NO126191B - - Google Patents

Description

Device for displaying characters or symbols on the screen i

a rendering device.

The invention relates to a device for displaying characters

or symbols on the screen in a display device, comprising a clock generator, a counting chain and one of these controlled control stages which is connected to a storage device for storing the characters and symbols

the boles and with a character generator for the periodic production of the characters and symbols corresponding modulation voltages for producing these on the reproduction device, as well as a device for producing

raise characters or symbols on the screen.

In modern electronic data processing facilities it is

increasing use of equipment that is based on light effects for offal

ning and extraction of data that is used to exchange information between man and machine in a simpler and faster way. When this information is displayed in the form of symbols, characters and/or letters on

a light-emitting surface, is an appropriate device for satisfactory reading of great importance. An appropriate reading is possible with the help of suitable proportions of the displayed image. In addition, it is very advantageous, if possible, to use devices that highlight certain parts of the information in relation to the rest of the image's content in order to attract attention, e.g. to very important parts of the information on the image surface.

With previously known devices, certain signs and groups of signs can be accentuated by means of flashing, i.e. that the brightness of the image surface appears to vary at a rate of approx. 1 - 10 Hz for the observer, as the ratio between light and dark can be changed as desired. However, this method is not advantageous because flashing characters can irritate the observer and give him the impression of shaking of the whole picture. There are also methods where special symbols and signs are accentuated by underlining them, but this means a limitation with regard to the clarity of the reading.

The purpose of the present invention is to accentuate parts which are permanently adjustable and which are selected by control information for the light-emitting surfaces by means of a given brightness as a contrast to other parts with symbols.

This is achieved according to the invention by the fact that an inverter is arranged between the character generator and the rendering device to highlight characters or symbols, and that for controlling the inverter this is connected to the counting chain which contains a column, a character, a scanning line and a reading line counter.

Production of the active and passive parts takes place from line to line or column to column over the entire light-emitting surface on which the symbols, letters or numbers are to be displayed.

The information to be displayed is used as an image signal for controlling the brightness of the device that is to emit light. Symbols to be accentuated on the image surface can be automatically inverted in brightness, i.e. normally dark pixels in the image can be inverted to light pixels and bright pixels

can be inverted to dark pixels.

The device according to the invention is particularly suitable for inserting permanent stripes or lines of different brightness between characters which are arranged in lines, so that a horizontal division of the entire image takes place to achieve better readability.

Furthermore, an image impression that is more pleasant for the city can be achieved by means of a slight increase in the brightness of the entire image background, which appears as a weak gray background. This happens in a simple way by adding a constant signal to the image signal.

To explain the invention below, the image screen in a cathode ray tube is used as an active light-emitting surface and the electron beam in the tube is used as the production of light emission.

Alternatively, however, it is possible to use a passive light-emitting surface which is brought to light up by means of a digit light deflection device which serves as a light source. In this case, however, it is the case that all the lines in the surface are formed by points located at a small distance from each other which are light-control modulated, and coherent scanning lines and reading lines are also possible in an active light-emitting surface.

Some embodiments of the invention shall

is explained in more detail with reference to the drawings.

Fig. 1-7 schematically show different possibilities of image proportions according to the invention. Fig. 8 shows a block diagram for a device according to the invention where signs and symbols can be displayed on the image screen in a cathode ray tube. Fig. 9 - 13 show embodiments according to the invention for addition to the device in fig. 8.

1. Application of sliding fields.

A sliding field marks the position where symbols or signs are to be inserted on the image screen by the observer, e.g. using a keyboard. In the case of corrections in the text, the observer moves the slider to the position where a correction is to be made or where a character is to be rewritten. The position marked by the slider must be highlighted in the image because changes to the image content take place in this position. This position must be marked as clearly as possible, but must not impair the clarity of a sign to be reproduced in this position. Fig. 1-3 shows how the sliding field clearly and easily marks the position by means of inversion of the image signal.

In fig. 1, a blank position is marked and in fig. 2 and 3 is a character marked in the sliding field C. Fig. 1 and 2 show black characters on a white background,_ and fig. 3 shows white characters on a black background. In this example, the individual characters are shown using a grid consisting of seven horizontal and eight vertical pixels.

2. Highlighting of certain parts of the image

which occupy symbols or signs.

To separate sent and received information, a transition from red to black text can be achieved, e.g. in a teleprinter exchange, so that e.g. manually entered and sent data can be displayed in black and white and data sent by the data processing device can be displayed in red on white. The device according to the invention enables different displays in a similar way. Received information is displayed e.g. white on black, while information originating from the user of the device is displayed in black on white. In fig.

4, the third line is displayed in white on a black background/while the others

lines are shown in black on a white background.

3. Vertical lines.

Vertical lines can be drawn in the image's vertical direction by means of inversion of the image signal in a time period that corresponds to the width of one or more image points. This makes it possible to display particularly tabulated addition in the usual way. These lines are made narrower than horizontal spaces between two characters, (e.g. the width of an image point), so that the image content is not disturbed. The vertical lines can be used to mark tab positions, e.g. when the tab function is engaged using a special key on a keyboard, the slider C will move behind the position of the next vertical straight line. Fig. 5 shows how such a tab marking becomes clear. In image areas with white on black, the vertical line V automatically appears as a white line on a black background.

4• Horizontal lines.

By inverting the image signal during the period when the beam drawing the image is in a horizontal space, the line above the space can be emphasized as shown with H. In this way, titles can be highlighted. Tables with subdivisions or lines that are fed into the data processing equipment can be marked. This possibility is shown in fig. 6.

5• Highlighting the space between lines.

For better readability of the displayed text, especially tables or several lines of text, it is recommended to subdivide the image on the screen into horizontal strips to guide the city during the reading. This can be achieved by the image screen having a strip-like structure so that, as shown in fig. 7> the characters appear black on a white background, while the horizontal spaces Z are grey. This gray shading of the bright horizontal spaces is particularly advantageous because the image shows a much smaller flickering effect. In a similar way, dark spaces can be made brighter to some extent by displaying information consisting of characters in white or black. With this method, it has also been shown that when the entire background is somewhat lighter, the observer has the impression that the image is muted in a pleasant way without affecting readability. As mentioned under points 1 and 4", in the case of inversion of the image signal, this can be done

the image clearer on is used to highlight special parts of the image, e.g. columns of arbitrary width in tables, especially if different gray values are used whose hue can still be clearly distinguished from each other.

In fig. 8, a control signal BAS which is composed of an image signal B, a blocking signal A and a synchronization signal S is produced for use in a television monitor TV. A counting device comprising a column counter SpZ, a character counter ZchZ, a declination line counter LZ and a reading line counter Z1Z is controlled by a time signal generator TG. The column counter SpZ controls the columns in the image raster that will display a character, the character counter ZchZ controls the position of the character in a reading line, the scan line counter LZ controls the separate scanned lines in a character, (the electron beam descends in horizontal paths) and the reading line counter Z1Z determines the reading lines in the complete image. This counting device controls the blocking stage A, the synchronizing stage Sy and a control stage St. The stage A produces image blocking pulses and the stage Sy produces synchronizing pulses, while the control stage St, which is also connected to the timing signal generator TG, controls a storage device Sp and a character generator ZG. The image signal B, i.e. the character control signal from the character generator ZG, is supplied through an inverter stage CI which is active or inactive in accordance with the observer's choice, to an input in a port P whose other input is supplied with the blocking signal A. If a character is displayed, the inverter CI serves to produce directional signs for an image area that should emphasize horizontal or vertical straight lines and to vary the image background. The combined frame blocking signal BA and the synchronization signal S are combined in a mixing stage M to provide a frame blocking synchronization signal BAS. The signs to be displayed are kept in readiness in a storage device Sp. Information is exchanged between the storage device Sp and a data processing system through the line E/A, as the observer can vary the image content with the help of a keyboard Ta and a line T. Characters that are coded with the least possible bid in the storage device Sp> are converted into an image signal B i the character generator ZG which for this purpose supplies a corresponding modulation voltage to the electron beam in the monitor.

Fig. 9 shows a block core for generating direction signs. The positions of slide field counters ZC1 and ZC2 whose positions can be selected manually using the keyboard Ta and which are indicated by the key contacts Cl and C2 are compared in two comparison circuits VC1 and VC2 with the positions of the character counter ZchZ and the reading line counter Z1Z. In the case of the same positions of the counters which are connected to each other through comparison circuits, a signal is supplied through an AND gate U to a directional control stage CSt. The vertical dimension of the scroll field on the image screen is limited by the offset line counter LZ with the character height plus e.g. a line above and below the character. The heating control stage CSt controls the inverter CI which inverts the image signal B supplied by the character generator

ZG (fig. 8) for a specific duration by operating the inverter CI (B or

Fig. 10 shows the construction of the various components in detail. NAND gates 1, 2, 3 and 6,7 and 8 compare the positions of the various counters ZchZ, ZC1, Z1Z resp. ZC2 in the comparison circuits VC1 VC2. As these counters comprise different sub-stages which are provided with flip-flop circuits, it is necessary to have a connection group corresponding to the NAND gates 1, 2, 3 and 6, 7, 8 for each pair of flip-flop circuits, as the output from these NAND gates is connected to an input in the NAND gates 4 and 5 which are provided with several inputs. Gate 4 thus marks a column, gate 5 a reading line and a NAND gate 11 which, through two inverters 9°g 1°, is connected to the outputs of gates 4 and 5, marks the position where the sliding field is to be displayed on the image screen. The width of the slider is equal to the width of the character that should normally be displayed, plus half a horizontal space before and after the character. The height of the sliding field is determined by the control stage CSt in that the gate 11 through an inverter 12 is connected to an input in the NAND gate

15 which is different from the one connected to the line counter

LZ through an SR flip-flop circuit (eg a bistable multivibrator) formed by NAND gates 13 and 14, so that the shift field is limited to the desired number of sweep lines. The NAND gate 15 is connected respectively directly and through an inverter 17 with the NAND gates resp.

19 and l8 in the inverter CI. The image signal B is supplied respectively through an inverter 16 and directly to the ports or 18 and 19, and the outputs of these are connected to the inputs of a NAND gate 20. The inverter CI controls the image signal B in such a way that it reaches the mixing stage M in the course of a normal image through the gates 19 and 20 and therefore in

not inverted form B, but B is inverted in ports 16, 18 and 20 during the time when the steering signs are displayed on the image screen.

Devices for proportioning the image using accentuated image parts, vertical and horizontal lines as well as gray stripes shall be described below only in principle. Fig. 11 shows a device where arbitrary image parts can be inverted. The counters ZchZ, LZ and ZIZ correspond to those shown in fig. 8. The character counter ZchZ is connected to a decoder DI which is also connected to the control stage St. The scan line counter LZ and the reading line counter ZIZ are connected to a decoder D2 which is also connected to the control stage St. The counters affect the decoders Dl and D2 in such a way that the beginning and the end of the inverted range for horizontal (ah resp. eh) and vertical (av resp. ev) direction is determined by the control stage St. Two nflip-flop circuits formed by NAND gates 21, 22 and 23, 24 and which are connected to the decoders D1 and D2 control an inverter which corresponds to the inverter CI in fig. 10 through an AND circuit 25. Since the control stage St is connected to the storage device Sp for the entire image content, arbitrarily large image sections can be inverted if desired, e.g. when more information units are added for proportioning the image in each readout line. Fig. 12 shows a device for producing horizontal or vertical straight lines on the picture screen. The operation corresponds to the operation of the device in fig. 11. In this case, however, the flip-flop circuits are not necessary because only one readout line and the pixels in one column are inverted. The column counter SpZ and the character counter ZchZ are connected to a column decoder DSP, the decoder being denoted by DZ for the counter LZ and ZIZ. The column decoder DSP and the reading line decoder DZ

acts as an inverter corresponding to the inverter CI in fig. 10, through an OR gate 26.

The devices described can alternatively be used to control the gray tone of the image background. Fig. 13 shows an example of a mixing step M (see Fig. 8) which is extended in such a way that a gray control step G makes a dark image background brighter and a light image background darker. In the mixing stage M, the synchronization signal S controls a transistor T-^ °§ the image blocking signal BA controls a transistor Tg. The emitter of the transistor T-^ is connected directly to ground while the emitter of the transistor Tg is connected to ground through a variable resistance P-^ in parallel with the collector-emitter circuit of a transistor T0 3 in series with a resistor R0 D. The collector of the transistors T- ^ and Tg and in a transistor T^ whose emitter is connected to ground through a variable resistor Pg, is connected through a resistor R-^ to a terminal for a voltage source +V and is in that case connected to a television monitor. The base of the transistors T^ and T^ is connected to the gray control stage G. The black level is fixed

at the resistance R^ when the transistor T^ is conducting. Normally, transistor T^ is conducting and transistor T^ is off. If the gray value is to be provided on a black background, the transistor T^ is blocked and the degree of brightness increase can be set by means of the variable resistance P-^. If the gray value is to be provided on a light background, the transistor T^ is conductive and the degree of the gray tone can be set using the variable resistor Pg.

The beginning and end of the variation of gray-

the tone occurs with the help of the control stage St through the lines a and e to the gray control stage G, but it must be taken into account that the gray control must not occur during the blocking signal A without the amplitude of the synchronization pulses S being regulated. In addition, a control input g must receive a signal 1" from the control stage St if there is dark text on it

light background and a signal <n>0" if there is light text on a dark background. The control input g is connected directly to the UANIT gate 2b and through an inverter 27 with NAND gates 29. The other inputs<g>s in the parts 23 and 29 is connected to the outputs of a flip-flop circuit which is formed by NAND gates whose inputs are connected to lines a and e. The output from gate 29 leads to transistor Time's output from gate 28 leads to transistor T^ through an inverter 3°«

Claims (8)

1. Device for displaying characters or symbols on the screen in a display device, comprising a timer, a counting chain and one of these controlled control stages which is connected to a storage device for storing the characters and symbols and to a character generator for periodically generating the characters and the symbols corresponding to modulation voltages for generating these on the display device, as well as a device for highlighting characters or symbols on the screen, characterized in that d* for highlighting characters or symbols, an inverter (CI) is arranged between the character generator (ZG) and the display device (TV) , and that for controlling the inverter (CI) this is connected to the counting chain which contains a column -(SpZ), a character -(Zch Z), a scan line -(LZ) and a read line counter (ZIZ). 2. Device according to claim 1, characterized in that the reproduction device (TV) is provided with a cathode ray tube and is connected to the output of a mixing stage (M) which is connected to an image increase stage (A) controlled by the counting chain and a synchronization stage (SY) and through the inverter (CI) with the character generator (ZG). 3" Device according to claim 1 or 2, characterized in that a comparison circuit (VC1 or VC2) is connected to the character counter (ZchZ) and the reading line counter (ZIZ) which is also connected through pressure switches (Cl, C2) with selectable 1 direction -teen counters (ZC1.,ZC2), both comparison circuits being connected through an 0G gate circuit (U) to a directional control stage (CSt) which is'-connected to the inverter (CI).. 4. Device according to claim 3" characterized in that the direction control circuit (CSt) contains the bistable multivibrator (13, 14) controlled by the line scan counter (LZ) whose output through ai NAND gate circuit (15) is connected to the output of the comparison circuits (VC1, VC2). 5" Device according to claim 2, 3 or 4, characterized in that the comparison circuits (VC1, VC2) consist of sequentially connected NAND gate circuits (1-10) which are interconnected through a further NAND gate circuit (11). 6. Device according to one of the preceding claims, characterized in that the character counter (Zch Z) is connected to a decoder (Dl) controlled by the control stage (St) and the scanning line counter in (LZ) and the read line counter (ZIZ) are connected to a second, aviy re-stage (St) controlled decoder (D2), and that the outputs of the decoders (Dl, D2) are connected to bistable multivibrators (21-24) whose outputs through a NAND -gate circuit (25) is connected to the inverter (CI). 7. Device according to one of the preceding claims, characterized in that the column counter (Sp Z) and the character counter (ZchZ) are connected to a column decoder (DSP), and the scan line counter (LZ) and the read line counter (ZIZ) are connected to a line decoder there (DZ), and that the outputs from the decoders (DSP, DZ) are connected to the inverter (CI) through an OR gate circuit (26). 8. Device according to one of the preceding claims, characterized in that for grayscale change of the image background, two transistor amplifier stages (T2, T3 or T4) with adjustable gain are arranged in the mixing stage (M), whose inputs are through NAND gate circuits (G, SR ) is connected to the control stage (St).