DE4042478C2 - Printing method for dot matrix printer - Google Patents

Abstract

The printing method for a dot matrix printer involves receiving the point data representing an original dot matrix corresp. to text, graphics, etc., and converting the original pattern whereby M, where M greater or = to 3, points lying in a row are converted into N points, where M greater than N greater or = 2, M2N. Printing is then conducted on the basis of the converted point data. The print head is moved more rapidly than usual wrt. the recording medium.

Description

The invention relates to a printing method for use in Dot printers.

From JP-A-60-73852 it is to achieve a high printing speed in a dot matrix printer known from an original dot pattern that corresponds to a time to be printed Chen or symbol corresponds to a secondary dot pattern to produce that every other point of the original dot pattern is omitted, and then the printhead based of the secondary dot pattern at twice the speed move as usual.

Although in this known method, the printing speed printed is twice as high as normal Dot pattern compared to the original dot pattern a considerable one Distortion, which means poor print quality.

From EP 0 331 033 A2 it is known to increase the Print speed with a dot matrix printer the Origi to convert the point pattern into a secondary point pattern in which chem the point distance compared to that of the original point pattern is enlarged. This is done by putting four on top of each other the following points of the original point pattern, which have an Ab stood from 1/180 ′ ′, the first and the last in the Secondary point patterns are taken over and the two middle to a middle point of the secondary point pattern be set. So the secondary dot pattern contains three Points that are 1/120 ′ apart. This Process results in poor print quality because lines, which are drawn through when the original dot pattern is printed out normally gen appear, have gaps of a width of 1/360 ''.  

The same document describes another method, at which also has an original dot pattern in a secondary dot mu ster is converted and then the secondary dot pattern with is printed at an increased printing speed. In the opposite sentence to the aforementioned known method, based on the the original dot pattern and the secondary dot pattern ster on the same grid. Whether one in the original point most occupied grid position also in the secondary dot pattern depends on whether one of the two is in line rich tion immediately preceding grid positions in the secondary dot patterns are occupied or not. If due to this Algorithm be one of the two preceding grid positions is set, the current grid position is not occupied. The result of this procedure is an increase in the minimum dot spacing in the secondary pattern, but with considerable distortion of the original pattern.

EP 0 326 295 A1 describes a method for enlargement of bitmap font data in the horizontal direction is known. It is in common in many cases, the individual characters in the form of Character matrices to be printed out as dot matrices To store bitmap font data, with memory for each Character contains an image of the matrix. For every time size is usually a separate data set required, which requires a corresponding storage capacity different. The cited document describes a process that it allows a basic data set to be used for a ver larger sign required additional points to he count.

The object of the invention is to provide a printing method for Ver application at a dot printer to create the increase the printing speed with only minor impairments printing quality allowed.  

This object is achieved by the in the patent claims 1 and 3 specified features solved.

An embodiment of the invention is described below the drawings explained in more detail. Show it:

Fig. 1 is a block diagram of an arrangement for implementing the method according to the invention,

2 shows an exemplary expression based on an original dot pattern ,

Fig. 3 is a flowchart of an operation of the arrangement shown in Fig. 1,

Fig. 4 is a diagram for explaining the operation,

Fig. 5 and 6, an original dot patterns and a print example based on the embodiment of the invention in comparison to a print example in accordance with a defined procedure walls (DE 40 30 010 A1),

Fig. 7 is an exemplary expression based on the embodiment of the invention, and

Fig. 8 is an illustration for explaining the operation of the arrangement shown in Fig. 1.

Fig. 1 shows an arrangement for performing the inventive method. 1 is a print character determination device, such as a personal computer. 2 is an original dot pattern memory circuit in the form of a font ROM in which dot data for a plurality of original dot patterns of letters, numbers, symbols and the like are stored. 3 is a RAM for temporarily storing both dot data of an original dot pattern read by the original dot pattern memory circuit 2 and dot data of a secondary dot pattern obtained by converting the original dot pattern according to a predetermined algorithm. 4 is a control circuit for reading the dot data from the original dot pattern storage circuit 2 , for performing the pattern conversion based on the original dot pattern, for controlling the printing, etc., 5 is a printing device such as a print head or the like for performing the printing on the basis of FIG point data stored in RAM 3 .

If rapid printing is to be carried out, an operating mode switch (not shown) is switched to select the rapid printing mode and then the print character determination device 1 is operated to determine print characters. Due to the determination of a print character, the print data of an original dot pattern corresponding to the designated print character is read out from the original dot pattern memory circuit 2 . The original dot pattern is implemented by the control circuit 4 on the basis of a pregiven algorithm and then stored in the RAM 3 . Then the printing is carried out by the printing device based on the dot pattern stored in the RAM 3 .

With reference to the flowchart in Fig. 3, an embodiment of the method of pattern conversion of the original point pattern by the control circuit 4 will now be described.

In general, the maximum response frequency of the Druckele elements, so about the printing needles in a dot matrix printer, is determined under the assumption that all the dots of a line are printed one after the other, and the normal speed of the print head is determined so that the character is printed optimally when the pressure elements are controlled at the maximum response frequency. In practice, however, if only two or three consecutive dots are to be printed, the printing elements can be operated with a response frequency that is greater than the maximum. The third embodiment is based on the assumption that the printing device 5 can print the last of consecutive dots, that is, two consecutive dots, with a response frequency 1.5 times as usual, and strives to improve the print quality Exploitation of this property.

It is assumed that the dot data representing one dot line of the original dot pattern is stored in the RAN 3 in the developed form shown in Fig. 4 (a). First, each point is converted into two consecutive intermediate points as shown in Fig. 4 (b) (step ( 1 ) in Fig. 3).

Then the first intermediate point is taken over into the secondary point pattern and it is checked whether the number x of successive intermediate points following the taken point fulfills the condition nx2n-1 (n is the number of intermediate points that are generated for an original point, that is n = 2 in this example). If the condition is fulfilled, that is, if there is only one more point that can then be accepted, then printing can be carried out at a response frequency equal to 1.5 times the normal. Therefore, a point is adopted in the secondary point pattern that is at a point position that is the same point distance from the first point position as that of the original point pattern (point d1 in Fig. 4 (c)). On the other hand, if x2n, that is, if there are two or more points that can then be adopted, intermediate points are selected that are at point positions that are spaced apart by a point distance that is 1.5 times the usual ( Point d2 in Fig. 4 (c)). This is because in this case the control is carried out with the usual response frequency. All points except for the points adopted in the secondary point pattern in the manner described are removed and the point data corresponding to a point line as shown in Fig. 4 (a) is converted into a point sequence according to Fig. 4 (c) (step ( 2) in Fig. 3).

When all the dot lines have been completely implemented, the print head is moved on the basis of the secondary dot pattern thus generated at a speed which is 1.5 times the usual, so that the printing elements with the maximum response frequency of the usual printing or a response frequency are controlled, which is 1.5 times the usual maximum response frequency (step (3) in Fig. 3).

In this way, letters and the like, which are specified by the print character determination device 1, are printed at a speed which is 1.5 times as fast as usual.

For illustration, Fig. 5 shows (a) an original dot pattern, (b) a secondary dot pattern, which was obtained by pattern implementation of the original dot pattern (a) according to a method proposed in DE 40 39 010 A1, and in (c) a secondary dot pattern obtained by pattern conversion of the original dot pattern (a) according to the present embodiment. The secondary dot pattern (b) has bold vertical lines compared to the original dot pattern (because the dot pitch has been increased 1.5 times), and the upper and lower parts on the right are slightly noted. These weak points are improved in pattern (c), which means that the secondary dot pattern (c) comes closer to the original dot pattern.

Fig. 6 (a) shows an original dot pattern, (b) a secondary dot pattern obtained by pattern conversion of the original dot pattern (a) according to the method proposed in DE 40 39 010 A1, and (c) a secondary dot pattern obtained by pattern conversion of the original dot pattern (a) according to the present embodiment. The secondary dot pattern (b) has skewed oblique lines compared to the original dot pattern. This is improved in the secondary point pattern (c), i.e. the slanted lines in the secondary point pattern (c) represent a better approximation to the original point pattern.

FIG. 7 shows a print example of a secondary dot pattern obtained by pattern conversion of the original dot pattern of FIG. 2 according to the described embodiment of the invention.

Although it has been described in the present embodiment that each point of the original point pattern is converted into two intermediate points as shown in Figs. 4 (a) and (b), a conversion into four intermediate points can also be made as shown in Figs Fig. 8 (a) and (b) emerges. As shown in Fig. 8 (c), according to the maximum response frequency of the printing elements obtained by printing successive dots of a short period, only dots of consecutive intermediate dots in the secondary dot pattern which are at dot positions which are from are adopted the first point position by an integer multiple of a point distance that is 1.25 times or 1.75 times the usual. If the number x of consecutive intermediate points after a point thus selected satisfies the condition nx2n-1 (n = 4 in this example), then a point is selected which is at a point position which is the same from that of the previously selected one Dot spacing is removed as in the original dot pattern. It is thus possible to achieve a printing speed increased to 1.25 or 1.75 times the usual speed by increasing the speed of the print head to 1.25 or 1.75 times during printing.

Although the described embodiment allows the printer 5 to print two consecutive dots at a response frequency higher than the usual maximum response frequency, it is also possible to print three or more consecutive dots at a response frequency higher than the usual maximum response frequency . For this purpose, suitable intermediate points that correspond to such a procedure must be selected.

Although in the described embodiment, the dot data corresponding to one line is stored in the RAM 3 in a developed form, it would also be possible to store the dot data of an entire character.

While in the foregoing embodiment, the pattern conversion takes place after the point data of the original point pattern has been stored in the RAM 3 in a developed form, the point conversion can be carried out while the point data of the original point pattern is read out from the original point pattern storage circuit 2 . In this case, only the point data of the secondary point pattern need to be stored in the RAM 3 in a developed form.

With the measures according to the invention described, the Print speed can be increased without the print quality lity suffers noticeably. The measures make it possible print a secondary dot pattern that matches the original dot ster largely corresponds, so that the print quality only we is reduced.

Claims (3)

1. A printing method for use in a dot printer with a print head displaceable in the line direction relative to a recording medium, comprising the steps:
Receiving original point data representing an original point pattern which has points arranged in the line direction while maintaining a minimum distance d ₁ ,
Converting the original point pattern by converting each original point data into n (n2) successive secondary point data,
Select desired secondary point data whose point data distance is equal to or greater than the minimum distance of the original point data,
Moving the print head at a speed V ₂ greater than a speed V ₁ at which the print head is moved when printing based on the original dot pattern, and
Performing printing based on the secondary point data thus selected,
wherein the distance of the dots printed using the selected secondary point data is equal to or larger than the distance d ₁ . 2. The method of claim 1, wherein the distance of the dots printed using the selected secondary point data is d ₁ or d ₂ , where d ₂ = d ₁ · V ₂ / V ₁ . 3. A printing method for use with a dot printer comprising the steps of:
Receiving point data representing an original point pattern,
when printing at a speed greater than the print head shift speed when printing the original dot pattern,
Converting the original dot pattern by converting each dot into n (n2) consecutive secondary dots, of which only those dots are selected in a zone where printing with the same dot pitch as in the original dot pattern is possible, with the same dot pitch as that of the Original point pattern are arranged, and in a different zone every mth secondary point ( 2 n-1mn + 1) is selected, and
Printing using the point data thus converted.