DE2952419C2 - Arrangement for displaying curves on the screen of a display device - Google Patents

Description

a) an area of the symbol memory (SS) is available for each drawing space provided for the curve display;

b) for each character space provided for the curve display, a cell of the image memory (BS) is provided, the content of which is the partial address of the associated symbol memory area, which is completed with the Slanci of the raster line counter (RZ) of the image counter (ABZ) ;

c) there is a computer (RE) available, the curve values present as coordinates (xy) of a curve field (KF) formed by the door, the curve display provided by the door, the curve values present in the symbol memory, the coordinates (xy) in symbol memory addresses assigned in character position raster lines ( SSA) and converted into one pixel column position (.?) Each, which acts on the input / output register (EAR) , in which a light button information is entered in the pixel column position (.v) and from which the signal combination is written into the addressed memory area.

2. Arrangement according to claim I _1, characterized in that the computing circuit (RE) is designed in such a way that it forms the symbol memory addresses (SSA) and the pixel column positions (.?) To be provided with a light key information according to the formulas:

_r

SSA = SSB + yi- X + y and s = / J--

I *

where x, y are the curve field coordinates transformed to a reference point, SSB is a base address,

X - G \ - the integer part and R - the incomplete remainder of the ratio of the coord: -

nate χ the number of raster spaces contained in a character space and the number of raster lines contained in the curve field.

3. Arrangement according to claim 1 or 2, characterized in that for shifting image points from curves perpendicular to the row direction the contents of the symbol memory cells into other memory cells be rewritten, the new addresses depending on the direction of the shift by one or larger are smaller than the old addresses.

4. Arrangement according to one of claims 1 to 3, characterized in that for the pixel-by-pixel shifting of curves in the row direction, the contents of the symbol memory cells are shifted by one place to the right or left depending on the direction of the shift and the contents of the last or the cells pushed out The first digit must be entered in the first or last digit of the cell that has become free as a result of the movement, the address of which is greater or smaller in relation to the number of raster lines yi of the curve field (KF).

The invention relates to an arrangement for displaying graphics on the screen of a after the display device operating with the line raster method according to the preamble of claim 1.

The images displayed with data display devices generally consist of alphanumeric characters and Symbols. Often, however, they also contain graphics, such as curves, diagrams, or other symbols, Signs and texts.

For the representation of digital values as curves on the screen of a display device, one can proceed according to DE-PS 10 84 954 so that a memory location with a capacity of at least 1 bit is assigned to each possible pixel on the screen and the memory locations are synchronously milder The electron beam scans the screen. In accordance with the stored signals, the electron beam is scanned light or dark. With a resolution in the abscissa and ordinate direction of 256 possible points each results in a memory requirement of about 64,000 words. If the curves are to be manipulated independently of one another, a separate memory must be provided for each curve, so that not only a considerable amount of hardware but also a large amount of software and a very fast processor are required.
This Aufwnnd can be reduced if, as known from DE-OS 2541 104, every possible

A point on the abscissa is assigned a digital value. The digital values are stored in the refresh memory. The abscissa of the pixels can, for. B. be the address of the refresh memory and the ordinate the content of the respective memory cell. In order to generate the individual pixels, the ones that are saved are saved Digital values with the current deficit given by the reading of a column and a line counter. location on the screen is compared, and if there is a coincidence, a light pulse is generated. This arrangement s tion enables, especially if a curve memory is permanently assigned to each curve, with little software effort a representation of curves, but also requires a large amount of hardware.

So-called microvectors are used for a type of curve display described in DE-OS 2413 680 used, code signals for microvectors are permanently programmed in the symbol memory. By appropriate Curves can be displayed if these vectors are lined up. Such a curve display does not require any significant additional in a display device prepared for character display Hardware overhead; however, only a rough curve display is possible, even if a large one Number of microvectors is stored. Another disadvantage is that it is difficult to cross curves are to be realized.

In DE-OS 2541104 it is also described, the representation of curves on a part of the screen, the so-called curve field to restrict. For this purpose, a curve field decoder is provided in which the coordinates the boundary points, preferably the corner points of the curve field within which the curves are shown are to be entered. The curve field decoder switches control pulses to the display of the curves causing units when the contents of a Rarter counter match the coordinates of a curve field lying pixel.

From "NTZ-Report 15 - data display devices", VDE-Verlag, Berlin 1973, pages 22 to 3 i got it. sign to represent within character spaces that consist of a larger number of pixels, e.g. 7 X 10 pixels, exist. The light button signals for character display are contained in a symbol memory, the is addressed by a character position counter via an image memory. The character space counter gives each Number of the character position on which the electron beam hits. The image memory has each character space a memory cell containing the character to be displayed at the associated character space in the form of a Contains symbol memory address. The image and the symbol memory are therefore each called once, when the electron beam hits the associated character space, which consists of several pixels.

Since with this known arrangement restrictions in the display options of graphics are accepted must be taken, curves or other graphics are generally displayed pixel by pixel, d. This means that the curve memory is to be interrogated when scanning every pixel. Because of these different The modes of operation of the memory for curve and character display have been set up up to now Arrangements for the mixed representation of curves and alphanumeric characters or other symbols with separate memories for the display of characters and curves (DE-OS 2836500).

The present invention has for its object to provide an arrangement with the curves and alphanumeric characters are displayed with little effort without restrictions on the display options can be, the resolution of the curves only given by the limited number of pixels is.

LirllndrngsgcmäU this task with the measures specified in the characterizing part of claim I. solved.

In the new arrangement, no separate curve memory is required for displaying curves, because the image and symbol memory not only for the character, but also for the curve display be used. With the exception of the simple arithmetic circuit, there is therefore no additional work involved in displaying the curve necessary compared to an arrangement for pure character representation.

The image memory is used to convert the character space numbers into symbol memory addresses by giving it the number of the character space covered by the electron beam is supplied as an address and he outputs the content of the addressed cell as the address of that symbol memory cell in which the information to light the electron beam are contained in the respective character space hit. the Calculation rule according to which the arithmetic circuit converts the curve values into brightness information, hang! from the numbering of the character spaces and the relationship between the character space number and Symbol memory address that is largely freely selectable.

The invention and further advantages and additions are described below on the basis of an exemplary embodiment described and explained in more detail.

Fig. 1 illustrates the representation of curves on the screen of a viewing device.

Fig. 2 shows schematically an arrangement for mixed curve and character display.

In Fig. 3 shows the graph. The F i g. 4 and 5 show in connection with FIG. 3 details the addressing of the image and symbol memory cells as well as the storage of the light button information.

In Fig. 1 is denoted by KFe'in curve field which is reproduced in a partial area of an image displayed on the screen of a viewing device. In the area outside the curve field / ^ only alphanumeric characters and other symbols should be displayed, e.g. at the points marked with A. Within the curve field KF , two curves 1 and II are displayed and, in addition, arbitrary: Characters, for example in places also marked with an A. The characters are each positioned in a character space, which in the exemplary embodiment consists of 8 x 8 pixels. A total of 352 drawing spaces are provided, which are arranged in 16 drawing lines and 22 drawing spaces. The K'irvenfeld KF'isl is bounded by the character spaces SPS and SPiI as well as by the characters / lines Z4 and ZIl. The curve field therefore consists of 8 X 8 drawing spaces, which are also called curve elements in the following. The character spaces are numbered, in columns from top to bottom, so that the corner points of the curve field KF are formed by the character fields 84, 91, 396, 203. The screen of the display device is to be scanned line by line, e.g. B.

along the lines of characters. Since each drawing area consists of 8 x 8 pixels, the electron beam runs eight times over each character line, whereby each scanning line can be lighted eight times in each character field. The curve field is therefore 64 X 64 pixels, so that 64 curve values with 64 amplitude levels can be displayed. In practice, one will generally choose larger curve fields, e.g. B. from 128 x 128 Pixels in order to achieve a higher resolution. You can also use several small curve fields the image will be spread out.

The arrangement according to FIG. 2 contains a viewing device 56 ', on whose screen images of the in FIG. 1 are to be reproduced. It receives the pulses required for operation, such as blanking and synchronizing pulses, as well as light key signals from a video signal generator KVC, which also has an image counter ABZ

ίο controls. This consists of a character column counter ZS, a raster line counter RZ and a character line counter ZZ, which the character space. indicate the drawing line and the razor line within the line of characters onto which the electron beam is being deflected. Character line and character column counters therefore indicate character locations; their combination is therefore called a character position counter. In the exemplary embodiment, each pulse supplied to the column counter ZS has the value 16 and each pulse is assigned to the line counter. led to the valency 1. The character space numbering selected in FIG. 1 is then obtained. If the input pulses of the counter ZS are given the value 1 and those of the counter ZZ the value 22, a line-by-line numbering is obtained. All three counters are reset with each frame reversal and during the scanning of the in Fig.! Darse-represented screen area for clock pulses of the video signal generator KSC released, whose period is equal to the time it takes the electron beam to scan a character field in lines direction needs. It therefore receives the first pulse when the electron beam first zeroed the character field times hits.

The contents of the two counters ZZ and ZS are supplied as an address to an image memory BS in which a memory cell is provided for each character space. To display characters, these cells each contain a code signal for the character that is to be displayed at the associated drawing station. This code signal is over a changeover switch USX is supplied to a symbol memory .SSaIs base address, which is supplemented by the status of the raster line counter RZ guided by a second changeover switch US1 . Eight addresses are therefore formed for each character field, and words of 8 bits are read from the associated cells, which specify the lelligkcits information at the eight pixels of the individual raster lines within a character space. These words are fed to the video signal generator via an input register EAR, from which the

Video signal forms.

A storage capacity of 8 × 8 bits is provided in the symbol memory SS per curve field element for the curve display, which is divided into eight cells with a capacity of 8 bits each. These symbol memory cells, like the cells which contain light-key signals for displaying characters, are called up via the image memory BS . It is specified in the image memory where on the screen the curve field is to be located by entering the image memory memory cells with the numbers of the character spaces in the curve field, the basic addresses of the symbol memory are entered in which the light button information for the curve display is contained in these character spaces.

In FIG. 2, the areas of the image and symbol memory which are used for the curve display are shown hatched. In the image memory area with the addresses 0 to 15 for the column SPO and with the address Sen 16 to 31 for the column SP1 and for the following three columns only contain code words for character representation. In contrast, the memory area for the PLC column with cells 84 to 91 contains basic addresses of the symbol memory, e.g. B. the addresses 2048,2056,2064 etc. to 2111. These addresses are supplemented with the status of the Rasler counter RZ , fed to the symbol memory SS, where the cells 2048 to 2111 of the area for the column PLC are called at the appropriate time. The contents refer accordingly of the image memory cells 100 to 107, ... 196 to 203 to symbol memory areas in which the helical information for the curve display is contained in the columns SPS to SP12 as signal combination ions.

The representation of curves is explained in more detail below with reference to FIGS. 3, 4 and 5. Fig. 3 shows enlarged the in F i g. 1 character spaces marked with 120 and 136. Each character space consists of 8X8 pixels, of which the crossed ones are lighted to show the curves I and II. The Helltastinforma- tion for the clock location 120 is contained in cells 2208 to 2215 of the symbol memory SS (FIG. 5), never, for example, by entering a log. "1" marked places of the storage cells are an image of the Kurveripunkic. The same applies to the memory cells 2272 to 2279, in which the light button information for the character space 136 is contained. The addresses of the image memory BS (Fig. 4) match the character space numbers. The image memory SS is supplied as an address with the number of the character space that derElek electron beam just hits. Accordingly, cell 120 is called when the electron beam hits the character place 120 scans. The symbol memory address 2208 is in the image memory cell 120, so that when the top line z0 of the character space 120, the raster counter ÄZ being 0, the symbol memory address 2208 being called. The signal combination in this symbol memory cell (digits 0 to 2 and 4 to 7 contain log. "0", the position 3 log. »1«) is fed via the input / output register.

6 (i supplied via VSG after parallel series conversion, so that the fourth pixel of the top line of the character space 120 is light-scanned.

When the electron beam is transferred to the character space 136, the image memory cell 136 is called up and the symbol memory receives the address 2272. No position is marked in the cell with this address, the electron beam remains blanked. After scanning the top line of the character field 136 runs the electron beam continues to the right edge of the picture. With the Horizontairrückiaui "the reading of the raster counter AZ (Fig. 1) is increased by one. If the line z \ of the character space 120 is then scanned, the base address 2208 is read out again from the image memory BS One, is incremented so that the symbol memory has the address 2209. The contents of the cell with this address

In the case of the curve limit shown, this coincides with that of cell 2208, so that in the / wcilobcrslen line of drawing area 120 the pixel is hidden, which is below the previously bright button in the topmost cell. The other cells of the symbol memory "" are read out in a corresponding manner and image points are lightly loaded, whereby all eight positions of a cell can be marked. Hs can therefore be shown clicbigi * figures. %

In the exemplary embodiment, the relationship / between the / cicheiiplat / numbers and basic symbol storage addresses is established in that the curve field elements as well as the character spaces are in columns from above; are numbered below, their numbers are multiplied by the number of box lines contained in a drawing space (8) and added to a base address (2048) . Accordingly, the character location 84 has the curve field element number 0, and the associated basic symbol memory address is 2048. The character location 91 has the curve Icldelemenlnummer7, and the basic value is 2048 + 8X7 = 2104. The character location 119 has the curve field element number 19, this results in the base address 2200, and the character locations 120 and 136 have the curve element numbers 20 and 28, with which the basic addresses 2208 and 2272 are obtained.

It is not necessary for all curve elements to be assigned symbol memory addresses in this way. Especially when no curve runs through a curve field element, an alphanumeric character can be displayed at this location, for example the letter B in character location 118 , which is located in the symbol memory under the base address 956.

The numbers Z / TV of the character spaces and thus the image memory addresses that are intended for the curve display are can be ciicCuMct according to the relationship

ZPN = KPO + ZN- X + Y (O = s X <■ XN, O ^ Y <YN)

In this equation, KPOä \ t mean the lowest drawing place number in the curve field, in the embodiment according to FIG. 1 this is the drawing position 84 in the upper left corner of the curve field, ΖΛ / the number of drawing lines on the screen, in the example 16, Λ 'the respective curve field element column , K the respective curve field element row, Af / V the number of curve field element columns and YN the number of curve field element rows.

The symbol memory addresses SSA assigned to the curve field are to be entered in the image memory cells with these addresses according to the formula

SSA = SSB + zm \ ZPN - KPO - (ZN- YN) ■ G \ ^ZFN ~ ^KP0

ZN SSB is the base address of the symbol storage area, which is reserved for the curve display, zm the

Number of raster lines ic character field, G

ZPN - KPO ZN

is the integer part of the when dividing the

Difference of Zeichenplalznummern APN and KPO formed by the number of character lines ZN w result. The two relationships given can be realized with arithmetic circuits, one of which determines whether the respective character space is in the curve field and of which the second indicates which signal combination is to be entered in the respective image memory cell as the address for the symbol memory. In the arrangement described, the curve field elements are assigned symbol memory addresses that are ascending in columns from top to bottom. Of course, other assignments are also possible.

Digilal objects that are to be represented as curves are generally specified as coordinates, in the case of representation in a curve field as curve field coordinates. According to the present invention, the Digilalwcrtc are entered in the symbol memory. The curve field coordinates must therefore be converted into symbol memory addresses and symbols. It is assumed that the symbol memory cells each store the last information for a raster / line of a / cichonpiut / irs. In the following, the transfer of curve values to the symbol memory is explained in more detail. Ks should z. B. in the second bottom line of the / cichcnfcldcs 120, which is marked with a circle / calibration point of the curve I can be entered in the symbol memory (Fig. 3). The curve coordinates of this point are .v 23, y ^; 25, if the origin of the coordinates is in the lower left corner of the end of the curve iicgi. These coordinates are fed to the computing circuit RE ( FIG. 2) from outside, for example from a measuring device. Advantageously, a coordinate transformation is first carried out in such a way that the origin of the coordinates lies at a certain point on the curve area, /.B. at its left upper back, where the line.! »= O is the uppermost razor line in the curve field and the line .v = U runs on its left edge. With regard to this origin, the coordinates are then .v = .ν = 23, y = .1'O - v * = 63 - 25 - 38. The relationship then applies to the symbol storage spaces

SSA = SSB + zm- X- YN + y,

where X = G - the integral part of the division of the abscissa χ by the number of .Ader columns of a line _L s * j

space and W is the number of curve field element lines. In the example chosen, the base address is SSB = 2048, the number of raster lines zm per character space is 8, the number of curve field element lines is also 8 and

:: the integer part X = G \ ~ = 2. This results in the symbol memory address 2214. In the memory

: <v L ⁸ J

t; cell with the address calculated in this way, a position must be marked that is determined from the relationship

5 r η

■ s = R \ - , that is the non-integer remainder of the division -, in the exemplary embodiment -. It is therefore the place V7

}; W ■ * ⁸

i, to be marked in memory cell 2214 (Fig. 5).

: K 'The input / output register of the arrangement according to FIG. 2 is designed so that the content of each called Memory cells only the marked position is changed. The content of the target is read out The calculated position is marked and the signal connection thus formed is then written back into the same cell.

The integral part G and the remainder R can be determined by repeated subtraction with the number of gaps.

,) 15 telt, after each subtraction it is checked whether the subtraction result <0 is. Isn't this the one

If so, the content of a first register is increased by one. If the subtraction result is <0, sk is added to this value and the result is entered in a second register. In the first register there is then the

■ '2 integer part G -, in the second register the remainder s =

^: ■; Moving curves where the new value is always on the left or top edge of the curve field

j .: appears and the rest of the curve is shifted one pixel to the right or one down,

fp can be implemented by relocating curve points. To move to the left to point to the picture

Ϋ? 25 the contents of the Symbolspcichcr / .cllcn z. B. read into a shift register and the content to the left

; re-entered shifted by one position. The marking, which as a result of the shift, is no longer

'φ the same cell can be written back, is in the right place si of the memory cells with the addresses

I * SSA = SSAO- we entered, where SS AO Ute is the address of the cell whose content is one position to the left

jjg was pushed and yi is the number of razor lines within the curve field. Hei a shift in the

f | JO curves to the right calculates the address into which the marking shifted to the right out of the rushes

f | redeem according to the formula SSA SSAO + yi. Of course there is such a rewrite

ΙΪ of curve values does not take place if curve points outside of the curve area were displayed as a result.

i | When shifting upwards, the entire contents of the memory cells are rewritten, with the

• | The new address is SSA = SSAO- 1, provided SSAO * SSB + rjyi (n = 0, 1 ... XN) or SSA ¥ SSB + {yil ) + / i Wist.

ψ 35 A downward shift is achieved by readdressing SSA-SSAO + 1. This readdressing

§ is only carried out if SSAO ¥ SSB + {yi- \) + nyi or SSA ¥ SSB + η- yi . The move

% of the curves is, of course, simpler if not shifted by point to point, but shifted by characters

The main advantage of the arrangement according to the invention is that the same picture 40 memory and the same symbol memory as used for character display and that this memory can be addressed in the same way for the curve display as for the character display. the Curve display therefore only requires a small amount of additional hardware and no major software effort than the pure representation of characters. Another advantage of the arrangement according to the invention is that the curve field is freely positioned like the alphanumeric characters and, like these, columns and lines 45 can be moved anywhere on the screen. This is particularly important for the display of so-called Large pictures in which the picture memory is designed for more character spaces than on the screen available. By redirecting the image memory, the memory that is visible on the screen can then Section can be moved over the large image. With such a shift, curves and characters treated equally.

50

For this purpose 2 sheets of drawings

M)

Claims (1)

Patent claims: 1. Arrangement for displaying curves on the screen of a display device working according to the line raster method with an image memory (BS), the memory cells of which are each one from a previous s given number of pixels are assigned to the existing character space by being addressed by a character space counter (ZZ, ZS ) contained in an image counter (ABZ) , the status of which is changed synchronously with the deflection of the electron beam and in each case indicates the character space hit by the electron beam and the memory cells of which each contain a code signal, and thus a symbol memory (SS) which can be addressed with these code signals and rasper line signals of the mapping counter (ABZ) , in the memory cells of which signal combinations are contained which represent bright key information for the image points next to one another in a line of a character space and its input / output Output register (EAR) outputs the content of the symbol memory (SS) when it is displayed on the screen of the display device (SG) , characterized by the following features: