DE3631329A1 - Control unit for visual display unit - Google Patents

Abstract

Between a VDU computer (SGR) and a memory, in which image data for several images which can be displayed on the screen of a VDU are held, an address converter (ADU) is connected, to which addresses which correspond to the screen co-ordinates are fed by the VDU computer (SGR), and which forms image memory addresses from these addresses, in such a way that the image data are taken from different areas of memory (SPa, SPb, SPc, SPd) and shown on the screen. The main application field of the invention is VDUs for data and processes. <IMAGE>

Description

The invention relates to a control device according to the Preamble of claim 1.

On the screen of terminals of office technology the process technology or CAD, CAT systems or the like often images of different, independent from each other Content shown. These images can be whole or partially cover. It then has to be spent on the picture memory are constantly checked whether the information issued tion should be visible or hidden. A similar problem exists in the representation of three-dimensional bodies. Whole or partially hidden areas must be recognized and their output to the display device can be suppressed.

The rendering of a picture with overlapping drawing files is possible by first entering the image memory enters the image data for the image elements of the background and then one after the other for the drawing files in front of it. This has the disadvantage, however, that picture elements are temporarily visible are bar that should not appear at all. In addition, at Every image change will be checked to see if the change is visible may or may not be.

To display image information in visual display units posed pictures it is known from DE-PS 30 35 636, to provide several image memories in which image data and Priority information is stored in parallel be read out. The read image information will over a multiplexer, which depending on the Priority information is controlled so that the image data depending on the priority of their display on the display device  be switched. Such an arrangement requires priori level an image memory, at least one image memory level. Manipulations on the type of presentation, e.g. B. against moving the drawing files to the side, enlarging, reducing and the like are difficult or impossible to carry out.

EP-A 8 61 00 786.2 proposes in addition to To enter write protection signals in the image memory, which are read out with a write command and the on Block writing of new image data. Registered mail Image data takes place in the order that the image first data for the picture elements, the representation of which has the highest priority act, registered and ver with the write protection signal will be seen, then the image data for the image elements with the second highest priority and so on. Finally, they will be Image data turned on for the image elements of the image background wrote, the entry of image data for hidden image elements is locked. The valid one is created automatically Image taking into account all overlays and verdec kungen. Is a special write protection for each drawing file Code provided, then targeted changes to the individual drawing files possible.

The present invention has for its object a Visual control to create that with little effort enables a quick image build-up with overlaid single images light.

According to the invention, this task with the characteristic Part of claim 1 specified measures solved.

Based on the drawing, configurations and Further developments of the invention are described and explained in more detail.

Fig. 1 shows the outline diagram of an exemplary embodiment of the invention, the

Fig. 2 and 3 illustrate an embodiment of the embodiment of Fig. 1 and its function, in

FIG. 4 shows a further embodiment of the example according to FIG. 1.

In Fig. 1, SGR denotes a viewer computer which, among other things, provides screen coordinates of the screened device SG which is scanned on the screen of a device operating according to the line screening method. These coordinates are supplied on the one hand to a video signal unit VSE , which forms the necessary synchronous and blanking pulse for the operation of the display device SG , and on the other hand the screen coordinates receive an address converter ARU to which an image memory BSP is connected. This has several areas SPa, SPb, SPc, SPd , in which the image data of one image each can be displayed with the display device SG . For the sake of simplicity, it is assumed that the capacity of the individual image storage areas is adapted to the number of image data that can be displayed simultaneously on the screen of the display device SG . But it can also be larger or smaller. The address converter converts the screen addresses into image memory addresses based on parameters supplied by it that from different areas, e.g. B. SPa, SPc, SPd , image data are read out and an image is displayed on the view device , which is formed by superimposing the partial images Ba, Bb, Bc, Bd contained in these memory areas. The images can be partially hidden. The coordinates of the corner points of the drawing files are x ₁₁ , x ₁₂ , y ₁₁ , y ₁₂ ; x ₂₁ , x ₂₂ , y ₂₁ , y ₂₂ . . .

Fig. 2 illustrates the address transformation and the presentation of different fields for the case that the address transducer consists of an address converter table containing the memory ADS . In the left column of the popu with ADS recorded block addresses are registered in computational th column of the contents of the memory cells. The addresses are the screen coordinates 00, 01. . . nm , of which the first digit indicates the column number and the right one the row number. There are therefore n · m picture elements in n columns and m rows and a corresponding number of cells in the memory ADS . The contents of the cells are each an address for the image memory BSP . Its cells with the addresses a _ÿ form the memory area SPa , the cells with the addresses b _{ÿ form} the area SPb and so on. The image data contained in cells a _ÿ , b _ÿ are designated A _ÿ , B _ÿ , e.g. B. in the cell a _{n 1 contains} the image data A _{n 1} . For the sake of clarity, the image storage areas are drawn in FIG. 2 in accordance with the representation of the image data on the screen. The content of the memory area SPa gives the image shown symbolically in FIG . B. the image data A ₀₀ . . . A _{n 0} in the first line and the image data A ₀₀ . . . A _{0 m can be shown} in the first column. The indices indicate the screen coordinates. Accordingly, cells are b ₀₀ . . . b _{nm of} the memory area SPb image data B ₀₀ . . . B _nm saved that coordinates to the screen 00. . . nm are shown.

The display device computer SGR outputs the screen coordinates 00, 01 synchronously with the raster scan of the screen. . . nm as addresses on the address conversion memory ADS , which assigns an image memory address to each screen coordinate. For example, when the screen coordinate 00 is supplied, it gives the address a ₀₀ to the image memory BSP , so that the image data A _{00 is} displayed on the screen at the coordinates 00. Is the vision computer, the coordinates which SGR from 1.1, the image umbrella cell with the address called b _00, and naten to 1.1 Koordi the date B is represented _00th In the conversion table adopted as an example in FIG. 2 and contained in the address conversion memory ADS , the image symbolically drawn in block SG in FIG. 2 results, which is composed of image data of the memory areas SPa and SPb . Correspondingly, image data from other memory areas can be called up by the address converter, the order being arbitrary.

Images can thus be put together as desired. The size and position of the areas SPa, SPb in the image memory are also freely selectable; there is no connection between the position of the memory area in the image memory and the position of the partial image stored therein on the screen. The address converter contains the information about which image data from which sub-area are displayed at which point on the screen. The image information is in the image memory BSP . Changes to the image content are carried out in the image memory, changes in the type of display, such as masking, moving, enlarging, reducing, in the address converter.

If only a few standardized types of representation are required, these can each be stored as an address conversion table which is called up by entering a base address in the address conversion memory ADS . Since the images are generally overlaid according to simple rules, a simple logic and arithmetic circuit can also be used as the address converter.

FIG. 4 shows an address converter in which the image memory addresses are not stored, as in the arrangement according to FIG. 2, but in which they are calculated. For each sub- picture there is an arithmetic and logic circuit RLa, RLb, RLc, RLd , which contains four subtractors SUB 1 , SUB 2 , SUB 3 , SUB 4 , which show the differences between the coordinates given by the display device computer SGR and the coordinates of the corner points of the form each drawing. For example, the coordinate differences x - x ₁₁ , x - x ₁₂ , y - y ₁₁ , y - y _{12 are} formed in the computing and logic circuit RLa . These coordinate differences are fed to a logic circuit LG which generates an enable signal when the current coordinates x, y output by the visual computer SGR lie within the field. This release signal is fed to a priority decoder PRD , in which is entered the priority with which the partial images are to be displayed, for. B. which drawing file must not be covered and which drawing picture can be covered by all other drawing files. In the example of FIG. 1, for. B. the field Bc the highest priority, the field Bd the second highest, the field Bb the third highest and the field Ba the lowest priority. The priority decoder PRD can be a read-only memory. Its output signals control switch S , which are supplied by adders ADD image memory addresses. These are formed for the partial image Ba by adding the base address a ₀₀ and the coordinate differences x - x ₁₁ , y - y ₁₁ . Of the addresses thus formed, the address belonging to the field with the highest priority is switched through by the switch S to the address input of the image memory BSP .

Claims (2)

1. Viewing device control with an image memory (BSP) , in which more image data are stored than can be displayed in an image on the screen of a viewing device (SG) , and with a viewing device computer (SGR) providing screen coordinates, characterized by

• - The image memory (BSP) contains several areas (SPa, SPb, SPc, SPd) , in each of which the information for a field is stored;
• - memory between the vision computer (SGR) and the image (BSP) is an address converter (ARU) geschal tet, the screen are supplied to coordinate the vision computer (SGR) and which forms addresses from image memory such that image data from Various NEN image memory areas ( SPa, SPb, SPc, SPd) are called up and displayed on the screen of the display device (SG) .

2. Arrangement according to claim 1, characterized in that the address converter (ARU) is an address memory (ADS) containing at least one address table , to which the screen coordinates are supplied as addresses and in whose cells the image memory addresses are contained.