DE4219925C1 - - Google Patents

Abstract

In the character matrix-like memory (ZM) of a character generator for a picture reproduction device (BW) the number of columns (SP) per character (Z) is increased by a column factor. The clock frequency for reading the character memory (ZM) is likewise increased, whereas each pixel (P) in the horizontal direction is stored multiplied by more than the column factor.

Description

The invention relates to a circuit arrangement for control an image display device according to the preamble of claim 1.

DE 29 09 922 C2 describes a device for controlling a Matrix printer or a matrix display device according to the The preamble of claim 1 is known. The facility contains a control unit for reading out pixel information from a character store. With the well-known facility can be one with a certain width in the character memory stored character in different character widths for Image reproduction can be read out. The respective Character width is determined by a logic circuit.

For rendering characters using an image display device is in a device that is the image display device controls, contain a character generator. In the character memory of this character generator are characters of a certain filed by attributes. For each For example, characters that can be named in ASCII code are in Character memory specific matrix points (pixels), for example with the value 1. The character memory becomes line by line read out. In places where there is no character information, the value 0 is read out and in places where a the value 1 is read out. This value 1 corresponds to information in the form a pulse that depends on the cutoff frequency of the character generator a certain steepness of the rise and Has waste edge. In unfavorable cases it can happen that one by an impulse Setpoint not reached. An impulse that meets its setpoint  not or just reached, then leads in the image display device to a reduced contrast of the pixel to the picture background. Kick a variety in one sign of pixels with reduced contrast, then this leads to defective image reproduction of the displayed character.

The present invention is therefore based on the object the representation of characters on an image display device to improve in a simple and inexpensive way.

This object is achieved by those specified in the claim Features solved. The number of columns in the character memory increased by the column factor and at the same time the clock frequency for reading out the character memory also by the Column factor increased, then a character is read out the same time as before the enlargement of the Number of columns. By multiplying the pixels in the row direction by more than the column factor, arise comparatively broader impulses. Enable these broader impulses a reliable rise in the pulse edge up to the setpoint. The display device with an unchanged video frequency acts and gives the signs due to the improved Pulse formation with higher contrast again. This will turn on simple and inexpensive way of improved image reproduction achieved with unchanged image display device.

In the following, the invention will be described with reference to the drawing explained. Show

Fig. 1 is a block diagram of the inventive circuit arrangement with the image display device,

Fig. 2 is a field for a character in a character memory according to the prior art,

Fig. 3 is a field for a character in a character memory with an increased number of columns,

Fig. 4a shows a detail of the character memory shown in FIG. 2,

Fig. 4b a set pulse for a pixel of a character memory in accordance with Fig. 4a,

Fig. 4c a actual pulse for a pixel of a character memory in accordance with Fig. 4a,

Fig. 5a shows a detail of a character memory shown in FIG. 3,

Fig. 5b shows a target pulse for a pixel of a character memory shown in FIG. 5a and

Fig. 5c an actual pulse for a pixel of a character memory shown in FIG. 5a.

According to the block diagram of Fig. 1 receives a control unit C for a picture display device D BW data in coded form. The control unit C converts the data D into pulses using a character memory ZM, which are fed to the image display unit BW and displayed there. The character memory ZM is structured in a matrix in rows ZE and columns SP (see FIG. 2). For each character Z, fields with a certain number of columns and rows are reserved in the character memory ZM. As shown in FIG. 2, a field for a character Z of a known character memory ZM consists of sixteen lines ZE and nine columns SP. A character Z, here the capital letter A, is stored in the field of the character memory ZM in the form of information. A pixel P is activated when a logical 1 is read out of the character memory ZM when addressing a specific column SP and a specific row ZE. If, on the other hand, a logical 0 is read out, no pixel P is activated at this point. For the character Z, which represents the capital letter A, the following pixels P are set in the corresponding section of the character memory ZM:

Columns SP / rows ZE
2 / 6-11
3/9, 12
4/9, 13
5/9, 14
6/9, 13
7/9, 12
8 / 6-11

A corresponding field of a character memory ZM according to the invention is shown in FIG. 3, in which the character Z for the capital letter A is stored. This field comprises sixteen rows ZE and eighteen columns SP. The number of columns SP is accordingly increased by a column factor of 2 compared to the character memory ZM according to FIG. 2. The following pixels are set for the capital letter A in the character memory ZM according to the invention:

Columns SP / rows ZE
3 / 6-11
4 / 6-11
5 / 6-12
6/9, 12
7/9, 12, 13
8/9, 13
9/9, 13, 14
10/9, 14
11/9, 13, 14
12/9, 13
13/9, 12, 13
14/9, 12
15 / 6-12
16 / 6-11
17 / 6-11

If one now compares the controlled pixels P from FIG. 2 and from FIG. 3 with one another, then it must first be ascertained that the number of pixels P per character Z in FIG. 3 has increased compared to FIG. 2. If one looks at the pixel P from FIG. 2, which is located at the intersection of the second column SP and the sixth row ZE, then it can be seen that this pixel P marks the lower end of the left vertical bar of the capital letter A. The lower end of the left vertical bar of the capital letter A according to FIG. 3 is marked by three pixels P, namely the crossing points of the sixth line ZE with the third, fourth and fifth column SP. From the example of this pixel P it can easily be seen that a pixel P of a character Z of a known character memory ZM is stored in a character memory ZM according to the invention in the row direction multiplied by more than the column factor in the character memory ZM. In the example shown, the column factor is 2 and the pixel P is stored multiplied by a factor of 3 in the row direction (row 6).

If, as in line 9 of the capital letter A, several pixels P are stored directly in succession in the line direction in the prior art according to FIG. 2, this leads to a multiplication when line 9 of the character Z is implemented in a character memory ZM according to the invention each pixel P in the row direction by the column factor. Only the last pixel of such a row ZE shows the multiplication of a pixel P by more than the column factor. For example, the pixel P, which is located at the intersection of the eighth column SP and the ninth row ZE in FIG. 2, is tripled in FIG. 3 at the intersection points of the ninth row ZE with the fifth, sixth and seventh column SP.

The section of the character memory ZM according to the prior art, which is shown in Fig. 4a, comprises the second, third and fourth column SP and the sixth, seventh and eighth row ZE. If, for example, the sixth line ZE is read out at a certain clock frequency, then the rectangular target pulse PS shown in FIG. 4b should be read from the second column SP and output to the image display device BW. In fact, however, the actual pulse PI shown in FIG. 4c reaches the image display device BW. This actual pulse PI has flattened rising and falling edges and does not reach the desired height H of the desired pulse PS. Even if the desired height H should be reached, the needle-like actual pulse PI directed to the image display device BW generates a point of little contrast, which is difficult to recognize on the image display device BW designed in the form of a cathode ray tube.

If one now considers a section of the character memory ZM according to the invention, which is shown in FIG. 5a and comprises the sixth to ninth rows ZE and the third to ninth columns SP, then a target pulse PS shown in FIG. 5b is expected, which represents the 11th / 2 times the width of the desired pulse PS shown in FIG. 4b. To read out this target pulse PS, the clock frequency is increased by the column factor, ie by a factor of 2. The actual immune pulse PI that arises from the readout and is shown in FIG. 5c completely reaches the target height H and is significantly broadened compared to the actual pulse PI shown in FIG. 4c. If this broadened actual pulse PI is supplied to the image display device BW, then this image display device BW can display the section of the character Z under consideration with increased contrast and thus with increased quality. The image display device BW is not subjected to an increased video frequency compared to the known prior art.

The maximum video frequency results from the state of the Technology from the reciprocal of the readout time for two columns SP of a row ZE and in the circuit arrangement according to the invention from the reciprocal of the time for reading out four adjacent columns SP of a row ZE.

The image display devices used in the prior art BW can therefore continue to be used. On Show reason of the circuit arrangement according to the invention these image display devices BW however a better one Display quality. Even the C control can remain unchanged provided it is able to move one around the clock frequency increased the column factor, for example by inserting an appropriate quartz. Customary character memories ZM can also continue be used. However, if not previously unused Memory spaces are available, the number of characters in the memory ZM stored characters Z by the column factor be made smaller.

Claims (1)

Circuit arrangement for controlling an image display device (BW) with information which is assigned to individual pixels and can be read out with the help of a control unit (C) from a character memory (ZM) structured in rows in rows (ZE) and columns (SP) in order to display characters, characterized in that, with unchanged character width, the number of columns (SP) per character (Z) in the character memory (ZM) is increased by a column factor, that the clock frequency for reading out the character memory (ZM) at an unchanged video frequency with which the control unit ( C) controls the image display device (BW) by this column factor is increased, and that each pixel (P) of a single character (Z) is stored in the row direction multiplied by more than the column factor in the character memory (ZM).