DE3634024A1 - METHOD FOR CONVERTING CONTOUR PATTERNS - Google Patents

Description

The invention relates to a method of conversion a contour pattern such as B. a letter pattern, the method in a graphic pattern processing apparatus is applicable, the pattern in the form of Vector data processed.

A method for converting a letter pattern in the form of vector cateurs is characterized in that patterns with a high data density and with a desired enlargement and reduction ratio can be converted in such a way that patterns with high fidelity result. This method uses a vector data format that represents coordinates of a contour of a letter pattern, e.g. B. A series of coordinates of successive points of the contour, a series of displacement values from a starting point coordinate or the like. However, a conventional enlargement or reduction of a pattern is accompanied by the following problem: For example, a letter "H" is shown in Fig. 2 (A) in simply enlarged its magnification into a similar figure as shown in Fig. 2 (B) or 2 (C).

In addition to the above problem, recently Desire for output of graphic letters in different Forms widespread. For example, did not exist just the desire for conventional simple enlargement or downsizing, but it was also a visual Effect desired, such as B. an assembly of a or more contours created by enlargement or narrowing an original outline in the form of vector data generated to form a so-called contour letter will. Such graphic data processing can but not done using a computer or it cannot be a visual balance of letters. That is why such processing was with complicated tedious procedures including associated with photographic processing.

The present invention is in view of the above mentioned problems of the prior art been. An object of the invention is a method of converting a graphic pattern, such as B. a letter pattern, and a processing system create for this, being by a single Pattern conversion or multiple conversions if desired or, if desired, by adding the converted one Pattern to an original pattern an expansion or narrowing a graphic pattern while maintaining visual balance becomes.

The invention is also intended to provide a method for conversion  a graphic pattern using a processing device for graphic patterns that the Contour of a pattern processed in the form of vector data, whereby by calculating to contour line segments of the Pattern parallel lines and by calculating the coordinates the line intersections using the vector data a widening or narrowing of the pattern Contour can be done while a visual Balance of the pattern is maintained.

The invention is based on exemplary embodiments Reference to the drawing explained in more detail. Show it:

Fig. 1 is a block diagram illustrating an embodiment of the graphic pattern processing system according to the invention,

Fig. 2 represents (A) to 2 (C) are views showing examples of enlargement and reduction of a character according to the prior art,

Fig. 3 shows an example of vector data of a contour of a graphic character according to the invention;

Fig. 4 is a drawing illustrating the relationship between vector information and the contour segment parallel lines;

Fig. 5 is coordinates of a new contour generated during the expansion processing;

Fig. 6 is a flow chart for expansion control method; and

Fig. 7 is a flowchart illustrating the entire graphic pattern processing system.

An exemplary embodiment according to the invention is illustrated the drawing. It is obvious that the task, effect and structure of a system that consists of several components, or met by a single component alone can be.

Fig. 1 is a block diagram showing an embodiment of the graphic pattern processing system according to the invention. In the figure , reference numeral 1 denotes a vector processing unit, 2 a vector data storage unit, 3 a pattern generation unit and 4 a pattern buffer storage unit.

Vector data of letter data is stored in the vector data storage unit 2 . In this embodiment, although the description relates to letter data, the present invention is not limited to letter data, but other data can also be used. Upon receipt of an external command to start processing, the vector processing unit 1 reads in data necessary for the processing from the vector data storage unit 2 and processes the data. The result of the vector data processing is then fed to the pattern generation unit 3 . The vector processing unit 1 has a central processing unit (CPU) (not shown), read-only memory (ROM) startup control programs as shown in Figs. 6 and 7, etc. The pattern generation unit 3 wraps a current vector pattern from numerical vector data and stores it in the pattern buffer unit 4th The saved pattern is read and output as processed data output. Although not shown in Fig. 1, it is apparent that a control unit is provided which has a display, a pointer mark device or various keys for respectively initiating such expansion processing.

The contour of a letter pattern is represented by interpolation of a series of vector data points (coordinates), which according to FIG. 3 are indicated by circles with straight or curved line sections.

The direction of all vector data between neighboring coordinates is determined so that the vector is always the inside of the letter (or the inside of the outline) looks on the right.

The description now refers to the case where the vector data pattern "P" shown in Fig. 3 is expanded (or narrowed). For reasons of simpler description, the vectors represented by arrows in FIG. 3 are called contour lines. The method for expanding the contour line by d and for reaching a new contour line, which is shown in FIG. 4 by dashed lines, will now be described. As illustrated in FIG. 4, in the expansion processing, each of the vectors (contour line) is shifted parallel to each vector concerned by the same distance d . This measure makes it possible to obtain a letter pattern "P" shifted by d , while maintaining a visual balance.

FIG. 5 shows a drawing for explaining the expansion processing of a pattern "P" according to FIG. 4. FIG. 6 shows a control flow chart of the expansion processing, the associated program being stored in a read-only memory of a non-reproducible control unit and the calculated lines and intersections of patterns are stored in a memory.

Referring to Fig. 5 represent the vectors V ₀ and V ₁ two possible adjacent vectors among a number of vectors is that the form in FIGS. 3 and contour pattern shown. 4 The two straight lines of the contour part are represented by W ₀ and W ₁ . The straight line W ₀ goes through two points ( x ₀ , y ₀ ) and ( x ₁ , y ₁ ), while the straight line W ₁ goes through two points ( x ₁ , y ₁ ) and ( x ₂ , y ₂ ). The intersection of the straight lines W ₀ and W ₁ is ( x ₁ , y ₁ ). The expansion processing is carried out using the above data. In step S 1 according to FIG. 6, after the amount d of the parallel displacement (expansion or contraction) has been entered, the vector data are decoded (coordinate conversion). Then in step S 3 there are parallel lines W ₀ 'and W ₁ ', which have the distance d from the lines W ₀ and W ₁ . In step S 4 there is the intersection between the straight lines W ₀ 'and W ₁ '. These processing steps are carried out m times for a vector loop (closed region) formed from m vectors (steps S 3 , S 4 , S 6 and S 5 ). In the case of FIG. 3, m = 10 for the outer contour and m = 8 for the inner contour. In step 7 it is judged whether all contours have been processed or not, ie in the case of FIG. 3, for example, whether steps S 3 to S 6 for the outer contour ( m = 10) and the inner contour ( m = 8 ) have been carried out. After completion, the coding vector data for all contours of the letter "P" are vector-coded, so that 8 vector data result in step S.

Next, the processing in steps S 5 and S 6 will be explained in detail with reference to FIG. 5.

As can be understood from FIG. 5, the straight line W ₀ can be expressed by:

where Δ y ₀ and Δ x _{0 represent} changes in the straight line W ₀ in x and y coordinates, respectively. Δ y ₁ and Δ x ₁ according to FIG. 5 also represent such changes.

The straight lines W to ₀ W parallel line ₀ 'is expressed by:

where e _{0 represents} the amount of the shift from the straight line W ₀ to the straight line W ₀ 'in the y direction. e ₀ is replaced by:

By inserting equation (3) into equation (2), the straight line W ₀ ′ is obtained depending on the above-mentioned coordinates ( x ₀ , y ₀ ) and ( x ₁ , y ₁ ) and the amount of the parallel displacement d .

The equations for the calculation of the straight line W ₁ 'of the next, to the vector V ₀ V ₁ following vector parallel to the line W ₁ are expressed as follows:

A new intersection point ( x ₁ ′, y ₁ ′) generated by the displacement of the vectors V ₀ and V ₁ by the distance d results from the joint solving of equations (2) and (4) according to ( x , y ). To simplify things, the straight gradients are expressed here by:

with that is

By inserting the known values x ₀ , y ₀ , x ₁ , y ₁ , e ₀ , e ₁ , a ₀ and a ₁ , the intersection ( x ₁ ′, y ₁ ′) results from equations (7) and (8 ).

If a pattern has m vectors, the above calculation is repeated m times, so that there is a new contour line shifted by the same distance d from the original contour line. If the pattern has n contour lines, the above m times calculation is repeated n times. (In the case of Fig. 3, n = 2).

If Δ x ₀ = 0 or Δ x ₁ = 0 in equation (6) or a ₀ = a ₁ in equation (7), the above calculation is replaced by an exception processing.

The amount of the parallel shift d can assume an expansion or contraction value. If d is positive, the amount of shift e ₀ in equation (3) is such that the contour is widened for all vector data, whereas if d is negative, the contour is narrowed. Fig. 7 is a flowchart showing the entire graphic pattern processing system formed by the control unit, not shown. According to the flow chart, after formation and display of a contour pattern in step S 1, preparation processing, such as. B. a rotation or slope change including z. B. the expansion processing shown in FIG. 6.

As from the foregoing description of the present Seeing invention becomes a visual balance for those of rotation or pitch conversion or any other patterns subjected to conversion before Pattern conversion of the present invention secured.

Furthermore, a shadow effect can be obtained in this way that after changing the interior of a pattern, that has undergone expansion processing, into a dot pattern the dot pattern around a certain one Amount is shifted to another with similar ones To match the dot patterns obtained. New vector data with a good visual balance can be reliably generated by using original Vector data through expansion or contraction processing being transformed.

The present invention is not limited to one graphic letters, but it is applicable to a general pattern of vector data. The present Invention has various uses, such as e.g. B. in an image processing system, the pattern, shapes etc. can process.  

As described so far in detail, the process has to convert a graphic pattern that is used in a processing the contour line of the pattern in the form of vector data Pattern processing device is used in Agreement with the predetermined processing steps the calculation of to contour line segments the vector data of parallel lines and their intersection coordinates as well as parallel widening or narrowing while maintaining visual balance.

The invention thus provides a pattern conversion method and a device including a memory unit for storing representative data of the contour of a pattern, a readout unit for reading the data from the memory unit and a processing unit for processing the data read from the memory unit and representative of the contour of the pattern, the processing by the processing unit comprising the following steps: parallel displacement of each of a number of segments forming the contour of the pattern by the same distance d , calculation of an intersection between the shifted segments and repetition of the steps for the entire contour of the pattern.

Claims (10)

A pattern conversion method including a device for storing data representing the contour of a pattern, a device for reading the data from the storage device and a device for processing the data read from this device and representing the contour of the pattern, characterized in that the processing is carried out by the processing device comprises the following steps: parallel displacement of each of a number of segments forming the contour of the pattern by the same distance d , calculation of an intersection between the moving segments and repetition of the steps for the entire contour of the pattern. 2. Pattern conversion method according to claim 1, characterized in that the storage device ( 2 ) stores the contour of the pattern in the form of a series of coordinates. 3. Pattern conversion method according to claim 1 or 2, characterized characterized in that the segment is a line below a number of each of the coordinates connecting one after the other Lines is. 4. Image processing system, characterized by a storage device ( 2 ) for storing a series of coordinate values representing the contour of a pattern, a device ( 3 ) for generating an instruction signal for instructing preparation processing of a pattern stored in the storage device, an operating device ( 4 ) for receiving straight lines that are parallel shifted by a constant distance d relative to corresponding straight lines that pass through two adjacent coordinates stored in the storage device depending on the instruction signal generated by the generating device, and a calculating device ( 3 ) for obtaining an intersection between two adjacent straight lines obtained with parallel displacement by the operating device ( 4 ), the operating device determining the straight lines in such a way that an original pattern is dependent on whether d is positive or negative iv is, is expanded or restricted. 5. Image processing system according to claim 4, characterized in that the generating device ( 3 ) is a working unit for initializing the widening or narrowing of an original pattern. 6. Image processing system according to claim 4, characterized in that the operating device ( 4 ) determines the amount of parallel displacement of the straight line from the series of coordinate values as a function of y coordinates. 7. Image processing system, characterized by a storage device ( 2 ) for storing a series of coordinate values representing the contour of the image, a first processing device ( 1 ) for carrying out processing such as e.g. B. a rotation conversion or slope conversion of the image stored in the storage device, an instruction device ( 1 ) for instructing to carry out an enlargement or narrowing processing of the image processed by the first editing device, a second editing device ( 1 ) to perform an enlargement or narrowing processing of the the first rendering device in response to an instruction by the instruction device, the second rendering device a first deriving device for deriving a straight line which results from parallel displacement by a certain distance of each of those straight lines which pass through two adjacent coordinates representing the image , and a second deriving device for deriving intersections between a number of straight lines derived by the first deriving device, an output device g ( 4 ) for outputting an image after performing expansion or contraction processing, the image being represented by the intersection points derived from the second derivation device ( 1 ) and the straight lines passing through the intersection points derived from the first derivation device ( 1 ). 8. Image processing system according to claim 7, characterized in that the output device ( 4 ) has an interpolation device for interpolating the straight lines between the intersections. 9. Image processing system according to claim 7, characterized in that the first derivation device ( 1 ) carries out a widening or narrowing processing of an original image depending on whether the constant distance is positive or negative. 10. An image processing system according to claim 7, characterized in that the second rendering device ( 1 ) can perform uniform expansion or contraction processing of an original image regardless of the fact that the first rendering device ( 1 ) performs processing.