding register REG12. . . Switch through REG21 if the first Block with print data belonging to the new page, the respective register REG12. . . Has reached REG21.

Although the example described above is an implementation of Print data with 300 dpi resolution data in 600 dpi describes, the circuit can also be used for another implementation tion, for example from 240 dpi to 480 dpi, from 300 dpi after 900 dpi and so on. The use of a 16th Bit and a 32 bit data bus for input and output not mandatory. Changes to the register design and the timing diagram can be made to others Support bus widths. Finally, the invention with the corresponding algorithm in the implementation unit DUC instead of the data in two levels (without control of the pixel diameter) into a multi-level print data stream (variable Pixel diameter) can be changed.

Claims (15)

1. A method for increasing the image quality in image output devices with an image display unit (ZG) for the reproduction of matrix-like image information of high resolution, the image output devices having image information of low resolution available, with the following method:

• Detection of a pixel to be converted (A) and a number of surrounding pixels (P),
• - Determine a matrix of high-resolution pixels (HP), which replace the pixel to be converted (A), by means of a comparison of the detected pixel pattern with low resolution
  • - A set of predetermined pixel patterns of low resolution, each of which is assigned a matrix of high-resolution pixels (HP) and
  • - A second set of low resolution pixel patterns, which is formed from an inversion of the first set of predetermined pixel patterns.

2. The method according to claim 1, in which a set of pixel patterns is composed of a plurality of rules and sequence rules, the sequence rules each arising from a rule

• Reflection on an axis running through the pixel (A) to be converted,
• - Rotation by 90 degrees around the pixel to be converted (A), and
• - Reflection on the axis running through the pixel to be converted (A).

3. The method according to any one of claims 1 or 2 in which the Set of predetermined pixel patterns containing such patterns who concluded that 90 ° corners exist can be, creating such corners in the image information high resolution.   4. The method according to any one of claims 2 or 3 in the rules for smoothing certain gradients in the pixel pattern where the slope is the number of neighboring pixels (P) in a row or column from a column or rows change to the next is determined. 5. The method according to claim 4, wherein the rules for smoothing certain slopes are further differentiated according to whether the pixel to be converted (A)

• - is part of a contour,
• - Is located directly next to a hairline made of set pixels (P), and
• - Part of a hairline made up of unset pixels (P).

6. The method according to any one of claims 1 to 5 in which the Set of predetermined pixel patterns containing such patterns those on the presence of alternating diagonal ver last pixels (P) can be closed. 7. The method of claim 6 in the pattern with alternately diagonally offset pixels (P) are further distinguished according to whether the pixel to be converted belongs (A)

• - a group of individual pixels (P) or
• - A group of pixels directly adjacent to a contour (P).

8. The method according to any one of claims 1 to 7 in which the Sets of predetermined pixel patterns in the form of boolean Equations are expressed and thus logically with the correspondingly formulated pixel pattern that the to be implemented Contains pixels (A), can be linked.   9. The method according to any one of claims 1 to 8 in which one Implementation of low resolution image information in high-resolution image information is obtained in that the Size of the matrix of high-resolution pixels (HP) in one periodically recurring pattern fluctuates. 10. Apparatus for increasing the image quality in image output devices with an image display unit (ZG) for the reproduction of a matrix-like image information of high resolution, the image output devices having image information of low resolution available with the following means

• for detecting a pixel to be converted (A) and a number of surrounding pixels (P),
• - To determine a matrix of high-resolution pixels (HP), which replace the pixel to be converted (A), by means of a comparison of the detected pixel pattern with low resolution
  • - A set of predetermined pixel patterns of low resolution, each of which is assigned a matrix of high-resolution pixels (HP) and
  • - A second set of low resolution pixel patterns, which is formed from an inversion of the first set of predetermined pixel patterns.

11. The device according to claim 10, wherein the means are formed by an electronic circuit inserted between a raster unit (SRA) and the image reproduction unit (ZG), which contains:

• - A plurality of register chains through which the low resolution image information is slidable so that a row or column of image information is at least partially contained in each register chain, whereby the pixels to be converted (A) and the required number of surrounding pixels (P) at the outputs the register chains are available in parallel,
• - At least one coupled with the outputs of the register chains decision unit (DUC), which contains sets of predetermined pixel patterns in the form of a logical switching network and provides the resulting matrix of high-resolution pixels (HP) at its output and
• - An output circuit (OUTC) which converts the resulting matrices of high-resolution pixels (HP) into image information that can be output in rows or columns.

12. The apparatus of claim 11 in which in the register chains contained registers (REG1 ... REG10, REG12 ... REG21), the the surrounding pixels (P) of the pixel to be converted (A1... A16) included, at their outputs with multiplexers (MUX1... MUX10, MUX12. . . MUX21) are coupled via their second inputs predetermined image data can be entered. 13. Device according to one of claims 11 or 12 in the data words can be pushed in parallel through the register chains, so that a plurality of low resolution pixels (A1 ... A16) can be implemented in parallel. 14. Use of the method according to claims 1 to 9 and the device according to claims 10 to 13 in a high speed printing or copying machine. 15. Use of the method according to claims 1 to 9 and the device according to claims 10 to 13 for decompression sion with a faximile transmission.